Transcript
Modern Steels and their properties Carbon and Alloy Steel Bars and Rods Another Customer Service of
Akron Steel Treating Company
Since 1943
Combining Art & Science for Solutions that Work
MTI STATEMENT OF LIMITED LIABILITY (Please Read Carefully) (Standards Adopted by the Metal Treating Institute, inc.) ALL WORK IS ACCEPTED SUBJECT TO THE FOLLOWING CONDITIONS: It is recognized that even after employing all the scientific methods known to us, hazards still remain in metal treating. THEREFORE, OUR LIABILITY SHALL NOT EXCEED TWICE THE AMOUNT OF OUR CHARGES FOR THE WORK DONE ON ANY MATERIAL (FIRST TO REIMBURSE FOR THE CHARGES AND SECOND TO COMPENSATE IN THE AMOUNT OF THE CHARGES), EXCEPT BY WRITTEN AGREEMENT SIGNED BY THE METAL TREATER. THE CUSTOMER, BY CONTRACTING FOR METAL TREATMENT, AGREES TO ACCEPT THE LIMITS OF LIABILITY AS EX PRESSED IN THIS STATEMENT TO THE EXCLUSION OF ANY AND ALL PROVISIONS AS TO LIABILITY ON THE CUSTOMER'S OWN INVOICES, PURCHASE ORDERS OR OTHER DOCUMENTS. IF THE CUSTOMER DESIRES HIS OWN PROVISIONS AS TO LIABILITY TO REMAIN IN FORCE AND EFFECT, THIS MUST BE AGREED TO IN WRITING. SIGNED BY AN OFFICER OF THE TREATER.. IN SUCH EVENT, A DIFFERENT CHARGE FOR OUR SERVICES, REFLECTING THE HIGHER RISK TO TREATER, SHALL BE DETERMINED BY TREATER AND CUSTOMER. THE TREATER MAKES NO EXPRESS OR IMPLIED WARRANTIES AND SPECIFICALLY DISCLAIMS ANY IMPLIED WAR RANTY OF FITNESS FOR A PARTICULAR PURPOSE OR MERCHANTABILITY, AS TO THE PERFORMANCE OF CAPABILITIES OF THE MATERIAL AS HEAT TREATED, OR THE HEAT TREAMENT. THE AFOREMENTIONED UMITATION OF LIABILITY STATED ABOVE IS SPECIFICALLY IN LIEU OF ANY EXPRESS OR IMPLIED WARRANTY, INCLUDING ANY IMPLIED WARRANTY OF MERCHANTABILITY OR FITNESS, AND OF ANY OTHER SUCH OBLIGATION ON THE PART OF THE TREATER. No claims for shortage in weight or count will be entertained unless presented within five (5) working days after receipt of materials by customer. No claims will be allowed for shrinkage, expansion, deformity, or rupture of material in treating or straightening, except by prior written agreement, as above, nor in any case for rupture caused by or.occurring during subse quent grinding. Whenever we are given material with detailed instructions as to treatment, our responsibility shall end with the carrying out of those instructions. Failure by a customer to indicate plainly and correctly the kind of material (i alloy designation) to be treated, shall cause an extra charge to be made to cover any additional expense incurred as a result
, proper
thereof, but shall not change the limitation of liability stated above. Customer agrees there will be no liability on the treater in contract or tort for any special, indirect or consequential damages arising from any reason whatsoever, including but not limited to personal injury, property damage, loss of profits, loss of production, recall or any other losses, expenses or liabilities allegedly occasioned by the work performed on the part of the treater. It shall be the duty of the customer to inspect the merchandise immediately upon its return, and in any eveht claims must be reported prior to the time that any further processing, assembling or any other work is undertaken. OUR LIABILITY TO OUR CUSTOMERS SHALL CEASE ONCE ANY FURTHER PROCESSING, ASSEMBLING OR ANY OTHER WORK HAS BEEN UNDERTAKEN ON SAID MATERIAL. No agent or representative is authorized to alter the conditions, except by writing duly signed by an officer of treater.
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Akron Steel Treating Company 336 Morgan Avenue Akron, OH 44311 P.O. Box 2290 Akron, OH 44309-2290 330-773-8211 Fax: 330-773-8213 Toll Free: 1-800-364-ASTC(2782) Email:
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Combining Art & Science for Solutions that Work
Contents
MODERN STEELMAKING Raw Materials Blast Furnace
5 5
6
Steelmaking Methods The Steel Ingot Types of Steel 12 Strand Casting Vacuum Treatment
6 12 14 15
CARBON AND ALLOY STEELS •
19
Effects of Chemical Elements 19 AISI/SAE Standard Grades and Ranges 25
HARDENABILITY OF STEEL
43
End-Quench Hardenability Testing 44 Calculation of Hardenability 46 Hardenability Limits Tables 51 THERMAL TREATMENT OF STEEL Conventional Quenching and
Tempering
61
61
Isothermal Treatments Surface Hardening Treatments Normalizing and Annealing
63 66 71
SAE Typical Thermal Treatments
74 81
G RAI N SiZE
MECHANICAL PROPERTIES
OF CARBON AND ALLOY STEELS
MACHINABILITY OF STEEL
168
NONDESTRUCTIVE EXAMINATION
USEFUL DATA
84
173
177
GLOSSARY OF STEEL TESTING
AND THERMAL TREATING TERMS 191
INDEX
200
MODERN STEELIVIAKING Steel is essentially a combination of iron and carbon, the carbon content of common grades ranging from a few hundredths to about one per cent. All steels also contain varying amounts of other ele ments, principally manganese, phosphorus, sulfur, and silicon, which are always present if only in trace amounts. The presence and amounts of these and some 20 other alloying elements, which are added in various combinations as desired, determine to a great ex tent the ultimate properties and characteristics of the particular steel.
Raw Materials The principal raw materials of the steel industry are iron ore, iron and steel scrap, coal, and limestone. Iron ore is a natural com bination of iron oxides and other materials, such as silicon and phos phorus. Until recently, the industry's main sources of iron were the high-grade ores, containing from 55 to 65 per cent iron, which were mined and sent directly to the steel plants. Today, the most available domestic iron ore is taconite, which contains a lesser amount of iron, making its use uneconomical without some kind of beneficiation, a
process in which the material is upgraded and formed into high-iron bearing pellets. Nearly one-half of the iron ore produced on this con tinent is now used in this pellet form. A second source of iron is scrap. Most of this comes from the
steel plant itself; only about two-thirds of the steel produced by steel plants is shipped as product, the remainder being discarded during processing and returned to the furnaces as scrap. Other scrap, if needed, comes from outside the plant from such sources as old auto mobiles, worn out railway cars and rails, obsolete machinery, and cuttings from metalworking shops.
Coal is converted into coke, gas, and chemicals in the coke ovens. The coke is used in the blast furnace as a fuel and reducing agent, the gas is burned in heating units, and the chemicals are pro cessed into various organic materials. Limestone is employed as a flux in both the blast furnace and steelmaking furnace where it serves to remove impurities from the melt. It is used either as crushed stone direct from the quarry or, after calcining, as burnt lime.
Blast Furnace The principal charging material used in making steel is molten pig iron, the product of the blast furnace. To produce it, iron ore, coke, and limestone are charged into the top of the furnace. A con tinuous blast of preheated air, introduced near the bottom of the fur nace, reacts with the coke to form carbon monoxide gas which then combines with the oxygen in the iron oxides, thereby reducing them to metallic iron. The molten iron is tapped into a ladle for transporta tion to the steel producing unit. Pig iron contains considerable amounts of carbon, manganese, phosphorus, sulfur, and silicon. In the solid form, it is hard and brittle and therefore unsuitable for applications where ductility is important.
S t e elm a king Methods Steelmaking may be described as the process of refining pig iron or ferrous scrap by removing the undesirable elements from the melt and then adding the desired elements in predetermined amounts. These additions are often the same elements which were originally removed, the difference being that the elements present in the final steel product are in the proper proportion to produce the desired properties. The open-hearth, the basic oxygen, and the electric-arc pro cesses account for nearly all the steel tonnage produced in this coun try today. The open-hearth furnace was the nation's major source of steel until 1969, when this role was assumed by the relatively new basic oxygen process. Together, these two methods account for over 80 per cent of the steel made in America. The remainder is made up of electric furnace steels.
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Simplified cutaway diagram of a typical open-hearth furnace, equipped with oxygen lance. Oxygen may be injected through one or more lances.
OPEN-HEARTH FURNACE. The open-hearth furnace has the ability to produce steels in a wide range of compositions. The
process can be closely controlled, yielding steels of high quality from charges which need be only nominally restrictive in their analyses. Most modern open-hearth furnaces are lined with a chemically basic material, such as magnesite, and use a basic refining slag. Furnace capacities range from 100 to 500 tons per melt, or heat, each heat requiring from 4 to 10 hours of furnace time. To begin the process, the basic open-hearth furnace is charged with scrap, limestone, and iron ore. This initial charge lies on an "open" hearth, where it is melted by exposure to flames sweeping over its surface. The pig iron, which may constitute as much as 75 per cent of the charge, is added in the molten state after the scrap is par tially melted. During the subsequent refining of the heat a process which is frequently accelerated by the introduction of oxygen through roof lances nearly all of the manganese, phosphorus, and silicon are oxidized and retained by the slag, which floats on the heavier molten metal. Appreciable percentages of sulfur can also be taken into the slag.
The heat is allowed to react until its carbon content has been
reduced by oxidation to approximately that desired in the finished steel. The furnace is then tapped, allowing the molten metal to flow into a ladle. To obtain the desired analysis, appropriate quantities of needed elements, usually in the form of ferroalloys, are added to the heat as it pours into the ladle, or, in the case of some elements, added to the furnace just prior to tapping. A deoxidizer, such as aluminum or ferrosilicon, is also normally added to control the amount of gas evolved during solidification (see p. 12). The heat is then usually poured into ingot molds where it solidifies into steel ingots.
BASIC OXYGEN FURNACE. The "BOF" involves the same chemical reactions as the open-hearth, but uses gaseous oxygen as the oxidizing agent to increase the speed of these reactions and thereby reduce the time of the refining process. Although the advan tages of the use of oxygen were obvious to steelmakers a hundred years ago, only in recent years has the pure gas become commercially available in the vast quantities required to make the BOF feasible. Heats of steel as large as 300 tons can be made in less than an hour, several times faster than the average open-hearth can operate. The steel is of excellent quality, equivalent to open-hearth steel in every respect.
WATER COOLED HOOD
ST J SHEL
During the charging and tapping of the
TAP BOF, the oxygen lance is raised and the t" HOLE vessel is tilted.
REFRACTORY LINING
CD
The basic oxygen furnace, a closed-bottom, refractory-lined vessel, is charged with molten pig iron and scrap. During the oxygen blow, burnt lime and fluorspar, which form the slag, are charged into the furnace. A high-velocity stream of oxygen is directed down onto the charge through a water-cooled lance, causing the rapid oxidation of carbon, manganese, and silicon in the melt. These reactions pro vide the heat required for scrap melting, slag formation, and refining. Additions of deoxidizers and any required alloying elements are made as the steel is tapped from the vessel into the ladle. It is then usually poured into ingot molds, as with other steelmaking processes. In keeping with the industry's trend to use the most advanced technologies, the entire process is usually controlled by a computer. From data on the analysis and weights of the charge materials and of melt samplings, the computer quickly determines the precise amounts of the additive elements needed, as well as the cycle time required for the refining operation.
ELECTRIC-ARC FURNACE. Special steels, such as the high-alloy, stainless, and tool steels, are normally made in electric arc furnaces. The primary advantage of this type furnace is that it permits the extremely close control of temperature, heat analysis, and refining conditions required in the production of these complex steels. As another advantage, these furnaces can be operated effi ciently on a cold metal charge, thereby eliminating the need for blast furnaces and associated facilities. For this reason, electric furnaces are today being used with increasing frequency for the production of standard carbon and alloy steels. The furnace proper is round or elliptical, with carbon or graphite electrodes extending through the roof. In operation, the electrodes are lowered to a point near the charge, which is melted by the heat of the electricity arcing between the electrodes and the charge. When the charge of carefully selected steel scrap is about 70 per cent molten, iron ore and burnt lime are added. Alloying ele ments are added during a later stage of the refining process. Some 3 to 7 hours are required for each heat, depending mostly on the type of steel being produced. Furnace capacity can vary from a few hun dred pounds to 200 tons or more.
10
Tapping a 50-ton, tilting electric-arc furnace.
Slag practice is geared to the economies of refining steels for different levels of quality. The standard carbon and alloy steels may be refined under a single slag to meet product requirements. Where cleanliness or a specific chemical analysis is the prime consideration, a double-slag practice may be used. The first of these is an oxidizing slag, used to remove some unwanted elements, principally phospho rus and some of the sulfur. This is discarded during the refining process and replaced by a reducing slag which serves to prevent excessive oxidation of the melt, thus enhancing cleanliness and the recovery of alloying additions of oxidizable elements. A further re duction in sulfur is also accomplished during this stage.
11
The Steel Ingot The cross section of most ingots is square or rectangular with rounded corners and corrugated sides. Some round-corrugated ingots are produced, but have a limited usage. All ingot molds are tapered to facilitate removal of the ingot, which may be poured big-end-up or big-end-down depending on the type of steel and ultimate product. All steel is subject to variation in internal characteristics as a result of natural phenomena which occur as the metal solidifies in the mold. The shrinkage which occurs in cooling may cause a central cavity known as "pipe" in the upper part of the ingot. The extent of the piping is dependent upon the type of steel involved, as well as the
size and design of the ingot mold itself. Pipe is eliminated by suf ficient cropping during rolling. Another condition present in all ingots to some degree is non uniformity of chemical composition, or segregation. Certain elements tend to concentrate slightly in the remaining molten metal as ingot solidification progresses. As a result, the top center portion of the
ingot which solidifies last will contain appreciably greater percent ages of these elements than indicated by the average composition of the ingot. Of the normal elements found in steels, carbon, phosphorus, and sulfur are most prone to segregate. The degree of segregation is influenced by the type of steel, pouting temperature, and ingot size.
It will also vary within the ingot, and according to the tendency of the individual element to segregate.
Types of Steel In most steelmaking processes the primary reaction involved is the combination of carbon and oxygen to form a gas. If the oxygen available for this reaction is not removed prior to or during pouring
(by the addition of ferrosilicon or some other deoxidizer), the gas eous products continue to evolve during solidification. Proper con trol of the amount of gas evolved during solidification determines the type of steel. If no gas is evolved, the steel is termed "killed" because it lies quietly in the molds. Increasing degrees of gas evolution char acterize semi-killed, capped, or rimmed steel.
RIMMED STEELS are only slightly deoxidized, thereby al lowing a brisk effervescence, or evolution of gas to occur as the metal begins to solidify. The gas is produced by a reaction between the car
12
bon and oxygen in the molten steel which occurs at the boundary between the solidified metal and the remaining molten metal. As a result, the outer skin, or "rim" of the ingot is practically free of car bon. The rimming action may be stopped mechanically or chem ically after a desired period, or it may be allowed to continue until the action subsides and the ingot top freezes over, thereby ending all gas evolution. The center portion of the ingot, which solidifies after the rimming ceases, has a fairly pronounced tendency to segregate, as discussed above. The low-carbon surface layer of rimmed steel is very ductile. Proper control of the rimming action will result in a very sound sur face in subsequent rolling. Consequently, rimmed grades are par
ticularly adaptable to applications involving cold forming, and where surface is of prime importance. The presence of appreciable percentages of carbon or man ganese will serve to decrease the oxygen available for the rimming action. If the carbon is above .25 % and the manganese over .60%, the action is very sluggish or non-existent. If a rim is formed, it will be quite thin and porous. As a result, the cold-forming properties and surface quality are seriously impaired. It is therefore standard prac tice to specify rimmed steel only for grades with lower percentages of these elements.
KILLED STEELS are strongly deoxidized and are character ized by a relatively high degree of uniformity in composition and properties. The metal shrinks during solidification, thereby forming a cavity, or "pipe", in the uppermost portion of the ingot. Generally, these grades are poured in big-end-up molds. A refractory hot-top is
placed on the mold before pouring and filled with metal after the ingot is poured. The pipe formed will be confined to the hot-top sec
tion of the ingot, which is removed by cropping during subsequent rolling. The most severely segregated areas of the ingot will also be
eliminated by this cropping. While killed steels are more uniform in composition and prop erties than any other type, they are nevertheless susceptible to some degree of segregation. As in the other grades, the top center portion
of the ingot will exhibit greater segregation than the balance of the ingot.
13
The uniformity of killed steel renders it most suitable for appli cations involving such operations as hot-forging, cold extrusion, carburizing, and thermal treatment.
SEMI-KILLED STEELS are intermediate in deoxidation be tween rimmed and killed grades. Sufficient oxygen is retained so that its evolution counteracts the shrinkage on solidification, but there is no rimming action. Consequently, the composition is more uniform than in rimmed steel, but there is a greater possibility of segregation than in killed steel. Semi-killed steels are used where neither the sur face and cold-forming characteristics of rimmed steel nor the greater uniformity of killed steels are essential requirements.
CAPPED STEELS are much the same as rimmed steels ex cept that the duration of the rimming action is curtailed. A deoxidizer
is usually added during the pouring of the ingot, with the result that a sufficient amount of gas is entrapped in the solidifying steel to cause the metal to rise in the mold. With the bottle-top mold generally used, action is stopped when the rising metal contacts a heavy metal cap placed on the mold after pouring. A similar effect can be obtained
chemically by adding ferrosilicon or aluminum to the ingot top after the ingot has rimmed for the desired time. Action will be stopped and rapid freezing of the ingot top follows. Capped steels have a thin low-carbon rim which imparts the surface and cold-forming characteristics of rimmed steel. The re mainder of the cross section approaches the degree of uniformity typical of semi-killed steels. This combination of properties has re sulted in a great increase in the use of capped steels in recent years,
primarily for cold forming.
Strand Casting In traditional steelmaking, molten steel is poured into molds to form ingots. The ingots are removed from the molds, reheated, and rolled into semi-finished products--blooms, billets, or slabs. Strand casting bypasses the operations between molten steel and the semi-finished product. Molten steel is poured at a regulated rate via a tundish into the top of an oscillating water-cooled mold with a cross-sectional size corresponding to that of the desired bloom, billet or slab. As the molten metal begins to freeze along the mold walls, it forms a shell that permits the gradual withdrawal of the
14
strand product from the bottom of the mold into a water-spray cham ber where solidification is completed. With the straight-type mold, the descending solidified product may be cut into suitable lengths while still vertical, or bent into the horizontal position by a series of rolls and then cut to length. With the curved-type mold, the solidified strand is roller-straightened after emerging from the cooling cham ber, and then cut to length. In both cases, the cut lengths are then reheated and rolled into finished product as in the conventional manner.
Vacuum Treatment Liquid steel contains measurable amounts of dissolved gases, principally oxygen, hydrogen, and nitrogen. For the great majority of applications, the effect of these gases on the properties of the solidified steel is insignificant and may be safely ignored. Some of the more critical applications, however, require steels with an exceptionally high degree of structural uniformity, internal soundness, or some
other quality which may be impaired by the effects of uncontrolled amounts of dissolved gases. In such cases, certain steelmaking and deoxidation practices are specified to reduce and control the amounts of various gases in the steel. Supplementary vacuum treatment may also be used. This additional procedure of exposing the molten steel to a vacuum during the melting or refining process may be justified in order to achieve one or more of several results: . Reduced hydrogen, thereby reducing tendency to flaking and em
brittlement, and minimizing time for slow cooling of primary mill products.
. Reduced oxygen, thereby improving microcleanliness.
. Improved recovery and distribution of alloying and other additive elements.
. Closer control of composition. . Higher and more uniform transverse ductility, improved fatigue resistance and elevated-temperature characteristics. . Exceptionally low carbon content, normally unattainable with conventional refining practices. Hydrogen removal by vacuum degassing is regularly specified for a variety of steels. Reducing the amount of this gas to levels where it can no longer cause flaking is of particular importance where the steel is to be used in large sections, such as for heavy forgings. 15
The control of dissolved oxygen, however, is a more complex undertaking because of this element's great chemical activity. It can exist in solution as free oxygen or as a soluble non-metallic oxide; it can combine with carbon to form gaseous oxides; it can be present as complex oxides in steelmaking slags and refractories. As a conse quence, deoxidation and other metallurgical procedures performed during refining must be carefully coordinated to assure a final steel product which will meet the specification requirements. Conventional deoxidation at atmospheric pressure is normally accomplished by adding suitable metallic deoxidizers, such as silicon or aluminum, to the molten steel. The deoxidizers combine with dis solved oxygen to form silicates and oxides, which are largely retained in the solidified steel in the form of non-metallic inclusions. To mini mize such inclusions, vacuum treatment is often specified. This is conducted in conjunction with the use of a metallic deoxidizer, and is most effective when the deoxidizer is added late in the vacuum treatment cycle. Such practice is known as "vacuum carbon deoxida tion" because the vacuum environment causes the dissolved oxygen to react with the bath carbon to form carbon monoxide gas, which is removed from the chamber by the pumping system. With most of the oxygen thus removed, the amounts of metallic deoxidizers required for final deoxidation is minimized, and a cleaner steel results. Where the ultimate in cleanliness is required, steel can be melted as well as refined under vacuum. The vacuum induction melting, the consumable arc remelting, and the electroslag processes are all used in the production of certain specialty steels. These processes, how ever particularly when used in combination are expensive and
are generally specified only for steels needed for the most critical applications. There are three principal commercial processes used for vacuum treatment of steels produced by standard steelmaking methods:
(1) STREAM DEGASSING. In this process, molten steel from the furnace is tapped into a ladle from which it is poured into a vacuum chamber containing either 1 ) an ingot mold for subsequent direct processing of the steel into heavy forgings, or 2) a second ladle from which the steel is cast into smaller ingots for processing into semi-finished and bar products. As the liquid stream enters the cham ber, the low pressure causes the steel to break up into droplets, facili tating the release of its gases into the chamber from which they are exhausted.
16
ALLOYS
ELECTRIC HEATING ROD
(2) CONTINUOUS CIRCULATION DEGASSING. Here, a ladle containing molten steel is moved beneath a suspended vacuum vessel, which is essentially a chamber wherein the degassing or deoxidizing process occurs. When the vessel is lowered, its two refractory tubes are immersed in the steel. The chamber is then opened to a vacuum and inert gas is bubbled into one tube. This gas creates a density differential between the two tubes, thus allowing atmospheric pressure to move the molten metal up through one tube into the chamber and down through the other back into the ladle. Circulation is continued until the steel is degassed to the degree desired.
(3) LADLE DEGASSING. In this process, a ladle of molten steel is placed in a large tank which is then covered and sealed. Pumps exhaust the air from the tank and maintain the vacuum throughout the degassing operation. To expose the maximum amount of steel directly to the vacuum, the melt is usually stirred by electrical induction or agitated by argon gas introduced through orifices near
the bottom of the ladle. 17
Nerve center for basic oxygen steelmaking is the computer room on the charging floor.
18
CAR BON AN D ALLOY STEELS In commercial practice, carbon and alloy steels have some common characteristics, and differentiation between them is arbitrary to a degree. Both contain carbon, manganese, and usually silicon in vary ing percentages. Both can have copper and boron as specified addi tions. A steel qualifies as a carbon steel when its manganese content is limited to 1.65 % max, silicon to .60% max, and copper to .60% max; with the exception of deoxidizers and boron when specified, no other alloying element is intentionally added. Alloy steels comprise not only those grades which exceed the above limits, but also any grade to which any element other than those mentioned above is added for the purpose of achieving a specific alloying effect. The alloy steels discussed in this edition of Modern Steels are limited to the "constructional alloy steels," or those which depend on thermal treatment for the development of properties required for specific applications. Other important categories of alloy steels, such as high-strength, low-alloy steels (which are alloyed for the purpose of increasing strength in the as-rolled or normalized condition), cor rosion- and heat-resisting steels, and tool steels, are discussed in other Bethlehem Steel Corporation publications, obtainable on request.
Effects of Chemical Elements The effects of the commonly specified chemical elements on the properties of hot-rolled carbon and alloy bars are discussed here by considering the various elements individually. In practice, however, the effect of any particular element will often depend on the quan tities of other elements also present in the steel. For example, the total effect of acombination of alloying elements on the hardenability of a steel is usually greater than the sum of their individual contributions. This type of interrelation should be taken into account whenever a change in a specified analysis is evaluated.
19
CARBON is the principal hardening element in steel, with each additional increment of carbon increasing the hardness and tensile strength of the steel in the as-rolled or normalized condition. As the carbon content increases above approximately .85%, the resulting increase in strength and hardness is proportionately less than it is for the lower carbon ranges. Upon quenching, the maximum attainable hardness also increases with increasing carbon, but above a content of .60%, the rate of increase is very small. Conversely, a steel's ductility and weldability decreases as its carbon content is increased. The effect of carbon on machinability is discussed on page 171. Carbon has a moderate tendency to segregate within the ingot, and because of its significant effect on properties, such segregation is frequently of greater importance than the segregation of other ele ments in the steel.
MANGANESE is present in all commercial steels, and con tributes significantly to a steel's strength and hardness in much the same manner, but to a lesser extent, than does carbon. Its effective ness depends largely upon, and is directly proportional to, the carbon content of the steel. Another important characteristic of this element is its ability to decrease the critical cooling rate during hardening, thereby increasing the steel's hardenability. Its effect in this respect is greater than that of any of the other commonly used alloying
i'i i
elements.
Manganese is an active deoxidizer, and shows less tendency to segregate within the ingot than do most other elements. Its presence
in a steel is also highly beneficial to surface quality in that it tends to combine with sulfur, thereby minimizing the formation of iron sulfide, the causative factor of hot-shortness, or susceptibility to cracking and tearing at rolling temperatures.
PHOSPHORUS is generally considered an impurity except where its beneficial effect on machinability and resistance to atmo spheric corrosion is desired. While phosphorus increases strength and hardness to about the same degree as carbon, it also tends to decrease ductility and toughness, or impact strength, particularly for steel in the quenched and tempered condition. The phosphorus content of most steels is therefore kept below specified maxima, which range up to .04 per cent.
20
i i lil L ii:'
In the free-machining steels, however, specified phosphorus con tent may run as high as. 12 %. This is attained by adding phosphorus to the ladle, commonly termed rephosphorizing. For a discussion of the effect of phosphorus on machinability, see page 169. SULFUR is generally considered an undesirable element ex cept where machinability is an important consideration (see page 169). Whereas sulfides in steel act as effective chip-breakers to improve machinability, they also serve to decrease transverse ductility and impact strength. Moreover, increasing sulfur impairs weldability and has an adverse effect on surface quality. Steels with the higher sulfur and particularly those with .15 to .25 % carbon contents require appreciable surface preparation during processing. Extra discard of these steels at the mill may also be necessary to minimize the amount of segregated steel in the finished product, inasmuch as sulfur, like phosphorus, shows a strong tendency to segregate within the ingot.
SILICON is one of the principal deoxidizers used in the manu facture of both carbon and alloy steels, and depending on the type of steel, can be present in varying amounts up to .35 % as a result of deoxidation. It is used in greater amounts in some steels, such as the silico-manganese steels, where its effects tend to complement those of manganese to produce unusually high strength combined with good ductility and shock-resistance in the quenched and tempered condi tion. In these larger quantities, however, silicon has an adverse effect on machinability, and increases the steel's susceptibility to decarbu rization and graphitization. NICKEL is one of the fundamental steel-alloying elements. When present in appreciable amounts, it provides improved tough ness, particularly at low temperatures; simplified and more eco nomical thermal treatment; increased hardenability; less distortion in quenching; and improved corrosion resistance. Nickel lowers the critical temperatures of steel, widens the tem perature range for effective quenching and tempering, and retards the decomposition of austenite. In addition, nickel does not form
carbides or other compounds which might be difficult to dissolve dur ing heating for austenitizing. All these factors contribute to easier and more successful thermal treatment. This relative insensitivity to vari ations in quenching conditions provides insurance against costly failures to attain the desired properties, particularly where the furnace is not equipped for precision control.
21
CHROMIUM is used in constructional alloy steels primarily to increase hardenability, provide improved abrasion-resistance, and to promote carburization. Of the common alloying elements, chro mium is surpassed only by manganese and molybdenum in its effect on hardenability. Chromium forms the most stable carbide of any of the more common alloying elements, giving to high-carbon chromium steels exceptional wear-resistance. And because its carbide is relatively stable at elevated temperatures, chromium is frequently added to steels used for high temperature applications. A chromium content of 3.99 % has been established as the maxi mum limit applicable to constructional alloy steels. Contents above this level place steels in the category of heat-resisting or stainless steels.
MOLYBDENUM exhibits a greater effect on hardenability per unit added than any other commonly specified alloying element except manganese. It is a non-oxidizing element, making it highly useful in the melting of steels where close hardenability control is desired. Molybdenum is unique in the degree to which it increases the high-temperature tensile and creep strengths of steel. Its use also reduces a steel's susceptibility to temper brittleness.
VANADIUM improves the strength and toughness of ther mally treated steels, primarily because of its ability to inhibit grain growth over a fairly broad quenching range. It is a strong carbide former and its carbides are quite stable. Hardenability of medium carbon steels is increased with a minimum effect upon grain size with vanadium additions of about .04 to .05 %; above this content,, the hardenability effect per unit added decreases with normal quenching temperatures due to the formation of insoluble carbides. However, the hardenability can be increased with the higher vanadium contents by increasing the austenitizing temperatures. COPPER is added to steel primarily to improve the steel's re sistance to corrosion. In the usual amounts of from .20 to .50%, the copper addition does not significantly affect the mechanical proper ties. Copper oxidizes at the surface of steel products during heating and rolling, the oxide forming at the grain boundaries and causing a hot-shortness which adversely affects surface quality.
22
:Sil¸¸¸¸ ii!
BORON has the unique ability to increase the hardenability of steel when added in amounts as small as .0005 %. This effect on hardenability is most pronounced at the lower carbon levels, dimin ishing with increasing carbon content to where, as the eutectoid com position is approached, the effect becomes negligible. Because boron is ineffective when it is allowed to combine with oxygen or nitrogen, its use is limited to aluminum-killed steels. Unlike many other elements, boron does not increase the fer rite strength of steel. Boron additions, therefore, promote improved
machinability and formability at a particular level of hardenability. It will also intensify the hardenability effects of other alloys, and in some instances, decrease costs by making possible a reduction of total alloy content.
LEAD does not alloy with steel. Instead, as added in pellet form during teeming of the ingot, it is retained in its elemental state as a fine dispersion within the steel's structure. Lead additions have no sig nificant effect on the room temperature mechanical properties of any steel; yet, when present in the usual range of .15 to .35 %, the lead additive enhances the steel's machining characteristics to a marked degree. Although lead can be added to any steel, its use to date has been most significant with the free-machining carbon grades. Added to a base composition which has been resulfurized, rephosphorized, and nitrogen-treated, lead helps these steels achieve the optimum in ma
chinability (see page 170). NITROGEN is inherently present in all steels, but usually only in small amounts which produce no observable effect. Present in amounts above about .004%, however, nitrogen will combine with certain other elements to precipitate as a nitride. This increases the steel's hardness and tensile and yield strengths while reducing its ductility and toughness. Such effect is similar to that of phosphorus,
and is highly beneficial to the machining performance of the steel (see page 169). ALUMINUM is used in steel principally to control grain size (see page 81) and to achieve deoxidation. Aluminum-killed steels exhibit a high order of fracture toughness.
A specialized use of aluminum is in nitriding steels (see page 67). When such steels containing .95 to 1.30% aluminum are heated in a nitrogenous medium, they achieve a thin case containing alumi num nitride. This stable compound imparts a high surface hardness and exceptional wear resistance to the steels involved.
23
24
AIS! and SAE Standard Grades and Ranges The following tables list the ladle chemical ranges and limits in per cent for those grades of carbon and alloy steel bars, blooms, billets, slabs, and rods
designated as standard by AISI (American Iron and Steel Institute) and/or SAE (Society of Automotive Engineers), and in effect as of the printing date of this book. The tables are not intended to be a listing of the steels which are produced or offered for sale by Bethlehem Steel Corporation.
Accompanying these tables are tables on prod uct analysis tolerances and ladle chemical ranges and limits for both carbon and alloy steels.
25
CARBON STEELS NONRESULFURIZED (Manganese 1.00 per cent maximum)
AISI/SAE Number
in
P
S
Max
Max
.050
1005* 1006* 1008
.06 max .08 max .10 max
.35 max .25/ .40 .30/ .5O
.040 .040
1010
.08/.13 .08/.13 .10/.15 .11/.16 .13/.18 .13/.18 .15/.20 .15/.20 .15/.20
.30/ .60 .60/ .90 .30/ .60 .50/ .80 .30/ .60 .60/ .90 .30/ .60 .60/ .90
.040 .040 .040 .040 .040 .040 .040
.70/1.00
.040
.18/.23 .18/.23
.30/ .60
1022 1023 1025 1026 1029
.18/.23 .20/.25 .22/.28 .22/.28
.70/1.00
.040 .040 .040 .040
1030 1035 1037 1038 1039
.28/.34
.35/.42 .37/.44
.60/ .90
1040 1042 1043 1044 1045 1046 1049
.37/.44 .40/.47 .40/.47 .43/.50 .43/.50 .43/.50 .46/.53
.60/ .90 .60/ .90
1011t 1012 1013t 1015 1016 1017 1018 1019 1020 1021
26
C
.25/.31
.32/.38 .32/.38
.60/ .90 .30/ .60 .30/ .60 .60/ .90 .6O/ .9O .60/ .90 .60/ .90
.70/1.00 .70/1.00
.70/1.00 .30/ .60 .60/ .90
.70/1.00 .60/ .90
.040
.040
.040 .040
.040
.050 .050 .050
.050 .050 .050 .050 .050 .050 .050 .050 .050 .050 .050 .050 .050 .050 .050
.040 .040 .040 .040 .040
.050 .050 .050 .050
.040 .040 .040 .040 .040 .040 .040
.050
.050
.050 .050 .050 .050 .050 .050
AISI/SAE Number
C
MR
P Max
1050 1053 1055 1059*
.48/ .55
.60/ .90
.48/ .55 .50/ .60 .55/ .65
.70/1.00 .60/ .90 .50/ .80
1060
.55/ .65
.60/ .90
.040
.60/ .70 .60/ .70
.50/ .80
.040 .040 .040
1064t 1065t 1069t 1070
1074t 1075t
.65/ .75 .65/ .75
.70/ .80
.60/ .90 .40/ .70 .60/ .90 .50/ .80 .40/ .70
.040 .040 .040
.040
.040
.040
S Max
.050
.050 .050 .050 .050 .050 .050 .050 .050 .050 .050 .050
.30/ .60
.040 .040
.60/ .90 .60/ .90 .70/1.00
.040 .040 .040
1086*
.75/ .88 .80/ .93 .80/ .93 .80/ .93
.30/ .50
.040
.050 .050 .050 .050
1090 1095
.85/ .98 .90/1.03
.60/ .90 .30/ .50
.040 .040
.050 .050
1078
1080 1084
1085t
.70/ .80 .72/ .85
*Standard grades for wire rods and wire only. tSAE only NOTE: In the case of certain qualities, the foregoing standard steels are ordinarily furnished to lower phosphorus and lower sulfur maxima.
BARS AND SEMI-FINISHED
Silicon. When silicon ranges or limits are required, the values shown in the table for
Ladle Chemical Ranges and Limits apply. RODS Silicon. When silicon is required, the following ranges and limits are commonly used for nonresulfurized carbon steels: 0.10 per cent maximum 0.10 to 0.20 per cent 0.20 to 0.40 per cent 0.07 to 0.15 per cent 0.15 to 0.30 per cent 0.30 to 0.60 per cent
ALL PRODUCTS
Boron. Standard killed carbon steels may be produced with a boron addition to improve hardenability. Such steels can be expected to contain 0.0005 per cent minimum boron. These steels are identified by inserting the letter "B" between the second and third numerals of the AISI number, e.g., 10B46. Lead. Standard carbon steels can be produced to a lead range of 0.15 to 0.35 per cent to improve machinability. Such steels are identified by inserting the letter "L'° between the second and third numerals of the AISI number, e.g., 10L45.
Copper. When copper is required, 0.20 per cent minimum is generally used.
27
CARBON STEELS N O NR E S UL F UR IZED (Manganese maximum over 1.00 per cent)
AISI/SAE Number
C
P
in
S
Max
Max
1513
.10/.16
1.10/1.40
.040
.O5O
1522 1524 1526 1527
.18/.24 .19/.25
1.10/1.40 1.35/1.65 1.10/1.40 1.20/1.50
.040 .040
.O5O
.040 .040
.050
.22/.29 .22/.29
.050
1541
.36/.44
.O5O
.44/.52
1.35/1.65 1.10/1.40
.040
1548
.040
.050
1551
.45/.56 .47/.55
.85/1.15 1.20/1.50
.040 .040
.O5O
.55/.65 .60/.71
.75/1.05 .85/1.15
.040
1552 1561
1566
.040
NOTE: in the case of certain qualities, the foregoing standard steels are ordinarily furnished to lower phosphorus and lower sulfur maxima. NOTE: Addenda to table "Carbon Steels, Nonresulfurized (Manganese 1.00 per cent maximum)," p. 27, in reference to Silicon, Boron, Lead, and Copper, also apply to table above.
28
.O50
.05O
.O50 .O50
CARBON STEELS R ES UL F UR IZED
AISi/SAE
P
C
Number
MR
Max
.3O/ .60
1110 1117 1118
.08/.13 .14/.20 .14/.20
1.00/1.30 1.30/1.60
.040 .040 .040
.08/.13 .08/.13 .08/.13
1137 1139
.32/.39 .35/.43
1.35/1.65 1.35/.165
.040 .040
.08/.13 .13/.20
1140 1144 1146
.37/.44 .37/.45 .40/.48 .42/.49
.70/1.00 1.35/1.65 1.35/1.65 .70/1.00
.040 .040 .040 .040
.08/.13 .08/.13 .24/.33 .08/.13
1151
.48/.55
.70/1.00
.040
.08/.13
1141
BARS AND SEMI-FINISHED Silicon. When silicon ranges and limits are required, the values shown in the table for Ladle Chemical Ranges and Limits apply. RODS Silicon. When silicon is required, Standard Steel Silicon Ranges or the following ranges and Designations Limits, per cent limits are commonly used:
Up to 1110 incl
1116 and over
0.10 max
0.10 max; or 0.10 to 0.20; or 0.15 to 0.30
ALL PRODUCTS Lead. See note on lead, p. 27.
29
CARBON STEELS REPHOSPHORIZED AND RES ULFURIZED AISi/SAE
MR
C
Number
.60/ .90 .70/1.00 .70/1.00 .85/1.15 .75/1.05
.13 max .13 max .13 max .15 max .09 max
1211
1212 1213 12L14 1215
Pb
P
.07/.12 .07/.12 .07/.12
.10/.15 .16/.23 .24/.33
.04/,09
.26/.35
.04/.09
.26/.35
......
R
.15/.35
,,
Silicon. It is not common practice to produce these steels to specified limits for silicon because of its adverse effect on machinability. Nitrogen. These grades are normally nitrogen treated unless otherwise specified. Lead. See note on lead, p. 27.
BETHLEHEM FREE-MACHINING CARBON STEELS Name Beth-Led Beth- Led B 1213-B
Mn
C .09 max .15 max .09 max
S
Pb
.07/.12
.26/.35
.04/.09 .07/.12
.40 min
.15/.35 .15/.35
P
.70/1.00 .85/1.35 .70/1.00 .........
.26/.35
Silicon. It is not common practice to )roduce these steels to s limits for silicon because of its adverse effect on machinability.
.......
ecified
Nitrogen. Beth-Led and 1213-B are nitrogen treated.
CARBON STEELS "'M" Series
AISI Number
M 1008
M1010 M1012 M1015 M1017
M1020 M1023
M1025 M1031 M 1044
P
S
Max
Max
.25/.60 .25/.60 .25/.60 .25/.60 .25/.60
.04 .04 .04 .04 .04
.05 .05 .05 .05 .05
.17/.24 .19/.27
.25/.60
.20/.30 .26/.36
.25/.60
.04 .04 .04 .04 .04
.05 .05 .05 .05 .05
C
in
.10 max .07/.14 .09/.16 .12/.19 .14/.21
.40/.50
.25/.60 .25/.60 .25/.60
NOTE: Standard ranges and limits do not apply to °'M"-Series steels.
NOTE: These modified steels are available in the indicated analyses only.
30
CARBON H-STEELS AISI/SAE Number
1038 H 1045 H 1522 H 1524 H 1526 H 1541 H
C
Mn
.34/.43
.50/1.00 .50/1.00 1.00/1.50 1.25/1.75* 1.00/1.5O 1.25/1.75*
.42/.51 .17/.25
.18/.26 .21/.30 .35/.45
Max
P
Max
.040 .040 .040 .040 .040 .040
S
Si .050 .050 .050 .050 .050 .050
.15/.30 .15/.30 .15/.30 .15/.30 .15/.30 .15/.30
CARBON BORON H-STEELS These steels can be exeected to contain 0.0005 to 0.003% boron.
AISI/SAE
MR
Number
15B21 H 15B35 H 15B37 H 15B41 H 15B48 H 15B62 H
.17/.24 .31/.39 .30/.39 .35/.45 .43/.53 .54/.67
.70/1.20 .70/1.20 1.00/1.5O 1.25/1.75* 1.00/1.5O 1.00/1.50
P
S
Max
Max
.040 .040 .040 .040 .040 .040
.050 .050 .050 .050 .050 .050
Si .15/.30 .15/.30 .15/.30 .15/.30 .15/.30 .40/.60
*Standard H-Steels with 1.75 per cent maximum manganese are classified as carbon steels. NOTE: In the case of certain qualities, the foregoing standard steels are ordinarily furnished to lower phosphorus and lower sulfur maxima.
SEE ALSO: Note on Lead, page 27 ; and Note 1, page 39.
31
CARBON STEELS LADLE CHEMICAL RANGES AND LIMITS Bars, Blooms. Billets. Slabs, and Rods
Element
When maximum of specified element is, per cent
Range, per cent
To 0.12 incl Over 0.12 to 0.25 incl Over 0.25 to 0.40 incl Over 0.40 to 0.55 incl Over 0.55 to 0.80 incl Over 0.80
0.06 0.07 0.10 0.13
Manganese
To 0.40 incl Over 0.40 to 0.50 incl Over 0.50 to 1.65 incl
0.15 0.20 0.30
Phosphorus
To 0.040 incl Over 0.040 to 0.08 incl Over 0.08 to 0.13 incl
0.03 0.05
Sulfur
To 0.050 incl Over 0.050 to 0.09 incl Over 0.09 to 0.15 incl Over 0.15 to 0.23 incl Over 0.23 to 0.35 incl
0.03 0.05 0.07 0.09
To 0.10 incl Over 0.10 to 0.15 incl Over 0.15 to 0.20 incl Over 0.20 to 0.30 incl Over 0.30 to 0.60 incl
0.08 0.10 0.15 0.20
Carbon (Note 2)
Silicon (Note 3)
m
O.O5
!
Copper
When copper is required, 0.20 minimum is generally used.
Lead
When lead is required, a range of 0.15/0.35 is generally used.
(Note 4)
Boron
When boron treatment is specified for killed carbon steels, a boron content of 0.0005 to 0.003 per cent can be expected.
NOTE 1. In the case of certain qualities, lower phosphorus and lower sulfur maxima are ordinarily furnished. NOTE 2. Carbon. The carbon ranges shown in the column headed "Range" apply ximum limit for manganese does not exceed 1.10 per cent. When the maximum manganese limit exceeds 1.10 per cent, add 0.01 to the carbon ranges shown above.
when the specified m
NOTE 3. Silicon. It is not common practice to produce a rephosphorized and resul
furized carbon steel to specified limits for silicon because of its adverse effect on machinability. NOTE 4. Lead is reported only as a range (generally 0.15 to 0.35 per cent) since it is added to the ladle stream as the steel is being poured.
32
CARBON STEELS PR OD UCT ANAL YSIS TOLERANCES Bars. Blooms. Billets. Slabs. and Rods
Tolerance Over the Maximum Limit or Under the Minimum Limit, per cent Limit, or Maximum
of
Element
Specified Range, per cent
To
Over 200
Over 100
100
to
to
Over 400 to
400 sq in. 800 sq in. incl incl
sq in. 200 sq in. incl incl
Carbon
To 0.25 incl 0.02 0.03 Over 0.25 to 0.55 incl 0.03 0.04 Over 0.55 0.04 0.05
0.04 0.05 0.06
0.05 0.06 0.07
Manganese
To 0.90 incl 0.03 0.04 Over 0.90 to 1.65 incl 0.06 0.06
0.06 0.07
0.07 0.08
Phosphorus
Over maximum only,
0.010
0.015
0.010
0.015
0.03
0.04
to 0.040 incl
0.008 0.008
Sulfur
Over maximum only
Silicon
To 0.35 incl
0.008 0.010
0.02
0.02
Over 0.35 to 0.60 incl 0.05
-
Copper
Under minimum only
0.02
Lead
Over and under
0.15 to 0.35 incl Boron
0.03
0.03
0.03
Not subject to product analysis tolerances.
NOTE 1. Rimmed or capped steels are characterized by a lack of uniformity in their chemical composition, especially for the elements carbon, phosphorus, and sulfur, and for this reason product analysis tolerances are not technologically appropriate for those elements. NOTE 2. In all types of steel, because of the degree to which phosphorus and sulfur segregate, product analysis tolerances for those elements are not technologically appropriate for re phosphorized or resulfurized steels.
33
ALLOY STEELS AISI/SAE
MR
Number
1330 1335 1340 1345
4012tt
.38/.43 .43/.48
1.60/1.90 1.60/1.90 1.60/1.90 1.60/1.9O
.09/.14
.75/1.00
.28/.33 .33/.38
4023
.20/.25
4024 4027 4028
.20/.25 .25/.30
.25/.30 4032tt .30/.35 4037 .35/.40
4042tt 4047
.40/.45 .45/.50
4118 4130
.18/.23 .28/.33 4135tt .33/.38 4137 .35/.40 4140 .38/.43 4142 .40/.45 4145 .43/.48 4147 .45/.5O 4150 .48/.53 4161 .56/.64 4320 4340 E4340
.70/ .90
4419tt .18/.23 4422tt .20/.25 4427tt .24/.29
.70/ .90 .70/.90
4615
.13/.18
.45/ .65
.17/.22 4621tt .18/.23 4626 .24/.29
.45/ .65
m
J m I m
.40/ .60
w m
w w
m
1.65/2.00 1.65/2.00 1.65/2.00
.45/ .65
1.65/2.00 1.65/2.00 1.65/2.00 1.65/2.00 .70/1.00
.7O/ .9O
.90/1.20 .90/1.20
4815 4817 4820
.13/.18
.40/ .60 .4O/ .60
3.25/3.75 3.25/3.75 3.25/3.75
ttSAE only
34
.5O/ .70
.20/.30 .20/.30 .20/.30 .20/.30 .20/.30 .08/.15 .15/.25 .15/.25 .15/.25 .15/.25 .15/.25 .15/.25 .15/.25 .15/.25
.70/ .9O
.25/.35
.4O/ .6O
.20/.30 .20/.30 .20/.30
.7O/ .9O .70/ .90
S
.035/.050 .O35/.O5O
w
I
u !
! h !
.45/.60 .35/.45 .35/.45
.7o/ .90 .50/ .70
.15/.20 .18/.23
.80/1.10 .80/1.10 .80/1.10 .80/1.10 .80/1.10 .80/1.10 .80/1.10 .80/1.10
.45/ .65
.45/ .65
.15/.25
.20/.30 .20/.30 .20/.30
.16/.21
.17/.22
n m
4718tt 4720
m m
.70/ .90 .70/ .9O .4O/ .6O .70/.90 .70/ .9O .75/1.00 .75/1.00 .75/1.00 .75/1.00 .75/1.00 .75/1.00
Other Elements
m
.70/ .90 .70/ .90
.70/ .90 .70/ .90
io
m
.70/ .90
.45/ .65 .60/ .80 .65/ .85
4620
Or m
m
.70/ .90
.17/.22 .38/.43 .38/.43
4617tt .15/.20
Ni
.20/.30 .20/.30 .20/.30 .20/.30 .15/.25 .35/ .55 .35/ .55
R n i
.30/.40 .15/.25 .20/.30 .20/.30 .20/.30
n m D
AISI/SAE
MR
Number
5015tt 5046tt 5060tt 5115tt
.12/ .17 .43/ .48 .56/ .64
.13/ 5120 .17/ 5130 .28/ 5132 .30/ 5135 .33/ 5140 .38/ 5145tt .43/ 5147tt .46/ 5150 .48/ 5155 .51/ 5160 .56/ 50100tt .98/1 E51100 .98/1 E52100 .98/1
.30/ .50
.75/1.00 .75/1.00 .70/ .90 .70/ .90 .70/ .90 .6O/ .80
.18 .22 .33 .35 .38 .43 .48 .51 .53 .59 .64
.75/1.00
.10 .10 .10
.25/ .45 .25/ .45 .25/ .45
.16/ .48/ .13/ .13/ .15/ .18/ .20/ .23/ .25/ .28/ .35/ .38/ .4O/ .43/ .48/ .51/ .56/ .18/ .38/ .2O/
.21 .53
.50/ .70 .70/ .90 .70/ .90
9254tt .51/ 9255tt .51/
.59 .59 .64
6118 6150
8115tt 8615 8617 8620 8622 8625 8627 8630 8637 8640 8642 8645
8650tt 8655
8660tt 8720 8740 8822
9260
9310tt
.18 .18 .20 .23 .25 .28 .30 .33 .40 .43 .45 .48 .53 .59 .64 .23 .43 .25
.56/ .08/ .13
ttSAE only
Ni
m
.30/ .50 .20/ .35 .40/ .60
m
.7O/ .9O
m
D m i
.60/ .80
.7O/ .90 .70/ .90 .70/ .95 .7O/ .90 .70/ .90
.70/ .90
.70/ .90 .70/ .90 .70/ .9O .70/ .90 .7O/ .9O .70/ .9O
.75/1.00 .75/1.00 .75/1.00 .75/1.00 .75/1.00 .75/1.00 .75/1.00 .70/ .9O
.75/1.00 .75/1.00
m m
.7O/ .9O .80/1.10 .75/1.00 .80/1.05
.7O/ .90 .7O/ .9O
.85/1.15
Other Elements
io m
i
m i
n m
m
m m D m
.70/ .9O
m
.7O/ .9O .7O/ .90
m
.40/ .6O
u
.90/1.15 1.30/1.60
.20/.40 .40/.70 .40/.70 .40/.70 .40/.70 .40/.70 .40/.70 .40/.70
.40/.70
.50/ .70 .80/1.10 .30/ .50 .40/ .60 .40/ .60 .40/ .60 .4O/ .6O .4O/ .6O .4O/ .60 .4O/ .6O .4O/ .6O .40/.60 .40/ .60
.40/.70 .40/.70 .40/.70 .40/.70 .40/.70 .40/.70
.4O/ .6O .4O/ .6O .40/ .6O
.40/.70 .40/.70
.4O/ .60 .4O/ .6O
.40/.70
.40/ .60
.60/ .80
D
.75/1.00
m
.70/ .95
.45/ .65
Or
.4O/ .6O
m
m
m
V .10/.15 .15 min
m
.08/.15 .15/.25
.15/.25 .15/.25 .15/.25 .15/.25 .15/.25 .15/.25
.15/.25
.15/.25 .15/.25 .15/.25 .15/.25 .15/.25 .15/.25
.20/.30 .20/.30 .30/.40 Si
1.20/1.60 1.80/2.20 1.80/2.20
.60/ .80 m
3.00/3.50
1.00/1.40
.08/.15 (See Notes, page 39) 35
ALLOY H-STEELS AISI/SAE
in
Number
Ni
Or
m
m
m
m
io
Other Elements
1330 H 1335 H 1340 H 1345 H
.27/.33 .32/.38 .37/.44 .42/.49
1.45/2.05 1.45/2.05 1.45/2.05 1.45/2.05
4027 H
.24/.30
.60/1.00
.20/.30
m
4028 H 4032 Htt 4037 H 4042 H tt 4047'H
.24/.30 .29/.35 .34/.41 .39/.46 .44/.51
.60/1.00 .60/1.00 .60/1.00 .60/1.00 .60/1.00
.20/.30
.035/.050
4118H 4130H
.17/.23 .27/.33
.60/1.00 .30/ .70 .60/1.00 .60/1.00 .65/1.10 .65/1.10 .65/1.10 .65/1.10 .65/1.10 .65/1.10
n m m
m
m
S
4135 Htt 4137 H 4140 H
.32/.38
4145 H 4147 H 4150 H 4161 H
.34/.41 .37/.44 .39/.46 .42/.49 .44/.51 .47/.54 .55/.65
4320 H 4340 H E4340 H
.17/.23 .37/.44 .37/.44
.55/ .90
4419 Htt
.17/.23
.35/ .75
4620 H
.17/.23
.35/ .75
4142H
4621 Htt .17/.23 4626 Ht .23/.29 4718 Htt
.40/ .70 .60/ .95
m w
m w
m
1.55/2.00 1.55/2.00 1.55/2.00
4815 H 4817 H 4820 H
.12/.18 .14/.20 .17/.23
.30/ .70 .30/ .70
.40/ .80
.20/.30 .20/.30 .20/.30
.60/ .95
.08/.15 .15/.25 .15/.25 .15/.25 .15/.25 .15/.25 .15/.25 .15/.25 .15/.25 .25/.35
.35/ .65
.20/.30
.65/ .95 .65/ .95
.20/.30
.75/1.20 .75/1.20 .75/1.20 .75/1.20 .75/1.20 .75/1.20 .75/1.20 .75/1.20
i m
m m m m m
.20/.30 .45/.60
.85/1.25 .85/1.25
.60/ .95 .45/ .75
36
.30/ .70
.40/ .70
.15/.21 .17/.23
m
.20/.30
1.55/2.00 1.55/2.00 .65/1.05
.60/1.00
4720 H
tAISl only IISAE only
m !
3.20/3.80 3.20/3.80 3.20/3.80
.20/.30 .20/.30 .15/.25
m
.30/.40 .15/.25
m
m
.20/.30
m
m
.20/.30
u
.20/.30
m u m
.30/ .60 .30/ .60
m
m
AISI/SAE Number
C
MR
5046 Htt
.43/.50
.65/1.10
5120 H 5130 H 5132 H 5135 H 5140 H
.17/.23 .27/.33 .29/.35 .32/.38
.60/1.00 .60/1.00 .50/ .90 .5O/ .9O .60/1.00 .60/1.00 .60/1.05 .60/1.00 .60/1.00 .65/1.10
.37/.44 .42/.49
5145 Htt 5147 Hff .45/.52 5150 H 5155 H 5160 H
.47/.54
6118 H 6150 H
.15/.21
8617 H 8620 H 8622 H 8625 H 8627 H 8630 H 8637 H 8640 H 8642 H 8645 H
.14/.20 .17/.23 .19/.25 .22/.28 .24/.30 .27/.33 .34/.41 .37/.44 .39/.46
.50/.60 .55/.65
.47/.54
Ni
Cr
Other Elements
io
.13/ .43
m
m
m n m m m
.60/1.00 .75/1.20 .65/1.10 .70/1.15 .60/1.00 .60/1.00 .80/1.25 .60/1.00 .60/1.00 .60/1.00 .40/ .80 .75/1.20
.40/ .80 .60/1.00
m
n
m
!
m n
n
!
m
m
m
m m
m
n
V .10/.15
n
.15 min
.35/ .65 .35/ .65 .35/ .65 .35/ .65 .35/ .65 .35/ .65 .35/ .65 .35/ .65 .35/ .65 .35/ .65 .35! .65 .35/.65 .35/ .65
.15/.25 .15/.25 .15/.25 .15/.25 .15/.25 .15/.25 .15/.25 .15/.25 .15/.25 .15/.25
.50/.60 8660 Htt .55/.65
.70/1 .O5
.70/1.05
.35/.75 .35/.75 .35/.75 .35/.75 .35/.75 .35/.75 .35/.75 .35/.75 .35/.75 .35/.75 .35/.75 .35/.75 .35/.75
8720 H 8740 H
.17/.23 .37/.44
.60/ .95 .70/ .05
.35/.75 .35/.75
.35/ .65 .35/ .65
.20/.30 .20/.30
8822 H
.19/.25
.70/1.05
.35/.75
.35/ .65
.30/.40
9260 H
.55/.65
.65/1.10
9310 Htt .07/.13
.40/ .70
8650 Htt
.42/.49 .47/.54
8655 H
.60/ .95 .60/ .95 .60/ .95 .60/ .95 .60/ .95 .60/ .95 .70/1.05 .70/1.05 .70/1.05 .70/1.05 .70/1.05
.15/.25
.15/.25 .15/.25
u m m m
m
m m m i m
m
Si
ttSAE only
1.70/2.20 2.95/3.55
1.00/1.45
.08/.15
(See Notes, page 39) 37
ALLOY BORON STEELS These steels can be expected to contain 0.0005 to 0.003% boron.
AISI/SAE Number
50B40tt
C
in
50B44 50B46 50B50 50B60
.38/.43 .43/.48 .44/.49 .48/.53 .56/.64
.75/1.00 .75/1.00 .75/1.00 .75/1.00 .75/1.00
51 B60
.56/.64
.75/1.00
81B45
.43/.48 .43/.48
.75/1.00 .75/1.00
94B15tt
.13/.18 .15/.20 .28/.33
.75/1.00 .75/1.00 .75/1.00
86B45tt 94B17 94B30
Ni
m m R D
Cr
ao
.40/.60 .40/.60 .20/.35 .40/.60 .40/.60
w m
m m
.70/.90
w
.20/.40 .40/.70
.35/.55 .40/.60
.08/.15 .15/.25
.30/.60 .30/.60 .30/.60
.30/.50 .30/.50 .30/.50
.08/.15 .08/.15 .08/.15
ftSAE only
(See Notes, page 39)
ALLOY BORON H-STEELS These steels can be expected to have 0.0005% min boron content.
AlSl/SAE
MR
Number
50B40 Htt
Ni
Or
io
50B44 H 50B46 H 50B50 H 50B60 H
.55/.65
.65/1.10 .65/1.10 .65/1.10 .65/1.10 .65/1.10
51B60
.55/.65
.65/1.10
.42/.49
.70/1.05 .60/ .95 .70/1.05
.15/.45
.35/.75
30/ .6O
.35/.75
.35/ .65 .35/ .65
.08/.15 .15/.25 .15/.25
.70/1.05 .70/1.05
.25/.65 .25/.65 .25/.65
.25/ .55 .25/ .55 .25/ .55
.08/.15 .08/.15 .08/.15
81B45
86B30
H H
86B45 Htt 94B15 Htt 94B17 H 94B30 H ttSAE only
38
.37/.44 .42/.49 .43/.50 .47/.54
.27/.33 .42/.49
.12/.18 .14/.20 .27/.33
.70/1 .O5
m
m !
.30/ .70 .3O/ .70 .13/ .43 .30/ .70 .30/ .70
.60/1.00
m m m
w
(See Notes, page 39)
NOTES ON ALLOY TABLES 1. Grades shown with prefix letter E are made only by the basic electric furnace process. All others are normally manufactured by the basic open hearth or basic oxygen processes, but may be manu factured by the basic electric furnace process with adjustments in phosphorus and sulfur. 2. The phosphorus and sulfur limitations for each process are as follows: Maximum per cent
Basic electric Basic open hearth or basic oxygen Acid electric or acid open hearth
0.025 0.035 0.050
0.025 0.040 0.050
3. Minimum silicon limit for acid open hearth or acid electric furnace alloy steel is. 15 per cent. 4. Small quantities of certain elements are present in alloy steels, but are not specified or required. These elements are considered as inci dental and may be present in the following maximum percentages: copper, .35; nickel, .25; chromium, .20; molybdenum, .06. 5. The listing of minimum and maximum sulfur content indicates a resulfurized steel. 6. Standard alloy steels can be produced to a lead range of .15/.35 per cent to improve machinability. 7. Silicon range for all standard alloy steels except where noted is .15/.30 per cent.
39
ALLOY STEELS LADLE CHEMICAL RANGES AND LIMITS Bars, Blooms, Billets, Slabs, and Rods Range, per cent
Element
...............
When maximum of specified element is, per cent
Open hearth Electric or basic furnace oxygen steel steel
.......
Carbon
To 0.55 incl Over 0.55 to 0.70 inci Over 0.70 to 0.80 incl Over 0.80 to 0.95 incl Over 0.95 to 1.35 incl
Manganese
To 0.60 incl Over 0.60 to 0.90 incl Over 0.90 to 1.05 incl Over 1.05 to 1.90 incl Over 1.90 to 2.10 incl
Phosphorus
Basic open hearth or basic oxygen steel (Note 5) Acid open hearth steel Basic electric furnace steel Acid electric furnace steel
Sulfur
To 0.050 incl Over 0.050 to 0.07 incl Over 0.07 to 0.10 incl Over 0.10 to 0.14 incl
0.05 0.08 0.10 0.12 ,0.13" ii
0.20 0.20 0.25 0.30 0.40
........
0.02 0.04 0.05
0.05 0.07 0.09 0.11 0.12
Silicon
.... ............
To 0.15 incl Over 0.15 to 0.20 incl Over 0.20 to 0.40 incl Over 0.40 to 0.60 incl Over 0.60 to 1.00 incl Over 1.00 to 2.20 incl
Acid steels (Note 1 )
Nickel
..........
To 0.50 incl Over 0.50 to 1.50 incl Over 1,5Q to 2.00 incl Over 200 to 3.0-0 incl Over 3.00 to 5.30 incl Over 5.30 to 10.00 incl
O.O8 O.O8 0.10 0.10 0.15 0.15 O.2O O.2O 0.30 0.30 0.40 O.35 0.20 0.20 O.3O O.30 0.35 0.35 O.40 0.40 0.50 0.50 1.00 1.00
......
*Applies to only nonrephosphorized and nonresulfurized steels.
40
......
0.15 O.20 0.25 O.30 0.35 0.035 0.050 0.025 0.050 0.015 0.02 0.04 0.05
Basic open hearth or basic oxygen steel (Note 5)
Acid open hearth steel Basic electric furnace steel Acid electric furnace steel
Maximum limit, per cent*
0.040 0.050 0.025 0.050 ........
Range, per cent
Element
When maximum of specified element is, per cent
Open hearth
Electric furnace steel
or basic oxygen steel
Chromium
To 0.40 incl Over 0.40 to 0.90 incl Over 0.90 to 1.05 incl 1.60 rmt Over 1.05 t Over 1.60 to 1.75 incl Over 1.75 to 2.10 incl Over 2.10 to 3.99 incl
0.15 0.20 0.25 0.30
0.15 0.20 0.25 0.30 0.35 0.40 0.50
Molybdenum
TQ 0.10 in cl Over 0.10 to 0.20 incl Over 0.20 to 0.50 incl Over 0.50 to 0.80 incl Over 0.80 to 1.1 5 incl
0.05 0.07 0.10 0.15 0.20
0.05 0.07 0.10 0.15 0.20
Tungsten
To 0.50 incl Over 0.50 to 1.00 incl Over 1.00 to 2.00 incl Over 2.00 to 4.00 incl
0.20 0.30 0.50 0.60
0.20 0.30 0.50 0.60
Vanadium
To 0.25 incl Over 0.25 to 0.50 incl
0.05 0.10
0.05 0.10
Aluminum
Up to 0.10 incl Over 0.10 to 0.20 incl Over 0.20 to 0.30 incl Over 0.30 to 0.80 incl Over 0.80 to 1.30 incl Over 1.30 to 1.80 incl
0.05 0.10 0.15 0.25 0.35 0.45
0.05 0.10 0.15 0.25 0.35 0.45
Copper
To 0.60 incl Over 0.60 to 1.50 incl Over 1.50 to 2.00 incl
0.20 0.30 0.35
0.20 0.30 0.35
.........
**Not normally produced in open hearth or basic oxygen furnaces.
NOTE 1. Minimum silicon limit for acid open hearth or acid electric furnace alloy steels is 0.15 per cent. NOTE 2. Boron steels can be expected to have 0.0005 per cent minimum boron content.
NOTE 3. Alloy steels can be produced with a lead range of 0.15/0.35. A ladle analysis for lead is not determinable, since lead is added to the ladle stream while each ingot is poured. NOTE 4. The chemical ranges and limits of alloy steels are produced to prod= uct analysis tolerances shown in Table on p. 42. NOTE 5. In the case of certain qualities, lower phosphorous and lower sulphur maxima are ordinarily furnished. 41
ALLOY STEELS PR OD UCT ANAL YSIS TOLERANCES Bars, Blooms, Billets, Slabs, and Rods Tolerance Over the Maximum Limit or Under the Minimum Limit, per cent To 100
Limit, or Maximum
of Specified Range,
Element
Over 0.30 to 0.75 incl Over 0.75
To 0.90 incl
Manganese
Over 0.90 to 2.10 incl
Over 400
to 400 sq in.
incl
to 800 sq in. incl
0.01 0.02 0.03
0.02 0.03 0.04
0.03 0.04 0.05
0.04 0.05 0.06
0.03 0.04
0.04 0.05
0.05 0.06
0.06 0.07
0.010
incl
To 0.30 incl
Carbon
Over 200
to 200 sq in. incl
sq in.
per cent
Over 100
Phosphorus
Over max only
0.005
0.010
0.010
Sulfur
Over max only*
O.0O5
0.010
0.010
0.010
Silicon
To 0.40 incl
0.02 0.05
0.02 0.06
0.03 0.06
0.04 0.07
NicKel
To 1.00 incl
0.03 0.05 O.07 0.10
0.03 0.05 0.07 0.10
0.03 0.05 O.07 0.10
0.03 0.05 0.07 0.10
0.03 0.05 0.10
0.04 0.06 0.10
0.04 0.06 0.12
0.05 0.07 0.14
0.01 0.02 0.03
0.01 0.03 0.04
0.02 0.03 0.05
0.03 0.04 0.06
0.01 0.02 0.03
0.01 0.02
0.01 0.02 0.03
0.01 0.02 0.03
Over 0.40 to 2.20 incl Over 1.00 to 2.00 incl Over 2.00 to 5.30 incl Over 5.30 to 10.00 incl
To 0.90 incl
Chromium
Over 0.90 to 2.10 incl Over 2.10 to 3.99 incl
To 0.20 incl
Molybdenum
Over 0.20 to 0.40 incl Over 0.40 to 1.1 5 incl
To 0.10 incl
Vanadium
Over 0.10 to 0.25 incl Over 0.25 to 0.50 incl Min value specified,
check under min limitt
0.01
0.01
0.01
0.01
To 1.00 incl
0.04 0.08
0.05 0.09
0.05 0.10
0.06 0.12
0.03 0.04 0.05 0.07 0.10
m
D
m
Tungsten
Over 1.00 to 4.00 incl
Up to 0.10 incl
Aluminum**
Over 0.10 to 0.20 incl Over 0.20 to 0.30 incl Over 0.30 to 0.80 incl Over 0.80 to 1.80 incl Lead"
0.15 to 0.35 incl
Copper"
0.03
0.03""
To 1.00 incl
m
0.03
Over 1.00 to 2.00 incl
m
m
m m m
m
m
m
m
0.05
--
iil
Columbium** To 0.10 incl
Nitrogen'*
n
0.01 "**
To 0.15 incl
0.03
To 0.30 incl
0.005
--
--
-
if the minimum of the range is 0.01%, the under tolerance is 0.005%. *Sulfur over 0.060 per cent is not subject to product analysis. **Tolerances shown apply only to 100 sq in. or less.
42
m
m
Titanium'" Zirconium'*
iii!¸¸ 'ii
"**Tolerance is over and under.
NOTE: Boron is not subject to product analysis tolerances.
............
HAR DENAB ILITY OF STEEL Hardenability is a term used to designate that property of steel which determines the depth and distribution of hardness induced by quench ing from the austenitizing temperature. Whereas the as-quenched sur face hardness of a steel part is dependent primarily on carbon content and cooling rate, the depth to which a certain hardness level is main tained with given quenching conditions is a function of its harden
ability. Hardenability is largely determined by the percentage of alloying elements present in the steel. Austenitic grain size, time and temperature during austenitizing, and prior microstructure also can have significant effects. Since hardenability is determined by standard procedures as described below, it is constant for a given composition, whereas hardness will vary with the cooling rate. Thus, for a given composi tion, the hardness obtained at any location in a part will depend not only on carbon content and hardenability but also on the size and configuration of the part and the quenchant and quenching condi tions used.
The hardenability required for a particular part depends on many factors, including size, design, and service stresses. For highly stressed parts, particularly those loaded principally in tension, the best combination of strength and toughness is attained by through hardening to a martensitic structure followed by adequate tempering. Quenching such parts to a minimum of 80% martensite is generally considered adequate. Carbon steel can be used for thin sections, but as section size increases, alloy steels of increasing hardenability are required. Where only moderate stresses are involved, quenching to a minimum of 50% martensite is sometimes appropriate. In order to satisfy the stress loading requirements of a partic ular application, a carbon or alloy steel having the required harden ability must be selected. Grades suitable for highly stressed parts are listed on page 60 according to the section sizes in which the proper ties shown can be attained by oil or water quenching to 80% marten site. Grades for moderately stressed parts (quenched to 50% marten site) are listed on pages 58 and 59. The usual practice is to select 43
the most economical grade which can consistently meet the desired properties. These tables should be used as a guide only, in view of the many variables which can exist in production heat-treating. Further, these tables are of only nominal use when the part must exhibit special properties which can be obtained only by composition (see Effects of Elements, page 19). There are many applications where through-hardening is not necessary, or even desirable. For example, for parts which are stressed principally at or near the surface, or in which wear-resistance or resistance to shock loading are primary considerations, shallow hardening steels or surface hardening treatments, as discussed below, may be appropriate.
End-Quench
Hardenability Testing The most commonly used method of determining hardenability is the end-quench test developed by Jominy and Boegehold . In con ducting the test, a 1-inch-round specimen 4 inches long is first normal ized to eliminate the variable of prior microstructure, then heated uniformly to a standard austenitizing temperature. The specimen is removed from the furnace, placed in a jig, and immediately end quenched by a jet of water maintained at room temperature. The water contacts the end-face of the specimen without wetting the sides, and quenching is continued until the entire specimen has cooled. Longitudinal flat surfaces are ground on opposite sides of the quenched specimen, and Rockwell C scale readings are taken at 16tho inch intervals for the first inch from the quenched end, and at greater intervals beyond that point until a hardness level of HRC 20 or a distance of 2 inches from the quenched end is reached. A harden ability curve is usually plotted using Rockwell C readings as ordinates and distances from the quenched end as abscissas. Representative data have been accumulated for a variety of standard grades and are
published by SAE and AISI as H-bands. These show graphically and in tabular form the high and low limits applicable to each grade. Steels specified to these limits are designated as H-grades. Limits for standard H-grades are listed on pages 51-57. Since only the end of the specimen is quenched in this test, it is obvious that the cooling rate along the surface of the specimen de creases as the distance from the quenched end increases. Experiments 1For a complete description of this test. see the SAE Handbook J406, or ASTM Designation A255.
44
COOLING RATE, DEG. F PER SECOND AT 1300 DEG. F
z3 m
LLI h,,
2
< c
[E
<
m
1 ........
,[
I
Rounds Quenched in Mildly Agitated Oil
0
2
1
5
llllill 111il
6 7 8 910
12 14 161820 24 32 48
POSITION ON JOMINY BAR--SIXTEENTHS OF IN. COOLING RATE, DEG. F PER SECOND AT 1300 DEG. F
,f
,f
.... S
z3
iv
/
uJ ,h,
/
I // , /v
,/"
/
2"
,<2 m rr
<
m
J
1
I
Rounds Quenched in Mildly Agitated Water 1ii111[ i I III ........
1
2
3 4
5
6 7 8 g10
POSITION ON JOMINY BAR--SIXTEENTHS OF IN.
12
14 16 1820 24 32 48
(From 1959 SAE Handbook, p. 55)
have confirmed that the cooling rate at a given point along the bar can be correlated with the cooling rate at various locations in rounds of various sizes. The graphs above show this correlation for sur A radius, and center locations for rounds up to 4 face, 3,4 radius,
inches in diameter quenched in mildly agitated oil and in mildly agitated water. Similar data are shown at the top of each H-band as published by SAE and AISI. These values are not absolute, but are useful in determining the grades which may achieve a particular hardness at a specified location in a given section.
45
Calculation of End-Quench
Hardenability Based on Analysis It is sometimes desirable to predict the end-quench harden ability curve of a proposed analysis or of a commercial steel not available for testing. The methodx described here affords a reason ably accurate means of calculating hardness at any Jominy location on a section of steel of known analysis and grain size. To illustrate this method, consider a heat of 8640 having a grain size of No. 8 at the quenching temperature and the analysis shown in step II, below.
STEP I. Determine the initial hardness (IH). This is the hard . inch on the end-quench specimen and is a function of the carbon content as illustrated by the graph below. The IH for .39% carbon is HRC 55.5. ness at
Based on the work of M. A. Grossman, AIME, February 1942, and J. Field, Metal Progress, March 1943.
46
STEP II. Calculate the ideal critical diameter (DI). This is the diameter of the largest round of the given analysis which will harden to 50% martensite at the center during an ideal quench. The DI is the product of the multiplying factors representing each element. From the graphs below and on page °48, find the multiplying fac tors for carbon at No. 8 grain size, and for the other elements:
C Heat Analysis(%)
.39
Multiplying Factor
.91
Mn .25
.195
4.03
Si
.54
Ni
Cr Mo
.56 .20
1.18
1.20
2.21 1.60
The product of these factors is 3.93 DI. MULTIPLYING FACTORS FOR CARBON PER GRAIN SIZE •
; ,i '!,i
ii
,iI l tlJ l iil l,i
i[
!, t !
t ! li If tl t
tiJ
lilI !i
i{ii iili J I
/
No. 4 GRAIN
.32 : ' i ! . ;. ', [ { i : [ ! I [ I ! [ t , [ [/ , i' i
li ii!; il ii iilI ill
{ i i i i ] t ! i l i i ; , 1/i i]_ ; [ } i I I i I i ! ': ] I / i !Z,N°.5 ;i I!iI I!!I iiIi
;:!
:
--
.30 i i i i { i { i I i i i I I i ':
-
' ;l
Z 0
.28 i ! i !. i i ' i I.....i i I ii ) f ' t i l !
< m
ii i i
il
i,
i
:"
.. ,
ili iiiI 1 !/ i / ! i/ i ' ! i
'
:
;
;
,
No. 7
iV l
I/! ', _ lI J I/i i
ll! i il ! i / i i!
'.i'.'. ..... i ; ; 7, . , i I i i, II. ;/ /; i /i i,
i
" i i I [I
, i i ; t li i Yi 1! i
:ii
No. 8
, ......... iii
<
! ' ; :/ i/ . 11 , : i : !
o , . ,, < ' i.u l
i
/i ://
i :, : : /: !/i i/ I I...! / ' ' i i i : :
F-. .20 i
.
'i ! i
'
Ii i ,I
l
Im
i j/'I i V'i i i
l i t I/ i1I I /
'I ,
"'
'[ i iJl
[/! i [/ L
1 i i i ]ii i iY i i /i I 11 ;l,#'il l/i J l!r
, '
i ! f i i ......
,,
'i lit
t .... /]i! No. 6
< 0
iIi !II/ i
''ii l i i! !i!;
o5
I
;,
' l l II ! i/ i i i i i : : i
, . i : i/ i/ /{ Z i './ ' i i i ! ! i 1
' i ' I 1.1/ i /i [Y i ] [ [ ] i " [ ',' d Ii/ il i!') i! i i:! .,i'il
:.;i i!:!
7':ii
iJfli ' ';! ! i:i i [
i i/:
r< : : : : l
I i/
! : : I ! ://j V.
,, .16 i : : :. 7 i i/ #; ..... ii ' i i i ! "
!" ; i
,/ ii: i :!!!i!i , , , i
i:i!
'
, '.. ; '
,
: ' ! '/ i / ! ; i { i { ! i :, i i i i i
:: : ! i
'i ! / ' I i i li
' : ! t': .14 ,, : : ' : i i ! i t
0
.10
:20
.30
,:i i!!
.40
.50
.60
f
ii:[
CARBON, PER CENT
47
MULTIPLYING FACTORS FOR ALLOYING ELEMENTS
6.00
/
/ 1/ r
I /
3.00
/
/
/
/ / 1t
//
//
i
PER CENT OF ELEMENT
STEP !11. Determine the IH/DH ratios corresponding to each Jominy distance for a DI of 3.93. The IH/DH ratio is based on the observation that with a DI 7.30 or greater, an end-quench curve approximating a straight line out to 2 inches is obtained, and that a DI less than 7.30 will produce a falling curve. The drop in hardness at any point on the curve may be conveniently expressed as a ratio of the maximum hardness attainable (IH) to the hardness actually obtained (DH). The IH/DH ratios, or dividing factors, are plotted on page 49.
48
RELATION BETWEEN DI AND DIVIDING FACTORS FOR VARIOUS DISTANCES FROM QUENCHED END I il
I
t il 1 1 1 II I I j
1
t
It
I
1
..... I I
I i i
7.00
|
i
[
r •
L
I
6.00
L Ll&%
I llll l It11%
l lll\ k
I ill
5.00
&
l Ill l
l L
I
I ll IIl
n" III
¥%&%
I |I _/
4.00
L I
i I I 1
(..) I-. .=.
'
I'
I |
n
O
k X , ,%\
L .....
k
I
-.i
\\ ,\'k
L %
UJ
E)
I I
t .... 1
3.00
L
%
! 1
%
L \ t 1 I I I
k
\
.......
i
l
\ \
\]
[l
2.00
\
, tl
i\? J'
i
%
\
] "r",,
\
\
?-" :"
1 -I
1.00
11"
1.00
2.00
1
i I I
I I*i
3.00
• L
4.00
DIVIDING FACTOR (IH/DH)
49
STEP IV.Calculate the Rockwell C hardness for each distance
by dividing the IH (5 5.5 ) by each respective dividing factor" Distance, in. 1,46
--
¼ ½ ¾ 1
1¼
Dividing Factor 55.5
1.03 1.21 1.41 1.61
54 46 39.5 34.5
1.75
32
1½ 1.84 30 1¾ 1.92 29 2 1.96 28.5
5O
Calculated HRC
HARDENABILITY
LIMITS The following tables show maximum and minimum hardenability limits for carbon and alloy H-steels
from the latest published data of AISI. These values are rounded off to the nearest Rockwell C hardness unit, and are to be used for specification purposes. For steels which may have been designated as H-steels after the publishing date of this handbook, refer to the latest issues of the applicable AISI Car bon and Alloy Steel Products Manuals.
End-Quench Hardenability Limits ,,j,, Distance Sixteenths of an inch
1038 H Max Min 58
55
i
51 26
30 28
22 21
27
62
34
49
37
Max Min
52
23
9
33 32 30
55 31
42 28
26 25
25
24
50
Max Min 41
47
45
39 34 30
27
22
32 20
51 45
29
Max Min 42
39
35 32 27
Max Min 53
48
29
38 22
1541 H
46
27
44 26
49
39
33 30 26
60 57
38
21
53 44
59
55
44
52 48
25
50 38
39
32 27 23
26 25
24 24
33 22
28 21
23
23
32
23
27 20
22
21
26
10
25
29
12
24
13 14 15 16
38
31
26
11
59
Max Min
1526 H
1524 H
1522 H
1045 H
22
21
31 20 30
18 20 22 24 26 28 30 32
51
End-Quench Hardenability Limits (Cont'd) ,,j ,,
Distance 1 5B21 H Sixteenths of an
inch
15B35 H
15B37 H
15B41 H
Max Min
Max Min
1 2 3 4
48 41 47 40 46 38 44 30
58 56
5 6 7 8
4O 20 35 27 2O
53
55 54 51
47 41
9
10 11
12
,,,
51 50
49 48
39
24 22
52
58 56
Max Min 50 50
49 48
59 58
53
57
51 50
27
40 21 53 28 20
51
29
49 24
24
27
42 22
22
25
36 21
23
60 59
53 52
58
51
57 56
49 48
60 59 58 57 56 55 53 51 48 45 41 38
55
25
9
1 330 H
50
25
39 21 34
33
Max Min
1 335 H Max Min
56 49 56 47 55 44 53 40
58 57
51 49
52 50 48 45
35 31 28 26
54 52 50 48
43 42 40 39
25 23 22 21
37 36 35
20
56 55
20
Max Min
60 53 60 52
63 56 63 56
38 34 31 29
57 56 55 54
46 44 42 41
27 26 25 24
40 39 38 37
15B62 H
56 56 55 54
Max Min
'60 60 60 60
53 65 59 52 65 58 42 64 57 37 64 52 31 64 43 30 63 39 29 63 37 28 63 35 27 62 35 27 62 34 26 61 33 26 60 33
........
34 25 58 32 32 24 54 31 31 23 48 30 30 22 43 30 29 21 40 29 29 20 37 28 28 35 27 28 34 26
4027 H 4028 H
4037 H
Max Min
Max Min
52 45 50 40 46 31 40 25
59 52 57 49 54 42 51 35
62 61
55 54
46 40 35 33
61 60 60 59
51 44 38 35
34 22 30 20
45 30 38 26 34 23 32 22
52 51 50 48
31 29 28 27
58 57 56 55
33 32 31 30
25 25 24 23
30 21 29 20
23 22 22 21
46 44 42 41
26 25 25 24
54 53 52 51
29 29 28 28
23 22 22
26 26 26 25
20
39
23
49
27
21
25 25 25 24
28 26
21
28 27
....................
35
26 28 30 32
31 31
31 31 30 30
30 30
1 345 H
Max ' Min
51 49
34 33 32 31
47 44
1 340 H
59 58
18 20 22 24
52
26
31 31
38 15 16
52
46 23
3O
10
37
54 32
32 ,,j,,
Max Min
63 62 62 61
55 44
22
25
20
50
33 26
45
33
52 51
43
37
20
......
26 28
55 54
28
26
18 20 22 24
Max Min
30 ...........
13 14 15 16
Distance Sixteenths of an inch
15B48 H
.....
34 33 32
38 23 48 27 37 22 47 26 36 22 46 26 35 35 34 20 34 20
21 45 21 45 45 24 45 24
25 25
20
24 24 23 23
#ojeo
Distance
4047 H
Sixteenths ................................ of an
inch
Max Min
4118 H
Max Min
4130 H
Max Min
4137 H
Max Min
4140 H
Max Min
4142 H
Max Min
.........................................
1
64
2 3
62 60
4
58
55 50
57
42
48
46 41
35
36 27
41 23
55 53
56
49
46 42
52
59
59 58
51 50
57
49 57 56
38
52
58
60 60
53 52
59
51 58 58
49
60
53
62 62
59
51
55 54
62
55
61
53
............................
5
6 7 8 9 10 11 12
55
35
52 32 28 47 30 27 43 28 25 40 28 38 27 37 26 35 26
20
49
34 47 44
31 29
42
27
55
................ , ................
24 23 22 21
40
26
38
26
36 35
13 14 15 16
34 25 21 33 25 20 33 25 32 25
18 20 22 24
31 24 30 24 30 23 30 23
26 28 30 32
31
,,
25 25
54
.......
34 34 33 33
24 24 23 23
55 53 52
48 45
43 40
39
51 50 49 48
37 36
35 34 33 33
50 48
61
53 61 60
57
47
57
44
56 55
40 39
55 54' 54 53
38 37 36 35
56
42
52 51
59
60
50
60
49
59 58
46 44
47
58 42 57 41 57 40 56 39
...................... ,
32
22
32
I .........
30 22 29 22 29 21 29 21
46
21
32 31
45
20
44 43
32
31
30 30
52
51
49
34
33
33
48
54
32
55 53
37
36
35
53
34
.........
31 30 30
42 42 41
29
41
30 29 29
29
47 46 45
44
32 31 31
30
52 51 51
34 34 33
50
33
............... ..,.. ................... . .............
-.
J
Distance
4145 H
Sixteenths ................. of an
inch
Max Min
4147 H
Max Min
4150 H
Max Min
4161 H
Max Min
4320 H
Max Min
4340 H
Max Min
......
1 2 3 4
63 63 62 62
56 55 55 54
64 64 64 64
57 57 56 56
65 65 65 65
59 59 59 58
65 65 65 65
60 60 60 60
48 47 45 43
41 38 35 32
60 60 60 60
53 53 53 53
...........
5
6
7 8
61
62
61 61
53
53 52 52
63
63
55
55
65
63 63
55 54
57
65 64
65
65
57 56
58
60
65 65
38
65
60
27
60 60
41
29
60
"60
53 25 23
60 60
53 52
22 21 20 20
60 60 59 59
52 52 51 51
36 34
53
...............
9 10 11 12
60 60 60 59
51 50 49 48
63 62 62 62
54 53 52 51
64 64 64 63
56 55 54 53
65 65 65 64
59 59 59 59
33 31 30 29
13 14 15 16
59 59 58 58
46 45 43 42
61 61 60 60
49 48 46 45
63 62 62 62
51 50 48 47
64 64 64 64
58 58 57 56
28 27 27 26
59 58 58 58
50 49 49 48
18 20 22 24
57 57 56 55
40 38 37 36
59 59 58 57
42 40 39 38
61 60 59 59
45 43 41 40
64 63 63 63
55 53 50 48
25 25 24 24
58 57 57 57
47 46 45 44
56 56 56
42 41 40
........
.................
26 28 30 32
55
55 55 54
35
35 34 34
57 56 56
57
37 37 36
37
58 58 58
58
38 38 38
39
63 63 63
63 43 42 41
45
24 24 24
24
57
43
53
End-Quench Hardenability Limits (Cant'd) EijIt
E4340 H
Distance Sixteenths ,,
of an
Max Min
inch
1 2 3 4
60 53 60 53 60 53 60 53
5 6 7 8
60 60 60 60
53 53 53 53
4419 H
'1
Max Min 48 45 41 34 30
28 27 25
Max Min
Max Min
41 35 27 24
48 47 46 44
21
34
21
41
20 31 37 25 29 34 23 25 27 32 22 24
25 24 24 23
26 25 24 23
13 14 15 16
60 52 59 52 59 52 59 51
23 22 22 21
22 22 22 21
24
18 20 22 24
58 51 58 50 58 49 57 48
21 20
21 2O
23
26 28 30 32
57 47 57 46 57 45 57 44
4720 H
Max Min
48 45 42 39
60 53 60 53 60 53 60 53
,,j,,
4626 H
40 33 27 23
9 10 11 12
Distance
4621 H
4620 H
28
30
41 38 34 30 27
27
20
4718 H Max
Min
51 48 41 33
45 36 29 24
47 47 45 43
40 40 38 33
29
21
40 37 35 33
29
32
23 22 22
23 22 22
27 26
31
30 29
21
26 25 25
29 28 27 27
21
20
23 22
inch
Max Min
Max Min
1 2 3 4
48 41 47 39 43 31 39 27
45 44 44 42
5 6 7 8
35 23 32 21 29 28
19
27
213
38 37 34 30
Max Min
4820 H
5120 H
39 38 35 32
Max Min
Max Min
48 40 56 49 46 34 55 46 41 28 53 42 36 23 51 39
41 27 42 29 39 24 41 27 37 22 39 25 35 21 37 23
45 43 42 40
34 31 29 27
33 20 49 35 30 47 32 28 45 3O 27 42 28
33 31 30 29
35 22 33 21 32 20 31 20
39 26 37 25 36 24 35 23
25 24 23 22
40 38 37 36
21 21 20
35 21 34 20 34
25 24
13 14 15 16
24 23 23 22
28 28 27 27
30 29 28 28
34 22 33 22 32 21 31 21
21 21 21 20
26 25 24 24
27 26 25 25
29 28
24 23 23 23
26 28 30 32
54
Max Min
,,
41 4O 39 38
11 12
18 20 22 24
28 27 25 25 24 24
21
20 20
5130 H
48 48 47 46
20
46 46 45 44
21
25 24 24 24
Sixteenths
of an
21
27 26 26 25
21 21
4817 H
25 24
,,
24
22 22
4815 H
27
27
26 26 25
20 20
26 25 23 22
33 32 31
30 29 27 26 25 24
oojoo Distance Sixteenths of an
inch
5132 H Max Min
5135 H
5140 H
Max Min
Max Min
5147 H
5145 H Max Min
Max Min
Max Min
........
1 2 3 4
57 50 56 47 54 43 52 40
58 51 57 49 56 47 55 43
60 59 58 57
53 52 50 48
63 62 61 60
56 55 53 51
64 64 63 62
57 56 55 54
5 6 7 8
50 35 48 32 45 29 42 27
54 38 52 35 50 32 47 30
56
43
59
48
62
53
52
35
57
38
61
40 25
45 28 43 27 41 25 40 24
48 46
.................
9
12
37 23 36 22 34 20 33
54 50
45
43
39 23 38 22 37 21 37 21
40
37
42 39 38
38 33
31 30
29
28
27
27
26 25
36
26 28 30 32
28 27 26 25
32 32
31 30 ,
34 33 33 32
5160 H
6118 H
,,j,,
5155 H
0istance Sixteenths of an inch
Max Min
36
35 34
Max Min
1 2 3 4
60 60 65 59 60 64 58 60 64 57 65 59
5 6 7 8
63 55 65 63 52 64 56 62 47 64 52 62 41 63 47
9 10 11 12
61 37 62 42 60 36 61 39 59 35 60 37 57 34 59
13 14 15 16
55 52 51 49
34 33 33 32
18 20 22 24 26 28 30 32
58
24
23
21 20
55 53
52
30
35
33 32
31
48
47
41
29
42
39 38
58 30
28 28 25
57
26
24 23
61
49
60 60 59
59
35
34
54
6
64 63 62
52 45
40 37
58-
32
57 56
65
33
55 53 52
29
30 27 26
6150 H Max Min
8617 H Max Min
46 44 41 38
30 28 27 26
34 20 37 23 31 34 21 28 32 27 30
43 41 39 38
26 25 24 23
29 28 27 26
58 35 56 35 54 34 52 34
24 23 23 22
57 37 55 36 54 35 52 35
23 22 22 21
25 25 24 24
47 45 44 43
31 48 33 31 47 32 30 46 31 29 45 30
22 21 21 20
50 48 47 46
21 20
23 23
42 41 41 40
28 27 26 25
44 29 43 28 43 28 42 27
45 29 44 27 43 26 42 25
58 56 55 53
36 34 33 32
51 5O
31 31 3O 3O
45 43 42 41
29 28 27 26
40 39 39 38
25 24 23 22
48 41 47 37 44 32 41 27
61 60 59 58
34 32 31 30
53 49 42 38
Max Min
26 25 25 24
36
60 59
8620 H
46 39 65 59 44 36 65 58 38 28 64 57 33 24 64 56 22 63 55 20 63 53 62 50 61 47
39 33 27 24
59 58 57 56
61
48 47
32 31
37 22 51 25 37 21 50 24 36 49 22 35 48 21
Max Min
,,,
42
56
45 44
32 31 30 29
20
58
50
18 20 22 24
35 34 33
5150 H
23 23 23 22 22 22
55
End-Quench Hardenability Limits (Cant'd) ,,j ,,
Distance Sixteenths of an
inch
8622 H
Max Min
8625 H
50 49
43 39
52 51
45 41
4
44
30
46
32
47
5 6 7
40 37 34
8
32
9
31
10
11
34
20
30
29
Max Min
Max Min, Max Min
1 2
3
8630 H 8637 H
8627 H
26 24 22
48
43 40 37
35
29 27 25
23
32
30
21
31
32 22
48 45 43 40
38
33 22 36 24
54 52
36
26
20
34
50
47 43. 35
56 55 54 52
38
32 29 27
24
33
23
49 46 43 39
Max Min
59 58 58 57
52 51 50 48
50 47 44 41
35 32 29 28
56 55 54 53
45 42 39 36
39 37 35 34
27 26 25 24
51 49 47 46
34 32 31 30
8640 H Max
Min
60
53 53 52
........
6O
60 59
51
,, ,
49 46 42 39
59 58 57
55 54 52
5O
36 34 32
33 23 44 29 33 22 43 28 32 22 41 27 31 21 40 26
47 45 44 42
30 29 28 28
12
28
13 14 15 16
27 26 26 25
29 28
18 20 22 24
25 24 24 24
27 26 26 26
28 28 28 27
30 21 39 25 30 20 37 25 29 20 36 24 29 36 24
41
39 38 38
26 26 25 25
26 28 30 32
24 24 24 24
26 25 25 25
27 27 27 27
29 29 29 29
37 37 37 37
24 24 24 24
28 27
31 21 30 21 30 29
.o j,,
Distance
20 20
8655 H
8645 H
8642 H
49
35 24 35 24 35 23 35 23
8720 H
8740 H
31
8822 H
Sixteenths
of an inch
Max Min
1 2 3 4
62 62 62 61
5 6 7 8
61 50 60 48 61 59 45 58 42 60
9
57 39 59 41
10 11
55 54 53 52
Max Min
55 54
12
52
13
50
63 56 63 56 63 55 63 54 62 50 61 45
37 34
33 32
52 48
58 56
14 15 16
49 48 46
31 30 29
52 51 49
18 20 22 24
44 42 41 40
28 28 27 27
47 45 43 42
26
40
28 30
39 39
32
39
56
Max Min
26
26 26
26
41 41
52 55 54
39 37
33 32 31
35 34
30 29 28 28
42 41
27 27
65 65
63 63 62 60 59 58
27 27
56 55
49 46
41 60 53 38 60 53 35 60 52 30 60 51
50 49 48 46
57 56 55 54
38 35 33 31
26 59 49 24 58 46 22 57 43 21 56 40
43 29 40 27 37 25 35 24
30 29 28 27
34 33 32 31
64
41
1 35 34 34
37 24 23 23
33 32
53
Max Min
48 47 45 42
43
57
Max Min
60 59 59 58
64
40 39 38
Max Min
26 25 25
55 37 53 35 52 34 50 32
26
24
33
23
32
221
23 22
20
I
49
48 46 45
31 30 29
42 41 40
43 28 27 27
39 38
27 26
39
38
31
28 27 27
27 26
24 23 23 22
31 22 30 22 30 21 29 21 29
28
43 42 39 33
27
27 27 27
20
.........
oaj tr
Distance
9260 H
50B44 H
Sixteenths
of an
inch
Max Min
60
3 4
65
57
5 6 7 8
63
46
64
62 60 58
63 62
53
63
Max Min
56 55
62
61
41 38 36
56
61 60 60
63 61
55 54
52 48 43
Max Min
56
12
50B60 H
51 B60 H
59
59
54
64
60
41
58 57 56
Max Min
65
59
58
50
64
63
32 31 30
Max Min
60
56
63 62 62
60 60 60 60
60
60
57
60 60
55 52 47
65
6O
59 57 53
59 58 57
............
............
55 52 49
11
65
62
52
.....
9 10
50B50 H
,,,
I
Max Min
60
1
2
50B46 H
47
36 35 34
59 58 57
34
56
38 34 31
30
.........
54 51 47
43
29 28 27
26
61 60 60
42 37 35
59
33
65 64 64
47 42 39
64
54 50 44
37
65
41
...................... p ....
13 14 15 16
45
18 20 22 24
38
43
42 40
33
33
54
52
32 32
50 48
29
29 28. 27
38
40 37
25
36
26 25
57
24
58
56
31
54
32 30
63
29
35
63
63
62
36
64
34 34
65
39
64 63
40
38 37
......
37 36 36
31
44
31 30 30
40 38 37
26
24 23 21
35
34 33 32
23
22 21 20
50
28
47 44 41
60
27 26 25
33
58 55 53
61
31 30 29
36
59 57 55
34 33 31
......
....
26 28 30 32
35 35 35
34
29 29
28
34
28
36 35
20
31 30
29
33
37
28
39 38
24 22
36
20
21
47
51 49
28 27
44
25
26
49
53 51
30 28
47
25
27
..........
..... ,,j,, Distance Sixteenths of an inch 1
2
3 4
81 B45 H Max Min
94B17 H Max Min
63 63 63 63
56 56 56 56
63 63 62
55 54 53
46 46 45 45
94B30 H
Max Min 39 39 38 37
56 56 55 55
34 29 26
54 54 53
Max Min
Max Min
Max Min
49 49 48 48
.........
,,,
5 6 7 8
62
....
9
10 11
12
61 60 60
51
44 43 42
41
48 44 41
59 39 34
40 38 36
24
23 21 20
51 32
53
47 42
52 52 51
46 44 39 37 34
13 14 15 16
58 38 33 57 37 32 57 36 31 56 35 30
50 30 49 29 48 28 46 27
18 20 22 24
55 34 28 53 32 27 52 31 26 50 30 25
44 42 4O 38
26 28 30 32
49 47 45 43
37 22 35 21 34 21 34 20
.....
29 28 28 27
24 24 23 23
25 24 23 23
.......
57
Mechanical properties obtainable with steels for
MODERATELY STRESSED PARTS OIL QUENCH Round Sections
To ½ in. Hard ness after quench Yield strength, psi
Over Over Over Over ½ in. Over 1 in. 1½ in. 2 in. to 2½ in. to 1 in. to 1½ in. to 2 in. 2½ in. to 3 in.
Quenched to 50% Martensite Full radius to center
Hardness ing 50% after marten temper,
RC
6/16
1330H 4130H
8637H
tO
125,000
5132H
Over 125,000 to
30 to 36
42
44
36 to 41
48
3140H 4135H
1340H 3140H 4047H 4135H 50B40
4137H 4140H 5150H 8642H 8645H 8742H
4142H 4337H
5140H 8637H Over 170,000 to
41 to 46 51
185,000
4063H 4140H 50B44 5145H 5150H 8640H 8642H 8740H
7-1/2/16 10/16 10-1/2/16 3140H
8640H 8740H
50B50 5147H 6150H
4137H
Over 46 min 55
58
4150H 5160H 8655H 9262H
15/16
4140H
4142H
4145H
4337H 86B45 9850
4142H 50B50 5147H
4145H
4147H 4337H 81B45 86B45
4340H
4145H 50B60 81B45 8650H 8655H 9260H
4147H
6150H 8642H 8645H 8742H
8742H 9260H
185,000
13/16
8740H
1335H 4042H 5135H
150,000
Over 150,000 to 170,000
At ¾ radius
Jominy Reference Point 3-1/2/16
90,000 23 tO 30
At ½ radius
site,
min
Over 3 in. to 3½ in.
50B60
8660H
8655H 9840
4340H 51B60 81B45 86B45 8660H
4150H 9850
Mechanical properties obtainable with steels for
MODERATELY STRESSED PARTS WAT E R Q U E N C H Round Sections
To ½ in.
Over Over Over Over ½ in. Over 1 in. 1½ in. 2 in. to 2½ in. to 1 in. to 1½ in. to 2 in. 2½ in. to 3 in.
Over 3 in. to 3½ in,
.......... Hard ness after quench
Yield
RC
site.
min
90,000 23 to 30 to 125,000
Full radius to center
At ½ radius
Hardness ing 50% after marten
strength, temper,
psi
....... i
Quenched to 50% Martensite At
radius
Jominy Reference Point
1-1/2/16 3/16
42 1040
4/16
1330H 4037H 4130H
6/16
5/16 6-1/2/16
7-1/2/16
1340H 4135H 8637H
3140H 8640H 8740H
5130H 5132H 8630H
Over 30 to 36 44 1036 1335H 1340H 4135H 125,000 1045 5135H 3140H 5150H to 1330H 5140H 8640H 150,000 4130H 5145H 8740H 8630H 8637H
4137H 4140H 50B40 6150H 8642H 8645H 8742H
Over 36 to 41 48 1335H 4042H 1340H 4137H 4140H 150,000 4037H 50B40 4135H 50B40 50B44 to 5135H 50B40 5145H 6150H 170,000 5140H 8640H 8645H 8637H 8740H 8742H
50B50 5147H 9262H
....
NOTE: Parts made of steel with a carbon content of .33% or higher should not be water quenched without careful exploration for quench cracking.
59
Mechanical properties obtainable with steels for
HIGHLY STRESSED PARTS--OIL QUENCH Round Sections Over ½ in. Over 1 in. to 1 in. to 1½ in.to2
To ½ in. Hard ness after quench
temper,
RC
to
1330H 4130H
125,0001
5132H
Over 30 to 36 44 125,000 to 150,000
6/16
1335H
3140H 4135H 50B40 8640H 8740H
5135H
36 to 41 48
Over 150,000 to
1340H 5140H 3140H 8637H
4137H 8642H 8645H
4047H
170,000
41 to 46
Over 170,000 to 185,000
3½ in.
At ½ radius
At ¾ radius
Jominy Reference Point 3-1/2/16
90,000 23 to 30 42
Over
3 in. to
........
Full radius to center
site,
min
Over Over Over 2 in. to 2½ in. 2½ in. to 3 in.
Quenched to 80% Martensite
Hardness ing 80% after marten
Yield strength, psi
1½ in. in.
7-1/2/16
4137H
10/16 10-1/2/16
4142H
13/16
9840
4337H 86B45 9850
4147 4147H
4340H
81B45
4140H
4145H 9840
15/16
4337H 81B45 86B45
4135H 50B40
8742H
4063H 8640H 4140H 8642H 50B44 8740H 50B50 8742H 5145H 9260H
50B50 4142H 8650H 51B60 5147H 4145H 8655H 8660H 5160H 4337H 6150H 50B60 9262H 81B45
4147H
4340H 81B45 86B45
4150H 9850
5150H
Over 46 min
4150H 8655H 50B60 9262H
185,000
8660H
5160H
WATER QUENCH Jominy Reference Point 1-1/2/16
90,000 23 to 30
• 3/16
42
,i
4/16
6/16
5/16 6-1/2/16 7-1/2/16
1330H 4130H
to
5130H 5132H 8630H
125,000
30 to 36 44
Over 125t.000
1330H 5132H 4130H 8630H 5130H
150,000
5132H
1340H 3140H 50B40 8637H
4135H 4137H
NOTE: Parts made of steel with a carbon content of .33% or higher should not be water quenched without careful exploration for quench cracking.
60
THERMAL TREATMENT OF STEEL The versatility of steel is attributable in large measure to its response to a variety of thermal treatments. While a major percentage of steel is used in the as-rolled condition, thermal treatment greatly broadens the spectrum of properties attainable. Treatments fall into two general categories: ( 1 ), those which increase the strength, hardness and toughness by virtue of rapid cooling from above the transforma tion range, and (2), those which decrease hardness and promote uniformity by slow cooling from above the transformation range, or by prolonged heating within or below the transformation range, followed by slow cooling. The first category can involve through hardening by quenching and tempering, or a variety of specialized treatments undertaken to enhance hardness of the surface to a con trolled depth. The second category encompasses normalizing and various types of annealing, the purpose of which may be to improve machinability, toughness, or cold forming characteristics, or to re lieve stresses and restore ductility after a processing which has in volved some form of cold deformation.
Conventional Quenching
and Tempering As discussed in the previous section, the best combination of
strength and toughness is usually obtained by suitably tempering a quenched microstructure consisting of a minimum of 80% marten site throughout the cross section. Steels of suitable hardenability at tain this martensitic structure when liquid-quenched from their austenitizing temperatures. Those used most frequently for quenched and tempered parts contain from .30 to .60% carbon, although the carbon specification for any particular application must be de termined by the surface hardness and overall strength level required. The hardenability necessary to attain the desired through hardening is a function of the section size and the quenching parameters (see
graph, page 62). Plain carbon steels with low manganese content can be through hardened only in very thin sections when a mild quench is used. With
61
higher manganese carbon grades, or more drastic quenches, some
what heavier sections can be quenched effectively. For sections beyond the hardening capability of carbon steels, carbon-boron or alloy steels are required.
QUENCHING MEDIA. As indicated above, the mechanical properties obtained in a quenched part are primarily dependent upon the hardenability of the steel as determined by its chemical composi tion and by the rate at which it is cooled from the austenitizing temperature. Once the desired cooling rate has been determined, a variety of factors must be considered before the method of achieving that rate can be specified. A part with a specific mass will cool at a rate determined by its temperature in relation to that of the quench ing medium, by the characteristics of that medium, and by the quenching conditions used. Furthermore, the cooling rate developed in a particular quenching facility will depend on the volume of the quenching medium as well as its temperature, specific heat, viscosity, and degree of agitation. Careful selection of the quenching medium is essential. For example, use of a drastic quench will make possible the development of a given set of properties in a steel of a specific hardenability. However, size and design of the part, or the steel composition itself, may be such that a drastic quench will cause quench cracks or distortion. Under these conditions, overall economy as well as safety will best be served by using a quenchant with less cooling capacity and a steel of greater hardenability. RELATION BETWEEN DISTANCE ON STANDARD END-QUENCH TEST AND DIAMETER OF ROUND
6 03 •
wz z
oOS n
LECIEND "OR T PES CF QUENCH (1) .bii--N,J Gi,cu,.i.ion (i-i .25)
"
_
(2))iI--G
x)d Cin,ulatio (H .4.Ji) tPI 1. JO) [ 1 /ater-,NoCirculatio' (4) /ater-Good ;ircula'ion (H 1.50) (5) 3rine-NoCir,;ulatiol, (H 2.()0) /, (6) 3rine-Vi01enl Circulation [ t 5.00)
./
/
/ .. f--J .
.
'/
"r-, '
/
//
c0 z_o
D z 2 o. rr'rr U..UJ rr"
< rn 0
2
4
6
8
11
12
14
16
1'8
20
22
24
26
28
DISTANCE FROM QUENCHED END, SIXTEENTHS OF IN.
62
30
.,..,,.
The most common quenching media are water and various mineral oils. In most quenching facilities, water is maintained at a temperature of about 65 F. As the water temperature increases, or as the amount of agitation during the quench decreases, there is an in creasing tendency for an envelope of steam to form around the part. Because this envelope interferes with the flow of water around the part, it reduces the water's effective cooling capacity. A brine of 5 to 10% sodium chloride has a lower tendency than plain water to form an envelope, and therefore provides a more effective quench. Sodium hydroxide solutions are even more effective. The brine and sodium hydroxide solutions are generally used on very shallow hardening steels to attain high surface hardness while retaining a ductile core. Quenching oils providing a wide variety of cooling rates are available commercially. These are characterized by relative stability and chemical inactivity with respect to hot steel, high flash point, and little change in cooling capacity with normal variation in tempera ture. Most production quenching facilities incorporate cooling coils to maintain the oil bath at a reasonably constant temperature, and
provide for sufficient agitation to minimize localized effects of vapor envelopes formed during quenching. Regardless of the quenching medium used, it is of utmost im portance to temper parts immediately after the quenching operation. Delay in tempering greatly increases the risk of cracking, since the as-quenched part is in a highly stressed condition.
Isothermal Treatments The preceding sections are concernedwith hardening of steel by quenching, using a medium which is at or near room temperature. Another approach to the thermal treatment of steels involves isother mal transformation, accomplished by quenching in a medium held at a constant temperature. For a given steel it may be shown by means of a series of test specimens quenched in media at various tempera tures that the time required for the beginning and for the completion of transformation varies considerably. By plotting the various quenching bath temperatures against the time interval required for inception and completion of transformation (on a logarithmic scale) the so-called "S" curve, or TTT (time-temperature-transformation) curve is produced. 63
It is not within the scope of this book to engage in a lengthy technical discussion of these curves. Some features of the curves have received rather widespread application and will be presented in the following sections. These applications involve both annealing and hardening. Each steel has a temperature range in which transformation takes place quite rapidly. This occurs at a fairly elevated temperature, and that section of the transformation curve is often referred to as the nose of the curve. Above or below this rapid transformation range, the times required for the critical changes are considerably greater. In order to harden steel it is necessary to quench at such a rate that transformation at the higher temperatures is avoided. If the bath temperature is below approximately 400 F, martensite will form. The highest temperature at which martensite will start to form is termed the Ms temperature. The Mr temperature is the highest temperature at which the transformation can be considered complete. If the quenching bath temperature is above the Ms temperature, other microstructures are formed, as discussed below. Quenching at a temperature above that of the nose of the curve results in a soft structure after completion of transformation and sub sequent cooling to room temperature. (See Annealing, page 71. )
AUSTEMPERING
Ae3
COOLING CURVES
Ms
Mf
BAINtTE TIME-LOG SCALE
64
AUSTEMPERING is a hardening treatment which consists of quenching in a molten salt bath maintained somewhat above the Ms temperature, and holding until transformation is complete. The product formed is termed lower bainite and is somewhat softer than martensite.
The advantage of austempering is the high degree of freedom it provides from distortion and quenching cracks. Higher hardenability material must be used, however, to insure against transformation oc curring at the nose of the curve, since cooling rates in molten salt baths may be lower than in the oil or water used in conventional quenching. The transformation rate of the higher hardenability steels is quite slow in the temperature range involved, and therefore, austempering has the disadvantage of requiring more time than other
quenching methods, even though it is not followed by a tempering treatment.
Ae3
,COOLING CURVES
ILl n"
rr" LLI Q.. LLI !-
TEMPERED TO
DESIRED HARDNESS
Mf TEMPERED MARTENSITE
TIME-LOG SCALE
MARTEMPERING involves quenching from the normal austenitizing temperature in a molten salt bath maintained at ap proximately the Ms temperature. The part is held at this temperature for a period of time sufficient to allow equalization of temperature within the part, but not long enough to permit any transformation to
65
occur. The material is then removed from the bath and allowed to cool in air through the martensite range, followed by the customary tempering treatment to obtain the desired mechanical properties. Like austempering, martempering tends to minimize distortion and quench cracking, since the high stresses typical of conventional quenching are avoided. The two processes also share the character
istic of requiring higher hardenability steels than those suitable for conventional quenching, as mentioned above. However, martemper
ing compares favorably with full quenching as far as time is con cerned, since the material need only be held for temperature equalization.
Surface Hardening Treatments A variety of applications require high hardness or strength primarily at the surface; for example, instances involving wear or torsional loading. Service stresses are frequently complex, neces sitating not only a hard, wear-resistant surface, but also core strength and toughness to withstand tensile or impact stresses and fatigue. Treatments required to achieve these properties involve two general types of processes: those in which the chemical composition of the surface is altered prior to quenching and tempering; and those in which only the surface layer is hardened by the heating and quenching process employed. The first category includes carburizing, cyanid ing, carbo-nitriding, and nitriding. The most common processes included in the second category are flame hardening and induction hardening.
CARBURIZlNG. In this process, carbon is diffused into the surface of the part to a controlled depth by heating in a carbonaceous medium. The resultant depth of carburization, commonly referred to as case depth, depends on the carbon potential of the medium used and the time and temperature of the carburizing treatment. The steels most suitable for carburizing are those with sufficiently low carbon contents (usually below .30% ) to enhance toughness. The actual carbon level, as well as the necessary hardenability and the type of quench, is determined by the section size and the desired core hardness.
There are three types of carburizing in general use:
LIQUID CARBURIZING involves heating in barium cya nide or sodium cyanide at temperatures ranging from 1550 to
66
1750 F. The temperature and the time at temperature are ad justed to obtain various case depths, usually up to .03 inch, although greater depths are possible. The case absorbs some nitrogen in addition to carbon, thus enhancing surface hardness.
GAS CARBURIZING involves heating in a gas of con trolled carbon potential such that the steel surface absorbs carbon. Case depths in the range of .01 to .04 inch are common, the depth again depending on temperature and time. Carbon level in the case can be controlled where advantageous.
PACK CARBURIZING consists of sealing the parts in a gas-tight container together with solid carbonaceous material and heating for eight hours or more to develop case depths in excess of .04 inch. This method is particularly suitable for pro ducing deep cases of .06 inch and over. With any of the above methods, the part may be quenched after the carburizing cycle without reheating, or it may be air-cooled fol lowed by reheating to the austenitizing temperature prior to quench ing. The recommended carburizing temperatures and quenching treatments published by SAE are listed on pages 74-76. The depth of case may be varied to suit the conditions of loading in service. For simple wear applications a very thin case may suffice. Under conditions of severe loading which would tend to collapse the case, greater case depth and higher core hardness are required. Frequently, service characteristics require that only selective areas of a part be hardened. Such selective hardening can be accom plished in various ways. The most common method is by copper plating the non-wear surfaces, or by coating them with one of several available commercial pastes, thereby allowing the carbon to penetrate only the exposed areas. A second method is by carburizing the entire part and then removing the case in the selected areas by machining or grinding. A localized hardening treatment after carburizing is another method sometimes used
NITRIDING consists of heating at a temperature of 900 to 1150 F in an atmosphere of ammonia gas and dissociated ammonia for an extended period of time, depending on the case depth desired. A thin, very hard case results from the formation of nitrides. Special compositions containing the strong nitride-forming elements (usually aluminum, chromium, and molybdenum) are used. The major ad vantages of this process are that parts can be machined prior to nitrid ing, and that during such treatment, they exhibit desirable dimen
67
sional stability with little distortion. Where required to develop core properties, parts are quenched and tempered prior to final machining. Nitrided parts have exceptional wear resistance with little tendency to gall and seize, and are therefore particularly serviceable in applica tions involving metal-to-metal wear. They also have high resistance to fatigue plus improved corrosion resistance.
CYANIDING involves heating in a bath of sodium cyanide to a temperature slightly above the transformation range to obtain a thin case of high hardness, followed by quenching. This results in a hard, somewhat brittle case (because of the presence of nitrides) backed by a fine-grained tough core. Parts have superior wear resistance, approaching that of a nitrided case.
CARBO-NITRIDING is similar to cyaniding except that the absorption of carbon and nitrogen is accomplished by heating in a gaseous atmosphere containing hydrocarbons and ammonia. Case depths range from .003 to .025 inch. Case composition depends on the atmosphere, temperature, time, and steel composition. Tempera tures of 1425 to 1625 F are used for parts to be quenched, while lower
temperatures (1200 to 1450 F) may be used where a liquid quench is not required.
FLAME HARDENING involves rapid heating with a direct high-temperature gas flame, such that the surface layer of the part is heated above the transformation range, followed by cooling at arate
which will accomplish the desired hardening. Heating and Cooling cycles must be precisely controlled to attain the desired depth of hardening consistently. Steels for flame hardening are usually in the range of .30 to .60% carbon, with hardenability appropriate for the depth to be hardened and the quenchant used. Various quenching media are used, and usually sprayed on the surface at a short distance
behind the heating flame. Immediate tempering is required to avoid cracking caused by residual stresses, and may be accomplished by conventional furnace tempering or flame tempering processes, de pending on part size and economic considerations.
INDUCTION HARDENING. In recent years considerable quantities of steel have been heated for hardening by electrical in duction. As optimum results from this type of thermal treatment involve metallurgical considerations somewhat unique for the pro cess, an explanation of the fundamental principles and metallurgical aspects follows.
68
When high frequency alternating current is sent through a coil or inductor, a magnetic field is developed in the coil. If an electrical conductor, such as a steel part, is placed in this field, it will be heated by induced energy. Heating results primarily from the resistance of the part to the flow of currents created by the induced voltage (viz., eddy current losses) and also from hysteresis losses caused by the rapidly alternating magnetic field if the part is magnetic. Thus, most plain carbon and alloy steels heat most rapidly below the Curie tem perature (approximately the upper critical temperature) where they are ferromagnetic, and less rapidly above this temperature. With conventional induction-heating generators, the heat is
developed primarily on the surface of the part. The total depth of heating depends upon the frequency of the alternating current passing through the coil, the rate at which heat is conducted from the surface to the interior, and the length of the heating cycle. Thus, the process is capable either of surface (or case) hardening to various controlled depths, or of through hardening. Surface hardening is normally ac
complished with frequencies of 10,000 to 500,000 cycles per second using high power and short heating cycles, while lower frequencies and long heating cycles are preferred for through heating by induction. Quenching is usually accomplished with a water spray intro duced at the proper time by a quench ring or through the inductor block or coil. In some instances, however, oil quenching is success
fully employed by dropping the pieces into a bath of oil after they reach the hardening temperature. From the metallurgical standpoint, induction heating and con ventional heating vary primarily in the time allowed for metallurgical reactions. Heating by induction is very rapid and zero time is nor mally provided at the hardening temperature prior to quenching. The very short austenitizing times which result may have a significant in fluence on the metallurgical results and often make it necessary to give special attention to the selection of the steel, the microstructure prior to heating, and the hardening temperature. Plain medium carbon steels are preferred for induction surface
hardening, although the free machining grades 1141 and 1144 are frequently used. Alloy steels can also be successfully induction hardened, although it is often necessary to increase the hardening temperature to provide alloy solution in steels containing carbide forming elements, e.g., 4340 and 4150. Alloy steels may be required
69
if a very deep case or through hardening is necessary. The steels tabulated below are typical of those which have been satisfactorily hardened by induction heating. Since steels containing higher carbon than those shown are also successfully induction hardened, the list should be considered indicative rather than inclusive. Plain Carbon
1040
Free Surface Hardness Machining Alloy after Quenching
1141
4140
HRC 52 Min 4340 8740
1045
1144
4145
HRC 56 Min 8645
1050
4150
HRC 60 Min 5150 6150
This tabulation also provides minimum hardnesses to be ex pected on the surface of parts surface-hardened by induction heating and quenching. These values are considered conservative minima. While the hardness in induction heating is a function of the carbon content as in conventional heating, higher hardness values for a given carbon content have often been observed for induction surface hardened parts. The increment of added hardness may be as much as 5 HRC points for steels of .30% carbon, and decreases with the car bon content.
Microstructures which show a fine uniform distribution of fer rite and carbide respond most rapidly to induction heating and are necessary where shallow case depths are required. Thus quenched and tempered or normalized structures provide optimum results, while annealed, hot-rolled, or spheroidized structures which may contain considerable amounts of massive free ferrite will require a longer heating cycle. Conventional hardening temperatures can generally be used when induction heating plain carbon grades and alloy steels con taining non-carbide-forming elements. With alloy steels containing carbide-forming elements such as chromium, molybdenum, and vanadium, however, the hardening temperature must be increased if the normal influence of the alloying elements is desired. Increased hardening temperatures do not increase the austenitic grain size since grain growth is inhibited by the undissolved carbides. In general,
70
steels heated to conventional hardening temperatures by induction show a similar or somewhat finer grain size than steels heated in the furnace for hardening. It is, of course, essential to remove any decarburized surface by machining or grinding prior to induction hardening if maximum sur face hardness is desired.
No rm a liz in g a n d A n n e a ling Preceding discussions have been concerned with the principles and techniques of hardening and strengthening of steels by various processes which involve some form of quenching and tempering. Another important type of thermal treatment has as its purpose either a softening of the steel or the development of a more uniform micro structure prior to further processing.
NORMALIZING involves heating to a temperature of about 1 O0 to 150 F above the upper critical temperature, followed by cool ing in still air. The uniformly fine-grained pearlitic structure which normally results enhances the uniformity of mechanical properties, and for certain grades, improves machinability. Notch toughness in particular is much better than that experienced in the as-rolled condi tion. For large sections, and where freedom from residual stresses or lower hardness is desired, the normalizing treatment may be followed by a stress-relief treatment (see below). Normalizing is also fre quently used as a conditioning treatment prior to quenching and tempering. The purpose is to facilitate austenitizing, particularly in grades containing strong carbide-forming elements.
ANNEALING consists of a heatingcycle, a holding period, and a controlled cooling cycle. As discussed below, various types of annealing are used for various purposes, such as to relieve stresses, to soften the steel, to improve formability, or to develop a particular microstructure conducive to optimum machinability or cold form
ability. STRESS RELIEF ANNEAL.This treatment consists of heat ing to a temperature approaching the lower transformation tempera ture (mcx), holding for a sufficient time to achieve temperature uniformity throughout the part, and then cooling to ambient tem perature. Its usual purpose is to relieve residual stresses induced by normalizing, welding, machining, or straightening or cold deforma tion of any kind. A similar treatment is sometimes used to facilitate
71
cold-shearing of as-rolled material. If the steel has undergone a con siderable amount of prior cold work, this annealing treatment will cause the ferrite in the microstructure to recrystallize; otherwise, little change in structure will result. A degree of softening and im proved ductility may beexperienced, depending on the temperature and time involved.
SUB-CRITICAL ANNEAL. This treatment differs from stress-relieving primarily in that it requires a longer holding period at the annealing temperature, and that the furnace charge is then slow-cooled at a controlled rate. The purpose of this type anneal is to soften the steel, usually in preparation for subsequent cold defor mation. The treatment does not allow consistent control of micro structures, inasmuch as the carbide tends to spheroidize to a degree which depends on prior structure and on the temperature, time, and cooling rates involved.
SOLUTION, OR FULL ANNEAL. This treatment involves heating to a temperature above the transformation range, followed by controlled cooling to a temperature substantially below that range. A predominantly lamellar microstructure is normally obtained, with some variation depenctent upon the rate of cooling through the trans formation range and the degree of homogenization of the carbides prior to cooling. This treatment softens the steel, but its principal use is to improve the machinability of medium carbon steels.
SPHEROIDIZE ANNEAL. The purpose of this type of an nealing is to achieve a spheroidal or globular form of the carbides, primarily to provide optimum cold forming characteristics. A spher
oidized structure is also desirable for machinability in high carbon steels. Several methods are used to develop this condition: (1) Heating to a temperature between the upper and lower transformation temperatures and cooling very slowly in the furnace to below the transformation range.
(2) Heating as in (1), then cooling rapidly to a temperature just below the transformation range and holding for a prolonged period (see Isothermal Anneal). (3) Heating to a temperature just below the Acz, holding for an extended length of time, then slow cooling. (4) Alternate repetitive heating to a temperature within, and to a temperature slightly below the transformation range.
72
ISOTHERMAL ANNEALING
l
Ae3
coo.
CURVES
D ,,=,
Ms
Mf FERRITE AND PEARLITE
TIME-LOG SCALE
ISOTHERMAL ANNEAL. This process makes use of the principles discussed under Isothermal Treatments (page 63)and is effective in obtaining either a lamellar or a spheroidiz d structure. If a lamellar pearlitic structure is desired, the work is austenitized above the upper transformation temperature, then cooled to, and held at a temperature at or above the nose of the S-curve. Transfor mation at the nose of the curve will be more rapid, but will result in finer pearlite and a higher hardness than transformation at higher temperatures.
To obtain a spheroidized structure, a lower austenitizing tem perature is used so that some carbide remains undissolved. Cooling and transformation as for the pearlitic anneal above will result in a spheroidized structure. By accelerating the cooling to the transformation temperature and also the cooling subsequent to transformation, appreciable time savings can be realized as compared with that required for con ventional annealing practices.
73
SAE Typical Thermal Treatments
ALLOY STEELS--Carburizing Grades Pretreatments Normalizeb Normalize Cycle SAE Numbera and Anneald Temperc
Carburizinge Temp, F
Cooling Method
Reheat Temp, F
Quenching Medium
Temperingf Temp, F
4012 4023 4024 4027
Yes
1650-1700
-
250-350
Quench in oilg
4028 4032 4118
4320
Yes
-
Yes
1650-1700
Quench in oilg Cool slowly
i
1525-1550i
m
0il
250-350
4419 4422
Yes
-
Yes
1650-1700
Yes
-
Yes
1650-1700
Quench in oilg
250-350
4427 4615 4617
Quench in oilg
4620 4621 4626
w
Cool slowly
1500-1550i
Quench in oil
1500-1550h
0il 0il
Quench in oil
1500-1550h
0il
250-350
250,350
4718
Yes
4720
-
Yes
1650-1700
.........
Quench in oilg
4815
-
4817
Yes
Yes
1650-1700
4820
m
Cool slowly
1475-1525i
Quench in oil
1475-1525h
0il 0il
250-325
m
250-350
5015 5115
Yes
1650-1700
Quench in oilg
Yes
1650
Quench in oilg
5120 6118
74
325
Pretreatments
I
I
J
lizeb Normalize Cycle and Anneald Temperc
SAE INorm
Numbera
Carburizinge Temp, F
Cooling Method
Quench in 0ilg
8115
Yes
8615
-
-
1650-1700
C001 slowly Quench in 0il
8617
Reheat Quenching Temperingf Temp, F Medium Temp, F
m
w
1550-1600i 0il 1550-1600h 0il
250-350
1550-1600Z 0il 1550-1600h 0il
250-350
8620 8622
Quench in 0ilg
8625
Yes
8627
-
Yes 1650-1700
C001 slowly Quench in 0il
8720 8822 9310
-
94B15 94B17
-
Yes
Yes
-
-
1600-1700
1650-1700
Quench in 0il Co01 slowly
1450-1525h 0il 1450-1525i 0il
250-325
250-350
Quench in 0ilg
a These steels are fine grain. Heat treatments are not necessarily correct for coarse grain. b Normalizing temperature should be at least as high as the carburizing temperature followed by air cooling. c After normalizing, reheat to temperature of11OO-1200 F and hold at temperature approximately 1 hr per in. of maximum section or 4 hr minimum time. d Where cycle annealing is desired, heat to at least as high as the carburizing temperature, hold for uniformity, cool rapidly to 1000-1250 F, hold 1 to 3 hr, then air cool or furnace cool to obtain a structure suitable for machining and finish. e It is general practice to reduce carburizing temperatures to approximately 1550 F before quenching to minimize distortion and retained austenite. For 4800 series steels, the carburizing temperature is reduced to approximately 1500 F before quenching. f Temperatures higher than those shown are used in some instances where application requires. g This treatment is most commonly used and generally produces a minimum of distortion. h This treatment is used where the maximum grain refinement is required and/or where parts are sub sequently ground on critical dimensions. A combination of good case and core properties is secured with somewhat greater distortion than is obtained by a single quench from the carburizing treatment.
i In this treatment the parts are slowly cooled, preferably under a protective atmosphere. They are then reheated and oil quenched. A tempering operation follows as required. This treatment is used when machining must be done between carburizing and hardening or when facilities for quench ing from the carburizing cycle are not available. Distortion is at least equal to that obtained by a single quench from the carburizing cycle, as described in note e.
75
SAE Typical Thermal Treatments
CARBON STEELS--Carburizing Grades SAE Carburizing Number Temp, F
Cooling Method
Cooling Medium
Reheat Temp, F
1010 1015
1016 1650-1700 Water or Caustic
-
-
Carbo
nitriding
Coolin¢.
Temp, F
Mediun
1450-1650
Oil
1450-1650
Oil
1450-1650 0il
1018 1019 1020 1022
1650-1700
Water or Caustic
1450
Water or Caustica
1026 1030 1109 1650-1700
Water or 0il
1117 1650-1700
1400-1450 Water or Caustica
Water or 0il
1118 1650-1700
0il
-
1450-1600 Water or Caustica 1450-1650 0il
1450-1600
0il
_b
_
1513 1518 1522 1524
1650-1700
0il
1450
0il
_b
1525 1526 1527
NOTE: Normalizing is generally unnecessary for fulfilling either dimensional or machinability
requirements of parts made from the above grades. Where dimension is of vital importance, normalizing temperatures of at least 50 F above the carburizing temperatures are sometimes required to minimize distortion.
NOTE: Tempering temperatures are usually 250-400 F, but higher temperatures may be used when permitted by the hardness specification for the finished parts.
a 3% sodium hydroxide. bThe higher manganese steels such as 1118 and the 1500 series are not usually carbonitrided. If carbonitriding is performed, care must be taken to limit the nitrogen content because high nitrogen will increase their tendency to retain austenite.
76
SAE Typical Thermal Treatments
CARBON STEELS Water and Oil Hardening Grades Annealing Temp, F
Normalizing Temp, F
SAE Number
1030
--
1035
-
--
1575-1600
-
Quenching Medium
Hardening Temp, F
Water or Caustic
1550-1600 ......
Water or Caustic
1037 1038a 1039a
1525-1575
Water or Caustic
1500-1550
Water or Caustic
1040a 1042 1043a 1045a 1046a 1050a
1600-1700
1053
1060
1600-1700
1074
1550-1650
--
1575-1625
0il
1400-1500
1575-1625
0ii
1400-1500b
1575-162.5
.......
1550-1650
1085
Water or Caustic
1400-1500
......................
1080 1084
1500-1550
.......
0ilc
1090
1095 1137 1141
1550-1650 1400-1500b 1575-1625 1550-1600 Oil 1400-1500 1500-1550 0il
1144
1600-i700
1400-1500 ......... 1500-1550
1145
-
1146
-
1151
1600-1700 ........ - ......... 1475-1500
1536
1541 1548 1552
1566
Water and Oil
Oil
1475-1500 1600-1700
1600-1700
-
Water or 0il
Water or 0il ..................
1500-1550
Water or 0il
1400-1500
i 500-1550
Water or 0il
1600-1700
-
1500-1550
0il
1600-1700
-
1575-1625
0il
...........
........
.,
NOTE- When tempering is required, temperature should be selected to effect desired hardness. a These grades are commonly used for parts where induction hardening is employed, although all steels from 1030 up may be induction hardened. b Spheroidal structures are often required for machining purposes and should be cooled very slowly or be isothermally transformed to produce the desired structure. c May be water or brine quenched by special techniques such as partial immersion or time quenched; otherwise, they are subject to quench cracking.
77
SAE Typical Thermal Treatments
ALLOY STEELS--Directly Hardenable Grades SAE Numbera
Normalizing Temp, F
Annealingd Temp, F
Hardeninge Temp, F
Quenching
1330
1600-1700b
1550-1650
1525-1575
Water or Oil
1600-1700b
1550-1650
1500-1550
Oil
1500-1575
1525-1575
Oil
1450-1550
1500-1575
Oil
1450-1550
1500-1600
Water or Oil
1450-1550
1550-1600
Oil
1450-1550
1500-1550
Oil
1450-1550
1550-1550
Oilf
1600-1700b
1450-1550
1500-1550
Oilc
1600-1700b
1500-1600
1500-1550
Oil
1600-1700
1500-1600
1475-1550
Oil
1600-1700b
1450-1550
1525-1575
1600-1700b
1500-1600
1500-1550
Medium
1335 1340 1345 4037 4042 4047 4130
1600-1700b
4135 4137 4140 4142 4145 4147 4150 4161 434O
50B40 50B44 5046 50B46 50B50 5060 50B60 5130 5132
Water, Caustic or Oil
5135 5140 5145
78
Oil
SAE Numbera
Normalizing Temp, F
Annealingd Temp, F
Hardeninge Temp, F
Quenching
1600-1700b
1500-1600
1475-1550
0il
1425-1475
Water
1500-1600
0il
1550-1650
1550-1625
0il
Medium
5147 5150 5155 5160 51B60 50100 1350-1450
51100 52100 6150 81B45
1600-1700b
1550-1650
1500-1575
0il
8630
1600-1700b
1450-1550
1525-1600
Water or 0il
1500-1600
1525-1575
0il
1500-1600
1500-1575
0il
1500-1600
1475-1550
0il
1500-1600
1525-1575
0il
1500-1650
0il
1550-1625
0il
8637 8640 8642 8645 86B45 8650 8655 8660 8740 9254 9255 9260 94B30
1600-1700b
1450-1550
NOTE. When tempering is required, temperature should be selected to effect desired hardness. See footnotes c and f. aThese steels are fine grain. bThese steels should be either normalized or annealed for optimum machinability. c Temper at 1 1 OO- 1225 F. d The specific annealing cycle is dependent upon the alloy content of the steel, the type of subsequent machining operations, and desired surface finish. e Frequently, these steels, with the exception of 4340, 50100, 51100, and 52100, are hardened and tempered to a final machinable hardness without preliminary thermal treatment.
fTemper above 700 F.
79
80
GRAIN SIZE Grain size, as considered within the scope of this publication, is the austenitic grain size. As any carbon or alloy steel is heated to a temperature just above the upper critical temperature, it transforms to austenite of uniformly fine grain size. On heating to progressively higher temperatures, coarsening of the austenite grains eventually will occur. The temperature at which this occurs is dependent to some extent on the composition of the steel, but is influenced primarily by the type and degree of deoxidation used in the steelmaking process. Time at temperature also influences the degree of coarsening. De oxidizers such as aluminum, and alloying elements such as vanadium, titanium, and columbium, inhibit grain growth, thereby increasing the temperature at which coarsening of the austenitic grains occurs. Aluminum is most commonly used for grain size control because of
its low cost and dependability. For steels used in the quenched and tempered condition, a fine grain size at the quenching temperature is almost always preferred, because fine austenitic grain size is conducive to good ductility and toughness. Coarse grain size enhances hardenability, but also in creases the tendency of the steel to crack during thermal treatment. When austenitic grain size is specified, the generally accepted method of determining it is the McOuaid-Ehn test . This test consists
of carburizing a specimen at 1700 F, followed by slow cooling to develop a carbide network at the grain boundaries. The specimen is
polished and etched, and then compared at 100 diameters magnifica tion with a standard (pages 82-83 ). Since it is impossible to produce steels of a single grain size, a range of grain size numbers is usually reported. For specification purposes, a steel is considered fine grained
if it is predominantly 5 to 8 inclusive, and coarse grained if it is pre dominantly 1 to 5 inclusive. These requirements are usually con sidered fulfilled if 70% of the grains examined fall within these ranges.
Steels which are fine grained at 1700 F will be fine grained at a lower quenching temperature. A steel which exhibits coarse grain size at 1700 F, is usually fine grained at conventional quenching temperatures, but this cannot be guaranteed. Consequently, fine
grain size (McOuaid:Ehn) is usually specified for applications in volving hardening by thermal treatment. 1A detailed discussion of the McQuaid-Ehn test and of other methods for determining grain size can be found in ASTM Specification El12.
81
O0 I',0
01 ....i
3
4
7
8
II
83
IVIECHANICAL PROPERTIES of Carbon andAlioy Steels The mechanical properties of a number of common carbon and alloy steels are given on the following pages. The data were obtained by testing single heats of the compositions indicated, and may be used as a guide in selecting grades for specific applications. However,
it should be kept in mind that every grade of steel is furnished to a range of composition, and that the resultant heat-to-heat variations in the percentages of individual elements present in any grade can cause significant differences in the properties obtainable by thermal treatment. Similarly, section size and thermal treatment parameters markedly influence the properties which can be developed in any particular part. Hence, the mechanical properties given in this section should not be considered as maximum, minimum, or average values for a particular application of the grades involved.
84
Page
Carbon Carburizing Grades
88 89 90 91
92
Carbon Water- and Oil-Hardening Grades
94 96 1 O0
104 106 108 112 116 118
Alloy Carburizing Grades
Alloy Water-Hardening Grades
Alloy Oil-Hardening Grades
122 124 126 128 130 132 134
Grade
1015 1020 1022 1117 1118 1030 1040 1050 1060 1080 1095 1137 1141
1144 4118 4320 4419 4620 4820 8620--'
E9310
138 140 142
4027 4130 8630
146 148 150 152
1340 4140 4340 5140 8740 4150 5150 6150 8650 9255 5160
154 156 158 160 162
164 166
85
CARBON STEEL CARBURIZING GRADES
88 89 90
1015 1020
91
1117 1118
1022,
92
87
1015 SINGLE HEAT RESULTS C Mn P S Grade .13/.18
.30/.60
Ladle .15
.53
.040 Max
Si
.050 Max
--
Grain
Size
.018 .031 .17 6-8 F" Acl 1390 Ac3 1560 Ar3 1510 Ari 1390
SINGLE QUENCH AND TEMPER Carburized at 1675 F for 8 hours ; pot-cooled ; reheated to 1425 F ; water-quenched ; tempered at 350 F. 1-in. Round Treated Case Depth .048 in. Case Hardness HRC 62
MASS EFFECT Size Round Tensile Strength Yield Point Elongation Reduction Hardness in.
psi
psi
% 2 in. of Area, %
HB
Annealed (Heated to 1600 F, furnace-cooled 30 F per hour to 1340 F, cooled in air.)
1
56,000
41,250
37.0
69.7
111
Normalized (Heated to 1700 F, cooled in air.)
½ 63,250 48,000 38.6 71.0 126 1 61,500 47,000 37.0 69.6 121 2 60,000 44,500 37.5 69.2 116 4 59,250 41,800 36.5 67.8 116 Mock-Carburized at 1675 F for 8 hours; reheated to 1425 F; quenched in water; tempered at 350 F.
½ 1
106,250 75,500
2
70,750
4
60,000 44,000 41,375
67,250
1 5.0 32.9 217 30.0 69.0 1 56
32.0 '
39,000
70.4
30.5
131
69.5
As-quenched Hardness (water) Size Round Surface ½
1 2
4
88
HRC 36.5
HRB 99
HRB 98
HRB 97
½ Radius HRC 23
HRB 91
HRB 84
HRB 80
Center HRC 22
HRB 90
HRB 82
HRB 78
121
1020 SINGLE HEAT RESULTS C Mn P S Grade .18/.23
.30/.60
.040 Max
.050 Max
Si --
Grain
Size
Ladle .19 .48 .012 .022 .18 6-8 Critical Points, F: Ac 1350 Ac3 1540 Ar3 1470 Ar
1340
SINGLE QUENCH AND TEMPER Carburized at 1675 F for 8 hours ; pot-cooled ; reheated to 1425 F ; water-quenched ; tempered at 350 F. 1-in. Round Treated Case Depth .046 in. Case Hardness HRC 62
MASS EFFECT Size Round Tensile Strength Yield Point Elongation Reduction Hardness in.
As-Rolled
1
psi
68,500
psi
% 2 in. of Area, %
55,750
32.0
66.5
HB
137
Annealed (Heated to 1600 F, furnace-cooled 30 F per hour to 1290 F, cooled in air.)
1
57,250
42,750
36.5
66.0
111
Normalized (Heated to 1700 F, cooled in air.)
½ 1 2 4
64,500 64,000 63,500 60,000
50,250 50,250 46,250 40,750
39.3 35.8 35.5 36.0
69.1 67.9 65.5 66.6
131 131 126 121
Mock-Carburized at 1675 F for 8 hours; reheated to 1425 F; quenched in water; tempered at 350 F.
½ 1 2 4
129,000 72,000 11.4 29.4 255 87,000 54,000 23.0 64.2 179 75,500 43,750 31.3 67.9 156 71,250 42,000 33.0 67.6 143
As-quenched Hardness (water) Size Round Surface ½ 1 2
4
½ Radius
HRC 40.5 HRC 29.5 HRB 95
HRB94
HRC 30 HRB 96 HRB 85
HRB78
Center HRC 28 HRB 93 HRB 83
HRB77
89
1022 SINGLE HEAT RESULTS C Mn P S Grade .18/.23 .70/1.00 .040 Max
Ladle .22
.82
.016
Si
.050 Max
.023
--
.20
Grain
Size
6-8
Critical Points, F: Acl 1360 Ac3 1530 Ar3 1440 Arl 1300
SINGLE QUENCH AND TEMPER Carburized at 1675 F for 8 hours ; pot-cooled ; reheated to 1425 F ; water-quenched ; tempered at 350 F. 1-in. Round Treated Case Depth .046 in. Case Hardness HRC 62
MASS EFFECT Size Round Tensile Strength Yield Point Elongation Reduction Hardness in.
As-Rolled
1
psi
70,250
psi
52,250
% 2 in. of Area, %
33.0
65.2
HB
137
Annealed (Heated to 1600 F, furnace-cooled 30 F per hour to 1250 F, cooled in air.)
1
65,250
46,000
35.0
63.6
137
35.7 34.0 34.0 33.8
68.3 67.5 66.6 63.9
143 143 137 131
Normalized (Heated to 1700 F, cooled in air.)
½ 1 2 4
70,500 70,000 68,750 67,250
53,000 52,000 48,000 45,000
Mock-Carburized at 1675 F for 8 hours; reheated to 1425 F; quenched in water; tempered at 350 F.
½ 1 2 4
135,000 75,000 13.6 24.3 262 89,000 55,000 25.5 57.3 179 82,000 50,250 30.0 69.6 163 74,000 42,500 32.5 71.6 149
As-quenched Hardness (water) Size Round Surface
½
1 2
4
9O
HRC 45
HRC 41
HRC 38
HRC 34
½ Radius HRC 29
HRB 95
HRB 88
HRB 84
Center HRC 27
HRB 92
HRB 84
HRB 81
1117 SINGLE HEAT RESULTS C Mn P S Grade .14/.20
1.00/1.30
.040 Max
Si
.08/.13
--
Grain
Size
Ladle .19 1.1 0 .015 .084 .11 2-4 Critical Points, F: Acl 1345 Aca 1540 Ar3 1450 Ari 1340
SINGLE QUENCH AND TEMPER Carburized at 1700 F for 8 hours ; pot-cooled ; reheated to 1450 F ; water-quenched ; tempered at 350 F. 1-in. Round Treated Case Depth .045 in. Case Hardness HRC 65
MASS EFFECT Size Round Tensile Strength Yield Point in.
As-Rolled
1
psi
69,750
Elongation Reduction Hardness % 2 in. of Area, % H B
psi
49,500
33.5
61.1
149
Annealed (Heated to 1575 F, furnace-cooled 30 F per hour to 1290 F, cooled in air.)
1
62,250
40,500
32.8
58.0
121
Normalized (Heated to 1650 F, cooled in air.)
½
1
2 4
69,750
67
45,000
750
67,000 63,750
34.3
44,000
41,500 35,000
61.0
33.5.
33.5 34.3
63.8
64.7 64.7
143 137
137 126
Mock-Carburized at 1700 F for 8 hours; reheated to 1450 F; quenched in water; tempered at 350 F.
½ 1 2 4
124,750 66,500 9.7 18.4 235 89,500 50,500 22.3 48.8 183 78,000 47,750 26.3 65.7 156 74,750 42,750 27.3 62.6 149
As-quenched Hardness (water) ½ Radius
Size Round Surface
½ 1 2 4
HRC 42
Center
HRC 34.5 HRC 29.5
HRC 37 HRC 33 HRC 32
HRB 96 HRB 90 HRB 83
HRB 93 HRB 86 HRB 81
91
1118 SINGLE HEAT RESULTS C Mn P S Grade
.14/.20
Ladle
.20
1.30/1.60 1.34
Si
.040 Max .08/.13 .017
.08
.09
--
Grain
Size
90% 3- 5
10% 2
Critical Points, F: Acl 1330 Ac3 1515 Ar3 1385 Arl 1175
SINGLE QUENCH AND TEMPER Carburized at 1700 F for 8 hours ; pot-cooled ; reheated to 1450 F ; water-quenched ; tempered at 350 F. 1-in. Round Treated Case Depth .065 in. Case Hardness HRC 61
MASS EFFECT Size Round Tensile Strength Yield Point in.
As-Rolled
1
psi
Elongation Reduction Hardness % 2 in. of Area, % H B
psi
70,500
51,500
32.3
63.0
143
Annealed (Heated to 1450 F, furnace-cooled 30 F per hour to 1125 F, cooled in air.)
1
65,250
41,250
34.5
66.8
131
33.3 33.5 33.0 34.0
62.8 65.9 67.7 67.4
1 56 143 137 131
Normalized (Heated to 1700 F, cooled in air.)
½ 1 2 4
72,750 69,250 68,500 66,250
47,800 46,250 43,250 37,750
Mock-Carburized at 1700 F for 8 hours; reheated to 1450 F; quenched in water; tempered at 350 F.
½ 1 2 4
144,500 102,500 82,250 77,000
90,000 59,250 47,875 45,000
13.2 30.8 285 19.0 48.9 207 27.3 65.5 167 31.0 67.4 156
As-quenched Hardness (water) Size Round Surface ½ 1 2 4
92
HRC 43 HRC 36 HRC 34 HRC 32
½ Radius HRC 36 HRB 99 HRB 91 HRB 84
Center HRC 33 HRB 96.5 HRB 87 HRB 82
CARBON STEEL WATER- AND OIL-HARDENING GRADES It will be noted in the properties charts that the hardness values listed are frequently incom
patible with the tensile strength shown for the same tempering temperatures. These carbon steels are comparatively shallow hardening; and hardness tests made on the surface of a quenched and tempered bar will not be equivalent to the tensile strength obtained on a .505-in. specimen machined from the center of the same bar.
1030 1040 1050 1060 1080 1095 1137
94 96 100 104 106 108 112 116 118
1141
1144
93
1030 Water-quenched SINGLE HEAT RESULTS C Mn P Grade .28/.34
.60/.90 .040 Max
Ladle .31 .65 .023 Critical Points, F: Ac
S
.050 Max
.026
--
.14
Si Grain
Size
5-7
1350 Ac3 1485 Ar3 1395 Ar
1250
MASS EFFECT Size Round Tensile Strength Yield Point Elongation Reduction Hardness in.
psi
psi
% 2 in. of Area, %
HB
Annealed (Heated to 1550 F, furnace-cooled 20 F per hour to 1200 F, cooled in air.)
1
67,250
49,500
31.2
57.9
126
32.1 32.0 29.5 29.7
61.1 156 60.8 149 58.9 137 56.2 137
Normalized (Heated to 1700 F, cooled in air.)
½ 1 2 4
77,500 75,500 74,000 72,500
50,000 50,000 49,500 47,250
Water-quenched from 1600 F, tempered at 1000 F.
½ 1 2 4
91,500 88,000 86,500 80,750
75,000 68,500 63,750 54,750
28.2 28.0 28.2 32.0
58.0 68.6 65.8 68.2
187 179 170 163
Water-quenched from 1600 F, tempered at 1100 F.
½ 1 2 4
88,500 85,250 83,750 80,500
64,000 63,000 57,250 54,500
28.9 69.7 179 29.0 70.8 170 29.0 69.1 167 32.0 68.5 163
Water-quenched from 1600 F, tempered at 1200 F.
½ 1 2 4
85,500 84,500 80,000 74,500
62,000 61,500 56,750 49,500
29.9 28.5 30.2 34.2
70.5 71.4 70.9 71.0
174 170 156 149
As-quenched Hardness (water) Size Round Surface ½ 1 2 4
94
HRC 50 HRC 46 HRC 30 HRB 97
½ Radius
Center
HRC 50 HRC 23 HRB 93 HRB 88
HRC 23 HRC 21 HRB 90 HRB 85
Water-quenched 1030 Treatment" Normalized at 1700 F" reheated to 1600 F" quenched in water, 1-in. Round Treated" .505-in. Round Tested.
As-quenched HB 514.
psi 200,000 .....
150,000
Tensile St 100,000
\
70% 60%
50,000
J
5O%
40% E
ongat'
30%
'-
on
20% 10%
temper, F 400 500 600 700 800 900
HB 495 429 401 375 302 277
1000 255
1100 1200 1300 235 207 179 95
1040 Oil-quenched SINGLE HEAT RESULTS C Mn P S Grade .37/.44
.60/.90
.040 Max .050 Max
Si --
Grain
Size
Ladle .39 .71 .019 .036 .15 5-7 Critical Points, F: ACl 1340 Ac3 1445 Ar3 1350 Arl 1250
MASS EFFECT Size Round Tensile Strength Yield Point Elongation Reduction Hardness in.
psi
psi
% 2 in. of Area, %
HB
Annealed (Heated to 1450 F, furnace-cooled 20 F per hourto 1200 F, cooled in air.)
1
75,250
51,250
30.2
57.2
149
30.0 28.0 28.0 27.0
56.5 54.9 53.3 51.8
183 170 167 167
62.0 61.1 59.7 60.3
217 197 187 179
65.2 63.5 62.5 61.6
207 187 174 170
65.4 67.4 66.4 64.5
197 170 167 156
Normalized (Heated to 1650 F, cooled in air.)
½ 1 2 4
88,250 85,500 84,250 83,500
58,500 54,250 53,000 49,250
Oil-quenched from 1575 F, tempered at 1000 F.
½ 1 2 4
104,750 96,250 92,250 90,000
72,500 68,000 59,750 57,500
27.0 26.5 27.0 27.0
Oil-quenched from 1575 F, tempered at 1100 F.
½ 1 2 4
100,500 91,500 86,750 82,750
69,500 64,250 56,875 52,250
27.0 28.2 28.0 30.0
Oil-quenched from 1575 F, tempered at 1200 F.
½ 1 2 4
95,000 85,250 82,500 78,750
66,625 60,250 54,500 50,000
28.9 30.0 31.0 31.2
As-quenched Hardness (oil) Size Round Surface
½
1
2 4 96
HRC 28
HRC 23
HRB 93 HRB 91
½ Radius HRC 22
HRC 21 HRB 92 HRB 91
Center HRC 21
HRC 18 HRB 91 HRB 89
Oil-quenched 1040 Treatment" Normalized at 1650 F; reheated to 1575 F" quenched in oil. 1-in. Round Treated" .505-in. Round Tested.
As-quenched HB 269.
psi ......
200,000 .......
150,000 .......
i,i
_______ -----.--.
Tensile Strength _
100,000 ----
Id Point
. ,,
70% ..m.-.= -
6O%
-L
5O%
50,000
40% 30% E
ongatiO
20% .... 10%
Temper, F 400 500 600 700 800
HB 262 255 255 248 241
900 1000 1100 1200 1300 235 212 197 192 183 97
1040 Water-quenched SINGLE HEAT RESULTS C Mn P Grade .37/.44
Ladle .39
.60/.90 .040 Max
.71
.019
.050 Max
.036
S --
.15
Si Grain
Size
5-7
Critical Points, F: Aci 1340 Ac3 1445 Ar3 1350 Arl 1250
MASS EFFECT Size Round Tensile Strength Yield Point Elongation Reduction Hardness in.
psi
psi
% 2 in. of Area, %
HB
Water-quenched from 1550 F, tempered at 1000 F.
½ 1 2 4
109,000 81,500 23.8 61.5 223 107,750 78,500 23.2 62.6 217 101,750 69,500 24.7 63.6 207 99,000 63,826 24.7 60.2 201
Water-quenched from 1550 F, tempered at 1100 F.
½ 1 2 4
101,250 100,000 95,000 94,250
71,000 26.4 65.2 212 69,500 26.0 65.0 207 68,000 29.0 69.2 197 59,125 27.0 63.4 192
Water-quenched from 1550 F, tempered at 1200 F.
½ 1 2 4
96,000 93,500 89,000 85,000
69,000 68,000 59,875 54,750
27.7 27.0 28.7 30.2
66.6 67.9 69.0 67.2
201 197 183 170
As-quenched Hardness (water) Size Round Surface ½ 1
2
4
98
HRC 54 HRC 50
HRC 50
HRB 98
½ Radius HRC 53 HRC 22
Center HRC 53 HRC 18
HRB 97
HRB 95
HRB 96
HRB 95
Water-quenched 1040 Treatment" Normalized at 1650 F" reheated to 1550 F'quenched in water. 1-in. Round Treated" .505-in. Round Tested.
As-quenched HB 534.
psi
200,000
150,000
-____.__
100,000
Yield Point
Reduct'lon o4 Area _ 50,000
60%
'
5O%
--
40% 30%
N EIonu
2O% 10%
Temper, F 400 500 600 700 800 900
HB 514 495 444 401 352 293
1000 1100 1200 1300 269 235 201 187 99
1050 Oil-quenched SINGLE HEAT RESULTS C Mn P Grade .48/.55
.60/.90 .040 Max
Ladle .54 .69 ..... 030 Critical Points, F: Ac
S
.050 Max
.19
--
Si Grain
Size
5-7
1340 Ac3 1420 Ar3 1320 Ar, 1250
MASS EFFECT Size Round Tensile Strength Yield Point Elongation Reduction Hardness in.
psi
psi
% 2 in. of Area, %
HB
Annealed (Heated to 1450 F, furnace-cooled 20 F per hour to 1200 F, cooled in air.)
1
92,250
53,000
23.7
39.9
187
21.5 20.0 20.0 21.7
45.1 39.4 38.8 41.6
223 217 212 201
Normalized (Heated to 1650 F, cooled in air.)
½ 1 2 4
111,500 108,500 106,250 100,000
62,500 62,000 58,325 56,000
Oil-quenched from 1550 F, tempered at 1000 F.
½ 1 2 4
132,500 123,500 122,500 121,000
87,500 76,000 74,875 69,000
20.7 52.9 262 20.2 53.3 248 19.7 51.4 248 19.7 48.0 241
Oil-quenched from 1550 F, tempered at 1100 F.
½ 1 2 4
122,000 114,000 112,000 101,000
81,000 70,500 68,000 58,750
22.8 23.5 23.0 25.2
58.1 57.6 55.6 54.5
248 223 223 207
Oil-quenched from 1550 F, tempered at 1200 F.
½ 1 2 4
112,500 106,000 105,000 96,750
74,000 64,250 64,000 55,750
24.6 61.8 229 24.7 60.5 217 25.0 59.1 217 25.5 56.6 197
As-quenched Hardness (oil) Size Round Surface
½ 1 2 4
100
HRC 57 HRC 33 HRC 27 HRB 98
½ Radius
HRC 37 HRC 30 HRC 25 HRB 95
Center
HRC 34 HRC 26 HRC 21 HRB 91
Oil-quenched 1050 Treatment" Normalized at 1650 F' reheated to 1550 F'quenched in oil. 1-in. Round Treated • .505-in. Round Tested.
As-quenched HB 321.
psi
200,000
1 50,000 TenSile Str.
,--
\
100,000
70%
-,
Reduction of Area
50,000
60% ..
5O%
40%
E
ongat
30%
On
20% 10%
Temper, F 400 HB
500 600 700 800 900 321
321
293
277
269
1000 1100 1200 1300 262 241 223 192 101
1050 Water-quenched SINGLE HEAT RESULTS C Mn P Grade .48/.55
.60/.90 .040 Max
Ladle .54 .69 .012 Critical Points, F: Ac
S
.050 Max
.030
--
.19
Si Grain
Size
5-7
1340 Ac3 1420 Ar3 1320 Ar
1250
MASS EFFECT Size Round Tensile Strength Yield Point Elongation Reduction Hardness in.
psi
psi
% 2 in. of Area, %
HB
Water-quenched from 1525 F, tempered at 1000 F.
½ 1 2 4
134,000 131,250 129,500 122,750
99,000 92,250 84,125 78,250
20.0 20.0 20.7 21.5
54.4 55.2 56.6 55.3
269 262 255 248
59.9 59.9 61.0 55.5
241 241 235 229
Water-quenched from 1525 F, tempered at 1100 F.
½ 1 2 4
119,000 118,000 117,250 112,250
88,000 80,000 78,750 68,250
21.7 22.5 23.0 23.7
Water-quenched from 1525 F, tempered at 1200 F.
½ 1 2 4
110,000 109,000 107,750 104,500
86,000 76,500 68,500 65,250
24.8 23.7 24.7 25.2
60.6 61.2 61.0 60.8
As-quenched Hardness (water) Size Round Surface
½ 1 2 4
102
HRC 64 HRC 60 HRC 50 HRC 33
½ Radius
HRC 59 HRC 35 HRC 32 HRC 27
Center
HRC 57 HRC 33 HRC 26 HRC 20
229 229 223 217
Water-quenched 1050 Treatment" Normalized at 1650 F" reheated to 1525 F" quenched in water. 1-in. Round Treated" .505-in. Round Tested.
As-quenched HB 601.
psi
200,000
150,000
\ -----._....
\
100,000
70% 60% 50%
5O,O0O
40%
E
ongat
--
.,..,.--. 30% on__.
20%
10%
temper, F 400
HB 514
5OO
495
600 444
700 415
8OO
375
900 352
1000 1100 1200 1300 293 277 235 217 103
1060 Oil-quenched SINGLE HEAT RESULTS C Mn P Grade .55/.65
Ladle
.60
.60/.90 .040 Max
.66
.016
Critical Points, F: Ac
S
.050 Max
.046
--
Si Grain
Size
.17
90% 5- 7
10% 1-3
1355 Ac3 1400 Ar3 1300 Ar
1250
MASS EFFECT Size Round Tensile Strength Yield Point Elongation Reduction Hardness in.
psi
psi
% 2 in. of Area, %
HB
Annealed (Heated to 1450 F, furnace-cooled 20 F per hour to 1200 F, cooled in air.)
1
90,750
54,000
22.5
38.2
179
20.4 18.0 17.7 18.0
40.6 37.2 34.0 31.3
229 229 223 223
Normalized (Heated to 1650 F, cooled in air.)
½ 1 2 4
113,000 112,500 110,000 108,250
62,000 61,000 57,500 51,250
Oil-quenched from 1550 F, tempered at 900 F.
½ 1 2 4
149,000 145,500 142,750 134,750
98,250 93,000 89,500 75,250
15.1 16.2 16.5 18.2
46.0 302 44.0 293 46.2 285 44.8 269
19.6 17.7 18.5 20.0
52.1 48.0 50.3 48.0
277 269 262 248
20.7 20.0 20.2 21.5
53.5 51.7 53.3 49.4
262 255 248 241
Oil-quenched from 1550 F, tempered at 1000 F.
½ 1 2 4
139,500 136,500 133,000 124,500
92,000 85,750 79,250 66,250
Oil-quenched from 1550 F, tempered at 1100 F.
½ 1 2 4
131,500 127,750 125,250 118,750
82,500 79,000 76,500 62,000
As-quenched Hardness (oil) Size Round Surface
½ 1
2 4
104
HRC 59 HRC 34
½ Radius
HRC 37 HRC 32
Center
HRC 35 HRC 30
HRC 30.5 HRC 27.5 HRC 25 HRC 29
HRC 26
HRC 24
Oil-quenched 1060 Treatment" Normalized at 1650 F" reheated to 1550 F° quenched in oil. 1-in. Round Treated • .505-in. Round Tested.
As-quenched HB 321.
psi
200,000
-
Tensile Strength k
150,000
Yi"'eid Point ......
\
h .......... ,,,, ...............
100,000 ....
\
60% 5O%
50,000 ..........
Reduction of Area
40%
............ i,ii
30% 20%
Elongation
10%
.......
.......
emper, F 400 500 600 700 800 900
HB 321 321 321 321 311 302
1000 1100 1200 1300 277
248
229
212 105
1080 Oil-quenched SINGLE HEAT RESULTS C Mn P S Grade .75/.88
Ladle
.85
.60/.90 .040 Max
.76
.012
Si
.050 Max
--
.027
.13
Grain
Size
8O% 5-7
20% 1-4
Critical Points, F: Acl 1350 Ac3 1370 At3 1280 Arl 1250
MASS EFFECT Size Round Tensile Strength Yield Point Elongation Reduction Hardness in.
psi
psi
% 2 in. of Area, %
HB
Annealed (Heated to 1450 F, furnace-cooled 20 F per hour to 1200 F, cooled in air.)
1
89,250
54,500
24.7
45.0
1 74
12.4 11.0 10.7 10.7
27.7 20.6 17.0 15.5
293 293 285 269
Normalized (Heated to 1650 F, cooled in air.)
½ 1 2 4
150,500 146,500 141,000 134,750
80,500 76,000 70,000 64,500
Oil-quenched from 1500 F, tempered at 900 F.
½ 1 2 4
184,000 181,500 180,000 171,250
125,500 112,500 110,000 104,000
12.1 13.0 12.7 11.7
34.4 35.8 37.3 28.6
363 352 352 341
15.0 15.0 15.2 11.5
38.6 37.6 38.0 24.4
341 331 321 311
17.0 16.5 17.7 15.7
43.6 40.3 42.2 33.1
302 302 277 269
Oil-quenched from 1500 F, tempered at 1000 F.
½ 1 2 4
169,000 166,000 163,500 157,000
121,500 103,500 102,625 89,750
Oil-quenched from 1500 F, tempered at 1100 F.
½ 1 2 4
152,000 150,000 140,250 134,500
107,000 97,000 87,500 75,000
As-quenched Hardness (oil) Size Round Surface
½ 1 2 4
106
HRC 60 HRC 45 HRC 43 HRC 39
½ Radius
Center
HRC 43 HRC 42 HRC 40 HRC 37
HRC 40 HRC 39 HRC 37 HRC 32
Oil-quenched 1080 Treatment: Normalized at 1650 F" reheated to 1500 F" quenched in oil. 1 -in. Round Treated • .505-in. Round Tested.
As-quenched H B 388.
psi •
200,000 '
"
2e
150,000
\ •
\
elo' .......
\
100,000
70%
......
60% 50,000
5O%
40%
Reduction of Area.......
30% Elongation
f
20%
--'
10%
nper, F 400 500 600 700 800 900
HB 388 388 388 388 375 341
1000 1100 1200 1300 321 293 255 223 107
1095 Oil-quenched SINGLE HEAT RESULTS C Mn P Grade .90/1.03 .30/.50 .040 Max Ladle .96
.40
.012
S
.050 Max
.029
.20
m
Si
Size
50% 5- 7
50% 1-4
1365 At3 1320 Ar
Critical Points, F: Acl 1350 Ac
Grain
1265
MASS EFFECT Size Round Tensile Strength Yield Point Elongation Reduction Hardness in.
psi
psi
% 2 in. of Area, %
HB
Annealed (Heated to 1450 F, furnace-cooled 20 F per hour to 1215 F, cooled in air.)
1
95,250
55,000
13.0
20.6
192
Normalized (Heated to 1650 F, cooled in air.)
½ 1 2 4
151,000 147,000 132,500 128,250
80,500 72,500 58,000 57,250
12.3 27.7 302 9.5 13.5 293 9.2 13.4 269 10.0 13.9 255
Oil-quenched from 1475 F, tempered at 900 F.
½ 1 2 4
184,000 175,750 167,750 165,000
116,000 12.8 35.5 363 102,250 10.0 23.4 352 98,250 12.0 29.8 331 93,000 12.2 17.3 331
Oil-quenched from 1475 F, tempered at 1000 F.
½ 1 2 4
166,500 159,750 151,000 148,000
101,500 15.7 40.0 331 95,250 13.2 32.4 321 92,500 13.7 31.4 311 80,000 11.7 22.1 302
Oil-quenched from 1475 F, tempered at 1100 F.
½ 1 2 4
142,000 139,750 134,500 130,000
87,000 79,000 77,250 65,750
17.4 17.2 18.7 17.2
42.8 38.8 43.4 34.4
As-quenched Hardness (oil) Size Round Surface
½ 1 2
4
108
HRC 60 HRC 46 HRC 43
HRC 40
½ Radius HRC 44 HRC 42 HRC 40
HRC 37
Center HRC 41 HRC 40 HRC 37
HRC 30
293 277 269 262
Oil-quenched 1095 Treatment" Normalized at 1650 F" reheated to 1475 F" quenched in oil. 1-in. Round Treated • .505-in. Round Tested.
As-quenched HB 401.
psi 200,000 ..... .......... I
150,000
\
\
\ \ 100,000
I
70% 60% 50,000
5O%
ReduCtiOn o Are
40%
...
30%
........
Elongation
20%
.,,...-,"'
10%
emper, F 400
HB 401
500 600 700 800 900 388
375
375
363
352
1000 1100 1200 1300 321
293
269
229 109
10 9 5 Water-q uenched SINGLE HEAT RESULTS C Mn P Grade .90/1.03 .30/.50 .040 Max
Ladle .96
.40
.012
S
.050 Max
.029
--
.20
Si Grain
Size
50% 5- 7
50% 1-4
Critical Points, F: Ac, 1350 Ac3 1365 Ar3 1320 Ar, 1265
MASS EFFECT Size Round Tensile Strength Yield Point Elongation Reduction Hardness in.
psi
psi
% 2 in. of Area, %
HB
Water-quenched from 1450 F, tempered at 900 F.
½ 1 2 4
191,500 182,000 179,750 167,250
135,500 121,000 113,000 94,500
12.3 13.0 12.7 12.5
31.7 37.3 33.8 31.4
375 363 352 331
44.1 41.4 39.1 35.3
321 311 302 285
Water-quenched from 1450 F, tempered at 1000 F.
½ 1 2 4
172,000 165,000 154,750 150,000
111,000 102,500 98,500 81,000
12.4 16.0 15.7 15.7
Water-quenched from 1450 F, tempered at 1100 F. ½ 1 2 4
144,000 143,000 140,000 131,250
99,000 96,500 90,000 78,000
17.2 16.7 17.5 18.7
As-quenched Hardness (water) Size Round Surface ½ 1 2 4
110
HRC 65 HRC 64 HRC 63 HRC 63
½ Radius HRC 55 HRC 46 HRC 43 HRC 38
Center HRC 48 HRC 44 HRC 40 HRC 30
44.9 43.7 43.6 41.1
293 293 285 262
Water-q uenched 10 9 5 Treatment" Normalized at 1650 F" reheated to 1450 F" quenched in water. 1-in. Round Treated" .505-in. Round Tested.
As-quenched H B 601.
psi
200,000
150,000
,,---
__.._._.__
\ \
100,000 ....
\
\
\ 70% ......... 60%
/50%
50,000 ReduCtion of Are
40%
.a
3O%
.......
20%
-
Elonoatio_n._n iii
'emper, F 400 500 600
H B 601 601 534
10%
.... l
700 800 900 461 388 331
1000 1100 1200 1300 293 262 235 201 111
1137 Oil-quenched SINGLE HEAT RESULTS C Mn P Grade .32/.39
1.35/1.65 .040 Max
.08/.13
S
Si
--
Size
Grain
Ladle .37 1.40 .015 .08 .17 1-4 Critical Points, F: Acl 1330 Ac3 1450 Ar3 1310 Arl 1180
MASS EFFECT Size Round Tensile Strength Yield Point Elongation Reduction Hardness in.
psi
psi
% 2 in. of Area, %
HB
Annealed (Heated to 1450 F, furnace-cooled 20 F per hour to 1130 F, cooled in air.)
1
84,750
50,000
26.8
53.9
174
25.0 22.5 21.8 23.3
58.5 48.5 51.6 51.0
201 197 197 192
Normalized (Heated to 1650 F, cooled in air.)
½ 1 2 4
98,000 97,000 96,000 94,000
58,500 57,500 49,000 48,000
Oil-quenched from 1575 F, tempered at 1000 F.
½ 1 2 4
127,500 108,000 105,000 100,500
100,000 18.2 55.8 255 75,750 21.3 56.0 223 63,000 23.0 56.2 217 58,750 22.3 55.5 201
Oil-quenched from 1575 F, tempered at 1100 F.
½ 1 2 4
112,500 100,750 98,000 95,250
90,000 21.8 61.0 229 68,750 23.5 60.1 207 61,500 23.0 57.8 207 57,000 24.5 59.5 192
Oil-quenched from 1575 F, tempered at 1200 F.
½ 1 2 4
104,000 97,750 97,000 94,500
80,500 68,750 57,250 56,000
24.6 23.5 25.0 24.0
63.6 60.8 64.1 61.1
As-quenched Hardness (oil) Size Round Surface
½ 1 2 4 112
HRC 48 HRC 34 HRC 28 HRC 21
½ Radius
HRC 43 HRC 28 HRC 22 HRC 18
Center
HRC 42 HRC 23 HRC 18 HRC 16
217 201 197 192
Oil-quenched 1137 Treatment" Normalized at 1650 F" reheated to 1575 F" quenched in oil. 1-in. Round Treated" .505-in. Round Tested.
As-quenched H B 363.
psi .00,000
t50,O00
100,000
........
70% 60%
i
50,000
5O%
Z
40% 30% 20% 10%
]"
mper, F 400 500 600 700 800 900 1000 1100 1200 1300
HB 352 331 285 277 262 241 229 217 197 174 113
1137 Water-quenched SINGLE HEAT RESULTS P C Mn Grade .32/.39
1.35/1.65 .040 Max
.08/.13
Ladle .37 1.40 .015 .08 .17 Critical Points, F: Acl 1330 Ac
S
Si
--
Size
Grain
1-4
1450 Ar3 1310 Arl 1180
MASS EFFECT Size Round Tensile Strength Yield Point Elongation Reduction Hardness in.
psi
psi
% 2 in. of Area, %
HB
Water-quenched from 1550 F, tempered at 1000 F.
½ 1 2 4
129,500 122,000 110,000 108,000
112,000 17.1 51.3 262 98,000 16.9 51.2 248 71,250 20.8 56.1 229 69,000 20.3 52.1 223
Water-quenched from 1550 F, tempered at 1100 F.
½ 1 2 4
112,500 107,750 105,250 97,750
95,000 21.4 57.6 229 87,750 21.0 59.2 223 76,000 22.0 61.7 217 61,250 23.5 60.9 201
Water-quenched from 1550 F, tempered at 1200 F.
½ 1 2 4
105,000 102,500 97,500 95,500
89,000 81,750 67,000 60,000
23.9 22.3 24.0 24.0
61.2 58.8 64.1 63.5
223 217 201 197
As-quenched Hardness (water) Size Round Surface ½
1
2 4
114
HRC 57
HRC 56
HRC 52 HRC 48
½ Radius HRC 53
HRC 50
HRC 35 HRC 23
Center HRC 50
HRC 45
HRC 24 HRC 20
Water-quenched 1137 Treatment" Normalized at 1650 F" reheated to 1550 F'quenched in water. 1-in. Round Treated • .505-in. Round Tested.
As-quenched HB 415.
psi
\
").00,000
\ \
150,000
X,\ \
100,000
70%
f
60%
50,000
5O%
40% 30% f
Eiongat'lon ...,,.,.
20%
-'-
10%
mper, F 400 500 600 700 800 900
HB 415 415 375 341 311 285
1000 1100 1200 1300 262 229 187 179 115
1141 Oil-quenched SINGLE HEAT RESULTS C Grade .37/.45
Ladle .39
Mn 1.35/1.65 .040 Max
1.58
.02
P
S
--
Size
.08/.13
.08
.19
Si Grain
90% 2-4
10% 5
Critical Points, F: Act 1330 Ac3 1435 Ar3 1230 Art 1190
MASS EFFECT
Yield Strength Size Round Tensile Strength (.2% Offset) Elongation Reduction Hardness in.
psi
psi
% 2 in. of Area, %
HB
Annealed (Heated to 1500 F, furnace-cooled 20 F per hour to 900 F, cooled in air.)
1
86,800
51,200
25.5
49.3
163
22.7 22.7 22.5 21.7
57.8 207 55.5 201 55.8 201 49.3 201
18.7 23.5 21.8 20.8
57.1 58.7 57.2 54.3
262 229 217 212
20.7 23.8 24.0 23.5
60.6 62.2 62.5 59.1
235 207 201 197
23.5 24.8 25.2 25.2
63.8 64.1 65.1 63.0
217 197 192 183
Normalized (Heated to 1650 F, cooled in air.)
½ 1 2 4
105,800 102,500 101,200 100,500
62,300 58,750 57,000 55,000
Oil-quenched from 1500 F, tempered at 1000 F.
½ 1 2 4
129,500 110,200 108,500 107,200
110,200 75,300 74,700 66,800
Oil-quenched from 1500 F, tempered at 1100 F.
½ 1 2 4
116,200 103,000 101,000 100,000
95,700 69,800 68,700 61,300
Oil-quenched from 1500 F, tempered at 1200 F.
½ 1 2 4
105,200 96,300 95,800 95,200
87,400 69,600 65,300 60,300
As-quenched Hardness (oil) Size Round Surface
½ 1
2 4 116
HRC 52 C 48 HRC 36 HRC 27
Ht
½ Radius HRC 49 HRC 43 HRC 28 HRC 22
Center HRC 46 HRC 38 HRC 22 HRC 18
Oil-quenched 1141 Treatment" Normalized at 1575 F" reheated to 1500 F" quenched in oil. .530-in. Round Treated • .505-in. Round Tested. As-quenched H B 495.
psi
-,\
\ 200,000
\\
150,000
i "< \
o%
100,000
40%
/f
30% 20%
--
7 50,000 emper, F 400
HB 461
10%
500 444
600 415
7OO 8OO
388 331
900 293
1000 262
1100 1200 1300 235 217 192 117
1144 Oil-quenched SINGLE HEAT RESULTS C Mn P Grade .40/.48 Ladle .46
S
1.35/1.65 .040 Max
.24/.33
1.37
.05
.019
.24
Si
--
Grain
Size
75% 1-4
25% 5-6
Critical Points, F: Acl 1335 Ac3 1400 At3 1285 Ar
1200
MASS EFFECT Size Round Tensile Strength Yield Point Elongation Reduction Hardness in.
psi
psi
% 2 in. of Area, %
HB
Annealed (Heated to 1450 F, furnace-cooled 20 F per hour to 1150 F, cooled in air.)
1
84,750
50,250
24.8
41.3
167
24.6 21.0 21.5 21.5
51.0 40.4 45.0 42.7
201 197 192 192
Normalized (Heated to 1650 F, cooled in air.)
½ 1 2 4
98,000 96,750 95,500 94,250
60,500 58,000 54,000 52,500
Oil-quenched from 1550 F, tempered at 1000 F.
½ 1 2 4
113,500 108,500 105,000 101,750
79,000 72,750 67,750 63,000
20.4 52.1 235 19.3 46.0 223 20.5 49.6 212 21.5 50.0 207
Oil-quenched from 1550 F, tempered at 1100 F.
½ 1 2 4
104,000 102,750 101,000 94,250
71,250 20.7 51.2 217 68,000 21.5 51.4 212 65,000 23.3 56.5 207 57,750 23.8 54.4 192
Oil-quenched from 1550 F, tempered at 1200 F.
½ 1 2 4
97,500 97,000 94,000 89,000
69,000 68,000 61,500 54,000
23.2 23.0 24.0 25.8
55.2 52.4 57.7 57.7
201 201 192 183
As-quenched Hardness (oil) Size Round Surface ½ 1 2 4
118
HRC 39 HRC 36 HRC 30 HRC 27
½ Radius
Center
HRC 32 HRC 29 HRC 27 HRB 98
HRC 28 HRC 24 HRC 22 HRB 97
Oil-quenched 1144 Treatment: Normalized at 1650 F" reheated to 1550 F" quenched in oil. 1-in. Round Treated • .505-in. Round Tested.
As-quenched HB 285.
psi
200,000
150,000
------- ----
-
Tensile Strength
100,000 Yield Point
70% 60%
50,000
Reduction
5O%
of Area ,,,,-,"
4O%
30% Elongation __.__._
.._._._.._
20% 10%
emper, F 400 500 600 700 800 900
HB 277 269 262 255 248 241
1000 1100 1200 1300 235 229 217 201 119
120
ALLOY STEEL CARBURIZING GRADES
122 124 126 128 130 132 134
121
4118 4320 4419 4620 4820 8620 E9310
4118 SINGLE HEAT RESULTS C
Mn
Grade .18/.23 .70/.90 --
Ladle .21
P
S
Si
Ni
Cr
Mo
Grain
-- .20/.35 -- .40/.60 .08/.15 Size
.80 .008 .007 .27
.16 .52
.08
6-8
MASS EFFECT Yield Strength Size Round Tensile Strength (.2% Offset) Elongation Reduction Hardness in.
psi
psi
% 2 in. of Area, % H B
Annealed (Heated to 1600 F ; furnace-cooled 20 F per hour to 1150 F ; cooled in air.) 1
75,000
53,000
Normalized (Heated to 1670 F; cooled in air.) .565 85,000 57,000 31.5
1 2
4
84,500 77,500
56,000 54,500
75,500
33.0
70.1
32.0 34.0
49,500
170
71.0
74.4
34.0
63.7
156
143
71.2
137
Mock-Carburized at 1700 F for 8 hours; reheated to 1525 F; quenched in oil; tempered at 300 F. .565
1 2 4
143,000
119,000 97,000 93,000
93,500
64,500 46,000 43,500
17.5
41.3
21.0 26.5 28.0
293
37.5 56.3 61.3
241 201 192
Mock-Carburized at 1700 F for 8 hours; reheated to 1525 F; quenched in oil; tempered at 450 F. .565
1 2 4
138,000
115,000 93,500 89,500
89,500
64,000 45,500 43,000
17.5
41.9
22.0 28.0 28.5
277
49.0 62.0 63.5
As-quenched Hardness (oil) Size Round Surface
.565
1 2
4
122
½ Radius
Center
HRC 33
HRC 33
HRC 33
HRB87
HRB87
HRB85
HRC 22 HRC 20 HRC 20 HRB88 HRB88 HRB87
235 192 187
137
4118 SINGLE HEAT RESULTS
Ladle
c
Mn
P
S
Si
Ni
.21
.80
.008
.007
.27
.16
Cr .52
Grain Size
Mo .08
6-8
Critical Points, F: Acl 1380 Ac3 1520 Ar3 1430 Arl 1260 .565-in. Round Treated; .505-in. Round Tested CASE
CORE PROPERTIES
Hardness Depth HRC in.
Yield Strength Tensile Strength (.2% Offset) Elongation Reduction Hardness psi
psi
% 2 in. of Area, %
HB
Recommended Practice for Maximum Case Hardness Direct quench from pot: 1) Carburized at 1700 F for 8 hours; 2) quenched in agitated oil; 3) tempered at 300 F.
61
.063
177,500
131,000
9.0
42.3
352
Single-quench and temper--for good case and core properties:
1 ) Carburized at 1700 F for 8 hours; 2) pot-cooled; 3) reheated to 1525 F; 4) quenched in agitated oil; 5) tempered at 300 F.
62
.047
143,000
93,500
17.5
41.3
293
Double-quench and temper--for maximum refinement of case and core:
1 ) Carburized at 1700 F for 8 hours; 2) pot-cooled; 3) reheated to 1525 F;
4) quenched in agitated oil; 5) reheated to 1475 F; 6) quenched in agitated oil; 7) tempered at 300 F.
62
.047
126,000
63,500
21.0
42.4
241
Recommended Practice for Maximum Core Toughness Direct quench from pot: 1) Carburized at 1700 F for 8 hours; 2) quenched in agitated oil; 3) tempered at 450 F.
57
.063
177,000
130,000
13.0
48.0
341
Single-quench and temper--for good case and core properties: 1) Carburized at 1700 F for 8 hours; 2) pot-cooled; 3) reheated to 1525 F; 4) quenched in agitated oil; 5) tempered at 450 F.
56
.047
138,000
89,500
17.5
41.9
277
Double-quench and temper--for maximum refinement of case and core:
1) Carburized at 1700 F for 8 hours; 2) pot-cooled; 3) reheated to 1525 F; 4) quenched in agitated oil ; 5) reheated to 1475 F ; 6) quenched in agitated oil; 7) tempered at 450 F.
56
.047
120,000
63,000
22.0
48.9
229
123
4320 SINGLE HEAT RESULTS C
Mn
P
S
Si
Ni
Cr
Mo
Grain
Grade .17/.22 .45/.65 -- -- .20/.35 1.65/2.00 .40/.60 .20/.30 Size Ladle .20
.59 .021 .018 .25
1.77
.47
.23
6-8
MASS EFFECT Size Round Tensile Strength Yield Point Elongation Reduction Hardness in.
psi
psi
% 2 in. of Area, %
HB
Annealed (Heated to 1560 F; furnace-cooled 30 F per hour to 790 F; cooled in air.) 1
84,000
61,625
29.0
58.4
Normalized (Heated to 1640 F; cooled in air.)
½ 1 2 4
121,500 115,000 102,500 102,000
74,375 67,250 58,750 57,000
23.9 20.8 23.3 22.3
54.3 50.7 59.2 54.7
248 235 212 201
Mock-Carburized at 1700 F for 8 hours; reheated to 1500 F; quenched in oil; tempered at 300 F.
½ 1 2 4
212,000 152,500 132,500 119,750
163,250 107,250 86,000 75,250
11.8 17.0 22.5 24.0
45.5 51.0 56.4 57.1
415 302 255 248
Mock-Carburized at 1700 F for 8 hours; reheated to 1500 F; quenched in oil; tempered at 450 F.
½ 1 2 4
187,500 148,750 129,750 118,000
149,500 13.9 52.8 105,000 17.8 55.2 85,000 20.8 63.8 75,000 22.5 51.9
As-quenched Hardness (oil) Size Round Surface
½
1
2 4
124
HRC 44.5
HRC 39
HRC 35 HRC 25
½ Radius HRC 44.5
HRC 37
HRC 30 HRC 24
Center HRC 44.5
HRC 36
HRC 27 HRC 24
388 285 255 241
163
4320 SINGLE HEAT RESULTS C Ladle .20
Mn .59
P
.021
S
.018
Si
.25
Ni
1.77
Cr
.47
Mo
.23
Grain
Size
6-8
Critical Points, F: Acl 1350 Ac3 1485 Ar3 1330 Arl 840 .565-in. Round Treated; .505-in. Round Tested
CASE
CORE PROPERTIES
Hardness Depth H RC
in.
Tensile Strength Yield Point Elongation Reduction Hardness psi
psi
% 2 in. of Area, %
HB
Recommended Practice for Maximum Case Hardness Direct quench from pot: 1) Carburized at 1700 F for 8 hours; 2) quenched in agitated oil; 3) tempered at 300 F. 60.5 .060
217,000
159,500
13.0
50.1
429
Single-quench and temper--for good case and core properties:
1) Carburized at 1700 F for 8 hours; 2) pot-cooled; 3) reheated to 1500 F; 4) quenched in agitated oil; 5) tempered at 300 F. 62.5
.075
218,250
178,000
13.5
48.2
429
Double-quench and temper--for maximum refinement of case and core:
1) Carburized at 1700 F for 8 hours; 2) pot-cooled; 3) reheated to 1500 F;
4) quenched in agitated oil; 5) reheated to 1425 F; 6) quenched in agitated oil; 7) tempered at 300 F. 62
.075
151,750
97,000
19.5
49.4
302
Recommended Practice for Maximum Core Toughness Direct quench from pot: 1) Carburized at 1700 F for 8 hours; 2) quenched in agitated oil; 3) tempered at 450 F. 58.5 .060
215,500
158,750
12.5
49.4
415
Single-quench and temper--for good case and core properties:
1 ) Carburized at 1700 F for 8 hours; 2) pot-cooled; 3) reheated to 1500 F; 4) quenched in agitated oil; 5) tempered at 450 F.
59
.075
211,500
173,000
12.5
50.9
41 5
Double-quench and temper--for maximum refinement of case and core:
1) Carburized at 1700 F for 8 hours; 2) pot-cooled; 3) reheated to 1500 F;
4) quenched in agitated oil; 5) reheated to 1425 F ; 6) quenched in agitated oil; 7) tempered at 450 F.
59
.075
145,750
94,500
21.8
56.3
293
125
4419 SINGLE HEAT RESULTS c
Mn
Grade .18/.23 .45/.65 --
Ladle .18
.57
P
S
Si
-- .20/.35 -- -- .45/.60
.010 .029
.28
Ni Cr
Mo Grain
Size
.03 .01
.52
6-8
MASS EFFECT Size Round Tensile Strength Yield Point Elongation Reduction Hardness in.
psi
psi
% 2 in. of Area, %
HB
Annealed (Heated to 1675 F ; furnace-cooled 20 F per hour to 900 F ; cooled in air.) 1
64,750
48,000
31.2
62.8
121
Normalized (Heated to 1750 F; cooled in air.) ½"
77,500
1 2 4
75,250 72,250 72,750
52,250
33.2
51,000 50,000 47,750
69.9
32.5 30.8 30.0
149
69.4 64.9 60.8
143 143 143
Mock-Carburized at 1700 F for 8 hours; reheated to 1550 F; quenched in oil; tempered at 300 F.
½" 1
103,250 97,250
2 4
96,000 86,000
65,250 62,750
24.3 60.3 217 24.2 66.4 201
60,250 53,250
25.3 27.7
64.7 66.3
Mock-Carburized at 1700 F for 8 hours; reheated to 1550 F; quenched in oil; tempered at 450 F.
½" 1 2 4
102,750 62,500 24.8 63.6 212 94,250 58,750 25.0 68.6 197 92,500 58,000 26.2 68.2 192 83,500 48,500 27.0 67.1 170
As-quenched Hardness (oil) Size Round Surface ½ 1 2
4
HRB 96 HRB 94 HRB 94
HRB 93
"Treated as .565 in. Rd.
126
½ Radius HRB 95 HRB 93 HRB 92
HRB 90
Center HRB 93 HRB 89 HRB 88
HRB 82
201 179
4419 SINGLE HEAT RESULTS c Ladle .18
Mn .57
P
.010
S .029
Si .28
Ni
Cr
Mo
.03
.01
Critical Points, F: Acl 1380 Ac3 1600 Ar3 1510
.52
Size
Ar 1420
Grain
6-8
.565-in. Round Treated; .505-in. Round Tested CASE
CORE PROPERTIES
Hardness Depth HRC in.
Tensile Strength Yield Point Elongation Reduction Hardness psi
psi
% 2 in. of Area, %
HB
Recommended Practice for Maximum Case Hardness Direct quench from pot: 1) Carburized at 1700 F for 8 hours; 2) quenched in agitated oil; 3) tempered at 300 F.
64
.054
120,500
88,250
19.7
64.7
241
Single-quench and temper--for good case and core properties: 1) Carburized at 1700 F for 8 hours; 2) pot-cooled; 3) reheated to 1550 F; 4) quenched in agitated oil; 5) tempered at 300 F.
65
.062
103,250
65,250
24.3
60.3
217
Double-quench and temper--for maximum refinement of case and core:
1 ) Carburized at 1700 F for 8 hours; 2) pot-cooled; 3) reheated to 1 575 F;
4) quenched in agitated oil; 5) reheated to 1525 F ; 6) quenched in agitated oil; 7) tempered at 300 F.
66
.070
106,500
54,750
21.7
49.7
217
Recommended Practice for Maximum Core Toughness Direct quench from pot: 1) Carburized at 1700 F for 8 hours; 2) quenched in agitated oil; 3) tempered at 450 F.
59
.054
118,500
86,500 18.8
67.0
235
Single-quench and temper--for good case and core properties: 1) Carburized at 1700 F for 8 hours; 2) pot-cooled; 3) reheated to 1550 F; 4) quenched in agitated oil; 5) tempered at 450 F. 60.5 .062
102,750
62,500
24.8
63.6
212
Double-quench and temper--for maximum refinement of case and core:
1) Carburized at 1700 F for 8 hours; 2) pot-cooled; 3) reheated to 1575 F;
4) quenched in agitated oil; 5) reheated to 1525 F ; 6) quenched in agitated oil; 7) tempered at 450 F.
61
.070
98,500
54,500
23.4
59.7
201
127
4620 SINGLE HEAT RESULTS c
Mn
P
Grade .17/.22 .45/.65 --
Ladle .17
.52
S
Si
Ni
Cr
Mo Grain
.20/.35 1.65/2.00 -- .20/.30 Size
-
.017 .016
.26
1.81
.10 .21
6-8
MASS EFFECT Size Round Tensile Strength Yield Point in.
psi
Elongation Reduction Hardness
psi
%2in. of Area,%
HB
Annealed (Heated to 1575 F ; furnace-cooled 30 F per hour to 900 F ; cooled in air.) 1
74,250
54,000
31.3
60.3
Normalized (Heated to 1650 F; cooled in air.)
½ 1 2
87,250 83,250 80,500
4
77,000
54,750 53,125 53,000 51,750
30.7 29.0 29.5 30.5
68.0 66.7 67.1
65.2
192 174 167
163
Mock-Carburized at 1700 F for 8 hours; reheated to 1500 F; quenched in oil; tempered at 300 F.
½ 1 2 4
127,000 98,000 96,500 84,750
89,500 67,000 65,250 52,500
20.0 59.8 255 25.8 70.0 197 27.0 69.7 192 29.5 69.2 170
Mock-Carburized at 1700 F for 8 hours; reheated to 1500 F; quenched in oil; tempered at 450 F.
½ 1 2 4
117,500 98,000 95,750 84,500
81,000 66,250 62,000 52,750
21.4 65.3 241 27.5 68.9 192 26.8 69.2 187 29.8 70.3 170
As-quenched Hardness (oil) Size Round Surface
½
1
2 4
128
HRC 40
HRC 27
HRC 24 HRB96
½ Radius HRC 32
HRB 99
HRB 94 HRB91
Center HRC 31
HRB 97 HRB 91 HRB88
149
4620 SINGLE HEAT RESULTS c Ladle .17
Mn .52
P
.017
S
Si
.016
.26
Ni
Cr
Grain Size
Mo
1.81
.10
Critical Points, F: Acl 1300 Ac3 1490 Ar3 1335
.21
6-8
Arl 1220
.565-in. Round Treated; .505-in. Round Tested CASE
CORE PROPERTIES
Hardness Depth HRC in.
Tensile Strength Yield Point Elongation Reduction Hardness psi
psi
% 2 in. of Area, %
HB
Recommended Practice for Maximum Case Hardness Direct quench from pot: 1) Carburized at 1700 F for 8 hours" 2) quenched in agitated oil; 3) tempered at 300 F. 60.5
.075
148,250
116,500
17.0
55.7
311
Single-quench and temper--for good case and core properties: 1 ) Carburized at 1700 F for 8 hours; 2) pot-cooled; 3) reheated to 1500 F; 4) quenched in agitated oil; 5) tempered at 300 F. 62.5
.075
119,250
83,500
19.5
59.4
277
Double-quench and temper--for maximum refinement of case and core:
1) Carburized at 1700 F for 8 hours; 2) pot-cooled; 3) reheated to 1525 F;
4) quenched in agitated oil ; 5) reheated to 1475 F ; 6) quenched in agitated oil; 7) tempered at 300 F.
62
.060
122,000
77,250
22.0
55.7
248
Recommended Practice for Maximum Core Toughness Direct quench from pot: 1) Carburized at 1700 F for 8 hours; 2) quenched in agitated oil; 3) tempered at 450 F. 58.5
.060
147,500
115,750
16.8
57.9
302
Single-quench and temper--for good case and core properties: 1 ) Carburized at 1700 F for 8 hours; 2) pot-cooled; 3) reheated to 1500 F; 4) quenched in agitated oil; 5) tempered at 450 F.
59
.065
115,500
80,750
20.5
63.6
248
Double-quench and temper--for maximum refinement of case and core:
1 ) Carburized at 1700 F for 8 hours; 2) pot-cooled; 3) reheated to 1525 F;
4) quenched in agitated oil; 5) reheated to 1475 F ; 6) quenched in agitated oil; 7) tempered at 450 F.
59
.060
115,250
77,000
22.5
62.1
235
129
4820 SINGLE HEAT RESULTS C
Mn
Grade .18/.23 .50/.70 --
Ladle .20
P
S
Si
Ni
Cr
Mo
Grain
-- .20/.35 3.25/3.75 -- .20/.30 Size
.61 .027 .016 .29
3.47
.07 .22
6-8
MASS EFFECT Size Round Tensile Strength Yield Point Elongation Reduction Hardness in.
psi
psi
% 2 in. of Area, %
HB
Annealed (Heated to 1500 F ; furnace-cooled 30 F per hour to 500 F ; cooled in air.) 1
98,750
67,250
22.3
58.8
Normalized (Heated to 1580 F; cooled in air.)
½ 1 2 4
11 2,500 109,500 107,250 103,500
72,500 26.0 57.8 235 70,250 24.0 59.2 229 69,000 23.0 59.8 223 68,000
22.0
58.4
21 2
Mock-Carburized at 1700 F for 8 hours; reheated to 1475 F; quenched in oil; tempered at ,300 F.
½ 1 2 4
209,000 1 69,500 135,500 118,750
172,750 14.2 54.3 401 126,500 1 5.0 51.0 352 93,250 19.8 56.3 277 81,000
23.0
59.4
241
Mock-Carburized at 1700 F for 8 hours; reheated to 1475 F; quenched in oil; tempered at 450 F.
½ 1 2 4
205,000 163,250 130,000 117,000
170,000 13.2 52.3 388 120,500 15.5 53.1 331 92,500 19.0 62.7 269 80,000
21.0
63.8
235
As-quenched Hardness (oil) Size Round Surface
½ 1 2 4
130
HRC 45 HRC 43 HRC 36 HRC 27
½ Radius HRC 45 HRC 39 HRC 31 HRC 24
Center HRC 44 HRC 37 HRC 27 HRC 24
197
4820 SINGLE HEAT RESULTS c Ladle .21
Mn .51
P
S
.021
.018
Si .21
Ni
Cr
Mo
3.49
.18
1310 Ac3 1440 Ar3 1215
Critical Points, F: Ac
.24
Grain
Size
Arl 780
6-8
.565-in. Round Treated; .505-in. Round Tested CASE
CORE PROPERTIES
Hardness Depth HRC in.
Tensile Strength Yield Point Elongation Reduction Hardness psi psi % 2 in. of Area, % H B
Recommended Practice for Maximum Case Hardness Direct quench from pot: 1) Carburized at 1700 F for 8 hours; 2) quenched in agitated oil; 3) tempered at 300 F. 60
.039
205,000
165,500
13.3
53.3
41 5
Single-quench and temper--for good case and core properties:
1) Carburized at 1700 F for 8 hours; 2) pot-cooled; 3) reheated to 1475 F; 4) quenched in agitated oil; 5) tempered at 300 F.
61
.047
207,500
167,000
13.8
52.2
41 5
Double-quench and temper--for maximum refinement of case and core:
1) Carburized at 1700 F for 8 hours; 2) pot-cooled; 3) reheated to 1500 F; 4) quenched in agitated oil ; 5) reheated to 1450 F ; 6) quenched in agitated oil ; 7) tempered at 300 F.
60
.047
204,500
165,500
13.8
52.4
415
Recommended Practice for Maximum Core Toughness Direct quench from pot: 1) Carburized at 1700 F for 8 hours; 2) quenched in agitated oil; 3) tempered at 450 F.
56
.039
200,500
170,000
12.8
53.0
401
Single-quench and temper--for good case and core properties: 1) Carburized at 1700 F for 8 hours; 2) pot-cooled; 3) reheated to 1475 F; 4) quenched in agitated oil; 5) tempered at 450 F. 57.5 .047
205,000
184,500
13.0
53.3
41 5
Double-quench and temper--for maximum refinement of case and core:
1) Carburized at 1700 F for 8 hours; 2) pot-cooled; 3) reheated to 1500 F; 4) quenched in agitated oil; 5) reheated to 1450 F ; 6) quenched in agitated oil; 7) tempered at 450 F. 56.5 .047
196,500
171,500.
13.0
53.4
401
131
8620 SINGLE HEAT RESULTS Ni
Cr
Grade .18/.23 .70/.90 -- -- .20/.35 .40/.70 .40/.60 .15/.25
Size
C
Ladle .23
Mn
P
Si
S
.81 .025 .016 .28
.56
.43
.19
Mo
Grain 90% 7-8
10% 4
MASS EFFECT Size Round Tensile Strength Yield Point Elongation Reduction Hardness in.
psi
psi
% 2 in. of Area, %
HB
Annealed (Heated to 1600 F ; furnace-cooled 30 F per hour to 1150 F ; cooled in air.) 1
77,750
55,875
31.3
62.1
149
Normalized (Heated to 1675 F; cooled in air.)
½ 1 2
4
96,500 91,750 87,250
54,250 51,750 51,500
81,750
26.3
26.3 27.8
51,500
62.5
59.7 62.1
28.5
197
183 179
62.3
163
Mock-Carburized at 1700 F for 8 hours; reheated to 1550 F; quenched in oil; tempered at 300 F.
½ 1 2 4
199,500 126,750 117,250 98,500
157,000 13.2 49.4 388 83,750 20.8 52.7 255 73,000 23.0 57.8 235 57,750 24.3 57.6 207
Mock-Carburized at 1700 F for 8 hours; reheated to 1550 F; quenched in oil; tempered at 450 F.
½ 1 2 4
178,500 124,250 114,500 98,000
139,500 14.6 53.9 352 80,750 19.5 54.2 248 72,250 22.0 59.0 229 55,500 25.5 57.8 201
As-quenched Hardness (oil) Size Round Surface
½
1
2 4
132
HRC 43
HRC 29
HRC 23 HRC22
½ Radius
HRC 43
HRC 27
HRC 22 HRB95
Center
HRC 43
HRC 25
HRB 97 HRB 93
8620 SINGLE HEAT RESULTS c Ladle .23
Mn .81
P
.025
S .016
Si .28
.56
Ni
Mo
Cr
.43
.19
Critical Points, F: Acl 1380 Ac3 1520 Ar3 1400
Arl 1200
Grain Size
90% 7-8
10% 4
.565-in. Round Treated; .505-in. Round Tested CASE
CORE PROPERTIES
Hardness Depth HRC in.
Tensile Strength Yield Point Elongation Reduction Hardness
psi
psi
% 2 in. of Area, %
HB
i
Recommended Practice for Maximum Case Hardness Direct quench from pot: 1) Carburized at 1700 F for 8 hours; 2) quenched in agitated oil; 3) tempered at 300 F.
63
.056
192,000
150,250
12.5
49.4
388
Single-quench and temper--for good case and core properties:
1) Carburized at 1700 F for 8 hours; 2) pot-cooled; 3) reheated to 1550 F; 4) quenched in agitated oil; 5) tempered at 300 F.
64
.075
188,500
149,750
11.5
51.6
388
Double-quench and temper--for maximum refinement of case and core:
1) Carburized at 1700 F for 8 hours; 2) pot-cooled; 3) reheated to 1550 F; 4) quenched in agitated oil ; 5) reheated to 1475 F ; 6) quenched in agitated oil; 7) tempered at 300 F.
64
.070
133,000
83,000
20.0
56.8
269
Recommended Practice for Maximum Core Toughness Direct quench from pot: 1) Carburized at 1700 F for 8 hours; 2) quenched in agitated oil; 3) tempered at 450 F.
58
.050
181,250
134,250
12.8
50.6
352
Single-quench and temper--for good case and core properties: 1) Carburized at 1700 F for 8 hours; 2) pot-cooled; 3) reheated to 1550 F; 4) quenched in agitated oil; 5) tempered at 450 F.
61
.076
167,750
120,750
14.3
53.2
341
Double-quench and temper--for maximum refinement of case and core:
1) Carburized at 1700 F for 8 hours; 2) pot-cooled; 3) reheated to 1550 F; 4) quenched in agitated oil ; 5) reheated to 1475 F ; 6) quenched in agitated oil ; 7) tempered at 450 F.
61
.070
130,250
77,250
22.5
51.7
262
133
E9310 SINGLE HEAT RESULTS C
Mn
P
S
Si
Ni
Cr
Mo Grain
Grade .08/.13 .45/.65 -- -- .20/.35 3.00/3.50 1.00/1.40 .08/.15 Size Ladle .09
.57 .012 .010 .32
3.11
1.23
.13
8O% 5
20% 2-4
MASS EFFECT Size Round Tensile Strength Yield Point Elongation Reduction Hardness in.
psi
psi
% 2 in. of Area, %
HB
Annealed (Heated to 1550 F; furnace-cooled 30 F per hour to 760 F ; cooled in air.) 1
119,000
63,750
17.3
42.1
Normalized (Heated to 1630 F; cooled in air.)
½ 1
133,000 131,500
2 4
131,250 125,250
87,750 82,750 82,000 81,750
20.0 18.8 19.5 19.5
63.7 58.1
60.5 61.7
285 269
262 255
Mock-Carburized at 1700 F for 8 hours; reheated to 1450 F; quenched in oil; tempered at 300 F. 16
178,750
1 2
1 59,000 145,250
4
136,000
143,000
1 5.7
122,750 108,000 94,750
58.9
363
1 5.5 57.5 321 18.5 66.7 293
19.0
62.3
277
Mock-Carburized at 1700 F for 8 hours; reheated to 1450 F; quenched in oil; tempered at 450 F.
½ 1 2 4
178,250 157,500 143,500 131,500
141,500 1 5.0 60.3 363 1 23,000 16.0 61.7 321 105,500 17.8 68.1 293 96,500 20.5 67.0 269
As-quenched Hardness (oil) Size Round Surface
½ 1 2 4
134
HRC 40 HRC 40 HRC 38 HRC 31
½ Radius
HRC 40 HRC 38 HRC 35 HRC 30
Center
HRC 38 HRC 37 HRC 32 HRC 29
241
E9310 SINGLE HEAT RESULTS C Ladle 11.
Mn .53
P
.013
Si
S
.014
.29
Ni
Cr
3.19
1.23
Critical Points, F: Acl 1350 Ac3 1480 Ar3 1210
Mo Grain .11
Size
5-7
Ar 810
.565-in. Round Treated; .505-in. Round Tested CASE
CORE PROPERTIES
Hardness Depth HRC in.
Tensile Strength Yield Point Elongation Reduction Hardness psi
psi
% 2 in. of Area, %
HB
Recommended Practice for Maximum Case Hardness Direct quench from pot: 1) Carburized at 1700 F for 8 hours; 2) quenched in agitated oil; 3) tempered at 300 F. 59.5 .039
179,500
144,000
15.3
59.1
375
Single-quench and temper--for good case and core properties:
1) Carburized at 1700 F for 8 hours; 2) pot-cooled; 3) reheated to 1450 F; 4) quenched in agitated oil; 5) tempered at 300 F.
62
.047
173,000
135,000
1 5.5
60.0
363
Double-quench and temper--for maximum refinement of case and core:
1 ) Carburized at 1700 F for 8 hours; 2) pot-cooled; 3) reheated to 1475 F; 4) quenched in agitated oil ; 5) reheated to 1425 F; 6) quenched in agitated oil ; 7) tempered at 300 F. 60.5 .055
174,500
139,000
15.3
62.1
363
Recommended Practice for Maximum Core Toughness Direct quench from pot: 1) Carburized at 1700 F for 8 hours; 2) quenched in agitated oil; 3) tempered at 450 F. 54.5 .039
178,000
146,500
15.0
59.7
363
Single-quench and temper--for good case and core properties:
1) Carburized at 1700 F for 8 hours; 2) pot-cooled; 3) reheated to 1450 F; 4) quenched in agitated oil; 5) tempered at 450 F. 59.5 .047
168,000
137,500
15.5
60.0
341
Double-quench and temper--for maximum refinement of case and core:
1) Carburized at 1700 F for 8 hours; 2) pot-cooled; 3) reheated to 1475 F; 4) quenched in agitated oil ; 5) reheated to 1425 F ; 6) quenched in agitated oil; 7) tempered at 450 F.
58
.055
169,500
138,000
14.8
61.8
352
135
136
ALLOY STEEL WATER-HARDENING GRADES
138 140 142
137
4027 Water-quenched SINGLE HEAT RESULTS C
Mn
Grade .25/.30 .70/.90
Ladle .27
.75
--
P --
S
Si
Ni Cr
Mo Grain
.20/.35 -- -- .20/.30 Size
.014 .033
.28
.05 .07
.22
5-7
MASS EFFECT Size Round Tensile Strength Yield Strength Elongation Reduction Hardness in. psi (.2% Offset) psi % 2 in. of Area, % HB
Annealed (Heated to 1585 F, furnace-cooled 20 F per hour to 800 F, cooled in air.)
1
75,000
47,250
30.0
52.9
143
Normalized (Heated to 1660 F, cooled in air.) .565 1 2 4
94,500 93,250 85,500 81,750
61,500 61,250 55,750 51,250
25.5 25.8 27.7 28.3
60.2 60.2 57.1 55.9
179 179 163 156
58.4
321
Water-quenched from 1 585 F, tempered at 900 F. .565
1 2 4
1 56,500
1 50,000 114,500 101,000
143,250
1 5.8
133,000 89,000 77,500
1 6.0 57.8 22.0 66.6
25.0
68.3
311 229
201
Water-quenched from 1585 F, tempered at 1000 F. .565
1 2 4
144,000
139,250 111,000 100,000
1 30,500
17.7
1 22,250 85,000 73,750
61.3
1 8.8
23.7 25.2
302
60.1
67.2 67.4
223 201
Water-quenched from 1585 F, tempered at 1100 F. .565 1 2 4
130,250 114,250 1 04,250 95,000
11 5,750 20.0 64.5 262 93,250 23.0 67.6 229 80,000 24.8 68.3 212 71,000 26.6 68.0 1 92
As-quenched Hardness (water) Size Round Surface
.565 1 2 4
138
HRC 50 HRC 50 HRC 47 HRB 83
½ Radius
HRC 50
Center
HRC 50
HRC 47 HRC 27 HRB 77
HRC 44 HRC 27 HRB 75
285
Water-quenched 4027 SINGLE HEAT RESULTS C Mn Ladle
P
S
Si Ni Cr Mo Grain
Size
.27 .75 .014 .033 .28 .05 .07 .22 5-7
Critical Points, F: Ac, 1370 Ac31510 Ar3 1410 Ar, 1320 Treatment" Normalized at 1660 F" reheated to 1585 F" quenched in water. .565-in. Round Treated ' .505-in. Round Tested. As-quenched HB 477.
psi
250,000
200,000
1 50,000 .......
r. o\
70% 100,000'
, , 60% 50%
40% 30% --
Elongation
50,000 per, F 400
HB 41 5
20%
- 10%
500 415
600 41 5
700 388
800 363
900 321
1000 302
1100 1200 1300 262 229 1 92
139
4130 Water-quenched SINGLE HEAT RESULTS C
Mn
Grade .28/.33 .40/.60 --
Ladle .30
.48
P
S
Si
Ni
Cr
Mo
.80/1.10 .15/.25 Size
u .20/.35
.015 .015
.20
.12
.91
.20
Grain
6-8
MASS EFFECT Size Round Tensile Strength Yield Point in. psi psi
Elongation Reduction Hardness % 2 in. of Area, % H B
Annealed (Heated to 1585 F, furnace-cooled 20 F per hour to 1255 F: cooled in air.)
1
81,250
52,250
28.2 55.6
1 56
Normalized (Heated to 1600 F, cooled in air.)
½
106,500
1 2 4
97,000 89,000 88,750
67,000 63,250 61,750 57,750
25.1
25.5 28.2 27.0
59.6
59.5 65.4 61.2
217
197 167 163
Water-quenched from 1 575 F, tempered at 900 F.
½ 1
2 4
166,500 161,000
161,000 137,500
132,750 121,500
110,250 95,000
16.4
14.7
61.0
54.4
19.0
20.5
331
321
63.0
63.6
269
241
Water-quenched from 1575 F, tempered at 1000 F.
½ 1 2 4
1 51,000 142,500 18.1 63.9 302 144,500 129,500 18.5 61.8 293 121,750 116,000
98,750 91,500
21.2 21.5
66.3 63.5
241 235
Water-quenched from 1 575 F, tempered at 1100 F.
½ 1 2 4
133,000 122,500 128,000 113,250 114,500 101,500
91,500 77,500
20.7 21.2
21.7 24.5
69.0 67.5
67.7 69.2
229 197
As-quenched Hardness (water) Size Round Surface
½ 1 2
4
140
HRC 51
HRC 51
HRC 47
½ Radius
HRC 50
HRC 50
HRC 50
HRC 44
HRC 32
HRC 45.5 HRC 25
Center
HRC 31
HRC 24.5
269 262
Water-quenched 4130 SINGLE HEAT RESULTS C Mn P Ladle
S
Si Ni Cr Mo Grain
Size
.30 .48 .015 .015 .20 .12 .91 .20 6-8
Critical Points, F: Acl 1400 Ac3 1510 Ar3 1400 Arl 1305 Treatment: Normalized at 1600 F" reheated to 1575 F • quenched in water. .530-in. Round Treated" 505-in. Round Tested. As-quenched H B 495.
psi
\
\
200,000
z \ ?_ 150,000
t'lon o
f
Area
N
100,000
60%
"
40%
'"
30% 1
-
]Elongation .....
- 20% 10%
50,000 l emper, F 400
HB 461
500 444
600 429
700 415
800 401
900 1000 1100 1200 1300 331 302 269 241 202 141
8630 Water-quenched SINGLE HEAT RESULTS C
Mn
P
S
Si
Ni
Cr
Mo Grain
Grade .28/.33 .70/.90 m m .20/.35 .40/.70 .40/.60 .15/.25 Size Ladle .29
.85 .012 .021
.25
.62
.44
.19
6-8
MASS EFFECT Size Round Tensile Strength Yield Point Elongation Reduction Hardness in. psi psi % 2 in. of Area, % H B
Annealed (Heated to 1 550 F, furnace-cooled 20 F per hour to 11 55 F, cooled in air.) 1
81,750
54,000
29.0
58.9
1 56
60.2 53.5
201 187
Normalized (Heated to 1600 F, cooled in air.) ½ 1
2 4
95,000 94,250
61,750 62,250
93,000 92,500
25.2 23.5
62,000 56,250
26.2 24.5
59.2
57.3
187
187
Water-quenched from 1550 F, tempered at 900 F.
½ 1 2 4
1 52,250 150,500 16.4 59.4 302 146,750 131,750 16.2 56.5 293 129,750 107,250 19.2 63.7 269 113,000
86,000
21.2
64.7
235
Water-quenched from 1 550 F, tempered at 1000 F.
½ 1 2 4
139,250 134,750 1 20,250 107,250
132,500 1 8.9 58.1 285 123,000 18.7 59.6 269 100,000 21.2 65.6 235 82,500 23.0 63.0 217
Water-quenched from 1 550 F, tempered at 1100 F.
½ 1 2 4
134,500 11 8,000 111,250 96,000
132,000 101,250 89,000 72,250
19.2 18.7
22.5 25.5
61.0 58.2
68.6 68.1
223 197
As-quenched Hardness (water) Size Round Surface
½ 1
2
4
142
HRC52 HRC 52
HRC51
HRC 47
½ Radius
Center
HRC49 HRC 48
HRC47 HRC 43
HRC 25
HRC 22
HRC31
HRC30
269 241
Water-quenched 8630 SINGLE HEAT RESULTS C Mn P
S
Si Ni
Or
Ladle .30 .80 .018 .024 .27 .65 .48
Mo Grain Size .18 6-8
Critical Points, F: Ac11365 Ac31465
Ar31335
Ar, 1205
Treatment: Normalized at 1600 F; reheated to 1550 F; quenched in water. .530-in. Round Treated ; .505-in. Round Tested.
As-quenched H B 534.
psi
250,000
\
\
200,000
150,000
\\\
•
70%
100,000
50% 40% 30% Elongation
'
20% 10%
50,000 mper, F 400
HB 495
5OO
6OO
477
444
700 415
800 375
900 1000 1100 1200 1300 341 311 285 248 217
143
1717L
ALLOY STEEL OIL-HARDENING GRADES
146 148 150 152 1 54
156 158 160 162 164 166
145
1340 Oil-quenched SINGLE HEAT RESULTS C
Mn
Grade .38/.43 1.60/1.90
Ladle ,40
1.77
P --
S
--
.027
Si
Ni Cr Mo Grain
.20/.35 -- -- -- Size
.016
.25
.10 .12 .01 6-8
MASS EFFECT Size Round Tensile Strength Yield Point Elongation Reduction Hardness in.
psi
psi
% 2 in, of Area, %
HB
Annealed (Heated to 1475 F, furnace-cooled 20 F per hour to 1110 F, cooled in air.)
1
102,000
63,250
25.5
57.3
207
20.0 22.0 23.5 21.7
51.0 62.9 61.0 59.2
269 248 235 235
18.8 19.2 21 . 21.7
55.2 57.4
285 285
57.9
241
21.0 21.7 24.7 25.5
57.9 60.1 64.3 64.5
255 241 217 217
22.1 23.2 25.5 26.0
59.5 241 62.4 229 66.2 217 64.8 212
Normalized (Heated to 1600 F, cooled in air.)
½ 1 2 4
132,000 121,250 120,000 120,000
81,500 81,000 76,250 72,250
Oil-quenched from 1525 F, tempered at 1000 F.
½ 1 2 4
142,500 137,750 120,500 116,500
131,500 121,000 84,250 83,000
_
60.7
Oil-quenched from 1525 F, tempered at 1100 F.
½ 1 2 4
127,000 118,000 108,750 103,250
118,000 98,250 82,250 71,000
Oil-quenched from 1525 F, tempered at 1200 F.
½ 1 2 4
118,500 112,000 105,750 102,250
108,500 96,000 79,500 72,000
As-quenched Hardness (oil) Size Round Surface
½ 1 2 4
146
HRC 58 HRC 57 HRC 39 HRC 32
½ Radius
Center
HRC 57 HRC 56 HRC 34 HRC 30
HRC 57 HRC 50 HRC 32 HRC 26
248
Oil-quenched 1340
SINGLE HEAT RESULTS C Mn
P
S Si Ni Cr Mo Grain
Size
Ladle .43 1.70 .015 .039 .23 .03 .02 -- 6-8
Critical Points, F: Acl 1340 Ac3 1420 Ar3 1195 Arl 1160 Treatment: Normalized at 1600 F ; reheated to 1525 F ; quenched in agitated oil. .565-in. Round Treated ; .505-in. Round Tested.
As-quenched H B 601.
psi
\
\
250,000
\
\
\
\
\
L
200,000
150,000
70% 60% 100,000
50% 40% J
30% Elongation .,.,..-
20%
v
--
50,000
Temper, F 400
10%
L
H B 578
500 534
600 495
700 444
800 415
900 388
1000 1100 1200 1300 363 331 293 235
147
4140 Oil-quenched SINGLE HEAT RESULTS C
Mn
P
S
Si
Ni
Cr
Mo Grain Size
Grade .38/.43 .75/1.00 -- -- .20/.35 -- .80/1.10 .15//125 Ladle .40
.83
.012 .009
.26
.11
.94
.21
7-8
MASS EFFECT Size Round Tensile Strength Yield Point Elongation Reduction Hardness in. psi psi % 2 in. of Area, % H B
Annealed (Heated to 1 500 F, furnace-cooled 20 F per hour to 1 230 F, cooled in air.) 1
95,000
60,500
25.7
56.9
197
Normalized (Heated to 1600 F, cooled in air.)
½
148,500
1 2
148,000 140,750
4
117,500
98,500 95,000 91,750
17.8
17.7 1 6.5
69,500
48.2
46.8 48.1
22.2
302
302 285
57.4
241
Oil-quenched from 1550 F, tempered at 1000 F.
½ 1 2 4
171,500 156,000 139,750 127,750
161,000 15.4 55.7 341 143,250 1 5.5 56.9 311 115,750 17.5 59.8 285 99,250 19.2 60.4 277
Oil-quenched from 1550 F, tempered at 1100 F.
½ 1 2 4
1 57,500 148,750 18.1 59.4 321 140,250 135,000 19.5 62.3 285 127,500 102,750 21.7 65.0 262 116,750
87,000
21..5
62.1
235
Oil-quenched from 1 550 F, tempered at 1200 F.
½ 1 2 4
136,500 1 32,750 121,500 112,500
128,750 19.9 62.3 277 1 22,500 21.0 65.0 269 98,250 23.2 65.8 241 83,500 23.2 64.9 229
As-quenched Hardness (oil) Size Round" Surface
½
1 2 4
148
HRC57
HRC55 HRC 49 HRC 36
½ Radius
HRC56
HRC55
Center
HRC55
HRC50
HRC 43 HRC 34.5
HRC 38 HRC 34
Oil-quenched 4140
SINGLE HEAT RESULTS C Mn P Ladle
S
Si Ni Cr Mo Grain
Size
.41 .85 .024 .031 .20 .12 1.01 .24 6-8
Critical Points, F' Ac; 1395 Ac3 1450 Ar3 1330 Arl 1280 Treatment" Normalized at 1600 F" reheated to 1550 F" quenched in agitated oil. .530-in. Round Treated" .505-in. Round Tested.
As-quenched HB 601.
psi
\ \
250,000
\
200,000
..a
%
o o
-o
d
\
\
(33
150,000 -I-:
i
o6
\ 70% 60% 50%
100,000
40% 30% ..... ElOngation
"-
20% 10%
':=.mper, F 400
H B 578
500 534
600 495
700 461
800 429
900 1000 1100 1200 1300 388 341 311 277 235
149
4340 Oil-quenched SINGLE HEAT RESULTS c
Mn
P
S
Si
Ni
Cr
Mo Grain
Grade .38/.43 .60/.80 m -- .20/.35 1.65/2.00 .70/.90 .20/.30 Size Ladle .40
.68 .020 .013 .28
1.87
.74
.25
7-8
MAS S EFFECT Size Round Tensile Strength Yield Point Elongation Reduction Hardness in. psi psi % 2 in. of Area, % H B
Annealed (Heated to 1490 F, furnace-cooled 20 F per hour to 670 F, cooled in air.)
1
108,000
68,500
22.0
49.9
217
12.1 12.2 13.5 13.2
35.3 36.3 37.3 36.0
388 363 341 321
13.7 14.2 16.0 15.5
45.0 45.9 54.8 53.4
363 352 341 331
Normalized (Heated to 1600 F, cooled in air.)
½ 1 2 4
209,500 185,500 176,750 161,000
141,000 125,000 114,500 103,000
Oil-quenched from 1475, tempered at 1000 F.
½ 1 2 4
182,000 175,000 170,000 164,750
169,000 166,000 1 59,500 145,250
Oil-quenched from 1475 F, tempered at 1100 F.
½ 1 2 4
165,750 164,750 147,250 133,750
162,000 17.1 57.0 331 159,000 16.5 54.1 331 139,250 19.0 60.4 293 114,500 19.7 60.7 269
Oil-quenched from 1475 F, tempered at 1200 F.
½ 1 2 4
145,000 139,000 134,750 124,000
135,500 128,000 121,000 105,750
20.0 20.0 20.5 21.7
59.3 59.7 62.5 63.0
As-quenched Hardness (oil) Size Round Surface
½ 1 2 4
150
HRC 58 HRC 57 HRC 56 HRC 53
½ Radius
HRC 58 HRC 57 HRC 55 HRC 49
Center
HRC 56 HRC 56 HRC 54 HRC 47
285 277 269 255
SINGLE HEAT RESULTS C Mn P
S
Oil-quenched 4340
Si Ni Cr Mo Grain
Size
Ladle .41 .67 .023 .018 .26 1.77 .78 .26 6-8 Critical Points, F: Ac
1350 Ac3 1415 Ars 890 Arl 720
Treatment: Normalized at 1600 F; reheated to 1475 F; quenched in agitated oil. .530-in. Round Treated ; .505-in. Round Tested.
As-quenched H B 601.
psi
\ 250,000
\
\
\ \
200,000
\
%
150,000
7O%
60% 5O%
100,000
4O% 3O% Elongation
.,mper, F 400 500 600 700 800 900 1000 1100 1200 1300
HB 555 514 477 461 415 388 363 321 293
20% - 10%
151
5140 Oil-quenched SINGLE HEAT RESULTS C
Mn
Grade .38/.43 .70/.90 --
Ladle .43
.78
P
S
Si
Ni
Cr
Mo Grain Size
m .20/.35 m .70/.90
.020 .033
.22
.06
.74
.01
6-8
MASS EFFECT Size Round Tensile Strength Yield Point Elongation Reduction Hardness in. psi psi % 2 in. of Area, % H B
Annealed (Heated to 1 525 F, furnace-cooled 20 F per hour to 1200 F, cooled in air.)
1
83,000
42,500
28.6
57.3
167
22.0 22.7 21.8 21.6
62.3 235 59.2 229 55.8 223 52.3 217
Normalized (Heated to 1600 F, cooled in air.)
½ 1 2 4
120,000 11 5,000 113,000 111,400
75,500 68,500 65,500 60,375
Oil-quenched from 1550 F, tempered at 1000 F.
½ 1 2 4
146,750 141,000 128,000 125,000
131,500 17.8 57.1 302 121,500 18.5 58.9 293 100,500 19.7 59.1 255 81,500 20.2 55.4 248
Oil-quenched from 1550 F, tempered at 1100 F.
½ 1 2 4
130,500 127,250 118,000 115,500
113,000 105,000 89,000 73,500
20.2 20.5 22.0 22.1
61.4 61.7 63.2 59.0
269 262 241 235
Oil-quenched from 1550 F, tempered at 1200 F.
½ 1 2 4
120,000 117,000 109,500 106,000
102,000 22.2 63.4 241 94,500 22.5 63.5 235 81,500 24.5 67.1 223 68,000 24.6 63.1 217
As-quenched Hardness (oil) Size Round Surface
½ 1 2 4
152
HRC 57 HRC 53 HRC 46 HRC 35
½ Radius
HRC 57 HRC 48 HRC 38 HRC 29
Center
HRC 56 HRC 45 HRC 35 HRC 20
Oil-quenched 5140 SINGLE HEAT RESULTS C Mn P
S
Si Ni Cr Mo Grain
Size
Ladle .43 .78 .020 .033 .22 .06 .74 .01 6-8 Critical Points, F: Ac
1370 Ac3 1440 Ar3 1320 Ar
1260
Treatment: Normalized at 1600 F; reheated to 1550 F; quenched in agitated oil. .530-in. Round Treated; .505-in. Round Tested.
As-quenched HB 601.
psi
250,000 .......
\
\ 200,000
\\
150,000 ...............
\
7O%
\ 100,000
60% 50% \ 40% 30%
Elongation ........
'
20% 10%
temper, F 400 500 600 700 800 900
HB 534 514 461 429 375 331
1000 1100 1200 1300 302 269 241 207
153
8740 Oil-quenched SINGLE HEAT RESULTS C
Mn
P
S
Si
Ni
Cr
Mo Grain
Grade .38/.43 .75/1.00 -- -- .20/.35 .40/.70 .40/.60 .20/.30 Size Ladle .41
.90
.016 .010 .25
.63
.53
.29
7-8
MASS EFFECT Size Round Tensile Strength Yield Point Elongation Reduction Hardness in.
psi
psi
% 2 in. of Area, %
HB
Annealed (Heated to 1500 F, furnace-cooled 20 F per hour to 11 O0 F, cooled in air.) 1
"L00,750
60,250
22.2
46.4
201
Normalized (Heated to 1600 F, cooled in air.)
½ 1 2 4
135,500 134,750 132,000 132,000
89,500 88,000 87,500 87,000
16.0 16.0 16.7 15.5
47.1 47.9 50.1 46.1
269 269 262 255
13.5 16.0 15.7 18.0
47.4 53.0 52.8 55.6
352 352 331 277
17.4 18.2 18.5 20.5
55.1 59.9 62.0 59.8
311 302 277 248
Oil-quenched from 1525 F, tempered at 1000 F.
½ 1 2 4
179,000 178,500 170,750 138,750
165,000 164,250 153,500 108,500
Oil-quenched from 1525 F, tempered at 1100 F.
½ 1 2 4
153,500 149,250 142,500 123,750
139,500 134,500 122,500 96,750
Oil-quenched from 1525 F, tempered at 1200 F.
½ 1 2 4
140,000 138,000 127,250 115,500
127,250 19.9 60.7 285 123,000 20.0 60.7 285 105,750 21.5 65.4 255 88,250 22.7 62.9 229
As-quenched Hardness (oil) Size Round Surface
½ 1 2 4
1 54
HRC 57 HRC 56 HRC 52 HRC 42
½ Radius
HRC 56 HRC 55 HRC 49 HRC 37
Center
HRC 55 HRC 54 HRC 45 HRC 36
Oil-quenched 8740
SINGLE HEAT RESULTS C Mn
P
S
Si Ni Cr Mo Grain
Size
Ladle .39 1.00 .012 .017 .25 .53 .52 .28 6-8
Critical Points, F: Acl 1370 Ac3 1435 Ar3 1265 Arl 1160 Treatment: Normalized at 1600 F; reheated to 1525 F; quenched in agitated oil. .565-in. Round Treated; .505-in. Round Tested.
psi
As-quenched HB 601.
\
\
250,000
\
X ......
\\
\,\
200,000
150,000
70% 60% 50% 100,000
40% 30% Elongation
-/ 20% 10%
emper, F 400 500 600 700 800 900
HB 578 534 495 461 415 388
1000 1100 1200 1300 363 331 302 241
155
4150 Oil-quenched SINGLE HEAT RESULTS C
Mn
P
S
Si
Grade .48/.53 .75/I.00 Ladle .51
.89
Ni
Cr
.20/.35
.018 .017
.27
Mo
.80/1.10 .15/.25 Size .87
.12
.18 95% 7-8
MASS EFFECT Size Round Tensile Strength Yield Point Elongation Reduction Hardness in. psi psi % 2 in. of Area, % H B
Annealed (Heated to 1525 F, furnace-cooled 20 F per hour to 1190 F, cooled in air.)
1
105,750
55,000
20.2
40.2
197
Normalized (Heated to 1600 F, cooled in air.)
½ 1 2 4
194,000 167,500 158,750 146,000
129,500 10.0 24.8 375 106,500 11.7 30.8 321 104,000 13.5 40.6 311 91,750 19.5 56.5 293
Oil-quenched from 1525 F, tempered at 1000 F.
½ 1 2 4
189,500 175,250 168,750 158,750
176,250 159,500 151,000 127,750
13.5 14.0 15.5 15.0
47.2 46.5 51.0 46.7
375 352 341 311
14.6 15.7 18.7 20.0
45.5 51.1 56.4 57.5
341 331 302 269
Oil-quenched from 1 525 F, tempered at 1100 F.
½ 1 2 4
170,000 165,500 150,250 132,500
155,500 150,000 131,500 98,250
Oil-quenched from 1525 F, tempered at 1200 F.
½ 1 2 4
148,000 141,000 134,750 124,000
137,250 17.4 53.3 302 127,500 18.7 55.7 285 118,250 20.5 60.0 269 91,000 21.5 61.4 255
As-quenched Hardness (oil) Size Round Surface ½ 1
2 4
156
HRC 64 HRC 62
HRC 58
HRC 47
½ Radius HRC 64 HRC 62
HRC 57
HRC 43
Center HRC 63 HRC 62
HRC 56
HRC 42
Grain
5% 5
SINGLE HEAT RESULTS C Mn P
S
Oil-quenched 4150
Si Ni Cr Mo Grain
Size
Ladle .50 .76 .015 .012 .21 .20 .95 .21 90% 7-8
Critical Points, F: Acl 1390 Ac3 1450 Ar3 1290 Arl 1245 Treatment: Normalized at 1600 F; reheated to 1525 F; quenched in agitated oil. .530-in. Round Treated; .505-in. Round Tested.
psi
\
250,000
As-quenched H B 656.
\
\
200,000
-.(:3 --,--
0
.0
LO
150,000
0
-t'
.LO
-.0
..=_
¢'q
03 .00
03
¢
4
¢5 u
70% 60%
100,000 '
50% Reduction of
..
,
40% 30%
!
Elongation
50,000 ,
20% 10%
!
remper, F 400
H B 578
500 555
600 534
700 800 900
495 444 429
1000 1100 1200 1300 401 363 331 262
157
515 0 Oil-quenched SINGLE HEAT RESULTS C
Mn
Grade .48/.53 .70/.90 --
Ladle .49
.75
P
S
Si
Ni
Cr
Mo Grain
-- .20/.35 -- .70/.90 -- Size
.018 .018
.25
.11
.80
.05 7-8
MASS EFFECT Size Round Tensile Strength Yield Point Elongation Reduction Hardness in.
psi
psi
% 2 in. of Area, %
HB
Annealed (Heated to 1520 F, furnace-cooled 20 F per hour to 1190 F, cooled in air.)
1
98,000
51,750
22.0
43.7
197
21.0 20.7 20.0 18.2
60.6 58.7 53.3 48.2
262 255 248 241
16.4 17.0 18.5 20.0
52.9 54.1 55.5 57.5
311 302 255 248
Normalized (Heated to 1600 F, cooled in air.)
½ 1 2 4
131,000 126,250 123,000 122,000
81,500 76,750 72,500 63,000
Oil-quenched from 1525 F, tempered at 1000 F.
½ 1 2 4
158,750 153,000 132,000 125,000
145,250 131,750 96,750 85,750
Oil-quenched from 1525 F, tempered at 1100 F.
½ 1 2 4
144,000 137,000 126,750 120,000
131,000 19.2 55.2 285 115,250 20.2 59.5 277 87,250 20.0 58.8 255 80,500 19.7 56.4 241
Oil-quenched from 1525 F, tempered at 1200 F.
½ 1 2 4
135,500 128,000 118,750 115,000
121,000 108,000 88,500 75,500
21.7 21.2 22.7 21.5
59.7 61.9 63.0 60.8
269 255 241 235
As-quenched Hardness (oil) Size Round Surface
½ 1 2 4
158
HRC 60 HRC 59 HRC 55 HRC 37
½ Radius
HRC 60 HRC 52 HRC 44 HRC 31
Center
HRC 59 HRC 50 HRC 40 HRC 29
Oil-quenched 5150 SINGLE HEAT RESULTS C Mn P
S
Si Ni Cr Mo Grain ......... Size
Ladle .49 .75 .018 .018 .25 .11 .80 .05 7-8
1310 Ar
Critical Points, F: Acl 1345 Ac3 1445 Ar
1240
Treatment: Normalized at 1600 F; reheated to 1525 F; quenched in oil. psi
.530-in. Round Treated; .505-in. Round Tested. As-quenched HB 653.
300,000 ,
\
\
\
250,000
"\ \
\
-.t3 ..=.
200,000
O
ei
%
e e
\ \\
ffl e
150,000
-
\\.
70%
\
• o
6o
-
/x e
,
\
\
100,000 '
| .....
--'
o
40% ' 3O%
20% 1 O%
Temper, F 400 500 600 700 800 900 1000
HB 601 555 514 461 415 363 321
1100 1200 1300
293 269 241
159
6150 Oil-quenched SINGLE HEAT RESULTS C
Mn
P
S
Si
Grade .48/.53 .70/.90 Ladle .51
Ni
.20/.35
.80 .014 .015 .35 .11
.95
.01
--
Cr
Mo
V .15min
.80/1.10
.18
Grain Size 70% 5-6 30% 2-4
MASS EFFECT Size Round Tensile Strength Yield Point Elongation Reduction Hardness in. psi psi % 2 in. of Area, % H B
Annealed (Heated to 1500 F, furnace-cooled 20 F per hour to 1240 F, cooled in air.) 1
96,750
59,750
23.0
48.4
Normalized (Heated to 1600 F, cooled in air.)
½ 1 2 4
141,250 136,250 129,750 128,000
93,000 89,250 75,250 67,000
20.6
21.8 20.7 18.2
63.0
61.0 56.5 49.6
285
269 262 255
Oil-quenched from 1 550 F, tempered at 1000 F. ½ 1
179,500 173,500
2 4
1 66,000 1 51,500
177,750 1 67,750
14.6 14.5
145,250 127,000
49.4 48.2
14.5 1 6.0
363 352
46.7 48.7
331 302
Oil-quenched from 1 550 F, tempered at 1100 F.
½ 1 2 4
160,000 1 58,500 1 6.4 52.3 321 1 58,250 1 50,500 1 6.0 53.2 311 148,250 1 31,750 17.7 55.2 293 130,000 108,500 19.0 55.4 262
Oil-quenched from 1 550 F, tempered at 1200 F.
½ 1 2 4
147,000 141,250 133,750 121,500
141,500
17.8
53.9
293
1 29,500 1 8.7 56.3 293 11 6,500 1 9.5 57.4 269 94,500 21.0 59.7 241
As-quenched Hardness (oil) Size Round Surface
½ 1
2
4
160
HRC 61 HRC 60
HRC 54
HRC 42
½ Radius
Center
HRC 60 HRC 58
HRC 60 HRC 57
HRC 36
HRC 35
HRC 47
HRC 44
197
Oil-quenched 6150
SINGLE HEAT RESULTS C Mn P Ladle
S Si Ni Cr Mo V Grain
Size
.49 .78 .012 .016 .29 .18 1.00 .05 .17 6-8
Critical Points, F : Acl 1395 Ac3 1445 Ar3 1315 Ar, 1290 Treatment" Normalized at 1600 F" reheated to 1550 F" quenched in agitated oil. .565-in. Round Treated" .505-in. Round Tested.
\ \ \ \
psi
250,000
As-quenched H B 627.
\
\ 200,000
n
O o
150,000 ,
O
.o
",,,\
.u
\\, \,\ \\
k
100,000
oo
60% 50%
40% 30% i
Elongation 50,000 Temper, F 400
HB 601
500 600 700 578 534 495
800 444
900 401
20% 10%
1000 1100 1200 1300 375 341 293 241
161
8650 Oil-quenched SINGLE HEAT RESULTS c
Mn
P
S
Si
Ni
Cr
Mo Grain
Grade .48/.53 .75/1.00 m -- .20/.35 .40/.70 .40/.60 .15/.25 Size Ladle .48
.86
.020 .016 .31
.58
.53
.24
6-8
MASS EFFECT Size Round Tensile Strength Yield Point Elongation Reduction Hardness in.
psi
psi
% 2 in. of Area, %
HB
Annealed (Heated to 1465 F, furnace-cooled 20 F per hour to 860 F, cooled in air.)
1
103,750
56,000
22.5
46.4
212
Normalized (Heated to 1600 F, cooled in air.)
½
182,000
1
148,500
2 4
144,250 139,250
131,250 99,750
10.3
14.0
95,750 93,250
25.3
40.4
363
302
15.5 1 5.0
44.8 40.5
293 285
14.6 14.5 17.0 18.7
48.2 49.1 55.6 54.9
363 352 331 285
Oil-quenched from 1475 F, tempered at 1000 F.
½ 1 2 4
177,500 172,500 165,250 143,250
168,750 159,750 148,500 113,000
Oil-quenched from 1475 F, tempered at 1100 F.
½ 1 2 4
154,500 153,500 145,000 126,250
151,000 17.8 54.9 321 142,750 17.7 57.3 311 131,000 20.0 61.0 293 98,500 22.0 61.2 255
Oil-quenched from 1475 F, tempered at 1200 F.
½ 1
2 4
148,000 141,000
137,000 132,000
135,250 121,750
121,000 94,000
18.5
19.5
54.8
59.8
21.2
22.5
62.3
59.8
293
285
277
241
As-quenched Hardness (oil) Size Round Surface
½ 1 2 4
162
HRC61 HRC 58 HRC53 HRC 42
½ Radius
HRC61 HRC 58 HRC53 HRC 39
Center
HRC61 HRC 57 HRC52 HRC 38
SINGLE HEAT RESULTS C Mn P
S
Oil-quenched 8650
Si Ni Cr Mo Grain
Size
Ladle .51 .80 .018 .019 .24 .53 .52 .25 6-8
Critical Points, F: Acl 1325 Ac3 1390 Ar3 1230 Arl 910 Treatment: Normalized at 1600 F; reheated to 1475 F; quenched in agitated oil. .530-in. Round Treated ; .505-in. Round Tested.
\
psi L
As-quenched H B 638.
\
\ \
250,000
\\
\,\
200,000 "
o/'%
\
\
\ \
-p,.
"¢'4
\\,
u
150,000 -M
\ .
70% 60%
100,000
50%
._
Reduction of-
40% ,,, 3O%
--
| '--" --'
,
Elongatton ''-"-
L "
20% 10%
50,000 --'----'
mper, F 400 500 600 700 800 900 1000 1100 1200 1300
HB 555 555 514 495 429 415 363 321 302 255
163
9255 Oil-quenched SINGLE HEAT RESULTS c
Mn
Grade .51/.59 .70/.95
Ladle .52
.75
--
P --
S
Si
1.80/2.20 --
.024 .016
--
2.20
--
Ni Cr Mo Grain
Size
.07 .12 .01
6-8
MASS EFFECT Size Round Tensile Strength Yield Point Elongation Reduction Hardness in. psi psi % 2 in. of Area, % H B
Annealed (Heated to 1 550 F, furnace-cooled 20 F per hour to 1 220 F, cooled in air.) 1
112,750
70,500
21.7
41.1
229
Normalized (Heated to 1650 F, cooled in air.) ½ 1
137,500 135,250
2 4
135,000 133,000
85,250 84,000
20.0 19.7
82,000 79,500
45.5 43.4
277 269
19.5 18.7
39.5 36.1
269 269
14.9 16.7 18.0 19.2
40.0 38.3 45.6 43.7
331 321 302 293
Oil-quenched from 1625 F, tempered at 1000 F.
½ 1 2 4
170,000 164,250 154,750 149,000
146,500 133,750 102,500 94,000
Oil-quenched from 1625 F, tempered at 1100 F.
½ 1 2 4
155,000 150,000 145,500 137,000
132,250 118,000 91,750 83,000
18.1 19.2
20.0 21.0
45.3 302 44.8 293
48.7 46.0
293 277
Oil-quenched from 1625 F, tempered at 1200 F. ½
144,750
1
138,000
2 4
137,500 132,250
123,000
21.0
106,500 87,250 81,750
50.4
21.2
21.0 21.7
285
48.2
50.7 48.3
277 262
As-quenched Hardness (oil) ½ Radius
Size Round Surface
½ 1
2 4
164
HRC61
HRC57
HRC59
HRC55
HRC 52 HRC 35.5
Center
HRC 58
HRC48
HRC 37 HRC 31.5
HRC 33 HRC 27.5
277
Oil-quenched 9255 SINGLE HEAT RESULTS C Mn P
S
Si Ni Cr Mo Grain
Size
Ladle .58 .78 .020 .024 2.00 .08 .08 -- 6-8
Critical Points, F : Ac
1270
1410 Ac3 1480 Ar3 1330 Ar
Treatment: Normalized at 1650 F; reheated to 1625 F; quenched in agitated oil.
psi
1-in. Round Treated ; .505-in. Round Tested.
As-quenched H B 653.
300,000
\\
\\ \ \ \ \
250,000
\\,
200,000 k
'\ \
\\ \ \ \
150,000
70% 60%
'
" -'
I ,
1 00,000
ey"f
50%
\
40% 30% 20% 10% 165
Temper, F 400
HB 601
500 601
600 578
700 534
8OO
900
1000 1100 1200 1300
477
415
352
321
285
262
5160 Oil-quenched SINGLE HEAT RESULTS C
Mn
Grade .56/.64 .75/1.00
Ladle .62
.84
m
P
S
Si
-- .20/.30 m .70/.90 --
.010 .034
.24
.04
Ni
Cr
Mo Grain
Size
.74
.01
6-8
MASS EFFECT Size Round Tensile Strength Yield Strength Elongation Reduction Hardness in. psi (.2% Offset)psi % 2 in. of Area, % H B
Annealed (Heated to 1495 F, furnace-cooled 20 F per hour to 900 F, cooled in air.) 1
104,750
40,000
17.2
30.6
1 97
18.2 1 7.5 16.0 14.8
50.7 44.8 39.0 34.2
285 269 262 255
Normalized (Heated to 1575 F, cooled in air.) ½ 1 2 4
149,000 138,750 1 33,750 1 33,500
93,750 77,000 73,500 70,250
Oil-quenched from 1 525 F, tempered at 1000 F.
½ 1 2 4
170,500 1 65,500 1 54,250 140,500
1 55,250 14.2 45.1 341 145,500 14.5 45.7 341 102,250 17.8 51.2 293 101,750 18.5 52.0 285
Oil-quenched from 1 525 F, tempered at 1100 F.
½ 1
1 52,250 134,000 16.6 50.6 302 145,250 126,000 18.0 53.6 302
2
135,250
4
129,250
91,750
20.0
89,250
54.6
21.2
277
57.0
262
Oil-quenched from 1525 F, tempered at 1200 F.
½ 1
2 4
133,000 1 28,750
11 5,250 110,750
113,250 1 20,500
84,000 77,750
1 9.8
20.7
21.8 22.8
55.5
55.6
57.5
60.8
269
262
248
241
As-quenched Hardness (oil) Size Round Surface
½ 1
2
4
166
HRC 63 HRC 62
HRC 53
HRC 40
½ Radius
Center
HRC 62 HRC 61
HRC 62 HRC 60
HRC 32
HRC 29
HRC 46
HRC 43
Oil-quenched 5160 SINGLE HEAT RESULTS C Mn P
S
Si Ni Cr Mo Grain
Size
Ladle .62 .84 .010 .034 .24 .04 .74 .01 6-8
Critical Points, F: Acl 1380 Ac3 1420 Ar3 1310 Arl 1280 Treatment: Normalized at 1575 F; reheated to 1525 F; quenched in oil. .530-in. Round Treated ; .505-in. Round Tested.
As-quenched H B 682.
psi
300,000
\
\ \
250,000
\\
200,000 )
70% '
e
150,000
- 60% 50%
30% 20%
I
-.----
Temper, F 400
H B 627
500 601
600 555
10%
700 800 900 1000 1100 1200 1300 514 461 388 341 302 269 229
167
MACHINABILITY
OF STEEL
Among the many practical methods of shaping steel, machining is perhaps the most widely employed, both alone and in conjunction with such other methods as forging, extrusion, and cold-heading. The term, machinability, is most often used to describe the performance of metals in machining. By its simplest definition, it is the ability to be cut by an appropriate tool; but notwithstanding the simplicity, there appear to be no fundamental units by which this ability can be measured. Machining performance is therefore gen erally expressed in relative terms which compare the response of one material to that of a standard in a similar machining operation and employing similar performance criteria.
Machinability Testing Over a period of many years, Bethlehem has conducted almost continuous machinability studies involving hundreds of tests run on multiple-spindle automatic bar machines of the types commonly used in industry. This approach has clearly shown that the machining performances of different steels can be truly compared only when the production conditions for each steel satisfy two basic similarity requirements: 1) The level of product quality with respect to surface finish and dimensions must be similar among the steels being evaluated; 2) The duration of average tool life must also be similar to that of the other steels being evaluated. Six to eight hours of actual running time is the preferable duration. Under these conditions, machinability can be rated by compar ing either the maximum production rates achieved with each steel, or the cutting speeds used to attain these rates. Historically, the cut ting-speed method of rating has been more commonly employed; yet, this method does not include the equally important effect of tool feed rate on production. As a consequence, it can overlook the con
tributions of some elements, notably nitrogen and phosphorus, which augment production by permitting the use of higher feed rates. This 1A more detailed discussion of this subject is contained in the Bethlehem Steel booklet,"Machinability of Steel." available on request.
168
problem is avoided when machinability comparisons are based on maximum production rates consistent with the basic similarity re quirements, inasmuch as this method automatically considers both cutting speed and tool feed rate. Free-cutting steels, comprising the 1200 and 1100 series, find their greatest application in the manufacture of parts requiring ex tensive machining into shapes of varying complexity on automatic bar machines. Within the composition ranges of the 1200 series, the elements which most affect machining performance are sulfur, phos phorus, nitrogen, lead, and selenium; in the 1100 series, sulfur and carbon are major variables, with manganese exerting a secondary but significant influence.
Sulfur Increasing sulfur improves machining performance at all carbon levels in both alloy and plain carbon grades. Small increases in sulfur up to .05/.06% markedly improve the machinability of a nonresul furized base. For increases above this level, machinability improves at a lower rate. In the case of the 1200 and 1100 series steels, the rate of improvement caused by increasing sulfur is somewhat higher in steels with the lower carbon contents.
Phosphorus and Nitrogen One of the distinguishing features of the very free-cutting grades is their ability to be machined at higher production rates while main taining the desired finish on the product. But even in these grades, the quality of the machined surface varies with composition. Phosphorus and nitrogen can be added to free-machining grades of steel to en hance machining performance. Both increase hardness and tensile strength, particularly in the cold-drawn condition. Actual tests as
described above have established that the machinability of the 1200 series steels, as measured by relative production rates for equal part quality and tool life, is markedly improved by increasing phosphorus content to within the range of .07/.12%. Further improvement is realized when nitrogen content is increased to a level of about .010%. The ability to use higher speeds and feeds with increasing phosphorus and nitrogen contents (within the stated limits) is re
169
lated to the decreased size and more controllable behavior of the built-up-edge on the cutting tools. This control of the built-up-edge results in an improvement of surface finish.
L e a d A dditio n s The machining performance of steel is considerably improved
by the addition of lead (see page 23 ) in the usual specification range of .15/.35 %. Lead lubricates the cutting edge of the tool and per mits an increase in cutting speed and feed and an improvement in surface finish quality without an attendant decrease in tool life. As a result, lead additions can be expected to improve production rates in screw-machine operations in particular by some 20 to 40 per cent.
170
EFFECT OF CARBON AND MANGANESE ON MACHINABILITY
Machinability Rating, Per Cent (B1112=100% at 170 fpm)
V 100
As-Rolled, Cold-Drawn
.-- (Resulfurized to .08/.13% S) 8O
,,o9,
;
:'
,o8,,,
!110
0
, ,,,
I
I Cold-,Fawn
/° I01 'i°j°
,oo8
2 o\ -, °\ -
,o
',o4
i
Loeo
,oo
As-Rolled, Cold-Drawn 4O
oe5 ,oe
I
I
'"
• .30/.60% Mn
o.".- .60/.90% Mn (except 1095) ,, Spheroidized 20
,,,
.20
.4O
.60
.80
1.00
CARBON, PER CENT
Carbon and Manganese Plain carbon steels with very low carbon contents tend to be tough and gummy in machining operations. Increases in carbon and manganese increase the strength and hardness of steel and result in improved surface finish and chip character. For carbon contents up to .20/.25%, this results in improved machinability for both hot rolled and cold-drawn steels. As the carbon is increased above this level, however, hardness increases to the point where tool life is adversely affected, leading to a decrease in the machinability rating.
The graph above illustrates this effect by plotting machin ability ratings for a series of grades with increasing carbon contents at two manganese levels. Note also how the machinability ratings of 1040, 1045, and 1050 were significantly improved by annealing.
171
Most carbon steels below .35 % carbon are machined in the as-rolled or as-rolled, cold-drawn condition. Higher carbon grades are fre
quently annealed to improve machinability, particularly when they are to be cold-drawn prior to machining.
Alloy Steels The commonly used alloying elements increase the as-rolled strength and hardness in comparison with a plain carbon steel of equivalent carbon content. The intensity of this effect on hardness differs for the various elements; but in all cases, hardness increases with increasing percentages of the element. In the as-rolled condition, the leaner alloys machine more like their plain carbon counterparts than do the more highly alloyed types. For example, 4023 behaves about the same as 1022 or 1026 under the cutting tool, whereas the
more highly alloyed 8620 has about the same machinability as the higher-carbon 1040. Accordingly, it is common practice to ther mally treat alloy bars prior to cold-drawing and machining. Normalizing is sometimes used for the lower carbon grades, but annealing is more frequently used because it results in lower hardness. Optimum microstructure varies with the per cent of pearl ite typical of the composition involved, and to a degree, with the parameters of the machining operation itself. In general, a lamellar annealed structure is preferred in the low and medium carbon ranges, or up to the carbon level of about .40/.50% which corresponds to -approximately 90% pearlite, depending on both carbon and alloy content.Above that carbon level, a spheroidized structure is usually preferred because it imp[oves tool life, although at some sacrifice of surface finish. Where machined finish is of paramount importance in these higher carbon grades, it is sometimes desirable to use a lamellar structure and accept a somewhat shorter tool life. For certain ma chining operations, a compromise structure consisting of lamellar pearlite with some spheroidized carbides may be desirable. Since alloying elements increase the percentage of pearlite in the micro structure of a given carbon level over that typical of plain carbon steels, determination of the optimum microstructure must take into consideration the carbon level and the alloy content.
172
NONDESTRUCTIVE
EXAM I N ATi O N
Nondestructive tests are effective for the inspection of the surface or internal quality of steel products, supplementing or replacing visual methods of inspection. In general, for bar and billet testing, ultra sonic methods are used for internal inspection, and magnetic particle and eddy current methods for the inspection of surface.
Ultrasonic Testing Ultrasonic testing is based upon ultra-sound, or sound which is pitched too high (above 20,000 cps) for the human ear to detect. Pulses of this sound energy are sent into a section of a material, such as a steel bar, and are reflected from the boundaries of the section as well as from internal discontinuities. The reflected pulses are received and portrayed on a cathode ray tube, and the image interpreted with respect to the strength of the returning pulse and the time lapse between its generation and reception. With proper calibration of the test equipment, the location, size, shape and orientation of discontinuities within the steel can be estimated. Two basic calibration methods are used to provide stan dards for the test against which the received signals can be compared. In one, the standard is provided by signals from a reference reflector, such as a notch or hole in a test block. In the second, the standard is derived from the signal reflected from the far side of the steel section. Some discontinuities are not good reflectors, but can be detected by their shadowing effect which results in a partial or total loss of this back reflection signal.
PULSE ECHO ULTRASONIC SYSTEM. Ultrasonic test systems are based upon the behavior of piezoelectric material which, when excited electrically, is caused to vibrate mechanically with ultra sonic energy. Conversely, an electrical voltage is generated when this material, or crystal, is vibrated. The holder containing the crystal
173
and its associated electrical components is called a transducer, or search unit, and is one of the major elements of the test system. Another essential part of the overall unit is the electronic package which functions as the control center. This instrument generates a brief power output, or pulse, that excites the crystal. It also receives and amplifies the voltage generated as a result of reflected sound vibrating the crystal. Both the exciting pulse and any echoes are displayed on a cathode ray tube. Since sound travels at a constant speed in a specific material under constant conditions, distance within a material is a function of time. Thus, distance (time) is represented on the hori
zontal axis of the tube, and signal amplitudes (exciting pulse and echoes) on the vertical axis. The magnitude of the echo will depend upon several external factors including the operating frequency,
which is usually between 1 and 10 MHz (1MHz= 1 million cycles per second), the amount of beam dispersion, the surface condition and internal metallurgical structure of the steel, the amount of hot or cold working of the steel, temperatures, and variables associated with transducer and instrument characteristics. With these variables rela
tively constant, the reflected signal amplitude will be dependent upon the following material characteristics" • the area of the reflector, which may be a discontinuity or boundary, its shape and orientation to the ultrasonic path, plus its roughness;
PU LSER
TRANSDUCER ,,,,,o,
SYNCH RONIZER
SWEEP GENERATOR
MARKER GENERATOR
;,
|lie log II ! Olllll OI e I IoO|ol II I I
;T o,
AMPLIFIER
VIDEO DISPLAY
REFLECTOR Pulse-echo ultrasonic system.
174
CRT
° the distance of the reflector from the search unit; • the acoustic impedance of the reflector. It should be noted that the ultrasonic vibrations are normally directed into the test piece through a suitable coupling medium such as water, glycerin, or oil to prevent the high energy losses that would occur in air transmission.
Electromagnetic Test Methods
Magnetic particle indications of quench cracks.
In a ferromagnetic material that has been magnetized, the
normal lines of magnetic force are distrupted by discontinuities within the otherwise homogenous microstructure of the material, thus causing localized force gradients. Fine magnetic particles are attracted to these field gradients; and so provide a measure of the geometry and extent of the discontinuity. Many variations of magnetic particle testing are employed in
practice depending upon the type of anticipated discontinuity and its location. Results are affected by the type of current used (a.c. or d.c.) and its magnitude and duration, the direction of magnetization, and the wet or.dry condition of the indicating particles. For bars and billets, circular magnetization is most frequently used to facilitate the detection of longitudinal discontinuities such as laps or seams. This type of field is created when the current is passed
longitudinally through the material itself. Discontinuities at right
175
angles to the bar length would need to be detected by longitudinal magnetization produced by passing current through a coil encircling the material being tested. This testing method is useful in detecting primary discontinu ities, such as non-metallic inclusions and porosity, as well as fab ricating discontinuities, such as laps, bursts, cracks and seams.
EDDY CURRENT TESTING. Eddy current testing is a non-contact means of testing bars, rods or tubes for surface flaws at production speeds. It is based upon the interaction between alter nating current flow in metallic materials and the reactive magnetic fields thus produced, and on the detection of variations in these fields as caused by structural discontinuities in the material under test. There are two basic variations of the eddy current test. In one, the material being tested is passed lengthwise through an electrical coil assembly consisting of an inducing coil positioned between two sensing coils that respectively produce an eddy current flow in the steel and detect variations in the induced reactive fields. This test mode provides detection capability oriented essentially for discon tinuities at right angles to the long axis of the bar. In the other method, a small pair of coils, an inductor and a sensor, is rotated circum ferentially about the bar. With the fields thus generated, discon tinuities which are oriented parallel to the bar axis can be detected. Certain variables, such as test signal frequency, probe spacing between the coils and the work, and the surface condition of the bar can have an important influence on test results. Variations attribut able to differing magnetic characteristics of the steel itself can be minimized by magnetic field saturation.
176
US EF UL DATA
Bethlehem produces tool steels in all popular sections, sizes, and types.
177
TOOL STEELS Identification and Type Classification The percentages of the elements shown for each type are only for identification purposes and are not to be considered as the means of the composition ranges of the elements. I
AISI Type
I
Bethlehem
Identifying Elements, per cent
i
GradeNamel C I MR I Si I W I Mo i Crl
Other
WATER-HARDENING TOOL STEELS Wl
X, XCL, XX .60/1.40 * ..... Best, Superior .60/1.40" ......25V
W2 W5
--
1.10 .... .50
• Other carbon contents may be available.
COLD-WORK TOOL STEELS Oil-Hardening Types 01
BTR
02
--
.90
06 07
O-6 1.45 .80 1.00 -67 Tap 1.20 -- -- 1.75
A2
A-H5
.90
1.00
--
.50
--
.50
1.60 ....
.25 -- .75
Medium Alloy Air-Hardening Types A3
A4 A6
A7 A8 A9
--
1.00 1.25
Air-4 --
.70
---
---
---
1.00
2.00
2.00
--
1.00
5.00
1.00
5.00
--
--
--
1.25
1.00V 1.00
1.00
A-7 2.25 --- 1.00 Cromo-W55 .55 --- 1.25 --
.50
A10
--
--
A-HT
--
1.35
--
--
1.40
1.00
1.00 1.25
5.00
1.25
--
1.50
-
--
--
1.05
1.1 0
3.00
4.75V 1.00V 1.50Ni 1.80Ni
5.00
1.80
1.00
5.25
I .25V
1.00Ti
Optional High Carbon--High Chromium Types D2 D3
Lehigh H Lehigh S
1.50 -- -- -2.25 .... 12.00
1.00 12.00
D4
--
2.25
--
--
--
1.00 12.00
D5
--
1.50
--
--
--
1.00 12.00
D7
--
2.35
--
--
--
1.00 12.00
$1 $2 $5 $6 $7
67 Chisel .50 --- 2.50 -- 1.50 Imperial .50 -- 1.00 -.50 Omega .55 .80 2.00 -.40 -.45 1.40 2.25 -.40 1.50 Bearcat .50 ---- 1.40 3.25
1.00V 3.00Co 4.00V
SHOCK-RESISTING TOOL STEELS
178
m
m
AISI Bethlehem Type Grade Name
Identifying Elements, per cent
clMnls, E w Molc, Iv
Co ...........
HOT-WORK TOOL STEELS Chromium Types H10
.40
--
Cromo-V
.35
--
H 12 Cromo-W H13 Cromo-High V H14 H19
.35
H11
--
Cromo-N
--
--
--
2.50 3.25 --
1.50
--
• 35
--
--
,40
.40
--
.26
.95
m
1.50
--
--
• 40
.40
1.50
--
--
m
5.00
1.50
5.00
5.00
--
5.00
-
4.25
--
4.25
2.00
1,00
,90
1.00
n
1.00
5,00
--
.40
11.00
m
4.25 .50
.1 ON
1.00Ni
Tungsten Types
H21 H22 H23
H24
57 HW 57 Special
H25 H26 Special HS-55
.35
--
--
9.00
.35
--
--
11.00
---
3.50 2.00
-
.30
--
--
12.00
--
12.00
-
.45
--
--
15.00
--
3.00
.25
--
--
15.00
--
4.00
-
.50
--
--
18.00
--
4.00
1.00
m
-
Molybdenum Types H43
HW8
.55
--
--
--
8.00
4.00
2.00
HIGH-SPEED TOOL STEELS Tungsten Types T1 T2 T4 T5 T6 T8 T15
T-1
.75"
--
--
18.00
--
4.00
1.00
.80
--
--
18.00
--
4.00
2.00
.75
--
--
18.00
--
4.00
1.00
.80
--
--
18.00
--
4.00
2.00
.80
--
--
20.00
--
4.50
1.50
u
.75
--
--
14.00
--
4.00
2.00
1.50
--
--
12,00
--
4.00
5,00
5.00 8.00 12.00 5.00 5.00
Molybdenum Types M1
M2 M3 M3 M4 M6 M7
MIO M30 M33 M34 M36 M41 M42 M43 M44 M46 M47
M-1 M-2
(Class 1 ) (Class 2) M-4
M-7 M-10
m
D
.85* -.85/1.00" -1.05 -1.20 -1.30 -.80 -1.00 -- --
-------
.85/1.00" --
--
--
.80 --• 90 -• 90 -.80 -1.1 0 -1.1 0 -1.20 -1.1 5 -1.25 -1.1 0 --
1.50 8.50 4.00 1.00 6.00 5.00 4.00 2.00 6.00 5.00 4.00 2.40 6.00 5.00 4.00 3.00 5.50 4.50 4.00 4.00 4.00 5.00 4.00 1.50 1.75 8.75 4.00 2.00
n
12.00
8.00 4.00 2.00
2.00 8.00 4.00 -1.50 -2.00 -6.00 -6.75 -1.50 -2.75 -5.25 -2.00 -1.50
1.25 9.50 8.00 5.00 3.75 9.50 8.00 6.25 8.25 9.50
4.00 4.00 4.00 4.25 3.75 3.75 4.25 4.00 3.75
1.1 5 2.00 2.00 2.00 1.1 5 1.60 2.00 3,20 1.25
5.O0 8.O0
8.00 8.00 5.00 8.00 8.25 12.00 8.25 5.00
*Other carbon contents may be available.
179
TOOL STEELS (Cont'd) AISI
Identifying Elements, per cent
Bethlehem
clMnls'lw MolCr 1 "' I
Type Grade Name
PLASTIC-MOLD STEELS P2
Duramold B
P3
Duramold Ni-Cr .10 .... .60
P4
Duramoid A
P5
--
P6
--
.07
--
--
Duramoid N P-20
P21
--
.20
--
--
--
--
.20 ..... 4.00 .50
2.00
.50
1.25
.75
-
-
5.00
--
-
-
.10 .... 1.50
.35
Lustre-Die
--
--
.10 .... 2.25
P20 --
.07
--
3.50
.40
-
1.70
--
-
.25
1.10
1.20AI
1.00
.30
--
--
-
SPECIAL-PURPOSE TOOL STEELS Low Alloy Types .50/
L2
Tough M
1.10 * .... 1.00
L6
Bethalloy
.70
--
--
--
.20V
.25t
75
1.50
fOptional.
• Other carbon contents may be available.
OTHER SPECIAL-PURPOSE TOOL STEELS Identifying Elements, per cent
Bethlehem
cl Mn is, IWIMo i C ICu
Name Grade
Brake Die
.51
1.00
--
Non-Tempering
.35
.70
.25
.50
--
--
--
Lehigh L 71 Alloy Bearing Standard
1.00 .55
,80
--
.20
.95
.35 1.00
.85
-
.30
12.00
-
2.00 ....
1.00 .... 1.25
NITRIDING STEELS Identifying Elements, per cent
C I Mn { Si 1 Mo l Cr 1 Ni 1 A' [ .........
Type Nitriding 135 (Type G)
.30/ .40/ .20/ .15/
.40 .70 .40 .25 1.40
--
.90/
.85/
1.20
Nitriding 135 Mod. .38/ .40/ .20/ .30/ 1.40/ (Aircraft Spec.)
Nitriding N (3.5% Ni)
.45
180
.40
.45
1.80
--
.85/
1.20
.20/ .40/ .20/ .20/ 1.00/ 3.25/
.27 .70 .40 .30 1.30 3.75 1.20
Nitriding EZ
(Type G with S)
.70
.30/ .50/ .20/ .15/ 1.00/
.40 1.10 .40 .25 1.50
--
1.20
.85/
.85/
.08/ .13
HARDNESS CONVERSION TABLE Brinell
Rockwell
Tensile Strength,
Indent. Diam., mm
2.25 2.30 2.35 2.40 2.45 2.50 2.55 2.60 2.65 2.70 2.75 2.80 2.85
No.*
745 712 682 653 627 601
578 555 534 514 495 477 461
444 429 415
3.05 3.10 3.15
401
3.35 3.40 3.45 3.5O 3.55 3.60 3.65 3.70
C
1000 psi Approx.
2.90 2.95 3.00
3.20 3.25 3.30
B
388 375 363 352 (110.0) 341 (109.0) 331 ( 08.5) 321 (108.0) 311 (107.5) 302 (107.0) 293 (106.0) 285 (105.5) 277 (104.5) 269 (104.0)
65.3 61.7 60.0 58.7 57.3 56.0 54.7 53.5 52.1
51.6 50.3 48.8 47.2 45.7 44.5 43.1 41.8 40.4
298 288 274 269 258 244 231
219 212 202
Brinell mm
3.75 3.80 3.85 3.90 3.95 4.00 4.05 4.10 4.15 4.20 4.25 4.30 4.35 4.40 4.45 4.50
4.60 170
177
4.65 167
164
35.5
159
34.3
1 54
33.1
149 146
4.70 4.80 4.90 5.00 5.10 5.20 5.30
141
138 134
28.8 27.6
262 255 248 241 235 229 223 217 212 207 201 197 192 187 183 179
4.55 174
39.1 37.9 36.6
32.1 30.9 29.9
B
Diam., No.*
193 184 171
Rockwell
Indent.
163 156 149 143 137 131 126
(103.0) (102.0) (101.0) 100.0 99.0 98.2 97.3 96.4 95.5 94.6 93.8 92.8 91.9 90.7 90.0 89.0 87.8 86.8 86.0 85.0 82.9
Tensile Strength, 1000 psi Approx.
I I
C 26.6
127
25.4 24.2 22.8
123 120 116 114
21.7 20.5
111
(18.8) (17.5) (16.0) (15.2) (13.8) (12.7) (11.5) (lO.O)
(9.0) (8.0) (6.4) (5.4) (4.4) (3.3) (0.9)
105 102 100 98 95 93 90 89 87 85 83 81
79 76
80.8
73
78.7
71
67 65 63
5.40 121
76.4 74.0 72.0 69.8
5.50 116
67.6
5.60 111
65.7
58 56
6O
130
NOTE" This is a condensation of Table 2, Report J417b, SAE 1971 Handbook. Values in ( )
are beyond normal range
and are presented for information only.
*Values above 500 are for tungsten carbide ball" below 500 for standard ball.
181
TEMPERATURE CONVERSION TABLE --459.4 to 0
0 to 1 00
1 00 to 1 000 .......
C
F
--273 --268
--262 --257 251 --246 --240
--234 --229 223 --218
C
310 300 --290 w280
273 --270 --260
--157 --1 51 --146
--459.4
m 6.7 20 68.0 21.1 70 158.0 143 290 554 371 700 1292 -- 6.1 21 69.8 21.7 71 159.8 149 300 572 377 710 1310 418 D 5.6 22 71.6 22.2 72 161.6 154 310 590 382 720 1328 --400 -- 5.0 23 73.4 22.8 73 163.4 160 320 608 388 730 1346 382 -- 4.4 24 75.2 23.3 74 165.2 166 330 626 393 740 1364
240 --230
220 210
=140 --134 --129
200
--190 180
118 --112 --107
--160
60 50
-- 29 w 23
20 10 0
40 30
..............
w364 w 3.9 25 77.0 23.9 75 167.0 171 340 644 399 750 1382 --346 -- 3.3 26 78.8 24.4 76 168.8 177 350 662 404 760 1400 328 -- 2.8 27 80.6 25.0 77 170.6 182 360 680 410 770 1418 --310 -- 2.2 28 82.4 25.6 78 172.4 188 370 698 416 780 1436 --292 -- 1.7 29 84.2 26.1 79 174.2 193 380 716 421 790 1454 274
170 --256
-- 51 46 -- 40 -- 34
17.8
-- 9.4 15 59.0 18.3 65 149.0 116 240 464 343 650 1202 -- 8.9 16 60.8 18.9 66 150.8 121 250 482 349 660 1220 m 8.3 17 62.6 19.4 67 152.6 127 260 500 354 670 1238 7.8 18 64.4 20.0 68 154.4 132 270 518 360 680 1256 -- 7.2 19 66.2 20.6 69 156.2 138 280 536 366 690 1274
D454 --436
--250
--123
F
12.2 10 50.0 15.6 60 140.0 93 200 392 316 600 1112 --11.7 11 51.8 16.1 61 141.8 99 210 410 321 610 1130 11.1 12 53.6 16.7 62 143.6 100 212 413.6 327 620 1148 m10.6 13 55.4 17.2 63 145.4 104 220 428 332 630 1166 10.0 14 57.2 17.8 64 147.2 110 230 446 338 640 1184
320
--168 --162
C
--15.0 5 41.0 12.8 55 131.0 66 150 302 288 550 1022 --14.4 6 42.8 13.3 56 132.8 71 160 320 293 560 1040 --13.9 7 44.6 13.9 57 134.6 77 170 338 299 570 1058 --13.3 8 46.4 14.4 58 136.4 82 180 356 304 580 1076 m12.8 9 48.2 15.0 59 138.2 88 190 374 310 590 1094
--330
173 169
C F
..--410 400 --390 --380 370
--196
--179
C
--17.8 o 32 10.0 50 122.0 38 1oo 212 260 500 932 m17.2 1 33.8 10.6 51 123.8 43 11o 230 266 51o 950 --16.7 2 35.6 11.1 52 125.6 49 12o 248 271 520 968 m16.1 3 37.4 11.7 53 127.4 54 130 266 277 530 986 o15.6 4 39.2 12.2 54 129.2 60 140 284 282 540 1004
--350
--190 --184
F
m459.4 45o --440 --430 ---420
--340
--201
C
.....
--360
--212 --207
F
-- 1.1
30 .6
76 58 -- 40 m 22 --
4 14 32
31
86.0
26.7
87.8
27.2
80 81
176.0
199
390
734
427
800
1472
177.8
5.0 41 105.8 32.8 5.6 42 107.6 33.3 6.1 43 109.4 33.9 6.7 44 111.2 34.4
91 195.8 92 197.6 93 199.4 94 201.2
488 493 499 504
910 1670 920 1688 930 1706 940 1724
7.2 45 113.0 35.0 7.8 46 114.8 35.6 8.3 47 116.6 36.1 8.9 48 118.4 36.7 9.4 49 120.2 37.2
95 203.0 96 204.8 97 206.6 98 208.4 99 210.2
510 516 521 527 532
95O 1742 96O 1760 97O 1778 980 1796 990 1814
37.8 100 212.0
538 1000 1832
Look up reading in middle column. If in degrees Centigrade, read Fahrenheit equivalent ir right hand column'if in Fahrenheit degrees, read Centigrade equivalent in left hand column.
182
1000 to 2000 C F"
F
C
2000 to 3000
F
CF
,,
F
C
F
......
538 543 549 554 560
1000 1010 1020 1030 1040
1832 1850 1868 1886 1904
816 821 827 832 838
1500 1510 1520 1530 1540
2732 2750 2768 2786 2804
1093 1099 1104 1110 1116
2000 2010 2020 2030 2040
566 571 577 582 588
1050 1060 1070 1080 1090
1922 1940 1958 1976 1994
843 849 854 860 866
1550 1560 1570 1580 1590
2822 2840 2858 2876 2894
1121 1127 1132 1138 1143
2050 2060 2070 2080 2090
593 599 604 610 616
1100 1110 1120 1130 1140
2012 2030 2048 2066 2084
871 877 882 888 893
1600 1610 1620 1630 1640
2912 2930 2948 2966 2984
1149 1154 1160 1166 1171
2100 3812 1427 2600 4712 2110 3830 1432 2610 4730 2120 3848 1438 2620 4748 2130 3866 1443 2630 4766 2140 3884 1449 2640 4784
621 627 632 638 643
1150 1160 1170 1180 1190
2102 2120 2138 2156 2174
899 904 910 916 921
1650 1660 1670 1680 1690
3002 3020 3038 3056 3074
1177 1182 1188 1193 1199
2150 3902 1454 2650 4802 2160 3920 1460 2660 4820 2170 3938 1466 2670 4838 2180 3956 1471 2680 4856 2190 3974 1477 2690 4874
649 654 660 666 671
1200 1210 1220 1230 1240
2192 2210 2228 2246 2264
927 932 938 943 949
1700 1710 1720 1730 1740
3092 3110 3128 3146 3164
1204 1210 1216 1221 1227
2200 2210 2220 2230 2240
3992 4010 4028 4046 4064
1482 1488 1493 1499 1504
2700 2710 2720 2730 2740
4892 4910 4928 4946 4964
677 682 688 693 699
1250 1260 1270 1280 1290
2282 2300 2318 2336 2354
954 960 966 971 977
1750 1760 1770 1780 1790
3182 3200 3218 3236 3254
1232 1238 1243 1249 1254
"2250 2260 2270 2280 2290
4082 4100 4118 4136 4154
1510 1516 1521 1527 1532
2750 2760 2770 2780 2790
4982 5000 5018 5036 5054
704 710 716 721 727
1300 1310 1320 1330 1340
2372 2390 2408 2426 2444
982 988 993 999 1004
1800 1810 1820 1830 1840
3272 3290 3308 3326 3344
1260 1266 1271 1277 1282
2300 2310 2320 2330 2340
4172 4190 4208 4226 4244
1538 1543 1549 1554 1560
2800 2810 2820 2830 2840
5072 5090 5108 5126 5144
732 738 743 749 754
1350 1360 1370 1380 1390
2462 2480 2498 2516 2534
1010 1016 1021 1027 1032
1850 1860 1870 1880 1890
3362 3380 3398 3416 3434
1288 1293 1299 1304 1310
760 766 771 777 782
1400 1410 1420 1430 1440
2552 2570 2588 2606 2624
1038 1043 1049 1054 1060
1900 1910 1920 1930 1940
3452 3470 3488 3506 3524
788 793 799 804 810
1450 1460 1470 1480 1490
2642 2660 2678 2696 2714
1066 1071 1077 1082 1088
..... I..
1093
1950 1960 1970 1980 1990
3542 3560 3578 3596 3614
2000
3632
3632 3650 3668 3686 3704 3722 3740 3758 3776 3794
1371 1377 1382 1388 1393
1399 1404 1410 1416 1421
2500 2510 2520 2530 2540
4532 4550 4568 4586 4604
2550 4622 2560 4640 2570 4658 2580 4676 2590 4694
2350 4262 1566 2850 5162 2360 4280 1571 2860 5180 2370 4298 1577 2870 5198 2380 4316 1582 2880 5216 2390 4334 1588 2890 5234
1316 2400 4352 1593 2900 5252 1321 2410 4370 1599 2910 5270 1327 2420 4388 1604 2920 5288 1332 2430 4406 1610 2930 5306 1338 2440 4424 1616 2940 5324 1343 1349 1354 1360 1366
2450 4442 1621 2950 5342 2460 4460 1627 2960 5360 2470 4478 1632 2970 5378 2480 4496 1638 2980 5396 2490 4514 1643 2990 5414 .......
1649
3000
5432
Look up reading in middle column. If in degrees Centigrade, read Fahrenheit equivalent in right hand column; if in degrees Fahrenheit, read Centigrade equivalent in left hand column.
183
INCH/MILLIMETER EQUIVALENTS Fraction //64
Decimal
Millimeters
Fraction
Decimal
.015625
0.39688 0.79375 1.19063 1.58750
3%4
.515625
1 3.09690
.53125
13.49378 13.89065 14.28753
.03125
.046875 .0625
.078125
35
.546875
4
.5625
%,
.109375
1.98438 2.38125 2.77813
%
.125
3.17501
.140625 .171875
3.57188 3.96876 4.36563
.1875
4.76251
11/ 6
.6875
.203125
'%4
.703125
23/ 2
.71875
4
.09375
9
4
.15625
%2
.625 4
.640625
2
.65625
4
.671875
4 21 43
.578125 .59375 .609375
.234375
5.15939 5.55626 5.95314
¼
.25
6.35001
¾
1%4
.265625 .28125 .296875
6.74689 7.14376 7.54064 7.93752
,,%,,
.765625
25//32
.78125
s
.796875
13//64
.21875
% 1%4
.3125
2%4
.328125 .34375 .359375
%
.375
2%4
.390625
2¼4 11/ 2
.40625 27
4
.421875 .4375
=%4
.453125 .46875
3
4
½
184
.484375 .5
8.33439 8.73127 9.12814 9.52502 9.92189 10.31877 10.71565 11.11252 11.50940 11.90627 12.30315 12.70003
4
4
4
1 9.05004
.828125 s
.859375 .875
s%4
.890625
29/32
.90625
s%4
.921875
15A6
.9375
s¼4
.953125
31/ 2
.96875
4
17.85941
.734375
.84375
1
16.27191
16.66878 17.06566 17.46253
.75
27//32
6
14.68440 15.08128 15.47816 15.87503
18.25629 18.65316
.8125
4
Millimeters
.984375 1.
19.44691
19.84379 20.24067 20.63754 21.03442 21.43129 21.82817 22.22504 22.62192 23.01880 23.41567 23.81255 24.20942 24.60630 25.00318 25.40005
[ .ETRIC EQUIVALENTS FOR WEIGHTS
IVI ETRIC EQUIVALENTS
FOR MEASURES
I ,,unce Avoirdupois (oz) = 28.3495 gm
1 inch (in.) = 2.54 cm
I pound (Ib) (16 oz) = 453.6 gm
1 square inch (in.=) = 6.4516 cm2
I ) per in. = 178.6 gm per cm
1 cubic inch (in2) = 16.3872 cm3 1 foot (ft) (12 in.) = 30.48 cm
I ) per in.= = 70.31 gm per cm=
I Ib per in2 = 27.68 gm per cm3 I ) per ft = 1.4882 kg per m I ) per ft= = 4.8824 kg per m= I Ib per ft3 = 16.0184 kg per m3
= 929.03 cm= 1 square foot (ft=) = 0.0929 m2 = 28,317 cm3 1 cubic foot (ft3) = 0.0283 m3
I et ton (NT) (2,000 Ib) = 907.19 kg
= 9t .44 cm
1 yard (yd) (3 ft) = 0.9144 m I qram (gm) = 0.0022 Ib I im per cm = 0.0056 Ib per in. I gm per cm= = 0.0142 Ib per in.2 I qm per cm3 = 0.0361 Ib per in.3
1 square yard (yd=) = 0.8361 m= 1 cubic yard (yd3) = 0.7646 m = 1,609.344 m
1 mile (5,280 ft, or 1,760 yd) = 1.6093 km
I ilogram (kg)(1,000 gm) = 2.2046 Ib i ,,g per m = 0.67197 Ib per ft i kg per m= = 0.2048 Ib per ft=
1 millimeter (mm) = 0.03937 in.
i :g per m3 - 0.0624 Ib per ft=
1 square mm (mm=) = 0.0015 in.=
t .netric ton (1,000 kg) = 1.1023 NT
1 centimeter (cm) (10 mm) = 0.3937 in. 1 square cm (cm=) = 0.1549 in.= 1 cubic cm (cm3) = 0.0610 in2 = 39.37 in.
1 meter (m) (100 cm) = 3.2808 ft = 1.0936 yd 1 square meter (m=) 1 cubic meter (m3)
= 10.7639 ft= = 1.196 yd2 = 35.314 ft = 1.3079 yds = 3,280.83 ft
1 kilometer (km) (1,000 m) = 1,093.61 yd = 0.6214 mile
185
WEIGHTS AND AREAS OF SQUARE AND ROUND STEEL BARS Weight, Ib per ft
Size or
Diam
.013 .021 .030 .041
6
.094 .110 .128 .147
.212 .240 .269 .300
.167 .188 .211 .235
.332 .366 .402 .439
.261 .288 .316 .345
.478 .519 .561 .605
.376 .407 .441 .475
.651 .698 .747 .798
.511 .548 .587 .627
.850 .904 .960 1.017
.668 .710 .754 .799
1.076 1.136
.845 .893 .941 .992
4
%= 1%4
¼ 17,, 4 ,
1%4 .s,,/16
2 4
% 2%4 13,, z 27/ 4
29/
4
31/ 4
½
33
17
4 2
3%4 37
4
1%2
1.199
:3%4
1.263 1.328
% 41/ 4
21/ 2
1.395 1.464
11Ae
1.535 1.607
45/ 4
1.681
43
4
2%2 47/ 4
.010 .016 .023 .032
.120 .140 .163 .187
3A
11/
!
.042 .053 ,065 .079
11/64
23
i
.053 .067 .083 .100
%,
%
e
II
%4
13
Round
Square
in.
1.756 1.834
49//64
2%2 sl/ 4
1.913 1.993 2.075
2.159
1.043
Area, sq in.
Round
rq
©
1.763 1.831 1.901 1.972
.6602 .6858
.5185 .5386
.7385
.5800
2.044 2.118
.2656
2.792 2.889
2.193 2.270
.7932 .8213 .8498
.6013 .6230 .6450 .6675
2.988 3.089
2.347 2.426 2.506 2.587
.8789 .9084 .9385 .9689
.6903
2.670 2.840 3.014 3.194
1.0000 1.0635 1.1289 1.1963
.7854 .8353 .8866
3.379 3.570 3.766 3.966
1.2656 1.3369 1.4102 1.4853
.9940 1.0500 1.1075 1.1666
4.173 4.384
5.857 6.139
4.600 4.822
1.5625 1.6416 1.7227 1.8056
1.2272 1.2893 1.3530 1.4182
5.049
I%2
6.428 6.724 7.026 7.334
1.8906 1.9775 2.0664 2.1572
1.4849 1.5532 1.6230 1.6943
.2991
½
7.650
6.008
.3164 .3342 .3525 .3713 .3906
1½2
8.636
6.520 6.783
2.2500 2.3447 2.4414 2.5400
1.8415 1.9175 1.9949
13/
6 53,/64
2%2 s%4
.0198
57
.0244 .0295
59/
4
ls/16 61//64 31//32 s 4
2.697
3.191
3.294
%=
4.303 4.545
¾6
4.795
%2
5.050
¼
5.312 5.581
%2 %6
.1914
.2053 .2197 .2346 .2500 .2659 .2822
.6350
2.511
3.838 4.067
.1077 .1182 .1292 .1406 .1526 .1650 .1780
.5862 .6103
2.332 2.420
3.616
.0977
.5166 .5393 .5625
2.245
t
3.400
1
.0791 .0881
il I •
2.603 4
2%2
.0352 .0413 .0479 .0549 .0625 .0706
.4727 .4944
1.696
in.
.0039 .0031 .0061 ,0048 .0088 .0069 .0120 .0156
1.262 1.320 1.379 1.440
1.630
Diam
E3 ! C) .....
.4104 .4307 .4514
1.502 1.565
Square i Round
11/
2
% 13/
2
7/ 6
5.281
5.518 5.761
.5591
.7135 .7371 .7610
.9396
1.7671
6.261
8.978
7.051 7.325 7.604 7.889
2.6406 2.9541
2.0739 2.1545 2.2365 2.3202
=%2 10.788 13/16 11.170 2 / 2 11.558
8.178 8.473 8.773 9.078
3.0625 3.1728 3.2852 3.3994
2.4053 2.4920 2.5802 2.6699
i 11.953 2%2 I 12.355
9.704
9.388
3.5156 3.6337 3.7539 3.8760
2.7612 2.8540 2.9483 3.0442
%6 1%2 % 21//32 11As
2%2
9.327
9.682 10.044
¾ 10.413
.4604 ,,1811 .4794 .4987
.7119
7.972 8.301
1%6 I 12.763 31/ 2 13.178
10.024 10.350 A
186
Area, sq in.
Square
Squarei Round
1.096 1.150
1.205
Weight, Ib per ft
Size or
2.7431
2.8477
Size Weight, Ib per ft or
Diam Square Round
in
II
13.600 14.463 15.353 16.270 17.213 18.182 19.178
2 1A6
3A,
¼ %6 % ?A6
20.201
½
21.250 22.326 23.428 24.557 25.713 26.895 28.103 29.338 30.600 31.888 33.203 34.545
9A6
% 11A6
¾ 13A6
1%6
3 'A6 %e
¾ ?/16
½
6
¾ 13A6 7 1 s//16
4 1/
3Ae
¼
7/ 6
½ %6
% 11//16
¾ 7
1.35.c
2.05E 2.77E 3.51E 4.28( 5.06; 5.86( 6.69(; 7.53,=
8.40£
6
15/16
Square
©
4.0000 4.2539 4.5156 4.7852 5.0625 5.3477 5.6406 5.9414 6.2500 6.5664 6.8906 7.2227 7.5625 7.9102 8.2656 8.6289 9.0000 9.3789 9.7656 10.160 10.563 10.973
3.1416 3.3410 3.5466 3.7583
11.816 12.250 12.691 13.141
44.678 46.232 47.813 49.420 51.053 52.713 54.400 56.113 57.853 59.620 61.413 63.232 65.078
42.726 44.071
45.438 46.825
48.233 49.662 51.112 66.951 52.583 68.850 54.075 70.776 !55.587 72.728 57.121 74.707 158.675 76.713 60.250 78.745 61.846 80.803 63.463 82.888 65.100 l
Round
rq
11.391
43.151
%e %
1
0.681
35.913 37.307 38.728 40.176 41.650
¼ '/le
11
@
Area, sq in.
13.598 14.063 14.535 15.016 15.504 16.000 16.504 17.016 1"
.53E
1
.063
1 .59E
1£.141 lC,.691
20.250 20.816 21.391
21.973 22.563 23.160 23.766 24.379
Weight, Ib per ft
Size or
Squarei
Diam
66.759 85.000 87.138 68.438 89.303 i 70.139I 71.860 91.495 73.602 93.713 75.364 95.957 77.148 98.228 100.53 I 78.953 80.778 102.85 82.624 105.20 107.58 84.492 86.380 109.98 112.41 88.289 114.87 90.218 117.35 92.169 119.86 94.140 122.40 96.133 124.96 98.146 127.55 100.18 130.17 102.23
5 'A6 A6
3.9761
¼
4.2000
%6
4.4301
¾
4.6664 4.9087 5.1572 5.4119 5.6727 5.9396 6.2126 6.4918
?Ae 1/£
%6 %
¾ 13//16 7
6.7771
7.0686 7.3662 7.6699 7.9798 8.2958 8.6179 8.9462 9.2806
6
11A6
135.48 138.18 140.90 143.65 146.43 149.23 152.06
¾
154.91
6
¾ 7/ 6
½
9.9678
%6 %
10.321
10.680 11.045 11.416 11.793 1.
132.81
¼
9.6211
;.177
1;:.566
1
157.79 160.70 163.64 166.60 169.59 172.60 175.64
6
7
1 ;:.962
13.364 13.772 14.186 14.607 15.033 15.466 15.904 16.349 16.800
3/ 6
178.71 181.81
¼
17.257
184.93 188.08 191.25 194.45 197.68 200.93
6
17.721
18.190 18.665 19.147
7
Round
mi•
in.
15/ 6 l
108.52 110.66 112.82 115.00 117.20 119.43 121.67 123.93 126.22 128.52 130.85 133.19 135.56 137.95 140.36 142.79 145.24 147.71 150.21
152.72 155.26 157.81
204.21
160.39 162.99 165.60
214.21
168.24 ,
207.52 210.85
6
104.31 106.41
Area, sq in.
Round
Square
0
r--1
25.000 25.629 26.266 26.910 27.563 28.223
i 19.635 i 20.129
!20.629 21.1 35
21.648
i 22.166 122.691 i 29.566 !23.221 28.891
30.250
23.758
30.941 31.641
i 24.301 124.850 32.348 i 25.406
33.063 33.785 34.516 35.254 36.000 36.754 37.516 38.285 39.063 39.848 40.641 41.441
125.967 126.535 127.109 i 27.688 128.274 128.866 i 29.465 i 30.069 130.680
[31.296 i 31.91 9
32.548 42.250 133.183 43.066 i 33.824 43.891
44.723 45.563 46.410 47.266 48.129 49.000 49.879 50.766 51.660 52.563 53.473
134.472 i 35.125
i 35.785 136.450 1 37.122
i 37.800
!38485
i 39.175 i 39.871 i
1140.574
i 41.282 i 41.997
42.718 55.316 ;43.445 I 56.250 t44.179 57.191 i 44.918 58.141 45.664 59.098 46.415 t 6O.063 i 47.173 61.035 !47.937 62.016 ' 48.707 63.004 49.483 54.391
, ........
187
WEIGHTS OF SQUARE EDGE FLATS Pounds per Linear Foot Thickness, Inches
Width, Inches ¼ ½ 34 1
1% 1½ 134 2
2% 2% 23 3
3% 3½ 334 4
4% 4% 434 5
5% 5% 534 6
6% 6% 634 7
7% 7% 73, 8
8% 8% 834 9
9% 934 10
]/1
]/8 3/1s ¼ 5/1
i % ?/]e
.053 .10]] .159 .213 .266 .319 .372 .106 .213 .319 .425 .531 .638 .744 .159 .319 .478 .638 .797 .956 1.116
% 11,4
34
z3/l
% 15/1s
1 .85O 1.700 2.550
.213 .425 .638 .850 1.063 1.275 1.488
3.400
.266 .531 .797 1.063 1.328 1.594 1.859 .319 .638 .956 1.275 1.594 1.913 2.231 .372 .744 1.116 1.488 1.859 2.231 2.603 .425 .850 1.275 1.700 2.125 2.550 2.975
4.250
.478 .956 1.434 1.913 2.391 2.869 3.347 .531 1.063 1.594 2.125 2.656 3.188 3.719 .584 1.169 1.753 2.338 2.922 3.50 4.091 .638 1.275 1.913 2.550 3.188 3.825 4.463 .691 1.381 2.072 2.763 3.453 4.144 4.834 ,744 1.488 2.231 2.975 3.719 4.463 5.20 ] .79"/ 1.5941 2.3911 3.188 3.994 4.781 5.578 .850 1.700 2.550 3.400 4.250 5.100 5.950 .903 1.8061 2.709 3.613 4.516 5.419 6.322 ,9561.913 2.869 3.825 4.781 5.738 6.694 1.009 2.019 3.028 4.039 5.047 6.056 7.066 1,063 2.125 3.188 4.250 5.313 6.375 7.438 i
5.100 5.950 6.800 7.650 8.500 9.350 10.20 11.05 11.90 12.75 13.60 14.45 15.30 16.15 17.00
1.116 2.231 3.347 4.463 5.578 6.694 7.809 1.169 2.338 3.506 4.675 5.844 7.013 8.181 1.222 2.444 3.666 4.888 6.109 7.331 8.553 1.275 2.550 3.825 5.100 6.375 7.650 8.925
17.85
1.328 2.656 3.994 5.313 6.641 7.989 9.297 1.381 2.763 4,144 5.525 6.906 8.288 9.669 1.434 2.869 4.303 5.738 7.172 8.60I] 10.04 1.488 2.975 4.463 5.950 7.438 8.925 10.41
21.25
1.541 3.081i 4.622 6.163 7.703 9.244 10.78 1.594 3.188 4.781 6.375 7.969 9.563 11.16 1.641 3.294 4.941 6.588 8.234 9.881 11.53 1.700 3.400 5.100 6.800 8.500 10.20 11.90 1.753 3.506 5.259 7.013 8.766 10.52 12.27 1.806 3.613 5.419 7.225 9.031 10.84 12.64 1.859 3.719 5.579 7.438 9.29711.16 13.02 1.913 3.825 5.738 7.650 9.563 11.48 13.39 1.986 2.019 2.072 2.125
i
3.931 5.897 4.038 6.056 4.144 6.216 4.250! 6.375 /
188
I ....... i
7.863 9.828 11.79 8.075 10.09 12.11 8.2 ]8 10.36 12.43 8.500 10.63 12.75
13.76 14.13 14.50 14.88
18.70 19.55 20.40
22.10 22.95 23.80 24.65 25.50 26.35 27.20 28.05 28.90 29.'75 30.60 31.45 32.30 33.15 34.00
Thickness, Inches
Widthl Inches % 1/2
¾ 1
1¾ 2
2% 2% 2% 3
1V16
1%
1.11E .903 .951 1.806 1.91; 2.019 2.1251 2.231 2.709 2.869 3.028 3.188i 3.347 3.613 3.825 4.O38 4.25O 4.463
4.516 4.781j 5.419 5.73 6.322 6.694 7.225 7.65O
12.43 i 13.39
33,
13.55
14.34
4
14.45
15.30
4% 4%
15.35
16.26
16.26
43, 5
6z 61/2 63 7
17/16
!%
1%
1%
i .169
1.222
1.27!
1.328
1.381
2.338
2.444
2.55(
2.656
2.763
3.82
3.506
3.666
4.675
4.888i 5.10(
1¾
113/ 6
1.43,
1.488
1.541
1.594
16"
2.869
3.188
3.294
3.400
4.781
4.941
5.100
4.144J 4.303
5.313
5.525
5.738
5.95O I 6.163
6.375
6.588
6.80O
7.969
8.234
8.500
9.563
9.881 10.20
5.578
5.844
6.109
6.37!
6.641
6.9061 7.172
7.438
6.694
7.013
7.3311 7.65(
7.969
8.2881 8.606
8.925
9.244
7.066 7.438 7.809 8.181 8.553j 8.92!
13.12 13.81 i 14.13 14.88 15.14 15.94 16.15 17.001
8.925 • 9.350 9.775 10.20
1.700
3.984
6.0561 6.375 8.0751 8.500
1 5A6
2.9?5 1 3.oel 4.463 ! 4.622
5.047[ 5.313J
9.084 9.563 9.031 9.563 10.09 10.63 i 9.934 10.52 11.10 11.69 10.84 11.48 12.11 12.75
12.64
1%
7.703
8.128 8.601
11.74
6
[ 1%
' I 1.0091 1.063]
31/2
53
13/1
9.297 10.63
9.669 10.04
10.41
10.78
11.16
11.53
11.90
11.48
11.90
12.33
12.75
13.18
13.60
11.05
10.84
10.52
11.00
11.48
11.95
12.43
12.91
13.39
13.87
14.34
14.82
15.30
11.16
11.69
12.22
12.75
13.28
13.81
14.34
14.88
15.41
15.94
16.47
17.00
12.27
12.86
13.44
14.03
14.61
15.19
15.78
16.36
16.95
17.53
18.12
18.70
13.39
14.03
14.66
15.30
15.94
16.58
17.21
17.85
18.49
19.13
19.76
20.40
14.50
15.19
15.88
16.58
17.27
17.96
18.65
19.34
20.03
20.72
21.41
22.10
15.62
16.36
17.11
17.85
18.59
19.34
20.08
20.83
21.57
22.31
23.06
23.80
20.72
21.52i 22.31 23.11
23.91
24.70
25.50
16.73
17.53
18.33
19.13
19.92
17.85
18.1,)
19.55
20.40
21.25
22.10
22.95
23.80
24.65
25.50
26.35 ! 27,20
17.16 18.06 18.97 18.17 19.13 20.08
19.87
20.77
21.68
22.58
23.48
24.38
25.29
26.19
27.09
28.00 J 28.90
17.21
21.04
21.99
22 95
23.91
24.86
25.82
26.78
27.73
28.69
17.16
18.17
19.18 120.19
21.20
22.21
23.22
24.23
25.23
26.24
27.25
28 .26 29.27
30.28
29.64 30.60 31.29 i 32.30
18.06
19.13
20.19 21.25 22.31 23.38
24.44
25.50
26.56
27.63
28.69
29.75
30.81
31.88
32.94
34.00
25.66 ! 26.78
27.69
29.01
35.70
18.97 20.08 21.20 22.31 19.87 21.04 22.21 23.38 20.77 121.99 23.22 24.44 21.68 22.95 24.23 25.50 22.58 23.91 25.23 26.56 26.24 27.63 24.38 25.82 27.25 28 69 25.29 26.78 28.26 29.75 23.48 124.86
23.43
24.54
30.12
31.24
32.35
33.47
34.58
24.54
25.71i 26.88
28.05
29 .22 30.391 31.56
32.73
33.89
35.06
36.23
37.40
25.66
26.88
28.10
29.33
30.55
31.77
32.99
34.21
35.43
36.66
37.88
39.10
26.78
28.05
29.33
30.60
31.88
33.15 I 34.43
35.70
36.98
38.25
39.53
40.80
27.89
29.22
30.55
31.88
33.20
34.53 ' 35.86
37.19
38.52
39.84
41.17
42.58
29.01
30.39
31.77
33.15
34.53
35.91
37.29
38.68
40.06
41.44
42.82
44.20
30.12
31.56
32.99
34.43
35.86
37.29
38.73
40.16
41.60
43.03
44.47
45.90
31.24
32.73
34.21I 35.70 37.19
38.68
40.16
41.65 i43.14
44.63
46.11
4?.60
73/
26.19 27.73 [29.27 i 30.81 32.35 33.09 1 35.43 36.98 38.52 40.06 41.60 43.14 44.68 46.22 47.76 49.30 33.47 35.06 i 36.66 38.25 39.84 41.44 i 43.03 44.63 i46.22 47.81 49.41 51.00 27.09 28.69 130.28 31.88 28.00 29.64 31 29 32.94 3 1.58 36.231 37.88 39.53 41.17 42.82 44.47 46.11 i47.76 49.41 51.05 52.70
8
28.90 130.60
8% 8%
29.80 30.71
83
31.61
9
32.51
9% 9%
134.32 36.34
7% 7'/2
93 10
51.00
52.70
54.40
49.09 150.84 52.59
54.35
56.10
50.58 i52.38
54.19
55.99
57.80
52.06
53.92
55.78
57.64
59.50
51.64
53.55
55.46
57.38
59 .29 61.20
35.70
37.40
39.10
40.80 142.50 44 .20 45.9O 47.60
31.56
36.82
38.57
40.32
42.08
32.51
37.93
39.74
41.54
43.35 i45.16
!39.05
40.91
42.77
44.63
48.34
50.20
40.16
42.08
43.99
45.90 147.81 49.73
41.28
43.241 45.21
49.14
32130 34.00
33.31 35.06 34.32 36.13 33.47 i35.33 37.19 34.43 36.34 38.25
33.42 !35.38
37.35 139.31
]38.36 40.38 42.39 35.22 i37.29 39.37 41.44 43.51 36.13 38.25 40.38 42.50 44.63
43.83 46.48
45.58 47.33 46.96 ' 48.77
49.30
51.11
53.07
55.04 157.00
58.97
60.93
62.90
46.43
48.45 150.47 52.49
54.51
56.53 158.54
60.56
62.58
64.60
45.58 i 47.65
49.73 151.80 53.87
55.94
58.01 160.08
62.16
64.23
66.30
48.88
51.00 153.13 55.25
57.38
59.50 ]61.63
63.75
65.88
68.00
44.41 46.75
47.18
189
ROLLING TOLERANCES--INCHES Hot-Rolled Carbon and Alloy Steel Bars Rounds, Squares, & Round-Cornered Squares Variation from Size
Out-of-Round
Specified Sizes To %6 incl Over %6 to 7A6 inci Over 7/16 to % incl Over % to 7 incl
Over
Under
0.005
0.005 0.006 0.007 0.008 0.009 0.010
0.006 0.007 0.008 0.009 0.010
to 1 incl incl Over 1 to 1 Over 1 to 1¼ incl Over 1¼ to 1¾ incl Over 1% to 1½ incl Over1½ to 2 incl Over 2 to 2½ incl Over 2½ to 3½ incl Over 3½ to 4½ incl Over 4½ to 5½ incl Over 5½ to 6½ incl Over 6½ to 8¼ incl Over 8¼ to 9½ incl Over9½to 10 Over
0.011
or Out-of-Square
0.008 0.009 0.010 0.012
0.013 0.015 0.016 0.018
0.011
0.012 0.014
0.012 0.014
1/ ,
1A,
+A2
0 0 0 0 0 0 0 0
¾, 1A6
%, %2 %6 ¼
0.021
0.023 0.023 0.035 0.046 O.O58
0.070 0.085 0.100 0.120
..........
NOTE: Out-of-round is the difference between the maximum and minimum diameters of the bar, measured at the same cross section. Out-of-square is the difference in the two dimensions at the same cross section of a square bar between opposite faces.
Hexagons Specified Sizes
Variation from Size Out-of Hexagon
between
Opposite Sides
Over
Under
0.007 !
To ½ incl Over ½to1 incl Over1 tol½incl Overl½to2 incl Over 2 to 2½ incl Over 2½ to 3½ incl
0.007
0.011
0.010 i 0.010
0.021 +A
,
A6
0.015 0.025
0.013
I
+A,
i
¾6
+A,
1A6
NOTE: Out-of-hexagon is the greatest difference between any two dimensions at the same cross section between opposite faces.
Square-Edge and Round-Edge Flats Variation from Thickness for Thicknesses Given
Specified Widths
.203 to ¼,
excl
To 1 incl Over 1 to 2 incl Over 2 to 4 incl Over 4 to 6 incl Over 6 to 8 incl
0.007 0.007 O.O08 O.009 0.015"
¼ to ½,
inci
0.008 0.012 0.015 0.015 0.016
Over ½ to 1, incl
0.010 0.015 0.020 i 0.020! 0.025 ,
Variation
from Width
Over 1 to 2, Over incl 2 Over Under I i i +A2 i --
+A2
'/32
+A2
+A2 I ¾, +,62 I + ¾,
"A6 t ',6= ! %2 1A6
¾+**
*"i %=** +
*Flats over 6 in. in width are not available in thicknesses under 0.230 in. **Tolerances not applicable to flats over 6 in. in width and over 3 in. in thickness. 1 90
GLOSSARY OF STEEL TESTING AND THERMAL
TR EATI N G TER IVIS
Ac TEMPERATURE. See Transformation Temperature. AGING. A time-dependent change in the properties of certain steels that occurs at ambient or moderately elevated temperatures after hot working, after a thermal treatment (quench aging), or after a cold working operation (strain aging).
AN N EALI N G. A thermal cycle involving heating to, and hold ing at a suitable temperature and then cooling at a suitable rate, for such purposes as reducing hardness, improving machinability, facil itating cold working, producing a desired microstructure, or obtain ing desired mechanical or other properties. AR TEMPERATURE. See Transformation Temperature.
AUSTEMPERING. A thermal treatment process which in volves quenching steel from a temperature above the transformation range in a medium having a rate of heat abstraction high enough to prevent the formation of high-temperature transformation products, and holding the material at a temperature above that of martensite formation until transformation is complete. The product formed is termed lower bainite.
AUSTENITIZING. The process of forming austenite by heat ing a ferrous alloy into the transformation range (partial austenitiz ing) or above this range (complete austenitizing). BAINITE. A decomposition product of austenite consisting of an aggregate of ferrite and carbide. In general, it forms at tempera tures lower than those where very fine pearlite forms, and higher than that where martensite begins to form on cooling. Its microstructural appearance is feathery if formed in the upper part of the temperature range; acicular, resembling tempered martensite, if formed in the lower part. Certain of these definitions have been derived from ASTM Standard E44-75. 191
BLUE BRITTLENESS. Brittleness occurring in some steels after being heated to within the temperature range of 400 to 700 F, or more especially, after being worked within this range. Killed steels are virtually free from this kind of brittleness.
BRINELL HARDNESS NUMBER (HB). Ameasureof hardness determined by the Brinell hardness test, in which a hard steel ball under a specific load is forced into the surface of the test
material. The number is derived by dividing the applied load by the surface area of the resulting impression.
CARBURIZING.A process in which an austenitized ferrous material is brought into contact with a carbonaceous atmosphere or medium of sufficient carbon potential as to cause absorption of carbon at the surface and, by diffusion, create a concentration gra dient. Hardening by quenching follows.
CASE HARDENING. A term descriptive of one or more processes of hardening steel in which the outer portion, or case, is made substantially harder than the inner portion, or core. Most of the processes involve either enriching the surface layer with carbon and/or nitrogen, usually followed by quenching and tempering, or the selective hardening of the surface layer by means of flame or induction hardening. CEMENTITE. A hard, brittle compound of iron and carbon (FeaC), the major form in which carbon occurs in steel.
CONTROLLED COOLING. A process by which steel is cooled from an elevated temperature in a predetermnied manner to avoid hardening, cracking, or internal damage, or to produce de sired microstructure or mechanical properties. CREEP. A time-dependent deformation of steel occurring under conditions of elevated temperature accompanied by stress in tensities well within the apparent elastic limit for the temperature involved.
CRITICAL RANGE. Synonymous with Transformation Range, which is the preferred term.
DECARBURIZATION. The loss of carbon from the surface of steel as a result of heating in a medium which reacts with the carbon. 192
DUCTILITY. The ability of a material to deform plastically without fracturing, usually measured by elongation or reduction of area in a tension test, or, for flat products such as sheet, by height of cupping in an Erichsen test.
ELASTIC LIMIT. The greatest stress that a material can withstand without permanent deformation.
ELONGATION. A measure of ductility, determined by the amount of permanent extension achieved by a tension-test specimen, and expressed as a percentage of that specimen's original gage length. (as: 25% in 2 in.).
END-QUENCH HARDENABILITY TEST (JOIVIlNY TEST). A method for determining the hardenability of steel by water-quenching one end of an austenitized cylindrical test specimen and measuring the resulting hardness at specified distances from the quenched end.
ENDURANCE LIMIT. The maximum cyclic stress, usually expressed in pounds per sq in., to which a metal can be subjected for indefinitely long periods without damage or failure. Conventionally established by the rotating-beam fatigue test.
EXTENSOMETER. An instrument capable of measuring small magnitudes of strain occurring in a specimen during a tension test, conventionally used when a stress-strain diagram is to be plotted.
ETCH TEST (MACROETCH). An inspection procedure in which a sample is deep-etched with acid and visually examined for the purpose of evaluating its structural homogeneity. FERRITE. A crystalline form of alpha iron, one of the two major constituents of steel (cf Cement#e) in which it acts as the solvent to form solid solutions with such elements as manganese, nickel, silicon, and, to a small degree, carbon. FLAKES. Internal fissures which may occur in wrought steel product during cooling from hot-forging or rolling. Their occurrence may be minimized by effective control of hydrogen, either in melting or in cooling from hot work.
FLAME HARDENING. A hardening process in which the surface is heated by direct flame impingement and then quenched.
193
FULL ANNEALING. A thermal treatment for steel with the primary purpose of decreasing hardness. It is accomplished by heat ing above the transformation range, holding for the proper time in terval, and controlled slow cooling to below that range. Subsequent cooling to ambient temperature may be accomplished either in air or in the furnace.
GRAIN SIZE NUMBER. An arbitrary number which is calculated from the average number of individual crystals, or grains, which appear on the etched surface of a specimen at 100 diameters magnification. See page 81.
HARDENABILITY. That property of steel which determines the depth and distribution of hardness induced by quenching.
HARDNESS. The resistance of a material to plastic defor mation. Usually measured in steels by the Brinell, Rockwell, or Vickers indentation-hardness test methods (q.v.).
IMPACT TEST. A test for determining the ability of a steel to withstand high-velocity loading, as measured by the energy, in ft-lb, which a notched-bar specimen absorbs upon fracturing.
INDUCTION HARDENING. A quench hardening process in which the heat is generated by electrical induction.
ISOTHERMAL TRANSFORMATION. A change in phase at any constant temperature. Practical application of the principle involved may be found in the isothermal annealing and aus tempering of steel.
MARTEMPERING. A method of hardening steel. Involves quenching an austenitized ferrous alloy in a medium at a tempera ture in the upper part of the martensitic range, or slightly above that range, and holding in the medium until the temperature throughout
the alloy is substantially uniform. The alloy is then allowed to cool in air through the martensitic range. MARTENSITE. A microconstituent or structure in hardened steel, characterized by an acicular, or needle-like pattern, and having the maximum hardness of any of the decomposition products of austenite.
194
MECHANICAL PROPERTIES. Properties which reveal the reactions, elastic and inelastic, of a material to applied forces. Sometimes designated erroneously as "physical properties." Some common mechanical properties, tests, and units are
listed below: Mechanical Property
Test
Units:
Customary (Si metric) angular degrees (radians) psi (kPa) psi (kPa)
Cold bending Cold-bend Compressive strength Compression Corrosion-fatigue
limit Creep strength
Corrosion-fatigue
Creep
psi (kPa) per time and
temperature
Elastic limit Elongation
Tension; Compression psi (kPa) Tension per cent of a specific specimen gage length Endurance Limit Fatigue psi (kPa) Hardness Static: Brinell; empirical numbers Rockwell; Vickers Dynamic: Shore empirical numbers (Scleroscope) Impact Notched-bar impact ft-lb (Joule) (Charpy; Izod) Impact, bending Bend ft-lb (Joule) Impact, torsional Torsion-impact ft-lb (Joule) Modulus of rupture Bend psi (kPa) Proof stress Tension; Compression psi (kPa) Proportional limit Tension; Compression psi (kPa) Reduction of area
Tension
Shear strength Shear Tensile strength Tension Torsional strength Torsion
Yield point
Tension
Yield strength
Tension
per cent
psi (kPa) psi (kPa) psi (kPa)
psi (kPa) psi (kPa)
MODULUS OF ELASTICITY (YOUNG'S MODULUS). A measure of stiffness, or rigidity, expressed in pounds per sq in. Developed from the ratio of the stress, as applied to a tension test specimen, to the corresponding strain, or elongation of the specimen, and applicable for tensile loads below lhe elastic limit of the material.
195
NITRIDING. A surface hardening process in which certain steels are heated to, and held at a temperature below the transfor mation range in contact with gaseous ammonia or other source of nas cent nitrogen in order to effect a transfer of nitrogen to the surface layer of the steel. The nitrogen combines with certain alloying ele ments, resulting in a thin case of very high hardness. Slow cooling completes the process.
N O R MALIZI N G. A thermal treatment consisting of heating to a suitable temperature above the transformation range and then cooling in still air. Usually employed to improve toughness or ma chinability, or as a preparation for further heat treatment. PEARLITE. A microconstituent of iron and steel consisting of a lamellar aggregate of ferrite and cementite.
PHYSICAL PROPERTIES. Properties which pertain to the physics of a material, such as density, electrical conductivity, and coefficient of thermal expansion. Not to be confused with mechanical properties (q.v.).
PROPORTIONAL LIMIT. The maximum stress at which strain remains directly proportional to stress.
QUENCHING AND TEMPERING. A thermal process used to increase the hardness and strength of steel. It consists of austenitizing, then cooling at a rate sufficient to achieve partial or complete transformation to martensite. Tempering should follow immediately, and involves reheating to a temperature below the transformation range and then cooling at any rate desired. Temper ing improves ductility and toughness, but reduces the quenched hardness by an amount determined by the tempering temperature used.
REDUCTION OF AREA. A measure of ductility determined by the difference between the original cross-sectional area of a ten sion test specimen and the area of its smallest cross section at the point of fracture. Expressed as a percentage of the original area.
196
ROCKWELL HARDNESS (HRB or HRC). A measure of hardness determined by the Rockwell hardness tester, by which a diamond spheroconical penetrator (Rockwell C scale) or a hard
steel ball (Rockwell B scale) is forced into the surface of the test material under sequential minor and major loads. The difference between the depths of impressions from the two loads is read directly on the arbitrarily calibrated dial as the Rockwell hardness value.
SPHEROIDIZE ANNEALING (SPHEROIDIZlNG). A thermal treatment which produces a spheroidal or globular form of carbide in steel. This is the softest condition possible in steel, hence, the treatment is used prior to cold deformation. Spheroidizing also improves machinability in the higher carbon grades.
STRESS RELIEVING. A thermal cycle involving heating to a suitable temperature, usually 1000/1200 F, holding long enough to reduce residual stresses from either cold deformation or thermal treatment, and then cooling slowly enough to minimize the develop ment of new residual stresses.
TEMPER BRITTLENESS. Brittleness that results when cer tain steels are held within, or are cooled slowly through, a specific range of temperatures below the transformation range. The brittle ness is revealed by notched-bar impact tests at or below room tem perature.
TEMPERING. See Quenching and Tempering. TENSILE STRENGTH. The maximum tensile stress in pounds per sq in. which a material is capable of sustaining, as de veloped by a tension test.
TENSION TEST. A test in which a machined or full-section specimen is subjected to a measured axial load sufficient to cause fracture. The usual information derived includes the elastic prop erties, ultimate tensile strength, and elongation and reduction of area.
THERMAL TREATMENT. Any operation involving the heating and cooling of a metal or alloy in the solid state to obtain desired microstructure or mechanical properties. This definition ex cludes heating for the sole purpose of hot working.
197
TRANSFORMATION RANGES. Those ranges of tem peratures within which austenite forms during heating, and trans forms during cooling.
TRANSFORMATION TEMPERATURE. The tempera ture at which a change in phase occurs. The term is sometimes used to denote the limiting temperature of a transformation range. The symbols of primary interest for iron and steels are: Aeem---In hypereutectoid steel, the temperature at which the solution of cementite in austenite is completed during heating. Aez --The temperature at which transformation of ferrite to aus tenite begins during heating. Ae8 --The temperature at which transformation of ferrite to aus tenite is completed during heating. Arl ---The temperature at which transformation of austenite to fer rite or to ferrite plus cementite is completed during cooling. Ar8 --The temperature at which transformation of austenite to fer rite begins during cooling. Ms --The temperature at which transformation of austenite to mar tensite begins during cooling. Mf --The temperature at which transformation of austenite to mar tensite is substantially completed during cooling. Note: All these changes (except the formation of martensite) occur at lower temperatures during cooling than during heating, and depend on the rate of change of temperature.
VICKERS HARDNESS (HV). A measure of hardness de termined by the Vickers, or Diamond Pyramid Hardness Test, which is similar in principle to the Brinell test, but utilizes a pyramid-shaped diamond penetrator instead of a ball.
YIELD POINT. The minimum stress at which a marked in crease in strain occurs without an increase in stress.
YIELD STRENGTH. The stress at which a material exhibits a specified deviation from the proportionality of stress to strain. The deviation is expressed in terms of strain, and in the offset method, usually a strain of 0.2 per cent is specified.
YOUNG'S MODULUS. See Modulus of Elasticity. 198
INDEX t...,y steels
AISI/SAE standard grades and ladle chemical ranges 34
Definition 19 Effects of chemical elements 19 Hardenability limits tables 51 Ladle chemical ranges and limits 40 Mechanical properties tables Carburizing grades 121 Oil-hardening grades 145 Water-hardening grades 137
Carbo-nitriding treatment for surface hardening 68 Carburizing treatment for surface hardening 66
Chemical analyses of carbon and alloy steel
AISI/SAE grades 25
Conversion tables Hardness 181 Metric equivalents for weights & measures 184 Temperature 182 Cyaniding treatment for surface hardening 68
Machinability 172
Product analysis tolerances 42 Rolling tolerances 190 SAE typical thermal treatments Carburizing grades 74 Directly hardenable grades 78
Degassing, vacuum 15
Eddy-current testing 176 Electric-arc furnace 10
Elements, chemical, effects on machinability 169 ...ealing
Isothermal 73 Solution, or Full 72 Spheroidize 72 Stress-relief 71 _ Sub-critical 72
Elements, chemical, effects on steel properties 19 Aluminum 23 Boron 23 Carbon 20 Chromium 22 Copper 22
Lead 23
) as of square and round bars 186 ) ;tempering 65 3asic open-hearth furnace 7
! ic oxygen furnace 8 ilast furnace 6
3oron steel grade analyses
Alloy and Alloy H 38 Carbon H 31
Manganese 20 Molybdenum 22
Nickel 21
Nitrogen 23 Phosphorus 20
Silicon 21
Sulfur 21 Vanadium 22 End-quench hardenability limits tables 51 End-quench hardenability testing 44
2apped steels 14
Flame-hardening treatment for surface 68
: :bon steels AISI/SAE standard grades and ladle chemical ranges 26
Free-machining carbon steels 30, 168
Flats, weights of square-edge 188
Definition 19
Furnace, blast 6
Effects of chemical elements 19 Free-machining grades, chemical analyses 30 Hardenability limits tables 51 Ladle chemical ranges and limits 32 ,
Furnaces, steelmaking
Mechanical properties tables Carburizing grades 87
Glossary of steel testing & thermal treating terms 191
Machinability 168 Water- and oil-hardening grades 93
Product analyses tolerances 33 Rolling tolerances 190 SAE typical thermal treatments Carburizing grades 76 Water- and oil-hardening grades 77
Basic oxygen 8 Electric-arc 10
Open-hearth 7
Grain size 81 Hardenability 43 Calculation of end-quench 46 End-quench testing 44 Limits tables 51 Hardening, induction 68
199
IN DEX (CONT,D) Hardening treatment, surface 66
Pig iron production 6
Hardness conversion tables 181
Piping in the ingot 12
H-Steels
Alloy grades, chemical analyses 36 Alloy boron grades, chemical analyses 38 Carbon and carbon boron grades,
chemical analyses 31 Hardenability limits tables 51 Induction hardening treatment for surface 68 Ingots, segregation in steel 12
Isothermal treatments 63 Austempering 65 Martempering 65 Killed steels 13 Ladle chemical ranges and limits Alloy steels 40 Carbon steels 32 "M" steels, grade analyses 30
Quenching and tempering, conventional 61
Quenching media 62 Raw materials for steelmaking 5 Rimmed steels 12 Rolling tolerances, carbon and alloy steels 190 SAE typical thermal treatments Alloy steels, carburizing grades 74 Alloy steels, directly hardenable grades 78 Carbon steels, carburizing grades 76 Carbon steels, water-& oil-hardening grades 77
Segregation in the ingot. 12 Semi-killed steels 14 Steelmaking methods Basic oxygen process 8 Electric-arc process l0 Open-hearth process 7
Machinability of steel 168
Strand casting 14
Machinability testing 168
Surface hardening treatments 66 Carbo-nitriding 68 Carburizingwliquid, gas, pack 66 Cyaniding 68 Flame hardening 68 Induction hardening 68
Magnetic measurement testing 175 Magnetic particle testing 175 Martempering 65 Mechanical properties obtainable in H-steels Oil quench 58, 60 Water quench 59, 60 Mechanical properties tables Alloy carburizing grades 121 Alloy oil-hardening grades 145 Alloy water-hardening grades 137 Carbon carburizing grades 87 Carbon water- and oil-hardening grades 93
Metric equivalents for weights and measures 184 Nitriding treatment for surface hardening 67 Nondestructive examination of steel 173 Electromagnetic test methods 175 Eddy current 176
Nitriding 67 Taconite 5 Temperature conversion table 182 Thermal treatments
Austempering and martempering 65 Conventional quenching and tempering 61 Normalizing and annealing 71 Quenching media 62 SAE typical 74-79 Tool steels, identification & type classification 178 Types of steel (capped, killed, rimmed, semi-killed) 12 Ultrasonic testing 173
Magnetic measurement 175
Magnetic particle 175 Ultrasonic testing 173 Normalizing and annealing 71
Vacuum treatment 15
Ladle degassing 17 Stream degassing 16 Vacuum lifter degassing 17
Open-hearth furnace, basic 7
Weights of square and round bars 186
Oxygen furnace, basic 8
Weights of square-edge flats 188
2OO
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