Transcript
Electrical network protection
Protection guide Guide
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2003
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51G
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network
protection pr
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Protection guide
Contents
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Presentation Power-system architecture
2
Selection criteria Examples of architectures
4 5
Neutral earthing Five neutral earthing systems Isolated neutral Resistance earthing Low reactance earthing Compensation reactance earthing Solidly earthed neutral
6 7 8 9 10 11
Short-circuit currents Introduction to short-circuits Types of short-circuit Short-circuit across generator terminals Calculation of short-circuit currents Equipment behaviour during short-circuits
12 14 16 17 18
Sensors Phase-current sensors (CT) Phase-current sensors (LPCT) Residual-current sensors Voltage transformers (VT)
19 21 22 23
Protection functions General characteristics List of functions Associated functions
24 26 27
Discrimination Time-based discrimination Current-based discrimination Logic discrimination Directional protection discrimination Differential protection discrimination Combined discrimination
28 30 31 32 33 34
Power-system protection Single-incomer power systems Dual-incomer power systems Open loop power systems Closed loop power systems
36 38 40 41
Busbar protection Types of faults and protection functions
42
Link (line and cable) protection Types of faults and protection functions
44
Transformer protection Types of faults Protection functions Recommended settings Examples of applications
46 47 48 49
Motor protection Types of faults Protection functions Recommended settings Examples of applications
50 51 53 54
Generator protection Types of faults Protection functions Recommended settings Examples of applications
55 56 58 59
Capacitor protection Types of faults Protection functions Recommended settings and examples of applications
60 61 62
Appendices Glossary - Key words and definitions Bibliography Definitions of symbols Index of technical terms
64 66 67 68 1
Protection guide
Contents
0
Presentation Power-system architecture
2
Selection criteria Examples of architectures
4 5
Neutral earthing Five neutral earthing systems Isolated neutral Resistance earthing Low reactance earthing Compensation reactance earthing Solidly earthed neutral
6 7 8 9 10 11
Short-circuit currents Introduction to short-circuits Types of short-circuit Short-circuit across generator terminals Calculation of short-circuit currents Equipment behaviour during short-circuits
12 14 16 17 18
Sensors Phase-current sensors (CT) Phase-current sensors (LPCT) Residual-current sensors Voltage transformers (VT)
19 21 22 23
Protection functions General characteristics List of functions Associated functions
24 26 27
Discrimination Time-based discrimination Current-based discrimination Logic discrimination Directional protection discrimination Differential protection discrimination Combined discrimination
28 30 31 32 33 34
Power-system protection Single-incomer power systems Dual-incomer power systems Open loop power systems Closed loop power systems
36 38 40 41
Busbar protection Types of faults and protection functions
42
Link (line and cable) protection Types of faults and protection functions
44
Transformer protection Types of faults Protection functions Recommended settings Examples of applications
46 47 48 49
Motor protection Types of faults Protection functions Recommended settings Examples of applications
50 51 53 54
Generator protection Types of faults Protection functions Recommended settings Examples of applications
55 56 58 59
Capacitor protection Types of faults Protection functions Recommended settings and examples of applications
60 61 62
Appendices Glossary - Key words and definitions Bibliography Definitions of symbols Index of technical terms
64 66 67 68 1
Presentation
Protection guide
Protection units continuously monitor the electrical status of power system components and de-energize them (for instance by tripping a circuit breaker) when they are the site of a serious disturbance such as a short-circuit, insulation fault, etc. The choice of a protection device is not the result of an isolated study, but rather one of the most important steps in the design of the power system. Based on an analysis of the behaviour of electrical equipment (motors, transformers, etc.) during faults and the phenomena produced, this guide is intended to facilitate your choice of the most suitable protective devices.
Introduction Among their multiple purposes, protection devices: b contribute to protecting people against electrical hazards, b avoid damage to equipment (a three-phase short-circuit on medium-voltage
busbars can melt up to 50 kg of copper in one second and the temperature at the centre of the arc can exceed 10 000 °C), °C), b limit thermal, dielectric and mechanical stress on equipment, b maintain stability and service continuity in the power system, b protect adjacent installations (for example, by reducing induced voltage in adjacent circuits). In order to attain these objectives, a protection system must be fast, reliable and ensure discrimination. Protection, however, has its limits because faults must first occur before the protection system can react. Protection therefore cannot prevent disturbances; it can only limit their effects and their duration. Furthermore, the choice of a protection system is often a technical and economic compromise between the availability and safety of the electrical power supply.
Designing power system protection The design of protection for a power system can be broken down into two distinct steps: b definition of the protection system, also called the protection-system study, b determination of the settings for each protection unit, also called protection coordination or discrimination.
Definition of the protection system N E 7 5 3 5 5 E D
Interruption
Sensor
Order
Measurement
Processing
Protection relay Fig. 1. Protection system.
This step includes selection of the protection components and a consistent, overall structure suited to the power system. The protection system is made up of a string of devices including the following (fig. 1): b measurement sensors (current and voltage) supplying the data required to detect faults, b protection relays in charge of continuously monitoring the electrical status of the power system up to and including the formulation and emission of orders to the trip circuit to clear the faulty parts, b switchgear in charge of clearing faults, such as circuit breakers or combinations of switches or contactors and fuses. The protection-system study determines the devices to be used to protect against the main faults affecting the power system and the machines: b phase-to-phase and phase-to-earth short-circuits, b overloads, b faults specific to rotating-machines. The protection-system study must take the following parameters into account: b power system architecture and size, as well as the various operating modes, b the neutral-earthing systems, b the characteristics of current sources and their contributions in the event of a fault, b the types of loads, b the need for continuity of service.
Determination of protection-unit settings Each protection function must be set to ensure the best possible power system operation in all operating modes. The best settings are the result of complete calculations based on the detailed characteristics of the various elements in the installation. These calculations are now commonly carried out by specialized software tools that indicate the behaviour of the power system during faults and provide the settings for each protection function.
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Presentation
Protection guide
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Contents of this guide This guide is intended for those in charge of designing protection for power systems. It comprises two parts: b part 1, Power-system study, b part 2, Solutions for each application.
Power-system study 8 5 3 5 5 E D
A
B
This is a theoretical section presenting the information required to carry out a protectionsystem study covering the following points: b power-system architecture - what are the main architectures used in medium-voltage power systems? b neutral earthing systems - what are the main neutral earthing systems in medium voltage and what are the selection criteria? b short-circuit currents - what are their characteristics, how are they calculated and how do electrical devices react? b measurement sensors - how should instrument transformers for current and voltage be used? b protection functions - what functions do protection units provide and what are their codes (ANSI codes)? b discrimination of protection devices - what techniques must be used to ensure effective fault clearing?
51 51N
49 51 51N
Fig. 1. Protection-system study.
Precise determination of protection settings is not dealt with in this guide.
Solutions for each application 4 0 3 5 5 E D
26 63 49T
M
12 14 27D 27R 46 48 - 51LR 49RMS 51 51G 66 87T
This section provides practical information on the types of faults encountered in each application: b power systems, b busbars, b lines and cables, b transformers, b motors, b generators, b capacitors, and the protection units required for each type of fault, with setting recommendations and application examples.
38/ 49T
Fig. 2. Example of a motor application.
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Power-system architecture
Selection criteria
Protection of a power system depends on its architecture and the operating mode. This chapter compares typical structures of power systems.
Power-system architecture The various components of a power system can be arranged in different ways. The complexity of the resulting architecture determines the availability of electrical energy and the cost of the investment. Selection of an architecture for a given application is therefore based on a trade-off between technical necessities and cost. Architectures include the following: b radial systems v single-feeder, v double-feeder, v parallel-feeder, v dual supply with double busbars. b loop systems v open loop, v closed loop. b systems with internal power generation v normal source generation, v replacement source generation.
The table below lists the main characteristics of each architecture for comparison. Illustrations are provided on the next page. Architecture Radial Single-feeder radial
Use
Advantages
Drawbacks
Processes not requiring continuous supply E.g. a cement works
Most simple architecture Easy to protect Minimum cost
Double-feeder radial
Continuous processes: steel, petrochemicals
Parallel-feeder
Large power systems Future expansion is limited Processes requiring high continuity of service Processes with major load changes
Low availability Downtime due to faults may be long A single fault interrupts supply to the entire feeder Expensive solution Partial operation of busbars during maintenance Requires automatic control functions
Good continuity of supply Maintenance possible on busbars of main switchboard Good continuity of supply Simple protection Good continuity of supply Expensive solution Flexible operation: no-break transfers Requires automatic control functions Flexible maintenance
Double busbars
Loop systems Open loop
Very large power systems Major future expansion Loads concentrated in different zones of a site Closed loop Power system offering high continuity of service Very large power systems Loads concentrated in different zones of a site Internal power generation Normal source Industrial process sites generation producing their own energy E.g. paper plants, steel Replacement source Industrial and commercial (source changeover) sites E.g. hospitals
4
Less expensive than closed loop Simple protection
Faulty segment can be isolated during loop reconfiguration Requires automatic control functions
Good continuity of supply Does not require automatic control functions
Expensive solution Complex protection system
Good continuity of supply Expensive solution Cost of energy (energy recovered from process) Good continuity of supply for priority Requires automatic control functions outgoing feeders
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Examples of architectures
Power-system architecture
Single-feeder radial
Double-feeder radial
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Legend: NC: normally closed
1 6 3 5 5 E D
NC or NO
N E 2 6 3 5 5 E D
NO: normally open Unless indicated otherwise, all switchgear is NC.
NO
NO
Parallel-feeder
Double busbars NC or NO
N E 3 6 3 5 5 E D
N E 4 6 3 5 5 E D
NC
NO
NO
NC
NC or NO
NC
NO NC
NC
NO
NC
NO NO
NC
NO
Open loop
Closed loop NC or NO
N E 5 6 3 5 5 E D
NC
NC
NC
NC or NO
N E 6 6 3 5 5 E D
NO
NC
NC
Local normal source generation
NC
NC
NC
NC
NC
Replacement source generation (source changeover)
G
N E 7 6 3 5 5 E D
NC
G
N E 8 6 3 5 5 E D
G
NO NC or NO
NC or NO
source changeover NC
5
Neutral earthing
Five neutral earthing systems
The choice of neutral earthing for MV and HV power systems has long been a topic of heated controversy due to the fact that it is impossible to find a single compromise for the various types of power systems. Acquired experience now allows an appropriate choice to be made according to the specific constraints of each system. This chapter compares the different types of neutral earthing, distinguished by the neutral point connection and the operating technique used.
Earthing impedance
0
The neutral potential can be earthed by five different methods, according to type (capacitive, resistive, inductive) and the value (zero to infinity) of the impedance ZN of the connection between the neutral and earth: b ZN = ∞: isolated neutral, i.e. no intentional earthing connection, b ZN is related to a resistance with a fairly high value, b ZN is related to a reactance, with a generally low value, b ZN is related to a compensation reactance, designed to compensate for the system capacitance, b ZN = 0: the neutral is solidly earthed.
Difficulties and selection criteria The selection criteria involve many aspects: b technical considerations (power system function, overvoltages, fault current, etc.), b operational considerations (continuity of service, maintenance), b safety, b cost (capital expenditure and operating expenses), b local and national practices. Two of the major technical considerations happen to be contradictory:
1 0 2 5 5 E D
ZN
Ik1
C
C
C
Fig. 1. Equivalent diagram of a power system with an earth fault.
Reducing the level of overvoltages Excessive overvoltages cause the dielectric breakdown of electrical insulating materials, resulting in short-circuits. Overvoltages are of several origins: b lightning overvoltage, to which all overhead systems are exposed, up to the user supply point, b overvoltage within the system caused by switching and critical situations such as resonance, b overvoltage resulting from an earth fault itself and its elimination. Reducing earth fault current (Ik1) (fig. 1) Fault current that is too high produces a whole series of consequences related to the following: b damage caused by the arc at the fault point; particularly the melting of magnetic circuits in rotating machines, b thermal withstand of cable shielding, b size and cost of earthing resistor, b induction in adjacent telecommunication circuits, b danger for people created by the rise in potential of exposed conductive parts. Unfortunately, optimizing one of these requirements is automatically to the disadvantage of the other. Two typical neutral earthing methods accentuate this contrast: b isolated neutral, which eliminates the flow of earth fault current through the neutral but creates higher overvoltages, b solidly earthed neutral, which reduces overvoltage to a minimum, but causes high fault current. As for the operating considerations, according to the neutral earthing method used: b continued operation may or may not be possible after a persisting first fault, b the touch voltages are different, b protection discrimination may be easy or difficult to implement. An in-between solution is therefore often chosen, i.e. neutral earthing via an impedance.
Summary of neutral earthing characteristics Characteristics Damping of transient overvoltages Limitation of 50 Hz overvoltages Limitation of fault currents Continuity of service (no tripping required on first fault) Easy implementation of protection discrimination No need for qualified personnel
Neutral earthing isolated compensated – +– – – + ++ + + – – Legend:
6
–– – + good – mediocre
resistance + + + –
reactance +– + + –
direct ++ + –– –
+ +
+ +
+ +
Isolated neutral
Neutral earthing
0
Block diagram There is no intentional earthing of the neutral point, except for measurement or protection devices.
2 0 2 5 5 E D
V
Operating technique
C
Ik1
C
In this type of power system, a phase-to-earth fault only produces a low current through the phase-to-earth capacitances of the fault-free phases (fig. 1). It can be shown that Ik1 = 3 • C • ω • V where: b V is the phase-to-neutral voltage, b C is the phase-to-earth capacitance of a phase, b ω is the angular frequency of the power system defined as ω = 2 • π • f
C
Ic Fig. 1. Capacitive fault current in isolated neutral system.
The fault current Ik1 can remain for a long time, in principle, without causing any damage since it is not more than a few amperes (approximately 2 A per km for a 6 kV single-core cable with a cross-section of 150 mm2 , XLPE insulation and a capacitance of 0.63 µF/km). Action does not need to be taken to clear this first fault, making this solution advantageous in terms of maintaining service continuity. However, this entails the following consequences: b the insulation must be continuously monitored and faults that are not yet cleared must be indicated by an insulation monitoring device or by a neutral voltage displacement protection unit (ANSI 59N) (fig. 2), b subsequent fault tracking requires complex automatic equipment for quick identification of the faulty feeder and also maintenance personnel qualified to operate the equipment, b if the first fault is not cleared, a second fault occurring on another phase will cause a real two-phase-to-earth short circuit, which will be cleared by the phase protection units.
N E 3 0 2 5 5 E D
IM D
Advantage The basic advantage is service continuity since the very low fault current does not cause automatic tripping for the first fault; it is the second fault that requires tripping.
Fig. 2. Insulation monitoring device (IMD).
Drawbacks b The failure to eliminate transient overvoltages through the earth can be a major
V0
4 0 2 5 5 E D
IrsdB V0
V0
handicap if the overvoltage is high. b Also, when one phase is earthed, the others reach a phase-to-phase voltage at power frequency (U = 3 • V ) in relation to the earth, and this increases the probability of a second fault. Insulation costs are higher since the phase-to-phase voltage may remain between the phase and earth for a long time with no automatic tripping. b Insulation monitoring is compulsory, with indication of the first fault. b A maintenance department with the equipment to quickly track the first insulation fault is required. b It is difficult to implement protection discrimination for the first fault. b There are risks of overvoltages created by ferroresonance.
Protection function
IrsdA
IrsdA
IrsdB A
67N
B
67N
The faulty feeder may be detected by a directional earth fault protection unit (ANSI 67N) (fig. 3). The diagram shows that discrimination is implemented by a comparison of the phase displacement angle between the residual voltage and residual currents, for the faulty feeder and for each fault-free feeder. The current is measured by a core balance CT and the tripping threshold is set: b to avoid nuisance tripping, b lower than the sum of the capacitive currents of all the other feeders. This makes it difficult for faults to be detected in power systems that are limited in size, consisting of only a few hundreds of meters of cable.
Applications Ik1
This solution is often used for industrial power systems (≤ 15 kV) that require service continuity. It is also used for the public distribution systems in Spain, Italy and Japan.
Fig. 3. Detection for directional earth fault protection.
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Resistance earthing
Neutral earthing
0
Block diagram A resistor is intentionally connected between the neutral point and earth. 5 0 2 5 5 E D
Operating technique
RN
In this type of power system, the resistive impedance limits the earth fault current Ik1 and still allows satisfactory evacuation of overvoltages. However, protection units must be used to automatically clear the first fault. In power systems that supply rotating machines, the resistance is calculated so as to obtain a fault current Ik1 of 15 to 50 A. This low current must however be IRN ≥ 2 Ic (where Ic is the total capacitive current in the power system) to reduce switching surges and allow simple detection. In distribution power systems, higher values are used (100 to 300 A) since they are easier to detect and allow the evacuation of lightning overvoltages.
IRN Ik1
Ic
Advantages
Fig. 1. Earthing with accessible neutral: resistor between neutral and earth.
b This system is a good compromise between low fault current and satisfactory
overvoltage evacuation. b It does not require equipment with phase-to-earth insulation sized for the phaseto-phase voltage. b The protection units are simple and selective and the current is limited.
0 0 2 5 5 E D
Drawbacks b The service continuity of the faulty feeder is downgraded and earth faults must be
cleared as soon as they occur (first fault tripping). b The higher the voltage and the current limited, the higher the cost of the earthing resistor.
RN
Neutral earthing Fig. 2. Earthing with accessible neutral: resistor on single-phase transformer secondary circuit.
6 0 2 5 5 E D
b If the neutral point is accessible (star-connected windings with an accessible
neutral), the earthing resistor may be connected between the neutral and earth (fig. 1) or via a single-phase transformer with an equivalent resistive load on the secondary winding (fig. 2). b When the neutral is not accessible (delta-connected winding) o r when the protection system study shows that it is appropriate, an artificial neutral point is created using a zero sequence generator connected to the busbars; it consists of a special transformer with a very low zero sequence reactance. v star-delta transformer with solidly earthed primary neutral, and a delta connection including a limiting resistor (LV insulation, therefore the most inexpensive solution) (fig. 3), v star-delta transformer with limiting resistor (HV insulation) between the primary neutral point and earth, and a closed delta connection (no resistor); this solution is less often used (fig. 4).
RN
Protection functions RN
Earthing with inaccessible neutral: Fig. 3. Limiting resistor Fig. 4. Limiting resistor on on secondary circuit . primary circuit.
To detect a fault current Ik1 that is low, protection functions other than phase overcurrent are required (fig. 5). These “earth fault’’ protection functions detect fault current: b directly in the neutral earthing connection 1, b or in the power system by the vector sum of the 3 currents measured by: v 3 current sensors supplying the protection units 2, v or a core balance CT 3: preferred method since more accurate. The threshold is set according to the fault current Ik1 calculated without taking into account the source and connection zero sequence impedance in relation to the impedance RN, in compliance with two rules: b setting > 1.3 times the capacitive current of the power system downstream from the protection unit, b setting in the range of 10 to 20% of the maximum earth fault current.
8 0 2 5 5 E D
1
2
51G RN
3 51G
51N
In addition, if 3 CTs are used for detection, in view of current technologies, the setting should be within 5 to 30% of the CT rating to account for the uncertainty linked to: b transient current asymmetry, b CT saturation, b scattering of performance.
Applications Fig. 5. Earth fault protection solutions.
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Public and industrial MV distribution systems.
Neutral earthing
Low reactance earthing
0
Block diagram A reactor is intentionally connected between the neutral point and earth. For power system voltages greater than 40 kV, it is preferable to use a reactor rather than a resistor because of the difficulties arising from heat emission in the event of a fault (fig. 1).
9 0 2 5 5 E D
Operating technique
LN
In this type of power system, an inductive impedance limits earth fault current Ik1 and still allows satisfactory evacuation of overvoltages. However, protection units must be used to automatically clear the first fault. To reduce switching surges and allow simple detection, the current IL must be much higher than the total capacitive current of the power system Ic. In distribution systems, higher values are used (300 to 1000 A) since they are easier to detect and allow the evacuation of lightning overvoltages.
ILN Ik1
Ic Fig. 1. Earthing with accessible neutral.
Advantages b This system limits the amplitude of fault currents. b Protection discrimination is easy to implement if the limiting current is much greater
than the capacitive current in the power system. b The coil has a low resistance and does not dissipate a large amount of thermal energy; the coil can therefore be reduced in size. b In high voltage systems, this solution is more cost-effective than resistance earthing.
Drawbacks b The continuity of service of the faulty feeder is downgraded; earth faults must be
cleared as soon as they occur (first fault tripping). b When earth faults are cleared, high overvoltages may occur due to resonance between the power system capacitance and the reactance.
Neutral earthing 0 1 2 5 5 E D
b If the neutral point is accessible (star-connected windings with an accessible
LN
neutral), the earthing reactance may be connected between the neutral and earth. b When the neutral is not accessible (delta-connected winding) or when the protection system study shows that it is appropriate, an artificial neutral point is created by a neutral point coil connected to the busbars; it consists of a zigzag coil with an accessible neutral (fig. 2). The impedance between the two parts of the winding, essentially inductive and low, limits the current to values that remain greater than 100 A. A limiting resistor may be added between the coil neutral point and earth to reduce the amplitude of the fault current (HV insulation).
Protection functions Fig. 2. Earthing with inaccessible neutral.
b The protection setting is in the range of 10 to 20% of the maximum fault current. b The protection function is less restrictive than in the case of resistance earthing,
especially considering the high value of ILN given that Ic is less than the limited current.
Applications Public and industrial MV distribution systems (currents of several hundred amperes).
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Neutral earthing
Compensation reactance earthing
Block diagram A reactor tuned to the total phase-to-earth capacitance of the power system is inserted between the neutral point and earth so that the fault current is close to zero if an earth fault occurs (fig. 1).
1 1 2 5 5 E D
Operating technique
R
This system is used to compensate for capacitive current in the power system. The fault current is the sum of the currents flowing through the following circuits: b reactance earthing circuit, b fault-free phase capacitances with respect to earth. The currents compensate for each other since: b one is inductive (in the earthing circuit), b the other one is capacitive (in the fault-free phase capacitances). They therefore add up in opposite phase. In practice, due to the slight resistance of the coil, there is a low resistive current of a few amperes (fig. 2).
LN
Ik1
ILN + IR
Ic
Fig. 1. Earth fault in power system with compensation reactance earthing. IL current in the reactor
N E 2 1 2 5 5 E D
Ik1 V0 residual voltage
IR Ic capacitive current
Fig. 2. Vector diagram of currents during an earth fault.
Advantages b The system reduces fault current, even if the phase-to-earth capacitance is high:
spontaneous extinction of non-permanent earth faults. b The touch voltage is limited at the location of the fault. b The installation remains in service even in the event of a permanent fault. b The first fault is indicated by detection of current flowing through the coil.
Drawbacks b The cost of reactance earthing may be high since the reactance needs
to be modified to adapt compensation. b It is necessary to make sure that the residual current in the power system during the fault is not dangerous for people or equipment. b There is a high r isk of transient overvoltages on the power system. b Personnel must be present to supervise. b It is difficult to implement protection discrimination for the first fault.
Protection function Fault detection is based on the active component of the residual current. The fault creates residual currents throughout the power system, but the faulty circuit is the only one through which resistive residual current flows. In addition, the protection units must take into account repetitive self-extinguishing faults (recurrent faults). When the earthing reactance and power system capacitance are tuned (3 LN • C • ω2 = 1) b fault current is minimal, b it is a resistive current, b the fault is self-extinguishing. The compensation reactance is called an extinction coil, or Petersen coil.
Application Public and industrial MV distribution systems with high capacitive current.
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0
Neutral earthing
Solidly earthed neutral
0
Block diagram An electrical connection with zero impedance is intentionally set up between the neutral point and earth.
3 1 2 5 5 E D
Operating technique Since the neutral is earthed without any limiting impedance, the phase-to-earth fault current Ik1 is practically a phase-to-neutral short-circuit, and is therefore high (fig. 1). Tripping takes place when the first insulation fault occurs.
Advantages IN
b This system is ideal for evacuating overvoltages. b Equipment with insulation sized for phase-to-neutral voltage may be used. b Specific protection units are not required: the normal phase overcurrent protection
Ik1
Ic Fig. 1. Earth fault in a solidly earthed neutral power system.
units can be used to clear solid earth faults.
Drawbacks b This system involves all the drawbacks and hazards of high earth fault current:
maximum damage and disturbances. b There is no service continuity on the faulty feeder. b The danger for personnel is high during the fault since the touch voltages created are high.
Protection function Impedant faults are detected by a delayed earth fault protection unit (ANSI 51N), set in the range of the rated current.
Applications b This type of system is not used in European overhead or underground MV power
systems, but is prevalent in North American distribution systems. In the North American power systems (overhead systems), other features come into play to justify the choice: v distributed neutral conductor, v 3-phase or 2-phase + neutral or phase + neutral distribution, v use of the neutral conductor as a protective conductor with systematic earthing at each transmission pole. b This type of system may be used when the short-circuit power of the source is low.
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Short-circuit currents
Introduction to short-circuits
A short-circuit is one of the major incidents affecting power systems. This chapter describes short-circuits and their effects on power systems and their interaction with equipment. It also provides a method and the main equations to calculate currents and voltages when short-circuits occur.
Definitions
0
b A short-circuit is an accidental connection between conductors by a zero
(solid short-circuit) or non-zero impedance (impedant short-circuit). b A short-circuit is referred to as internal if it is located within equipment or external if its occurs on links. b The duration of a short-circuit is variable. A short-circuit is said to be self-extinguishing if its duration is too short for tripping of the protection devices, transient if cleared following tripping and reclosing of the protection devices and continuous or sustained if it does not disappear following tripping. b The causes of a short-circuit can be mechanical (a shovel, a branch, an animal), electrical (damaged insulation, overvoltages) or human (operating error) (fig. 1).
Effects of short-circuit currents R
N E 5 5 3 5 5 E D
X Isc
A
Zsc
E B
N E 6 5 3 5 5 E D
Ia = I • sin(ω t + α) – R • t L
Ic = – I • sinα • e I
t
The consequences are often serious, if not dramatic. b A short-circuit disturbs the power system environment around the fault point by causing a sudden drop in voltage. b It requires disconnection, through the operation of the protection devices, of a part (often large) of the installation. b All equipment and connections (cables, lines) subjected to a short-circuit are subjected to high mechanical stress (electrodynamic forces) that can cause breaks and thermal stress that can melt conductors and destroy insulation. b At the fault point, there is often a high-energy electrical arc, causing very heavy damage that can quickly spread. Although short-circuits are less and less likely to occur in modern, well-designed, well-operated installations, the serious consequences they can cause are an incentive to implement all possible means to swiftly detect and eliminate them. The short-circuit current at different points in the power system must be calculated to design the cables, busbars and all switching and protection devices and determine their settings.
Characterization of short-circuits
α
Isc = Ia + Ic Moment fault occurs Fig. 1. Graphical representation of a short-circuit current based on an equivalent diagram.
A number of types of short-circuits can occur in a power system. b Three-phase short-circuit: a fault between the three phases. This type generally provokes the highest currents (fig. 2). b Phase-to-earth short-circuit: a fault between a phase and earth. This type is the most frequent (fig. 3). b Two-phase short-circuit clear of earth: a fault between two phases (phase-tophase voltage). The resulting current is lower than for a three-phase short-circuit, except when the fault is in the immediate vicinity of a generator (fig. 4). b Two-phase-to-earth short-circuit: a fault between two phases and earth (fig. 5). 5 1 2 5 5 E D
Ph 1
Ph 1
Ph 2
Ph 2
Ph 3 Fig. 2. Three-phase short-circuit (5% of cases).
6 1 2 5 5 E D
Ph 3 Fig. 4. Two-phase short-circuit clear of earth.
Ph 1
Ph 1
Ph 2
Ph 2
Ph 3
Ph 3
Current (I)
N E 9 2 2 5 5 E D
Fig. 3. Phase-to-earth short-circuit (80% of cases). Fig. 5. Two-phase-to-earth short-circuit. DC component Ip 2 2 Ik
Time (t)
Fig. 6. Typical short-circuit current curve.
12
Short-circuit current at a given point in the power system is expressed as the rms value Ik (in kA) of its AC component (fig. 6). The maximum instantaneous value that short-circuit current can reach is the peak value Ip of the first half cycle. This peak value can be much higher than 2 • Ik because of the damped DC component IDC that can be superimposed on the AC component. This DC component depends on the instantaneous value of the voltage at the start of the short-circuit and on the power system characteristics. The power system is defined by the short-circuit power, according to the equation: Ssc = 3 • Un • Ik (in MVA). This theoretical value has no physical reality; it is a practical conventional value comparable to an apparent power rating.
Introduction to short-circuits
Short-circuit currents
0
Symmetrical components During normal, balanced symmetrical operation, analysis of three-phase systems is similar to that of an equivalent single-phase system, characterized by the phase-toneutral voltages, phase currents and power system impedances (called cyclical impedances). As soon as a significant dissymmetry appears in the configuration or in power system operation, simplification is no longer possible. It is not possible to establish simple electrical relations in the conductors, using the cyclical impedances. In this case, the symmetrical-components method is used, which consists of expressing the real system as a superposition of three independent, single-phase power systems, called: b positive sequence (designated by a subscript 1, e.g. V 1), b negative sequence (designated by a subscript 2, e.g. V 2), b zero-sequence (designated by a subscript 0, e.g. V 0). For each system (positive-, negative- and zero-sequence respectively), voltages V1, V2, V0 and currents I1, I2, I0 are related by the impedances Z1, Z2, Z0 of the same system. The symmetrical impedances are a function of the real impedances, notably the mutual inductances. The notion of symmetrical components is also applicable to power.
a 2 • V2
1 3
V2 + V3 )
V1
= --- ( V1 +
V2
=
a 2 • V1 + a • V 2 + V0
V2
= --- ( V1 +
V3
=
a • V 1 + a 2 • V 2 + V0
V0
= --- ( V1 +
2π j • ------3 = e
Positive sequence
where a
Negative sequence
=
e
V1
V11
+
a • V3 )
2π j • ------3
Zero sequence V10
V2 2
V3
ω
1 3
V1 + V2 + V0
V31
V2
a • V2 + a 2 • V3 )
=
where a
N E 4 1 2 5 5 E D
1 3
V1
V1 2
V20
ω
t
V30
t ω
V21
t
V3 2
ω
t
Decomposition of a three-phase system into symmetrical components.
Decomposition into symmetrical components is not simply a mathematical technique, it corresponds to the physical reality of the phenomena. It is possible to directly measure the symmetrical components (voltages, currents, impedances) of an unbalanced system. The positive-, negative- and zero-sequence impedances of an element in the power system are the impedances of the element subjected to voltage systems that are, respectively, positive three-phase, negative three-phase and phase-to-earth on three parallel phases. Generators produce the positive-sequence component and faults may produce the negative and zero-sequence components. In the case of motors, the positive-sequence component creates the useful rotating field, whereas the negative-sequence component creates a braking rotating field. For transformers, an earth fault creates a zero-sequence component that produces a zero-sequence field passing through the tank.
13
Types of short-circuit
Short-circuit currents
Ik3
N E 7 1 2 5 5 E D
Zsc U Zsc
Zsc ZN
0
Three-phase short-circuit between the phase conductors (fig. 1) F
The value of the three-phase short-circuit current at a point F within the power system is: U Ik 3 = -----------------------3 • Zsc where U refers to the phase-to-phase voltage at point F before the fault occurs and Zsc is the equivalent upstream power system impedance as seen from the fault point. In theory, this is a simple calculation; in practice, it is complicated due to the difficulty of calculating Zsc, an impedance equivalent to all the unitary impedances of series and parallel-connected units located upstream from the fault. These impedances are themselves the quadratic sum of reactances and resistances. Zsc = R 2 + X 2 Calculations can be made much simpler by knowing the short-circuit power Ssc at the connection point for utility power. It is possible to deduce the equivalent impedance Za upstream of this point. U2 U Za = ----------Is c = -------------------Ss c 3 • Za
Fig. 1. Three-phase short-circuit.
Similarly, there may not be a single source of voltage, but rather several sources in parallel, in particular, synchronous and asynchronous motors which act as generators when short-circuits occur. The three-phase short-circuit current is generally the strongest current that can flow in the power system. N E 9 1 2 5 5 E D
E
I1
= -----Z1
I2
=
I0
V1
=
V2
= =
E
I1
V2 Z2
0 V0
V1 Z1
=
0
I2
V0 Z0
I0
Model of a three-phase short-circuit using the symmetrical components.
N E 8 1 2 5 5 E D
Zsc
Single-phase short-circuit between a phase conductor and earth (fig. 2)
Zsc
The value of this current depends on the impedance ZN between the neutral and earth. This impedance can be virtually nil if the neutral is solidly earthed (in series with the earthing resistance) or, on the contrary, almost infinite if the neutral is isolated (in parallel with the power system phase-to-earth capacitance).
U
Zsc ZN
Fig. 2. Phase-to-earth short-circuit.
Ik1
The value of the phase-to-earth fault current is: 3•U Ik 1 = ------------------------------------------------------( Z 1 + Z 2 + Z0 + 3Z N ) This calculation is required for power systems in which the neutral is earthed by an impedance ZN. It is used to determine the setting of the “earth fault” protection devices which must break the earth-fault current. If Z1, Z2 and Z0 are negligible with respect to ZN, then: U Ik 1 = --------------------3 • ZN This is the case, for example, when Ik1 is limited to 20 A in an MV power system supplied by a high-power transformer (10 MVA). I1
=
I2
=
I0
E
= --------------------------------------------Z1 + Z2 + Z0 + 3Z
E ( Z2 + Z0 + 3Z ) --------------------------------------------Z 1 + Z 2 + Z 0 + 3Z
V1
=
V2
–Z 2 • E = --------------------------------------------Z 1 + Z 2 + Z 0 + 3Z
V0
–Z 0 • E = --------------------------------------------Z 1 + Z 2 + Z 0 + 3Z
N E 0 2 2 5 5 E D
E
V1 Z1 V2 Z2 V0 Z0 3Z
Model of a phase-to-earth short-circuit using the symmetrical components.
14
I1
I2
I0
Types of short-circuit
Short-circuit currents
0
Two-phase short-circuit between phase conductors (fig.1) Zsc
N E 1 2 2 5 5 E D
U Zsc Ik2 Zsc ZN
The value of the two-phase short-circuit current at a point within the power system is: U Ik 2 = -----------------Z1 + Z 2 In a power system supplied by a transformer (fault far from the sources), the value of the two-phase short-circuit current at a point within the power system is: U Ik 2 = -------------------2 • Zsc The two-phase short-circuit current is weaker than three-phase short-circuit current, by a ratio of 3 /2, i.e. approximately 87%. If the fault occurs close to a generator ( Z2 ≤ Z1), the current can be higher than in a three-phase fault. I1
Fig. 1. Two-phase short-circuit clear of earth.
E
= ---------------------------Z1 + Z2 + Z
I2
–E = ---------------------------Z1 + Z2 + Z
I0
=
N E 4 2 2 5 5 E D
E
V2 Z2
0
V1
E (Z2 + Z ) = ---------------------------Z1 + Z2 + Z
V2
E • Z2 = ---------------------------Z1 + Z2 + Z
V0
=
V1 Z1
V0 Z0
I1
Z
I2
I0
0
Model of a two-phase short-circuit using the symmetrical components.
N E 2 2 2 5 5 E D
Zsc
Two-phase short-circuit between two phase conductors and earth (fig. 2)
Zsc
For a solid short-circuit (fault far from the sources), the value of the two-phaseto-earth short-circuit is: 3•U IkE2E = --------------------------( Z1 + 2Z 0 )
U Ik2E Zsc ZN
Fig. 2. Two-phase-to-earth short-circuit.
IkE2E
I1
=
E ( Z2 + Z0 + 3Z ) ------------------------------------------------------------------------------Z1 • Z 2 + ( 3Z + Z0 ) • ( Z1 + Z2 )
N E 5 2 2 5 5 E D
E
V1 Z1
I2
– E ( Z 0 + 3Z ) = ------------------------------------------------------------------------------Z1 • Z 2 + ( 3Z + Z0 ) • ( Z1 + Z2 )
V2 Z2
I0
–E • Z2 = ------------------------------------------------------------------------------Z1 • Z 2 + ( 3Z + Z0 ) • ( Z1 + Z2 )
V0 Z0
I1
I2
3Z
I0
Model of a two-phase-to-earth short-circuit using the symmetrical components.
15
Short-circuit across generator terminals
Short-circuit currents
Current
N E 3 2 2 5 5 E D
Transient
Subtransient
Steady-state
I1 t
I2 t
I3 t
Moment fault occurs Fig. 1. Typical curves for short-circuit currents across generator terminals.
Current
N E 8 2 2 5 5 E D
Subtransient component t
Transient component t
Steady-state component t
DC component
t
Total-current curve
t
Subtransient
Transient
Steady-state
Fig. 2. Decomposition of the short-circuit current.
16
0
It is more complicated to calculate short-circuit current across the terminals of a synchronous generator than across the terminals of a transformer connected to the power system. This is because the internal impedance of the machine cannot be considered constant after the start of the fault. It increases progressively and the current becomes weaker, passing through three characteristic stages: b subtransient (approximately 0.01 to 0.1 second), the short-circuit current (rms value of the AC component) is high, 5 to 10 times the rated continuous current. b transient (between 0.1 and 1 second), the short-circuit current drops to between 2 and 6 times the rated current. b steady-state, the short-circuit current drops to between 0.5 and 2 times the rated current. The given values depend on the power rating of the machine, its excitation mode and, for the steady-state current, on the value of the exciting current, therefore on the load on the machine at the time of the fault. What is more, the zero-sequence impedance of the AC generators is generally 2 to 3 times lower than their positive-sequence impedance. The phase-to-earth short-circuit current is therefore greater than the three-phase current. By way of comparison, the steady-state three-phase short-circuit current across the terminals of a transformer ranges between 6 and 20 times the rated current, depending on the power rating. It can be concluded that short-circuits across generator terminals are difficult to assess, in particular their low, decreasing value makes protection setting difficult.
Calculation of short-circuit currents
Short-circuit currents
0
IEC method (standard 60909) Current (I)
N E 6 2 2 5 5 E D
2 2 I"k IDC
2 2 Ib
2 2 Ik
Ip
Time (t) t min Fig. 1. Graphic representation of short-circuit quantities as per IEC 60909.
Type of short-circuit
I''k c • Un
3-phase
-------------------
2-phase
-----------------Z1 + Z2
2-phase-to-earth Phase-to-earth
3 • Z1
c • Un
c • U n • 3 • Z2 ------------------------------------------------------------------Z1 • Z2 + Z2 • Z 0 + Z 1 • Z 0 c •Un • 3
------------------------------Z1 + Z2 + Z0
Short-circuit currents as per IEC 60909 (general situation).
Type of short-circuit
I''k c • Un
3-phase
-------------------
2-phase
c • Un ----------------2 • Z1
3 • Z1
2-phase-to-earth
c •Un • 3 -----------------------------Z 1 + 2Z 0
Phase-to-earth
c •Un • 3 -----------------------------2Z 1 + Z0
Short-circuit currents as per IEC 60909 (distant faults).
The rules for calculating short-circuit currents in electrical installations are presented in IEC standard 60909, issued in 2001. The calculation of short-circuit currents at various points in a power system can quickly turn into an arduous task when the installation is complicated. The use of specialized software accelerates calculations. This general standard, applicable for all radial and meshed power systems, 50 or 60 Hz and up to 550 kV, is extremely accurate and conservative. It may be used to handle the different types of solid short-circuit (symmetrical or dissymmetrical) that can occur in an electrical installation: b three-phase short-circuit (all three phases), generally the type producing the highest currents, b two-phase short-circuit (between two phases), currents lower than three-phase faults, b two-phase-to-earth short-circuit (between two phases and earth), b phase-to-earth short-circuit (between a phase and earth), the most frequent type (80% of all cases). When a fault occurs, the transient short-circuit current is a function of time and comprises two components (fig. 1): b an AC component, decreasing to its steady-state value, caused by the various rotating machines and a function of the combination of their time constants, b a DC component, decreasing to zero, caused by the initiation of the current and a function of the circuit impedances. Practically speaking, one must define the short-circuit values that are useful in selecting system equipment and the protection system: b I''k: rms value of the initial symmetrical current, b Ib: rms value of the symmetrical current interrupted by the switching device when the first pole opens at t min (minimum delay), b Ik: rms value of the steady-state symmetrical current, b Ip: maximum instantaneous value of the current at the first peak, b IDC: DC value of the current. These currents are identified by subscripts 3, 2, 2E, 1, depending on the type of shortcircuit, respectively three-phase, two-phase clear of earth, two-phase-to-earth, phase-to-earth. The method, based on the Thevenin superposition theorem and decomposition into symmetrical components, consists in applying to the short-circuit point an equivalent source of voltage in view of determining the current. The calculation takes place in three steps. b Define the equivalent source of voltage applied to the fault point. It represents the voltage existing just before the fault and is the rated voltage multiplied by a factor taking into account source variations, transformer on-load tap changers and the subtransient behavior of the machines. b Calculate the impedances, as seen from the fault point, of each branch arriving at this point. For positive and negative-sequence systems, the calculation does not take into account line capacitances and the admittances of parallel, non-rotating loads. b Once the voltage and impedance values are defined, calculate the characteristic minimum and maximum values of the short-circuit currents. The various current values at the fault point are calculated using: b the equations provided, b a summing law for the currents flowing in the branches connected to the node: v I''k, see the equations for I''k in the tables opposite, where voltage factor c is defined by the standard; geometric or algebraic summing, v ip = κ • 2 • I''k, where κ is less than 2, depending on the R/X ratio of the positivesequence impedance for the given branch; peak summing, v Ib = µ • q • I''k, where µ and q are less than 1, depending on the generators and motors, and the minimum current interruption delay; algebraic summing, v Ik = I''k, when the fault is far from the generator, v Ik = λ • Ir, for a generator, where Ir is the rated generator current and λ is a factor depending on its saturation inductance; algebraic summing.
17
Equipment behaviour during short-circuits
Short-circuit currents
0
Characterization N E 7 2 2 5 5 E D
There are 2 types of system equipment, based on whether or not they react when a fault occurs.
Current (I)
Passive equipment IAC
Time (t) IDC
This category comprises all equipment which, due to its function, must have the capacity to transport both normal current and short-circuit current. This equipment includes cables, lines, busbars, disconnecting switches, switches, transformers, series reactances and capacitors, instrument transformers. For this equipment, the capacity to withstand a short-circuit without damage is defined in terms of: b electrodynamic withstand (expressed in kA peak), characterizing mechanical resistance to electrodynamic stress, b thermal withstand (expressed in rms kA for 1 to 5 seconds), characterizing maximum permissible heat rise.
Active equipment
IAC: peak of the periodic component. IDC: aperiodic component. Fig. 1. Rated breaking current of a circuit breaker subjected to a short-circuit as per IEC 60056.
This category comprises the equipment designed to clear short-circuit currents, i.e. circuit breakers and fuses. This property is expressed by the breaking capacity and, if required, the making capacity when a fault occurs. Breaking capacity (fig. 1) This basic characteristic of a current interrupting device is the maximum current (in rms kA) it is capable of breaking under the specific conditions defined by the standards; it generally refers to the rms value of the AC component of the short-circuit current. Sometimes, for certain switchgear, the rms value of the sum of the 2 components (AC and DC) is specified, in which case, it is the “asymmetrical current”. The breaking capacity depends on other factors such as: v voltage, v R/X ratio of the interrupted circuit, v power system natural frequency, v number of breaks at maximum current, for example the cycle: O - C/O - C/O (O = opening, C = closing), v device status after the test. The breaking capacity is a relatively complicated characteristic to define and it therefore comes as no surprise that the same device can be assigned different breaking capacities depending on the standard by which it is defined. Short-circuit making capacity In general, this characteristic is implicitly defined by the breaking capacity because a device should be able to close for a current that it can break. Sometimes, the making capacity needs to be higher, for example for circuit breakers protecting generators. The making capacity is defined in terms of the kA peak because the first asymmetric peak is the most demanding from an electrodynamic point of view. For example, according to standard IEC 60056, a circuit breaker used in a 50 Hz power system must be able to handle a peak making current equal to 2.5 times the rms breaking current. Prospective short-circuit breaking current Some devices have the capacity to limit the fault current to be interrupted. Their breaking capacity is defined as the maximum prospective breaking current that would develop during a solid short-circuit across the upstream terminals of the device.
Specific device characteristics The functions provided by various interrupting devices and their main constraints are presented in the table below. Device
Isolation
Disconnector
yes
Current switching conditions Normal Fault no no
Switch
no
yes
no
Contactor
no yes, if withdrawable
yes
no
Circuit breaker
no yes, if withdrawable no
yes
yes
no
yes
Fuse
18
Main constraints
Longitudinal input/output isolation Earthing switch: short-circuit making capacity Making and breaking of normal load current Short-circuit making capacity With a fuse: short-circuit breaking capacity in fuse no-blow zone Rated making and breaking capacities Maximum making and breaking capacities Duty and endurance characteristics Short-circuit breaking capacity Short-circuit making capacity Minimum short-circuit breaking capacity Maximum short-circuit breaking capacity
Sensors
Phase-current sensors (CT)
Protection and measuring devices require data on the electrical rating of the equipment to be protected. For technical, economic and safety reasons, this data cannot be obtained directly from the high-voltage power supply of the equipment. The following intermediary devices are needed: b phase-current sensors, b core balance CTs to measure earth fault currents, b voltage transformers (VT). These devices fulfill the following functions: b reduction of the value to be measured (e.g. 1500/5 A), b galvanic isolation, b provision of the power required for data processing and for the protection function itself.
The role of a phase-current sensor is to provide its secondary winding with a current proportional to the measured primary current. They are used for both measurements and protection. There are two types of sensors: b current transformers (CT), b current transformers with a voltage output (LPCT).
0
General characteristics (fig.1) The current transformer is made up of two circuits, the primary and the secondary, coupled by a magnetic circuit. When there are a number of turns in the primary circuit, the transformer is of the woundprimary type. When the primary is a single conductor running through a sensor, the transformer may be of the bar-primary type (integrated primary made up of a copper bar), support type (primary formed by an uninsulated conductor of the installation) or the toroidal type (primary formed by an insulated cable of the installation). The CTs are characterized by the following values (according to standard IEC 60044) (1). CT rated insulation level This is the highest voltage applied to the CT primary. Note that the primary is at the HV voltage level and that one of the secondary terminals is generally earthed. Similar to other equipment, the following values are defined: b maximum1 min. withstand voltage at power frequency, b maximum impulse withstand voltage. Example. For a 24 kV rated voltage, the CT must withstand 50 kV for 1 minute at 50 Hz and an impulse voltage of 125 kV. Rated transformation ratio It is usually given as the transformation ratio between primary and secondary current Ip/Is. The rated secondary current is generally 5 A or 1 A.
P1
Ip
0 3 3 5 5 E D
S1
Is
S2 P2 Ip: primary current Is: secondary current (proportional to Ip and in phase) Fig. 1. Current transformer.
Accuracy It is defined by the composite error for the accuracy-limit current. The accuracy-limit factor is the ratio between the accuracy-limit current and the rated current. b For class P: 5P10 means 5% error for 10 In and 10P15 means 10% error for 15 In, 5P and 10P are the standard accuracy classes for protection CTs, 5 In, 10 In, 15 In, 20 In are the standard accuracy-limit currents. b The PR class is defined by the remanence factor, the ratio between the remanent flux and the saturation flux, which must be less than 10%. 5PR and 10PR are the standard accuracy classes for protection CTs. b Class PX is another way of specifying CT characteristics based on the “knee-point voltage”, the secondary resistance and the magnetizing current (see next page, fig. 1, CT response in saturated state). Rated output This is the apparent power in VA that the CT is intended to supply to the secondary circuit at the rated secondary current without causing the errors to exceed the values specified. It represents the power consumed by all the connected devices and cables. If a CT is loaded at a power lower than its rated output, its actual accuracy level is higher than the rated accuracy level. Likewise, a CT that is overloaded loses accuracy. Short time withstand current Expressed in kA rms, the maximum current permissible for 1 second (Ith) (the secondary being short-circuited) represents the thermal withstand of the CT to overcurrents. The CT must be able to withstand the short-circuit current for the time required to clear it. If the clearing time t is other than 1 sec., the current the CT can withstand is Ith ⁄ t Electrodynamic withstand expressed in kA peak is at least equal to 2.5 • Ith Normal values of rated primary currents (in A): 10 - 12.5 - 15 - 20 - 25 - 30 - 40 - 50 - 60 - 75 and multiples or decimal submultiples. (1) Also to be taken into account are elements related to the type of assembly, characteristics of the site (e.g. temperature, etc.), power frequency, etc.
19
Phase-current sensors (CT)
Sensors
0
CT response in saturated state When subjected to a very high primary current, the CT becomes saturated. The secondary current is no longer proportional to the primary current. The current error which corresponds to the magnetization current increases significantly. Knee-point voltage (fig.1) This is the point on the current tr ansformer magnetization curve at which a 10% increase in voltage E requires a 50% increase in magnetization current Im. P1
N E 1 3 3 5 5 E D
E
Ip
R Vk C T + R w i r e + R l o a d
Is RCT S1
Rwire
Im E
Lm
Vs
Rload
10%
50%
S2 Imagnetizing
Isecondary P2 Fig. 1. Equivalent diagram of a CT secondary current...
Isat
Isn
Im at Vk
1.5 Im
and CT magnetization curve.
The CT secondary satisfies the equation: (RCT + Rload + Rwire) • ALF • Isn2 = constant where Isn = rated secondary current ALF = accuracy-limit factor Isat = ALF • Isn
CT for phase overcurrent protection For definite-time overcurrent protection, if saturation is not reached at 1.5 times the current setting, operation is ensured no matter how high the fault current (fig. 2). For IDMT overcurrent protection, saturation must not be reached at 1.5 times the current value corresponding to the maximum in the useful part of the operation curve (fig. 3). t
t
N E 2 3 3 5 5 E D
x 1.5
x 1.5
I Isetting
I
Isaturation
Fig. 2.
Iscmax
Isaturation
Fig. 3.
CT for differential protection (fig. 4) The CTs should be specified for each application, according to the operating principle of the protection unit and to the protected component. Refer to the instruction manual of the protection unit. N E 4 3 3 5 5 E D
Protected zone P1 P2
P2 P1
Differential protection Fig. 4.
20
Sensors
Phase-current sensors (LPCT)
0
Low-power current transducers (LPCT) (fig.1) P1 6 3 3 5 5 E D
Ip S1 Vs S2
P2 Fig. 1. LPCT-type current sensors.
These are special voltage-output sensors of the Low-Power Current Transducer (LPCT) type, compliant with standard IEC 60044-8. LPCTs are used for measurement and protection functions. They are defined by: b the rated primary current, b the rated extended primary current, b the rated accuracy-limit primary current. They have a linear output over a wide current range and begin to saturate at levels above the currents to be interrupted. Example of measurement characteristics as per IEC 60044-8 b Rated primary current Ipn = 100 A b Rated extended primary current Ipe = 1250 A b Secondary voltage Vsn = 22.5 mV b Class 0.5: v accuracy 0.5% from 100 A to 1250 A, v accuracy 0.75% at 20 A, v accuracy 1.5% at 5 A. Example of protection characteristics as per IEC 60044-8 b Primary current Ipn = 100 A b Secondary voltage Vsn = 22.5 mV b Class 5P from 1.25 kA to 40 kA (fig.2). Module (%) 5%
N E 7 3 3 5 5 E D
1.5% 0.75% Module
0.5%
Ip Phase (min) 90' 60' 45' Phase
30'
Ip 5A
20 A 100 A
1 kA
1.25 kA
10 kA
40 kA
Fig. 2. LPCT accuracy characteristics.
21
Residual-current sensors
Sensors
0
Zero-sequence current - residual current
I3 8 3 3 5 5 E D
The residual current characterizing the earth-fault current is equal to the vector sum of the 3 phase currents (fig.1). The residual current is equal to three times the zero-sequence current I0.
Irsd I1
I2
Irsd Fig. 1. Definition of residual current.
=
3 • I0
=
I1 + I2 + I3
Detection of the fault current Earth-fault current can be detected in a number of ways.
Measurement sensors
Special core balance CT
Accuracy
Recommended minimum threshold for earth-fault protection
+++
A few amperes
Assembly
N E 0 4 3 5 5 E D
Irsd
Direct measurement by special core balance CT connected directly to the protection relay. The CT is installed around the live conductors and directly creates the residual current. Toroidal CT + interposing ring CT
++
Neutral
51G 9 3 3 5 5 E D
51G Irsd
It can also be installed on the accessible neutral to earth link. The result is high measurement accuracy; a very low detection threshold (a few amperes) can be used. Neutral
10% of InCT (DT) 5% of InCT (IDMT)
N E 1 4 3 5 5 E D
51G 1 or 5 A
N E 2 4 3 5 5 E D
51G 1 or 5 A
Irsd
Irsd
Differential measurement using a classic toroidal CT installed around the live conductors and generating the residual current, plus an interposing ring CT used as an adapter for the protection relay. 3 phase CTs + interposing ring CT
++
10% of InCT (DT) 5% of InCT (IDMT)
N E 3 4 3 5 5 E D
51N
I1 I2
The toroidal CT can also be installed on the accessible neutral to earth link with an interposing ring CT. This solution offers good accuracy and flexibility in CT selection.
1 or 5 A
Measurement of the currents in the three phases with one CT per phase and measurement of the residual current by a special interposing ring CT.
I3
Irsd
Practically speaking, the residual-current threshold must be: b Is0 ≥ 10% InCT (DT protection), b Is0 ≥ 5% InCT (IDMT protection). 3 phase CTs (Irsd calculated by relay)
+
No H2 restraint 30% InCT (DT) 10% InCT (IDMT) With H2 restraint 10% InCT (DT) 5% InCT (IDMT)
22
4 4 3 5 5 E D
I1
51N
I2 I3
Calculation based on measurement of the currents in the three phases with one CT per phase. b The residual current is calculated by the protection relay. b Measurement accuracy is not high (sum of CT errors and saturation characteristics, calculated current). b Installation is easier than in the previous case, but measurement accuracy is lower. Practically speaking, the protection threshold settings must comply with the following rules: b Is0 ≥ 30% InCT for DT protection (10% InCT for a protection relay with H2 restraint), b Is0 ≥ 10% InCT for IDMT protection.
Sensors
Voltage transformers (VT)
The role of a voltage transformer is to provide its secondary winding with a voltage proportional to that applied to the primary circuit. Voltage transformers are used for both measurements and protection.
Measurement of phase-to-phase voltages
5 4 3 5 5 E D
0
The voltage transformer is made up of two windings, the primary and the secondary, coupled by a magnetic circuit, and connections can be made between phases or between a phase and earth. Voltage transformers are characterized by the following values: (publications IEC 60186, IEC 60044-2 and NFC 42-501) (1) b power frequency, generally 50 or 60 Hz, b highest primary voltage in the power system, b rated secondary voltage 100, 100/ 3, 110, 110/ 3 volts depending on the type of connection, b rated voltage factor used to define the heat-rise characteristics, b apparent power, in VA, that the voltage transformer can supply to the secondary, without causing errors exceeding its accuracy class, when connected to the rated primary voltage and to its rated load. Note that a VT must never be short-circuited on the secondary, because the power supplied increases and the transformer can be damaged by the resulting heat rise, b accuracy class defining the guaranteed error limits for the voltage ratio and phasedisplacement under the specified power and voltage conditions. A number of measurement assemblies are possible: b 3-transformer star assembly (fig. 1) (requires 1 insulated high-voltage terminal per transformer)
Fig. 1. Star-connected voltage transformers (VT).
6 4 3 5 5 E D
⁄ 3 Transformation ratio: -Un -------------------- for example 100 ⁄ 3 b 2-transformer “V” assembly, (fig. 2) (requires 2 insulated high-voltage terminals per transformer) Transformation ratio: Un ⁄ 100 for example In isolated neutral systems, all phase-neutral VTs sufficiently loaded to avoid the risk of ferromagnetic resonance. (1) Elements related to the type of assembly, characteristics of the site (e.g. temperature), etc. must also be taken into account.
Fig. 2. V-connected voltage transformers (VT).
Measurement of residual voltage
V3
The residual voltage characterizing the neutral-point voltage with respect to earth is equal to the vector sum of the 3 phase-to-earth voltages. The residual voltage is equal to three times the zero-sequence voltage V0:
7 4 3 5 5 E D
Vrsd
Vrsd V1
V2 Fig. 3. Definition of residual voltage.
=
3 • V0
=
V1 + V2 + V3 (fig. 3)
The occurrence of this voltage signals the existence of an earth fault. It can be measured or calculated: b measurement using three voltage transformers whose primaries are star connected and the secondaries, in an open delta arrangement, supply the residual voltage (fig. 4), b calculation by the relay, using three voltage transformers whose primaries and secondaries are star connected (fig. 5). 8 4 3 5 5 E D
59N
9 4 3 5 5 E D
V1
59N
V2 Vrsd V3
Fig. 4. Direct measurement of residual voltage.
Fig. 5. Calculation of residual voltage.
23
Protection functions
General characteristics
The protection relays that continuously monitor power system variables include combinations of basic functions to suit the power system components being monitored.
Operation
0
The relay includes (fig. 1): b analog measurement input for the variable observed, received from the sensor, b logic result of measurement processing (noted S), b instantaneous logic output of the protection function, used for indication, for example (noted Si), b delayed logic output of the protection function, used to control circuit breaker tripping (noted St).
Characteristics (fig. 2) 0 7 2 5 5 E D
I
I > Is
S
0
St Si
Fig. 1. Relay operating principle. (example of ANSI 51 phase overcurrent protection relay)
The protection function work mode involves characteristic times (IEC 60255-3): b operating time: this is the time between the application of the characteristic quantity (at twice the threshold setting) and the switching of the output relay (instantaneous output), b overshoot time: this is the difference between operating time and the maximum time during which the characteristic quantity can be applied with no tripping, b reset time: this is the time between a sudden decrease in the characteristic quantity and the switching of the output relay. Note: other non-standardized terms are commonly found as well, the definitions of which may vary from one manufacturer to another: reclaim time, no response time, instantaneous tripping time, memory time.
To improve stability, the functions have a drop out/pick up ratio d that is a % of the threshold setting: in the example in figure 3, S goes from 1 to 0 when I = d • Is N E 2 7 2 5 5 E D
I rms 2 Is
Threshold Is
t Si
Reset time
Operating time
1 t
0 I
Overshoot time
2 Is Is t Maximum no trip time Fig. 2. Protection function characteristic times.
1 7 2 5 5 E D
I Is d • Is t
S 1
0 Fig. 3. Drop out/pick up ratio.
24
t
Protection functions
General characteristics
0
Settings Some protection functions may be set by the user, in particular: b tripping set point: it sets the limit of the observed quantity that actuates the protection function. b tripping time: v definite time delay (DT) The example in figure 1, applied to a current relay, shows that above the current threshold Is, the protection tripping time is constant (time delay setting T). t N E 3 7 2 5 5 E D
Current threshold
No operation
Delayed operation
T Delay
I
Is Fig. 1. Definite time tripping principle.
v IDMT delay (IDMT: Inverse Definite Minimum Time)
The example in figure 2, applied to a current relay, shows that above the current threshold Is, the higher the current, the shorter the protection tripping time. t N E 4 7 2 5 5 E D
Current threshold
No operation
Delayed operation
T Delay
I
Is
10 • Is
Fig. 2. IDMT tripping principle.
There are several types of curves, determined by equations and defined by the various standardization organizations: for example, the IEC defines the following (fig. 3): - standard inverse time (SIT), - very inverse time (VIT), - extremely inverse time (EIT). t 5 7 2 5 5 E D
EIT VIT SIT
T I Is
10 • Is
Fig. 3. IDMT tripping curves.
b timer hold: adjustable reset time, b restraint: inhibition of tripping according to percentage of second harmonic, b time constants (e.g. thermal overload ANSI 49RMS), b characteristic angle (e.g. directional overcurrent ANSI 67).
25
Protection functions
List of functions
The main protection functions are listed with a brief definition in the table below. They are listed in numerical order by ANSI C37.2 code. ANSI code 12 14 21 21B 24 25 26 27 27D 27R
Name of function
Definition
Overspeed
Detection of rotating machine overspeed
Underspeed
Detection of rotating machine underspeed
Distance protection
Impedance measurement detection
Underimpedance
Back-up phase-to-phase short-circuit protection for generators
Flux control
Overfluxing check
Synchro-check
Check before paralleling two parts of the power system
Thermostat
Protection against overloads
Undervoltage
Protection for control of voltage sags
Positive sequence undervoltage
Protection of motors against operation with insufficient voltage
Remanent undervoltage
27TN 32P 32Q 37 37P 37Q 38 40 46 47 48 - 51LR
Third harmonic undervoltage
Check on the disappearance of voltage sustained by rotating machines after the power supply is disconnected Detection of stator winding insulation earth faults (impedant neutral)
Directional active overpower
Protection against active overpower transfer
49 49T 50 50BF 50N or 50G 50V
Instantaneous voltage-restrained phase overcurrent Inadvertent generator energization
50/27 51 51N or 51G
Directional reactive overpower
Protection against reactive overpower transfer
Phase undercurrent
3-phase protection against undercurrent
Directional active underpower
Protection against active underpower transfer
Directional reactive underpower
Protection against reactive underpower transfer
Bearing temperature monitoring
Protection against overheating of rotating machine bearings
Field loss
Protection of synchronous machines against faults or field loss
Negative sequence / unbalance
Protection against unbalanced phase current
Negative sequence overvoltage
Negative sequence voltage protection and detection of reverse rotation of rotating machines
Excessive starting time and locked rotor Thermal overload
Protection of motors against starting with overloads or reduced voltage, and for loads that can block Protection against overloads
RTDs
Protection against overheating of machine windings
Instantaneous phase overcurrent
3-phase protection against short-circuits
Breaker failure
Checking and protection if the circuit breaker fails to trip after a tripping order
Instantaneous earth fault
Protection against earth faults: 50N: residual current calculated or measured by 3 CTs 50G: residual current measured directly by a single sensor (CT or core balance CT) 3-phase protection against short-circuits with voltage-dependent threshold Detection of inadvertent generator energization
Delayed phase overcurrent
3-phase protection against overloads and short-circuits
Delayed earth fault
51V 59 59N 63 64REF 64G 66 67 67N/67NC
Delayed voltage-restrained phase overcurrent
Protection against earth faults: 51N: residual current calculated or measured by 3 CTs 51G: residual current measured directly by a single sensor (CT or core balance CT) 3-phase protection against short-circuits with voltage-dependent threshold
Overvoltage
Protection against excessive voltage or sufficient voltage detection
Neutral voltage displacement
Insulation fault protection
Pressure
Detection of transformer internal faults (gas, pressure)
Restricted earth fault differential
Earth fault protection for star-connected 3-phase windings with earthed neutral
100% generator stator earth fault
Detection of stator winding insulation earth faults (impedant neutral power systems)
Successive starts
Protection function that monitors the number of motor starts
Directional phase overcurrent
3-phase short-circuit protection according to current flow direction
Directional earth fault
78 78PS 79 81H 81L 81R 87B 87G 87L 87M 87T
Vector shift
Earth fault protection depending on current flow direction (NC: Neutral compensated) Vector shift disconnection protection
26
Pole slip
Detection of loss of synchronization of synchronous machines
Recloser
Automated device that recloses the circuit breaker after transient line fault tripping
Overfrequency
Protection against abnormally high frequency
Underfrequency
Protection against abnormally low frequency
Rate of change of frequency (ROCOF)
Protection for fast disconnection of two parts of the power system
Busbar differential
3-phase protection against busbar internal faults
Generator differential
3-phase protection against internal faults in AC generators
Line differential
3-phase protection against line internal faults
Motor differential
3-phase protection against internal faults in motors
Transformer differential
3-phase protection against internal faults in transformers
0
Protection functions
Associated functions
The protection functions are completed by the following: b additional control functions, b operation monitoring functions, b operation functions, b indication functions, b metering functions, b diagnosis functions, b communication functions, for enhanced operation of power systems. All of these functions may be provided by the same digital protection unit.
Switchgear control
0
This function controls the different types of switchgear closing and tripping coils.
Trip circuit supervision This function indicates switchgear trip circuit failures.
Control logic This function is used to implement logic discrimination by the sending and/or reception of “blocking signals” by different protection units.
Logic functions These functions perform logic equation operations to generate additional data or orders used for the application.
Operation functions These functions make operation more convenient for the user. b Transformer on-load tap changers, b Reactive energy regulation, b Fault locator (ANSI 21FL), b Capacitor bank control, b Remaining operating time before thermal overload tripping.
Metering functions These functions provide information required for a good understanding of power system operation. b Phase current, b Tripping current, b Residual current, b Differential and through currents, b Current THD (total harmonic distortion), b Phase-to-neutral and phase-to-phase voltages, b positive sequence, negative sequence and residual voltages, b Voltage THD (total harmonic distortion), b Frequency, b Active, reactive and apparent power, b Power factor (cos ϕ), b Active and reactive energy, b Peak demand current, active and reactive power, b Temperature, b Motor starting time, b Disturbance recording.
Switchgear diagnosis functions b Switchgear closing and fault tripping operation counters, b Operation time, b Charging time, b Sensor supervision (VT, CT); this function monitors the voltage or current
transformer measurement chain and acts on the related protection functions, b Cumulative breaking current (kA2).
Communication functions These functions are used for the exchange of available data by the different power system components (measurements, states, control orders…).
27
Discrimination
Time-based discrimination
Protection functions form a consistent system depending on the overall structure of the power distribution system and the neutral earthing arrangement. They should therefore be viewed as a system based on the principle of discrimination, which consists of isolating the faulty part of the power system and only that part as quickly as possible, leaving all the fault-free parts of the power system energized. Various means can be used to implement discrimination in power system protection: b time-based discrimination, b current-based discrimination, b discrimination by data exchange, referred to as logic discrimination, b discrimination by the use of directional protection functions, b discrimination by the use of differential protection functions, b combined discrimination to ensure better overall performance (technical and economic), or back-up.
Principle Time-based discrimination consists of assigning different time delays to the overcurrent protection units distributed through the power system. The closer the relay is to the source, the longer the time delay.
Operating mode The fault shown in the diagram opposite (fig. 1) is detected by all the protection units (at A, B, C, and D). The contacts of delayed protection unit D close faster than those of protection unit C, which themselves close faster than those of protection unit B… Once circuit breaker D tripped and the fault current has been cleared, protection units A, B and C, which are no longer required, return to the stand-by position. The difference in operation time ∆T between two successive protection units is the discrimination interval. It takes into account (fig. 2): b breaking time Tc of the downstream circuit breaker, which includes the breaker response time and the arcing time, b time delay tolerances dT, b upstream protection unit overshoot time: tr, b a safety margin m. ∆T should therefore satisfy the relation: ∆T ≥ Tc + tr + 2dT + m Considering present switchgear and relay performances, ∆T is assigned a value of 0.3 s. Example: Tc = 95 ms, dT = 25 ms, tr = 55 ms; for a 300 ms discrimination interval, the safety margin is 100 ms. N E 2 4 2 5 5 E D
TB
TA
t dTB
N E 1 4 2 5 5 E D
TcB
m
trA
dTA
Discrimination interval ∆T
Fig. 2. Breakdown of a discrimination interval.
A
B
51
51
TA = 1.1 s
TB = 0.8 s
Advantages This discrimination system has two advantages: b it provides its own back-up; for example if protection unit D fails, protection unit C is activated ∆T later, b it is simple.
Drawbacks C
D
51
51
TC = 0.5 s
TD = 0.2 s
Phase-to-phase fault
Fig. 1. Time-based discrimination principle.
28
0
However, when there are a large number of cascading relays, since the protection unit located the furthest upstream has the longest time delay, the fault clearing time becomes prohibitive and incompatible with equipment short-circuit current withstand and external operating necessities (e.g. constraint imposed by utility).
Discrimination
Time-based discrimination
0
Application This principle is used in radial power systems. (fig. 1) 3 4 2 5 5 E D
The time delays set for time-based discrimination are activated when the current exceeds the relay settings. The settings must be consistent. There are two cases, according to the type of time delay used. A
51
IsA, TA
Definite time relays (fig. 2) The conditions to be fulfilled are: IsA > IsB > I sC et TA > TB > TC. The discrimination interval ∆T is conventionally in the range of 0.3 seconds. B
51
IsB, TB N E 4 4 2 5 5 E D
C
51
t
C
B
A
IsC, TC TA ∆T
TB ∆T
Fig. 1. Radial power system with time-based discrimination.
TC I IsC IsB
IsA
IscC IscB IscA max max max
Fig. 2. Time-based discrimination with definite time relays.
IDMT relays (fig. 3) If the thresholds are set to the rated current In, overload protection is ensured at the same time as short-circuit protection and setting consistency is guaranteed. InA > InB > InC IsA = InA, lsB = I nB, and IsC = InC The time delays are set to obtain the discrimination interval ∆T for the maximum current seen by the downstream protection relay. The same family of curves is used to avoid overlapping in a portion of the domain.
5 4 2 5 5 E D
t
C
B
A
∆T
∆T
I IsC IsB
IsA
IscC IscB IscA max max max
Fig. 3. Time-based discrimination with IDMT relays.
29
Current-based discrimination
Discrimination
Principle Current-based discrimination uses the principle that within a power system, the further the fault is from the source, the weaker the fault current is.
Operating mode A current protection unit is installed at the starting point of each section: the threshold is set to a value lower than the minimum short-circuit current caused by a fault in the monitored section, and higher than the maximum current caused by a fault downstream (outside the monitored area).
Advantages With these settings, each protection device is only activated by faults located immediately downstream, within the monitored zone, and is not sensitive to faults outside that zone. For sections of lines separated by a transformer, it can be of benefit to use this system since it is simple, cost-effective and quick (tripping with no delay). An example is given below (fig.1): IscBmax < IsA < IscAmin IsA = current setting IscB on the transformer primary is proportional to the maximum short-circuit current on the secondary. Time delays TA and TB are independent, and TA may be shorter than TB.
Drawbacks The upstream protection unit (A) does not provide back-up for the downstream protection unit (B). In practice, it is difficult to define the settings for two cascading protection units, and still ensure satisfactory discrimination, when there is no notable decrease in current between two adjacent areas. This is the case in medium voltage power systems, except for sections with transformers.
Application The following example concerns current protection of a transformer between two cable sections. The overcurrent protection setting Is satisfies the relation: 1.25 IscBmax < IsA < 0.8 IscAmin Discrimination between the two protection units is ensured. t
N E 6 4 2 5 5 E D
IscAmin
A
51
IsA, TA
B
A
IscBmax
A
51
IsA, TA
TB TA
I IsB
IscB max
Discrimination curves
B
Condition IsA < IscAmin
51
IsB, TB
Condition IsA > IscBmax
Fig. 1. Current-based discrimination operation.
30
IsA
IscA min
0
Discrimination
Logic discrimination
0
Principle This system was developed to solve the drawbacks of time-based discrimination. This principle is used when short fault clearing time is required (fig. 1).
N E 7 4 2 5 5 E D
Operating mode
51
51
Blocking signal
The exchange of logic data between successive protection units eliminates the need for discrimination intervals, and thereby considerably reduces the tripping time of the circuit breakers closest to the source. In radial power systems, the protection units located upstream from the fault are activated; those downstream are not. The fault point and the circuit breaker to be tripped can therefore be clearly located. Each protection unit activated by a fault sends: b a blocking signal to the upstream level (an order to increase the upstream relay time delay), b a tripping order to the related circuit breaker unless it has already received a blocking signal from the downstream level. Time-delayed tripping is provided as back-up. The principle is illustrated in figure 2: b when a fault appears downstream from B, the protection unit at B blocks the protection unit at A, b only the protection unit at B triggers tripping after the delay TB, provided it has not received a blocking signal, b the duration of the blocking signal for the protection unit at A is limited to TB + T3, with T3 ≥ opening and arc extinction time of circuit breaker B (typically 200 ms), b if circuit breaker B fails to trip, protection unit A gives a tripping order at TB + T3, b when a fault appears between A and B, protection unit A trips after the delay TA.
51
51 Phase-to-phase fault
Advantages Fig. 1. Logic discrimination principle.
N E 8 4 2 5 5 E D
Tripping time is not related to the location of the fault within the discrimination chain or to the number of protection units in the chain. This means that discrimination is possible between an upstream protection unit with a short time delay and a downstream unit with a long time delay. For example, a shorter time delay may be used at the source than near the loads. The system also has back-up designed into it.
Drawbacks A
TA IsA inst.
Blocking signal
TB + T3 (back-up) B
IsB
TB inst.
Since logic signals must be transmitted between the different levels of protection units, extra wiring must be installed. This can be a considerable constraint when the protection units are far apart each other, in the case of long links, for example (several hundreds of meters long). This difficulty may be bypassed by combining functions: logic discrimination in the nearby switchboards and time-based discrimination between zones that are far apart (refer to chapter on combined logic + time-based discrimination).
Application This principle is often used to protect medium voltage power systems that include radial branches with several levels of discrimination.
Fig. 2. Logic discrimination operation.
31
Directional protection discrimination
Discrimination
Principle In a looped power system, in which faults are fed from both ends, it is necessary to use a protection unit that is sensitive to the direction of the flow of fault current in order to locate and clear the fault selectively. This is the role of directional overcurrent protection units.
Cable
N E 9 4 2 5 5 E D
Operating mode 67
The protection actions differ according to the direction of the current (figs. 1 and 2), i.e. according to the phase displacement of the current in relation to a reference given by the voltage vector; the relay therefore needs both current and voltage data. The operating conditions, namely the position of the tripping and no tripping zones, are adapted to fit the power system to be protected (fig. 3).
Is, T
I
Vref
Example of the use of directional protection units (fig. 4): Circuit breakers D1 and D2 are equipped with directional protection units that are activated if the current flows from the busbars to the cable. If a fault occurs at point 1, it is only detected by the protection unit at D1. The protection unit at D2 does not detect it, because of the detected current direction. The D1 circuit breaker trips. If a fault occurs at point 2, it is not detected by these protection units and the D1 and D2 circuit breakers remain closed. Other protection units must be included to protect the busbars.
Busbar Directional protection principle Fig. 1. Protection unit active.
N E 0 5 2 5 5 E D
Cable
Advantage 67
Is, T
The solution is simple and may be used in a large number of cases.
I
Drawback Voltage transformers must be used to provide a phase reference to determine the direction of the current.
Vref
Application
Busbar
This principle is used to protect parallel incomers and closed loop power systems and also for certain cases of earth fault protection. Directional protection principle Fig. 2. Protection unit not active.
Cable
N E 2 5 2 5 5 E D
Tripping zone
N E 1 5 2 5 5 E D
I busbars V cable
Cable
No tripping zone
Vref
1
67
67 Vref
I cable V busbars
D1
D2
Busbars
2 Directional protection principle Fig. 3. Detection of current direction.
32
Directional protection Fig. 4. Example of two parallel incomers.
0
Differential protection discrimination
Discrimination
0
Principle These protection units compare the current at the two ends of the monitored section of the power system (fig. 1).
N E 3 5 2 5 5 E D
Operating mode
A
Any amplitude or phase difference between the currents indicates the presence of a fault: The protection units only react to faults within the area they cover and are insensitive to any faults outside that area. This type of protection is therefore selective by nature. Instantaneous tripping takes place when IA-IB ≠ 0 In order for differential protection to work, it is necessary to use current transformers specifically sized to make the protection units insensitive to other phenomena.
IA
Protected zone
87
What makes differential protection units stable is that they do not pick up as long as there are no faults in the zone being protected, even if a differential current is detected: b transformer magnetizing current, b line capacitive current, b error current due to saturation of the current sensors.
IB
B
There are two main principles according to the stabilization mode: r elay is series-connected to a stabilization b high impedance differential protection: the relay resistor Rs in the differential circuit (figs. 2 and 3), b percentage-based differential protection: the relay is connected independently to the circuits carrying the currents IA and IB. The difference between the currents IA and IB is determined in the protection unit and the protection stability is obtained obtained by a restraint related to the through current (figs. 4 and 5).
Fig. 1. Differential protection principle.
IA
I differential
IB Protected zone
N E 4 5 2 5 5 E D
N E 6 5 2 5 5 E D
Is
Constant threshold
I through
Rs ∆I
Fig. Fig. 2. High High impe impeda danc nce e dif diffe fere rent ntia iall pro prote tect ctio ion n dia diagr gram am.. IA N E 5 5 2 5 5 E D
Fig. Fig. 3. Stab Stabil ilit ity y by by res resis ista tanc nce. e. I differential
IB Protected zone
N E 7 5 2 5 5 E D
Threshold % It Is
∆I/I
Fig. Fig. 4. Per Perce cent ntag agee-ba base sed d diffe differe rent ntia iall prote protect ctio ion n diagr diagram am..
I through
Fig. Fig. 5. Sta Stabi bili lity ty b by y restr restrai aint nt..
Advantages b Protection sensitive to fault current less than the rated current of the protected equipment. b Zone protection that can trip instantaneously.
Drawbacks b The cost of the installation is high. b It takes skill to implement the system. b An overcurrent back-up function needs to be included.
Comparison of the two principles b High impedance differential protection: v the upstream and downstream CTs must have the same r ated currents (primary
and secondary), v the resistance of the stabilization resistor is chosen to avoid tripping by external faults with a saturated CT and to allow the relay to be supplied by the CT, v The relay is relatively simple, but requires the use of stabilization resistors. b Percentage-based differential protection: v can be adapted to fit the equipment to be protected, v the relay is relatively more complicated, but is easy to use.
Application Differential protection may concern all priority high power components: motors, generators, transformers, busbars, cables and lines.
33
Discrimination
Combined discrimination
Combined discrimination is a combination of basic discrimination functions that provides additional advantages in comparison to individual types of discrimination. total discrimination, b total b redundancy redundancy or back-up.
Several practical examples of applications using combined discrimination are given below: current-based + time-based, b current-based logic + time-based, b logic time-based + directional, b time-based b logic logic + directional, b differential differential + time-based.
0
Current-based + time-based discrimination N E 8 5 2 5 5 E D
The example shows an arrangement with both of the following: b current-based discrimination between A1 and B, b time-based discrimination between A2 and B. 51 51
A
This provides total discrimination, and the protection unit at A provides back-up for the protection unit at B.
IsA1, TA1 IsA2, TA2
t
B
A
N E 9 5 2 5 5 E D
Protected zone
TA2 ∆T
TB 51
B
IsB, TB
TA1 I
Fig. 1. Current-based + time-based discrimination.
IsB
IsA2
IscB
IsA1
IscA
Logic + back-up time-based discrimination 0 6 2 5 5 E D
The example shows an arrangement with both of the following: b logic discrimination between A1 and B, b time-based discrimination between A2 and B. IsA, TA1 51
A
The A2 protection unit provides back-up for the A1 protection unit, if A1 fails to trip due to a blocking signal fault (permanent blocking signal).
IsA, TA2 51
t
B
A
N E 1 6 2 5 5 E D
TA2 ∆T
IsB
B
TB
TB T=0
TA1 I
Fig. 2. Logic + back-up time-based discrimination.
IsB
IsA
IscB
IscA
Logic + time-based discrimination N E 2 6 2 5 5 E D
The example shows an arrangement with both of the following:
51
Combined Time-based discrimination discrimination 0.1 s 1.3 s
51
0.7 s
1.0 s
51
0.1 s
0.7 s
51
0.4 s
0.4 s
A
B
C
D
Fig. 3. Comparison of combined (logic + time-based) discrimination and time-based discrimination tripping times.
34
b logic discrimination inside a switchboard
(between A and B and between C and D). b time-based discrimination between two switchboards B and D, with TB = TD + ∆T.
It is not necessary to install a logic signal transmission link between two switchboards that are far apart. The tripping delays are shorter than with time-based discrimination discrimination alone (fig. 3). b back-up time-based discrimination needs to be included at points A and C (refer to the paragraph above).
Combined discrimination
Discrimination
0
Time-based + directional discrimination 3 6 2 5 5 E D
H1
H2
1
51
51
67
67
D1
D1 and D2 are equipped with short time-delayed directional protection units; H1 and H2 are equipped with time-delayed overcurrent protection units. If a fault occurs at point 1, it is only detected by the D1 (directional), H1 and H2 protection units. The protection unit at D2 does not detect it, because of the detected current direction. D1 trips. The H2 protection unit drops out, H1 trips and the faulty section H1-D1 is isolated. TH1 = TH2 TD1 = TD2 TH = TD + ∆T
D2
Fig. 1. Time-based + directional discrimination. discrimination.
N E 4 6 2 5 5 E D
51 D1
Logic + directional discrimination
BSIG 51 D2
67
The example shows that the orientation of blocking signals depends on the direction of the current flow. This principle is used for busbar coupling and closed loops. Fault at D2 end: b tripping at D2 and B, b D1 is blocked by B ( BSIG: blocking signal).
Vref B
51 BSIG D1
51 D2
67
Fault at D1 end: b tripping at D1 and B, b D2 is blocked by B ( BSIG: blocking signal).
Vref B Fig. 2. Logic + directional discrimination.
Differential + time-based discrimination N E 5 6 2 5 5 E D
The example shows an arrangement with both of the following: b instantaneous differential protection, b a phase overcurrent or earth fault protection unit at A as back-up for the differential A
51
This provides back-up for the differential protection function, but double-wound current transformers are sometimes necessary.
Protected zone
B
protection unit, b a current protection unit at B to protect the downstream zone, b time-based discrimination between the protection units at A and B, with TA = TB + ∆T.
IsA, TA
87
51
Note: time-based discrimination may be replaced by logic discrimination.
IsB, TB
Fig. 3. Differential + time-based discrimination. discrimination.
35
Power-system protection
Single-incomer power systems
Power-system protection should: b detect faults, b isolate the faulty parts of the power system, keeping the fault-free parts in operation. Protection units are chosen according to the power-system configuration (parallel operation of generators or transformers, loop or radial power system, neutral earthing arrangement…). Consideration must be given to: b phase-to-phase fault protection, b earth fault protection, linked to the neutral earthing arrangement. The following types of systems will be examined: single-incomer, dual-incomer, open loops and closed loops.
Phase-to-phase faults (fig. 1)
0
The incomer and feeders are equipped with phase overcurrent protection units (ANSI 51). Time-based discrimination is used between the incomer protection unit (A) and the feeder protection units (D). The protection unit at D detects fault 1 on the feeder and trips circuit breaker D after a delay TD. The protection unit at A detects fault 2 on the busbars and trips after a delay TA. It also acts as back-up should protection D fail. Choose: IsA ≥ IsD and TA ≥ TD + ∆T ∆T: discrimination interval (generally 0.3 s). The protection unit at D must be selective in relation to the downstream protection units: if the delay required for protection A is too long, logic or combined (logic + time-based) discrimination should be used.
Phase-to-earth faults Resistance earthing on the transformer (fig.2) Earth fault protection units (ANSI 51N) are installed on the feeders, incomer and neutral earthing connection. Time-based discrimination is used between the different protection units. These units are necessarily different from phase fault protection units since the fault currents are in a different range. The feeder protection units are set selectively in relation to the incomer protection unit, which is itself set selectively in relation to the neutral earthing protection unit (in accordance with discrimination intervals). The fault current flows through the capacitances of the fault-free feeders and the earthing resistance. All the fault-free feeder sensors detect capacitive current. To prevent inadvertent tripping, the protection unit on each feeder is set higher than the feeder’s capacitive current. b fault at 3: the D1 circuit breaker is tripped by the protection unit linked to it, b fault at 4: the A circuit breaker is tripped by the incomer protection unit, b fault at 5: the protection unit on the neutral earthing connection trips circuit breaker H on the transformer primary circuit. (fig. 1). The protection unit at D must be selective in relation to the downstream protection units: if the delay required for protection A is too long, logic discrimination should be used. The neutral earthing protection unit at H acts as back-up should the incomer protection unit at A fail to trip. The incomer protection unit at A acts as back-up should a feeder protection unit at D fail to trip.
0 3 2 5 5 E D
t
51
D
N E 1 3 2 5 5 E D
A
H t
51G
A
H
TH
5
IsA, TA
D
∆T
51G
TA
TA
∆T
A
∆T
A
TD
TD
I
2
I
IsD IsA
IsD IsA IsH
4
D 51
IsD, TD
D3
D2 51G
51G
51G
3
1
I fault
D1
Capacitive current Resistive current
Fig. 1. Phase-to-phase fault protection.
36
Fig. 2. Phase-to-earth fault protection (resistance-earthed neutral at transformer).
Power-system protection
Single-incomer power systems
0
Phase-to-earth faults (cont’d) 2 3 2 5 5 E D
Resistance-earthed neutral at busbars (fig. 1) A zero sequence generator is used for resistance-earthing. Earth fault protection units (ANSI 51G) are installed on the feeders, incomer and zero sequence generator. Time-based discrimination is used between the different protection units. The feeder protection units and incomer protection unit are set selectively in relation to the earthing impedance protection unit. As in the previous case, the protection unit on each feeder is set higher than the feeder's capacitive current. In the event of a fault on feeder 1, only the D1 feeder circuit breaker trips. In the event of fault on the busbars 2, only the protection unit on the earthing connection detects the fault. It trips circuit breaker A. In the event of fault on the transformer secondary circuit 3, the incomer protection units detects the fault. It trips circuit breaker H. Note: when circuit breaker A is open, the transformer secondary circuit neutral is isolated. It may be necessary to protect it by a neutral voltage displacement measurement (ANSI 59N).
H
3 51G IsA, TA A
2
D2
D1 51G
51G IsD, TD
51G
1
The zero sequence generator protection unit acts as back-up should the incomer protection unit at A or a feeder protection unit at D fail to trip. If the condition IsD > 1.3 Ic cannot be satisfied for a feeder, a directional earth fault protection unit may be used to discriminate between fault current and capacitive current. Reactance-earthed neutral The same procedure is used as for resistance-earthing at the transformer or busbars.
Fig. 1. Phase-to-earth fault protection (resistance-earthed neutral at busbars).
N E 3 3 2 5 5 E D
CP I 59N
Isolated neutral (fig. 2) A fault, regardless of its location, produces current which flows through the capacitance of the fault-free feeders. In industrial power systems, this current is generally weak (a few amperes), allowing operations to carry on while the fault is being tracked. Time-based discrimination is used between the different protection units. The fault is detected by an insulation monitoring device or a neutral voltage displacement protection unit (ANSI 59N). When the total capacitive current of a power system is high (in the range of ten amperes), additional measures must be taken to quickly clear the fault. Directional earth fault protection can be used to selectively trip the fault feeder. Solidly earthed neutral This is similar to r esistance-earthing at the transformer, but the capacitive currents are negligible compared to the fault current, so the protection function is simpler to implement. Compensated neutral The power system is earthed at the transformer. Faults are detected by a specific directional earth fault protection unit (ANSI 67NC), which monitors the active residual current and recognizes faults during their initial transient phase.
Fig. 2. Phase-to-earth fault protection (isolated neutral).
37
Power-system protection
Dual-incomer power systems
0
Phase-to-phase faults (fig. 1) 4 3 2 5 5 E D
H1
H2 51 TH
51 TH
T1
T2
3 67 51
TR TA
67 51
A1
TR TA
A2
2 D1
D2 51 TD
51 TD
Power system with two transformer incomers or two line incomers The feeders are equipped with phase overcurrent protection units with delays set to TD. The two incomers A1 and A2 are equipped with phase overcurrent protection units (ANSI 51) set selectively in relation to the feeders, i.e. TA ≥ TD + ∆T. They are also equipped with directional protection units (ANSI 67) with delays set at TR < TA – ∆T. Time-based discrimination is used between the incomer A protection units and feeder D protection units. Current-based discrimination is used between the power supply H protection units and incomer A protection units. This means that a fault at 1 is cleared by the tripping of D2 after a delay TD. A fault at 2 is cleared by the tripping of A1 and A2 with a delay of TA (the directional protection units do not detect the fault). A fault at 3 is detected by the A1 directional protection unit which trips at the time TR, allowing continued operation of the fault-free part of the power system. However, the fault at 3 is still fed by T1. At the time TH ≥ TA + ∆T, H1 is tripped by the phase overcurrent protection unit linked to it.
Phase-to-earth faults (fig. 2) 1 Fig. 1. Phase-to-phase fault protection.
5 3 2 5 5 E D
H1
H2 51G TN
51G TN
6 67N
TR
A1
67N
TR
A2
5 D1
D2 51G TD
D3 51G TD
51G TD
4 Fig. 2. Phase-to-earth fault protection (resistance-earthed neutral at the transformer).
Resistance-earthed neutral at incomer transformers Earth fault protection units (ANSI 51G) are installed on the feeders and set higher than the corresponding capacitive currents, with delays of TD. Directional earth fault protection units (ANSI 67N) are installed on incomers A1 and A2, with time delays of TR. Earth fault protection units (ANSI 51G) are installed on the earthing connections and set higher than the incomer and feeder protection units, with time delays such that TN ≥ TD + ∆T. Time-based discrimination is used between the different protection units. This means that a fault at 4 is cleared by the tripping of D1. A fault at 5 is cleared by the tripping of A1, A2, H1 and H2 by the protection units located on the neutral earthing connections of the 2 transformers. A fault at 6 is detected by the A1 directional protection unit which trips at the time TR, allowing continued operation of the fault-free part of the power system. However, the fault at 6 continues to be supplied up to the time TN at which the protection unit on the corresponding transformer earthing connection trips the H1 circuit breaker. Resistance-earthed neutral at the busbars A zero sequence generator is used for resistance-earthing. Earth fault protection units are installed on the feeders, incomers and zero sequence generator. Time-based discrimination is used between the different protection units. The system operates in the same way as in single-incomer power systems. Isolated neutral The system operates in the same way as in single-incomer power systems. Solidly earthed neutral This is similar to r esistance-earthing, but the phase-to-earth current is higher and reaches the phase-to-phase current level. Compensated neutral Only one earthing coil is in service at a given time to ensure power system capacitance matching; this is similar to single-incomer power systems.
38
Power-system protection
Dual-incomer power systems
0
Additional protection functions Coupling (fig. 1) The synchro-check function (ANSI 25) is used to check that the circuits to be connected have voltage amplitude, phase and frequency differences within acceptable limits to allow closing of the coupling circuit breaker.
G
6 3 2 5 5 E D
Decoupling When electrical installations are supplied by the utility and an independent power source, interference between the two sources as a result of events such as a utility failure or earth faults should be avoided. The consequences include voltage and frequency fluctuations and current and power exchanges between the different circuits. Protection functions are often advocated or imposed in the distributors’ technical guides. There are several methods of decoupling two sources: b monitoring of the active power direction and protection by a reverse power protection relay (ANSI 32P), b monitoring of voltage amplitude and under or overvoltage protection (ANSI 27 or 59), b monitoring of frequencies and underfrequency (ANSI 81L) or overfrequency (ANSI 81H) protection, b protection against phase shifts caused by faults (ANSI 78), b monitoring of frequency variations and ROCOF (rate of change of frequency) protection (ANSI 81R) with respect to a threshold. This protection function is faster than the frequency protection functions and more stable than phase shift protection.
25 Fig. 1. Power system coupling protection.
N E 7 3 2 5 5 E D
Source 1
Source 2 27
59
50 50N C O
C O C
M 27R
Automatic source transfer (fig. 2) The system in figure 2 shows an installation with two busbars normally supplied by two sources with the coupling open (2/3 configuration). If source 1 is lost, the power system is reconfigured. Source 1 is opened and the coupling is closed; this automatic source transfer takes place according to a procedure: b initialization of the transfer by the detection of undervoltage (ANSI 27) on source 1 resulting in opening of the source 1 circuit breaker: Us = 70% Un, b inhibition of transfer if a fault is detected downstream from source 1 by an overcurrent protection unit (ANSI 50 and 50N), b enabling of transfer after the disappearance of voltage sustained by rotating machines is checked by the remanent undervoltage protection unit (ANSI 27R): Us = 25% Un, b enabling of transfer after verification that there is sufficient voltage (ANSI 59) on source 2 and closing of coupling circuit breaker: Us = 85% Un.
Fig. 2. Automatic source transfer.
39
Power-system protection
Open loop power systems
In distribution systems that include substations supplied in open loops, protection is provided at the head of the loop.
The power system is operated as an open loop and protection is provided at the ends of the loops, which are equipped with circuit breakers (fig. 1). The switching devices used on the substations are switches. Faults cause power outages. Phase overcurrent and earth fault protection units (ANSI 51 and 51N) are installed on the circuit breakers at the head of each loop. A fault occurring in a cable that connects 2 substations may trip either of these circuit breakers depending on the position of the loop opening. The protection is often completed by an automated device that: b clears the fault (with the power off) by opening the devices located at the ends of the faulty cable, after the faulty cable has been located by the fault detector, b closes the circuit breaker that has tripped at the head of the loop, b closes the device that ensured the normal opening of the loop in order to restore power to the fault-free downstream half of the loop. The power system can be put back into its initial operating state after the faulty circuit has been repaired. The outage may last from a few seconds to a few minutes depending on whether the loop is reconfigured automatically or manually.
N E 8 3 2 5 5 E D
51 51N C
C
C
C
C
C
C
C O
Fig. 1. Open loop protection principle.
40
51 51N
C
0
Power-system protection
Closed loop power systems
In distribution systems that include substations supplied in closed loops, protection is provided for different sections.
The power system may be operated in closed loops, with each section protected by circuit breakers at the ends of the section. Most faults do not cause power outages. Various protection solutions may be used.
0
Differential protection (fig. 1) Each cable is equipped with a line differential protection unit (ANSI 87L) and each substation is equipped with a busbar differential protection unit (ANSI 87B). This type of protection is very quick. If the neutral is resistance-earthed, the sensitivity of the differential protection units must cover phase-to-earth faults. N E 9 3 2 5 5 E D
C
C
87L
87L
C
C 87B
87B
C
C
Fig. 1. Closed loop differential protection.
Overcurrent protection and directional logic discrimination (fig. 2) The circuit breakers in the loop are equipped with overcurrent and directional protection units. Logic discrimination is used to clear faults as quickly as possible. A fault in the loop activates: b all the protection units if the loop is closed, b all the protection units upstream from the fault when the loop is open. Each protection unit sends a blocking signal to one of the adjacent units in the loop, according to the data transmitted by the directional protection unit. Protection units that do not receive a blocking signal trip with a minimum delay that is not dependent on the fault’s position in the loop: b the fault is cleared by two circuit breakers, one on either side of the fault if the loop is closed, and all the switchboards remain energized, b the fault is cleared by the upstream circuit breaker if the loop is open. This solution is a comprehensive one since it protects cables and busbars. It is fast, selective and includes back-up protection. 0 4 2 5 5 E D
51 51N
51 51N
67 67N
67 67N
67 67N
67 67N
67 67N
67 67N
67 67N
67 67N
Fig. 2. Loop overcurrent protection and directional logic discrimination.
41
Types of faults and protection functions
Busbar protection
Busbars are electrical power dispatching nodes that generally have more than two ends. Specific busbar protection may be provided in a variety of ways, using basic functions.
N E 1 8 2 5 5 E D
A
2 51 51N TB = 0.4 s
1 51 TC = 0.1 s 51N
C
Fig. 1. Time-based discrimination.
N E 2 8 2 5 5 E D
TA1 = 0.1 s 51
A
TA2 = 0.7 s 51
4 TB = 0.4 s
51
B
3
C
51
TC = 0.1 s
Fig. 2. Logic discrimination.
3 8 2 5 5 E D
Rs 51
51
Fig. 3. Differential protection.
42
51
Overcurrent protection The use of time-based discrimination with the overcurrent (ANSI 51) and earth fault (ANSI 51N) protection functions may quickly result in excessive fault clearing time due to the number of levels of discrimination. In the example (fig. 1), protection unit B trips in 0.4 s when there is a busbar fault at point 1 ; when a busbar fault occurs at point 2, protection unit A trips in 0.7s, since the discrimination interval is set to 0.3 s. The use of logic discrimination (fig. 2) with overcurrent protection provides a simple solution for busbar protection. A fault at point 3 is detected by protection unit B, which sends a blocking signal to protection unit A. Protection unit B trips after 0.4 s. However, a fault at point 4 is only detected by protection unit A, which trips after 0.1 s; with backup protection provided if necessary in 0.7 s.
51 51N TA = 0.7 s
B
Phase-to-phase and phase-to-earth faults
87B
51
Differential protection Differential protection (ANSI 87B) is based on the vector sum of the current entering and leaving the busbars for each phase. When the busbars are fault-free, the sum is equal to zero, but when there is a fault on the busbars, the sum is not zero and the busbar supply circuit breakers are tripped. This type of protection is sensitive, fast and selective. b With percentage-based, low impedance differential protection, the difference is calculated directly in the relay. The threshold setting is proportional to the through current and CTs with different ratios may be used. However, the system becomes complicated when the number of inputs increases. b With high impedance differential protection (fig. 3), the difference is calculated in the cables, and a stabilization resistor is installed in the differential circuit. The CTs are sized to account for saturation according to a rule given by the protection relay manufacturer. The threshold setting is approximately 0.5 CT In and it is necessary to use CTs with the same ratings.
0
Busbar protection
Types of faults and protection functions
0
Load shedding function The load shedding function is used when a shortage of available power in comparison to the load demand causes an abnormal drop in voltage and frequency: certain consumer loads are disconnected according to a preset scenario, called a load shedding plan, in order to recover the r equired power balance. Different load shedding criteria may be chosen: b undervoltage (ANSI 27), b underfrequency (ANSI 81L), b rate of change of frequency (ANSI 81R).
Breaker failure The breaker failure function (ANSI 50BF) provides backup when a faulty breaker fails to trip after it has been sent a trip order: the adjacent incoming circuit breakers are tripped. The example (fig. 1) shows that when a fault occurs at point 1 and the breaker that has been sent the trip order fails, the breaker failure protection function is faster than action by upstream protection time-based discrimination: 0.6 s instead of 0.7 s.
51
N E 4 8 2 5 5 E D
0.7 s
51
0.7 s
Faulty breaker 51 0.4 s
50BF 0.2 s
51
50BF
51
50BF
1 Fig. 1. Breaker failure.
43
Link (line and cable) protection
Types of faults and protection functions
The term “link” refers to components designed to convey electrical power between two points that are several meters to several kilometers apart: links are generally overhead lines with bare conductors or cables with insulated conductors. A specific type of protection is required for links.
Thermal overload Protection against overheating due to overload currents in conductors under steady state conditions is provided by the thermal overload protection function (ANSI 49RMS), which estimates temperature buildup according to the current measurement.
Phase-to-phase short circuits b Phase overcurrent protection (ANSI 51) may be used to clear the fault,
the time delay being set to provide discrimination. A distant 2-phase fault creates a low level of overcurrent and an unbalance; a negative sequence / unbalance protection function (ANSI 46) is used to complete the basic protection function (fig. 1). b To reduce fault clearance time, a percentage-based differential protection function (ANSI 87L) may be used. It is activated when the differential current is equal to more than a certain percentage of the through current. There is a relay at either end of the link and information is exchanged by the relays via a pilot (fig. 2). N E 5 8 2 5 5 E D
6 8 2 5 5 E D
46 51 51N or 67N
87L
87L
Fig. 1. Link protection by overcurrent relay.
Fig. 2. Link protection by differential relays.
Phase-to-earth short circuits Time-delayed overcurrent protection (ANSI 51N) may be used to clear faults with a high degree of accuracy (fig. 1). For long feeders though, with high capacitive current, the directional earth fault protection function (ANSI 67N) allows the current threshold to be set lower than the capacitive current in the cable as long as system earthing is via a resistive neutral.
44
0
Types of faults and protection functions
Link (line and cable) protection
0
Distance protection Distance protection (ANSI 21) against faults affecting line or cable sections is used in meshed power systems (parallel links, several sources). It is selective and fast, without requiring time-based discrimination. Sensitivity depends on the short-circuit power and the load. It is difficult to implement when the type of link is not the same throughout (overhead line + cable). It operates according to the following principle: b measurement of an impedance proportional to the distance from the measurement point to the fault, b delimitation of impedance zones which represent line sections of different lengths (fig.1), b tripping by zone with time delay.
N E 9 7 2 5 5 E D
21
A
21
0%
The example in figure 2 shows the following for the protection unit at point A in line section AB: b an impedance circle at 80% of the length of the line (zone 1), inside which tripping is instantaneous, b an impedance band between 80% and 120% of the length of the line (zone 2), in which tripping is delayed (200 ms), b an impedance circle at 120% of the length of the line (zone 3), outside which there is long-time delayed backup tripping of protection unit B outside AB, b an impedance circle at 120% downstream to provide backup for downstream protection, b When there is communication between the protection units at the ends, tripping can take place instantaneously between 0 and 100%.
Zone 1
X N E 0 8 2 5 5 E D
ZL
Zone 3
T3
Zone 2
T2 Zone 1
T1
Load Z R
80%
Downstream zone
Zone 2
21
B
100%
Fig. 2. Impedance circles.
21
Zone 2
120%
Zone 3
Recloser The recloser function (ANSI 79) is designed to clear transient and semi-permanent faults on overhead lines and limit down time as much as possible. The recloser function automatically generates circuit breaker reclosing orders to resupply overhead lines after a fault. This is done in several steps: b tripping when the fault appears to de-energize the circuit, b time delay required for insulation recovery in the location of the fault, b resupply of the circuit by reclosing. Reclosing is activated by the link protection units. The recloser may be single-phase and/or 3-phase, and may comprise one or more consecutive reclosing cycles.
L
Fig. 1. Distance protection principle.
45
Transformer protection
Types of faults
The transformer is a particularly important power system component. Transformers requires effective protection against all faults liable to damage them, whether of internal or external origin. The choice of a protection unit is often based on technical and cost considerations related to the power rating.
The main faults that can affect transformers are: b overloads, b short-circuits, b frame faults.
0
Overloads Overloads may be caused by an increase in the number of loads supplied simultaneously or by an increase in the power drawn by one or more loads. Overloads result in overcurrent of long duration, causing a rise in temperature that is detrimental to the preservation of insulation and to the service life of the transformer.
Short-circuits Short-circuits can occur inside or outside the transformer. Internal short-circuits: faults between different phase conductors or faults between turns of the same winding. The fault arc damages the transformer winding and can cause fire. In oil transformers, the arc causes the emission of decomposition gas. If the fault is slight, a small amount of gas is emitted and the accumulation of gas can become dangerous. A violent short-circuit can cause major damage liable to destroy the winding and also the tank frame by the spread of burning oil. External short-circuits: phase-to-phase faults in the downstream connections. The downstream short-circuit current creates electrodynamic stress in the transformer that is liable to have a mechanical effect on the windings and lead to an internal fault. I
Frame faults
I
N E 8 8 2 5 5 E D
Imax
Imax
Imax 2 % 0
%
100%
Fig. 1
0
50%
Fig. 2
100%
Information on transformer operation
Fault current according to the position of the fault in the winding.
9 8 2 5 5 E D
Ic ˆi e
• (t)
= ˆI e
–t ------
•e
τe
t
Fig. 3. Transformer energizing. Ie: inrush current envelope τ e: time constant
46
Frame faults are internal faults. They may occur between the winding and the tank frame or between the winding and the magnetic core. They cause gas emission in oil transformers. Like internal short-circuits, they can cause transformer damage and fire. The amplitude of the fault current depends on the upstream and downstream neutral earthing arrangements, and also on the position of the fault in the winding: b in star connected arrangements (fig.1), the frame fault current varies between 0 and the maximum value depending on whether the fault is at the neutral or phase end of the winding. b in delta connected arrangements (fig. 2), the frame current varies between 50 and 100% of the maximum value depending on whether the fault is in the middle or at the end of the winding.
Transformer energizing (fig. 3) Transformer energizing creates a transient peak inrush current that may reach 20 times the rated current with time constants of 0.1 to 0.7 seconds. This phenomenon is due to saturation of the magnetic circuit which produces a high magnetizing current. The peak current is at its highest when energizing takes place as the voltage goes through zero and there is maximum remanent induction on the same phase. The waveform contains a substantial amount of 2nd harmonics. This phenomenon is part of normal power system operation and should not be detected as a fault by the protection units, which should let the peak energizing current through. Overfluxing Transformer operation at a voltage or frequency that is too low creates excessive magnetizing current and leads to deformation of the current by a substantial amount of 5th harmonics.
Protection functions
Transformer protection
0
Overloads Overcurrent of long duration may be detected by a definite time or IDMT delayed overcurrent protection unit (ANSI 51) that provides discrimination with respect to the secondary protection units. The dielectric temperature is monitored (ANSI 26) for transformers with liquid insulation and the winding temperature is monitored (ANSI 49T) for dry type transformers. Thermal overload protection (ANSI 49RMS) is used for more sensitive monitoring of temperature rise: heat rise is determined by simulation of the release of heat according to the current and thermal inertia of the transformer. For MV/LV transformers, overloads may be detected on the low voltage side by the long time trip function of the main LV circuit breaker.
0 9 2 5 5 E D
87T
Short-circuits
Fig. 1. Transformer differential protection. N E 1 9 2 5 5 E D
t 51 51 50
50
I Transformer energizing curve
Max. LV Isc
Max. HV Isc
Fig. 2. Transformer overcurrent protection. 2 9 2 5 5 E D
51G
Several protection functions may be implemented. b For oil transformers, devices that are sensitive to gas emission or oil movement (ANSI 63) caused by short-circuits between turns of the same phase or phase-to-phase short-circuits: v Buchholz relays for free breathing HV/HV transformers, v gas and pressure detectors for hermetically sealed HV/LV transformers. b Transformer differential protection (ANSI 87T) (fig.1) which provides fast protection against phase-to-phase faults. It is sensitive and used for vital high power transformers. To avoid nuisance tripping, the 2nd harmonic of the differential current is measured to detect transformer energizing (H2 restraint) and the 5th harmonic is measured to detect overfluxing (H5 restraint). The use of this protection function with neural network technology provides the advantages of simple setting and stability. b An instantaneous overcurrent protection unit (ANSI 50) (fig. 2) linked to the circuit breaker located on the transformer primary circuit provides protection against violent short-circuits. The current threshold is set higher than the current due to short-circuits on the secondary winding, thereby ensuring current-based discrimination. b HV fuses can be used to protect transformers with low kVA ratings.
Frame faults b Tank frame fault (fig. 3)
This slightly delayed overcurrent protection unit (ANSI 51G), installed on the transformer frame earthing connection (if the setting is compatible with the neutral earthing arrangement), is a simple, effective solution for internal winding-to-frame faults. In order for it to be used, the transformer must be isolated from the earth. This protection function is selective: it is only sensitive to transformer frame faults on the primary and secondary sides.
Fig. 3. Transformer tank frame fault protection. 3 9 2 5 5 E D
51N
64REF
Fig. 4. Earth fault protection. Fig. 5. Restricted earth fault protection. 4 9 2 5 5 E D
Another solution consists of using earth fault protection: b earth fault protection (ANSI 51N) located on the upstream power system for frame faults that affect the transformer primary circuit. b earth fault protection (ANSI 51N) located on the incomer of the switchboard being supplied, if the neutral of the downstream power system is earthed on the busbars (fig. 4). These protection functions are selective: they are only sensitive to phase-to-earth faults situated in the transformer or on the upstream and downstream connections. b restricted earth fault protection (ANSI 64REF) if the downstream power system neutral is earthed at the transformer (fig. 5). This is a differential protection function that detects the difference between residual currents measured at the neutral earthing point and at the three-phase output of the transformer. b neutral point earth protection (ANSI 51G) if the downstream power system is earthed at the transformer (fig. 6). b neutral voltage displacement protection (ANSI 59N) may be used if the downstre am power system neutral is isolated from the earth (fig. 7).
59N 51G
Fig. 6. Neutral point earth protection.
Fig. 7. Neutral voltage displacement protection.
47
Transformer protection
Faults
Recommended settings
0
Appropriate protection function
ANSI code
Setting information
Dielectric temperature monitoring (transformers with liquid insulation) Winding temperature monitoring (dry type transformers) Thermal overload
26
Alarm at 95°C; tripping at 100°C
49T
Alarm at 150°C; tripping at 160°C
49 RMS
Low voltage circuit breaker
Alarm threshold = 100% of thermal capacity used Tripping threshold = 120% of thermal capacity used Time constant in the 10 to 30 minute range Threshold ≥ In
Fuses
Choice of rating according to appropriate method for switchgear concerned
Overloads
Short-circuits Instantaneous overcurrent Definite time overcurrent
50 51
Percentage-based differential
51 87T
Buchholz or gas and pressure detection
63
Tank frame overcurrent
51G 51N/51G
IDMT overcurrent
High threshold > downstream Isc Low threshold < 5 In Delay ≥ downstream T + 0.3 seconds IDMT low threshold, selective with downstream, approximately 3 In Slope = 15% + setting range Min. threshold 30% logic
Earth faults Earth fault
Neutral voltage displacement
64REF 51G 59N
Flux control
24
Restricted earth fault differential Neutral point earth fault
Threshold > 20 A, delay 0.1 seconds Threshold ≤ 20% of maximum earth fault current and > 10% of CT rating (with 3CTs and H2 restraint) Delay 0.1 seconds if earthing is on the power system Time delay according to discrimination if earthing is on the transformer Threshold 10% of In, no delay Threshold < permanent limitation resistance current Threshold approximately 10% of residual overvoltage
Overfluxing
48
Threshold > 1.05 Un/fn Delay: constant time, 1 hour
Transformer protection
Examples of applications
5 9 2 5 5 E D
0
6 9 2 5 5 E D
51G 26 63
26 63
Low rated HV/LV transformer Fuse protection
High-rated HV/LV transformer Circuit breaker protection
7 9 2 5 5 E D
49RMS 50 51 51G (2 x)
8 9 2 5 5 E D
26 63
Low-rated HV/HV transformer
49RMS 50 51 51N 51G (2 x)
26 63 49T
49RMS 50 51 51G (2 x) 64REF 87T
High-rated HV/HV transformer
49
Motor protection
Types of faults
Motors are the interface between electrical and mechanical equipment. They are connected to the machines they drive and are therefore exposed to the same environment. Motors may be subjected to internal mechanical stress due to their moving parts. A single faulty motor can disrupt an entire production process. Modern motors have optimized characteristics which make them unsuitable for operation other than according to their rated characteristics. This means that they are relatively fragile electrical loads that need to be carefully protected. There are asynchronous motors (mainly squirrel-cage motors or wound-rotor motors) and synchronous motors (motors with DC rotor excitation). Questions concerning synchronous motors are the same as those that concern asynchronous motors plus those that concern generators.
Motors are affected by: b faults related to the driven loads, b power supply faults, b motor internal faults.
Faults related to the driven loads Overloads If the power drawn is greater than the rated power, there is overcurrent in the motor and an increase in losses, causing a rise in temperature. Excessive starting time and frequency of starts Motor starting creates substantial overcurrents which are only admissible for short durations. If a motor starts too frequently or if starting takes too long due to insufficient motor torque compared to load torque, overheating is inevitable and must be avoided. Blocking Rotation suddenly stops due to blocking of the driven mechanism. The motor draws the starting current and stays blocked at zero speed. There is no more ventilation and overheating occurs very quickly. Loss of load Loss of pump priming or a break in load coupling causes no-load operation of the motor, which does not directly harm the motor. However, the pump itself is quickly damaged.
Power supply faults Loss of supply This causes motors to operate as generators when the inertia of the driven load is high. Voltage sag This reduces motor torque and speed: the slow-down causes increased current and losses. Abnormal overheating therefore occurs. Unbalance 3-phase power supply may be unbalanced for the following reasons: b the power source (transformer or AC generator) does not supply symmetrical 3-phase voltage, b all the other consumers together do not constitute a symmetrical load and this unbalances the power supply system, b the motor is powered by two phases after a fuse has blown on one phase, b The phase order is reversed, changing the direction of motor rotation. Power supply unbalance creates negative sequence current which causes very high losses and quick rotor overheating. When the voltage is re-supplied after a motor power failure, the motor sustains remanent voltage that may lead to overcurrent when the motor starts again or even a mechanical break in transmission.
Motor internal faults Phase-to-phase short-circuits These faults vary in strength according to where they occur in the coil and they cause serious damage. Stator frame fault The amplitude of the fault current depends on the power system neutral earthing arrangement and the position of the fault within the coil. Phase-to-phase short-circuits and stator frame faults require motor rewinding, and frame faults can also irreparably damage the magnetic circuit. Rotor frame faults (for wound-rotor motors) Rotor insulation breakdown can cause a short-circuit between turns and produce a current that creates local overheating. Overheating of bearings due to wear or faulty lubrication. Field loss This fault affects synchronous motors; motor operation is asynchronous and the rotor undergoes considerable overheating since it is not designed accordingly. Pole slip This fault also affects synchronous motors, which may lose synchronism for different reasons: b mechanical: sudden load variation, b electrical: power supply system fault or field loss.
50
0
Motor protection
Protection functions
0
Overloads Overloads may be monitored the following: b IDMT overcurrent protection (ANSI 51), b thermal overload protection (ANSI 49RMS), which involves overheating due to current, b RTD temperature monitoring (ANSI 49T).
Excessive starting time and locked rotor The same function provides both types of protection (ANSI 48-51LR). For excessive starting time protection, an instantaneous current threshold is set below the value of the starting current and activated after a delay that begins when the motor is energized; the delay is set longer than the normal starting time. Locked rotor protection is activated outside starting periods by current above a threshold, after a delay.
Successive starts The successive starts protection function (ANSI 66) is based on the number of starts within a given interval of time or on the time between starts.
Loss of pump priming This is detected by a definite time undercurrent protection unit (ANSI 37) which is reset when the current is nil (when the motor stops).
Speed variation Additional protection may be provided by the direct measurement of rotation speed by mechanical detection on the machine shaft. The underspeed protection function (ANSI 14) detects slow-downs or zero speed resulting from mechanical overloads or locked rotors. The overspeed protection function (ANSI 12) detects racing when the motor is driven by the load, or a loss of synchronization for synchronous motors.
Loss of supply Loss of supply is detected by a directional active power protection unit (ANSI 32P).
Voltage sag This is monitored by a delayed positive sequence undervoltage protection unit (ANSI 27D). The voltage threshold and delay are set to allow discrimination with the power system’s short-circuit protection units and to tolerate normal voltage sags such as those that occur during motor starting. The same protection function may be shared by several motors in the switchboard.
Unbalance Protection is provided by the detection of negative sequence current by an IDMT or definite time protection unit (ANSI 46). The phase rotation direction is detected by the measurement of negative sequence overvoltage (ANSI 47).
Resupply Motor remanence is detected by a remanent undervoltage protection unit (ANSI 27R) which enables resupply when the voltage drops below a certain voltage threshold.
51
Protection functions
Motor protection
0
Phase-to-phase short circuits 0 0 3 5 5 E D
87M
They are detected by a delayed overcurrent protection unit (ANSI 50 and 51). The current threshold is set higher than the starting current and a very short delay is applied to prevent the protection unit from tripping on transient inrush currents. When the corresponding breaking device is a contactor, it is associated with fuses which ensure short-circuit protection. For large motors, a high impedance or percentage-based differential protection system (ANSI 87M) is used (fig.1). As an alternative, by appropriate adaptation of the connections on the neutral side and by the use of 3 summing current transformers, a simple overcurrent protection unit (ANSI 51) can be used to provide sensitive, stable detection of internal faults (fig.2).
Stator frame fault The type of protection depends on the neutral earthing arrangement. High sensitivity is required to limit damage to the magnetic circuit. If the neutral is solidly earthed or impedance-earthed, a delayed residual overcurrent protection unit (ANSI 51N/51G) may be used to protect the main windings. In isolated neutral arrangements, a neutral voltage displacement protection unit (ANSI 59N) may be used to detect neutral voltage displacement. If the motor feeder is capacitive (long cable), a directional earth fault protection unit (ANSI 67N) is used.
Fig. 1. Phase-to-phase short-circuit. Differential protection (ANSI 87M)
Rotor frame fault
1 0 3 5 5 E D
An insulation monitoring device with AC or DC current injection detects winding insulation faults.
Overheating of bearings The bearing temperature is measured by RTDs (ANSI 38).
Field loss For synchronous motors: refer to the chapter on generators. 51
Pole slip For synchronous motors: refer to the chapter on generators.
Fig. 2. Phase-to-phase short-circuit. Autodifferential overcurrent protection (ANSI 51)
52
Motor protection
Faults Appropriate protection function Faults related to the driven loads Overloads
IDMT overcurrent Thermal overload
Recommended settings
ANSI code
Setting information
50/51 49RMS
Setting that enables starting
Excessive starting time Locked rotor
Delayed current threshold
49T 48
Delayed current threshold
51LR
Successive starts Loss of load
Counting of number of starts
66
Phase undercurrent
37
Speed variation
Mechanical detection of overspeed, underspeed
12, 14
RTDs
0
According to motor operating characteristics (time constant in the range of 10 to 20 minutes) Depends on the thermal class of the motor Threshold in the 2.5 In range Delay: starting time + a few seconds Threshold: 2.5 In Delay: 0.5 to 1 second According to motor manufacturer Threshold in the range of 70% of drawn current Delay: 1 second Threshold ± 5% of rated speed Delay of a few seconds
Power supply faults Loss of supply
Directional active overpower
32P
Voltage sag
Positive sequence undervoltage
27D
Unbalance
Negative sequence / unbalance
46
Rotation direction Resupply
Phase rotation direction
47
Remanent undervoltage
27R
Threshold < 20 to 25% of Un Delay in the 0.1 second range
50/51 87M 51N/51G
Threshold > 1.2 starting I, delay in the 0.1 second range (DT)
Threshold 5% of Sn Delay: 1 second Threshold from 0.75 to 0.80 Un Delay in the 1 second range b Definite time Is1 = 20% In, delay = starting time + a few seconds Is2 = 40% In, delay 0.5 seconds b IDMT Is = 10% In, tripping time at 0.3 In > starting time Negative sequence voltage threshold at 40% of Un
Internal motor faults Phase-to-phase Fuses short circuits Definite time overcurrent Differential protection Stator frame fault
Rotor frame fault Overheating of bearings
Earthed neutral Isolated neutral
Earth fault
Rating that allows consecutive starts Slope 50%, threshold 5 to 15% of In, no delay
Power system with low capacitance Neutral voltage displacement High capacitance Directional earth fault Insulation monitoring device
59N
10% of maximum earth fault current Delay in the 0.1 second range (DT) Threshold = 30% of Vn
67N
Minimum threshold according to sensor
Temperature measurement
38
According to manufacturer’s instructions
Directional reactive overpower
32Q
Underimpedance
40 78PS
Threshold 30% of Sn Delay: 1 second Same as for generator
Specific synchronous motor faults Field loss
Pole slip
Loss of synchronization
Same as for generator
53
Motor protection
Examples of applications
2 0 3 5 5 E D
3 0 3 5 5 E D
37 46 48 - 51LR 49RMS 51G 66
M
27D 27R 46 48 - 51LR 49RMS 51 51G 66 67N
M
Asynchronous motor controlled by fuse and contactor Example: 100 kW pump
4 0 3 5 5 E D
Asynchronous motor controlled by circuit breaker Example: 250 kW fan
5 0 3 5 5 E D
26 63 49T
M
12 14 27D 27R 46 48 - 51LR 49RMS 51 51G 66 87T
38/ 49T
Motor-transformer unit: asynchronous motor/transformer Example: 1 MW crusher
54
0
27D 27R 32P 32Q 40 46 48 - 51LR 49RMS 51 51G 66 78PS 87M
M
38/ 49T
Priority synchronous motor Example: 2 MW compressor
Generator protection
Types of faults
Generator operation can be altered by both faults within the machine and disturbances occurring in the power system to which it is connected. A generator protection system therefore has a dual objective: to protect the machine and protect the power system. The generators referred to here are synchronous machines (AC generators).
Faults such as overloads, unbalance and internal phase-to-phase faults are the same type for generators and motors. Only faults specifically related to generators are described below.
0
External phase-to-phase short-circuits When a short circuit occurs in a power system close to a generator, the fault current looks like the current shown in figure 1. The maximum short-circuit current should be calculated taking into account the machine’s substransient impedance X"d. The short-circuit current detected by a protection unit with a very short time delay (about 100 ms) should be calculated taking into account the machine's transient impedance X'd. The short-circuit current in steady state conditions should be calculated taking into account the synchronous impedance X. It is low, generally less than the generator’s rated current. Voltage regulators can often keep it higher than the rated current (2 or 3 times higher) for a few seconds.
Internal phase-to-frame faults This is the same type of fault as for motors and the effects depend on the neutral earthing arrangement used. There is a difference however in comparison to motors in that generators can be decoupled from the power system during start-up and shutdown and also in test or stand-by mode. The neutral earthing arrangement may differ according to whether the generator is connected or disconnected and the protection functions should be suitable for both cases.
Current
N E 6 0 3 5 5 E D
Subtransient phenomena
Transient phenomena
Field loss t
Fig. 1. Short circuit currents across generator terminals.
When a generator coupled with a power system loses its field, it becomes desynchronized with respect to the power system. It then operates asynchronously, at a slight overspeed, and it draws reactive power. This causes stator overheating since the reactive current may be high and rotor overheating since the rotor is not sized for the induced currents.
Loss of synchronism The loss of generator synchronization occurs when balanced steady state operation is disrupted by strong disturbances: for example, when a short-circuit in the power system causes a drop in the electrical power supplied by the generator and the generator accelerates, still driven by the prime mover.
Operation as a motor When a generator is driven like a motor by the power system (to which it is connected), it applies mechanical energy to the shaft and this can cause wear and damage to the prime mover.
Voltage and frequency variations Voltage and frequency variations under steady state conditions are due to regulator malfunctions and cause the following problems: b frequencies that are too high cause motor overheating, b frequencies that are too low cause motor power loss, b frequency variations cause motor speed variations, that may cause mechanical damage and malfunctioning of electronic devices, b voltage that is too high puts stress on the insulation of all parts of the power system, causes magnetic circuit overheating and damages sensitive loads, b voltages that are too low cause torque loss and an increase in current and motor overheating, b voltage fluctuations cause motor torque variations resulting in flicker (flickering of light sources).
Generator management Normal generator management may be disturbed: b inadvertent energization when the normal starting sequence is not complied with: the generator, shut down but coupled to the power system, runs like a motor and may damage the prime mover, b power management: when there are several parallel sources, the number of sources must be adapted to suit the power drawn by the loads; there is also the case of islanded operation of an installation with its own power generation.
55
Generator protection
Protection functions
0
Overloads The overload protection functions for generators are the same as those for motors: b IDMT overcurrent (ANSI 51), b thermal overload (ANSI 49RMS), b RTD temperature monitoring (ANSI 49T).
Unbalance Protection is ensured, the same as for motors, by IDMT or definite time negative sequence current detection (ANSI 46).
N E 7 0 3 5 5 E D
External phase-to-phase short-circuits (in the power system)
Tripping threshold
b As the value of short-circuit current decreases over time to approximately the rated
Is
0.2 Is
U 0.3 Un
Un
Fig. 1. Voltage restrained overcurrent protection threshold.
current, if not lower, in steady state conditions, simple current detection may be insufficient. This type of fault can be detected effectively by a voltage-restrained overcurrent protection device (ANSI 51V), the threshold of which increases with the voltage (fig. 1). Operation is delayed. b When the machine is equipped with a system that maintains the short-circuit at about 3 In, the use of a phase overcurrent protection unit (ANSI 51) is recommended. b Another solution consists of using a delayed underimpedance protection unit (ANSI 21G), which may also provide back-up (ANSI 21B) for the overcurrent protection unit.
Internal phase-to-phase short-circuits (in the stator) b High impedance or percentage-based differential protection (ANSI 87G) provides
8 0 3 5 5 E D
50
A
G
B
50
a sensitive, quick solution. b If the generator is operating in parallel with another source, a directional phase overcurrent protection unit (ANSI 67) can detect internal faults. b In certain cases, particularly for generators with low power ratings compared to the power system to which they are connected , internal phase-to-phase short-circuit protection may be provided as follows (fig. 2): v instantaneous overcurrent protection (A), validated when the generator circuit breaker is open, with current sensors on the neutral point side, set lower than the rated current, v instantaneous overcurrent protection (B), with current sensors on the circuit breaker side, set higher than the generator short-circuit current.
Stator frame fault b If the neutral is earthed at the generator neutral point, earth fault protection Fig. 2. AC generator coupled with other sources.
(ANSI 51G) or restricted earth fault protection (ANSI 64REF) is used. b If the neutral is earthed within the power system rather than at the generator neutral point, a stator frame fault is detected by: v an earth fault protection unit on the generator circuit breaker when the generator is coupled to the power system, v by an insulation monitoring device for isolated neutral arrangements when the generator is decoupled from the power system. b If the neutral is impedant at the generator neutral point, 100% stator frame fault protection (ANSI 64G) is used. This protection combines two functions: v neutral voltage displacement, which protects 80% of the windings (ANSI 59N) v third harmonic (H3) neutral point undervoltage, which protects the 20% of the windings on the neutral side (ANSI 27TN). b If the neutral is isolated, frame fault protection is provided by an insulation monitoring device. This device operates either by detecting residual voltage (ANSI 59N) or by injecting DC current between the neutral and earth. If this device exists on the power system, it monitors the generator when it is coupled; a special generator device, validated by the open position of the generator circuit breaker being in the open position, is needed to monitor insulation when the generator is uncoupled.
Rotor frame fault When the excitation current circuit is accessible, frame faults are monitored by an insulation monitoring device.
56
Generator protection
Faults Appropriate protection function Prime mover related faults Overloads
Overcurrent Thermal overload RTDs
Operation as a motor Speed variation
Directional active overpower Mechanical detection of overspeed, underspeed
Recommended settings
ANSI code
Setting information
51 49RMS
In threshold, IDMT curve
49T 32P 12, 14
0
According to the generator operating characteristics: maximum thermal capacity used 115 to 120% Depends on the thermal class of the generator Threshold 5% of Sn (turbine) to 20% of Sn (diesel) Delay of a few seconds Threshold ± 5% of rated speed Delay of a few seconds
Power supply system faults External short-circuits
Inadvertent energization
With current maintained at 3 In Without current maintained at 3 In
Overcurrent
Voltage-restrained overcurrent Underimpedance (back-up) Inadvertent energization
51 51V 21B 50/27
Threshold 2 In Delay for discrimination with downstream protection Threshold 1.2 In Delay for discrimination with downstream protection About 0.3 Zn Delay for discrimination with downstream protection Current threshold = 10% of generator In Voltage threshold = 80% of Un Inhibit time after voltage sag = 5 seconds Minimum current appearance time after voltage appearance = 250 ms
Generator internal faults and generator control Phase-to-phase High impedance differential short circuits Percentage-based differential
87G 87G
Directional phase overcurrent
67
Unbalance
Negative sequence / unbalance
46
Stator frame fault
If neutral is earthed at generator stator
Earth fault
51G
Restricted earth fault differential 100% stator frame fault
64REF
If neutral is impedant at generator stator If neutral is earthed within the power system
Earth fault on generator circuit breaker side
64G/59N 64G/27TN 51N/51G
Threshold 5 to 15% of In No delay Slope 50%, threshold 5 to 15% of In No delay Threshold In Delay according to discrimination with the other sources Threshold 15% of In Delay of a few seconds Threshold = 10% of maximum earth fault current Delay for discrimination with downstream protection Threshold 10% of In No delay Vrsd threshold = 30% of Vn Delay of 5 seconds Adaptive threshold = 15% of 3rd harmonic Vrsd Threshold 10 to 20% of maximum earth fault current Delay in the 0.1 second range
Neutral voltage displacement if the generator is decoupled If neutral Neutral voltage is isolated displacement Insulation monitoring device
59N
Vrsd threshold = 30% of Vn Delay of a few seconds
59N
Vrsd threshold = 30% of Vn Delay of a few seconds
Directional reactive overpower
32Q
Impedance measurement
40
Pole slip
Loss of synchronization
78PS
Voltage regulation
Overvoltage
59
Undervoltage
27
Frequency regulation
Overfrequency
Overheating of bearings Power management
RTDs
81H 81L 38
Threshold 30% of Sn Delay of a few seconds Xa = 0.15 Zn, Xb = 1.15 Zn, Xc = 2.35 Zn Zn circle delay: 0.1 second Xd circle delay: discrimination with downstream protection Equal-area criterion: delay of 0.3 seconds Power-swing criterion: 2 revolutions, 10 seconds between 2 power swings Threshold 110% of Un Delay of a few seconds Threshold 80% of Un Delay of a few seconds Threshold + 2 Hz of rated frequency
Directional active underpower
37P
Rotor frame fault Field loss
58
Underfrequency
Threshold - 2 Hz of rated frequency According to manufacturer’s specifications According to the application
Generator protection
Examples of applications
1 1 3 5 5 E D
0
2 1 3 5 5 E D
G
38/ 49T
Vrsd
27 32P 32Q 49RMS 46 51G 51V 51 59 64REF 67 67N 81H 81L
Low power generator
G
4 1 3 2 5 5 E D
38/ 49T
26 63 49T
21B 27 32P 40 46 49RMS 51 51G 59 64REF 78PS 81H 81L 87M
Medium power generator
3 1 3 5 5 E D
G
38/ 49T
27 32P 32Q 46 49RMS 51 51G (2 x) 51V 59 67 67N 81H 81L
Low power generator-transformer
Vnt
G
38/ 49T
26 63 49T
12 14 21B 27 32P 40 46 49RMS 50N 51 51G 59 64G 64REF 78PS 81H 81L 87T
Medium power generator-transformer
59
Capacitor protection
Types of faults
Capacitor banks are used to compensate for reactive energy drawn by power system loads and occasionally in filters to reduce harmonic voltage. Their role is to improve the quality of the power system. They may be connected in star, delta and double star arrangements, depending on the level of voltage and the total rated power of the loads. A capacitor comes in the form of a case with insulating terminals on top. It comprises individual capacitors (fig.1) which have limited maximum permissible voltages (e.g. 2250 V) and are mounted in groups: b in series to obtain the required voltage withstand, b in parallel to obtain the desired power rating. There are 2 types of capacitor banks: b without internal protection, b with internal protection where a fuse is added for each individual capacitor.
The main faults which are liable to affect capacitor banks are: b overloads, b short-circuits, b frame faults, b short-circuit of an individual capacitor.
0
Overloads An overload is due to continuous or temporary overcurrent: b continuous overcurrent due to: v an increase in the supply voltage, v the flow of harmonic current due to the presence of non-linear loads such as static converters (rectifiers, variable speed drives), arc furnaces, etc., b temporary overcurrent due to energizing of a capacitor bank step. Overloads result in overheating which has an adverse effect on dielectric withstand and leads to premature capacitor aging.
Short-circuits A short-circuit is an internal or external fault between live conductors, phase-to-phase (delta connection of capacitors) or phase-to-neutral (star connection). The appearance of gas in the gas-tight case of the capacitor creates overpressure which may lead to the opening of the case and leakage of the dielectric.
Frame faults A frame fault is an internal fault between a live capacitor component and the frame made up of the metal case that is earthed for safety purposes. The fault current amplitude depends on the neutral earthing arrangement and on the type of connection (star or delta). Similar to an internal short-circuit, the appearance of gas in the gas-tight case of the capacitor creates overpressure which may lead to the opening of the case and leakage of the dielectric.
Short-circuit of an individual capacitor 5 1 3 5 5 E D
Fig. 1. Capacitor bank.
Dielectric breakdown of an individual capacitor results in a short-circuit. Without internal protection, the parallel-wired individual capacitors are shunted by the faulty unit: b capacitor impedance is modified, b the applied voltage is distributed to one less group in the series, b each group is subjected to greater stress, which may result in further, cascading breakdowns, until a full short-circuit. Figure 2 shows the situation where group 2 is shunted following breakdown of an individual capacitor. With internal protection, blowing of the related internal fuse clears the faulty individual capacitor: b the capacitor remains fault-free, b its impedance is modified accordingly. Figure 3 shows the situation where the individual capacitor in group 2 is cleared by its internal fuse and group 2 remains in service. Group 1
N E 6 1 3 5 5 E D
Group 2 Group 3
V n–1 V V n–1
Group n Fig. 2. Capacitor bank without internal fuses.
60
Fig. 3. Capacitor bank with internal fuses.
Capacitor protection
Protection functions
0
Capacitors should not be energized unless they have been discharged. Re-energizing must be time-delayed in order to avoid transient overvoltages. A 10-minute time delay allows for sufficient natural discharging. Fast discharge inductors may be used to reduce discharging time.
Overloads b Extended overcurrents due to increases in the supply voltage can be avoided
by overvoltage protection (ANSI 59) that monitors the power-system voltage. This protection may cover the capacitor itself or a larger part of the power system. Given that the capacitor can generally accommodate a voltage of 110% of its rated voltage for 12 hours a day, this type of protection is not always necessary. b Extended overcurrents due to the flow of harmonic current are detected by an overload protection of one the following types: v thermal overload (ANSI 49RMS), v time-delayed overcurrent (ANSI 51), provided it takes harmonic frequencies into account. b The amplitude of short overcurrents due to the energizing of a capacitor bank step is limited by mounting impulse inductors in series with each step.
Short-circuits Short-circuits are detected by time-delayed overcurrent protection (ANSI 51). Current and time-delay settings make it possible to operate with the maximum permissible load current as well as close and switch capacitor bank steps.
Frame faults This type of protection depends on the neutral earthing arrangement. If the neutral is earthed, time-delayed earth fault protection (ANSI 51G) is used.
Capacitor component short-circuit Fault detection is based on the modification of the impedance created: b by short-circuiting the component for capacitors with no internal protection, b by clearing the faulty individual capacitor for capacitors with internal fuses. When the capacitor bank is double star-connected, the unbalance created by the change in impedance in one of the stars causes current to flow in the connection between the neutral points. This unbalance is detected by a time-delayed sensitive overcurrent protection device (ANSI 51).
61
Capacitor protection
Recommended settings and examples of applications
0
Recommended settings Faults Overloads
Suitable protection functions
ANSI code 59 49 RMS
Overvoltage Thermal overload
Short-circuits
Time-delayed overcurrent
51 51
Frame faults
Time-delayed earth fault
51N/51G
Capacitor component short-circuit
Time-delayed overcurrent
51
Time-delayed overcurrent
Setting information Threshold ≤ 110% Un Threshold ≤ 1.3 In Time constant in the 10-minute range Threshold ≤ 1.3 In, IDMT curve Threshold approximately 10 In Time delay approximately 0.1 s (DT) Threshold ≤ 20% I maximum earth fault Threshold ≥ 10% CT rating is supplied by 3 CTs, with H2 restraint Time delay approximately 0.1 s (DT) Threshold approx. 1 A, depending on the application Time delay approximately 1 s (DT)
Examples of applications 0 2 3 5 5 E D
51G
Delta compensation
1 2 3 5 5 E D
2 2 3 5 5 E D
49RMS 51, 51G 51
Double-star compensation
62
49RMS 51, 51G 59
Filtering assembly
Capacitor protection
0
63
Appendices
Key words Active power in MW Aperiodic component Apparent power in MVA Blocking signal Breaking capacity Compensated neutral Compensation coil (Petersen coil) Core balance CT Cos ϕ Coupling Current sensor Current-based discrimination Decoupling Definite-time delay Discrimination Dynamic stability Feeder Harmonics IDMT delay IEC 60909 Impedant neutral Incomer Inrush current Insulation monitoring device (IMD) Isolated neutral Load reconnection Load shedding Logic discrimination
Making capacity Neutral earthing Non-linear load Overload
64
Glossary Key words and definitions
0
Definitions The part of the apparent power that can be converted into mechanical or thermal power. Average value (that drops to zero) of the upper and lower envelopes of a current during energization or the initiation of a short-circuit. Power in MVA drawn by the loads in a power system. Order sent to an upstream protection device by a device that has detected a fault. Maximum current that a breaking device is capable of interrupting under prescribed conditions. The power system is earthed via a reactor tuned to the phase-to-earth capacitances. Neutral earthing reactor tuned to the phase-to-earth capacitances. Current sensor used to measure the residual current by summing the magnetic fields. Cosine of the angle between the fundamental components of the current and voltage. Operation whereby a source or part of a power system is connected to a power system already in operation when the necessary conditions are fulfilled. Device used to obtain a value related to the current. Discrimination system based on the fact that the closer the fault is located to the source, the stronger the fault current. Operation whereby a source or part of a power system is disconnected from a power system. Time delay before device tripping that does not depend on the measured current. Capacity of a set of protection devices to distinguish between conditions where a given protection device must operate and those where it must not. Capacity of a power system to return to normal operation following a sudden disturbance. Cables arriving from a set of busbars and supplying one or more loads or substations. Series of sinusoidal signals whose frequencies are multiples of the fundamental frequency. Variable time delay before device tripping that is inversely dependent upon the measured current. International standard dealing with the calculation of short-circuit currents in three-phase power systems. The power system is earthed via a resistance or a low reactance. A line supplying energy from a source to the busbars of a substation. Transient current that occurs when a load is connected to a power system. For inductive loads, it comprises an aperiodic component. In an isolated neutral system, device that verifies the absence of a fault. The power-system neutral is not earthed except for high-impedance connections to protection or measurement devices. Restoration of supply to loads that have been shed, when normal power system operating conditions have been re-established. Disconnection of non-priority loads from the power system when normal power system operating conditions no longer exist. Discrimination system in which any protection device detecting a fault sends a “no-trip” order (blocking signal) to the upstream protection device. The upstream protection trips a circuit breaker only if it did not receive a blocking signal from the downstream device. Maximum current that a breaking device is capable of making under prescribed conditions. It is at least equal to the breaking capacity. Method by which the power system neutral is connected to earth. Load drawing a current with a waveform that is not identical to that of the voltage. Current variations are not proportional to the voltage variations. Overcurrent lasting a long time and affecting one of the elements in the power system.
Appendices
Key words Polarization voltage
Power factor Power system Protection settings Protection system Protection-system study Rate of change of frequency (ROCOF) Reactive power in Mvar Recloser Residual current Residual voltage Restricted earth fault protection Short-circuit Short-circuit power Solidly earthed neutral Source transfer Subtransient Symmetrical components System reconfiguration Time delay Time-based discrimination
Total harmonic distortion Transient Tripping threshold Voltage sensor Zero-sequence generator
Glossary Key words and definitions
0
Definitions In a directional phase protection function, the phase-to-phase voltage value in quadrature with the current for cos ϕ = 1. In a directional earth-fault protection function, it is the residual voltage. Ratio between the active power and the apparent power. For sinusoidal signals, the power factor is equal to cos ϕ. Set of electrical-power production and consumption centres interconnected by various types of conductors. Protection function settings determined by the protection-system study. Set of devices and their settings used to protect power systems and their components against the main faults. Rational selection of all the protection devices for a power system, taking into account its structure and neutral earthing system. Protection used for rapid decoupling of a source supplying a power system in the event of a fault. The part of the apparent power that supplies the magnetic circuits of electrical machines or that is generated by capacitors or the stray capacitance of the links. Automatic device that recloses a circuit breaker that has tripped on a fault. Sum of the instantaneous line currents in a polyphase power system. Sum of the instantaneous phase-to-earth voltages in a polyphase power system. Protection of a three-phase winding with earthed neutral against phase-to-earth faults. Accidental contact between conductors or between a conductor and earth. Theoretical power in MVA that a power system can supply. It is calculated on the basis of the rated power system voltage and the short-circuit current. The power-system neutral is earthed via a connection with zero impedance. Operation whereby a power system is disconnected from one source and connected to another. The sources may or may not be parallel connected. Period lasting between 0 and 100 ms following the appearance of a fault. Three independent single-phase systems (positive sequence, negative sequence and zero sequence) superimposed to describe any real system. Operation, following an incident, involving switching of circuit breakers and switches to resupply power system loads. Intentional delay in the operation of a protection device. Discrimination system in which protection devices detecting a fault are organized to operate one after the other. The protection device closest to the source has the longest time delay. Ratio of the rms value of the harmonics to that of the fundamental. Period lasting between 100 ms and 1 second following the appearance of a fault. Value of the monitored parameter that trips operation of the protection device. Device used to obtain a value related to the voltage. Three-phase transformer used to create a neutral point in a power system for neutral earthing.
65
Appendices
Bibliography
Types of documents Standards
Titles b IEC 60050 international electrotechnical vocabulary b IEC 60044 current transformers b IEC 60186 voltage transformers b IEC 60255 electrical relays b IEC 60909 calculation of short-circuit currents in three-phase AC systems b IEEE C37.2 standard electrical power system device function numbers and contact designations
Schneider Electric documentation
b MV design guide b Protection of power systems (Published by Hermès) b MV partner b Cahier technique publications v N°2 Protection of electrical distribution networks by the logic-selectivity system v N°18 Analysis of three-phase networks under transient conditions using
symmetrical components v N°62 Neutral earthing in an industrial HV network v N°113 Protection of machines and industrial HV networks v N°158 Calculation of short-circuit currents v N°169 HV industrial network design v N°174 Protection of industrial and tertiary MV networks v N°181 Directional protection equipment v N°189 Switching and protecting MV capacitor banks v N°192 Protection of MV/LV substation transformers v N°194 Current transformers: how to specify them v N°195 Current transformers: specification errors and solutions b Schneider Electric site: http://www.schneider-electric.com b Sepam protection-relay site: http://www.sepamrelay.com b Sepam catalogues General
b Les techniques de l’ingénieur (Engineering techniques) b Guide de l’ingénierie électrique (Electrical engineering handbook) (Lavoisier)
66
0
Appendices
Symbol ALF C CT D ∆t
Definitions of symbols
0
Definition accuracy-limit factor capacitance of a phase with respect to earth current transformer feeder circuit breaker difference between the operating times of two protection devices tolerance of time delays phase-to-neutral voltage of the equivalent single-phase diagram power frequency initial symmetrical short-circuit current zero-sequence component of current positive-sequence component of current negative-sequence component of current phase 1 current
Symbol NPC Ph1 Ph2 Ph3 R
Definition neutral point coil phase 1 phase 2 phase 3 resistance
RCT RN
winding resistance in a current transformer neutral-point earthing resistance
Rs Ssc T Td THD Tmin tr U Un Us V
phase-to-phase voltage threshold phase-to-neutral voltage
Ik Ik1 Ik2 Ik3 ILN Im IMD In IN InCT Ip IpCT IRN Irsd Is Isat Isc Iscmax IsCT Ith
phase 2 current phase 3 current symmetrical short-circuit current interrupted when the first pole separates capacitive current decreasing aperiodic component of the short-circuit current continuous short-circuit current continuous phase-to-earth short-circuit current two-phase short-circuit current three-phase short-circuit current current flowing in the neutral earthing reactor magnetizing current insulation monitoring device rated current of an electrical component current flowing in the solidly earthed neutral-point circuit rated current of a current transformer peak value of short-circuit current primary current in a current transformer circuit flowing in the neutral earthing resistor residual current current threshold setting saturation current in a current transformer short-circuit current the highest short-circuit current secondary current in a current transformer maximum permissible current for 1s
stabilization resistance in a differential circuit short-circuit power tripping time delay tripping time total harmonic distortion circuit breaker breaking time (minimum time before separation of 1st pole) protection overshoot time phase-to-phase voltage rated phase-to-phase voltage
V0 V1 V2 V1 V2 V3 Vk Vn Vrsd Vs VT X Xd X'd X"d Z0 Z1 Z2 Za Zn
LN LPCT m MALT
neutral-point earthing reactance low-power current transformer safety margin earthing
ZN Zsc
zero-sequence component of voltage positive-sequence component of voltage negative-sequence component of voltage phase 1 phase-to-neutral voltage phase 2 phase-to-neutral voltage phase 3 phase-to-neutral voltage knee-point voltage rated phase-to-neutral voltage residual voltage phase-to-neutral voltage threshold voltage transformer reactance synchronous reactance transient reactance subtransient reactance zero-sequence impedance positive-sequence impedance negative-sequence impedance equivalent impedance apparent rated impedance (transformer, capacitor, motor, generator) impedance between the neutral point and earth short-circuit impedance
dT E f I"k I0 I1 I2 I1 I2 I3 Ib Ic IDC
67
Appendices
Index of technical terms
A aperiodic component 18
I IEC 60909 17
B blocking signal 27, 31, 34, 35, 41, 42 breaking capacity 18 busbars 4, 5, 33
L line 18, 33, 44, 45 load shedding 43 LPCT 19, 21
C cable 18, 33, 41, 44, 45 capacitor 18, 27, 60, 61, 62 capacitor bank 27 characteristic angle 25 circuit breaker 17, 18, 27, 36–43, 45 circuit-breaker failure 43 coil extinction 10 neutral point 9 Petersen 10 contactor 2, 18, 52, 54 core balance CT 7, 8, 22, 26 coupling 35, 39, 46, 57 current residual 10, 22 short-circuit 12–19, 28, 30 current sensors 19-22, 33
M making capacity 18 motor asynchronous 14, 50, 54, 55 synchronous 14, 50, 53, 54
D decoupling 19, 26, 39 differential protection busbars 26 generator 26 high impedance 33, 58 line 26 motor 26 percentage-based 48, 58 restricted earth fault 26, 47, 48, 56, 58 transformer 26 discrimination combined 34, 36 current-based 30, 34, 47 differential 35 directional 35 logic 34, 35, 36 time-based 28, 29, 31, 34, 35, 38 E earthing 6–11 F fault, characterization 12, 18 fuse 18, 47, 50, 52, 60 G generator 14–17, 33, 55–59 H harmonics 46, 47, 56, 58, 60
68
N neutral compensated 6, 26, 37, 38 impedant 26, 56, 58 isolated 6, 7, 23 solidly earthed 11, 37, 38 neutral earthing 6-11 neutral point 6–11, 37, 47, 48, 52, 56 O overfluxing 47 overload 44, 47, 51, 56, 61 overvoltage 6–12, 61 P power active 27, 39, 51, 53, 57, 58 apparent 19, 23 rated output 19 reactive 53, 55, 57, 58 short-circuit 11, 12, 45 power system architecture 3, 4, 5 loop 4, 5, 32, 35, 40, 41 radial 4, 5, 29, 31, 36 power factor 27 protection 100% generator stator 26 busbars 42, 43 capacitor 60–62 circuit breaker failure 26 differential 20, 26, 33, 35, 41, 42, 44, 47, 52, 53, 56 directional active overpower 26 directional active underpower 26, 58 directional reactive overpower 26, 53, 58 directional reactive underpower 26 distance 26, 45 excessive starting time and locked rotor 26, 51 field loss 26, 50, 52, 53, 55, 57, 58 generator 55–59 inadvertent generator energization 26 links 44, 45 motor 50–54 negative sequence / unbalance protection 26, 44, 53, 58 negative sequence overvoltage 26
0
Appendices
Index of technical terms
neutral voltage displacement 26, 48, 53, 58 overcurrent delayed earth fault 11, 26, 44, 61, 62 delayed phase 26, 47, 52, 62 delayed voltage-restrained phase 26, 56 directional earth fault 7, 26, 37, 44, 52, 53 directional phase 26, 56, 58 earth fault 36, 37, 38, 40, 42, 48, 53, 56, 58 instantaneous earth-fault 26 instantaneous phase 26, 47, 48 instantaneous voltage-restrained phase 26 phase 20, 36, 38, 40, 44, 56 overfluxing 26, 48, 57 overfrequency 26, 58 overspeed 26, 53, 58 overvoltage 26, 37, 47, 58, 62 phase undercurrent 26, 53 pole slip 26, 50-58 positive sequence undervoltage 26, 51, 53 power system 36–41 pressure 26, 47, 48 rate of change of frequency (rocof) 26, 39, 43 recloser 26, 45 remanent undervoltage 26, 51, 53 residual undervoltage (third harmonic) 26, 56, 58 RTD 26, 51, 53, 56, 58 successive starts 26 synchro-check 26, 39 temperature monitoring 26 thermal image 26, 44, 47, 51, 53, 56, 58, 61, 62 thermostat 26 transformer 46–49 underfrequency 26, 58 underimpedance 26, 53, 56, 57, 58 underspeed 26, 53, 58 undervoltage 26, 57, 58 vector shift 26 protection coordination 2 protection relays 22, 24, 42 protection settings 14 protection system study 2, 3, 8, 9
0
S saturation of a CT 8, 19, 20, 22, 33, 42 of a transformer 46 short-circuit phase-to-earth 12, 14, 17 phase-to-phase 12, 14, 17, 44, 47, 52, 56 three-phase 12, 14, 17 two-phase 15, 17 two-phase clear of earth 12 two-phase-to-earth 7, 12, 15, 17 source transfer 39 subtransient 16, 17, 55 switch 2, 18, 40 symmetrical components 13, 14, 15, 17 T temperature 27, 47, 51, 52 time operation 24, 28 overshoot 24, 28 reset 24, 25 timer hold 25 tripping 24, 25, 31, 34, 53 time delay definite 25 IDMT 25 total harmonic distortion 27 transformation ratio 23 transformer current 19, 21, 27, 33, 35, 52 voltage 19, 23, 27, 32 transformer energization 46 transient 6, 7, 10, 16, 46, 55 tripping threshold 7, 25, 48 Z zero-sequence generator 8, 37, 38
R rate of change of frequency 26, 39, 43 recloser 26, 45 residual voltage 7, 23, 37, 47, 52, 56 restraint current 33 H2 (second harmonic) 22, 25, 47, 48, 62 H5 (fifth harmonic) 47 voltage 26, 56, 58 restricted earth fault 26, 47, 48, 56, 58
69
Appendices
70
Notes
0
Appendices
Notes
0
71
Appendices
72
Notes
0