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Arc Flash Analysis Done Right Part1

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Part 1 – System Modeling & Studies for Existing Existing Systems Systems Operation Operati on Technol Technology ogy,, Inc. Inc . Copyright 2009    Result of rapid release of energy due to an arcing fault between two conductors. Bus voltages > 208V Temperatures as high as 36,000 36,000 oF Thermal Damage(I 2t) Cal/cm2 Current Time Current    Result of rapid release of energy due to an arcing fault between two conductors. Bus voltages > 208V Temperatures as high as 36,000 36,000 oF Thermal Damage(I 2t) Cal/cm2 Current Time Current        Intense Heat Thermo-acoustic Thermo-acoustic shock wave Molten metal Shrapnel Blinding light Toxic smoke Contact with energized components   Arc Flash prevention prevention is at the forefront: forefront:   Greater understanding of arc flash hazards and the risks they pose to personnel Increased enforcement on the part of OSHA to  judge whether the employer “acted reasonably” in protecting its workers from arc flash hazards       IEEE 1584-2002 IEEE 1584a-2004 IEEE 1584b-2009(?) – In Ballot IEEE 1584.1 – In Progress IEEE 3002.5 – In Progress NFPA 70E-2009   OSHA regulations were developed to mandate that employers provide a safe workplace for their employees CFR Part 1910 promotes the safety of employees working on or near electrical equipment and clearly defines employer responsibilities  Equipment must be de-energized before work is performed unless demonstrated:    De-energizing introduces additional or increased hazards Infeasible due to equipment design or operational limits Lockout / Tag out (LOTO) procedures must be used  If equipment cannot be de-energized prior to work:   Employees must be properly protected Employers are responsible for performing a hazard assessment     Arc Flash information needs to be determined and documented Protection boundaries established and appropriate PPE must be provided Panels and electrical equipment must be labeled:   Labels are the end product but a number of prerequisite steps must be followed  Arc flash calculations is one of the steps of the entire arc flash assessment    Arc flash calculations should be performed by or under the direction of a qualified person with experience in performing power system studies including arc flash calculations Have familiarity with the industry for which the study is being performed      Utilize IEEE 1584 – Guide for Performing  Arc Flash Calculations NFPA 70E table approach is not needed.  Avoid using quick calculators except for approximate calculations 3-Phase equations can be used for 1Phase system with conservative results. Empirical equations can be used where IEEE equations do not apply. (>15 kV or < 208 V)       Scope of study Field verification and audit Update one-line diagrams Software modeling and design Short-circuit analysis Protective device coordination  Scope and level of detail depend upon complexity of the system:   Simple System – Begin at point of electrical service. e.g. office buildings, commercial facilities, small industrial and institutional systems Intermediate System – Customer owned service transformer and/or secondary selective substation. e.g. mid sized industrial, institutional and large commercial facilities  Scope and level of detail depend upon complexity of the system:  Complex System – System includes nominal voltage > 600 V, protective relaying, network systems, customer owned primary substation, customer owned generation for prime power. e.g. large industrial complexes, campus type systems with multiple modes of operations   Encompass all equipment from customer owned service entrance down through major equipment rated 208V nominal Equipment rated < 240 V served by transformer rated <= 125 kVA may be excluded    Most critical step for all system studies Become familiar with plant layout, equipment and maintenance procedures Walk-downs to validate drawings and access equipment condition  Start with most recent / accurate one-line diagram. Highlight or mark-off each piece of equipment on the one-line: ▪ ▪ ▪ ▪  Connectivity Cable/Line lengths Nameplate ratings Protective device locations and settings Work with electricians to gather and document data  Take pictures during field verification   Generate / update worksheets with protective device information & settings. What is missing in this settings sheet? 50/51 CO SUB 8 TIME O.C. TAP:6 T.D.:9 INST 180 A. ABB 1200/5 50/51 50/51 CO CO SUB 8 SUB 8 TIME O.C. TIME O.C. TAP:6 T.D.:9 INST: 180 A. TAP:6 T.D.:9 INST: 180 A. ABB 1200/5 ABB 1200/5  Curve Type      Validate main feeder lengths Issue mark-ups to update CAD drawings as needed Wear PPE based on NFPA tables when collecting data for equipment with no labels  At higher voltages rely on HV qualified electricians to collect data Equipment ID’s in the electrical model must match the system device ID / tag number     Equipment Count (From Client) Count (After Field Verification) Bus 337 339 Cable 608 1292 HVCB 76 84 LVCB 451 1205 Contactor 485 1169 Fuse 219 220 Induction Motor 461 1143 OCR 466 474 CT 413 424  Above example shows missing equipment added to existing model after field verification such as LV motors > 50 HP and load equipment feeders Data collection must have high precision for arc flash studies for higher accuracy Other studies like short circuit may not need high precision data collection since they tend to be on the conservative side  Utility Normal, Max and Min SC Rating    Working Distances   Contact utility for most recent values Max and Min SC rating for Coordination IEEE 1584 –Table 3, however alternate working distances to be used as applicable. Equipment Type and Condition    MCC, Switchgear, etc. (Isolated / Not Isolated) Evaluate age, condition and maintenance history Poorly maintained equipment may not operate BREAKER IDENTIFICATION BREAKER TYPE FRAME SIZE TRIP UNIT MAIN 480V SWGR CH DSII632 3200 DIGITRIP RMS 510 TRIP UNIT# PLUG # In 3000A 3200A LONG SHORT SENSOR LTPU STPU INST. NOTES & REMARKS LAST CAL RATING DELAY DELAY 3200A 1.0 2.0 2.0 0.3 DIS 10/12/2006    When relay, circuit breaker and fuse data not available – no assumption should be made to their type, style, setting or clearing time.  Arc Flash analysis should not be performed on downstream devices with assumed data. If you must provide result, select the further upstream device that has known data and calculate results based on that device. Fuse considered to clear the fault since CB22 information unavailable. In this case, arc fault clearing PD is userdefined as fuse     Short circuit model provides accurate representation of system Z.  Arc flash study should be based on up-todate short circuit study that reflects existing conditions, system configurations and operating scenarios. Maximum fault levels calculated. Identify device duty problems prior to proceeding with arc flash calculations.  System representation should include accurate momentary, interrupting and steady state fault currents.   Neglecting steady state currents may give inaccurate picture of how devices will operate. This becomes an important factor for systems with generation. Incident energy decay is directly proportional to decay in short circuit current.