1、 SHORT CIRCUIT CHARACTERISTICS OF INSULATED CABLES ANSI/ICEA PUBLICATION P-32-382-2007 (R2013) 2013 by INSULATED CABLE ENGINEERS ASSOCIATION, Inc. Copyright 2013 by the Insulated Cable Engineers Association, Incorporated. Approved as an American National Standard ANSI Approval Date: February 27, 201
2、3 Insulated Cable Engineers Assoc., Publication No. P-32-382- 2007 (R2013) Short Circuit Characteristics of Insulated Cables Published by Insulated Cable Engineers Association P.O. Box 1568 Carrollton, Georgia 30112 Copyright 2012 by the Insulated Cable Engineers Association. All rights including t
3、ranslation into other languages, reserved under the Universal Copyright Convention, the Berne Convention for the Protection of Literary and Artistic Works, and the International and Pan American Copyright Conventions. Copyright 2013 by the Insulated Cable Engineers Association, Incorporated. NOTICE
4、AND DISCLAIMER The information in this publication was considered technically sound by the consensus of persons engaged in the development and approval of the document at the time it was developed. Consensus does not necessarily mean that there is unanimous agreement among every person participating
5、 in the development of this document. The Insulated Cable Engineers Association, Inc. (ICEA) standards and guideline publications, of which the document contained herein is one, are developed through a voluntary consensus standards development process. This process brings together persons who have a
6、n interest in the topic covered by this publication. While ICEA administers the process and establishes rules to promote fairness in the development of consensus, it does not independently test, evaluate, or verify the accuracy or completeness of any information or the soundness of any judgements co
7、ntained in its standards and guideline publications. ICEA disclaims liability for personal injury, property, or other damages of any nature whatsoever, whether special, indirect, consequential, or compensatory, directly or indirectly resulting from the publication, use of, application, or reliance o
8、n this document. ICEA disclaims and makes no guaranty or warranty, expressed or implied, as to the accuracy or completeness of any information published herein, and disclaims and makes no warranty that the information in this document will fulfill any of your particular purposes or needs. ICEA does
9、not undertake to guarantee the performance of any individual manufacturer or sellers products or services by virtue of this standard or guide. In publishing and making this document available, ICEA is not undertaking to render professional or other services for or on behalf of any person or entity,
10、nor is ICEA undertaking to perform any duty owed by any person or entity to someone else. Anyone using this document should rely on his or her own independent judgement or, as appropriate, seek the advice of a competent professional in determining the exercise of reasonable care in any given circums
11、tances. Information and other standards on the topic covered by this publication may be available from other sources, which the user may wish to consult for additional views or information not covered by this publication. ICEA has no power, nor does it undertake to police or enforce compliance with
12、the contents of this document. ICEA does not certify, test, or inspect products, designs, or installations for safety or health purposes. Any certification or other statement of compliance with any health or safety-related information in this document shall not be attributable to ICEA and is solely
13、the responsibility of the certifier or maker of the statement. ICEA P-32-382-2007 (R2013) Page i Copyright 2013 by the Insulated Cable Engineers Association, Incorporated. CONTENTS Page Foreword ii Section 1 GENERAL . 1 1.1 SCOPE . 1 1.2 REFERENCES . 1 GRAPHS Allowable Short Circuit Currents for Pap
14、er, Rubber, or Varnished Cloth Insulated Copper Conductors Rated for 75C Maximum Continous Operation . 3 Allowable Short Circuit Currents for Thermoplastic Insulated Copper Conductors Rated for 75C Maximum Continous Operation . 4 Allowable Short Circuit Currents for Thermoset Insulated Copper Conduc
15、tors Rated for 90C Maximum Continuous Operation 5 Allowable Short Circuit Currents for Thermoset Insulated Copper Conductors Rated for 105C Maximum Continuous Operation 6 Allowable Short Circuit Currents for Paper, Rubber, or Varnished Cloth Insulated Aluminum Conductors Rated for 75C Maximum Contin
16、uous Operation . 7 Allowable Short Circuit Currents for Thermoplastic Insulated Aluminum Conductors Rated for 75C Maximum Continuous Operation . 8 Allowable Short Circuit Currents for Thermoset Insulated Aluminum Conductors Rated for 90C Maximum Continuous Operation . 9 Allowable Short Circuit Curre
17、nts for Thermoset Insulated Aluminum Conductors Rated for 105C Maximum Continuous Operation . 10 ICEA P-32-382-2007 (R2013) Page ii Copyright 2013 by the Insulated Cable Engineers Association, Incorporated. Foreword This publication discusses factors for consideration in approximating the operabilit
18、y of insulated and/or covered wire and cable under the influence of uninterrupted short circuit currents encountered as a result of cable or other equipment faults. The duration of such a fault is considered to be up to approximately 2 seconds. Calculation for single short circuits of longer duratio
19、ns will yield increasingly conservative results. The following items must be considered in order to estimate the short circuit performance of a specific circuit: 1. The magnitude and duration of the fault current including any fault current division due to available conducting paths. 2. The capabili
20、ty of joints, terminations and other accessories in the affected circuit to withstand the thermal and mechanical stresses created by the fault. 3. The interaction between the faulting circuit and surrounding equipment, such as supports, ties and clamps. 4. The capability of the affected cable circui
21、t, as installed, to withstand the electromagnetic forces created during the fault. 5. The maximum temperature that cable components can withstand without incurring damage due to heating caused by fault current flow. 6. Damage to adjacent equipment due to arcing at the site of the fault. 7. For limit
22、ations imposed on the short-circuit capacity of the cable by the fault capacity of the cable metallic sheath/shield, See ICEA Publication P-45-482, Short Circuit Characteristics of Metallic Sheaths and Shields on Insulated Cable An important simplifying assumption in the formula is the adiabatic nat
23、ure of the heat generated, i.e., the duration of the fault is so short that all the heat developed by the fault current during this time is assumed to be completely contained within the conductor. The amount of heat dissipated from the conductor during continuous, single fault occurrences of relativ
24、ely short duration is small. A significant amount of heat may be dissipated because of the relatively long cooling periods involved for faults interrupted and re-established with automatic reclosing of circuit protective devices. A non-adiabatic calculation may be more suitable for these situations
25、and for single, uninterrupted short circuits in excess of 2 seconds requiring close accuracy. Non-adiabatic calculation methods are described in several published works listed Section 1.2 “References”. The formula described in this publication is based on the thermal capacity of the conductor materi
26、al and the transient temperature limit of the insulation. The quantity of heat contained in the conductor is that created by the fault current and is also a function of the temperature rise in the conductor. The magnitude of the temperature rise is the difference between the limiting transient tempe
27、rature of the ICEA P-32-382-2007 (R2013) Page iii Copyright 2013 by the Insulated Cable Engineers Association, Incorporated. insulation material and the operating temperature of the conductor immediately prior to the initiation of the fault. The limiting transient temperature is that temperature whi
28、ch caused no significant change in any cable component. Suggestions for improvements in this publication are welcome, and should be sent to ICEA at the address below. Insulated Cable Engineers Association, Inc. P.O. Box 1568 Carrollton, GA 30112 ICEA P-32-382-2007 (R2013) Page 1 Copyright 2013 by th
29、e Insulated Cable Engineers Association, Incorporated. Section 1 GENERAL 1.1 SCOPE Equations have been established for short circuit calculations for conductors made of copper or aluminum. The coverings and insulations, which determine the maximum allowable short circuit temperatures, are paper, var
30、nished cloth and several thermoplastic and thermosetting materials presently appearing in ICEA standards. Temperature limits, considered safe, were established for the various covering and insulation materials. The equations may be used to determine: The maximum short circuit permitted for a specifi
31、c conductor and short circuit duration. The conductor size necessary to carry a specific short circuit current for a given duration. The maximum duration a specific conductor can carry a specific short circuit current. An equation has been established for short circuit calculations with conductors o
32、f copper or aluminum. The insulations, which determine the maximum allowed short circuit temperatures, are described in the ICEA Standards. The equation is based on the heat content of the conductor material and the temperature limit of the insulation with the assumption that the time interval is so
33、 short that the heat developed during the short circuit is contained in the conductor. At the time this document was originally published there was no standard mathematical method available to calculate heat flow from the conductor through the insulation at the cessation of the short circuit load. I
34、t was necessary to enlist the aid and facilities of member laboratories and Massachusetts Institute of Technology to obtain in cooperation a solution to this problem so that safe temperature limits could be established for the various types of insulations. The solution is still a viable, conservativ
35、e approach to the calculation of short circuit capacity. Results are sufficiently conservative to neglect conductor skin effect except for very large conductors. Skin effect can be taken into account by dividing the right-hand member of the equations shown by the appropriate conductor ac/dc resistan
36、ce ratio. 1.2 REFERENCES The following publications were referred to in writing this standard. The Transient Temperature Rise of Round Wire Shields of Extruded Dielectric Cables Under Short Circuit Conditions, M. A. Martin Jr., A.W. Reczek Jr., IEEE-ICC Open Forum at 57 Meeting Nov. 17-19, 1975. Opt
37、imization of Design of Metallic Shield-Concentric Conductors of Extruded Dielectric Cables Under Fault Conditions, EPRI EL-3014, Project 1286-2, final Report 4/83. Optimization of Metallic Shields for Extruded Dielectric Cables Under Fault Conditions, IEEE Paper 86 T&D 339-B. ICEA P-32-382-2007 (R20
38、13) Page 2 Copyright 2013 by the Insulated Cable Engineers Association, Incorporated. Normal and Short Circuit Operating Characteristics of Metallic Shielded Solid Dielectric Power Cable, M.A. Martin Jr., D. A. Silver, R. G. Lukac, R. Suarez, IEEE Paper 973 495-9. Fault Test on Embedded Copper Wire
39、and Copper Tape Shielded Single Conductor Cables, C. Landinger, L. D. Cronin, IEEE Paper C73-124-5. Buried Power and Telephone Distribution Systems-Analysis of Primary Cable Fault Tests and Evaluations of Experience With Random Separation, EEI Pub. 68-62. The Short Circuit Rating of Thin Metal Tape
40、Cable Shields, AIEE Trans, Vol. 87, pp. 740-758, March 1968. Fault Current Rating of Metallic Cable Screens, T. M. White, S. E. Philbrick, JICABLE 1087, Paper B6.2. Are Cable Shields Being Damaged During Grounds Faults?, P. S. Hamer, B. M. Wood. IEEE Transactions on Industry Applications, Paper PID-
41、86-6. Design of Metallic Shields for Extruded Dielectric Cables, 1984 IEEE IAS Pulp and Paper Conference, D. A. Silver, M. D. Buckweitz, Paper PPI-84-14. Calculations of Thermally Permissible Short Currents Taking Into Account Non-Adiabatic Heating Effects, IEC Publication 60949-9-1988. ICEA P-32-38
42、2-2007 (R2013) Page 3 Copyright 2013 by the Insulated Cable Engineers Association, Incorporated. Allowable Short Circuit Currents for Paper, Rubber, or Varnished Cloth Insulated Copper Conductors Rated for 75C Maximum Continuous Operation 100100010000100000100000010000 100000 1000000Con ductor S ize
43、 (A W G/ k c mi l)ShortCircuit Current- Amperes1 Cy c l es 2 Cy c l es 4 Cy c l es 8 Cy c l es16 Cy c l es 30 Cy c l es 60 Cy c l es 10 0 Cy c l esC u r v e s B a s e d o n t h e For m u laW h e r e :I = S h o r t C irc u it C u r r e n t - A m p e r e sA = C o n d u c t o r A r e a - C irc u lar M
44、il st = Tim e o f S h o r t C irc u it - S e c o n d sT1= M a x im u m Op e ra ting Tem p e ra tu re - 7 5 CT2= M a x im u m S h o rt C irc u it Tem p e ra tu re - 2 0 0 C108 6 4 2 1 1/0 2/0 3/04/0 250 500 1000350 750234T234Tl o g0 . 0 2 9 7tAI122ICEA P-32-382-2007 (R2013) Page 4 Copyright 2013 by t
45、he Insulated Cable Engineers Association, Incorporated. Allowable Short Circuit Currents for Thermoplastic Insulated Copper Conductors Rated for 75C Maximum Continuous Operation 100100010000100000100000010000 100000 1000000Con ductor S ize (A W G/ k c mi l)ShortCircuit Current- Amperes1 Cy c l es 2
46、Cy c l es 4 Cy c l es 8 Cy c l es16 Cy c l es 30 Cy c l es 60 Cy c l es 10 0 Cy c l es108 6 4 2 1 1/0 2/0 3/0 4/0 250 500 1000350 750C u r v e s B a s e d o n t h e For m u laW h e r e :I = S h o r t C irc u it C u r r e n t - A m p e r e sA = C o n d u c t o r A r e a - C irc u lar M il st = Tim e
47、o f S h o r t C irc u it - S e c o n d sT1= M a x im u m Op e ra ting Tem p e ra tu re - 7 5 CT2= M a x im u m S h o rt C irc u it Tem p e ra tu re - 1 5 0 C234T234Tl o g0 . 0 2 9 7tAI122ICEA P-32-382-2007 (R2013) Page 5 Copyright 2013 by the Insulated Cable Engineers Association, Incorporated. Allo
48、wable Short Circuit Currents for Thermoset Insulated Copper Conductors Rated for 90C Maximum Continuous Operation 100100010000100000100000010000 100000 1000000Con ductor S ize (A W G/ k c mi l)ShortCircuit Current- Amperes1 Cy c l es 2 Cy c l es 4 Cy c l es 8 Cy c l es16 Cy c l es 30 Cy c l es 60 Cy
49、 c l es 10 0 Cy c l es108 6 4 2 1 1/0 2/0 3/0 4/0 250 5001000350 750C u r v e s B a s e d o n t h e For m u laW h e r e :I = S h o r t C irc u it C u r r e n t - A m p e r e sA = C o n d u c t o r A r e a - C irc u lar M il st = Tim e o f S h o r t C irc u it - S e c o n d sT1= M a x im u m Op e ra ting Tem p e ra tu re - 9 0 CT2= M a x im u m S h o rt C irc u it Tem p e ra tu re - 2 5 0 C234T234Tl o g0 . 0 2 9 7tAI122ICEA P-32-382-2007 (R2013) Page 6 Copyright 2013 by th
