ANSI IEEE 693-2005 Recommended Practice for Seismic Design of Substations《变电站抗震设计的推荐实施规程》.pdf

1、IEEE Std 693-2005(Revision of IEEE Std 693-1997)IEEE Recommended Practice forSeismic Design of SubstationsI E E E3 Park Avenue New York, NY 10016-5997, USA8 May 2006IEEE Power Engineering SocietySponsored by theSubstations Committee Recognized as anAmerican National Standard (ANSI)IEEE Std 693-2005(

2、Revision ofIEEE Std 693-1997)IEEE Recommended Practice for Seismic Design of SubstationsSponsorSubstations Committeeof theIEEE Power Engineering SocietyApproved 16 March 2006American National Standards InstituteApproved 8 November 2005IEEE-SA Standards BoardThe Institute of Electrical and Electronic

3、s Engineers, Inc.3 Park Avenue, New York, NY 10016-5997, USACopyright 2006 by the Institute of Electrical and Electronics Engineers, Inc.All rights reserved. Published 8 May 2006. Printed in the United States of America.IEEE is a registered trademark in the U.S. Patent +1 978 750 8400. Permission to

4、 photocopy portions ofany individual standard for educational classroom use can also be obtained through the Copyright ClearanceCenter.NOTEAttention is called to the possibility that implementation of this standard may require use of subjectmatter covered by patent rights. By publication of this sta

5、ndard, no position is taken with respect to theexistence or validity of any patent rights in connection therewith. The IEEE shall not be responsible foridentifying patents for which a license may be required by an IEEE standard or for conducting inquiries into thelegal validity or scope of those pat

6、ents that are brought to its attention.ivCopyright 2006 IEEE. All rights reserved.IntroductionThis revision of IEEE Std 693-1997 was developed as a recommended practice for the seismic design ofsubstations. This recommended practice emphasizes the qualification of electrical equipment. Nuclear Class

7、1E equipment is not covered by this recommended practice, but it is covered by IEEE Std 344TM.This recommended practice is intended to establish standard methods of providing and validating theseismic withstand capability of electrical substation equipment. It provides detailed test and analysismeth

8、ods for each type of major equipment or component found in electrical substations.This recommended practice is intended to assist the substation user or operator in providing substationequipment that will have a high probability of withstanding seismic events to predefined ground accelerationlevels.

9、 It establishes standard methods of verifying seismic withstand capability, which gives the substationdesigner the ability to select equipment from various manufacturers, knowing that the seismic withstandrating of each manufacturers equipment is an equivalent measure.This recommended practice is al

10、so intended to guide the manufacturers of power equipment in the seismicdesign and in demonstrating and documenting the seismic withstand capability of their product in a formthat can be universally accepted.Although most damaging seismic activity occurs in limited areas, many additional areas could

11、 experience anearthquake with forces capable of causing great damage. This recommended practice should be used in allareas that may experience earthquakes.It is the hope of those who worked on the development of this recommended practice that these standardmethods of verifying seismic withstand capa

12、bility will lead to better earthquake performance and to lowerqualification costs.Notice to usersErrataErrata, if any, for this and all other recommended practices can be accessed at the following URL: http:/standards.ieee.org/reading/ieee/updates/errata/index.html. Users are encouraged to check thi

13、s URL forerrata periodically.InterpretationsCurrent interpretations can be accessed at the following URL: http:/standards.ieee.org/reading/ieee/interp/index.html.This introduction is not part of IEEE Std 693-2005, IEEE Recommended Practice for Seismic Design of Substations.vCopyright 2006 IEEE. All

14、rights reserved.PatentsAttention is called to the possibility that implementation of this recommended practice may require use ofsubject matter covered by patent rights. By publication of this recommended practice, no position is takenwith respect to the existence or validity of any patent rights in

15、 connection therewith. The IEEE shall not beresponsible for identifying patents or patent applications for which a license may be required to implementan IEEE standard or for conducting inquiries into the legal validity or scope of those patents that are broughtto its attention.ParticipantsThe follo

16、wing is a list of participants in the Seismic Design of Substations Working Group. Rulon Fronk, ChairEric Fujisaki, Vice ChairAlan King, Co-Vice ChairWilliam (Woody) Savage, SecretaryLarry BowieSteve BrownDavid BruckerTerry BurleyPhilip CaldwellRon CamposFlorian CostaJean-Bernard DastousMike Dickins

17、onLonnie ElderKeith EllisWillie FreemanJoseph GrazianoVincente GuerreroWilliam E. GundyHusein HasanCarl HorvathJohn IrvinCarl JohnsonLeon Kempner Jr.Kamran KhanDonald Kleyweg Jr.Eric KressTim LittleAlberto LpezKevin MaconKelly MerzPeter MeyerBarry MillerMichael MillerPhilip MoJon MochizukiAl MolnerT

18、imothy MooreJerry MundonDennis OstromHelen PetersenJean-Robert PierreJohn RandolphCraig RikerDamaso RoldanWolfgang SaadAnshel SchiffJulia ShaughnessyGerald StewartRobert StewartCharles ToddRon TognazziniMark WilliamsPedro ZazuetaviCopyright 2006 IEEE. All rights reserved.The following members of the

19、 individual balloting committee voted on this recommended practice.Balloters may have voted for approval, disapproval, or abstention. William AckermanDavid AhoRichard AichingerStan J. ArnotSabir Azizi-GhannadMunnu BajpaiThomas BarnesStan BillingsWallace BinderAnne BosmaSteven BrownTed BurseCarl Bush

20、Weijen ChenRon CamposGiuseppe CarboneRobert CarruthDonald CashGarry ChapmanKeith ChowMichael ComberJerry CorkranJohn CrouseWilliam DarovnyJean-Bernard DastousR. DaubertMatthew DavisNicholas DeSantisFrank DenbrockGuru Dutt DhingraJerry DiSciulloDieter DohnalDenis DufournetJames EdmondsGary EngmannMeh

21、rdad EskandaryEric FujisakiHarry GianakourosDavid GilmerJoseph GrazianoWilliam GriesackerRandall GrovesRobert GrunertJim GurneyKenneth HarlessHusein HasanSteven HensleyCarl HorvathDennis HorwitzChris HuntleyMagdi IshacDavid IttnerDavid W. JacksonJames H. JonesLars-Erick JuhlinInnocent KamwaLeon Kemp

22、ner Jr.Gael R. KennedyKamran KhanAlan KingHermann KochRobert KonnikAntonio LimJason LinGene LindholmLisardo LouridoGregory LuriOtto LynchJoseph MaAl MaguireKeith MalmedalDonald MarihartJesus MartinezFrank MayleKen McClenahanNigel McQuinJohn MerandoGary MichelPhilip MoGary L. NissenJeffrey NelsonMich

23、ael NewmanJoe NimsRobert NowellT. W. OlsenMiklos OroszBob OswaldKlaus PappJames ParelloNeal ParkerBansi PatelPaul PillitteriJohn RandolphCraig RikerTimothy RobirdsDinesh SankarakurupDouglas SeelyH. Jin SimChuck SimmonsPritpal SinghTarkeshwar SinghDave SingletonH. Melvin SmithRichard StarckBob Stewar

24、tCharles ToddNorbert TrappJoe WatsonKenneth WhiteAlan WilksJames WilsonRichard YorkRoland YoungbergXi ZhuviiCopyright 2006 IEEE. All rights reserved.When the IEEE-SA Standards Board approved this recommended practice on 8 November 2005, it had thefollowing membership:Steve M. Mills, ChairRichard H.

25、Hulett, Vice ChairDon Wright, Past ChairJudith Gorman, Secretary*Member EmeritusAlso included are the following nonvoting IEEE-SA Standards Board liaisons:Satish K. Aggarwal, NRC RepresentativeRichard DeBlasio, DOE RepresentativeAlan H. Cookson, NIST RepresentativeDon MessinaIEEE Standards Project E

26、ditorMark D. BowmanDennis B. BrophyJoseph BruderRichard CoxBob DavisJulian Forster*Joanna N. GueninMark S. HalpinRaymond HapemanWilliam B. HopfLowell G. JohnsonHerman KochJoseph L. Koepfinger*David J. LawDaleep C. MohlaPaul NikolichT. W. OlsenGlenn ParsonsRonald C. PetersenGary S. RobinsonFrank Ston

27、eMalcolm V. ThadenRichard L. TownsendJoe D. WatsonHoward L. WolfmanContents 1. Overview 1 1.1 General 1 1.2 Scope . 1 1.3 Purpose 1 1.4 How to use this recommended practice . 2 1.5 Acceptance of previously qualified electrical equipment 3 1.6 Earthquakes and substations 4 1.7 Design and construction

28、 4 1.8 The equipment at risk 5 1.9 Mechanical loads . 5 2. Normative references 5 3. Definitions, acronyms, and abbreviations 7 3.1 Definitions . 7 3.2 Abbreviations and acronyms . 10 4. Instructions . 11 4.1 General 11 4.2 Specifying this recommended practice in users specifications. 11 4.3 Standar

29、dization of criteria 12 4.4 Selection of qualification level 12 4.5 Witnessing of shake-table testing 13 4.6 Optional qualification methods 13 4.7 Qualifying equipment by group. 14 4.8 Inherently acceptable equipment . 15 4.9 Shake-table facilities 15 4.10 Equipment too large to be tested in its in-

30、service configuration 16 4.11 Report templates 16 5. Installation considerations 16 5.1 General 16 5.2 Equipment assembly 17 5.3 Site response characteristics 17 5.4 Soil-structure interaction . 17 5.5 Support structures 17 5.6 Base isolation. 19 5.7 Suspended equipment 19 5.8 Anchorage 22 5.9 Condu

31、ctor induced loading 23 5.10 Short-circuit loads 28 5.11 Wind and ice loads 29 viii Copyright 2006 IEEE. All rights reserved. 6. Qualification methods: an overview. 29 6.1 General 29 6.2 Analysis methods. 30 6.3 Testing methods. 30 6.4 Special test cases . 31 6.5 Qualification method for specific eq

32、uipment 32 6.6 Functionality of equipment 32 6.7 Qualification by seismic experience data 32 6.8 Response spectra 33 6.9 Damping 34 7. Design considerations. 34 7.1 Structural supports, excluding foundations 34 7.2 Foundation analysis . 34 7.3 Station service 35 7.4 Emergency power systems 36 7.5 Te

33、lecommunication equipment . 38 8. Seismic performance criteria for electrical substation equipment 38 8.1 Introduction . 38 8.2 Objective 38 8.3 Seismic qualification levels . 39 8.4 Projected performance. 40 8.5 Seismic qualification . 42 8.6 Selecting the seismic level for seismic qualification .

34、42 Annex A (normative) Standard clauses 47 Annex B (normative) Equipment, general 74 Annex C (normative) Circuit breakers . 77 Annex D (normative) Transformers and liquid-filled reactors.82 Annex E (normative) Disconnect and grounding switches.89 Annex F (normative) Instrument transformers . 93 Anne

35、x G (normative) Air core reactors 97 Annex H (normative) Circuit switches. 100 Annex I (normative) Suspended equipment . 104 ix Copyright 2006 IEEE. All rights reserved. Annex J (normative) Station batteries and battery racks 109 Annex K (normative) Surge arresters. 113 Annex L (normative) Substatio

36、n electronic devices, distribution panels and switchboards, and solid-state rectifiers 117 Annex M (normative) Metalclad switchgear 120 Annex N (normative) Cable terminators (potheads). 123 Annex O (normative) Capacitors, series, and shunt compensation 126 Annex P (normative) Gas-insulated switchgea

37、r . 128 Annex Q (normative) Experience-based qualification procedures for low-voltage substation equipment 133 Annex R (informative) Composite and porcelain insulators 135 Annex S (normative) Analysis report template 148 Annex T (normative) Test report template . 155 Annex U (informative) Specificat

38、ions 165 Annex V (informative) Bibliography . 166 x Copyright 2006 IEEE. All rights reserved. IEEE Recommended Practice for Seismic Design of Substations 1. Overview 1.1 General This recommended practice provides minimum requirements for the seismic design of substations, excluding Class 1E equipmen

39、t for nuclear power generation stations. Seismic qualification of electrical equipment and its support is emphasized. 1.2 Scope The recommended practice contains recommendations for the seismic design of substation buildings, structures, and equipment. 1.3 Purpose This recommended practice is for ne

40、w substations and planned additions or improvements to existing substations. It is not intended that existing substations must be retrofitted to these recommended practices. For instruction on how to include this recommended practice in specifications, refer to 5.2. IEEE Std 693 is designed as an in

41、tegrated set of requirements for the seismic qualification of electrical power equipment. Users should use IEEE Std 693 as a whole. Do not modify or remove any requirement, except as allowed herein. If any part of this recommended practice is removed, not met, or reduced, then neither the user nor t

42、he manufacturer may claim the equipment is in compliance with IEEE Std 693 and should not attach the seismic identification plate to the equipment. The user is strongly urged not to modify any of the requirements herein, including increasing or adding to the requirements. The most important goal of

43、this recommended practice is to provide a single standard set of design recommendations for seismic qualification of each equipment type. Design recommendations consist of seismic criteria, qualification methods and levels, structural capacities, performance requirements for equipment operation, ins

44、tallation methods, and documentation. The intent of a uniform and consistent seismic qualification procedure is to reduce the cost for qualification of substation equipment, because the 1 Copyright 2006 IEEE. All rights reserved. IEEE Std 693-2005 IEEE Recommended Practice for Seismic Design of Subs

45、tations manufacturers can qualify their equipment once for each qualification level and eliminate specialized testing. It should also improve earthquake performance by establishing clear performance criteria that take into account the dynamic characteristics of substation equipment. Three qualificat

46、ion levels are defined. They are low, moderate, and high. The user should determine the desired qualification level when purchasing the equipment. See Clause 8. This recommended practice is divided into 8 Clauses (Clause 1 through Clause 8) and 22 Annexes (Annex A through Annex V). Clauses contain g

47、eneral seismic design requirements. Annex C through Annex P contain equipment-specific seismic design requirements and are located after the clauses. If the type of equipment to be qualified is not specifically addressed in Annex C through Annex P, the seismic design requirements of Annex B may be u

48、sed, if applicable. Annexes are titled normative or informative. Normative annexes are official parts of this recommended practice. Informative annexes include information only and are not an official part of this recommended practice. The following references are recommended for seismic design of s

49、ubstation structures, foundations, and anchorage1: Buildings: International Building Code (IBC), Mexican Code (MDOC/CFE), Uniform Building Code (UBC), or National Building Code of Canada (NBCC). Anchorage design: American Society of Civil Engineers (ASCE) Substation Structure Design Guide. NOTEAnchorage design requirements are found in the ASCE Substation Structure Design Guide. Anchorage requirements for equipment qualification are provided in this recommended practice.2 Foundation Design: International Building Code (IBC), Uniform Building Code (UBC), Mexican