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IEC TR 60909-1:2002

Current

Current

The latest, up-to-date edition.

Short-circuit currents in three-phase a.c. systems - Part 1: Factors for the calculation of short-circuit currents according to IEC 60909-0

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Hardcopy , PDF , PDF 3 Users , PDF 5 Users , PDF 9 Users

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English - French, English, French, Spanish, Castilian

Published date

07-31-2002

US$400.00
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FOREWORD
1 General
   1.1 Scope and object
   1.2 Reference documents
   1.3 Application of the factors
        1.3.1 Factor [c]
        1.3.2 Factors K[G] and K[S] or K[SO]
        1.3.3 Factors K[G,S], K[T,S] or K[G,SO], K[T,SO]
        1.3.4 Factor K[T]
        1.3.5 Factor [kappa]
        1.3.6 Factors [mu], [lambda] and [q]
        1.3.7 Factors [m] and [n]
        1.3.8 Contribution of asynchronous motors to the
              initial symmetrical short-circuit current
   1.4 Symbols, subscripts and superscripts
        1.4.1 Symbols
        1.4.2 Subscripts
        1.4.3 Superscripts
2 Factors used in IEC 60909-0
   2.1 Voltage factor [c] for the equivalent voltage source
        at the short-circuit location
        2.1.1 General
        2.1.2 Calculation methods
        2.1.3 Equivalent voltage source at the short-circuit
              location and voltage factor [c]
        2.1.4 A simple model illustrating the meaning of the
              voltage factor [c]
   2.2 Impedance-correction factors when calculating the
        short-circuit impedances of generators, unit
        transformers and power-station units
        2.2.1 General
        2.2.2 Correction factor K[G]
        2.2.3 Correction factors for power station units with
              on-load tap changer
        2.2.4 Correction factors for power station units
              without on-load tap-changer
        2.2.5 Influence of the impedance correction factor for
              power-station units when calculating short-circuit
              currents in meshed networks and maximum
              short-circuit currents at worst-case load flow
   2.3 Impedance correction factor K[T] when calculating the
        short-circuit impedances of network transformers
        2.3.1 General
        2.3.2 Example for a network transformer S[rT] = 300 MVA
        2.3.3 Statistical examination of 150 network transformers
        2.3.4 Impedance correction factors for network
              transformers in meshed networks
   2.4 Factor [kappa] for the calculation of the peak
        short-circuit current
        2.4.1 General
        2.4.2 Factor [kappa] in series R-L-circuits
        2.4.3 Factor [kappa] of parallel R-L-Z branches
        2.4.4 Calculation of the peak short-circuit current I[p]
              in meshed networks
        2.4.5 Example for the calculation of [kappa] and I[p] in
              meshed networks
   2.5 Factor [mu] for the calculation of the symmetrical
        short-circuit breaking current
        2.5.1 General
        2.5.2 Basic concept
        2.5.3 Calculation of the symmetrical short-circuit
              breaking current I[b] with the factor [mu]
   2.6 Factor [lambda] (lambda[max], lambda[min]) for the
        calculation of the steady-state short-circuit current
        2.6.1 General
        2.6.2 Influence of iron saturation
   2.7 Factor [q] for the calculation of the short-circuit
        breaking current of asynchronous motors
        2.7.1 General
        2.7.2 Derivation of factor [q]
        2.7.3 Short-circuit breaking currents in the case of
              unbalanced short circuits
   2.8 Factors [m] and [n] for the calculation of the Joule
        integral or the thermal equivalent short-circuit current
        2.8.1 General
        2.8.2 Time-dependent three-phase short-circuit current
        2.8.3 Factor [m]
        2.8.4 Factor [n]
        2.8.5 Factor [n] in IEC 60909-0, figure 22
   2.9 Statement of the contribution of asynchronous motors or
        groups of asynchronous motors (equivalent motors) to the
        initial symmetrical short-circuit current
        2.9.1 General
        2.9.2 Short circuit at the terminals of asynchronous
              motors
        2.9.3 Partial short-circuit currents of asynchronous
              motors fed through transformers
        2.9.4 Sum of partial short-circuit currents of several
              groups of asynchronous motors fed through several
              transformers
Bibliography
Figures
Tables

Applies to short-circuit currents in three-phase a.c. systems. This technical report aims at showing the origin and the application, as far as necessary, of the factors used to meet the demands of technical precision and simplicity when calculating short-circuit currents according to IEC 60909-0.

DevelopmentNote
To be read in conjunction with IEC 60909-0. (08/2002) Also numbered as BS PD7639-1(1994). (08/2005) Stability Date: 2018. (10/2012)
DocumentType
Technical Report
Pages
161
PublisherName
International Electrotechnical Committee
Status
Current

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I.S. EN 60027-7:2010 LETTER SYMBOLS TO BE USED IN ELECTRICAL TECHNOLOGY - PART 7: POWER GENERATION, TRANSMISSION AND DISTRIBUTION
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I.S. EN 60909-0:2016 SHORT-CIRCUIT CURRENTS IN THREE-PHASE A.C. SYSTEMS - PART 0: CALCULATION OF CURRENTS
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UNE-EN 61230:2011 Live working - Portable equipment for earthing or earthing and short-circuiting
BS IEC 61892-2:2012 Mobile and fixed offshore units. Electrical installations System design
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IEC 60038:2009 IEC standard voltages
IEC 60909-3:2009 Short-circuit currents in three-phase AC systems - Part 3: Currents during two separate simultaneous line-to-earth short circuits and partial short-circuit currents flowing through earth
IEC 60909-0:2016 Short-circuit currents in three-phase a.c. systems - Part 0: Calculation of currents
IEC 60865-1:2011 Short-circuit currents - Calculation of effects - Part 1: Definitions and calculation methods
IEC 60909:1988 Short-circuit current calculation in three-phase a.c. systems

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