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Ljubivoje M. Popović

PRACTICAL METHOD FOR ANALYSIS OF GROUND FAULT CURRENT DISTRIBUTION ON GROUNDING SYSTEM OF LARGE HV SUBSTATIONS I. Among outgoing lines there is no any one of double circuit parallel lines. Ljubivoje M. Popović. GROUND FAULT CURRENT COMPONENTS IN THE CASE OF FAULT INSIDE THE STATION.

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Ljubivoje M. Popović

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  1. PRACTICAL METHOD FOR ANALYSIS OF GROUND FAULT CURRENT DISTRIBUTION ON GROUNDING SYSTEM OF LARGE HV SUBSTATIONSI. Among outgoing lines there is no any one of double circuit parallel lines Ljubivoje M. Popović

  2. GROUND FAULT CURRENT COMPONENTS IN THE CASE OF FAULT INSIDE THE STATION

  3. GROUND FAULT CURRENT COMPONENTS IN THE CASE OF FAULT AT AN LINE TOWER IN THE VICINITY OF THE STATION

  4. IDEALISED PHYSICAL MODEL OF AN ACTUAL OVERHEAD LINE

  5. EQUIVALENT CIRCUIT OF AN OVERHEAD LINE UNDER GROUND FAULT CONDITIONS

  6. THEORETICAL BECKGROUND OF THE METHOD1. METHOD OF SIMETRICAL COMPONENTS2. EQUIVALENT VOLTAGE SOURCE AT THE FAULT PLACE, OR THEVENEN GENERATOR 3. DECOUPLING TECHNIQUE, SEPARATE CONSIDERATION OF CURRENTS APPEARING AS A CONSEQUENCE OF INDUCTIVE CONNECTIONS AND CURRENTS APPEARING AS A CONSEQUENCE OF CONDUCTIVE CONNECTIONS 4. GENERAL EQUATIONS OF THE UNIFORME LADER CIRCUITS

  7. EQUIVALENT CIRCUIT OF THE GROUND FAULT CURRENT RETURN PATHS

  8. GENERAL EQUATIONS OF THE UNIFORM LUMPED PARAMETRS LADER CIRCUITS

  9. CONDENSED UNIFORM LADER CIRQUIT TO AN EQUIVALENTπ – TYPE CIRCUIT

  10. CONDENSED EQUIVALENT CIRCUIT FOR THE GROUND FAULT ANYWHERE ALONG THE LINE

  11. ANALYTICAL EXPRESSIONS FOR EQUIVALENT CURRENT SOURCESAND LINE REDUCTION FACTOR

  12. ANALYTICAL EXPRESSIONSFOR EQUIVALENTπ- TYPE CIRCUITS

  13. ACTIVE LINE LENGTH FROM THE STANDPOINT OF GROUNDING EFFECTS

  14. SIMPLIFIED CONDENSED EQUIVALENT CIRCUIT Z0A << Z0B Za≈ 0 Zb ≈ 0

  15. GROUNDING IMPEDANCE AT A FAULT PLACE where: Under the condition: . . . Qb ≈i Pb ≈ Z∞

  16. THE EXAMPLES OF THE SOLVING PRESENTED TRANSCENDENTAL EQUATION

  17. A CASE OF RELATIVELY SHORT TRANSMISSION LINE

  18. EQUIVALENT CIRCUIT FOR DETERMINATION OF THE POTENTIAL AT A FAULTED TOWER

  19. ANALYTICAL EXPRESSIONS FOR POTENTIAL AT A FAULTED TRANSMISSION LINE TOWER

  20. DATA NECESSARY FOR QUANTITATIVE ANALYSIS

  21. SPACE DISPOSITION OF THE TRANSMISSION LINE CONDUCTORS

  22. GROUNDING IMPEDANCE AS A FUNCTION OF THE FAULT PLACE; STEEL G. WIRE

  23. GROUNDING IMPEDANCE AS A FUNCTION OF THE FAULT PLACE; STEEL G. WIRE

  24. GROUNDING IMPEDANCE AS A FUNCTION OF THE FAULT PLACE; ACSR G. WIRE

  25. GROUNDING IMPEDANCE AS A FUNCTION OF THE FAULT PLACE; ACSR G. WIRE

  26. ACTIVE LINE LENGTH FROM THE STANDPOINT OF GROUNDING EFFECTS

  27. CURRENT PASSING THROUGH THE EARTH AS A FUNCTION OF THE FAULT PLACE ALONG THE LINES OF THE LENGTH OF 7.5 km

  28. CURRENT PASSING THROUGH THE EARTH AS A FUNCTION OF THE LINES LENGTH

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