PRACTICAL METHOD FOR ANALYSIS OF GROUNDING SYSTEM OF HV/MV SUBSTATIONS LOCATED IN URBAN AND SUBURBAN AREAS
BASIC ELEMENTS OF GROUNDING SYSTEMS SPONTANEOUSLY FORMED IN AN URBAN AREA Substation grounding electrode (substation grounding grid and/or substation building foundation) Outgoing MV cable lines acting as long grounding conductors and /or as conductive connections with grounding systems of supplied MV/LV substations Different underground metal installations conductively connected to the HV/MV substation grounding electrode, mainly water pipelines Reinforced foundations of the surrounding buildings conductively connected to the HV/MV substation grounding electrode through the metal sheaths of outgoing MV cables and LV network neutrals Ground wire(s) of HV feeding line, when it is an overhead line
CHARACTERISTIC DISPOSITION OF HV/MV SUBSTATIONS AND OUTGOING CABLE LINES IN AN URBAN AREA
CHARACTERISTIC DISPOSITION OF THE CABLE LINES BELONGING TO ONE OF PRIMARY DIRECTIOS
SIMPLE CASE: GROUNDING GRID AND ONLY ONE CABLE LINE
ANALYTICAL EXPRESSIONS FOR: RESISTANCE OF GROUNDING GRID
EQUIVALENT CIRCUIT OF FINITE CABLE LINE AS GROUNDING CONDUCTOR OBTAINED BY DISCRETISATION OF ITS, IN REALITY DISTRIBUTED PARAMETERS
GENERAL EQUATIONS OF THE METAL SHEATH REPRESENTED BY DISCRETE PARAMETERS
CHARACTERISTIC PARAMETERS OF CABLE METAL SHEATH AS A SPECIFIC ELECTRICAL LINE
GROUNDING RESISTANCE OF THE CABLE LINE SECTION OF ONE METER ρ – equivalent soil resistivity along the cable line (Ωm) L’ - total cable line length (m) d - outer cable diameter (m) h - depth in which the cable line is buried (m)
SELF- IMPEDANCE OF METAL SHEATH OF THE CABLE LINE SECTION OF ONE METER
EARTH PENETRATION DEPTH OF FAULT CURRENT
GROUNDING SYSTEM COMPOSED OF A SUBSTATION GROUNDING ELECTRODE AND OF ONLY ONE OUTGOING CABLE LINE Grounding system impedance: ?
PROXIMITY EFFECT
CABLE LINES BELONGING TO ONE OF THE PRIMARY DIRECTIONS AND SIMPLIFIED ELECTRICAL CIRCUIT
ANALYTICAL EXPRESSION FOR THE GROUNDING IMPEDANCE OF INFINITE CABLE LINE INCLUDING PROXIMITY EFFECT
ACTIVE CABLE LINE LENGTH AND THE RADIOUS OF AREA COVERED BY THE SPONTENIOUSLY FORMED GROUNDING SYSTEM
ACTIVE CABLE LINE LENGTH AS A FUNCTION OF EQUIVALENT SOIL RESISTIVITY ALONG THE CABLE LINE
EQUIVALENT CIRCUIT FOR DETERMINATION OF THE GROUNDING CONTRIBUTION OF CABLE LINE LAID IN ONE OF THE SECONDARY DIRECTIONS
ANALYTICAL EXPRESSIONS FOR THE GROUNDING CONTRIBUTION OF THE CABLE LINE LAID IN A SECONDARY DIRECTION
AXIAL (TRANSFER) IMPEDANCE OF THE METAL SHEATH SEEN FROM THE BEGINNING TOWARD THE END OF THE LINE
ONE OF THE SUPPLIED MV/LV SUBSTATIONS IS CLOSED TO THE POINT OF DIVERGENCY
ANALYTICAL EXPRESSIONS FOR TAKING INTO ACCOUNT GROUNDING CONTRIBUTION OF THE GROUNDING SYSTEM OF SUPPLIED MV/LV SUBSTATION
POTENTIAL TRANSFERRED TO THE NEAREST MV/LV SUBSTATION
ANALYTICAL EXPRESSIONS FOR THE ESTIMATION OF TRANSFERRED POTENTIAL
ANALYTICAL EXPRESSION FOR THE GROUNDING SYSTEM IMPEDANCE
TRANSFER POTENTIAL COEFFICIENT AS A FUNCTION OF THE LINE LENGTH TO THE SUPPLIED MV/LV SUBSTATION
SAFETY CRITERION THAT SHOULD BE SATISFIED
PRACTICAL EXAMPLE
RELEVANT NUMERICAL DATA · The area covered by the substation is: 26 m x 52 m · The total number of outgoing cable lines is 11; · The places of divergences of the cable lines from the denoted primary directions are at the following distances seen from the substation building: for primary direction I: 210 m and 320 m; for primary direction II: 300 m and 390 m; for primary direction III: 220 m and 290 m; and for primary direction IV: 400 m; · Cables with uncoated metal sheath have an outer diameter of 44 mm and are buried at a depth of 0.7 m; · The self-impedance of the metal sheath of the cables obtained by measurements is: (0.0007 + j0.002) Ω/m; · The whole grounding system is located in an area with an equivalent soil resistivity estimated at about 30 Ωm; ; · The influence of the conductive connections with the grounding system of the nearest supplied MV/LV substation is considered negligible.
MAIN CALCULATION RESULTS