Sizing and protection of conductors: Difference between revisions
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=== [[Worked example of cable calculation|Worked example of cable calculation]] === | === [[Worked example of cable calculation|Worked example of cable calculation]] === | ||
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Download 2010 edition in English: [[Media:EIG-Chap_G-G-2010_haute_def.pdf|pdf]] | |||
Download 2010 edition in French: [[Media:GEI_Chapitre_G_2010_1.pdf|pdf 1/2]] [[Media:GEI_Chapitre_G_2010_2.pdf|2/2]] |
Revision as of 15:46, 12 March 2010
General Contents
Methodology and definition
Overcurrent protection principles
Practical values for a protective scheme
Location of protective devices
Conductors in parallel
Practical method for determining the smallest allowable cross-sectional area of circuit conductors
General
General method for cables
Recommended simplified approach for cables
Busbar trunking systems
Determination of voltage drop
Maximum voltage drop limit
Calculation of voltage drop in steady load conditions
Short-circuit current
Short-circuit current at the secondary terminals of a MV/LV distribution transformer
3-phase short-circuit current (Isc) at any point within a LV installation
Isc at the receiving end of a feeder in terms of the Isc at its sending end
Short-circuit current supplied by an alternator or an inverter
Particular cases of short-circuit current
Calculation of minimum levels of short-circuit current
Verification of the withstand capabilities of cables under short-circuit conditions
Protective earthing conductor
Connection and choice
Conductor sizing
Protective conductor between MV/LV transformer and the main general distribution board (MGDB)
Equipotential conductor
The neutral conductor
Sizing the neutral conductor
Protection of the neutral conductor
Breaking of the neutral conductor
Isolation of the neutral conductor
Worked example of cable calculation
Download 2010 edition in English: pdf