The analytical study of grounding systems is only possible for basic electrodes, i.e. hemispherical and spherical electrodes, rods and horizontal wires. However, it is normal practice to employ more complex earthing systems, such as grounding grids integrated with rods, in order to obtain lower resistances-to-ground and improve the electrical safety of substations. This paper introduces a semi-analytical (or semi-numerical) method, consisting of an analytical approach integrated with a numerical solution, to study grounding grids of complex geometry and their effects on non-stratified soils. The algorithm that was created, and realized with MATLAB, allows the determination of all the quantities of interest for the design and the analysis of such grounding systems: ground-resistance, ground potentials and the distribution of the ground-fault current along the grid's components (i.e. horizontal wires and rods). The model is based on the assumption that conductors forming grids have radii very small if compared to their lengths and that the wires can be considered equipotential cylindrical elements. A verification of the proposed algorithm through a finite element method (FEM) has also been carried out to confirm the validity of the results. Exemplary calculations of the ground resistance of grids are included in the paper.
[1]
YANQING CHEN,et al.
Algorithm 8 xx : CHOLMOD , supernodal sparse Cholesky factorization and update / downdate ∗
,
2006
.
[2]
C. Trowbridge,et al.
The Analytical and Numerical Solution of Electric and Magnetic Fields
,
1992
.
[3]
J. W. Humberston.
Classical mechanics
,
1980,
Nature.
[4]
A. Canova,et al.
Evaluation of Voltage Exposures Due to AC/DC Stray Currents
,
2007,
2007 IEEE Industry Applications Annual Meeting.
[5]
Patrick H. Worley,et al.
Algorithm 888: Spherical Harmonic Transform Algorithms
,
2008,
TOMS.
[6]
Sponsor,et al.
IEEE guide for safety in AC substation grounding
,
2013
.