Journal of Mechatronics, Electrical Power, and Vehicular Technology

High voltage substations built within areas prone to vegetation or with unfavourable subgrade conditions are paved with the addition of punched geotextiles and non-conductive synthetic fabrics underneath switchyard surfacing. The aim of this research is to identify the impact of synthetic textiles on earthing system performance through numerical analysis with the state-of-the-art software package. The new layer interferes with the earthing grids performance with a different behaviour depending on the installation above or underneath the layer with considerable impact taking place when the earthing grid is installed above the geotextile layer. Rods penetrating the geotextile can alleviate the potential voltage distribution issues and improve the earthing system performance regardless of the native soil stratification.

substation earthing; synthetic geotextile; tolerable voltages; high voltage.

J. He, R. Zeng, B. Zhang, Methodology and technology for power system grounding, John Wiley & Sons, 2013.

IEC 60479-1:2018: Effects of current on human beings and livestock - Part 1: General aspects.

IEEE Guide for Safety in AC Substation Grounding, in IEEE Std 80-2013 (Revision of IEEE Std 80-2000/ Incorporates IEEE Std 80-2013/Cor 1-2015), pp. 1-226, 15 May 2015.

J. Liu, F. P. Dawalibi, S. Tee, “Analysis of Current Density in Soil for Resistivity Measurements and Electrical Grounding Designs,” Journal of Electrical and Electronic Engineering, Vol. 5, No. 5, pp. 198-208, 2017.

B. Alsharari, A. Olenko, H. Abuel-Naga, Modeling of electrical resistivity of soil based on geotechnical properties, Expert Systems with Applications, 141, 112966, available online 19 September 2019.

R. A. Fayed and A. S. Ezeldin, Simulation and optimization model for electrical substation construction. PhD diss., American Univeristy in Cairo, 2016.

A. Ackerman, P. K. Sen, and C. Oertli, Designing safe and reliable grounding in AC substations with poor soil resistivity: An interpretation of IEEE STD. 80, Record of Conference Papers - Annual Petroleum and Chemical Industry Conference, 49 (4), 1883-1889, 2012.

R. D. Southey, M. Siahrang, S. Fortin, and F. P. Dawalibi, “Using fall-of-potential measurements to improve deep soil resistivity estimates,” IEEE Transactions on Industry Applications, 51(6), 5023-5029, 2015.

S. C. Lim, C. Gomes, and M. Z. A. Ab Kadir, “Electrical earthing in troubled environment,” International Journal of Electrical Power and Energy Systems, 47(1), 117-128, 2013.

J. E. Edlebeck and B. Beske, “Identifying and quantifying material properties that impact aggregate resistivity of electrical substation surface material,” IEEE Transactions on Power Delivery, 29(5), 2248-2253, 2014.

C. J. F. P. Jones, J. Lamont-Black, and S. Glendinning, “Electrokinetic geosynthetics in hydraulic applications,” Geotextiles and Geomembranes, 29(4), 381-390, 2011.

A. N. Ramani, A. R. Ahmad, M. F. Sulaima, M. N. M. Nasir, and A. Ahmad, “Analysis the configuration of earthing system based on high-low and low-high soil structure,” AIP Conference Proceedings, 1660, 2015.

W. L. Lai, W. F. H. Wan Ahmad, J. Jasni, and M. Z. A. Ab Kadir, “A review on the usage of Zeolite, Perlite and Vermiculite as natural enhancement materials for grounding system installations,” IEEE Student Conference on Research and Development: Inspiring Technology for Humanity, SCOReD 2017 - Proceedings, 2018-January, 338-343, 2018.

Global Synthetics, Geofirma technical datasheet.

C. Skaar, Electrical Properties of Wood, In: Wood-Water Relations, Springer Series in Wood Science, Springer, Berlin, Heidelberg, 1988.

“IEEE Guide for Measuring Earth Resistivity, Ground Impedance, and Earth Surface Potentials of a Grounding System," in IEEE Std 81-2012 (Revision of IEEE Std 81-1983), pp. 1-86, 28 Dec. 2012.

CDEGS RESAP Soil Resistivity Analysis Module – Safe Engineering Services & technologies ltd., Canada.