Abstract EN:

The PhD Thesis deals with the modelling of grounding systems of transmission lines with particular reference to the transient phenomena occurring when the conductors of these lines are struck by a lightning stroke. The first part presents the description of the role of grounding systems in transmission lines ; then it contains a brief summary of lightning phenomenology and of the main phenomena involved in the problem of interest. This part of the thesis serves as a base for the next developments as it is devoted to the analysis of the parameters that have the most important influence on the lightning response of the grounding system, withe particular concern on the mechanicsm of the diffusion of the current into the ground. The second part covers the response in the frequency domain of grounding system. The main models proposed in the literature are briefly analysed and one of them, the so-called electromagnetic model, is chosen as reference for the following developments. The choise is justified by thorough theoretical analysis and by comparison with experimental results obtained at the candidate's laboratory. Such a model is then employed in order to find some general criteria aimed at optimizing the structure of the grounding systems of interest. The third part of the thesis is devoted to the development of an innovative procedure ; aim of this procedure is to include the earlier mentioned reference model of grounding systems into transient analysis programs based on circuit and line theory, such as the Electromagnetic Transient Program (EMTP). The aim is to provide a "time-model" of grounding systems, to be used for transients studies. The developed approach allows the representation by means of state equations implemented in the revised version of the EMTP RV of a complex grounding system, having an arbitary number of electrical connections with the transmission system. Such a result is of particular importance for advanced insulation coordination studies and, more in general, for EMC problems involving grounding systems. The developed tool allows also, fourth part of the thesis, for analysis on the propagation of transient phenomena by ground electrodes, with the final aim of evaluating lightning deleterious effects on burien cables and on humans, with reference for this case to step and contact voltages. Cable modelling and risk evaluation for humans with reference to the problem of interest are two points dealt with too in this part of the dissertation. Finally, a part is devoted to the development of an effective numeric method to compute the so-called Pollaczek integral, used in the literature to compute the mutual impedance between an overhead and another overhead/underground conductor of the earth-return impedance of an underground cable, although they give origin to numerical complexities that often lead to use of simpligied models.