In other words how do conductors with different resistor, capacitor, and inductor ratings perform in a power system when matched with different transmission tower configurations?
500 kV system has a higher spacing as well as larger clearance from the ground compared to 345 kV system. This results in increased reactance and capacitance, as these quantities mainly depend on spacing and clearance.
As for the resistance, it's exclusively conductor dependent. So, the same conductor if used in both voltage levels will have the same resistance.
Spacing and groundclearamce are the factors but a power system is connected with a transformer so step up and step down action happens and conductors are usualy bundled to reduce corona loss and moreover the reactive drops are covered by the transmission line inductance and the role of capacitance comes into picture mainly for long distance lines leading to ferranti effect the question is aboit how power system is functional like 500 to 345 the answer here would be power system has stages of interconnection starting from generation then transmission and distribution for a more clear understanding power system distribution by turan gonen is recommended
Electric and Magnetic field properties may be considered rather than resistance, inductance and capacitance of transmission lines for HV lines. Better refer to the attached file.
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