Abstract:
The insulation strength of electrical equipment is
required to be accurately tested to prevent insulation failures
caused by abrupt overvoltages due to lightning strikes on power
systems. In conventional methods, Marx impulse generators are
used to produce impulse waveforms for testing. However, these
methods often involve time consuming trial and error procedures
and run the risk of damaging transformers during tests. This
study proposes an algorithmic method for selecting resistor
values in Marx generators to generate lightning impulse test
waveforms. The proposed method establishes a circuit model
based on the transformer’s frequency response and uses an
optimization algorithm that combines a genetic algorithm with
simulations of electromagnetic transients. The primary objective
of the optimization process is to minimize the difference between
the desired and simulated waveforms while obtaining optimum
resistor block values. The proposed optimization-enabled method
not only enhances accuracy in testing procedures but also reduces
testing time and improves protection for test transformers.
Consequently, these findings hold practical implications for electrical
equipment manufacturers, test engineers, and researchers
involved in insulation impulse testing, thereby promoting more
reliable and effective testing procedures in the industry.
Citation:
R. S. D. Silva, U. Vinusan, S. K. Aldeniya, R. Samarasinghe and M. Gunawardana, "Optimizing Marx Impulse Generator Settings for Lightning Impulse Testing of Transformers: An Automated Approach for Enhanced Efficiency and Accuracy," 2023 Moratuwa Engineering Research Conference (MERCon), Moratuwa, Sri Lanka, 2023, pp. 189-194, doi: 10.1109/MERCon60487.2023.10355423.