Numerical Analysis of Streamer Discharge Propagation Characteristics in Natural Ester

Natural ester is viewed as the most promising future alternative to mineral oil due to its high degradability, but its inferior breakdown characteristics prevent its application of large power equipment. The purpose of this research is to investigate the breakdown characteristics of natural ester. First, the natural ester's ionization potential and molecular number density are calculated. Then, an improved natural ester streamer discharge model is developed using the Poisson's equation and the carrier continuity equation, taking into account the effect of temperature on carrier mobility and incorporating the computed ionization potential and other factors. The results for different lightning impulse voltages were analyzed by COMSOL software. Comparing the mineral oil, the results indicate that the natural ester breakdown voltage is close to and slightly lower than that of the mineral oil but the acceleration voltage is very similar to the breakdown voltage. The lower ability of esters in prevention against the development of fast and energetic streamers is consistent with the description of the experimental results. In addition, the model takes into account the effect of temperature on the carrier mobility. As the applied voltage increases, the change of temperature in the streamer channel accelerates the carrier motion and promotes the propagation of the streamer. (c) 2022 Institute of Electrical Engineers of Japan. Published by Wiley Periodicals LLC.

Automated summary

Natural ester is a potential alternative to mineral oil with high degradability, but its inferior breakdown characteristics hinder its application in large power equipment. This research investigates the breakdown characteristics of natural ester through calculations and model development. The results show that the natural ester has a similar breakdown voltage but a lower acceleration voltage compared to mineral oil. The model also considers the effect of temperature on carrier mobility.