DETERMING AND ANALYSING PERFORMANCE CHARACTERISTICS OF HIGH-VOLTAGE ELECTROTECHNICAL SYSTEMS BASED ON A SERIES RESONANT LC-CIRCUIT WITH A HIGH Q-FACTOR

Tekhnichna Elektrodynamika Pub Date : 2024-01-31 DOI:10.15407/techned2024.01.003

A. Shcherba, O. D. Podoltsev, N. Suprunovska, D. Vinnychenko

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Abstract

The paper analyzes the performance characteristics of the electrоtechnical system (ETS), built on the basis of a series high-Q resonant LC circuit and intended for diagnosing the isolation of high-voltage equipment. The frequency dependences of the parameters L and C elements of the resonant circuit were experimentally studied and it was shown that for both elements there is an optimal frequency at which the value of the element’s Q- factor reaches its maximum value. It was established that the Q-factor of the investigated circuit is determined mainly by the Q-factor of its inductance and reaches the maximum value QLC,max = 280 at the frequency f= 40 kHz. The Simulink model was developed for the analysis of the performance characteristics of the ETS in steady state. Graphical dependences are given, which allow to determine the level of voltage on the load for a given active resistance of this load, as well as the energy characteristics and the value of the efficiency of the ETS at the stage of its design. A Simulink model has also been developed to analyze the dynamic characteristics of the ETS when a breakdown of the diagnosed insulation occurs. It is shown that the breakdown of the insulation in the ETS, which has a series high-Q resonant circuit, will cause a rapid decrease in current by Q times, and not an increase in current to emergency values, as in an ETS based on high-voltage transformers. In this way, a fast-acting parametric stabilization of the output current is implemented in the ETS even in case of electrical breakdowns of the high-voltage insulation of the power equipment under diagnosis. Thus, the ETS implements high-speed parametric stabilization of the output current, which prevents the destruction of both the ETS and the diagnosed high-voltage insulation of power equipment even during its electrical breakdown. References 11, figures 9.

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确定和分析基于高 Q 因子串联谐振 LC 电路的高压电工系统的性能特征

本文分析了电气技术系统（ETS）的性能特征，该系统以串联高 Q 值谐振 LC 电路为基础，用于诊断高压设备的隔离情况。实验研究了谐振电路中 L 和 C 元件参数的频率相关性，结果表明这两个元件都有一个最佳频率，在该频率上元件的 Q 因子值达到最大值。实验证明，所研究电路的 Q 因子主要由其电感的 Q 因子决定，在频率 f= 40 kHz 时达到最大值 QLC,max = 280。Simulink 模型用于分析 ETS 的稳态性能特征。该模型给出了图形依赖关系，可以确定在给定负载有源电阻的情况下负载上的电压水平，以及 ETS 在设计阶段的能量特性和效率值。此外，还开发了一个 Simulink 模型，用于分析 ETS 在诊断绝缘击穿时的动态特性。结果表明，具有串联高 Q 值谐振电路的 ETS 中的绝缘击穿将导致电流快速下降 Q 倍，而不会像基于高压变压器的 ETS 那样使电流增加到紧急值。这样，即使被诊断电力设备的高压绝缘发生电气故障，ETS 也能实现输出电流的快速参数稳定。因此，ETS 实现了输出电流的高速参数稳定，即使在电力设备发生电气故障时，也能防止 ETS 和被诊断的电力设备高压绝缘损坏。参考文献 11，图 9。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Tekhnichna Elektrodynamika

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