A Numerical Simulation Method Based on Particle Reactions for Corona Audible Noise

IF 1.3 4区物理与天体物理 Q3 PHYSICS, FLUIDS & PLASMAS

IEEE Transactions on Plasma Science Pub Date : 2025-02-05 DOI:10.1109/TPS.2025.3532792

Penghui Zhao;Haibin Yuan;Yingyi Liu;Haiwen Yuan;Yuxin Deng

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引用次数: 0

Abstract

High-voltage direct current (HVdc) transmission technology plays a crucial role in modern electrical power industries. However, with the increasing voltage of transmission lines, audible noise has become a significant factor limiting the planning and construction. To research audible noise’s generation mechanisms and prediction method, this article models corona discharge on a rod-plate structure and calculates the generation and movement of particles based on 23 gas-phase reactions and eight surface reactions. We integrate the model with an acoustic source framework, which employs the electroacoustic conversion theory, solving the acoustic fluctuation equation to compute audible noise. The simulation results show a 7.5% discrepancy in the time-domain amplitude of audible noise compared to experimental measurements. The average and distribution of audible noise amplitudes from simulations and measurements at different voltages and electrode distances show a high consistency, demonstrating the accuracy of the proposed method. This approach contributes to understanding the mechanisms underlying audible noise and facilitates predictions through numerical calculations, providing a reference for designing HVdc transmission lines.

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高压直流（HVdc）输电技术在现代电力工业中发挥着至关重要的作用。然而，随着输电线路电压的不断提高，可听噪声已成为限制规划和建设的重要因素。为了研究可听噪声的产生机理和预测方法，本文建立了杆板结构上的电晕放电模型，并根据 23 个气相反应和 8 个表面反应计算了粒子的产生和运动。我们将模型与声源框架相结合，采用电声转换理论，求解声学波动方程来计算可听噪声。模拟结果显示，与实验测量结果相比，可听噪声的时域振幅相差 7.5%。在不同电压和电极距离下，模拟和测量得出的可听噪声振幅的平均值和分布具有很高的一致性，证明了所提出方法的准确性。这种方法有助于理解可听噪声的基本机制，并通过数值计算进行预测，为设计高压直流输电线路提供参考。

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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来源期刊

IEEE Transactions on Plasma Science 物理-物理：流体与等离子体

CiteScore

3.00

自引率

20.00%

发文量

538

审稿时长

3.8 months

期刊介绍： The scope covers all aspects of the theory and application of plasma science. It includes the following areas: magnetohydrodynamics; thermionics and plasma diodes; basic plasma phenomena; gaseous electronics; microwave/plasma interaction; electron, ion, and plasma sources; space plasmas; intense electron and ion beams; laser-plasma interactions; plasma diagnostics; plasma chemistry and processing; solid-state plasmas; plasma heating; plasma for controlled fusion research; high energy density plasmas; industrial/commercial applications of plasma physics; plasma waves and instabilities; and high power microwave and submillimeter wave generation.