Research on the Stability of Biaxial Excitation of Synchronous Generators

2023 IEEE International Conference on Power Science and Technology (ICPST) Pub Date : 2023-05-05 DOI:10.1109/ICPST56889.2023.10165080

Zehao He, P. Zhou, Zenan Xu, Lingyang Sun, Zhuolin Ye

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Abstract

The biaxially excited synchronous generator overcomes the shortcomings of conventional synchronous generators in fault regulation and is able to regulate the output power of reactive power while transmitting active power, with deep phase in, significantly improving power system stability. In this paper, a vector model of the biaxially excited synchronous generator on the dq0 coordinate system is constructed, the power angle characteristics and basic equations are derived, and the dual-channel excitation method and the active and reactive power regulation process of the biaxially excited synchronous generator are further elaborated. By building a simulation model in Flux simulation software, the effects of the magnitude, action time and input moment of the generator's q-axis excitation current on the power angle and motor stability when a short-circuit fault occurs in the line are investigated in depth. The results indicate the conclusion that the motor with the q-axis excitation current incorporated is more helpful for power system stability than the conventional single-axis motor.

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同步发电机双轴励磁稳定性研究

双轴励磁同步发电机克服了传统同步发电机在故障调节方面的缺点，能够在输送有功功率的同时调节无功输出功率，深相进，显著提高了电力系统的稳定性。本文建立了双轴励磁同步发电机在dq0坐标系下的矢量模型，推导了功率角特性和基本方程，并进一步阐述了双轴励磁同步发电机的双通道励磁方法和有功无功调节过程。通过在Flux仿真软件中建立仿真模型，深入研究了当线路发生短路故障时，发电机q轴励磁电流的大小、作用时间和输入力矩对功率角和电机稳定性的影响。结果表明，与传统的单轴电机相比，加入q轴励磁电流的电机更有利于电力系统的稳定性。

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

2023 IEEE International Conference on Power Science and Technology (ICPST)

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