Research on temperature distribution characteristics of oil-immersed power transformers based on fluid network decoupling

IF 4.4 2区 工程技术 Q1 ENGINEERING, ELECTRICAL & ELECTRONIC
High Voltage Pub Date : 2024-09-27 DOI:10.1049/hve2.12488
Yongming Xu, Ziyi Xu, Congrui Ren, Yaodong Wang
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引用次数: 0

Abstract

Due to the complex structure and large size of large-capacity oil-immersed power transformers, it is difficult to predict the winding temperature distribution directly by numerical analysis. A 180 MVA, 220 kV oil-immersed self-cooling power transformer is used as the research object. The authors decouple the internal fluid domain of the power transformer into four regions: high voltage windings, medium voltage windings, low voltage windings, and radiators through fluid networks and establish the 3D fluid-temperature field numerical analysis model of the four regions, respectively. The results of the fluid network model are used as the inlet boundary conditions for the 3D fluid-temperature numerical analysis model. In turn, the fluid resistance of the fluid network model is corrected according to the results of the 3D fluid-temperature field numerical analysis model. The prediction of the temperature distribution of windings is realised by the coupling calculation between the fluid network model and the 3D fluid-temperature field numerical analysis model. Based on this, the effect of the loading method of the heat source is also investigated using the proposed method. The hotspot temperatures of the high-voltage, medium-voltage, and low-voltage windings are 89.43, 86.33, and 80.96°C, respectively. Finally, an experimental platform is built to verify the results. The maximum relative error between calculated and measured values is 4.42%, which meets the engineering accuracy requirement.

Abstract Image

基于流体网络解耦的油浸式电力变压器温度分布特性研究
由于大容量油浸式电力变压器结构复杂、体积庞大,很难通过数值分析直接预测绕组温度分布。本文以一台 180 MVA、220 kV 油浸式自冷电力变压器为研究对象。作者通过流体网络将电力变压器内部流体域解耦为高压绕组、中压绕组、低压绕组和散热器四个区域,并分别建立了四个区域的三维流体-温度场数值分析模型。流体网络模型的结果被用作三维流体温度数值分析模型的入口边界条件。而流体网络模型的流体阻力则根据三维流体-温度场数值分析模型的结果进行修正。绕组温度分布的预测是通过流体网络模型和三维流体温度场数值分析模型之间的耦合计算实现的。在此基础上,还利用所提出的方法研究了热源加载方法的影响。高压、中压和低压绕组的热点温度分别为 89.43、86.33 和 80.96°C。最后,建立了一个实验平台来验证结果。计算值和测量值之间的最大相对误差为 4.42%,符合工程精度要求。
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
High Voltage
High Voltage Energy-Energy Engineering and Power Technology
CiteScore
9.60
自引率
27.30%
发文量
97
审稿时长
21 weeks
期刊介绍: High Voltage aims to attract original research papers and review articles. The scope covers high-voltage power engineering and high voltage applications, including experimental, computational (including simulation and modelling) and theoretical studies, which include: Electrical Insulation ● Outdoor, indoor, solid, liquid and gas insulation ● Transient voltages and overvoltage protection ● Nano-dielectrics and new insulation materials ● Condition monitoring and maintenance Discharge and plasmas, pulsed power ● Electrical discharge, plasma generation and applications ● Interactions of plasma with surfaces ● Pulsed power science and technology High-field effects ● Computation, measurements of Intensive Electromagnetic Field ● Electromagnetic compatibility ● Biomedical effects ● Environmental effects and protection High Voltage Engineering ● Design problems, testing and measuring techniques ● Equipment development and asset management ● Smart Grid, live line working ● AC/DC power electronics ● UHV power transmission Special Issues. Call for papers: Interface Charging Phenomena for Dielectric Materials - https://digital-library.theiet.org/files/HVE_CFP_ICP.pdf Emerging Materials For High Voltage Applications - https://digital-library.theiet.org/files/HVE_CFP_EMHVA.pdf
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