期刊
INTERNATIONAL JOURNAL OF HEAT AND MASS TRANSFER
卷 181, 期 -, 页码 -出版社
PERGAMON-ELSEVIER SCIENCE LTD
DOI: 10.1016/j.ijheatmasstransfer.2021.121861
关键词
Converter transformer winding; Heat transfer; Colburn-j factor; Thermal performance; JF factor
资金
- National Natural Science Foundation of China [52076166]
- Opening Project of State Key Laboratory of Electrical Insulation and Power Equipment, Xi'an Jiaotong University [EIPE20206]
The oil inlet/outlet position and block washer number significantly impact the disc temperature of the winding. Placing the oil inlet near the outside wall reduces the number of overheated discs by 50% compared to the conventional design. Setting block washers reduces the maximum and mean temperature rises of the winding and improves the comprehensive performance. The optimal design includes placing the oil inlet near the outside wall, having 3 block washers, and using an oil mass flow rate of 2mo, resulting in temperature reductions and improved comprehensive performance.
Thermal and hydraulic performance of the converter transformer winding is essential for improving the reliability and economy of the oil-cooled converter transformer. In this paper, a full-scale axisymmetric numerical heat transfer model was developed for a unilateral valve winding of an oil-cooled converter transformer. This model was first validated using data from the reference. Effects of the oil inlet/outlet position and the block washer number on the oil velocity and disc temperature of the winding were then studied under different oil mass flow rates. The thermal, hydraulic and comprehensive performance of the winding was investigated using Colburn-j factor ( j ), Darcy friction factor ( f ) and JF factor (JF), respectively. Finally, the optimal oil inlet/outlet position and block washer number were identified and the performance of the winding in the optimized design was further evaluated. The results showed that both the oil inlet/outlet position and block washer number had a significant impact on the disc temperature of the winding. The number of overheated discs was reduced by 50% when the oil inlet was set near the outside wall of the winding, compared with the conventional design in which the oil inlet was set at the middle of the winding. Furthermore, the maximum and mean temperature rises of the winding were reduced and the comprehensive performance was improved by setting the block washers. The optimal design for the winding was that the oil inlet was allocated near the outside wall of the winding, the number of the block washer was 3 and the oil mass flow rate was 2mo. In this optimal design, the maximum and mean temperature rises of the winding were reduced by 56.1% and 63.9%, respectively, and the comprehensive performance was improved by 145%, compared with the conventional design. (c) 2021 Elsevier Ltd. All rights reserved.
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