考虑屏蔽套失效的主泵电机建模及性能分析

doi:10.19595/j.cnki.1000-6753.tces.L11046

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摘要屏蔽套是主泵电机的关键部件,由于屏蔽套受到多种应力作用容易发生失效及难以加装相关传感器观测屏蔽套状态,因此研究屏蔽套失效对主泵电机性能的影响很重要。目前,缺乏相关屏蔽套失效模型和失效对主泵电机性能的影响分析,该文提出了考虑屏蔽套失效的主泵电机建模及性能影响分析方法。首先,考虑屏蔽套鼓包、磨损与破裂三种常见失效模式,分别建立有限元模型,分析不同失效模式和失效程度对主泵电机电磁转矩、定子绕组电流、气隙磁通密度、反电动势和屏蔽套涡流损耗等性能的影响规律;其次,针对失效对屏蔽套涡流损耗的影响,提出考虑不同失效模式的屏蔽套涡流损耗计算解析式;最后,对屏蔽套不同失效模式和失效程度的性能变化进行比较分析。结果表明,屏蔽套失效对主泵电机涡流损耗的影响较为明显,对主泵电机的其他性能影响不明显;考虑不同屏蔽套失效涡流损耗解析计算方法是有效的,屏蔽套上的涡流损耗与屏蔽套失效的程度呈线性关系。

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关键词 ：屏蔽套, 主泵电机, 失效模拟, 性能分析, 涡流损耗

Abstract：The can is a critical component of the main pump canned motor, located within the air gap of the main pump. It endures various stresses such as electromagnetic force, coolant pressure, and thermal stress, making it prone to failure. Due to the limited installation space, it is challenging to install relevant sensors to monitor its condition, thus making the study of can faults and their impact on the performance of the main pump canned motor significantly important. Currently, there is a lack of models and analysis focusing on can faults and their effects on the performance of the main pump canned motor. This paper proposes a modeling method that considers can faults and analyzes their impact on the performance of canned motors for main pumps.
Firstly, to accurately calculate the performance of the main pump canned motor, a finite element model of the main pump canned motor was established. This model considers three common failure modes of the can: bulging, wear, and cracking. Maxwell finite element models of the main pump canned motor were developed for each type of can fault. Based on finite element calculation results, the impact of different can fault modes and varying degrees of severity on the performance of the main pump canned motor was analyzed. The study revealed that can failures have a significant effect on the eddy current loss within the can, but have minimal impact on back electromotive force and winding current, and relatively little effect on torque and air gap magnetic flux density. Finally, to address the impact of can failures on eddy current losses within the can, an analytical expression for eddy current loss calculation was proposed, considering the cross-sectional area variations of the can due to different fault modes. The changes in eddy current losses under different fault modes and severity levels were analyzed using this analytical expression and compared with simulation results.
The results indicate that: (1) When the main pump motor can fails, the maximum change rate of electromagnetic torque is 2.108%, the maximum change rate of air gap magnetic flux density is 1.748%, the maximum change rate of phase A current is 0.103%, and the maximum change rate of back electromotive force is 0.025%. Therefore, compared to other aspects of the main pump canned motor’s performance, can faults have a significant impact on the eddy current loss within the can, consistent with theoretical analysis. Under bulging and wear conditions, the maximum change rate of eddy current loss reached 5%, while under cracking conditions, it reached 14%. (2) The proposed eddy current loss calculation method considering bulging, wear, and cracking areas during can failure is effective, with the error between the analytical calculation and finite element calculation results being less than 5%, further proving the effectiveness of the calculation method. (3) Eddy current losses within the can exhibit a linear relationship with the degree of can failure. When a bulging fault occurs in the stator can, the eddy current loss within the can increases with the degree of bulging. In the cases of wear and cracking faults, the eddy current loss within the can decreases as the extent of wear or cracking increases.

Key words： Can main pump canned motor failure simulation performance analysis eddy current

收稿日期: 2024-07-14

PACS:

TM346

基金资助:国家自然科学基金资助项目（U2267206）

通讯作者: 向学位男,1993年生,副研究员,硕士生导师,研究方向为新型电机的运行理论及控制。E-mail：xueweixiang@cqu.edu.cn

作者简介: 刘能青男,2000年生,硕士研究生,研究方向为屏蔽电机失效故障诊断。E-mail：1713286063@qq.com

引用本文:

刘能青, 向学位, 陈智, 李辉, 蒋鹏. 考虑屏蔽套失效的主泵电机建模及性能分析[J]. 电工技术学报, 2024, 39(zk1): 25-36. Liu Nengqing, Xiang Xuewei, Chen Zhi, Li Hui, Jiang Peng. Modeling and Performance Impact Analysis of Main Pump Canned Motor Considering Can Failure. Transactions of China Electrotechnical Society, 2024, 39(zk1): 25-36.

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[1] 张明乾, 刘昱, 李承亮. 浅谈压水堆核电站AP1000屏蔽式电动主泵[J]. 水泵技术, 2008(4): 1-5.
Zhang Mingqian, Liu Yu, Li Chengliang.Discussion on AP1000 shielded electric main pump in PWR nuclear power plant[J]. Pump Technology, 2008(4): 1-5.
[2] 关锐, 高永军. AP1000反应堆主泵屏蔽套制造工艺浅析[J]. 中国核电, 2008, 1(1): 49-53.
Guan Rui, Gao Yongjun.Brief analysis on fabrication process of AP1000 reactor coolant pump can[J]. China Nuclear Power, 2008, 1(1): 49-53.
[3] Robinson R C, Rowe I, Donelan L E.The calculation of can losses in canned motors[J]. Transactions of the American Institute of Electrical Engineers Part III: Power Apparatus and Systems, 1957, 76(3): 312-315.
[4] 孙树林, 李觉民. 屏蔽式感应电动机屏蔽套损耗的计算及减少途径[J]. 大电机技术, 1987(6): 30-33.
Sun Shulin, Li Juemin.Calculation of electric loss on the shield for canned inductive motor and the ways of its reduction[J]. Large Electric Machine and Hydraulic Turbine, 1987(6): 30-33.
[5] Gao Lianlian, Wei Jingwei, Li Cangxue, et al.Analyses on performances of megawatt double-canned induction motors with different can materials[J]. IEEE Transactions on Energy Conversion, 2017, 32(2): 667-674.
[6] Yu Qiang, Wang Xuesong, Cheng Yuhu.Electromagnetic calculation and characteristic analysis of can effect of a canned permanent magnet motor[J]. IEEE Transactions on Magnetics, 2016, 52(12): 8108706.
[7] 梁艳萍, 张广超, 高莲莲, 等. 核主泵驱动电动机屏蔽套涡流损耗混合算法研究[J]. 电工技术学报, 2018, 33(5): 1015-1023.
Liang Yanping, Zhang Guangchao, Gao Lianlian, et al.Research on hybrid algorithm of can losses in double canned induction motor for nuclear pump[J]. Transactions of China Electrotechnical Society, 2018, 33(5): 1015-1023.
[8] 张晓晨, 李伟力, 曹君慈. 屏蔽电机屏蔽损耗与电机性能的计算与分析[J]. 哈尔滨工业大学学报, 2007, 39(9): 1422-1426.
Zhang Xiaochen, Li Weili, Cao Junci.Calculation and analysis for the can loss and performance of canned motors[J]. Journal of Harbin Institute of Technology, 2007, 39(9): 1422-1426.
[9] 何畅. 液浸电机屏蔽套能耗分析与优化[D]. 徐州: 中国矿业大学, 2020.
He Chang.Analysis and optimization of energy consumption of shielding sleeve of liquid immersed motor[D]. Xuzhou: China University of Mining and Technology, 2020.
[10] 纪繁祥, 吴庆广. 屏蔽电动机运行性能分析[J]. 防爆电机, 2015, 50(3): 22-24.
Ji Fanxiang, Wu Qingguang.Analyses on running performance of canned motor[J]. Explosion-Proof Electric Machine, 2015, 50(3): 22-24.
[11] 张亮. 无刷直流屏蔽电动机的涡流损耗与性能研究[J]. 微电机, 2016, 49(8): 16-18.
Zhang Liang.Research on eddy current losses and performance parameters of brushless DC canned motor[J]. Micromotors, 2016, 49(8): 16-18.
[12] 张建涛, 梁艳萍, 王鸿鹄, 等. 双屏蔽复合转子电动机性能分析[J]. 大电机技术, 2010(4): 22-26.
Zhang Jiantao, Liang Yanping, Wang Honghu, et al.The performance analysis of the double-cans composite-rotor motor[J]. Large Electric Machine and Hydraulic Turbine, 2010(4): 22-26.
[13] 金永星, 王爱元, 孙健, 等. 核屏蔽感应电机效率和功率因数综合优化设计[J]. 电机技术, 2019(2): 1-3, 8.
Jin Yongxing, Wang Aiyuan, Sun Jian, et al.Synthetic optimized design on efficiency and power factor of nuclear shielding induction motors[J]. Electrical Machinery Technology, 2019(2): 1-3, 8.
[14] 金永星, 王爱元, 王涛, 等. 基于粒子群算法的核屏蔽感应电机多目标优化设计[J]. 电机与控制应用, 2019, 46(9): 53-57.
Jin Yongxing, Wang Aiyuan, Wang Tao, et al.Multi-objective optimization design of nuclear canned induction motor based on particle swarm optimization[J]. Electric Machines & Control Application, 2019, 46(9): 53-57.
[15] 李贵敬, 阎昌琪, 王建军. 屏蔽电机设计性能的参数效应分析[J]. 原子能科学技术, 2013, 47(3): 442-448.
Li Guijing, Yan Changqi, Wang Jianjun.Effect analysis of parameters on canned motor’s design performance[J]. Atomic Energy Science and Technology, 2013, 47(3): 442-448.
[16] 佟文明, 侯明君, 孙鲁, 等. 基于精确子域模型的带护套转子高速永磁电机转子涡流损耗解析方法[J]. 电工技术学报, 2022, 37(16): 4047-4059.
Tong Wenming, Hou Mingjun, Sun Lu, et al.Analytical method of rotor eddy current loss for high-speed surface-mounted permanent magnet motor with rotor retaining sleeve[J]. Transactions of China Electrotechnical Society, 2022, 37(16): 4047-4059.
[17] 佟文明, 田野, 李晓健, 等. 双层复合护套高速永磁电机转子涡流损耗解析模型[J]. 电工技术学报, 2024, 39(14): 4328-4340.
Tong Wenming, Tian Ye, Li Xiaojian, et al.Analytical modeling for rotor eddy current loss of high-speed surface-mounted permanent magnet motor with double-layer compound retaining sleeve[J]. Transactions of China Electrotechnical Society, 2024, 39(14): 4328-4340.
[18] 刘细平, 朱治国, 陈栋, 等. 基于转子永磁分段优化的轴向磁通永磁电机涡流损耗分析与试验[J]. 电工技术学报, 2024, 39(12): 3616-3629.
Liu Xiping, Zhu Zhiguo, Chen Dong, et al.Analysis and experiment of eddy current loss of axial flux permanent magnet motor based on rotor segment optimization[J]. Transactions of China Electrotechnical Society, 2024, 39(12): 3616-3629.
[19] 曹龙飞, 范兴纲, 李大伟, 等. 基于快速有限元的永磁电机绕组涡流损耗半解析高效计算[J]. 电工技术学报, 2023, 38(1): 153-165.
Cao Longfei, Fan Xinggang, Li Dawei, et al.Semi analytical and efficient calculation method of eddy current loss in windings of permanent magnet machines based on fast finite element method[J]. Transactions of China Electrotechnical Society, 2023, 38(1): 153-165.
[20] 陈浈斐, 邢宁, 马宏忠, 等. 分数槽永磁电机永磁体谐波涡流损耗建模与分析[J]. 电工技术学报, 2022, 37(14): 3514-3527.
Chen Zhenfei, Xing Ning, Ma Hongzhong, et al.Analytical modeling and analysis of magnet harmonic loss in fractional slot permanent-magnet machines[J]. Transactions of China Electrotechnical Society, 2022, 37(14): 3514-3527.
[21] 凌在汛, 周理兵, 张毅, 等. 笼型实心转子屏蔽感应电机电磁场及参数研究(一): 等效电路及其参数分析[J]. 电工技术学报, 2018, 33(15): 3518-3526.
Ling Zaixun, Zhou Libing, Zhang Yi, et al.Parameters determination and electromagnetic field analysis of canned solid-rotor induction motor(1): an overview of motor’s equivalent circuit and its parameter analysis method[J]. Transactions of China Electrotechnical Society, 2018, 33(15): 3518-3526.
[22] 凌在汛, 周理兵, 张毅, 等. 笼型实心转子屏蔽感应电机电磁场及参数研究(二): 二维多层电磁场模型及其解析计算[J]. 电工技术学报, 2018, 33(17): 4016-4028.
Ling Zaixun, Zhou Libing, Zhang Yi, et al.Parameters determination and electromagnetic field analysis of canned solid-rotor induction motor(2): 2D-multilayer electromagnetic model and its analytical calculation[J]. Transactions of China Electrotechnical Society, 2018, 33(17): 4016-4028.
[23] 胡月. 屏蔽电机主泵定子屏蔽套屈曲稳定性研究[D]. 上海: 上海交通大学, 2013.
Hu Yue.Study on buckling stability of stator shield sleeve of main pump of shielded motor[D]. Shanghai: Shanghai Jiao Tong University, 2013.
[24] 冯颖慧. AP1000屏蔽电机主泵屏蔽套力学分析[D]. 上海: 上海交通大学, 2011.
Feng Yinghui.Mechanical analysis of main pump shielding sleeve of AP1000 shielded motor[D]. Shanghai: Shanghai Jiao Tong University, 2011.
[25] 张强. 新型移相式屏蔽电动机定子屏蔽套涡流与热应力研究[D]. 沈阳: 沈阳工业大学, 2015.
Zhang Qiang.Study on eddy current and thermal stress of stator shield sleeve of new phase-shifting shielded motor[D]. Shenyang: Shenyang University of Techno-logy, 2015.
[26] 汤蕴璆, 梁艳萍. 电机电磁场的分析与计算[M]. 北京: 机械工业出版社, 2010.