RISS 검색 - 국내학술지논문 상세보기

다국어 초록 (Multilingual Abstract)

When the inter-turn short circuit (ITSC) fault occurs, the distortion of the magnetic field is serious. The motor loss variations of each part are obvious, and the motor temperature field is also affected. In order to obtain the influence of the ITSC fault on the motor temperature distribution, firstly, the normal and the fault finite element models of the permanent magnet synchronous motor (PMSM) were established. The magnetic density distribution and the eddy current density distribution were analyzed, and the mechanism of loss change was revealed. The effects of different forms and degrees of the fault on the loss were obtained. Based on the loss analysis, the motor temperature field calculation model was established, and the motor temperature change considering the loop current was analyzed. The influence of the fault on the motor temperature distribution was revealed. The sensitivity factors that limit the motor continuous operation were obtained. Finally, the correctness of the simulation was verified by experiments. The conclusions obtained are of great significance for the fault and high temperature demagnetization of the permanent magnet analysis.

목차 (Table of Contents)

Abstract
1. Introduction
2. Model Establishment and Loss Analysis
3. The Temperature Field Distributions
4. Experimental Study

Abstract
1. Introduction
2. Model Establishment and Loss Analysis
3. The Temperature Field Distributions
4. Experimental Study
5. Conclusions
References

참고문헌 (Reference)

1 K. T. Kim, "Transient Analysis of Irreversible Demagnetization of Permanent-Magnet Brushless DC Motor With Interturn Fault Under the Operating State" 50 (50): 3357-3364, 2014

2 S. Nadarajan, "Online Model-Based Condition Monitoring for Brushless Wound-Field Synchronous Generator to Detect and Diagnose Stator Windings Turn-to-Turn Shorts Using Extended Kalman Filter" 63 (63): 3228-3241, 2016

3 H. Qian, "Modeling and Analysis of Interturn Short Fault in Permanent Magnet Synchronous Motors With Multistrands Windings" 31 (31): 2496-2509, 2016

4 J. G. Cintron-Rivera, "Mitigation of Turn-to-Turn Faults in Fault Tolerant Permanent Magnet Synchronous Motors" 30 (30): 465-475, 2015

5 B. Du, "Interturn Fault Diagnosis Strategy for Interior Permanent-Magnet Synchronous Motor of Electric Vehicles Based on Digital Signal Processor" 63 (63): 1694-1706, 2016

6 A. Sarikhani, "Inter-Turn Fault Detection in PM Synchronous Machines by Physics-Based Back Electromotive Force Estimation" 60 (60): 3472-3484, 2013

7 W. Li, "Influence of Rotor-Sleeve Electromagnetic Characteristics on High-Speed Permanent-Magnet Generator" 61 (61): 3030-3037, 2014

8 B. Vaseghi, "Inductance Identification and Study of PM Motor With Winding Turn Short Circuit Fault" 47 (47): 978-981, 2011

9 Faiz J, "Impacts of rotor inter-turn short circuit fault upon performance of wound rotor induction machines" 135 : 48-58, 2015

10 J. Dusek, "Impact of Slot/Pole Combination on Inter-Turn Short-Circuit Current in Fault-Tolerant Permanent Magnet Machines" 52 (52): 1-9, 2016