Volume 2, Issue 3, September 2017, Page: 53-57
Research on the Stability of Circuit Breaker Based on Sinusoidal Excitation
Kun Zhang, College of Mechanical Engineering, Shanghai University of Engineering Science, Shanghai, China
Ying Pan, College of Mechanical Engineering, Shanghai University of Engineering Science, Shanghai, China
Received: Feb. 28, 2017;       Accepted: Mar. 16, 2017;       Published: Apr. 7, 2017
DOI: 10.11648/j.es.20170203.11      View  2060      Downloads  192
With the rapid development of new technology of electrical, all walks of life to the reliability of low voltage circuit breaker and other electronic products requirements are increasingly demanding, low voltage circuit breaker as the main electrical equipment in the power distribution system to connect to the circuit and disconnect plays a decisive role in the railway road, maritime transport, strong shock and vibration. Natural mechanical environment has become one of the important factors affecting the safe operation of electrical equipment is stable and reliable. The circuit breaker is generally under static conditions to study the performance index, this paper circuit breaker on-off of dynamic reliability experiment, build platform, find the circuit breaker on-off phase Should the parameters (frequency, acceleration). This paper adopts Es-60Wls3-445/LT0606/LTT1212 electric vibration system stability test sine on SIEMENS 3VL2716-1AA33-0AA0 molded case circuit breaker, and to study its stability.
Low Voltage Circuit Breaker, Sinusoidal Excitation, MCCB, Stability
To cite this article
Kun Zhang, Ying Pan, Research on the Stability of Circuit Breaker Based on Sinusoidal Excitation, Engineering Science. Vol. 2, No. 3, 2017, pp. 53-57. doi: 10.11648/j.es.20170203.11
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Shilin Huang. Application of modal analysis to the study of automobile vibration [J]. technology and management, 1984 (2): 7-20.
Sanling Wu. Practical vibration test technology. Ordnance Industry Press, 1993.
Hu brother. Implementation of vibration test technology. Some are ready to explore environmental technology. 1994.1.
Average Control For Simusoidal-And Random-Vibration Testing, Usher. T. J. Aeoust, Soe, Amev, Vol 41 no. 4.
GB/T 2423.10: 2008 environmental testing for electric and electronic products part second: Test methods test Fc and guidance: vibration (sinusoidal).
IEC 60068-2-6: 2007 testing - Part Tests - Test Fc: Vibration (sinusoidal) 2-6: (Environmental).
Lizi Xu. Reliability analysis of substation automation system [J]. Power System Technology, 2002, 26 (8): 68-72.
Xiaofeng Wu. Hao Zhang. Development of digital processor based measuring and controlling unit for intelligent breaker [J]. Power System Technology, 2003, 27 (7): 70-74.
Nochumson C J. Disscussion of”survey results of low-voltage circuit breakers as found during maintenance testing: working group report” [J]. IEEE Trransaction on Industry Applications, 1997, 33 (5): 1370-1371.
Billinton R, Allan R N. Reliability Evalution of Engineering Systems. London [M]: PITMAN B00KS LIMITED, 1983.
Daolian Wang, Guang Xu, Haoyang Zhou, et al. Analysis of fatigue life of composite cylinders under random vibration [J]. Strength and environment, 2015, 42 (1): 18–22.
Qianmin Mao, Jiayou Zhao. RongTai Jin. Asynchronous motor speed measurement and rotor fault monitoring [J]. Instrument technique and sensor, 2015 (12): 29–31.
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