Design of Magnetorheological Fluid Dynamometer which Electric Current and Resisting Moment have Corresponding Relationship
Automation, Control and Intelligent Systems
Volume 2, Issue 2, April 2014, Pages: 16-20
Received: Mar. 7, 2014;
Accepted: Apr. 16, 2014;
Published: Apr. 20, 2014
Views 3030 Downloads 177
Luo Yiping, College of Automobile Engineering, Shanghai University of Engineering Science, Shanghai, China
Xu Biao, College of Automobile Engineering, Shanghai University of Engineering Science, Shanghai, China
Ren Hongjuan, College of Automobile Engineering, Shanghai University of Engineering Science, Shanghai, China
Chen Fuzhi, College of Automobile Engineering, Shanghai University of Engineering Science, Shanghai, China
Based on the research of the new material magnetorheological fluid, magnetorheological fluid dynamometer is designed. Under the premise of certain structure size and material, there is a one-to-one correspondence between MRF dynamometer loading current and load torque provided with the machine electricity and the theoretical calculation. This papergives the design method and specific geometric parameters of magnetorheological fluid dynamometer. The process of magnetorheological fluid dynamometer theory design is obtained by taking a specific model motor as an example, which provides a theoretical basis for the application of MRF in the field of dynamometer
Design of Magnetorheological Fluid Dynamometer which Electric Current and Resisting Moment have Corresponding Relationship, Automation, Control and Intelligent Systems.
Vol. 2, No. 2,
2014, pp. 16-20.
Meng Li, Jiangang Lv, Yong Wei. Study on the System of Tracked Vehicles Magnetorheological Fluid Damper Suspension[J]. Mechanical Design, 2004, 21(12): 52-55.
Yanrong Yang, Huiyong Shan, Yong Wei. The Theoretical Analysis and Design of a Cylindrical Magnetorheological Brake [J]. Electromechanical Engineering Technology , 2005, 34(10): 15-16.
Lin Zhang. Research and Design of Disk Type Magnetorheological Transmission Mechanism [J]. Mechanical Design, 2009, 26(1): 31-32.
Bossis G, Mathis C, Mimouni Z. Magneto rheolgical suspensions[J]. Euro phys Lett, 1990, 11(2): 133-137.
Kormann C, Laun H. M, Richter H J. MR Fluid with Nano-Sized Magnetic Particles Technology [J]. International Journal of Modern Physics, 1996, 10(23): 3167-3172.
Cutillas S. Bossis G CebersA [J]. Vhys Rev E, 1998, 57(1): 804-811.
Gopalswamy S, Linzell S M, Jones G L. MR fluid clutch with minimized reluctance [P]. USA:US Patent: 5896965,1999.
Jianhua Ni, Zhiqian Zhang, Ke Zhang. A New Type of Magnetorheological Damper and Its Application in Semi-active Control of Vehicle Suspension [J]. Mechanical Science and Technology , 2004, 23(1): 4-6.
O．Ashour, A. Craig. Magnetorheological Fluid: materials, characterization, and devices [J]. Int. Mater．Syst. struct, 1996, 7(2): 123-130.
Jian Chang, Yunmin Yang, Xianghe Peng. Research on testing device for magnetorheological fluid properties [J]. Chinese Journal of scientific instrument, 2001, 22(4): 354-358.
Wu Ai, Cheng Li. Circuit and Magnetic Circuit [M]. Wuhan City: Huazhong University of Science and Technology press , 2002.
Canbin Liang, Guangrong Qin, Zhujiang Liang. Electromagnetics [M]. Beijing: Higher Education Press, 1980.
Jinming Tian. Design and Application of Electromagnetic Clutch [M]. Suzhou: Jiangsu Science and Technology Publishing House, 1982.
Kejun Jiang, Chengye Liu. Design and Performance Simulation of Magnetorheological Fluid Clutch [J]. Computer Sumulation, 2011, 28(8): 337-341.
Jun Zheng. Magnetorheological Transmission Theory and Experimental Study [D]. Chongqing: Chongqing University, 2008.
W. H. Li and, H. Du. Design and Experimental Evaluation of a Magnetorheological Brake [J]. The International Journal of Advanced Manufacturing Technology, 2003, 21(7): 508-515.