Research on the Dynamometer Temperature Characteristics of Magneto-Rheological Fluid Dynamometer
Volume 2, Issue 6, December 2014, Pages: 185-189
Received: Dec. 9, 2014;
Accepted: Dec. 23, 2014;
Published: Jan. 4, 2015
Views 2891 Downloads 190
Fang Yi, College of Automotive, Shanghai University of Engineering Science, Shanghai, 201620, P.R. China
Luo Yiping, College of Automotive, Shanghai University of Engineering Science, Shanghai, 201620, P.R. China
Ren Hongjuan, College of Automotive, Shanghai University of Engineering Science, Shanghai, 201620, P.R. China
The dynamometer measuring device through the magnetic rheological fluid self-designed, analyzes the basic characteristics of magneto rheological fluid, and then through the experimental study on the temperature characteristics of magneto rheological fluid. Dynamometer with magneto rheological fluid (MRF) was tested, in different conditions, when the system reached the steady state, temperature changes in the key points of the rotary. And through the analysis, the temperature distribution of the device was obtained, which provides the theoretical basis for the effect of temperature on transmission performance. Then, the obtained results, which can provided a good reference for the design of MRF gearing to optimum design and intelligent cooling system.
Research on the Dynamometer Temperature Characteristics of Magneto-Rheological Fluid Dynamometer, Science Research.
Vol. 2, No. 6,
2014, pp. 185-189.
Kordonski W I, “Magneto-rheological Effect as a Base of New Devices and Technologies,” J Magnetism &Magnetic Mat, vol.122, pp.395-398, 1993.
Lan Wenkui, Zheng Ling, Li Yinong, et al, “FEM analysis of magnetic field of piston-type MR fluids damper,” Transactions of the Chinese Society for Agricultural Machinery, vol. 38, no. 4, pp.142-145, 2007.
Ma H R, Wen W J, Tam W Y, et al, “Dielectric electro rheological fluids: Theory and experiment,” Adv Phys ,vol.52, pp.343~347, 2003.
Winslow W M, “Method and Means for Translating Electrical Impulse into Mechanical Force,” U. S. Patent No.2417850.1947.
Rabinow J, “The Magnetic Fluild Cluth,” AIEE Transactions, vol. 67, pp.1308-1315, 1948.
Park B J, Park CW, Yang SW, et al, “Core shell Typed Polymer Coated-carbonyl Iron Suspensions and Their Magneto-rheology,” Journal of Physics：Conference Series, vol.149, no.1, pp.1-5, 2009.
Barber D E, Carlson J D, “Performance Characteristics of Prototype MR Engine Mounts Containing LORD Glycol MR Fluids,” Journal of Physics: Conference Series, vol.149, pp.1-4, 2009.
Chin B D, Park J H, Kwon M H, et a1, “Rheological Properties and Dispersion Stability of Magneto-rheological (MR) Suspensions,” Rheol Acta, vol.40, no.3, pp.211-219, 2001.
Yang Shiqing, Zhang Wanli,“Rheological properties of magneto-rheological fluid,” Functional material,vol.29, no.5, pp.550-552, 1998.
Xie Fangwei, HouYoufu, “Transient thermal-stress coupling of friction pair of hydro-viscous drive device,” Journal of Central South University: Science and Technology, vol.41, no.6, pp. 2201-2206, 2010.
Li Zhongxian, Wu Linlin, XuLonghe, etc.. Structural design of MR damper and experimental study for performance of damping force [J]. Earthquake engineering and engineering vibration, 2003,23(1):128-132.
Wang Hongtao, Zhang Jinqiu, Bi Zhandong, etc.. Model and Analysis of Damping for Twin-tube Magneto-rheological Fluid Damper Based on Disc Type Orifice [J]. Journal of mechanical engineering, 2010,46(18):139-144.
Wang Xiuyong, Sun Hongxin, Chen Zhengqing. Rotation shear magneto-rheological fluid damper design and mechanical model [J]. Journal of vibration and shock, 2010, 29 (10):77-81.
Lu He, Liu Xinhua, magneto-rheological fluids and its applications in mechanical engineering [J]. Technology and application of manufacturing, 2013, (1):66-70.
Kordonaky W.I., Garodkin S.R., Magneto-rheological Fluid Based Seal. In Bullogh W.A., Proc of the 5th Int. Conf. on ER Fluids, MR Suspensions and Associated Technology, Singapore: World Scientific, 1996, P.704-709.
Tang X, Zhang X, Tao T. Flexible Fixture with Magneto-rheological Fluids, In: Tao R, Proc. Of the 7th Int. Conf. on ER Fluids, MR Suspensions and Associated Technology, Singapore: World Scientific, 2000, P.712-720.
W.M I Kordonski, Adaptive Structures Base on Magneto-rheological Fluids, Proc. 3 Int. Conf. Adaptive Struct., ed. Wada, Natori and Breitbach. P.13-17, San Diego, CA, 1992.
Jolly R, Bender W, Carlson J. Pro per ties and applications of commercial magneto-rheological fluids [J]. Journal of Intelligent Mateial Systems and Structures, 1999, 10: 5～13.
Li H, Peng X, and Chen W. A Micro-to-macroscopic Analysis for the Yield Stress of Magneto-rheological Fluids, Proc. Int. Conf. Heterogeneoud Materials Mechanics, edited by Fan j, McDowell D and Huang K, Chongqing University Press, Chongqing, 2004: 276-280.
Yi Zhou, Jianzuo, Ma, Dong Zuo. A Self-adaptive Fan Clutch for Automobile. New and Advanced Materials. Advanced Materials Research Vols. 197-198, 2011: 339-343