稳定型硅油基磁流变液的制备及性能
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摘要
以羰基铁粉为磁性颗粒,硅油为载液,添加了硅烷偶联剂和纳米SiO2,通过球磨机球磨分散的方法制备磁流变液;采用NXS-11D旋转黏度计、自然沉降法和MRTS-01型磁流变仪分别对其黏度、沉降稳定性和流变性能进行了测试。结果表明:磁流变液零场黏度较低,为0.675 Pa.s,零场黏度随着剪切速率的增大而减小,表现出剪切稀化现象,属于弱Bingham流体;磁流变液具有较好的沉降稳定性,3个月的沉降率为13%,无板结现象,搅拌很容易再分散,表现为软性沉降;在磁场强度为0.6 T时,剪切应力能够达到60 kPa。
Taking carboxyl iron powders and silicon oil as magnetic particles and carrier fluid separately,adding silane coupling agent and nano-SiO2,magneto-rheological fluid was prepared by the method of using ball mill to disperse.Through utilizing NXS-11D rotational viscometer,natural sedimentation method and MRTS-01 magnetic rheometer to test viscosity,sedimentation stability and rheological properties of the magneto-rheological fluid.The results show that zero-field viscosity of the magneto-rheological fluid was low which was 0.675 Pa·s.It decreased with the increasing of shear rate and showed shear-thinning phenomenon,which manifested the magneto-rheological fluid belonged to weak Bingham fluid.The fluid had good sedimentation stability,whose sedimentation rate for 3 months was 13% and no harden phenomenon appeared.It was quite easy to re-disperse after mixing,that presented as soft sedimentation.The shear stress could reach 60 kPa when the magnetic field intensity was 0.6 T.
Taking carboxyl iron powders and silicon oil as magnetic particles and carrier fluid separately,adding silane coupling agent and nano-SiO2,magneto-rheological fluid was prepared by the method of using ball mill to disperse.Through utilizing NXS-11D rotational viscometer,natural sedimentation method and MRTS-01 magnetic rheometer to test viscosity,sedimentation stability and rheological properties of the magneto-rheological fluid.The results show that zero-field viscosity of the magneto-rheological fluid was low which was 0.675 Pa·s.It decreased with the increasing of shear rate and showed shear-thinning phenomenon,which manifested the magneto-rheological fluid belonged to weak Bingham fluid.The fluid had good sedimentation stability,whose sedimentation rate for 3 months was 13% and no harden phenomenon appeared.It was quite easy to re-disperse after mixing,that presented as soft sedimentation.The shear stress could reach 60 kPa when the magnetic field intensity was 0.6 T.
引文
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[2]CARLSONJ D.Magnetorheological fluid actuators[C]//In:Janocha H.Adaptronics and Smart Structures.Berlin:Springer-Verlag Berlin Heidelberg,1999:180-195.
[3]姚金光,晏华.高性能磁流变液研究的进展[J].材料开发与应用,2009,24(2):62-67.
[4]潘双夏,杨礼康,冯培恩.磁流变液减振控制应用的研究动态[J].汽车工程,2002,24(3):254-258.
[5]江万权,张复殿,陈祖耀,等.羰基铁粉表面纳米钴修饰及其对磁流变液性能的影响[J].功能材料,2006,37(7):1163-1165.
[6]CARLSONJ D,WEISS K D.A growing attraction to mag-netic fluids[J].Machine Design,1994(8):61-64.
[7]HOUSNER G W,BERGMAN L A,CAUGHEY T K,et al.Structural control:past,present,and future[J].Journal ofEngineering Mechanics,1997,123(9):938-942.
[8]欧进萍,关新春.可控流体减振驱动器的研究与应用[J].世界地震工程,1999,14(4):30-41.
[9]赵雯,张秋禹,王结良,等.磁流变液及其应用[J].材料导报,2004,18(5):68-71.
[10]浦鸿汀,蒋峰景,杨正龙.以碳纳米管作为抗沉降剂的高性能磁流变液及其制备方法:中国,CN 1658341A[P].2005-08-24.
[11]胡林,张朝平,郑璐瑶,等.磁悬浮流体中颗粒对分散体系流变性的影响[J].贵州大学学报,2000,17(3):194-198.
[12]张平,刘奇,王东亚,等.磁流变体的制备及性能[J].化学物理学报,2001,14(5):559-561.
[13]拉甫罗夫N C.胶体化学实验[M].北京:高等教育出版社,1992:134.
[14]胡林,付伟,张朝平,等.磁流变液沉降稳定性改进及对流变性能的影响[J].贵州大学学报,2001,18(3):176-180.
[15]关新春,李金海,欧进萍.软性沉降磁流变液的研制及性能实验研究[J].功能材料与器件学报,2004,10(1):115-119.
[16]王玉铨,王焕定,徐国涵,等.用均匀设计法制备性能优良的磁流变液[J].哈尔滨工业大学学报,2005,37(1):52-59.
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