磁流变流体在新型磁优化微磁流变阻尼器中的耗散粒子动力学建模

IF 2.2 4区 工程技术 Q2 MECHANICS Korea-Australia Rheology Journal Pub Date : 2022-08-08 DOI:10.1007/s13367-022-00037-8
Mohsen Ghafarian Eidgahi Moghadam, Mohammad Mohsen Shahmardan, Mahmood Norouzi
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引用次数: 1

摘要

采用耗散粒子动力学方法作为分子尺度建模技术,研究了基于磁流变流体特性和阻尼器结构的微型磁流变阻尼器的磁优化问题。为了选择合适的磁流变液,研究了磁颗粒直径和磁颗粒质量对10 N阻尼力的影响。结果表明:阻尼力随磁性颗粒直径的增大而增大,最终趋于恒定,随磁性颗粒重量的增大而呈非抛物线型变化。对阻尼器结构参数的研究结果表明,随着流道间隙尺寸的增大,阻尼力增大,而增大气缸内径和活塞长度则会产生相反的效果。磁流变阻尼器的优化设计主要是通过对线圈的布置和磁场强度的阶跃分布进行研究来完成的。为了优化磁流变阻尼器在最小电能消耗和磁滞水平下的运行工况,选择了以140CG磁流变液为剂液,在相对磁强为40%、步长差为15%的情况下,长度为3、5、7mm的3段线圈。
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Dissipative particle dynamics modeling of MR fluid flow in a novel magnetically optimized mini-MR damper

Magnetically optimization of mini-MR damper with focused on MR fluid properties and damper construction is investigated using dissipative particle dynamics method as a molecular scale modeling technique. To select a suitable MR fluid, the effect of diameter and weight of magnetic particles on damping force of 10 N as set point is studied. The results show damping force increases by increasing diameter of magnetic particles and finally trends to a constant value while changes nonparabolic by enhancement of their weight. The results of studies on structural parameters of damper show that by increasing gap size of flow passage, damping force increases while enhancement in inner diameter of cylinder and piston length has reverse effect. Optimum design of MR damper completed by investigation on electrical coils in terms of their arrangement and step wise distribution of magnetic field strength as our major innovation. To optimum operating conditions of MR damper at minimum electrical energy consumption and hysteresis level, the scenario of three segment coils in length of 3, 5, and 7 mm at base relative magnetic strength of 40% with 15% difference in steps by utilizing 140CG MR fluid as agent fluid are selected.

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来源期刊
Korea-Australia Rheology Journal
Korea-Australia Rheology Journal 工程技术-高分子科学
CiteScore
2.80
自引率
0.00%
发文量
28
审稿时长
>12 weeks
期刊介绍: The Korea-Australia Rheology Journal is devoted to fundamental and applied research with immediate or potential value in rheology, covering the science of the deformation and flow of materials. Emphases are placed on experimental and numerical advances in the areas of complex fluids. The journal offers insight into characterization and understanding of technologically important materials with a wide range of practical applications.
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