Development of Properties Control Methods for Magnetorheological Medium to Regulate the Stiffness of Exoskeleton Variable-Length Link

А. О. Blinov, А. V. Borisov, L. Konchina, M. Novikova, A. Chigarev
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Abstract

   Introduction. The article investigated one of the problems of creating exoskeletons — controlling the properties of magnetic rheological fluid in links of variable length with adjustable stiffness. Based on the research of domestic and foreign authors, the development and urgency of the topic was evaluated. The disadvantage of known exoskeleton models has been specified, i.e., the use of absolutely solid links, whose dynamics does not convey the dynamics of the human musculoskeletal system.   The scientific research aimed at the formation of a new direction in the development of exoskeletons that accurately simulate the biomechanics of movements.   Materials and Methods. Different states of structures of variable-length links with a magnetorheological fluid were studied. It has been noted that the links work on the principle of magnetic shock absorbers and consist of a piston rod, electromagnetic coils, and a housing filled with magnetorheological fluid. The ordering effect of an external magnetic field on the particles of a magnetorheological fluid was visualized and mathematically presented. The significance of such factors as time, charge density, magnetic field strength, as well as vectors of electric and magnetic induction, electric intensity and electric current density for this system was shown. The input parameter affecting the behavior of the magnetorheological fluid was determined. This was the magnetic field intensity. It was shown that the viscosity of the liquid varied depending on the shape of the magnetic particles (oblong or oblate ellipsoid).   Results. The dependences that were fundamental for solving the task were investigated and visualized. The magnetic field strength and the angle between the vector directed along a straight line connecting the centers of two micron particles, and the vector of the external magnetic field strength were taken as the basic parameters. It was shown how the magnetic moment, voltage and its antisymmetric part depended on them. It was established that to control the properties of a magnetorheological fluid, it was required to change: – the external magnetic field intensity; – the angle between the external magnetic field intensity and the orientation vector between the dipoles. Two values of force were compared: one – for a given link design, and the other — fixed when walking in the lower leg of a person. The consistency of these indicators was established.   Discussion and Conclusion. The scientific research results allowed us to present: – a method for controlling the properties of a magnetorheological fluid by an external magnetic field; – a variable-length link model with adjustable stiffness. The results obtained can be used in modeling multilink structures to create comfortable exoskeletons that interact synchronously with the human musculoskeletal system as a single human-machine system. The development is applicable to solving significant social and economic problems.
调节外骨骼变长连杆刚度的磁流变介质性能控制方法的研究
介绍。本文研究了制造外骨骼的问题之一——在可变长度、可调刚度的连杆中控制磁流变液的性质。结合国内外作者的研究成果,对该课题的发展和紧迫性进行了评价。已知外骨骼模型的缺点已经明确,即使用绝对固体链接,其动力学不能传达人体肌肉骨骼系统的动力学。科学研究的目的是在外骨骼的发展形成一个新的方向,准确地模拟运动的生物力学。材料与方法。研究了磁流变液作用下变长连杆结构的不同状态。已经注意到,连杆的工作原理是磁减震器,由活塞杆、电磁线圈和充满磁流变液的外壳组成。对外加磁场对磁流变液粒子的有序效应进行了可视化和数学描述。分析了时间、电荷密度、磁场强度、电磁感应矢量、电强度、电流密度等因素对该体系的影响。确定了影响磁流变液性能的输入参数。这是磁场强度。结果表明,液体的粘度随磁性颗粒的形状(椭圆形或扁圆形)而变化。结果。对解决任务的基本依赖项进行了调查和可视化。以磁场强度和沿连接两个微米粒子中心的直线方向的矢量与外磁场强度矢量之间的夹角为基本参数。说明了磁矩、电压及其反对称部分是如何依赖于它们的。为了控制磁流变流体的性质,需要改变:-外部磁场强度;-外加磁场强度与偶极子之间的方向矢量之间的夹角。他们比较了两种力的值:一种是给定的连杆设计,另一种是固定的,当人用小腿走路时。建立了这些指标的一致性。讨论与结论。科学研究结果使我们能够提出:-一种通过外部磁场控制磁流变流体特性的方法;-具有可调刚度的变长连杆模型。所获得的结果可用于建模多连杆结构,以创建舒适的外骨骼,与人体肌肉骨骼系统作为一个单一的人机系统同步交互。这一发展适用于解决重大的社会和经济问题。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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