一种弹簧加载恒力运动装置

Matthew J. Chatham, B. A. Todd, J. Parker, Audrey S. House, Jenny L. Taylor
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摘要

在微重力环境中度过大量时间的宇航员中观察到骨密度损失[1]。在这种环境下,骨骼缺乏机械应力是骨密度下降的主要因素。为了抵消这些影响,阻力运动一直是许多研究的重点。在地面卧床休息研究中,加重板已被用来提供恒定的力阻力。卧床休息已被认为是模拟地球上微重力长期影响的最佳方法之一[2]。然而,在失重状态下,需要一种替代的阻力来源。一些运动装置用松紧带提供阻力。不幸的是,这些松紧带往往会随着使用而失去其机械刚度,因此需要许多备用松紧带用于长时间的太空任务。一个需要更少维护的更强大的系统将是可取的。金属螺旋弹簧满足这一要求。螺旋弹簧的机械性能是可预测的,这些弹簧有很长的寿命,使它们非常适合长时间的任务。然而,螺旋弹簧表现为线性行为。也就是说,弹簧提供的阻力与挠度成正比。因此,设计了一种与线性弹簧相互作用的机构,以在给定的行程长度上提供恒定的输出力。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
A Spring-Loaded Constant Force Exercise Device
Bone mineral density loss has been observed in astronauts who have spent a significant amount of time in a micro-gravity environment [1]. The lack of mechanical stress placed on the bones while in this environment is a major factor in the decrease in bone mineral density. To counteract these effects, resistive exercise has been the focus of many studies. Weighted plates have been used to provide a constant force resistance in ground-based bed rest studies. Bed rest has been established as one of the best ways to simulate the long-term effects of micro-gravity on earth [2]. In weightlessness, however, an alternate source of resistive force is required Some exercise devices provide resistance with elastic bands. Unfortunately, these elastic bands tend to lose their mechanical stiffness with use, requiring many spare elastic bands to be available for long duration missions in space. A more robust system that requires less maintenance would be preferable. Metallic helical springs meet this requirement The mechanical properties of helical springs are predictable, and these springs have a long life, making them well suited for long duration missions. However, helical springs exhibit linear behavior. That is, the resistive force provided by the spring is directly proportional to the amount of deflection. Therefore, a mechanism was designed to interact with the linear springs to provide a constant output force over a given length of travel.
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