手握手柄耦合：手柄形状、方向和摩擦对分离强度的影响。

Hand-handhold coupling: effect of handle shape, orientation, and friction on breakaway strength.

机构信息

Industrial and Operations Engineering, University of Michigan, Ann Arbor, MI 48109, USA.

出版信息

Hum Factors. 2009 Oct;51(5):705-17. doi: 10.1177/0018720809355969.

DOI:10.1177/0018720809355969

PMID:20196295

Abstract

OBJECTIVE

The aim was to determine the maximum force that can be exerted on an object before it is pulled or slips from the grasp of the hand ("breakaway strength") for fixed overhead handholds of varying orientation, shape, and friction.

BACKGROUND

Many studies have quantified hand strength by having participants squeeze, pull on, or create torque on an object or handle, but few studies have measured breakaway strength directly.

METHOD

In two experiments, hand strength was measured as both overhead breakaway strength for handholds typical of fixed industrial ladders and as maximum isometric grip strength measured using a common Jamar grip dynamometer.

RESULTS

Breakaway strength was greatest for a fixed horizontal cylinder ("high friction"; 668 +/- 40 N and 691 +/- 132 N for Experiments 1 and 2, respectively), then for a horizontal cylinder that simulated low surface friction ("low friction"; 552 +/- 104 N), then for a vertical cylinder (435 +/- 27 N), and finally, for a vertical rectangular-shaped rail (337 +/- 24 N). Participants are capable of supporting only their own body weight with one hand when grasping the fixed horizontal cylinder. Breakaway strength for both the high- and low-friction horizontal cylinders was significantly greater than isometric grip strength (1.58 +/- 0.25 and 1.26 +/- 0.19 times, respectively).

CONCLUSION

Results support the hypothesis that hand-handhold coupling is composed of active (isometric or eccentric finger flexion) and passive (frictional) components. Traditional isometric grip strength alone does not predict the strength of a couple between a hand and a handhold well.

APPLICATION

This research shows that handhold shape, orientation, and friction are important in the safe design of grab rails or ladders.

摘要

目的

确定在物体从手中滑脱或被拉开之前（“滑脱强度”），手能够施加在物体上的最大力，用于测量不同方向、形状和摩擦系数的固定头顶手柄。

背景

许多研究已经通过让参与者挤压、拉动或对手柄施加扭矩来量化手的力量，但很少有研究直接测量滑脱强度。

方法

在两项实验中，通过头顶手柄的滑脱强度来测量手的力量，这些手柄通常用于固定工业梯，还通过常用的 Jamar 握力计来测量最大等长握力。

结果

固定水平圆柱体（“高摩擦”）的滑脱强度最大（实验 1 和 2 分别为 668 +/- 40 N 和 691 +/- 132 N），其次是模拟低表面摩擦的水平圆柱体（“低摩擦”）（552 +/- 104 N），然后是垂直圆柱体（435 +/- 27 N），最后是垂直矩形轨道（337 +/- 24 N）。参与者在握住固定水平圆柱体时仅能支撑自己的体重。高摩擦和低摩擦水平圆柱体的滑脱强度均显著大于等长握力（分别为 1.58 +/- 0.25 和 1.26 +/- 0.19 倍）。

结论

结果支持手与手柄之间的耦合由主动（等长或偏心手指弯曲）和被动（摩擦）组成的假设。传统的等长握力不能很好地预测手和手柄之间的耦合强度。

应用

本研究表明，手柄的形状、方向和摩擦力在手和手柄安全设计中很重要。

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手握手柄耦合：手柄形状、方向和摩擦对分离强度的影响。

Hand-handhold coupling: effect of handle shape, orientation, and friction on breakaway strength.

机构信息

出版信息

OBJECTIVE

BACKGROUND

METHOD

RESULTS

CONCLUSION

APPLICATION

目的

背景

方法

结果

结论

应用

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