A Method for Measuring Fluid Pressures in the Shoe-Floor-Fluid Interface: Application to Shoe Tread Evaluation.

Gurjeet Singh, Kurt E Beschorner
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引用次数: 35

Abstract

Background: Fluid contaminants cause slipping accidents by reducing shoe-floor friction. Fluid pressures in the shoe-floor interface reduce contact between the surfaces and, thus, reduce friction between the surfaces. A technological gap for measuring fluid pressures, however, has impeded improved understanding of what factors influence these pressures.

Purpose: This study aimed to introduce a technique for measuring fluid pressures under the shoe and to demonstrate the utility of the technique by quantifying the effects of tread depth and fluid viscosity on fluid pressures for two different shoes.

Methods: A fluid pressure sensor embedded in the floor surface was used to measure fluid pressures, while a robotic slip-tester traversed the shoe over the floor surface. Multiple scans were collected to develop 2D fluid pressure maps across the shoe surface. Two shoe tread types (an athletic shoe and a work shoe), two fluids (high-viscosity diluted glycerol and a low-viscosity detergent solution), and three tread depths (full tread, half tread, and no tread) were tested, while fluid pressures were measured.

Results: Untreaded shoes combined with a high-viscosity fluid resulted in high fluid pressures, while treaded shoes or low-viscosity fluids resulted in low fluid pressures. The increased fluid pressures that were observed for the untreaded shoes are consistent with tribology theory and evidence from human slipping studies.

Conclusions: The methods described here successfully measured fluid pressures and yielded results consistent with tribological theory and human slipping experiments. This approach offers significant potential in evaluating the slip-resistance of tread designs and determining wear limits for replacing shoes.

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一种测量鞋-地板-流体界面流体压力的方法:在鞋面评价中的应用。
背景:流体污染物通过减少鞋与地板的摩擦而导致滑倒事故。鞋-地板界面的流体压力减少了表面之间的接触,从而减少了表面之间的摩擦。然而,测量流体压力的技术差距阻碍了对影响这些压力的因素的进一步了解。目的:本研究旨在介绍一种测量鞋下流体压力的技术,并通过量化两种不同鞋子的胎面深度和流体粘度对流体压力的影响来证明该技术的实用性。方法:使用嵌入地板表面的流体压力传感器来测量流体压力,而机器人滑动测试仪则在地板表面上穿过鞋子。收集了多次扫描,形成了鞋表面的二维流体压力图。测试了两种鞋面类型(运动鞋和工作鞋)、两种液体(高粘度稀释甘油和低粘度洗涤剂溶液)和三种胎面深度(全胎面、半胎面和无胎面),同时测量了流体压力。结果:未踩踏的鞋与高粘度流体混合会导致较高的流体压力,而踩踏的鞋或低粘度流体导致较低的流体压力。未穿鞋时观察到的流体压力增加与摩擦学理论和人体滑倒研究的证据一致。结论:本文描述的方法成功地测量了流体压力,并获得了与摩擦学理论和人体滑动实验一致的结果。这种方法在评估胎面设计的防滑性和确定更换鞋子的磨损极限方面具有重要的潜力。
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