Literature DB >> 31280808

Changes in under-shoe traction and fluid drainage for progressively worn shoe tread.

Sarah L Hemler1, Danielle N Charbonneau2, Arian Iraqi3, Mark S Redfern4, Joel M Haight5, Brian E Moyer6, Kurt E Beschorner7.   

Abstract

Shoe wear is known to increase slipping risk, but few studies have systematically studied this relationship. This study investigated the impact of progressive shoe wear on the available coefficient of friction (ACOF) and under-shoe fluid dynamics. Five different slip-resistant shoes were progressively worn using an accelerated, abrasive, wear protocol. The ACOF and fluid forces (the load supported by the fluid) were measured as shoes were slipped across a surface contaminated with a diluted glycerol solution. As the shoes became worn, an initial increase in ACOF was followed by a steady decrease. Low fluid forces were observed prior to wear followed by increased fluid forces as the worn region became larger. Results suggest that traction performance decreases particularly when the heel region without tread exceeds a size of 800 mm2. This study supports the concept of developing shoe replacement guidelines based upon the size of the worn region to reduce occupational slips.
Copyright © 2019 Elsevier Ltd. All rights reserved.

Entities:  

Keywords:  Available coefficient of friction; Biomechanics; Slips and falls

Mesh:

Year:  2019        PMID: 31280808      PMCID: PMC6659727          DOI: 10.1016/j.apergo.2019.04.014

Source DB:  PubMed          Journal:  Appl Ergon        ISSN: 0003-6870            Impact factor:   3.661


  21 in total

1.  Predicting slips and falls considering required and available friction.

Authors:  J P Hanson; M S Redfern; M Mazumdar
Journal:  Ergonomics       Date:  1999-12       Impact factor: 2.778

Review 2.  Biomechanics of slips.

Authors:  M S Redfern; R Cham; K Gielo-Perczak; R Grönqvist; M Hirvonen; H Lanshammar; M Marpet; C Y Pai; C Powers
Journal:  Ergonomics       Date:  2001-10-20       Impact factor: 2.778

3.  The role of friction in the measurement of slipperiness, Part 2: survey of friction measurement devices.

Authors:  W R Chang; R Grönqvist; S Leclercq; R J Brungraber; U Mattke; L Strandberg; S C Thorpe; R Myung; L Makkonen; T K Courtney
Journal:  Ergonomics       Date:  2001-10-20       Impact factor: 2.778

4.  The effect of shoe soling tread groove width on the coefficient of friction with different sole materials, floors, and contaminants.

Authors:  Kai Way Li; Chin Jung Chen
Journal:  Appl Ergon       Date:  2004-11       Impact factor: 3.661

5.  Development and validation of a novel portable slip simulator.

Authors:  Carita Aschan; Mikko Hirvonen; Tarmo Mannelin; Erkki Rajamäki
Journal:  Appl Ergon       Date:  2005-03-26       Impact factor: 3.661

6.  Prediction of slips: an evaluation of utilized coefficient of friction and available slip resistance.

Authors:  J M Burnfield; C M Powers
Journal:  Ergonomics       Date:  2006-08-15       Impact factor: 2.778

7.  Effects of slip testing parameters on measured coefficient of friction.

Authors:  Kurt E Beschorner; Mark S Redfern; William L Porter; Richard E Debski
Journal:  Appl Ergon       Date:  2007-01-02       Impact factor: 3.661

8.  The effect of shoe sole tread groove depth on the friction coefficient with different tread groove widths, floors and contaminants.

Authors:  Kai Way Li; Horng Huei Wu; Yu-Chang Lin
Journal:  Appl Ergon       Date:  2006-01-19       Impact factor: 3.661

9.  Occupational slip, trip, and fall-related injuries--can the contribution of slipperiness be isolated?

Authors:  T K Courtney; G S Sorock; D P Manning; J W Collins; M A Holbein-Jenny
Journal:  Ergonomics       Date:  2001-10-20       Impact factor: 2.778

10.  A prospective study of floor surface, shoes, floor cleaning and slipping in US limited-service restaurant workers.

Authors:  Santosh K Verma; Wen Ruey Chang; Theodore K Courtney; David A Lombardi; Yueng-Hsiang Huang; Melanye J Brennan; Murray A Mittleman; James H Ware; Melissa J Perry
Journal:  Occup Environ Med       Date:  2010-10-08       Impact factor: 4.402
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  5 in total

1.  Worn region size of shoe outsole impacts human slips: Testing a mechanistic model.

Authors:  Vani H Sundaram; Sarah L Hemler; Arnab Chanda; Joel M Haight; Mark S Redfern; Kurt E Beschorner
Journal:  J Biomech       Date:  2020-04-18       Impact factor: 2.712

2.  Traction performance across the life of slip-resistant footwear: Preliminary results from a longitudinal study.

Authors:  Sarah L Hemler; Erika M Pliner; Mark S Redfern; Joel M Haight; Kurt E Beschorner
Journal:  J Safety Res       Date:  2020-07-09

3.  An observational ergonomic tool for assessing the worn condition of slip-resistant shoes.

Authors:  Kurt E Beschorner; Johanna L Siegel; Sarah L Hemler; Vani H Sundaram; Arnab Chanda; Arian Iraqi; Joel M Haight; Mark S Redfern
Journal:  Appl Ergon       Date:  2020-05-20       Impact factor: 3.661

4.  Gait kinetics impact shoe tread wear rate.

Authors:  Sarah L Hemler; Jessica R Sider; Mark S Redfern; Kurt E Beschorner
Journal:  Gait Posture       Date:  2021-03-08       Impact factor: 2.840

5.  Predicting Hydrodynamic Conditions under Worn Shoes using the Tapered-Wedge Solution of Reynolds Equation.

Authors:  Sarah L Hemler; Danielle N Charbonneau; Kurt E Beschorner
Journal:  Tribol Int       Date:  2020-01-08       Impact factor: 5.620
  5 in total

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