Literature DB >> 16151012

Generating electricity while walking with loads.

Lawrence C Rome1, Louis Flynn, Evan M Goldman, Taeseung D Yoo.   

Abstract

We have developed the suspended-load backpack, which converts mechanical energy from the vertical movement of carried loads (weighing 20 to 38 kilograms) to electricity during normal walking [generating up to 7.4 watts, or a 300-fold increase over previous shoe devices (20 milliwatts)]. Unexpectedly, little extra metabolic energy (as compared to that expended carrying a rigid backpack) is required during electricity generation. This is probably due to a compensatory change in gait or loading regime, which reduces the metabolic power required for walking. This electricity generation can help give field scientists, explorers, and disaster-relief workers freedom from the heavy weight of replacement batteries and thereby extend their ability to operate in remote areas.

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Year:  2005        PMID: 16151012     DOI: 10.1126/science.1111063

Source DB:  PubMed          Journal:  Science        ISSN: 0036-8075            Impact factor:   47.728


  26 in total

1.  Soft Tissue Deformations Contribute to the Mechanics of Walking in Obese Adults.

Authors:  Xiao-Yu Fu; Karl E Zelik; Wayne J Board; Raymond C Browning; Arthur D Kuo
Journal:  Med Sci Sports Exerc       Date:  2015-07       Impact factor: 5.411

2.  Vibration-Energy-Harvesting System: Transduction Mechanisms, Frequency Tuning Techniques, and Biomechanical Applications.

Authors:  Lin Dong; Andrew B Closson; Congran Jin; Ian Trase; Zi Chen; John X J Zhang
Journal:  Adv Mater Technol       Date:  2019-08-13

3.  A pressure driven electric energy generator exploiting a micro- to nano-scale glass porous filter with ion flow originating from water.

Authors:  Yo Tanaka; Satoshi Amaya; Shun-Ichi Funano; Hisashi Sugawa; Wataru Nagafuchi; Yuri Ito; Yusufu Aishan; Xun Liu; Norihiro Kamamichi; Yaxiaer Yalikun
Journal:  Sci Rep       Date:  2022-10-20       Impact factor: 4.996

4.  Recycling energy to restore impaired ankle function during human walking.

Authors:  Steven H Collins; Arthur D Kuo
Journal:  PLoS One       Date:  2010-02-17       Impact factor: 3.240

5.  The up and down bobbing of human walking: a compromise between muscle work and efficiency.

Authors:  Firas Massaad; Thierry M Lejeune; Christine Detrembleur
Journal:  J Physiol       Date:  2007-04-26       Impact factor: 5.182

6.  In vivo demonstration of a self-sustaining, implantable, stimulated-muscle-powered piezoelectric generator prototype.

Authors:  B E Lewandowski; K L Kilgore; K J Gustafson
Journal:  Ann Biomed Eng       Date:  2009-08-06       Impact factor: 3.934

7.  Biomechanical energy harvesting from human motion: theory, state of the art, design guidelines, and future directions.

Authors:  Raziel Riemer; Amir Shapiro
Journal:  J Neuroeng Rehabil       Date:  2011-04-26       Impact factor: 4.262

8.  Generating Electricity during Walking with a Lower Limb-Driven Energy Harvester: Targeting a Minimum User Effort.

Authors:  Michael Shepertycky; Qingguo Li
Journal:  PLoS One       Date:  2015-06-03       Impact factor: 3.240

9.  Development of a biomechanical energy harvester.

Authors:  Qingguo Li; Veronica Naing; J Maxwell Donelan
Journal:  J Neuroeng Rehabil       Date:  2009-06-23       Impact factor: 4.262

10.  Self-rechargeable cardiac pacemaker system with triboelectric nanogenerators.

Authors:  Hanjun Ryu; Hyun-Moon Park; Moo-Kang Kim; Bosung Kim; Hyoun Seok Myoung; Tae Yun Kim; Hong-Joon Yoon; Sung Soo Kwak; Jihye Kim; Tae Ho Hwang; Eue-Keun Choi; Sang-Woo Kim
Journal:  Nat Commun       Date:  2021-07-16       Impact factor: 14.919
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