“Controlled Slip” Energy Harvesting While Walking

Rapid development in wearable electronics and systems continues to impose challenges on portable energy storage sustained over time, and thus human energy harvesting is a potentially attractive means of sustainable, long-term energy. We introduce a novel ‘controlled slip’ energy harvesting approach for capturing energy during human locomotion. While slip is normally considered undesirable, controlled slip holds potential to enable a significant amount of energy harvesting during each step of human gait. Custom-designed ‘controlled slip’ energy harvesting shoes were fabricated by mounting a sliding plate and a generator with a one-way bearing to the sole of standard walking shoes, which induces controlled forward slip during early stance while energy is harvested. Fourteen healthy subjects performed treadmill walking trials with the ‘controlled slip’ energy harvesting shoes which generated average electrical power of 1.15-1.44 W at walking speeds of 2.9-4.3 km/h. Interestingly, without prompting, subjects chose to walk with the ‘controlled slip’ energy harvesting shoes in either one of two distinct ways: landing with the heel first (heel strikers) or landing with the toe first (toe strikers). While heel strikers and toe strikers exhibited similar electrical power output and hip flexion angle at initial foot contact, heel strikers had higher peak ankle power and lower knee flexion angle at initial foot contact than toe strikers. ‘Controlled slip’ energy harvesting could potentially generate electrical power for a broad spectrum of wearable devices.

• Publication year

  2019

• Venue

  IEEE transactions on neural systems and rehabilitation engineering

• Publication date

  2019-12-23

• Fields of study

  Medicine, Engineering, Geology

• Identifiers
  DOI 10.1109/TNSRE.2019.2961428PMID 31870988
• External record

  Open on Semantic Scholar

• Source metadata

  Semantic Scholar, PubMed

• No claims are published for this paper.

• No concepts are published for this paper.

• An Unpowered Flexible Lower Limb Exoskeleton: Walking Assisting and Energy Harvesting

  2019cited by this paper
• Foot strike pattern, step rate, and trunk posture combined gait modifications to reduce impact loading during running.

  2019cited by this paper
• Design of smart harvester for capturing energy from human ankle dorsiflexion to reduce user effort

  2018cited by this paper
• High performance human-induced vibration driven hybrid energy harvester for powering portable electronics

  2018cited by this paper
• Energy Optimization is a Major Objective in the Real-Time Control of Step Width in Human Walking

  2018cited by this paper
• Energy harvesting textiles for a rainy day: woven piezoelectrics based on melt-spun PVDF microfibres with a conducting core

  2018cited by this paper
• Wearable Biomechanical Energy Harvesting Technologies

  2017cited by this paper
• Motor Control: No Constant but Change.

  2016cited by this paper
• Self-powered textile for wearable electronics by hybridizing fiber-shaped nanogenerators, solar cells, and supercapacitors

  2016cited by this paper
• A highly shape-adaptive, stretchable design based on conductive liquid for energy harvesting and self-powered biomechanical monitoring

  2016cited by this paper
• Motor Control: No Constant but Change

  2016cited by this paper
• Reducing the energy cost of human walking using an unpowered exoskeleton

  2015cited by this paper
• An In-Shoe Harvester With Motion Magnification for Scavenging Energy From Human Foot Strike

  2015influential reference
• Humans Can Continuously Optimize Energetic Cost during Walking.

  2015cited by this paper
• Data sensing and analysis: Challenges for wearables

  2015cited by this paper
• Generating Electricity during Walking with a Lower Limb-Driven Energy Harvester: Targeting a Minimum User Effort

  2015cited by this paper
• Hip-mounted electromagnetic generator to harvest energy from human motion

  2014influential reference
• A Shoe-Embedded Piezoelectric Energy Harvester for Wearable Sensors

  2014influential reference
• A review of wearable sensors and systems with application in rehabilitation

  2012cited by this paper
• Kinematic and kinetic characteristics of Masai Barefoot Technology footwear.

  2012cited by this paper
• Biomechanical energy harvesting from human motion: theory, state of the art, design guidelines, and future directions

  2011cited by this paper
• Biomechanical Energy Harvesting: Generating Electricity During Walking with Minimal User Effort

  2008cited by this paper
• The effects of adding mass to the legs on the energetics and biomechanics of walking.

  2007cited by this paper
• Design and Performance of Linear Biomechanical Energy Conversion Devices

  2006influential reference
• Generating Electricity While Walking with Loads

  2005cited by this paper
• Orthotic intervention in forefoot and rearfoot strike running patterns.

  2004cited by this paper
• Biomechanics of the double rocker sole shoe: gait kinematics and kinetics

  2004cited by this paper
• Biomechanics of the double rocker sole shoe: gait kinematics and kinetics.

  2004cited by this paper
• Biomechanics of the toe-only rocker sole shoe: gait kinematics and kinetics

  2003cited by this paper
• Electroelastomers: applications of dielectric elastomer transducers for actuation, generation, and smart structures

  2002cited by this paper
• Parasitic power harvesting in shoes

  1998cited by this paper
• The role of ankle plantar flexor muscle work during walking.

  1998cited by this paper
• Human-Powered Wearable Computing

  1996cited by this paper
• A gait-powered autologous battery charging system for artificial organs.

  1995cited by this paper
• A gait analysis data collection and reduction technique

  1991cited by this paper

• Hybrid actuators and their reuse methodologies for amphibious robots

  2025cites this paper
• A Knee-Guided Evolutionary Algorithm Based Navigation Approach for Mobile Robots in Intelligent Manufacturing Scenarios

  2025cites this paper
• Design and implementation of a hybrid piezoelectric, radio frequency, solar, and thermal energy‐harvesting system for portable medical devices

  2024cites this paper
• Classification of Parkinson’s disease severity using gait stance signals in a spatiotemporal deep learning classifier

  2024cites this paper
• Wearable Continuous Gait Phase Estimation During Walking, Running, Turning, Stairs, and Over Uneven Terrain

  2024cites this paper
• A high-performance mini-generator with average power of 2 W for human motion energy harvesting and wearable electronics applications

  2023cites this paper
• Piezoelectric transducer comparison for vibrational motion energy harvesting

  2022cites this paper
• A Literature Review of Emerging Research Needs for Micromobility—Integration through a Life Cycle Thinking Approach

  2022cites this paper
• Multi-functional Smart E-Glasses for Vision-Based Indoor Navigation

  2021cites this paper
• Design of A Multi-Functional Soft Ankle Exoskeleton for Foot-Drop Prevention, Propulsion Assistance, and Inversion/Eversion Stabilization

  2020cites this paper
• Modeling and Prediction of Wearable Energy Harvesting Sliding Shoes for Metabolic Cost and Energy Rate Outside of the Lab

  2020cites this paper