A Wearable Footstep Energy Harvester With Novel Dual-Clutch Mechanical Motion Rectification for Self-Powered Sensing

Xiangyang Wang; Meilin Gu; Xingwang Zhou; Hailing Fu; Yeyun Cai; Ziyue Kong; Maobin Lu; Fang Deng

doi:10.1109/TIE.2026.3675109

A Wearable Footstep Energy Harvester With Novel Dual-Clutch Mechanical Motion Rectification for Self-Powered Sensing

Xiangyang Wang
, Meilin Gu
, Xingwang Zhou
, Hailing Fu^*
, Yeyun Cai
, Ziyue Kong
, Maobin Lu
, Fang Deng^*

^*Corresponding author for this work

Beijing Institute of Technology
Greater Bay Area Innovation Research Institute of BIT

Research output: Contribution to journal › Article › peer-review

Abstract

Wearable and autonomous sensing systems require efficient energy conversion under low-frequency, bidirectional mechanical excitations generated by daily human motion. This work presents a novel dual-clutch ratchet energy harvester (DREH) that converts bidirectional heel motions into unidirectional high-speed rotation, enabling direct DC power generation without conventional AC–DC rectification losses. The dual-clutch architecture ensures robust motion rectification under weak excitation and enables recovery of elastic potential energy during the liftoff phase, thereby improving effective energy utilization. A coupled dynamic–electromechanical model is developed to analyze the system behavior and predict electrical output. A compact prototype (86.4 cm³, 89 g) is fabricated and experimentally evaluated under pseudowalk and natural walking conditions. Experimental results show that elastic energy recovery increases output power by 59.5% at 0.3 Hz; at 6 km/h with a 75 Ω load, the prototype delivers 82 mW peak and 28 mW average power with a driving force below 14 N. System-level validation demonstrates continuous operation of a wireless sensing node, confirming the DREH as an effective self-sustained power source for wearable and industrial sensing applications.

Original language	English
Journal	IEEE Transactions on Industrial Electronics
DOIs	https://doi.org/10.1109/TIE.2026.3675109
Publication status	Accepted/In press - 2026

Keywords

Electromechanical energy conversion
low-frequency energy capturing
mechanical energy harvesting
motion rectification
self-powered sensing

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10.1109/TIE.2026.3675109

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@article{0a57cbe4a95644019097c44f2ee161e3,

title = "A Wearable Footstep Energy Harvester With Novel Dual-Clutch Mechanical Motion Rectification for Self-Powered Sensing",

abstract = "Wearable and autonomous sensing systems require efficient energy conversion under low-frequency, bidirectional mechanical excitations generated by daily human motion. This work presents a novel dual-clutch ratchet energy harvester (DREH) that converts bidirectional heel motions into unidirectional high-speed rotation, enabling direct DC power generation without conventional AC–DC rectification losses. The dual-clutch architecture ensures robust motion rectification under weak excitation and enables recovery of elastic potential energy during the liftoff phase, thereby improving effective energy utilization. A coupled dynamic–electromechanical model is developed to analyze the system behavior and predict electrical output. A compact prototype (86.4 cm3, 89 g) is fabricated and experimentally evaluated under pseudowalk and natural walking conditions. Experimental results show that elastic energy recovery increases output power by 59.5\% at 0.3 Hz; at 6 km/h with a 75 Ω load, the prototype delivers 82 mW peak and 28 mW average power with a driving force below 14 N. System-level validation demonstrates continuous operation of a wireless sensing node, confirming the DREH as an effective self-sustained power source for wearable and industrial sensing applications.",

keywords = "Electromechanical energy conversion, low-frequency energy capturing, mechanical energy harvesting, motion rectification, self-powered sensing",

author = "Xiangyang Wang and Meilin Gu and Xingwang Zhou and Hailing Fu and Yeyun Cai and Ziyue Kong and Maobin Lu and Fang Deng",

note = "Publisher Copyright: {\textcopyright} 1982-2012 IEEE.",

year = "2026",

doi = "10.1109/TIE.2026.3675109",

language = "English",

journal = "IEEE Transactions on Industrial Electronics",

issn = "0278-0046",

publisher = "Institute of Electrical and Electronics Engineers Inc.",

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TY - JOUR

T1 - A Wearable Footstep Energy Harvester With Novel Dual-Clutch Mechanical Motion Rectification for Self-Powered Sensing

AU - Wang, Xiangyang

AU - Gu, Meilin

AU - Zhou, Xingwang

AU - Fu, Hailing

AU - Cai, Yeyun

AU - Kong, Ziyue

AU - Lu, Maobin

AU - Deng, Fang

PY - 2026

Y1 - 2026

N2 - Wearable and autonomous sensing systems require efficient energy conversion under low-frequency, bidirectional mechanical excitations generated by daily human motion. This work presents a novel dual-clutch ratchet energy harvester (DREH) that converts bidirectional heel motions into unidirectional high-speed rotation, enabling direct DC power generation without conventional AC–DC rectification losses. The dual-clutch architecture ensures robust motion rectification under weak excitation and enables recovery of elastic potential energy during the liftoff phase, thereby improving effective energy utilization. A coupled dynamic–electromechanical model is developed to analyze the system behavior and predict electrical output. A compact prototype (86.4 cm3, 89 g) is fabricated and experimentally evaluated under pseudowalk and natural walking conditions. Experimental results show that elastic energy recovery increases output power by 59.5% at 0.3 Hz; at 6 km/h with a 75 Ω load, the prototype delivers 82 mW peak and 28 mW average power with a driving force below 14 N. System-level validation demonstrates continuous operation of a wireless sensing node, confirming the DREH as an effective self-sustained power source for wearable and industrial sensing applications.

AB - Wearable and autonomous sensing systems require efficient energy conversion under low-frequency, bidirectional mechanical excitations generated by daily human motion. This work presents a novel dual-clutch ratchet energy harvester (DREH) that converts bidirectional heel motions into unidirectional high-speed rotation, enabling direct DC power generation without conventional AC–DC rectification losses. The dual-clutch architecture ensures robust motion rectification under weak excitation and enables recovery of elastic potential energy during the liftoff phase, thereby improving effective energy utilization. A coupled dynamic–electromechanical model is developed to analyze the system behavior and predict electrical output. A compact prototype (86.4 cm3, 89 g) is fabricated and experimentally evaluated under pseudowalk and natural walking conditions. Experimental results show that elastic energy recovery increases output power by 59.5% at 0.3 Hz; at 6 km/h with a 75 Ω load, the prototype delivers 82 mW peak and 28 mW average power with a driving force below 14 N. System-level validation demonstrates continuous operation of a wireless sensing node, confirming the DREH as an effective self-sustained power source for wearable and industrial sensing applications.

KW - Electromechanical energy conversion

KW - low-frequency energy capturing

KW - mechanical energy harvesting

KW - motion rectification

KW - self-powered sensing

UR - https://www.scopus.com/pages/publications/105036737587

U2 - 10.1109/TIE.2026.3675109

DO - 10.1109/TIE.2026.3675109

M3 - Article

AN - SCOPUS:105036737587

SN - 0278-0046

JO - IEEE Transactions on Industrial Electronics

JF - IEEE Transactions on Industrial Electronics

ER -

A Wearable Footstep Energy Harvester With Novel Dual-Clutch Mechanical Motion Rectification for Self-Powered Sensing

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Keywords

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