Design self-sustainable wearable E-textile systems using the microgrid
Current wearable systems with energy harvesters are limited in compatibility, practicality, and reliability. Learning from the success of renewable energy microgrids, we demonstrate an E
s41467-021-21701-7 OPEN A self-sustainable wearable multi
on the careful selection of components with compatible performance and complementary characteristics. Inspired by this notion, we herein propose and demonstrate the concept of a wearable...
A self-sustainable wearable multi-modular E-textile bioenergy
Inspired by this notion, we herein propose and demonstrate the concept of a wearable e-textile microgrid system: a multi-module, textile-base system with applications powered by complementary and
A self-sustainable wearable multi-modular E-textile bioenergy
Implementing "compatible form factors, commensurate performance, and complementary functionality" design principles, the flexible, textile-based bioenergy microgrid offers attractive prospects for the
Design self-sustainable wearable E-textile systems
Current wearable systems with energy harvesters are limited in
A self-sustainable wearable multi-modular E-textile bioenergy
Here, we introduce the concept and design principles of e-textile microgrids by demonstrating a multi-module bioenergy microgrid system.
NanoEngineering Researchers Introduce E-textile Bioenergy Microgrid
Researching efforts led by NanoEngineering professors Joseph Wang and Sheng Xu introduce the design of flexible e-textile microgrids by presenting a multi-module bioenergy microgrid system.
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