ERC Improves Durability of Flexible Thermoelectric Generators for Body Heat-Powered Wearable Devices

Outcome/Accomplishment

The NSF-funded Engineering Research Center (ERC) for Advanced Self-Powered Systems of Integrated Sensors and Technologies (ASSIST) has improved scalable thermoelectric generators (TEGs) that can be integrated into textiles and circuits to create self-powered and wearable monitoring devices. The testing of various materials for durability and flexibility improved overall design functionality.

Impact/Benefits

The use of heat from the human body is a promising approach to creating self-powered, wearable devices that can run continuously. The development of soft, stretchable, and low-resistance materials that can withstand a variety of environmental strains increases the available power and durability of wearable devices powered by TEGs.

Explanation/Background

Flexible TEGs convert the small temperature difference between the body and the environment into electricity to power self-contained circuit systems, like those found in industrial settings, and self-sustaining health monitoring systems.

The NSF-funded research team tested flexible TEGs with Ecoflex fillers, a biodegradable and certified compostable plastic, to improve device performance. The TEGs fabricated with porous Ecoflex fillers matched the performance of TEGs with aerogel doped fillers. In one experiment, all flexible TEGs tested were able to handle extreme amounts of tensile strain before physical failure. The experimental results indicated that the TEGs can tolerate strain levels well over 200%.

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Location

Raleigh, North Carolina

e-mail

assistcenter@ncsu.edu

Start Year

Biotechnology and Healthcare

Biotechnology and Health Care Icon
Biotechnology and Health Care Icon

Biotechnology and Health Care

Lead Institution

North Carolina State University

Core Partners

Florida International University, Pennsylvania State University, University of Virginia
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Outcome/Accomplishment

The NSF-funded Engineering Research Center (ERC) for Advanced Self-Powered Systems of Integrated Sensors and Technologies (ASSIST) has improved scalable thermoelectric generators (TEGs) that can be integrated into textiles and circuits to create self-powered and wearable monitoring devices. The testing of various materials for durability and flexibility improved overall design functionality.

Location

Raleigh, North Carolina

e-mail

assistcenter@ncsu.edu

Start Year

Biotechnology and Healthcare

Biotechnology and Health Care Icon
Biotechnology and Health Care Icon

Biotechnology and Health Care

Lead Institution

North Carolina State University

Core Partners

Florida International University, Pennsylvania State University, University of Virginia

Impact/benefits

The use of heat from the human body is a promising approach to creating self-powered, wearable devices that can run continuously. The development of soft, stretchable, and low-resistance materials that can withstand a variety of environmental strains increases the available power and durability of wearable devices powered by TEGs.

Explanation/Background

Flexible TEGs convert the small temperature difference between the body and the environment into electricity to power self-contained circuit systems, like those found in industrial settings, and self-sustaining health monitoring systems.

The NSF-funded research team tested flexible TEGs with Ecoflex fillers, a biodegradable and certified compostable plastic, to improve device performance. The TEGs fabricated with porous Ecoflex fillers matched the performance of TEGs with aerogel doped fillers. In one experiment, all flexible TEGs tested were able to handle extreme amounts of tensile strain before physical failure. The experimental results indicated that the TEGs can tolerate strain levels well over 200%.