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Miller, Scott
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Topics
Publications (6/6 displayed)
- 2023Additive Printing of Wearable EDA Sensors on In-Mold Electronics on Automotive Platform
- 2022Effect of U-Flex-to-Install and Dynamic U-Flexing on Li-Ion Battery State of Health Degradation Subjected to Varying Fold Orientations, Folding Speeds, Depths of Charge, C-Rates, and Temperaturescitations
- 2022Multilayer Conductive Metallization With Offset Vias Using Aerosol Jet Technologycitations
- 2022Process-Recipe Development for Printing of Multilayer Circuitry With <i>Z</i>-Axis Interconnects Using Aerosol-Jet Printed Dielectric Viascitations
- 2020Process Capability of Aerosol-Jet Additive Processes for Long-Runs Up to 10-Hourscitations
- 2020Flexure and Twist Test Reliability Assurance of Flexible Electronicscitations
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article
Effect of U-Flex-to-Install and Dynamic U-Flexing on Li-Ion Battery State of Health Degradation Subjected to Varying Fold Orientations, Folding Speeds, Depths of Charge, C-Rates, and Temperatures
Abstract
<jats:title>Abstract</jats:title><jats:p>The demand for wearable consumer electronics, fitness accessories, and biomedical equipment has led to the growth research and development of thin flexible batteries. Wearable equipment and other asset monitoring applications require conformal installation of power sources on nonplanar surfaces. For power sources in wearable electronics, durability to sustain repetitive mechanical stresses induced by human body motion is paramount along with the usual desirable power source characteristics. Previous research documenting the reliability of statically and dynamically folded power sources is scarce and does not follow standardized test protocols. Particularly, the use of manual stressing for mechanical folding of the power sources instead of a mechanical test setup is a key shortcoming in existing literature. Data are lacking on battery life cycling and in situ mechanical stress-testing of the power sources including their impact of performance and reliability. This study aims to overcome these deficiencies by testing a commercial Li-ion power source under static as well as dynamic folding. Furthermore, the fold orientation and its fold speed are varied to evaluate the effect of different mechanical stress topologies on the power source. Finally, a regression model was developed to capture the effect of these use parameters on battery capacity degradation.</jats:p>