Abstract
This paper investigates the performance of a near field wireless power transfer system that uses curved relay resonator to extend transfer distance. Near field wireless power transfer operates based on the near-field electromagnetic coupling of coils. Such a system can transfer energy over a relatively short distance which is of the same order of dimensions of the coupled coils. The energy transfer distance can be increased using flat relay resonators. Recent developments in printing electronics and e-textiles have seen increasing demand of embedding electronics into fabrics. Near field wireless power transfer is one of the most promising methods to power electronics on fabrics. The concept can be applied to body-worn textiles by, for example, integrating a transmitter coil into upholstery, and a flexible receiver coil into garments. Flexible textile coils take on the shape of the supporting materials such as garments, and therefore curved resonator and receiver coils are investigated in this work. Experimental results showed that using curved relay resonator can effectively extend the wireless power transfer distance. However, as the curvature of the coil increases, the performance of the wireless power transfer, especially the maximum received power, deteriorates.
Highlights
Recent developments in printing electronics and e-textiles have seen increasing demand for embedding electronics into fabrics for wearable applications
This paper investigates the performance of a near field wireless power transfer system that uses curved relay resonator to extend transfer distance
Flexible textile coils take on the shape of the supporting materials such as garments, and curved resonator and receiver coils are investigated in this work
Summary
Recent developments in printing electronics and e-textiles have seen increasing demand for embedding electronics into fabrics for wearable applications. One of the difficulties with such applications is how to provide a sufficient and reliable power source. Traditional batteries are not an ideal solution for this application because its bulky size makes it difficult to be integrated into fabrics. They have limited capacity and, require constant maintenance such as replacement or recharging. Energy harvesting concerns conversion of ambient energy into electrical energy and can potentially be used to power electronics in wearable applications. Ambient energy sources in this application include human movement, temperature difference and ambient light.
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