Self-Powered Wearable Electrocardiography Using a Wearable Thermoelectric Power Generator

Kim, C. S.; Yang, Hyeong Man; Lee, Jin-Seok; Lee, Gyu Soup; Choi, Hyeongdo; Kim, Yong Jun; Lim, Se Hwan; Cho, Seong Hwan; Cho, Byung Jin

doi:10.1021/acsenergylett.7b01237

Cited by 259 publications

(227 citation statements)

References 31 publications

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“…Different from heat sinks with PCMs or micro-channels mentioned above, not much research has been done on flexible heat sinks as their demand has been low. There have been several works [26,72,94] which adopt a flexible heat sink on a thermoelectric generator for body heat harvesting. Although the performance of body heat harvesting has been enhanced with the existence of a flexible heat sink, those research have aimed more on the flexible thermoelectric system rather than flexible heat sink.…”

Section: Heat Sink For Tegmentioning

confidence: 99%

“…To operate a miniaturized accelerometer which requires 2.4 μW of power with a 1.6 mV voltage, a DC-DC converter with an efficiency of 50% is adopted to boost the voltage up to 2.2 V. A demonstrated thermoelectric system successfully operates the miniaturized accelerometer powered from body heat, as in figure 6(a). Kim et al[72] represent a self-powered wearable ECG system using a DC-DC converter, as infigure 6(b). The system consists of a DC-DC converter, VDD shifter and an ECG module.…”

mentioning

confidence: 99%

“…Flexible thermoelectric system with a voltage converter and wireless sensor powered by body heat: (a) the system operating an accelerometer from human motion[71]. (b) Operation of self-powered wearable electrocardiography[72]. (a) Reprinted from[71], Copyright 2018, with permission from Elsevier.…”

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confidence: 99%

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confidence: 99%

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Energy harvesting using thermoelectricity for IoT (Internet of Things) and E-skin sensors

et al. 2019

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With the increasing demand for Internet of Things (IoT) with integrated wireless sensor networks (WSNs), sustainable power supply and management have become important issues to be addressed. Thermal energy in forms of waste heat or metabolic heat is a promising source for reliably supplying power to electronic devices; for instance, thermoelectric power generators are widely being researched as they are able to convert thermal energy into electricity. This paper specifically looks over the application of thermoelectricity as a sustainable power source for IoT including WSNs. Also, we discuss a few thermoelectric systems capable of operating electronic skin (e-skin) sensors despite their low output power from body heat. For a more accurate analysis on body heat harvesting, models of the human thermoregulatory system have been investigated. In addition, some clever designs of heat sinks that can be integrated with thermoelectric systems have also been introduced. For their power management, the integration with a DC-DC converter is addressed to boost its low output voltage to a more usable level.

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Section: Heat Sink For Tegmentioning

confidence: 99%

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confidence: 99%

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confidence: 99%

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confidence: 99%

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Energy harvesting using thermoelectricity for IoT (Internet of Things) and E-skin sensors

et al. 2019

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“…Thermoelectricity, a phenomenon which enables the direct conversion of heat into electricity or vice versa, is attractive because it allows electricity to be generated from waste heat and provide environmentally friendly cooling. Given its many advantages, a large number of studies have been carried out to investigate a wide spectrum of applications in military, medical, industrial, and telecommunications fields . For example, to generate power from a heat source that has an arbitrary shaped surface, flexible thermoelectric generators (TEGs) have been developed and studied …”

Section: Introductionmentioning

confidence: 99%

UV‐Curable Silver Electrode for Screen‐Printed Thermoelectric Generator

Choi

Kim

Song

et al. 2019

Adv Funct Materials

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Fabricating thermoelectric generators (TEGs) using the screen-printing process has advantages, including mass production, device scalability, and system applicability. However, the thick film formed through the process typically has low film density, and reduced performance, because of the presence of pores in the film created by the vaporization of the resin during hightemperature annealing. During the soldering process used for thermoelectric module fabrication, the printed solder infiltrates into the screen-printed electrodes through the micropores in the electrodes, causing cracks of the electrode film and an increase in resistivity. In this paper, an ultraviolet radiation (UV)-curable process for screen-printed electrodes is reported. The paste for the electrodes is synthesized by mixing Ag flakes that can be cured at low temperature with a UV resin. Scanning electron microscope images show that the UV-curing process significantly reduces pores and thereby results in a smooth-surfaced electrode layer. The film density after crystallization is also enhanced. TEGs composed of 72 couples with UV-curable Ag electrodes generate a high power density of ≈6.69 mW cm −2 at a temperature difference of 25 °C; the device resistance is ≈0.75 Ω, and the figure of merit of the device is recorded to be 0.57, which is the highest among the printed TEGs.

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Smart Nanotextiles for Energy Generation

Xiong

Lee

2022

Smart Nanotextiles

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Self-Powered Wearable Electrocardiography Using a Wearable Thermoelectric Power Generator

Cited by 259 publications

References 31 publications

Energy harvesting using thermoelectricity for IoT (Internet of Things) and E-skin sensors

Energy harvesting using thermoelectricity for IoT (Internet of Things) and E-skin sensors

UV‐Curable Silver Electrode for Screen‐Printed Thermoelectric Generator

Smart Nanotextiles for Energy Generation

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