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Modeling heat transfer in humans for body heat harvesting and personal thermal management

Author

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  • Park, Gimin
  • Kim, Jiyong
  • Woo, Seungjai
  • Yu, Jinwoo
  • Khan, Salman
  • Kim, Sang Kyu
  • Lee, Hotaik
  • Lee, Soyoung
  • Kwon, Boksoon
  • Kim, Woochul

Abstract

The human thermoregulatory system dictates the transfer of heat, produced within organs and skeletal muscles, through body layers and its dissipation to the environment. With the remarkable progress in the field of heat transfer within human beings (bioheat transfer), numerical modeling of the thermal behavior of humans became possible. Such models allow a rough diagnosis of the subject’s health in various clinical conditions (humans undergoing hyperthermia or hypothermia, humans under sleep, newborn infants, etc.) and more accurate estimation of power generated from body heat harvesting devices. In this review, elements that accompany the bioheat transfer models (e.g., heat conduction through body layers, heat generation due to metabolism and blood perfusion, and heat loss mechanisms) are discussed, along with how they have been integrated to develop various numerical methods for estimating the human thermal behavior under different environmental conditions. More importantly, we introduce two representative applications of bioheat transfer models: body heat harvesting and core body temperature measuring devices. The human body is a reliable and continuous heat source that can be used for operating wearable sensors and devices. Accurately determining the amount of heat flowing into the device is crucial for estimating the power output. Furthermore, noninvasive core body temperature sensors based on bioheat transfer mechanisms are explained. Reportedly, the measurements taken with these sensors agree well with the actual core temperatures. This review will be beneficial for heat transfer engineers interested in bioheat transfer as well as for those working in the field of wearable sensors and devices pursuing a reliable energy harvester to operate their sensors.

Suggested Citation

  • Park, Gimin & Kim, Jiyong & Woo, Seungjai & Yu, Jinwoo & Khan, Salman & Kim, Sang Kyu & Lee, Hotaik & Lee, Soyoung & Kwon, Boksoon & Kim, Woochul, 2022. "Modeling heat transfer in humans for body heat harvesting and personal thermal management," Applied Energy, Elsevier, vol. 323(C).
  • Handle: RePEc:eee:appene:v:323:y:2022:i:c:s030626192200914x
    DOI: 10.1016/j.apenergy.2022.119609
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    References listed on IDEAS

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    1. Nozariasbmarz, Amin & Collins, Henry & Dsouza, Kelvin & Polash, Mobarak Hossain & Hosseini, Mahshid & Hyland, Melissa & Liu, Jie & Malhotra, Abhishek & Ortiz, Francisco Matos & Mohaddes, Farzad & Rame, 2020. "Review of wearable thermoelectric energy harvesting: From body temperature to electronic systems," Applied Energy, Elsevier, vol. 258(C).
    2. Sultana, Ayesha & Alam, Md. Mehebub & Middya, Tapas Ranjan & Mandal, Dipankar, 2018. "A pyroelectric generator as a self-powered temperature sensor for sustainable thermal energy harvesting from waste heat and human body heat," Applied Energy, Elsevier, vol. 221(C), pages 299-307.
    3. Abdul Mageeth, Aqeel Mohammed & Park, SungJin & Jeong, Myunghwan & Kim, Woochul & Yu, Choongho, 2020. "Planar-type thermally chargeable supercapacitor without an effective heat sink and performance variations with layer thickness and operation conditions," Applied Energy, Elsevier, vol. 268(C).
    4. Zhao, Dongliang & Lu, Xing & Fan, Tianzhu & Wu, Yuen Shing & Lou, Lun & Wang, Qiuwang & Fan, Jintu & Yang, Ronggui, 2018. "Personal thermal management using portable thermoelectrics for potential building energy saving," Applied Energy, Elsevier, vol. 218(C), pages 282-291.
    5. Park, Hwanjoo & Eom, Yoomin & Lee, Dongkeon & Kim, Jiyong & Kim, Hoon & Park, Gimin & Kim, Woochul, 2019. "High power output based on watch-strap-shaped body heat harvester using bulk thermoelectric materials," Energy, Elsevier, vol. 187(C).
    6. Seok Woo Lee & Yuan Yang & Hyun-Wook Lee & Hadi Ghasemi & Daniel Kraemer & Gang Chen & Yi Cui, 2014. "An electrochemical system for efficiently harvesting low-grade heat energy," Nature Communications, Nature, vol. 5(1), pages 1-6, September.
    7. Ghomian, Taher & Kizilkaya, Orhan & Choi, Jin-Woo, 2018. "Lead sulfide colloidal quantum dot photovoltaic cell for energy harvesting from human body thermal radiation," Applied Energy, Elsevier, vol. 230(C), pages 761-768.
    8. Eom, Yoomin & Wijethunge, Dimuthu & Park, Hwanjoo & Park, Sang Hyun & Kim, Woochul, 2017. "Flexible thermoelectric power generation system based on rigid inorganic bulk materials," Applied Energy, Elsevier, vol. 206(C), pages 649-656.
    9. Lee, Dongkeon & Park, Hwanjoo & Park, Gimin & Kim, Jiyong & Kim, Hoon & Cho, Hanki & Han, Seungwoo & Kim, Woochul, 2019. "Liquid-metal-electrode-based compact, flexible, and high-power thermoelectric device," Energy, Elsevier, vol. 188(C).
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