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Experimental evaluation of prototype thermoelectric domestic-refrigerators

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  • Min, Gao
  • Rowe, D.M.

Abstract

A number of prototype thermoelectric refrigerators are investigated and their cooling performances evaluated in terms of the coefficient-of-performance, heat-pumping capacity and cooling-down rate. The coefficient-of-performance of a thermoelectric refrigerator is found to be around 0.3-0.5 for a typical operating temperature at 5 °C with ambient at 25 °C. The potential improvement in the cooling performance of a thermoelectric refrigerator is also investigated employing a realistic model, with experimental data obtained from this work. The results show that an increase in its COP is possible through improvements in module contact resistances, thermal interfaces and the effectiveness of heat exchangers.

Suggested Citation

  • Min, Gao & Rowe, D.M., 2006. "Experimental evaluation of prototype thermoelectric domestic-refrigerators," Applied Energy, Elsevier, vol. 83(2), pages 133-152, February.
    • Handle: RePEc:eee:appene:v:83:y:2006:i:2:p:133-152
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    1. Afshari, Faraz & Mandev, Emre & Muratçobanoğlu, Burak & Yetim, Ali Fatih & Ceviz, Mehmet Akif, 2023. "Experimental and numerical study on a novel fanless air-to-air solar thermoelectric refrigerator equipped with boosted heat exchanger," Renewable Energy, Elsevier, vol. 207(C), pages 253-265.
    2. Siviter, J. & Montecucco, A. & Knox, A.R., 2015. "Rankine cycle efficiency gain using thermoelectric heat pumps," Applied Energy, Elsevier, vol. 140(C), pages 161-170.
    3. Diaz-Londono, Cesar & Enescu, Diana & Ruiz, Fredy & Mazza, Andrea, 2020. "Experimental modeling and aggregation strategy for thermoelectric refrigeration units as flexible loads," Applied Energy, Elsevier, vol. 272(C).
    4. Agnieszka Żelazna & Justyna Gołębiowska, 2020. "A PV-Powered TE Cooling System with Heat Recovery: Energy Balance and Environmental Impact Indicators," Energies, MDPI, vol. 13(7), pages 1-22, April.
    5. Silva, D.J. & Ventura, J. & Araújo, J.P. & Pereira, A.M., 2014. "Maximizing the temperature span of a solid state active magnetic regenerative refrigerator," Applied Energy, Elsevier, vol. 113(C), pages 1149-1154.
    6. Martínez, A. & Astrain, D. & Rodríguez, A., 2011. "Experimental and analytical study on thermoelectric self cooling of devices," Energy, Elsevier, vol. 36(8), pages 5250-5260.
    7. He, Wei & Zhou, Jinzhi & Hou, Jingxin & Chen, Chi & Ji, Jie, 2013. "Theoretical and experimental investigation on a thermoelectric cooling and heating system driven by solar," Applied Energy, Elsevier, vol. 107(C), pages 89-97.
    8. Andrés Villarruel-Jaramillo & Manuel Pérez-García & José M. Cardemil & Rodrigo A. Escobar, 2021. "Review of Polygeneration Schemes with Solar Cooling Technologies and Potential Industrial Applications," Energies, MDPI, vol. 14(20), pages 1-30, October.
    9. Enescu, Diana & Virjoghe, Elena Otilia, 2014. "A review on thermoelectric cooling parameters and performance," Renewable and Sustainable Energy Reviews, Elsevier, vol. 38(C), pages 903-916.
    10. Cheng, Chin-Hsiang & Huang, Shu-Yu, 2012. "Development of a non-uniform-current model for predicting transient thermal behavior of thermoelectric coolers," Applied Energy, Elsevier, vol. 100(C), pages 326-335.
    11. Irshad, Kashif & Habib, Khairul & Basrawi, Firdaus & Saha, Bidyut Baran, 2017. "Study of a thermoelectric air duct system assisted by photovoltaic wall for space cooling in tropical climate," Energy, Elsevier, vol. 119(C), pages 504-522.
    12. Hermes, Christian J.L. & Barbosa, Jader R., 2012. "Thermodynamic comparison of Peltier, Stirling, and vapor compression portable coolers," Applied Energy, Elsevier, vol. 91(1), pages 51-58.
    13. 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).
    14. Zhao, Dongliang & Tan, Gang, 2014. "Experimental evaluation of a prototype thermoelectric system integrated with PCM (phase change material) for space cooling," Energy, Elsevier, vol. 68(C), pages 658-666.
    15. Silva, D.J. & Bordalo, B.D. & Pereira, A.M. & Ventura, J. & Araújo, J.P., 2012. "Solid state magnetic refrigerator," Applied Energy, Elsevier, vol. 93(C), pages 570-574.
    16. Tijani, Ismaila B. & Al Hamadi, Ahmad A.A. & Al Naqbi, Khaled A.S.S. & Almarzooqi, Rashed I.M. & Al Rahbi, Noura K.S.R., 2018. "Development of an automatic solar-powered domestic water cooling system with multi-stage Peltier devices," Renewable Energy, Elsevier, vol. 128(PA), pages 416-431.
    17. Sergiy Filin & Ludmiła Filina-Dawidowicz, 2021. "Improvement of Criteria for Assessing the Energy Efficiency of Thermoelectric Refrigerators Used in Supply Chains," Energies, MDPI, vol. 14(6), pages 1-18, March.
    18. Oswaldo Hideo Ando Junior & Nelson H. Calderon & Samara Silva De Souza, 2018. "Characterization of a Thermoelectric Generator (TEG) System for Waste Heat Recovery," Energies, MDPI, vol. 11(6), pages 1-13, June.
    19. Rui Miao & Xiaoou Hu & Yao Yu & Qifeng Zhang & Zhibin Lin & Abdulaziz Banawi & Ahmed Cherif Megri, 2021. "Experimental Study to Analyze Feasibility of a Novel Panelized Ground-Source Thermoelectric System for Building Space Heating and Cooling," Energies, MDPI, vol. 15(1), pages 1-17, December.
    20. Fitriani, & Ovik, R. & Long, B.D. & Barma, M.C. & Riaz, M. & Sabri, M.F.M. & Said, S.M. & Saidur, R., 2016. "A review on nanostructures of high-temperature thermoelectric materials for waste heat recovery," Renewable and Sustainable Energy Reviews, Elsevier, vol. 64(C), pages 635-659.

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