Authors

Thermoelectric solar cooling systems

DOI: 10.17586/1606-4313-2025-24-2-31-39
UDC 621.565.83

Thermoelectric solar cooling systems

Sulin A.B., Hein Htet Aung, Shein V.М.

For citation: Sulin A.B., Hein T.A., Shein V.M. Thermoelectric solar cooling systems. Journal of International Academy of Refrigeration. 2025. No 2. p. 31-39. DOI: 10.17586/1606-4313-2025-24-2-31-39

Abstract
Solar cooling systems are divided into two types. Cooling systems that consume solar thermal energy are based on sorption principles and have many implementations depending on the temperature potential of the heat transfer medium, which in turn depends on the type of solar collector. The highest temperature potential is provided by concentrating collectors which are the most expensive. They allow to realize efficient two- and three-stage absorption cooling cycles in lithium bromide and water-ammonia plants. Cooling systems based on electric energy from solar panels utilize electrically driven refrigeration machines. These are vapor-compression systems and direct energy conversion systems: thermoelectric and on caloric effects (electrocaloric, magnetocaloric, and piezocaloric). Specifically, it is necessary to emphasize thermoelectric systems on the Peltier effect, because they consume DC energy which is produced by solar panels and does not require conversion to AC. In the article a review of scientific literature in the field of solar-driven thermoelectric cooling is performed. The schematic solutions and technical characteristics of two groups of these systems are given: devices for cooling of external objects and devices for cooling of solar panels themselves to improve their performance.

Keywords: alternative energy sources, solar cells, thermoelectric cooling, thermal modes, energy efficiency.

All references

1. Yüksel I. Global warming and renewable energy sources for sustainable development in Turkey. Renew. Energy. 2008. vol. 33 (4), 802-812.

2. Alsagri A.S. Photovoltaic and photovoltaic thermal technologies for refrigeration purposes: an overview. Arab. J. Sci. Eng. 2022. 47 (7), 7911-7944.

3. Raihan Uddin M., et al. Energy analysis of a solar driven vaccine refrigerator using environment-friendly refrigerants for off-grid locations. Energy Convers. Manag. 2021. X 11, 100095.

4. Opoku R., Anane S., Edwin I.A., Adaramola M.S., Seidu R. Comparative techno-economic assessment of a converted DC refrigerator and a conventional AC refrigerator both powered by solar PV. Int. J. Refrig. 2016. 72, 1-11.

5. Hermann W. Quantifying global exergy resources. Energy. 2006. 31 (12), 1685-1702.

6. Gunapriya B. et al. Modelling and Design of Solar-Powered DC Refrigerator for Vaccines Transportation in Remote Areas. In: 2022 3rd International Conference on Smart Electronics and Communication (ICOSEC), Oct. 2022.

7. S. Rajasekaran,A. B. K. Reddy, K. Saiteja,P Rajesh,Pritam Raj.Portable thermoelectric refrigeration system using solar energy, In: 2022 4th International Conference on Inventive Research in Computing Applications (ICIRCA), Sep. 2022.

8. Kalkan N., Young E.A., Celiktas A., Solar thermal air conditioning technology reducing the footprint of solar thermal air conditioning. Renew. Sustain. Energy Rev. 2012. 16 (8), 6352-6383.

9. Gourab Saha, AKM Abdul Malek Azad. A review of advancements in solar PV-powered refrigeration: Enhancing efficiency, sustainability, and operational optimization. Energy. Reports 12. 2024. 1693-1709.

10. S.B. Riffat, X. Ma, Improving the coefficient of performance of thermoelectric cooling systems: a review, Int. J. Energy Res. 2004. 28 (9). P. 753-768.

11. N. Alam, M. Salman Ali, S. Sajid, D. Sharma, Z. Hasan, Experimental investigation and analysis of cooling performance of solar thermoelectric refrigerator, Sol. Energy 263 (August) (2023) 111892.

12. S.A. Abdul-Wahab, et al., Design and experimental investigation of portable solar thermoelectric refrigerator, Renew. Energy. Jan. 2009. 34 (1). P. 30-34.

13. T. Hara, H. Azuma, H. Shimizu, H. Obora, S. Sato, Cooling performance of solar cell driven, thermoelectric cooling prototype headgear, Appl. Therm. Eng. Nov. 1998. 18 (11). P.1159-1169.

14. M.M.S.A. Qamar, M. Farooq, M. Amjad, H. Bilal, Effect of heat sink configuration on the COP of thermoelectric vaccine refrigerator, J. Facul. Eng. Technol. 2016. 23 (1). P. 33-43.

15. R. Saidur, et al., Performance investgation of a solar powered thermoelectric refrigerator, Int. J. Mech. Mater. Eng. 2008. 3 (1). p. 7-16.

16. W. He, G. Zhang, X. Zhang, J. Ji, G. Li, X. Zhao, Recent development and application of thermoelectric generator and cooler, Appl. Energy. 2015. 143. P. 1-25.

17. S. Rajasekaran, A.B.K. Reddy, K. Saiteja, P. Rajesh, P.V. Raj, Portable thermoelectric refrigeration system using solar energy, in: 4th International Conference on Inventive Research in Computing Applications, ICIRCA 2022 - Proceedings, Institute of Electrical and Electronics Engineers Inc., 2022, pp. 235-240.

18. J.J. Mil´on Guzm´an, S.L. Braga, J.C. Zú˜ niga Torres, H.J. Del Carpio Beltr´an. Solar thermoelectric cooling technology applied to transport of vaccines in isolated communities, in E3S Web of Conferences, EDP Sciences, Jul., 2020.

19. J.A.D. Nohay, et al. Design and fabrication of a portable solar powered thermoelectric refrigerator for insulin storage, in: 2020 11th IEEE Control and System Graduate Research Colloquium, ICSGRC 2020 - Proceedings, Institute of Electrical and Electronics Engineers Inc., Aug. 2020, pp. 150-154.

20. B. Ohara, R. Sitar, J. Soares, P. Novisoff, A. Nunez-Perez, H. Lee, Optimization strategies for a portable thermoelectric vaccine refrigeration system in developing communities,J. Electron. Mater. Jun. 2015. 44 (6). P. 1614-1626.

21. S. Thiangchanta, T.A. Do, W. Tachajapong, Y. Mona, Experimental investigation of the thermoelectric cooling with vacuum wall system, Energy Rep. Dec. 2020. 6. P. 1244-1248.

22. Erin Fenton, Mehran Bozorgi, Syeda Tasnim, Shohel Mahmud Solar-powered thermoelectric refrigeration with integrated phase change material: An experimental approach to food storage. Journal of Energy Storage. 79 (2024) 110247.

23. B. Bakthavatchalam, K. Habib, R. Saidur, B.B. Saha. Cooling performance analysis of nanofluid assisted novel photovoltaic thermoelectric airconditioner for energy efficien tbuildings. Appl. Therm. Eng. 213 (2022) 118691.

24. M.E. Zayed, M.M. Aboelmaaref, M. Chazy. Design of solar airconditioning system integrated with photovoltaic panel sand thermoelectric coolers: experimental analysis and machine learning modeling by random vector functional link coupled with white whale optimization. Therm. Sci. Eng. Prog. 44 (2023) 102051.

25. S. Lv, M. Zhang, J. Tian, Z. Zhang, Z. Duan, Y. Wu, Y. Deng. Performance analysis of radiative cooling combined with photovoltaic-driven thermoelectric cooling system in practical application. Energy. 294 (2024) 130971.

26. R. Chandel, S.S. Chandel, D. Prasad, R.P. Dwivedi. Experimental analysis and modelling of a photovoltaic powered thermoelectric solid-state cooling system for transition towards net zero energy buildings under different solar loading conditions. J. Clean. Prod. 442 (2024) 141099.

27. K. Irshad, S. Rehman, MdH. Zahir, F. Khan, D. Balakrishnan, B.B. Saha, Analysis of photovoltaic thermoelectric air conditioning for personalized cooling in arid climate // J. Build. Eng. 84 (2024) 108533

28.Yang Cai, Wei-Wei Wang, Cheng-Wei Liu, Wen-Tao Ding, Di Liu d, Fu-Yun Zhao. Performance evaluation of a thermoelectric ventilation system driven by the concentrated photovoltaic thermoelectric generators for green building operations. Renewable Energy. 147 (2020) 1565e1583.

29. Yejiong Xing, Suqi Wang The energy and exergy examination of a thermoelectric ventilation system powered by photovoltaic/thermoelectric for space cooling and heating in a residential building. Journal of Building Engineering. 98 (2024) 111305.

30. Hossam Eldein Abdelfattah Mohamed Ahmed, ets.Novel design of thermo-electric air conditioning system integrated with PV panel for electric vehicles: Performance evaluation. Applied Energy. 349 (2023) 121662.

31. Yanmei Su, Ruoyun Wu, Jinwen Yang, Chaoyang Mou, Jitian Han. Research Paper Performance evaluation on a novel split thermoelectric system driven by solar energy for electric vehicle seats. Applied Thermal Engineering. 253 (2024) 123801.

32. M.S. Kumar, K.R. Balasubramanian, L. Maheswari. Effect of temperature on solar photovoltaic panel efficiency, Int. J. Eng. Adv. Technol. 8 (6) (2019) 2593-2595.

33. G.T.V. Mooko, P.A. Hohne, K. Kusakana. Enhancing photovoltaic operation system efficiency and cost-effectiveness through optimal control of thermoelectric cooling. Solar Energy Materials & Solar Cells. 273 (2024) 112937.

34. R. Chandel, S.S. Chandel. Performance analysis outcome of a 19-MWp commercial solar photovoltaic plant with fixed-tilt, adjustable-tilt, and solar tracking config urations, Prog. Photovolt. Res. Appl. (2021) 85.

35. O.S. Sastry, R. Chandel, R.K. Singh, P.K. Dash, R. Kumar. Bandopadhyay Degradation analysis of different PV modules after prolonged field operation. In: Proceedings of the 26th European Photovoltaic Solar Energy Conference and Exhibition, 2011, pp. 3495-3499.

36. M. Owen-Bellini, E.L. Warren. Reliability of tandem solar cells and modules: what’s next? Energy. 1(4) (2023) 100062.

37. H. Moshfegh, M. Eslami, A. Hosseini. Thermoelectric cooling of a photovoltaic panel. The Role of Exergy in Energy and the Environment. (2018) 625-634.

38. S. Maryani, R.D. Kusumanto, R.S. Carlos. Solar panel optimization using peltier module TEC1-12706, Journal of Mechanical, Civil and Industrial Engineering. 4 (3) (2023) 43-50.

39. D. Algül, D.˙ I.R.˙ I. Cüneyt. A method proposal to increase the efficiency of photovoltaic panels integrated to buildings in both cold and hot seasons. Journal of Architectural Sciences and Applications. 6 (1) (2021) 227-236.

40. I. Najihi, C. Ennawaoui, A. Hajjaji, Y. Boughaleb. Theoretical modeling of longitudinal piezoelectric characteristic for cellular polymers. Cell. Polym. 02624893211055830 (2021).

41. J.G. Ingersoll. Simplified calculation of solar cell temperatures in terrestrial photovoltaic arrays. ASME J. Solar Energy Eng. 108 (1986) 95-101.

42. Hafsa Kandry, Chouaib Ennawaoui, El Mehdi Laadissi, El Mehdi Loualid, Abdessamad El Ballouti, Zakaria Malki, Mohamed El Jouad, Adil Balhamri, Abdelowahed Hajjaji. Optimized photovoltaic panels power using cooling system based thermoelectric materials. Materials Today: Proceedings. 66 (2022) 479-483.

43. Hamidreza Najafi, Keith A. Woodbury Optimization of a cooling system based on Peltier effect for photovoltaic cells. Solar Energy. 91 (2013) 152-160.