EXPERIMENTAL STUDY ON THE SYNERGISTIC EFFECTS OF COOLING METHODS AND HEAT SINK DESIGN ON THERMOELECTRIC GENERATOR PERFORMANCE

Authors

  • C. N. Udekwe

    Department of Information and Communication Engineering, Federal University of Technology, Akure, Ondo State, Nigeria

  • A. A. Ponnle

    Department of Electrical and Electronics Engineering, Federal University of Technology, Akure, Ondo State, Nigeria

  • A. O. Omolade

    Department of Electrical and Electronics Engineering, Federal University of Technology, Akure, Ondo State, Nigeria

DOI:
https://doi.org/10.51459/futajeet.2026.20.Special.534
Keywords:
Thermoelectric Generator (TEG), Heat Sinks, Fan cooling, Ice cooling, Temperature difference
Abstract

Thermoelectric generators (TEGs) are a promising option for recovering waste heat into electricity, particularly in low-power applications. However, their performance is often limited by poor heat management, inefficient cooling at the cold side, and substandard material choices. This paper investigates the performance of different heat sink configurations which are the, High-Density Fin Aluminum Alloy (HDFA) and Extruded Aluminum Fin Alloy (EAFA), on a thermoelectric generator (TEG) module and tested under different temperature differences and cooling options such as the ice cooling and fan cooling. The study analyzes the impact of temperature difference on voltage, current, and power output of the thermoelectric generator to determine the most effective heat sink configuration and cooling technique for optimizing thermoelectricity generation. Experimental results showed that the HDFA consistently performed better than the EAFA across all trials which demonstrates higher voltage, current, and power output. Additionally, ice cooling was more effective than fan cooling which generates more power by maintaining higher temperature difference. Results also indicated a direct correlation between power output and temperature difference, further validating how important heat management is in thermoelectric energy conversion. Despite these promising results, some limitations were found such as, controlled laboratory conditions that was used in the experiments that may not fully represent real-world applications. Further research should explore alternative thermoelectric materials, hybrid cooling techniques, and dynamic environmental conditions. These results contribute to the advancements of thermoelectric generators (TEGs) modules, while further supporting their applications into renewable energy systems. Finally, selecting better heat sink materials and cooling techniques would help accelerate the technologies for waste heat recovery and renewable energy systems.

References

Holyk S. (2023). Heating Systems and Households’ Expenditure. Master’s thesis, University of San Francisco, San Francisco. Available at: https://repository.usfca.edu/thes [Accessed 28 February 2025].

Globe Newswire (2024). Waste heat recovery market to reach $129.6 billion globally by 2033 at 6.8% CAGR: Allied Market Research. Globe Newswire, 1 October. Available at: https://www.globenewswire.com/news-release/2024/10/01/2956277/0/en/Waste-Heat-Recovery-Market-to-Reach-129-6-Billion-Globally-by-2033-at-6-8-CAGR-Allied-Market-Research.html [Accessed 14 March 2025].

Talebjedi B., Khosravi A. and El Haj Assad M. (2023). Thermoelectric generators (TEGs). In: The Fundamentals of Thermal Analysis. New York: Nova Science Publishers, pp. 63–88.

Nourdanesh N. and Kantzas A. (2023). Using thermoelectric generators (TEGs) for electric power generation from waste heat in geothermal plants. In: Proceedings of the SPE Canadian Energy Technology Conference and Exhibition, 23 March, Calgary, Alberta, Canada. Richardson, TX: Society of Petroleum Engineers. Paper No. SPE-212748-MS. Available at: https://doi.org/10.2118/212748-MS.

Liu Y., Riba J-R., Moreno-Eguilaz M. and Sanllehí J. (2023). Application of thermoelectric generators for low-temperature-gradient energy harvesting. Applied Sciences, 13(4), 2603. Available at: https://doi.org/10.3390/app13042603

Jaldurgam F. F. and Ahmad Z. (2022). A systematic review of structures and geometries of thermoelectric generators. Applied Research, 2(2), pp. 1–15. Available at: https://doi.org/10.1002/appl.202200074.

Coherent Market Insights (2025). Thermoelectric generator market size and share analysis—growth trends and forecasts (2025 to 2032). Coherent Market Insights. Available at: https://www.coherentmarketinsights.com/industry-reports/thermoelectric-generator-market [Accessed 14 March 2025].

Iversen B. B. (2021). Breaking thermoelectric performance limits. Nature Materials, 20(10), pp. 1309–1310. Available at: https://doi.org/10.1038/s41563-021-01065-5.

Bos J. W. (2012). Thermoelectric materials: efficiencies found in nanocomposites. RSC Education, 1 March. Available at: https://edu.rsc.org/feature/thermoelectric-materials-efficiencies-found-in-nanocomposites/2020263.article [Accessed 11 June 2025].

Kumari N., Singh A. and Dasgupta T. (2025). Thermoelectric generator performance evaluation of Mg?Sb?.?Bi?.? for low-grade heat recovery. ACS Applied Energy Materials, 8(3), pp. 2741–2751. Available at: https://doi.org/10.1021/acsaem.4c02609.

Chen C.-Y., Du K.-W., Chung Y.-C. and Wu C.-I. (2024). Advancements in thermoelectric generator design: exploring heat exchanger efficiency and material properties. Energies, 17(2), 453. Available at: https://doi.org/10.3390/en17020453.

Singh B. S. B. (2023). Thermoelectric generators: design, operation, and applications. In: New Materials and Devices for Thermoelectric Power Generation. IntechOpen. Available at: https://doi.org/10.5772/intechopen.1002722.

Hi-Z Technology (2025). HZ-14HV thermoelectric module. Hi-Z Technology. Available at: https://hi-z.com/product/hz-14hv-thermoelectric-module/ [Accessed 14 March 2025].

Agoundedemba M., Kim C. K. and Kim H.-G. (2023). Energy status in Africa: challenges, progress and sustainable pathways. Energies, 16(23), 7708. Available at: https://doi.org/10.3390/en16237708.

Zoui M. A., Bentouba S., Stocholm J. G. and Bourouis M. (2020). A review on thermoelectric generators: progress and applications. Energies, 13(14), 3606. Available at: https://doi.org/10.3390/en13143606.

BioLite (2025). CampStove 2+. BioLite. Available at: https://www.bioliteenergy.com/products/campstove-2-plus [Accessed 14 March 2025].

Attar A., Yazdani S. and Shabgard M. (2017). Efficiency calculation of a thermoelectric generator for investigating the applicability of various thermoelectric materials. ResearchGate. Available at: https://www.researchgate.net/publication/314139770_Efficiency_calculation_of_a_thermoelectric_generator_for_investigating_the_applicability_of_various_thermoelectric_materials [Accessed 12 June 2025].

Cover Image
Downloads
Published
2026-03-13
Issue
Vol. 20 No. Special (2026): FUTA JEET: Special Issue on Innovative Solutions for Sustainable Living and Environmental Challenges: Engineering Perspectives
Section
Articles
License

Copyright (c) 2026 FUTA JOURNAL OF ENGINEERING AND ENGINEERING TECHNOLOGY

Creative Commons License

This work is licensed under a Creative Commons Attribution-NonCommercial-NoDerivatives 4.0 International License.

Copyright

With the submission of a manuscript, the corresponding author confirms that the manuscript is not under consideration by another journal. With the acceptance of a manuscript, the Journal reserves the exclusive right of publication and dissemination of the information contained in the article. The veracity of the paper and all the claims therein is solely the opinion of the authors not the journal.

How to Cite

EXPERIMENTAL STUDY ON THE SYNERGISTIC EFFECTS OF COOLING METHODS AND HEAT SINK DESIGN ON THERMOELECTRIC GENERATOR PERFORMANCE. (2026). FUTA JOURNAL OF ENGINEERING AND ENGINEERING TECHNOLOGY, 20(Special), 70-83. https://doi.org/10.51459/futajeet.2026.20.Special.534

Similar Articles

11-20 of 57

You may also start an advanced similarity search for this article.