Thermoelectric power sources using low-grade heat

Part 2

Authors

  • L.I. Anatychuk 1. Institute of Thermoelectricity of the NAS and MES of Ukraine, 1 Nauky str., Chernivtsi, 58029, Ukraine. 2. Yuriy Fedkovych Chernivtsi National University 2 Kotsiubynskyi str., Chernivtsi, 58012, Ukraine https://orcid.org/0000-0002-2521-7666
  • A.V. Prybyla 1. Institute of Thermoelectricity of the NAS and MES of Ukraine, 1 Nauky str., Chernivtsi, 58029, Ukraine. 2. Yuriy Fedkovych Chernivtsi National University 2 Kotsiubynskyi str., Chernivtsi, 58012, Ukraine https://orcid.org/0000-0003-4610-2857
  • M.M. Korop Yuriy Fedkovych Chernivtsi National University, 2 Kotsiubynsky str., 58000, Chernivtsi, Ukraine
  • Yu.V. Kiziuk Yuriy Fedkovych Chernivtsi National University, 2 Kotsiubynsky str., 58000, Chernivtsi, Ukraine
  • I.A. Konstantynovych 1. Institute of Thermoelectricity of the NAS and MES of Ukraine, 1 Nauky str., Chernivtsi, 58029, Ukraine. 2. Yuriy Fedkovych Chernivtsi National University 2 Kotsiubynskyi str., Chernivtsi, 58012, Ukraine https://orcid.org/0000-0001-6254-6904

Keywords:

thermoelectric generator, computer-aided design, heat recovery, heat exchange

Abstract

This work is the second part of a series of studies on thermoelectric power sources using low-grade heat. The results of computer-aided  design of a thermoelectric generator with forced convection heat exchange that uses thermal waste from industrial installations are presented. The generator design has been developed and a series of experimental studies have been conducted on a test bench. Bibl. 9, Figs. 5.

References

1. Mukherjee, M., Srivastava, A., & Singh, A. K. (2022). Recent advances in designing thermoelectric materials. Journal of Materials Chemistry C, 10(35), 12524-12555. https://doi.org/10.1039/D2TC02448A

2. Brown, S. R., Kauzlarich, S. M., Gascoin, F., & Snyder, G. J. (2006). Yb₁₄MnSb₁₁: New high efficiency thermoelectric material for power generation. Chemistry of Materials, 18(7), 1873–1877. https://doi.org/10.1021/cm060261t

3. Anatychuk, L. I., & Prybyla, A. V. (2012). On the influence of heat exchange on the efficiency of thermoelectric devices. Journal of Thermoelectricity, (3), 39–45.

4. Anatychuk, L. I., & Prybyla, A. V. (2012). On the influence of heat exchange on the efficiency of thermoelectric generator. Journal of Thermoelectricity, (4), 3–88.

5. Anatychuk, L. I., Kuz, R. V., & Rozver, Y. Y. (2012). Efficiency of thermoelectric recuperators of the exhaust gas energy of internal combustion engines. AIP Conference Proceedings, 1449,

516–519.

6. Anatychuk, L. I., Lysko, V. V., & Prybyla, A. V. (2022). Rational areas of using thermoelectric heat recuperators. Journal of Thermoelectricity, (3-4), 43–67.

7. I.A. Konstantynovych, M.M. Ivanochko, K.O. Kadelnyk, (2024) Design of a portable universal thermoelectric generator. Journal of Thermoelectricity, (1-2), 78–89.

8. Candolfi, C., El Oualid, S., Lenoir, B., & Caillat, T. (2023). Progress and perspectives in thermoelectric generators for waste-heat recovery and space applications. Journal of Applied Physics, 134(10), 100901. https://doi.org/10.1063/5.0166338

9. Anatychuk, L. I., Prybyla, A. V., Korop, M. M., Kiziuk, Yu. I., Konstantynovych I.A. (2024). Thermoelectric power sources using low-grade heat (part 1). Journal of Thermoelectricity, (1-2), 90–96.

How to Cite

Anatychuk, L., Prybyla, A., Korop, M., Kiziuk, Y., & Konstantynovych, I. (2024). Thermoelectric power sources using low-grade heat : Part 2. Journal of Thermoelectricity, (3), 36–43. Retrieved from http://jte.ite.cv.ua/index.php/jt/article/view/164

Issue

No. 3 (2024): Journal of Thermoelectricity

Section

Design

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