Studing the dynamic properties of thermoelectric coolers of naval military complexes electronic equipment
Article Sidebar
Published:
May 1, 2023
Keywords:
Peltier thermoelement, transfer function, dynamic properties, simulation model.
Main Article Content
Abstract
The paper examines the dynamic properties of thermoelectric Peltier elements as coolers for special electronic equipment of ship systems. Based on the thermal conductivity equation, the transfer function of the Peltier thermoelement as a control object was obtained. Research and verification of the Peltier thermoelement model based on Bi-Te alloys has been carried out.
Article Details
How to Cite
Bukaros, A., Sergeiev, V., Konkov, K., Hordishevskyi, L., & Lebedieva, L. (2023). Studing the dynamic properties of thermoelectric coolers of naval military complexes electronic equipment. Herald of the Odessa National Maritime University, (68), 104-116. https://doi.org/10.47049/2226-1893-2023-1-104-116
Section
Technical problems of ship equipment operation
References
1. Pro rishennia Rady natsionalnoi bezpeky i oborony Ukrainy vid 14 veresnia 2020 roku «Pro Stratehiiu natsionalnoi bezpeky Ukrainy» : Ukaz Prezydenta Ukrainy vid 14.09.2020 r. №392/2020. URL: https://www.president.gov.ua/documents/3922020-35037 (in Ukrainian).
2. Sulaiman, A.C., Amin, N.A.M., Basha, M.H., Majid, M.S.A., bin Mohd Nasir, N.F., & Zaman, I. (2018). Cooling performance of thermoelectric cooling (TEC) and applications: a review. In MATEC Web of Conferences. Vol. 225. P. 03021). EDP Sciences (in English).
3. Iradukunda, A.C., Huitink, D.R., Luo, F. (2019). A review of advanced thermal management solutions and the implications for integration in highvoltage packages. IEEE Journal of Emerging and Selected Topics in Power Electronics, 8(1), 256-271 (in English).
4. Barrubeeah, M., Rady, M., Attar, A., Albatati, F., Abuhabaya, A. (2021). Design, modeling and parametric optimization of thermoelectric cooling systems for high power density electronic devices. International Journal of Low-Carbon Technologies, 16(3), 1060-1076 (in English).
5. Zaykov, V., Mescheryakov, V., Zhuravlov, Y. (2021). Comparative analysis of means to control the thermal regime of a cooling thermoelement while minimizing the set of basic parameters. Eastern-European journal of enterprise technologies. 5/8 (113), 38-50 (in English).
6. Zaykov, V., Mescheryakov, V., Zhuravlov, Y. (2020). Developing a model to control the thermal mode of thermoelectric cooling devices by minimizing the set of three basic parameters. Eastern-European journal of enterprise technologies. 5/8 (107), 63-73 (in English).
7. Thermoelectric-vacuum shipping container: pat. US3823567A USA: F25B21/02. № 348183; fil. 05.04.73; publ. 16.07.74, 6 p.
8. Portable cooler : pat. US11162716B2 USA: F25B21/02. № 17/094098; fil. 10.11.20; publ. 02.11.21, 55 p. (in English).
9. Customized Thermoelectic Cooling Systems Tough Enough for Military Warships. URL: https://www.eicsolutions.com/success-stories/customized-thermoelectic-cooling-systems-tough-enough-military-warships/ (in English).
10. Anatychuk L. I., Semenjuk V. A. (1992) Optimal'noe upravlenie svojstvami termojelektricheskih materialov i priborov. Chernovcy: Prut. 263 p. (in Russian).
11. Kocur M.P., Nakonechnyj A.G. (2015) Optimal'noe upravlenie nestacionarnym rezhimom kaskadnogo termojelektricheskogo ohladitelja. Kibernetika i vychislitel'naja tehnika. №. 180. P. 66-82 (in Russian).
2. Sulaiman, A.C., Amin, N.A.M., Basha, M.H., Majid, M.S.A., bin Mohd Nasir, N.F., & Zaman, I. (2018). Cooling performance of thermoelectric cooling (TEC) and applications: a review. In MATEC Web of Conferences. Vol. 225. P. 03021). EDP Sciences (in English).
3. Iradukunda, A.C., Huitink, D.R., Luo, F. (2019). A review of advanced thermal management solutions and the implications for integration in highvoltage packages. IEEE Journal of Emerging and Selected Topics in Power Electronics, 8(1), 256-271 (in English).
4. Barrubeeah, M., Rady, M., Attar, A., Albatati, F., Abuhabaya, A. (2021). Design, modeling and parametric optimization of thermoelectric cooling systems for high power density electronic devices. International Journal of Low-Carbon Technologies, 16(3), 1060-1076 (in English).
5. Zaykov, V., Mescheryakov, V., Zhuravlov, Y. (2021). Comparative analysis of means to control the thermal regime of a cooling thermoelement while minimizing the set of basic parameters. Eastern-European journal of enterprise technologies. 5/8 (113), 38-50 (in English).
6. Zaykov, V., Mescheryakov, V., Zhuravlov, Y. (2020). Developing a model to control the thermal mode of thermoelectric cooling devices by minimizing the set of three basic parameters. Eastern-European journal of enterprise technologies. 5/8 (107), 63-73 (in English).
7. Thermoelectric-vacuum shipping container: pat. US3823567A USA: F25B21/02. № 348183; fil. 05.04.73; publ. 16.07.74, 6 p.
8. Portable cooler : pat. US11162716B2 USA: F25B21/02. № 17/094098; fil. 10.11.20; publ. 02.11.21, 55 p. (in English).
9. Customized Thermoelectic Cooling Systems Tough Enough for Military Warships. URL: https://www.eicsolutions.com/success-stories/customized-thermoelectic-cooling-systems-tough-enough-military-warships/ (in English).
10. Anatychuk L. I., Semenjuk V. A. (1992) Optimal'noe upravlenie svojstvami termojelektricheskih materialov i priborov. Chernovcy: Prut. 263 p. (in Russian).
11. Kocur M.P., Nakonechnyj A.G. (2015) Optimal'noe upravlenie nestacionarnym rezhimom kaskadnogo termojelektricheskogo ohladitelja. Kibernetika i vychislitel'naja tehnika. №. 180. P. 66-82 (in Russian).