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Combustion Engines

Tytuł artykułu

The potential of thermoelectric energy harvesting in vehicles equipped with ICE

Autorzy Buchalik, Ryszard  Rogozinski, Krzysztof  Nowak, Grzegorz 
Treść / Zawartość
Warianty tytułu
Języki publikacji EN
EN The paper deals with an issue of waste heat recovery in a selected configuration of an internal combustion engine. A possibility of using thermoelectric cells (currently available on the market) for production of electricity with heat extracted from the exhaust gas was considered. The calculations were made using specialized software. Features and design assumptions of the heat recovery system were presented and their influence on parameters of the entire system was investigated (efficiency of the internal combustion engine, power, etc.). An assessment of the applicability of the energy recovery system based on thermoelectric effects and characteristic of the proposed configuration was performed. Some issues that require further research have been highlighted.
Słowa kluczowe
PL silnik spalinowy   odzysk ciepła   moduł termoelektryczny   wymiana ciepła   układ wydechowy  
EN combustion engine   heat recovery   thermoelectric module   heat transfer   exhaust system  
Wydawca Polskie Towarzystwo Naukowe Silników Spalinowych
Czasopismo Combustion Engines
Rocznik 2019
Tom R. 58, nr 4
Strony 70--74
Opis fizyczny Bibliogr. 14 poz., il. kolor., wykr.
autor Buchalik, Ryszard
autor Rogozinski, Krzysztof
autor Nowak, Grzegorz
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[2] HENDRICKS, T. J. Thermal system interactions in optimizing advanced thermoelectric energy recovery systems. Journal of Energy Resources Technology. 2007, 129. DOI: 10.1115/1.2751504
[3] IZIDORO, C.L., ANDO JUNIOR, O. H., CARMO, J.P., SCHAEFFER, L. Characterization of thermoelectric genera-tor for energy harvesting. Measurement. 2017, 106, 283-290. DOI: 10.1016/j.measurement.2016.01.010
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[5] KUMAR, S., HEISTER, S.D., XU, X. et al. Thermoelectric generators for automotive waste heat recovery systems part i: numerical modeling and baseline model analysis. Journal of Electronic Materials. 2013, 42(4), 665-674.
[6] LIENHARD, J.H.IV., LIENHARD, J.H.V., A Heat Transfer Textbook. Phlogiston Press. Cambridge Massachusetts, 2017.
[7] LIU, X., DENG, Y.D., LI, Z., SU, C.Q. Performance analysis of a waste heat recovery thermoelectric generation sys-
tem for automotive application. Energy Conversion and Management. 2015, 90, 121-127.
[8] LIU, X., DENG, Y.D., ZHANG, K. et al. Experiments and simulations on heat exchangers in thermoelectric generator for automotive application. Applied Thermal Engineering. 2014, 71, 364-370.
[9] NOLAS, G.S., SHARP, J., GOLDSMID, H.J. Thermoelectrics; Basic Principles and New Materials. Springer-Verlag. Berlin-Heidelberg-New York 2001.
[10] RYCHTER, T., TEODORCZYK, A. Teoria silników tłokowych. WKL. Warszawa 2006.
[11] SCHOCK, H. et al. Prospects for implementation of thermo-electric generators as waste heat recovery systems in class 8 truck applications. Journal of Energy Resources Technology. 2013, 135. DOI: 10.1115/1.4023097
[12] Tecteg TEG1-PB12690 Thermoelectric module datasheet:
[13] WENDLAND, D. Automobile exhaust-system steady-state heat transfer. SAE 1993 Transactions: Journal of Materials & Manufacturing-V102-5.
[14] ZHU, G., LIU, J., FU, J., WANG, S.A. Combined organic Rankine cycle with double modes used for internal combustion engine waste heat recovery. Journal of Engineering for Gas Turbines and Power. 2017, 139. DOI: 10.1115/ 1.4036955
Kolekcja BazTech
Identyfikator YADDA bwmeta1.element.baztech-ef1ec3a4-434c-4429-b922-0d4e96b0896f
DOI 10.19206/CE-2019-411