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Modeling of a hybrid electric heavy duty vehicle to assess energy recovery using a thermoelectric generator

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  • Muralidhar, Nischal
  • Himabindu, M.
  • Ravikrishna, R.V.

Abstract

Conventional internal combustion engines exhibit efficiency in the range of 30%–40%. A significant portion of the remaining energy is dissipated as exhaust heat, some of which can be recovered using thermoelectric generators to reduce fuel consumption and CO2 emissions. The current study evaluates the benefits of using thermoelectric electric generators in hybrid electric vehicles over a prescribed drive-cycle. Specifically, a hybrid electric bus was first modeled over a realistic urban drive-cycle. Engine operating parameters such as torque and speed were extracted and provided as inputs to an engine simulation model. A virtual thermoelectric generator was then modeled using the Matlab/Simulink architecture to evaluate the quantity of energy that can be recovered based on inputs from the engine simulation model. Simulations were carried out to accurately assess the amount of fuel savings achieved due to the use of the thermoelectric generators system. From the analysis, it was observed that a fuel saving of 7.2% and 6.5% can be achieved with the use of Skutterudite and Silicon Germanium-based thermoelectric generator systems, respectively. It was also observed that the additional weight of the thermoelectric generator system had a negligible effect on the fuel consumption.

Suggested Citation

  • Muralidhar, Nischal & Himabindu, M. & Ravikrishna, R.V., 2018. "Modeling of a hybrid electric heavy duty vehicle to assess energy recovery using a thermoelectric generator," Energy, Elsevier, vol. 148(C), pages 1046-1059.
  • Handle: RePEc:eee:energy:v:148:y:2018:i:c:p:1046-1059
    DOI: 10.1016/j.energy.2018.02.023
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    References listed on IDEAS

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    5. Massaguer, E. & Massaguer, A. & Pujol, T. & Comamala, M. & Montoro, L. & Gonzalez, J.R., 2019. "Fuel economy analysis under a WLTP cycle on a mid-size vehicle equipped with a thermoelectric energy recovery system," Energy, Elsevier, vol. 179(C), pages 306-314.
    6. Garud, Kunal Sandip & Seo, Jae-Hyeong & Bang, You-Ma & Pyo, Young-Dug & Cho, Chong-Pyo & Lee, Moo-Yeon & Lee, Dong-Yeon, 2022. "Energy, exergy, environmental sustainability and economic analyses for automotive thermoelectric generator system with various configurations," Energy, Elsevier, vol. 244(PA).
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    8. He, Min & Wang, Enhua & Zhang, Yuanyin & Zhang, Wen & Zhang, Fujun & Zhao, Changlu, 2020. "Performance analysis of a multilayer thermoelectric generator for exhaust heat recovery of a heavy-duty diesel engine," Applied Energy, Elsevier, vol. 274(C).
    9. Negash, Assmelash A. & Choi, Young & Kim, Tae Young, 2021. "Experimental investigation of optimal location of flow straightener from the aspects of power output and pressure drop characteristics of a thermoelectric generator," Energy, Elsevier, vol. 219(C).
    10. Lan, Song & Stobart, Richard & Wang, Xiaonan, 2022. "Matching and optimization for a thermoelectric generator applied in an extended-range electric vehicle for waste heat recovery," Applied Energy, Elsevier, vol. 313(C).
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