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Assessment of an Exhaust Thermoelectric Generator Incorporating Thermal Control Applied to a Heavy Duty Vehicle

Author

Listed:
  • Carolina Clasen Sousa

    (MEtRICs, Mechanical Engineering Department, Campus of Azurem, University of Minho, 4800-058 Guimaraes, Portugal)

  • Jorge Martins

    (MEtRICs, Mechanical Engineering Department, Campus of Azurem, University of Minho, 4800-058 Guimaraes, Portugal)

  • Óscar Carvalho

    (CMEMS, Mechanical Engineering Department, Campus of Azurem, University of Minho, 4800-058 Guimaraes, Portugal)

  • Miguel Coelho

    (CMEMS, Mechanical Engineering Department, Campus of Azurem, University of Minho, 4800-058 Guimaraes, Portugal)

  • Ana Sofia Moita

    (Instituto Universitário Militar—CINAMIL, Academia Militar, IN+ University of Lisbon, 1649-004 Lisboa, Portugal)

  • Francisco P. Brito

    (MEtRICs, Mechanical Engineering Department, Campus of Azurem, University of Minho, 4800-058 Guimaraes, Portugal
    TEMA, Mechanical Engineering Department, Campus of Santiago, University of Aveiro, 3810-193 Aveiro, Portugal)

Abstract

The road transport industry faces the need to develop its fleet for lower energy consumption, pollutants and CO 2 emissions. Waste heat recovery systems with Thermoelectric Generators (TEGs) can directly convert the exhaust heat into electric energy, aiding the electrical needs of the vehicle, thus reducing its dependency on fuel energy. The present work assesses the optimisation and evaluation of a temperature-controlled thermoelectric generator (TCTG) concept to be used in a commercial heavy-duty vehicle (HDV). The system consists of a heat exchanger with wavy fins (WFs) embedded in an aluminium matrix along with vapour chambers (VCs), machined directly into the matrix, that grant the thermal control based on the spreading of local excess heat by phase change, as proposed by the authors in previous publications and patents. The TCTG concept behaviour was analysed under realistic driving conditions. An HDV with a 16 L Diesel engine was simulated in AVL Cruise to obtain the exhaust gas temperature and mass flow rate for each point of two cycle runs. A model proposed in previous publications was adapted to the new fin geometry and vapour chamber configuration and used the AVL Cruise data as input. It was possible to predict the thermal and thermoelectric performance of the TCTG along the corresponding driving cycles. The developed system proved to have a good capacity for applications with highly variable thermal loads since it was able to uncouple the maximisation of heat absorption from the regulation of the thermal level at the hot face of the TEG modules, avoiding both thermal dilution and overheating. This was achieved by the controlled phase change temperature of the heat spreader, that would ensure the spreading of the excess heat from overheated to underheated areas of the generator instead of wasting excess heat. A maximum average electrical production of 2.4 kW was predicted, which resulted in fuel savings of about 2% and CO 2 emissions reduction of around 37 g/km.

Suggested Citation

  • Carolina Clasen Sousa & Jorge Martins & Óscar Carvalho & Miguel Coelho & Ana Sofia Moita & Francisco P. Brito, 2022. "Assessment of an Exhaust Thermoelectric Generator Incorporating Thermal Control Applied to a Heavy Duty Vehicle," Energies, MDPI, vol. 15(13), pages 1-19, June.
    • Handle: RePEc:gam:jeners:v:15:y:2022:i:13:p:4787-:d:851825
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    References listed on IDEAS

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    1. F. P. Brito & João Silva Peixoto & Jorge Martins & António P. Gonçalves & Loucas Louca & Nikolaos Vlachos & Theodora Kyratsi, 2021. "Analysis and Design of a Silicide-Tetrahedrite Thermoelectric Generator Concept Suitable for Large-Scale Industrial Waste Heat Recovery," Energies, MDPI, vol. 14(18), pages 1-21, September.
    2. Georgatzi, Vasiliki V. & Stamboulis, Yeoryios & Vetsikas, Apostolos, 2020. "Examining the determinants of CO2 emissions caused by the transport sector: Empirical evidence from 12 European countries," Economic Analysis and Policy, Elsevier, vol. 65(C), pages 11-20.
    3. Pacheco, N. & Brito, F.P. & Vieira, R. & Martins, J. & Barbosa, H. & Goncalves, L.M., 2020. "Compact automotive thermoelectric generator with embedded heat pipes for thermal control," Energy, Elsevier, vol. 197(C).
    4. Ana Sofia Moita & Pedro Pontes & Lourenço Martins & Miguel Coelho & Oscar Carvalho & F. P. Brito & António Luís N. Moreira, 2022. "Complex Fluid Flow in Microchannels and Heat Pipes with Enhanced Surfaces for Advanced Heat Conversion and Recovery Systems," Energies, MDPI, vol. 15(4), pages 1-20, February.
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    Cited by:

    1. Philippe Poure & Mashiul Huq, 2022. "Thermoelectric Generator for Waste Energy Recovery in Transport," Energies, MDPI, vol. 15(21), pages 1-2, October.
    2. Enas Taha Sayed & Abdul Ghani Olabi & Abdul Hai Alami & Ali Radwan & Ayman Mdallal & Ahmed Rezk & Mohammad Ali Abdelkareem, 2023. "Renewable Energy and Energy Storage Systems," Energies, MDPI, vol. 16(3), pages 1-26, February.
    3. Carvalho, Rui & Martins, Jorge & Pacheco, Nuno & Puga, Hélder & Costa, Joaquim & Vieira, Rui & Goncalves, L.M. & Brito, Francisco P., 2023. "Experimental validation and numerical assessment of a temperature-controlled thermoelectric generator concept aimed at maximizing performance under highly variable thermal load driving cycles," Energy, Elsevier, vol. 280(C).

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