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Heat and Moisture Relevant In Situ Measurements in a Railway Passenger Vehicle Driving through the Swiss Alpine Region

Author

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  • Wolfgang Raedle

    (Institute for Timber Construction, Structures and Architecture, Bern University of Applied Sciences (BFH), Solothurnstrasse 102, 6, CH-2500 Biel, Switzerland)

  • K. Ghazi Wakili

    (Institute for Timber Construction, Structures and Architecture, Bern University of Applied Sciences (BFH), Solothurnstrasse 102, 6, CH-2500 Biel, Switzerland)

  • Christoph Geyer

    (Institute for Timber Construction, Structures and Architecture, Bern University of Applied Sciences (BFH), Solothurnstrasse 102, 6, CH-2500 Biel, Switzerland)

  • Roman Hausammann

    (Institute for Timber Construction, Structures and Architecture, Bern University of Applied Sciences (BFH), Solothurnstrasse 102, 6, CH-2500 Biel, Switzerland)

  • Urs Uehlinger

    (Institute for Timber Construction, Structures and Architecture, Bern University of Applied Sciences (BFH), Solothurnstrasse 102, 6, CH-2500 Biel, Switzerland)

Abstract

Transportation is a major sector of energy consumption in most, if not in all, European countries. Besides the energy used for traction, energy is also consumed for ventilation, heating, and cooling inside the vehicles to assure traveler comfort. This issue gains increasing importance as the demand for public transport increases in the future. There is a need for retrofit to improve the thermal resistance of the envelope of existing vehicles to reduce the heat loss to the environment during the cold period of the year, especially in the Alpine region. A major concern in adding insulation material to the envelope is the possibility of convective moisture transfer due to air circulation in the vehicle, which would cause condensation accumulation on the cold surfaces. The present investigation addresses this topic by measuring surface and air temperature, air moisture, air flow, and heat flow at several critical locations of a vehicle during its travel in the Swiss Alpine region over several months during the cold period of the year. Temperature measurements showed the potential of reducing the heat losses in some parts of the vehicle. The level and duration of the moisture exposure did not suggest a relevant formation of condensation in the cross-section of the vehicle wall. The observed increase in relative humidity when driving through tunnels is too short to cause relevant condensation in the vehicle shell. The measured low air flow justifies the assumption that no forced convection occurs in the envelope cavities.

Suggested Citation

  • Wolfgang Raedle & K. Ghazi Wakili & Christoph Geyer & Roman Hausammann & Urs Uehlinger, 2022. "Heat and Moisture Relevant In Situ Measurements in a Railway Passenger Vehicle Driving through the Swiss Alpine Region," Sustainability, MDPI, vol. 14(12), pages 1-20, June.
    • Handle: RePEc:gam:jsusta:v:14:y:2022:i:12:p:7462-:d:842145
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    References listed on IDEAS

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    1. Barone, Giovanni & Buonomano, Annamaria & Forzano, Cesare & Palombo, Adolfo, 2020. "Enhancing trains envelope – heating, ventilation, and air conditioning systems: A new dynamic simulation approach for energy, economic, environmental impact and thermal comfort analyses," Energy, Elsevier, vol. 204(C).
    2. Chang, Yuan & Lei, Shuhua & Teng, Jianjian & Zhang, Jiangxue & Zhang, Lixiao & Xu, Xiao, 2019. "The energy use and environmental emissions of high-speed rail transportation in China: A bottom-up modeling," Energy, Elsevier, vol. 182(C), pages 1193-1201.
    3. Chow, W. K., 2002. "Ventilation of enclosed train compartments in Hong Kong," Applied Energy, Elsevier, vol. 71(3), pages 161-170, March.
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