Abstract
Emissions from heavy-duty vehicles need to be reduced to decrease their impact on the climate and to meet future regulatory requirements. The use of a cost-optimized thermoelectric generator based on total cost of ownership is proposed for this vehicle class with natural gas engines. A holistic model environment is presented that includes all vehicle interactions. Simultaneous optimization of the heat exchanger and thermoelectric modules is required to enable high system efficiency. A generator design combining high electrical power (peak power of about 3000 W) with low negative effects was selected as a result. Numerical CFD and segmented high-temperature thermoelectric modules are used. For the first time, the possibility of an economical use of the system in the amortization period of significantly less than 2 years is available, with a fuel reduction in a conventional vehicle topology of already up to 2.8%. A significant improvement in technology maturity was achieved, and the power density of the system was significantly improved to 298 W/kg and 568 W/dm3 compared to the state of the art. A functional model successfully validated the simulation results with an average deviation of less than 6%. An electrical output power of up to 2700 W was measured.
Highlights
Emissions from heavy-duty vehicles (HDV) must be reduced to meet future regulatory requirements and mitigate climate change [1]
As HDV will continue to run on internal combustion engines due to a lack of technical and economic alternatives, a waste heat recovery system (WHRS) offers future potential for reducing fuel consumption and emissions
Natural gas (NG) HDV offer a promising alternative to the predominant diesel units for long-distance transport [2]
Summary
Emissions from heavy-duty vehicles (HDV) must be reduced to meet future regulatory requirements and mitigate climate change [1]. As HDV will continue to run on internal combustion engines due to a lack of technical and economic alternatives, a waste heat recovery system (WHRS) offers future potential for reducing fuel consumption and emissions. In this context, natural gas (NG) HDV offer a promising alternative to the predominant diesel units for long-distance transport [2]. Natural gas (NG) HDV offer a promising alternative to the predominant diesel units for long-distance transport [2] They are economically viable and have a lower environmental impact than diesel HDV. NG engines with stoichiometric combustion process compared to diesel engines offer greater potential for WHRS due to the higher exhaust enthalpy
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