화학공학소재연구정보센터
International Journal of Hydrogen Energy, Vol.39, No.31, 17873-17883, 2014
On the comparison and the complementarity of batteries and fuel cells for electric driving
This paper considers different current and emerging power train technologies (ICE, BEV, HEV, FCEV and PC-RE) and provides a comparison within a techno-economic framework, especially for the architectures of range-extender power trains. The economic benefits in terms of Total Cost of Ownership (TCO) are based on forecasts for the major TCO-influencing parameters up to 2030: electric driving distances, energy (fuel, electricity, hydrogen) prices, batteries and fuel cell costs. The model takes into account functional parameters such as the battery range as well as daily trip segmentation statistics. The TCOs of all the vehicles become similar in 2030, given a 200 km battery range for BEVs. BEVs are profitable for yearly mileages of 30,000 km and over, and for higher battery ranges. The competitiveness of FCEVs is examined through the H2 target price at the pump. There is a very significant effect of the fuel cell cost on the TCO. A FCEV with a fuel cell cost of 40 (sic)/kW will be competitive with a similar ICE car for a 1.75 (sic)/1 fuel cost and ca. 7 (sic)/kg hydrogen cost, This depends too to a great extent on possible ICE cars' CO2 taxes. As regard the FC-RE electric car, the hydrogen target price at the pump is noticeably higher (ca 10 1 Kg). PC-RE cars TCOs are strongly affected by the FC power, the discount rate chosen and the yearly mileage. Moreover, it therefore seems reasonable to confine FC-RE battery ranges in the region of 60 km. Copyright (C) 2014, Hydrogen Energy Publications, LLC. Published by Elsevier Ltd. All rights reserved.