Realistic simulation of fuel economy and life cycle metrics for hydrogen fuel cell vehicles

Ahmadi, Pouria; Kjeang, Erik

doi:10.1002/er.3672

Cited by 91 publications

(36 citation statements)

References 35 publications

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“…The TDP results obtained for combined driving cycles are compared with ordinal optimization (OO) results and with Hyundai Tucson fuel cell results . Hyundai Tucson is a realistic fuel cell car that is currently available in the market.…”

Section: Resultsmentioning

confidence: 99%

Power sources sizing for a fuel cell hybrid vehicle

2020

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Fuel cell hybrid vehicles (FCHV) are attractive alternatives to fossil fuel based ones in terms of lowering levels of polluting emissions. This paper presents a methodology for modeling, sizing, and power management of FCHV. The aim of the study is to achieve the lowest cost of driving over different driving cycles taking into consideration the vehicle specifications and minimum drivability constraints. The tunnel dynamic programming (TDP) is used to find the optimal power split between the battery and the fuel cell to meet the power demand for driving. On the other hand, since cost is a major barrier hindering the commercialization of FCHV, Pareto front is used to determine the best combination of sizes to achieve the lowest operational cost. The analysis covers different driving cycles including a combination of the highway and urban driving cycles mimicking a realistic one. The focus on lithium titanate battery and the combination of TDP‐Pareto front are the significant contributions of this paper. Comparative results against a commercial hybrid vehicle showed that the proposed model found a more efficient design in terms of hydrogen consumption and more capable in meeting aggressive drivability constraints as the electric motor size selected is greater.

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Section: Resultsmentioning

confidence: 99%

Power sources sizing for a fuel cell hybrid vehicle

2020

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“…Due to the various ways of producing, storing, and transporting hydrogen, there is a large difference in the hydrogen life cycle cost . Ahmadi and Kjeang divided the life cycle of a passenger vehicle into a fuel cycle and a vehicle cycle.…”

Section: Literature Reviewmentioning

confidence: 99%

“…Based on the users' selection probability, the hydrogen refueling volumes at the demand points are allocated to the refueling stations, and the capacities of the stations are determined accordingly. Considering that different types of vehicles (e.g., cars and busses) obviously vary in the volumes of hydrogen they demand, this paper establishes Equation 13 to estimate the capacities of the stations.…”

Section: Hydrogen Station Capacity Designmentioning

confidence: 99%

Optimal siting and sizing of hydrogen refueling stations considering distributed hydrogen production and cost reduction for regional consumers

Sun

et al. 2019

Int J Energy Res

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Summary Hydrogen fuel cell vehicles are currently facing two difficulties in achieving their general use: the lack of hydrogen refueling stations and high hydrogen prices. Hydrogen refueling stations are the middle stage for delivering hydrogen from its sources to consumers, and their location could be affected by the distributed locations of hydrogen sources and consumers. The reasonable siting and sizing of hydrogen refueling stations could both improve the hydrogen infrastructure and reduce regional consumers' cost of using hydrogen. By considering the hydrogen life cycle cost and using a commercial volume forecasting model, this paper creates a relatively thorough and comprehensive model for hydrogen station siting and sizing with the objective of achieving the optimal costs for consumers using hydrogen. The cost‐based model includes the selection of the hydrogen sources, transportation methods, and storage methods, and thus, the hydrogen supply chain can also be optimized. A numerical example is established in Section 4 with the solution algorithm and results.

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“…With respect to E OCV mix , there is no existing mathematical model to describe the voltage drop because of the PtO percentage increase. In the study, it is assumed as a piecewise function in Equation 3. ECSA 0 is a boundary value that mixed potential has a significant effect; S sum is the total ECSA without PtO.…”

Section: Semiempirical Ocv Modelmentioning

confidence: 99%

“…An increase in awareness with respect to environmental pollution and the growing energy crisis have spurred interest in developing new energy technologies. 1 A fuel cell vehicle with its high efficiency, 2 low environment impact, 3 and relatively long service life 4 is recognized by several governments and research institutions as a potential solution. 5 The most basic research on the fuel cell corresponds to voltage modeling.…”

Section: Introductionmentioning

confidence: 99%

A semiempirical dynamic model of reversible open circuit voltage drop in a PEM fuel cell

Song

et al. 2018

Int J Energy Res

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Summary Fuel cell voltage modeling is important for fundamental research. The main focus of previous studies has been the working voltage segment, whereas the accuracy of the open circuit voltage (OCV), especially the dynamic OCV change process, has been ignored. A semiempirical model including the OCV and an electrochemical model has been proposed in this study to clarify the reversible voltage drop process. A mixed cathode potential drop that is assumed as corresponding to a piecewise function relationship with an active surface area is introduced in this study. Fitting results exactly coincide with the original data in 2 modes, namely a quasistatic condition in a bench test and a dynamic condition in a fuel cell city bus. In the dynamic OCV drop process, the voltage drop due to the hydrogen crossover current approximately corresponds to 0.003 V and the mixed cathode potential drop approximately corresponds to 0.02 V.

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Realistic simulation of fuel economy and life cycle metrics for hydrogen fuel cell vehicles

Cited by 91 publications

References 35 publications

Power sources sizing for a fuel cell hybrid vehicle

Power sources sizing for a fuel cell hybrid vehicle

Optimal siting and sizing of hydrogen refueling stations considering distributed hydrogen production and cost reduction for regional consumers

A semiempirical dynamic model of reversible open circuit voltage drop in a PEM fuel cell

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