Modeling, Simulation and Control Strategy Optimization of Fuel Cell Hybrid Electric Vehicle

Usmanov, Umidjon; Ruzimov, Sanjarbek; Tonoli, Andrea; Mukhitdinov, Akmal

doi:10.3390/vehicles5020026

Cited by 8 publications

(4 citation statements)

References 32 publications

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“…In order to ensure that roads meet the requirements of modern and future road traffic, it will be necessary to further increase capital investments, including investments. Rational, scientifically substantiated spending of these investments is an important national economic task [15,[16][17][18][19][20][21][22][23][24][25][26].…”

Section: Methodsmentioning

confidence: 99%

Specific features of improving automobile road complex of the Republic of Uzbekistan

Khalmukhamedov,

Anvarjonov

2024

E3S Web Conf.

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Automobile and Road Complex (ARC) is a complex technical and economic system, including means of transport (automobile transport) and communications (automobile roads), united by a single goal - to provide constant safe transport of goods and people with maximum efficiency. The term “ARC” [1, 2] more objectively reflects the essence of the efficient transport process carried out by vehicles on roads. It emphasises the equivalence of the contribution of vehicles and roads to a single transport process. The problem of the efficiency of the ARC function is not only of terminological significance, but also touches on the issues of improving the efficiency of the road and motorway economy as a whole.

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Section: Methodsmentioning

confidence: 99%

Specific features of improving automobile road complex of the Republic of Uzbekistan

Khalmukhamedov,

Anvarjonov

2024

E3S Web Conf.

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“…where ρ1 and ρ2 are the density of the oil product at temperatures T1 and T2 The accuracy of determining β depends on the selected temperature range and the error in determining ρ1 and ρ2, which should be quite high, on the order of ±0.05-0.1% [5]. To process experimental data on the thermal conductivity of gas condensates using the method under consideration, experimental data on the density of gas condensates in Central Asia [8][9][10][11][12][13][14][15][16][17][18][19][20][21][22][23][24][25][26], which were measured according to the author's estimate with a maximum error of ±0.1%, were used. The proposed empirical equations for calculating λ of heavy petroleum products, obtained on the basis of the correlation between thermal conductivity and complexes and in the temperature range −20...150°С, give an error of no more than 8%.…”

Section: Recommended Methods For Calculating the Thermal Conductivity...mentioning

confidence: 99%

Development of methods for calculating thermal conductivity of gas condensates-alternative motor fuels

Makhmudov

2024

E3S Web Conf.

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The article is devoted to the development of methods for calculating the thermal conductivity of complex hydrocarbon mixtures such as gas condensates, which are widely used as components for motor and jet fuels. The work was carried out on the basis of the results of experimental studies of thermal conductivity of the eight most representative deposits in Central Asia in terms of group hydrocarbon composition. An analysis of existing equations for calculating the thermal conductivity of liquid petroleum products and the possibility of their use for gas condensates was carried out. A number of new equations are presented for calculating the thermal conductivity of gas condensates depending on the group hydrocarbon composition in a wide range of temperatures and pressures.

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“…A clear example of these restrictions is the European Union (EU), which aims to achieve zero GHG emissions by 2050 through the Green Deal program with an emphasis on transportation [1,2]. Among the alternatives, synthetic liquid fuels and electric vehicles are recognized [3], and more recently, H2 propulsion has stood out [4], either through fuel cells for electric power generation or through direct hydrogen combustion. For this reason, it is crucial to conduct studies comparing different propulsion systems for various types of vehicles and their respective uses.…”

Section: Introductionmentioning

confidence: 99%

Mild Hybrid Powertrain for Mitigating Loss of Volumetric Efficiency and Improving Fuel Economy of Gasoline Vehicles Converted to Hydrogen Fueling

Bibiloni,

Irimescu,

Martinez-Boggio

et al. 2024

Machines

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The pursuit of sustainable and environmentally friendly transportation has led to the exploration of alternative fuel sources, among which hydrogen stands out prominently. This work delves into the potential of hydrogen fuel for internal combustion engines (ICEs), emphasizing its capacity to ensure the required performance levels while concurrently enhancing overall efficiency. The integration of a mild hybrid powertrain in a small size passenger car was considered for obtaining a twofold advantage: mitigating power loss due to low volumetric efficiency and increasing fuel economy. A comprehensive approach combining 0D/1D modeling simulations and experimental validations was employed on a gasoline-powered small size ICE, considering its conversion to hydrogen, and mild hybridization. Vehicle simulations were performed in AVL Cruise M and validated against experimental data. Various electric motors were scrutinized for a small size battery pack typical of mild hybrid vehicles. Furthermore, the paper assesses the potential range achievable with the hydrogen-powered hybrid vehicle and compares it with the range reported by the manufacturer for the original gasoline and pure electric version. In terms of global results, these modifications were found to successfully improve efficiency compared to baseline gasoline and hydrogen fueling. Additionally, performance gains were achieved, surpassing the capabilities of the original gasoline vehicle despite its intrinsic volumetric efficiency limitations when using hydrogen. Along with the conversion to hydrogen and thus zero-carbon tail-pipe emissions, incorporating a Start/Stop system, and the integration of mild hybrid technology with energy recuperation during braking, overall efficiency was enhanced by up to 30% during urban use. Furthermore, the hybridization implemented in the H2 version allows an autonomy comparable to that of the electric vehicle but with evident shorter refilling times. Specific aspects of the 48 V battery management are also scrutinized.

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Modeling, Simulation and Control Strategy Optimization of Fuel Cell Hybrid Electric Vehicle

Cited by 8 publications

References 32 publications

Specific features of improving automobile road complex of the Republic of Uzbekistan

Specific features of improving automobile road complex of the Republic of Uzbekistan

Development of methods for calculating thermal conductivity of gas condensates-alternative motor fuels

Mild Hybrid Powertrain for Mitigating Loss of Volumetric Efficiency and Improving Fuel Economy of Gasoline Vehicles Converted to Hydrogen Fueling

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