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The Multi-Objective Optimization of Powertrain Design and Energy Management Strategy for Fuel Cell–Battery Electric Vehicle

Jiaming Zhou / Chunxiao Feng / Qingqing Su / Shangfeng Jiang / Zhixian Fan / Jiageng Ruan / Shikai Sun / Leli Hu

Considering the limited driving range and inconvenient energy replenishment way of battery electric vehicle, fuel cell electric vehicles (FC EVs) are taken as a promising way to meet the requirements for long-distance low-carbon driving. However, due to the limitation of FC power ability, a battery is usually adopted as the supplement power source to fill the gap between the requirement of driving and the serviceability of FC. In consequence, energy management is essential and crucial to an efficient power flow to the wheel. In this paper, a self-optimizing power matching strategy is proposed, considering the energy efficiency and battery degradation, via implementing a deep deterministic policy gradient. Based on the proposed strategy, less energy consumption and longer FC and battery life can be expected in FC EV powertrain with optimal hybridization degree.

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The Multi-Objective Optimization of Powertrain Design and Energy Management Strategy for Fuel Cell–Battery Electric Vehicle

Jiaming Zhou / Chunxiao Feng / Qingqing Su / Shangfeng Jiang / Zhixian Fan / Jiageng Ruan / Shikai Sun / Leli Hu

Considering the limited driving range and inconvenient energy replenishment way of battery electric vehicle, fuel cell electric vehicles (FC EVs) are taken as a promising way to meet the requirements for long-distance low-carbon driving. However, due to the limitation of FC power ability, a battery is usually adopted as the supplement power source to fill the gap between the requirement of driving and the serviceability of FC. In consequence, energy management is essential and crucial to an efficient power flow to the wheel. In this paper, a self-optimizing power matching strategy is proposed, considering the energy efficiency and battery degradation, via implementing a deep deterministic policy gradient. Based on the proposed strategy, less energy consumption and longer FC and battery life can be expected in FC EV powertrain with optimal hybridization degree.

The Multi-Objective Optimization of Powertrain Design and Energy Management Strategy for Fuel Cell–Battery Electric Vehicle

Jiaming Zhou / Chunxiao Feng / Qingqing Su / Shangfeng Jiang / Zhixian Fan / Jiageng Ruan / Shikai Sun / Leli Hu

Considering the limited driving range and inconvenient energy replenishment way of battery electric vehicle, fuel cell electric vehicles (FC EVs) are taken as a promising way to meet the requirements for long-distance low-carbon driving. However, due to the limitation of FC power ability, a battery is usually adopted as the supplement power source to fill the gap between the requirement of driving and the serviceability of FC. In consequence, energy management is essential and crucial to an efficient power flow to the wheel. In this paper, a self-optimizing power matching strategy is proposed, considering the energy efficiency and battery degradation, via implementing a deep deterministic policy gradient. Based on the proposed strategy, less energy consumption and longer FC and battery life can be expected in FC EV powertrain with optimal hybridization degree.

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Title:

The Multi-Objective Optimization of Powertrain Design and Energy Management Strategy for Fuel Cell–Battery Electric Vehicle

Contributors:

Jiaming Zhou (author) / Chunxiao Feng (author) / Qingqing Su (author) / Shangfeng Jiang (author) / Zhixian Fan (author) / Jiageng Ruan (author) / Shikai Sun (author) / Leli Hu (author)

Published in:

Sustainability, Vol 14, Iss 10, p 6320 (2022)

Publication date:

2022

ISSN:

DOI:

https://doi.org/10.3390/su14106320

Type of media:

Article (Journal)

Type of material:

Electronic Resource

Language:

Unknown

Keywords:

fuel cell , hybrid electric vehicle , EMS , particle swarm optimization (PSO) , machine learning , Environmental effects of industries and plants , TD194-195 , Renewable energy sources , TJ807-830 , Environmental sciences , GE1-350

Metadata by DOAJ is licensed under CC BY-SA 1.0

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