Your search keyword '"Guo, Ziang"' showing total 3 results

1. Optimal energy management strategies for hybrid power systems considering Pt degradation.

Author

Sheng, Chuang, Guo, Ziang, Lei, Jingzhi, Zhang, Shuyu, Zhang, Wenxuan, Chen, Weiming, Jiang, Xuefeng, Wang, Zhuo, and Li, Xi

Subjects

*HYBRID power systems, *PROTON exchange membrane fuel cells, *PONTRYAGIN'S minimum principle, *OPTIMIZATION algorithms, *ENERGY management, *HIGH voltages

Abstract

Proton exchange membrane fuel cells (PEMFCs) will greatly shorten their lifespan due to platinum (Pt) catalyst degradation during operation. This paper proposes an optimization-based energy management method considering Pt degradation, which is an improvement over the traditional strategy that only focuses on fuel optimization to consider both the minimal fuel and the minimum fuel cell life decay. Firstly, a one-dimensional (1D) Pt degradation model is established to comprehend how various voltage situations affect Pt deterioration. Then, various strategies to suppress Pt degradation are designed using Pontryagin's minimum principle (PMP) optimization algorithm in light of the influence analysis results, and the effects of the PMP algorithm under different strategies are tested on the hardware-in-the-loop (HIL) simulation platform. The results demonstrate that the performance of the PMP algorithm in real-time strategy is extremely near to the global optimal solution generated by the offline dynamic programming (DP) algorithm. After adding the tendency to limit high potential and voltage variation in the PMP algorithm, hydrogen consumption increases by only 2%. In comparison, the stack's degradation is decreased by nearly 50%, considerably extending the stack's service life and reducing the system's comprehensive use cost. • Prior literature verified the construction of a one-dimensional Pt degradation model. • Frequent voltage fluctuations and high voltage will exacerbate degradation via model analysis. • Developed two optimization-based strategies for reducing stack performance degradation. [ABSTRACT FROM AUTHOR]

Published

2024

2. Energy management for proton exchange membrane fuel cell-lithium battery hybrid power systems based on real-time prediction and optimization under multimodal information.

Author

Zeng, Linghong, Fu, Jun, Sheng, Chuang, Li, Beijia, Guo, Ziang, Xiang, Qian, Wang, Jingjing, Shan, Xinkai, Fu, Xiaowei, Deng, Zhonghua, Wang, Zhuo, and Li, Xi

Subjects

*HYBRID power systems, *ELECTRIC batteries, *ELECTRIC vehicle batteries, *PROTON exchange membrane fuel cells, *CONVOLUTIONAL neural networks, *ENERGY management, *FUZZY neural networks, *ELECTRIC vehicles

Abstract

As an emerging power source for new energy vehicles, the proton exchange membrane fuel cell-lithium battery hybrid power system still faces challenges such as difficulty in remaining life prediction and unreasonable energy allocation management. This study investigates how electrochemical surface area degradation and carbon corrosion in the catalyst layer affect the proton exchange membrane fuel cell output power. An integrated assessment system combining electrochemical surface area degradation and carbon corrosion, which could effectively evaluate degradation in the proton exchange membrane fuel cell degradation is proposed. To assess the lifespan of proton exchange membrane fuel cells, the electrochemical surface area degradation and carbon corrosion are utilized as key indicators, which in turn lead to the development of a semi-empirical model. To solve the problem of energy allocation management, this paper proposes a predictive-feedback optimization method that combines data-driven and model-driven approaches. The method includes a hybrid prediction model of a long short-term memory-convolutional neural network, an improved rapid optimization strategy of grey wolf optimizer-particle swarm optimization, and an attention-enhanced fuzzy neural network controller. The inference capability of the convolutional neural network is utilized to correct the larger prediction error of long short-term memory during short-term drastic changes, realizing the maximization of energy utilization efficiency, minimal hydrogen consumption, minimization of operation cost, and optimization objectives for information containing a wide time horizon. Tests of experiments show that the implementation of this control scheme effectively postponed the deterioration of the proton exchange membrane fuel cell-lithium battery hybrid power system, resulting in an extended lifespan. [Display omitted] • Integrating ECSA and carbon corrosion data for a holistic system understanding. • Pioneering a PEMFC model, merging ECSA degradation and carbon corrosion. • Introducing predictive optimization for broad-time performance maximization. [ABSTRACT FROM AUTHOR]

Published

2024

3. Energy management strategy based on health state for a PEMFC/Lithium-ion batteries hybrid power system.

Author

Sheng, Chuang, Fu, Jun, Li, Dong, Jiang, Chang, Guo, Ziang, Li, Beijia, Lei, Jingzhi, Zeng, Linghong, Deng, Zhonghua, Fu, Xiaowei, and Li, Xi

Subjects

*ENERGY management, *HYBRID power systems, *LITHIUM-ion batteries, *BATTERY storage plants

Published

2022