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Multi-scale correlation method for proton exchange membrane fuel cell

A proton exchange membrane and fuel cell technology, applied to battery electrodes, circuits, electrical components, etc., can solve the problems of depicting the interrelated characteristics of fuel cells from micro to macro, large amount of calculation, and insufficient computing power

Inactive Publication Date: 2016-04-06
WUHAN UNIV OF TECH
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Problems solved by technology

At present, scholars at home and abroad have applied this method to carry out related research on the diffusion layer, catalytic layer and membrane electrode. However, for such a complex and complete object as the proton exchange membrane fuel cell, the molecular dynamics method requires a huge amount of calculation. difficult to solve
[0005] To sum up, for the multi-scale transport phenomena in proton exchange membrane fuel cells, it is difficult to describe the fuel cell completely and accurately only by using the continuum model based on macroscopic mechanics or the first-principles method based on quantum mechanics. and its structure from microscopic to macroscopic interrelated properties, while only using molecular dynamics methods, the computational power is insufficient

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Embodiment Construction

[0029] The present invention will be described in detail below in conjunction with the accompanying drawings and specific embodiments.

[0030] Overall research scheme of the present invention such as figure 1 As shown, it is mainly divided into 4 steps:

[0031] 1) Extraction and analysis of microscopic features of porous layer materials;

[0032] 2) Experimental measurement and model verification of porous layer material properties;

[0033] 3) Single battery performance test and multi-scale model verification;

[0034] 4) The effect of the microstructure characteristics of the porous layer on the performance of the battery.

[0035] Step 1) Obtain microstructure data and images of the porous layer through experiments, and perform fractal and microscopic feature analysis. The idea of ​​analyzing the microscopic characteristics of porous layer materials is as follows: figure 2 As shown, it mainly includes fractal analysis based on experimental principles and data and fr...

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Abstract

The invention relates to a multi-scale correlation method for a proton exchange membrane fuel cell. The method is characterized in that complicated physical and chemical phenomena such as coupled mass and heat transfer, an electrochemical reaction and the like in the proton exchange membrane fuel cell are subjected to modeling of macroscopic sizes of a monocell and parts as well as microscopic scales of a gas diffusion layer, a catalytic layer and a proton exchange membrane which have a micron structure, a submicron structure and a nano-porous structure respectively, multi-scale correlation and simulation. A fractal-based modeling method proposed by the invention adopts a mechanism modeling method in microscopic scale, so that a model is clear in physical meaning and high in accuracy. A parameter transmission method is adopted for coupling of a microscopic model and a macroscopic model, so that multi-scale correction of a transmission mechanism in the monocell can be realized, the defect that existing multi-scale simulation calculation is complicated can be made up for, the transmission mechanism in the proton exchange membrane fuel cell can be understood more essentially and objectively, and a brand-new means is provided for exploring an optimal porous layer microstructure and optimization design of the porous layer microstructure.

Description

technical field [0001] The invention relates to a simulation method of an energy system, in particular to a multi-scale simulation method of a proton exchange membrane fuel cell. Background technique [0002] Proton exchange membrane fuel cells have the characteristics of working at room temperature and fast start-up, and have become a research hotspot in the world. In order to improve the cell performance, in-depth study of the transport phenomena and their mechanisms in proton exchange membrane fuel cells is required. Proton exchange membrane fuel cells have multi-scale complex structures, and their multi-scale performance ranges from the macroscopic dimensions of the cell and its components to the microscopic dimensions of the gas diffusion layer, catalyst layer, and proton exchange membrane with micron, submicron, and nanoporous structures, respectively. scale. Battery performance is closely related to both the macroscopic dimensions of the component and the microstruc...

Claims

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Application Information

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Patent Type & Authority Applications(China)
IPC IPC(8): G06F17/50H01M4/86
CPCG06F30/367G06F2119/06H01M4/8605Y02E60/50
Inventor 石英杜科全书海谢长君陈启宏张立炎黄亮邓坚徐眯雷博文伍龙昶蒙珊珊杨振
Owner WUHAN UNIV OF TECH
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