Multi objective optimization using artificial neural network to maximize the power output of PEMFCs

Designing a PEM fuel cell model is exceedingly challenging because of its multivariate in nature. Optimization is required to achieve highest operating condition. Neural Network Model is one of the possible methods to solve complex problems. The polarisation curve of a PEMFC (Proton Exchange Membran...

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Bibliographic Details
Published in:Indian chemical engineer (Calcutta, India : 1997) India : 1997), 2024-07, Vol.66 (4), p.323-336
Main Authors: Ghosh, Sankhadeep, Routh, Avijit, Rahaman, Mehabub, Ghosh, Avijit
Format: Article
Language:English
Subjects:
artificial neural network (ANN)
Artificial neural networks
Cathodes
co-efficient of determination (R
Electrode polarization
Fuel cells
Humidity
multi objective optimization
Neural networks
objective function
Optimization
Parameters
Partial pressure
Predictions
Proton exchange membrane (PEM) fuel cell (PEMFC)
Proton exchange membrane fuel cells
Relative humidity
Steady state models
Stoichiometry
Thickness
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Summary:Designing a PEM fuel cell model is exceedingly challenging because of its multivariate in nature. Optimization is required to achieve highest operating condition. Neural Network Model is one of the possible methods to solve complex problems. The polarisation curve of a PEMFC (Proton Exchange Membrane Fuel Cell) is investigated in this paper in relation to the effects of seven parameters, including temperature, relative humidity in the cathode, relative humidity in the anode, anode stoichiometry, cathode stoichiometry, partial pressure of H 2 , and partial pressure of O 2 , using an ANN (artificial neural network) model. Where model geometric parameters i.e. Channel width, Channel depth, Channel length, Rib width, Cell width, GDL thickness, CL thickness, Membrane thickness of PEMFC was constant. Initially single Objective Function (Output Power) is predicted. The research presented here makes predictions about a PEMFC stack's electrical performance under multiple operating conditions. Mathematical model was further verified using laboratory data. Co-efficient of Determination (R 2 ), Mean Square Error (MSE), and Mean Absolute Error (MAE) was determined using the fuel cell stack voltage model and stack power model. The model results show the possibility of using ANN in the implementation of such models to predict the PEMFC system's steady-state behaviour. Experimentally data useful for investigation and work on PEMFCs. ANN models to predict the steady state behaviour of the PEMFC system for different operating conditions Single Objective Function (Output Power Predicted) ANN-Multi Objective function is presented to predict Efficiency and output Power simultaneously ANN-MOO model is Validated using Laboratory Data
ISSN:0019-4506
0975-007X
DOI:10.1080/00194506.2024.2392630