Abstract

This paper presents a simple strategy for controlling an interleaved boost converter that is used to reduce the current fluctuations in proton exchange membrane fuel cells, with high impact on the fuel cell lifetime. To keep the output voltage at the desired reference value under the strong fluctuations of the fuel flow rate, fuel supply pressure, and temperature, a neural network controller is developed and implemented using Matlab-Simulink (R2012b, MathWorks limited, London, UK). The advantage of this controller resides in its simplicity, where limited number of tests are carried out using Matlab-Simulink to construct it. To investigate the robustness of the proposed converter and the neural network controller, strong variations of the fuel flow rate, fuel supply pressure, temperature and air supply pressure are applied to both the fuel cell and the neural network controller of the converter. The simulation results show the effectiveness and the robustness of the both the proposed controller and converter to control the load voltage and minimize the current and voltage ripples. As a result of that, fuel cell current oscillations are considerably reduced on the one hand, while on the other hand, the load voltage is stabilized during transient variations of the fuel cell inputs.

Highlights

  • A Neural Network-Based Four Phases InterleavedEl Manaa Barhoumi 1,2, *, Ikram Ben Belgacem 3 , Abla Khiareddine 4 , Manaf Zghaibeh 1 and Iskander Tlili 5

  • Fuel cell technologies are becoming used in many industrial applications due to the cleanliness, high reliability and high performance of such electrical generators [1]

  • To minimize the current and voltage ripples as well as regulating the load voltage, a four phases interleaved boost converter was proposed in this paper

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Summary

A Neural Network-Based Four Phases Interleaved

El Manaa Barhoumi 1,2, *, Ikram Ben Belgacem 3 , Abla Khiareddine 4 , Manaf Zghaibeh 1 and Iskander Tlili 5. Laboratoire Analyse, Conception et Commande des Systèmes (LR11ES20), Ecole Nationale d’Ingénieurs de. Received: 26 October 2018; Accepted: 4 December 2018; Published: 6 December 2018

Introduction
Fuel Cell Modeling
Interleaved Boost Converter
Impact of External Parameters on the Output Voltage
Neural Network Regulation
Effect of the Load Impedance Variation
Effect of the Temperature Variation
Effect of the Fuel Flow Rate
Conclusions

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