An enhanced maximum power point tracking and voltage control for proton exchange membrane fuel cell using predictive model control techniques

Proton Exchange Membrane Fuel Cells serve as sustainable devices for converting renewable energy sources into electricity, offering advantages such as rapid startup, high power density, and operation at low temperatures. They are highly efficient and environmentally friendly energy sources, yet thei...

Full description

Saved in:
Bibliographic Details
Published in:Energy reports 2024-12, Vol.12, p.2958-2970
Main Authors: Fam, Jye Yun, Wong, Shen Yuong, Bin Mohamed Basri, Hazrul, Lias, Kasumawati Binti, Abdullah, Mohammad Omar
Format: Article
Language:English
Subjects:
DC-AC inverter
DC-DC boost converter
Finite-control-set model predictive control
Maximum power point tracking
Proton exchange membrane fuel cell
Renewable Energy
Citations: Items that this one cites
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:Proton Exchange Membrane Fuel Cells serve as sustainable devices for converting renewable energy sources into electricity, offering advantages such as rapid startup, high power density, and operation at low temperatures. They are highly efficient and environmentally friendly energy sources, yet their non-linear output characteristics under variable conditions present challenges in maximizing power output. Furthermore, they generates direct current, while many electrical devices rely on alternating current. This research addresses the necessity of enhancing the performance and efficiency through the development of an advanced maximum power point tracking technique and voltage control strategy. A modified finite-control-set model predictive control technique is proposed for both maximum power point tracking and voltage control. Specifically, a finite-control-set model predictive control technique approach is employed to modulate the switching signal for both the DC-DC boost converter and the DC-AC inverter. The DC-DC boost converter step up the fuel cell output voltage to the desired level, ensuring it reaches the maximum power point, and a DC-AC inverter to convert the direct current voltage to a pure sinusoidal alternating waveform. The investigation demonstrates the effectiveness of the proposed method in achieving its objectives. The proposed maximum power point tracking technique accuracy achieved the maximum power with a rate of 97 % with excellent respond time within 7 ms. For alternating current power, only less than 1.5 % of total harmonic distortion is recorded. The study evaluates the control scheme under robust operating conditions, demonstrating its effectiveness in optimizing PEMFC output and providing high-quality AC voltage. [Display omitted] •A predictive maximum power point tracking technique and voltage control is proposed.•The proposed technique can track the maximum power with 97 % accuracy.•The proposed technique has superior performance in fast-tracking speed within 7 ms.•The proposed voltage control technique has a stable AC voltage supply.•The proposed methods are validated in various operating parameters and loads.
ISSN:2352-4847
2352-4847
DOI:10.1016/j.egyr.2024.08.055