A perturbation strategy for fuel consumption minimization in polymer electrolyte membrane fuel cells: Analysis, Design and FPGA implementation

In this paper a perturbation approach to the minimization of hydrogen consumption in polymer electrolyte membrane fuel cell systems is introduced. The control technique is mainly based on the minimization of the current produced by the fuel cell by means of the Perturb and Observe method. The controller works in conjunction with the dc/dc converter which is usually connected at the fuel cell system terminals and processing the power it produces: the electrical power requested by the load is provided at the minimum current, so that the minimum hydrogen consumption is ensured. The technique is explained by means of some results obtained by using a fuel cell dynamic model which was experimentally validated on a Ballard Nexa 1.2 kW commercially available system. One of the main features of the fuel cell system model used in this paper is its ability in virtually sensing the value of the oxygen excess ratio: such a possibility is employed in order to implement the proposed model based control approach. The manuscript shows the advantages of the proposed control technique by means of simulation results and gives the details of the implementation of the algorithm into a digital device, thus an FPGA. The implementation is also used in order to confirm the effectiveness of the control technique: simulations and tests using the hardware-in-the-loop concept, both in steady state conditions as well as during load transients, are provided. The time behavior of the oxygen excess ratio, which is an important variable in any fuel cell application, obtained by means of the proposed technique is also shown. (C) 2013 Elsevier Ltd. All rights reserved.