A Control-Oriented Model of a PEM Fuel Cell Stack Based on NARX and NOE Neural Networks

Hydrogen-related technologies have been proposed as an alternative to store the energy surplus from renewable sources. Among these technologies, the proton exchange membrane fuel cell (PEMFC) and electrolyzer are the preferred choice for practical applications since they have reached a certain level of maturity and are commercially available at present. In order to achieve a cost-effective operation, a PEMFC stack must operate at maximum efficiency most of the time. Since PEMFC stacks present a time-varying behavior, an adaptive model-based controller should be employed to accomplish this goal. A fixed-parameter electrochemical model may not offer a reliable prediction over a midterm time horizon for such a controller. For this reason, system identification techniques appear as more appropriate choices to obtain an effective model for this class of control systems. In this paper, a system identification modeling methodology employing nonlinear autoregressive with exogenous input (NARX) and nonlinear output error (NOE) neural networks is presented to obtain a black-box model of a PEMFC stack oriented for a predictive control system. The experimental data for the model development are obtained with a commercial 3-kW PEMFC stack. The model built according to the proposed methodology provides accurate predictions of the voltage for the whole operating range of the stack for a long time and, hence, the ability to represent the time-varying behavior of a PEMFC stack for a predictive control application.

[1]  Ilya V. Kolmanovsky,et al.  A Dynamic Semi-Analytic Channel-to-Channel Model of Two-Phase Water Distribution for a Unit Fuel Cell , 2009, IEEE Transactions on Control Systems Technology.

[2]  Ali Keyhani,et al.  Neural Network Modeling of Proton Exchange Membrane Fuel Cell , 2010, IEEE Transactions on Energy Conversion.

[3]  Bo-Hyung Cho,et al.  Equivalent Circuit Modeling of PEM Fuel Cell Degradation Combined With a LFRC , 2013, IEEE Transactions on Industrial Electronics.

[4]  R. Gouriveau,et al.  Fuel Cells prognostics using echo state network , 2013, IECON 2013 - 39th Annual Conference of the IEEE Industrial Electronics Society.

[5]  Daniel Hissel,et al.  A New Modeling Approach of Embedded Fuel-Cell Power Generators Based on Artificial Neural Network , 2008, IEEE Transactions on Industrial Electronics.

[6]  Shehab Ahmed,et al.  PEM Fuel Cell Stack Model Development for Real-Time Simulation Applications , 2011, IEEE Transactions on Industrial Electronics.

[7]  Haralambos Sarimveis,et al.  Operational optimization and real-time control of fuel-cell systems , 2009 .

[8]  K. W. Harrison,et al.  Wind-To-Hydrogen Project: Operational Experience, Performance Testing, and Systems Integration , 2009 .

[9]  Alireza Rezazadeh,et al.  An Innovative Global Harmony Search Algorithm for Parameter Identification of a PEM Fuel Cell Model , 2012, IEEE Transactions on Industrial Electronics.

[10]  Prodromos Daoutidis,et al.  Modeling and Control of a Renewable Hybrid Energy System With Hydrogen Storage , 2014, IEEE Transactions on Control Systems Technology.

[11]  Qi Li,et al.  Parameter Identification for PEM Fuel-Cell Mechanism Model Based on Effective Informed Adaptive Particle Swarm Optimization , 2011, IEEE Transactions on Industrial Electronics.

[12]  Tine Konjedic,et al.  Simplified Mathematical Model for Calculating the Oxygen Excess Ratio of a PEM Fuel Cell System in Real-Time Applications , 2014, IEEE Transactions on Industrial Electronics.

[13]  T Rushi Santhosh Singh,et al.  Energy Management and Power Control of a Hybrid Active Wind Generator for Distributed Power Generation and Grid Integration , 2016 .

[14]  Luis M. Fernández,et al.  ANFIS-Based Control of a Grid-Connected Hybrid System Integrating Renewable Energies, Hydrogen and Batteries , 2014, IEEE Transactions on Industrial Informatics.

[15]  Roberto F. de Souza,et al.  An evaluation of the potential of the use of wasted hydroelectric capacity to produce hydrogen to be used in fuel cells in order to decrease CO2 emissions in Brazil , 2009 .

[16]  K. Agbossou,et al.  Online System Identification and Adaptive Control for PEM Fuel Cell Maximum Efficiency Tracking , 2012, IEEE Transactions on Energy Conversion.

[17]  Lennart Ljung,et al.  Perspectives on system identification , 2010, Annu. Rev. Control..

[18]  Silvio Carlos Anibal de Almeida,et al.  Performance analysis of a 5 kW PEMFC with a natural gas reformer , 2010 .

[19]  E. H. Watanabe,et al.  A recurrent neural approach for modeling non-reproducible behavior of PEM fuel cell stacks , 2013, 2013 IEEE International Conference on Industrial Technology (ICIT).

[20]  Vincenzo Piuri,et al.  Neural modeling of dynamic systems with nonmeasurable state variables , 1999, IEEE Trans. Instrum. Meas..

[21]  Francisco Jurado,et al.  Predictive control of solid oxide fuel cells using fuzzy Hammerstein models , 2006 .

[22]  Edson H. Watanabe,et al.  Analysis of the time-varying behavior of a PEM fuel cell stack and dynamical modeling by recurrent neural networks , 2013, 2013 Brazilian Power Electronics Conference.

[23]  A. Massardo,et al.  Time-dependent optimization of a large size hydrogen generation plant using “spilled” water at Itaipu 14 GW hydraulic plant , 2012 .

[24]  Felix N. Büchi,et al.  Heterogeneous Cell Ageing in Polymer Electrolyte Fuel Cell Stacks , 2009 .

[25]  Carlos Bordons,et al.  Real-Time Implementation of a Constrained MPC for Efficient Airflow Control in a PEM Fuel Cell , 2010, IEEE Transactions on Industrial Electronics.

[26]  Jonas Sjöberg,et al.  Neural networks for modelling and control of dynamic systems, M. Nørgaard, O. Ravn, N. K. Poulsen and L. K. Hansen, Springer, London, 2000, xiv+246pp. , 2001 .

[27]  Ashwin M. Khambadkone,et al.  Modeling of a PEM Fuel-Cell Stack for Dynamic and Steady-State Operation Using ANN-Based Submodels , 2009, IEEE Transactions on Industrial Electronics.