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ME492 FUEL CELL FUNDAMENTALS

Course Objectives

• Understanding the difference between electrochemical and chemical reactions.
• Understanding the difference between fuel cell engines and heat engines.
• Ability to distinguish various fuel cell types and their uses in practical applications.
• Understanding the functions of generic fuel cell components.
• Ability to calculate enthalpy and Gibbs energy changes for electrochemical reactions.
• Ability to calculate maximum expected open circuit voltage.
• Ability to calculate thermal voltage.
• Ability to calculate Nernst potential and thermodynamical efficiency.
• Understanding the potential losses
• Ability to draw polarization curve for a generic fuel cell.
• Ability to estimate activation losses.
• Ability to estimate ohmic losses.
• Ability to estimate concentration losses.
• Understanding the electrolyte structure and ion transport in polymer electrolyte fuel cells.
• Understanding the electrolyte structure and ion transport in solid oxide fuel cells.
• Ability to carry out 1-D modeling of a PEFC.
• Understanding the importance of water management in PEFCs.
• Understanding the future directions in Fuel Cell research.
• Understanding the environmental importance of fuel cells in renewable energy systems and stationary applications.

Course Content

Mathematical modeling of fuel cell thermodynamics, reaction kinetics, charge transport and mass transport. Performance of real and ideal fuel cells. 1-D fuel model. Fuel cell types and systems. Fuel environmental impacts.

Course Learning Outcomes

• Understanding the difference between electrochemical and chemical reactions.
• Understanding the difference between fuel cell engines and heat engines.
• Ability to distinguish various fuel cell types and their uses in practical applications.
• Understanding the functions of generic fuel cell components.
• Ability to calculate enthalpy and Gibbs energy changes for electrochemical reactions.
• Ability to calculate maximum expected open circuit voltage.
• Ability to calculate thermal voltage.
• Ability to calculate Nernst potential and thermodynamical efficiency.
• Understanding the potential losses
• Ability to draw polarization curve for a generic fuel cell.
• Ability to estimate activation losses.
• Ability to estimate ohmic losses.
• Ability to estimate concentration losses.
• Understanding the electrolyte structure and ion transport in polymer electrolyte fuel cells.
• Understanding the electrolyte structure and ion transport in solid oxide fuel cells.
• Ability to carry out 1-D modeling of a PEFC.
• Understanding the importance of water management in PEFCs.
• Understanding the future directions in Fuel Cell research.
• Understanding the environmental importance of fuel cells in renewable energy systems and stationary applications.

Program Outcomes Matrix