Response of a proton exchange membrane fuel cell to step changes in mass flow rates

Kupeli, Seda; Celik, Erman; Karagöz, İrfan

doi:10.1002/fuce.202000170

Cited by 7 publications

(5 citation statements)

References 30 publications

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“…To simulate the heat-up process, the equations of conservation of mass, momentum, and energy are solved in their transient form with the assumptions of laminar flow regime, homogeneous porous media, and ideal behavior of all gas species. [10,28,50] Equation (1) shows the conservation of mass, in which ũ is the velocity vector, t represents the time, and ε shows the porosity of porous media. [10,28,50] Also, ρ denotes the gas density which is calculated from the ideal gas law as shown in Equation ( 2), where P, T, and R are pressure, temperature, and gas constant, respectively: [10,50]…”

Section: Governing Equationsmentioning

confidence: 99%

“…The harmful environmental impact of fossil fuel usage, the depletion of fossil fuel resources, and the ever-increasing global energy demand had led researchers to seek alternative energy resources. [1][2][3] Fuel cells, as a group of clean energy systems, have attracted special attention and been employed in various applications such as transportation, power generation, and space missions. Fuel cells consume hydrogen (fuel) and oxygen, and produce electricity, water, and heat as a result of some electrochemical reactions.…”

Section: Introductionmentioning

confidence: 99%

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Optimal Heat‐Up Planning of a Solid Oxide Fuel Cell with and without Hot Air Recycling by Considering Energy, Time, and Temperature Gradient

Hami

Mahmoudimehr

2023

Energy Tech

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A solid oxide fuel cell (SOFC) needs to be heated to a high temperature to be able to start generating electricity. This study aims to manage the heat-up process of a SOFC by considering the three objectives of time duration, energy consumption, and temperature gradient, simultaneously. Mass flow rate (MFR) and rate of temperature rise (RTR) of the hot air, passing through the cathode channel of the SOFC, are considered as decision variables. The transient heatup process is numerically simulated for six different MFR values (5-50 mg s À1 ) and six different RTR values (0.1-5 K s À1 ). The results indicate that higher RTR leads to lower heat-up duration, lower energy consumption, but higher temperature gradient. Also, higher MFR results in lower heat-up duration, lower temperature gradient, but higher energy consumption. The results also reveal that hot air recycling increases thermal efficiency from below 40% to nearly 100%. Finally, when hot air recycling is employed and all the objectives are considered simultaneously, the heat-up plan with a RTR of 0.5 K s À1 and a MFR of 50 mg s À1 is selected as the best choice by using linear programming technique for multidimensional analysis of preference.

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Section: Governing Equationsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Optimal Heat‐Up Planning of a Solid Oxide Fuel Cell with and without Hot Air Recycling by Considering Energy, Time, and Temperature Gradient

Hami

Mahmoudimehr

2023

Energy Tech

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“…Transient effects are significant for mobile applications, and were the focus of a 3-D CFD study of a PEMFC with a serpentine channel. A step-change in the mass flow rates resulted in current-and power-density increases with time at low cell voltage due to concentration losses, but this was negligible at high voltages [60].…”

Section: Fluid Dynamic Modellingmentioning

confidence: 99%

Modelling of Fuel Cells and Related Energy Conversion Systems

Rossetti¹

2022

ChemEngineering

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Heat and power cogeneration plants based on fuel cells are interesting systems for energy- conversion at low environmental impact. Various fuel cells have been proposed, of which proton-exchange membrane fuel cells (PEMFC) and solid oxide fuel cells (SOFC) are the most frequently used. However, experimental testing rigs are expensive, and the development of commercial systems is time consuming if based on fully experimental activities. Furthermore, tight control of the operation of fuel cells is compulsory to avoid damage, and such control must be based on accurate models, able to predict cell behaviour and prevent stresses and shutdown. Additionally, when used for mobile applications, intrinsically dynamic operation is needed. Some selected examples of steady-state, dynamic and fluid-dynamic modelling of different types of fuel cells are here proposed, mainly dealing with PEMFC and SOFC types. The general ideas behind the thermodynamic, kinetic and transport description are discussed, with some examples of models derived for single cells, stacks and integrated power cogeneration units. This review can be considered an introductory picture of the modelling methods for these devices, to underline the different approaches and the key aspects to be taken into account. Examples of different scales and multi-scale modelling are also provided.

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“…Transient effects are significant for mobile applications and were the focus of a 3-D CFD study of a PEMFC with a serpentine channel. A step-change in the mass flow rates ends in current and power densities increase with time at low cell voltage due to concentration losses, but negligible at high voltages [46].…”

Section: Fluid Dynamic Modellingmentioning

confidence: 99%

Multiscale Modelling of Fuel Cells and Related Energy Conversion Systems

Rossetti¹

2022

Preprint

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Heat and power cogeneration plants based on fuel cells are interesting systems for energy- conversion at low environmental impact. Different fuel cells have been proposed, but experimental testing rigs are expensive and the development of commercial systems is time consuming if based on fully experimental activities. Furthermore, tight control of operation of fuel cells is compulsory to avoid damage, which must be based on accurate models, able to predict the cell behaviour and prevent stresses and shut-down. Some selected examples of steady state, dynamic and fluid dynamic modelling of different types of fuel cells are proposed, mainly PEMFC and SOFC type. The general ideas behind the thermodynamic, kinetic and transport description are recalled, with some examples of models derived for single cells, stacks and integrated power co-generation units.

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Response of a proton exchange membrane fuel cell to step changes in mass flow rates

Cited by 7 publications

References 30 publications

Optimal Heat‐Up Planning of a Solid Oxide Fuel Cell with and without Hot Air Recycling by Considering Energy, Time, and Temperature Gradient

Optimal Heat‐Up Planning of a Solid Oxide Fuel Cell with and without Hot Air Recycling by Considering Energy, Time, and Temperature Gradient

Modelling of Fuel Cells and Related Energy Conversion Systems

Multiscale Modelling of Fuel Cells and Related Energy Conversion Systems

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