Numerical optimization of evaporative cooling in artificial gas diffusion layers

•Direct pore-level model allows to describe evaporative cooling in GDL.•Artificial lattice replaces partially saturated GDL with similar morphology.•Kinetic gas theory models pore-level evaporation at water-gas interface.•Evaporation is mostly impacted by GDL porosity, carrier gas type and operating...

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Veröffentlicht in:	Applied thermal engineering 2021-03, Vol.186, p.116460, Article 116460
Hauptverfasser:	van Rooij, Sarah, Magnini, Mirco, Matar, Omar K., Haussener, Sophia
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Sprache:	eng
Schlagworte:	Artificial lattice Carrier gases Computational fluid dynamics Conservation equations Cooling Cooling rate Diffusion layers Electrochemical cells Electrolytic cells Energy dissipation Evaporation Evaporation rate Evaporative cooling Fuel cells Gas diffusion layers Gaseous diffusion Heat exchangers Heat flux Heat transfer Kinetic gas theory Kinetic theory Liquid-vapor interfaces Mass transport Mathematical models Operating temperature Optimization Pore-scale modeling Porosity Solid phases Thermal energy Thermophysical properties Three dimensional models Transport phenomena Wildlife conservation
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description	•Direct pore-level model allows to describe evaporative cooling in GDL.•Artificial lattice replaces partially saturated GDL with similar morphology.•Kinetic gas theory models pore-level evaporation at water-gas interface.•Evaporation is mostly impacted by GDL porosity, carrier gas type and operating temperature.•Water vapor diffusion into the vapor phase domain of the GDL limits evaporation. The utilization of evaporative cooling in the gas diffusion layers (GDLs) of fuel cells or electrolyzers can effectively dissipate the heat produced by high power density operation, thus leading to economically more competitive electrochemical cells. The highly porous GDLs offer a large surface area, allowing to cope with larger heat fluxes and leading to larger evaporation rates. The understanding of the best GDL structure and cell operating conditions for optimized cooling is difficult to determine, given the complexity of the multi-physical processes involved. A direct pore-level numerical modeling framework was developed to analyze the heat and mass transport phenomena occurring within GDLs with integrated evaporative cooling. A three-dimensional model was developed that solves the Navier-Stokes equations, species transport and energy conservation equations in the gas domain, and energy conservation equations in the stagnant fluid phase and solid phase. Evaporation at the liquid-vapor interface was modeled using kinetic theory. The GDL geometry was approximated by an artificial lattice so as to enable the analysis of the effect of a systematic change in the geometry on the transport and evaporation characteristics. A parametric study indicated that increasing the GDL’s porosity from 0.8 to 0.9 and the operating temperature from 60°C to 80°C led to an increase of the evaporation rate of 19.9% and 197%, respectively. Changing the thermophysical properties of the carrier gas (air to hydrogen) enhanced the evaporation rate, and therefore the cooling of the GDL, by a factor 2.7. The decrease of the amount of vapor in the carrier gas at the water-gas interface impacted positively the evaporative cooling in the GDL.
doi_str_mv	10.1016/j.applthermaleng.2020.116460
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The utilization of evaporative cooling in the gas diffusion layers (GDLs) of fuel cells or electrolyzers can effectively dissipate the heat produced by high power density operation, thus leading to economically more competitive electrochemical cells. The highly porous GDLs offer a large surface area, allowing to cope with larger heat fluxes and leading to larger evaporation rates. The understanding of the best GDL structure and cell operating conditions for optimized cooling is difficult to determine, given the complexity of the multi-physical processes involved. A direct pore-level numerical modeling framework was developed to analyze the heat and mass transport phenomena occurring within GDLs with integrated evaporative cooling. A three-dimensional model was developed that solves the Navier-Stokes equations, species transport and energy conservation equations in the gas domain, and energy conservation equations in the stagnant fluid phase and solid phase. Evaporation at the liquid-vapor interface was modeled using kinetic theory. The GDL geometry was approximated by an artificial lattice so as to enable the analysis of the effect of a systematic change in the geometry on the transport and evaporation characteristics. A parametric study indicated that increasing the GDL’s porosity from 0.8 to 0.9 and the operating temperature from 60°C to 80°C led to an increase of the evaporation rate of 19.9% and 197%, respectively. Changing the thermophysical properties of the carrier gas (air to hydrogen) enhanced the evaporation rate, and therefore the cooling of the GDL, by a factor 2.7. 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The utilization of evaporative cooling in the gas diffusion layers (GDLs) of fuel cells or electrolyzers can effectively dissipate the heat produced by high power density operation, thus leading to economically more competitive electrochemical cells. The highly porous GDLs offer a large surface area, allowing to cope with larger heat fluxes and leading to larger evaporation rates. The understanding of the best GDL structure and cell operating conditions for optimized cooling is difficult to determine, given the complexity of the multi-physical processes involved. A direct pore-level numerical modeling framework was developed to analyze the heat and mass transport phenomena occurring within GDLs with integrated evaporative cooling. A three-dimensional model was developed that solves the Navier-Stokes equations, species transport and energy conservation equations in the gas domain, and energy conservation equations in the stagnant fluid phase and solid phase. Evaporation at the liquid-vapor interface was modeled using kinetic theory. The GDL geometry was approximated by an artificial lattice so as to enable the analysis of the effect of a systematic change in the geometry on the transport and evaporation characteristics. A parametric study indicated that increasing the GDL’s porosity from 0.8 to 0.9 and the operating temperature from 60°C to 80°C led to an increase of the evaporation rate of 19.9% and 197%, respectively. Changing the thermophysical properties of the carrier gas (air to hydrogen) enhanced the evaporation rate, and therefore the cooling of the GDL, by a factor 2.7. The decrease of the amount of vapor in the carrier gas at the water-gas interface impacted positively the evaporative cooling in the GDL.</description><subject>Artificial lattice</subject><subject>Carrier gases</subject><subject>Computational fluid dynamics</subject><subject>Conservation equations</subject><subject>Cooling</subject><subject>Cooling rate</subject><subject>Diffusion layers</subject><subject>Electrochemical cells</subject><subject>Electrolytic cells</subject><subject>Energy dissipation</subject><subject>Evaporation</subject><subject>Evaporation rate</subject><subject>Evaporative cooling</subject><subject>Fuel cells</subject><subject>Gas diffusion layers</subject><subject>Gaseous diffusion</subject><subject>Heat exchangers</subject><subject>Heat flux</subject><subject>Heat transfer</subject><subject>Kinetic gas theory</subject><subject>Kinetic theory</subject><subject>Liquid-vapor interfaces</subject><subject>Mass transport</subject><subject>Mathematical models</subject><subject>Operating temperature</subject><subject>Optimization</subject><subject>Pore-scale modeling</subject><subject>Porosity</subject><subject>Solid phases</subject><subject>Thermal energy</subject><subject>Thermophysical properties</subject><subject>Three dimensional models</subject><subject>Transport phenomena</subject><subject>Wildlife conservation</subject><issn>1359-4311</issn><issn>1873-5606</issn><fulltext>true</fulltext><rsrctype>article</rsrctype><creationdate>2021</creationdate><recordtype>article</recordtype><recordid>eNqNkMtOwzAQRS0EEqXwD5Fgm-JXbEdigyoKSBWwgLXlOpPiKI2DnVQqX4-rsGHHamY098zjInRD8IJgIm6bhen7dviEsDMtdNsFxTS1iOACn6AZUZLlhcDiNOWsKHPOCDlHFzE2GBOqJJ-ht5dxB8FZ02a-H9zOfZvB-S7zdQZ70_uQyj1k1vvWddvMdZkJg6uddYnYmphVrq7HeERac4AQL9FZbdoIV79xjj5WD-_Lp3z9-vi8vF_nlhM65DQdZEFIJatK1dWmYEoqbAkvcFUyKnAhpeLGqsoQTrmAomSWlJRuuOVYYjZH19PcPvivEeKgGz-GLq3UtMBECaZUmVR3k8oGH2OAWvfB7Uw4aIL10UPd6L8e6qOHevIw4asJh_TJ3kHQ0TroLFQugB105d3_Bv0A5KGC9Q</recordid><startdate>20210305</startdate><enddate>20210305</enddate><creator>van Rooij, Sarah</creator><creator>Magnini, Mirco</creator><creator>Matar, Omar K.</creator><creator>Haussener, Sophia</creator><general>Elsevier Ltd</general><general>Elsevier BV</general><scope>6I.</scope><scope>AAFTH</scope><scope>AAYXX</scope><scope>CITATION</scope><scope>7TB</scope><scope>8FD</scope><scope>FR3</scope><scope>KR7</scope></search><sort><creationdate>20210305</creationdate><title>Numerical optimization of evaporative cooling in artificial gas diffusion layers</title><author>van Rooij, Sarah ; 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subjects	Artificial lattice Carrier gases Computational fluid dynamics Conservation equations Cooling Cooling rate Diffusion layers Electrochemical cells Electrolytic cells Energy dissipation Evaporation Evaporation rate Evaporative cooling Fuel cells Gas diffusion layers Gaseous diffusion Heat exchangers Heat flux Heat transfer Kinetic gas theory Kinetic theory Liquid-vapor interfaces Mass transport Mathematical models Operating temperature Optimization Pore-scale modeling Porosity Solid phases Thermal energy Thermophysical properties Three dimensional models Transport phenomena Wildlife conservation
title	Numerical optimization of evaporative cooling in artificial gas diffusion layers
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