Experimental investigation of temperature distribution over a planar solid oxide fuel cell

Experimental investigation of temperature distribution over a planar solid oxide fuel cell

► A stack of six cross-flow SOFC cell was tested in different oven temperatures. ► Temperature profile over the cell surface was extracted by five thermocouples inserted inside the stack. ► Effects of the current density and the oven temperature on temperature distribution and SOFC performance were...

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Veröffentlicht in:Applied energy 2013-05, Vol.105, p.155-160
Hauptverfasser: Razbani, Omid, Wærnhus, Ivar, Assadi, Mohsen
Format: Artikel
Sprache:eng
Schlagworte:
air
Applied sciences
cells
Corners
Current density
data analysis
Energy
Energy. Thermal use of fuels
Equipments for energy generation and conversion: thermal, electrical, mechanical energy, etc
Exact sciences and technology
Experiment
Fuel cells
Fuels
monitoring
Ovens
platinum
Solid oxide fuel cell
Solid oxide fuel cells
Stacks
temperature
Temperature distribution
Temperature gradient
thermocouples
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container_title Applied energy
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creator Razbani, Omid
Wærnhus, Ivar
Assadi, Mohsen
description ► A stack of six cross-flow SOFC cell was tested in different oven temperatures. ► Temperature profile over the cell surface was extracted by five thermocouples inserted inside the stack. ► Effects of the current density and the oven temperature on temperature distribution and SOFC performance were explained. ► A literature review around the subject was done. ► The presented experimental results will be used in the future for validation of simulation works. Temperature distribution over a Solid oxide fuel cell (SOFC) surface is a crucial parameter for design of a SOFC stack. The selection of both materials and the operating point of a stack is heavily affected by temperature gradient. Temperature distribution can also be used for control and monitoring purposes. An experimental set-up consisting of a cross flow type stack of six cells was built to measure the temperature distribution in different current densities and in two oven temperatures. Five thermocouples were inserted inside the middle cell to measure temperatures in four corners and in the middle of the cell. Voltage was also measured for different cells using platinum wires. Low fuel utilization (meaning low current density) and high excess air caused maximum temperature at the fuel inlet-air outlet corner. Higher oven temperature caused more uniform temperature distribution, while increasing the current density resulted in higher temperature gradient over the cell surface. This paper provides measurement data and analysis of the results from the test runs.
doi_str_mv 10.1016/j.apenergy.2012.12.062
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Temperature distribution over a Solid oxide fuel cell (SOFC) surface is a crucial parameter for design of a SOFC stack. The selection of both materials and the operating point of a stack is heavily affected by temperature gradient. Temperature distribution can also be used for control and monitoring purposes. An experimental set-up consisting of a cross flow type stack of six cells was built to measure the temperature distribution in different current densities and in two oven temperatures. Five thermocouples were inserted inside the middle cell to measure temperatures in four corners and in the middle of the cell. Voltage was also measured for different cells using platinum wires. Low fuel utilization (meaning low current density) and high excess air caused maximum temperature at the fuel inlet-air outlet corner. Higher oven temperature caused more uniform temperature distribution, while increasing the current density resulted in higher temperature gradient over the cell surface. 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Temperature distribution over a Solid oxide fuel cell (SOFC) surface is a crucial parameter for design of a SOFC stack. The selection of both materials and the operating point of a stack is heavily affected by temperature gradient. Temperature distribution can also be used for control and monitoring purposes. An experimental set-up consisting of a cross flow type stack of six cells was built to measure the temperature distribution in different current densities and in two oven temperatures. Five thermocouples were inserted inside the middle cell to measure temperatures in four corners and in the middle of the cell. Voltage was also measured for different cells using platinum wires. Low fuel utilization (meaning low current density) and high excess air caused maximum temperature at the fuel inlet-air outlet corner. Higher oven temperature caused more uniform temperature distribution, while increasing the current density resulted in higher temperature gradient over the cell surface. 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source ScienceDirect Journals (5 years ago - present)
subjects air
Applied sciences
cells
Corners
Current density
data analysis
Energy
Energy. Thermal use of fuels
Equipments for energy generation and conversion: thermal, electrical, mechanical energy, etc
Exact sciences and technology
Experiment
Fuel cells
Fuels
monitoring
Ovens
platinum
Solid oxide fuel cell
Solid oxide fuel cells
Stacks
temperature
Temperature distribution
Temperature gradient
thermocouples
title Experimental investigation of temperature distribution over a planar solid oxide fuel cell
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