The Experts below are selected from a list of 43782 Experts worldwide ranked by ideXlab platform
Nico Hotz - One of the best experts on this subject based on the ideXlab platform.
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a micro solid oxide Fuel Cell System as battery replacement
Journal of Power Sources, 2008Co-Authors: Anja Bieberlehutter, Daniel Beckel, Anna Infortuna, Ulrich P Muecke, Jennifer L M Rupp, Ludwig J Gauckler, Samuel Reymermet, Paul Muralt, Nicole R Bieri, Nico HotzAbstract:Abstract The concept and the design of a micro-solid oxide Fuel Cell System is described and discussed. The System in this study is called the ONEBAT System and consists of the Fuel Cell PEN (positive electrode – electrolyte – negative electrode) element, a gas processing unit, and a thermal System. PEN elements of free-standing multi-layer membranes are fabricated on Foturan ® and on Si substrates using thin film deposition and microfabrication techniques. Open circuit voltages of up to 1.06 V and power of 150 mW cm −2 are achieved at 550 °C. The membranes are stable up to 600 °C. The gas processing unit allows butane conversion of 95% and hydrogen selectivity of 83% at 550 °C in the reformer and efficient after-burning of hydrogen, carbon monoxide, and lower hydrocarbons in the post-combustor. Thermal System simulations prove that a large thermal gradient of more than 500 °C between the hot module and its exterior are feasible. The correlation between electrical power output – System size and thermal conductivity – heat-transfer coefficient of the thermal insulation material are shown. The System design studies show that the single sub-Systems can be integrated into a complete System and that the requirements for portable electronic devices can be achieved with a base unit of 2.5 W and a modular approach.
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a micro solid oxide Fuel Cell System as battery replacement
Journal of Power Sources, 2008Co-Authors: Anja Bieberlehutter, Daniel Beckel, Anna Infortuna, Ulrich P Muecke, Jennifer L M Rupp, Ludwig J Gauckler, Samuel Reymermet, Paul Muralt, Nicole R Bieri, Nico HotzAbstract:Abstract The concept and the design of a micro-solid oxide Fuel Cell System is described and discussed. The System in this study is called the ONEBAT System and consists of the Fuel Cell PEN (positive electrode – electrolyte – negative electrode) element, a gas processing unit, and a thermal System. PEN elements of free-standing multi-layer membranes are fabricated on Foturan ® and on Si substrates using thin film deposition and microfabrication techniques. Open circuit voltages of up to 1.06 V and power of 150 mW cm −2 are achieved at 550 °C. The membranes are stable up to 600 °C. The gas processing unit allows butane conversion of 95% and hydrogen selectivity of 83% at 550 °C in the reformer and efficient after-burning of hydrogen, carbon monoxide, and lower hydrocarbons in the post-combustor. Thermal System simulations prove that a large thermal gradient of more than 500 °C between the hot module and its exterior are feasible. The correlation between electrical power output – System size and thermal conductivity – heat-transfer coefficient of the thermal insulation material are shown. The System design studies show that the single sub-Systems can be integrated into a complete System and that the requirements for portable electronic devices can be achieved with a base unit of 2.5 W and a modular approach.
Anja Bieberlehutter - One of the best experts on this subject based on the ideXlab platform.
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a micro solid oxide Fuel Cell System as battery replacement
Journal of Power Sources, 2008Co-Authors: Anja Bieberlehutter, Daniel Beckel, Anna Infortuna, Ulrich P Muecke, Jennifer L M Rupp, Ludwig J Gauckler, Samuel Reymermet, Paul Muralt, Nicole R Bieri, Nico HotzAbstract:Abstract The concept and the design of a micro-solid oxide Fuel Cell System is described and discussed. The System in this study is called the ONEBAT System and consists of the Fuel Cell PEN (positive electrode – electrolyte – negative electrode) element, a gas processing unit, and a thermal System. PEN elements of free-standing multi-layer membranes are fabricated on Foturan ® and on Si substrates using thin film deposition and microfabrication techniques. Open circuit voltages of up to 1.06 V and power of 150 mW cm −2 are achieved at 550 °C. The membranes are stable up to 600 °C. The gas processing unit allows butane conversion of 95% and hydrogen selectivity of 83% at 550 °C in the reformer and efficient after-burning of hydrogen, carbon monoxide, and lower hydrocarbons in the post-combustor. Thermal System simulations prove that a large thermal gradient of more than 500 °C between the hot module and its exterior are feasible. The correlation between electrical power output – System size and thermal conductivity – heat-transfer coefficient of the thermal insulation material are shown. The System design studies show that the single sub-Systems can be integrated into a complete System and that the requirements for portable electronic devices can be achieved with a base unit of 2.5 W and a modular approach.
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a micro solid oxide Fuel Cell System as battery replacement
Journal of Power Sources, 2008Co-Authors: Anja Bieberlehutter, Daniel Beckel, Anna Infortuna, Ulrich P Muecke, Jennifer L M Rupp, Ludwig J Gauckler, Samuel Reymermet, Paul Muralt, Nicole R Bieri, Nico HotzAbstract:Abstract The concept and the design of a micro-solid oxide Fuel Cell System is described and discussed. The System in this study is called the ONEBAT System and consists of the Fuel Cell PEN (positive electrode – electrolyte – negative electrode) element, a gas processing unit, and a thermal System. PEN elements of free-standing multi-layer membranes are fabricated on Foturan ® and on Si substrates using thin film deposition and microfabrication techniques. Open circuit voltages of up to 1.06 V and power of 150 mW cm −2 are achieved at 550 °C. The membranes are stable up to 600 °C. The gas processing unit allows butane conversion of 95% and hydrogen selectivity of 83% at 550 °C in the reformer and efficient after-burning of hydrogen, carbon monoxide, and lower hydrocarbons in the post-combustor. Thermal System simulations prove that a large thermal gradient of more than 500 °C between the hot module and its exterior are feasible. The correlation between electrical power output – System size and thermal conductivity – heat-transfer coefficient of the thermal insulation material are shown. The System design studies show that the single sub-Systems can be integrated into a complete System and that the requirements for portable electronic devices can be achieved with a base unit of 2.5 W and a modular approach.
Samuel Reymermet - One of the best experts on this subject based on the ideXlab platform.
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a micro solid oxide Fuel Cell System as battery replacement
Journal of Power Sources, 2008Co-Authors: Anja Bieberlehutter, Daniel Beckel, Anna Infortuna, Ulrich P Muecke, Jennifer L M Rupp, Ludwig J Gauckler, Samuel Reymermet, Paul Muralt, Nicole R Bieri, Nico HotzAbstract:Abstract The concept and the design of a micro-solid oxide Fuel Cell System is described and discussed. The System in this study is called the ONEBAT System and consists of the Fuel Cell PEN (positive electrode – electrolyte – negative electrode) element, a gas processing unit, and a thermal System. PEN elements of free-standing multi-layer membranes are fabricated on Foturan ® and on Si substrates using thin film deposition and microfabrication techniques. Open circuit voltages of up to 1.06 V and power of 150 mW cm −2 are achieved at 550 °C. The membranes are stable up to 600 °C. The gas processing unit allows butane conversion of 95% and hydrogen selectivity of 83% at 550 °C in the reformer and efficient after-burning of hydrogen, carbon monoxide, and lower hydrocarbons in the post-combustor. Thermal System simulations prove that a large thermal gradient of more than 500 °C between the hot module and its exterior are feasible. The correlation between electrical power output – System size and thermal conductivity – heat-transfer coefficient of the thermal insulation material are shown. The System design studies show that the single sub-Systems can be integrated into a complete System and that the requirements for portable electronic devices can be achieved with a base unit of 2.5 W and a modular approach.
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a micro solid oxide Fuel Cell System as battery replacement
Journal of Power Sources, 2008Co-Authors: Anja Bieberlehutter, Daniel Beckel, Anna Infortuna, Ulrich P Muecke, Jennifer L M Rupp, Ludwig J Gauckler, Samuel Reymermet, Paul Muralt, Nicole R Bieri, Nico HotzAbstract:Abstract The concept and the design of a micro-solid oxide Fuel Cell System is described and discussed. The System in this study is called the ONEBAT System and consists of the Fuel Cell PEN (positive electrode – electrolyte – negative electrode) element, a gas processing unit, and a thermal System. PEN elements of free-standing multi-layer membranes are fabricated on Foturan ® and on Si substrates using thin film deposition and microfabrication techniques. Open circuit voltages of up to 1.06 V and power of 150 mW cm −2 are achieved at 550 °C. The membranes are stable up to 600 °C. The gas processing unit allows butane conversion of 95% and hydrogen selectivity of 83% at 550 °C in the reformer and efficient after-burning of hydrogen, carbon monoxide, and lower hydrocarbons in the post-combustor. Thermal System simulations prove that a large thermal gradient of more than 500 °C between the hot module and its exterior are feasible. The correlation between electrical power output – System size and thermal conductivity – heat-transfer coefficient of the thermal insulation material are shown. The System design studies show that the single sub-Systems can be integrated into a complete System and that the requirements for portable electronic devices can be achieved with a base unit of 2.5 W and a modular approach.
Paul Muralt - One of the best experts on this subject based on the ideXlab platform.
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a micro solid oxide Fuel Cell System as battery replacement
Journal of Power Sources, 2008Co-Authors: Anja Bieberlehutter, Daniel Beckel, Anna Infortuna, Ulrich P Muecke, Jennifer L M Rupp, Ludwig J Gauckler, Samuel Reymermet, Paul Muralt, Nicole R Bieri, Nico HotzAbstract:Abstract The concept and the design of a micro-solid oxide Fuel Cell System is described and discussed. The System in this study is called the ONEBAT System and consists of the Fuel Cell PEN (positive electrode – electrolyte – negative electrode) element, a gas processing unit, and a thermal System. PEN elements of free-standing multi-layer membranes are fabricated on Foturan ® and on Si substrates using thin film deposition and microfabrication techniques. Open circuit voltages of up to 1.06 V and power of 150 mW cm −2 are achieved at 550 °C. The membranes are stable up to 600 °C. The gas processing unit allows butane conversion of 95% and hydrogen selectivity of 83% at 550 °C in the reformer and efficient after-burning of hydrogen, carbon monoxide, and lower hydrocarbons in the post-combustor. Thermal System simulations prove that a large thermal gradient of more than 500 °C between the hot module and its exterior are feasible. The correlation between electrical power output – System size and thermal conductivity – heat-transfer coefficient of the thermal insulation material are shown. The System design studies show that the single sub-Systems can be integrated into a complete System and that the requirements for portable electronic devices can be achieved with a base unit of 2.5 W and a modular approach.
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a micro solid oxide Fuel Cell System as battery replacement
Journal of Power Sources, 2008Co-Authors: Anja Bieberlehutter, Daniel Beckel, Anna Infortuna, Ulrich P Muecke, Jennifer L M Rupp, Ludwig J Gauckler, Samuel Reymermet, Paul Muralt, Nicole R Bieri, Nico HotzAbstract:Abstract The concept and the design of a micro-solid oxide Fuel Cell System is described and discussed. The System in this study is called the ONEBAT System and consists of the Fuel Cell PEN (positive electrode – electrolyte – negative electrode) element, a gas processing unit, and a thermal System. PEN elements of free-standing multi-layer membranes are fabricated on Foturan ® and on Si substrates using thin film deposition and microfabrication techniques. Open circuit voltages of up to 1.06 V and power of 150 mW cm −2 are achieved at 550 °C. The membranes are stable up to 600 °C. The gas processing unit allows butane conversion of 95% and hydrogen selectivity of 83% at 550 °C in the reformer and efficient after-burning of hydrogen, carbon monoxide, and lower hydrocarbons in the post-combustor. Thermal System simulations prove that a large thermal gradient of more than 500 °C between the hot module and its exterior are feasible. The correlation between electrical power output – System size and thermal conductivity – heat-transfer coefficient of the thermal insulation material are shown. The System design studies show that the single sub-Systems can be integrated into a complete System and that the requirements for portable electronic devices can be achieved with a base unit of 2.5 W and a modular approach.
Daniel Beckel - One of the best experts on this subject based on the ideXlab platform.
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a micro solid oxide Fuel Cell System as battery replacement
Journal of Power Sources, 2008Co-Authors: Anja Bieberlehutter, Daniel Beckel, Anna Infortuna, Ulrich P Muecke, Jennifer L M Rupp, Ludwig J Gauckler, Samuel Reymermet, Paul Muralt, Nicole R Bieri, Nico HotzAbstract:Abstract The concept and the design of a micro-solid oxide Fuel Cell System is described and discussed. The System in this study is called the ONEBAT System and consists of the Fuel Cell PEN (positive electrode – electrolyte – negative electrode) element, a gas processing unit, and a thermal System. PEN elements of free-standing multi-layer membranes are fabricated on Foturan ® and on Si substrates using thin film deposition and microfabrication techniques. Open circuit voltages of up to 1.06 V and power of 150 mW cm −2 are achieved at 550 °C. The membranes are stable up to 600 °C. The gas processing unit allows butane conversion of 95% and hydrogen selectivity of 83% at 550 °C in the reformer and efficient after-burning of hydrogen, carbon monoxide, and lower hydrocarbons in the post-combustor. Thermal System simulations prove that a large thermal gradient of more than 500 °C between the hot module and its exterior are feasible. The correlation between electrical power output – System size and thermal conductivity – heat-transfer coefficient of the thermal insulation material are shown. The System design studies show that the single sub-Systems can be integrated into a complete System and that the requirements for portable electronic devices can be achieved with a base unit of 2.5 W and a modular approach.
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a micro solid oxide Fuel Cell System as battery replacement
Journal of Power Sources, 2008Co-Authors: Anja Bieberlehutter, Daniel Beckel, Anna Infortuna, Ulrich P Muecke, Jennifer L M Rupp, Ludwig J Gauckler, Samuel Reymermet, Paul Muralt, Nicole R Bieri, Nico HotzAbstract:Abstract The concept and the design of a micro-solid oxide Fuel Cell System is described and discussed. The System in this study is called the ONEBAT System and consists of the Fuel Cell PEN (positive electrode – electrolyte – negative electrode) element, a gas processing unit, and a thermal System. PEN elements of free-standing multi-layer membranes are fabricated on Foturan ® and on Si substrates using thin film deposition and microfabrication techniques. Open circuit voltages of up to 1.06 V and power of 150 mW cm −2 are achieved at 550 °C. The membranes are stable up to 600 °C. The gas processing unit allows butane conversion of 95% and hydrogen selectivity of 83% at 550 °C in the reformer and efficient after-burning of hydrogen, carbon monoxide, and lower hydrocarbons in the post-combustor. Thermal System simulations prove that a large thermal gradient of more than 500 °C between the hot module and its exterior are feasible. The correlation between electrical power output – System size and thermal conductivity – heat-transfer coefficient of the thermal insulation material are shown. The System design studies show that the single sub-Systems can be integrated into a complete System and that the requirements for portable electronic devices can be achieved with a base unit of 2.5 W and a modular approach.
