Process intensification in fuel cell CHP systems, the ReforCELL project

José Luis Viviente; Sylvie Escribano; Giampaolo Manzolini; Marit Stange; Carlo Tregambe; Leonardo Roses; Arjan J.J. Koekkoek; Cécile Guignard; Arnaud Dauriat; Fausto Gallucci

doi:10.3390/pr4040037

Process intensification in fuel cell CHP systems, the ReforCELL project

José Luis Viviente^*
, Sylvie Escribano
, Giampaolo Manzolini
, Marit Stange
, Carlo Tregambe
, Leonardo Roses
, Arjan J.J. Koekkoek
, Cécile Guignard
, Arnaud Dauriat
, Fausto Gallucci

^*Autor correspondiente de este trabajo

Commissariat à l’énergie atomique et aux énergies alternatives
Polytechnic University of Milan
SINTEF
I.C.I CALDAIE SPA
HyGear B.V.
Hybrid Catalysis B.V.
Swiss Federal Institute of Technology Lausanne
Eindhoven University of Technology

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4 Citas (Scopus)

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Resumen

This paper reports the findings of a FP7/FCH JU project (ReforCELL) that developed materials (catalysts and membranes) and an advance autothermal membrane reformer for a micro Combined Heat and Power (CHP) system of 5 kWel based on a polymer electrolyte membrane fuel cell (PEMFC). In this project, an active, stable and selective catalyst was developed for the reactions of interest and its production was scaled up to kg scale (TRL5 (TRL: Technology Readiness Level)). Simultaneously, new membranes for gas separation were developed. In particular, dense supported thin palladium-based membranes were developed for hydrogen separation from reactive mixtures. These membranes were successfully scaled up to TRL4 and used in lab-scale reactors for fluidized bed steam methane reforming (SMR) and autothermal reforming (ATR) and in a prototype reactor for ATR. Suitable sealing techniques able to integrate the different membranes in lab-scale and prototype reactors were also developed. The project also addressed the design and optimization of the subcomponents (BoP) for the integration of the membrane reformer to the fuel cell system.

Idioma original	Inglés
Número de artículo	37
Publicación	Processes
Volumen	4
N.º	4
DOI	https://doi.org/10.3390/pr4040037
Estado	Publicada - 1 dic 2016

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title = "Process intensification in fuel cell CHP systems, the ReforCELL project",

abstract = "This paper reports the findings of a FP7/FCH JU project (ReforCELL) that developed materials (catalysts and membranes) and an advance autothermal membrane reformer for a micro Combined Heat and Power (CHP) system of 5 kWel based on a polymer electrolyte membrane fuel cell (PEMFC). In this project, an active, stable and selective catalyst was developed for the reactions of interest and its production was scaled up to kg scale (TRL5 (TRL: Technology Readiness Level)). Simultaneously, new membranes for gas separation were developed. In particular, dense supported thin palladium-based membranes were developed for hydrogen separation from reactive mixtures. These membranes were successfully scaled up to TRL4 and used in lab-scale reactors for fluidized bed steam methane reforming (SMR) and autothermal reforming (ATR) and in a prototype reactor for ATR. Suitable sealing techniques able to integrate the different membranes in lab-scale and prototype reactors were also developed. The project also addressed the design and optimization of the subcomponents (BoP) for the integration of the membrane reformer to the fuel cell system.",

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AU - Viviente, José Luis

AU - Escribano, Sylvie

AU - Manzolini, Giampaolo

AU - Stange, Marit

AU - Tregambe, Carlo

AU - Roses, Leonardo

AU - Koekkoek, Arjan J.J.

AU - Guignard, Cécile

AU - Dauriat, Arnaud

AU - Gallucci, Fausto

PY - 2016/12/1

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N2 - This paper reports the findings of a FP7/FCH JU project (ReforCELL) that developed materials (catalysts and membranes) and an advance autothermal membrane reformer for a micro Combined Heat and Power (CHP) system of 5 kWel based on a polymer electrolyte membrane fuel cell (PEMFC). In this project, an active, stable and selective catalyst was developed for the reactions of interest and its production was scaled up to kg scale (TRL5 (TRL: Technology Readiness Level)). Simultaneously, new membranes for gas separation were developed. In particular, dense supported thin palladium-based membranes were developed for hydrogen separation from reactive mixtures. These membranes were successfully scaled up to TRL4 and used in lab-scale reactors for fluidized bed steam methane reforming (SMR) and autothermal reforming (ATR) and in a prototype reactor for ATR. Suitable sealing techniques able to integrate the different membranes in lab-scale and prototype reactors were also developed. The project also addressed the design and optimization of the subcomponents (BoP) for the integration of the membrane reformer to the fuel cell system.

AB - This paper reports the findings of a FP7/FCH JU project (ReforCELL) that developed materials (catalysts and membranes) and an advance autothermal membrane reformer for a micro Combined Heat and Power (CHP) system of 5 kWel based on a polymer electrolyte membrane fuel cell (PEMFC). In this project, an active, stable and selective catalyst was developed for the reactions of interest and its production was scaled up to kg scale (TRL5 (TRL: Technology Readiness Level)). Simultaneously, new membranes for gas separation were developed. In particular, dense supported thin palladium-based membranes were developed for hydrogen separation from reactive mixtures. These membranes were successfully scaled up to TRL4 and used in lab-scale reactors for fluidized bed steam methane reforming (SMR) and autothermal reforming (ATR) and in a prototype reactor for ATR. Suitable sealing techniques able to integrate the different membranes in lab-scale and prototype reactors were also developed. The project also addressed the design and optimization of the subcomponents (BoP) for the integration of the membrane reformer to the fuel cell system.

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KW - Fluidized membrane reactor

KW - Hydrogen production

KW - Micro-CHP system

KW - PEM fuel cell

KW - Palladium membrane

KW - SMR

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M3 - Article

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JO - Processes

JF - Processes

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Process intensification in fuel cell CHP systems, the ReforCELL project

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