A Flexible natural gas membrane Reformer for m-CHP applications

FERRET
Project Information
Framework Programme: 
FP7
Call for proposals: 
2013
Application area: 
Stationary power production and CHP
Logo: 

The potential for fuel CHP units in Europe as a large market in the future is in general well recognised. Although the size of this market is large and is undisputed when the cost targets of m-CHP units is reached, it is often overlooked that it is a very segmented market. All micro-CHP units, as new heating appliances, will have to be certified against the Gas Appliance Directive (90/396/CE). The latest legislation in Europe and some specific countries, which is expected will be adopted by other countries will lead to a broader range of natural gas specifications per country with larger differences of natural gas qualities.

- And last and most important: the gas quality is allowed to change more rapidly in time. In future, more oxygen will be present in natural gas. Now, in Europe actions are taken (regulatory actions) to allow even more fluctuations of the gas composition in time over a day. This means that not only the fuel processor should be efficient in reforming NG to hydrogen, but should be also very robust and flexible, reducing the possibility of hot spots and low selectivity when the oxygen content increases. Within FERRET, we will design the reactor, balance of plant and revise the controls to allow the sudden change of natural gas specification that can be expected in the field in the coming years.

According to the problems mentioned above, FERRET project will:

  • Design a flexible reformer in terms of catalyst, membranes and control for different natural gas compositions.
  • Use hydrogen membranes to separate pure hydrogen and help shifting all the possible H2 production reactions towards the products, thus reducing side reactions.
  • Scale up the new H2 selective membranes and catalysts production
  • Introduce ways to improve the recyclability of the membranes.
  • Integrate the novel reforming in a CHP system
  • Optimize of the BoP for the novel reforming CHP system
  • Simulate and optimize of the reformer integration with the entire system.
Project details
Project reference: 
621181
Topic: 
SP1-JTI-FCH.2013.3.3: Stationary Power and CHP Fuel Cell System Improvement Using Improved Balance of Plant Components/Sub-Systems and/or Advanced Control and Diagnostics Systems
Project type: 
Research and technological development
Contract type: 
Collaborative Project
Start date: 
Tuesday, April 1, 2014
End date: 
Friday, March 31, 2017
Duration: 
36 months
Project cost: 
€ 3,202,767
Project funding: 
€ 1,730,663.00
Coordinator: 

TECHNISCHE UNIVERSITEIT EINDHOVEN, NL

Contact: 
Dr. Fausto Gallucci
Contact email: 
Other participating organisations: 
FUNDACION TECNALIA RESEARCH & INNOVATION ES
POLITECNICO DI MILANO IT
ICI CALDAIE SPA IT
HyGear B.V. NL
JOHNSON MATTHEY PLC UK
Linkedin