This shall be achieved by integrating a novel and highly efficient biomass micro-CHP technology based on an updraft gasifier, a gas cleaning system and a solid oxide fuel cell (SOFC), a state-of-the-art PV system and appropriate innovative energy storage solutions.
This system shall not only satisfy the energy demands of the building but also distinguish itself by virtually zero emissions of CO, OGC and particulate matter and 55% to 65% reduced NOx emissions compared to other biomass-based CHP technology.
System
Description
The project aims at the development of an innovative RES-based system for heat and electricity supply in order to achieve an almost energy autonomous multi-family building with regard to heating and electricity consumption as well as electro-mobility. This shall be achieved by integrating a novel highly efficient biomass micro-CHP technology based on an updraft gasifier, a new gas cleaning system and a solid oxide fuel cell (SOFC), a state-of-the-art PV system and appropriate innovative energy storage solutions.
This system shall be economically highly attractive for future users and it shall also distinguish itself by virtually zero emissions of CO, OGC and dust as well as 55% to 65% reduced NOx emissions compared to other biomass CHP technologies. Consequently, it shall increase the penetration of RES on the multi-family house level and has the potential to significantly contribute to reaching the EU climate and clean air goals. The key innovations of the project are related to the novel micro-scale biomass CHP system.
They comprise a flexible partitioning of product gas supplied to the SOFC and to a gas burner in order to cover the overall heat demand and to maximize SOFC operation at the same time, a novel combined thermal and catalytic tar reformer, new highly efficient and durable stack units and a novel compact SOFC system with integrated HCl and H2S removal reactor. Based on a 2.5 kWel SOFC with an electric efficiency of 44%, which is flexibly coupled with a 14 kW gasifier, overall efficiencies of more than 90% shall be gained. A TRL of 5 shall be achieved at the end of the project.
The methodology applied to reach these goals relies on technology development tasks (based on process simulations, CFD aided design of the single units, test plant construction, performance and evaluation of test runs), a technology assessment part covering risk, techno-economic, environmental and overall impact assessments as well as targeted dissemination activities.
Disclaimer of warranties
This project has received funding from the European Union’s Horizon Europe research and innovation programme under Grant Agreement No 101083409.
This document has been prepared by the Micro-Bio-CHP project partners as an account of work carried out within the framework of the EC-GA contract no 101083409.
Neither the Project Coordinator, nor any signatory party of the Micro-Bio-CHP Project Consortium Agreement, nor any person acting on behalf of any of them:
- makes any warranty or representation whatsoever, express or implied,
- with respect to the use of any information, apparatus, method, process, or similar item disclosed in this document, including merchantability and fitness for a particular purpose, or
- that such use does not infringe on or interfere with privately owned rights, including any party's intellectual property, or
- that this document is suitable to any particular user's circumstance; or
- assumes responsibility for any damages or other liability whatsoever (including any consequential damages, even if the Project Coordinator or any representative of a signatory party of the Micro-Bio-CHP Project Consortium Agreement, has been advised of the possibility of such damages) resulting from selection or use of this document or any information, apparatus, method, process, or similar item disclosed in this document.