Bio-HyPPProject reference: 641073
Funded under :
H2020-EU.3.3. - SOCIETAL CHALLENGES - Secure, clean and efficient energy
H2020-EU.3.3.2. - Low-cost, low-carbon energy supply
H2020-EU.18.104.22.168. - Develop the full potential of wind energy
H2020-EU.22.214.171.124. - Develop efficient, reliable and cost-competitive solar energy systems
H2020-EU.126.96.36.199. - Develop geothermal, hydro, marine and other renewable energy options
Biogas-fired Combined Hybrid Heat and Power Plant
Total cost:EUR 5 775 868,75
EU contribution:EUR 5 775 868,5
Topic(s):LCE-02-2014 - Developing the next generation technologies of renewable electricity and heating/cooling
Call for proposal:H2020-LCE-2014-1See other projects for this call
Funding scheme:RIA - Research and Innovation action
To reach the goals of improving the efficiency of CHP systems while simultaneously widening the biomass feedstock base as well as increasing operational flexibility, the project aims to develop a full scale technology demonstrator of a hybrid power plant using biogas as main fuel in lab environment. A combined hybrid heat and power plant combines a micro gas turbine (MGT) and a solid oxide fuel cell (SOFC).
The focus of the technology demonstration plant is to prove the functional capability of the plant concept, followed by detailed characterization and optimization of the integration of both subsystems. The main objective is to move the technology beyond the state of the art to TRL 4.
Electrical efficiencies of more than 60% and total thermal efficiencies of more than 90% are intended to reach at base load conditions. An operational flexibility ranging from 25% to 100% electric power should be achieved. The emission levels should not exceed 10 ppm NOx and 20 ppm CO (at 15% vol. residual oxygen). The system should allow the use of biogas with methane contents varying from 40-75%, thus covering the biogas qualities from the fermentation of the entire biomass feedstock range.
To achieve the objectives the subsystems MGT and SOFC including their subcomponents have to be adjusted and optimized by a multidisciplinary design approach using numerical and experimental measures to ensure a proper balance of plant. In addition an integrated control system has to be developed and implemented to achieve a reliable operation of the coupled subsystems.
A detailed analysis of different European markets, economic and technical constraints in terms of biogas production potentials will clarify the regional suitable sizes and attractive performance conditions of the power plant system. To identify cost reduction potentials a thermo-economic analysis will be performed. Here, an internal rate of return (IRR) of the system of higher than 15% should be achieved over a 20 years.
EU contribution: EUR 2 432 017,5
EU contribution: EUR 1 296 406,25
DE RONDOM 1
EU contribution: EUR 89 611
EU contribution: EUR 623 125
VIA BALBI 5
EU contribution: EUR 417 500
55 GOWER STREET THIRD FLOOR HEATHROW CORPORATE PARK UNIT C1
WC1E 6HQ LONDON
EU contribution: EUR 448 458,75
DEN DOLECH 2
5612 AZ EINDHOVEN
EU contribution: EUR 377 500
Via San Nazaro 19
EU contribution: EUR 91 250
9726 AC GRONINGEN