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Changes between Version 2 and Version 3 of BioBoost


Ignore:
Timestamp:
02/10/16 21:03:46 (8 years ago)
Author:
gkronber
Comment:

partners

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  • BioBoost

    v2 v3  
    3131</div>
    3232
    33 <p>We have presented the software at multiple occasions</p>
     33<p>We have presented the software at multiple occasions
     34<ul>
     35 <li>enInnov 2016, Symposium Energieinnovation</li>
     36</ul>
     37</p>
    3438
    3539<h2>Thank you!</h2>
    36 
     40<p>
     41We thank all our partners who helped in the development of the BioBoost simulator and for allowing us to release all data!
     42<p>
     43<strong>KIT:</strong> KIT was the Coordinator of the project and investigated the fast pyrolysis pathway in the conversion work package 2. KIT led the work package 3 dedicated towards the chemical by-products of the hydrothermal conversion and pyrolysis.
     44</p>
     45<p>
     46<strong>CPERI/CERTH:</strong> The Chemical Process Engineering Research Institute CPERI was the leader of the work package 2 “Decentralized conversion technologies to an energy carrier” focusing on biomass catalytic pyrolysis for the production of fuels and chemicals.
     47</p>
     48<p>
     49<strong>AVA-CO2:</strong> AVA-CO2 contributed the hydrothermal carbonization technology (HTC) for wet biomass conversion. AVA-CO2 operates the first industrial size HTC plant in Karlsruhe.
     50</p>
     51<p>
     52<strong>CHIMAR:</strong> CHIMAR investigated the use of chemical green by-products for the development of thermosetting polymers.
     53</p>
     54<p>
     55<strong>EnBW:</strong> EnBW led the work package 5 “Applications of energy carrier” and contributed by providing test facilities for the use of energy carriers.
     56</p>
     57<p>
     58<strong>TNO:</strong> TNO (departments Industrial Innovation and Energy) was the leader of work package 6 “Techno-economic, social and environmental assessment of complete chains”. The focus was on the assessment of the techno-economic feasibility, environmental and social sustainability of the various value chains that could emerge from the energy carrier.
     59</p>
     60<p>
     61<strong>GRACE:</strong> GRACE developed, scale-up (to pilot scale) and evaluate novel micro-/meso-porous materials as catalysts for biomass pyrolysis.
     62</p>
     63<p>
     64<strong>IUNG:</strong> IUNG led the work package 1 and performed a feedstock potential assessment on the base of existing data about European biomass feedstock and converted it into the geographical information system (GIS). Which resulted, with the support of FHOÖ and SYNCOM, in the modeling of the biomass potential on European level and the development of a Geo-portal for results in GIS format.
     65</p>
     66<p>
     67<strong>NESTE:</strong> NESTE undertook the evaluation for the application of the catalytic pyrolysis oil for further treatment and estimated its composition. Also the applicability of different energy carriers to NESTE OIL refinery set was investigated.
     68</p>
     69<p>
     70<strong>SYNCOM:</strong> SYNCOM contributed its experience with the determination of feedstock costs, was responsible for the dissemination activities and assisted the consortium in administrative tasks.
     71</p>
     72<p>
     73<strong>DSM:</strong> To improve the economic and environmental balance of energy carrier chains DSM investigated methods for the recovery of high value chemicals and nutrients from pyrolysis condensates and HTC processes.
     74</p>
     75<p>
     76<strong>Universität Stuttgart:</strong> The Institute of Combustion and Power Plant Technology (IFK) is part of the University of Stuttgart and conducted combustion tests to evaluate the usability of the solid by-products from the bioliq and hydrothermal carbonization process in combustion systems.
     77</p>
     78<p>
     79<strong>DLR:</strong> DLR was involved in the application of the energy carriers by adaptation and testing of a FLOX®-based combustion system for pyrolysis oil.
     80</p>
    3781}}}