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1/23Dipl.-Ing. (EUR ING) Jan Kai Dobelmann MSc
DGS-Vize-PräsidentTorquay 11.10.2004
MicroCheapWork Package 5
2/23Dipl.-Ing. (EUR ING) Jan Kai Dobelmann MSc
DGS-Vize-PräsidentTorquay 11.10.2004
The DGS e.V.
www.dgs.deActivities of the DGS:
DGS-Newsletter weekly 3.700 readers
3/23Dipl.-Ing. (EUR ING) Jan Kai Dobelmann MSc
DGS-Vize-PräsidentTorquay 11.10.2004
Renewables2004, Bonn
Bonn
• political declaration (154 States)
Ministers and Government Representatives from 154 countries acknowledge that renewable energies combined with enhanced energy efficiency, can significantly contribute to sustainable development, thereby creating new economic opportunities.
They share the vision that renewable energies, combined with increased energy efficiency, will become a most important and widely available source of energy and will offer new opportunities for cooperation among all countries.
results:
4/23Dipl.-Ing. (EUR ING) Jan Kai Dobelmann MSc
DGS-Vize-PräsidentTorquay 11.10.2004
Renewables2004, Bonn
Bonn
• International Action Programme (194 Projects)
If implemented fully 22 Bilion tons of CO2 avoided by 2020
This is equivalent to 1 full yearly production of humanity!
results:
5/23Dipl.-Ing. (EUR ING) Jan Kai Dobelmann MSc
DGS-Vize-PräsidentTorquay 11.10.2004
results of climate change
Münchner Re AG:
Increase of covered insurance damage by large strom events since 1960
•Total damage x 3,6
•Insured costs x 9
hidden costs of fossil energy
6/23Dipl.-Ing. (EUR ING) Jan Kai Dobelmann MSc
DGS-Vize-PräsidentTorquay 11.10.2004
reserve development
Data: Exxon Mobil
Jon Thompson president of ExxonMobil Exploration “In other words, by 2015, we will need to find, develop and produce a volume of new oil and gas that is equal to eight out of every 10 barrels being produced today.”
Prof. Aleklett (Hydrocarbon Study Group) “To understand how impossible this is I like to make a comparison with the top production of 6 million barrels per day in the North Sea. The question is where can we find 10 new regions of the size of the North Sea?”
According to the rules of SEC, Securities and Exchange Commission, which made Shell downgrade the reserves by 20%, Saudi Aramco Inc. would have to downgrade their reserves by 50%.
7/23Dipl.-Ing. (EUR ING) Jan Kai Dobelmann MSc
DGS-Vize-PräsidentTorquay 11.10.2004
the future of energy
8/23Dipl.-Ing. (EUR ING) Jan Kai Dobelmann MSc
DGS-Vize-PräsidentTorquay 11.10.2004
Renewable energy potential
Solar radiation to earth: 150.000 x 1013 kWh
biomass potential: 152,4 x 1013 kWh
World energy consuption: 11,5 x 1013 kWh
9/23Dipl.-Ing. (EUR ING) Jan Kai Dobelmann MSc
DGS-Vize-PräsidentTorquay 11.10.2004
WP 5 in the project framework
WP4: Co-ordination of European research activities
Will exchange information with WP2, WP3 and WP5, and feed information to WP6
WP2: Elaboration of the current state of the art and market size
Will exchange information with WP3 and WP4 and feed information to WP6
WP3: Mapping of current research activities and centres of excellence
Will exchange information with WP2 and WP4, and feed information to WP5 and WP6
WP5: Investigation of links between renewable energy systems and micro-CHP
Will receive input from WP2 – WP4, and feed information to WP6
WP6: Technology transfer and staff secondments
Will make use of results from WP2 – WP5
Start Month 13
End Month 30
10/23Dipl.-Ing. (EUR ING) Jan Kai Dobelmann MSc
DGS-Vize-PräsidentTorquay 11.10.2004
Tasks of the partners I
Work package number: 5 Start date or starting event: Month 13 Title: Investigation of links between renewable energy systems and micro-CHP
Leader: DGS
Participant ID Person-months
Partner roles
DGS 3 Co-ordinate all technological investigation, to ensure no duplication between partners. Lead analysis of technologies to highlight the most promising systems. Investigate technologies that can be linked to geothermal, and solar systems
EC NET 1.5 Lead consideration of industrial, and market relevance of potential technologies. Cost analysis of technologies compared to existing micro-CHP systems and modern central heating systems
BTG 2.5 Specification of the most promising biomass conversion systems to be linked with micro-CHP. Documentation of the potential for liquid biofuels to be used within micro-CHP engine systems
CRES 1.25 Investigation of the potential for biomass to be linked with fuel cells. Documentation of biomass to hydrogen conversion systems
STSL 0.5 Evaluate the potential of non-Stirling combustion engines to be developed into renewable micro-CHP systems. Aid in the analysis of technologies for their industrial potential
FHG-ISE 1 Evaluate potential of low band-gap photovoltaic cells for the conversion of heat radiation into electricity
EAT 1 Aid in the consideration of technologies for their industrial and market potential. Consider highlighted technologies with regards to market trends and predicted future market scenarios and energy pricing
GAIA 0.5 Aid in the evaluation of technologies with regards to market trends and future scenarios
ECN 0.75 Investigate the potential for existing types of Stirling engines for the potential to be linked with new renewable energy systems. To highlight technologies that aid the integration of Stirling engines with renewable systems
LUND 0.9 Aid ECN in the investigation of Stirling engines, renewable energy systems, and integration technologies
CHALEX 0.75 Investigate the potential for thermoelectric technology to be integrated into micro-CHP systems
UB 0.75 Investigation for the potential of biogas within existing micro-CHP systems CODES 2 Planning of format for work package review. Collection of information,
preparation of documentation, and distribution to partners. Distribute documentation through appropriate dissemination channels
ISET 0.25 Assist DGS and FHG-ISE with analyses of solar technologies DK TEKNIK 0.5 Evaluate potential of straw and other biomasses as fuels for CHP and micro-
CHP systems BEAMA 0.5 Contribution from SME perspective and dissemination AUE 0.25 Assist DK TEKNIK with its tasks AF
0.5 Micro-CHP, small-scale combustion, renewable fuels
ASTON 0.5 Assist DK TEKNIK with its tasks ARMINES 0.75 Contribution of expertise relating to advanced modelling of complex energetic
systems TOTAL 19.65 Labour cost (€) 127,560
11/23Dipl.-Ing. (EUR ING) Jan Kai Dobelmann MSc
DGS-Vize-PräsidentTorquay 11.10.2004
Tasks of the partners II
Work package number: 5 Start date or starting event: Month 13 Title: Investigation of links between renewable energy systems and micro-CHP
Leader: DGS
Participant ID Person-months
Partner roles
DGS 3 Co-ordinate all technological investigation, to ensure no duplication between partners. Lead analysis of technologies to highlight the most promising systems. Investigate technologies that can be linked to geothermal, and solar systems
EC NET 1.5 Lead consideration of industrial, and market relevance of potential technologies. Cost analysis of technologies compared to existing micro-CHP systems and modern central heating systems
BTG 2.5 Specification of the most promising biomass conversion systems to be linked with micro-CHP. Documentation of the potential for liquid biofuels to be used within micro-CHP engine systems
CRES 1.25 Investigation of the potential for biomass to be linked with fuel cells. Documentation of biomass to hydrogen conversion systems
STSL 0.5 Evaluate the potential of non-Stirling combustion engines to be developed into renewable micro-CHP systems. Aid in the analysis of technologies for their industrial potential
FHG-ISE 1 Evaluate potential of low band-gap photovoltaic cells for the conversion of heat radiation into electricity
EAT 1 Aid in the consideration of technologies for their industrial and market potential. Consider highlighted technologies with regards to market trends and predicted future market scenarios and energy pricing
GAIA 0.5 Aid in the evaluation of technologies with regards to market trends and future scenarios
ECN 0.75 Investigate the potential for existing types of Stirling engines for the potential to be linked with new renewable energy systems. To highlight technologies that aid the integration of Stirling engines with renewable systems
LUND 0.9 Aid ECN in the investigation of Stirling engines, renewable energy systems, and integration technologies
CHALEX 0.75 Investigate the potential for thermoelectric technology to be integrated into micro-CHP systems
UB 0.75 Investigation for the potential of biogas within existing micro-CHP systems CODES 2 Planning of format for work package review. Collection of information,
preparation of documentation, and distribution to partners. Distribute documentation through appropriate dissemination channels
ISET 0.25 Assist DGS and FHG-ISE with analyses of solar technologies DK TEKNIK 0.5 Evaluate potential of straw and other biomasses as fuels for CHP and micro-
CHP systems BEAMA 0.5 Contribution from SME perspective and dissemination AUE 0.25 Assist DK TEKNIK with its tasks AF
0.5 Micro-CHP, small-scale combustion, renewable fuels
ASTON 0.5 Assist DK TEKNIK with its tasks ARMINES 0.75 Contribution of expertise relating to advanced modelling of complex energetic
systems TOTAL 19.65 Labour cost (€) 127,560
12/23Dipl.-Ing. (EUR ING) Jan Kai Dobelmann MSc
DGS-Vize-PräsidentTorquay 11.10.2004
WP5 Objectives + Results
Objectives:• To identify renewable energy technologies to be combined with micro-CHP systems• To assess the market feasibility of new renewable micro-CHP systems in comparison with systems analysed in WP1• To steer future research in micro-CHP towards sustainable energy systems
Deliverables:
D21 Documented review of technological links to renewable energy systems and market potential (Month 30)
Expected results and corresponding milestones:
M5.1 Identification of suitable technologies for investigation (Month 18)
13/23Dipl.-Ing. (EUR ING) Jan Kai Dobelmann MSc
DGS-Vize-PräsidentTorquay 11.10.2004
WP 5 description of work
Description of work:
• identify technologies for new renewable micro-CHP systems or conversion with renewable energy sources. • Basis on information from WP1 and WP2.• Technology criteria:Efficiency of energy conversion, Cost of production, Reliability and maintenance, Cost of integration, Environmental benefits and impact, payback time, costs of energy production outlined within WP, existing research recorded within WP2 • Feasibility studies on new or converted technologies. • Evaluation of the results for overcoming the barriers of implementation highlighted within WP1.