1. Biomass to Energy in Germany Past – Present – Future an Overview Prof. Dr. Bernd Stephan University of Applied Science Bremerhaven, Germany

2. Structure of Energy Consumption World - EC25 – Germany (IEA/BEE-eV) WorldEC25Germany (2003)(2003)(2005) (%) (%) Natural Gas19.5228.832.1 Nuclear2.54 6.43 5.7 Renewables20.34 8.57 6.4 Coal13.86 9.0518.1 Mineral oil43.7147.1537.7 Total (TWh/year)84 744100802 936

3. Energy Consumption Germany 2002 to 2005, BEE-eV 200220042005 % Natural Gas21.722.432.1 Nuclear12.612.6 5.7 Renewables 3.4 3.6 6.4 Lignite11.611.4 8.7 Mineral Coal13.213.4 9.4 Mineral Oil37.536.4 37.7

4. Utilization of Renewables in Germany in 2004 (%) Biomass solid44.1 Biomass liquid 0.1 Biomass gaseous 6.3 Solar thermal 1.8 Geothermal 1.1 Waste 6.4 Biodiesel 7.2 Rape oil/ethanol 0.4 Hydropower14.7 Wind energy17.5 Photovoltaic 0.3

5. Primary Energy for Generating Electricity in Germany Lignite27% Lignite27% Nuclear Power27% Nuclear Power27% Coal24% Coal24% Renewables12% Renewables12% (including hydropower) (including hydropower) Natural gas 9% Natural gas 9% Fuel oil 1% Fuel oil 1%

6. German Energy Imports 2005 Source: IEA, Federal Office for Economy Germany Mineral oilRussia34.1% Norway14.7% Great Britain12.7% Natural GasRussia42.6% Norway30.1% Netherlands22.5% CoalSouth Africa22.9% Poland22.0% Russia15.7%

7. What is meant by „Biomass“ ? Materials produced by metabolic activities of biological systems and/or products of their decomposition or conversion Materials produced by metabolic activities of biological systems and/or products of their decomposition or conversion The materials are based on carbon compounds The materials are based on carbon compounds The chemical and energetic value of those materials is based on the carbon-carbon and carbon-hydrogen bond The chemical and energetic value of those materials is based on the carbon-carbon and carbon-hydrogen bond Biomass suitable for utilization must have a net heating value Biomass suitable for utilization must have a net heating value Biomass is collected and stored solar energy Biomass is collected and stored solar energy

8. Sources of Biomass agriculture agriculture residues from forestry, specific industries (e.g. furniture production, saw dust), food processing residues from forestry, specific industries (e.g. furniture production, saw dust), food processing solid municipal and industrial wastes solid municipal and industrial wastes used wood e.g. from old furniture, used timber used wood e.g. from old furniture, used timber marine systems: the oceans of our world contain much more biomass than existing on the continents (but they are not regarded as a source of biomass for energetic utilization) marine systems: the oceans of our world contain much more biomass than existing on the continents (but they are not regarded as a source of biomass for energetic utilization)

9. Biomass contributions to energy supply in Germany: thermal energy Wood Wood Wood residues Wood residues Municipal waste Municipal waste Sewage sludge Sewage sludge Agricultural waste Agricultural waste

10. Biomass contributions to energy supply in Germany: electrical energy Wood Wood Biogas Biogas Waste incineration Waste incineration Fermentation of sewage sludge Fermentation of sewage sludge Biogas from industrial waste water Biogas from industrial waste water

11. Biomass Conversion Microbial treatment Microbial treatment Thermal treatment Thermal treatment Chemical treatment Chemical treatment Combinations Combinations Mechanical processes Mechanical processes

12. Microbial Treatment Long traditions in many cultures in the field of food processing e.g. beer brewing, alcoholic fermentation, preservation technologies as lactic acid fermentation Long traditions in many cultures in the field of food processing e.g. beer brewing, alcoholic fermentation, preservation technologies as lactic acid fermentation Waste treatment in agriculture and food industry by aerobic treatment (composting) and anaerobic fermentation Waste treatment in agriculture and food industry by aerobic treatment (composting) and anaerobic fermentation Treatment of municipal and industrial waste water Treatment of municipal and industrial waste water (Pre)Treatment of solid waste containing organic materials (Pre)Treatment of solid waste containing organic materials

13. Alcoholic fermentation Fermentation and destillation: ethanol and residues Processing and recycling of residues Agriculture: production of carbohydrates as raw material

14. Aerobic Processes Agricutural wastes: Traditional method: composting Treatment of solid urban waste: Technology with good prospects Pretreatment of hazardous waste Treatment of gaseous phases for desodorizing (e.g. compost filters in fish industry)

15. Composting Composting is a traditional technology in agriculture and gardening. Today there are processes of treatment of municipal waste which make use of the heat of composting for drying the solid waste before separation under investigation. There is no significant contribution to the energy supply of Germany by composting of biomass. Composting is a traditional technology in agriculture and gardening. Today there are processes of treatment of municipal waste which make use of the heat of composting for drying the solid waste before separation under investigation. There is no significant contribution to the energy supply of Germany by composting of biomass. Composting of mixtures of municipal and organic waste of food industry is implemented in many cities Composting of mixtures of municipal and organic waste of food industry is implemented in many cities

16. Anaerobic Digestion: Biogas History History in Germany starting with utilization of „marsh gas“ in the 19th century: gas tight drums with an diameter of about 2 to 3 meter were placed upside down into the wet lands for gas collection and gas utilization for cooking – similar to the Indian Gabor Gas plant History in Germany starting with utilization of „marsh gas“ in the 19th century: gas tight drums with an diameter of about 2 to 3 meter were placed upside down into the wet lands for gas collection and gas utilization for cooking – similar to the Indian Gabor Gas plant Around 1920 trucks of public services were operated with compressed biogas from digestion of sewage sludge – in the fifties of the 20th century this was given up due to low cost mineral oil Around 1920 trucks of public services were operated with compressed biogas from digestion of sewage sludge – in the fifties of the 20th century this was given up due to low cost mineral oil In the fifties of last century some farmers built biogas plants for the treatment of aninmal wastes – the technology was based on different principles and processes In the fifties of last century some farmers built biogas plants for the treatment of aninmal wastes – the technology was based on different principles and processes The oil price crisis in the seventies stimulated broad activities on the research and implementation side of agricultural biogas plants and resulted in optimized plant design and process performance. About 200 plants were bulit and operated at that time, but could not compete with the market prices for gas or liquid hydrocarbons. The oil price crisis in the seventies stimulated broad activities on the research and implementation side of agricultural biogas plants and resulted in optimized plant design and process performance. About 200 plants were bulit and operated at that time, but could not compete with the market prices for gas or liquid hydrocarbons. The energy policy of German Federal Government now subsidies the utilization of renewables – as a result the market for big biogas plant goes up (most of them are connected to cogeneration plants) The energy policy of German Federal Government now subsidies the utilization of renewables – as a result the market for big biogas plant goes up (most of them are connected to cogeneration plants)

17. Potential of Biogas Animal excreta 4.5 Animal excreta 4.5 Vegetable residues from agriculture 3.0-5.3 Vegetable residues from agriculture 3.0-5.3 Wastes from Industry 0.3-0.6 Wastes from Industry 0.3-0.6 Waste from parks and gardens 0.3-0.6 Waste from parks and gardens 0.3-0.6 Organic municipal waste 0.6 Organic municipal waste 0.6 Energy crops 3.7 Energy crops 3.7 TOTAL 12.7-15.3 TOTAL 12.7-15.3 Potential of Potential of total (PJ/year)electric. (TWh/a) total (PJ/year)electric. (TWh/a) 96.57.2 65-1134.9-8.5 6.4-12.20.5-0.9 6.4-12.20.4-0.8 12.50.9 78.75.9 265.1-324.919.8-24.2 (billion m 3 /a)

18. Thermal and Chemical Processes Combustion Combustion Pyrolysis Pyrolysis Chemical Prozesses: hydrogenation, transesterification Chemical Prozesses: hydrogenation, transesterification Process combinations (e.g. the Choren- Process: BTL „biomass to liquid“) Process combinations (e.g. the Choren- Process: BTL „biomass to liquid“)

19. Mechanical Processes Filtering Filtering Dewatering Dewatering Sedimetation Sedimetation Chopping/Cutting Chopping/Cutting Pelletising Pelletising

20. Conversion Technologies – state of the art Biogas Biogas Incineration Incineration Pyrolysis Pyrolysis BTL (Biomass to liquid) BTL (Biomass to liquid)

21. Anaerobic Digestion of Sewage Sludge Sewage sludge is fermented and used to cover the energy demand of the waste water treatment plants. By doing this those plants need no external energy. The biogas is used for cogeneration of heat for the digesters an electricity for the aerobic waste water purification process (energy for pumping and aeration of the waste water).

22. Wood Incineration Units Normally chopped wood or chopped woodv residues are used as feeding materials for large cogeneration plants Normally chopped wood or chopped woodv residues are used as feeding materials for large cogeneration plants For the heating of households pelletised materials are available. By using them the incineration process can be operated automatically. The cost for the pelletized wood in relation to mineral oil come to about 2/3 For the heating of households pelletised materials are available. By using them the incineration process can be operated automatically. The cost for the pelletized wood in relation to mineral oil come to about 2/3

23. Wood Incineration Plants - practical examples -

24. 200kW-Plant for heat production Feed: chopped from forestry, 50 kg/h Feed: chopped from forestry, 50 kg/h Density of feed material: 0.25 kg/liter Density of feed material: 0.25 kg/liter Efficiency: 0.85 Efficiency: 0.85 1600 hours of operation per year 1600 hours of operation per year Feed need per year: 380 m 3 Feed need per year: 380 m 3 Storage capacity for 2-3 weeks: 40 m 3 Storage capacity for 2-3 weeks: 40 m 3

25. 19.5 MW – Plant for gerating heat and electricity Input „fresh“ and old wood chops, 5.33 t/h max Input „fresh“ and old wood chops, 5.33 t/h max Steam production: 25.5 t/h at 47 bar/430 o C), steam outlet from turbine: 2.2 bar/126 o C Steam production: 25.5 t/h at 47 bar/430 o C), steam outlet from turbine: 2.2 bar/126 o C Operation 8000 hours per year Operation 8000 hours per year Energy output electrical from 3.8 to 5.1 MW depending on heat delivery for the households Energy output electrical from 3.8 to 5.1 MW depending on heat delivery for the households Energy output thermal: maximum 10 MW Energy output thermal: maximum 10 MW

26. Wood – a big potential in the forests In Germany there are growing about 60 to 100 millions of m 3 wood per year, that can be harvested In Germany there are growing about 60 to 100 millions of m 3 wood per year, that can be harvested That is an energtic equivalent of about 1.5 to 2.5 TWh/a That is an energtic equivalent of about 1.5 to 2.5 TWh/a Compared to the actual energy consumtion of Germany this is a potential of 50 to 80 % Compared to the actual energy consumtion of Germany this is a potential of 50 to 80 % Actual energetic utilization of wood comes to 0.09 TWh/a only Actual energetic utilization of wood comes to 0.09 TWh/a only

32. Market prices for selected materials -current prices- Wood chops 50€ per 1000kg Wood chops 50€ per 1000kg Wood pellets (dry)200€ per 1000kg Wood pellets (dry)200€ per 1000kg Wood, fresh50-80 € per m 3 Wood, fresh50-80 € per m 3 Biodiesel based on rape oil0.95 € per Liter Biodiesel based on rape oil0.95 € per Liter Wheat100 € per 1000kg Wheat100 € per 1000kg Mineral oil650 € per 1000 Liters Mineral oil650 € per 1000 Liters

33. Energy content of wood based substrates average data water content calorific value oil equivalent (%)(kWh/kg)L oil/m 3 Pieces204165 Pellets105325 Chops204100 Saw dust402.670 ----------------------------------------------------------------------------------------------- Wheat154400 L/1000 kg

34. Waste Incineration - Example: Bremerhaven - Capacity: 315 000 tons/year Capacity: 315 000 tons/year Energy output: 100 000 000 kWh/year electrical and 250 000 000 kWh/ year thermal Energy output: 100 000 000 kWh/year electrical and 250 000 000 kWh/ year thermal

37. Biomass as fuel, biomass to fuel 1 Vegetable oil, fresh and used 1 Vegetable oil, fresh and used 2 Modified vegetable oil, biodiesel 2 Modified vegetable oil, biodiesel 3 Bioethanol 3 Bioethanol 4 Biogas 4 Biogas 5 Synthetic fuels 5 Synthetic fuels

38. Implementation Biofuels 1 to 4: proven technology of production and application proven technology of production and application 5: Under intense investgation with great potential: „sun fuel“, „BTL, Biomass to Liquid“

40. Biomas To Liquid: SunFuel (Choren) Modified „Fischer-Tropsch“ process: gasification of substrates at 400 to 500 o C with lack of oxygen, further oxidation above ash melting point, mixing of resulting gas mixture with solid carbon residues to produce a raw gas for furher specific synthesis (similar Fischer-Tropsch) Modified „Fischer-Tropsch“ process: gasification of substrates at 400 to 500 o C with lack of oxygen, further oxidation above ash melting point, mixing of resulting gas mixture with solid carbon residues to produce a raw gas for furher specific synthesis (similar Fischer-Tropsch) 15 000 ton/year pilot plant is under operation 15 000 ton/year pilot plant is under operation Cooperation with Shell, based on Gas to Liquid process, operated in Malaysia Cooperation with Shell, based on Gas to Liquid process, operated in Malaysia

41. The Hydrogen Problem CHO*) Methane0.750.25- „Mineral Oil“0.850.15- „Mineral Coal“0.830.050.12 Biomass0.500.070.43 *) fractions by weight, rough figures

42. Potential for SunFuel from… (million tons per year) Forestry 2.5 Forestry 2.5 Unused straw4.0 Unused straw4.0 Energy crops3 to 6 Energy crops3 to 6 Biomass available total Biomass available total (Germany) 30 (Germany) 30 EU 25115 EU 25115

43. Fuel Consumption (million tons per year) 200550 200550 2020 (exp)44 2020 (exp)44 2005 Biodiesel(est.)1.4 2020 Biodiesel (exp.)11.1

44. Future The future development will be based on increasing production of energy crops, optimized utilization of organic residues and on thermal- chemical treatment of organic matter to produce gaseous and liquid fuels. The future development will be based on increasing production of energy crops, optimized utilization of organic residues and on thermal- chemical treatment of organic matter to produce gaseous and liquid fuels. There are lot of estimations for future contributions of biomass to energy supply, they will come to at least 20 or 30 percent until 2020. There are lot of estimations for future contributions of biomass to energy supply, they will come to at least 20 or 30 percent until 2020.

45. Windenergy in Germany 2005 German Association for Windenergy Total installed capacity18 400 MW Total installed capacity18 400 MW Number of converters17 5784 Number of converters17 5784 Installed in 2005: 1049 new plants with a total capacity of 1800 MW Installed in 2005: 1049 new plants with a total capacity of 1800 MW New installations expected for 2006: 1500 MW New installations expected for 2006: 1500 MW Increasing market for German export Increasing market for German export

46. Proposed Future Installation of Power Plants in Germany - not from Renewables Capacity23 000 MW (2012) Capacity23 000 MW (2012) Capacity40 000 MW (2020) Capacity40 000 MW (2020) Total Investment40 billion € Total Investment40 billion €