Development of the bioenergy sector
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- Kerrie Gilbert
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1 Development of the bioenergy sector Jean Marc Jossart AEBIOM Eberswalde, 8 December 2009
2 AEBIOM AEBIOM European Biomass Association Representing and promoting interests of bioenergy stakeholders 30 national associations 70 companies Activities : lobbying, workshops, newsletter, projects, etc. Based in Brussels Renewable Energy House
3 Statistics 2007 Gross final energy demand (ktoe) total : ktoe RES production (ktoe) Total : ktoe Transport ; ; 31% Electricity; ; 24% Transport ; 7.877; 7% Electricity; ; 38% Heat; ; 45% Heat; ; 55% Source : Eurostat Renewable heat (ktoe) Total : ktoe 1.217; 2% 387; 1% 938; 1% 777; 1% ; 82% 7.713; 12% 860; 1% Biogas (derived heat) Solid biomass (derived heat) Biowaste (derived heat) Solid biomass Geothermal Solar thermal Heat pumps
4 Why bioenergy? Developing alternatives to oil is essential Oil supply IEA reference scenario 120 mb/d NGLs Unconventional oil Crude oil fields yet to be developed or found Crude oil currently producing fields Source : World Energy outlook What future is this? Towards stronger and stronger oil companies! When is the next energy crisis expected? How can the economy run with unpredictable energy prices? Output of existing fields will decline by 2/3 by 2030! In BAU case (low RES) a EU country will pay high prices for CO2 emissions rights, RES credits and fossil energy!
5 Why bioenergy? Bioenergy generates jobs, also in rural areas Jobs in the RES sector in Germany Source : Energy Revolution, Greenpeace, from BMU Energy cannot be decentralised so easily. Recirculation of energy expenses in the local economy brings positive loop effect.
6 Why bioenergy? Biomass can be stored and converted in energy on demand.
7 Technologies Biomass technologies BioEnergy Forest and derived industries Wood logs Wood pellets Wood chips Stoves Boilers Space heating for buildings District heating Sanitary water Byproducts/ Wastes Cogeneration plant Heat for industrial process Agriculture and derived industries Crops and by-products like straw Wet biomass/ wastes Methanisation plant Cogeneration engine Methane in grid Bioelectricity Heat
8 Solid biomass fuels Wood logs Wood chips Pellets
9 Solid biomass fuels Volume necessary to store kwh energy (2000 l gasoil) Gasoil Wood logs Wood chips Pellets
10 Solid biomass fuels There are many possibilities to store pellets and wood chips Source : Geoplast
11 Heat small scale Wood log stove Pellets stove Pellets boiler Wood log boiler Wood chips Condensation technologies
12 Heat small scale Technology improvements towards higher efficiency and cleaner emissions Source : FJ BLT Wieselburg, 2005
13 Bioelectricity Electrabel, Les Awirs, 80 MWe, t pellets (100% of the fuel) MVV Energie AG plant, 20 MWe, t wood waste Source : Laborelec Alholmens Kraft, Pietarsaari, 240 MWe, m3 wood/hour Source : BBE Dong energy, Avedore Copenhagen, 570 MWe, fossil + straw, pellets Source :
14 Biomass supply demand Primary biomass Eurostat structure Import Gross inland consumption Export Heat Electricity Transport Input to electricity and CHP Input to DH Losses Bioelectricity Derived heat Final energy consumption Biomass for households and services Biomass for industry Biofuels Understanding the Eurostat energy structure is essential!
15 Biomass supply demand Import ktoe Primary biomass ktoe Export ktoe Targets 2020 Gross inland consumption ktoe 220 Mtoe Europe 27 Source : Eurostat for year 2007 Input to electricity and CHP ktoe Input to DH ktoe Losses ktoe Bioelectricity ktoe Derived heat ktoe 17,2 Mtoe Or GWh 34,5 Mtoe Biomass for households and services Biomass for industry ktoe Biofuels ktoe 30 Mtoe 40 Mtoe 73 Mtoe ktoe
16 Potential of biomass EEA potential
17 Potential of biomass EU 27 Biomass Potential by sector Mtoe Source : DG Agri, from BEE, 2008
18 Potential of biomass Pellets production and consumption in the world Source: ISO/TC 238 Business Plan; Second Draft 2009
19 Potential of biomass Biomass Supply in 2020
20 Energy crops Sweden Hemp 800 ha Willows ha CO2 tax of about 100 /t Large market/demand for biomass Support scheme for SRF plantation (500 /ha now) Finland Reed canary grass ha Large market/demand for biomass Mix with peat Emission Trading biomass as zero emission factor United Kingdom Willows 4000 ha Miscanthus 1000 ha Limited wood resources Energy crop support schemes ( /ha) ROCs for electricity- advantage for crops
21 Energy crops France Denmark Germany Miscanthus 1300 ha Sugar reform fund (64 M available) drying pulp Diversification from alfalfa pellets Waste water treatment/water table protection/sewage sludge Willows ha High biomass price SRC 1000 ha Miscanthus 325 ha Crops for biogas 5 to ha Electricity support schemes and bonuses Advanced biofuels/security of supply Energy crops development depends on national initiatives. EU priority is still weak (no mandatory measures in rural development programme).
22 Maximising the use of 1 ton oil equivalent (toe) Replaced fossil (toe) CO2 avoided (t) Bioheat in automatic boilers 0,9 toe 1 toe light fuel oil 3,1 1 toe biomass Bioelectricity - co-firing 0,35 toe Cogeneration bioheat 0,6 toe and bioelec. 0,25 toe 1 toe coal 0,67 toe light fuel oil 0,71 toe coal 4,6 4,9 2 nd generation biofuels (BtL) 0,4 toe 0,4 toe diesel 1,2 Source : AEBIOM calculations Bioheat and cogeneration are more effective for final energy production and CO2 reduction.!!!! Reduction per toe is different from % reduction!!!!
23 Maximising the use of 1 hectare land (ha) Rape - biodiesel 3 t/ha 450 l biodiesel/ t 32,7 MJ/l Gross energy per ha (toe) 1,0* CO2 avoided (t) 3,3 1 ha land Wheat - ethanol 7,5 t/ha 370 l ethanol/ t 21,2 MJ/l 1,4* 4,3 Sugar beet eth. 60 t/ha 100 l ethanol/ t 21,2 MJ/l 3,0* 9,3 Willow, misc. BtL 12 t/ha dry matter 212 l BtL/t 2,0 6,4 Maize - biogas 15 t/ha dry matter 600 m 3 biogas/ t 21,6 MJ/m 3 Source : AEBIOM calculations Land use should be optimised according to energy production and CO2 reduction 4,6 * + by-products 14,2
24 Thank you for your attention Jean-Marc Jossart