- NextGenBioWaste - Project objectives and overview

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Transcription:

- NextGenBioWaste - Project objectives and overview Lars Sørum SINTEF Energiforskning AS Coordinator of NextGenBioWaste Picture: Courtesy of ASM, Brescia, Italy 1

2 NextGenBioWaste in the big picture Reducing greenhouse gases and pollutant emissions (Kyoto) Increasing the security of supply by increasing the share of renewable energy production from biomass and waste Enhancing the competitiveness of European industry (Capitalising from European research) Improving quality of life both within the EU and globally (Johannesburg follow-up) International collaboration Contributions to standards

3 Energy from MSW combustion in Europe

4 Estimated Investment Costs/Benefits by Sector Source: Energy for the future: Renewable sources of energy, COM(97)599 final (26/11/1997)

5 State-of the-art Challenging fuels High chlorine/sulphur ratio High content of alkali metals High content of heavy metals (waste) The use of additives is not commercially proven High fuel costs (biomass) High ash content (waste)

6 State-of the-art Conversion technology Low electrical efficieny Severe corrosion and fouling High maintenance cost Co-combustion of waste wood up to 50% Residue management Poor utilisation of residues in general Leaching of heavy metals and other pollutants

7 Scope of NextGenBioWaste

8 The objective The objective of NextGenBioWaste is to demonstrate innovative ways of improving the energy conversion and renewable electricity production using municipal solid waste materials and biomass for large-scale supply of renewable electricity and heating/cooling to end-users - at a more competitive cost and improved environmental parameters.

9 Targets 1. Increase the electric efficiency for waste to energy plants from 22% to 30% (gross generated). 2. Double the lifetime of heat exchanger components at existing steam temperatures 3. Increase the electric efficiency for biomass combustion plants from 33% to 35%, while making the systems more cost-effective by the use of more low-grade fuels 4. Lower the fuel cost at least 1 mill. /year for a 100 MW th biomass combustion plant while maintain the two former sub targets (2 and 3). 5. Enable technologies for upgrading of bottom ash, thus, enabling the utility companies to valorise from 70% of their bottom ashes for civil engineering purposes

10 Technology advancement A full-scale demonstration of a retrofit fluidised bed bottom design for combustion of 100% of waste wood fuel in a 100 MWth biomass boiler Large-scale demonstration of advanced control systems enabling plant operators to obtain more stable conditions and improved electrical efficiency Large-scale tests of advanced boiler materials and cladding of superheater surfaces to reduce maintenance costs Large-scale demonstration of advanced combustion techniques using low excess air enabling more compact and cost-effective systems with higher electrical efficiency Full-scale demonstration of high-dust selective catalytic reduction (SCR) of NOx for improved electrical efficiency and environmental performance Full-scale demonstrations on the use of additives in order to reduce operation costs because of decreased fouling and to reduce maintenance costs via an increased lifetime Demonstration of novel design and retrofitting of boilers for improved efficiency Full-scale demonstration of artificial aging of bottom ashes for improved leaching properties giving added value products

11 Project management European Commision General Assembly All partners + EB Chairman Control Executive Board 6 members Chairman: Co-ordinator Overall Project Responsibility Major decisions Administrative Support Legal, financial, adm. staff Administrative work Project Manager and Co-ordinator (Sub-project 0) Project operation and lead Technical Advisory and Exploitation Committee Scientific Experts and end-users for the project Sub-project 1 SP+WP Leaders R&D Work + Demonstration Sub-project 2 SP+WP Leaders R&D Work + Demonstration Sub-project 3 SP+WP Leaders R&D Work + Demonstration Sub-project 4 All partners Dissemination

12 NEXTGENBIOWASTE SP 0 Project management and administration SP 1 Innovative fuel preparation and mixing SPL: VUAB SP 2 Conversion technologies SPL: TNO SP 3 Residue handling and use SPL: KEMA SP 4 Dissimination SPL SINTEF WP 1.1 Innovative fuel preparation and mixing. Research WP 2.1 Process control Research WP 3.1 Residue quality Research WP 4.1 Dissemination WP 1.2 Innovative fuel preparation and mixing. Demo. WP 2.2 Process control Demo WP 3.2 Residue quality Demo WP 2.3 Corrosion and sensors. Research WP 3.3 Ash treatment Research WP 2.4 Corrosion and sensors. Demo WP 3.4 Ash treatment Demo WP 2.5 Boiler optimisation Research WP 2.6 Boiler optimisation Demo

13 Progress report - SINTEF WP 1.1 Innovative fuel preparation and mixing - Research Lars Sørum, Edvard Karlsvik and Willy Horrigmo SINTEF Energy Research Partner no. 1

14 Objectives of WP 1.1 1. To study the importance of feedstock quality, preparation and mixing on flue gases and residues 2. To provide a basis for selecting fuels to be tested in large scale demonstration tests 3. To study previously published data on the effect of fuel additives and select additives for demonstration tests in boilers

15 The current multifuel reactor Vekt 5 independent heating elements within the reactor. Possible to control the vertical temperature profile Ceramic tube inside to prevent catalytic reactions. Length of reactor chamber: 1 m, diameter 100 mm. Max. temperature 900ºC Max. heatingrate 15ºC/min 4 flowcontrollers control the purge gas flow and composition

16 Current experimental set-up Balance Tar trap Tar trap Flue gas Filter Fuel basket Purge gas Reactor

17 Challenges and changes Providing conditions as close as possible to a large scale system Comparison of different fuels under the same conditions Batch feeding Not realistic compared to continously operating reactors Fixed bed or fluidised bed? Sampling of fly ashes Cooling/heating of flue gas line Filter or cyclone? Cut off size? Particle size distribution

18 Rebuilding the multifuel reactor

19 Flue gas and ash measurements Gas analysis FTIR: SO 2, HCl, NO, NO 2, N 2 O, CO, NH 3, HF, H 2 O, CO 2, HCN Gas analysis GC: CH 4, C 2 H 4 + C 2 H 2, C 2 H 6, H 2, O 2, N 2, CO, CO 2 Ash analysis Heavy metals: Cd, Hg, Pb, Cr, Cu, Mn, Ni, As, Ti, Sb, Co, V, Sn, Zn Alkali metals: K, P, Na, Si,

20 Hot filter Design with a flexible sampling temperature Flue gas temperatures ranging from 150 to 500 o C

21

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