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Biomass CHP

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... plants 15 grate-fired steam boiler ... collect reliable data Different technolgies covered 19 biogas and landfill gas plants 4 gasification plants 10 CFB ... – PowerPoint PPT presentation

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Title: Biomass CHP


1
Biomass CHP best practiceConclusions and
recommendations
  • Anders Evald, Janet Witt, Kati Veijonen
  • Harrie Knoef, Johan Vinterbäck, Elvira Lutter
  • Vienna 9 March 2006

2
Project aims
  • Promote biomass CHP in Europe and highlight
    plants with the best operation
  • Provide e.g. authorities and future plant owners
    with information about typical plant performance
    and about best available technologies.
  • Enable benchmarking, identify the improvement
    potential of the existing European CHP plants
  • Replicate best practices
  • Challenge collect reliable data

3
Different technolgies covered
  • 19 biogas and landfill gas plants
  • 4 gasification plants
  • 10 CFB (circulating fluidized bed) plants
  • 11 BFB (bubbling fluidized bed) plants
  • 15 grate-fired steam boiler plants using
    uncontaminated biomass
  • 8 grate-fired steam boiler plants using municipal
    solid
  • waste (MSW) as a fuel
  • 1 dust fired steam boiler plant

4
Fuels covered
  • Solid biomass
  • Forest fuels
  • Forest industry by-products such as bark, sawdust
    etc.
  • Wood pellets
  • Agricultural residues such as straw, husk etc.
  • Municipal solid waste
  • Landfill gas
  • Manure etc. for biogas plants
  • Fossil fuels
  • Heavy fuel oil
  • Natural gas
  • Coal

5
Key performance indicators
  • availability
  • utilisation period
  • total efficiency
  • fuel input biofuels vs. fossil fuels
  • nominal efficiency vs. operational efficiency
  • own power consumption
  • total efficiency on monthly basis

6
Gasification plantsUtilization factor the
extent, to which installed power is
utilisedAvailability factor the extent, to
which the plant is available for operation
7
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8
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9
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10
Gratefired boiler plants
11
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12
Ranked to increasing capacity
13
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14
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15
Cross technology comparison
16
Plant size
17
Electric efficiency
18
Total efficiency
19
Utilization
20
Availability
21
Conclusions and recommendations
  • Bigger is better
  • Higher efficicency
  • Lower own consumption
  • Better availability
  • Lower specific investment
  • But constrained by heat marked, and not
    necessarily true for biogas plants

22
Capacity and utilization
  • Plants are bigger than simply justified by the
    heat market
  • High electricity price
  • Optimizing tariff income
  • Heat accumulator
  • Plants built for the future
  • Plant nominal capacity is too optimistic very
    few plant perform anywhere near their anticipated
    (nominal) efficiency in practical operation
  • Economic optimization
  • Not too small
  • Not too big
  • Low utilization poor payback on invested
    capital

23
CHP or not CHP
  • Many plants are not 100 dependent on heat market
    (combined heat and power only as a fraction)
  • German biogas plants produce very little heat,
    and they dont meassure it
  • Premium price for electricity not allways require
    full combined production
  • Incentive for RE, but not for the most efficient
    RE
  • Large plants (MSW) cannot connect enough heat
    demand

24
Balancing heat and power
  • Energy efficiency electricity is the premium
    product heat is a by-product
  • Valid also money-wise
  • But not allways nordic heat markets show high
    value for heat
  • Industrial facilities might see steam as the main
    product and electricity as a byproduct

25
Choosing the right technology
  • Large difference in electric efficiency
  • Low electric efficiency is compensated by more
    heat
  • Heat market set the framework
  • Steam cycles go for high steam data
  • Retrofitting old equipment to improve efficiency
    and reduce own consumption

26
Industrial systems
  • A more fragile heat market
  • Industries change
  • Operated according to steam demand less power
    and low utilization

27
Reducing own consumption
  • Big difference depending on choice of technology
  • Option for improvement in old plants
  • Low efficiency lead to high own concumption

28
Operational problems
  • New challenges for plant operators
  • Fuel quality problems (feed systems, moisture
    content, flue gas fans etc.)
  • Sintering bed material
  • Fouling heat transfer surfaces
  • Decrease efficiency and high temperature
    corrosion
  • Result lower efficiencies, higher maintenance
  • Exchange experience!

29
Some concluding remarks 1
  • Technology implemented must be mature
  • Proven prototype models
  • Long-term duration tests
  • Adequate infrastructure
  • Local manufacturing capacity
  • After-sale service
  • Training facilities
  • Sustainable feedstock supply
  • Motivated skilled labor
  • Operators, Management
  • Incentives

30
Some concluding remarks 2
  • Information knowledge exchange
  • Performance, limitations, opportunities
  • Evaluation with competing options
  • Set-up monitoring program of successes in India,
    China
  • Clear regulations
  • Permitting procedures
  • Emission according to ALARP
  • Health, Safety Environment
  • Sale of electricity and heat
  • Any legal obstacle should be removed
  • Long-term fixed price is prerequisite

31
Some concluding remarks 3
  • Product quality must meet client specifications
  • Technical performance
  • Financial/economic performance
  • Operational performance
  • Gaining confidence
  • Certification
  • stimulation
  • product must meet defined quality standards
  • Scale-up, demonstration, replication,
    optimization
  • Economy of numbers (instead of economy of scale)
  • Reduced capital costs
  • Improvement from learning by doing

32
Some concluding remarks 4
  • Do not repeat the mistakes from the past
  • learning by doing and not by a scientific
    approach (cooperation is prefered)
  • too optimistic approach of the economics,
    efficiency and availability, projections 7000
    hrs of operation in 1st year
  • no optimal cooperation of the ownership-consortium
    and conflicting interests (who is responsible
    for what).
  • Manufacturer versus plant owner
  • Plant owner/technology supplier versus permitting
    authority

33
Health, Safety Environment
www.gasification-guide.eu
34
Success stories CHP gasifiers 1
  • More than 5 installed systems
  • Bioneer district heating
  • Co-firing at power stations
  • Biomass engineering, UK
  • Eqtec, Spain
  • Xylowatt, BE
  • Mothermik, DE
  • Pyroforce, CH
  • Güssing concept, AT
  • Volund (DK, DE, Japan, Italy))
  • India, China (thousands, but unfavourable
    emissions)

35
Success stories 2
36
Success stories 3
37
Thank you for your attention!

Harrie Knoef BTG biomass technology group
BV www.btgworld.com Knoef_at_btgworld.com Ph
31-53-4861190
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