industrial digestion - integration with engines
TRANSCRIPT
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Industrial digestion & MBT-ADIntegration with Gas Engines
Renewable Energy Association Bioenergy Conference8th October 2009
Alex Marshall
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Graveyard slot!
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Agenda
Clarke Energy introduction MBT-AD & industrial digestion CHP basics Gas characteristics Gas treatment Physical integration Biogas CHP GHP savings Summary
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Locations
9 Territories Globally
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ESTABLISHED 1989
1990
ISO ACCREDITATION 1991
1992
1993
1994
UK JENBACHER DISTRIBUTOR 1995
1996
1997
AUSTRALIA, NZ AND NIGERIA DISTRIBUTOR 1998
1999
2000
2001
2002
GE PURCHASE JENBACHER, CEL ACQUIRE COGEN INDIA 2003
ACQUIRED JENBACHER FRANCE 2004
IRELAND DISTRIBUTOR 2005
2006
2007
CHINA, TUNISIA DISTRIBUTOR 2008
2009
Timeline
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Clarke Energy MW Installed
0.0
100.0
200.0
300.0
400.0
500.0
600.0
700.0
MW
UK France ANZ India Nigeria China Tunisia
Country
Biogas Landfill gas Syngas Natural gas Mines gas Flare gas
Bioenergy
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MBT-AD and industrial digestion comparison
Landfill, RDFTo landDigestate utilisation
IntensiveLightMechanical pre-treatment
Highly variedPackaging, sandContaminants
Mixed wastesFood waste, biowaste, slurries, energy crops
Input
Gate fee, energy, sale of recyclables
Gate fee, energyRevenue
MBT-ADIndustrial ADFactor
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Food Waste & Co-Fermentation
Source: Haase Midlum, Sibstin plants
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MBT – AD
Source: Haase Goettingen MBT facility
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Gas contaminant comparison
PossibleYesMixed waste
NoYesFood
NoYesMaize
YesYesSewage
YesYesLandfill
VOSCs*Hydrogen sulphide
Biogas type
*Volatile organic silicon compounds
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H2S Reduction – Air dosing
~1% oxygen dosing Biological reduction Air allocation
important Additional air
increases corrosion Fluctuating
efficiency Lower capital
investment
M
Biogas
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H2S Reduction - Air dosing
Biological desulphurisation – the H2S will be converted into sulphur
Source: MT Energie
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H2S Reduction – Scrubber tower
air water
biogas
Biological reduction Gas saturated with water Additional air increases
corrosion Stable performance Higher investment costs
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H2S Removal – FeCl dosing
Iron chloride binds to H2S
Fast action Adjustable to substrate Industrial digestion Moderate investment costs
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GE Jenbacher gas module
Heat recovery -heat exchanger
EngineEngine control
panelGenerator
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Energy balance
HE 1 - Mixture intercooler
HE 2 - Oil exchange heater
HE 3 - Engine jacket water heat exchanger
HE 4 - Exhaust gas heat exchanger
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Typical engine integration
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Heat limits & hazards
Acid dew point22050Exhaust gas
Condensation8055Intercooler
Viscosity9070Lube oil
Overheating9557Jacket water
DangerMax. (oC)Min. (oC)Heat source
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Engine integration
EvaluateEvaluateResidential/ Industrial heating
Heat sink
YesNoReduce weight
Increase CV
Digestate drying
EvaluateYesPathogen killPasteurising
EvaluateYesEncourage microbial action
Digester heating
Exhaust gasJacket waterPurposeHeat use
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Engine integration
Exhaust heat
Jacket water, oil heat & intercooler
~400ºC
90ºC
Drier
2-300ºCAir
Heat exchanger
Pasteuriser
External heat sink
Digester
District heating Industry
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Pasteurisation unit integration
Pasteurisation
Inflow from buffer tank
Outflow to digesters
Heating water from
CHP
Fill70OC 1hr
Purge
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Biogas utilisation – GHG Savings
Source: Optimierungen fur einen nachhaltigen ausbau der biogaserzeugung und nutzung in Deutschland (Ifeu et al. 2008)
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Summary
Main biogas contaminants – H2S & VOSCs
H2S treatment – biological or chemical Heat utilised for:
Digesters Pasteurisation Drying External heating
Biogas CHP – Significant GHG savings