development of biomass energy systems in ecuador
TRANSCRIPT
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DEVELOPMENT OF BIOMASS
ENERGY SYSTEMS IN ECUADOR
Prepared by
Salman Zafar
BioEnergy Consult (Aligarh, INDIA)
and
Carlos Serrano Decker
TECAM Ltd. (Guayaquil, ECUADOR)
May 2009
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What is Biomass?
Any material derived from plants that use
sunlight to grow.
Wood from forests, agricultural residues, and
organic industrial, human and animal wastes
etc.
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Major Sources of Biomass in Ecuador
Agricultural Residues
Animal Manure
Woody Biomass
Bio-solids and Industrial Effluents
Municipal Solid Wastes / Sewage
Algae
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Woody Biomass
Forest and harvesting residues
Municipal wood waste
Wood processing residue
Horticultural residue
Short-rotation forestry
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Agricultural Residues
Straw (from crops like Wheat, Oat, Barley)
Corn Stover
Crop Residues (Leaves, Stalks etc.)
Husk (from Rice and Coffee)
Green Crop Residues (Soybean tops)
Energy Crops
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Animal Manure
Livestock waste
Dairy cattle waste
Poultry litter
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Municipal Solid Wastes
Household waste
Institutional waste
Garbage
Street sweeping
Sewage sludge
Food residuals from hotels, restaurants etc.
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Bio-solids and Industrial Effluents
Agro-industrial wastes
Food processing wastes
Slaughterhouse wastes
Tannery effluent
Sugar mill effluent
Distillery effluent
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Algal Biomass
Marine algae
Seaweed
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A Glance at Biomass Conversion Technologies
BIOMASS
Thermochemical Processes
Power Generation Electricity
CHP Electricity, Heat
Gasification Gas for Fuel
Pyrolysis Heavy Oil
Biochemical Processes
Fermentation Ethanol
Anaerobic Digestion Biogas
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Major Energy Pathways
Thermochemical Pathway
o Combustion
o Gasification
o Pyrolysis
Biochemical Pathway
o Anaerobic digestion
o Fermentation
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Major Biomass Conversion Pathways
Thermal Biological
Combustion Gasification Pyrolysis
Heat Fuel Gases
(CO + H2)
Liquids
Pretreatment
Fermentation
Ethanol
No AirPartial airExcess air
AD
H2
Biogas
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Comparison of Heating Value of Important Biomass
and Conventional Energy Resources
Type of Fuel Heating Value, MJ/kg
Dry Wood 18
Dry Rice Husk 13
Coconut Fiber 17
Dry Cow Dung 14
Charcoal 24
Coal 27
Diesel 46
LPG 45
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Residues Generation Potential of Agricultural Crops
Crops Crop wastes Residues production
Rice Straw, husk, bran 1.5t of straw and 0.2t of husk from 1t of rice
Wheat Straw, husk, bran 2t of residues from 1t of wheat seed
Maize Stalk, leaves 6t of waste from 1t of maize
Sorghum Straw, bran 2.5t of residues from 1t of sorghum seed
Barley Straw, bran 1.5t of straw from 1t of barley
Millet Straw, bran 2t of residue from 1t of millet produced
Coffee Pulp, husk 3.6t of waste from 1t of green coffee
Coco Hull, fibre 0.9t of waste from 1t of coconut
Palm oil Shell, fibre, fruit bunches 75%; waste from weight of fruit bunch
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Pictorial Representation of Agricultural Residues-based
Biomass Energy System
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Sources and Types of Municipal Solid Wastes
Sources Typical waste generators Types of solid waste
Residential Single and multi-family dwellings Food wastes, paper, cardboard, plastics,
textiles, glass, metals, ashes, special wastes
(bulky items, consumer electronics, batteries,
oil, tires) and household hazardous wastes
Commercial Stores, hotels, restaurants,
markets, office buildings
Paper, cardboard, plastics, wood, food wastes,
glass, metals, special wastes, hazardous
wastes
Institutional Schools, government center,
hospitals, prisons
Paper, cardboard, plastics, wood, food wastes,
glass, metals, special wastes, hazardous
wastes
Municipal Street cleaning, landscaping,
parks, beaches, recreational
areas
Street sweepings, landscape and tree
trimmings, general wastes from parks,
beaches, and other recreational areas
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A Glance at Woody Biomass Resources
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Wood-residues from Forestry-based Industries
Process Type of Residue Percentage of Residue
Logging Solid 40
Saw-milling Solid 38
Saw-milling Sawdust 12
Plywood Solid 45
Plywood Dust 5
Particle board Dust 10
Fibre board Dust 10
Chemical pulpwood Black liquor 2.27 m3/ton
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Different Routes for Biomass Conversion into
Energy Products and Services
Resource Processes Biofuels Energy Services
Agricultural residues Densification
Combustion
Gasification
Pyrolysis
Pellets
Briquettes
Bales
Biodiesel
Heat
Electricity
Transport
Wood residues Densification
Esterification
Combustion
Gasification
Pyrolysis
Pellets
Briquettes
Heat
Electricity
Transport
Organic industrial
wastes
Digestion
Hydrolysis
Gasification
Biogas
Bioethanol
Solvents
Heat
Electricity
Transport
Municipal wastes Digestion
Combustion
Gasification
RDF
Biogas
Heat
Electricity
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Biomass Conversion Technologies and their Products
Technologies Conversion Process Feedstock Products
Combustion
Thermochemical
Woody biomass
Agricultural residues
Municipal solid waste
Heat
Process Steam
Electricity
GasificationProducer Gas
PyrolysisBio-Oil
Charcoal
Anaerobic Digestion
Biochemical
Animal manure
Agricultural residues
Industrial effluents
OFMSW
Algae
Biogas
Bio-fertilizer
Bio-ethanol Production
Sugar or starch crops
Wood waste
Pulp sludge
Straw
Ethanol
Biodiesel ProductionChemical
Waste vegetable oil
Animal fat
Energy crops
Biodiesel
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Overview of Biomass Conversion Technologies
Conversion Option Typical Capacity Net Efficiency Status and Deployment
Biogas production via
anaerobic digestionUpto several MWe 10 – 15% (electrical) Widely applied.
Combined heat and power
(CHP)0.1 – 20 MWe 60 – 100% (overall) Widely deployed.
Combustion for power
generation20 - > 100 MWe 20 – 40% (electrical) Well established
Co-firing of biomass with coal 5 – 100 MWe 30 – 40 % (electrical) Widely deployed
Gasification/CHP using gas
engines0.1 – 1 MWe
15 – 30% (electrical)
60 – 80% (overall)Deployment limited
Gasification using combined
cycles for electricity30 – 200 MWe 40 – 50% (electrical)
Demonstration phase at 5-10
MWe range
Pyrolysis for production of
bio-oil10 – 100 tons per hour
60 – 80% for bio-oil
and 85% for oil and
char
Commercial technology
available.
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Biomass Energy Systems
Fuel Specifications and Capacity Range
Technology Type of fuel Particle size requirement Moisture content
requirement
(wet basis)
Average capacity
Stove / Furnace Solid wood, pressed logs, wood chips,
pellets
Limited by stove size and
opening
10 – 30% 15 kWt
Pile burners Wood residues, agricultural residues Limited by grate size and
feed opening
< 65% 4 to 110 MWe
Pile burner fed with under-fire
stoker
Sawdust, shavings, chips, non-stringy
bark, hog fuel
6 – 38 mm 10 – 30% 4 to 110 MWe
Stoker grate boilers Sawdust, shavings, chips, end-cuts, non-
stringy bark, hog fuel
6 – 50 mm 10 – 50% 20 – 300 MWe
Suspension boilers
(cyclonic and air-spreader)
Sawdust, non-stringy bark, sander dust,
shavings, wood flour, sawdust
1 - 6 mm < 20% 1.5 - 30 MWe
Fluidized-bed combustor Low alkali content fuels, mostly wood
residues or peat
< 50 mm < 60% 20 – 300 MWe
Co-firing
(pulverized coal boilers)
Sawdust, shavings, non-stringy bark,
flour, sander dust
< 6 mm < 25% upto 1500 MWe
Co-firing
(cyclones)
Sawdust, shavings, non-stringy bark,
flour, sander dust
< 12 mm 10 – 50% 40 – 1150 MWe
Co-firing
(stokers, fluidized bed)
Sawdust, shavings, non-stringy bark,
flour, hog fuel
< 72 mm 10 – 50 % -
Counter-current fixed-bed updraft
gasifiers
Chipped wood, hog fuel, rice hull, dried
sewage sludge
6 – 100 mm < 20% 5 – 90 MWt +
12MWe
Downdraft moving-bed updraft
gasifier
Wood chips, pellets, wood scrapes, nut
shells
< 50 mm < 15% 20 – 100 kWe
Circulating fluidized bed, dual-
vessel, gasifier
Almost all wood and agricultural
residues
6 – 50 mm 15 – 50% 5 – 10 MWe
Fast pyrolysis Wide range of wood and agricultural
residues
1 – 6 mm < 10% 2.5 MWe
Anaerobic digester Animal manures, food processing
residues, industrial wastewaters
n.a. 65 to 99.9 % liquid
depending on type of
waste
10 kWe to several
MWe
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Biomass Combustion
Simplest and most common technology for biomass
utilization.
Biomass fuel is burnt in excess of air to produce
heat.
Hot air, hot water and steam are the main products.
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Schematic of a Heat Plant
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Co-firing of Coal and Biomass at Zeran CHP Plant in Poland
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Straw is co-fired with Coal in Denmark
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CHP - Combined Heat and Power
(or Cogeneration)
Simultaneous production of heat and power with
upto 90% efficiency
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Technology Options for Biomass CHP
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CHP Prime Movers
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Layout of a Cogeneration (or CHP) Plant
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Schematic of a fuel preparation plant to handle
biomass wastes, municipal solid wastes and sludge.
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Biomass Gasification
The process takes place in limited air at 1200 -
1300 0C.
Final fuel gas, termed as Producer Gas, consist of
carbon monoxide, hydrogen and methane.
Calorific value of producer gas is 4 – 6 MJ/Nm3.
Producer gas is utilized in turbines to generate
power.
A wide range of biomass resources can be subjected
to gasification.
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Schematic of Biomass Gasification Process
Biomass
Feedstock
Gasification
Reactor
Clean Gases
(CO2, H2, N2)
Syngas
Cleaning
Boiler + Steam
Turbine (Rankine
Steam Cycle)
Syngas, CO, H2,
N2, dust, tars
Air
(O2, N2)
Gas
Engine
Electricity
Ash
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Types of Gasifiers (Design Basis: Fuel Properties, End-use, Scale and Cost)
Updraft
Downdraft
Fluidized Bed
o Bubbling
o Circulating Flow
Entrained Flow
Staged (pyrolysis / steam reforming)
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Biomass Gasification Plant
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Biomass Gasifier at Vermont (USA)
200 tons of wood
chips daily
Forest thinnings; wood
pallets
Converted to gas at
~1850 ºF
Combined cycle gas
turbine
8MW power output
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Biomass Pyrolysis
Pyrolysis involves combustion in absence or restricted
supply of air .
The products are
o A solid ( char or charcoal)
o A liquid (bio-oil)
o A mixture of gases (CO, H2 and N2)
Ratio of products varies with biomass composition
and operating conditions.
Bio-oil has been tested for use in engines, boilers
and turbines.
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Schematic of MSW Gasification and Power Generation Plant
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Schematic of Biomass Pyrolysis
Pyrolysis
(5500C, no air)
Combustion
Condensation
Biomass Catalytic Conversion to
Hydrogen (Optional)
Vapors
Liquids
Power
Generation
Gases
(H2, CO, CH4, C2H2, C2H4)
Char
Heat
BIOMASS LIQUEFACTION via PYROLYSIS
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Feedstock and Products in Biomass Pyrolysis
Bio-Diesel
Combustion
Fuel
Fuel for Engines
and Turbines
Fuel Upgrade
Short-rotation
Crops
Wood-based
Residues
Agricultural
Residues
Gasification to
Syngas
PYROLYSIS
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Schematic of Biomass Pyrolysis Plant
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Products of Fast Pyrolysis Process
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Anaerobic Digestion
Microbial decomposition of biomass in closed tanks
(known as anaerobic digesters).
High energy value gas, called Biogas (a mixture of
Methane and CO2), is produced.
Good-quality fertilizer is also produced in the form
of digestate.
The process finds wide application in animal
feedlots, dairies, agricultural farms etc.
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Feedstock for Anaerobic Digestion Plants
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Composition of Biogas
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Applications of Biogas
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Schematic of an agricultural co-digestion biogas plant
based on slurry, organic wastes and energy crops
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Biogas-fired 1 MW Gas Engine at a Dairy Complex in
Punjab, India
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This Filling Station in Laholm (Sweden) supplies biogas via the natural
gas grid to a growing number of light duty vehicles and lorries
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Production of Ethanol from Biomass
Biomass
Pretreatment
Cellulose
Hydrolysis
Enzyme
Production
Pentose
Fermentation
Glucose
Fermentation
Lignin
Utilization
Ethanol
Recovery
Ethanol Biomass
Handling
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Production of Ethanol from Cellulosic Biomass
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A Lignocellulose Biomass-based Biorefinery in Sweden
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Thank you!
BioEnergy Consult – Towards a Clean Energy Future