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Various Integrated Forest Biorefinery (IFB)options… and suitable technologies for the
future Follum mill and it’s partners?2011‐09‐21Follum millLasse Blom
(Eigil Søndegård & Henrik Plesner)
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Table of Content
▪ Introduction – Why we do the things we do?
▪ Background – What is done before?
▪ The biomass resources – The sobering facts!
▪ Bio‐business options at Follum –New and “old” ideas!
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Introduction– Why we do the things we do?
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Why we do the things we do?
EU Commission 2050 roadmap to a low carbon economy where the target is 80% reduction (100%=1990).
Target
What about Norway’s contribution?
We will not reach the EU goal in 2050 if we continuous in the samepace as today with GHG reductions!!!!
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Feedstock resources in Norway▪ Wood resources in Norway
– Growing stock: 765 mill. m3– Annual growth : 28 mill. m3– Annual logging: 10 mill. m3
▪ Annual harvesting today is 16 TWh. Total biomass harvesting is estimated to be approx 30 – 35 TWh (NVE, NINA), but competing usage will queue up.
▪ As an example; The conversion to biofuels will at its best be 15 TWh if all biomass is utilised for biofuels solely, while the need is 75 TWh (SSB) in the transport sector. This means that we will only cover 20% of the transport fuel needed.
▪ We have too scare biomass resourcesin Norway to “save the world”.
“We need to find the right way to utilising our biomass sustainable!”
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Background – What is done before?
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BioDiesel – Xynergo – not an option yet…!
BioDiesel left out in the cold…!
▪ BioDiesel from biomass is still not technically fully developed
▪ Poor energy efficiency for biodiesel▪ Market uncertainties▪ Authority uncertainties ‐ if it had to
really on this to be implemented?▪ Needed large production volume to
be economical feasible, and this again was dependent on locationand the source of available biomass
▪ Openness, honesty and co‐operation is key for project success
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BioOil – Xynergo – not an option yet…!
▪ Fast pyrolysis oil has many undesirable properties:– High water content: 15‐30%– High O content: 35‐40%– High acid: pH=2.5, TAN>100 mg KOH/g oil– Unstable (phase separation, reactions)– Low HHV: 16‐19 MJ/kg– Catalytic methods can be used to improve
these properties for the bio‐oil
▪ The quality of bio‐oil is today not goodenough for direct pure bio‐oil usage
▪ Market uncertainties, small volumes▪ The bio‐oil need to be hydrolysed to be
usable for further processing at refineries, and will therefore become expensive.
What now then?
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The PROFIT‐Project Introduction▪ “PROFITable bioenergy and paper production through innovative raw
material handling and process integration” (PROFIT‐Project) – Sub‐project 1. Raw materials logistics– Sub‐project 2. Improved paper production– Sub‐project 3. Bioenergy production and Process Integration
▪ The industry and R&D partners are: Norske Skog, Viken Skog, PFI, Chalmers, NTNU, Bio Varme, Follum Industripark, Andritz og Moelven.
▪ The project main goal:– The project aims at establishing innovative systems and technological solutions for
integrated raw material and heat handling in a paper mill, waste combustion plant, pellet plant and a synthetic biofuel plant, opening for:• Considerable increase in wood logging for bioenergy purposes, amounting to a
minimum of 0.4 TWh/year, only in the Follum case, however with considerably higher potentials
• Development of a new, innovative fractionation system for chip handling, allowing for a more optimal use of the wood raw material
• Cost‐effective production of pellets• Cost‐effective production of synthetic biodiesel• A step‐change in critical pulp properties (e.g. strength, variation, optical
properties, energy consumption) ensuring more uniform and improved TMP pulp quality.
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The PROFIT‐Project progress…when looking back!
[2010, Mar] – Wood pellets
[2010, May] – Torrefaction pellets
[2011, Feb] – Bio‐oil (pyrolysis)
[2011, May] – Gasification
[Today] Biomass IntegratedGasification CombinedCycle (BIGCC)”A rugged road!...”
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The PROFIT‐Project progress…when looking back!
Wood pellets:Pros:‐ Most suitable for smallmarkets and therefore alsosuitable for smaller local industries.
Cons:‐ Market uncertainties‐ The PROFIT SP1 concluded thatwood pellets would not be suitablefor the Follum mill!!!
‐ We would like to use the biomass ourselves for producing specialproducts.
Torrefaction pellets:Pros:‐ Higher energy density than wood pellets (30%).
‐ Good for pre‐treatment for theEntrained Flow Gasifier (EFG).
Cons:‐ Market uncertainties.‐ The energy densification may in somecases not be economical valid.
‐ Some issues with spontaneousignition when stockpiled.
‐ A “hype wave” product (?)‐ Torrefied material gives much dust forall the gasification types, except the EFG.
Bio‐oil (pyrolysis):Pros:‐ Good logistics, but may not be worth it.Cons:‐ The bio‐oil need to be hydrolysed to beusable for further processing at refineries, and will therefore become expensive.
‐ The quality of bio‐oil is today not goodenough for direct pure bio‐oil usage.
Gasification:Pros:‐ Numerous usage options.‐ Flexible feed and products.‐ Circulating Fluidized Bed the best option for Follum.
Cons:‐ High investment costs, but the chosentechnology will make it very flexible system
Biomass Integrated Gasification Combined Cycle (BIGCC):• Steam – for the mill• Heat – for the district heating• Electricity – for the grid• Methane, Hydrogen &/or Methanol – for the transport sector
2010 May 2011 Feb2010 Mar
2011 May
2011 Jul
[START]
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The Biomass Resources– The sobering facts
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The Biomass Resources – the sobering facts
▪ Forests comprise about @80% of the world’s biomass▪ Biomass supply @14% of the world’s energy needs▪ Depending on the energy source, the markets vary:
– Fossil fuels => World market– Electricity => Region market– Biofuel => District market– District heating => City market
▪ Biomass is often scattered in small “local reservoirs” and is not suitable for a global market
▪ Biomass fuel prices can vary significantly between countries, due to different national policy instruments
▪ Logistics are one of the major cost saving potentials▪ Biorefinery needs to be close to the source of biomass
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Raw materials availability at Follum
▪ Investigate feedstock resources in the Follum mill area, with main focus on forest residues (GROT) has been performed
Biomass origin at Follum
Hønefoss… in the heart of the Norwegian forests!
Norway
85 km
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Biomass inventory around the Follum mill
Total annual effect available biomass around Follum mill (upto 85 km)
12.7
8.0 8.9
12.8
1.5
6.4
2.5 2.0 1.10
2
4
6
8
10
12
14
16
GROTMas
sevir
ke fu
ruEne
rgigra
n
Heltre
Biovirk
eRivn
ingsv
irke
Sagflis
Tørrflis
Kutterf
lis
Tota
l Effe
ct (M
W)
≈ 55 MW
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Bio‐businesses options at Follum– New and “old” ideas!
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Product portfolio development at the Follum mill
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Forest BioRefineries and Energy Conversion techn.:• Wood pellets• Torrefaction• District Heating• Pyrolysis oil• Gasification• Extracting “products”• Steam Turbines• Heat Pumps• Etc.
0
50
100
150
200
250
300
350
400
1000
Ton
n
78 79 80 81 82 83 84 85 86 87 88 89 90 91 92 93 94 95 96 97 98 99 .00 .01 .02 .03 .04 .05 .06 .07 .08 .09 .10OP11
Newsprint Sulphitepaper SC UMI MFC Book
Standard Newsprint
Improved Newsprint
Coated Magazine
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Integrated Forest Biorefineries (IFB’s):
IFB
BioChemicals
BioEnergyBioFuels
BioMaterials
‐ Paper ‐ Nanofibres‐ Fibers ‐ Textile‐ Composites ‐ PHA‐ Polymers ‐ etc
‐ BioGas ‐ BioButanol‐ BioDiesel ‐ BioMethanol‐ BioEthanol ‐ BioSNG‐ BioHydrogen ‐ etc
‐ Proteins ‐ Glycerine.‐ Lignin ‐ Acetone‐ Turpentine ‐ Fertilizers‐ Gasification ‐ etc
‐ Chips ‐ Hydrolysis.‐ Pellets ‐ Fuel Cells‐ Torrefaction ‐ BioOil‐ Combustion ‐ etc
▪ Definition: By producing multiple products, a Integrated Forest Biorefinery (IFB) takes advantage of the various components in the biomass and their intermediates maximising the value derived from the biomass feedstock. These can be grouped into:
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How to get successful BioBusinesses– with Utility and Product Integrations
BioMaterials
BioFuels
BioChemicals
BioEnergy
Knowledge + Solutions = Environment + BioBusiness
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What decide the technology options?
Resources Market
▪ The biorefinery technology chosen is dependent on both upstream and downstream external influences and internal needs
Follum mill and co‐companies
Raw material and pre‐treatment
Integrated Forest
Biorefinery
Post treatment
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What is the best biorefinery pathway?▪ “It’s time to frame and tame the activities!”… we are in the forests of opportunities!
Biogas
Pellets(wood, torrefaction)
Steam Turbines
District Heating
BioDiesel
BioOil
Gasification ?BioButanol
Combustion
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Strategic‐ and Classical Process DesignNumber of design options
Product portfolio design
Screening out
Feasibility study
Pre‐study
Main‐study
Engineering
Very early stage selection
Early stage selection
Strategic Process Design
Classical Process Design
▪ Product portfolio Design▪ Strategic Process Design
– Generate product alternatives (matrix)
– Very early stage design– Early stage design
▪ Classical Process Design– Feasibility‐, main‐ and engineering design
– Evaluation, ROI, ROCE and IRR.
1
2
3
Timeline
Idea input
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R&D Pilot/Demonstration Commercial
BioHydrogenSupercritical Gasification
Bio‐oil applications
BioOil (Fast/flash Pyrolysis)
BioEthanol from cellulose
BioDiesel
BioGas (Anaerobic digestion)
CombustionDensification (pelletising)
SynGas (Gasification of biomass)Glucomannan extraction
Harvesting lignin
Harvesting PHA
BioMethanol
BioButanol
Harvesting of Hemicellulose
Developing stages
Time
Carbonisation (slow pyrolysis)
Option(s) selected from a technical pool
▪ A continuous loop– Screening becomes very site specific!
No.: Ideas / processes: Discussions / comments:
Status:R&D /
Demo /Com
FBR groups:BioMaterials /
BioChemicals /BioFuels /BioEnergy
& ECT
1 - R
ecove
red pap
er pro
cess
ing
(50%)
2 - C
hemica
l pulping (3
2%)
3 - Therm
omechan
ical p
ulping
(18%)
Priorit
ies (A
, B &
C)
GHG emission comments:
1-0 Bio pellets (wood pellets) - Sale of pellets to Central Europe coal plants or domestic market.- Using the existing TMP1 refiner as prefiltration to a pelletizing machine
Com BioEnergy X X A
- Pellets gives more CO2 savings in stationary CHP plants than production of bio-fuel.- It is said that the coal fire plant can burn 20% mixture of wood pellets without doing large rebuilds.The well-to-gate emissions for wood fuel handling is 10 kg CO2/MWh [9].As an average, the CO2 emission reduction for wood is 336 kg CO2/MWh if coal power plant is the marginal user.
1-1 Torrefied pellets - Torrefied pellets can substitute coal almost 100%.Demo BioEnergy X X A
It is expected that the CO2 emission reduction is the same as for the wood pellets (336 kg CO2/MWh).
1-2 Charcoal pellets - A product that has various applications; (1) it can substitute Active Carbon for water purification, (2) it can be used as soil improvement (ref CenBio and Michael J.Atal).-The biomass source can also be revenue of waste streams from TMP.
Demo BioEnergy X X X B
Same as above.
1-3 Steam pellets - Steam explosions of chips as pre-treatment can be an option. Positive is that it is a fast process, but it uses higher pressure than our surplus LP steam- Plant at Kongsvinger (Norway) - still some operating challenges.
(Com) BioEnergy X X B
Same as above.
1-4 Lignin pellets - Lignin pellets (wood pellets+lignin), better energy yield than torrefaction, DME, Ethanol and Methane.- Can only be made when lignin is available
Demo BioEnergy X BIn this case. The lignin will boost the energy content of the pellets with 20% (?), which then will give a CO2 reduction of 270 kg CO2/MWh if coal is the marginal user.
2-0 Enhance the steam system - Ongoing separate activity in the PROFIT project (Energy Conversion Technologies)- Usage of the TMP de-compressors?- With upto 100 MWel available of, we will be self sufficient with electricity at Follum.
Com BioEnergy X X X B
As an overall figure, the CO2 reduction from thermal energy is around 225 kg CO2/MWh.
2-1 Steam turbines - Todays steam turbine is too large (history dependent)- ÅF report available
Com BioEnergy X X X B
If the electricity produced will substitute electricity from coal, the CO2 reduction will be 770 - 31 = 740 kg CO2/MWh, but if electricity is produced from NG with CCS in 2050, the reduction will only be 120 - 99 = 20 kg CO2/MWh. [9]
2-2 Condense turbine on the surplus LP steam Payback in 4-5 years
Com BioEnergy X X X B
Normally, a condense turbine is used used on surplus steam, which means that the energy produced from this is CO2 neutral. This again means that the CO2 reduction is 770 kg CO2/MWh if the marginal electricity producer is coal. If natural gas is the marginal producer, the reduction is 345 kg CO2/MWh.
2-3 Pressure Release Valve (PRV) options Many mills are today uses PRV's- DifGen usage- Steam Turbine
Com BioEnergy X X X B
3-0 Heat Pump technology -The mapping during the pinch analysis will identify the surplus heat potensial at the mill- Wich technology uses Akershus Energi to recover their heat in the waste streams? Com BioEnergy X X X B
The CO2 emission reduction is all dependent on the application. This can varies all from 100% reduction for coal as marginal producers (770 kg CO2/MWh) down to the efficiency of the HP based on the marginal producer. If natural gas in 2020, this will be around 345*0.33=114 kg CO2/MWh.
4-0 Absorption Heat Pump - Direct AHP like a scrubber can be used for heating of the water at the WTP- AHP Coolers are also available- This can be the heat recovery from the furnace flue gas, or the heat from discharge process pipes
Com BioEnergy X X X B
Same as above.
5-0 Gasification - Poor energy conversion efficiency today, but can be an initial start for a future SNG conversion plant producing various products?- There are many technologies available- A process integration of electricity production and District Heating (CHP) will give an efficiency of >85%
Com BioEnergy X X A
By gasification, 1 kg of fossil fuel can be replaced using about 3.5 kg of biomass.
Com
R&D!Pilot!Demo!Com!
R&D?Pilot?Demo?Com?
R&DPilotDemo
New ideas!
Old ideas!
12
3
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BioBusinesses at Follum… with its synergies
Partners
FeedstockCO2 emissions
Transport/Distribution:
Electricity pricesSpot Price Market in Norway (NOK/MWh)
0
100
200
300
400
500
600
700
08 J
an
08 M
ar08
May
08 J
ul
08 S
ep
08 N
ov
09 J
an
09 M
ar09
May
09 J
ul
09 S
ep
09 N
ov
10 J
an
10 M
ar
10 M
ay10
Jul
10 S
ep
10 N
ov
11 J
an
NO
K/M
Wh
Absolute vs. Specific CO2 emissions
35
36
37
38
39
40
41
42
43
1990 2000 2007 2008
Abso
lute
(Meg
a to
nnes
/y)
0
0.1
0.2
0.3
0.4
0.5
0.6
Spec
ific
(tonn
es/p
rod.
tonn
es)
Environment
Customers
Authorities/Legislations
Sales/Marketing
Products
▪ Process Integration and industry synergies
It is important to find “real synergies”, and not only “placebo synergies”.
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Forest BioRefinery BioBusiness options
District Heating
BioGas
Wood Pellets
Torrefied Pellets
El. TurbinesPaper
Turpentine
Gasification
Bio‐OilsFuture???
Past &Future
Examples of a “brownfield”mill becoming an Integrated Forest Biorefinery (IFB):
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What decide the options?
Raw material availability Market
▪ The gasification technology chosen is dependent on both upstream and downstream external influences and internal needs
Follum mill and co‐companies
Raw material and pre‐treatment
iGasificationiCombustion
Gas cleaning and
conditioning
Post treatment (synthesis)
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Biomass CHPPLUSS® Options
Chipping
DryingiGasification
and conditioning
Combustion(Oxidation)
‐ Circulating Fludized Gasifier, or‐ Entrained Flow Gasifier, or‐ Updraft Flow Gasifier
‐ Gas Engine, or‐ Gas Turbine
Methanation,or similar
Steam Turbine
Steam to Mill (MP & LP):
‐ Belt (Andritz), or‐ Drum, or‐ Belt/Drum integrated, or‐ No drier
Bio Fuels:‐Methane‐Methanol‐ BioDME
Combined Cycle
BiomassResidues
Bark
50 MW200k m3/a
30 MW 25 MW
Alte
rnatives
80 MW 63 MW 32 MWth40 MW
8 MWel
23 MW
18 MW
Process efficiencies:
η Gasification = 78 %
η Methanation = 82 %
η Steam Turbine = 80 %
η Combustion = 80 %
Process efficiencies:
η Gasification = 78 %
η Methanation = 82 %
η Steam Turbine = 80 %
η Combustion = 80 %
Colour legend:
Blue – Fixed figures
Red – Export products
Colour legend:
Blue – Fixed figures
Red – Export products
7 MWel
Internal & District Heating 3.7 MW4.5 MW
w=40%
w=10%
iCombustion
Electricity to the grid
Gasification Oxidation
Alt.1
Alt.2
‐ Backpressure turbine
Alternatives:
Alt.1: Biomass Integrated Gasification Combined Cycle (BIGCC)
Alt.2: Integrated Combustion
Alternatives:
Alt.1: Biomass Integrated Gasification Combined Cycle (BIGCC)
Alt.2: Integrated Combustion
Bleed‐off option
Bleed‐off o
ption
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Optimalization of energy with pinch analysis
Heat &Power
Fuel & ProductGases (Syngas)
Liquids(Bio‐oil)
500˚C800‐1400˚C650˚C
Thermo‐chemical conversion
Combustion PyrolysisGasification
Excess air Partial air No air
50%
100%
60%
70%
80%
90%
Combus
tion‐ CH
P
Gasific
ation ‐
EFG
Gasific
ation ‐
CFB Bio‐oil
FuelHP Steam (>60 bar)MP Steam (20 bar)LP Steam (<3 bar)
It should be noted that there are differences in efficiency also between the technologies among Combustion, Gasification and Pyrolysis.
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BioFuel – Conversion routes
▪ BioFuel product pathway examples
Gasification has become broadly recognized as an attractive conversion process. The reasons most often mentioned are the high efficiency and the back‐end flexibility. [102]
MethaneMethane
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CO2 emission reduction vs. Energy efficiency for various fuels
CO
2 em
issi
on re
lativ
e to
Gas
olin
e
Tota
l ene
rgy
effic
ienc
y
100%
Gasoline FTD Ethanol Methane
85%
41%
FastPyrolysis
77%
45%
20% 20%
Raps fuel
50%
It should be noted that the more conversion stages to get to theend product, the lower total energy efficiency is generated!
Since generally biomass will be relatively expensive, high efficient conversion processes are needed to obtain economically attractive systems.
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Various technology options
Various gasification technologies have theiradvantageous anddisadvantages, and thereis no such thing as a technology that “fits all”.
The ENERGOS integratedcombustion has the advantage that it canhave a slip‐stream withsyngas out before the combustion chamber.
CFB EFG UFG
Integrated Combustion
The product we decideto produce decidesquite much whichtechnology we will use!
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Overall strategy
▪ Flexibility, flexibility, flexibility….
Electricity
Gas (methane?), Liquid (Methanol?)…
Gasification
Biomass
Sale or energy storage with methane, methanolor similar products!
Steam for local usage
El. certificates
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Future thoughts…
▪ A biomass gasification plant will replace Follum’s multi fuel boiler (MBK).▪ A CFB producing BioMethane will have the advantage that methane from
sludge digestion could be added at a later stage. But the other option will be to gasify the biosludge instead of anaerobic digestion.
▪ Because of its high efficiency and low emissions, the BIGCC can also be applied to a growing market niche, the repowering of older facilities. [66]
▪ In addition, the advanced gasification process can be used to generate fuels and chemicals, such as low‐cost hydrogen and syngas for chemical synthesis, as well as baseload power. [66]
▪ The higher thermodynamic efficiency of the IGCC cycle minimizes carbon dioxide emissions relative to other technologies. [92]
▪ The Milena gasifier produces much methane compared to other, due to its indirect gasifier. [58]
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Biomass Gasification Reference plants▪ Södra Cell Varö has operated a low temperature bark gasifier since 1987.
The gas is used in the lime Klin [10].▪ Värnamo BIGCC, starting up again now▪ UPM, Fortum, Gasification plant from Metso integrated with the bio‐boiler▪ Gasification plant in Karlsruhe (Metso?)▪ Nexterra Systems Corp. Their first installation with direct‐fires syngas
derived from wood, into industrial process boilers, at Kruger Products. [32]▪ Gøteborg Energi, CFB, 20 MW. Starting to build soon, 2011. Expansion of the
plant in 2016 to 80 MW. Producing methane, SNG for the grid.▪ Chalmers University, CFB, 2‐4 MW, operated in many years.▪ ECN is developing the Milena indirect gasifier. 10 MW. [58]▪ Entrained flow gasifier test plant (2ton/day) at Kawagoe, Japan. [74]▪ Lahti Energia, Waste Gasification, 2x80 MW, cost 157 MEuro, start April
2012.▪ UPM, Andritz‐Carbonara, UPM Kaukas, pilot plant, Laapenranta.
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Thank you for your time!Questions?
®For more info: www.re‐cube.net
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