Precio Syngas

Techno-economic echno-economic and and Market Analysis of Pathways from Syngas to Fuels and Chemicals

TC Biomass 2013 – Chicago, Illinois Michael Talmadge, Abhijit Dutta & Richard Bain September 4, 2013

Objective Assess the economics of producing fuels and chemicals from biomass-derived synthesis gas. •

Process economics based on literature literature (consistent (consistent TEA assumptions)

•

Perform more rigorous TEA on promising pathways

•

o

Biochemical conversion conversion of syngas to ethanol and higher h igher alcohols

o

Ethanol and higher alcohols to infrastructure-compatible infrastructure-compatible hydrocarbons

Simple product market analyses

What can we do with syngas?

Objective Assess the economics of producing fuels and chemicals from biomass-derived synthesis gas. •

Process economics based on literature literature (consistent (consistent TEA assumptions)

•

Perform more rigorous TEA on promising pathways

•

o

Biochemical conversion conversion of syngas to ethanol and higher h igher alcohols

o

Ethanol and higher alcohols to infrastructure-compatible infrastructure-compatible hydrocarbons

Simple product market analyses

What can we do with syngas?

Analysis Approach •

Simplified TEA model

•

Inputs from literature sources o

o

o

o

•

Common scaling assumptions o

o

•

•

Feedstock rate rate and properties (heating value) Product yields Operating costs (variable & fixed) Capital costs Capital scaling exponents Economies of scale for fixed operating costs

Operating and financing assumptions for n th plant and pioneer plant

Minimum Product Selling Price literature values  average, standard deviation & 90% confidence intervals

nth Plant Assumptions Parameter Basis year for analysis Feedstock processing capacity

Value 2011 2,000 Dry Tonnes / SD

Feedstock cost (woody biomass)

$75 / Dry Tonne

Debt / equity for plant financing

60% / 40%

Internal rate of return (after-tax) for equity financing Annual interest rate and term for debt financing Total income tax rate Plant life Plant depreciation schedule Reliability of operations / on-stream factor Site development costs Working capital Indirect costs for capital project Capital equipment capacity scaling exponent

10% 8% / 10 years 35% 30 years 7-year IRS MACRS MACRS = Modified Accelerated Cost Recovery System

0.90 4% of ISBL Installed Capital 5% of Fixed Capital Investment 60% of Total Direct Costs 0.70

Pioneer Plant Assumptions •

Internal Rate of Return (IRR): 10% – 25%

•

Capital Costs: Pioneer Plant Escalation ~ 210% of nth Plant Estimates (Merrow et al, Rand, 1981)

•

Reliability of Operations / On-Stream Factor: Initial value of 0.5 (Merrow et al, Rand, 1981) Increasing to 0.9 per experience curve (Heinen, SRI Consulting, 2001) 1.0

r 0.8 o t c a 0.6 F m a 0.4 e r t S n 0.2 O 0.0 0

2

4

6

8

10 12 14 16 18 20 22 24 26 28 30

Year of Plant Operation

Fuel Pathways Explored Hydrocarbons

Ethanol & C3+ Alcohols

(FT Gasoline, Diesel, Jet, Lubricants)

Ethanol Synthetic Natural Gas

Syngas

Syngas Fermentation

Butanol 2,3-Butanediol

Methanol

Triptyls

Gasoline (MTG)

Dimethyl Ether (DME)

Olefins (MTO)

Chemical Pathways Explored Urea Hydrocarbons (FT Lubes, Waxes)

PHA (Polyhydroxyalkanoates)

Ammonia

Syngas Fermentation

Hydrogen

Syngas

Aldehydes

DME Ethylene Glycol MethylAmines Methanol Methyl Formate

Formaldehyde

Acetic Anhydride

Acetic Acid

Ethyl Acetate

Acetic Acid

Formic Acid

Propylene (MTO) Ethylene (MTO)

(Oxosynthesis)

Major Pathway Categories Explored •

Synthetic Natural Gas via Methanation of Syngas

•

Ethanol

•

o

Catalytic Mixed Alcohol Synthesis

o

Syngas Fermentation *

Hydrocarbons o

Fischer-Tropsch

o

Methanol to Naphtha Hydrocarbons

o

Ethanol & Higher Alcohols to Hydrocarbons *

•

Hydrogen via Steam Reforming, WGS & Purification

•

Methanol via Catalytic Methanol Synthesis * Pathways explored by NREL through Aspen modeling and rigorous TEA.

Synthetic Natural Gas •

Methanation of Syngas

Synthetic Natural Gas Process

Sources

Min. Selling Price Range ($ / MScf)

Syngas to SNG via methanation

McKeough & Kurkela, 2007 Mozaffarian et al, 2004 van der Drift et al, 2005

nth Plant

16.52 – 19.13

Pioneer 10% IRR

28.50 – 31.05

Pioneer 25% IRR

50.00 – 56.93

35 30

f c 25 S M / 20 $ 1 15 1 0 10 2

Pioneer 10% IRR

29.80 ± 2.10

nth Plant

17.62 ± 2.23

Pricing History

5 0 2000

2002

2004

2006

2008

2010

2012

2014

Synthetic Natural Gas •

Techno-economic Analysis 40

f 35 c 30 S M25 / 20 $ 1 15 1 10 0 2 5 0

•

53.50 ± 5.70 ~~~~~~~~~~~~~~ ~~~~~~~~~~~~~~ ~~~~~~~~~~~~~~ ~

29.80 ± 2.10

17.62 ± 2.23

5.50 Market Price (5-Yr)

IRR = 10%

nth-Plant MSP

25%

Pioneer Plant MSP

Market Analysis Average Product per Ton Biomass U.S. Consumption (EIA, 2012)

11,440 Scf / Ton 25.5T Scf / Year

10% of U.S. Natural Gas Market Equivalent Biomass Consumption

2.55T Scf / Year 223 MMTon / Year

Equivalent Biorefineries

310

2,000 Tonne / Day Facilities

Ethanol •

Catalytic Mixed Alcohol Synthesis

•

Syngas Fermentation *

* Pathways explored by NREL through Aspen modeling and rigorous TEA.

Ethanol via Mixed Alcohol Synthesis Process

Sources

Min. Selling Price Range ($ / Gal GE)

Syngas to ethanol via catalytic mixed alcohol synthesis

Dutta et al, 2011 Dutta & Phillips, 2009 Dutta et al, 2010 He & Zhang, 2011 Villanueva Perales et al, 2011

nth Plant

2.87 – 4.83

Pioneer 10% IRR

5.67 – 9.64

Pioneer 25% IRR

11.27 – 19.20

12

E10 G n 8 o l l a G 6 / $ 4 1 1 0 2 2 0 2000

Pioneer 10% IRR

8.05 ± 2.08

nth Plant

4.16 ± 1.06

Pricing History

2002

2004

2006

2008

2010

2012

2014

Ethanol via Syngas Fermentation Process

Sources


Ethanol via syngas fermentation

Putsche,1999 van Kasteren & Verbene, 2005 Piccolo & Bezzo, 2007

nth Plant

3.67 – 5.08

Pioneer 10% IRR

6.11 – 8.99

Pioneer 25% IRR

11.07 – 17.02

12

E 10 G n 8 o l l a G 6 / $ 4 1 1 0 2 2 0 2000

Pioneer 10% IRR

7.14 ± 1.82

nth Plant

4.32 ± 0.83

Pricing History

2002

2004

2006

2008

2010

2012

2014

Ethanol via Syngas Fermentation NREL TEA Model Flue Gas

Woody Biomass

Feed Handling & Preparation

Seed Train

Ethanol Biomass Gasification

Syngas Cleanup

Syngas Fermentation

Product Recovery

C3+ Alcohols

Heat Integration, Power Generation & Other Utilities

•

•

•

Acetic Acid

Power

Design Report NREL/TP-5100-51400 utilized as basis through clean compressed syngas from biomass. Yield structures based on publications from LanzaTech & INEOS Bio. Capital costs for fermenters, seed train and cell recovery developed by Harris Group Inc.

Ethanol •

Techno-economic Analysis

12

E G10 n o l l 8 a G6 / $ 4 1 1 2 0 2

15.76 ± 4.11 ~~~~~~~~~~~~~ ~~~~~~~~~~~~~~ ~~~~~

12.59 ± 3.93 ~~~~~~~~~~~~~ ~~~~

8.05 ± 2.08

2.72

3.06

7.14 ± 1.82 4.32 ± 0.83

4.16 ± 1.06 IRR = 10 % 25%

IRR = 10 % 25%

IRR = 10 % 25%

0 Market Price (4-Yr)

Price Projection (4-Yr)

nth-Plant MSP

Pioneer Plant MSP

Mixed Alcohols (Literature) •

nth- Pl ant MS P

Pi one er Pl ant MS P

Syngas Fermentation (Literature)

nth-Pl ant MSP

Pi oneer Pl ant MSP

Syngas Fermentation (NREL TEA)

Market Analysis Average Product per Ton Biomass U.S. Consumption (EIA, 2013)

85 Gallons / Ton 13.0B Gallons / Year

50% of U.S. Fuel Ethanol Market Equivalent Biomass Consumption

6.5B Gallons / Year 76 MMTon / Year


100


Hydrocarbons Fischer-Tropsch

•

•

Methanol to Naphtha Hydrocarbons

•

Ethanol & Higher Alcohols to Hydrocarbons *

* Pathways explored by NREL through Aspen modeling and rigorous TEA.

Fischer-Tropsch Hydrocarbons Process

Sources


Hydrocarbons via Fischer-Tropsch synthesis

Hamelinck et al, 2003 Larson et al, 2009 McKeough & Kurkela, 2007 SRI PEP Yearbook, 2009 Udengaard, 2011 Byrne, 2011 Freeman, 2011

nth Plant

2.52 – 4.19

Pioneer 10% IRR

4.75 – 7.43

Pioneer 25% IRR

9.08 – 13.52

8 7

E G6 n o l l 5 a G4 / $ 3 1 1 2 0 2 1 0 2000

Pioneer 10% IRR

5.63 ± 1.53

nth Plant

3.09 ± 0.96

Pricing History

2002

2004

2006

2008

2010

2012

2014

Methanol to Hydrocarbons Process

Sources


Hydrocarbons via methanol synthesis and methanol conversion

Phillips et al, 2011 Hindman, 2010 SRI PEP Report 191A, 1999 Udengaard, 2011 Jones & Zhu, 2009 Ahn et al, 2009

nth Plant

2.61 – 3.84

Pioneer 10% IRR

4.67 – 6.47

Pioneer 25% IRR

8.61 – 11.38

8 7

E G6 n o l l 5 a G4 / $ 3 1 1 2 0 2 1 0 2000

Pioneer 10% IRR

5.37 ± 1.09

nth Plant

3.24 ± 0.81

Pricing History

2002

2004

2006

2008

2010

2012

2014

Ethanol & Higher Alcohols to Hydrocarbons NREL TEA Model Flue Gas

Woody Biomass

Feed Handling & Preparation

Co-Product(s) Biomass Gasification

Syngas Cleanup

Alcohol Synthesis

Alcohol Separation

Ethanol (and C3+ Alcohol) Intermediates

Heat Integration, Power Generation & Other Utilities

Light Ends Mixed C3 Hydrogen Plant

Mixed C4 Naphtha

Hydrocarbon Product Recovery

Alcohol to Hydrocarbon Conversion

Mid-Distillates Natural Gas •

Ethanol (and higher alcohol) intermediates for hydrocarbon fuel production.

•

Eliminates constraints of renewable ethanol blend limits.

•

Technology development taking place in academia, national labs and industry.

Hydrocarbon Fuels Techno-economic Analysis

•

8

E 7 G n 6 o l l 5 a G4 / 3 $ 1 2 1 1 0 2 0

10.66 ± 2.56 ~~~~~~~~~~~~~ ~~~~~~~~~~~~~~~ ~~~~

9.54 ± 1.87 ~~~~~~~~~~~~~~ ~~~

5.63 ± 1.53 2.72

Market Price (4-Yr)

3.06

Price Projection (4-Yr)

3.24 ± 0.81

3.09 ± 0.96

nth-Plant MSP

Pioneer Plant MSP

Fischer-Tropsch (Literature) •

5.37 ± 1.09

nth- Pl ant MSP

Pi onee r Pl ant MSP

MeOH to Hydrocarbons (Literature)

nth- Pl ant MSP

Pi one er Pl ant MSP

EtOH to Hydrocarbons (NREL TEA)

Market Analysis Average Product per Ton Biomass U.S. Consumption (EIA, 2013) 10% of U.S. Hydrocarbon Fuels Market Equivalent Biomass Consumption Equivalent Biorefineries

65 Gallons / Ton 220B Gallons / Year 22B Gallons / Year 338 MMTon / Year

440


Hydrogen •

Steam reforming, water-gas shift & purification

Hydrogen Process

Sources

Min. Selling Price Range ($ / MScf)

Syngas to H2 via steam reforming, water-gas shift & purification

Spath et al, 2005 McKeough & Kurkela, 2003 Williams et al, 1995 Hamelinck & Faaij, 2001

nth Plant

5.33 – 8.84

Pioneer 10% IRR

10.46 – 15.63

Pioneer 25% IRR

20.93 – 29.07

18 16

f 14 c S M12 / 10 $ 1 8 1 0 6 2

Pioneer 10% IRR

Pricing History

4

nth Plant

2 0 2000

12.52 ± 3.62

2002

2004

2006

6.67 ± 2.48

2008

2010

2012

2014

Hydrogen •

Techno-economic Analysis 18 f 16 c 14 S M12 / 10 $ 8 1 6 1 0 4 2 2 0

•

24.23 ± 5.72 ~~~~~~~~~~~~~ ~~~~~~~~~~~~~~~ ~~~~~~~~~~~~~~ ~

12.52 ± 3.62

5.95

6.67 ± 2.48 IRR = 10%

Market Price (5-Yr)

nth-Plant MSP

25%

Pioneer Plant MSP

Market Analysis Average Product per Ton Biomass U.S. Consumption (EIA, 2013) 10% of U.S. Hydrogen Market Equivalent Biomass Consumption Equivalent Biorefineries

37,300 Scf / Ton 4.1T Scf / Year 0.41T Scf / Year 11 MMTon / Year

14


Methanol •

Catalytic Methanol Synthesis

Methanol Process

Sources

Min. Selling Price Range ($ / Gal)

Syngas to methanol via catalytic synthesis

Tarud & Phillips, 2011 McKeough & Kurkela, 2007 SRI PEP Yearbook, 2009 Williams et al, 1995 Hamelinck & Faaij, 2001

nth Plant

0.96 – 1.32

Pioneer 10% IRR

1.63 – 2.13

Pioneer 25% IRR

2.97 – 3.91

2.5

n2.0 o l l a1.5 G / $1.0 1 1 0 20.5 0.0 2000

Pioneer 10% IRR

1.93 ± 0.39 Contract Spot

Pricing History

nth Plant

2002

2004

2006

1.15 ± 0.26

2008

2010

2012

2014

Methanol as Chemical Intermediate •

Techno-economic Analysis 2.5

f 2.0 c S M 1.5 / $1.0 1 1 00.5 2 0.0

•

3.41 ± 0.64 ~~~~~~~~~~~~~ ~~~~~~~~~~~~~~~ ~~~~~~~~~~~~~~ ~

1.93 ± 0.39

1.16

1.15 ± 0.26

IRR = 10%

Market Price (5-Yr)

nth-Plant MSP

25%

Pioneer Plant MSP

Market Analysis Average Product per Ton Biomass U.S. Consumption (SRI / IHS, 2010)

170 Gallons / Ton 1.9B Gallons / Year

10% of U.S. Methanol Market Equivalent Biomass Consumption

0.19B Gallons / Year 1.1 MMTon / Year


1.4


Methanol as Fuel Intermediate •

Techno-economic Analysis 2.5

f 2.0 c S M 1.5 / $1.0 1 1 00.5 2 0.0

•

3.41 ± 0.64 ~~~~~~~~~~~~~ ~~~~~~~~~~~~~~~ ~~~~~~~~~~~~~~ ~

1.93 ± 0.39

1.16

1.15 ± 0.26

IRR = 10%

Market Price (5-Yr)

nth-Plant MSP

25%

Pioneer Plant MSP

Market Analysis Average Product per Ton Biomass U.S. Consumption (EIA, 2013) 10% of U.S. Hydrocarbon Fuels Market Equivalent Biomass Consumption Equivalent Biorefineries

65 Gallons / Ton 220B Gallons / Year 22B Gallons / Year 338 MMTon / Year

440


Conclusions •

Hydrocarbon, ethanol and methanol economics can be competitive for nth-plant.

•

Pioneer plant economics are challenged overall.

•

Market capacities do not constrain bio-product pathways in major hydrocarbon fuel markets (natural gas, petroleum fuels).

•

With fixed ethanol blend limit, cellulosic pathways and grainderived product will compete for limited market.

•

Market capacities for methanol-derived chemicals are constraining.

•

Syngas fermentation is potentially competitive, depending on CO / H2 conversion to product(s).

•

Methanol and ethanol are attractive intermediates for production of infrastructure-compatible hydrocarbons.

Future Work •

Develop design reports for selected biomass-to-hydrocarbon fuel pathways under DOE-BETO directed efforts.

•

Apply simplified TEA and market analysis on emerging pathways to identify economic feasibility in early stages of development.

•

Explore opportunities to improve Pioneer Plant economics o

Biomass co-feeding opportunities (NG-Biomass to Liquids)

o

Utilizing inexpensive feedstocks

o

High-value co-products

o

RIN credits

Acknowledgements •

•

•

•

Abhijit Dutta and Richard Bain (co-authors) Matt Worley and Ben Fierman of Harris Group Inc, Atlanta, Georgia. Bioenergy Technology Office (BETO) of the United States Department of Energy NREL Biorefinery Analysis and Thermochemical Platform Teams

Precio Syngas

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