Overview of the DOE Industrial Carbon Capture and Storage Program Overview of the DOE Industrial Carbon Capture and Storage Program Storage Program Storage Program Gasification Technologies Conference 2010 No ember 2 2010 Dr Darren Mollot November 2, 2010 Dr. Darren Mollot Director, Office of Clean Energy Systems Office of Fossil Energy
26
Embed
Overview of the DOE Industrial Carbon Capture and Storage ... · •Comppg glete 1st generation demonstrations addressing safe and reliable integration into power and industrial plant
This document is posted to help you gain knowledge. Please leave a comment to let me know what you think about it! Share it to your friends and learn new things together.
Transcript
Overview of the DOE Industrial Carbon Capture and Storage Program
Overview of the DOE Industrial Carbon Capture and Storage ProgramStorage ProgramStorage Program
Gasification Technologies Conference 2010No ember 2 2010
Dr Darren Mollot
November 2, 2010
Dr. Darren MollotDirector, Office of Clean Energy Systems
Office of Fossil Energy
1
Why Invest in CCS
“Overwhelming scientific evidence shows that CO2 emissionsOverwhelming scientific evidence shows that CO2 emissions from fossil fuels have caused the climate to change, and a dramatic reduction of these emissions is essential to reduce the risk of future devastating effects.” Sec. Chu, Science g ,Magazine, Sept. 2009
“Coal is essential as a leading source of energy for the UnitedCoal is essential as a leading source of energy for the United States and the world well into the future. But for our state and nation to remain strong and competitive, we must have a real and urgent plan to invest in new technologies, especially g p g p ycarbon capture and storage or CCS,” Sen. Rockefeller August, 2010
2
Path Forward
3
Carbon Capture & Storage RD&D Goals
Early low-cost, reliable and safe CCS deployment becomes a viable technology option and significant contributor to achieving
the President’s Greenhouse Gas reduction target of >80% by 2050
• Accelerate CCS deployment potential by 10 years.
g % y
p y p y y
• Leverage R&D investment against potential savings in cost of electricity and capital investment relative to current baseline R&D.
• Complete 1st generation demonstrations addressing safe and reliable p g gintegration into power and industrial plant operations in the 2015 timeframe.
• Accelerate new, advanced 2nd Generation CCS and power plant technologies to reduce cost and be in a position to rapidly deploy low-cost CCS in post 2020 time frame.
• Expedite the development and demonstration of “transformational CCS technologies” aimed at revolutionizing the market for low-carbon power and industrial markets in the 2030 timeframe.
4
American Recovery and Reinvestment Act of 2009 (Stimulus) Funding Summary( ) g y
Program/Project Activity ($ in thousands)
Clean Coal Power Initiative (CCPI) - Round 3 800,000
Fossil Energy R&D (FutureGen) 1,000,000
CCS from Industrial Sources 1,520,000
Site Characterization 50,000
Regional Sequestration Training and Research 20,000
Fossil Energy Program Direction 10,000
Total 3,400,000
5
Accelerating Coal CCS Program R&D by 10 Years … Achieving the President’s GHG Reduction Targetsg g
DOE Base R&D – Enables 2nd Gen technology deployment by 2030
• Department’s Target‐level budget provides $1.651 Billion FY11‐15 for core R&Ddi d i ifi i d b i b d h i h f d i i• Readies 2nd Generation gasification and combustion‐based pathways with CCS for demonstration in 2026
timeframe
Accelerated R&D – Enables 2nd Gen technology deployment by 2020 (+$635M ARRA Funds)
• Additional investment of $635 million accelerates power and industrial carbon capture technology forAdditional investment of $635 million accelerates power and industrial carbon capture technology for existing plants, oxy‐combustion for existing and new plants, advanced gasification and turbine combined cycle plants with CCS, and carbon storage site characterization
• Readies 2nd Generation gasification and combustion electric power production systems with CCS for demonstration in 2016 timeframe
• Establishes the Carbon Capture Simulation Initiative (NETL and other National Labs) and NETL’s Simulation‐based Engineering User Center linked with the Regional University Alliance
• Support transformation research and flexibility to integrate OS and ARPA‐E technology
• Saves the Nation $300 billion in electricity costs reduces capital investment requirements by $80 billion• Saves the Nation $300 billion in electricity costs, reduces capital investment requirements by $80 billion thru 2050 based on STEP Base Case Analysis
• Does not include benefits of applying CCS to existing or new NGCC plants, or growing benefits beyond 2050
• Maintains U.S. leadership in CCS and promotes global deployment
6
Driving Down the Cost of CCS with Advanced Technology (IGCC)
160
with Advanced Technology (IGCC)Cost of Electricity (COE) decreases by 30%
140
150
160
2009
$/M
Wh)
IGCC with capture
110
120
130
st o
f Ele
ctric
ity (2
IGCC t
80
90
100
Leve
lized
Cos IGCC no capture
Supercritical PC no capture
70
80
efer
ence
al P
ump
85%
CF
War
m
Cle
anup
H2
embr
ane
Adv.
Tu
rbin
e
ITM
Adv.
rb
ine
(II)
90%
CF
SO
FC7
Re
Co C
Me
Tu
CCS Demonstrations for 1st Gen Technology Location & Cost ShareLocation & Cost Share
Basin ElectricPost Combustion CO2 Capture
$287M T t l
Basin ElectricPost Combustion CO2 Capture
$287M T t l
Archer Daniels MidlandIndustrial Power & Ethanol
$164M – Total
Archer Daniels MidlandIndustrial Power & Ethanol
$164M – Total
Future GenIGCC w/ Full Carbon Capture
$3.052B – Total$1.070B – DOE
Future GenIGCC w/ Full Carbon Capture
$3.052B – Total$1.070B – DOE
Summit TX Clean EnergyCommercial Demo of AdvancedSummit TX Clean EnergyCommercial Demo of Advanced
$287M – Total$100M – DOE$287M – Total$100M – DOE
$$99M – DOE
$$99M – DOE
$$
Commercial Demo of AdvancedIGCC w/ Full Carbon Capture
$1.727B – Total$350M – DOE
Commercial Demo of AdvancedIGCC w/ Full Carbon Capture
IGCC w/ Full Carbon Capture$2.840B – Total$308M DOE
Post Combustion CO2 Capture$668M – Total$334M – DOE
Post Combustion CO2 Capture$668M – Total$334M – DOE
$167M – DOE$167M – DOE
w/Carbon Capture$2.880B – Total$270M – DOE
w/Carbon Capture$2.880B – Total$270M – DOE
$308M – DOE
Air ProductsH2 Production$384M – Total$259M – DOE
Air ProductsH2 Production$384M – Total$259M – DOE
Leucadia EnergyMethanol
$432M – Total$259M – DOE
Leucadia EnergyMethanol
$432M – Total$259M – DOE
8
Cl C l P I iti ti (CCPI)Clean Coal Power Initiative (CCPI)
9
USDOE CCS Utility Demonstration ProjectsBasin ElectricBasin Electric
Post Combustion • 120 MWe Slipstream from
Existing PC Plant• Capture 1 Million TPY CO2
Inject in Saline Reservoir
AEP MountaineerPost Combustion
• 235 MWe Slipstream from Existing PC Plant
C t 1 5 Milli TPY CO
Hydrogen Energy California IGCC Inject in Saline Reservoir
• HTC Purenergy Amine • Mar 2011 - Oct 2013
$100M DOE $287M Total
• Capture 1.5 Million TPY CO2 Inject in Saline Formation
• Chilled Ammonia• Jan 2013 – Dec 2015
$334M DOE $668M Total
• 257 MWe Net, 75% Coal/ 25% Petcoke
• 90% Capture - 2 Million TPY CO2for EOR
• Feb 2012 – Nov 2016
Southern Company ServicesIGCC-Transport Gasifier
$308M DOE $2,840M Total
S C
• 582 MWe Net, Lignite• Designed for 67% Capture –Initially 1 million TPY For EOR• June 2010 – May 2014
$294M DOE $1,625MTotal
NRG EnergyPost Combustion
• 60 MWe Slipstream from Existing PC Plant• 90% Capture- 400,000 TPY CO2 for EOR
Summit Texas Clean EnergyIGCC
• 400 MWe Net, Coal• 90% Capture – 3 Million TPY CO2
for EOR
10
• Fluor Economine FG Plus (advanced)• Ramgen Advanced Compressor• Dec 2012 – Dec 2014
$167M DOE $334M Total
• Oct 2010 – July 2014$350M DOE $1,726M Total
F t G 2 0FutureGen 2.0
11
FutureGen 2.0
FutureGen Goals:• Provide a clean coal repowering program and carbon dioxide (CO2) storage network.
The world’s first commercial scale oxy combustion power plant• The world’s first, commercial-scale, oxy-combustion power plant• Will help to open up the over $300 billion market for coal unit repowering and
position the nation’s electric power sector to utilize technologies that could capture and sequester significant amounts of CO2
• To repower Ameren’s 200 megawatt Unit 4 in Meredosia Illinois with advanced oxy-• To repower Ameren s 200 megawatt Unit 4 in Meredosia, Illinois with advanced oxy-combustion technology. The plant’s new boiler, air separation unit, CO2 purification and compression unit will deliver 90 percent CO2 capture and eliminate most SOx, NOx, mercury, and particulate emissions.
• Cooperative agreements have being negotiated that awarded $1 billion in Recovery A t f di t th F t G Alli A E R B b k & WilAct funding to the FutureGen Alliance, Ameren Energy Resources, Babcock & Wilcox, and American Air Liquide.
• In addition, the project partners, working with the State of Illinois, will establish a regional CO2 storage site and a CO2 pipeline network that will transport and store more than 1 million tons of captured CO2 per year.
12
p 2 p y• Project partners estimate the program will bring 900 jobs to downstate Illinois and
another 1,000 to suppliers across the state.
FutureGen 2.0
Project Details:• Cooperative Agreement signed on September 28, 2010• Preparations are underway for the repowering of Unit 4 at the Ameren facility in Meredosia,
with construction set to begin in 2012with construction set to begin in 2012.• The Project scope includes the project definition, design, procurement, manufacture,
installation, startup, commercial operation and testing of an integrated oxy-fired coal plant with CO2 capture, purification and compression.
• The plant will generate approximately 202 MW gross output with a plant net output of 139 MW• The plant will generate approximately 202 MW gross output with a plant net output of 139 MW. • Validate the technical and financial feasibility of the use of the oxy-combustion technology for
utility power plant applications • Be a Near Zero Emissions Plant (NZEP)
Treat 100% of the flue gas and remove 90+% of the CO resulting in the capture of• Treat 100% of the flue gas and remove 90+% of the CO2 resulting in the capture of approximately 1.3 million tonnes (1.3MMT) per year of CO2 from the plant
• The CO2 will be cleaned and compressed for transport and delivered to a terminal point for transfer to the FutureGen 2.0 Pipeline and Regional CO2 Storage Reservoir Project.
13
FutureGen 2.0
Project Details:• Cooperative Agreement signed on September 27, 2010• The sequestration component includes the development of a geologic storage facility
integrated with the operations of the oxy-combustion surface facility to be located atintegrated with the operations of the oxy-combustion surface facility to be located at Meredosia, Illinois. The scope of this project includes: – the selection of a suitable sequestration site– the development of the subsurface sequestration field
the development of any necessary CO2 transport infrastructure (e g pipeline)– the development of any necessary CO2 transport infrastructure (e.g., pipeline)– the design and construction of associated visitor research and training and education
facilities.• A site selection process is being conducted to locate a site for the carbon sequestration
research repowering workforce training facility visitor center and long-term COresearch, repowering workforce training facility, visitor center, and long-term CO2repository.
– 10/28/2010 - Site Selection Bidders and Public Information Meetings (Springfield, IL)– 11/15/2010 - Site Offeror’s formal proposal due to FGA
• A state-of-the-art international training center will prepare future operators for careers in
14
• A state-of-the-art international training center will prepare future operators for careers in coal plant repowering, future CO2 pipeline networks, and storage facility development.
I d t i l C b C tIndustrial Carbon Capture & Storage (ICCS)g ( )
15
Industrial CCS Project LocationsLarge-scale CCS from Industrial Sources (Area 1)
Objectives
Large scale CCS from Industrial Sources (Area 1)
• Demonstrate advanced CCS technologies• To progress beyond the R&D stage of readiness
I t ti ith h i M it i• Integration with comprehensive Monitoring, Verification & Accounting (MVA)
Site selection and characterization Permitting and NEPA compliance;
W ll l ti d t ti
Scale up is required to provide insight into several operational and technical i th t diff f f ti tWell completion and testing;
Infrastructure development.
Stage 2
issues that differ from formation to formation
Stage 2.
CO2 procurement and transportation; Injection operations; Monitoring activities.
Stage 3.
Site closure; Post-injection monitoring; Project assessment.
RCSP Development Phase – 10+ years (FY 2008-2017+)
24
RCSP Development Phase – 10+ years (FY 2008-2017+)
Regional Carbon Sequestration Partnerships Phase III: Development Phase
5
Injection Well Drilled
Core Sampling Taken
pLarge-Scale Geologic Tests
8
31
2
4
9
Nine large-volume testsInjections scheduled 2011/2015
76
9Partnership Geologic Province Type
Big Sky Triassic Nugget Sandstone / Moxa Arch Saline
MGSC Deep Mt Simon Sandstone Saline
1
2 MGSC Deep Mt. Simon Sandstone SalineMRCSP St. Peter Sandstone Saline
PCORBell Creek Field Oil Bearing
Devonian Age Carbonate Rock Saline
2
3
4
5
Injection Started
g
SECARBLower Tuscaloosa Formation
SalinePaluxy Formation
SWP Regional Jurassic & Older Formations Saline
Injection Ongoing
Injection Scheduled 2011/2015 7
8
6
5
Note: Some locations presented on map may differ from final injection location
25
FormationsWESTCARB Central Valley Saline9
differ from final injection location
Observations and Challenges
• Technology is available today for carbon capture from new and retrofitted coal-fired IGCC and PC power plants, however:retrofitted coal fired IGCC and PC power plants, however:– It is very expensive– Parasitic load is very high– Reliability needs to be provenReliability needs to be proven
• DOE RD&D program is targeting the key issues – Improve efficiency of system (low hanging fruit)