ACO TM, The Advanced Catalytic Olefins Process Michael Tallman Evolution of the Modern Car 18: Inventor Cugnot invents steam powered car 18 s Steam Powered Car 187 1 st Gasoline Powered Car Early 19s 187: 1 st gasoline powered car Timeline Early 19 s, mass production of cars Bigger cars fueled by oil Hybrid cars, a response to a need Energy Efficient Hybrid Car Bigger & Better Cars Necessity is the mother of invention Plato 428BC-348 BC
Evolution of Thermal Cracking 19 s: investigations in thermal cracking for fuels 192 s: first steam cracker (Union Carbide) 1921 Dubbs Thermal Cracker 1925, 1 st Commercial Plant 194-6: advances in technology TIME LINE 196-now: revolutionary advances 26: Mega crackers 21: ACO 1953 KBR Plant ICI England 198s KBR Plant- Idemitsu, Japan ACO Reactor Singapore Olefins Plant Current State of the Art Thermal Cracking Breaking and rearrangement of chemical bonds High temperatures required, >85C Overall olefins yields decline with heavier feeds /ethylene (P/E) ratios ~.4-.6 Steam Cracking Wt% Yield 8 6 4 2.1.4.43.53.58 P/E Ethane Propane Butane Lt. Naph Hvy. Naph
Handling of Coke and Heavy Ends is Not a Fun Activity in Steam Cracking! A Paradigm Shift The ACO Process Development of a CATALYTIC route to ethylene and propylene Lower temperatures, ~6-7C Higher olefins yield with liquid feeds Very little coke production P/E ratios of ~1/1 Utilize most common liquid feeds available (straight run naphtha and distillates) Advanced Catalytic Olefins (ACO)
The Olefins Market World Demand Forecast ~4% overall growth ~5% overall growth Million Metric Tons 16 14 12 1 8 6 4 2 1 2 3 4 5 6 7 8 9 1 PE Oxide EDC EBz Others Capacity Million Metric Tons 1 Polypropylene Cumene Steam cracking will NOT meet future propylene demand 8 6 4 2 World Demand Forecast Capacity 1 2 3 4 5 6 7 8 9 1 Acrylonitrile (Source: CMAI) Oxo Alc Oxide Acrylic Acid Others Sources 54 KTA in 2 66 KTA in 25 89 KTA in 21 Plant 66% Refineries 31% Plant 65% Refineries 31% Plant 57% Refineries 31% Other 3% Other 4% Other 12% Steam Cracking Wt% Yield 8 6 4 2.1.4.43.53.58 P/E Ethane Propane Butane Lt. Naph Hvy. Naph
Olefins Regional Issues % Total Supply 45 Regional Growth 35 25 Europe Americas 15 5 (Source: CMAI) 9 92 94 96 98 2 4 6 8 1 12 Olefins Regional Issues Regional Growth % Total Supply 45 35 25 15 5 Europe Asia Pacific (Source: CMAI) Americas Africa/Middle East 9 92 94 96 98 2 4 6 8 1 12 Highest growth in Middle East Ethane feed makes little propylene Asia market also increasing
Olefins Regional Issues Regional Growth 24-12 Incremental Olefins Growth % Total Supply 45 35 25 15 Europe Asia Pacific Americas KTA Olefins 25 2 15 1 Source: Refineries, Nexant PERP Report Africa/Middle East 5 (Source: CMAI) 9 92 94 96 98 2 4 6 8 1 12 Highest growth in Middle East Ethane feed makes little propylene Asia market also increasing 5 N America S America W Europe Middle East Asia has very high P/E demand Asia Pacific P/E Ratios.77.44 1.5.24.85 What Does This All Mean? growth lower than propylene growth Alternative propylene technologies needed Shift to lighter feeds will give lower P/E Steam Crackers will not meet propylene demand ACO can be a technology solution
ACO Process Why Straight Run Feeds? Production by Feedstocks Source: CMAI Capacity Ethane Propane Butane Naphtha Gas Oil Others KTA Olefins 16 14 12 1 8 6 24-12 Incremental Olefins Growth Source: Refineries, Nexant PERP Report The majority of global ethylene is produced from liquid feed Straight run naphtha is the predominant feed globally Greater than 5% of ethylene made from naphtha Widely available Most common feed in Asia (highest P/E ratio) 4 2 N America S America W Europe Middle East Asia Pacific Asia has very high P/E demand ACO Process Uses Naphtha Feeds Production: Millions KTA Olefins Production by Feedstocks Source: CMAI Capacity 2 21 22 23 24 25 26 27 28 29 21 Ethane Propane Butane Naphtha Gas Oil Others 16 14 12 1 8 6 4 2 24-12 Incremental Olefins Growth Source: Refineries, Nexant PERP Report N America S America W Europe Middle East Asia Pacific Straight run naphtha is the predominant feed globally Widely available Greater than 5% of ethylene made from naphtha Naphtha is the most common feed in Asia Naphtha becoming more common in Middle East
ACO Process Key Features - Reactor Straight Run Naphtha Proprietary KBR FCC reactor features /ethylene (P/E) Product Ratio ~1/1 Proprietary catalyst from SK Corporation All proven hardware and processes Robust and flexible, compared to other processes ACO Process Key Features - Separation Reactor Effluent R E C O V E R Y Tail gas BTX gasoline Product treatment and separation follows ethylene plant technology Compression Acid gas removal and drying Separation and fractionation to chemical or polymer grade products Proprietary expertise for trace impurities removal C4s and C5s can be recycled to reactor with no further treatment All proven technology
ACO Key Features Summary Co-developed by SKenergy (Korea) and KBR Worldwide licensing rights by KBR SKenergy will become the first commercial user of ACO Plans underway to install ACO reactor at the SK complex at Ulsan, Korea ~21 startup SKenergy Background Large conglomerate ~$24 billion 26 sales ~5.8 MM t/a products volume Very large olefins facilities 2 KBR steam crackers at Ulsan ~8 kta ethylene Regional need for propylene and high P/E SK plans to become the first adopter of ACO process by 21
SKenergy Experience and Status Zeolite ACO Catalyst SK pilot plan Key to ACO is catalyst Developed by SK R&D Worldwide patents in progress High acid activity tailored to light olefins and LPG production High hydrothermal stability to high temperature steam Pilot testing conducted at SK R&D in Daejeon Fluidized bed reactor Fractionation recycle capability KBR Experience and Status Sasol SUPERFLEX Feb 26 KBR Fluid Bed Catalytic Cracking Pilot Plant KBR Fluid Cat Cracking 5+ years Process/ mechanical design More than 12 units worldwide Yield Predictions Development & modeling KBR in-house and client feed pilot studies Sasol SUPERFLEX Startup and Commercialization
Case Study Light Straight Run (LSR) Naphtha Case 1: Conventional Steam Cracker 1 kta ethylene ~.5 P/E ratio Case 2: ACO Process Maintain same feed rate as Case 1 ~1/1 P/E ratio ACO Reaction Section To Flue Gas System CW Reactor Effluent To Recovery Catalyst Fines ACO Orthoflow Reactor / Regenerator Catalyst Storage And Handling Steam BFW Fuel Oil Oil Wash Tower Fresh Feed Recycle Regeneration Air
ACO Recovery Section Mix C4/C5/C6 NA Recycle to Reactor 1-2 Drying 3 Quenched Gas Treating Coldbox C3 Ref C2 Ref C2 Splitter C3 Splitter Dehexanizer Light gas Depropanizer Demethanizer Deethanizer BTX+ Ethane/ Propane Steam Cracker Yields Wt% 1 75 5 Other Gasoline 25 Steam Cracker
Steam Cracker vs. ACO Overall Yields Wt% 1 75 Compared to Steam Cracker ACO has ~15-2% relatively higher olefins yield 5 25 Steam Cracker ACO Other Gasoline ACO has higher P/E of ~1/1 ACO makes more 25% more BTX ACO can recycle all the C4s/C5 without additional treating Steam Cracker vs. ACO Cost of Production (COP) Case 1 Steam Cracker Cost of Production = ~$73/MT Case 2 ACO Cost of Production = $64/MT Feed minus byproduct Utility & Operation Cost Other Costs Depreciation & Profit Feed minus byproduct Utility & Operation Cost Other Costs Depreciation & Profit
ACO Advantages Converts widely available feeds to ethylene and propylene Straight run naphtha, distillates Higher total light olefins yields compared to steam cracker P/E ratio of 1/1 addresses propylene market More BTX for potential recovery, higher octane No C4/C5 processing required, all C4/C5 utilized in the ACO process Attractive ACO economics compared to steam cracking CO2 Emissions lower than the steam cracking case Advanced Catalytic Olefins Process ACO Naphtha & Distillates Recycle R E C O V E R Y Tail gas BTX gasoline President Challand and President Shin at signing ceremony High growth rates for both ethylene & propylene plants will not meeting propylene growth On Purpose technologies require niche feedstocks Consider ACO Process Higher overall yields 1/1 P/E ratio Commercialization plans by 21 by SK
Thank you very much Questions?