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Yasunari Matsuno, Ichiro Daigo, Masaru Yamashita
Reduction of Environmental Impacts by Development of Industrial Symbiosis in Japan - Case Studies for Application of Co-production Technologies in Steel Industries and its Reduction Potential of Greenhouse Gas Emissions - Yasunari Matsuno, Ichiro Daigo, Masaru Yamashita and Yoshihiro Adachi Department of Material Engineering, Graduate School of Engineering, The University of Tokyo
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Topics Introduction – Backgrounds of this study
What is “Co-production” technology Application of Co-production technologies in Steel industry Low-temperature Gasification Plant CO2 Recovery and Utilization System Results of the case studies Conclusion
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Recycle-oriented Society Kyoto Protocol (Reduction of GHGs)
Industrial symbiosis Industry A Industry A Energy, Resources Energy, Resources Industry B Industry B Industry C Industry C To maximize energy, resource, environmental efficiency Individually optimization
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Example of “Industrial symbiosis” Jurong Island, Singapore
Oil coal Natural gas Low grade oil Fuel Oil Steel, Cement Recycle Hub゙ (value chain cluster) Environment Final wastes CO2, Exhaust heat Products Wastes Power, gas Recycled materials H2 , Syngas High press. Steam Elec. Power Fuels IGCC Power Plant consumer Final wastes Chemicals Medicine To develop Jurong Island into a World-Class Chemicals Hub in the Asia Pacific Region
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Locations of key industries
Steel works Refineries – Petroleum industry Ethylene plants – Petrochemical industry LNG tanks Potentials to develop industrial symbiosis
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What is co-production technology?
- Technologies for Industrial symbiosis (1) Existing System Main products ・Goods ・Electricity ・Materials Fuels,Energy Power Generation Manufacturing Pro. Raw materials Large amount of waste heat (2) Co-production System Main products ・Goods ・Electricity ・Materials Fuels,Energy Power Generation Manufacturing Pro. materials Raw materials Wastes Little waste heat Co-products ・Fuels ・Chemicals ・Steam etc. Newly Energy Saving Process
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Industry A Industry A Industry B Industry C Industry B Industry C
Energy, Resources Energy, Resources Industry B Industry C Industry B Industry C
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Goal and scope ・ To investigate environmental impacts of Co-production technologies (for Industrial symbiosis) Gasification plant Dry ice (cryogenic energy ) production plant with CHP Steel works ・ To expand system boundary to evaluate total environmental impacts
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Methodology 1. To investigate where to apply co-production technologies ・Industries (capacity, location) ・Waste heat distribution ・Demand and supply of products, energy 2.To conduct LCA for co-production technologies - CO2 emissions- 3.To optimize the transport of products by Linear Planning method 4.To investigate total environmental impacts
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Steel plant with co-production process
1st Step To assess the reduction potential of environmental impacts by co-production technology. To compare with current technology. 2nd Step To assess the reduction potential of environmental impacts in a industrial cluster scale. To investigate the demand and supply of energy and products. To develop a model 3rd Step To assess the reduction potential of environmental impacts in a regional (country) scale. To develop database. To integrate with other tools. Power stations Demand and Supply Grid mix Conventional process Electricity Co-production technology Steel plant with co-production process Fuel gas Demand and Supply Current technology
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Where to apply co-production technologies?
- Waste heat distribution in industries in Japan Others Paper pulp Electricity Ceramic Waste incin. 9% Steel Chemical Waste heat amount Waste heat distribution Apply Co-production technology to Steel industry
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Exhaust gas from Coke oven, BFG etc
Waste heat distribution in steel works Water Solid Gas Exhaust gas from Coke oven, BFG etc COG LDG etc
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Methanol: easy for storage,
Co-production technology (1) High efficiency gasification plant with high-temperature waste heat (600℃) High-temperature Waste heat Methanol Tar 1t Gas 5810 Mcal CO/H2=2 8300Mcal or Waste heat at 873 K 1300 Mcal Gasification plant Electricity Steam Methanol: easy for storage, Utilizing waste heat
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ICFG : Internally Circulating Fluidized-bed Gasifier
Synthesis Gas Combustion Gas Gasification Chamber Char-Combustion Fluidizing medium descending zone Heat Recovery Fluidizing medium & Pyrolysis Residue (Char, Tar) Heat Transfer Tubes Steam Air Feedstock (Fuel or Wastes)
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Co-production technology (2)
Dry Ice (cryogenic energy ) production with CHP (Utilizing waste heat) Low temperature waste heat Exhaust gas recovery DI CHP Waste heat at at 423 K 305kcal Dry ice production process 1kg Electricity: kWh
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Co-production technology (2)
Compressor Gas Cooler Liquefier Sub-cooler Liquefied CO2 tank Flash tank CO2 gas from co-production processes High-stage expander Cooling Tower Chemical Heat Pump Dry-Ice Low-stage expander Dry-Ice press
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Fig. CO2 emission intensity for co-products (kg-CO2/kg)
LCA for Co-production technologies Fig. CO2 emission intensity for co-products (kg-CO2/kg)
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Location of steel works in Japan
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Location of methanol consumer in Japan
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Location of steel works and methanol consumer in Japan
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Total CO2 emissions - Core technology
Fig. CO2 emission intensity of methanol
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Total CO2 emission reduction potential in Japan
CO2 emission reduction potential by co-production technologies: Methanol: ton-CO2/ton-methanol Dry ice: ton-CO2/ton-dry ice Current demand in Japan: Methanol: 1.8 million ton/y, Dry ice: 0.24 million ton/y Total CO2 emission reduction potential in Japan: Methanol: million ton/y Dry ice: million ton/y
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PP pellet (3mm diameter) Microscope of crushed pp pellet (200μm/div)
Other possible application of dry ice Low temperature crushing of PP pellet PP pellet (3mm diameter) Microscope of crushed pp pellet (200μm/div)
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Low temperature crushing of PP - Conventional technology
Crushed PP:1 kg PP pellet: 1 kg CO2 emissions: 2.33 kg-CO2 Liquefied N2: 9.68 kg Δ2.10 kg-CO2 Low temperature crushing of PP - by dry ice Crushed PP:1 kg PP pellet: 1 kg Dry ice: 3 kg CO2 emissions: 0.23 kg-CO2 Potential demand of crushed PP: million ton/y (0.64% of total PP) CO2 reduction potential: million ton-CO2
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Conclusion Methanol production by co-production technology (gasification plant) will reduce CO2 emissions by 91% compared with conventional technology (92% reduction in production, 90% reduction in transport) Total CO2 emission reduction potential in Japan by methanol production : 0.6 million ton-CO2 Dry Ice (cryogenic energy) production by co-production technology will also reduce CO2 emissions by 64% compared with conventional technology. Total CO2 emission reduction potential in Japan is 0.03 million ton-CO2. Other CO2 reduction potential by applying dry ice is being investigated, such as low temperature crushing of PP pellet
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