The Characteristics of Catalyst-coated Highly Reactive Coke
スポンサーリンク
概要
- 論文の詳細を見る
It is important to develop the production and utilization technology of highly reactive coke in order to improve the efficiency of blast furnace reactions. In this study, the characteristics of catalyst-coated highly reactive coke produced by the ‘post-addition of catalyst to coke’ method were investigated. First, the catalytic effect of Fe and Ca on graphite and deashed coke during the C–CO2 reaction was investigated. Fe and Ca addition increased the reaction rate and decreased the reaction beginning temperature. Second, the reaction rate of Fe or Ca coated coke was kept high until the weight loss reached 10%. This means that a high catalytic effect is maintained in the thermal reserve zone of the blast furnace. Furthermore, it was found that 70% of the catalyst coated on the coke surface remains after drop impacts. It is expected that the loss of catalyst during coke handling and transportation is small. Catalyst-coated highly reactive coke is promising for improving the efficiency of blast furnace reactions.
- 社団法人 日本鉄鋼協会の論文
- 2007-02-15
著者
-
Nomura Seiji
Environment & Process Technology Center, Nippon Steel Corporation
-
NAITO Masaaki
Environment & Process Technology Center, Nippon Steel Corporation
-
Naito M
Environment & Process Technology Center Nippon Steel Corporation
-
Nomura Seiji
Environment & Process Technol. Center Nippon Steel Corp.
-
Nomura S
Environment & Process Technology Center Nippon Steel Corporation
-
KITAGUCHI Hisatsugu
Advanced Technology Research Laboratories, Nippon Steel Corporation
-
YAMAGUCHI Kouichi
Oita Works, Nippon Steel Corporation
-
Kitaguchi Hisatsugu
Advanced Technology Research Laboratories Nippon Steel Corporation
-
Kitaguchi Hisatsugu
Advanced Research Technology Center Nippon Steel Corp.
-
Yamaguchi Kouichi
Oita Works Nippon Steel Corporation
-
Naito Masaaki
Nippon Steel Corporation Environment & Process Technology Center
関連論文
- Estimation of Bulk Density Distribution in Particle Charging Process Using Discrete Element Method Considering Particle Shape
- Non-spherical Carbon Composite Agglomerates : Lab-scale Manufacture and Quality Assessment
- Optimization of Chemical Composition and Microstructure of Iron Ore Sinter for Low-temperature Drip of Molten Iron with High Permeability
- Blast Furnace Ironmaking System Using Partially Reduced Iron Ore Reduced by an Energy Source with Low Carbon Content
- The Characteristics of Catalyst-coated Highly Reactive Coke
- Improvement in Blast Furnace Reaction Efficiency through the Use of Highly Reactive Calcium Rich Coke
- Effects of Coal Inertinite Size on Coke Strength
- Waste plastics recycling process using coke ovens
- Some Fundamental Aspects of Highly Reactive Iron Coke Production
- Estimation of Bulk Density Distribution in Particle Charging Process Using Discrete Element Method Considering Particle Shape
- Analysis of Exhaust Gas Visibility in Iron Ore Sintering Plant
- Post-reaction Strength of Catalyst-added Highly Reactive Coke
- Reaction behavior of Formed Iron Coke and Its Effect on Decreasing Thermal Reserve Zone Temperature in Blast Furnace
- Enhancement of Low-temperature Gasification and Reduction by Using Iron-coke in Laboratory Scale Tests
- Quantitative Evaluation of Relationship between Coke Strength and Pore Structure
- Quantification of the Existence Ratio of Non-Adhesion Grain Boundaries and Factors Governing the Strength of Coke Containing Low-Quality Coal
- Numerical Analysis of 3-D Microstructure of Coke Using Micro X-ray CT
- Numerical Analysis of 3-D Microstructure of Coke Using Micro X-ray CT