鉄と鋼
Online ISSN : 1883-2954
Print ISSN : 0021-1575
ISSN-L : 0021-1575
101 巻, 12 号
選択された号の論文の6件中1~6を表示しています
高温プロセス基盤技術
論文
  • 鍋島 誠司, 小川 尚志, 三木 祐司
    2015 年 101 巻 12 号 p. 627-635
    発行日: 2015年
    公開日: 2015/11/30
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    To clarify the effects of blowing a H2-N2 mixture onto the surface of molten steel containing various oxygen contents on the absorption reaction of nitrogen in the molten steel, experimental studies were carried out using a 20 kg induction furnace. Blowing of the H2-N2 mixture accelerates the nitrogen absorption rate because the oxygen concentration at the gas-metal interface is decreased by the reducing effect of the hydrogen gas. The apparent chemical reaction rate of nitrogen absorption in the present work was evaluated at almost the same reaction rate as that of desorption of nitrogen in previous works. Furthermore, a mathematical model for the nitrogen absorption and desorption reactions in a RH degasser was developed in order to estimate the contribution of each nitrogen reaction site during decarburization and killing treatment with injection of pure N2 gas or the H2-N2 mixture in the molten steel. Using the mathematical model, it was estimated that a larger increase in the nitrogen concentration during decarburization treatment could be achieved by applying a 30% H2-N2 mixture to the injection gas in the RH degasser than by applying pure N2 gas.
  • 山口 勝弘, 小野 英樹, 竹内 栄一
    2015 年 101 巻 12 号 p. 636-644
    発行日: 2015年
    公開日: 2015/11/30
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    The copper distribution ratio between the Na2S flux and silver, LCu(flux-Ag) (=[mass% Cu](in flux) / [mass% Cu](in Ag)), was measured at 1473 K in order to know the copper capacity of Na2S flux. As the greatest value, LCu(flux-Ag) = 42 was obtained. By combining the LCu(flux-Ag) value with the distribution ratio of copper between the silver and the carbon-saturated iron, LCu(Ag-Fe), the distribution ratio of copper between the Na2S flux and carbon-saturated iron, LCu(flux-Fe), is derived to be 330 at 1473 K. Moreover, the sulfurization removal of copper in iron silver phase into Na2S flux has been tried at 1473 K. Silver can keep iron from being sulfurized, which enables to maintain the high copper capacity of the Na2S flux. For this reason, the LCu value increases with an increase of sulfur potential. Copper removal proceeds at lower 0.1mass%Cu, and the Cu content decreased to 0.06mass%. The silver phase prevents the sulfur dissolution into the iron, and the sulfur content of iron can be kept lower ([mass%S]in Fe-C < 0.007-0.02).
製銑
論文
  • 小西 宏和, 小野 英樹, 谷澤 賢司
    2015 年 101 巻 12 号 p. 645-652
    発行日: 2015年
    公開日: 2015/11/30
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    Kinetics of iron carburization via CaO-SiO2-Al2O3 slag containing sulfur at 1723 K was investigated. The simulated blast-furnace (B.F.) slag (CaO/SiO2=1) containing sulfur and high basicity slag (CaO/SiO2=7.6) containing sulfur were prepared. The rate of carburization of iron through the high basicity slag containing sulfur was higher than the rate of carburization of iron through the simulated blast-furnace slag containing sulfur. Furthermore, the rate of carburization of iron through the slag containing sulfur was higher than the rate of carburization of iron through the slag without sulfur. On the other hand, the rates in the middle stage of carburization of iron through the slag containing sulfur were k=6.15×10–5 mol/m2·s (the simulated blast-furnace slag) and k=1.35×10–4 mol/m2·s (the high basicity slag), and were much higher than the other stages, and were influence by the existence of sulfur in the slag. The rates in the last stage of carburization of iron through the slag containing sulfur were k=2.95×10–5 mol/m2·s (the simulated blast-furnace slag) and k=6.21×10–5 mol/m2·s (the high basicity slag), and were closed to the rates carburization of iron through the slag without sulfur, and were not influenced by the existence of sulfur in the slag.
  • 村尾 明紀, 柏原 佑介, 高橋 功一, 大山 伸幸, 松野 英寿, 佐藤 道貴
    2015 年 101 巻 12 号 p. 653-660
    発行日: 2015年
    公開日: 2015/11/30
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    Reducing CO2 emission in ironmaking process is pressing issue. Low RAR (reducing agent rate) operation of the blast furnace and the utilization of hydrogenous reducing agent are effective to reduce CO2 emission. In this study, the influence of the hydrogenous reducing agent on the combustibility of the pulverized coal was examined by using a small scale combustion furnace. As a result, the combustibility of the pulverized coal was improved by simultaneous injection of the pulverized coal and the hydrogenous reducing agent. Furthermore, the fundamental study about the effect of natural gas (CH4) injection point on the combustibility of the pulverized coal was conducted by experiment using above mentioned small scale combustion furnace and by three-dimensional numerical analysis for further high efficiency. In the case of the relative position of CH4 injection point and the pulverized coal injection point being near, the ignition point of the pulverized coal came closer to lance tip. Especially, in the case of CH4 injection point being upstream in blow pipe about 0 to 20 mm from the pulverized coal injection point, the fastest ignition of the pulverized coal was confirmed by experimental and calculation results.
鋳造・凝固
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