Some Properties and Degrading Patterns of Materials in a Blast Furnace Shaft

Jōmoto, Yoshiteru; Kanayama, Yuji; Okuno, Yoshio; Isoyama, Masashi

doi:10.2355/tetsutohagane1955.57.10_1606

Cited by 5 publications

(4 citation statements)

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“…The degradation behavior of sinter in the blast furnace will be discussed at another opportunity. The RDI value in (1) or 33.9 % is close to the values in (3).…”

Section: Relationship Between Rdi and Degradation Degree Insupporting

confidence: 80%

Investigation of degradation of sinter in blast furnace with a new vertical probe.

et al. 1986

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“…The degradation behavior of sinter in the blast furnace will be discussed at another opportunity. The RDI value in (1) or 33.9 % is close to the values in (3).…”

Section: Relationship Between Rdi and Degradation Degree Insupporting

confidence: 80%

Investigation of degradation of sinter in blast furnace with a new vertical probe.

et al. 1986

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“…77) Degradation of sinter during reduction was reported at Yawata Works and Sumitomo Metal Industries, 121,122) and it was found that this degradation increases drastically in the temperature range of 500-600°C. [121][122][123] Starting with Fuji Iron & Steel Hirohata Works, all companies initiated sinter reduction degradation testing, 121,124,125) and in 1974, the 44th Ironmaking Committee of the Iron and Steel Institute of Japan established a RDI standard procedure as an index for sinter reduction degradation. Countermeasures for improving RDI have been developed, including increases in sinter basicity (CaO/SiO2), 121) gangue amount, 121,126) and FeO content (manufacture of magnetite sinter) 121,127) and addition of chlorides.…”

Section: Improvement Of Sinter Qualitymentioning

confidence: 99%

Ironmaking Technology for the Last 100 Years: Deployment to Advanced Technologies from Introduction of Technological Know-how, and Evolution to Next-generation Process

Naito

Takeda²,

Matsui³

2015

ISIJ International

106

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The 150 year history of the Japanese steel industry dates from the first western blast furnace, which was built by T. Ohashi in 1857. Modern blast furnace operation at integrated steel works in Japan started in 1901 with the first blow-in of Higashida No. 1 blast furnace at Yawata Steel Works. Throughout the prewar and postwar periods, the steel industry has supported the Japanese economy as a key industry which supplies basic materials for social infrastructure and development.After the period of recovery following the destruction caused by World War II, Chiba Works of Kawasaki Steel Corporation (now JFE Steel Corporation) was built and began operation in 1953 as the first integrated steel works in the Keiyo Industrial Region after the war. During Japan's period of high economic growth, many coastal steel works with large blast furnaces having inner volumes of more than 3 000 m 3 and even 5 000 m 3 were built to enable efficient marine transportation of raw materials and steel products. Japanese steel makers introduced and improved the most advanced technologies of the day, which included high pressure equipment, stave cooler systems, bell-less charging systems, etc. As a result, Japanese steel works now lead the world in low reducing agent rate (RAR) operation, energy saving, and long service life of blast furnaces and coke ovens.Following the Oil Crises of the 1970s, the Japanese steel industry changed energy sources from oil to coal and implemented cost-oriented operation design and technology. In 2012, the Japanese steel industry produced approximately 80 million tons of hot metal from 27 blast furnaces, including large-scale furnaces with inner volumes over 5 000 m 3 . During this period, the industry has faced many economic and social challenges, such as the high exchange rate of the yen, oligopoly in the mining industry, global warming, and the surge in iron ore and coal prices driven by the rapid growth of the BRICs. The industry has successfully responded to these challenges and maintained its international competitiveness by developing advanced technologies for pulverized coal injection, expanded use of low cost iron resources, recycling for environmental preservation, and CO2 mitigation.In this paper, the prospects for ironmaking technologies in the coming decades are described by reviewing published papers and looking back on the history of developments in ironmaking during the last 100 years.

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“…3) Jomoto et al suggested a reduction test with the application of load analogized in the shaft region of the BF. 4) Machida et al developed a simulator with compression and agitation functions for estimating sinter degradation in the BF. 5) However, each of these methods involves a cooling process, and it is not possible to evaluate crack generation during cooling by thermal stress.…”

Section: In-situ Evaluation Methods For Crack Generation and Propagatimentioning

confidence: 99%

<i>In-situ</i> Evaluation Method for Crack Generation and Propagation Behaviors of Iron Ore Burden during Low Temperature Reduction by Applying Acoustic Emission Method

et al. 2018

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Some Properties and Degrading Patterns of Materials in a Blast Furnace Shaft

Cited by 5 publications

References 0 publications

Investigation of degradation of sinter in blast furnace with a new vertical probe.

Investigation of degradation of sinter in blast furnace with a new vertical probe.

Ironmaking Technology for the Last 100 Years: Deployment to Advanced Technologies from Introduction of Technological Know-how, and Evolution to Next-generation Process

<i>In-situ</i> Evaluation Method for Crack Generation and Propagation Behaviors of Iron Ore Burden during Low Temperature Reduction by Applying Acoustic Emission Method

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