高炉での製鉄

鉄鋼生産と産業文明の基礎

Metallurgy & Metal Processing Global Industrial Scale $800 billion

概要

The blast furnace reduces iron ore (hematite, Fe₂O₃) to pig iron using coke as both fuel and reducing agent. This process has been the foundation of iron and steel production since the Industrial Revolution. Modern blast furnaces are enormous structures up to 100 meters tall, producing 10,000-13,000 tons of hot metal per day. The iron industry consumes approximately 1 billion tons of iron ore and 350 million tons of metallurgical coke annually. Pig iron is subsequently converted to steel in basic oxygen furnaces (BOF) or electric arc furnaces (EAF).

化学プロセス

Iron ore, coke, and limestone are charged from the top of the blast furnace. Hot blast air (1,000-1,200 degrees C) is injected through tuyeres at the bottom, combusting coke to produce CO, which rises through the furnace reducing iron oxides. Molten iron (pig iron, ~4% C) collects at the hearth at 1,500 degrees C, while slag (CaO-SiO₂-Al₂O₃) floats on top. Both are tapped periodically through separate tapholes.

C + O₂ → CO₂ (combustion at tuyeres, 2,100 degrees C)
CO₂ + C → 2CO (Boudouard reaction)
Fe₂O₃ + 3CO → 2Fe + 3CO₂ (indirect reduction, 400-900 degrees C)
CaCO₃ → CaO + CO₂
CaO + SiO₂ → CaSiO₃ (slag formation)

原材料

  • Iron ore (Fe₂O₃, hematite) — Mining (Australia, Brazil, China, India) (Iron source)
  • Metallurgical coke — Coking of bituminous coal (1,000-1,100 degrees C) (Fuel and reducing agent)
  • Limestone (CaCO₃) — Quarrying (Flux (removes silica impurities as slag))

最終製品

  • Pig iron (hot metal) — Steelmaking in BOF or foundry casting (~4% C, 1,500 degrees C liquid, 93-94% Fe)
  • Blast furnace slag — Cement additive (GGBS), road aggregate (CaO-SiO₂-Al₂O₃ glass, valuable byproduct)
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Environmental Impact

The iron and steel industry is responsible for approximately 7% of global CO₂ emissions. Each ton of hot metal requires approximately 500 kg of coke and produces 1.5-2.0 tons of CO₂. Blast furnace gas is captured and used as fuel. Slag is increasingly recycled as a cement substitute, reducing both waste and cement industry emissions.

安全性の考慮事項

最新のイノベーション

Hydrogen direct reduction (H-DRI) using green hydrogen eliminates CO₂ emissions entirely (HYBRIT project, Sweden).
Top gas recycling with CO₂ capture (ULCOS) reduces emissions by 50%.
Electric arc furnace steelmaking from scrap is growing, requiring no blast furnace.
Carbon capture utilization (CCU) converts blast furnace CO₂ to chemicals.

生産規模

1400000000

トン/年

$800 billion

市場価値

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Frequently Asked Questions

What industry uses 高炉での製鉄?
高炉での製鉄 is used in the metallurgy & metal processing sector at global industrial scale scale.
What process is involved in 高炉での製鉄?
Iron ore, coke, and limestone are charged from the top of the blast furnace. Hot blast air (1,000-1,200 degrees C) is injected through tuyeres at the bottom, combusting coke to produce CO, which rises through the furnace reducing iron oxides. Molten iron (pig iron, ~4% C) collects at the hearth at 1
What is the economic significance of 高炉での製鉄?
高炉での製鉄 has a market value of $800 billion and annual production of 1,400,000,000 tons.
What is the environmental impact of 高炉での製鉄?
The iron and steel industry is responsible for approximately 7% of global CO₂ emissions. Each ton of hot metal requires approximately 500 kg of coke and produces 1.5-2.0 tons of CO₂. Blast furnace gas is captured and used as fuel. Slag is increasingly recycled as a cement substitute, reducing both w
What raw materials are used in 高炉での製鉄?
The main raw materials include: Iron ore (Fe₂O₃, hematite), Metallurgical coke, Limestone (CaCO₃).