Extracting iron

The blast furnace

Iron is extracted from iron in a huge container called a blast furnace. Iron ores such as haematite contain iron(III) oxide, Fe₂O₃. The oxygen must be removed from the iron(III) oxide in order to leave the iron behind. Reactions in which oxygen is removed are called reduction reactions.

Raw materials for the reaction

Raw material	Contains	Function
Iron ore (haematite)	Iron(III) oxide (Fe₂O₃)	A compound that the iron is extracted from
Coke	Carbon (C)	Used as a fuel and reacts to form carbon monoxide (needed to reduce the iron(III) oxide)
Limestone	Calcium carbonate (CaCO₃)	Helps to remove acidic impurities from the iron by reacting with them to form molten slag
Air	Oxygen (O₂)	Provides oxygen to allow the coke to burn, and so produces heat

Raw material	Iron ore (haematite)
Contains	Iron(III) oxide (Fe₂O₃)
Function	A compound that the iron is extracted from

Raw material	Coke
Contains	Carbon (C)
Function	Used as a fuel and reacts to form carbon monoxide (needed to reduce the iron(III) oxide)

Raw material	Limestone
Contains	Calcium carbonate (CaCO₃)
Function	Helps to remove acidic impurities from the iron by reacting with them to form molten slag

Raw material	Air
Contains	Oxygen (O₂)
Function	Provides oxygen to allow the coke to burn, and so produces heat

Blast furnace. Iron ore, carbon, limestone enter at top. Air enters at side near bottom. Three zones. Air into zone 1, waste gases out above zone 3. Slag out below zone 1, iron out at very bottom.

Carbon is more than iron, so it can iron from iron(III) oxide. Here are the equations for the reaction.

Step 1 – Hot air (oxygen) reacts with the coke (carbon) to produce carbon dioxide and heat energy to heat up the furnace.

C(s) + O₂(g) → CO₂(g)

Step 2 – More coke is added to the furnace and reduces the carbon dioxide into carbon monoxide, a good reducing agent.

CO₂(g) + C(s) → 2CO(g)

Step 3 – iron(III) oxide is reduced.

iron(III) oxide + carbon → iron + carbon dioxide

2Fe₂O₃(s) + 3C(s) → 4Fe(l) + 3CO₂(g)

In this reaction, the iron(III) oxide is to iron, and the carbon is to carbon dioxide.

In the blast furnace, it is so hot that carbon monoxide can be used, in place of carbon, to reduce the iron(III) oxide:

iron(III) oxide + carbon monoxide → iron + carbon dioxide

Fe₂O₃(s) + 3CO(g) → 2Fe(l) + 3CO₂(g)

Removing impurities

The calcium carbonate in the to form calcium oxide.

calcium carbonate → calcium oxide + carbon dioxide

CaCO₃(s) → CaO(s) + CO₂(g)

The calcium oxide then reacts with silica (sand) impurities in the haematite, to produce slag – which is calcium silicate. This is separated from the iron and used to make road surfaces.

calcium oxide + silica → calcium silicate

CaO(s) + SiO₂(s) → CaSiO₃(l)

This reaction is a reaction. Calcium oxide is (as it is a metal oxide) and silica is (as it is a non-metal oxide).

Choice of blast furnace site

There are a number of important factors to consider when choosing the site of a blast furnace. A blast furnace should be:

near the coast to allow for the import of raw materials
near roads and railway lines to allow for products to be taken to where they are needed
near a town or city, so that workers have somewhere to live close-by
away from built-up areas, so that the noise and pollution of the site do not affect the local population

Port Talbot, in south Wales, is a good example of a suitable site for a blast furnace.

91�ȱ�

Redox, extraction of iron and transition metalsExtracting iron