- Native Ores: These ores contain the metal in free state eg. Silver gold etc. These are usually formed in the company of rock or alluvial impurities like clay, sand etc.
- Oxidised Ores:These ores consist of oxides or oxysalts (eg. carbonates, phosphate) and silicate of metal. Important oxide ore includes, Fe2O3, Al2O3.2H2O etc. and important cabonate ores are limestone (CaCO3), Calamine (ZnCO3) etc.
- Sulphurised Ores: These ores consist of sulfides of metals like iron, lead, mercury etc. Examples are iron pyrites (FeS2). galena (PbS), Cinnabar (HgS)
- Halide ores: Metallic halides are very few in nature. Chlorides are most common examples include horn silver (AgCl) carnallite KCl. MgCl2.6H2O and fluorspar (CaF2) etc.
Metallurgy:
It is the process of extracting a metal from its ores. The following operations are carried out for obtaining the metal in the pure form.
- Crushing of the ore
- Dressing or concentration of the ore.
- Reduction of metal.
- Purification or refining of the metal
Concentration
Physical Method
Gravity separation: The powdered ores is agitated with water or washed with a running stream of water. The heavy ore particles of sand, clay etc. are washed away.
Froth Floatation Process: The finely divided ore is introduced into water containing small quantity of oil (e.g. Pine Oil). The mixture is agitated violently with air a froth is formed which carries away along with it the metallic particles on account of the surface tension forces. The froth is transferred to another bath where gangue-free ore settles down.
Electro Magnetic Separator:. A magnetic separator consists of a belt moving over two rollers, one of which is magnetic. The powdered ore is dropped on the belt at the other end. Magnetic portion of the ore is attracted by the magnetic roller and falls near to the roller while the non-magnetic impurity falls farther off
Chemical Methods
Calcination: Carbonate or hydrated oxide ores are subjected to the action of heat in order of expel water from hydrated oxide and carbon dioxide from a carbonate.
Examples:
ZnCO3 --> ZnO + CO2
CaCO3 --> CaO + CO2
Al2O3×2H2O --> Al2O3 + 2H2O
2Fe2O3×3H2O --> 2Fe2O3 + 3H2O
Roasting: Sulphide ores either are subjected to the action of heat and air at temperatures below their melting points in order to bring about chemical changes in them.
Examples:
2PbS + 3O2 --> 2PbO + 2SO2
PbS + 2O2 --> PbSO4
2ZnS + 3O2 --> 2ZnO + 2SO2
ZnS + 2O2 --> ZnSO4
CuS + 2O2 --> CuSO4
2Cu2S + 3O2 --> 2Cu2O + 2SO2
Leaching: It involves the treatment of the ore with a suitable reagent as to make it soluble while impurities remain insoluble. The ore is recovered from the solution by suitable chemical method.
Al2O3 + 2NaOH -->2 NaAlO2 + H2O
Reduction of Free Metal:
Smelting:
Reduction of a metal from its ore by a process involving melting
Several reducing agents such as sodium, magnesium and aluminium are used for reduction.
The calcinated or roasted ore is mixed with carbon (coal or coke) and heated in a reverberatory or a blast furnace.
Carbon and carbon monoxide produced by incomplete combustion of carbon reduce the oxide to the metal.
Flux:
The ores even after concentration contain some earthy matter called gangue which is heated combine with this earthy matter to form an easily fusible material. Such a substance is known as flux and the fusible material formed during reduction process is called slag.
- Acidic fluxes like silica, borax etc are used when the gangue is basic such as lime or other metallic oxides like MnO, FeO, etc
- Basic fluxes like CaO, lime stone (CaCO3), magnesite (MgCO3), hematite (Fe2O3) etc are used when the gangue is acidic like silica, P4O10 etc.
Refining
The metals obtained by the application of above reduction methods from the concentration ores are usually impure. The impure metal is thus subjected to some purifying process known as refining in order to remove undesired impurities. Various process for this are
a) Liquation process b) Distillation process
c) Cupellation d) Poling
e) Electrolytic refining f) Bessemerisation
Thermodynamic Principles of Metallurgy:
ΔG =ΔH-TS
or ΔG0 =-RT ln K
An element A can reduce element B if ΔG value for oxidation of A to AO is lower than the ΔG value for oxidation of B to BO.
i.e. ΔG(A→AO) < ΔG(B→BO)
Extraction of Aluminium:
Important Ores of Aluminium:
- Bauxite : Al2O3×2H2OCryolite: Na3AlF6
- Feldspar: K2OAl2O3×6SiO2 or KAlSi3O8
- Mica: K2O×3Al2O3×6SiO2×2H2O
- Corundum: Al2O3
- Alumstone or Alunite: K2SO4×Al2(SO4)3×4Al(OH)3
Purification of Bauxite
Electrolysis of fused pure alumina (Hall & Herwlt Method)
The addition of cryolite (Na3AlF6) and fluorspar (CaF2) makes alumina a good conductor of electricity and lowers its Fusion temperature from 2323 to 1140 K. the reaction taking place during electrolysis.
Refining of Aluminium:
The graphite rods dipped in pure aluminium and Cu–Al alloy rod at the bottom in the impure aluminium work as conductors. On electrolysis, aluminium is deposited at cathode from the middle layer and equivalent amount of aluminium is taken up by the middle layer from the bottom layer (impure aluminium). Therefore, aluminium is transferred from bottom to the top layer through middle layer while the impurities are left behind. Aluminium thus obtained is 99.98% pure.
Hydrometallurgy (solvent extraction)
Solvent extraction is the latest separation technique and has become popular because of its elegance, simplicity and speed. The method is based on preferential solubility principles.
Solvent or liquid-liquid extraction is based on the principle that a solute can distribute itself in a certain ratio between two immiscible solvents, one of which is usually water and the other an organic solvent such as benzene, carbon tetrachloride or chloroform. In certain cases, the solute can be more or less completely transferred into the organic phase.
Extraction of Iron:
a) Important Ores of Iron:
Hematite Fe2O3 (red oxide of iron)
Limonite Fe2O3×3H2O (hydrated oxide of iron)
Magnetite Fe3O4 (magnetic oxide of iron)
Extraction of Cast Iron:
Extraction of Copper:
Ores of Copper:
- Copper glance (chalcocite) : Cu2S
- Copper pyrites (Chalopyrites): CuFeS2
- Malachite : Cu(OH)2 ×CuCO3
- Cuprite or Ruby copper: Cu2O
- Azurite : Cu(OH)2×2CuCO3
Refining of Metals:
Zone refining (Fractional crystallization): This method is employed for preparing extremely pure metals. This method is based upon the principle that when a molten solution of the impure metal is allowed to cool, the pure metal crystalises out while the impurities remain in the melt.
Electro-refining: In this method, the impure metal is converted into a block which forms the anode while cathode is a rod or plate of pure metal. These electrodes are suspended in an electrolyte which is the solution of a soluble salt of the metal usually a double salt of the metal. When electric current is passed, metal ions from the electrolyte are deposited at the cathode in the form of pure metal while an equivalent amount of metal dissolves from the anode and goes into the electrolyte solution as metal ion. The soluble impurities present in the crude metal anode go into the solution while the insoluble impurities settle down below the anode as anode mud.
Van-Arkel Method: In this method, the metal is converted into it volatile unstable compound such as iodide leaving behind the impurities. The unstable compound thus formed is decomposed to get the pure metal.
Cupellation and Poling are used for refining of metals, cupellation is contain impurities of other metals with traces of lead are removed from silver by heating impure silver with a blast of air in a cupel (an oval shaped pan made up of bone ash) in which lead is oxidised to lead oxide (PbO) which being volatile escapes leaving behind pure silver.Poling is used for refining of such metals which contain impurities of its own oxide. In this process, the molten impure metal is stored with green wooden poles. At the high temperature of the molten metal, wood liberates methane which reduces the oxide of the metal to free metal.
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