CHE2119 Lecture 4: Extractive Metallurgy PDF

Summary

This document is a lecture on extractive metallurgy, covering topics such as mineral ores, ore dressing, and extraction processes. It's designed for undergraduate chemical engineering students at UST.

Full Transcript

 TABLE OF CONTENTS 2

01 Extractive Metallurgy

02 Mineral Ores

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03 Ore Dressing

04 Extraction Processes
 TABLE OF CONTENTS 3

05 Extractive Metallurgy of Iron

06 Extractive Metallurgy of Aluminum

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07 Extractive Metallurgy of Copper
 TABLE OF CONTENTS 4

01 Extractive Metallurgy

02 Mineral Ores

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03 Ore Dressing

04 Extraction Processes
 INTRODUCTION 5

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Aluminum is made from the aluminum-
bearing minerals in bauxite.

Source: https://courses.lumenlearning.com/geology/chapter/reading-mining-and-mineral-use/
 INTRODUCTION 6

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Acid drainage from a surface coal mine in Missouri.

Source: https://courses.lumenlearning.com/geology/chapter/reading-mining-and-mineral-use/
 EXTRACTIVE METALLURGY 7
deals with the extraction and refining of metals from its naturally
existing ore or minerals

Source of Minerals
Earth’s crust: 8.1% aluminum, 5.1% iron, 3.6% calcium, 2.8%

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sodium, 2.6% potassium, 2.1% magnesium, 2.1% titanium, 0.10%
manganese
ocean water: 10,500 g/ton Na, 1270 g/ton Mg, 400 g/ton Ca, 380
g/ton K; ocean nodules: 23.86% Mn, 1.166% Mg, 2.86% Al,
13.80% Fe
recycled scrap: at the end of metals’ life
EXTRACTIVE METALLURGY 8

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manganese nodules in the seabed
 EXTRACTIVE METALLURGY 9

Extractive Metallurgy

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pyrometallurgy hydrometallurgy electrometallurg
y
 TABLE OF CONTENTS 10

01 Extractive Metallurgy

02 Mineral Ores

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03 Ore Dressing

04 Extraction Processes
 MINERAL ORES 11
An ore is a mineral deposit which can be profitably exploited.
It may contain three groups of minerals namely:
o valuable minerals of the metal which is being sought
o compounds of associated metals which may be of secondary
value

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o gangue minerals of minimum value
Some Types of Ores
❖ oxide ores: Fe2O3, Fe3O4
❖ sulphide ores: CuFeS2, (Zn,Fe)S, PbS, FeS2
❖ carbonate ores: CaMg(CO3)2, MgCO3, Cu2CO3(OH)2
❖ halide ores: rock salts of sodium, magnesium chloride in
seawater
 MINERAL ORES 12

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Chalcocite Garnierite
copper sulfide ore nickel silicate ore
 TABLE OF CONTENTS 13

01 Extractive Metallurgy

02 Mineral Ores

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03 Ore Dressing

04 Extraction Processes
 ORE DRESSING 14
physical pre-treatment before ores are subjected
to the main chemical treatment
meant to affect the concentration of the valuable
minerals and to render the enriched material into
the most suitable physical condition for

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subsequent operations
Ore dressing may include:
❖ Comminution
❖ Sorting
❖ Agglomeration
 ORE DRESSING: COMMINUTION 15
reduction of the size of the ore by crushing, grinding, cutting, and
vibrating to such a size that will release or expose all valuable
minerals
usually followed by screening process

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 ORE DRESSING: COMMINUTION 16
Examples of crushers/grinders:

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jaw crusher roll crusher
 ORE DRESSING: COMMINUTION 17
Examples of crushers/grinders:

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industrial-scale jaw crusher inside of a jaw crusher
 ORE DRESSING: COMMINUTION 18
Examples of crushers/grinders:

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gyratory crusher cone crusher
 ORE DRESSING: COMMINUTION 19
Examples of crushers/grinders:

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hammer mill ball mill
 ORE DRESSING: SORTING 20
performed to separate particles of ore minerals from gangue
(non-valuable) minerals or different ores from one another
Classification Process
Due to difference in size, shape, and densities, materials are
classified in fluids- or water-based processes based on the

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following factors:
1. Smaller particles fall more slowly in fluids than do larger ones.
2. Centrifugal force have larger influence on larger size particles.
3. Small particles having less inertia tend to behave like the
suspending medium or fluid.
4. Larger particles require higher velocity for separation.
 ORE DRESSING: SORTING 21
Froth Flotation
uses difference in surface
properties of the
individual minerals to
selectively adsorb

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material on the air
bubbles
 ORE DRESSING: SORTING 22
Froth Flotation Process

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 ORE DRESSING: SORTING 23
Froth Flotation Process

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 ORE DRESSING: SORTING 24
Froth Flotation Process in the Industry

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copper extraction by froth gold froth flotation tanks
 ORE DRESSING: SORTING 25
Magnetic Separation
takes advantage of differences in magnetic properties of materials
Magnetic Properties
Ferromagnetic: magnetic materials
Paramagnetic: weakly-attracted into a magnetic field

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Diamagnetic: weakly-repelled by a magnetic field
 ORE DRESSING: SORTING 26
Magnetic Separation
takes advantage of differences in magnetic properties of materials

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 ORE DRESSING: SORTING 27
Electrostatic Separation
selective sorting of
solid species by means
of utilizing forces
acting on charged and

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polarized bodies in an
electric field
 ORE DRESSING: AGGLOMERATION 28
formation of lumps of appropriate size
and strength when ore or concentrate is
too small for use in a latter stage of
treatment

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This is done by any of the following
methods: iron briquettes
❖ Pelletizing
❖ Briqueting
❖ Sintering
 TABLE OF CONTENTS 29

01 Extractive Metallurgy

02 Mineral Ores

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03 Ore Dressing

04 Extraction Processes
 EXTRACTION PROCESSES: CALCINATION 30
thermal treatment of an ore to affect its decomposition and the
elimination of a volatile product, usually carbon dioxide or water

CaCO3 🡪 CaO + CO2 T = 1000oC
MgCO3 🡪 MgO + CO2 T = 417oC

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MnCO3 🡪 MnO + CO2 T = 377oC
FeCO3 🡪 FeO + CO2 T = 400oC
 EXTRACTION PROCESSES: ROASTING 31

process of heating of
concentrated ore to a
high temperature in
excess of air

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involves chemical
changes other than
decomposition, usually
with furnace atmosphere

diagram of a reverberatory furnace
 EXTRACTION PROCESSES: ROASTING 32
Roasting vs Calcination
Roasting Calcination
Ore is heated in the presence of excess Ore is heated in the absence or limited
oxygen or air. supply of oxygen or air.
This method is employed for sulphide ores. This method is employed for carbonate

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ores.
Sulfur dioxide is produced along with metal Carbon dioxide is produced along with
oxide. metal oxide.
Sample balanced equation: Sample balanced equations:
For the ores ZnS (sphalerite) and Cu2S For the ore, ZnCO3 (calamine):
(chalcocite): ZnCO3 🡪 ZnO + CO2
2 ZnS + 3 O2 🡪 2 ZnO + 2 SO2
2 Cu2S + 3 O2 🡪 2 Cu2O + 2 SO3
 EXTRACTION PROCESSES: SMELTING 33
Ore (usually mixed with purifying and/or heat generating
substances such limestone and coke) is heated at high
temperature in an enclosed furnace.
It is opposite to roasting (oxidizing reaction) as it involves
reducing reactions.

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The components of the charge in the molten state separate into
two or more layers which may be:
❖ matte
❖ slag
❖ speiss
EXTRACTION PROCESSES: SMELTING 34

fusible chloride

Slag (mixture of metal oxides and SiO2)

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matte (a solution of metallic sulphides)
speiss (a compound of one or more metals
with As or Sb)
Pb button
 TABLE OF CONTENTS 35

05 Extractive Metallurgy of Iron

06 Extractive Metallurgy of Aluminum

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07 Extractive Metallurgy of Copper
 EXTRACTIVE METALLURGY OF IRON 36
Iron Ores
limonite
❖ haematite (Fe2O3)
❖ limonite (FeO(OH).nH2O)
❖ magnetite (FeO.Fe2O3)
❖ Pyrite, (FeS2)

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Iron Forms pyrite
❖ white cast iron
❖ grey pig iron
❖ steel
❖ alloy grey pig iron
EXTRACTIVE METALLURGY OF IRON 37
Raw Materials
Iron Ore
abundant, makes up 5% of earth’s crust
main impurities: silica and alumina
Limestone or Dolomite

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calcium carbonate
used to remove impurities
Coke
produced at the bottom of the blast furnace by
carbonization of coal
used to heat the furnace and produce CO which acts as
the reducing agent
 EXTRACTIVE METALLURGY OF IRON 38
Reactions (Complete)

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 EXTRACTIVE METALLURGY OF IRON 39
Reactions (Complete)

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 EXTRACTIVE METALLURGY OF IRON 40
Reactions (Simplified)

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 TABLE OF CONTENTS 41

05 Extractive Metallurgy of Iron

06 Extractive Metallurgy of Aluminum

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07 Extractive Metallurgy of Copper
 EXTRACTIVE METALLURGY OF ALUMINUM 42
Aluminum is the most abundant metal in
earth.
Bauxite ore
mixture of hydrous aluminum oxides,
aluminum hydroxides, clay minerals, and

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insoluble materials
Aluminum Mineral in Bauxite
Bauxite Ore
 EXTRACTIVE METALLURGY OF ALUMINUM 43
Extraction of aluminum from bauxite is carried out in three stages:

1. Ore Dressing: cleaning ore by means of separation of the metal
containing mineral from the waste (gangue)
2. Chemical Treatment of Bauxite: conversion of hydrated

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aluminum oxide to pure aluminum oxide
3. Reduction of Aluminum from Aluminum Oxide: by the
electrolytic process
 EXTRACTIVE METALLURGY OF ALUMINUM 44
Bayer Process
the process of refining alumina from bauxite by selective
extraction of pure aluminum oxide dissolved in sodium
hydroxide
Bayer process is comprised of four steps:

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❖ Digestion
❖ Clarification
❖ Precipitation
❖ Calcination
 EXTRACTIVE METALLURGY OF ALUMINUM 45
Bayer Process
Digestion: extraction of the alumina through digestion with hot
sodium hydroxide solution which dissolves the aluminum
hydroxide, forming a solution of sodium aluminate

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Clarification: removal of undissolved solid impurities (calcium
oxide, iron oxide, titanium oxide) that form the “red mud”, which
settles down at the bottom of mud thickeners
 EXTRACTIVE METALLURGY OF ALUMINUM 46
Bayer Process
Precipitation: recovery of crystals of aluminum hydroxide
(Al(OH)3)
o Precipitation is promoted by seeding the liquor with pure
alumina crystals acting as nuclei for the precipitation process.

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o Crystals of aluminum hydroxide/ alumina trihydrate (Al2O3.3H2O)
grow and aggregate.
 EXTRACTIVE METALLURGY OF ALUMINUM 47
Bayer Process
Calcination: the aluminum hydroxide after separation from the
sodium hydroxide is converted to pure aluminum oxide by heating
to 1800oF (1000oC) in rotary kilns or fluidized bed calciners.

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 EXTRACTIVE METALLURGY OF ALUMINUM 48
Hall-Heroult Process
production of aluminum by
the electrolytic reduction of
the aluminum oxide
It involves dissolution of

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aluminum oxide in molten
cryolite (mineral containing
sodium aluminum fluoride,
Na3AlF6) and electrolysis of electrolytic process of
manufacturing aluminum
the molten salt bath.
12 e-
 TABLE OF CONTENTS 49

05 Extractive Metallurgy of Iron

06 Extractive Metallurgy of Aluminum

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07 Extractive Metallurgy of Copper
 EXTRACTIVE METALLURGY OF COPPER 50
Copper is mostly extracted from ores containing copper sulphides,
copper oxides or copper carbonates.
Copper ores are generally poor-quality and contain between 1.5 to
5% copper
The extraction of copper from its sulphide ore involves:

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% copper
▪ concentration 15 – 25
▪ roasting 30 – 45
▪ smelting -
▪ matte conversion 98
▪ fire refining 99.5
▪ electrolytic conversion 99.9
 EXTRACTIVE METALLURGY OF COPPER 51
Concentration: separation of the copper mineral from the gangue
o In froth flotation cell, the ore particles are lifted by air bubble
while the gangue remain in the cell.
Roasting: removal of excess sulfur

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o The dry pulp is fed into the
roaster at 600 to 700oC.
o The burning of the sulphide
ores supplies the heat to
maintain the temperature at
which roasting takes place.
 EXTRACTIVE METALLURGY OF COPPER 52
Matte Smelting: concentrate is smelted in a furnace to produce a
mixture of copper

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Blister Copper Production: conversion of matte into molten blister
copper containing 96 to 98% copper and remove the iron-rich slag
Slag Formation Stage

Blister Copper
Formation
 EXTRACTIVE METALLURGY OF COPPER 53
Electrolytic Refining: e- flow
cathodes produced as a
result of the electrolytic
refining process contain
99.9% copper

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 RESOURCES 54

Helen Njeri NJENGA, Industrial Chemistry - African Virtual university
Dr. Ajay Kumar Shukla, Department of Metallurgical and Materials
Engineering, IIT Madrs, India,
(https://mme.iitm.ac.in/shukla/Principles%20of%20Extractive%20Met
allurgy.pdf)
http://www.majordifferences.com/2013/10/roasting-vs-
calcination.html#.WLPTbzt97IU
http://www.businessdictionary.com/definition/smelting.html
http://www.rocksandminerals.com/aluminum/process.html
http://www.idc-
online.com/technical_references/pdfs/chemical_engineering/Bayer_p
rocess.pdf