2. Mineral Processing Overview Mineral Processing Terms, Economics
Comminution and Classification
Physical processing methods
Chemical processing methods
Waste products treatment and disposal
Process plant flow sheets: uranium and potash
4. Lecture 11 Chemical Processing
Hydrometallurgy
Basic Circuits
Leaching
Solvent Extraction
Precipitation
Drying
Pyrometallurgy
Smelting
Electrometallurgy
Electrowinning
5. Chemical Processing
6. Hydrometallurgy Terminology Hydrometallurgy: aqueous methods of extracting metals from their ores
hydrometallurgical plant: large amounts of water are needed, and a water balance must be maintained
Generally involves two distinct steps:
leaching = Selective dissolution of the metal values from an ore
precipitation = Selective recovery of the metal values from the solution
Sometimes includes purification/concentration
7. Hydrometallurgy
8. Leaching
9. Leaching
10. Leaching - Solubility
11. Leaching
12. Leaching
13. Leaching
14. Leaching
15. Leaching
16. Leaching
17. Agitated Leaching
18. Leaching
19. Leaching
20. Leaching
21. Leaching
22. In-Situ Uranium Leaching
23. In Situ Leaching
24. Heap/Dump Leaching
25. Heap/Dump Leaching
26. Bio-Heap Leaching example – Talvivaara, Finland
27. Hydrometallurgy Terminology purification/concentration operation:
After leaching.
Prior to precipitation.
Goals: 1) purification and 2) increase solution concentration, from which the metal values can subsequently be precipitated effectively.
methods used are:
adsorption on activated charcoal,
sorption on ion exchange resins
extraction by organic solvents.
Common operation scheme: loading, washing, and unloading (elution or stripping) is used in all three operations.
After the elution step, the material is ready for another cycle.
28. Purification and Concentration
29. Purification and Concentration
30. Purification and Concentration
31. Granular Activated Carbon
32. Example - Gold
33. Gold Cyanidation
34. Gold Leaching
35. Gold Cyanidation
36. Ion Exchange (IX) Natural (zeolite) or synthetic (polymer resin) material
Uranium was the first metal to be recovered commercially using IX – paved the way for other metals
Especially useful in the treatment of very dilute solutions with metal ion concentration of the order of 10 ppm or less
An ion exchanger is a framework or a matrix (sponge) which carries a positive or a negative electric charge.
Counter-ions (holes) can be replaced by other ions of the same sign, while the fixed ions (matrix) are not mobile.
37. Ion Exchange� Types of IX systems:
Columns – fixed resin bed. Batchwise, carousel operation
38. Ion Exchange Equipment Types of IX systems:
Resin-in-pulp - unfiltered leach liquor fed through tanks with wire-mesh baskets containing coarse-grade resin
Continuous – pump the resin between loading and elution
39. Ion Exchange Types of IX resins:
Strong acid: cation exchangers, containing -SO3H groups
Weak acid: cation exchangers, containing -COOH groups
Strong base: anion exchangers. Strength of the resin can be increased by using substituted amines
Weak base: anion exchangers, containing amino groups
Anion exchange.. The extracted species is a negatively charged ion and the extractant is a base, e.g., an amine:
40. Solvent Extraction
41. Solvent Extraction Pregnant – loaded with the metal of interest
Barren – metal of interest has been removed
Pregnant aqueous – the feed solution to SX that contains the components to be separated.
Solutes – minor components in the feed (or other) solutions = dissolved metals.
Solvent – the immiscible liquid added to a process for the purpose of extracting a solute or solutes from the feed.
Organic – the “light” phase, used for extraction from feed.
Raffinate – the liquid phase left from the feed after extraction = barren aqueous.
Strip solution – acts as the solvent to remove metal of interest from the organic phase
43. Hydrometallurgy Equipment Solvent extraction mixer-settlers
mixing chamber: aqueous and organic phases are mixed together by a rotating impeller
settling chamber: mixed phases are given enough time to separate
44. Solvent Extraction
45. Solvent Extraction Equipment Krebs mixer-settler:
Interphase regulator
Mixer and conical pump
Top launder for initial phase disengagement
46. Solvent Extraction Equipment
Column cell:
Discs and doughnuts
No exposure to air
Gentle mixing
47. Solvent Extraction Equipment
Outotec Spirok mixers
Low shear
48. Solvent Extraction Organic typically has the following components:
Carrier – main volume of organic, eg. kerosene
Extractant – active in collecting metal. Eg. amine
Diluent – Reduces surface tension, aids phase separation, eg. Isodecanol (alcohol)
49. Example: Uranium
50. Solvent Extraction
51. Uranium Solvent Extraction and Precipitation
52. Uranium Solvent Extraction Key Lake SX circuit
53. Hydrometallurgy Precipitation is the final step in many hydrometallurgical processes.
It is also used as a purification step to separate impurities
Can be physical or chemical
54. Precipitation Equipment Solar Crystallizers:
Used for evaporating sea water or brines from wells for the bulk recovery of sodium chloride or other salts (magnesium chloride, lithium chloride)
Large evaporation ponds are constructed adjacent to the source.
Climate in the region must show high yearly evaporation and low rainfall.
55. Precipitation Equipment Vacuum crystallizer:
no reagents are added, but the concentration and temperature adjusted
concentrate a solution such that crystallize solids by evaporation
Evaporation is conducted under vacuum to decrease the boiling point of the solution and thus economize in heat requirement
common procedure for obtaining pure salts, e.g., sodium chloride, ammonium sulphate
However, cooling will also effectively lead to crystallization of a salt provided its solubility is largely dependent on temperature.�
56. Precipitation Equipment multiple effect evaporators - steam generated in the first evaporator is used to heat the charge in the second evaporator, and that from the second is used to heat the charge in the third.
57. Hydrometallurgy Equipment Chemical precipitation methods:
hydrolysis – just add water! Precipitation of oxides, hydrated oxides, hydroxides, or hydrated salts
Ionic - ions formed are neutralized by a base, example:
Reduction - a reducing agent is added which results in the precipitation of a metal and the agent is oxidized:
An important sub-group is hydrogen reduction
Substitution – precipitate metal ions from organic solvents
58. Precipitation Particle size��Particle size and form of a precipitate depend upon the conditions of formation.��Freshly formed precipitate is sometimes described as amorphous or gelatinous and is difficult to separate by filtration.��Precipitates undergo continuous recrystallization as they age ... accelerated by heating
59. Precipitation Precipitation involves two steps:�
nucleation�
crystal growth�
Rate of nucleation is influenced by:�
concentration�
agitation�
nucleating agents
Change in valency by adding an oxidizing or reducing agent may be used to effect selective precipitations.
60. Extractive Metallurgy Terminology Electrometallurgy – use of electrical energy to induce a chemical transformation
Electrowinning – to precipitate a metal from solution using electric potential
Electrorefining – to purify a metal by dissolving it, then re-precipitating it
61. Electrometallurgy Equipment Electrolytic process:
precipitation of a metal from its aqueous solution is affected by imposing an outside electromotive force from a direct current source. This can be represented by:
62. Electrometallurgy Equipment Alternating anodes and cathodes in a tankhouse for electrowinning
For example, copper, zinc, cadmium, and nickel are recovered industrially from leach solutions by electrolytic methods
Example: Gold and silver are recovered from the eluate by electrolysis using steel wool cathodes
The aqueous solutions are electrolyzed using inert electrodes; the pure metal is deposited on the cathode.
63. Extractive Metallurgy Terminology Pyrometallurgy – use of heat to induce a chemical transformation
Roasting – convert to oxide form. Often first step preceding smelting for Cu, Ni, Pb
Example: 2 CuS2 + 5 O2 ? 2 CuO + 4 SO2
Equipment – fluidized bed roaster
64. Extractive Metallurgy Terminology Smelting - uses reducing substances that will combine with those oxidized elements to free the metal.
Example: 2 Fe2O3 + 3 C ? 4 Fe + 3 CO2
Converter – add back a bit of oxygen to purify, example: blister copper
65. Pyrometallurgy Equipment Smelter:
Add flux (silica or lime) to remove impurities - waste becomes slag
Dust and off gas control are big issues
66. Pyrometallurgy The molten components coalesce, each forming an individual molten layer
Slag: top layer with specific gravity 3.6, and is composed of silicates.
Matte: next layer with specific gravity 5.2, and is composed of sulfides.
Speiss: next layer with specific gravity 6.0, and is composed of arsenides.
Bullion: bottom layer with specific gravity > 6, and is composed of metals.
67. Pyrometallurgy Calcination – Chemical decomposition – but not oxidation or reduction.
Example: CaCO3 = CaO + CO2(g)
68. Pyrometallurgy Multi-hearth calciner/roaster:
73. Assignment / Tutorial #11 Tutorial / Assignment
Complete selected EduMine sections:
Hydrometallurgy 1: Review #3
Extractive Metallurgy 2: Review #2
74. Flowsheet examples Aluminum: from bauxite
Copper: from chalcopyrite
Iron: from hematite
Gold – Placer, sulphide and oxide
Dead Sea – Israel
75. Aluminum
76. Copper
77. Iron
78. Gold
79. Dead Sea brine
