Basics in Mineral Processing PDF

Summary

This document provides a comprehensive overview of fundamental concepts in mineral processing. It covers a range of topics, including size reduction techniques, size control methods, and various enrichment processes. The text emphasizes the practical aspects of mineral processing.

Full Transcript

Basics in
Basics
Minerals in
Processing
Minerals Processing
Edition 12
 Contents
1. Introduction 12
1.1 Basic definitions 12
1.2 Minerals by value 13
1.3 The process frame of minerals 14
1.4 Mineral processing and hardness 15
1.5 Size and hardness 15
1.6 The stress forces of rock mechanics 16

2. Minerals in operation 18
2.1 Operation stages 18
2.2 Operation – Dry or wet ? 18
2.3 Mining and quarry fronts 19
2.4 Natural fronts 19
2.5 Size reduction 21
2.6 Size control 22
2.7 Enrichment – Washing 22
2.8 Enrichment – Separation 23
2.9 Upgrading 23
2.10 Materials handling 24
2.11 Wear in operation 25
2.12 Operation and environment 26
2.13 Operation values 26

3. Size reduction 28
3.1 The size reduction process 28
3.2 Feed material 29
3.3 Reduction ratio 29
3.4 The art of crushing 30
3.5 Crushing of rock and gravel 30
3.6 Crushing of ore and minerals 31
3.7 Crushing – Calculation of reduction ratio 32
3.8 Selection of crushers 33
3.9 Primary crusher – Type 33
3.10 Primary crusher – Sizing 34
3.11 Secondary crusher – Type 35
3.12 Cone crusher – A powerful concept 35
3.13 Secondary crushers – Sizing 36
3.14 Final crushing stage – More than just crushing 38
3.15 VSI – A rock on rock autogeneous crushing impactor 38
3.16 High Pressure Grinding Rolls (HPGRs) - HRC™ 39

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3.17 Final crusher – Sizing 40
3.18 Wet crushing prior to grinding* 41
3.19 Technical data: Gyratory crusher – SUPERIOR® MK-II Primary 42
3.20 Technical data: Jaw crusher – C series 43
3.21 Technical data: Impact crusher – NP series 44
3.22 Technical data: Cone crusher – GPS series 45
3.23 Technical data: Cone crusher – HPX00 series 46
3.24 Technical data: Cone crusher – HPX series 47
3.25 Technical data: Cone crusher – MP series 48
3.26 Technical data: Cone crusher – GP series 49
3.27 Technical data: Vertical shaft impactor (VSI) 50
3.28 High Pressure Grinding Rolls (HPGRs) - HRC™ 51
3.29 Grinding – Introduction 52
3.30 Grinding methods 52
3.31 Grinding mills – Reduction ratios 52
3.32 Grinding – Tumbling mills 53
3.33 Grinding – Stirred mills 55
3.34 Grinding – Vibrating mills 56
3.35 Cost of grinding – Typical 57
3.36 Mill linings and grinding media 57
3.37 Grinding mills – Sizing 58
3.38 Grinding circuits 58
3.39 VERTIMILL® Circuits 63
3.40 Stirred Media Detritors (SMD) Circuits 65
3.41 Grinding – Power calculation 67
3.42 Grinding – Bonds Work Index* 67
3.43 Pulverizing of coal 68
3.44 VERTIMILL® – More than a grinding mill 69
3.45 VERTIMILL® as lime slaker 70
3.46 Grinding vs enrichment and upgrading 70
3.47 Technical data: AG and SAG mills 71
3.48 Technical data: Ball mills 72
3.49 Technical data: Spherical roller bearing supported ball mill 74
3.50 Technical data: Conical ball mill 75
3.51 Technical data: SRR mill 76
3.52 Technical data: VERTIMILL® (wide body) 77
3.53 Technical data: VERTIMILL® 78
3.54 Technical data: VERTIMILL® (lime slaking) 79
3.55 Technical data: Stirred media grinding mIll 80
3.56 Technical data: Vibrating ball mill 80

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 4. Size control 82
4.1 Size control – Introduction 82
4.2 Size control by duties 82
4.3 Size control by methods 82
4.4 Screens 83
4.5 Screening by stratification 83
4.6 Screen types 84
4.7 Screen capacities 84
4.8 Selection of screening media 85
4.9 Particle size – Mesh or Micron? 86
4.10 Technical data: Single inclination screen – Circular motion 87
4.11 Technical data: Double inclination screen – Linear motion 88
4.12 Technical data: Triple inclination screen – Linear motion 89
4.13 Technical data: Multiple inclination screen – Linear motion (Banana screen) 89
4.14 Classification – Introduction 90
4.15 Wet classification – fundamentals 90
4.16 Hydrocyclone – Introduction 91
4.17 Hydrocyclone cluster 92
4.18 Technical data: Hydrocyclone 93
4.19 Spiral classifier* 94
4.20 Dry classification – Introduction 96
4.21 Static classifiers 96
4.22 Dynamic classifiers 99
4.23 Ancillary air solutions 99
4.24 Dry Grinding 101
4.25 Size control in crushing and grinding circuits 103

5. Enrichment 104
5.1 Enrichment – Introduction 104
5.2 Enrichment – Processes 104
5.3 Separation – Introduction 107
5.4 Separation by gravity 107
5.5 Separation in water 107
5.6 Separation by jigs* 108
5.7 Separation by spiral concentrators* 108
5.8 Separation by shaking tables* 108
5.9 Separation in dense media 109
5.10 Separation by flotation 110
5.11 Flotation circuit layout 111
5.12 Reactor cell flotation system (RCS) 112
5.13 Reactor cell system (RCS) – Sizing, metric 113
5.14 RCS specifications 115
5.15 Flotation machine – RCS 116

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5.16 DR Flotation cell system 117
5.17 Technical data: Flotation machine – DR, Metric 118
5.18 Technical data: Flotation machine – DR, US 119
5.19 Column flotation cells system 120
5.20 Column flotation – Microcel sparger features 121
5.21 Magnetic separation – Introduction 122
5.22 Magnetic separation – Methods 123
5.23 Magnetic separation – Separator types 124
5.24 Magnetic separation equipment 124
5.25 Dry LIMS – Belt drum separator, BS 125
5.26 Technical data: Dry LIMS – Belt separator (BSA and BSS) 126
5.27 Dry LIMS – Drum separator, DS 127
5.28 Technical data: Dry LIMS – Drum separator – (DS) 128
5.29 Wet LIMS – Wet magnetic separators 129
5.30 Wet LIMS – Concurrent CC 129
5.31 Wet LIMS – Counter rotation CR and CRHG 130
5.32 Wet LIMS – Countercurrent CTC and CTCHG 130
5.33 Wet LIMS – Counter rotation froth DWHG 131
5.34 Technical data: Wet LIMS – Dense media recovery DM and DMHG 131
5.35 Technical data: Wet LIMS – Concurrent (CC) 132
5.36 Technical data: Wet LIMS – Counterrotation CR and CRHG 132
5.37 Technical data: Wet LIMS – Countercurrent CTC and CTCHG 133
5.38 Technical data: Wet LIMS – Counter rotation froth DWHG 133
5.39 Technical data: Wet LIMS – Dense media DM and DMHG 134
5.40 Wet HGMS/F – Magnet design 135
5.41 Wet HGMS, HGMF – Separator types 135
5.42 Wet cyclic HGMS 136
5.43 Wet cyclic HGMS – Process system 137
5.44 Wet cyclic HGMS – Operation 137
5.45 Wet cyclic HGMS – Applications 138
5.46 Wet cyclic HGMS – Sizing (indicative) 138
5.47 Technical data: Wet cyclic HGMS 139
5.48 Technical data: Wet cyclic high gradient magnetic filter HGMF 140
5.49 HGMF - Applications 142
5.50 HGMF – Process data 142
5.51 HGMF – Sizing 142
5.52 Technical data: Wet cyclic high gradient magnetic filter – HGMF 143
5.53 Wet continuous HGMS 144
5.54 Wet continuous HGMS – Process system 144
5.55 Wet continuous HGMS – Applications 144
5.56 Wet continuous HGMS – Sizing and selection 145
5.57 Technical data: Wet continuous HGMS 146
5.58 Leaching of metals 147

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 5.59 Gold leaching 148
5.60 Gold leaching – Carbon adsorption 148
5.61 Gold leaching – CIP 149

6. Upgrading 150
6.1 Upgrading – Introduction 150
6.2 Upgrading by methods 150
6.3 Upgrading by operation costs 150
6.4 Sedimentation 151
6.5 Flocculation 151
6.6 Conventional clarifier 152
6.7 Conventional clarifier – sizing 152
6.8 Conventional thickener 153
6.9 Conventional thickeners – Sizing 153
6.10 Conventional clarifier/thickener – Design* 154
6.11 Conventional clarifier/thickener* – Drive system 155
6.12 Conventional clarifier/thickener* drive – Sizing 156
6.13 Inclined plate sedimentation – Introduction 158
6.14 Inclined Plate Settler – IPS 160
6.15 Inclined Plate Settler – Drives 161
6.16 Inclined Plate Settler – Product range 162
6.17 Technical data: Inclined Plate Settler – LTO 165
6.18 Technical data: Inclined Plate Settler – LTS 166
6.19 Technical data: Inclined Plate Settler – LTK 167
6.20 Technical data: Inclined Plate Settler – LTE 168
6.21 Technical data: Inclined Plate Settler – LTE/C 169
6.22 Technical data: Inclined Plate Settler – LTC 170
6.23 Mechanical dewatering – Introduction 171
6.24 Mechanical dewatering – Methods and products 171
6.25 Gravimetric dewatering 172
6.26 Spiral dewaterer 172
6.27 Technical data: Spiral dewaterer 173
6.28 Sand screw* 174
6.29 Dewatering screen* 174
6.30 Dewatering wheel* 174
6.31 Mechanical dewatering by pressure – Introduction 175
6.32 Drum vacuum filters 175
6.33 Belt drum filter* 176
6.34 Top feed drum filter* 176
6.35 Vacuum filters – Vacuum requirement 177
6.36 Vacuum plant – Arrangement 177
6.37 Vertical plate pressure filter – Introduction 178
6.38 Vertical plate pressure filter – Design 179

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6.39 Pressure filter VPA – Operation 179
6.40 Pressure filter VPA – Nomenclature 181
6.41 Pressure filter VPA – Technical data 181
6.42 Pressure filter VPA – Sizing 184
6.43 Pressure filter VPA - Moisture in filter cake 185
6.44 Pressure filter VPA - Typical air flows 185
6.45 Pressure filter VPA – Feed pump selection (guidance only) 185
6.46 Pressure filter VPA - Feed pump power (approximate) 185
6.47 Pressure filter VPA - Product system 186
6.48 Tube press – Introduction 187
6.49 Tube press – Design 188
6.50 Tube press – Operation 189
6.51 Tube press – Examples of applications 191
6.52 Tube press – Material of construction 192
6.53 Tube press – Sizes 192
6.54 Tube press – Sizing 192
6.55 Tube press – Cycle times and cake moisture 193
6.56 Tube press – Capacity 193
6.57 Tube press – Product systems 194
6.58 Tube press booster system 195
6.59 Mechanical description 196
6.60 Technical data: Tube press 197
6.61 Tube press booster 197
6.62 Thermal processing – Introduction 198
6.63 Direct heat rotary dryer (Cascade type) 199
6.64 Indirect heat rotary dryer (Kiln) 199
6.65 Fluidized bed 200
6.66 Indirect heat screw dryer (Holo-Flite®) 202
6.67 Holo-Flite® – Process system 202
6.68 Holo-Flite® System common sizes 204
6.69 Iron ore pelletizing 206
6.70 Typical pellet plant schematic 207
6.71 Grate Kiln technology 209
6.72 Major process equipment components of iron ore pellet plant 212
6.73 Design criteria and plant sizing 213
6.74 Comparisons of indurating technologies 214
6.75 Lime calcining system 215
6.76 Coke calcining system 217
6.77 Tire pyrolysis 218

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 7. Materials handling 220
7.1 Introduction 220
7.2 Loading and unloading 220
7.3 Railcar dumpers 220
7.4 Train positioners 221
7.5 Unloaders 222
7.6 Storage buffering 224
7.7 Stacker reclaimer 225
7.8 Scraper reclaimer 225
7.9 Barrel reclaimer for “Full cross section recovery” 226
7.10 Feeding 227
7.11 Technical data: Feeder – Apron 229
7.12 Technical data: Feeder – Vibration (linear motion) 230
7.13 Technical data: Feeders – Unbalanced motor 231
7.14 Technical data: Feeder – Belt 232
7.15 Technical data: Feeder – Electromagnetic 233
7.16 Technical data: Feeder – Wobbler 234
7.17 Conveying 235
7.18 Conveying systems 236
7.19 Conveyor capacities 237
7.20 Volume weight and angle of inclination 237
7.21 Conveyor – More than a rubber belt 238
7.22 Technical data: Conveyor – Standard belt 239
7.23 Vertical conveyor system 240

8. Slurry Handling 242
8.1 Slurry Handling – Introduction 242
8.2 Basic definitions 243
8.3 Technical description 246
8.4 Metso Outotec slurry pump series and sizes 247
8.5 Metso Outotec horizontal slurry pump wet-end modular configurations 248
8.6 Metso Outotec vertical slurry pump wet-end modular configurations 249
8.7 Slurry pump range MD 250
8.8 Slurry pump range XM 251
8.9 Dredge pumps 252
8.10 Slurry pump range VASA HD and XR 253
8.11 Slurry pump range HR and HM 254
8.12 Slurry pump range MR and MM 255
8.13 Slurry pump range VT 256
8.14 Slurry pump range VF 257
8.15 Slurry pump range VS 258
8.16 Slurry pump range VSHM, VSHR and VSMM 259
8.17 Application guide 260

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8.18 Selection by solids 261
8.19 Duties realted to head and volume 261
8.20 Duties realted to slurry type 261
8.21 Selection of slurry pumps – by industrial application 262
8.22 Industrial segment:Construction 263
8.23 Industrial segment: Coal 263
8.24 Industrial segment:Waste & recycling 263
8.25 Industrial segment: power & FGD 263
8.26 Industrial segments:Pulp & paper 263
8.27 Industrial segment:Metallurgy 264
8.28 Industrial segment:Chemical 264
8.29 Industrial segment: Mining 264
8.30 Slurry transport 265
8.31 Slurry pipeline sizing 266
8.32 Wear 268
8.33 Accessories: 269
8.34 Slurry valves – Introduction 271
8.35 Slurry valves 273

9. Wear in operation 276
9.1 Wear in operation - Introduction 276
9.2 Wear in operation 276
9.3 Wear by compression 277
9.4 Wear by impaction (high) 277
9.5 Wear by impaction (low) 278
9.6 Wear by sliding 279
9.7 Wear protection – Wear lining and sheeting 280
9.8 Wear protection – Wear parts 282
9.9 Wear parts – Slurry pumps 290
9.10 Something about ceramic liners 291
9.11 Wear in slurry pipelines 292

10. Operation and environment 293
10.1 Operation and environment – Introduction 293
10.2 Dust 293
10.3 Dust control – Basic 294
10.4 Dust control – Basic 294
10.5 Noise 296
10.6 Noise reduction 297
10.7 Ear protection 299

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 11. Process system 300
11.1 Process system – Introduction 300
11.2 System modules – Aggregates 301
11.3 System modules – Sand and gravel 301
11.4 System modules – Ore and minerals 302
11.5 Process system – Railway ballast 303
11.6 Process systems – Asphalt / Concrete ballast 303
11.7 Process system – Ferrous ore (hosting apatite) 304
11.8 Process system – Base metal ore 304
11.9 Process system – Gold bearing ore 305
11.10 Process system – Coal 305
11.11 Process system – Industrial mineral fillers 306
11.12 Process system – Glass sand 306
11.13 Process system – Diamonds (Kimberlite) 307
11.14 Process system – Kaolin 307
11.15 Mobile systems 308
11.16 Primary jaw crusher + Grizzly (typical) 309
11.17 Primary impact crusher + Grizzly (typical) 309
11.18 Metso Outotec simulation tools 310
11.19 Consulting business 310
11.20 Process technology and innovation 310

12. Miscellaneous 311
12.1 Conversion factors 311
12.2 Tyler standard scale 312
12.3 Specific gravity 313

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Metso Outotec mining and aggregates
Brand names in minerals processing and aggregates

Allis Chalmers (AC) McNally Wellman
Allis Minerals System Neims
Altairac NICO
Armstrong Holland Nokia
Barmac Nolan
Bergeaud Nordberg
Boliden Allis MPSI
Cable Belt Orion
Conrad Scholtz PECO
Denver Pyrotherm
Dominion Read
FACO REDLER
GFA Sala
Hardinge Scamp
Hewitt Robins Skega
Kennedy Van Saun KVS Stansteel
Kue-ken Seco Stephens – Adamson
Koppers Strachan & Henshaw
Lennings Svedala
Lokomo Thomas
Marcy Tidco
Masterscreens Trellex
McDowell Wellman Tyler

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 Introduction

12
1. Introduction
“The practice of minerals processing is as old as human civilization. Minerals and
products derived from minerals have formed our development cultures from the flints of the Stone Age man to the
uranium ores of Atomic Age”.
The ambition with this handbook, “Basics in Minerals Processing”, is not to give a full coverage of the subject above.
The intention is to give technicians involved in mineral operations practical and useful information about the process equipment
used, their systems and operational environment.
The technical data given are basic, but will increase the understanding of the individual machines,
their functions and performances.
Always contact Metso Outotec for information regarding specific products since the data given is subject to change without
notice.

1.1 Basic definitions
It is important to know the definitions of mineral, rock and ore as they represent
different product values and partly different process systems
Mineral Rock Ore
Na+
Ca + Si4+ O2-
Mineral

Mineral

2
Mineral

Rock
Rock
CO22- Fe2+ OH-

Heat Pressure Heat Pressure Heat Pressure
Deformation Chemical activity
Ca Co3

Fe2 O3

Rock
Rock
SiO2

Ore

Ore

Ore

Artificial minerals
“Man made” minerals are not minerals by definitions. But from processing point of view they are similar to virgin minerals and
are treated accordingly (mainly in recycling processes).

Slag Concrete Mill scale Glass & Ceramics

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14
1.2
Minerals

Industrial minerals Mineral fuels Rock Ores
Minerals by value

Abrasives Ceramics Refractories Non-ferrous Ferrous alloy Ferrous
Corundum Quartz Wollastonite Coals
Oil shale Base metals Alloying metals Iron
Quartz Kaolin Calcite
(Oil sand) Copper Chromium
Diamond a.o. Feldspar a.o. Dolomite Lead Vanadium
Glass Fertilisers Corundum a.o. Zinc a.o. Molybdenum
Quartz Phosphate Tungsten
Feldspar Potash Aggregate, sand & gravel Light metals a.o.
Calcite Calcite Aluminium
Dolomite a.o. Dolomite a.o. Concrete ballast Magnesium
Plastic Fillers and pigment Asphalt ballast Titanium
Calcite Barite Rock fill
Kaolin Bentonite Industrial sand Precious metals
Talc Calcite a.o. Gold
Wollastonite Dolomite Silver
Mica a.o. Feldspar Platinum a.o.
Talc a.o.
Rare metals
Uranium
Radium
Beryllium a.o.
1.3 The process frame of minerals
The goal in mineral processing is to produce maximum value from a given raw material. This goal can be a crushed product
with certain size and shape or maximum recovery of metals out of a complex ore.
The technologies to achieve these goals are classical, complementary and well defined.
Below they are presented in the Process Frame of Minerals, classified according to their interrelations in product size and
process environment (dry or wet).

Size 1m 100 mm 10 mm 1 mm 100 micron 10 micron 1 micron

Drilling (and blasting) is the technology of achieving primary fragmentation of “in situ” minerals. This is the starting point for
most mineral processes with the exception of natural minerals in the form of sand and gravel.
Crushing and screening is the first controlled size reduction stage in the p
­ rocess. This is the main process in aggregate
production and a preparation process for further size reduction.
Grinding is the stage of size reduction (wet or dry) where the liberation size for individual minerals can be reached. By further
size reduction filler (mineral powder) is produced.
Slurry processing includes the technologies for wet processing of mineral fractions.
Pyro processing includes the technologies for upgrading of the mineral fractions by drying, calcining or sintering.
Materials handling includes the technologies for moving the process flow (dry) forward by loading, transportation, storage
and feeding.
Compaction of minerals includes the technologies for moving and densifying minerals by vibration, impaction and pressure,
mainly used in construction a­ pplications.

15
 1.4 Mineral processing and hardness
All deposits of minerals, rock or ores have different hardness depending on the chemical composition and the geological
environment.
Mohs numbers are a simple classification:

1. Talc Crushed by a finger nail Graphite, Sulphur, Mica, Gold
2. Gypsum Scratched by a finger nail Dolomite
3. Calcite Scratched by an iron nail Magnesite
4. Fluorite Easily scratched by a knife Magnetite
5. Apatite Scratched by a knife Granite, Pyrite
6. Feldspar Hardly scratched by a knife Basalt
7. Quartz Scratches glass Beryl
8. Topaz Scratched by quartz
9. Corundum Scratched by a diamond
10. Diamond Cannot be scratched

In 1813 an Austrian geologist, Mr. Mohs, classified minerals according to their individual hardness.

In operation we naturally need more information about our feed material.
See information on work index and abrasion index, section 3 page 2.

1.5 Size and hardness
All operations have different process environments due to mineral hardness and size range. It is important to know in which
“range” we are operating as this will affect many process parameters, (wear rate, uptime, operation costs etc.).
Size and hardness together give interesting information.

Hardness
Mohs
10

METALLIC 9
ROCK CONSTRUCTION MATERIALS MINERALS
8
BALLAST
7

6
AGGREGATES SAND
5

4
MICRO FILLER
SAND 3

2
INDUSTRIAL
1
MINERALS COARSE FILLER FINE FILLER

Size 1m 100 mm 10 mm 1 mm 100 micron 10 micron 1 micron
8

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1.6 The stress forces of rock mechanics
Beside size and hardness, the classical stress forces of rock mechanics are the fundamentals in most of what we do in mineral
processing. They guide us in equipment design, in systems layout, in wear protection etc. They are always around and they
always have to be considered.

Tensile Compression

Impaction Shearing

Attrition

17
 Minerals in operation

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2. Minerals in operation
2.1 Operation stages
The operating stages in minerals processing have remained the same for t­housands of years. Of course we have come far in
development of equipment and processes since then, but the hard, abrasive and inhomogeneous mineral crystals have to be
treated in special ways in order to extract maximum value out of each size fraction.
The operation pattern below has been used since the days of “ mineralis antiqua”

PROTECTION

SIZE
REDUCTION
FRONT ENRICHMENT UPGRADING
AND
SERVICE
CONTROL

MATERIALS HANDLING

Front service: Starting point of mineral processing
Size reduction & control: Processes to produce requested size distributions from feed material
Enrichment: Processes to improve value of minerals by washing and/or separation
Upgrading: Processes to produce requested end products from value and waste minerals.
Materials handling: Operations for moving the processes forward with a minimum of flow disturbances
Protection: Measures to protect the process environment above from wear and emissions of dust and sound

2.2 Operation – Dry or wet ?

Dry processing Wet processing
When no water is needed for processing In all other cases due to:
When no water is allowed for processing Better efficiency
More compact installation
No dusting
Note! Wear rate is generally higher in wet processing!

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 2.3 Mining and quarry fronts
The mining and quarry fronts are the starting points for recovery of rock and mineral values from surface and underground
deposits.
Operations are drilling (blasting), primary crushing (optional) and materials handling, dry and wet.

Mining and quarrying

Underground

Open pit

2.4 Natural fronts
In the glacial, alluvial and marine fronts nature has done most of the primary size reduction work.
Raw material such as gravel, sand and clay are important for processing of construction ballast,
metals and industrial mineral fillers.
Operations are materials handling (wet and dry) and front crushing (optional).

Glacial
Glacial sand and gravel occur in areas which are – or have been – covered by ice. The material is rounded and completely
unsorted with an heterogeneous size distribution which ranges from boulders larger than 1 m (3 ft) down to silt (2-20 microns).
Clay contamination is concentrated in well defined layers.

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Alluvial
The size of alluvial sand and gravel depends on the flow velocity of the water, among other things. Normally the maximum size
is around 100 mm (4”). Alluvial sand and gravel have a homogeneous size distribution and larger particles often have high silica
content. The clay content is often high, normally in the range of
5 to 15 %. Alluvial fronts are in certain areas hosting gold, tin and precious stones.

Marine
Marine sand and gravel often have a more limited size distribution than other types of sand and gravel. The minerals in marine
sand and gravel have survived thousands – or even millions of years – of natural attrition, from erosion in the mountain ranges
and grinding during transport down to the sea. The particles have become well rounded and the clay content is extremely low.
Marine fronts are in certain areas hosting heavy minerals like hematite, magnetite, rutile a.o.

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 2.5 Size reduction
Crushing of rock and minerals
By tonnage this is by far the largest process operation in minerals processing. The goal is to produce rock or (more seldom)
mineral fractions to be used as rock fill or ballast material for concrete and asphalt production. Quality parameters are normally
strength, size and shape. The size fractions, see below, are priced according to defined size intervals and can be reached by
crushing only, see section 3.

HSI
IMPACTORS
PRIMARY
PRIMARY AND
GYRATORY
SECONDARY
CRUSHER
CRUSHER
CONE CRUSHER
SECONDARY

Product value

CONE
CRUSHER
CRUSHERS TERTIARY
VSI

JAW
CRUSHER

>1000 >500 >100>80 64 32 22 16 11 8 4 0 Size mm

Crushing and grinding of ore and minerals
Size reduction of ores is normally done in order to liberate the value minerals from the host rock. This means that we must
reach the liberation size, normally in the interval 100 – 10 micron, see value curve 1 above.
If the raw material is a single mineral (Calcite, Feldspar a.o.) the value normally lays in the production of very fine powder (filler),
see value curve 2 below.
In order to maximise the value in size reduction of rock and minerals, see below, we need both crushing and grinding in
various combinations, see section 3.

The equipment shown below is a general application range. The actual range depends on the material properties and
process requirements.

PRIMARY GYRATORY HRC
CRUSHER
VERTIMILL
CONE
CRUSHER
AG/SAG 1.
MILLS
2.
CRUSHERS/ IMPACTORS STIRRED
ROD MEDIA
DETRITOR
BALL

JAW PEBBLE
VSI
CRUSHER 100 micron

Size
1m 100 mm 10 mm 1 mm 100 micron 10 micron 1 micron
8

22
2.6 Size control
Neither crushers nor grinding mills are very precise when it comes to the correct sizing of the end products. The reason is to
find partly in the variation of the
mineral crystals compounds (hard-soft, abrasive – non abrasive), partly in the design and performance of the equipment.
Size control is the tool for improvement of the size fractions in the process stages and in the final products.
For the coarser part of the process, screens are used (in practise above 1-2 mm).
In the finer part we have to use classification with spiral classifiers, see section 4.

100 micron

Size 1m 10 mm 10 mm 1 mm 100 micron 10 micron 1 micron
8

2.7 Enrichment – Washing
Washing is the simplest method of enrichment used to improve the value of rock and mineral fractions from sand size and
upwards. Removing of surface impurities like clay, dust, organics or salts is often a must for a saleable product.
Different techniques are used depending on how hard these impurities are a­ ttached to the rock or mineral surface, see section 5.

Washing using
Wet screens* Scrubbers* Attrition cells* Gravity beds*

* Contact Metso Outotec for further information.

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 2.8 Enrichment – Separation
Most value minerals (both metallic and industrial) are priced by their purity. After liberation by size reduction and size control all
minerals are free to be separated from each other.
Depending on the properties of the individual minerals they can be recovered by different methods of separation, see section 5.

Gravimetric Flotation Magnetic Leaching

 

Gravity
Air
= value mineral

2.9 Upgrading
After the enrichment operation we end up with a value product (concentrate) and a non-value product (tailings).
These products are probably not sellable nor disposable due to the content of process water, particle size, or chemical composition.
By upgrading we mean the methods of increasing the value of these products by sedimentation, mechanical dewatering,
drying, calcining or sintering and recovering the process water from the tailings, making them disposable, see section 6.

Upgrading by methods

RELATIVE COST

SINTERING

CALCINING

DRYING
DEWATERING BY
TUBE
PRESSES
DEWATERING BY
PRESSURE FILTERS
DEWATERING BY VACUUM FILTERS
DEWATERING BY SCREENS
DEWATERING BY SPIRALS
SEDIMENTATION

Size 100 mm 10 mm 1 mm 100 micron 10 micron 1 micron

24
2.10 Materials handling
Without a proper set up for materials handling no processing system will perform. Different process stages may be in various
locations, may have various feed conditions, are on different shift cycles etc.
Materials handling of dry material is based on the operations of loadíng, unloading, transportation,
storing and feeding, see section 7.
Materials handling of wet material, called slurry handling is also based on the operations of transportation (by slurry pumps
and hoses), feeding (by slurry pumps) and storage (by slurry agitation), see section 8.

Dry handling

Slurry handling











 


25
 2.11 Wear in operation
Whenever energy in any form penetrates rock, ore or mineral, wear will appear.
There is of course a difference whether the minerals are hard or soft, small or large, abrasive or non-abrasive, wet or dry, but
wear will always be around. Both machines and structures must be protected from wear using metals, polymers or compound
material. See section 9, wear in operation.

26
2.12 Operation and environment
If wear is dangerous for equipment and structures, dust and noise is primarily a danger to the operators.
Dust is a problem to both equipment and operators in dry processing
Noise is a problem to operators both in wet and dry processing.
By tradition, the environment in mineral processing has a bad reputation.
This is now changing fast due to harder restrictions by law and harder demands from the operators, see section 10,
Operation and environment.

2.13 Operation values
Prices for products from your operation are seldom set by yourself, but by the market buying them. There is always a possibility
to increase the income from your operation by added values generated by the operation itself.
By improving the output we can increase the product volumes
By improving the quality we can increase the price of our products
By improving the cost control we can reduce our costs of operation
By improving the comfort for our operators we can improve motivation and reduce disturbances in operation
This can be done by small adjustments, by improved service or by reinvestment in more effective equipment, see all sections.
Added value in operation

VOLUME x PRICE – COSTS + MOTIVATION = S
Output Quality Cost control Comfort

AVAILABILITY SIZE /
CAPITAL SECURITY
(up time) SHAPE

PURITY / ENVIRON-
CAPACITY ENERGY
RECOVERY MENT

COMPAC-
FLEXIBILITY TION / MATERIAL RELATIONS
DENSITY

27
 Size reduction

28
3. Size reduction
3.1 The size reduction process
Minerals being crystals have a tendency to break into endless numbers of sizes and shapes every time they are introduced to energy.
The difficulty in size reduction lays in the art of limiting the number of over and under sizes produced during the reduction. If this is
not controlled, the mineral will follow its natural crystal behaviour, normally ending up in over-representation of fines.

I II III IV V Reduction
stage

80%
passing

Size 1m 100 mm 10 mm 1 mm 100 micron 10 micron 1 micron
8

Size reduction behaviour of minerals - by nature

Note!
There is a large benefit to flotation and separation if there is a steep size distribution of the feed to these processes. So, the trick
when producing quality products from rock or minerals (fillers excepted) is to keep the size reduction curves in the later stages as
steep as possible. Normally that is what we get paid for – the shorter or more narrow fraction – the more value!
To achieve that goal we need to select the correct equipment out of the repertoire for size reduction in a proper way.
They are all different when it comes to reduction technique, reduction ratio, feed size etc. and have to be combined in the
optimum way to reach or come close to the requested size interval for the end product.

29
 3.2 Feed material
All operations in size reduction, both crushing and grinding are of course determined by the feed characteristics of the
minerals (rock/ore) moving into the circuit. The key parameters we need are the “crushability or grindability”, also called work
index and the “wear profile”, called abrasion index. Values for some typical feed materials from crushing of rocks, minerals and
ore are tabulated below.
Impact Work Index Wi kWh/sh.ton Abrasion index = Ai
Material Wi value Material Ai value

Basalt 20 ± 4 Basalt 0,200 ± 0,20
Diabase 19 ± 4 Diabase 0,300 ± 0,10
Dolomite 12 ± 3 Dolomite 0,010 ± 0,05

Iron-ore, Hematite 13 ± 8 Iron-ore, Hematite 0,500 ± 0,30
Iron-ore, Magnetite 12 ± 8 Iron-ore, Magnetite 0,200 ± 0,10
Gabbro 20 ± 3 Gabbro 0,400 ± 0,10

Gneiss 16 ± 4 Gneiss 0,500 ± 0,10
Granite 16 ± 6 Granite 0,550 ± 0,10
Greywacke 18 ± 3 Greywacke 0,300 ± 0,10

Limestone 12 ± 3 Limestone 0,001 – 0,03
Quartzite 16 ± 3 Quartzite 0,750 ± 0,10
Porphyry 18 ± 3 Porphyry 0,100 – 0,90

Sandstone 10 ± 3 Sandstone 0,600 ± 0,20
Syenite 19 ± 4 Syenite 0,400 ± 0,10

INFLUENCING INFLUENCING
Size reduction Wear rate
Energy requirement Regarding Work Index (Bond) for grinding, see 3:40.
Machine status

3.3 Reduction ratio
As seen above all size reduction operations are performed in stages. All equipment involved, crushers or grinding mills have
different relation between feed and discharge sizes. This is called reduction ratio. Typical values below. Note! High reduction
ratio is generally inefficient. For maximum energy efficiency, we recommend multiple stages of grinding
Compression crushers Impactors (horizontal type) Impactors (vertical type)

Jaw 3-4
Gyratory 3-5 5-10 1-2
Cone 3-5
High pressure grinding rolls Grinding mills (tumbling type) Stirred grinding mills

Rod 100
Ball 1000
AG & SAG 5000

25 100

30
3.4 The art of crushing
Crushing means different things for different operations and the production goals are not always equal.

Crushing rock Crushing gravel Crushing ore

Limited reduction Limited reduction Maximum reduction

Cubical shape Cubical shape Shape of no importance

Over and undersize Over and undersize Over and under size
important important of minor importance

Flexibility of minor
Flexibility Flexibility
importance

Crushing and Less crushing - More crushing-
screening more screening less screening

Low production costs
High utilisation

3.5 Crushing of rock and gravel
In the business you are normally paid for short fractions of relatively coarse material with the correct size and shape. Most of
the ballast for concrete and asphalt is in the 4 - 18 mm (1/5 - 3/4’’) interval.
In order to produce the correct shape and keep over- and under sizes as low as possible this crushing must be done
in several stages (3 - 5).

31
 3.6 Crushing of ore and minerals
In these operations the value is achieved at the fine end, say below 100 micron
(150 mesh).
Normally the size reduction by crushing is of limited importance besides the top size of the product going to grinding.
This means that the number of crushing stages can be reduced depending on the feed size accepted by primary grinding stage.

”Classical” 3-stage crushing prior to rod mill

Primary
crushing
Tertiary
crushing

Secondary
crushing

Typical 1-2 stage ore crushing in AG-SAG circuit

Primary
crushing

Secondary
crushing

Primary grinding

Typical 3- stage crushing prior to ball mill 3-stage crushing utilizing an HPGR prior to a rod
mill or ball mill
Another option is including HPGRs in the crushing circuit.
Commons circuits include utilizing HPGRs as a:
Primary – tertiary crusher, followed by a ball mill or VERTIMILL®
crushing – quarternary crusher, followed by a ball mill or VERTIMILL®
– pebble crusher in a SABC circuit

Secondary Primary
Tertiary
crushing crushing HPGR crusher
crushing

Secondary
crushing

32
3.7 Crushing – Calculation of reduction ratio
All crushers have a limited reduction ratio meaning that size reduction will take place in stages. The number of stages is guided
by the size of the feed and the requested product, example see below.
The same size reduction with soft feed (low Bond work index) is done with two stages of

Feed material size: F80 = 400 mm

Blasted rock, 80% smaller than 400 mm




Product size: P80 = 16 mm



Road aggregates or rod mill feed 80% smaller than 16 mm

 




Total reduction ratio (R) F80/P80 400/16 = 25 



Reduction ratio in the primary crushing stage R1 = 3 

Reduction ratio in the secondary crushing stage R2 = 4 

Total in 2 crushing stages gives R1xR2 = 3x4 = 12 
This is not sufficient. We need a third crushing stage.*
*As we have to use three stages, we can reduce the reduction
ratio a bit in every stage, giving more flexibility to the circuit!
For example: Reduction first stage R1 = 3
Reduction second stage R2 = 3
Reduction third stage R3 = 3

Together these three stages give R1xR2xR3 = 3x3x3 = 27 = sufficient reduction

Stage I
JAW CRUSHER

I
Stage II
CONE CRUSHER

II
Reduction ratio 1:3
Stage III
CONE CRUSHER

III
Reduction ratio 1:3

Reduction ratio 1:3
100 micron

>1000 >500 >100 >80 64 32 22 16 11 8 4 0
Size mm

The same size reduction with soft feed (low Bond work index) is done with two stages of HSI (horizontal shaft impactors).
With the increased reduction ratio capable in an impactor this process can be achieved in two stages, such as 6:1 and 5:1.

33
 3.8 Selection of crushers
Knowing the number of crushing stages we can now start to select the correct crusher for each reduction stage. Depending on
operating conditions, feed size, capacity, hardness etc, there are always some options. For primary crushers,
see below.
Stationary crushers – surface and underground

Primary Gyratory Jaw Impact

Mobile Crushers

Jaw + grizzly Impact + grizzly

For mobile crushers see further section 11:9

3.9 Primary crusher – Type
For soft feed and non-abarasive feed (low Bond work index) a horizontal Impactor (HSI) is an option if the capacity is not too
high.
For harder feed there is a choice between a gyratory or a jaw crusher, see below.

Note: HSI can be used only if the abrasion index is lower and
the plant does not mind fines production. Otherwise, a jaw
crusher is preferred for lower capacity aggregate plants.)

Rule 1: Always use a jaw crusher if you can, jaws are the
least capital cost.
Rule 2: For low capacity use jaw crusher and hydraulic
Feed opening Feed opening hammer for oversize.
Jaw crusher Gyratory crusher Rule 3: For high capacities (800-1500 tph)use jaw crusher
with big intake opening.
Rule 4: For very high capacities (1200+ tph use gyratory
crusher.

Discharge opening Discharge opening
Jaw crusher Gyratory crusher

34
3.10 Primary crusher – Sizing
Crushers are normally sized from top size of feed. At a certain feed size, knowing the capacity, we can select the correct
machine, see below.
A correct sizing of any crusher is not easy and the charts below can only be used for guidance.
Ex. Feed is a blasted hard rock ore with top size 750 mm. Capacity is 4750 t/h.
Which primary crusher can do the job?
Check on the two compression machines below and take out the sizing point!
Correct selection is Superior® MK-II Primary Gyratory Crusher type MK-II 60-89
Primary gyratory – Feed size vs capacity
Feed top size mm (inch: divide by 25)

1500
MK-II 62 - 75
MK-II 60 - 89 Data sheet,
MK-II 60 - 110 E
MK-II 50 - 65 see 3:15
1000 MK-II
MK-II 42 - 65 54 - 75

500

Capacity
t/h
2000 3000 4000 5000 6000 7000 8000 9000

Primary jaw crusher – Feed size vs capacity

100%

90%

80%

70%

60%

50%

40%

30%

20%

10%

0%
0,1 1 10 100 1000

Primary impactor – Feed size vs capacity
Feed top size mm (inch: divide by 25)

1500
NP2023
1300
NP1620

1000
900 NP1415 Data sheet,
NP1313 see 3:17
700
600

400
350

0
Capacity t/h
0
500 1000 1500 2000

35
 3.11 Secondary crusher – Type
In a rock crushing circuit, the second stage normally starts to be of importance for control of size and shape.
Because of this the jaw crusher, in most cases, is disqualified as secondary crusher. Instead the cone crusher is used more frequently.
Also in comminution (crushing and grinding) circuits for ore and minerals the cone crusher is frequently used as the secondary
stage, see 3:4.
Using a secondary HSI means as always a restriction in feed hardness and abrasiveness.

Yesterday Today Demands

Limitations in
Wi and Ai
Big feed opening
High capacity
Controlled feed
Shape
HSI

Jaw Crusher Cone Crusher

3.12 Cone crusher – A powerful concept
Compared to other crushers the cone crusher has some advantages making them very suitable for size reduction and shaping
downstream a crushing circuit. Reason is the crushing chamber and the possibilities to change feed and discharge openings
during operation.

Chamber geometry Closed side setting Chamber settings
(CSS)
Upper concave
+
Eccentric setting (Ecc.)
=
Open side setting (OSS) CSS OSS
Nip an Ecc.
gle Concave
Lower
concave

CSS,
Closed
Mantle
Mantle Side
CSS, Setting
Closed
Side
Setting

Chamber intake to match feed size Decreased CSS will improve reduction but will also reduce
Each machine size has different chamber options (other capacity and increase risk for packing
crusher types have not)
Approx. size of discharge:
Each chamber has a certain feed size vs capacity relation
Increased Ecc. (at the same CSS) will give higher capacity. From Cone 70-80%120 48 – 120 7 – 48 4–7 50 20 – 50 3 – 20 1.5 – 3 60
weight
Specific gravity
dry solids 75% Rakes are lifted until 100% load is reached. Rakes stay in upper position until 70% is reached,
then lowering towards bottom position.
> 100% Cut-out torque stops rotation of rakes. Lifting to the top position and alarm.
Starts up normally from drive head control panel.

Control panel
PLC controlled
Fully automatic incl. functions for:
– Speed control of flocculator
– Torque signal
– Start and stop sequences
– Alarm indications for levels, flows etc.
– Control of underflow valve and pump

164
6.16 Inclined Plate Settler – Product range
Type LTO
Sizes up to 400 m2 (4 305 ft2) ­effective clarification area (500 m² total projected area)
Effective also with coarser material
Limited solids content in feed
Extension of lower part as option
Lifting device as option

See also data sheet 6:16.

Type LTS
Sizes up to 400 m2 (4 305 ft2) e ­ ffective clarification area (500 m² total projected area)
Not suitable for coarse material (> 0.5-1 mm, 32 – 16 Mesh)
Higher solids load
Extension of lower part as option
Lifting device as option

See also data sheet 6:17.

Type LTK
Sizes up to 400 m2 (4 305 ft2) e­ ffective clarification area (500 m² total projected area)
For higher solids load
Used when storage and thickening is critical
Extension of lower part as option
Lifting device as standard

See also data sheet 6:18.

165
 Type LTO, LTS, LTK with extended tank
By lower tank extensions the volume can be increased giving better storage and
improved thickening.

Type combi LTC
Sizes up to tank dia 24 m (78.7 ft) = 400 m2 (53 800 ft2)
For light and heavy duties
High storage capacity
Improved thickening
Plate or concrete tank
Conventional thickener drives

See also data sheet 6:21.

“Combi IPS” built up by using inclined plate packs in circular tanks have principally no limitation in sizes.
From design point, however, max. practical area for each plate pack unit is approx. 5 400 m2.
These sizes can then be combined in modules 5 400 m2 + 5 400 m2 +... (58 125 ft 2+ 58 1250 ft 2 +...)

166
Type LTE
Sizes up to 1 140 m2 (12 270 ft2) projected area.
Increased solids storage capacity, e.g. for installation prior to a batch process such as a filter press.

See also data sheet 6:19.

Type LTE/C
Similar to LTE above.
Conical bottom for denser underflow.
Improved access to underflow valves, pump and piping.

See also data sheet 6:20.







167
 Technical data sheet

6.17 Inclined Plate Settler – LTO

H Total Sludge Flocculator Weight
L W A
Model (max) volume volume volume empty
mm (ft) mm (ft) mm (ft)
mm (ft) mm³ (ft³) m³ (ft³) m³ (ft³) kg (lbs)
3 485 2 640 1 345 1 800 4.6 1.1 0.8 1 800
LTO 15
(11.4) (8.7) (4.4) (5.9) (162) (39) (28) (3 968)
4 300 3 430 1 830 1 800 9.2 2.3 0.8 3 500
LTO 30
(14.1) (11.3) (6.0) (5.9) (325) (81) (28) (7 716)
4 650 3 865 2 230 1 800 16.2 4.2 2.0 4 800
LTO 50
(15.3) (12.7) (7.3) (5.9) (572) (148) (71) (10 582)
5 400 4 510 2 870 1 800 28.7 9.4 3.0 7 800
LTO 100
(17.7) (14.8) (9.4) (5.9) (1 014) (332) (106) (17 196)
5 950 5 540 3 100 1 800 41.5 14.5 4.0 10 500
LTO 150
(19.5) (18.2) (10.2) (5.9) (1 466) (512) (141) (23 149)
6 500 5 740 3 690 1 800 54.6 18.8 5.0 13 200
LTO 200
(21.3) (18.8) (12.1) (5.9) (1 928) (664) (177) (29 101)
8 100 6 910 4 500 2 000 105.8 47.8 7.0 24 300
LTO 350
(26.6) (22.7) (14.8) (6.6) (3 736) (1 688) (247) (53 572)
8 630 7 810 5 780 2 000 160.8 72.8 8.0 39 500
LTO 500
(28.3) (25.6) (19.0) (6.6) (5 679) (2 571) (283) (87 082)

168
Technical data sheet

6.18 Inclined Plate Settler – LTS

H Total Sludge Flocculator Weight
L W A
Model (max) volume volume volume empty
mm (ft) mm (ft) mm (ft)
mm (ft) mm³ (ft³) m³ (ft³) m³ (ft³) kg (lbs)
3 750 2 640 1 345 1 800 5.2 1.7 0.8 2 000
LTS 15
(12.3) (8.7) (4.4) (5.91) (184) (60) (28) (4 409)
4 620 3 430 1 830 1 800 11.1 4.2 0.8 3 700
LTS 30
(15.2) (11.3) (6.0) (5.91) (392) (148) (28) (8 157)
4 700 3 865 2 230 1 800 18.6 6.6 2.0 5 100
LTS 50
(15.4) (12.7) (7.3) (5.91) (657) (233) (71) (11 244)
5 130 4 510 2 870 1 800 32.5 13.2 3.0 8 600
LTS 100
(16.8) (14.8) (9.4) (5.91) (1 148) (466) (106) (18 960)
5 300 5 540 3 100 1 800 45.8 18.8 4.0 11 300
LTS 150
(17.4) (18.2) (10.2) (5.91) (1 617) (664) (141) (24 912)
6 100 5 740 3 690 1 800 61.8 26.0 5.0 15 800
LTS 200
(20.01) (18.8) (12.1) (5.91) (2 182) (918) (177) (34 833)
6 200 6 910 4 500 2 000 114.0 56.0 7.0 23 000
LTS 350
(20.3) (22.7) (14.8) (6.56) (4 026) (1 978) (247) (50 706)
6 400 7 810 5 780 2 000 153.0 65.0 8.0 36 000
LTS 500
(21.0) (25.6) (19.0) (6.56) (5 403) (2 295) (283) (79 366)

169
 Technical data sheet

6.19 Inclined Plate Settler – LTK

Total Sludge Flocculator Weight
H L W A
Model volume volume volume empty
mm (ft) mm (ft) mm (ft) mm (ft)
mm³ (ft³) m³ (ft³) m³ (ft³) kg (lbs)
5 100 2 795 1 610 1 800 8.0 4.5 0.8 2 200
LTK 15
(16.7) (9.2) (5.3) (5.9) (283) (159) (28) (4 850)
4 550 3 690 2 310 1 800 14.5 7.6 0.8 4 500
LTK 30
(14.9) (12.11) (7.6) (5.9) (512) (268) (28) (9 921)
4 800 4 170 2 810 1 800 23.5 11.5 2.0 6 200
LTK 50
(15.7) (13.7) (9.2) (5.9) (830) (406) (71) (13 669)
5 390 5 020 3 715 1 800 45.5 26.2 3.0 10 100
LTK 100
(17.7) (16.5) (12.2) (5.9) (1 607) (925) (106) (22 267)
5 800 5 885 4 490 1 800 61.0 34.0 4.0 13 000
LTK 150
(19.0) (19.3) (14.7) (5.9) (2 154) (1 201) (141) (28 660)
6 500 6 235 4 715 1 800 87.0 51.2 5.0 16 500
LTK 200
(21.3) (20.6) (15.5) (5.9) (3 072) (1 808) (177) (36 376)
6 930 7 485 6 220 2 000 143.0 85.0 7.0 26 500
LTK 350
(22.7) (24.6) (20.4) (6.6) (5 050) (3 002) (247) (58 422)
6 940 8 705 7 520 2 000 200.0 112.0 8.0 46 500
LTK 500
(22,8) (28,6) (24,7) (6,6) (7 063) (3 955) (283) (102 515)

170
Technical data sheet

6.20 Inclined Plate Settler – LTE

D

1,5 - 2,5 m
4.5 - 7.5 ft

H

Settling area Tank dia (D) Tank height (H) Sludge volume Total volume
Model
m2 (ft2) mm (ft) mm (ft) m3 (ft3) m3 (ft3)
LTE 220-6.3 220 (2 386) 6 300 (20.7) 6 000 (19.7) 86 (3 040) 192 (6 780)
9 000 (29.5) 179 (6 320) 285 (10 065)
LTE 275-7.1 275 (2 960) 7 100 (23.3) 6 000 (19.7) 110 (3 885) 244 (8 629)
9 000 (29.5) 228 (8 050) 363 (12 820)
LTE 440-8.3 440 (4736) 8 300 (27.0) 6 000 (19.7) 151 (5 335) 335 (11 830)
9 000 (29.5) 314 (11 090) 497 (17 550)
12 000 (39.4) 476 (16 810) 660 (23 310)
LTE 550-9.0 550 (5 920) 9 000 (29.5) 6 000 (19.7) 179 (6 320) 395 (13 950)
9 000 (29.5) 370 (13 065) 586 (20 695)
12 000 (39.4) 561 (19 810) 777 (27 440)
LTE800-10.5 800 (8 611) 10 500 (34.4) 6 000 (19.7) 246 (8 690) 541 (19 105)
9 000 (29.5) 506 (17 870) 801 (28 290)
12 000 (39.4) 766 (27 050) 1 060 (37 435)
LTE 1140 1 140 (12 270) 12 000 (39.4) 6 000 (19.7) 326 (11 510) 710 (25 0705)
9 000 (29.5) 665 (23 480) 1 050 (37 080)
12 000 (39.4) 1004 (35 4555) 1 389 (49 050)

171
 Technical data sheet

6.21 Inclined Plate Settler – LTE/C

1,5 - 2,5 m
4.9 -8.2
ft



(3.3 ft)


Settling area Tank dia (D) Tank height (H) Sludge volume Total volume
Model
m2 (ft2) mm (ft) mm (ft) m3 (ft3) m3 (ft3)
LTE/C 220-6.3 220 (2 368) 6 300 (20.7) 8 500 (27.9) 66 (2 3301) 172 (6 075)
LTE/C 275-7.1 275 (2 960) 7 100 (23.3) 10 000 (33.0) 91 (3 215) 225 (7 945)
LTE/C 440-8.3 440 (4 736) 8 300 (27.2) 11 000 (36.0) 140 (4 945) 324 (11 440)
LTE/C 550-9.0 550 (5 920) 9 000 (29.5) 11 500 (37.7) 175 (6 180) 391 (13 810)
LTE/C 800-10.5 800 (8 611) 10 500 (34.4) 12 500 (41.0) 269 (9 500) 563 (19 880)
LTE/C 1040-12 1 140 (11 194) 12 000 (39.4) 13 500 (44.3) 392 (13 845) 776 (27 405)

172
Technical data sheet

6.22 Inclined Plate Settler – LTC

D
1,5 - 2,5 m
4.9 - 9.2 ft

H

*Model Settling Tank Tank height **Sludge Total
area dia