RU2464097C1 - Method of crushing-grinding of polymineral ores containing precious stones and crushing-grinding machine to this end (versions) - Google Patents

Abstract

FIELD: process engineering.

SUBSTANCE: set of inventions relates to processing of rocks and ores, particularly to crushing equipment. Proposed method comprises crushing ores by mechanical effects produced by working tool. Crushing-grinding is performed selectively by one or several flat sectors of working tool pressed against each other and fitted as-stacked to slide on damper. Said sectors are arranged to slide independently in one plane under dynamic effects brought about thereon by precious stones or unbreakable inclusions in ore material. For method implementation, jaw crushing-grinding tool is used made up of flat sectors as well as roll crushing-grinding tool made up of flat disc sectors. Stack of said sectors is shaped to mate roll or jaw shape.

EFFECT: (ruled out) reduced risk of damaging larger precious stones.

3 cl, 3 dwg

Description

The invention relates to the field of disintegration and processing of rocks and ores and is intended for use in the mining industry, processing solid minerals. The main ore dressing processes include crushing and grinding of ore materials and the separation of concentrate. Crushing refers to mechanical processes by which the extracted ore materials are broken down to sizes suitable for further grinding by grinding. Milling is the final stage in the mechanical separation of useful minerals from waste rock. Usually it is produced in an aqueous medium using crushing and grinding machines (DIM).

The preferred field of use of the invention is the crushing of polymineral ore materials containing precious stones, for example diamond-containing kimberlites.

A known method of crushing and grinding rocks, which includes the destruction of the material by counter-directed pulses of the working bodies and reflective elements synchronized with each other (RU 2111056 C1, 05.20.1998).

A known method of crushing and grinding rocks, including the supply of material to a rotating drum, lifting it along the inner surface of the drum and pneumatic unloading; pieces of material after separation from the inner surface of the drum are subjected to impact by a working body coaxially mounted on the hollow shaft in the drum with the possibility of opposite rotation with a speed equal to 85-92% of the critical; pneumatic unloading of the material is carried out through the holes of the hollow shaft (RU 2185885 C2, 07.27.2002).

The closest solution in technical essence is the method of crushing-grinding of polymineral ore materials containing precious stones, including the supply of ore materials to the crushing and grinding machine, the destruction of ore materials by mechanical impact on them by the working bodies of the machine, the unloading of destroyed ore materials, and the impact of working bodies crushing and grinding machine combines, as a rule, operations such as crushing, breaking, splitting, abrasion, impact (Dro beating, grinding and preparation of raw materials for enrichment. Textbook / EE Andreev, O. Tikhonov. St. Petersburg State Mining Institute (Technical University). St. Petersburg 2007, p. 439).

In crushing and grinding machines (DIM), the destruction of solid material occurs simultaneously in several ways simultaneously (by their combined effect with the predominance of, as a rule, one of the methods). There is no fundamental physical difference between crushing and grinding, they only conditionally differ in the size of the fractions.

The disadvantage of this method is the possibility of destruction (damage) by a mechanical working body DIM of the largest gemstones, the cost of which significantly exceeds the cost of stones of medium size. This leads to a significant reduction in the profitability of production, as well as to the possibility of failure of the working body of the machine as a result of the ingress of large stones and impenetrable inclusions in ore materials.

The objective of the invention is to prevent destruction by the mechanical working body of the crushing and grinding machine of the largest gemstones with sizes higher than the average normative for this deposit, as well as preventing breakdowns and stops of DIM when large stones and crushed bodies get into the mechanical working body.

The essence of the first object of the invention is expressed in the following set of essential features, sufficient to achieve the above technical result.

A method of crushing and grinding polymineral ore materials containing precious stones, including feeding ore materials to a crushing and grinding machine, destroying ore materials by mechanically acting on them by the machine’s working body, and unloading the destroyed ore materials, is characterized by the fact that the crushing and grinding operation is carried out selectively ( selectively) one or more flat sectors of the working body pressed against each other, movably fixed in a package on a damper-shock absorber with the possibility of awn independent sliding one relative to the other sectors of plane in one plane at the time of the dynamic effects of these sector gemstone or tramp impurities in the ore material.

A lot of pieces are involved in the crushing-grinding process in the crushing chamber, but each piece is destroyed individually, which is characterized by the separation characteristics of the crushing-grinding method: the accuracy of separation and the degree of mutual contamination of the products by foreign particle size classes. During crushing-grinding, the effect on the phases of the polymineral ore material occurs along microcracks, bonded faces, which ensures the selectivity of their disclosure.

Known crushing and grinding machines based on the main principle - to crush solid materials only to the required sizes and not to expend energy on excessive grinding, must meet the following basic requirements:

1) Obtaining crushed solid material of a given particle size distribution.

2) The ability to control the degree of grinding.

3) Immediate removal from the working area of grains that have already reached a given size.

4) Minimum dust generation.

Known crushing and grinding machines that implement the following mechanical effects:

1. Crushing occurs after the transition of stresses beyond the compressive strength of the ore material.

2. Cleavage is observed as a result of wedging of the ore material with its breaking into pieces due to the applied tensile stresses.

3. A kink occurs when a piece of ore material is bent.

4. The slice is observed when the parts of the piece of ore material are shifted relative to each other in opposite directions.

5. During abrasion, the outer layers of ore material gradually become thinner due to the application of shear stress exceeding the tensile strength of the material.

6. Destruction by impact is carried out by application of shock loads.

The listed impacts on polymineral ore materials containing precious stones are produced by the well-known crushing and grinding machines of the jaw and roll type

All of them are equipped with working bodies capable of performing the following stages of crushing-grinding of polymineral ore materials with initial sizes of pieces of 500-1500 mm:

1. Large (up to 100-300 mm).

2. Average (up to 20-60 mm).

3. Small (up to 5-10 mm).

4. Thin (to the required size).

The first of these stages are considered as actual crushing, and the last - grinding. Crushing-grinding by these crushers takes place according to weakened sections, cracks and other defects of pieces of ore material with the application of significant loads to these pieces with fixed clearances of working bodies, designed for the selective opening of mineral grains, including precious stones of the most common sizes. This leads to the fact that large gemstones with dimensions of more fixed gaps are crushed by the working bodies of these crushing and grinding machines and are irretrievably lost, and non-crushed inclusions in ore materials lead to breakage and stop of these crushers for repair. All this reduces the profitability of mining operations. These shortcomings are common to all of the above mechanical crushing and grinding machines.

With regard to the processing of polymineral ore material containing precious stones, such as diamond-containing kimberlites, the main criterion is the preservation of large gemstones (crystals) and the possibility of unhindered passage of non-crushed inclusions. From these positions, the following options are described for crushing and grinding machines for implementing the above method of crushing and grinding of polymineral ore material.

There are known analogues of jaw-type crushing and grinding machines in which polymineral ore material is crushed between two cheeks, one of which is stationary, and the second is made swinging (see ibid.). The oscillating movement is created, as a rule, by a rotating eccentric shaft. The movable cheek alternately either moves away from the motionless, then approaches it. Polymineral ore material is fed from above into the working space between the cheeks. The crushed product is unloaded from below when the movable cheek leaves. The size of the maximum pieces in the crushed ore material is due to the width of the exit gap between the movable and fixed cheeks.

The closest in technical essence to the claimed version of the jaw machine is a jaw crusher described in SU 992093 A1, 01/30/1983. The working body of the known chopper is made up of composite sectors, mounted movably in a package on shock absorbers with the possibility of independent movement of some sectors relative to others. The crushing of material in this DIM occurs between two cheeks suspended from the housing on torsion bars. This allows you to reduce the effort on the cheeks in comparison with analogues and thereby reduce the possibility of damage to the machine itself when it gets impenetrable inclusions, while the design provides automatic passage of impenetrable bodies, the dimensions of which exceed the size of the discharge gap, without the use of safety devices.

The disadvantage of the prototype is that when processing polymineral ore materials containing precious stones, the swinging movement of the sectors like a pendulum can increase the likelihood of damage to large gems.

The objective of the invention is to increase the degree of preservation of large grains (crystals) of precious stones (diamonds, emeralds, agates, etc.).

The essence of the second object of the invention is expressed in the following set of essential features, sufficient to achieve the above technical result.

Crushing and grinding machine for crushing and grinding polymineral ore materials containing precious stones, including a casing, a device for loading ore material, a working jaw-type crushing and grinding organ, an unloading device, mainly in the form of a grate, is characterized in that the working body is made integral from flat sectors, mounted movably in a package on a damper-damper with the possibility of independent movement of some sectors relative to others in the same plane, with this package of sectors of the working body is selected in such a way that its outer shape follows the shape of the cheeks.

As the damper-damper, an elastomeric damper-damper or a rubber-metal damper-damper can be used.

Known analogues of the crushing and grinding machine of the roll type, comprising a housing, a loading device for ore material, a working grinding and grinding body of a roll type, an unloading device, mainly in the form of a grate. The main working body of the roll crusher is a pair of rolls with bandages made of wear-resistant material. The rolls are installed with some clearance and rotate towards each other. Pieces of ore material trapped between the rolls are captured by them and crushed. The width of the gap between the rollers is adjusted by stop bolts. If the object gets into the gap, the rolls may collapse under the action of the loads arising from this. To prevent the destruction of the rolls, one of them is mounted in motionless bearings, the other in sliding bearings.

Gemstones contained in polymineral ore materials are not among the crushed and such roll crushers are destroyed if their size exceeds the specified size of the gap. In this case, the most valuable stones are lost, and the medium and small stones pass through the roller crusher intact.

The closest in technical essence to the claimed invention is a roll-type crushing and grinding machine described in SU 355978 A1, 12/18/1972, the working body of which is made up of disk sectors mounted movably on shock absorbers with the possibility of independent movement of some sectors relative to others.

The disadvantage of the prototype is that when processing polymineral ore materials containing precious stones, damage to grains (crystals) of precious stones (diamonds, emeralds, agates, etc.) is possible in the process of crushing-destruction of ore material.

The objective of the invention is the elimination (reduction) of the risk of damage to large precious stones during crushing-grinding of polymineral ore materials.

The essence of the third object of the invention is expressed in the following set of essential features, sufficient to achieve the above technical result.

Crushing and grinding machine for crushing and grinding polymineral ore materials containing precious stones, including a casing, a device for loading ore material, a working crushing and grinding body of the roll type, an unloading device, mainly in the form of a grate, is characterized in that the working body is made integral from flat disk sectors mounted movably in a package on a damper-shock absorber with the possibility of independent movement of some sectors relative to others in one plane bone, the package working body sectors dialed so that its outer shape repeats the shape of rolls.

As the damper-damper, an elastomeric damper-damper or a rubber-metal damper-damper can be used.

The essence of the claimed solutions is illustrated by drawings, where figure 1 shows a technological diagram of the implementation of the claimed method; figure 2-3 - embodiments of crushing and grinding machines for implementing the inventive method.

The claimed method is implemented as follows.

Polymineral ore material 1 using a feeder-conveyor 2 is fed through a feed hopper 3 into a crushing and grinding chamber 4 located in the housing 5 of the crushing and grinding machine, where it is subjected to crushing and grinding by the action of a mechanical working member 6, driven by an electromechanical drive 7 through transmission 8.

Pressing pieces of polymineral ore material 1 by crushing and crushing said pieces by mechanical working member 6, and then crushed ore material 9 is moved under its own weight through an adjustable discharge slit-window 10 and discharge funnel 11 into a receiving hopper storage 12, from where it comes from using the conveyor-feeder 13 is moved through the classification module 14 in the enrichment module 15.

Mechanical working body 6 is implemented in versions of crushing and grinding machines of the jaw and roll type.

The efficiency of the crushing-grinding process is influenced by the size of the pieces of polymineral ore material 1 and their grindability, which varies widely. Polymineral raw materials contain inclusions of minerals, mainly precious stones, significantly different in energy consumption and destruction kinetics. Pieces of polymineral ore material 1 must be destroyed and reduced in size before the mutual liberation of valuable minerals and rocks. A lot of pieces are involved in the crushing-grinding process in the crushing chamber, but each piece is destroyed individually, which is characterized by the separation characteristics of the crushing-grinding method, the separation accuracy and the degree of mutual contamination of products by foreign particle size classes. When crushing-grinding, the effect on the phases of the polymineral ore material 1 occurs along microcracks, soldered faces, which ensures the selectivity of their disclosure. The implementation of the claimed method provides:

1) Increasing the safety of large gemstones (crystals) and increasing the profitability of mining and processing industries.

2) Breakage of the crushing and grinding machine is prevented when “non-crushed” objects get into the mechanical working body and its repair stops.

3) The stability of the crushing and grinding machine is ensured, operating costs are reduced, and the profitability of the processing complex is increased.

Jaw-type crushing and grinding machine for implementing the above method is depicted in figure 2.

The jaw-type crushing and grinding machine consists of a movable jaw 16 mounted on axles 17 in bearings 18 on a bed 19 with the possibility of swinging on these axes under the action of a mechanical drive (not shown in the drawing). The drive transmission of the movable cheek (electric motor and gearbox) is mounted on the bed of the movable cheek 16, the position of which can be adjusted relative to the bed. The fixed cheek is made of flat alternating sectors 20, assembled with the possibility of sliding of one sector relative to another in one package between parallel guides 21, mounted on a cage frame 22. One end of the sectors abuts against the damper-shock absorber 23 of the elastomeric or rubber-metal type. The movable cheek 16 and sectors 20 are installed with an adjustable gap between them, and the profile of the cheek 16 and the configuration of the sectors 20 are made the same in order to prevent “biting” of large gems during the crushing of ore material 1. The damper is equipped with a sensor 24 for moving sectors 20 relative to the bed -Omblages 22, mainly of capacitive type.

Crushing and grinding machine jaw-type works as follows. When the movable cheek 16 is open (shown by a dashed line), pieces of polymineral ore material 1 are fed into the gap. Closing the movable cheek 16 by means of a drive transmission leads to crushing of the ore material 1, the crushed pieces of which fall into the gap between the cheeks. If large grains (crystals) of precious stones get into the working area, the corresponding sector 20 moves towards the damper-shock absorber 23. At the signal of the sensor 24, the drive stops and the stone is removed from the working area. Similarly, when they get into the working area of non-fragmentable inclusions. This ensures the elimination (reduction) of the risk of damage to large gemstones during crushing-grinding of polymineral ore materials and damage to the machine as a result of getting into it crushed inclusions.

Roller crushing and grinding machine for implementing the above method is shown in Fig.3.

The roll-type crushing and grinding machine consists of a housing 25, in the supports of which two axles 26 rotate, made in the form of truncated cones, able to move along their longitudinal axes in order to control the compression ratio of the shock absorbers-dampers 27 mounted on them. 27 are mounted on the dampers-shock absorbers rolls 28, which are flat disk sectors, assembled in bags and capable of sliding relative to each other. In the upper part of the casing, a loading hopper 29 is made, in the lower part there is a slit window 30 for unloading the crushed material. The machine is equipped with a position sensor disk sectors of the rolls 31.

Crushing and grinding machine operates as follows. Ore material 1 is fed into the loading hopper 29. Material 1 is captured by rollers 28 rotating towards one another and crushed by them. The crushed material is discharged through the slit window 30. If large gems or impenetrable inclusions fall between the rollers 28, they are received by the disk sectors, move to the axes 26, deform the shock absorbers 27, which is sensed by the sensors 31. The signals from the sensors 31 stop the machine.

The possibility of industrial application of the claimed technical solutions is confirmed by known and described means and methods by which it is possible to carry out the claimed inventions in the form described in the claims. The claimed method can be implemented industrially using known technical means and technologies.

Claims (3)

1. The method of crushing-grinding polymineral ore materials containing precious stones, including the supply of ore materials to the crushing and grinding machine, the destruction of ore materials by mechanical action on them by the working body of the machine, unloading the destroyed ore materials, characterized in that the crushing-grinding operation is carried out selectively (selectively) one or more flat sectors of the working body pressed against each other, movably fixed in a package on a damper-shock absorber with possibly the independent sliding of some flat sectors relative to others in the same plane at the time of the dynamic impact on these sectors of precious stones or impenetrable inclusions in ore materials. 2. Crushing and grinding machine for polymineral ore materials containing precious stones, including a casing, a device for loading ore material, a working jaw-type crushing and grinding organ, an unloading device, mainly in the form of a grate, characterized in that the working body is made up of flat sectors, mounted movably in a package on a damper-shock absorber with the possibility of independent movement of some sectors relative to others in the same plane, while the package of sectors then typed body so that its external shape repeats the shape of cheeks. 3. Crushing and grinding machine for polymineral ore materials containing precious stones, including a casing, a device for loading ore material, a working crushing and grinding body of a roll type, an unloading device, mainly in the form of a grate, characterized in that the working body made of composite flat disk sectors mounted movably in a package on a damper-damper with the possibility of independent movement of some sectors relative to others in the same plane, with this package of sectors of the working body is selected in such a way that its outer shape follows the shape of the rolls.

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