CN110124821B

CN110124821B - Automatic mesh-dividing grinding and collecting device for raw ore and using method

Info

Publication number: CN110124821B
Application number: CN201910415646.9A
Authority: CN
Inventors: 陈益敏
Original assignee: CHIZHOU LINGZHI HUAJIAN MATERIAL TECHNOLOGY CO LTD
Current assignee: CHIZHOU LINGZHI HUAJIAN MATERIAL TECHNOLOGY Co.,Ltd.
Priority date: 2019-05-18
Filing date: 2019-05-18
Publication date: 2020-11-06
Anticipated expiration: 2039-05-18
Also published as: CN110124821A

Abstract

The invention discloses an automatic mesh-dividing grinding and collecting device for raw ores, which comprises a box body, wherein a dust collector fixedly connected with the ground is arranged on the front, the rear and the left sides of the box body, and a first motor fixedly connected with the ground is arranged at the front, the rear and the right ends of the box body, and the automatic mesh-dividing grinding and collecting device has the beneficial effects that: the grinding device has a simple structure, is simple and convenient to operate, directly skips the crushing step for grinding, saves the cost, can grind the raw ore in a multi-mesh mode at one time, can automatically collect the raw ore powder in the grinding process, solves the problem that the raw ore can only be ground by a single specified mesh in the conventional equipment, avoids the conditions of multiple feeding and discharging and grinding tools with different meshes, and is simple, efficient, convenient and quick in the whole process.

Description

Automatic mesh-dividing grinding and collecting device for raw ore and using method

Technical Field

The invention relates to the technical field of mineral separation and grinding, in particular to an automatic raw ore mesh-separating, grinding and collecting device and a using method thereof.

Background

The mineral separation is a process of separating useful minerals from gangue minerals, separating various symbiotic (associated) useful minerals from each other as much as possible, removing or reducing harmful impurities to obtain raw materials required by smelting or other industries by adopting methods such as a gravity separation method, a flotation method, a magnetic separation method, an electric separation method and the like after crushing and grinding the ores according to physical and chemical properties of different minerals in the ores, wherein the mineral separation treatment process of the ores is completed in a mineral separation plant and generally comprises the following three basic process processes of preparation operation, separation operation and treatment operation, wherein the preparation operation is further divided into crushing, grinding, screening and grading and washing, the crushing is a process of crushing ore blocks with the particle size of 500-1500 mm, which are mined from mines, to the particle size of 5-25 mm, the crushing, chopping and the like are generally carried out according to three sections of coarse crushing, medium crushing and fine crushing, grinding mainly comprises grinding and impacting, a crushed product is ground to the particle size of 10-300 mu m, the ground particle size is determined according to the dip-dyeing particle size of useful minerals in ores and the adopted sorting method, the grinding operation energy consumption is high and generally accounts for about half of the total energy consumption of mineral separation, the existing mined ores can be ground only after being crushed because the existing grinding machine such as a ball mill can only grind small-particle ores, but the equipment purchase, processing, energy consumption and other costs are increased, the crushed raw ores are moved to grinding equipment to be manually operated, the raw ores are ground into different meshes for different purposes of the raw ores in the grinding link for mineral separation, the existing equipment can only grind the raw ores into single meshes, the quantity of the raw ores is small, but the situation of large demand is not friendly, and the repeated feeding and discharging are very inconvenient, at present, no fully automatic production line device which can directly grind raw ores by skipping a crushing step and can grind various meshes in a single time exists on the market.

Disclosure of Invention

The invention aims to solve the problems in the prior art, and provides an automatic raw ore mesh-dividing grinding and collecting device which can grind mined raw ores directly without a grinding step in preparation operation, can complete continuous full-automatic feeding, grinding and discharging, can grind the raw ores in a multi-mesh manner at one time, solves the problem that the quantity of the raw ores is small but the demands are more, reduces unnecessary equipment purchasing expenditure, reduces labor consumption, greatly improves ore dressing efficiency, is full-automatic, simple, efficient, convenient and quick.

The invention adopts the technical scheme for solving the technical problems that: the automatic mesh-dividing grinding and collecting device for the raw ores comprises a box body, wherein a dust collector fixedly connected with the ground is arranged on the front and rear left sides of the box body, a first motor fixedly connected with the ground is arranged at the front and rear ends of the right side of the box body, a second motor is fixedly arranged on the front half part and the rear half part of the top of the left dust collector, an inlet and an outlet communicated with the outside are formed in the inner wall of the right end of the box body, a dust collection box is fixedly arranged in the middle of the inner wall of the front and rear left ends of the box body, a grinding layer is fixedly arranged at one end, close to the center of the box body, of the dust collection box, first through holes which are distributed in an array manner and are communicated with each other are formed in the front half part and the rear half part of the box body, a guide pipe is arranged at one end, close to the box body, of the dust collection box and, the left ends of the first screw rod and the second screw rod are movably connected with the inner wall of the left end of the box body, the right ends of the first screw rod and the second screw rod are respectively connected with the first motor after penetrating through the inlet and the outlet, the outer sides of the first screw rod and the second screw rod are respectively connected with the first sliding block and the second sliding block in a sliding manner, the top of the first sliding block is fixedly provided with a third motor, the rear end of the third motor is provided with a first double screw rod, the rear end of the first double screw rod is movably connected with the second sliding block, the outer side of the first double screw rod is connected with a third sliding block in a sliding manner, the center of the bottom of the inner wall of the first fixed box is fixedly provided with a first air cylinder, the top of the first air cylinder is fixedly provided with a first support plate, the top of the first support plate is fixedly provided with a fourth motor, the top, the top of the second air cylinder is provided with a telescopic rod, the top of the inner wall of the fixed box is respectively provided with a second through hole and a third through hole, the diameters of the second through hole and the third through hole are slightly larger than those of the side wing and the telescopic rod, and the axes of the second through hole and the third through hole are aligned with those of the first through hole and the second through hole, the third screw rod and the fourth screw rod, which are positioned in the front half part and the rear half part inside the box body, are respectively arranged above the dust collection box, the right ends of the third screw rod and the fourth screw rod are movably connected with the inner wall of the right end of the box body, the third screw rod and the fourth screw rod are respectively and slidably connected with a fourth sliding block and a fifth sliding block, the top of the fourth sliding block is fixedly provided with a fifth motor, the rear end of the fifth motor is provided with a second double, the bottom of the supporting plate II is fixedly provided with a cylinder III, and the bottom of the cylinder III is fixedly provided with a drill bit II, so to sum up, the side wings can be opened at the bottom of the raw ore through small-amplitude back-and-forth rotation, and one end of the dust collection box close to the center of the box body is in a semi-circular arc shape so as to be better attached to the raw ore and suck the ground raw ore powder.

A use method of an automatic mesh-dividing grinding and collecting device for raw ores comprises the following steps:

firstly, early preparation: a control chip is arranged inside the top of the box body, and grinding layers with different meshes are arranged on a dust collection box inside the box body;

firstly, feeding: the control chip controls the motor I to rotate to drive the screw rod I and the screw rod II to rotate, so that the sliding block III slides out of the box body through the inlet and the outlet, the center of the raw ore to be ground is approximately aligned with the through hole II and placed at the top of the fixed box, the control chip controls the cylinder II to lift the telescopic rod to prevent the raw ore from falling off, and then the motor I rotates reversely to enable the sliding block III to return to the inside of the box body through the inlet and the outlet;

secondly, fixing the bottom: the control chip controls the motor IV to continuously rotate forwards and backwards to drive the drill bit I and the side wing to rotate back and forth within an angle of 30 degrees, meanwhile, the air cylinder I slowly rises to enable the top of the drill bit I to be in contact with the bottom of the raw ore through the through hole II, the side wing slots the bottom of the raw ore after the top of the drill bit I drills into the raw ore, when the air cylinder I rises to the maximum stroke, the motor IV stops rotating back and forth to rotate clockwise normally, and at the moment, the side wing can drive the raw ore to rotate through the slot at the bottom of the raw ore;

thirdly, fixing the top: the control chip controls the sliding block six to move so that the drill bit two is aligned with the axis of the drill bit one, then the control chip simultaneously controls the motor six to rotate anticlockwise and the air cylinder three to extend out, so that the drill bit two drills into the top of the raw ore anticlockwise, when the drill bit two halves drill into the top of the raw ore, the motor six and the air cylinder three stop running, at the moment, two-point fixation is formed on the top and the bottom of the raw ore, and then the telescopic rod retracts into the air cylinder two;

fourthly, grinding: the control chip controls the dust collector to be started, the control chip controls the third sliding block and the sixth sliding block to use the first drill bit and the second drill bit as planetary points, a vertical point between the grinding layers is used as a fixed star point, the first drill bit and the second drill bit rotate around the vertical point between the grinding layers and conduct outward slow diffusion escape revolution, the maximum revolution radius of the first drill bit and the second drill bit is smaller than the distance from the vertical point between the grinding layers to the grinding layers, therefore, raw ore can rotate clockwise while the surfaces of the raw ore can be attached to the grinding layers with different meshes for grinding, the raw ore powder ground with different meshes is sucked into the dust collection box through the first through hole, and then the raw ore powder is sucked into the dust collector for storage.

The invention has the beneficial effects that: the grinding device has a simple structure, is simple and convenient to operate, directly skips the crushing step for grinding, saves the cost, can grind the raw ore in a multi-mesh mode at one time, can automatically collect the raw ore powder in the grinding process, solves the problem that the raw ore can only be ground by a single specified mesh in the conventional equipment, avoids the conditions of multiple feeding and discharging and grinding tools with different meshes, and is simple, efficient, convenient and quick in the whole process.

Drawings

FIG. 1 is a schematic structural view of the present invention;

FIG. 2 is a sectional view taken along line A-A of FIG. 1;

FIG. 3 is a sectional view taken along line B-B of FIG. 1;

FIG. 4 is a partial enlarged view of the second twin-screw, the sixth sliding block and the fifth motor in FIG. 1;

FIG. 5 is a partial, enlarged view of the grinding bed and through-hole one of FIG. 1;

FIG. 6 is an enlarged view of a portion of the holding tank of FIG. 1;

FIG. 7 is an enlarged view of a portion of the first bit, the shoulder, and the third through hole 22 of FIG. 3;

fig. 8 is a left side view of the first drill bit of the present invention.

Description of reference numerals: the dust collector comprises a box body 1, a control chip 2, a motor II 3, a dust collector 4, a guide pipe 5, a dust collection box 6, a sliding block IV 7, an inlet and outlet 8, a cylinder III 9, a motor I10, a drill bit I11, a fixed box 12, a motor IV 13, a support plate I14, a cylinder I15, a screw I16, a screw I17, a sliding block III 18, a sliding block I19, a motor III 20, a cylinder II 21, a through hole III 22, a through hole II 23, a screw II 24, a sliding block VI 25, a motor V26, a screw III 27, a support plate II 28, a motor VI 29, a grinding layer 30, a through hole I31, a drill bit II 32, a screw IV 33, a sliding block II 34, a sliding block V35, a screw II 36.

Detailed Description

The invention will be further described with reference to the accompanying drawings in which:

referring to figures 1, 2, 3, 4, 5, 6, 7, 8: the automatic mesh-dividing grinding and collecting device for the raw ores in the embodiment comprises a box body 1, wherein a dust collector 4 fixedly connected with the ground is arranged on the front side, the rear side and the left side of the box body 1, a motor I10 fixedly connected with the ground is arranged on the front end, the rear end and the right side of the box body 1, a motor II 3 is fixedly arranged on the front half part and the rear half part of the top of the left dust collector 4, an inlet and an outlet 8 communicated with the outside are arranged on the inner wall of the right end of the box body 1, a dust collection box 6 is fixedly arranged in the middle of the inner walls of the front end, the rear end and the left end of the box body 1, a grinding layer 30 is fixedly arranged on the dust collection box 6, through holes I31 which are distributed in an array and are mutually communicated are arranged on one end, close to the box body 1, of the dust collector 4, a guide pipe 5 is arranged on one end, close, a first screw 16 and a second screw 36 which are positioned at the front half part and the rear half part inside the box body 1 are respectively arranged below the dust collection box 6, the left ends of the first screw 16 and the second screw 36 are movably connected with the inner wall of the left end of the box body 1, the right ends of the first screw 16 and the second screw 36 penetrate through the inlet and outlet 8 and are respectively connected with a first motor 10, the outer sides of the first screw 16 and the second screw 36 are respectively connected with a first sliding block 19 and a second sliding block 34 in a sliding manner, a third motor 20 is fixedly arranged at the top of the first sliding block 19, a first double screw 17 is arranged at the rear end of the third motor 20, the rear end of the first double screw 17 is movably connected with the second sliding block 34, a third sliding block 18 is connected at the outer side of the first double screw 17 in a sliding manner, a fixed box 12 is fixedly arranged at the top of the third, a motor IV 13 is fixedly installed at the top of the supporting plate I14, a drill bit I11 is fixedly installed at the top of the motor IV 13, a side wing 38 extending outwards is arranged on the outer side of the middle of the drill bit I11, a cylinder II 21 fixedly connected with the bottom of the inner wall of the fixed box 12 is arranged around the cylinder I15, an expansion link 37 is installed at the top of the cylinder II 21, a through hole II 23 and a through hole III 22 which are slightly larger than the side wing 38 and the expansion link 37 in diameter and are aligned with the axis are respectively arranged at the top of the inner wall of the fixed box 12, a screw rod III 27 and a screw rod IV 33 which are positioned at the front half part and the rear half part inside the box 1 are respectively arranged above the dust collection box 6, the right ends of the screw rod III 27 and the screw rod IV 33 are movably connected with the inner wall of the right end of the box 1, the left ends of the screw rod III 27 and the screw rod IV 33 are respectively connected with, the top of the fourth sliding block 7 is fixedly provided with a fifth motor 26, the rear end of the fifth motor 26 is provided with a second double-screw 24, the rear end of the second double-screw 24 is movably connected with a fifth sliding block 35, the outer side of the second double-screw 24 is slidably connected with a sixth sliding block 25, the bottom of the sixth sliding block 25 is fixedly provided with a sixth motor 29, the bottom of the sixth motor 29 is fixedly provided with a second support plate 28, the bottom of the second support plate 28 is fixedly provided with a third cylinder 9, and the bottom of the third cylinder 9 is fixedly provided with a second drill.

Referring to figures 1, 2, 3, 4, 5, 6, 7, 8: a use method of an automatic mesh-dividing grinding and collecting device for raw ores comprises the following steps:

firstly, early preparation: the control chip 2 is arranged in the top of the box body 1, and the dust collection box 6 in the box body 1 is arranged with different meshes

A number of ground layers;

firstly, feeding: the control chip 2 controls the motor I10 to rotate to drive the screw rod I16 and the screw rod II 36 to rotate, so that the sliding block III 18 slides out of the box body 1 through the inlet and outlet 8, the center of the raw ore to be ground is approximately aligned with the through hole II 23 and placed at the top of the fixed box 12, the control chip 2 controls the cylinder II 21 to lift the telescopic rod 37 to prevent the raw ore from falling off, and then the motor I10 rotates reversely to enable the sliding block III 18 to return to the interior of the box body through the inlet and outlet 8;

secondly, fixing the bottom: the control chip 2 controls the motor IV 13 to continuously rotate forwards and backwards to drive the drill bit I11 and the side wing 38 to rotate back and forth within an angle of 30 degrees, meanwhile, the air cylinder I15 slowly rises, so that the top of the drill bit I11 is contacted with the bottom of the raw ore through the through hole II 23, the side wing 38 slots the bottom of the raw ore after the top of the drill bit I11 drills into the raw ore, when the air cylinder I15 rises to the maximum stroke, the motor IV 13 stops rotating back and forth to rotate clockwise normally, and at the moment, the side wing 32 can drive the raw ore to rotate through the slot at the bottom of the raw ore;

thirdly, fixing the top: the control chip 2 controls the sliding block six 25 to move, so that the drill bit two 32 is aligned with the axis of the drill bit one 11, then the control chip 2 simultaneously controls the motor six 29 to rotate anticlockwise and the air cylinder three 9 to extend, so that the drill bit two 32 drills downwards anticlockwise into the top of the raw ore, when half of the drill bit two 32 drills into the top of the raw ore, the motor six 29 and the air cylinder three 9 stop running, two-point fixation is formed on the top and the bottom of the raw ore at the moment, and then the telescopic rod 37 retracts into the air cylinder two 21;

fourthly, grinding: the control chip 2 controls the dust collector 4 to be opened, the control chip 2 controls the sliding block III 18 and the sliding block VI 25 to use the drill bit I11 and the drill bit II 32 as planetary points, the vertical point between the grinding layers 30 as a star point, the drill bit I11 and the drill bit II 32 rotate around the vertical point between the grinding layers 30 to perform outward slow diffusion escape revolution, the maximum revolution radius of the drill bit I11 and the drill bit II 32 is smaller than the distance from the vertical point between the grinding layers 30 to the grinding layers 30, so that the raw ore can be ground while rotating clockwise, the surface of the raw ore can be attached to the grinding layers 30 with different meshes, the raw ore powder ground with different meshes is sucked into the dust collection box 6 through the through hole I31, and then the raw ore powder is sucked into the dust collector 4 to be stored.

While the invention has been shown and described with reference to a preferred embodiment, it will be understood by those skilled in the art that various changes in form and detail may be made therein without departing from the scope of the appended claims.

Claims

1. The utility model provides an automatic mesh grinding collection device that divides of raw ore, includes box (1), characterized by: left side is equipped with dust catcher (4) with ground fixed connection around box (1), box (1) right-hand front and back both ends be equipped with ground fixed connection's motor (10), half and latter half fixed mounting has motor two (3) before dust catcher (4) top of left side, box (1) right-hand member inner wall is equipped with exit (8) with external intercommunication, left three-terminal inner wall middle part fixed mounting has dust collection box (6) around box (1), dust collection box (6) are close to box (1) center one end fixed mounting has grinding layer (30), dust collection box (6) are close to box (1) center one end and grinding layer (30) inside through-hole one (31) that are equipped with array distribution and communicate each other, dust catcher (4) are close to box (1) one end and install pipe (5), pipe (5) pass box (1) inner wall and dust collection box (6) in proper order and keep away from box (1) center one end (6) The inner wall of the dust collection box reaches the inside of the dust collection box (6), a first screw (16) and a second screw (36) which are positioned at the front half part and the rear half part of the inside of the box body (1) are respectively arranged below the dust collection box (6), the left ends of the first screw (16) and the second screw (36) are movably connected with the inner wall of the left end of the box body (1), the right ends of the first screw (16) and the second screw (36) penetrate through the inlet and outlet (8) and are respectively connected with a first motor (10), the outer sides of the first screw (16) and the second screw (36) are respectively and slidably connected with a first sliding block (19) and a second sliding block (34), a third motor (20) is fixedly installed at the top of the first sliding block (19), a first double screw (17) is installed at the rear end of the third motor (20), the rear end of the first double screw (17) is movably connected with the second sliding, sliding block three (18) top fixed mounting has fixed box (12), fixed box (12) inner wall bottom center fixed mounting has cylinder (15), cylinder (15) top fixed mounting has backup pad (14), backup pad (14) top fixed mounting has motor four (13), motor four (13) top fixed mounting has drill bit (11), drill bit (11) middle part outside is equipped with outside flank (38) that extends, cylinder (15) are equipped with all around with fixed box (12) inner wall bottom fixed connection's cylinder two (21), telescopic link (37) are installed at cylinder two (21) top, fixed box (12) inner wall top is equipped with diameter slightly and is greater than flank (38) and telescopic link (37) and axis and its aligned through-hole two (23) and through-hole three (22), dust collection box (6) top is equipped with the screw rod that is located box (1) inside first half and latter half respectively A third screw rod (27) and a fourth screw rod (33), the right ends of the third screw rod (27) and the fourth screw rod (33) are movably connected with the inner wall of the right end of the box body (1), the left ends of the third screw rod (27) and the fourth screw rod (33) penetrate through the inner wall of the left end of the box body (1) and then are respectively connected with a second motor (3), the outer sides of the third screw rod (27) and the fourth screw rod (33) are respectively and slidably connected with a fourth sliding block (7) and a fifth sliding block (35), the top of the fourth sliding block (7) is fixedly provided with a fifth motor (26), the rear end of the fifth motor (26) is provided with a second double screw rod (24), the rear end of the second double screw rod (24) is movably connected with the fifth sliding block (35), the outer side of the second double screw rod (24) is slidably connected with a sixth sliding block (25), the bottom of the, and a third cylinder (9) is fixedly mounted at the bottom of the second support plate (28), and a second drill bit (32) is fixedly mounted at the bottom of the third cylinder (9).

2. The use method of the automatic mesh-dividing grinding and collecting device for the raw ore according to claim 1 comprises the following steps:

firstly, early preparation: a control chip (2) is arranged in the top of the box body (1), and grinding layers with different meshes are arranged on a dust collection box (6) in the box body (1);

firstly, feeding: the control chip (2) controls the motor I (10) to rotate, drives the screw rod I (16) and the screw rod II (36) to rotate, enables the sliding block III (18) to slide out of the box body (1) through the inlet and outlet (8), enables the center of raw ore to be ground to be approximately aligned with the through hole II (23), and is placed at the top of the fixed box (12), the control chip (2) controls the cylinder II (21) to lift the telescopic rod (37) to prevent the raw ore from falling, and then the motor I (10) rotates reversely to enable the sliding block III (18) to return to the inside of the box body through the inlet and outlet (8);

secondly, fixing the bottom: the control chip (2) controls the motor IV (13) to continuously rotate forwards and backwards to drive the drill bit I (11) and the side wing (38) to rotate back and forth within an angle of 30 degrees, meanwhile, the cylinder I (15) slowly rises to enable the top of the drill bit I (11) to be in contact with the bottom of the raw ore through the through hole II (23), the side wing (38) slots the bottom of the raw ore after the top of the drill bit I (11) drills into the raw ore, when the cylinder I (15) rises to the maximum stroke, the motor IV (13) stops rotating back and forth to rotate clockwise normally, and at the moment, the side wing (38) can drive the raw ore to rotate through the slot at the bottom of the raw ore;

thirdly, fixing the top: the control chip (2) controls the sliding block six (25) to move, so that the drill bit two (32) is aligned with the axis of the drill bit one (11), then the control chip (2) simultaneously controls the motor six (29) to rotate anticlockwise and the air cylinder three (9) to extend out, so that the drill bit two (32) drills into the top of the raw ore anticlockwise, when half of the drill bit two (32) drills into the top of the raw ore, the motor six (29) and the air cylinder three (9) stop running, two-point fixation is formed on the top and the bottom of the raw ore at the moment, and then the telescopic rod (37) retracts back to the interior of the air cylinder two (21);

fourthly, grinding: the control chip (2) controls the dust collector (4) to be started, the control chip (2) controls the third sliding block (18) and the sixth sliding block (25) to take the first drill bit (11) and the second drill bit (32) as planetary points, taking a vertical point between the grinding layers (30) as a star point, the drill bit (11) and the drill bit (32) rotate around the vertical point between the grinding layers (30) to perform slow diffusion escape revolution outwards, the maximum revolution radius of the drill bit (11) and the drill bit (32) is smaller than the distance from the vertical point between the grinding layers (30) to the grinding layers (30), therefore, the surface of the raw ore can be attached to grinding layers (30) with different meshes for grinding while rotating clockwise, the raw ore powder ground with different meshes is sucked into the dust collection box (6) through the first through hole (31), and then the raw ore powder is sucked into the dust collector (4) for storage.