CN216756581U - High-efficient breaker that mine engineering operation was used - Google Patents

Abstract

The utility model provides a high-efficiency crusher for mine engineering operation. The efficient crusher for mine engineering operation comprises a bottom plate, wherein four support rods are fixedly mounted at the top of the bottom plate in a matrix manner, a top plate is fixedly mounted at the top ends of the four support rods, a discharging opening is formed in the top plate, a crushing cavity is fixedly mounted on the top plate, a feeding hopper is arranged at the top of the crushing cavity, sliding grooves are formed in two sides of the crushing cavity, dust collecting openings are formed in two sides of the crushing cavity, and separation nets are arranged on the two dust collecting openings; the crushing mechanism is arranged on the inner wall of the crushing cavity; and the screening mechanism is arranged on the inner wall of the crushing cavity. The efficient crusher for the mine engineering operation has the advantages of dust collection function, ore classification and collection function and convenience in operation.

Description

High-efficient breaker that mine engineering operation was used

Technical Field

The utility model relates to the technical field of ore crushing, in particular to a high-efficiency crusher for mine engineering operation.

Background

Ore refers to a collection of minerals from which useful components can be extracted or which themselves have some property that can be exploited. Can be divided into metal mineral and nonmetal mineral. The unit content of useful components in the ore is called ore grade, the precious metal ore such as gold, platinum and the like is expressed by gram/ton, and other ores are expressed by percentage. The value of the ore is usually measured by the ore grade, but the ore value is also influenced by the composition of gangue (useless ore or ore with little useful component content and unavailable useful component) and the amount of harmful impurities in the effective component ore. After the ore is produced, the ore is usually crushed by a crusher due to large volume.

However, the existing crusher often cannot classify and collect the crushed ores with different sizes, which is inconvenient; meanwhile, in the process of crushing the ore, more dust is often splashed, and the dust which is sucked into the lungs by the workers can affect the health of the workers.

Therefore, it is necessary to provide a high-efficiency crusher for mining work to solve the above-mentioned technical problems.

SUMMERY OF THE UTILITY MODEL

The utility model aims to provide the efficient crusher for the mine engineering operation, which has the functions of dust collection and ore classification and collection and is convenient to operate.

In order to solve the above technical problems, the present invention provides a high efficiency crusher for mining work, comprising: the top of the bottom plate is fixedly provided with four supporting rods in a matrix manner, the top ends of the four supporting rods are fixedly provided with the same top plate, the top plate is provided with a discharging opening, the top plate is fixedly provided with a crushing cavity, the top of the crushing cavity is provided with a feeding hopper, two sides of the crushing cavity are provided with sliding grooves, two sides of the crushing cavity are provided with dust collecting openings, and two dust collecting openings are provided with separating nets; the crushing mechanism is arranged on the inner wall of the crushing cavity; the screening mechanism is arranged on the inner wall of the crushing cavity; the collecting mechanism is arranged on one side of the crushing cavity; the dust suction mechanism is arranged on the crushing cavity.

Preferably, the crushing mechanism comprises two rotating shafts, two crushing wheels and two main motors, wherein the two rotating shafts are rotatably installed on the inner wall of the crushing cavity, the two crushing wheels are respectively fixedly sleeved on the two rotating shafts, the two main motors are respectively fixedly installed on one side of the crushing cavity, and the output shafts of the two main motors are respectively fixedly connected with the two rotating shafts.

Preferably, the screening mechanism comprises two sliding plates, a screen, an auxiliary motor, a rotary table and a transmission plate, wherein the two sliding plates are respectively slidably mounted on the inner walls of the two sliding grooves, one side, close to each other, of each sliding plate is fixedly provided with the same screen, the auxiliary motor is arranged on one side of the crushing cavity, the rotary table is fixedly sleeved on an output shaft of the auxiliary motor, the transmission plate is hinged to the rotary table, and the transmission plate is hinged to the one sliding plate.

Preferably, the collecting mechanism comprises a collecting hopper and a side opening, the collecting hopper is arranged on one side of the crushing cavity, and the side opening is arranged on one side of the crushing cavity.

Preferably, dust absorption mechanism includes curb plate, air exhauster, first exhaust column, second exhaust column and collection dirt sack, curb plate fixed mounting be in one side in broken chamber, air exhauster fixed mounting be in the bottom of curb plate, first exhaust column sets up on the air intake of air exhauster, first exhaust column and one collection dirt opening is linked together, the second exhaust column sets up another on the collection dirt opening, the second exhaust column with first exhaust column is linked together, collection dirt sack sets up on the air outlet of air exhauster.

Preferably, a first conveyor belt is arranged on the bottom plate, the position of the first conveyor belt corresponds to the blanking opening, a second conveyor belt is arranged on the bottom plate, and the position of the second conveyor belt corresponds to the collecting hopper.

Compared with the related technology, the high-efficiency crusher for mine engineering operation provided by the utility model has the following beneficial effects:

the utility model provides a high-efficiency crusher for mine engineering operation, which can be used for feeding ores into a crushing cavity through a feeding hopper, crushing the ores through a crushing mechanism, classifying and screening the ores with two sizes through a screening mechanism, collecting larger ores through a collecting mechanism, removing dust in the crushing cavity through a dust collecting mechanism, and conveying the ores with two different sizes through a first conveyor belt and a second conveyor belt.

Drawings

FIG. 1 is a schematic structural view of a high-efficiency crusher for mining work according to a preferred embodiment of the present invention;

FIG. 2 is a schematic view of the rear view of the external structure of FIG. 1;

FIG. 3 is an enlarged view of portion A shown in FIG. 1;

fig. 4 is an enlarged schematic view of a portion B shown in fig. 1.

Reference numbers in the figures: 1. a base plate; 2. a support bar; 3. a top plate; 4. a crushing chamber; 5. a feeding hopper; 6. a rotating shaft; 7. a crushing wheel; 8. a main motor; 9. a sliding plate; 10. screening a screen; 11. an auxiliary motor; 12. a turntable; 13. a drive plate; 14. a collecting hopper; 15. the side edge is open; 16. a side plate; 17. an exhaust fan; 18. a first exhaust pipe; 19. a second exhaust pipe; 20. a dust collecting cloth bag; 21. a first conveyor belt; 22. a second conveyor belt.

Detailed Description

The utility model is further described with reference to the following figures and embodiments.

Referring to fig. 1-4, fig. 1 is a schematic structural diagram of a high-efficiency crusher for mining work according to a preferred embodiment of the present invention; FIG. 2 is a schematic view of the rear view of the external structure of FIG. 1; FIG. 3 is an enlarged view of portion A shown in FIG. 1; fig. 4 is an enlarged schematic view of a portion B shown in fig. 1. The high-efficiency crusher for mine engineering operation comprises: the crushing device comprises a bottom plate 1, wherein four support rods 2 are fixedly mounted at the top of the bottom plate 1 in a matrix manner, the top ends of the four support rods 2 are fixedly mounted with a top plate 3, a blanking opening is formed in the top plate 3, a crushing cavity 4 is fixedly mounted on the top plate 3, a feeding hopper 5 is arranged at the top of the crushing cavity 4, sliding grooves are formed in two sides of the crushing cavity 4, dust collecting openings are formed in two sides of the crushing cavity 4, and isolating nets are arranged on the two dust collecting openings; the crushing mechanism is arranged on the inner wall of the crushing cavity 4; the screening mechanism is arranged on the inner wall of the crushing cavity 4; a collecting mechanism arranged at one side of the crushing chamber 4; and the dust suction mechanism is arranged on the crushing cavity 4.

Broken mechanism includes two pivot 6, two broken wheels 7 and two main motors 8, two pivot 6 all rotates to be installed on the inner wall in broken chamber 4, two broken wheel 7 fixed cover respectively is established two in the pivot 6, two the equal fixed mounting of main motor 8 is in one side in broken chamber 4, two the output shaft of main motor 8 respectively with two 6 fixed connection in pivot can carry out the breakage to the ore through broken mechanism.

The screening mechanism comprises two sliding plates 9, a screen 10, an auxiliary motor 11, a rotary table 12 and a transmission plate 13, wherein the two sliding plates 9 are respectively slidably mounted on the inner walls of the sliding grooves, the two sliding plates 9 are fixedly mounted on one side close to each other and provided with the same screen 10, the auxiliary motor 11 is arranged on one side of the crushing cavity 4, the rotary table 12 is fixedly sleeved on an output shaft of the auxiliary motor 11, the transmission plate 13 is hinged on the rotary table 12, the transmission plate 13 is hinged with one sliding plate 9, and ores of two sizes can be classified and screened through the screening mechanism.

The collecting mechanism comprises a collecting hopper 14 and a side opening 15, the collecting hopper 14 is arranged on one side of the crushing cavity 4, the side opening 15 is arranged on one side of the crushing cavity 4, and large ores can be collected through the collecting mechanism.

Dust absorption mechanism includes curb plate 16, air exhauster 17, first exhaust column 18, second exhaust column 19 and dirt sack 20, curb plate 16 fixed mounting is in one side of broken chamber 4, air exhauster 17 fixed mounting be in the bottom of curb plate 16, first exhaust column 18 sets up on the air intake of air exhauster 17, first exhaust column 18 and one the collection dirt opening is linked together, second exhaust column 19 sets up another on the collection dirt opening, second exhaust column 19 with first exhaust column 18 is linked together, dirt sack 20 sets up on the air outlet of air exhauster 17, can remove dust in the broken chamber 4 through dust absorption mechanism.

The bottom plate 1 is provided with a first conveyor belt 21, the position of the first conveyor belt 21 corresponds to the blanking opening, the bottom plate 1 is provided with a second conveyor belt 22, the position of the second conveyor belt 22 corresponds to the collecting hopper 14, and ores with two different sizes can be conveyed through the first conveyor belt 21 and the second conveyor belt 22.

The working principle of the high-efficiency crusher for mine engineering operation provided by the utility model is as follows:

when the ore crusher is used, the two main motors 8 are started, the two main motors 8 drive the two rotating shafts 6 to rotate in opposite directions, the two rotating shafts 6 drive the two crushing wheels 7 to rotate in opposite directions, ores are fed into the crushing cavity 4 along the feeding hopper 5, the ores are crushed by the two crushing wheels 7 when passing through the two crushing wheels 7 rotating in opposite directions, the crushed ores fall onto the screen 10, the auxiliary motor 11 is started, the auxiliary motor 11 drives the rotary disc 12 to rotate, the rotary disc 12 drives the two sliding plates 9 and the screen 10 to move left and right through the transmission plate 13, the crushed ores can be screened through the screen 10 continuously moving left and right, smaller ores fall onto the first transmission belt 21 through the screen 10 and a blanking opening, the first transmission belt 21 is started, the smaller ores are conveyed and collected through the first transmission belt 21, and the larger ores fall into the collecting hopper 14 along the side opening 15, then the ore falls onto the second conveyor belt 22 along the collecting hopper 14, the second conveyor belt 22 is started, and the larger ore is conveyed and collected through the second conveyor belt 22;

during the dust removal, start air exhauster 17, air exhauster 17 through first exhaust column 18 and second exhaust column 19 with the air that contains dust in broken chamber 4 take out and arrange into collection dirt sack 20 in, the dust in the air is by the separation in the inside of collection dirt sack 20, will collect dirt sack 20 during the clearance and take off, then will collect the interior sedimentary dust of dirt sack 20 and fall, then will collect dirt sack 20 cover and continue to use on air outlet of air exhauster 17.

Compared with the related technology, the high-efficiency crusher for mine engineering operation provided by the utility model has the following beneficial effects:

the utility model provides a high-efficiency crusher for mine engineering operation, which can be used for feeding ores into a crushing cavity 4 through a feeding hopper 5, crushing the ores through a crushing mechanism, classifying and screening the ores with two sizes through a screening mechanism, collecting larger ores through a collecting mechanism, removing dust in the crushing cavity 4 through a dust collecting mechanism, and conveying the ores with two different sizes through a first conveyor belt 21 and a second conveyor belt 22.

The above description is only an embodiment of the present invention, and not intended to limit the scope of the present invention, and all modifications of equivalent structures and equivalent processes, which are made by using the contents of the present specification and the accompanying drawings, or directly or indirectly applied to other related technical fields, are included in the scope of the present invention.

Claims (6)

1. A high-efficient breaker that mine engineering operation was used which characterized in that includes:

the top of the bottom plate is fixedly provided with four supporting rods in a matrix manner, the top ends of the four supporting rods are fixedly provided with the same top plate, the top plate is provided with a discharging opening, the top plate is fixedly provided with a crushing cavity, the top of the crushing cavity is provided with a feeding hopper, two sides of the crushing cavity are provided with sliding grooves, two sides of the crushing cavity are provided with dust collecting openings, and two dust collecting openings are provided with separating nets;

the crushing mechanism is arranged on the inner wall of the crushing cavity;

the screening mechanism is arranged on the inner wall of the crushing cavity;

the collecting mechanism is arranged on one side of the crushing cavity;

the dust suction mechanism is arranged on the crushing cavity.

2. The efficient crusher for mining engineering operation as claimed in claim 1, wherein the crushing mechanism comprises two rotating shafts, two crushing wheels and two main motors, the two rotating shafts are rotatably mounted on the inner wall of the crushing cavity, the two crushing wheels are respectively fixedly sleeved on the two rotating shafts, the two main motors are respectively fixedly mounted on one side of the crushing cavity, and output shafts of the two main motors are respectively fixedly connected with the two rotating shafts.

3. The efficient crusher for mining engineering operation as claimed in claim 1, wherein the material sieving mechanism comprises two sliding plates, a screen, an auxiliary motor, a rotary plate and a transmission plate, the two sliding plates are slidably mounted on the inner walls of the two sliding grooves, the same screen is fixedly mounted on the side where the two sliding plates are close to each other, the auxiliary motor is arranged on one side of the crushing cavity, the rotary plate is fixedly mounted on an output shaft of the auxiliary motor, the transmission plate is hinged to the rotary plate, and the transmission plate is hinged to one of the sliding plates.

4. A high efficiency crusher for mining operations as claimed in claim 1 wherein the collection mechanism includes a collection hopper disposed on one side of the crushing chamber and a side opening disposed on one side of the crushing chamber.

5. The efficient crusher for mining engineering operation according to claim 1, wherein the dust suction mechanism comprises a side plate, an exhaust fan, a first exhaust pipe, a second exhaust pipe and a dust collection cloth bag, the side plate is fixedly installed at one side of the crushing cavity, the exhaust fan is fixedly installed at the bottom of the side plate, the first exhaust pipe is arranged on an air inlet of the exhaust fan, the first exhaust pipe is communicated with one dust collection opening, the second exhaust pipe is arranged on the other dust collection opening, the second exhaust pipe is communicated with the first exhaust pipe, and the dust collection cloth bag is arranged on an air outlet of the exhaust fan.

6. The efficient crusher for mining engineering work according to claim 4, wherein a first conveyor belt is arranged on the bottom plate, the position of the first conveyor belt corresponds to the blanking opening, a second conveyor belt is arranged on the bottom plate, and the position of the second conveyor belt corresponds to the collecting hopper.

Images