CN115445730A - High-efficiency and low-energy-consumption mineral crushing equipment and method - Google Patents

Abstract

The invention discloses a high-efficiency and low-energy-consumption mineral crushing device and a method thereof, which belong to the technical field of mineral processing and aim at solving the problems that when an ore crusher in the prior art is used, further crushing treatment is lacked, so that the ore crushing fineness is poor and the crushing sufficiency is low; according to the invention, the output end of the motor drives the circular plate c to rotate, the circular plate c drives the transmission mechanism to work, the transmission mechanism drives the crushing mechanism to further crush and refine the ores, so that the fineness of crushed ores is increased, the ores are synchronously crushed and refined in small parts through the plurality of crushing mechanisms, and the condition that excessive ores are crushed simultaneously is avoided, so that the efficiency of crushing the ores is effectively improved, and the driving energy consumption is lower.

Description

High-efficiency and low-energy-consumption mineral crushing equipment and method

Technical Field

The invention belongs to the technical field of mineral processing, and particularly relates to high-efficiency and low-energy-consumption mineral crushing equipment and a method thereof.

Background

Mineral resources are the material basis for the survival and development of modern human beings, even today with high-speed development of information technology, the mineral resources still play an irreplaceable role in the daily life of human beings, and in the mining production of mines, after the ores are often required to be coarsely crushed, according to the processing requirements, part of the ores are required to be further crushed, so that the utilization is convenient.

Chinese patent publication no: CN205056089U discloses an ore crusher, including first extrusion wheel, the second extrusion wheel, first motor, second motor and casing, be provided with first extrusion wheel and second extrusion wheel that are parallel to each other in the casing, the below of first extrusion wheel and second extrusion wheel is provided with the reciprocating sieve, the below of reciprocating sieve is provided with first transmission band, be provided with the second transmission band between reciprocating sieve and the first transmission band, the top of second transmission band is provided with motor support, the last first motor of being connected with first extrusion wheel of installing of motor support, the last second motor of being connected with second extrusion wheel of still installing of motor support, a side of casing is provided with the thin material export, another side is provided with the coarse fodder export. According to the invention, the vibrating screen is arranged below the first extrusion wheel and the second extrusion wheel, so that the labor intensity of workers is reduced, the working efficiency is improved, and the automation degree is high;

although the technical problem that proposes in its background art has been solved to above-mentioned patent, still there is not enough, and the ore passes through first extrusion wheel, the cooperation of second extrusion wheel and smashes the back, wherein still has partial incomplete kibbling ore, lacks further shredding to lead to ore crushing fineness relatively poor, smash the sufficiency lower.

Therefore, a mineral crushing device with high efficiency and low energy consumption and a method thereof are needed, and the problems that the ore crushing fineness is poor and the crushing sufficiency is low due to the lack of further crushing treatment when the ore crusher in the prior art is used are solved.

Disclosure of Invention

The invention aims to provide mineral crushing equipment with high efficiency and low energy consumption and a method thereof, so as to solve the problems in the background technology.

In order to achieve the purpose, the invention provides high-efficiency low-energy-consumption mineral crushing equipment which comprises a shell, wherein a motor is fixed on the inner side wall of the top end of the shell, a circular plate c is rotatably connected to the inner side wall of the shell through a bearing, the output end of the motor is fixed with the center position of the top end of the circular plate c, a plurality of transmission mechanisms distributed annularly are arranged at the bottom end of the motor, a circular plate b fixed with the inner side wall of the shell is arranged below the circular plate c, a circular plate a fixed with the inner side wall of the shell is arranged below the circular plate b, a crushing mechanism in transmission connection with the transmission mechanisms is arranged in the circular plate a, a blanking port located right below the transmission mechanisms is arranged on the side surface of the bottom end of the circular plate a, a feeding pipe is fixed on the side wall of the shell, the inner side end of the feeding pipe is communicated with a feeding cylinder, and a blanking pipe communicated with the crushing mechanism is arranged at the bottom end of the feeding cylinder.

It is further worth explaining, drive mechanism includes the arc lug an fixed with plectane c bottom side, arc lug a is provided with a plurality ofly and is the annular and distributes, sliding connection has a plurality of arc lug b that are the annular and distribute on the arc lug a, arc lug b's bottom mounting has the slip to run through plectane b's slide bar, the cover is equipped with reset spring on the side of slide bar, reset spring's both ends are fixed with arc lug b's bottom and reset spring's top side respectively.

It should be further noted that the crushing mechanism comprises a connecting plate fixed to the bottom end of the sliding rod, a high-strength blade is fixed to the bottom end of the connecting plate, a crushing cavity which is matched with the connecting plate in a sliding mode and is communicated with one end, far away from the conveying cylinder, of the blanking pipe is formed in the side face of the top end of the circular plate a, a plurality of blanking holes distributed at equal intervals are formed in the side face of the bottom end of the crushing cavity, and the blanking holes are located under the crushing cavity.

In a preferred embodiment, the high-strength blade at the bottom of the connecting plate is provided with a plurality of high-strength blades which are distributed at equal intervals.

As a preferred embodiment, two symmetrically distributed connecting rods are arranged on the inner side wall of the top end of the shell, and the two connecting rods are fixed to the surface of the motor close to the proximal end.

In a preferred embodiment, two legs are fixed on the outer side wall of the housing, and the legs are symmetrically distributed.

As a preferred embodiment, the bottom ends of the two support legs are jointly fixed with a bottom plate, and a collection box is placed on the side surface of the top end of the bottom plate and is positioned below the bottom end of the shell.

A mineral crushing method with high efficiency and low energy consumption comprises the following steps:

s1, putting the coarsely crushed ore into a feeding pipe, feeding the ore into a conveying cylinder through the feeding pipe, and feeding the ore into a crushing cavity through a blanking pipe;

s2, starting a motor to work, wherein an output end of the motor drives a circular plate c to rotate, the circular plate c drives a plurality of arc-shaped convex blocks a which are distributed in an annular shape to rotate, and the arc-shaped convex blocks a are in sliding contact with the arc-shaped convex blocks b when rotating, so that the sliding rod is driven to reciprocate by the arc-shaped convex blocks a, the arc-shaped convex blocks b and a reset spring;

s3, the sliding rod drives the high-strength blade to perform reciprocating extrusion cutting in the crushing cavity through the connecting plate when reciprocating up and down, so that the ore is further crushed and refined, and the fineness of crushed ore is increased;

and S4, leaking the fully refined ore through a plurality of blanking holes.

Compared with the prior art, the mineral crushing equipment with high efficiency and low energy consumption and the method thereof provided by the invention at least have the following beneficial effects:

(1) Through the slide bar when reciprocating and reciprocating, drive the reciprocal extrusion cutting of high strength blade in crushing intracavity through the connecting plate, thereby further smashing the ore and refining, increase the kibbling fineness of ore, the ore after fully refining spills through a plurality of blanking holes, thereby divide into the synchronous smashing of small share ground and refine to the ore through a plurality of high strength blades, avoid too much ore to carry out kibbling condition simultaneously, thereby effectively improve the kibbling efficiency of ore, the drive energy consumption is lower, the energy saving.

(2) Further increase the efficiency that the ore was smashed and is refined through a plurality of high strength blade, the bottom plate that sets up increases the stability of device and falls into in the collection box through the ore after abundant crushing that the blanking mouth spills, concentrates the collection.

Drawings

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

FIG. 2 is an overall sectional structural view of the present invention;

FIG. 3 is an enlarged view of the structure at A in FIG. 2;

FIG. 4 is an enlarged view of the structure at B in FIG. 2;

FIG. 5 is a partial structural view of an arc bump b according to the present invention;

fig. 6 is a partial structural schematic view of the arc bump b of the present invention.

In the figure: 1. a transmission mechanism; 101. an arc-shaped bump a; 102. an arc-shaped bump b; 103. a return spring; 104. a slide bar; 2. a crushing mechanism; 201. a high strength blade; 202. a grinding chamber; 203. a blanking hole; 204. a connecting plate; 3. a housing; 4. a base plate; 5. a support leg; 6. a collection box; 7. a feeding pipe; 8. a connecting rod; 9. a motor; 10. a delivery cylinder; 11. a blanking pipe; 12. a circular plate a; 13. a circular plate b; 14. a circular plate c; 15. and a blanking port.

Detailed Description

The present invention will be further described with reference to the following examples.

In order to make the objects, technical solutions and advantages of the embodiments of the present invention clearer, the technical solutions of the embodiments of the present invention will be described clearly and completely with reference to the drawings of the embodiments of the present invention, and it is obvious that the described embodiments are some embodiments of the present invention, but not all embodiments, and all other embodiments obtained by a person of ordinary skill in the art without creative work based on the described embodiments of the present invention belong to the protection scope of the present invention.

The following examples are intended to illustrate the invention, but are not intended to limit the scope of the invention. The conditions in the embodiments can be further adjusted according to specific conditions, and simple modifications of the method of the present invention based on the concept of the present invention are within the scope of the claimed invention.

Referring to fig. 1-6, the invention provides a high-efficiency low-energy consumption mineral crushing apparatus, which comprises a housing 3, wherein a motor 9 is fixed on the inner side wall of the top end of the housing 3, the inner side wall of the housing 3 is rotatably connected with a circular plate c14 through a bearing, the output end of the motor 9 is fixed with the center position of the top end of the circular plate c14, a plurality of transmission mechanisms 1 distributed annularly are arranged at the bottom end of the motor 9, a circular plate b13 fixed with the inner side wall of the housing 3 is arranged below the circular plate c14, a circular plate a12 fixed with the inner side wall of the housing 3 is arranged below the circular plate b13, a crushing mechanism 2 in transmission connection with the transmission mechanisms 1 is arranged in the circular plate a12, a blanking port 15 located right below the transmission mechanisms 1 is arranged on the side surface of the bottom end of the circular plate a12, a feeding pipe 7 is fixed on the side wall of the housing 3, an inner side end of the feeding pipe 7 is communicated with a feeding barrel 10, and a blanking pipe 11 communicated with the crushing mechanism 2 is communicated with the bottom end of the feeding barrel 10; when carrying out the use, the ore after will passing through the coarse crushing drops into in the feeding pipe 7, enter into the conveying feed cylinder 10 through feeding pipe 7 in, rethread blanking pipe 11 enters into rubbing crusher constructs 2 in, starter motor 9 carries out work, the output of motor 9 drives plectane c14 and rotates, plectane c14 drives drive mechanism 1 and carries out work, drive mechanism 1 drives rubbing crusher structure 2 and carries out further smashing to the ore and refines, increase the kibbling fineness of ore, divide into the synchronous smashing of small share ground and refine to the ore through a plurality of rubbing crusher constructs 2, avoid too much ore to carry out the kibbling condition simultaneously, thereby effectively improve the kibbling efficiency of ore, drive energy consumption is lower, energy saving.

As further shown in fig. 4, fig. 5 and fig. 6, it should be specifically described that the transmission mechanism 1 includes an arc-shaped protrusion a101 fixed to a side surface of a bottom end of the circular plate c14, the arc-shaped protrusion a101 is provided with a plurality of arc-shaped protrusions a 102 distributed annularly, the arc-shaped protrusion a101 is connected to the plurality of arc-shaped protrusions b102 distributed annularly in a sliding manner, a sliding rod 104 penetrating through the circular plate b13 in a sliding manner is fixed to a bottom end of the arc-shaped protrusion b102, a return spring 103 is sleeved on a side surface of the sliding rod 104, and two ends of the return spring 103 are respectively fixed to a bottom end of the arc-shaped protrusion b102 and a top end side surface of the return spring 103; the starting motor 9 works, the output end of the motor 9 drives the circular plate c14 to rotate, the circular plate c14 drives a plurality of arc-shaped convex blocks a101 which are distributed annularly to rotate, the arc-shaped convex blocks a101 are in sliding contact with the arc-shaped convex blocks b102 when rotating, so that the sliding rods 104 are driven to reciprocate through the arc-shaped convex blocks a101, the arc-shaped convex blocks b102 and the reset springs 103, and the sliding rods 104 drive the crushing mechanism 2 to crush ores in the reciprocating process.

As further shown in fig. 1, fig. 2 and fig. 3, it is worth specifically explaining that the crushing mechanism 2 includes a connecting plate 204 fixed to the bottom end of the sliding rod 104, a high-strength blade 201 is fixed to the bottom end of the connecting plate 204, a crushing cavity 202 slidably fitted to the connecting plate 204 and communicated with one end of the blanking pipe 11 away from the feeding cylinder 10 is formed on a side surface of a top end of the circular plate a12, a plurality of blanking holes 203 are formed in the side surface of the bottom end of the crushing cavity 202, and the blanking hole 15 is located right below the crushing cavity 202; the ore falls into crushing chamber 202 through blanking pipe 11 in, slide bar 104 drives high strength blade 201 through connecting plate 204 when reciprocating to reciprocate crushing chamber 202 reciprocal extrusion cutting, thereby further smashing the ore and refining, increase the kibbling fineness of ore, the ore after fully refining leaks through a plurality of blanking holes 203, thereby divide into the synchronous smashing of subtotal and refine to the ore through a plurality of high strength blades 201, avoid too much ore to carry out the kibbling condition simultaneously, thereby effectively improve the kibbling efficiency of ore, the drive energy consumption is lower, energy saving.

The scheme has the following working processes: the ore after coarse crushing is put into the feeding pipe 7, the ore enters the conveying cylinder 10 through the feeding pipe 7 and then enters the crushing cavity 202 through the blanking pipe 11, the motor 9 is started to work, the output end of the motor 9 drives the circular plate c14 to rotate, the circular plate c14 drives the arc-shaped convex blocks a101 which are distributed in an annular shape to rotate, the arc-shaped convex blocks a101 are in sliding contact with the arc-shaped convex blocks b102 when rotating, the sliding rods 104 are driven to reciprocate through the arc-shaped convex blocks a101, the arc-shaped convex blocks b102 and the reset springs 103, the sliding rods 104 drive the high-strength blades 201 to perform reciprocating extrusion cutting in the crushing cavity 202 through the connecting plates 204 when reciprocating up and down, further crushing and refining are performed on the ore, the fineness of crushed ore is increased, the ore after being fully refined leaks out through the plurality of blanking holes 203, and the ore is synchronously crushed and refined by dividing the plurality of high-strength blades 201 into small parts.

According to the working process, the following steps are known: the transmission mechanism 1 drives the crushing mechanisms 2 to further crush and refine ores, the fineness of ore crushing is increased, the ores are synchronously crushed and refined in small parts through the plurality of crushing mechanisms 2, the situation that excessive ores are crushed simultaneously is avoided, the efficiency of ore crushing is effectively improved, the driving energy consumption is low, and energy is saved.

As further shown in fig. 3, it is worth specifically describing that a plurality of high-strength blades 201 are arranged at the bottom of a single connecting plate 204, and the plurality of high-strength blades 201 are distributed at equal intervals; in particular, the efficiency of ore pulverization and refinement is further increased by the plurality of high-strength blades 201.

As further shown in fig. 1 and fig. 2, it should be noted that two symmetrically distributed connecting rods 8 are disposed on the inner side wall of the top end of the housing 3, and the two connecting rods 8 are fixed to the surface of the motor 9 near the proximal end.

Further as shown in fig. 1, it is worth specifically explaining that two support legs 5 are fixed on the outer side wall of the housing 3, and the two support legs 5 are symmetrically distributed; during specific work, the arranged bottom plate 4 increases the stability of the device.

Further as shown in fig. 1, it is worth specifically explaining that the bottom ends of the two legs 5 are jointly fixed with a bottom plate 4, a collecting box 6 is placed on the side surface of the top end of the bottom plate 4, and the collecting box 6 is located below the bottom end of the housing 3; during specific work, the ores leaked through the blanking port 15 and fully crushed fall into the collecting box 6 for centralized collection.

A mineral crushing method with high efficiency and low energy consumption comprises the following steps:

s1, throwing the coarsely crushed ore into a feeding pipe 7, feeding the ore into a conveying cylinder 10 through the feeding pipe 7, and feeding the ore into a crushing cavity 202 through a blanking pipe 11;

s2, starting the motor 9 to work, wherein the output end of the motor 9 drives the circular plate c14 to rotate, the circular plate c14 drives the plurality of arc-shaped convex blocks a101 which are distributed annularly to rotate, and the arc-shaped convex blocks a101 are in sliding contact with the arc-shaped convex blocks b102 when rotating, so that the sliding rod 104 is driven to reciprocate by the arc-shaped convex blocks a101, the arc-shaped convex blocks b102 and the reset spring 103;

s3, when the sliding rod 104 moves up and down in a reciprocating mode, the connecting plate 204 drives the high-strength blade 201 to extrude and cut in the crushing cavity 202 in a reciprocating mode, so that ore is further crushed and refined, and the crushing fineness of the ore is increased;

and S4, leaking the fully refined ore through the plurality of blanking holes 203.

To sum up: drive mechanism 1 drive rubbing crusher constructs 2 and carries out further smashing to the ore and refines, increase the kibbling fineness of ore, divide into synchronous smashing in small parts and refine to the ore through a plurality of rubbing crusher constructs 2, avoid too much ore to carry out the kibbling condition simultaneously, thereby effectively improve the kibbling efficiency of ore, the drive energy consumption is lower, energy saving, further increase the efficiency that the ore was smashed and is refined through a plurality of high strength blade 201, the bottom plate 4 of setting increases the stability of device, the ore after abundant crushing that spills through blanking mouth 15 falls into in collecting box 6, concentrate the collection.

The motor 9 can be purchased in the market, and the motor 9 is provided with a power supply, which belongs to the mature technology in the field and is fully disclosed, so repeated description is not repeated in the specification.

Unless defined otherwise, technical or scientific terms used herein should be construed as commonly understood by one of ordinary skill in the art, and the use of the term "comprising" or "including" and the like in the present invention means that the element or item preceding the term covers the element or item listed after the term and its equivalents, but does not exclude other elements or items, and the term "connected" or "connected" and the like are not limited to physical or mechanical connections, but may also include electrical connections, whether direct or indirect, "upper", "lower", "left", "right", and the like, are used merely to indicate relative positional relationships, and when the absolute position of the object being described is changed, the relative positional relationships may be changed accordingly.

Although embodiments of the present invention have been shown and described, it will be appreciated by those skilled in the art that various changes, modifications, substitutions and alterations can be made in these embodiments without departing from the principles and spirit of the invention, the scope of which is defined in the appended claims and their equivalents.

Claims (8)

1. The utility model provides a mineral crushing apparatus of high efficiency, low energy consumption, includes shell (3), its characterized in that, the top inside wall of shell (3) is fixed with motor (9), the inside wall of shell (3) rotates through the bearing and is connected with plectane c (14), the output of motor (9) is fixed with the top central point of plectane c (14) puts, the bottom of motor (9) is provided with a plurality of drive mechanism (1) that are the annular and distribute, the below of plectane c (14) is provided with plectane b (13) fixed with shell (3) inside wall, the below of plectane b (13) is provided with plectane a (12) fixed with shell (3) inside wall, be provided with rubbing crusher structure (2) of being connected with drive mechanism (1) transmission in plectane a (12), set up blanking pipe (7) that are located drive mechanism (1) under on the bottom side of plectane a (12), be fixed with on the lateral wall of shell (3) and throw material pipe (7), the medial extremity intercommunication of material pipe (7) has feed conveying pipe (10), the bottom intercommunication of feed delivery pipe (10) has feed inlet (11) to feed mechanism (11) intercommunication.

2. The mineral crushing device with high efficiency and low energy consumption according to claim 1, wherein the transmission mechanism (1) comprises an arc-shaped projection a (101) fixed to the bottom end side of a circular plate c (14), the arc-shaped projection a (101) is provided with a plurality of arc-shaped projections a (101) distributed in an annular shape, the arc-shaped projection a (101) is connected with a plurality of arc-shaped projections b (102) distributed in an annular shape in a sliding manner, a sliding rod (104) sliding to penetrate through the circular plate b (13) is fixed to the bottom end of the arc-shaped projection b (102), a return spring (103) is sleeved on the side face of the sliding rod (104), and two ends of the return spring (103) are fixed to the bottom end of the arc-shaped projection b (102) and the top end side face of the return spring (103) respectively.

3. The mineral crushing device with high efficiency and low energy consumption according to claim 2, wherein the crushing mechanism (2) comprises a connecting plate (204) fixed at the bottom end of a sliding rod (104), a high-strength blade (201) is fixed at the bottom end of the connecting plate (204), a crushing cavity (202) which is in sliding fit with the connecting plate (204) and is communicated with one end, far away from the feeding cylinder (10), of a blanking pipe (11) is formed in the side surface of the top end of a circular plate a (12), a plurality of blanking holes (203) which are distributed at equal intervals are formed in the side surface of the bottom end of the crushing cavity (202), and the blanking hole (15) is located right below the crushing cavity (202).

4. A high efficiency, low energy consumption mineral comminution plant as in claim 3, characterized in that the high strength blades (201) at the bottom of the individual connection plate (204) are provided in a plurality, the high strength blades (201) being equally spaced.

5. An efficient and low energy consumption mineral comminution apparatus as in claim 1, wherein the housing (3) has two symmetrically disposed connecting rods (8) on the inside wall of the top end thereof, the two connecting rods (8) being fixed to the surface of the motor (9) near the proximal end thereof.

6. A mineral crushing plant with high efficiency and low energy consumption as claimed in claim 5, characterized in that the outer side wall of the outer casing (3) is fixed with two legs (5), and the two legs (5) are symmetrically distributed.

7. A mineral crushing plant with high efficiency and low energy consumption as claimed in claim 6, characterized in that the bottom ends of the two legs (5) are jointly fixed with a bottom plate (4), the top side of the bottom plate (4) is provided with a collecting box (6), and the collecting box (6) is positioned below the bottom end of the outer casing (3).

8. A mineral comminution method as claimed in any one of claims 1 to 7 in which: the method comprises the following steps:

s1, throwing the coarsely crushed ore into a feeding pipe (7), entering a conveying cylinder (10) through the feeding pipe (7), and entering a crushing cavity (202) through a blanking pipe (11);

s2, starting a motor (9) to work, wherein an output end of the motor (9) drives a circular plate c (14) to rotate, the circular plate c (14) drives a plurality of arc-shaped convex blocks a (101) which are distributed in an annular mode to rotate, and the arc-shaped convex blocks a (101) are in sliding contact with the arc-shaped convex blocks b (102) when rotating, so that the sliding rod (104) is driven to reciprocate through the arc-shaped convex blocks a (101), the arc-shaped convex blocks b (102) and a reset spring (103);

s3, when the sliding rod (104) moves up and down in a reciprocating mode, the connecting plate (204) drives the high-strength blade (201) to extrude and cut in the crushing cavity (202) in a reciprocating mode, so that ore is further crushed and refined, and the crushing fineness of the ore is increased;

and S4, leaking the fully refined ore through the plurality of blanking holes (203).

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