WO2024197681A1 - Ore screening apparatus - Google Patents

Abstract

An ore screening apparatus, comprising a housing (1). A feeding hopper (10) is arranged at the top of the housing, a second rotating shaft (15) is rotatably connected inside the housing, a power source is arranged at one end of the second rotating shaft, three cams (22) are fixedly connected to an outer wall of the second rotating shaft equidistantly, outer walls of the three cams each are in contact with the same lifting plate (16), the lifting plate is slidably connected inside the housing, top rollers (17) are fixedly connected to outer walls on two sides of the top of the lifting plate, each of outer walls of the tops of the top rollers are in contact with a screen plate (3), one end of each screen plate is hinged to an inner wall of one side of the housing, a through opening (4) is provided in one side of a bottom end of each screen plate, and return mechanisms are provided on top ends of the two screen plates. By providing the return mechanisms, the screen plates, the through openings, the second rotating shaft, the cams, the lifting plate and the top rollers, the two screen plates continuously vibrate, ore can be screened, and larger ore above the screen plates can be discharged through the through openings for facilitating subsequent treatment on the larger ore.

Description

Ore screening equipment Technical Field

The invention relates to the technical field of ore processing, and in particular to ore screening equipment.

Background Art

Ore refers to a mineral aggregate from which useful components can be extracted or which itself has certain properties that can be utilized. It can be divided into metallic minerals and non-metallic minerals. Ores are often required to be processed and used in the fields of metallurgy, mining, and chemical industry.

The Chinese patent with patent application number CN202022066428.X discloses an ore screening device, including a shell, a feed inlet, a discharge port, a screening device and a supporting device, wherein the feed inlet is connected to the upper end of the shell, the discharge port is connected to the lower end of the shell, the screening device is arranged inside the shell, the supporting device is fixedly installed on both sides of the shell, the screening device includes a fixed plate, the fixed plate is fixedly installed inside the shell, a sieve plate is arranged above the fixed plate, rollers are fixedly installed on both sides of the sieve plate, a screen is fixedly installed inside the sieve plate, and a tooth plate is fixedly installed at the bottom of the sieve plate. The present invention achieves the purpose of screening the ore by arranging the screening device, so that the ore can be crushed more quickly and thoroughly during the crushing process, and the height of the shell is adjusted by arranging the supporting device, so that storage vehicles of different heights can be placed.

However, when the equipment is in use, large pieces of ore screened out by the screening device will remain on the screen, and the large pieces of ore cannot be discharged. They need to be processed manually, which is time-consuming and labor-intensive.

In view of this, the present invention proposes an ore screening device to solve the problems existing in the above-mentioned prior art.

Summary of the invention

The purpose of the present invention is to solve the shortcomings of the prior art and to propose an ore screening device.

In order to achieve the above object, the present invention adopts the following technical solutions:

A kind of ore screening equipment includes a shell, a feed hopper is arranged on the top of the shell, and a second rotating shaft is rotatably connected inside the shell, and a power source is arranged at one end of the second rotating shaft, three cams are fixedly connected to the outer wall of the second rotating shaft at equal distances, and the outer walls of the three cams are in contact with the same lifting plate, the lifting plate is slidably connected to the inside of the shell, and the outer walls on both sides of the top of the lifting plate are fixedly connected to top rollers, the outer walls of the top of the top rollers are in contact with screening plates, and one end of the screening plates is hinged to the inner wall of one side of the shell, a through hole is arranged on one side of the bottom end of the screening plate, and a reset mechanism is arranged on the top of the two screening plates.

Furthermore, the reset mechanism includes an inverted U-shaped plate, which is fixedly connected to the inner wall of the shell, and the outer walls on both sides of the bottom of the inverted U-shaped plate are provided with sliding grooves, the inner walls of the sliding grooves are slidably connected with sealing plates, and a plurality of reset springs are fixedly connected between the sealing plate and the inner wall at the top of the sliding groove, the lower end of the sealing plate is in contact with the outer wall at the top of the screening plate, and the cross-section of the lower end of the sealing plate is semicircular.

Furthermore, a discharge port is provided at the bottom of the shell, and guide plates are fixedly connected between the outer walls on both sides of the top of the discharge port and the inner walls on both sides of the shell.

Furthermore, the outer walls on both sides of the shell are fixedly connected with fixed blocks, and the outer wall on one side of the fixed block is fixedly connected with a lifting cylinder, and a feed pipe is connected between the lifting cylinder and the through port.

Furthermore, the inner wall of the lifting barrel is rotatably connected to a rotating shaft 1, and the outer wall of the rotating shaft 1 is fixedly connected to spiral auger blades, and a rotating motor is arranged at the top of the rotating shaft 1.

Furthermore, crushing boxes are provided on both sides of the feed hopper, and crushing mechanisms are provided inside the crushing boxes. A feeding pipe is connected between each crushing box and the corresponding lifting barrel.

Furthermore, the outer wall of the shell is connected to a dust suction pipe, and the inner wall of the dust suction pipe is fixedly connected to a dust suction fan, and one end of the dust suction pipe is sleeved with a dust removal bag.

The beneficial effects of the present invention are:

1. By setting a reset mechanism, a screening plate, a through-port, a second rotating shaft, a cam, a lifting plate and a top roller, the power source enables the second rotating shaft to drive multiple cams to rotate, so that the lifting plate and the top roller on its top can move up and down reciprocatingly, thereby cooperating with the reset mechanism to make the two screening plates vibrate continuously, so that the ore can be screened, and at the same time, the large pieces of ore above the screening plate can be discharged through the through-port, which is convenient for subsequent processing.

2. By setting up the lifting barrel, rotating shaft 1, spiral auger blades, rotating motor, crushing box and crushing mechanism, the large pieces of ore discharged from the opening enter the lifting barrel. The rotating motor drives the spiral auger blades to rotate through the rotating shaft 1 to transport them to the crushing box, so that the large pieces of ore are crushed by the crushing mechanism, so that the size of the ore can be qualified, which is convenient for subsequent crushing to be fully crushed and improve work efficiency.

3. By setting up a dust suction pipe, a dust suction fan and a dust removal bag, during screening, the dust generated during screening can be sucked into the dust removal bag through the dust suction fan in the dust suction pipe, and then discharged after being filtered by the dust removal bag, so as to avoid dust flying and endangering the health of workers and polluting the environment.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG1 is a schematic structural diagram of an ore screening device proposed in Example 1;

FIG2 is an enlarged schematic diagram of the structure at A in FIG1 of an ore screening device proposed in Example 1;

FIG3 is a schematic cross-sectional structure diagram of a crushing box of an ore screening device proposed in Example 1;

FIG. 4 is a schematic diagram of the side structure of an ore screening device proposed in Example 2. FIG.

In the figure: 1. Shell; 2. Guide plate; 3. Screening plate; 4. Through port; 5. Lifting barrel; 6. Fixed block; 7. Rotating motor; 8. Feeding pipe; 9. Crushing box; 10. Feed hopper; 11. Rotating shaft 1; 12. Auger blade; 13. Feeding pipe; 14. Discharging port; 15. Rotating shaft 2; 16. Lifting plate; 17. Top roller; 18. Sliding groove; 19. Inverted U-shaped plate; 20. Return spring; 21. Sealing plate; 22. Cam; 23. Crushing mechanism; 24. Dust bag; 25. Dust suction fan; 26. Dust suction pipe.

Implementation Example

Please refer to Figures 1 to 3, an ore screening device includes a shell 1, a feed hopper 10 is arranged on the top of the shell 1, and a rotating shaft 15 is rotatably connected inside the shell 1, and a power source is arranged at one end of the rotating shaft 15, three cams 22 are fixedly connected to the outer wall of the rotating shaft 15 at equal distances, and the outer walls of the three cams 22 are all in contact with the same lifting plate 16, the lifting plate 16 is slidably connected to the inside of the shell 1, and the outer walls on both sides of the top of the lifting plate 16 are fixedly connected to top rollers 17, and the outer walls of the top of the top rollers 17 are in contact with the screen The screening plates 3 are hinged at one end to the inner wall of one side of the shell 1, a through hole 4 is arranged on one side of the bottom end of the screening plates 3, and a reset mechanism is arranged on the top of the two screening plates 3. The power source drives the rotating shaft 15 to drive multiple cams 22 to rotate, so that the lifting plate 16 and the top roller 17 on its top can move back and forth up and down, so that the two screening plates 3 can be continuously vibrated by cooperating with the reset mechanism, so that the ore can be screened, and at the same time, the large pieces of ore above the screening plates 3 can be discharged through the through hole 4, so as to facilitate the subsequent processing thereof.

The reset mechanism includes an inverted U-shaped plate 19, which is fixedly connected to the inner wall of the shell 1, and the outer walls on both sides of the bottom of the inverted U-shaped plate 19 are provided with sliding grooves 18, and the inner walls of the sliding grooves 18 are slidably connected with sealing plates 21, and a plurality of reset springs 20 are fixedly connected between the sealing plate 21 and the inner wall at the top of the sliding groove 18, and the lower end of the sealing plate 21 contacts the outer wall at the top of the screening plate 3, and the cross-section of the lower end of the sealing plate 21 is semicircular. When the two top rollers 17 on the lifting plate 16 respectively press against one end of the screening plate 3 and swing upward, the screening plate 3 is The sealing plate 21 applies force to compress the multiple reset springs 20 and extend them into the slide groove 18. When the lifting plate 16 drives the two top rollers 17 to move downward, one end of the screening plate 3 is reset under the action of the rebound force of the multiple reset springs 20 and the common gravity of the screening plate 3 and the ore on its surface. This cycle is repeated to make the two screening plates 3 vibrate continuously. At the same time, by making the cross-section of the lower end of the sealing plate 21 semicircular, the space between the inverted U-shaped plate 19 and the screening plate 3 can be sealed to avoid ore leakage and incomplete screening.

Among them, a discharge port 14 is provided at the bottom of the shell 1, and guide plates 2 are fixedly connected between the outer walls on both sides of the top of the discharge port 14 and the inner walls on both sides of the shell 1. The screened qualified ore is discharged through the discharge port 14 under the action of the guide plate 2, so as to be processed later.

Among them, the outer walls on both sides of the shell 1 are fixedly connected with fixed blocks 6, and the outer wall on one side of the fixed block 6 is fixedly connected with a lifting barrel 5, and a feed pipe 13 is connected between the lifting barrel 5 and the through port 4. The unqualified large pieces of ore screened out by the screening plate 3 enter the lifting barrel 5 through the barrel port 4 and the feed pipe 13.

Among them, the inner wall of the lifting barrel 5 is rotatably connected to a rotating shaft 11, and the outer wall of the rotating shaft 11 is fixedly connected to a spiral auger blade 12. A rotating motor 7 is arranged on the top of the rotating shaft 11. At the same time, the rotating motor 7 drives the spiral auger blade 12 to rotate through the rotating shaft 11, so as to transport the large pieces of ore at the bottom of the lifting barrel 5 to the upper side.

Among them, crushing boxes 9 are arranged on both sides of the feed hopper 10, and crushing mechanisms 23 are arranged inside the crushing boxes 9. A discharge pipe 8 is connected between each crushing box 9 and the corresponding lifting tube 5, and then the ore enters the crushing box 9 through the discharge pipe 8 and is crushed by the crushing mechanism 23, so that the size of the ore can be qualified, so that it can be fully crushed during the subsequent crushing, thereby improving work efficiency.

Working principle: Pour the ore into the shell 1 through the feed hopper 10, the inverted U-shaped plate 19 can avoid ore residue, then the power source makes the rotating shaft 15 drive the multiple cams 22 to rotate, and the multiple cams 22 make the lifting plate 16 move up and down during the rotation. When the two top rollers 17 on the lifting plate 16 respectively swing upward against one end of the screening plate 3, the screening plate 3 applies force to the sealing plate 21 to compress the multiple reset springs 20 and extend into the sliding groove 18, and when the lifting plate 16 drives the two top rollers 17 to move downward, under the action of the rebound force of the multiple reset springs 20 and the common gravity of the screening plate 3 and the ore on its surface, one end of the screening plate 3 is reset, and this cycle is repeated, so that the two screening plates 3 are constantly vibrating, and at the same time, the sealing plate 21 is pressed against the sealing plate 21. The cross-section of the lower end of the plate 21 is semicircular, so that the space between the inverted U-shaped plate 19 and the screening plate 3 can be sealed to prevent ore leakage resulting in incomplete screening, so that the ore can be screened, and at the same time, the large pieces of ore above the screening plate 3 can be discharged through the opening 4, which is convenient for subsequent processing; the unqualified large pieces of ore screened out by the screening plate 3 enter the lifting barrel 5 through the barrel gate 4 and the feed pipe 13, and at the same time, the rotating motor 7 drives the spiral auger blade 12 to rotate through the rotating shaft 11 to transport the large pieces of ore at the bottom of the lifting barrel 5 to the top, and then enter the crushing box 9 through the discharge pipe 8, and be crushed by the crushing mechanism 23, so that the size of the ore can be qualified, which is convenient for it to be fully crushed in the subsequent crushing, thereby improving work efficiency.

Example

Please refer to Figure 4, an ore screening equipment, compared with Example 1, the outer wall of the shell 1 is connected to a dust suction pipe 26, and the inner wall of the dust suction pipe 26 is fixedly connected to a dust suction fan 25, and one end of the dust suction pipe 26 is provided with a dust removal bag 24, which can collect the dust generated during screening and discharge it after treatment, so as to avoid dust flying to endanger the health of workers and pollute the environment.

Working principle: During screening, the dust generated during screening can be sucked into the dust bag 24 through the dust suction fan 25 in the dust suction pipe 26, and then discharged after being filtered by the dust bag 24, so as to prevent the dust from flying and endangering the health of the workers and polluting the environment. After using it for a period of time, the dust bag 24 can be detached from the dust suction pipe 26, so as to facilitate the cleaning of the dust filtered out by the dust bag 24.

The above description is only a preferred specific implementation manner of the present invention, but the protection scope of the present invention is not limited thereto. Any technician familiar with the technical field can make equivalent replacements or changes according to the technical scheme and inventive concept of the present invention within the technical scope disclosed by the present invention, which should be covered by the protection scope of the present invention.

Claims (7)

An ore screening device comprises a shell (1), characterized in that a feed hopper (10) is arranged on the top of the shell (1), and a second rotating shaft (15) is rotatably connected inside the shell (1), and a power source is arranged at one end of the second rotating shaft (15), three cams (22) are fixedly connected to the outer wall of the second rotating shaft (15) at equal distances, and the outer walls of the three cams (22) are in contact with the same lifting plate (16), the lifting plate (16) is slidably connected to the inside of the shell (1), and top rollers (17) are fixedly connected to the outer walls on both sides of the top of the lifting plate (16), the top outer walls of the top rollers (17) are in contact with screening plates (3), and one end of the screening plates (3) is hinged to the inner wall of one side of the shell (1), a through hole (4) is arranged on one side of the bottom end of the screening plate (3), and a reset mechanism is arranged on the top of the two screening plates (3). The ore screening equipment according to claim 1 is characterized in that the reset mechanism comprises an inverted U-shaped plate (19), the inverted U-shaped plate (19) is fixedly connected to the inner wall of the shell (1), and the outer walls on both sides of the bottom of the inverted U-shaped plate (19) are provided with sliding grooves (18), the inner walls of the sliding grooves (18) are slidably connected with sealing plates (21), and a plurality of reset springs (20) are fixedly connected between the sealing plate (21) and the top inner wall of the sliding groove (18), the lower end of the sealing plate (21) is in contact with the top outer wall of the screening plate (3), and the cross-section of the lower end of the sealing plate (21) is semicircular. The ore screening equipment according to claim 1 is characterized in that a discharge port (14) is provided at the bottom of the shell (1), and guide plates (2) are fixedly connected between the outer walls on both sides of the top of the discharge port (14) and the inner walls on both sides of the shell (1). The ore screening equipment according to claim 3 is characterized in that the outer walls on both sides of the shell (1) are fixedly connected to fixed blocks (6), and the outer wall on one side of the fixed block (6) is fixedly connected to a lifting cylinder (5), and a feed pipe (13) is connected between the lifting cylinder (5) and the through port (4). The ore screening equipment according to claim 4 is characterized in that the inner wall of the lifting barrel (5) is rotatably connected to a rotating shaft (11), and the outer wall of the rotating shaft (11) is fixedly connected to a spiral auger blade (12), and a rotating motor (7) is provided at the top of the rotating shaft (11). The ore screening equipment according to claim 5 is characterized in that crushing boxes (9) are provided on both sides of the feed hopper (10), and crushing mechanisms (23) are provided inside the crushing boxes (9), and a feed pipe (8) is connected between each crushing box (9) and the corresponding lifting cylinder (5). The ore screening equipment according to claim 1 is characterized in that the outer wall of the shell (1) is connected to a dust suction pipe (26), and the inner wall of the dust suction pipe (26) is fixedly connected to a dust suction fan (25), and one end of the dust suction pipe (26) is sleeved with a dust removal bag (24).