CN221115482U - Improved mine ore conveying equipment - Google Patents

Abstract

The utility model discloses an improved mining ore conveying equipment, comprising two conveyor belts and a cleaning box, wherein the cleaning box is arranged between the two conveyor belts, and conveying rollers are evenly arranged on the inner side of the cleaning box, and threaded rods are movably installed on both sides of the top of the cleaning box, and a first connecting rod and a second connecting rod are respectively sleeved on the outer sides of the two threaded rods through threads, and the bottom ends of the first connecting rod and the second connecting rod are fixedly connected with shunt pipes, and nozzles are evenly installed on the bottom ends of the shunt pipes. When the ore passes through the cleaning box, the transportation work is completed by the conveying rollers inside the cleaning box, and there is a certain gap between the conveying rollers, so that the stones and granular impurities in the ore can fall into the bottom of the cleaning box and be removed, and at the same time, the two shunt pipes on the upper inner side of the cleaning box reciprocate back and forth, and the nozzles at the bottom ends of the shunt pipes spray water, so that the ore can be washed and the soil on the surface of the ore can be cleaned.

Description

An improved mine ore conveying equipment

Technical Field

The utility model relates to the technical field of ore conveying equipment, in particular to an improved mine ore conveying equipment.

Background technique

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.

Conveyors are used to transport goods. According to their uses, they can be divided into bulk material conveying machinery and logistics conveying machinery. Most of the ore conveying machinery in mines uses belt conveyors. Belt conveyors are the most important bulk material conveying and loading and unloading equipment. They can be widely used in industrial fields such as mining, metallurgy, building materials, chemicals, electricity and food processing. After the ore is mined, it needs to be transported to the next station for processing by conveyors. After the ore is mined, a large amount of soil will adhere to the surface of the ore, and it will also be mixed with some small gravel. If it is not cleaned up, it will affect the efficiency of the next step of processing;

Therefore, those skilled in the art provide an improved mine ore conveying equipment to solve the problems raised in the above background technology.

Utility Model Content

The utility model aims to solve the shortcomings in the prior art and proposes an improved mine ore conveying equipment.

In order to achieve the above purpose, the utility model adopts the following technical solutions:

An improved mining ore conveying equipment comprises two conveyor belts and a cleaning box, wherein the cleaning box is arranged between the two conveyor belts, and conveyor rollers are evenly arranged on the inner side of the cleaning box, and threaded rods are movably installed on both sides of the top of the cleaning box, and a first connecting rod and a second connecting rod are respectively sleeved on the outer sides of the two threaded rods by threads, and the bottom ends of the first connecting rod and the second connecting rod are fixedly connected to a shunt pipe, and nozzles are evenly installed on the bottom ends of the shunt pipes, and a support block is fixedly connected to the top of the cleaning box, and one end of one of the threaded rods is fixedly connected to a first transmission gear, and the other end is installed with a driving motor, and a first transmission gear is rotatably installed on the side of the support block, and the two first transmission gears are connected by a first toothed belt transmission, and one end of the other threaded rod and the end of the first transmission gear on the support block are fixedly connected to a first driving gear, and the two first driving gears are meshed with each other.

Preferably, strip holes are provided on both sides of the top of the cleaning box, and the tops of the first connecting rod and the second connecting rod respectively pass through the two strip holes and are threadedly sleeved with the two threaded rods.

Preferably, the two diversion pipes are connected to a water receiving hose at one end away from each other, guide holes are provided on both sides of the cleaning box, and the two water receiving hoses respectively penetrate the two guide holes and extend to the outside.

Preferably, a plurality of movable plates are rotatably mounted inside the cleaning box, a first brush is mounted on the bottom end of the movable plate, and a return spring is mounted between the edge of the movable plate and the inner wall of the cleaning box.

Preferably, movable rollers are evenly installed on the inner side of the cleaning box below the transmission roller, a plurality of fixing bars distributed in a circular array are installed on the outer side of the movable roller, and second bristles are installed on the side of the fixing bars.

Preferably, one end of each of the transmission roller shafts is fixedly connected to a second transmission gear, and the second transmission gears are connected via a second toothed belt transmission; one end of each of the movable roller shafts is fixedly connected to a third transmission gear, and the third transmission gears are connected via a third toothed belt transmission.

Preferably, one of the second transmission gear ends is fixedly connected to a second drive gear, one of the third transmission gear ends is fixedly connected to a third drive gear, the second drive gear is meshed with the third drive gear, and the diameter of the second drive gear is smaller than the diameter of the third drive gear, and a driving device is installed at the other end of one of the transmission rollers.

Compared with the prior art, the beneficial effects of the utility model are:

The technical solution adopted by the utility model is to set a cleaning box between two conveyor belts. When the ore passes through the cleaning box, the transportation work is completed by the conveying rollers inside the cleaning box. There is a certain gap between the conveying rollers, which is convenient for the stones and granular impurities in the ore to fall into the bottom of the cleaning box and be removed. At the same time, the two shunt pipes on the upper inner side of the cleaning box reciprocate back and forth, and the nozzles at the bottom of the shunt pipes spray water, so that the ore can be washed and the soil on the surface of the ore is cleaned, so as to facilitate the next large processing of the ore. In addition, a corresponding movable roller is arranged at the bottom of the conveying roller, and a second brush is installed on the movable roller, and the rotation direction of the movable roller is opposite to that of the conveying roller. Therefore, when the conveying roller is working, the soil adhering to the conveying roller can be cleaned by the action of the movable roller and the second brush, so as to prevent excessive soil from affecting the use of the conveying roller.

BRIEF DESCRIPTION OF THE DRAWINGS

In order to more specifically and intuitively illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings required for use in the embodiments or the description of the prior art are briefly introduced below.

FIG1 is a schematic diagram of the structure of the utility model;

FIG2 is a schematic diagram of the transmission roller installation structure proposed by the utility model;

FIG3 is a schematic diagram of the installation structure of the shunt pipe proposed in the utility model;

FIG4 is a schematic diagram of the movable roller installation structure proposed by the utility model;

FIG5 is an enlarged structural diagram of point A in FIG1 proposed by the present invention;

FIG6 is an enlarged structural diagram of point B in FIG2 proposed by the present invention;

FIG. 7 is an enlarged structural schematic diagram of point C in FIG. 1 proposed by the present invention.

In the figure: 1. conveyor belt; 2. cleaning box; 3. conveyor roller; 4. threaded rod; 5. first connecting rod; 6. second connecting rod; 7. shunt pipe; 8. nozzle; 9. support block; 10. first transmission gear; 11. first toothed belt; 12. first drive gear; 13. strip hole; 14. water receiving hose; 15. guide hole; 16. movable plate; 17. first bristle; 18. return spring; 19. movable roller; 20. fixed strip; 21. second bristle; 22. second transmission gear; 23. second toothed belt; 24. third transmission gear; 25. third toothed belt; 26. second drive gear; 27. third drive gear; 28. drive motor.

Detailed ways

The technical solutions in the embodiments of the present invention will be described clearly and completely below in conjunction with the drawings in the embodiments of the present invention. Obviously, the described embodiments are only part of the embodiments of the present invention, rather than all of the embodiments.

Referring to Figures 1-7, an improved mining ore conveying equipment comprises two conveyor belts 1 and a cleaning box 2, the cleaning box 2 is arranged between the two conveyor belts 1, and conveying rollers 3 are evenly arranged on the inner side of the cleaning box 2. Threaded rods 4 are movably installed on both sides of the top of the cleaning box 2, and the outer sides of the two threaded rods 4 are respectively sleeved with a first connecting rod 5 and a second connecting rod 6 by threads, and the bottom ends of the first connecting rod 5 and the second connecting rod 6 are fixedly connected to a shunt pipe 7, and a nozzle 8 is evenly installed at the bottom end of the shunt pipe 7. A support block 9 is fixedly connected to the top of the cleaning box 2, one end of one of the threaded rods 4 is fixedly connected to a first transmission gear 10, and the other end is installed with a driving motor 28, and the first transmission gear 10 is rotatably installed on the side of the support block 9, and the two first transmission gears 10 are connected by a first toothed belt 11 for transmission, and the first drive gear 12 is fixedly connected to one end of the other threaded rod 4 and the end of the first transmission gear 10 on the support block 9, and the two first drive gears 12 are meshed with each other;

In the technical solution adopted above, the two shunt pipes 7 are in an up-and-down position, and the two shunt pipes 7 have a certain displacement difference in the horizontal position, so that when the two shunt pipes 7 move relative to each other, there will be no motion interference, and they will not be blocked by the first connecting rod 5 or the second connecting rod 6. One end of the shunt pipe 7 is in a blocked state, so that the water flow therein can only be sprayed out from the nozzle 8. By starting the driving motor 28 to drive one of the threaded rods 4 to rotate, the threaded rod 4 will drive the first transmission gear 10 on the support block 9 to rotate through the action of the first transmission gear 10 and the first toothed belt 11. Since the first transmission gear 10 on the support block 9 is coaxially fixed to the first driving gear 12 thereon, it drives The first driving gear 12 rotates, and at the same time, the first driving gear 12 is meshed with the first driving gear 12 fixedly connected to the end of the other threaded rod 4, thereby driving the other threaded rod 4 to rotate in the opposite direction, so that the two threaded rods 4 rotate in opposite directions. The rotation of the threaded rod 4 will drive the first connecting rod 5 or the second connecting rod 6 to move linearly along the thread direction. Since the two threaded rods 4 rotate in opposite directions, the two shunt pipes 7 move in opposite directions. By driving the motor 28 forward and reverse, the two shunt pipes 7 are driven to cross and reciprocate linearly, so that the nozzle 8 on the shunt pipe 7 sprays water to fully flush the ore. An opening is provided at the bottom of the cleaning box 2 to facilitate the outflow of impurities flushed accordingly.

Both sides of the top of the cleaning box 2 are provided with strip holes 13, and the tops of the first connecting rod 5 and the second connecting rod 6 respectively pass through the two strip holes 13 and are threadedly sleeved with the two threaded rods 4;

In the technical solution adopted above, the arrangement of the strip hole 13 facilitates the first connecting rod 5 and the second connecting rod 6 to pass through the top of the cleaning box 2 and connect with the corresponding threaded rod 4. At the same time, the strip hole 13 limits the movement direction and range of the first connecting rod 5 and the second connecting rod 6.

The two diversion pipes 7 are connected to a water receiving hose 14 at one end away from each other. Guide holes 15 are provided on both sides of the cleaning box 2, and the two water receiving hoses 14 respectively penetrate the two guide holes 15 and extend to the outside.

In the technical solution adopted above, the water receiving hose 14 is used to connect to the external water supply equipment to supply water to the corresponding diversion pipe 7 and the nozzle 8, and the setting of the guide hole 15 facilitates the movement of the water receiving hose 14 with the diversion pipe 7.

A plurality of movable plates 16 are rotatably mounted inside the cleaning box 2, a first brush 17 is mounted at the bottom end of the movable plate 16, and a return spring 18 is mounted between the edge of the movable plate 16 and the inner wall of the cleaning box 2;

The technical solution adopted above, through the first bristles 17, when the ore passes through the cleaning box 2, it contacts the first bristles 17, which can assist in cleaning the dirt on the surface of the ore. If the ore is too large, it will squeeze the first bristles 17 and the movable plate 16, causing the compression return spring 18 to rotate, thereby not affecting the transportation of the ore.

Active rollers 19 are evenly installed on the inner side of the cleaning box 2 below the transmission roller 3, and multiple fixed strips 20 distributed in a ring array are installed on the outer side of the active roller 19, and second bristles 21 are installed on the side of the fixed strips 20;

The technical solution adopted above can clean the dirt adhered to the surface of the conveying roller 3 when it rotates through the second bristles 21 on the movable roller 19, so as to prevent the dirt from adhering too much and affecting its use, thereby affecting the transportation of ore or its service life.

One end of the shaft of the plurality of transmission rollers 3 is fixedly connected with a second transmission gear 22, and the plurality of second transmission gears 22 are connected to each other through a second toothed belt 23; one end of the shaft of the plurality of movable rollers 19 is fixedly connected with a third transmission gear 24, and the plurality of third transmission gears 24 are connected to each other through a third toothed belt 25;

In the technical solution adopted above, the second toothed belt 23 and the second transmission gear 22 can drive multiple transmission rollers 3 together, so that when one of the transmission rollers 3 is driven to rotate, the other transmission rollers 3 can also rotate. Similarly, the function of the third transmission gear 24 and the third toothed belt 25 is that when one of the movable rollers 19 rotates, the other movable rollers 19 can be driven to rotate together.

A second drive gear 26 is fixedly connected to one end of the second transmission gear 22, a third drive gear 27 is fixedly connected to one end of the third transmission gear 24, the second drive gear 26 meshes with the third drive gear 27, and the diameter of the second drive gear 26 is smaller than that of the third drive gear 27, and a driving device is installed at the other end of one of the transmission rollers 3;

In the technical solution adopted above, a motor device is installed at the other end of one end of the transmission roller 3 to drive it to rotate. At the same time, the shaft at one end of the transmission roller 3 is meshed with the third drive gear 27 on the shaft of one of the movable rollers 19 through the second drive gear 26, so that the rotation of the transmission roller 3 will drive the movable roller 19 to rotate. At the same time, the diameter of the second drive gear 26 is smaller than the diameter of the third drive gear 27. Therefore, the rotation speed of the movable roller 19 is slower than that of the transmission roller 3. When the transmission roller 3 is working, the second brush 21 is driven to rotate in the direction of the movable roller 19 below it, so as to better clean the dirt and impurities on the transmission roller 3.

working principle:

The ore is transported by two conveyor belts 1. During the transportation process, the ore passes through the cleaning box 2 between the two conveyor belts 1. When entering the cleaning box 2, the ore is transported from the conveyor belt 1 to the conveyor roller 3. The ore is transported by the rotation of the conveyor roller 3. Since there is a gap between the conveyor rollers 3, smaller impurities such as stones will fall into the bottom of the cleaning box 2 and be removed. When the ore is transported on the conveyor roller 3, the drive motor 28 is started to drive one of the threaded rods 4 to rotate, and at the same time, the transmission effect of the first transmission gear 10, the first toothed belt 11 and the first driving gear 12 and other structures will drive the other threaded rod 4 to reverse at the same speed. The rotation of the two threaded rods 4 will drive the first connecting rod 5 and the second connecting rod 6 to move toward or away from each other, thereby driving the two diversion pipes 7 to rotate. The two shunt pipes 7 can move forward or backward by driving the motor 28 in a large forward and reverse rotation, so that the two shunt pipes 7 can cross and reciprocate in a straight line. The nozzle 8 at the bottom of the shunt pipe 7 will rinse the ore, and cooperate with the first brush 17 to fully clean the soil on the surface of the ore, which is convenient for subsequent processing. At the same time, when the transmission roller 3 rotates, the movable roller 19 at its bottom will rotate in the opposite direction. The movable roller 19 is located directly below the transmission roller 3, and the second brush 21 on the movable roller 19 can contact the transmission roller 3. The number ratio of the movable roller 19 corresponds to that of the transmission roller 3. When the movable roller 19 rotates, the second brush 21 will clean the soil impurities adhered to the surface of the transmission roller 3, thereby extending its service life. In addition, corresponding scrapers can be set at both ends of the inner side of the cleaning box 2, and one end of the scraper is attached to the conveyor belt 1 to clean impurities on the surface of the conveyor belt 1.

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 substitutions or changes within the technical scope disclosed by the present invention according to the technical scheme and the utility model concept of the present invention, which should be covered by the protection scope of the present invention.

Claims (7)

1. The utility model provides an improved generation mine ore conveying equipment, includes two conveyer belts (1) and clearance case (2), its characterized in that, clearance case (2) set up between two conveyer belts (1), clearance case (2) inboard evenly is provided with transmission roller (3), the equal movable mounting in clearance case (2) top both sides has threaded rod (4), two the threaded rod (4) outside is equipped with head rod (5) and second connecting rod (6) through the screw thread respectively, head rod (5) and second connecting rod (6) bottom all rigid coupling have shunt tubes (7), shower nozzle (8) are evenly installed to shunt tubes (7) bottom, clearance case (2) top rigid coupling has supporting shoe (9), one of them threaded rod (4) one end rigid coupling has first drive gear (10), and driving motor (28) are installed to the other end, and first drive gear (10) are installed in rotation of supporting shoe (9) side, and connect through first toothed bar (11) transmission between two first drive gear (10) drive rod (4) one end and supporting shoe (9) and first drive gear (12) are all engaged with mutually.

2. An improved mine ore conveying device according to claim 1, characterized in that strip-shaped holes (13) are formed in two sides of the top end of the cleaning box (2), and the top ends of the first connecting rod (5) and the second connecting rod (6) respectively penetrate through the two strip-shaped holes (13) to be in threaded sleeve connection with the two threaded rods (4).

3. An improved mine ore conveying apparatus as claimed in claim 1, wherein two shunt tubes (7) are connected with water receiving hoses (14) at their ends far away from each other, guide holes (15) are formed in both sides of the cleaning box (2), and the two water receiving hoses (14) extend to the outside through the two guide holes (15) respectively.

4. An improved mine ore conveying apparatus as claimed in claim 1, wherein a plurality of movable plates (16) are rotatably mounted on the inner side of the cleaning box (2), first bristles (17) are mounted on the bottom ends of the movable plates (16), and a return spring (18) is mounted between the edge portions of the movable plates (16) and the inner wall of the cleaning box (2).

5. An improved mine ore conveying apparatus as claimed in claim 1, wherein movable rollers (19) are uniformly arranged below the conveying rollers (3) on the inner side of the cleaning box (2), a plurality of fixing strips (20) distributed in a ring-shaped array are arranged on the outer side of the movable rollers (19), and second bristles (21) are arranged on the side surfaces of the fixing strips (20).

6. An improved mine ore conveying apparatus according to claim 5, wherein a plurality of transmission rollers (3) are fixedly connected with a second transmission gear (22) at one ends of the shaft rods, the second transmission gears (22) are in transmission connection through a second toothed belt (23), a plurality of movable rollers (19) are fixedly connected with a third transmission gear (24) at one ends of the shaft rods, and the third transmission gears (24) are in transmission connection through a third toothed belt (25).

7. An improved mine ore conveying apparatus as claimed in claim 6, wherein a second drive gear (26) is fixedly connected to an end of one of the second transmission gears (22), a third drive gear (27) is fixedly connected to an end of one of the third transmission gears (24), the second drive gear (26) is meshed with the third drive gear (27), and the diameter of the second drive gear (26) is smaller than that of the third drive gear (27), and a driving device is mounted at the other end of one of the transmission rollers (3).