A thickener distributor

By designing a multi-tube material distribution device and a motor drive system, the problems of low construction efficiency and inconvenient cleaning of traditional thickener material distribution machines have been solved, achieving uniform material distribution and efficient cleaning of slurry.

CN117861280BActive Publication Date: 2026-07-14HUAIBEI MINE MASCH MFG CO LTD

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Patents(China)
Current Assignee / Owner
HUAIBEI MINE MASCH MFG CO LTD
Filing Date
2024-01-23
Publication Date
2026-07-14

AI Technical Summary

Technical Problem

Traditional thickener cloth feeders typically have only one cloth feeder head, resulting in low construction efficiency, non-adjustable cloth width, and a fixed structure that makes cleaning difficult.

Method used

A multi-tube feeding device was designed, including a feeding cylinder, a defoaming cylinder, and a conveying cylinder. The device enables simultaneous feeding of multiple tubes through gear transmission and motor drive. It is equipped with a stirring device and an ultrasonic transmitter to promote uniform feeding and defoaming of the slurry. The motor drives the rotating cylinder for cleaning, and the device allows for adjustment of the multi-tube feeding head and width.

Benefits of technology

It achieves uniform distribution of slurry, improves construction efficiency, enhances cleaning convenience, and avoids air bubbles affecting the settling effect.

✦ Generated by Eureka AI based on patent content.

Smart Images

  • Figure CN117861280B_ABST
    Figure CN117861280B_ABST
Patent Text Reader

Abstract

The application discloses a thickener distributing device and relates to the technical field of thickeners, which comprises a thickening tank, a bridge frame fixedly connected to the top of the thickening tank, a feeding cylinder sleeved in the bridge frame, the feeding cylinder being rotationally connected with the bridge frame, a feeding pipe sleeved in the feeding cylinder, the feeding pipe being rotationally connected with the feeding cylinder, a gear sleeved on the feeding cylinder, the gear being fixedly connected with the feeding cylinder, a gear box sleeved on the gear, the gear box being fixedly connected with the bridge frame, a first motor mounted on the gear box and transmissionally connected with the gear through the gear box and the like. When the thickening tank needs to be distributed, the ore pulp in the feeding cylinder flows into other feeding cylinders through a second connecting cylinder body until the ore pulp in the feeding cylinder overflows the water outlet pipe. Since the ore pulp flows into all the feeding cylinders first and then overflows, the situation that some feeding cylinders have a large amount of ore pulp and some feeding cylinders have a small amount of ore pulp does not occur during the distribution.
Need to check novelty before this filing date? Find Prior Art

Description

Technical Field

[0001] This invention relates to the field of thickener technology, and more particularly to a thickener fabric feeding device. Background Technology

[0002] A thickener is a device used for solid-liquid separation, typically used to separate solid particles or suspensions from a liquid. It mainly consists of two parts: a circular thickener for solid-liquid separation and a rake scraper for scraping the sludge deposited at the bottom of the thickener to the central discharge port. Thickeners are widely used in mining, mineral processing, environmental protection, and chemical industries, and can be used to process various types of suspensions and solid particles.

[0003] The working principle of a thickener is based on gravity settling. In the thickener, solid particles suspended in the slurry settle under the influence of gravity, while the liquid rises to form a clarified liquid. The sludge deposited at the bottom of the thickener is continuously scraped by a rake scraper to the central discharge port at the bottom of the tank, while the clarified liquid overflows from the top edge of the thickener.

[0004] In mining, thickeners are often needed to separate the solids and liquids of the slurry produced during mining. However, traditional concrete placing booms usually only have one placing head, resulting in low construction efficiency and limited practicality as the width of the placing boom cannot be adjusted.

[0005] The purpose of this invention is to solve the problems of traditional cloth laying machines, which typically have only one cloth head, resulting in low construction efficiency, inability to adjust the width of the cloth, and difficulty in cleaning due to their fixed structure. Summary of the Invention

[0006] To address the problems of traditional concrete placing booms, which typically have only one placing head, resulting in low construction efficiency, non-adjustable fabric width, and a fixed structure that hinders cleaning, this invention adopts the following technical solution:

[0007] A thickener feeding device includes a thickening tank, a bridge frame fixedly connected to the top of the thickening tank, a feeding cylinder sleeved inside the bridge frame and rotatably connected to the bridge frame, a feeding pipe sleeved inside the feeding cylinder and rotatably connected to the feeding cylinder, a gear sleeved outside the feeding cylinder and fixedly connected to the feeding cylinder, a gearbox sleeved outside the gear and fixedly connected to the gearbox, a first motor mounted on the gearbox and connected to the gear transmission via the gearbox, a defoaming cylinder fixedly connected to the bottom of the feeding cylinder, a long rake fixedly connected to the bottom of the defoaming cylinder, a water pump installed inside the defoaming cylinder, a three-way pipe installed at the outlet of the water pump, rotating cylinders mounted on both sides of the defoaming cylinder and rotatably connected to the defoaming cylinder, and each rotating cylinder including a first cylinder body, a first connecting cylinder body, and a first flange, a first connecting cylinder body fixedly connected to one end of the first cylinder body, and a first flange fixedly connected to the other end of the first cylinder body.

[0008] L-shaped blocks are fixedly connected to both sides of the defoaming cylinder. A second motor is installed on the bottom surface of the L-shaped blocks. A chain is fitted over the rotor of the second motor. The chain is fitted over the first cylinder body. The second motor is connected to the first cylinder body via the chain. A feeding cylinder is installed at one end of the rotating cylinder. The feeding cylinder includes a second cylinder body. A second flange is fixedly connected to both ends of the second cylinder body. A second connecting cylinder body is fixedly connected to both ends of the second cylinder body. Several water outlet pipes are fixedly connected to one side of the second cylinder body. The inner wall of the water outlet pipes is tangent to the inner wall of the second cylinder body. The feeding cylinder and another feeding cylinder can be connected by connecting the second flange to another second flange. The feeding cylinder and another feeding cylinder can be connected internally by connecting the second connecting cylinder body to another second connecting cylinder body.

[0009] Preferably, a stirring device is installed at one end of the feed pipe. The stirring device includes a rod body, a connecting rod, and a stirring rod. A plurality of connecting rods are fixedly connected to the top end of the rod body. One end of the connecting rod is fixedly connected to the inner wall of the feed pipe. The bottom end of the connecting rod is disposed inside the defoaming cylinder. A plurality of stirring rods are fixedly connected to the bottom end of the rod body.

[0010] Preferably, the defoaming cylinder has supports fixedly connected to both sides inside, and an ultrasonic transmitter is installed on the top surface of the supports.

[0011] Preferably, one side of the L-shaped block has a plurality of first threaded holes, and a plurality of pull ropes are installed on one side of the L-shaped block. Each pull rope includes a steel cable, a first connector, and a second connector. One end of the steel cable is fixedly connected to the first connector, and the other end of the steel cable is fixedly connected to the second connector. The second connector is threadedly connected to the first threaded holes. A retaining ring is provided on the outer sleeve of the second cylinder, and the retaining ring is fixedly connected to the second cylinder. A collar is provided on the outer sleeve of the retaining ring, and the collar is rotatably connected to the retaining ring. The collar has a second threaded hole, and the first connector is threadedly connected to the second threaded hole.

[0012] Preferably, both sides of the defoaming cylinder are fixedly connected with first reinforcing ribs, and the first reinforcing ribs are fixedly connected to the bottom of the L-shaped block.

[0013] Preferably, the bottom of the L-shaped block is fixedly connected with a second reinforcing rib.

[0014] Preferably, a plurality of support frames are fixedly connected to both sides of the feed pipe, and one end of the support frame is fixedly connected to the bridge frame.

[0015] Preferably, a plug is fitted inside the second connecting cylinder, and the plug is threadedly connected to the second connecting cylinder.

[0016] Preferably, a rubber pad is installed at one end of the second connecting cylinder.

[0017] Compared with the prior art, the beneficial effects of the present invention are:

[0018] 1. In this invention, when it is necessary to distribute material in the thickening tank, the slurry entering the conveying cylinder flows into other conveying cylinders through the second connecting cylinder until the slurry in the conveying cylinder overflows the water outlet pipe. Since the slurry flows to all the conveying cylinders first and then overflows, there will be no situation where some conveying cylinders distribute a large amount of material while others distribute a small amount, thus achieving uniform distribution of the slurry. The conveying cylinder can distribute material in the thickening tank once the defoaming cylinder rotates once. Moreover, the simultaneous distribution of material through multiple pipes is more efficient than the traditional material distribution machine which usually only has one material distribution head. The conveying cylinders can be connected to each other, so the width of the material distribution can be adjusted according to the width of the thickening tank, making it highly practical.

[0019] 2. In this invention, when it is necessary to clean the defoaming cylinder, rotating cylinder, and conveying cylinder, the second motor is started. The second motor drives the rotating cylinder to rotate via a chain, and the rotating cylinder drives the conveying cylinder to rotate. After the water outlet pipe rotates, the slurry in the conveying cylinder will be discharged through the water outlet pipe and clean water will be delivered into the feed pipe. The clean water will rinse the feed cylinder. The water pump is started to pump the clean water into the rotating cylinder and the conveying cylinder, thereby cleaning the rotating cylinder and the conveying cylinder. The operation is simple and convenient. Moreover, the conveying cylinder is disassembled, which makes it easier to clean and perform deep cleaning.

[0020] 3. In this invention, the defoaming cylinder rotates, causing the slurry inside to rotate as well. During this rotation, the slurry is resisted by the stirring rod, creating turbulence. This turbulent motion increases shear force and mixing within the slurry, promoting the bursting of air bubbles. The ultrasonic transmitter emits ultrasonic waves into the slurry, and the vibrational energy of these waves breaks up the air bubbles. This prevents air bubbles from affecting the settling effect of the slurry in the thickening tank.

[0021] In summary, this invention solves the problems of traditional cloth placing machines, which typically have only one cloth placing head, resulting in low construction efficiency, inability to adjust the cloth width, and inconvenience in cleaning due to their fixed structure. Attached Figure Description

[0022] The accompanying drawings, which are included to provide a further understanding of the invention and form part of this application, illustrate exemplary embodiments of the invention and, together with their description, serve to explain the invention and do not constitute an undue limitation thereof. In the drawings:

[0023] Figure 1 This is a schematic diagram of the structure of a thickening machine fabric distribution device according to the present invention;

[0024] Figure 2 This is a schematic diagram of the structure of a thickener feeding device of the present invention without a thickener tank;

[0025] Figure 3 This is a partial structural schematic diagram of a dense fabric feeding device according to the present invention;

[0026] Figure 4 This is a schematic diagram of the internal structure of the defoaming cylinder of a thickening machine fabric device according to the present invention;

[0027] Figure 5 This is a schematic diagram of the structure of an L-shaped block in a thickening machine fabric distribution device according to the present invention;

[0028] Figure 6 This is a schematic diagram of the structure of the L-shaped block of the thickening machine fabric distribution device of the present invention after being connected to the second motor;

[0029] Figure 7 This is a schematic diagram of the mixing device of a thickener fabric distribution apparatus according to the present invention;

[0030] Figure 8 This is a schematic diagram of the structure of the thickening machine fabric feeding device of the present invention after the second motor is connected to the rotating cylinder;

[0031] Figure 9 This is a schematic diagram of the material feeding cylinder of a thickener fabric distribution device according to the present invention;

[0032] Figure 10This is a schematic diagram of the material feeding cylinder of a thickener fabric feeding device according to the present invention from another angle;

[0033] Figure 11 This is a schematic diagram of the structure of the draw rope of a dense fabric fabric device according to the present invention.

[0034] In the diagram, the components are numbered as follows: 1. Thickening tank; 2. Cable tray; 3. First motor; 4. Gearbox; 5. Defoaming cylinder; 6. Support frame; 7. Feed pipe; 8. Long rake; 9. Feed cylinder; 10. Gear; 11. L-shaped block; 12. Rotating cylinder; 1201. First cylinder body; 1202. First connecting cylinder body; 1203. First flange; 13. Conveying cylinder; 1301. Second cylinder body; 1302. Water outlet pipe; 1303. Second connecting cylinder body; 1304. Second flange; 1305. Snap ring; 1306. 1307. Collar; 1308. Second threaded hole; 1309. Plug; 14. Rubber pad; 15. Pull rope; 16. Steel cable; 17. First connector; 18. Second connector; 19. Stirring device; 10. Rod; 11. Connecting rod; 12. Stirring rod; 13. Second motor; 14. Water pump; 15. Ultrasonic transmitter; 16. Support; 27. T-pipe; 28. First reinforcing rib; 29. ​​First threaded hole; 20. Second reinforcing rib; 21. Chain. Detailed Implementation

[0035] The technical solutions of the present invention will be clearly and completely described below with reference to the accompanying drawings of the embodiments of the present invention. Obviously, the described embodiments are only some embodiments of the present invention, and not all embodiments.

[0036] Example 1: This example provides a thickener fabric feeding device, see [link to example]. Figure 1-11The system includes a thickening tank 1, with a bridge frame 2 fixedly connected to the top of the thickening tank 1. A feed cylinder 9 is fitted inside the bridge frame 2 and is rotatably connected to the bridge frame 2. A feed pipe 7 is fitted inside the feed cylinder 9 and is rotatably connected to the feed cylinder 9. Several support frames 6 are fixedly connected to both sides of the feed pipe 7, with one end of each support frame 6 fixedly connected to the bridge frame 2. A gear 10 is fitted outside the feed cylinder 9 and is fixedly connected to the feed cylinder 9. A gearbox 4 is fitted outside the gear 10 and is fixedly connected to the bridge frame 2. A first motor 3 is installed in the gearbox 4 and is connected to the bridge frame 2 via the gearbox 4. The gear 10 is connected to the transmission. The bottom end of the feed cylinder 9 is fixedly connected to the defoaming cylinder 5. The bottom end of the defoaming cylinder 5 is fixedly connected to the long rake 8. The defoaming cylinder 5 is equipped with a water pump 17. The outlet of the water pump 17 is equipped with a three-way pipe 20. Rotating cylinders 12 are installed on both sides of the defoaming cylinder 5. The rotating cylinder 12 is rotatably connected to the defoaming cylinder 5. The rotating cylinder 12 includes a first cylinder body 1201, a first connecting cylinder body 1202 and a first flange 1203. One end of the first cylinder body 1201 is fixedly connected to the first connecting cylinder body 1202 and the other end of the first cylinder body 1201 is fixedly connected to the first flange 1203.

[0037] L-shaped blocks 11 are fixedly connected to both sides of the defoaming cylinder 5. A second reinforcing rib 23 is fixedly connected to the bottom of the L-shaped blocks 11. First reinforcing ribs 21 are fixedly connected to both sides of the defoaming cylinder 5, and the first reinforcing ribs 21 are fixedly connected to the bottom of the L-shaped blocks 11. A second motor 16 is mounted on the bottom surface of the L-shaped blocks 11. A chain 24 is sleeved around the rotor of the second motor 16. The chain 24 is sleeved around the first cylinder body 1201. The second motor 16 is connected to the first cylinder body 1201 via the chain 24. A conveying cylinder 13 is installed at one end of the rotating cylinder 12. The conveying cylinder 13 includes a second cylinder body 1301. Second flanges 1304 are fixedly connected to both ends of the second cylinder body 1301. A second connecting cylinder 1303 is fixedly connected. A rubber gasket 1309 is installed at one end of the second connecting cylinder 1303. A plug 1308 is fitted inside the second connecting cylinder 1303 and is threadedly connected to the second connecting cylinder 1303. Several water outlet pipes 1302 are fixedly connected to one side of the second cylinder 1301. The inner wall of the water outlet pipe 1302 is tangent to the inner wall of the second cylinder 1301. The conveying cylinder 13 and another conveying cylinder 13 can be connected by connecting the second flange 1304 to another second flange 1304. The conveying cylinder 13 and another conveying cylinder 13 can achieve internal cavity communication by connecting the second connecting cylinder 1303 to another second connecting cylinder 1303.

[0038] In the specific implementation process, such as Figures 1 to 11As shown, during use, the solid particles suspended in the slurry in the thickening tank 1 settle under the action of gravity, while the upper part becomes clear water, thus separating the solid and liquid. The first motor 3 drives the feed cylinder 9 to rotate through the gearbox 4 and gear 10. The feed cylinder 9 drives the long rake 8 to rotate through the defoaming cylinder 5. The long rake 8 scrapes the sludge deposited at the bottom of the thickening tank 1 to the center of the bottom of the tank and then discharges it through the discharge port, while the clear water overflows from the upper edge of the thickening tank 1.

[0039] When it is necessary to distribute the material in the thickening tank 1, the slurry is conveyed into the feed cylinder 9 through the feed pipe 7. The slurry further enters the defoaming cylinder 5 through the feed cylinder 9. The water pump 17 in the defoaming cylinder 5 pumps the slurry into the rotating cylinder 12. The slurry in the rotating cylinder 12 enters the conveying cylinder 13 through the first connecting cylinder 1202 and the second connecting cylinder 1303. The slurry entering the conveying cylinder 13 flows into other conveying cylinders 13 through the second connecting cylinder 1303 until the slurry in the conveying cylinder 13 overflows from the water outlet pipe 1302. Since the slurry flows to all the conveying cylinders 13 first and then overflows, during the material distribution, there will be no situation where some conveying cylinders 13 distribute a large amount of material while others distribute a small amount, thus achieving uniform material distribution of the slurry. The defoaming cylinder 5 can distribute the material in the thickening tank 1 in one revolution of the conveying cylinder 13. Moreover, the simultaneous material distribution of multiple pipes is more efficient than the traditional material distribution machine, which usually only has one material distribution head. The conveying cylinders 13 can be connected to each other, so the width of the material distribution can be adjusted according to the width of the thickening tank 1, making it highly practical.

[0040] When cleaning is required for the defoaming cylinder 5, rotating cylinder 12, and conveying cylinder 13, the second motor 16 is started. The second motor 16 drives the rotating cylinder 12 to rotate via the chain 24. The rotating cylinder 12 drives the conveying cylinder 13 to rotate. After the water outlet pipe 1302 rotates 180 degrees, the slurry in the conveying cylinder 13 will be discharged through the water outlet pipe 1302 and clean water will be delivered into the feed pipe 7. The clean water will flush the feed cylinder 9. The water pump 17 is started to pump the clean water into the rotating cylinder 12 and the conveying cylinder 13, thereby cleaning the rotating cylinder 12 and the conveying cylinder 13. The operation is simple and convenient. Moreover, the conveying cylinder 13 is disassembled, which makes it easier to clean and perform deep cleaning.

[0041] Example 2: In Example 1, there was a problem that air bubbles in the slurry could easily affect the settling effect of the slurry in thickening tank 1. Therefore, based on Example 1, this example also includes:

[0042] A stirring device 15 is installed at one end of the feed pipe 7. The stirring device 15 includes a rod body 1501, a connecting rod 1502 and a stirring rod 1503. A plurality of connecting rods 1502 are fixedly connected to the top end of the rod body 1501. One end of the connecting rod 1502 is fixedly connected to the inner wall of the feed pipe 7. The bottom end of the connecting rod 1502 is set inside the defoaming cylinder 5. A plurality of stirring rods 1503 are fixedly connected to the bottom end of the rod body 1501.

[0043] Both sides of the inside of the defoaming cylinder 5 are fixedly connected to supports 19, and an ultrasonic transmitter 18 is installed on the top surface of the supports 19.

[0044] In the specific implementation process, such as Figure 4 and Figure 7 As shown, when the defoaming cylinder 5 rotates, it causes the slurry inside the cylinder to rotate as well. During this rotation, the slurry is resisted by the stirring rod 1503, creating turbulence. This turbulent motion increases shear force and mixing within the slurry, thus promoting the bursting of air bubbles. The ultrasonic transmitter 18 emits ultrasonic waves into the slurry, and the vibrational energy of these waves breaks up the air bubbles. This prevents air bubbles from affecting the settling effect of the slurry in the thickening tank 1.

[0045] Example 3: In Example 1, there is a problem that the longer the length of the multiple conveying cylinders 13 connected together, the greater the downward force on the second flange 1304, which can easily lead to damage to the second flange 1304. Therefore, based on Example 1, this example also includes:

[0046] A plurality of first threaded holes 22 are provided on one side of the L-shaped block 11. A plurality of pull ropes 14 are installed on one side of the L-shaped block 11. The pull ropes 14 include steel cables 1401, first connectors 1402 and second connectors 1403. One end of the steel cable 1401 is fixedly connected to the first connector 1402, and the other end of the steel cable 1401 is fixedly connected to the second connector 1403. The second connector 1403 is threadedly connected to the first threaded holes 22. A retaining ring 1305 is provided on the outer sleeve of the second cylinder 1301. The retaining ring 1305 is fixedly connected to the second cylinder 1301. A collar 1306 is provided on the outer sleeve of the retaining ring 1305. The collar 1306 is rotatably connected to the retaining ring 1305. A second threaded hole 1307 is provided on the collar 1306. The first connector 1402 is threadedly connected to the second threaded hole 1307.

[0047] In the specific implementation process, such as Figure 1 As shown, the pull rope 14 pulls the feed cylinder 13 through the collar 1306, thereby reducing the downward force on the second flange 1304 and preventing the second flange 1304 from being easily damaged.

[0048] Example 4: Specifically, the working principle of the present invention is as follows:

[0049] During use, the solid particles suspended in the slurry in the thickening tank 1 settle under the action of gravity, while the upper part becomes clear water, thus separating the solid and liquid. The first motor 3 drives the feed cylinder 9 to rotate through the gearbox 4 and gear 10. The feed cylinder 9 drives the long rake 8 to rotate through the defoaming cylinder 5. The long rake 8 scrapes the sludge deposited at the bottom of the thickening tank 1 to the center of the bottom of the tank and then discharges it through the discharge port, while the clear water overflows from the upper edge of the thickening tank 1.

[0050] When it is necessary to distribute the material in the thickening tank 1, the slurry is conveyed into the feed cylinder 9 through the feed pipe 7. The slurry further enters the defoaming cylinder 5 through the feed cylinder 9. The water pump 17 in the defoaming cylinder 5 pumps the slurry into the rotating cylinder 12. The slurry in the rotating cylinder 12 enters the conveying cylinder 13 through the first connecting cylinder 1202 and the second connecting cylinder 1303. The slurry in the conveying cylinder 13 flows into other conveying cylinders 13 through the second connecting cylinder 1303 until the slurry in the conveying cylinder 13 overflows from the outlet pipe 1302. Since the slurry flows to all the conveying cylinders 13 first and then overflows, there will be no situation where some conveying cylinders 13 have a large amount of material distributed while others have a small amount. This ensures uniform distribution of the slurry. One rotation of the defoaming cylinder 5 completes one rotation of the conveying cylinder 13 within the thickening tank 1. Furthermore, simultaneous distribution via multiple cylinders is more efficient than traditional conveying machines that typically have only one conveying head. The conveying cylinders 13 can be connected, allowing for adjustment of the distribution width according to the width of the thickening tank 1, enhancing practicality. The rotation of the defoaming cylinder 5 causes the slurry within it to rotate. During this rotation, the slurry is resisted by the stirring rod 1503, creating turbulence. This turbulence increases shear force and mixing within the slurry, promoting the bursting of air bubbles. The ultrasonic transmitter 18 emits ultrasonic waves into the slurry, and the vibrational energy of these waves breaks up the air bubbles, preventing them from affecting the settling effect of the slurry within the thickening tank 1.

[0051] When cleaning is required for the defoaming cylinder 5, rotating cylinder 12, and conveying cylinder 13, the second motor 16 is started. The second motor 16 drives the rotating cylinder 12 to rotate via the chain 24. The rotating cylinder 12 drives the conveying cylinder 13 to rotate. After the water outlet pipe 1302 rotates 180 degrees, the slurry in the conveying cylinder 13 will be discharged through the water outlet pipe 1302 and clean water will be delivered into the feed pipe 7. The clean water will flush the feed cylinder 9. The water pump 17 is started to pump the clean water into the rotating cylinder 12 and the conveying cylinder 13, thereby cleaning the rotating cylinder 12 and the conveying cylinder 13. The operation is simple and convenient. Moreover, the conveying cylinder 13 is disassembled, which makes it easier to clean and perform deep cleaning.

[0052] In summary, this invention solves the problems of traditional cloth placing machines, which typically have only one cloth placing head, resulting in low construction efficiency, inability to adjust the cloth width, and inconvenience in cleaning due to their fixed structure.

[0053] The above are merely preferred embodiments of the present invention, but the scope of protection of the present invention is not limited thereto. Any equivalent substitutions or modifications made by those skilled in the art within the scope of the technology disclosed in the present invention, based on the technical solution and inventive concept of the present invention, should be covered within the scope of protection of the present invention.

Claims

1. A thickening machine fabric distribution device, comprising a thickening tank (1), characterized in that: A bridge frame (2) is fixedly connected to the top of the thickening tank (1). A feed cylinder (9) is fitted inside the bridge frame (2). The feed cylinder (9) is rotatably connected to the bridge frame (2). A feed pipe (7) is fitted inside the feed cylinder (9). The feed pipe (7) is rotatably connected to the feed cylinder (9). A gear (10) is fitted outside the feed cylinder (9). The gear (10) is fixedly connected to the feed cylinder (9). A gearbox (4) is fitted outside the gear (10). The gearbox (4) is fixedly connected to the bridge frame (2). A first motor (3) is installed in the gearbox (4). The first motor (3) is connected to the gear (10) through the gearbox (4). The feed cylinder (9) A defoaming cylinder (5) is fixedly connected to the bottom end. A long rake (8) is fixedly connected to the bottom end of the defoaming cylinder (5). A water pump (17) is installed inside the defoaming cylinder (5). A three-way pipe (20) is installed at the outlet of the water pump (17). Rotating cylinders (12) are installed on both sides of the defoaming cylinder (5). The rotating cylinders (12) are rotatably connected to the defoaming cylinder (5). The rotating cylinder (12) includes a first cylinder body (1201), a first connecting cylinder body (1202), and a first flange (1203). The first connecting cylinder body (1202) is fixedly connected to one end of the first cylinder body (1201), and the first flange (1203) is fixedly connected to one end of the first cylinder body (1201). L-shaped blocks (11) are fixedly connected to both sides of the defoaming cylinder (5). A second motor (16) is installed on the bottom surface of the L-shaped blocks (11). A chain (24) is provided on the rotor of the second motor (16). The chain (24) is sleeved on the outside of the first cylinder (1201). The second motor (16) is connected to the first cylinder (1201) through the chain (24). A conveying cylinder (13) is installed at one end of the rotating cylinder (12). The conveying cylinder (13) includes a second cylinder (1301). A second flange (1304) is fixedly connected to both ends of the second cylinder (1301). A second connector is fixedly connected to both ends of the second cylinder (1301). The cylinder (1303) has several outlet pipes (1302) fixedly connected to one side of the second cylinder (1301). The inner wall of the outlet pipe (1302) is tangent to the inner wall of the second cylinder (1301). The conveying cylinder (13) is connected to another conveying cylinder (13) through the connection of the second flange (1304) and another second flange (1304). The conveying cylinder (13) is connected to another conveying cylinder (13) through the connection of the second connecting cylinder (1303) and another second connecting cylinder (1303). The outlet pipe (1302) allows the slurry to flow to all the conveying cylinders (13) first and then overflow.

2. The thickening machine fabric distribution device according to claim 1, characterized in that: A stirring device (15) is installed at one end of the feed pipe (7). The stirring device (15) includes a rod body (1501), a connecting rod (1502), and a stirring rod (1503). A plurality of connecting rods (1502) are fixedly connected to the top end of the rod body (1501). One end of the connecting rod (1502) is fixedly connected to the inner wall of the feed pipe (7). The bottom end of the connecting rod (1502) is set inside the defoaming cylinder (5). A plurality of stirring rods (1503) are fixedly connected to the bottom end of the rod body (1501).

3. The thickening machine fabric distribution device according to claim 1, characterized in that: Both sides of the inside of the defoaming cylinder (5) are fixedly connected to supports (19), and an ultrasonic transmitter (18) is installed on the top surface of the supports (19).

4. The thickening machine fabric distribution device according to claim 1, characterized in that: The L-shaped block (11) has several first threaded holes (22) on one side, and several pull ropes (14) are installed on one side of the L-shaped block (11). The pull ropes (14) include a steel cable (1401), a first connector (1402), and a second connector (1403). One end of the steel cable (1401) is fixedly connected to the first connector (1402), and the other end of the steel cable (1401) is fixedly connected to the second connector (1403). The first connector (1402) is threaded to the first threaded hole (22). The second cylinder (1301) is fitted with a retaining ring (1305). The retaining ring (1305) is fixedly connected to the second cylinder (1301). The retaining ring (1305) is fitted with a collar (1306). The collar (1306) is rotatably connected to the retaining ring (1305). The collar (1306) has a second threaded hole (1307). The first connector (1402) is threaded to the second threaded hole (1307).

5. A thickening machine fabric distribution device according to claim 1, characterized in that: Both sides of the defoaming cylinder (5) are fixedly connected with a first reinforcing rib (21), and the first reinforcing rib (21) is fixedly connected to the bottom of the L-shaped block (11).

6. A thickening machine fabric distribution device according to claim 1, characterized in that: The bottom of the L-shaped block (11) is fixedly connected with a second reinforcing rib (23).

7. A thickening machine fabric distribution device according to claim 1, characterized in that: Several support frames (6) are fixedly connected to both sides of the feed pipe (7), and one end of the support frame (6) is fixedly connected to the bridge frame (2).

8. A thickening machine fabric distribution device according to claim 1, characterized in that: The second connecting cylinder (1303) is fitted with a plug (1308), which is threadedly connected to the second connecting cylinder (1303).

9. A thickening machine fabric distribution device according to claim 1, characterized in that: A rubber pad (1309) is installed at one end of the second connecting cylinder (1303).