CN115581950B - Textile sewage recycling treatment system - Google Patents

Abstract

The invention relates to the technical field of textile wastewater treatment, and discloses a textile wastewater recycling treatment system, which includes a cylinder, a carrying circulation mechanism is installed inside the cylinder, and a cleaning and stirring mechanism is provided at the lower end of the carrying circulation mechanism. A filter plate is fixedly installed on the inner wall of the cylinder and below the cleaning and stirring mechanism. An impurity collection mechanism is provided outside the filter plate, and a bleaching box is provided below the cylinder. The driving motor drives the rotating shaft column and the stirring fan plate to rotate, and then the power transmission unit meshes with the gear on the inner wall of the cylinder, so that the impurity cleaning unit rotates around the rotating shaft column and then rotates, thereby cleaning the upper part of the filter plate in an all-round way. At the same time, the porous unit cleans the filter holes inside the filter plate to avoid clogging inside the filter plate, thereby achieving the effect of efficient filtration to prevent lint or fluff inside the sewage.

Description

A textile wastewater recycling and treatment system

Technical field

The invention relates to the technical field of textile wastewater treatment, specifically a textile wastewater recycling and treatment system.

Background technique

The textile industry is the industry with the most serious water pollution problems besides steel and papermaking. It requires a large amount of chemical agents to be added during textile processing. Discharging wastewater after processing will cause a lot of water pollution. Therefore, the textile industry now uses Wastewater is treated and recycled again.

In the process of textile wastewater treatment, the treated water is generally placed in a storage tank after sedimentation and conditioning, and then the treated water is recycled again. During the conditioning process, there are boiling wastewater, bleaching wastewater and mercerizing wastewater. Wastewater, etc. Among them, bleaching wastewater treatment is more efficient and more targeted for wastewater carrying pigments. However, during the bleaching process, because the wastewater easily carries some thread ends or fluff in the spinning thread, it is easy to settle in the bleaching process. At the bottom of the reservoir, on the one hand, it is easy to cause blockage of the delivery pipe; on the other hand, the lint settled in the reservoir accumulates at the bottom of the reservoir, making it difficult to clean.

Contents of the invention

In order to achieve the above object, the present invention adopts the following technical solution: a textile wastewater recycling and treatment system, including a cylinder, a carrying circulation mechanism is installed inside the cylinder, and a cleaning and stirring mechanism is provided at the lower end of the carrying circulation mechanism, and the A filter plate is fixedly installed on the inner wall of the cylinder and below the cleaning and agitation mechanism. An impurity collection mechanism is provided outside the filter plate, and a bleaching box is provided below the cylinder;

The cleaning and stirring mechanism includes a rotating shaft column, the upper end of the rotating shaft column is fixedly connected to the output shaft at the lower end of the driving motor, and a stirring fan plate is fixedly installed on the annular surface of the rotating shaft column, and the stirring fan plate is away from the rotating shaft column. There is a placement groove on one side, and a power transmission unit is provided on the upper side of the placement groove. The lower end of the power transmission unit is connected to a transmission belt. The end of the transmission belt away from the power transmission unit is located inside the stirring fan plate and is connected to an impurity cleaning device. unit, a sewage driving unit is provided inside the rotating shaft column and on one side close to the rotating shaft column, and a porous unit is installed at the lower end of the rotating shaft column and below the filter plate.

Further, the carrying circulation mechanism includes a fixed block, which is fixedly connected to the inner wall of the cylinder. A plurality of flow holes are provided inside the fixed block, and a driving motor is installed in the middle of the fixed block.

Further, the power transmission unit includes a positioning shaft, the upper end of the positioning shaft is rotatably inserted inside the cleaning agitation mechanism, the lower end of the positioning shaft is fixedly connected to a driven gear, and the lower end of the driven gear is fixedly connected to a transmission shaft, so The surface of the drive shaft is movably connected to the drive belt.

Furthermore, a plurality of through-flow holes are provided inside the rotating shaft column, and a plurality of driving plates are fixedly connected to the inner wall of the through-flowing holes. The driving plate and the side in the rotation direction of the rotating shaft column are inclined surfaces.

Further, the impurity cleaning unit includes a force-bearing rotating shaft, the force-bearing rotating shaft is located on the lower side of the placement groove, the annular surface of the force-bearing rotating shaft is movably connected to the transmission belt, and a cavity is provided on the lower side of the force-bearing rotating shaft. A moving rod is slidingly connected inside the cavity, a guide rod is slidingly connected to the lower end of the force-bearing rotating shaft, the moving rod is located in the middle of the compression spring, a load-bearing plate is fixedly connected to the lower end of the moving rod, and the load-bearing plate is connected to the force-bearing A compression spring is fixedly connected between the rotating shafts, an arc plate is fixedly connected to the annular surface of the load plate, and a cleaning brush is fixedly installed on the arc plate and the lower end of the load plate.

Further, the spacing unit includes a connecting plate, the upper end of the connecting plate is fixedly connected to the lower end of the rotating shaft column, the annular surface of the connecting plate is fixedly connected to a connecting rod, and the annular surface of the connecting rod is rotationally connected to a roller rod. , the surface of the roller rod is fixedly connected with a thorn, and the thorn is tapered.

Further, the impurity collection mechanism includes a collection channel, the collection channel is fixedly connected to the cylinder, the collection channel is connected to the inside of the cylinder, and the inner wall of the collection channel is fixedly connected with a first inclined plate and a first inclined plate arranged crosswise. On the second inclined plate, the lower end of the collection channel is fixedly connected with a placement annular cover, and the outer side of the placement annular cover is fixedly connected with a discharge valve.

Further, the filter plate is provided with a plurality of filter holes, the filter holes are tapered, and the filter holes fit with the spikes.

The beneficial effects of the present invention are:

1. In the present invention, the driving motor drives the rotating shaft column and the stirring fan plate to rotate, and then the power transmission unit meshes with the gear on the inner wall of the cylinder, so that the impurity cleaning unit rotates around the rotating shaft column and then rotates, thereby cleaning the upper part of the filter plate. Carry out all-round cleaning, and at the same time, the pore unit cleans the filter holes inside the filter plate to avoid clogging inside the filter plate, thereby achieving the effect of efficient filtration to prevent lint or fluff inside the sewage.

2. The present invention uses the impurity cleaning unit to clean the lint or fluff in the spinning wastewater and collect it in the impurity collection mechanism. Under the restriction of the first inclined plate and the second inclined plate, the lint or fluff cannot move into the cylinder. , thereby achieving the effect of centralized collection and processing of thread ends or fluff.

Description of the drawings

Figure 1 is a perspective view of the overall structure of the present invention.

Figure 2 is a front cross-sectional view of the cylindrical structure of the present invention.

Figure 3 is a schematic diagram of the power transmission unit of the present invention.

Figure 4 is a cross-sectional view of the structure of the stirring fan plate of the present invention.

Figure 5 is a partial cross-sectional view of the impurity cleaning unit of the present invention.

Figure 6 is a partial schematic diagram of the porous unit of the present invention.

Figure 7 is a partial schematic diagram of the impurity collection mechanism of the present invention.

In the picture: 1. Cylinder; 2. Carrying circulation mechanism; 21. Fixed block; 22. Overflow hole; 23. Driving motor; 3. Cleaning and stirring mechanism; 31. Rotating shaft; 32. Stirring fan plate; 33. Installation groove; 34. Power transmission unit; 341. Positioning shaft; 342. Driven gear; 343. Transmission shaft; 35. Transmission belt; 36. Impurity cleaning unit; 361. Forced rotating shaft; 362. Cavity; 363. Movement Rod; 364, compression spring; 365, load plate; 366, guide rod; 367, arc plate; 368, cleaning brush; 37, sewage driving unit; 371, flow hole; 372, drive plate; 38, porous unit ; 381. Connecting plate; 382. Connecting rod; 383. Roller rod; 384. Puncture; 4. Filter plate; 5. Impurity collection mechanism; 51. Collection channel; 52. First inclined plate; 53. Second inclined plate plate; 54, install annular cover; 55, discharge valve; 6, bleach box.

Detailed ways

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the accompanying drawings in the embodiments of the present invention. Obviously, the described embodiments are only some of the embodiments of the present invention, rather than all the embodiments. Based on the embodiments of the present invention, all other embodiments obtained by those of ordinary skill in the art without creative efforts fall within the scope of protection of the present invention.

Please refer to Figure 1. A textile wastewater recycling and treatment system includes a cylinder 1. A carrying circulation mechanism 2 is installed inside the cylinder 1. A cleaning and stirring mechanism 3 is provided at the lower end of the carrying circulation mechanism 2. The inner wall of the cylinder 1 is located on the cleaning and stirring mechanism. A filter plate 4 is fixedly installed below the mechanism 3, an impurity collection mechanism 5 is provided outside the filter plate 4, and a bleaching box 6 is provided below the cylinder 1.

The upper end of the cylinder 1 is connected with the sewage pipe, and the textile wastewater is discharged into the interior of the cylinder 1, flows downward along the interior of the cylinder 1, passes through the carrying circulation mechanism 2 and then reaches the position of the cleaning and stirring mechanism 3. At this time, the external driving source The cleaning and stirring mechanism 3 is driven to move, so that the cleaning and stirring mechanism 3 stirs the textile wastewater inside the cylinder 1 and changes the direction of the textile wastewater in many directions. When the textile wastewater continues to flow downward, it passes through the upper end of the filter plate 4 and passes through the filter holes inside the filter plate 4 It flows downward to complete the filtration and cleaning of the lint or fluff existing in the textile wastewater. Driven by the cleaning and stirring mechanism 3, the filtered lint and fluff located at the upper end of the filter plate 4 gradually move to the impurity collection mechanism 5 for sedimentation and collection. After the processing is completed, it is collected manually, and the textile wastewater passing through the filter plate 4 enters the inside of the bleaching box 6. Under the action of the bleach inside the bleaching box 6, the filtered textile wastewater is processed.

Please refer to Figure 1. The carrying circulation mechanism 2 includes a fixed block 21. The fixed block 21 is fixedly connected to the inner wall of the cylinder 1. A plurality of flow holes 22 are provided inside the fixed block 21. A driving motor 23 is installed in the middle of the fixed block 21.

Please refer to Figures 4 and 6. The cleaning agitation mechanism 3 includes a rotating shaft 31. The upper end of the rotating shaft 31 is fixedly connected to the output shaft at the lower end of the drive motor 23. The rotating shaft 31 is fixedly mounted with a stirring fan plate 32 on the annular surface. The stirring fan A placement slot 33 is provided on the side of the plate 32 away from the rotating shaft column 31. A power transmission unit 34 is provided on the upper side of the placement groove 33. A transmission belt 35 is connected to the lower end of the power transmission unit 34. The transmission belt 35 has one end away from the power transmission unit 34 and An impurity cleaning unit 36 is connected inside the stirring fan plate 32 , a sewage driving unit 37 is provided inside the rotating shaft 31 and close to the side of the rotating shaft 31 , and a porous unit is installed at the lower end of the rotating shaft 31 and below the filter plate 4 38.

Referring to FIG. 4 , a plurality of through-flow holes 371 are formed inside the rotating shaft 31 . A plurality of driving plates 372 are fixedly connected to the inner walls of the through-flow holes 371 . The driving plates 372 and the rotation direction side of the rotating shaft 31 are inclined surfaces.

After the textile wastewater enters the position of the cleaning agitation mechanism 3 through the overflow hole 22, the driving motor 23 drives the rotating shaft 31 to rotate. The rotating shaft 31 drives the agitating fan plate 32 to rotate together. The agitating fan plate 32 is aligned with the filter plate when rotating. 4. The textile sewage at the upper end is mixed. When the sewage passes through the circulation hole 371, the driving plate 372 pushes upward on part of the sewage, causing part of the sewage to flow upward, thereby causing the impurities in the textile sewage to move irregularly and remain in a suspended state. , to prevent impurities from settling on the upper end of the filter plate 4, causing clogging of the filter plate 4, and reducing the textile sewage filtration rate. When the agitation fan plate 32 rotates, the power transmission unit 34 is driven to rotate together. When the power transmission unit 34 moves, it interacts with the inner wall of the cylinder 1 The gear rings mesh, so that the power transmission unit 34 rotates around its own axis;

At the same time, the power transmission unit 34 transmits the rotation to the impurity cleaning unit 36 through the transmission belt 35, so that the impurity cleaning unit 36 also rotates around its own axis. Since the lower end of the impurity cleaning unit 36 fits the upper end of the filter plate 4, the impurity cleaning unit 36 rotates against The surface of the filter plate 4 is cleaned to prevent the surface of the filter plate 4 from being covered with impurities and causing blockage. At the same time, the impurities are pushed to the inside of the impurity collection mechanism 5 under the cleaning of the impurity cleaning unit 36. During the cleaning process of the impurity cleaning unit 36, the porous unit 38 rotates with the rotating shaft 31. Since the upper end of the pore unit 38 is close to the lower end of the filter plate 4, when the pore unit 38 rotates, the internal filter holes of the filter plate 4 are cleaned, and the impurities in the filter holes are cleaned to the upper end of the filter plate 4, and then It is cleaned by the impurity cleaning unit 36, thereby greatly extending the service life of the filter plate 4, efficiently cleaning the blocked impurities inside the filter plate 4, and speeding up the filtration efficiency.

Please refer to Figures 3 and 4. The power transmission unit 34 includes a positioning shaft 341. The upper end of the positioning shaft 341 is rotatably inserted inside the cleaning agitation mechanism 3. The lower end of the positioning shaft 341 is fixedly connected to a driven gear 342, and the lower end of the driven gear 342 is fixed. A transmission shaft 343 is connected, and the surface of the transmission shaft 343 is movably connected with the transmission belt 35 .

Please refer to Figure 5. The impurity cleaning unit 36 includes a force-bearing rotating shaft 361. The force-bearing rotating shaft 361 is located on the lower side of the placement groove 33. The annular surface of the force-bearing rotating shaft 361 is movably connected to the transmission belt 35. A cavity is provided on the lower side of the force-bearing rotating shaft 361. 362. There is a moving rod 363 slidingly connected inside the cavity 362. The lower end of the force-bearing rotating shaft 361 is slidingly connected with a guide rod 366. The moving rod 363 is located in the middle of the compression spring 364. The lower end of the moving rod 363 is fixedly connected with a load plate 365. The load plate 365 is connected to the load plate 365. A compression spring 364 is fixedly connected between the force rotating shafts 361, an arc plate 367 is fixedly connected to the annular surface of the load plate 365, and a cleaning brush 368 is fixedly installed on the arc plate 367 and the lower end of the load plate 365.

When the rotation of the rotating shaft column 31 drives the agitation fan plate 32 to rotate together with the power transmission unit 34, the driven gear 342 meshes with the gear ring on the inner wall of the cylinder 1, so the driven gear 342 also rotates with the agitation fan plate 32. When the rotation occurs, the transmission shaft 343 is driven to rotate together. When the transmission shaft 343 rotates, the torque is transmitted to the force-bearing rotating shaft 361 through the transmission belt 35, so that the force-bearing rotating shaft 361 also rotates. The force-bearing rotating shaft 361 passes through the guide rod 366. The load plate 365, the arc plate 367 and the cleaning brush 368 are driven to rotate axially around the force-bearing rotating shaft 361. Since the cleaning brush 368 is in contact with the upper end of the filter plate 4, the cleaning brush 368 continuously cleans the lint or fluff on the upper end of the filter plate 4. , and because the agitation fan plate 32 axially rotates around the rotation axis 31, the arc plate 367 and the cleaning brush 368 rotate axially with the agitation fan plate 32 around the rotation axis 31. Because the arc plate 367 It is curved, and under the rotation of the arc plate 367, the lint or fluff is cleaned toward the edge of the filter plate 4 to prevent the upper end of the filter plate 4 from being blocked by lint and other debris due to the fluidity of the sewage. , affecting the filtering effect.

Please refer to Figure 7 . The impurity collection mechanism 5 includes a collection channel 51 . The collection channel 51 is fixedly connected to the cylinder 1 . The collection channel 51 is connected with the inside of the cylinder 1 . The inner wall of the collection channel 51 is fixedly connected to a first inclined plate arranged crosswise. 52 and the second inclined plate 53, the lower end of the collection channel 51 is fixedly connected with an annular cover 54, and the outside of the annular cover 54 is fixedly connected with a discharge valve 55.

When the arc plate 367 and the cleaning brush 368 continuously clean the lint or fluff on the upper end of the filter plate 4 toward the edge of the filter plate 4, the lint or fluff gradually sinks into the inside of the collection channel 51 under the action of gravity, and along the first inclined plate 52 and the second inclined plate 53 sink to the inside of the annular cover 54. Because the textile wastewater inside the cylinder 1 is always in a swaying state under the constant agitation of the stirring fan plate 32, the threads or threads sinking into the collection channel 51. The fluff is easy to pour out, and the staggered distribution of the first inclined plate 52 and the second inclined plate 53 effectively limits the movement of the thread or fluff, so that the thread or fluff can settle at the bottom of the annular cover 54 and be opened and unloaded after the processing is completed. The material valve 55 is used to manually clean the lint or fluff accumulated inside the annular cover 54 to complete the filtration work.

Please refer to Figure 6. The spacing unit 38 includes a connecting plate 381. The upper end of the connecting plate 381 is fixedly connected to the lower end of the rotating shaft 31. The annular surface of the connecting plate 381 is fixedly connected to a connecting rod 382. The annular surface of the connecting rod 382 is rotatably connected to a roller. The surface of the rod 383 and the roller rod 383 is fixedly connected with a thorn 384. The thorn 384 is conical. The filter plate 4 is provided with a plurality of filter holes. The filter holes are conical and the filter holes fit with the thorn 384.

When the filter plate 4 filters the textile sewage inside the cylinder 1, when the sewage flows downward, some fluff passes through the filter holes inside the filter plate 4, causing the filter holes inside the filter plate 4 to be blocked, and the connecting plate 381 Because it is connected to the rotating shaft column 31, it rotates with the rotation of the rotating shaft column 31, and then drives the roller rod 383 to rotate axially around the rotating shaft column 31 through the connecting rod 382, and the roller rod 383 is connected to the bottom of the filter plate 4 At the same time, the thorns 384 are plugged into the filter holes inside the filter plate 4, so that when the connecting rod 382 drives the roller rod 383 to rotate axially around the rotating shaft 31, the thorns 384 are connected around the filter holes under the meshing engagement. The rod 382 rotates axially, so that the thorn 384 also rotates when it rotates axially around the rotating shaft 31, thereby fully clearing the filter holes inside the filter plate 4, pushing the fluff and the like to move to the upper end of the filter plate 4, and then being cleaned and brushed 368 clean up and complete the filtering work.

Working principle: The textile wastewater is discharged into the inside of the cylinder 1, flows downward along the inside of the cylinder 1, passes through the carrying circulation mechanism 2 and then reaches the position of the cleaning and stirring mechanism 3. At this time, the external driving source drives the cleaning and stirring mechanism 3 to move, so that The cleaning and stirring mechanism 3 stirs the textile wastewater inside the cylinder 1 and changes the direction of the textile wastewater in multiple directions. When the textile wastewater continues to flow downward, it passes through the upper end of the filter plate 4 and flows downward through the filter holes inside the filter plate 4, thus completing the textile wastewater treatment. The lint or fluff present in the wastewater is filtered and cleaned. Driven by the cleaning and agitation mechanism 3, the filtered lint and fluff located at the upper end of the filter plate 4 gradually move to the impurity collection mechanism 5 to settle and collect, and are collected manually after the processing is completed. The textile wastewater passing through the filter plate 4 enters the inside of the bleaching box 6, and under the action of the bleach inside the bleaching box 6, the filtered textile wastewater is processed.

In the description of the present invention, unless otherwise expressly stipulated and limited, the terms "set", "installation", "connected", "connected" and "fixed" should be understood in a broad sense. For example, it can be a fixed connection or a fixed connection. It can be detachably connected or integrated; it can be a mechanical connection or an electrical connection; it can be a direct connection or an indirect connection through an intermediate medium; it can be an internal connection between two elements or an interaction between two elements. For those of ordinary skill in the art, the specific meanings of the above terms in the present invention can be understood on a case-by-case basis.

The standard parts used in the present invention can be purchased from the market, and the special-shaped parts can be customized according to the instructions and drawings.

The above are only preferred specific embodiments of the present invention, but the protection scope of the present invention is not limited thereto. Any person familiar with the technical field can, within the technical scope disclosed in the present invention, use the technical solutions of the present invention and its Equivalent substitutions or changes of the inventive concept shall be included in the protection scope of the present invention.

Claims (4)

1. The utility model provides a textile sewage cyclic utilization processing system, includes drum (1), its characterized in that: the novel cleaning and stirring device is characterized in that a bearing and circulating mechanism (2) is arranged in the cylinder (1), a cleaning and stirring mechanism (3) is arranged at the lower end of the bearing and circulating mechanism (2), a filter plate (4) is fixedly arranged on the inner wall of the cylinder (1) and below the cleaning and stirring mechanism (3), an impurity collecting mechanism (5) is arranged on the outer side of the filter plate (4), and a bleaching box (6) is arranged below the cylinder (1);

the cleaning stirring mechanism (3) comprises a rotating shaft column (31), the upper end of the rotating shaft column (31) is fixedly connected with an output shaft at the lower end of a driving motor (23), a stirring fan plate (32) is fixedly arranged on the annular surface of the rotating shaft column (31), a placement groove (33) is formed in one side, far away from the rotating shaft column (31), of the stirring fan plate (32), a power transmission unit (34) is arranged on the upper side of the placement groove (33), a transmission belt (35) is connected with the lower end of the power transmission unit (34), one end, far away from the power transmission unit (34), of the transmission belt (35) is connected with an impurity cleaning unit (36) in the stirring fan plate (32), a sewage driving unit (37) is arranged in the rotating shaft column (31) and is arranged on one side, close to the rotating shaft column (31), and a hole dredging unit (38) is arranged below the filter plate (4);

the power transmission unit (34) comprises a positioning shaft (341), the upper end of the positioning shaft (341) is rotationally inserted into the cleaning stirring mechanism (3), the lower end of the positioning shaft (341) is fixedly connected with a driven gear (342), the lower end of the driven gear (342) is fixedly connected with a transmission shaft (343), the surface of the transmission shaft (343) is movably connected with a transmission belt (35), and the driven gear (342) is meshed with a gear ring on the inner wall of the cylinder (1);

the impurity cleaning unit (36) comprises a stress rotating shaft (361), the stress rotating shaft (361) is located at the lower side of the mounting groove (33), an annular surface of the stress rotating shaft (361) is movably connected with the transmission belt (35), a cavity (362) is formed in the lower side of the stress rotating shaft (361), a moving rod (363) is connected inside the cavity (362) in a sliding mode, a guide rod (366) is connected at the lower end of the stress rotating shaft (361) in a sliding mode, the moving rod (363) is located in the middle of the compression spring (364), a load disc (365) is fixedly connected to the lower end of the moving rod (363), a compression spring (364) is fixedly connected between the load disc (365) and the stress rotating shaft (361), an arc plate (367) is fixedly connected to the annular surface of the load disc (365), and a cleaning brush (368) is fixedly arranged at the lower end of the load disc (365).

The sewage driving unit (37) comprises a through-flow hole (371) and a driving plate (372), wherein a plurality of through-flow holes (371) are formed in the rotating shaft column (31), the inner wall of the through-flow hole (371) is fixedly connected with a plurality of driving plates (372), and one surface of the driving plates (372) and one surface of the rotating shaft column (31) in the rotating direction are inclined surfaces;

the impurity collection mechanism (5) comprises a collection channel (51), the collection channel (51) is fixedly connected with the cylinder (1), the collection channel (51) is circumferentially arranged outside the cylinder (1), the collection channel (51) is communicated with the inside of the cylinder (1), a first inclined plate (52) and a second inclined plate (53) which are arranged in a crossed mode are fixedly connected with the inner wall of the collection channel (51), an annular cover (54) is fixedly connected with the lower end of the collection channel (51), and a discharge valve (55) is fixedly connected with the outer side of the annular cover (54).

2. A textile wastewater recycling treatment system according to claim 1, wherein: the bearing circulation mechanism (2) comprises a fixed block (21), the fixed block (21) is fixedly connected with the inner wall of the cylinder (1), a plurality of overflow holes (22) are formed in the fixed block (21), and a driving motor (23) is mounted in the middle of the fixed block (21).

3. A textile wastewater recycling treatment system according to claim 1, wherein: the hole dredging unit (38) comprises a connecting disc (381), the upper end of the connecting disc (381) is fixedly connected with the lower end of the rotating shaft column (31), the annular surface of the connecting disc (381) is fixedly connected with a connecting rod (382), the annular surface of the connecting rod (382) is rotationally connected with a roller rod (383), the surface of the roller rod (383) is fixedly connected with a jacking thorn (384), and the jacking thorn (384) is conical.

4. A textile wastewater recycling treatment system according to claim 3, wherein: the filter plate (4) is provided with a plurality of filtering holes, the filtering holes are conical, and the filtering holes are matched with the jacking thorns (384).