CN219972101U - Mud pipeline adds medicine blender - Google Patents

Abstract

The utility model discloses a sludge pipeline dosing mixer, which relates to the field of sludge dewatering and comprises a mixer dosing bin, wherein a mixing pipe is fixedly arranged on the mixer dosing bin, a plurality of dosing pipes are fixedly arranged on the mixer dosing bin, and the dosing pipes are communicated with the mixer dosing bin. According to the utility model, through the arrangement of structures such as the dosing pipes, the baffle plates, the holes and the like, when the sludge passes through the dosing bin of the mixer, the arranged multiple dosing pipes can be used for carrying out multi-point dosing, the sludge and the medicament are coarsely mixed and enter the mixing pipe, the detachable baffle plates and the connecting rods are arranged in the mixing pipe, the baffle plates are provided with the multiple irregular holes, the sludge is separated and mixed after passing through the baffle plates and the holes, the mixing effect is achieved, the multi-point dosing mode is utilized to enable the mixing to be more uniform, the baffle plates only occupy one side of the mixing pipe, the pipeline blockage can be prevented, and the dosing bin of the mixer and the mixing pipe can be installed by utilizing the quick connector, so that the installation is more convenient.

Description

Mud pipeline adds medicine blender

Technical Field

The utility model relates to the technical field of sludge dewatering, in particular to a sludge pipeline dosing mixer.

Background

The chemical conditioning of sludge refers to adding inorganic or organic flocculant into sludge to destabilize the sludge and improve the dehydration performance of the sludge.

In the prior art, at present, in the sludge conditioning process, a pipeline dosing mode is used for sludge conditioning, sludge is utilized to move in a pipeline and roll, turbulent turbulence is generated, and the sludge is mixed with the medicament, under the traditional mode, the medicament in a sludge treatment pipeline is dosed, the medicament dosing pipe stretches into the center of the sludge pipeline to be singly dosed as a main mode, the turbulent flow effect of the sludge in the pipeline is fully utilized to realize mixing, and then the physicochemical reaction is carried out, when the flow rate of the sludge in the pipeline is too low, the mixing reaction effect of the pipeline dosing medicament is poor, the sludge treatment effect is directly influenced, namely, the pipeline single-point medicament dosing mode has defects, and the reaction effect can be poor, so that a sludge pipeline dosing mixer is needed to meet the demands of people.

Disclosure of Invention

The utility model aims to provide a sludge pipeline dosing mixer, which aims to solve the problems that in the background technology, when the flow rate of sludge in a pipeline is too low, the mixing reaction effect of a pipeline dosing agent is poor, the sludge treatment effect is directly influenced, namely, the pipeline single-point dosing mode has defects, and the reaction effect is poor.

In order to achieve the above purpose, the present utility model provides the following technical solutions: the utility model provides a mud pipeline dosing blender, includes the blender dosing storehouse, fixed mounting has the hybrid tube on the blender dosing storehouse, and fixed mounting has a plurality of dosing pipes on the blender dosing storehouse, and the dosing pipe is linked together with the blender dosing storehouse, and the inner wall in blender dosing storehouse installs the hybrid structure, installs a plurality of first bevel gears on the hybrid structure, installs the cleaning structure on the first bevel gear, installs the gangbar on the hybrid structure, installs the linkage structure on the gangbar.

Preferably, the mixing structure comprises two support rods, wherein the two support rods are movably arranged on the inner wall of the mixing pipe, the same connecting rod is fixedly arranged on the two support rods, a plurality of baffle plates are fixedly arranged on the connecting rod, and a plurality of holes are formed in the baffle plates.

Preferably, the cleaning structure comprises a cleaning rod, the cleaning rod is fixedly arranged on one side of the first bevel gear, the cleaning rod is contacted with one side of the baffle, and the cleaning rod and the first bevel gear are rotatably arranged on the connecting rod.

Preferably, the cleaning rod is provided with a limiting groove, a limiting ring is rotationally arranged in the limiting groove, and the limiting ring is fixedly arranged on the connecting rod.

Preferably, the linkage structure comprises two limiting rotating plates, the two limiting rotating plates are respectively and fixedly arranged at two ends of the linkage rod, the linkage rod is rotatably arranged on the inner wall of the connecting rod, the two limiting rotating plates are rotatably arranged on the inner wall of the connecting rod, one side of one limiting rotating plate is fixedly provided with one end of the connecting rod, the other end of the connecting rod penetrates through a corresponding supporting rod and is fixedly provided with a spiral plate, a plurality of second conical gears are fixedly arranged on the linkage rod, the inner wall of the connecting rod is rotatably provided with a plurality of third conical gears, the third conical gears are meshed with the second conical gears, one side of the third conical gears is fixedly provided with one end of a linkage shaft, the other end of the linkage shaft penetrates through the connecting rod and is fixedly provided with a fourth conical gear, and the fourth conical gear is meshed with the first conical gear.

Preferably, the connecting rod is provided with a plurality of rotating holes, and the linkage shaft is rotatably arranged in a corresponding rotating hole.

Preferably, the inner wall of the connecting rod is provided with two limiting grooves, and the two limiting rotating pieces are respectively and rotatably arranged in the two limiting grooves.

The beneficial effects of the utility model are as follows:

according to the utility model, through the arrangement of structures such as the dosing pipes, the baffle plates, the holes and the like, when the sludge passes through the dosing bin of the mixer, the arranged multiple dosing pipes can be used for carrying out multi-point dosing, the sludge and the medicament are coarsely mixed and enter the mixing pipe, the detachable baffle plates and the connecting rods are arranged in the mixing pipe, the baffle plates are provided with the multiple irregular holes, the sludge is separated and mixed after passing through the baffle plates and the holes, the mixing effect is achieved, the multi-point dosing mode is utilized to enable the mixing to be more uniform, the baffle plates only occupy one side of the mixing pipe, the pipeline blockage can be prevented, and the dosing bin of the mixer and the mixing pipe can be installed by utilizing the quick connector, so that the installation is more convenient.

According to the utility model, through the arrangement of the structures such as the cleaning rod, the linkage rod, the spiral piece and the like, when the sludge flows and passes through the mixing pipe, the spiral piece can drive the connecting rod to rotate under the impact of continuous flowing of the sludge, so that the linkage rod rotates, the cleaning rod can rotate and clean the baffle piece and the hole while the linkage rod rotates, the blocking of the baffle piece and the hole is prevented, and the connecting rod can also be driven to rotate by the motor, so that the cleaning effect is better.

Drawings

FIG. 1 is a schematic diagram of a sludge pipeline dosing mixer according to the present utility model;

FIG. 2 is a schematic cross-sectional view of a sludge pipeline dosing mixer according to the present utility model;

FIG. 3 is a schematic view of the structure of the connecting rod part of a sludge pipeline dosing mixer according to the present utility model;

FIG. 4 is a schematic cross-sectional view of a connecting rod portion of a sludge conduit dosing mixer according to the present utility model;

fig. 5 is a schematic structural view of a portion a in fig. 4 of a sludge pipeline dosing mixer according to the present utility model.

In the figure: 100. a mixer dosing bin; 101. a mixing tube; 200. a dosing tube; 201. a support rod; 202. a connecting rod; 203. a baffle; 204. a hole; 300. a cleaning lever; 301. a first bevel gear; 302. a limit groove; 303. a limiting ring; 400. a linkage rod; 401. limiting rotating plates; 402. a connecting rod; 403. a spiral sheet; 404. a second bevel gear; 405. a third bevel gear; 406. a linkage shaft; 407. a fourth bevel gear; 408. a rotation hole; 409. a limiting groove.

Detailed Description

The following description of the embodiments of the present utility model will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present utility model, but not all embodiments.

Referring to fig. 1 to 5, a sludge pipe dosing mixer comprises a mixer dosing bin 100, a mixing pipe 101 is fixedly installed on the mixer dosing bin 100, a plurality of dosing pipes 200 are fixedly installed on the mixer dosing bin 100, the dosing pipes 200 are communicated with the mixer dosing bin 100, a mixing structure is installed on the inner wall of the mixer dosing bin 100, a plurality of first bevel gears 301 are installed on the mixing structure, a cleaning structure is installed on the first bevel gears 301, a linkage rod 400 is installed on the mixing structure, a linkage structure is installed on the linkage rod 400, sludge firstly passes through the mixer dosing bin 100 at the front end of the mixer, multi-point dosing is performed by using the plurality of dosing pipes 200, the sludge and the medicament enter the mixing pipe 101 at the rear end of the mixer after being mixed roughly, a detachable baffle 203 and a connecting rod 202 are arranged in the rear end, a plurality of irregular holes 204 are formed on the baffle 203, the baffle 203 only occupies one side of the mixing tube 101 to prevent the pipeline from being blocked, the sludge passes through the baffle 203 and the hole 204 to achieve the mixing effect, and the mixer dosing bin 100 and the mixing tube 101 can be installed by using the quick connector during installation, the installation is more convenient, when the sludge flows and passes through the mixing tube 101, the spiral sheet 403 drives the connecting rod 402 to rotate under the impact of continuous flowing of the sludge, the rotating connecting rod 402 drives the linkage rod 400 to rotate through the cooperation with the limiting rotating sheet 401, the limiting rotating sheet 401 rotates in the limiting groove 409 at the same time, thereby avoiding the position deviation of the linkage rod 400, the linkage rod 400 rotates and drives the second conical gear 404 to rotate at the same time, thereby the rotating second conical gear 404 drives the third conical gear 405 to rotate through the meshing with the third conical gear 405, the third rotating bevel gear 405 drives the linkage shaft 406 to rotate in the rotation hole 408, so as to prevent the linkage shaft 406 from shifting, the continuously rotating linkage shaft 406 drives the fourth bevel gear 407 to rotate, so that the fourth rotating bevel gear 407 drives the cleaning rod 300 to rotate through meshing with the first bevel gear 301, the rotating cleaning rod 300 rotates on the limiting ring 303 through the limiting groove 302, the cleaning rod 300 is prevented from shifting in the rotation process of the cleaning rod 300, the continuously rotating cleaning rod 300 can clean the baffle 203 and the holes 204, the holes 204 are prevented from being blocked by sludge, and the connecting rod 402 can also be driven by a motor, so that the cleaning effect is better.

Further, the mixing structure comprises two supporting rods 201, the two supporting rods 201 are movably mounted on the inner wall of the mixing tube 101, the same connecting rod 202 is fixedly mounted on the two supporting rods 201, a plurality of baffle plates 203 are fixedly mounted on the connecting rod 202, a plurality of holes 204 are formed in the baffle plates 203, sludge firstly passes through the mixer dosing bin 100 at the front end of the mixer, multi-point dosing is carried out by using the plurality of arranged dosing tubes 200, the sludge and the medicament are coarsely mixed and then enter the mixer rear end mixing tube 101, the detachable baffle plates 203 and the connecting rod 202 are arranged in the rear end, a plurality of irregular holes 204 are formed in the baffle plates 203, the baffle plates 203 only occupy one side of the mixing tube 101, pipeline blockage is prevented, the sludge achieves a mixing effect through the baffle plates 203 and the holes 204, and the mixer dosing bin 100 and the mixing tube 101 can be mounted by using quick connectors during mounting, and the mounting is more convenient.

Further, the cleaning structure comprises a cleaning rod 300, the cleaning rod 300 is fixedly arranged on one side of the first bevel gear 301, the cleaning rod 300 is in contact with one side of the baffle plate 203, the cleaning rod 300 and the first bevel gear 301 are rotatably arranged on the connecting rod 202, the rotating cleaning rod 300 can rotate on the limiting ring 303 through the limiting groove 302, the cleaning rod 300 is prevented from shifting in the rotating process, and the continuously rotating cleaning rod 300 can clean the baffle plate 203 and the holes 204, so that the holes 204 are prevented from being blocked by sludge.

Further, the cleaning rod 300 is provided with a limiting groove 302, the limiting groove 302 is rotationally provided with a limiting ring 303, the limiting ring 303 is fixedly arranged on the connecting rod 202, and the rotating cleaning rod 300 can rotate on the limiting ring 303 through the limiting groove 302, so that the cleaning rod 300 is prevented from shifting in the rotating process.

Further, the linkage structure comprises two limiting rotating pieces 401, the two limiting rotating pieces 401 are respectively and fixedly installed at two ends of the linkage rod 400, the linkage rod 400 is rotatably installed on the inner wall of the connecting rod 202, the two limiting rotating pieces 401 are rotatably installed on the inner wall of the connecting rod 202, one side of one limiting rotating piece 401 is fixedly provided with one end of a connecting rod 402, the other end of the connecting rod 402 penetrates through a corresponding supporting rod 201 and is fixedly provided with a spiral piece 403, a plurality of second conical gears 404 are fixedly installed on the linkage rod 400, a plurality of third conical gears 405 are rotatably installed on the inner wall of the connecting rod 202, the third conical gears 405 are meshed with the second conical gears 404, one side of the third conical gears 405 is fixedly provided with one end of a linkage shaft 406, the other end of the linkage shaft 406 penetrates through the connecting rod 202 and is fixedly provided with a fourth conical gear 407, the spiral piece 403 is driven to rotate under the impact of continuous flow of sludge, the rotating connecting rod 402 is driven by the spiral piece 403 to rotate through the cooperation with the limiting rotating piece 401, meanwhile, the third conical gears 405 are driven by the rotating piece 400 to rotate, the third conical gears 405 are prevented from being driven by the rotating shaft 405, and the second conical gears 408 are prevented from being driven to rotate, and the second conical gears 408 are continuously offset, and the second conical gears 404 are prevented from rotating, and the second conical gears 404 are continuously rotated, and the second conical gears are driven by the second conical gears 405, and the second conical gears 404 are continuously rotated, and simultaneously, and the rotating shafts are driven by the second conical gears 405 and rotated, so that the rotating fourth bevel gear 407 rotates the cleaning rod 300 through engagement with the first bevel gear 301.

Further, the connecting rod 202 is provided with a plurality of rotation holes 408, the linkage shaft 406 is rotatably installed in a corresponding rotation hole 408, and the rotating third bevel gear 405 drives the linkage shaft 406 to rotate in the rotation hole 408, so as to avoid the deflection of the linkage shaft 406.

Further, two limiting grooves 409 are formed in the inner wall of the connecting rod 202, two limiting rotating plates 401 are respectively rotatably mounted in the two limiting grooves 409, and the limiting rotating plates 401 rotate in the limiting grooves 409 when rotating, so that the position of the linkage rod 400 is prevented from being deviated.

The working principle of the utility model is as follows:

the sludge passes through the mixer dosing bin 100 at the front end of the mixer at first, a plurality of dosing pipes 200 are utilized to carry out multi-point dosing, the sludge and the medicament are mixed roughly and then enter the mixer rear end mixing pipe 101, a detachable baffle plate 203 and a connecting rod 202 are arranged in the rear end, a plurality of irregular holes 204 are formed in the baffle plate 203, the baffle plate 203 only occupies one side of the mixing pipe 101 to prevent pipeline blockage, the sludge passes through the baffle plate 203 and the holes 204 to achieve the mixing effect, the mixer dosing bin 100 and the mixing pipe 101 can be installed by utilizing a quick connector during installation, the installation is more convenient, when the sludge flows and passes through the mixing pipe 101, the screw plate 403 can drive the connecting rod 402 to rotate under the impact of continuous flowing of the sludge, the rotating connecting rod 402 drives the linkage rod 400 to rotate through the cooperation of the limiting rotating plate 401, and meanwhile, the limiting rotating plate 401 can rotate in the limiting groove 409, thereby avoiding the shift of the position of the linkage rod 400, the linkage rod 400 rotates and drives the second bevel gear 404 to rotate, so that the second bevel gear 404 rotates to drive the third bevel gear 405 to rotate through the engagement with the third bevel gear 405, the rotating third bevel gear 405 drives the linkage shaft 406 to rotate in the rotating hole 408, the linkage shaft 406 is prevented from shifting, the continuously rotating linkage shaft 406 drives the fourth bevel gear 407 to rotate, the fourth bevel gear 407 drives the cleaning rod 300 to rotate through the engagement with the first bevel gear 301, the rotating cleaning rod 300 rotates on the limiting ring 303 through the limiting groove 302, the continuously rotating cleaning rod 300 can clean the baffle 203 and the holes 204, the holes 204 are prevented from being blocked by sludge, and the connecting rod 402 can also be driven by a motor, so that the cleaning effect is better.

The foregoing is only a preferred embodiment of the present utility model, but the scope of the present utility model is not limited thereto, and any person skilled in the art, who is within the scope of the present utility model, should make equivalent substitutions or modifications according to the technical scheme of the present utility model and the inventive concept thereof, and should be covered by the scope of the present utility model.

Claims (7)

1. The utility model provides a mud pipeline dosing blender, includes blender dosing storehouse (100), its characterized in that: the mixer dosing bin (100) is fixedly provided with a mixing pipe (101), the mixer dosing bin (100) is fixedly provided with a plurality of dosing pipes (200), the dosing pipes (200) are communicated with the mixer dosing bin (100), the inner wall of the mixer dosing bin (100) is provided with a mixing structure, the mixing structure is provided with a plurality of first bevel gears (301), the first bevel gears (301) are provided with cleaning structures, the mixing structure is provided with a linkage rod (400), and the linkage rod (400) is provided with a linkage structure.

2. A sludge line dosing mixer as claimed in claim 1 wherein: the mixing structure comprises two supporting rods (201), wherein the two supporting rods (201) are movably mounted on the inner wall of the mixing pipe (101), the same connecting rod (202) is fixedly mounted on the two supporting rods (201), a plurality of baffle plates (203) are fixedly mounted on the connecting rod (202), and a plurality of holes (204) are formed in the baffle plates (203).

3. A sludge line dosing mixer as claimed in claim 1 wherein: the cleaning structure comprises a cleaning rod (300), the cleaning rod (300) is fixedly arranged on one side of the first bevel gear (301), the cleaning rod (300) is in contact with one side of the baffle plate (203), and the cleaning rod (300) and the first bevel gear (301) are rotatably arranged on the connecting rod (202).

4. A sludge line dosing mixer as claimed in claim 3 wherein: the cleaning rod (300) is provided with a limiting groove (302), a limiting ring (303) is rotatably arranged in the limiting groove (302), and the limiting ring (303) is fixedly arranged on the connecting rod (202).

5. A sludge line dosing mixer as claimed in claim 1 wherein: the linkage structure comprises two limiting rotating plates (401), the two limiting rotating plates (401) are respectively and fixedly arranged at two ends of a linkage rod (400), the linkage rod (400) is rotatably arranged on the inner wall of a connecting rod (202), the two limiting rotating plates (401) are rotatably arranged on the inner wall of the connecting rod (202), one side of one limiting rotating plate (401) is fixedly provided with one end of a connecting rod (402), the other end of the connecting rod (402) penetrates through a corresponding supporting rod (201) and is fixedly provided with a spiral plate (403), a plurality of second conical gears (404) are fixedly arranged on the linkage rod (400), a plurality of third conical gears (405) are rotatably arranged on the inner wall of the connecting rod (202), the third conical gears (405) are meshed with the second conical gears (404), one side of each third conical gear (405) is fixedly provided with one end of a linkage shaft (406), and the other end of the linkage shaft (406) penetrates through the connecting rod (202) and is fixedly provided with a fourth conical gear (407), and the fourth conical gear (407) is meshed with the first conical gears (301).

6. A sludge line dosing mixer as claimed in claim 2 wherein: the connecting rod (202) is provided with a plurality of rotating holes (408), and the linkage shaft (406) is rotatably arranged in a corresponding rotating hole (408).

7. A sludge line dosing mixer as claimed in claim 2 wherein: two limiting grooves (409) are formed in the inner wall of the connecting rod (202), and the two limiting rotating pieces (401) are respectively and rotatably arranged in the two limiting grooves (409).