CN219925343U - Pipeline classification mechanism - Google Patents

Abstract

The utility model relates to a pipeline classification mechanism, which comprises a frame body, wherein a plurality of conveying units for conveying pipelines are sequentially arranged on the frame body along the conveying direction of the pipelines, different conveying units correspond to different production links, and one end of the frame body along the conveying direction of the pipelines is in butt joint with a discharge end of a pipeline cutting device; the frame body is provided with pushing units and pipeline output units respectively corresponding to different production links, one end of the frame body, which corresponds to the conveying unit and is far away from the pipeline cutting device, is provided with a blocking unit, when the blocking unit is in an open state, the pipeline follows the conveying unit to convey, when the blocking unit is in a closed state, the blocking unit blocks the conveying of the pipeline, and the pushing unit is used for pushing the blocked pipeline to the pipeline output unit. The utility model has the effects of more conveniently realizing the classified transportation of the pipelines and improving the classified transportation efficiency and the pipeline production efficiency.

Description

Pipeline classification mechanism

Technical Field

The utility model relates to the field of pipeline processing, in particular to a pipeline classification mechanism.

Background

In the production process of the pipeline, the pipeline is generally provided with a certain length after preliminary production, and the pipeline needs to be cut by a pipeline cutting device, so that the pipeline can be applied to other production and processing links. In general, a pipe conveying device is disposed at a discharge end of the pipe cutting unit, and the pipe conveying device is used for conveying the pipe after cutting to a corresponding pipe processing device.

However, in actual production, the pipeline cutting device can produce pipelines with different lengths according to requirements, and the pipelines with different lengths correspond to different subsequent production links. Therefore, a pipeline conveying device needs to be changed to a certain extent, so that pipelines with different lengths can be output to production and processing links corresponding to the pipelines with different lengths. When the follow-up processing production links are many, need relevant staff to control pipeline conveyor and carry out many diversion actions, cause production process loaded down with trivial details, influence the efficiency of pipeline classified transportation to influence the production efficiency of pipeline.

Disclosure of Invention

In order to more conveniently realize classified transportation of pipelines and improve classified transportation efficiency and pipeline production efficiency, the utility model provides a pipeline classification mechanism.

The utility model provides a pipeline classification mechanism which adopts the following technical scheme:

the pipeline classification mechanism comprises a frame body, wherein a plurality of conveying units for conveying pipelines are sequentially arranged on the frame body along the conveying direction of the pipelines, different conveying units correspond to different production links, and one end of the frame body along the conveying direction of the pipelines is in butt joint with the discharge end of a pipeline cutting device; the production links corresponding to different on the frame body are respectively provided with a pushing unit and a pipeline output unit, one end, corresponding to the conveying unit, of the frame body, far away from the pipeline cutting device is provided with a material blocking unit, when the material blocking unit is in an opening state, the pipeline is conveyed along with the conveying unit, when the material blocking unit is in a closing state, the material blocking unit blocks the conveying of the pipeline, and the pushing unit is used for pushing the blocked pipeline to the pipeline output unit.

By adopting the technical scheme, the pipeline is conveyed on the frame body by the conveying unit, so that the pipeline can be conveyed out from the discharge plate of the pipeline cutting device; the related staff controls the corresponding material blocking units to block the transportation of the pipeline through the external control system according to the length of the produced pipeline, so that pipelines with different lengths can be transferred to the corresponding pipeline output units under the action of the pushing units, and then different production links are entered, and the classified transportation of the pipelines is realized.

Preferably, the blocking unit comprises a blocking piece and a blocking driving piece, the blocking driving piece is rotatably mounted on the frame body, one side, close to the blocking driving piece, of the blocking piece is rotatably mounted on the frame body, and the blocking driving piece is used for driving the blocking piece to rotate; when the material blocking unit is in an open state, the blocking piece is positioned at the outer side of the frame body; when the blocking unit is in a closed state, one side, away from the blocking driving piece, of the blocking piece is abutted to the frame body.

By adopting the technical scheme, when the material blocking unit is in the closed state, the material blocking unit plays a role in blocking the transportation of the pipeline, so that the blocked pipeline can be transported to a corresponding production link under the action of the pushing unit and the pipeline output unit; when the blocking unit is in an open state, the pipeline can smoothly pass through the frame body where the blocking piece is located and is conveyed to the next frame body through the conveying unit until the pipeline is stopped by the blocking piece in a closed state, so that classified transportation of the pipeline is realized.

Preferably, a weight member is mounted on a side of the blocking member away from the blocking driving member.

By adopting the technical scheme, the blocking piece can rotate from the highest point to the lowest point more easily, so that the blocking piece can play a role in stopping a pipeline more conveniently.

Preferably, the blocking member is rotatably mounted with a buffer plate with respect to a side of the pipe conveying direction.

Through adopting above-mentioned technical scheme, the buffer board plays the cushioning effect, reduces the harm to keeping off the material unit that the direct striking of pipeline was blocked the piece and cause, prolongs the life who keeps off the material unit.

Preferably, a position sensor for sensing the pipe is provided between the buffer plate and the blocking member.

Through adopting above-mentioned technical scheme, after the fender material unit that corresponds is in the closed state when relevant staff control, the pipeline strikes the buffer board under the effect of transfer unit to make position sensor trigger, promote the unit and trigger automatically because position sensor's trigger this moment, thereby make the pipeline blocked the material unit and can be automatic from the support body transfer to pipeline output unit after, improved the convenience of relevant personnel operation.

Preferably, the pushing unit comprises a pushing driving member and a pushing plate, the support frame is arranged on the frame body, and the pushing driving member pushes the blocked pipeline by pushing the pushing plate.

Through adopting above-mentioned technical scheme, when pushing the unit to be triggered, promote the driving piece and promote the push pedal through the telescopic link to make the pipeline can be transferred to pipeline output unit from the support body.

Preferably, a discharge plate is arranged at the discharge end of the pipe cutting device, and one end of the frame body along the pipe conveying direction is close to the discharge plate of the pipe cutting device.

By adopting the technical scheme, the too short pipeline is prevented from falling from the gap between the pipeline cutting device and the conveying unit as much as possible.

Preferably, the pipeline output unit comprises a bearing frame and a rail for conveying the blocked pipeline, one end of the rail is close to the frame body, and the other end of the rail is close to the subsequent processing device.

By adopting the technical scheme, the pipeline output unit is utilized to enable the pipeline to be output to corresponding processing production links of pipelines with different lengths along the length direction of the track.

Preferably, the frame body is provided with a turnover unit close to the bearing frame, the turnover unit comprises a turnover plate and a turnover driving piece, one side of the turnover plate is rotatably installed on the frame body, and the turnover driving piece is used for driving the turnover plate to rotate; the overturning driving piece controls the overturning plate to be in a blocking state, and one side, away from the frame body, of the overturning plate is positioned above the frame body; the overturning driving piece controls the overturning plate to be in a guiding state, and one side, far away from the frame body, of the overturning plate is close to the track.

By adopting the technical scheme, the overturning unit can be triggered manually by related personnel or triggered by a position sensor; when the overturning unit is in an open state, the overturning plate is in a blocking state, and the pipeline can be conveyed through the transmission chain more stably, so that the possibility that the pipeline falls off from the frame body is reduced; when the turnover unit is in a closed state, the turnover unit is triggered to enable the turnover plate to be in a guiding state, and the turnover plate plays a guiding role at the moment. So that the pipe can be transferred to the pipe output unit by the pushing unit.

Preferably, the pipe cutting device is provided with a waste collecting unit in place of the pipe output unit on the frame, the waste collecting unit comprises a collecting plate and a collecting box, the collecting box is arranged on one side of the frame, and two opposite sides of the collecting plate are respectively connected to the frame and placed above the collecting box.

Through adopting above-mentioned technical scheme, utilize waste collection unit can collect the waste material, the waste material is because pipeline cutting device is in the produced pipeline that can not be applied to in the follow-up processing when debugging, and relevant staff makes the fender material unit that is closest to pipeline cutting device be in the state of closing through external control system this moment to in making the waste material can collect the collection box under pushing unit's effect uniformly, convenient centralized processing.

In summary, the present utility model includes at least one of the following beneficial technical effects: the pipeline can be conveyed along the length direction of the plurality of frame bodies by utilizing the conveying unit, and then related staff control corresponding material blocking units to be closed by an external control system according to the length of the pipeline produced by the pipeline cutting device; when the pipeline is stopped by the material blocking unit, the pipeline triggers the position sensor through impacting the buffer plate, so that the triggering pushing unit enables the pipeline to be pushed to the waste collecting unit or the corresponding pipeline output unit, and classified conveying of the pipeline is realized; in addition, the pipeline can be conveyed with the conveying unit more stably by utilizing the overturning unit, so that the possibility that the pipeline falls off from the frame body is reduced, and meanwhile, the transfer from the conveying unit to the pipeline output unit is not influenced.

Drawings

FIG. 1 is a schematic overall structure of an embodiment of the present utility model;

FIG. 2 is a schematic diagram showing the structure of a conveying unit according to an embodiment of the present utility model;

FIG. 3 is a schematic diagram showing the construction of a garbage collection unit according to an embodiment of the present utility model;

FIG. 4 is a schematic diagram showing a structure of a material blocking unit according to an embodiment of the present utility model;

FIG. 5 is a schematic view of an exploded view of an embodiment of the present utility model showing another view of a baffle unit;

FIG. 6 is a schematic diagram of an embodiment of the present utility model in a garbage collection stage;

FIG. 7 is a schematic diagram of an embodiment of the present utility model in a classification stage;

fig. 8 is an enlarged schematic view of the portion a in fig. 7.

Reference numerals: 1. a frame body; 11. a base; 12. a first side plate; 13. a second side plate; 21. a motor; 211. an output shaft; 22. a driving wheel; 23. driven wheel; 24. a drive chain; 3. a waste collection unit; 31. a collection plate; 32. a collection box; 33. a box frame; 4. a material blocking unit; 41. a first hinge; 42. a second hinge; 43. a material blocking driving piece; 431. a third hinge; 441. a first hinge part; 442. a second hinge part; 45. a blocking member; 46. a weight member; 47. a buffer plate; 48. a position sensor; 5. a pushing unit; 51. pushing the driving member; 52. a push plate; 54. a support frame; 6. a pipeline output unit; 61. a carrier; 62. a track; 7. a turnover unit; 71. a turnover plate; 72. a flip drive; 8. and a discharging plate.

Detailed Description

The utility model is described in further detail below with reference to fig. 1-8.

The embodiment of the utility model discloses a pipeline classification mechanism.

Referring to fig. 1, a pipe sorting mechanism includes a plurality of frame bodies 1, the frame bodies 1 are in a rectangular parallelepiped shape as a whole, and the plurality of frame bodies 1 are close to each other from head to tail along their own length directions. Each frame body 1 is provided with a conveying unit for conveying pipelines, and the input end of the conveying unit is close to the pipeline cutting device. When the apparatus is in the commissioning phase, the pipe cutting apparatus may produce some waste. In order to prevent the waste from being transferred to the subsequent production link, pushing units 5 and waste collecting units 3 are respectively arranged on two sides of the frame body 1 closest to the pipeline cutting device, and the pushing units 5 are used for pushing the waste on the transfer unit into the waste collecting units 3. The remaining plurality of frame bodies 1 respectively correspond to different subsequent production links, the two sides of the remaining frame bodies 1 are respectively provided with the pipeline output unit 6 and the pushing unit 5, and the pushing unit 5 can also be used for pushing the cut pipeline positioned on the conveying unit to the pipeline output unit 6, so that pipelines with different lengths can be output to the corresponding subsequent production links. In order to enable the pushing unit 5 to be started according to requirements, one end, far away from the pipeline cutting device, of each frame body 1 is provided with a blocking unit 4 for blocking waste materials or conveying pipelines, and related staff control corresponding blocking components to play a role in blocking pipeline conveying according to the length of the pipeline produced by the pipeline cutting device, so that classified conveying of the pipelines can be realized more conveniently.

Referring to fig. 1 and 2, the frame 1 includes a base 11, and the base 11 has a T-shape overall. The surface of the base 11 is perpendicular to the ground, and the length of the side edge of the base 11 far away from the ground is longer than that of the side edge of the base 11 close to the ground. The first side plate 12 and the second side plate 13 are arranged on the upper surface of the base 11, the first side plate 12 and the second side plate 13 are symmetrically arranged on two long-dimension side edges of the upper surface of the base 11, and the length direction dimensions of the first side plate 12 and the second side plate 13 are larger than the length direction dimension of the base 11.

Referring to fig. 2 and 3, a transfer unit is mounted on the first and second side plates 12 and 13, and includes a motor 21, a driving wheel 22, and a driven wheel 23. The motor 21 is mounted on the side of the first side plate 12 remote from the second side plate 13, and the motor 21 is mounted on the end of the first side plate 12 near the pipe cutting apparatus. The driving pulley 22 and the driven pulley 23 are rotatably mounted between the first side plate 12 and the first side plate 12 by a rotation shaft and a rotation bearing, and the driving pulley 22 and the driven pulley 23 are respectively located at both end portions of the first side plate 12. The motor 21 is provided with an output shaft 211 in a direction approaching the first side plate 12, and the output shaft 211 passes through the first side plate 12 to be connected to the rotating shaft of the driving wheel 22, so that the motor 21 can drive the driving wheel 22 to rotate through the output shaft 211. The driving wheel 22 and the driven wheel 23 are provided with a driving belt around the outer sides, in this embodiment the driving belt is provided as a driving chain 24, and the driving chain 24 is engaged with both the driving wheel 22 and the driven wheel 23. The motor 21 drives the driving wheel 22 to rotate, so as to drive the transmission chain 24 to drive the driven wheel 23 to rotate, and further realize the transmission function of the transmission unit. The motor 21 drives the transmission chain 24 to drive along the discharging direction of the cutting device so as to facilitate the subsequent sorting treatment. Wherein the end of the drive chain 24 closest to the frame 1 closest to the pipe cutting device is located below the discharge plate 8 of the pipe cutting device for discharge in order to reduce the possibility of falling from the gap between the pipe cutting device and the transfer unit due to the too small length dimension of the output pipe.

Referring to fig. 3, the pushing unit 5 includes a pushing driver 51 and a push plate 52, and the pushing driver 51 is provided as an air cylinder in this embodiment. A support bracket 54 is mounted on the side of the second side plate 13 remote from the first side plate 12, and the push driver 51 is mounted above the support bracket 54 and close to the second side plate 13. The telescopic rod of the push driving piece 51 is close to the second side plate 13, the push plate 52 is arranged in the direction that the telescopic rod of the push driving piece 51 is close to the second side plate 13, and the length direction of the push plate 52 is parallel to the length direction of the second side plate 13. The end of the push plate 52 adjacent to the stop unit 4 is adjacent to, but not abutting the stop unit 4, so as to push the waste material of a shorter length down from the drive chain 24.

Referring to fig. 3, the waste collection unit 3 is disposed at a side of the first side plate 12 remote from the second side plate 13, the waste collection unit 3 includes a collection plate 31 and a collection box 32, one side of the collection plate 31 in a length direction is installed at a side of the first side plate 12 remote from the base 11, and the other side of the collection plate 31 in a length direction is disposed above the collection box 32. The collecting box 32 is in a cuboid shape as a whole, and the bottom of the collecting box 32 close to the ground is provided with a box frame 33 arranged on the ground so as to facilitate lifting the collecting box 32 to be away from the ground, and reduce the distance between the collecting plate 31 and the collecting box 32 from the frame body 1, thereby avoiding the condition that waste is pushed to the outside of the collecting box 32 as much as possible.

Referring to fig. 4 and 5, the blocking unit 4 includes a blocking member 45 and a blocking driving member 43, and the blocking driving member 43 is provided as an air cylinder in the embodiment of the present utility model. The side of the first side plate 12 remote from the second side plate 13 is provided with a first hinge 41 and a second hinge 42. The second hinge 42 is provided at an edge of the first side plate 12 remote from the base 11, and the first hinge 41 is located below the second hinge 42. The first hinge 41 and the second hinge 42 are each rectangular parallelepiped, and the length direction of the first hinge 41 and the second hinge 42 is perpendicular to the first side plate 12. The material blocking driving piece 43 is integrally cylindrical, one end of the material blocking driving piece 43 is hinged to the first hinge piece 41, the telescopic rod of the material blocking driving piece 43 is arranged at the other end of the material blocking driving piece 43, and the telescopic rod of the material blocking driving piece 43 is far away from the end part of the material blocking driving piece 43 and is provided with a third hinge piece 431.

Referring to fig. 4 and 5, the blocking member 45 has a rectangular parallelepiped shape as a whole, and a longitudinal direction surface of the blocking member 45 is perpendicular to the conveying direction of the drive chain 24. The two adjacent sides of the blocking member 45 adjacent to the longitudinal direction surface thereof are respectively extended with a first hinge portion 441 and a second hinge portion 442, and the first hinge portion 441 is disposed on the short-sized side of the blocking member 45 adjacent to the first side plate 12, and the second hinge portion 442 is disposed on the long-sized side of the blocking member 45 adjacent to the driving chain 24. The first hinge portion 441 is far away from the first side plate 12, the first hinge portion 441 is hinged to the third hinge member 431, and the second hinge portion 442 is hinged to the second hinge member 42, so that the blocking member 45 can be driven by the blocking driving member 43 to rotate around the second hinge member 42, and the rotation surface of the blocking member 45 is perpendicular to the transmission direction of the transmission chain 24. In order to enable the blocking member 45 to perform the function of blocking the pipe conveyance more stably under the drive of the motor 21, a length direction surface of the blocking member 45 facing away from the pipe conveyance direction is provided with the weight member 46, and the weight member 46 is away from the second hinge portion 442. When the blocking driving piece 43 stretches to enable the blocking piece 45 to rotate to the lowest point, the blocking unit 4 is in a closed state, and the blocking piece 45 can be abutted to the second side plate 13 under the action of the weight piece 46, so that the effect of blocking pipeline conveying is achieved. When the blocking driving piece 43 is pulled by the telescopic rod to enable the blocking piece 45 to rotate to the highest point, the blocking unit 4 is in an open state, and at the moment, the blocking piece 45 is positioned on the side edge of the frame body 1, so that the conveying of a pipeline through the conveying unit is not affected.

Referring to fig. 4 and 5, the side of the blocking member 45 away from which the weight member 46 is provided is hinged with a buffer plate 47, which plays a role in buffering, and prevents the pipe from directly colliding with the blocking member 45, which causes damage to the blocking unit 4 and affects the service life of the blocking unit 4. A position sensor 48 is provided between the blocking member 45 and the buffer plate 47, the position sensor 48 being mounted on the side of the blocking member 45 remote from the hinge post to facilitate pipe triggering. When the pipeline triggers the position sensor 48 through the buffer plate 47, the pushing unit 5 is triggered to start, so that automation of pipeline classification is realized.

Referring to fig. 6, each pipe output unit 6 is configured to output pipes of different lengths to subsequent processing links corresponding to the pipes of the lengths. The pipe output unit 6 includes a carrier 61 and a rail 62, the carrier 61 is installed on the ground, and the carrier 61 is provided with a plurality of rails 62 parallel to each other in the length direction. The rail 62 is disposed above the carriage 61 away from the ground, and the length direction of the rail 62 is perpendicular to the pipe conveying direction. One end of the rail 62 in the length direction is close to the frame body 1, and the other end of the rail 62 in the length direction is close to a subsequent processing link. The side of the bearing frame 61 far away from the ground is of an inclined design, and the side of the bearing frame 61 far away from the frame body 1 is inclined towards the ground, so that the pipeline can be more conveniently transferred from the track 62 to a subsequent production link.

Referring to fig. 6, when the pipe cutting apparatus is in the debugging stage, at this time, the related staff rotates the blocking member 45 closest to the pipe cutting apparatus to the lowest point through the external control system, and when the waste material impacts the buffer plate 47 under the driving of the transfer unit, the position sensor 48 is triggered, so that the pushing driving member 51 is started to drive the push plate 52 to move toward the direction in which the waste material collecting unit 3 is located, so that the waste material can enter the collecting tank 32 through the collecting plate 31 under the pushing action of the push plate 52, so that the related staff can process the waste material intensively. Referring to fig. 7, when the pipe cutting apparatus is debugged to be able to work normally and no waste is generated, according to the length of the pipe produced by the pipe cutting apparatus at this time, the related staff rotates the blocking member 45 of the frame 1 where the pipe output unit 6 corresponding to the length of the pipe is located to the lowest point through the external control system, so that the pipe can be pushed to the rail 62 under the action of the pushing unit 5 and enter the corresponding processing link along the pipe.

Referring to fig. 7 and 8, in order to enable the pipe to be stably driven by the driving chain 24, the second side plate 13 is provided with a turnover unit 7 at a side close to the pipe output unit 6. The turnover unit 7 includes a turnover plate 71 and a turnover driving member 72, and a side plate of the turnover plate 71 in a length direction is hinged above the second side plate 13. One end of the turnover driving member 72 is hinged to the second side plate 13, and a telescopic rod of the turnover driving member 72 is arranged on one side of the turnover driving member 72 away from the hinged end of the turnover driving member 72, and one end of the telescopic rod of the turnover driving member 72 away from the turnover driving member 72 is hinged to one side of the turnover plate 71 away from the second side plate 13. When the inversion driving member 72 pushes the inversion plate 71 to be in the blocking state, the plate surface of the inversion plate 71 is parallel to the plate surface of the second side plate 13, so that the pipe can be stably conveyed in the conveying direction of the transmission chain 24; when the inversion driving member 72 pulls the inversion plate 71 in the guide state, the plate surface of the inversion plate 71 is parallel to the pipe conveying direction, and a guide function is provided so that the pipe can roll down along the inversion plate 71 to the pipe output unit 6.

The implementation principle of the pipeline classification mechanism provided by the embodiment of the utility model is as follows: the pipeline can be conveyed on the frame body 1 along the discharging direction of the pipeline cutting device through the conveying unit; relevant personnel make corresponding fender material unit 4 be in the closed state through outside control system according to the length of pipeline that pipeline cutting device produced, close fender material unit 4 after, thereby the pipeline strikes buffer board 47 under the effect of conveying unit triggers position sensor 48 to start pushing element 5 or start pushing element 5 and upset unit 7, thereby make the pipeline of different length enter into waste collection unit 3 or corresponding follow-up production link under pushing element 5's effect, thereby make the pipeline of different length can more conveniently realize categorised transport, improve the production efficiency of pipeline.

The above embodiments are not intended to limit the scope of the present utility model, so: all equivalent changes in structure, shape and principle of the utility model should be covered in the scope of protection of the utility model.

Claims (10)

1. A pipeline classification mechanism, characterized in that: the pipeline cutting device comprises a frame body (1), wherein a plurality of conveying units for conveying pipelines are sequentially arranged on the frame body (1) along the conveying direction of the pipelines, different conveying units correspond to different production links, and one end of the frame body (1) along the conveying direction of the pipelines is in butt joint with a discharge end of a pipeline cutting device; the production links corresponding to different on the frame body (1) are respectively provided with a pushing unit (5) and a pipeline output unit (6), one end, corresponding to the conveying unit, of the frame body (1) and far away from the pipeline cutting device is provided with a material blocking unit (4), when the material blocking unit (4) is in an opening state, the pipeline follows the conveying unit to convey, when the material blocking unit (4) is in a closing state, the material blocking unit (4) blocks the conveying of the pipeline, and the pushing unit (5) is used for pushing the blocked pipeline to the pipeline output unit (6).

2. A pipe sorting mechanism as claimed in claim 1, wherein: the blocking unit (4) comprises a blocking piece (45) and a blocking driving piece (43), the blocking driving piece (43) is rotatably mounted on the frame body (1), one side, close to the blocking driving piece (43), of the blocking piece (45) is rotatably mounted on the frame body (1), and the blocking driving piece (43) is used for driving the blocking piece (45) to rotate; when the material blocking unit (4) is in an open state, the blocking piece (45) is positioned at the outer side of the frame body (1); when the material blocking unit (4) is in a closed state, one side, away from the material blocking driving piece (43), of the blocking piece (45) is abutted to the frame body (1).

3. A pipe sorting mechanism as claimed in claim 2, wherein: a counterweight (46) is arranged on one side of the blocking piece (45) far away from the blocking driving piece (43).

4. A pipe sorting mechanism according to claim 3, wherein: the blocking member (45) is rotatably mounted with a buffer plate (47) with respect to a side face of the pipe conveying direction.

5. A pipe sorting mechanism as claimed in claim 4, wherein: a position sensor (48) for sensing the pipe is arranged between the buffer plate (47) and the blocking piece (45).

6. A pipe sorting mechanism as claimed in claim 1, wherein: the pushing unit (5) comprises a pushing driving piece (51) and a pushing plate (52), a supporting frame (54) is arranged on the frame body (1), and the pushing driving piece (51) pushes the blocked pipeline by pushing the pushing plate (52).

7. A pipe sorting mechanism as claimed in claim 1, wherein: the pipeline cutting device is characterized in that a discharge plate (8) is arranged at the discharge end of the pipeline cutting device, and one end of the frame body (1) along the pipeline conveying direction is close to the discharge plate (8) of the pipeline cutting device.

8. A pipe sorting mechanism according to claim 1 or 5, wherein: the pipeline output unit (6) comprises a bearing frame (61) and a track (62) for conveying the blocked pipeline, one end of the track (62) is close to the frame body (1), and the other end of the track (62) is close to a subsequent processing device.

9. A pipe sorting mechanism as claimed in claim 8, wherein: the frame body (1) is close to the bearing frame (61) and is provided with a turnover unit (7), the turnover unit (7) comprises a turnover plate (71) and a turnover driving piece (72), one side of the turnover plate (71) is rotatably installed on the frame body (1), and the turnover driving piece (72) is used for driving the turnover plate (71) to rotate; the overturning driving piece (72) controls the overturning plate (71) to be in a blocking state, and one side of the overturning plate (71) away from the frame body (1) is positioned above the frame body (1); the overturning driving piece (72) controls the overturning plate (71) to be in a guiding state, and one side, far away from the frame body (1), of the overturning plate (71) is close to the track (62).

10. A pipe sorting mechanism as claimed in claim 1, wherein: the pipeline cutting device is characterized in that the pipeline output unit (6) is replaced on the frame body (1) of the pipeline cutting device, the waste collection unit (3) comprises a collection plate (31) and a collection box (32), the collection box (32) is arranged on one side of the frame body (1), and two opposite sides of the collection plate (31) are respectively connected to the frame body (1) and placed above the collection box (32).