CN115258581A

CN115258581A - Plastic pipe production line based on anti-deviation function

Info

Publication number: CN115258581A
Application number: CN202211209651.2A
Authority: CN
Inventors: 尹建国; 刘佳豪; 周雷
Original assignee: Zhangjiagang Fulande Machinery Co ltd
Current assignee: Zhangjiagang Fulande Machinery Co ltd
Priority date: 2022-09-30
Filing date: 2022-09-30
Publication date: 2022-11-01

Abstract

The invention relates to the technical field of plastic pipe processing, in particular to a plastic pipe production line based on an anti-deviation function, which comprises a workbench, a lifting device, a first conveyor, a second conveyor and a side guide mechanism, wherein the workbench is arranged on the workbench; the first conveyor is horizontally arranged on the workbench and comprises a first conveying belt, and upper guide rollers which are distributed at equal intervals along the length direction of the first conveying belt are arranged on the first conveying belt; the second conveyor is horizontally arranged right above the first conveyor and can move up and down, the second conveyor comprises a second conveying belt, and lower guide rollers which are distributed at equal intervals along the length direction of the second conveying belt are arranged on the second conveying belt; lateral part guiding mechanism has a pair ofly and the mirror image setting is in the both sides of workstation, and this application can be spacing the quick carrying on of the great pipe fitting of diameter, avoids great pipe fitting off tracking in transportation process, improves the precision that the pipe fitting was carried.

Description

Plastic pipe production line based on anti-deviation function

Technical Field

The invention relates to the technical field of plastic pipe processing, in particular to a plastic pipe production line based on an anti-deviation function.

Background

Continuous production is carried out through an extruder in the production process of the plastic pipe, a cutting device is arranged at the rear end of the production line to cut the continuous pipe into equal-length pipe fittings, and before the pipe is cut, the pipe is not easy to deviate on the production line because the length of the pipe is longer and the pipe is usually moved through a special tractor;

the pipe fitting off tracking is avoided to the central transport of carrying through the roll table among the prior art usually, and the roll table is V type roll table usually, and tubular product is carried along the V type roll table, however this kind of mode can only be to the less tubular product of diameter, and when carrying to the great tubular product of diameter, tubular product is not then can increase by spacing region, leads to the great tubular product of diameter also can produce the phenomenon of off tracking through conventional V type roll table in transportation process.

Disclosure of Invention

To the problem that prior art exists, provide a plastics tubular product production line based on prevent off tracking function, this application can be spacing the quick carrying on of the great pipe fitting of diameter through mutually supporting of folding leg, actuating mechanism and lateral part deflector roll, avoids great pipe fitting off tracking in transportation process, improves the precision that the pipe fitting was carried.

In order to solve the problems of the prior art, the invention adopts the technical scheme that:

a plastic pipe production line based on an anti-deviation function comprises a workbench, a lifting device, a first conveyor, a second conveyor and a side guide mechanism;

the first conveyor is horizontally arranged on the workbench and comprises a first conveying belt, and upper guide rollers which are distributed at equal intervals along the length direction of the first conveying belt are arranged on the first conveying belt;

the second conveyor is horizontally arranged right above the first conveyor and can move up and down, the second conveyor comprises a second conveying belt, and lower guide rollers which are distributed at equal intervals along the length direction of the second conveying belt are arranged on the second conveying belt;

lateral part guiding mechanism has a pair ofly and the mirror image setting both sides at the workstation, lateral part guiding mechanism includes folding leg and several lateral part deflector roll, the folding leg is located between first conveyer and the second conveyer and is articulated with one side of first conveyer and second conveyer respectively, several lateral part deflector roll distributes on the folding leg along the horizontal direction equidistance of workstation, the lateral part deflector roll is the center department between first conveyer of level orientation and the second conveyer, lateral part guiding mechanism still includes the actuating mechanism who is used for driving lateral part deflector roll translation and removes.

Preferably, the upper guide roller and the lower guide roller each comprise a first idler frame and a first rotating roller;

the first carrier roller frame of the upper guide roller is arranged on the surface of the first conveying belt, and the first carrier roller frame of the lower guide roller is arranged on the surface of the second conveying belt;

the first rotating roller is horizontally arranged in the first roller carrier.

Preferably, the folding frame comprises a transverse positioning plate, a first connecting rod and a second connecting rod;

the transverse positioning plate is horizontally positioned in the middle between the first conveyor and the second conveyor, the length direction of the transverse positioning plate is parallel to the conveying direction of the first conveyor, and the driving mechanism is arranged on the transverse positioning plate;

a plurality of first connecting rods are vertically positioned above the transverse positioning plate, one end of each first connecting rod is hinged with the top of the transverse positioning plate, and the other end of each first connecting rod is hinged with one side of the second conveyor;

the second connecting rod has the several and is the vertical below that is located transverse location board, and the one end of second connecting rod is articulated with transverse location board's top, and the other end of second connecting rod is articulated with one side of first conveyer and is set up, and the length of second connecting rod is the same with the length of first connecting rod.

Preferably, the driving mechanism comprises a sliding sleeve and a sliding rod;

the sliding sleeves are provided with a plurality of sliding sleeves which are connected to the transverse positioning plates in a penetrating manner at equal intervals along the length direction of the transverse positioning plates, and one end of each sliding sleeve faces to the middle between the first conveyor and the second conveyor;

the sliding rod is inserted in the sliding sleeve in a horizontal and telescopic mode, one end of the sliding rod faces the middle between the first conveyor and the second conveyor, and the end, facing the middle between the first conveyor and the second conveyor, of the sliding rod is connected with the lateral portion guide roller.

Preferably, the outside of slide bar is equipped with the protruding strip that sets up along slide bar length direction extension, and the inside of sliding sleeve is equipped with the spacing gliding spacing recess of confession protruding strip spacing.

Preferably, the lateral guide roller comprises a vertical plate, a buffer spring, an axial limiting sleeve, a second roller supporting frame and a second rotating roller;

the vertical plate is vertically arranged at the tail end of the middle part between the first conveyor and the second conveyor, which faces the sliding rod;

the second roller carrier is positioned on one side of the vertical plate far away from the sliding rod, one side of the second roller carrier close to the vertical plate is provided with a plurality of buffer columns which are arranged horizontally, the vertical plate is provided with a through hole for each buffer column to movably pass through, and one end of each buffer column passes through the through hole and extends outwards;

the number of the axial limiting sleeves is the same as that of the buffer columns, and the axial limiting sleeves are arranged at the extending ends of the buffer columns in a one-to-one correspondence manner;

the buffer spring is sleeved on the buffer column, one end of the buffer spring is abutted with the inner side of the second roller carrier, and the other end of the buffer spring is abutted with one side of the vertical plate close to the second roller carrier;

the second changes the roller and is vertical and can the pivoted setting in the inside of second bearing roller frame.

Preferably, the driving mechanism further comprises a transverse push plate, a limiting sleeve and a limiting polished rod;

the transverse push plate is horizontally positioned on one side of the transverse positioning plate away from the third guide roller, and the transverse push plate and the transverse positioning plate are arranged in parallel;

the limiting polished rod is at least provided with a pair of limiting polished rods which are arranged at two ends of the transverse positioning plate in parallel, and the axis of the limiting polished rod is vertical to the length direction of the transverse push plate;

the number of the limiting sleeves is the same as that of the limiting polished rods, the limiting polished rods are connected to the transverse push plates in a one-to-one correspondence mode, and one end of each limiting polished rod is movably inserted into the inner ring of each limiting sleeve.

Preferably, the driving mechanism further comprises a connecting plate, a screw rod transmission machine and a third connecting rod;

the connecting plate is vertically arranged in the middle of the transverse positioning plate, and the screw rod transmission machine is vertically arranged on the connecting plate;

the third connecting rod is vertically positioned above the transverse push plate, one end of the third connecting rod is hinged with the top of the transverse push plate, and the other end of the third connecting rod is hinged with the working end of the screw rod transmission machine.

Preferably, every corner of workstation all is equipped with the hydraulic push rod that is vertical form setting, and every hydraulic push rod's output respectively with every corner fixed connection of second conveyer.

Preferably, the first roller and the second roller are integrally formed by two conical bodies arranged in a mirror image mode, and the reducing ends of the two conical bodies are connected with each other.

Compared with the prior art, the beneficial effect of this application is:

this application is through mutually supporting of folding leg, actuating mechanism and lateral part deflector roll, can be spacing the quick the carrying on of the great pipe fitting of diameter, avoids great pipe fitting off tracking in transportation process, improves the precision that the pipe fitting was carried.

Drawings

FIG. 1 is a schematic perspective view of a plastic pipe production line based on a deviation prevention function;

FIG. 2 is a state diagram I of a plastic pipe production line based on an anti-deviation function;

FIG. 3 is a state diagram II of a plastic pipe production line based on a deviation prevention function;

FIG. 4 is a left side view of a plastic pipe production line based on an anti-deviation function;

FIG. 5 is a schematic perspective view of a plastic pipe production line based on a deviation prevention function;

FIG. 6 is a first perspective view of a portion of the side guide mechanism of the present application;

FIG. 7 is a partial top view of the side guide mechanism of the present application;

FIG. 8 isbase:Sub>A cross-sectional view taken along A-A of FIG. 7 of the present application;

fig. 9 is a partial perspective view of the second side guide mechanism of the present application;

FIG. 10 is an enlarged view at B of FIG. 9 of the present application;

FIG. 11 is a partial perspective view of the side guide rollers of the present application;

fig. 12 is a partial perspective view of the upper guide roller of the present application.

The reference numbers in the figures are:

1-a workbench;

2-a lifting device;

21-a hydraulic push rod;

3-a first conveyor;

31-a first conveyor belt;

32-lower guide rollers; 321-a first carrier roller frame; 322-a first rotating roller;

4-a second conveyor;

41-a second conveyor belt;

42-upper guide rollers;

51-a folding leg;

511-transverse positioning plate; 512-a first link; 513-a second link;

52-side guide rollers;

521-a vertical plate; 522-a buffer spring; 523-axial stop collar; 524-a second carrier roller frame; 525-a second roller;

53-a drive mechanism; 531-sliding sleeve; 532-sliding bar; 5321-raised strips; 533-transverse push plate; 534-stop collar; 535-limit polished rod; 536-a connecting plate; 537-screw rod transmission machine; 538-third link.

Detailed Description

For further understanding of the features and technical means of the present invention, as well as the specific objects and functions attained by the present invention, the present invention will be described in further detail with reference to the accompanying drawings and detailed description.

Referring to fig. 1 to 12, a plastic pipe production line based on a deviation prevention function comprises a workbench 1, a lifting device 2, a first conveyor 3, a second conveyor 4 and a side guide mechanism;

the first conveyor 3 is horizontally arranged on the workbench 1, the first conveyor 3 comprises a first conveying belt 31, and lower guide rollers 32 which are distributed at equal intervals along the length direction of the first conveying belt 31 are arranged on the first conveying belt 31;

the second conveyor 4 is horizontally arranged right above the first conveyor 3 and can move up and down, the second conveyor 4 comprises a second conveying belt 41, and upper guide rollers 42 which are distributed at equal intervals along the length direction of the second conveying belt 41 are arranged on the second conveying belt 41;

the side guide mechanism is provided with a pair of side guide mechanisms arranged on two sides of the workbench 1 in a mirror image mode, the side guide mechanism comprises a folding frame 51 and a plurality of side guide rollers 52, the folding frame 51 is arranged between the first conveyor 3 and the second conveyor 4 and is hinged to one side of the first conveyor 3 and one side of the second conveyor 4 respectively, the plurality of side guide rollers 52 are distributed on the folding frame 51 at equal intervals in the horizontal direction of the workbench 1, the side guide rollers 52 horizontally face the center between the first conveyor 3 and the second conveyor 4, and the side guide mechanism further comprises a driving mechanism 53 for driving the side guide rollers 52 to move in a translation mode.

The upper guide roller 42 vertically corresponds to the lower guide roller 32, the upper guide roller 42 is used for limiting the external sliding of the upper position of the pipe, the lower guide roller 32 is used for limiting the external sliding of the lower position of the pipe, the conveying directions of the first conveyor 3 and the second conveyor 4 are the same, the upper guide roller 42 vertically corresponds to the lower guide roller 32 and limits the pipe in the conveying process, as shown in fig. 3, the pipe with a smaller diameter is guided and limited by the upper guide roller 42 and the lower guide roller 32, as shown in fig. 2, the pipe with a larger diameter passes through the upper guide roller 42 and the lower guide roller 32 to be limited, when the pipe is changed, the second conveyor 4 is lifted, meanwhile, the side guide rollers 52 are always positioned between the first conveyor 3 and the second conveyor 4 through the folding frame 51, the driving mechanism 53 drives the plurality of side guide rollers 52 to be limited, the area where the pipe with a larger diameter cannot be limited, the pipe is completely accommodated between the upper guide roller 42, the lower guide roller 32 and the two side guide rollers 52, the pipe 42 passes through the upper guide roller 42, the lower guide roller 32 and the two side guide rollers 52 in the conveying process, and the left and right sides of the pipe can be limited, and the pipe can move stably along the straight line, and the off tracking process can be prevented.

Referring to fig. 11 and 12, each of the upper guide roller 42 and the lower guide roller 32 includes a first roller frame 321 and a first rotating roller 322;

the first carrier roller frame 321 of the upper guide roller 42 is arranged on the surface of the first conveying belt 31, and the first carrier roller frame 321 of the lower guide roller 32 is arranged on the surface of the second conveying belt 41;

the first rotating roller 322 is horizontally disposed inside the first roller frame 321.

When the pipe fitting is carrying, the pipe fitting moves between the first roller 322 that changes of upper portion deflector roll 42 and lower deflector roll 32, it is spacing with the upper region in the pipe fitting transportation process to change the roller 322 through the first of upper portion deflector roll 42, it is spacing with the lower region in the pipe fitting transportation process to change the roller 322 through the first of lower deflector roll 32, the setting that can dismantle through the screw respectively on first conveyer belt 31 and second conveyer belt 41 of first bearing roller frame 321 on upper portion deflector roll 42 and the lower deflector roll 32, the later maintenance of being convenient for is changed.

Referring to fig. 1, 4 to 8, the folding leg 51 includes a transverse positioning plate 511, a first link 512 and a second link 513;

the transverse positioning plate 511 is horizontally positioned in the middle between the first conveyor 3 and the second conveyor 4, the length direction of the transverse positioning plate 511 is parallel to the conveying direction of the first conveyor 3, and the driving mechanism 53 is arranged on the transverse positioning plate 511;

the first connecting rods 512 are provided with a plurality of connecting rods and are vertically positioned above the transverse positioning plate 511, one end of each first connecting rod 512 is hinged with the top of the transverse positioning plate 511, and the other end of each first connecting rod 512 is hinged with one side of the second conveyor 4;

the second connecting rod 513 is provided with a plurality of connecting rods and is vertically positioned below the transverse positioning plate 511, one end of the second connecting rod 513 is hinged with the top of the transverse positioning plate 511, the other end of the second connecting rod 513 is hinged with one side of the first conveyor 3, and the length of the second connecting rod 513 is the same as that of the first connecting rod 512.

In the process that the second conveyor 4 moves up and down, the transverse positioning plate 511 is hinged to the second conveyor 4 and the first conveyor 3 through the first connecting rod 512 and the second connecting rod 513 respectively, so that the transverse positioning plate 511 is kept horizontal and is far away from the workbench 1 or close to the workbench 1, and all the side guide rollers 52 are driven to be far away from the workbench 1 or close to the workbench 1 at the same time, when the diameter of the pipe is small, the side guide rollers 52 move to the side of the workbench 1, and the first conveyor 3 and the second conveyor 4 are prevented from touching the side guide rollers 52.

Referring to fig. 1, 9 and 10, the driving mechanism 53 includes a sliding sleeve 531 and a sliding bar 532;

the sliding sleeve 531 is provided with a plurality of sliding sleeves which are connected to the transverse positioning plate 511 at equal intervals in a penetrating manner along the length direction of the transverse positioning plate, and one end of the sliding sleeve 531 faces to the middle between the first conveyor 3 and the second conveyor 4;

the slide bar 532 is horizontally and telescopically inserted in the sliding sleeve 531, one end of the slide bar 532 faces the middle between the first conveyor 3 and the second conveyor 4, and one end of the slide bar 532 faces the middle between the first conveyor 3 and the second conveyor 4 and is connected with the side guide roller 52.

When the side guide roller 52 moves linearly along the sliding sleeve 531 in order to prevent the side guide roller 52 from contacting the first conveyor 3 and the second conveyor 4, the side guide roller 52 is driven to translate to the side of the work table 1, and the side guide roller 52 is moved to a proper position to stop.

Referring to fig. 10, a protruding strip 5321 extending along the length direction of the sliding bar 532 is disposed outside the sliding bar 532, and a limiting groove for limiting the sliding of the protruding strip 5321 is disposed inside the sliding sleeve 531.

When the sliding bar 532 moves along the horizontal direction of the sliding sleeve 531, the protruding strips 5321 provided on the sliding bar 532 move along the limiting grooves provided on the sliding sleeve 531 in a limiting manner, so that the sliding bar 532 drives the side guide rollers 52 more stably.

Referring to fig. 1 and 11, the side guide roller 52 includes a vertical plate 521, a buffer spring 522, an axial stop sleeve 523, a second idler frame 524, and a second rotary roller 525;

the vertical plate 521 is in the end vertically disposed at the middle of the slide bar 532 between the first conveyor 3 and the second conveyor 4;

the second roller supporting frame 524 is positioned on one side of the vertical plate 521, which is far away from the sliding rod 532, a plurality of buffer columns are horizontally arranged on one side of the second roller supporting frame 524, which is close to the vertical plate 521, a through hole for each buffer column to movably pass through is formed in the vertical plate 521, and one end of each buffer column passes through the through hole and extends outwards;

the number of the axial limiting sleeves 523 is the same as that of the buffer columns, and the axial limiting sleeves are arranged at the extending ends of the buffer columns in a one-to-one correspondence manner;

the buffer spring 522 is sleeved on the buffer column, one end of the buffer spring 522 is abutted to the inner side of the second roller frame 524, and the other end of the buffer spring 522 is abutted to one side of the vertical plate 521 close to the second roller frame 524;

the second rotating roller 525 is vertically and rotatably disposed inside the second roller frame 524.

When the pipe fitting diameter is great, two second change roller 525 support and lean on the left and right sides of pipe fitting, through the mutually supporting of buffer spring 522, buffering post, riser 521 and axial stop collar 523, make second bearing roller frame 524 have elastic force, prevent that second change roller 525 from pressing from both sides when contacting with the pipe fitting.

Referring to fig. 1, 9 and 10, the driving mechanism 53 further includes a transverse push plate 533, a limiting sleeve 534 and a limiting polished rod 535;

the transverse push plate 533 is horizontally positioned on one side of the transverse positioning plate 511 away from the third guide roller, and the transverse push plate 533 is arranged in parallel with the transverse positioning plate 511;

the limiting polished rod 535 is at least provided with a pair of limiting polished rods 535 which are arranged at two ends of the transverse positioning plate 511 in parallel, and the axis of the limiting polished rod 535 is vertical to the length direction of the transverse push plate 533;

the number of the limiting sleeves 534 is the same as that of the limiting polished rods 535, and the limiting polished rods 535 are correspondingly communicated with the transverse push plates 533 one by one, and one end of the limiting polished rod 535 is movably inserted into the inner ring of the limiting sleeves 534.

When a plurality of side guide rollers 52 need to be adjusted simultaneously, all the sliding rods 532 can be driven to move along the sliding sleeves 531 simultaneously by pushing the transverse pushing plate 533, and the corresponding side guide rollers 52 are driven to move simultaneously by the sliding rods 532, so that the technical problem of adjusting a plurality of side guide rollers 52 simultaneously is solved.

Referring to fig. 1 and 8, the driving mechanism 53 further includes a connecting plate 536, a lead screw driver 537, and a third connecting rod 538;

the connecting plate 536 is vertically arranged in the middle of the transverse positioning plate 511, and the screw rod driver 537 is vertically arranged on the connecting plate 536;

the third connecting rod 538 is vertically positioned above the transverse push plate 533, one end of the third connecting rod 538 is hinged to the top of the transverse push plate 533, and the other end of the third connecting rod 538 is hinged to the working end of the screw rod driver 537.

When the horizontal push plate 533 needs to be pushed, the working end of the screw rod driver 537 moves downward, the working end of the screw rod driver 537 drives the third connecting rod 538 to move downward at the same time, at this time, the other end of the third connecting rod 538 drives the horizontal push plate 533, the transverse rod and the lateral guide roller 52 move parallel to the side of the workbench 1, when the working end of the screw rod driver 537 drives the third connecting rod 538 to move upward at the same time, the other end of the third connecting rod 538 drives the horizontal push plate 533, and the transverse rod and the lateral guide roller 52 move parallel to the position in the positive direction of the workbench 1.

Referring to fig. 1, 4 and 5, each corner of the working table 1 is provided with a hydraulic push rod 21 arranged vertically, and an output end of each hydraulic push rod 21 is fixedly connected with each corner of the second conveyor 4.

When the distance between the upper guide roller 42 and the lower guide roller 32 needs to be adjusted, the second conveyor 4 is driven to move upwards or downwards by the working end of the hydraulic push rod 21.

Referring to fig. 11 and 12, the first roller and the second roller are integrally formed by two cones arranged in a mirror image, and the reduced ends of the two cones are connected with each other.

Through the cooperation of two cones, form a cross-section and be the recess of V type, when the pipe fitting centre gripping, the pipe fitting of different diameters all can form a cross-section through two cones and realize spacingly for the recess of V type.

This application is mutually supported through folding leg 51, actuating mechanism 53 and lateral part deflector roll 52, can be spacing the quick the carrying on of the great pipe fitting of diameter, avoids great pipe fitting off tracking in transportation process, improves the precision that the pipe fitting was carried.

The above examples only show one or more embodiments of the present invention, and the description is specific and detailed, but not construed as limiting the scope of the present invention. It should be noted that various changes and modifications can be made by those skilled in the art without departing from the spirit of the invention, and these changes and modifications are all within the scope of the invention. Therefore, the protection scope of the present patent shall be subject to the appended claims.

Claims

1. A plastic pipe production line based on an anti-deviation function is characterized by comprising a workbench (1), a lifting device (2), a first conveyor (3), a second conveyor (4) and a side guide mechanism;

the first conveyor (3) is horizontally arranged on the workbench (1), the first conveyor (3) comprises a first conveying belt (31), and lower guide rollers (32) which are distributed at equal intervals along the length direction of the first conveying belt (31) are arranged on the first conveying belt (31);

the second conveyor (4) is horizontally arranged right above the first conveyor (3) and can move up and down, the second conveyor (4) comprises a second conveying belt (41), and upper guide rollers (42) which are distributed at equal intervals along the length direction of the second conveying belt (41) are arranged on the second conveying belt (41);

the side guide mechanism is provided with a pair of side guide mechanisms and is arranged on two sides of the workbench (1) in a mirror image mode, each side guide mechanism comprises a folding frame (51) and a plurality of side guide rollers (52), each folding frame (51) is arranged between the first conveyor (3) and the second conveyor (4) and is hinged to one side of the first conveyor (3) and one side of the second conveyor (4) respectively, the plurality of side guide rollers (52) are distributed on the folding frames (51) at equal intervals in the horizontal direction of the workbench (1), each side guide roller (52) horizontally faces to the center between the first conveyor (3) and the second conveyor (4), and each side guide mechanism further comprises a driving mechanism (53) for driving the corresponding side guide roller (52) to move in a translation mode.

2. The production line of plastic pipes based on the deviation-preventing function is characterized in that the upper guide roller (42) and the lower guide roller (32) comprise a first roller frame (321) and a first rotating roller (322);

the first roller frame (321) of the upper guide roller (42) is arranged on the surface of the first conveying belt (31), and the first roller frame (321) of the lower guide roller (32) is arranged on the surface of the second conveying belt (41);

the first rotating roller (322) is horizontally arranged in the first roller carrier frame (321).

3. The plastic pipe production line based on the deviation preventing function as claimed in claim 1, wherein the folding frame (51) comprises a transverse positioning plate (511), a first connecting rod (512) and a second connecting rod (513);

the transverse positioning plate (511) is horizontally positioned in the middle between the first conveyor (3) and the second conveyor (4), the length direction of the transverse positioning plate (511) is parallel to the conveying direction of the first conveyor (3), and the driving mechanism (53) is arranged on the transverse positioning plate (511);

the first connecting rods (512) are provided with a plurality of connecting rods which are vertically positioned above the transverse positioning plate (511), one end of each first connecting rod (512) is hinged with the top of the transverse positioning plate (511), and the other end of each first connecting rod (512) is hinged with one side of the second conveyor (4);

the second connecting rod (513) is provided with a plurality of connecting rods and is vertically positioned below the transverse positioning plate (511), one end of the second connecting rod (513) is hinged to the top of the transverse positioning plate (511), the other end of the second connecting rod (513) is hinged to one side of the first conveyor (3), and the length of the second connecting rod (513) is the same as that of the first connecting rod (512).

4. The plastic pipe production line based on the deviation preventing function as claimed in any one of claims 1 or 3, wherein the driving mechanism (53) comprises a sliding sleeve (531) and a sliding rod (532);

the sliding sleeves (531) are provided with a plurality of sliding sleeves which are connected to the transverse positioning plates (511) at equal intervals along the length direction of the transverse positioning plates, and one ends of the sliding sleeves (531) face to the middle between the first conveyor (3) and the second conveyor (4);

the sliding rod (532) is horizontally inserted in the sliding sleeve (531) in a telescopic mode, one end of the sliding rod (532) faces to the middle between the first conveyor (3) and the second conveyor (4), and one end of the sliding rod (532) faces to the middle between the first conveyor (3) and the second conveyor (4) is connected with the side guide roller (52).

5. The plastic pipe production line based on the deviation preventing function as claimed in claim 4, wherein a protruding strip (5321) extending along the length direction of the sliding rod (532) is arranged outside the sliding rod (532), and a limiting groove for limiting and sliding the protruding strip (5321) is arranged inside the sliding sleeve (531).

6. The plastic pipe production line based on the deviation prevention function as claimed in claim 4, wherein the side guide rollers (52) comprise vertical plates (521), buffer springs (522), axial limiting sleeves (523), a second roller carrier (524) and a second rotating roller (525);

the vertical plate (521) is vertically arranged at the tail end of the sliding rod (532) facing the middle between the first conveyor (3) and the second conveyor (4);

the second roller supporting frame (524) is positioned on one side of the vertical plate (521) far away from the sliding rod (532), a plurality of buffer columns which are horizontally arranged are arranged on one side of the second roller supporting frame (524) close to the vertical plate (521), a through hole for each buffer column to movably pass through is formed in the vertical plate (521), and one end of each buffer column passes through the through hole and extends outwards;

the number of the axial limiting sleeves (523) is the same as that of the buffer columns, and the axial limiting sleeves and the buffer columns are arranged at the extending ends of the buffer columns in a one-to-one correspondence manner;

the buffer spring (522) is sleeved on the buffer column, one end of the buffer spring (522) is abutted to the inner side of the second roller carrier frame (524), and the other end of the buffer spring (522) is abutted to one side, close to the second roller carrier frame (524), of the vertical plate (521);

the second rotating roller (525) is vertically arranged in the second roller carrier frame (524) in a rotatable mode.

7. The plastic pipe production line based on the deviation prevention function as claimed in claim 3, wherein the driving mechanism (53) further comprises a transverse push plate (533), a limiting sleeve (534) and a limiting polished rod (535);

the transverse push plate (533) is horizontally positioned on one side of the transverse positioning plate (511) far away from the third guide roller, and the transverse push plate (533) is arranged in parallel with the transverse positioning plate (511);

the limiting polished rods (535) are at least provided with a pair of limiting polished rods (535) which are arranged at two ends of the transverse positioning plate (511) in parallel, and the axes of the limiting polished rods (535) are vertical to the length direction of the transverse push plate (533);

the number of the limiting sleeves (534) is the same as that of the limiting polished rods (535), the limiting polished rods (535) are correspondingly communicated with the transverse push plates (533), and one end of each limiting polished rod (535) is movably inserted into the inner ring of each limiting sleeve (534).

8. The plastic pipe production line based on the deviation preventing function as claimed in claim 7, wherein the driving mechanism (53) further comprises a connecting plate (536), a lead screw driver (537) and a third connecting rod (538);

the connecting plate (536) is vertically arranged in the middle of the transverse positioning plate (511), and the screw rod transmission machine (537) is vertically arranged on the connecting plate (536);

the third connecting rod (538) is vertically located above the transverse pushing plate (533), one end of the third connecting rod (538) is hinged to the top of the transverse pushing plate (533), and the other end of the third connecting rod (538) is hinged to the working end of the screw rod transmission machine (537).

9. The plastic pipe production line based on the deviation preventing function is characterized in that a hydraulic push rod (21) is vertically arranged at each corner of the workbench (1), and the output end of each hydraulic push rod (21) is fixedly connected with each corner of the second conveyor (4).

10. The plastic pipe production line based on the deviation preventing function as claimed in claim 1, wherein the first roller and the second roller are integrally formed by two cones which are arranged in a mirror image manner, and the reduced ends of the two cones are connected with each other.