CN216862831U - Feeding and distributing device for laser pipe cutting machine - Google Patents

Abstract

The utility model relates to a feeding and distributing device for a laser pipe cutting machine, which comprises an annular first chain conveying assembly, an annular second chain conveying assembly and a distributing assembly, wherein the first chain conveying assembly is arranged on the upper side of the feeding and distributing device; the material distributing assemblies are arranged on the outer side of the first chain conveying assembly at equal intervals, and the outer side surfaces of the material distributing assemblies form supporting surfaces of the tubes conveyed by the first chain conveying assembly; the material distributing assembly comprises a manual adjusting block capable of rotating between a horizontal position and a vertical position, and when the manual adjusting block is located at the vertical position, the tubes located on the first chain conveying assembly can be separated. The discharge end of the first chain conveying component and the feed end of the second chain conveying component are arranged in an overlapping mode, and the upper surface of the second chain conveying component is higher than that of the first chain conveying component. The feeding and distributing device is high in inclusibility, and pipes of different types and lengths can be conveniently and efficiently transported.

Description

Feeding and distributing device for laser pipe cutting machine

Technical Field

The utility model relates to the technical field of laser pipe cutting machines, in particular to a feeding and distributing device for a laser pipe cutting machine.

Background

The laser pipe cutting machine has the characteristics of high precision, quick cutting, no limitation to cutting patterns, smooth cut, low processing cost and the like, and gradually replaces the traditional pipe cutting process equipment. In the automatic processing and feeding process, feeding and distributing pipes of different types and specifications are an important link in the whole feeding system, but no pipe feeding and distributing device capable of adapting to different types and specifications exists at present.

Therefore, it is highly desirable to provide a feeding and distributing device for a laser pipe cutting machine, which can adapt to different types and specifications of pipes.

SUMMERY OF THE UTILITY MODEL

Technical problem to be solved

In view of the above disadvantages and shortcomings of the prior art, the present invention provides a feeding and separating device for a laser pipe cutting machine, which solves the technical problem that the existing pipe feeding and separating device cannot adapt to pipes of different types and specifications.

(II) technical scheme

In order to achieve the purpose, the utility model adopts the main technical scheme that:

the embodiment of the utility model provides a feeding and distributing device for a laser pipe cutting machine, which comprises an annular first chain conveying assembly and a distributing assembly, wherein the first chain conveying assembly is arranged on the upper side of the feeding and distributing assembly;

the material distribution components are arranged on the outer side of the first chain conveying component at equal intervals, and the outer side surface of the material distribution component forms a supporting surface of the pipe transported by the first chain conveying component;

the material distributing assembly comprises a manual adjusting block capable of rotating between a horizontal position and a vertical position, and when the manual adjusting block is located at the vertical position, the tubes located on the first chain conveying assembly can be separated.

Optionally, the conveying device further comprises an annular second chain conveying assembly, the discharge end of the first chain conveying assembly and the feed end of the second chain conveying assembly are arranged in an overlapping mode, and the upper surface of the second chain conveying assembly is higher than that of the first chain conveying assembly.

Optionally, the material distribution assembly further comprises a supporting block, a rotating shaft and a limiting structure, wherein a square notch is formed in one end of the supporting block, one end of the manual adjusting block is installed at the square notch through the rotating shaft and can rotate between the horizontal position and the vertical position around the rotating shaft, and the limiting structure is used for limiting rotation of the manual adjusting block to enable the manual adjusting block to be kept at the horizontal position or the vertical position.

Optionally, limit structure includes: the top shaft and a spring sleeved on the top shaft;

a through hole is formed in the supporting block along the length direction of the supporting block, the through hole penetrates through the square notch, the jacking shaft penetrates through the through hole, one end of the jacking shaft penetrates through the through hole, and the other end of the jacking shaft can be inserted into a limiting hole of the manual adjusting block so as to limit the manual adjusting block;

the through hole is a step hole, the diameter of a round hole close to the manual adjusting block in the step hole is larger than that of a round hole far away from the manual adjusting block, one end of the spring is abutted to the head of the second end of the top shaft, and the other end of the spring is abutted to the step surface of the step hole.

Optionally, the limiting hole comprises a first limiting hole and a second limiting hole, wherein the axes of the first limiting hole and the second limiting hole are orthogonally arranged;

when the top shaft is inserted into the first limiting hole, the manual adjusting block is in a horizontal position;

when the jacking shaft is inserted into the second limiting hole, the manual adjusting block is in a vertical position.

Optionally, the first chain conveying assembly comprises a first chain which is annularly arranged, and the first chain is formed by connecting a plurality of chain links with each other;

the chain link comprises a pin shaft, a roller and an L-shaped outer chain plate;

the pair of L-shaped outer chain plates are oppositely arranged and sleeved on the pin shaft, and the pair of rollers are sleeved on the pin shaft and positioned on the outer sides of the pair of L-shaped outer chain plates;

the material distributing assembly is fixedly arranged on the pair of L-shaped outer chain plates;

the second chain conveying assembly comprises a second chain which is arranged in an annular mode, and the outer side surface of the second chain forms a supporting surface of the pipe conveyed by the second chain conveying assembly.

Optionally, the feeding and distributing device further comprises a feeding support frame;

the first chain conveying assembly also comprises a first transmission shaft, a first driving chain wheel, a first driven chain wheel, a first chain shaft and a first motor; the first motor is connected with a first transmission shaft through a speed reducer, the first transmission shaft penetrates through the middle part of the feeding support frame and forms a rotary support for the first transmission shaft through the feeding support frame, a first driving chain wheel is fixedly installed on the first transmission shaft, a first driven chain wheel is rotatably connected with a first chain shaft through a bearing, two ends of the first chain shaft are movably connected with the front end of the feeding support frame through chain tensioning structures, and a first chain is meshed with the first driving chain wheel and the first driven chain wheel;

the second chain conveying assembly also comprises a second transmission shaft, a second driving chain wheel, a second driven chain wheel, a second chain shaft and a second motor; the second motor is connected with the second transmission shaft through the speed reducer, the second transmission shaft penetrates through the middle of the feeding support frame and forms a rotating support for the second transmission shaft through the feeding support frame, the second driving sprocket is fixedly mounted on the second transmission shaft, the second driven sprocket is rotatably connected with the second chain shaft through a bearing, two ends of the second chain shaft are movably connected with the rear end of the feeding support frame through a chain tensioning structure, and the second chain is meshed with the second driving sprocket and the second driven sprocket.

Optionally, the chain tensioning structure comprises a threaded draw rod and a draw rod nut;

the front end of the feeding support frame is provided with a first chain shaft, two ends of the first chain shaft are provided with kidney-shaped holes, the feeding support frame is provided with a first fixing plate between the first chain shaft and the first transmission shaft, the first fixing plate is connected with one end of a threaded pull rod, the other end of the threaded pull rod penetrates through the kidney-shaped holes in the first chain shaft, and a pull rod nut is screwed on the threaded pull rod and used for adjusting the distance between the first chain shaft and the first fixing plate;

the second chain axle is installed to the rear end of material loading support frame, and some kidney-shaped holes are seted up at the both ends of second chain axle, are provided with the second fixed plate on the material loading support frame between second chain axle and second transmission shaft, and the second fixed plate is connected with the one end of belted wire pull rod, and the other end of belted wire pull rod passes the epaxial kidney-shaped hole of second chain, and the belted wire pull rod is screwed up and is twisted there is the pull rod nut for the distance between adjustment second chain axle and the second fixed plate.

Optionally, a first sensor and a second sensor for detecting the position of the pipe are further included;

the feeding support frame is provided with a first sensor at the discharge end of the first chain conveying assembly through a support and used as an induction device for starting and stopping the first motor; and a second sensor is arranged on the side surface of the feeding support frame at the discharge end of the second chain conveying assembly through a support and is used as an induction device for starting and stopping the second motor.

Optionally, a first baffle is arranged at the position of the feeding end of the first chain conveying assembly on the feeding support frame, and an included angle between the inner side surface of the first baffle and the upper surface of the first chain conveying assembly is 140-160 degrees;

the feeding support frame is provided with a second baffle at the discharge end of the second chain conveying assembly, and the included angle between the inner side surface of the second baffle and the upper surface of the second chain conveying assembly is 140-160 degrees.

(III) advantageous effects

The utility model has the beneficial effects that: the feeding and distributing device for the laser pipe cutting machine comprises an annular first chain conveying assembly and a distributing assembly; the material distributing assemblies are arranged on the outer side of the first chain conveying assembly at equal intervals, and the outer side surfaces of the material distributing assemblies form supporting surfaces of the tubes conveyed by the first chain conveying assembly; divide the material subassembly including can be between horizontal position and vertical position rotatory manual regulating block, when manual regulating block is in vertical position, can separate the tubular product that is located on the first chain conveyor components, for prior art, it is high to the inclusion of tubular product type and size, can be conveniently used for transporting the tubular product of different grade type and length high-efficiently, and can effectively prevent tubular product alternately, and can make things convenient for the rectangular pipe, square pipe, whole row's material loading such as runway pipe, can not take place in disorder, thereby effectively prevent that adjacent tubular product from colliding with, the fish tail surface.

Drawings

FIG. 1 is a schematic perspective view of a feeding and distributing device for a laser pipe cutter of the present invention;

fig. 2 is an enlarged schematic view of the feeding and distributing device in fig. 1 at a;

FIG. 3 is an exploded view of the dispensing assembly 3 of FIG. 2;

FIG. 4 is a perspective view of the dispensing assembly 3 of FIG. 2;

FIG. 5 is an enlarged schematic view of the feed and feed divider of FIG. 1 at C showing the second drive shaft and the second drive sprocket of the second chain transport assembly;

FIG. 6 is an enlarged schematic view of the feed and distribution device of FIG. 1 at B showing the first chain shaft and the first driven sprocket of the first chain transport assembly;

FIG. 7 is an enlarged schematic view of the feed and distribution device of FIG. 1 at D showing a second chain shaft and a second driven sprocket of the second chain transport assembly;

fig. 8 is an enlarged schematic view of the feed and feed divider of fig. 1 at E showing a second sensor, a second chain shaft of the second chain transport assembly, and a second driven sprocket.

[ description of reference ]

1: a feeding support frame; 2: a first chain conveying assembly; 3: a material distributing component; 4: a first chain axle; 5: a first drive sprocket; 6: a first driven sprocket; 7: a first drive shaft; 8: a second chain conveying assembly; 9: a first baffle plate; 10: a bearing with a square seat; 11: a bearing; 12: a second drive sprocket; 13: a first fixing plate; 14: a kidney-shaped hole; 15: a wire-drawing rod; 16: a draw rod nut; 17: a support; 18: a first sensor; 19: a second sensor; 20: a second baffle; 21: a second drive shaft; 22: a second chain axle; 23: a second driven sprocket; 24: a second fixing plate;

301: a top shaft; 302: a support block; 303: a spring; 304: a manual adjusting block; 305: a rotating shaft; 306: a pin shaft; 307: a roller; 308: an L-shaped outer link plate; 309: a through hole; 310: a first limit hole; 311: a second limiting hole.

Detailed Description

For the purpose of better explaining the present invention and to facilitate understanding, the present invention will be described in detail by way of specific embodiments with reference to the accompanying drawings. As used herein, the terms "upper," "lower," "left," "right," "front," "back," and the like are used with reference to the orientation of FIG. 1.

Referring to fig. 1, 2, 5 and 7, the present embodiment provides a feeding and distributing device for a laser pipe cutting machine, which includes a feeding support frame 1, an annular first chain conveying assembly 2, a distributing assembly 3, and an annular second chain conveying assembly 8. The material distributing assemblies 3 are arranged on the outer side of the first chain conveying assembly 2 at equal intervals, and the outer side surfaces of the material distributing assemblies 3 form supporting surfaces of the pipes conveyed by the first chain conveying assembly 2.

Install first chain conveyor components 2 and second chain conveyor components 8 on the material loading support frame 1, the discharge end of first chain conveyor components 2 and the feed end part of second chain conveyor components 8 overlap to the upper surface of second chain conveyor components 8 is a little higher than the upper surface of first chain conveyor components 2. When the first chain conveying assembly 2 conveys the pipe to the overlapping area, the second chain conveying assembly 8 can carry the pipe to move towards the rear end of the feeding support frame 1 through friction force.

Specifically, the first chain conveying assembly 2 includes a first transmission shaft 7, a first drive sprocket 5, a first driven sprocket 6, a first chain shaft 4, a first chain, and a first motor. The first motor is connected with a first transmission shaft 7 through a speed reducer, the first transmission shaft 7 penetrates through the middle of the feeding support frame 1, and a rotary support for the first transmission shaft 7 is formed by the feeding support frame 1, a first driving sprocket 5 is fixedly installed on the first transmission shaft 7, a first driven sprocket 6 is rotatably connected with a first chain shaft 4 through a bearing 11, two ends of the first chain shaft 4 are movably connected with the front end of the feeding support frame 1 through a chain tensioning structure, and a first chain is meshed with the first driving sprocket 5 and the first driven sprocket 6. Further, a shaft retaining ring is provided between the first chain shaft 4 and the bearing 11, and a hole retaining ring is provided between the bearing 11 and the first driven sprocket 6.

The second chain conveying assembly 8 includes a second transmission shaft 21, a second drive sprocket 12, a second driven sprocket 23, a second chain shaft 22, a second chain and a second motor. The second motor is connected with a second transmission shaft 21 through a speed reducer, the second transmission shaft 21 penetrates through the middle of the feeding support frame 1, the feeding support frame 1 forms a rotary support for the second transmission shaft 21, a second driving sprocket 12 is fixedly mounted on the second transmission shaft 21, a second driven sprocket 23 is rotatably connected with a second chain shaft 22 through a bearing 11, two ends of the second chain shaft 22 are movably connected with the rear end of the feeding support frame 1 through a chain tensioning structure, and a second chain is meshed with the second driving sprocket 12 and the second driven sprocket 23. Further, a shaft stopper is provided between the first chain shaft 4 and the bearing 11, and a hole stopper is provided between the bearing 11 and the second driven sprocket 23.

In this embodiment, square bearings 11 are disposed between the first and second transmission shafts 7 and 21 and the loading support frame 1, and the square bearings 11 are used for fixing the rotation axes of the first and second transmission shafts 7 and 21 and reducing the friction between the first and second transmission shafts 7 and 21 and the loading support frame 1. In addition, an expansion sleeve is arranged between the first transmission shaft 7 of the first chain conveying assembly 2 and the main first driving chain wheel 5, and an expansion sleeve is arranged between the second transmission shaft 21 of the second chain conveying assembly 8 and the second driving chain wheel 12.

As shown in fig. 3 and 4, the material distributing assembly 3 includes: support block 302, manual regulating block 304, rotation axis 305 and limit structure. The square incision has been seted up to the one end of supporting shoe 302, and the one end of manual regulating block 304 is installed at square incision department through rotation axis 305 to can rotate between horizontal position and vertical position, limit structure is used for restricting the rotation of manual regulating block 304, makes manual regulating block 304 keep at horizontal position or vertical position. It should be noted that, in the horizontal position, the manual adjusting block 304 and the supporting block 302 form an included angle of 180 degrees, and in the vertical position, the manual adjusting block 304 and the supporting block 302 form an included angle of 90 degrees, which is used for separating adjacent pipes to be processed.

Further, limit structure includes: a top shaft 301 and a spring 303 sleeved on the top shaft 301. The supporting shoe 302 is internally provided with a through hole 309 along the length direction thereof, the through hole 309 penetrates to the square notch, one end of the top shaft 301 penetrates through the through hole 309, and the other end can be inserted into a limiting hole of the manual adjusting block 304 so as to limit the manual adjusting block 304.

The through hole 309 is a step hole, the diameter of a round hole close to the manual adjusting block 304 in the step hole is larger than that of a round hole far away from the manual adjusting block 304, one end of the spring 303 is abutted against the head of the top shaft 301, and the other end of the spring is abutted against the step surface of the step hole.

The limiting holes comprise a first limiting hole 310 and a second limiting hole 311 which are arranged in an axis orthogonal mode. When the head of the top shaft 301 is inserted into the first limiting hole 310, the manual adjusting block 304 is in a horizontal position; when the head of the top shaft 301 is inserted into the second stopper hole 311, the manual adjustment block 304 is in a vertical position.

For pipes with different sizes, the manual adjusting blocks 304 which are separated by corresponding distances can be manually adjusted according to requirements, and the manual adjusting blocks 304 which form an included angle of 90 degrees with the first chain separate the adjacent pipes to be processed.

In this embodiment, the first chain is arranged in a ring shape and is formed by connecting a plurality of chain links. The chain link includes: a pin 306, a roller 307 and an L-shaped outer chain plate 308. The pair of L-shaped outer link plates 308 are oppositely arranged and sleeved on the pin shaft 306, and the pair of rollers 307 are sleeved on the pin shaft 306 and positioned outside the pair of L-shaped outer link plates 308; the material distributing component 3 is fixedly arranged on a pair of L-shaped outer chain plates 308. The feeding support frame 1 is fixedly provided with a bearing plate on the inner side of an annular first chain, and the first chain rolls on the bearing plate through a roller 307 and is used for transporting pipes.

As shown in fig. 6, the chain tensioning structure includes a tie rod 15 with wire and a tie rod nut 16.

First chain axle 4 is installed to the front end of material loading support frame 1, and kidney-shaped hole 14 has been seted up at the both ends of first chain axle 4, is provided with first fixed plate 13 between first chain axle 4 of material loading support frame 1 and the first transmission shaft 7, and first fixed plate 13 is connected with the one end of taking silk pull rod 15, and the other end of taking silk pull rod 15 passes kidney-shaped hole 14 on the first chain axle 4. A tension rod nut 16 is screwed onto the threaded tension rod 15 for adjusting the distance between the first chain axle 4 and the first fixing plate 13 and thus the first chain tension.

Referring to fig. 7 and 8, a second chain shaft 22 is installed at the rear end of the feeding support frame 1, two ends of the second chain shaft 22 are provided with kidney-shaped holes 14, a second fixing plate 24 is arranged between the second chain shaft 22 and the second transmission shaft 21 of the feeding support frame 1, the second fixing plate 24 is connected with one end of the threaded pull rod 15, and the other end of the threaded pull rod 15 penetrates through the kidney-shaped holes 14 of the second chain shaft 22. The tension rod nut 16 is screwed onto the wire tension rod 15 for adjusting the distance between the second chain axle 22 and the second fixing plate 24, and thus the second chain tension.

The feeding support frame 1 is provided with a first baffle 9 at the feeding end of the first chain conveying component 2, and an included angle between the inner side surface of the first baffle 9 and the upper surface of the first chain conveying component 2 is 140-160 degrees, so as to prevent the pipe from sliding off the first chain conveying component 2; the feeding support frame 1 is provided with a second baffle 20 at the discharge end of the second chain conveying assembly 8, and an included angle between the inner side surface of the second baffle 20 and the upper surface of the second chain conveying assembly 8 is 140-160 degrees, so as to prevent the tube from sliding off the second chain conveying assembly 8. Preferably, the included angle between the inner side surface of the first baffle 9 at the feeding end of the first chain conveying assembly 2 and the upper surface of the first chain conveying assembly 2 is 150 °, and the included angle between the inner side surface of the second baffle 20 at the discharging end of the second chain conveying assembly 8 and the upper surface of the second chain conveying assembly 8 is 150 °.

As shown in fig. 1 and 8, the feeding and separating device further includes a first sensor 18 and a second sensor 19 for detecting the pipes. A first sensor 18 is arranged on the side surface of the feeding support frame 1 at the discharge end of the first chain conveying assembly 2 through a support 17 and serves as an induction device for starting and stopping a first motor; and a second sensor 19 is arranged on the side surface of the feeding support frame 1 at the discharge end of the second chain conveying assembly 8 through a support 17 and is used as an induction device for starting and stopping the second motor.

The working process of the feeding and distributing device for the laser pipe cutting machine is as follows: when the feeding and distributing device works, the manual adjusting blocks 304 of the distributing component 3 are adjusted to be vertical positions at certain intervals on the first chain conveying component 2 according to the size of a pipe. The pipe to be processed is placed at the neutral position between the manual adjusting blocks 304 one by one through a forklift or a travelling crane, the first motor is connected with the reducer to drive the first transmission shaft 7 to rotate, the first driving sprocket 5 is connected with the first transmission shaft 7 through the expansion sleeve and drives the first chain of the first chain conveying assembly 2 to rotate, when the first chain conveying assembly 2 drives the pipe to be processed to move forwards to the position of the first sensor 18, the pipe to be processed performs deceleration movement and stops after moving for a pipe diameter distance, meanwhile, the second chain conveying assembly 8 synchronously rotates when the pipe to be processed triggers the first sensor 18, the manual adjusting block 304 on the first chain conveying assembly 2 shifts the pipe to be processed to the second chain conveying assembly 8, the second motor drives the second chain of the second chain conveying assembly 8 to rotate, the second chain rotates and drives the pipe to be processed to move to the tail end of the material supporting frame 1, after the second sensor 19 at the tail part senses the pipe to be processed, the second chain conveying assembly 8 stops after continuously running for 2 seconds. The second baffle 20 prevents the pipe to be processed from sliding off the second chain conveying assembly 8 and plays a role in aligning the pipe to be processed. And subsequently, the pipe to be processed is conveyed to a laser pipe cutting machine by a carrier roller for processing.

In the description of the present invention, it is to be understood that the terms "first", "second" and the like are used for descriptive purposes only and are not to be construed as indicating or implying relative importance or implying any number of technical features indicated. Thus, a feature defined as "first" or "second" may explicitly or implicitly include one or more of that feature. In the description of the present invention, "a plurality" means two or more unless specifically defined otherwise.

Although embodiments of the present invention have been shown and described above, it should be understood that the above embodiments are illustrative and not restrictive, and that those skilled in the art may make changes, modifications, substitutions and alterations to the above embodiments without departing from the scope of the present invention.

Claims (10)

1. The utility model provides a pay-off feed divider for laser pipe cutting machine which characterized in that: comprises a first annular chain conveying assembly (2) and a material distributing assembly (3);

the material distributing assemblies (3) are arranged on the outer side of the first chain conveying assembly (2) at equal intervals, and the outer side surfaces of the material distributing assemblies (3) form supporting surfaces of the tubes conveyed by the first chain conveying assembly (2);

the material distributing assembly (3) comprises a manual adjusting block (304) capable of rotating between a horizontal position and a vertical position, and when the manual adjusting block (304) is in the vertical position, the tubes on the first chain conveying assembly (2) can be separated.

2. The feed divider of claim 1, wherein: the conveying device is characterized by further comprising an annular second chain conveying assembly (8), wherein the discharging end of the first chain conveying assembly (2) and the feeding end of the second chain conveying assembly (8) are arranged in an overlapped mode, and the upper surface of the second chain conveying assembly (8) is higher than that of the first chain conveying assembly (2).

3. The feed divider of claim 1, wherein: the material distributing assembly (3) further comprises a supporting block (302), a rotating shaft (305) and a limiting structure, wherein a square cut is formed in one end of the supporting block (302), one end of the manual adjusting block (304) is installed at the square cut through the rotating shaft (305) and can rotate around the rotating shaft (305) between the horizontal position and the vertical position, and the limiting structure is used for limiting the rotation of the manual adjusting block (304) to enable the manual adjusting block (304) to be kept at the horizontal position or the vertical position.

4. The feed divider of claim 3, wherein: the limit structure comprises: the device comprises a top shaft (301) and a spring (303) sleeved on the top shaft (301);

a through hole (309) is formed in the supporting block (302) along the length direction of the supporting block, the through hole (309) penetrates through the square notch, one end of the top shaft (301) penetrates through the through hole (309), and the other end of the top shaft can be inserted into a limiting hole of the manual adjusting block (304) so as to limit the manual adjusting block (304);

through-hole (309) are the step hole, the round hole aperture that is close to manual regulating block (304) in the step hole is greater than the round hole aperture of keeping away from manual regulating block (304), spring (303) one end with the head butt of the second end of apical axis (301), the other end and the step face butt in step hole.

5. The feed divider of claim 4, wherein: the limiting hole comprises a first limiting hole (310) and a second limiting hole (311) which are arranged in an axis orthogonal mode;

when the top shaft (301) is inserted into the first limiting hole (310), the manual adjusting block (304) is in a horizontal position;

when the top shaft (301) is inserted into the second limiting hole (311), the manual adjusting block (304) is in a vertical position.

6. The feed divider of claim 2, wherein: the first chain conveying assembly (2) comprises a first chain which is annularly arranged, and the first chain is formed by mutually connecting a plurality of chain links;

the chain link comprises a pin shaft (306), a roller (307) and an L-shaped outer chain plate (308);

the pair of L-shaped outer chain plates (308) are oppositely arranged and sleeved on the pin shaft (306), and the pair of rollers (307) are sleeved on the pin shaft (306) and positioned on the outer sides of the pair of L-shaped outer chain plates (308);

the material distribution assembly (3) is fixedly arranged on the pair of L-shaped outer chain plates (308);

the second chain conveying assembly (8) comprises a second chain which is arranged in an annular mode, and the outer side surface of the second chain forms a supporting surface of the pipe transported by the second chain conveying assembly (8).

7. The feed divider of claim 6, wherein: the feeding and distributing device also comprises a feeding support frame (1);

the first chain conveying assembly (2) further comprises a first transmission shaft (7), a first driving chain wheel (5), a first driven chain wheel (6), a first chain shaft (4) and a first motor; the first motor is connected with a first transmission shaft (7) through a speed reducer, the first transmission shaft (7) penetrates through the middle of the feeding support frame (1) and forms a rotary support for the first transmission shaft (7) through the feeding support frame (1), the first driving chain wheel (5) is fixedly installed on the first transmission shaft (7), the first driven chain wheel (6) is rotatably connected with the first chain shaft (4) through a bearing (11), two ends of the first chain shaft (4) are movably connected with the front end of the feeding support frame (1) through a chain tensioning structure, and the first chain is meshed with the first driving chain wheel (5) and the first driven chain wheel (6);

the second chain conveying assembly (8) further comprises a second transmission shaft (21), a second driving chain wheel (12), a second driven chain wheel (23), a second chain shaft (22) and a second motor; the second motor passes through the reduction gear and is connected with second transmission shaft (21), the middle part of material loading support frame (1) is passed in second transmission shaft (21), and by material loading support frame (1) forms the rotation support to second transmission shaft (21), second drive sprocket (12) fixed mounting be in on second transmission shaft (21), second driven sprocket (23) are connected through bearing (11) and second chain axle (22) rotation, the both ends of second chain axle (22) pass through chain tensioning structure with the rear end swing joint of material loading support frame (1), the second chain with second drive sprocket (12) and second driven sprocket (23) meshing.

8. The feed divider of claim 7, wherein: the chain tensioning structure comprises a threaded pull rod (15) and a pull rod nut (16);

the front end of the feeding support frame (1) is provided with the first chain shaft (4), two ends of the first chain shaft (4) are provided with waist-shaped holes (14), the feeding support frame (1) is provided with a first fixing plate (13) between the first chain shaft (4) and the first transmission shaft (7), the first fixing plate (13) is connected with one end of a threaded pull rod (15), the other end of the threaded pull rod (15) penetrates through the waist-shaped holes (14) in the first chain shaft (4), and a pull rod nut (16) is screwed on the threaded pull rod (15) and used for adjusting the distance between the first chain shaft (4) and the first fixing plate (13);

the rear end of material loading support frame (1) is installed second chain axle (22), some waist type holes (14) are seted up at the both ends of second chain axle (22), be provided with second fixed plate (24) on material loading support frame (1) between second chain axle (22) and second transmission shaft (21), second fixed plate (24) are connected with the one end of taking silk pull rod (15), waist type hole (14) on second chain axle (22) are passed to the other end of taking silk pull rod (15), take silk pull rod (15) to go up to twist and have draw bar nut (16), be used for adjusting second chain axle (22) with the distance between second fixed plate (24).

9. The feed divider of claim 7, wherein: further comprising a first sensor (18) and a second sensor (19) for detecting the position of the pipe;

a first sensor (18) is arranged on the feeding support frame (1) at the discharge end of the first chain conveying assembly (2) through a support (17) and is used as an induction device for starting and stopping the first motor; and a second sensor (19) is arranged on the side surface of the feeding support frame (1) at the discharge end of the second chain conveying assembly (8) through a support (17) and is used as an induction device for starting and stopping the second motor.

10. The feed divider of claim 7, wherein: a first baffle (9) is arranged at the feeding end of the feeding support frame (1) of the first chain conveying component (2), and the included angle between the inner side surface of the first baffle (9) and the upper surface of the first chain conveying component (2) is 140 degrees and 160 degrees;

the feeding support frame (1) is provided with a second baffle (20) at the discharge end of the second chain conveying assembly (8), and the included angle between the inner side surface of the second baffle (20) and the upper surface of the second chain conveying assembly (8) is 140 degrees and 160 degrees.

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