CN218963655U - Traction mechanism of pipeline production equipment - Google Patents

Abstract

The utility model discloses a traction mechanism of pipeline production equipment, which relates to the field of machining equipment and comprises a frame, wherein a protective cover is movably arranged on the frame, an output double-shaft speed reducer is fixedly arranged on the frame, two output ends of the output double-shaft speed reducer are fixedly provided with transmission structures, sliding plates are fixedly arranged on the two transmission structures, the two sliding plates are slidably arranged on the top side of the frame, and traction clamping structures are slidably arranged on the top sides of the two sliding plates. According to the utility model, through the arrangement of the structures such as the air cylinder, the linkage slide block, the holding clamp and the like, the guide rail is arranged on the frame, the output double-shaft speed reducer is started to operate to drive the swinging rod, the relative movement of the traction clamping structure on the frame is realized, the production and processing of the pipe wire can be completed, the sizing die is arranged in front of the guiding clamp, the reducing and forming of the pipe wire can be completed while the traction is carried out, the production purpose is realized, the structure is simple, the production and the maintenance are easy, and the high mechanical automation is realized.

Description

Traction mechanism of pipeline production equipment

Technical Field

The utility model relates to the technical field of machining equipment, in particular to a traction mechanism of pipeline production equipment.

Background

The combined drawing machine is used for forming a machine array by drawing, straightening, cutting, polishing, flaw detection and the like, so that the quality and the production efficiency of products can be greatly improved, and the combined drawing machine array can be used for producing bar pipes and sectional materials.

In the prior art, the traction of the pipe, the wire and the material can be realized by the existing combined drawing machine in the process of drawing the pipe, the wire and the material by matching with the traction machine, and two kinds of equipment are matched for use, so that the combined drawing machine not only occupies more space and has high energy consumption, but also improves the cost of the equipment, and therefore, the traction mechanism of the pipe production equipment is required to meet the demands of people.

Disclosure of Invention

The utility model aims to provide a traction mechanism of pipeline production equipment, which solves the problems of more occupied space, high energy consumption and the like caused by the fact that two kinds of equipment, namely a combined drawing machine and a traction machine, are matched for use to realize traction drawing of pipelines, wires and materials, and further reduces the manufacturing and using costs of the equipment.

In order to achieve the above purpose, the present utility model provides the following technical solutions: the utility model provides a traction mechanism of pipeline production facility, includes the frame, movable mounting has the protection casing in the frame, and fixed mounting has output biax speed reducer in the frame, and two equal fixed mounting of output biax speed reducer have transmission structure, and equal fixed mounting has the sliding plate on two transmission structures, and two equal slidable mounting of sliding plate are in the top of frame, and the top of two sliding plates is all slided and is equipped with and pulls the clamping structure, and the equal fixed mounting of top of two sliding plates has the linkage structure.

Preferably, the transmission structure comprises an eccentric rotating rod, the eccentric rotating rod is fixedly arranged at the output end of the output double-shaft speed reducer, a swing rod is movably arranged on the eccentric rotating rod, the swing rod is rotatably arranged on the inner wall of the frame, one side of the swing rod is rotatably provided with one end of a linkage rod, the other end of the linkage rod is rotatably provided with a connecting rod, the connecting rod is slidably arranged on the frame, and the connecting rod is fixedly arranged at the bottom side of the sliding plate.

Preferably, the bottom side of the sliding plate is symmetrically and fixedly provided with four horizontal sliding blocks, the four horizontal sliding blocks are provided with horizontal sliding grooves, two horizontal sliding grooves on the same side are slidably provided with the same sliding rail, and the two sliding rails are fixedly arranged on the top side of the frame.

Preferably, the traction clamping structure comprises two inclined slide rails, two positioning inclined grooves are formed in the top side of the sliding plate, the two inclined slide rails are respectively and fixedly installed in the two positioning inclined grooves, two inclined sliding blocks are respectively and slidably installed on the two inclined slide rails, the same holding clamp is fixedly installed on the top sides of the two inclined sliding blocks located on the same side, clamping grooves are formed in the two holding clamps, one side of one sliding plate is fixedly installed with a guiding clamp, a sizing die is fixedly installed on the top side of the frame, sizing holes are formed in the sizing die, and the sizing holes correspond to the two clamping grooves.

Preferably, the inclined sliding block is provided with an inclined sliding groove, and the inclined sliding rail is slidably arranged in the inclined sliding groove.

Preferably, the linkage structure comprises a supporting block, the supporting block is fixedly arranged on the top side of the sliding plate, an air cylinder is fixedly arranged on one side of the supporting block, a linkage sliding block is fixedly arranged at the output end of the air cylinder, the linkage sliding block is movably arranged on the top sides of the two holding clamps, and a positioning hole is formed in the supporting block and corresponds to the two clamping grooves.

Preferably, the holding forceps are provided with a linkage groove, and the linkage sliding block is movably arranged in the linkage groove.

The beneficial effects of the utility model are as follows:

according to the utility model, through the arrangement of the structures such as the air cylinder, the linkage slide block, the holding clamp and the like, the guide rail is arranged on the frame, the output double-shaft speed reducer is started to operate to drive the swinging rod, the relative movement of the traction clamping structure on the frame is realized, the production and processing of the pipe wire can be completed, the sizing die is arranged in front of the guiding clamp, the reducing and forming of the pipe wire can be completed while the traction is carried out, the production purpose is realized, the structure is simple, the production and the maintenance are easy, and the high mechanical automation is realized.

Drawings

Fig. 1 is a schematic structural view of a traction mechanism of a pipeline production device according to the present utility model;

FIG. 2 is a schematic diagram of a traction mechanism of a pipeline production apparatus according to the present utility model;

FIG. 3 is a schematic diagram of the internal structure of a traction mechanism of a pipeline production device according to the present utility model;

FIG. 4 is a schematic diagram of a connection structure of a cylinder portion of a traction mechanism of a pipeline production apparatus according to the present utility model;

FIG. 5 is a schematic view of the holding clamp of the traction mechanism of the pipeline production device according to the present utility model;

FIG. 6 is a schematic view of a sliding plate portion of a traction mechanism of a line production apparatus according to the present utility model;

fig. 7 is a schematic structural view of a sizing die part of a traction mechanism of a pipeline production device according to the present utility model.

In the figure: 100. a frame; 200. a protective cover; 201. outputting a double-shaft speed reducer; 202. an eccentric rotating rod; 203. a swinging rod; 204. a linkage rod; 205. a connecting rod; 300. a horizontal slider; 301. a sliding plate; 302. a horizontal chute; 303. a slide rail; 400. a support block; 401. a cylinder; 402. a linkage slide block; 403. holding pliers; 404. a clamping groove; 405. positioning holes; 406. tilting the slider; 407. tilting the chute; 408. tilting the slide rail; 409. positioning chute; 410. a guiding clamp; 411. sizing die; 412. sizing holes; 413. and a linkage groove.

Detailed Description

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

Referring to fig. 1 to 7, a traction mechanism of a pipeline production device comprises a frame 100, a protective cover 200 is movably mounted on the frame 100, an output double-shaft speed reducer 201 is fixedly mounted on the frame 100, two output ends of the output double-shaft speed reducer 201 are fixedly mounted with transmission structures, sliding plates 301 are fixedly mounted on the two transmission structures, the two sliding plates 301 are slidably mounted on the top sides of the frame 100, traction clamping structures are slidably mounted on the top sides of the two sliding plates 301, linkage structures are fixedly mounted on the top sides of the two sliding plates 301, the output double-shaft speed reducer 201 is started to enable the output double-shaft speed reducer 201 to operate, the output end of the output double-shaft speed reducer 201 drives two eccentric rotating rods 202 to rotate towards the direction close to each other, the rotating two eccentric rotating rods 202 respectively drive two swinging rods 203 to swing, so that the swinging two swinging rods 203 respectively drive two connecting rods 205 to move through the two linkage rods 204, the moving connecting rod 205 drives the sliding plate 301 to move, so that the moving sliding plate 301 drives the horizontal sliding block 300 at the bottom side to slide on the sliding rail 303 through the horizontal sliding groove 302, and further limits the sliding plate 301 to slide only in the horizontal direction, a pipe, a line and a material can pass through the positioning hole 405 on the supporting block 400 and the clamping grooves 404 on the two holding clamps 403, and simultaneously can activate the two air cylinders 401, the output end of the air cylinders 401 can push the linkage sliding block 402 to move, the moving linkage sliding block 402 can push the two holding clamps 403 to move through the two linkage grooves 413, the moving holding clamps 403 can slide on the linkage sliding block 402 through the linkage grooves 413, meanwhile, the holding clamps 403 can drive the inclined sliding block 406 at the bottom side to slide on the inclined sliding rail 408 through the inclined sliding groove 407, so that the moving two holding clamps 403 are far away from or close to each other, thus, opening and closing of the holding clamps 403 can be achieved by starting the air cylinder 401, when the sliding plate 301 moves to the front end, the air cylinder 401 controls two holding clamps 403 to clamp a pipe, a wire and a material, the pipe, the wire and the material are moved to one direction, meanwhile, the other two holding clamps 403 are released to perform reverse movement, when the two holding clamps 403 move to the limit position, the other two holding clamps 403 start to clamp, meanwhile, the two holding clamps 403 are released, the outer two holding clamps 403 drag the pipe, the wire and the material to move continuously to the same direction, and the two holding clamps 403 move to the opposite direction, so that the pipe, the wire and the material are moved to the same direction continuously in a circulating manner, and stretching and reducing forming of the pipe, the wire and the material are completed.

Further, the transmission structure comprises an eccentric rotating rod 202, the eccentric rotating rod 202 is fixedly arranged at the output end of the output double-shaft speed reducer 201, a swinging rod 203 is movably arranged on the eccentric rotating rod 202, the swinging rod 203 is rotatably arranged on the inner wall of the frame 100, one side of the swinging rod 203 is rotatably provided with one end of a linkage rod 204, the other end of the linkage rod 204 is rotatably provided with a connecting rod 205, the connecting rod 205 is slidably arranged on the frame 100, the connecting rod 205 is fixedly arranged at the bottom side of the sliding plate 301, the output double-shaft speed reducer 201 is started to enable the output double-shaft speed reducer 201 to operate, the output end of the output double-shaft speed reducer 201 can drive the two eccentric rotating rods 202 to rotate towards the direction close to each other, the two rotating eccentric rotating rods 202 can respectively drive the two swinging rods 203 to swing, so that the two swinging rods 203 respectively drive the two connecting rods 205 to move through the two linkage rods 204, and the moving connecting rod 205 can drive the sliding plate 301 to move.

Further, four horizontal sliding blocks 300 are symmetrically and fixedly installed on the bottom side of the sliding plate 301, horizontal sliding grooves 302 are formed in the four horizontal sliding blocks 300, the same sliding rail 303 is slidably installed on two horizontal sliding grooves 302 located on the same side, the two sliding rails 303 are fixedly installed on the top side of the frame 100, and the moving sliding plate 301 drives the horizontal sliding blocks 300 on the bottom side to slide on the sliding rails 303 through the horizontal sliding grooves 302, so that the sliding plate 301 is limited to slide only in the horizontal direction.

Further, the traction clamping structure comprises two inclined slide rails 408, two positioning chute 409 are formed in the top side of the sliding plate 301, the two inclined slide rails 408 are respectively and fixedly installed in the two positioning chute 409, two inclined slide blocks 406 are slidably installed on the two inclined slide rails 408, the same holding forceps 403 are fixedly installed on the top side of the two inclined slide blocks 406 located on the same side, clamping grooves 404 are formed in the two holding forceps 403, one side of one sliding plate 301 is fixedly installed with a guiding forceps 410, a sizing die 411 is fixedly installed on the top side of the stand 100, sizing holes 412 are formed in the sizing die 411, the sizing holes 412 correspond to the two clamping grooves 404, a pipe, a wire and a material can pass through the positioning holes 405 on the supporting block 400 and the clamping grooves 404 on the two holding forceps 403, two air cylinders 401 can be started simultaneously, the output ends of the air cylinders 401 can push the linkage slide blocks 402 to move, the moving slide blocks 402 can push the two holding forceps 403 to move through the two holding forceps 403, and the moving holding forceps 403 can slide on the linkage slide blocks 402 through the grooves 413.

Further, the inclined sliding block 406 is provided with an inclined sliding slot 407, the inclined sliding rail 408 is slidably mounted in the inclined sliding slot 407, and the holding clamp 403 moves to drive the inclined sliding block 406 at the bottom side to slide on the inclined sliding rail 408 through the inclined sliding slot 407, so that the two moving holding clamps 403 are far away from each other or close to each other.

Further, the linkage structure comprises a supporting block 400, the supporting block 400 is fixedly arranged on the top side of the sliding plate 301, an air cylinder 401 is fixedly arranged on one side of the supporting block 400, a linkage sliding block 402 is fixedly arranged at the output end of the air cylinder 401, the linkage sliding block 402 is movably arranged on the top sides of the two holding clamps 403, a positioning hole 405 is formed in the supporting block 400, the positioning hole 405 corresponds to the two clamping grooves 404, and meanwhile the holding clamps 403 move to drive an inclined sliding block 406 on the bottom side to slide on an inclined sliding rail 408 through an inclined sliding groove 407, so that the two moving holding clamps 403 are far away from each other or close to each other.

Further, a linkage groove 413 is formed in the holding clamp 403, the linkage slider 402 is movably mounted in the linkage groove 413, the moving linkage slider 402 pushes the two holding clamps 403 to move through the two linkage grooves 413, and the moving holding clamp 403 slides on the linkage slider 402 through the linkage groove 413.

The working principle of the utility model is as follows:

starting the output double-shaft speed reducer 201 to enable the output double-shaft speed reducer 201 to operate, the output end of the output double-shaft speed reducer 201 can drive the two eccentric rotating rods 202 to rotate towards the direction close to each other, the rotating two eccentric rotating rods 202 can respectively drive the two swinging rods 203 to swing, so that the swinging two swinging rods 203 respectively drive the two connecting rods 205 to move through the two linkage rods 204, the moving connecting rods 205 can drive the sliding plate 301 to move, the moving sliding plate 301 can drive the horizontal sliding block 300 at the bottom side to slide on the sliding rail 303 through the horizontal sliding groove 302, the sliding plate 301 is further limited to slide only in the horizontal direction, a pipe, a line and a material can pass through the locating holes 405 on the supporting block 400 and the clamping grooves 404 on the two holding clamps 403, simultaneously, the output end of the air cylinder 401 can drive the linkage sliding block 402 to move, the moving linkage sliding block 402 can drive the two holding clamps 403 to move through the two linkage grooves 413, the moving holding clamp 403 slides on the linkage slide block 402 through the linkage groove 413, meanwhile, the moving holding clamp 403 drives the inclined slide block 406 at the bottom side to slide on the inclined slide rail 408 through the inclined slide groove 407, so that the moving two holding clamps 403 are far away from or close to each other, opening and closing of the holding clamp 403 can be realized through starting the air cylinder 401, when the sliding plate 301 moves to the front end, the air cylinder 401 controls the two holding clamps 403 to clamp pipes, wires and materials and moves the pipes, wires and materials in one direction, meanwhile, the other two holding clamps 403 are released to perform reverse movement, when the two holding clamps 403 move to the limit position, the other two holding clamps 403 start to clamp, meanwhile, the two holding clamps 403 are released, the outer two holding clamps 403 drag the pipes, wires and materials to move continuously in the same direction, the two holding clamps 403 move in opposite directions, the tube, wire and material are driven to move in the same direction repeatedly, the stretching and reducing forming of the tube, wire and material are completed, the sizing die 411 (forming die holder) is arranged in front of the guiding clamp 410, and the reducing forming of the tube and material is completed while the drawing is carried out, so that the production purpose is realized.

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

Claims (7)

1. A traction mechanism of a pipeline production device, comprising a frame (100), characterized in that: the novel double-shaft speed reducer is characterized in that a protective cover (200) is movably mounted on the frame (100), an output double-shaft speed reducer (201) is fixedly mounted on the frame (100), transmission structures are fixedly mounted at two output ends of the output double-shaft speed reducer (201), sliding plates (301) are fixedly mounted on the two transmission structures, the two sliding plates (301) are slidably mounted on the top sides of the frame (100), traction clamping structures are slidably mounted on the top sides of the two sliding plates (301), and linkage structures are fixedly mounted on the top sides of the two sliding plates (301).

2. A traction mechanism of a pipeline production apparatus according to claim 1, wherein: the transmission structure comprises an eccentric rotating rod (202), the eccentric rotating rod (202) is fixedly arranged at the output end of an output double-shaft speed reducer (201), a swinging rod (203) is movably arranged on the eccentric rotating rod (202), the swinging rod (203) is rotatably arranged on the inner wall of a frame (100), one side of the swinging rod (203) is rotatably provided with one end of a linkage rod (204), the other end of the linkage rod (204) is rotatably provided with a connecting rod (205), the connecting rod (205) is slidably arranged on the frame (100), and the connecting rod (205) is fixedly arranged at the bottom side of a sliding plate (301).

3. A traction mechanism of a pipeline production apparatus according to claim 1, wherein: four horizontal sliding blocks (300) are symmetrically and fixedly arranged on the bottom side of the sliding plate (301), horizontal sliding grooves (302) are formed in the four horizontal sliding blocks (300), the same sliding rail (303) is slidably arranged on the two horizontal sliding grooves (302) on the same side, and the two sliding rails (303) are fixedly arranged on the top side of the frame (100).

4. A traction mechanism of a pipeline production apparatus according to claim 1, wherein: the traction clamping structure comprises two inclined slide rails (408), two positioning inclined grooves (409) are formed in the top side of the sliding plate (301), the two inclined slide rails (408) are fixedly installed in the two positioning inclined grooves (409) respectively, two inclined slide blocks (406) are slidably installed on the two inclined slide rails (408), one holding clamp (403) is fixedly installed on the top side of the two inclined slide blocks (406) located on the same side, clamping grooves (404) are formed in the two holding clamps (403), one side of one sliding plate (301) is fixedly installed with a guiding clamp (410), a sizing die (411) is fixedly installed on the top side of the frame (100), sizing holes (412) are formed in the sizing die (411), and the sizing holes (412) correspond to the two clamping grooves (404).

5. A traction mechanism of a pipeline production apparatus according to claim 4, wherein: the inclined sliding block (406) is provided with an inclined sliding groove (407), and the inclined sliding rail (408) is slidably arranged in the inclined sliding groove (407).

6. A traction mechanism of a pipeline production apparatus according to claim 1, wherein: the linkage structure comprises a supporting block (400), wherein the supporting block (400) is fixedly arranged on the top side of a sliding plate (301), one side of the supporting block (400) is fixedly provided with an air cylinder (401), the output end of the air cylinder (401) is fixedly provided with a linkage sliding block (402), the linkage sliding block (402) is movably arranged on the top sides of two holding clamps (403), and the supporting block (400) is provided with a positioning hole (405), and the positioning hole (405) corresponds to two clamping grooves (404).

7. A traction mechanism of a pipeline production apparatus according to claim 6, wherein: the holding clamp (403) is provided with a linkage groove (413), and the linkage sliding block (402) is movably arranged in the linkage groove (413).

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