CN117047198B

CN117047198B - Continuous cutting device for cable bridge

Info

Publication number: CN117047198B
Application number: CN202311297781.0A
Authority: CN
Inventors: 冯汉斌; 李刚; 丁杰
Original assignee: Zhongpeng Electric Jiangsu Co ltd
Current assignee: Zhongpeng Electric Jiangsu Co ltd
Priority date: 2023-10-09
Filing date: 2023-10-09
Publication date: 2023-12-22
Anticipated expiration: 2043-10-09
Also published as: CN117047198A

Abstract

A continuous cutting device for a cable bridge relates to the technical field of cable bridge cutting, and comprises a frame, a sliding rail bin, a stop mechanism, a rotating mechanism and a cutting mechanism, wherein the sliding rail bin is fixedly arranged on an inclined plane of the frame; the turning mechanism of the rotating mechanism can adjust the direction of the cable bridge, and when the cable bridge can be put into the sliding rail bin in a positive state and a negative state, the feeding efficiency is improved; the screw rod of the cutting mechanism rotates to drive the translation plate and the cable bridge to translate, meanwhile, the cutting power head and the boss synchronously rotate along with the screw rod, and the boss drives the cutting knife to cut the cable bridge, so that the cutting size of the cable bridge is ensured to be correct.

Description

Continuous cutting device for cable bridge

Technical Field

The invention mainly relates to the technical field of cable bridge frame cutting, in particular to a continuous cutting device for a cable bridge frame.

Background

Along with the continuous development of modern engineering, people have more and more demands on electricity, especially have more and more demands on bridges in the building industry, and many connecting places need to be matched with the length construction of the bridges in the construction process, and the traditional bridge cutting has the problems of manual dimension drawing and cutting, and many defects of the cutting mode, such as inaccurate cutting, burrs and the like.

In the prior art, patent application with publication number of CN110000829A discloses a cutting device for bus duct bridge, and a belt transmission mechanism is used for transporting the bus duct, and a positioning mechanism is used for positioning and clamping the bus duct. However, the positioning mechanism of the device is complex to clamp and cannot turn over the bus duct to be cut.

Disclosure of Invention

The invention aims to provide a continuous cutting device for a cable bridge, which is characterized in that a rotating mechanism turns over the cable bridge, the front and back sides of the cable bridge are adjusted, and the cable bridge is automatically clamped and continuously cut by a cutting mechanism.

Aiming at the technical problems, the invention adopts the following technical scheme: the utility model provides a cable testing bridge continuous cutting device, includes frame, slide rail storehouse, stop mechanism, slewing mechanism and cutting mechanism, and slide rail storehouse is fixed to be located on the inclined plane of frame, and the cable testing bridge is located in the slide rail storehouse, and stop mechanism sets up in the end of slide rail storehouse, and slewing mechanism sets up in the frame, and slewing mechanism is located stop mechanism's side, and cutting mechanism is located slewing mechanism's side; the rotating mechanism comprises four pushing mechanisms, sliding hole rods of the pushing mechanisms are arranged between two four corner frames, a plurality of vertical rods are sequentially arranged on the sliding hole rods in a sliding mode, a cross rod is fixedly arranged at one end of each vertical rod, a pushing plate is arranged at the other end of each vertical rod, and two ends of a pushing spring are respectively connected with the sliding hole rods and the pushing plate; the frid is located in the frame, and the tip of horizontal pole inserts in the recess of frid.

Further, stop mechanism include the check slide bar, the fixed frame that locates of check slide bar on, the check post slides and locates the check slide bar, the check post passes the frame, check spring's both ends respectively with check slide bar and check post fixed connection, the check post side is equipped with the sloping block.

Further, the rotating mechanism comprises a rotating shaft, the rotating shaft is rotationally arranged on a shaft seat, the shaft seat is fixedly arranged on the frame, the shaft seat is connected with a rotating shaft of a rotating motor, the rotating motor is fixedly arranged on the frame, and two four corner frames are fixedly arranged on the rotating shaft.

Further, the rotating mechanism comprises four turnover mechanisms, the notch circular plates of the turnover mechanisms are arranged on the four corner frames, double-port chucks are arranged in the notch circular plates and fixedly arranged on rotating shafts of the turnover motors, and the turnover motors are fixedly arranged on the side surfaces of the four corner frames.

Further, the four corner frames are provided with poking columns which act on the inclined planes of the inclined plane blocks.

Further, the cutting mechanism comprises a cutting frame, a cutting motor is arranged on the cutting frame, a rotating shaft of the cutting motor is connected with a screw rod, the screw rod is rotationally arranged on the cutting frame, the screw rod is in threaded fit with a translation plate, the translation plate is slidably arranged on a sliding strip, and the sliding strip is fixedly arranged on the cutting frame.

Further, the translation plate is rotationally provided with a clamping plate, the pull rod is rotationally arranged on the translation plate, and two ends of the clamping plate spring are respectively and fixedly connected with the clamping plate and the pull rod.

Further, the cutting mechanism further comprises an initial touch head, the initial touch head is fixedly arranged on the cutting frame, and the end part of the clamping plate corresponds to the initial touch head.

Further, the cutting mechanism also comprises a cutting chute, the cutting chute is fixedly arranged on the cutting frame, a cutting knife is arranged on the cutting chute in a sliding manner, a notch of the cable bridge is formed in the cutting chute and the cutting knife, two ends of the cutter spring are respectively fixedly connected with the cutting knife and the cutting frame, a final contact head is arranged at the upper end of the cutting chute, the driven plate is arranged on the cutting chute in a sliding manner, and two ends of the driven spring are respectively fixedly connected with the cutting chute and the driven plate.

Further, the end part of the screw rod is provided with a cutting power head, the side surface of the cutting power head is provided with a boss, and the boss acts on a supporting rod of the cutting knife.

Compared with the prior art, the invention has the beneficial effects that: (1) The turnover mechanism can adjust the direction of the cable bridge, and when the cable bridge can be put into the slide rail bin in a positive state and a negative state, the feeding efficiency is improved; (2) When the cable bridge is fed to the side of the cutting mechanism by the double-port chuck, the groove design of the groove plate can automatically push the cable bridge into the cutting mechanism for cutting; (3) When the cable bridge is cut, the cable bridge is placed in the translation plate and the driven plate, and the clamping plate clamps the cable bridge on the translation plate, so that the cable bridge is prevented from tilting when being cut, and the deformation of the cable bridge is avoided; (4) The screw rod rotates to drive the translation plate and the cable bridge to translate, the cutting power head and the boss synchronously rotate along with the screw rod, and the boss drives the cutting knife to cut the cable bridge, so that the cutting size of the cable bridge is ensured to be correct.

Drawings

FIG. 1 is a schematic diagram of the overall structure of the present invention.

Fig. 2 is a schematic view of a stop mechanism according to the present invention.

Fig. 3 is a partial enlarged view of fig. 2 at a.

Fig. 4 is a schematic structural view of a rotating mechanism of the present invention.

Fig. 5 is a schematic structural view of the push-out mechanism of the present invention.

Fig. 6 is a partial enlarged view at B in fig. 5.

FIG. 7 is a schematic diagram of a fluted plate according to the present invention.

Fig. 8 is a schematic diagram of a groove structure of a groove plate according to the present invention.

FIG. 9 is a schematic view of a cutting mechanism according to the present invention.

Fig. 10 is a schematic structural view of a cutting mechanism of the cable-less bridge of the present invention.

FIG. 11 is a schematic view of a translating plate structure according to the present invention.

Fig. 12 is a schematic view of the matching structure of the cutting chute and the cutting blade according to the present invention.

Fig. 13 is a partial enlarged view of fig. 12 at C.

Reference numerals: 1-a frame; 2-a slide rail bin; 3-a stop mechanism; 4-a rotating mechanism; 5-a cutting mechanism; 6-a cable bridge; 301-a check slide bar; 302-check column; 303-a check spring; 304-a ramp block; 401-rotating shaft; 402-axle seat; 403-rotating the motor; 404-a quadrangle frame; 405-groove plate; 406-slide hole bar; 407-a cross bar; 408-vertical bars; 409-push spring; 410-pushing the plate; 411-notched circular plate; 412-turning over the motor; 413-a double-ended chuck; 414-pulling the column; 501-a cutting rack; 502-a cutting motor; 503-screw rod; 504-translating the plate; 505-slide bar; 506-clamping plate; 507-tie rod; 508-splint springs; 509-start touch; 510-cutting a chute; 511-cutting knife; 512-cutter spring; 513-final touch; 514-a driven plate; 515-a follower spring; 516-cutting power head; 517-boss.

Detailed Description

The invention is further described below in connection with specific embodiments, which are presented by way of illustration of exemplary embodiments of the invention and illustration of the invention, but not by way of limitation.

As shown in fig. 1 to 13, a continuous cutting device for a cable bridge comprises a frame 1, a slide rail bin 2, a stop mechanism 3, a rotating mechanism 4 and a cutting mechanism 5, wherein the slide rail bin 2 is fixedly arranged on an inclined plane of the frame 1, a cable bridge 6 is arranged in the slide rail bin 2, the stop mechanism 3 is arranged at the tail end of the slide rail bin 2, the rotating mechanism 4 is arranged on the frame 1, the rotating mechanism 4 is positioned at the side of the stop mechanism 3, and the cutting mechanism 5 is positioned at the side of the rotating mechanism 4.

The stop mechanism 3 comprises a check slide rod 301, the check slide rod 301 is fixedly arranged on the machine frame 1, a check column 302 is slidably arranged on the check slide rod 301, the check column 302 penetrates through the machine frame 1, two ends of a check spring 303 are respectively fixedly connected with the check slide rod 301 and the check column 302, and an inclined surface block 304 is arranged on the side face of the check column 302.

Specifically, the check spring 303 drives the check post 302 to be inserted into the cable bridge 6, preventing the cable bridge 6 from moving, and when the check post 302 is pulled out of the cable bridge 6, the cable bridge 6 slides into the tilting mechanism of the rotating mechanism 4.

The rotating mechanism 4 comprises a rotating shaft 401, the rotating shaft 401 is rotationally arranged on a shaft seat 402, the shaft seat 402 is fixedly arranged on the frame 1, the shaft seat 402 is connected with a rotating shaft of a rotating motor 403, the rotating motor 403 is fixedly arranged on the frame 1, and two four-corner frames 404 are fixedly arranged on the rotating shaft 401.

Specifically, the rotation motor 403 drives the rotation shaft 401 to rotate, and the rotation shaft 401 drives the four-corner frame 404 to rotate synchronously.

The rotating mechanism 4 comprises four pushing mechanisms, the pushing devices close to the stopping mechanism 3 are first stations, and as shown in fig. 1 and 4, the pushing devices are first stations, second stations, third stations and fourth stations in turn in the anticlockwise direction.

The slide hole rod 406 of the push-out mechanism is arranged between the two four-corner frames 404, a plurality of vertical rods 408 are sequentially arranged on the slide hole rod 406 in a sliding manner, a cross rod 407 is fixedly arranged at one end of each vertical rod 408, a push plate 410 is arranged at the other end of each vertical rod 408, and two ends of a push spring 409 are respectively connected with the slide hole rod 406 and the push plate 410.

The slot plate 405 is provided on the frame 1, and the end of the cross bar 407 is inserted into the recess of the slot plate 405.

Specifically, the four-corner frame 404 drives the pushing device to rotate synchronously, as shown in fig. 8, in the process that the pushing device at the second station rotates to the third station, the cross bar 407 is not limited by the groove of the groove plate 405, and the pushing plate 410 is driven by the pushing spring 409 to move outwards by the pushing plate 410; in the process of rotating the pushing device of the third station to the first station, the groove of the groove plate 405 limits the cross bar 407, so that the cross bar 407 is retracted, and the pushing plate 410 is synchronously retracted, so that the spring 409 is pushed to compress.

The turning mechanism 4 comprises four turning mechanisms, the four turning mechanisms are sequentially located beside the four pushing structures, a notch circular plate 411 of each turning mechanism is arranged on the four-corner frame 404, a double-mouth chuck 413 is arranged in the notch circular plate 411, the double-mouth chuck 413 is fixedly arranged on a rotating shaft of the turning motor 412, and the turning motor 412 is fixedly arranged on the side face of the four-corner frame 404.

Specifically, the cable bridge 6 is placed on the double-port chuck 413, one side of the cable bridge 6 contacts the notch circular plate 411, and the turnover motor 412 of the second station turnover mechanism rotates to drive the double-port chuck 413 to rotate, so that the cable bridge 6 is driven to rotate, and the notch circular plate 411 prevents the cable bridge 6 from falling down.

The four brackets of the four-corner frame 404 are all provided with poking columns 414, when the poking columns 414 of the first station pass through the stop mechanism 3, the poking columns 414 act on the inclined surfaces of the inclined surface blocks 304, so that the inclined surface blocks 304 and the non-return columns 302 synchronously slide outwards, and the limitation on the corresponding cable bridge 6 is relieved.

The cutting mechanism 5 comprises a cutting frame 501, a cutting motor 502 is arranged on the cutting frame 501, a rotating shaft of the cutting motor 502 is connected with a screw rod 503, the screw rod 503 is rotationally arranged on the cutting frame 501, the screw rod 503 and a translation plate 504 form threaded fit, the translation plate 504 is slidably arranged on a sliding strip 505, and the sliding strip 505 is fixedly arranged on the cutting frame 501.

Specifically, the cutting motor 502 provides power to drive the screw 503 to rotate, thereby driving the translating plate 504 to translate on the slide 505.

The translation plate 504 is rotatably provided with a clamping plate 506, the pull rod 507 is rotatably arranged on the translation plate 504, and two ends of the clamping plate spring 508 are respectively fixedly connected with the clamping plate 506 and the pull rod 507.

The cutting mechanism 5 further comprises a starting contact 509, the starting contact 509 is fixedly arranged on the cutting frame 501, and the end of the clamping plate 506 corresponds to the starting contact 509.

Specifically, the clamp spring 508 drives the clamp 506 to clamp the translating plate 504, and when the cable bridge 6 is located on the translating plate 504, the clamp 506 can clamp the cable bridge 6 on the translating plate 504; when the clamping plate 506 touches the initial touching head 509, the clamping plate 506 rotates on the translation plate 504, so that the clamping plate 506 can be opened.

The cutting mechanism 5 further comprises a cutting chute 510, the cutting chute 510 is fixedly arranged on the cutting frame 501, a cutting knife 511 is slidably arranged on the cutting chute 510, notches in the shape of a cable bridge are formed in the cutting chute 510 and the cutting knife 511, two ends of a cutter spring 512 are fixedly connected with the cutting knife 511 and the cutting frame 501 respectively, a final contact head 513 is arranged at the upper end of the cutting chute 510, a driven plate 514 is slidably arranged on the cutting chute 510, and two ends of the driven spring 515 are fixedly connected with the cutting chute 510 and the driven plate 514 respectively.

The end of the screw rod 503 is provided with a cutting power head 516, the side surface of the cutting power head 516 is provided with a boss 517, and the boss 517 acts on the supporting rod of the cutting knife 511.

Specifically, the cable bridge is inserted into the notch of the cutting chute 510 and the cutting blade 511, the screw rod 503 drives the cutting power head 516 to rotate synchronously, when the boss 517 acts on the strut of the cutting blade 511, the cutting blade 511 is driven to move downwards, the cutter spring 512 compresses, the cutting blade 511 completes cutting the cable bridge, the cut cable bridge 6 slides into the finished product box along the slideway, and when the boss 517 passes through the strut of the cutting blade 511, the cutter spring 512 drives the cutting blade 511 to restore to the original state.

When one cable bridge 6 is cut to the last section, the translation plate 504 and the clamping plate 506 clamp the last section of cable bridge 6 to move close to the cutting chute 510, the translation plate 504 touches the driven plate 514, the driven plate 514 moves towards the cutting chute 510, and when the cable bridge 6 moves to the end point, the final contact head 513 acts on the clamping plate 506 to enable the clamping plate 506 to rotate, and the last section of cable bridge 6 is loosened.

Working principle: a plurality of cable bridges 6 are placed in the sliding rail bin 2 above the stop mechanism 3, the cable bridges 6 slide downwards in the sliding rail bin 2, and the check springs 303 drive the check posts 302 to be inserted into the cable bridges 6, so that the cable bridges 6 are prevented from moving.

When the shifting post 414 of the first station passes the stop mechanism 3, the shifting post 414 acts on the inclined surface of the inclined surface block 304 to enable the inclined surface block 304 and the non-return post 302 to synchronously slide outwards, so that the limitation on the corresponding cable bridge 6 is removed, and the cable bridge 6 slides into the double-port chuck 413 of the first station.

The rotating motor 403 drives the rotating shaft 401 to rotate, the rotating shaft 401 drives the four-corner frame 404 to synchronously rotate, the double-mouth chuck 413 of the first station rotates to the second station, a camera is arranged at the second station to judge the positive and negative directions of the cable bridge 6, the turnover motor 412 of the second station turnover mechanism rotates to drive the double-mouth chuck 413 to rotate, thereby driving the cable bridge 6 to rotate, the notch circular plate 411 prevents the cable bridge 6 from falling down, the direction of the cable bridge 6 is aligned, and when the cable bridge 6 can be placed into the slide rail bin 2 in a positive and negative two states, the direction of the cable bridge 6 can be adjusted when passing through the turnover mechanism, and the feeding efficiency is improved.

When the cable bridge 6 at the second station rotates to the third station, the cross bar 407 is not limited by the groove of the groove plate 405, the pushing plate 410 is driven by the pushing spring 409 to move outwards by the pushing plate 410, the cable bridge 6 is pushed onto the translation plate 504 and the driven plate 514 by the pushing plate 410, and the groove of the groove plate 405 is designed to automatically push the cable bridge 6 into the cutting mechanism 5 for cutting.

Starting a cutting motor 502, driving a screw rod 503 to rotate, enabling a translation plate 504 to translate, enabling the translation plate 504 to leave an initial contact bump 509, driving a clamping plate 506 by a clamping plate spring 508 to clamp a cable bridge 6 on the translation plate 504, and clamping the cable bridge 6 when cutting the cable bridge 6, wherein the cable bridge 6 is not tilted; the translation plate 504 continuously translates, the cable bridge is inserted into the notch of the cutting chute 510 and the cutting knife 511, the screw rod 503 drives the cutting power head 516 to synchronously rotate, when the boss 517 acts on the supporting rod of the cutting knife 511, the cutting knife 511 is driven to move downwards, the cutter spring 512 compresses, the cutting knife 511 completes cutting the cable bridge, the cut cable bridge 6 slides into the finished product box along the slideway, and when the boss 517 passes through the supporting rod of the cutting knife 511, the cutter spring 512 drives the cutting knife 511 to restore to the original state.

When one cable bridge 6 is cut to the last section, the translation plate 504 and the clamping plate 506 clamp the last section of cable bridge 6 to move close to the cutting chute 510, the translation plate 504 touches the driven plate 514, the driven plate 514 moves towards the cutting chute 510, and when the cable bridge 6 moves to the end point, the final contact head 513 acts on the clamping plate 506 to enable the clamping plate 506 to rotate, the last section of cable bridge 6 is loosened, and the last section of cable bridge 6 slides into the finished box from the slideway.

The cutting motor 502 is turned over, the translation plate 504 is reversely translated to the original state, and when the clamping plate 506 touches the initial touching head 509, the clamping plate 506 rotates on the translation plate 504, so that the clamping plate 506 can be opened.

The invention is applicable to the prior art where it is not described.

Claims

1. The utility model provides a continuous cutting device of cable testing bridge which characterized in that: the cable bridge comprises a frame (1), a sliding rail bin (2), a stop mechanism (3), a rotating mechanism (4) and a cutting mechanism (5), wherein the sliding rail bin (2) is fixedly arranged on an inclined plane of the frame (1), a cable bridge (6) is arranged in the sliding rail bin (2), the stop mechanism (3) is arranged at the tail end of the sliding rail bin (2), the rotating mechanism (4) is arranged on the frame (1), the rotating mechanism (4) is positioned at the side of the stop mechanism (3), and the cutting mechanism (5) is positioned at the side of the rotating mechanism (4);

the rotating mechanism (4) comprises four pushing mechanisms, sliding hole rods (406) of the pushing mechanisms are arranged between two four corner frames (404), a plurality of vertical rods (408) are sequentially arranged on the sliding hole rods (406) in a sliding mode, a cross rod (407) is fixedly arranged at one end of each vertical rod (408), a pushing plate (410) is arranged at the other end of each vertical rod (408), and two ends of a pushing spring (409) are respectively connected with the sliding hole rods (406) and the pushing plates (410);

the groove plate (405) is arranged on the frame (1), and the end part of the cross rod (407) is inserted into the groove of the groove plate (405);

the groove plate (405) consists of a circular groove and a triangular groove, and the long side of the triangular groove is tangent with the circular groove;

the stop mechanism (3) comprises a check slide rod (301), the check slide rod (301) is fixedly arranged on the frame (1), the check column (302) is slidably arranged on the check slide rod (301), the check column (302) penetrates through the frame (1), two ends of the check spring (303) are fixedly connected with the check slide rod (301) and the check column (302) respectively, and inclined surface blocks (304) are arranged on the side surfaces of the check column (302);

the rotating mechanism (4) comprises a rotating shaft (401), the rotating shaft (401) is rotationally arranged on a shaft seat (402), the shaft seat (402) is fixedly arranged on the frame (1), the shaft seat (402) is connected with a rotating shaft of a rotating motor (403), the rotating motor (403) is fixedly arranged on the frame (1), and two four corner frames (404) are fixedly arranged on the rotating shaft (401);

the turning mechanism (4) comprises four turning mechanisms, the notch circular plates (411) of the turning mechanisms are arranged on the four-corner frames (404), double-mouth chucks (413) are arranged in the notch circular plates (411), the double-mouth chucks (413) are fixedly arranged on the rotating shafts of the turning motors (412), and the turning motors (412) are fixedly arranged on the side surfaces of the four-corner frames (404).

2. The continuous cutting device for cable trays according to claim 1, wherein: the four-corner frame (404) is provided with a poking column (414), and the poking column (414) acts on the inclined plane of the inclined plane block (304).

3. The continuous cutting device for cable trays according to claim 2, wherein: the cutting mechanism (5) comprises a cutting frame (501), a cutting motor (502) is arranged on the cutting frame (501), a rotating shaft of the cutting motor (502) is connected with a screw rod (503), the screw rod (503) is rotationally arranged on the cutting frame (501), the screw rod (503) and a translation plate (504) form threaded fit, the translation plate (504) is slidingly arranged on a sliding strip (505), and the sliding strip (505) is fixedly arranged on the cutting frame (501).

4. A continuous cutting device for cable bridges according to claim 3, characterized in that: the translational plate (504) is rotationally provided with a clamping plate (506), the pull rod (507) is rotationally arranged on the translational plate (504), and two ends of the clamping plate spring (508) are respectively fixedly connected with the clamping plate (506) and the pull rod (507).

5. The continuous cutting device for cable trays of claim 4, wherein: the cutting mechanism (5) further comprises an initial contact head (509), the initial contact head (509) is fixedly arranged on the cutting frame (501), and the end part of the clamping plate (506) corresponds to the initial contact head (509).

6. The continuous cutting device for cable trays of claim 5, wherein: the cutting mechanism (5) further comprises a cutting chute (510), the cutting chute (510) is fixedly arranged on the cutting frame (501), a cutting knife (511) is arranged on the cutting chute (510) in a sliding mode, a notch of a cable bridge is formed in the cutting chute (510) and the cutting knife (511), two ends of a cutter spring (512) are fixedly connected with the cutting knife (511) and the cutting frame (501) respectively, a final contact head (513) is arranged at the upper end of the cutting chute (510), a driven plate (514) is arranged on the cutting chute (510) in a sliding mode, and two ends of the driven spring (515) are fixedly connected with the cutting chute (510) and the driven plate (514) respectively.

7. The continuous cutting device for cable trays of claim 6, wherein: the end of the screw rod (503) is provided with a cutting power head (516), the side surface of the cutting power head (516) is provided with a boss (517), and the boss (517) acts on a supporting rod of the cutting knife (511).