CN220950676U - Cable rack for cable processing - Google Patents

Abstract

The utility model discloses a cable rack for cable processing, which belongs to the field of cables and comprises a base and a cable pay-off spool, wherein a connecting roll shaft is arranged on the cable pay-off spool, two supporting frames are symmetrically and fixedly arranged on the top side of the base, adjusting frames are slidably arranged on the two supporting frames, fixing frames are fixedly arranged on the two adjusting frames, and supporting structures are arranged on the two fixing frames. This cable rack is placing cable drawing drum and when connecting the roller, can drive the motor of both sides, can adjust the distance between two backing rolls of both sides under the effect of motor to make it adjust according to the diameter size of connecting the roller, support the use with connecting the roller with the cable drawing drum that adapts to not equidimension, promote the suitability, the cable drawing drum also can follow the rotation with connecting the roller when rotating the use, can not cause the influence to it, and the accommodation process is convenient simple.

Description

Cable rack for cable processing

Technical Field

The utility model relates to the technical field of cables, in particular to a cable rack for cable processing.

Background

The cable is a wire with insulating layer and protecting cover, and is formed from several wires insulated from each other, and several wires are placed in the air or underground or water for telecommunication or power transmission.

In the prior art, in the processing process of the cable, the rotating shafts at the two ends of the cable pay-off reel are required to be supported by the rollers on the placing frame so as to wind or pay-off the cable, but the rotating shafts at the two ends of different pay-off reels are different in size, and different placing frames or rollers with different intervals are required to be replaced, so that the cable pay-off reel is inconvenient to use.

Disclosure of Invention

The utility model aims to provide a cable rack for cable processing, which aims to solve the problems that in the cable processing process, the rotating shafts at two ends of a cable paying-off reel are required to be supported by the rollers on the rack so as to be convenient for winding or paying-off the cable, but the rotating shafts at two ends of different paying-off reels are different in size, and different racks are required to be replaced, or the rollers with different intervals are required to be replaced, so that the cable rack is inconvenient to use.

In order to achieve the above purpose, the present utility model provides the following technical solutions:

The utility model provides a cable rack for cable processing, includes base and cable pay-off reel, be equipped with the connection roller on the cable pay-off reel, the upside symmetry fixed mounting of base has two support frames, equal slidable mounting has the regulating frame on two support frames, equal fixed mounting has the mount on two regulating frames, all installs bearing structure on two mounts, bearing structure includes two regulating blocks, and two regulating blocks equal slidable mounting is on the mount, all rotates on two regulating blocks and installs supporting roller, and the one end of connecting the roller contacts with two supporting roller, and connection roller movable mounting is on bearing structure, and the equal fixed mounting in one side of two mounts has the motor, and the adjusting structure is all installed to the output of two motors, and the equal fixed mounting in both sides of two regulating frames has two fixed blocks, and the one side fixed mounting that is close to each other of two fixed blocks that is located same one side has same connecting axle, all rotates on four connecting axles and installs the gangbar, installs same elevation structure on two gangbars that are located same one side.

Preferably, the limit sliding grooves are formed in the inner walls of the two sides of the fixing frame, two limit sliding blocks are slidably mounted in the two limit sliding grooves, the two limit sliding blocks located on the same side are fixedly mounted on the two sides of the same adjusting block respectively, lifting grooves are formed in the inner walls of the two sides of the supporting frame, lifting connecting blocks are slidably mounted in the two lifting grooves respectively, and the two lifting connecting blocks are fixedly mounted on the two sides of the adjusting frame respectively.

Preferably, the adjusting structure comprises a positive and negative tooth screw rod, the positive and negative tooth screw rod is fixedly arranged at the output end of the motor, the positive and negative tooth screw rod is rotatably arranged on the fixing frame, two threaded connecting blocks are arranged on the positive and negative tooth screw rod in a threaded manner, the two threaded connecting blocks are slidably arranged on the inner wall of the fixing frame, and the two threaded connecting blocks are respectively and fixedly arranged at the bottom sides of the two adjusting blocks.

Preferably, the threaded connection block is provided with a threaded hole, and the front and back tooth screw rods are installed in the threaded hole in a threaded mode.

Preferably, the lifting structure comprises two linkage shafts, the two linkage shafts are respectively and rotatably arranged on the two linkage rods, push rods are fixedly arranged at two ends of the two linkage shafts, four push rods are respectively and symmetrically rotatably arranged at two sides of the support frame, one linkage block is movably arranged on the two push rods positioned at the same side, hydraulic cylinders are fixedly arranged at two sides of the support frame, and output ends of the two hydraulic cylinders are respectively and fixedly arranged on the two linkage blocks.

Preferably, the push rod is provided with a rotating hole, a rotating shaft is rotatably arranged in the rotating hole, the rotating shaft is fixedly arranged on one side of the supporting frame, the push rod is provided with a movable groove, a movable shaft is movably arranged in the movable groove, and the movable shaft is fixedly arranged on one side of the linkage block.

Preferably, the linkage rod is provided with two connecting holes, and the connecting shaft and the linkage shaft are respectively and rotatably arranged in the two connecting holes.

The beneficial effects of the utility model are as follows:

This cable rack is placing cable drawing drum and when connecting the roller, can drive the motor of both sides, can adjust the distance between two backing rolls of both sides under the effect of motor to make it adjust according to the diameter size of connecting the roller, support the use with connecting the roller with the cable drawing drum that adapts to not equidimension, promote the suitability, the cable drawing drum also can follow the rotation with connecting the roller when rotating the use, can not cause the influence to it, and the accommodation process is convenient simple.

According to the utility model, through the arrangement of the hydraulic cylinders, when the cable pay-off reel is required to be supported, the cable pay-off reel can be moved to drive the two ends of the connecting roller shaft to be positioned at the top side of the supporting roller, then the supporting roller can be lifted only by driving the hydraulic cylinders at the two sides, and the lifted supporting roller can support the connecting roller shaft and the cable pay-off reel for use.

Drawings

FIG. 1 is a schematic view of a cable rack for cable processing according to the present utility model;

FIG. 2 is a schematic view of a supporting frame portion of a cable rack for cable processing according to the present utility model;

FIG. 3 is a schematic view of a fixing frame portion of the cable rack for cable processing according to the present utility model;

FIG. 4 is a schematic cross-sectional view of a support frame portion of the cable processing rack of the present utility model;

fig. 5 is a schematic view of the structure of the link portion of the cable mount for cable processing according to the present utility model.

In the figure: 100. a base; 101. a cable pay-off reel; 102. connecting a roll shaft; 200. a support frame; 201. an adjusting frame; 202. a fixing frame; 203. an adjusting block; 204. supporting rollers; 205. limiting sliding grooves; 206. a limit sliding block; 207. a lifting groove; 208. lifting the connecting block; 300. a motor; 301. a positive and negative tooth screw rod; 302. a threaded connecting block; 303. a threaded hole; 400. a fixed block; 401. a connecting shaft; 402. a linkage rod; 403. a linkage shaft; 404. a push rod; 405. a linkage block; 406. a hydraulic cylinder; 407. a rotation hole; 408. a rotating shaft; 409. a movable groove; 410. a movable shaft; 411. and a connection hole.

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. 1-5, a cable rack for cable processing, including base 100 and cable take-off reel 101, be equipped with on the cable take-off reel 101 and connect roller 102, the top side symmetry fixed mounting of base 100 has two support frames 200, all slidable mounting has alignment jig 201 on two support frames 200, all fixed mounting has mount 202 on two alignment jigs 201, all install bearing structure on two mount 202, connect roller 102 movable mounting is on bearing structure, all fixed mounting has motor 300 on one side of two mount 202, the regulation structure is all installed to the output of two motor 300, both sides of two alignment jig 201 all fixed mounting have two fixed blocks 400, the one side that two fixed blocks 400 that are located same side are close to each other is fixed mounting has same connecting axle 401, all rotate on four connecting axles 401 and install gangbar 402, install same elevation structure on two gangbar 402 that are located same side.

The supporting structure comprises two adjusting blocks 203, the two adjusting blocks 203 are slidably mounted on a fixing frame 202, supporting rollers 204 are rotatably mounted on the two adjusting blocks 203, one end of a connecting roll shaft 102 is contacted with the two supporting rollers 204, two threaded connecting blocks 302 which are far away from each other drive the two adjusting blocks 203 to be far away from each other, the moving adjusting blocks 203 drive limit sliding blocks 206 on two sides to slide in two limit sliding grooves 205 respectively, the moving direction of the adjusting blocks 203 is further limited, the two continuously moving adjusting blocks 203 drive the two supporting rollers 204 to move respectively, and the distance between the two supporting rollers 204 can be adjusted according to the size of the connecting roll shaft 102, so that the connecting roll shaft 102 can be located at a position between the two supporting rollers 204.

In a preferred embodiment, as shown in fig. 2 and 3, limiting sliding grooves 205 are formed in inner walls of two sides of a fixing frame 202, two limiting sliding blocks 206 are slidably mounted in the two limiting sliding grooves 205, two limiting sliding blocks 206 located on the same side are fixedly mounted on two sides of the same adjusting block 203 respectively, lifting grooves 207 are formed in inner walls of two sides of a supporting frame 200, lifting connecting blocks 208 are slidably mounted in the two lifting grooves 207 respectively, the two lifting connecting blocks 208 are fixedly mounted on two sides of the adjusting frame 201 respectively, the moving adjusting block 203 drives the limiting sliding blocks 206 on two sides to slide in the two limiting sliding grooves 205 respectively, and therefore the moving direction of the adjusting block 203 is limited, and the moving adjusting frame 201 drives the lifting connecting blocks 208 on two sides to slide in the two lifting grooves 207 respectively, so that the moving direction of the adjusting frame 201 is limited.

In a preferred embodiment, as shown in fig. 4, the adjusting structure includes a positive and negative screw rod 301, the positive and negative screw rod 301 is fixedly installed at the output end of the motor 300, the positive and negative screw rod 301 is rotatably installed on the fixing frame 202, two threaded connection blocks 302 are threadedly installed on the positive and negative screw rod 301, the two threaded connection blocks 302 are slidably installed on the inner wall of the fixing frame 202, the two threaded connection blocks 302 are respectively fixedly installed at the bottom sides of the two adjusting blocks 203, the motors 300 on two sides are driven, the output end of the motor 300 drives the positive and negative screw rod 301 to rotate, the positive and negative screw rod 301 rotates and simultaneously drives the two threaded connection blocks 302 to move and move away from each other through cooperation with the two threaded holes 303, and the two threaded connection blocks 302 moving away from each other drive the two adjusting blocks 203 away from each other.

In a preferred embodiment, as shown in fig. 4, a threaded connection block 302 is provided with a threaded hole 303, a positive and negative screw 301 is installed in the threaded hole 303 in a threaded manner, and the positive and negative screw 301 rotates while respectively driving the two threaded connection blocks 302 to move and move away from each other through cooperation with the two threaded holes 303.

In a preferred embodiment, as shown in fig. 3-5, the lifting structure includes two linkage shafts 403, the two linkage shafts 403 are respectively rotatably mounted on the two linkage rods 402, two ends of the two linkage shafts 403 are fixedly mounted with push rods 404, four push rods 404 are respectively symmetrically rotatably mounted on two sides of the support frame 200, two push rods 404 located on the same side are movably mounted with a same linkage block 405, two sides of the support frame 200 are fixedly mounted with hydraulic cylinders 406, output ends of the two hydraulic cylinders 406 are respectively fixedly mounted on the two linkage blocks 405, the hydraulic cylinders 406 on the two sides are driven, the output ends of the hydraulic cylinders 406 push the linkage blocks 405 to move downwards, the movable shafts 410 are driven to move simultaneously when the linkage blocks 405 move, the moving movable shafts 410 move in the two movable grooves 409 and push one ends of the two push rods 404 to turn over, the turned push rods 404 rotate on the rotary shafts 408 through the rotary holes 407, the rotary shafts 408 are enabled to be pivot points, the other ends of the push rods 404 are driven to move upwards by utilizing the lever principle, the upward moving linkage shafts 403 are driven to move upwards through the linkage shafts 403 matched with the connecting holes to push the connecting rods 402 to move upwards, and the other ends of the linkage blocks 201 are matched with the connecting rods 402 to move upwards through the connecting rods 201.

In a preferred embodiment, the push rods 404 are provided with rotating holes 407, the rotating holes 407 are rotatably provided with rotating shafts 408, the rotating shafts 408 are fixedly arranged on one side of the supporting frame 200, the push rods 404 are provided with movable grooves 409, movable shafts 410 are movably arranged in the movable grooves 409, the movable shafts 410 are fixedly arranged on one side of the linkage block 405, the movable shafts 410 move in the two movable grooves 409 and push one ends of the two push rods 404 to turn over, and the turned push rods 404 rotate on the rotating shafts 408 through the rotating holes 407, so that the push rods 404 have the pivot point of the rotating shafts 408.

In a preferred embodiment, as shown in fig. 5, the linkage rod 402 is provided with two connecting holes 411, the connecting shaft 401 and the linkage shaft 403 are respectively rotatably installed in the two connecting holes 411, and the moving linkage shaft 403 drives one end of the linkage rod 402 to rotate and move upwards through cooperation with the connecting holes 411.

The working principle of the utility model is as follows:

When in use, the cable pay-off reel 101 can be pushed to drive the two ends of the connecting roll shaft 102 to move between the two supporting rollers 204 on the two sides, then the motor 300 on the two sides can be driven, the output end of the motor 300 can drive the positive and negative tooth screw rod 301 to rotate, the positive and negative tooth screw rod 301 can respectively drive the two threaded connecting blocks 302 to move and mutually separate through the cooperation with the two threaded holes 303, the two threaded connecting blocks 302 mutually separate can respectively drive the two adjusting blocks 203 to mutually separate, the moving adjusting blocks 203 can drive the limit sliding blocks 206 on the two sides to respectively slide in the two limit sliding grooves 205, thereby limiting the moving direction of the adjusting blocks 203, the two continuously moving adjusting blocks 203 can respectively drive the two supporting rollers 204 to move, the distance between the two supporting rollers 204 can be adjusted according to the size of the connecting roll shaft 102, the connecting roll shaft 102 can be positioned between the two supporting rollers 204, then driving the hydraulic cylinders 406 at two sides, the output ends of the hydraulic cylinders 406 push the linkage blocks 405 to move downwards, the linkage blocks 405 move and drive the movable shafts 410 to move, the moving movable shafts 410 move in the two movable grooves 409 and push one ends of the two push rods 404 to turn over, the turned push rods 404 rotate on the rotating shafts 408 through the rotating holes 407, the push rods 404 have the pivot 408, the other ends of the push rods 404 drive the linkage shafts 403 to move upwards by utilizing the lever principle, the upward moving linkage shafts 403 drive one ends of the linkage rods 402 to rotate and move upwards through the cooperation with the connecting holes 411, the other ends of the linkage rods 402 drive the adjusting frames 201 to move upwards through the cooperation of the connecting shafts 401 and the fixed blocks 400, the upward moving adjusting frames 201 drive the lifting connecting blocks 208 at two sides to slide in the two lifting grooves 207 respectively, and then restricted the direction of movement of alignment jig 201, the alignment jig 201 that continuously moves can drive mount 202 to remove, and then makes mount 202 drive regulating block 203 and backing roll 204 removal for the backing roll 204 that removes can prop up connecting roller 102, and connecting roller 102 then can prop up cable pay-off reel 101, so that use, when cable pay-off reel 101 drove connecting roller 102 rotation simultaneously, backing roll 204 can also rotate thereupon, can not cause the influence to it.

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. The utility model provides a cable rack for cable processing, includes base (100) and cable take-off reel (101), be equipped with on cable take-off reel (101) and connect roller (102), its characterized in that: the utility model discloses a lifting mechanism for a vehicle, including base (100), support frame (200) are installed to the upside symmetry fixed mounting of base (100), equal slidable mounting has alignment jig (201) on two support frames (200), equal fixed mounting has mount (202) on two alignment jig (201), all installs bearing structure on two mount (202), bearing structure includes two regulating blocks (203), equal slidable mounting of two regulating blocks (203) is on mount (202), all rotate on two regulating blocks (203) and install backing roller (204), the one end of connecting roller (102) is contacted with two backing roller (204), connecting roller (102) movable mounting is on bearing structure, one side of two mount (202) is equal fixed mounting has motor (300), the output of two motor (300) is equal to install alignment jig, equal fixed mounting in both sides of two alignment jig (201) has two fixed blocks (400), the one side fixed mounting that is close to each other has same connecting axle (401), all rotate on four connecting axles (401) and install gangbar (402), be located two gangbars (402) on the same one side.

2. The cable rack for cable processing of claim 1, wherein: limiting sliding grooves (205) are formed in the inner walls of two sides of the fixing frame (202), two limiting sliding blocks (206) are slidably mounted in the two limiting sliding grooves (205), the two limiting sliding blocks (206) located on the same side are fixedly mounted on two sides of the same adjusting block (203) respectively, lifting grooves (207) are formed in the inner walls of two sides of the supporting frame (200), lifting connecting blocks (208) are slidably mounted in the two lifting grooves (207), and the two lifting connecting blocks (208) are fixedly mounted on two sides of the adjusting frame (201) respectively.

3. The cable rack for cable processing of claim 1, wherein: the adjusting structure comprises a positive and negative screw rod (301), the positive and negative screw rod (301) is fixedly arranged at the output end of the motor (300), the positive and negative screw rod (301) is rotatably arranged on the fixing frame (202), two threaded connecting blocks (302) are arranged on the positive and negative screw rod (301) in a threaded mode, the two threaded connecting blocks (302) are slidably arranged on the inner wall of the fixing frame (202), and the two threaded connecting blocks (302) are fixedly arranged on the bottom sides of the two adjusting blocks (203) respectively.

4. A cable rest for cable processing according to claim 3, wherein: threaded holes (303) are formed in the threaded connecting blocks (302), and the front and back threaded rods (301) are installed in the threaded holes (303) in a threaded mode.

5. The cable rack for cable processing of claim 1, wherein: the lifting structure comprises two linkage shafts (403), the two linkage shafts (403) are respectively and rotatably mounted on the two linkage rods (402), push rods (404) are fixedly mounted at two ends of the two linkage shafts (403), the four push rods (404) are respectively and symmetrically rotatably mounted on two sides of the support frame (200), one linkage block (405) is movably mounted on the two push rods (404) located on the same side, hydraulic cylinders (406) are fixedly mounted on two sides of the support frame (200), and output ends of the two hydraulic cylinders (406) are respectively and fixedly mounted on the two linkage blocks (405).

6. The cable rack for cable processing of claim 5, wherein: the push rod (404) is provided with a rotating hole (407), the rotating hole (407) is rotationally provided with a rotating shaft (408), the rotating shaft (408) is fixedly arranged on one side of the support frame (200), the push rod (404) is provided with a movable groove (409), the movable groove (409) is internally provided with a movable shaft (410), and the movable shaft (410) is fixedly arranged on one side of the linkage block (405).

7. The cable rack for cable processing of claim 1, wherein: two connecting holes (411) are formed in the linkage rod (402), and the connecting shaft (401) and the linkage shaft (403) are respectively and rotatably arranged in the two connecting holes (411).