CN115347505A

CN115347505A - Cable support frame capable of improving arrangement efficiency

Info

Publication number: CN115347505A
Application number: CN202211038919.0A
Authority: CN
Inventors: 尹广东
Original assignee: Jiangsu Hanna New Energy Co ltd
Current assignee: State Grid Zhejiang Electric Power Co Ltd Xinchang County Power Supply Co; Xinming Industrial Co ltd
Priority date: 2022-08-26
Filing date: 2022-08-26
Publication date: 2022-11-15
Anticipated expiration: 2042-08-26
Also published as: CN115347505B

Abstract

The invention discloses a cable support frame capable of improving arrangement efficiency, which comprises a concrete cable rod, wherein a cable bracket mechanism is fixedly connected to the concrete cable rod, a non-return assembly is arranged on the cable bracket mechanism, a sealing assembly is further arranged at a position, corresponding to the non-return assembly, on the cable bracket mechanism, and a pushing assembly is arranged on the end face of the rear side of the cable bracket mechanism. The cable tray mechanism comprises a balance seat and a linkage shaft, a sliding connecting sleeve is sleeved on the surface of the linkage shaft, the opposite surfaces of the sliding connecting sleeve and the sliding pushing seat are fixedly connected through a first supporting spring, the first supporting spring is sleeved on the surface of the linkage shaft, and the top of the sliding connecting sleeve is rotatably connected with a rotary connecting shaft. The invention can ensure the basic stability of the cable and effectively improve the laying efficiency of the cable.

Description

Cable support frame capable of improving arrangement efficiency

Technical Field

The invention belongs to the technical field of cable support frames, and particularly relates to a support frame for cables, which can improve the arrangement efficiency.

Background

The cable is when laying, can select the mode of laying in high altitude under the typical situation to go on, because high tension cable is heavier, and at the in-process of laying, still need carry out the regulation of cable elasticity, so as to guarantee the stability of cable in the course of the work, can select to pull the cable with mechanical type jacking equipment usually, with the laying of realization cable, at present, current cable still has some weak points at the in-process of using with the carriage, because mechanical equipment's the power of pulling is great, the elasticity of difficult control cable when pulling, seriously influence the arrangement efficiency of cable, and at the in-process of pulling, still can take place accident such as cable drops sometimes, and still can use the wire to fix after the regulation and control of elasticity is finished, the laying efficiency of cable has further been reduced, therefore, need for one kind to improve the cable that arranges efficiency at present stage and use the carriage to solve above-mentioned problem.

Disclosure of Invention

The invention aims to: in order to solve the problem that the existing support frame for the cables still has some defects in the using process, mechanical equipment is large in dragging force, the tightness of the cables is difficult to control when the support frame is dragged, the arrangement efficiency of the cables is seriously influenced, in the dragging process, accidents such as cable falling and the like sometimes occur, in addition, metal wires can be used for fixing after the tightness regulation and control are finished, the cable laying efficiency is further reduced, and the support frame for the cables can improve the arrangement efficiency.

In order to achieve the purpose, the invention adopts the following technical scheme:

a supporting frame for cables capable of improving arrangement efficiency comprises a concrete cable rod, wherein a cable bracket mechanism is fixedly connected to the concrete cable rod, a non-return assembly is arranged on the cable bracket mechanism, a sealing assembly is further arranged at a position, corresponding to the non-return assembly, on the cable bracket mechanism, and a pushing assembly is arranged on the end face of the rear side of the cable bracket mechanism;

cable tray mechanism includes balanced seat and universal driving shaft, the surface of universal driving shaft has cup jointed the adapter sleeve that slides, the opposite face of sliding adapter sleeve and gliding propelling movement seat is through first supporting spring fixed connection to first supporting spring cup joints the surface at the universal driving shaft, the top of sliding the adapter sleeve is rotated and is connected with the even axle of rotary type, the first linkage bevel gear of fixed surface of the even axle of rotary type to the position department that the universal driving shaft surface corresponds first linkage bevel gear has the second linkage bevel gear through elastic component sliding connection, the top fixedly connected with drive wheel of the even axle of rotary type.

As a further description of the above technical solution:

the internal rotation of balanced seat in the same drive cavity is connected with two threaded connection poles, and two threaded connection pole's screw thread direction is reciprocal, threaded connection pole's surperficial threaded connection has a threaded connection section of thick bamboo, threaded connection section of thick bamboo joint is on the terminal surface of slippage formula propelling movement seat, slippage formula propelling movement seat sliding connection be in the drive cavity, and the one end that two threaded connection poles are close is through same universal driving shaft fixed connection.

As a further description of the above technical solution:

contrary subassembly is including contrary the sleeve that ends, be provided with the contrary tooth that ends in a plurality of outside on contrary telescopic inside wall of ending to the border department of the contrary tooth extrados that ends in the outside is articulated through spring hinge and the contrary telescopic intrados that ends, the rotary type links the equal fixedly connected with inboard contrary tooth that ends of the corresponding a plurality of outside contrary tooth position department of shaft surface to the inboard contrary tooth that ends and the outside contrary intermeshing between the tooth that ends.

As a further description of the above technical solution:

the contrary top at inboard cushion socket of sleeve joint that ends, the tip sliding connection of inboard cushion socket is in first sliding the spread groove, the embedded second supporting spring that is connected with of position department that corresponds inboard cushion socket in the first sliding the spread groove, the one end fixed connection of second supporting spring is on the inboard terminal surface of first sliding the spread groove, the one side fixed connection that the other end and inboard cushion socket of second supporting spring are close.

As a further description of the above technical solution:

the sealing assembly comprises an outer side buffer seat, an inner side penetrating connector is formed in the top of the outer side buffer seat, the inner side buffer seat is located on the inner side of the inner side penetrating connector, and the first sliding connecting groove is formed in the inner side wall of the inner side penetrating connector.

As a further description of the above technical solution:

the outside buffer seat is located the outside and passes through the connector, the outside is passed through the connector and is seted up at the top of balanced seat, the second connection groove that slides has been seted up at the top of outside buffer seat, the second slides and has first connection seat that slides in the connection groove.

As a further description of the above technical solution:

the top of the first sliding connecting seat is fixedly connected to the top of the inner side of the balance seat, a third supporting spring is connected to the position, corresponding to the first sliding connecting seat, of the inner side of the second sliding connecting groove in an embedded mode, one end of the third supporting spring is fixedly connected to the end face of the inner side of the second sliding connecting groove, and the other end of the third supporting spring is fixedly connected with the face, close to the first sliding connecting seat, of the other end of the third supporting spring.

As a further description of the above technical solution:

the pushing assembly comprises a driving seat, the front end of the driving seat is clamped on the rear end face of the balance seat, a second sliding connecting seat is connected in the driving seat in a sliding mode, a piston rod is fixedly connected to the front end face of the second sliding connecting seat, the piston rod is connected to the rear end face of the supporting seat in a sliding mode, the supporting seat is fixedly connected to the inner side wall of the driving seat, one end of the front side of the piston rod is rotatably connected with one end of a movable shaft, the other end of the movable shaft is rotatably connected to the position, deviating from the circle center, of the top of a third linkage bevel gear, the third linkage bevel gear is rotatably connected to the inner side wall of the driving seat, and the third linkage bevel gear is meshed with the first linkage bevel gear.

As a further description of the above technical solution:

fixedly connected with bridge type link on the side end face of second sliding connection seat, bridge type link sliding connection is in the sliding connection mouth of seting up on the drive seat side end face, the surperficial sliding connection who drives the seat has the propelling movement frame, the inside wall of propelling movement frame and the close one side fixed connection of bridge type link, the joint has the clamp on the inside wall of propelling movement frame to the position department that drives the seat top and corresponds the clamp has seted up the propelling movement groove.

As a further description of the above technical solution:

the utility model discloses a screw thread connecting rod, including threaded connection rod, rotary type adapter sleeve, swing type adapter sleeve and swing type connecting rod, threaded connection rod's tip rotates and is connected with drive assembly, drive assembly includes the rotary type adapter sleeve, the rotary type adapter sleeve rotates the tip of connection at threaded connection rod, the first adaptor of bottom fixedly connected with of rotary type adapter sleeve, the uncovered internal rotation of first adaptor bottom is connected with the switching axle, the one end fixedly connected with second adaptor of first adaptor is kept away from to the switching axle, uncovered internal rotation on second adaptor side end face is connected with the rocker, second adaptor top still joint has the magnetism to detain, the top of magnetism is adsorbed in the bottom of balanced seat.

In summary, due to the adoption of the technical scheme, the invention has the beneficial effects that:

1. according to the invention, through the designed cable bracket mechanism, the threaded connecting rod rotates in the threaded connecting cylinder, under the combined action effect of the torsion force and the thread occlusion force, the threaded connecting cylinder drives the sliding type pushing seat to slide on the inner side of the balance seat, the sliding connecting sleeve and the driving wheel associated with the sliding connecting sleeve are pushed through the first supporting spring to synchronously act, the two driving wheels are close to each other, so that various types of cables placed on the balance seat can be clamped and connected, the cables can be effectively prevented from falling off on the balance seat, the subsequent cable tightness adjustment work is ensured to be carried out smoothly, when the threaded connecting cylinder is separated from the threaded connecting rod, the threaded connecting rod is kept in a rotating state, due to the fact that the sliding connecting sleeve and the sliding type pushing seat are in an elastic connection relationship, and the second linkage bevel gear and the linkage shaft are also in an elastic connection relationship, the association between the first linkage bevel gear and the second linkage bevel gear can be effectively realized on the basis of conveniently clamping and connecting different types of cables, and the linkage shaft can still provide the effective cable transmission efficiency in the process of the linkage bevel gear transmission.

2. According to the invention, through the designed non-return assembly, the rotary connecting shaft can drive the inner non-return tooth to rotate on the outer non-return tooth in the process of driving the rotary connecting shaft to rotate, only one edge on the outer arc surface of the outer non-return tooth can rotate through the spring hinge, and in the process of forward rotation of the inner non-return tooth, the outer non-return tooth can rotate through the spring hinge, so that the inner non-return tooth can smoothly pass through, and when the inner non-return tooth rotates reversely, the outer non-return tooth cannot rotate through the spring hinge at the moment, so that the inner non-return tooth cannot pass through, therefore, the driving wheel can be effectively ensured to rotate reversely, and the stability of the cable after clamping connection is further improved.

3. According to the invention, through the designed pushing assembly, the first linkage bevel gear is also associated with the third linkage bevel gear when being associated with the second linkage bevel gear, the rotary connecting shaft utilizes the linkage effect between the first linkage bevel gear and the third linkage bevel gear to further drive one end of the movable shaft to perform eccentric motion, and both end parts of the movable shaft can rotate, so that the second sliding connecting seat can be driven by the piston rod to perform stable piston motion on the inner side of the driving seat, the bridge-type connecting frame drives the hoop on the pushing frame to move, and the reciprocating pushing action of the hoop is utilized, so that the cable can be pushed to move towards the driving wheel, and the supporting effect of the pushing groove is supplemented, so that the tightness adjusting operation of the cable is more flexible.

Drawings

Fig. 1 is a schematic view of an overall structure of a cable support according to the present invention, which can improve the arrangement efficiency;

FIG. 2 is a schematic cross-sectional view of a cable tray mechanism in a cable support rack according to the present invention, which can improve the arrangement efficiency;

fig. 3 is an enlarged schematic structural view of a position a of the cable support frame capable of improving the arrangement efficiency according to the present invention;

fig. 4 is an enlarged schematic structural diagram of a cable support frame B capable of improving the arrangement efficiency according to the present invention;

fig. 5 is a schematic structural view of a driving assembly in a cable support frame capable of improving arrangement efficiency according to the present invention;

fig. 6 is a schematic structural diagram of a check assembly in a cable support frame capable of improving arrangement efficiency according to the present invention;

fig. 7 is a schematic cross-sectional view of a pushing assembly in a supporting frame for cables, which is capable of improving the arrangement efficiency.

Illustration of the drawings:

1. a concrete cable pole; 2. a cable tray mechanism; 201. a threaded connecting rod; 202. a threaded connection barrel; 203. a sliding type pushing seat; 204. a first support spring; 205. a first linkage bevel gear; 206. a second linkage bevel gear; 207. a rotary connecting shaft; 208. a drive wheel; 209. a balance seat; 210. a sliding connecting sleeve; 211. a linkage shaft; 3. a non-return component; 301. a non-return sleeve; 302. an inner side reverse stop tooth; 303. an outer check tooth; 304. an inner cushion seat; 305. a first sliding connecting groove; 306. a second support spring; 4. a seal assembly; 401. the inner side passes through the connecting port; 402. an outer cushion seat; 403. a first sliding connection seat; 404. a second sliding connecting groove; 405. a third support spring; 406. the outer side passes through the connecting port; 5. a push assembly; 501. a driving seat; 502. a second sliding connection seat; 503. a bridge-type connecting frame; 504. a sliding connecting port; 505. a piston rod; 506. a supporting seat; 507. a movable shaft; 508. a third driving bevel gear; 509. a push tank; 510. a pushing frame; 511. clamping a hoop; 6. a drive assembly; 601. a rotary connecting sleeve; 602. a first transfer member; 603. a transfer shaft; 604. a second adaptor; 605. magnetic buckling; 605. a rocker.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

Referring to fig. 1-7, the present invention provides a technical solution: a supporting frame for cables capable of improving arrangement efficiency comprises a concrete cable rod 1, wherein a cable bracket mechanism 2 is fixedly connected to the concrete cable rod 1, a non-return component 3 is arranged on the cable bracket mechanism 2, a sealing component 4 is further arranged at a position, corresponding to the non-return component 3, on the cable bracket mechanism 2, and a pushing component 5 is arranged on the end face of the rear side of the cable bracket mechanism 2;

the cable bracket mechanism 2 comprises a balance seat 209 and a linkage shaft 211, a sliding connecting sleeve 210 is sleeved on the surface of the linkage shaft 211, opposite surfaces of the sliding connecting sleeve 210 and the sliding pushing seat 203 are fixedly connected through a first supporting spring 204, the first supporting spring 204 is sleeved on the surface of the linkage shaft 211, the top of the sliding connecting sleeve 210 is rotatably connected with a rotary connecting shaft 207, a first linkage bevel gear 205 is fixedly connected on the surface of the rotary connecting shaft 207, a second linkage bevel gear 206 is slidably connected on the surface of the linkage shaft 211 corresponding to the first linkage bevel gear 205 through an elastic piece, and a driving wheel 208 is fixedly connected on the top end of the rotary connecting shaft 207.

Specifically, as shown in fig. 3, two threaded connecting rods 201 are rotatably connected in the same driving cavity built in the balancing seat 209, the thread directions of the two threaded connecting rods 201 are opposite to each other, the surface thread of the threaded connecting rod 201 is connected with a threaded connecting cylinder 202, the threaded connecting cylinder 202 is clamped on the end surface of the sliding type pushing seat 203, the sliding type pushing seat 203 is slidably connected in the driving cavity, and one ends of the two threaded connecting rods 201 which are close to each other are fixedly connected through the same linkage shaft 211.

The implementation mode is specifically as follows: because the sliding connecting sleeve 210 and the sliding pushing seat 203 are in an elastic connection relationship, and the second linkage bevel gear 206 and the linkage shaft 211 are also in an elastic connection relationship, the association between the first linkage bevel gear 205 and the second linkage bevel gear 206 can be effectively realized on the basis of conveniently clamping and connecting cables of different types, and the linkage shaft 211 can drive the cables to perform transmission work through the two driving wheels 208 by utilizing the linkage between the first linkage bevel gear 205 and the second linkage bevel gear 206.

Specifically, as shown in fig. 6, the check assembly 3 includes a check sleeve 301, a plurality of outer check teeth 303 are disposed on an inner side wall of the check sleeve 301, and edges of outer arcs of the outer check teeth 303 are hinged to inner arcs of the check sleeve 301 through spring hinges, inner check teeth 302 are fixedly connected to surfaces of the rotary connecting shaft 207 corresponding to positions of the outer check teeth 303, and the inner check teeth 302 and the outer check teeth 303 are engaged with each other, the check sleeve 301 is clamped to a top of the inner buffer base 304, an end of the inner buffer base 304 is slidably connected to a first sliding connecting groove 305, a second support spring 306 is embedded in a position corresponding to the inner buffer base 304 in the first sliding connecting groove 305, one end of the second support spring 306 is fixedly connected to an inner end surface of the first sliding connecting groove 305, and another end of the second support spring 306 is fixedly connected to a surface of the inner buffer base 304.

The implementation mode is specifically as follows: the rotating type connecting shaft 207 can drive the inner side reverse stop tooth 302 to rotate on the outer side reverse stop tooth 303 in the process of driving the rotating type connecting shaft 207 to rotate, only one edge on the outer arc surface of the outer side reverse stop tooth 303 can rotate through the spring hinge, the outer side reverse stop tooth 303 can rotate through the spring hinge in the process of forward rotation of the inner side reverse stop tooth 302, so that the inner side reverse stop tooth 302 can smoothly pass through, and when the inner side reverse stop tooth 302 rotates reversely, the outer side reverse stop tooth 303 cannot rotate through the spring hinge at the moment, so that the inner side reverse stop tooth 302 cannot pass through.

Specifically, as shown in fig. 2 to 4, the sealing assembly 4 includes an outer buffer seat 402, an inner side passing connection port 401 is formed at the top of the outer buffer seat 402, the inner side buffer seat 304 is located at the inner side of the inner side passing connection port 401, a first sliding connection groove 305 is formed in the inner side wall of the inner side passing connection port 401, the outer side buffer seat 402 is located in the outer side passing connection port 406, the outer side passing connection port 406 is formed at the top of the balance seat 209, a second sliding connection groove 404 is formed at the top of the outer side buffer seat 402, a first sliding connection seat 403 is slidably connected in the second sliding connection groove 404, the top of the first sliding connection seat 403 is fixedly connected to the top of the inner side of the balance seat 209, a third support spring 405 is embedded in the position, corresponding to the first sliding connection seat 403, inside the second sliding connection groove 404, one end of the third support spring 405 is fixedly connected to the end surface of the inner side of the second sliding connection groove 404, and the other end of the third support spring 405 is fixedly connected to the surface of the first sliding connection seat 403.

The implementation mode specifically comprises the following steps: the outer cushion housing 402 is used to seal the outer passage connection port 406, and the inner cushion housing 304 is used to seal the inner passage connection port 401.

Specifically, as shown in fig. 7, the pushing assembly 5 includes a driving seat 501, a front end of the driving seat 501 is clamped on a rear end face of the balancing seat 209, a second sliding connection seat 502 is slidably connected to the driving seat 501, a piston rod 505 is fixedly connected to a front end face of the second sliding connection seat 502, the piston rod 505 is slidably connected to an end face of a rear side of the support seat 506, the support seat 506 is fixedly connected to an inner side wall of the driving seat 501, one end of a front side of the piston rod 505 is rotatably connected to one end of a movable shaft 507, the other end of the movable shaft 507 is rotatably connected to a position where a top of a third sliding bevel gear 508 deviates from a circle center, the third sliding bevel gear 508 is rotatably connected to the inner side wall of the driving seat 501, the third sliding bevel gear 508 is engaged with the first linking bevel gear 205, a bridge-type connection frame 503 is fixedly connected to a side end face of the second sliding connection seat 502, the bridge-type connection frame 503 is slidably connected to a sliding connection port 504 formed in a surface of the driving seat 501, a surface of the driving seat 501 is slidably connected to a pushing frame 510, a clamp 510 is fixedly connected to a side end face of the inner side wall 503 of the bridge-type connection frame, and a clamp 510 is formed at a position corresponding to a clamp 511 of the driving seat 501, and a clamp groove 511 is formed in the top of the pushing frame 511.

The implementation mode is specifically as follows: the rotating connecting shaft 207 utilizes the linkage effect between the first linkage bevel gear 205 and the third linkage bevel gear 508, so as to drive one end of the movable shaft 507 to perform eccentric motion, drive the second sliding connecting seat 502 to perform stable piston motion on the inner side of the driving seat 501 through the piston rod 505, and drive the hoop 511 on the pushing frame 510 to move through the bridge-type connecting frame 503.

Specifically, as shown in fig. 5, the end of the threaded connection rod 201 is rotatably connected with the driving component 6, the driving component 6 includes a rotary connection sleeve 601, the rotary connection sleeve 601 is rotatably connected to the end of the threaded connection rod 201, a first adapter 602 is fixedly connected to the bottom of the rotary connection sleeve 601, an adapter shaft 603 is connected to the open inner rotation of the bottom of the first adapter 602, a second adapter 604 is fixedly connected to one end of the adapter shaft 603 far away from the first adapter 602, a rocker 605 is connected to the open inner rotation on the end face of the second adapter 604, a magnetic buckle 605 is further connected to the top of the second adapter 604 in a clamping manner, and the top of the magnetic buckle 605 is adsorbed at the bottom of the balance seat 209.

The implementation mode is specifically as follows: the second adaptor 604 rotates in the opening of the first adaptor 602, the rocker 605 rotates in the opening of the second adaptor 604, so that the whole driving assembly 6 can be unfolded, and the threaded connecting rod 201 can be driven to rotate in the threaded connecting cylinder 202 by shaking the rocker 605 by hand.

The working principle is as follows: when in use, the rocker 605 is rotated to enable the threaded connecting rod 201 to rotate in the threaded connecting cylinder 202, under the combined effect of the torsion force and the thread engagement force, the threaded connecting cylinder 202 will drive the sliding type pushing seat 203 to slide on the inner side of the balance seat 209, and the sliding connecting sleeve 210 and the driving wheel 208 associated with the sliding connecting sleeve 210 are pushed by the first supporting spring 204 to synchronously act, so that the two driving wheels 208 approach each other, thereby clamping and connecting various types of cables placed on the balance seat 209, effectively preventing the cables from falling off on the balance seat 209, ensuring the smooth subsequent cable tightness adjustment work, when the threaded connecting cylinder 202 is separated from the threaded connecting rod 201, the threaded connecting rod 201 continues to keep a rotating state, because the sliding connecting sleeve 210 and the sliding type pushing seat 203 are in an elastic connection relationship, the second linkage bevel gear 206 and the linkage shaft 211 are in elastic connection, so that the relevance between the first linkage bevel gear 205 and the second linkage bevel gear 206 can be effectively realized on the basis of conveniently clamping and connecting cables of different types, the linkage shaft 211 utilizes the linkage between the first linkage bevel gear 205 and the second linkage bevel gear 206, and then the cables can be driven to carry out transmission work through the two driving wheels 208, in the process of adjusting the tightness of the cables, the basic stability of the cables can still be ensured, the laying efficiency of the cables is effectively provided, in the process of rotating the rotating connecting shaft 207 driving the rotating connecting shaft 207, the inner side check tooth 302 can be driven to rotate on the outer side check tooth, and only one edge on the outer arc surface of the outer side check tooth 303 can rotate through the spring hinge, in the process of forward rotation of the inner reverse stop tooth 302, the outer reverse stop tooth 303 rotates through the spring hinge, so that the inner reverse stop tooth 302 can pass smoothly, when the inner reverse stop tooth 302 rotates reversely, the outer reverse stop tooth 303 cannot rotate through the spring hinge at the moment, so that the inner reverse stop tooth 302 cannot pass, and therefore, the driving wheel 208 can be effectively ensured to rotate reversely, and the stability of the cable after clamping connection is further improved.

The above description is only for the preferred embodiment of the present invention, but the scope of the present invention is not limited thereto, and any person skilled in the art should be able to cover the technical scope of the present invention and the equivalent alternatives or modifications according to the technical solution and the inventive concept of the present invention within the technical scope of the present invention.

Claims

1. The utility model provides a can improve support frame for cable of arranging efficiency, includes concrete cable pole (1), fixedly connected with cable tray mechanism (2) are gone up in concrete cable pole (1), be provided with contrary subassembly (3) that ends on cable tray mechanism (2) to the position department that corresponds contrary subassembly (3) that ends on cable tray mechanism (2) still is provided with seal assembly (4), be provided with propelling movement subassembly (5), its characterized in that on the rear side terminal surface of cable tray mechanism (2):

cable tray mechanism (2) are including balanced seat (209) and universal driving shaft (211), the surface of universal driving shaft (211) has cup jointed and has slided adapter sleeve (210), the opposite face of slideing adapter sleeve (210) and sliding propelling movement seat (203) is through first supporting spring (204) fixed connection to first supporting spring (204) cup joint the surface at universal driving shaft (211), the top of slideing adapter sleeve (210) is rotated and is connected with rotary type even axle (207), the fixed surface of rotary type even axle (207) is connected with first linkage bevel gear (205) to the position department that universal driving shaft (211) surface corresponds first linkage bevel gear (205) has second linkage bevel gear (206) through elastic component sliding connection, the top fixedly connected with drive wheel (208) of rotary type even axle (207).

2. The supporting frame for cables capable of improving the arrangement efficiency as claimed in claim 1, wherein two threaded connecting rods (201) are rotatably connected in a same driving cavity built in the balance seat (209), the thread directions of the two threaded connecting rods (201) are opposite to each other, a threaded connecting cylinder (202) is threadedly connected on the surface of the threaded connecting rod (201), the threaded connecting cylinder (202) is clamped on the end surface of a sliding pushing seat (203), the sliding pushing seat (203) is slidably connected in the driving cavity, and the adjacent ends of the two threaded connecting rods (201) are fixedly connected through a same linkage shaft (211).

3. The utility model provides a can improve support frame for cable of arranging efficiency, characterized in that, contrary subassembly (3) of ending is including contrary sleeve (301), be provided with a plurality of outside contrary tooth (303) that ends on the inside wall of contrary sleeve (301) of ending to the border department of outside contrary tooth (303) extrados is articulated through the intrados of spring hinge with contrary sleeve (301) of ending, the even fixed connection in surface correspondence a plurality of outside contrary tooth (303) position department of axle (207) of rotary type is inboard contrary tooth (302) that ends to intermeshing between inboard contrary tooth (302) that ends and the outside contrary tooth (303) of ending.

4. The supporting frame for cables capable of improving the arrangement efficiency as claimed in claim 3, wherein the non-return sleeve (301) is clamped at the top of the inner buffer base (304), the end of the inner buffer base (304) is slidably connected in a first sliding connecting groove (305), a second supporting spring (306) is embedded in the first sliding connecting groove (305) at a position corresponding to the inner buffer base (304), one end of the second supporting spring (306) is fixedly connected to the end surface of the inner side of the first sliding connecting groove (305), and the other end of the second supporting spring (306) is fixedly connected to a surface close to the inner buffer base (304).

5. A cable support frame capable of improving arrangement efficiency according to claim 4, wherein the sealing component (4) comprises an outer buffer seat (402), the top of the outer buffer seat (402) is provided with an inner through connection port (401), the inner buffer seat (304) is positioned at the inner side of the inner through connection port (401), and the first sliding connection groove (305) is provided on the inner side wall of the inner through connection port (401).

6. The cable support frame capable of improving the arrangement efficiency as claimed in claim 5, wherein the outer buffer seat (402) is located in an outer passing connection port (406), the outer passing connection port (406) is opened at the top of the balance seat (209), a second sliding connection groove (404) is opened at the top of the outer buffer seat (402), and the first sliding connection seat (403) is slidably connected in the second sliding connection groove (404).

7. The cable support frame capable of improving the arrangement efficiency according to claim 6, wherein the top of the first sliding connection seat (403) is fixedly connected to the top of the inner side of the balance seat (209), a third support spring (405) is embedded and connected to the inner side of the second sliding connection groove (404) at a position corresponding to the first sliding connection seat (403), one end of the third support spring (405) is fixedly connected to the end surface of the inner side of the second sliding connection groove (404), and the other end of the third support spring (405) is fixedly connected to a surface close to the first sliding connection seat (403).

8. The cable support frame capable of improving the arrangement efficiency as claimed in claim 1, wherein the pushing assembly (5) comprises a driving seat (501), the front end of the driving seat (501) is clamped on the rear end face of the balance seat (209), a second sliding connection seat (502) is slidably connected in the driving seat (501), a piston rod (505) is fixedly connected on the front end face of the second sliding connection seat (502), the piston rod (505) is slidably connected on the rear end face of the support seat (506), the support seat (506) is fixedly connected on the inner side wall of the driving seat (501), one end of the front side of the piston rod (505) is rotatably connected with one end of a movable shaft (507), the other end of the movable shaft (507) is rotatably connected at a position where the top circle center of a third linkage bevel gear (508) deviates, the third linkage bevel gear (508) is rotatably connected on the inner side wall of the driving seat (501), and the third linkage bevel gear (508) is engaged with the first linkage bevel gear (205).

9. The supporting frame for the cables, which can improve the arrangement efficiency, as claimed in claim 8, wherein a bridge-type connecting frame (503) is fixedly connected to a side end face of the second sliding connecting seat (502), the bridge-type connecting frame (503) is slidably connected to a sliding connecting port (504) formed on a side end face of the driving seat (501), a pushing frame (510) is slidably connected to a surface of the driving seat (501), an inner side wall of the pushing frame (510) is fixedly connected to a side close to the bridge-type connecting frame (503), a clamp (511) is clamped to an inner side wall of the pushing frame (510), and a pushing groove (509) is formed at a position, corresponding to the clamp (511), of the top of the driving seat (501).

10. The supporting frame capable of improving the arrangement efficiency for the cables as claimed in claim 2, wherein the end of the threaded connecting rod (201) is rotatably connected with a driving component (6), the driving component (6) comprises a rotary connecting sleeve (601), the rotary connecting sleeve (601) is rotatably connected to the end of the threaded connecting rod (201), the bottom of the rotary connecting sleeve (601) is fixedly connected with a first adapter (602), an open inner rotation of the bottom of the first adapter (602) is connected with an adapter shaft (603), one end of the adapter shaft (603) far away from the first adapter (602) is fixedly connected with a second adapter (604), an open inner rotation of the end face of the second adapter (604) is connected with a rocker (605), the top of the second adapter (604) is further connected with a magnetic buckle (605), and the top of the magnetic buckle (605) is adsorbed to the bottom of the balance seat (209).