CN112660916A

CN112660916A - Cable coiling device for power cable fault

Info

Publication number: CN112660916A
Application number: CN202110092371.7A
Authority: CN
Inventors: 胡金俊
Original assignee: Individual
Current assignee: Shanghai Heyang Power Technology Co ltd; State Grid Shanghai Electric Power Co Ltd
Priority date: 2021-01-24
Filing date: 2021-01-24
Publication date: 2021-04-16
Anticipated expiration: 2041-01-24
Also published as: CN112660916B

Abstract

The invention relates to the field of power cables, in particular to a cable winding device for faulty power cables, comprising a winding assembly, a support assembly, a transmission assembly, a guide assembly and a cleaning assembly. The support assembly, transmission assembly, guide assembly and The cleaning assemblies are all arranged above the winding assembly, the support assembly and the transmission assembly are respectively arranged at both ends of the top of the winding assembly, and the guide assembly is arranged between the support assembly and the transmission assembly. The first toggle block in the winding assembly can drive the first rotating shaft to rotate, the first rotating shaft can drive the second gear to rotate through the first gear when it rotates, and the second gear can drive the second gear to rotate when it rotates The first screw rod at the bottom of the shaft rotates. When the first screw rod rotates, it can drive the lifting block to slide inside the first groove. The lifting block can adjust the distance between the winding roller and the base when lifting and sliding, which can effectively The adjustment of the length of the cable that the take-up roller can take up.

Description

Cable coiling device for power cable fault

Technical Field

The invention relates to the field of power cables, in particular to a cable winding device for power cable faults.

Background

The power cable is used for transmitting and distributing electric energy, and is commonly used for urban underground power grids, power station leading-out lines, power supply inside industrial and mining enterprises and power transmission lines under river-crossing seawater. When the power cable is dismantled after a fault occurs, the dismantled cable needs to be rolled up in order to recycle the cable. Current cable coiling mechanism its function singleness can only drive the wind-up roll through the wind-up shaft and carry out the rolling to the cable when rolling the cable, the cable is when rolling to the wind-up roll, the cable major part can pile up the mid portion at the wind-up roll, it can be loose when leading to the cable to pull down by the wind-up roll, and the length of its rolling is limited when rolling the cable to current cable coiling mechanism, the effect that leads to the rolling is not good, the while rolling is unable clearance of adnexed dirt on the cable on the wind-up roll, make the cable very inconvenient when subsequent recycle.

Disclosure of Invention

Aiming at the problems in the prior art, the invention provides a cable winding device for power cable faults.

The technical scheme adopted by the invention for solving the technical problems is as follows: a cable winding device for power cable faults comprises a winding component, a supporting component, a transmission component, a guiding component and a cleaning component, wherein the supporting component, the transmission component, the guiding component and the cleaning component are all arranged above the winding component, the supporting component and the transmission component are respectively arranged at two ends of the top of the winding component, the guiding component is arranged between the supporting component and the transmission component, and the cleaning component is arranged inside the guiding component; the winding assembly comprises a base, a first side plate is fixedly connected to one end of the top of the base, a first groove and a second groove are formed in the plate wall of the first side plate in a penetrating mode, the first groove is arranged below the second groove, a lifting block is connected to the inside of the first groove in a sliding mode, a first gear is arranged inside the second groove, a first rotating shaft is fixedly inserted into the top of the first gear in a penetrating mode, one end, away from the first gear, of the first rotating shaft extends out of the second groove and is fixedly connected with a first shifting block, second rotating shafts are symmetrically arranged on two sides of the first rotating shaft and are rotatably connected with the inner wall of the second groove, a second gear is fixedly sleeved on the shaft wall of the second rotating shaft and is meshed with the first gear, and the bottom of the second rotating shaft extends into the first groove through the second groove, just the second axis of rotation extends to the first lead screw of the inside one end fixedly connected with of first recess, the elevator is passed to the one end that the second axis of rotation was kept away from to first lead screw, just first lead screw and elevator threaded connection, it has the third axis of rotation to run through to rotate on the elevator lateral wall, the fixed cover of third axis of rotation has connect the wind-up roll on passing the axle wall of elevator one end, the wind-up roll is equipped with the annular around opening on being close to the roller wall of first curb plate one end, fixedly connected with direction rope on the inner wall of annular, the first slider of the equal fixedly connected with in both ends of elevator, correspond first slider on the inner wall of first recess and seted up first spout, first slider sliding connection is in the inside of first spout.

Specifically, the supporting component includes second curb plate and second spout, it has the second slider respectively to divide equally at the both ends of second curb plate bottom, the top at the base is seted up to the second spout, just second spout and second slider phase-match set up, second slider sliding connection is in the inside of second spout.

Specifically, the transmission assembly comprises a first transmission wheel and a fourth rotation shaft, the first transmission wheel is fixedly sleeved on a shaft wall at one end, far away from the wind-up roll, of the third rotation shaft, the fourth rotation shaft is fixedly connected to a plate wall at one side, far away from the second side plate, of the first side plate, a second transmission wheel is rotatably sleeved on the shaft wall at the other end of the fourth rotation shaft, a third groove is formed in one side, close to the first side plate, of the second transmission wheel, first meshing teeth are arranged on the inner wall of the third groove, a rotation disc is fixedly connected to the inside of the third groove, second meshing teeth are arranged on the side wall of the excircle side of the rotation disc, a third gear is arranged below the rotation disc, the third gear is meshed with the first meshing teeth and the second meshing teeth, a fifth rotation shaft is fixedly connected to one side of the third gear, and the fifth rotation shaft is rotatably connected to the first side plate, the side wall of the bottom of the first side plate is rotatably connected with a sixth rotating shaft, the other end of the sixth rotating shaft is fixedly connected with a third driving wheel, and the third driving wheel, the second driving wheel and the first driving wheel are in transmission connection through a driving belt.

Specifically, the direction subassembly includes a second lead screw and three guide bar, and is three guide bar and a second lead screw set up respectively in the first curb plate and are close to the four corners department of second curb plate lateral wall, the second lead screw rotates and pegs graft on the lateral wall of first curb plate, guide bar and first curb plate fixed connection, the one end fixedly connected with fourth gear that the first curb plate was passed to the second lead screw, the fourth gear is connected with the meshing of third gear, the screw thread is pegged graft on the pole wall that fourth gear one end was kept away from to the second lead screw has the guide block, the other end and the guide bar sliding connection of guide block, run through on the lateral wall of guide block and seted up the fourth recess.

Specifically, the cleaning assembly comprises two springs, the two springs are respectively and fixedly connected with the inner top and the inner bottom of the fourth groove, the adjacent ends of the two springs are fixedly connected with a clamping block, the clamping block is connected inside the fourth groove in a sliding manner, a fifth groove is formed in one end, far away from the spring, of the clamping block, a cleaning roller is arranged in the fifth groove, two ends of the cleaning roller are fixedly connected with pin shafts, the other end of the pin shaft is rotationally connected with the inner wall of a fifth groove, a scraper is fixedly connected on the inner wall of the fifth groove at a position corresponding to the cleaning roller, the other end of the scraper is contacted with the roller wall of the cleaning roller, both ends of the clamping block are fixedly connected with third sliding blocks, and a third sliding groove is formed in the inner wall of the fourth groove corresponding to the third sliding block, and the third sliding block is connected to the inside of the third sliding groove in a sliding mode.

Specifically, one end of the third rotating shaft penetrating through the first driving wheel is fixedly connected with a second stirring block, and the diameter of the second stirring block is larger than that of the third rotating shaft.

The invention has the beneficial effects that:

(1) according to the cable winding device for power cable faults, the first rotating shaft can be driven to rotate through the first poking block in the winding assembly, the first rotating shaft can drive the second gear to rotate through the first gear when rotating, the second gear can drive the first screw rod at the bottom of the second rotating shaft to rotate when rotating, the first screw rod can drive the lifting block to slide in the first groove when rotating, the lifting block can adjust the distance between the winding roller and the base when lifting and sliding, and the length of a cable which can be wound by the winding roller can be effectively adjusted.

(2) According to the cable winding device for power cable faults, through the arranged transmission assembly, when the third rotating shaft in the winding assembly drives the winding roller to wind cables, the first transmission wheel on the third rotating shaft can drive the second transmission wheel to rotate through the transmission belt, the second transmission wheel can drive the third gear to rotate in a reciprocating forward direction and a reciprocating reverse direction through the first meshing teeth and the second meshing teeth when rotating, the third gear can drive the second lead screw to rotate through the meshed fourth gear when rotating, and the second lead screw can drive the guide block which is in threaded sleeve joint on the rod wall to move between the first side plate and the second side plate in a reciprocating mode when rotating, so that the cables which penetrate through the fourth groove can be guided, and the cables are uniformly and flatly laid on the winding roller.

(3) According to the cable winding device for power cable faults, the cleaning assembly is arranged in the fourth groove, when a cable passes through the fourth groove and is wound onto the winding roller, the two clamping blocks can drive the cleaning roller to clamp the cable under the elastic force of the spring, and when the cable is wound, the cleaning roller can clean dirt on the cable, so that the cable wound on the winding roller is more convenient to recycle.

Drawings

The invention is further illustrated with reference to the following figures and examples.

Fig. 1 is a schematic structural view of a cable take-up device for power cable failure according to the present invention;

fig. 2 is a schematic view of an internal structure of a cable take-up device for power cable failure according to the present invention;

fig. 3 is a schematic structural diagram of a cleaning assembly in a cable take-up device for power cable faults according to the present invention;

fig. 4 is a sectional view taken along a direction a-a in fig. 1 of a cable retractor for power cable failure according to the present invention;

fig. 5 is a sectional view taken along the direction B-B in fig. 1 of a cable retractor for power cable failure according to the present invention;

fig. 6 is a partially enlarged view of a portion C of fig. 1 of a cable retractor for power cable failure according to the present invention;

fig. 7 is a schematic structural diagram of a second driving wheel in the cable take-up device for power cable failure according to the present invention;

fig. 8 is a schematic view of a connection structure of a first gear and a second gear in the cable take-up device for power cable failure according to the present invention.

In the figure: 1. a winding component; 11. a base; 12. a first side plate; 13. a first groove; 14. a lifting block; 15. a second groove; 16. a first gear; 17. a first rotating shaft; 18. a first toggle block; 19. a second rotating shaft; 110. a second gear; 111. a first lead screw; 112. a third rotating shaft; 113. a wind-up roll; 114. a ring groove; 115. a guide rope; 116. a first slider; 117. a first chute; 2. a support assembly; 21. a second side plate; 22. a hinge; 23. a second slider; 24. a second chute; 3. a transmission assembly; 31. a first drive pulley; 32. a fourth rotating shaft; 33. a second transmission wheel; 34. a third groove; 35. a first meshing tooth; 36. rotating the disc; 37. a second meshing tooth; 38. a third gear; 39. a fifth rotating shaft; 310. a sixth rotating shaft; 311. a third transmission wheel; 312. a drive belt; 313. a second toggle block; 4. a guide assembly; 41. a second lead screw; 42. a guide bar; 43. a fourth gear; 44. a guide block; 45. a fourth groove; 5. cleaning the assembly; 51. a spring; 52. a clamping block; 53. a fifth groove; 54. cleaning the roller; 55. a pin shaft; 56. a squeegee; 57. a third slider; 58. and a third chute.

Detailed Description

In order to make the technical means, the creation characteristics, the achievement purposes and the effects of the invention easy to understand, the invention is further described with the specific embodiments.

As shown in fig. 1-8, the cable winding device for power cable faults according to the present invention includes a winding assembly 1, a supporting assembly 2, a transmission assembly 3, a guiding assembly 4, and a cleaning assembly 5, wherein the supporting assembly 2, the transmission assembly 3, the guiding assembly 4, and the cleaning assembly 5 are all disposed above the winding assembly 1, the supporting assembly 2 and the transmission assembly 3 are respectively disposed at two ends of the top of the winding assembly 1, the guiding assembly 4 is disposed between the supporting assembly 2 and the transmission assembly 3, and the cleaning assembly 5 is disposed inside the guiding assembly 4; the winding assembly 1 comprises a base 11, one end of the top of the base 11 is fixedly connected with a first side plate 12, a first groove 13 and a second groove 15 are formed in the plate wall of the first side plate 12 in a penetrating manner, the first groove 13 is arranged below the second groove 15, a lifting block 14 is connected inside the first groove 13 in a sliding manner, a first gear 16 is arranged inside the second groove 15, a first rotating shaft 17 is fixedly inserted and inserted in the top of the first gear 16 in a penetrating manner, one end of the first rotating shaft 17, far away from the first gear 16, extends out of the second groove 15 and is fixedly connected with a first shifting block 18, second rotating shafts 19 are symmetrically arranged on two sides of the first rotating shaft 17, the second rotating shafts 19 are rotatably connected with the inner wall of the second groove 15, a second gear 110 is fixedly sleeved on the shaft wall of the second rotating shaft 19, and the second gear 110 is meshed with the first gear 16, the bottom of the second rotating shaft 19 extends through the second recess 15 to the inside of the first recess 13, and one end of the second rotating shaft 19 extending into the first groove 13 is fixedly connected with a first screw rod 111, one end of the first screw rod 111 far away from the second rotating shaft 19 passes through the lifting block 14, the first screw rod 111 is connected with the lifting block 14 by screw thread, a third rotating shaft 112 is inserted on the side wall of the lifting block 14 in a penetrating and rotating way, the third rotating shaft 112 is fixedly sleeved with a winding roller 113 through the shaft wall at one end of the lifting block 14, an annular groove 114 is formed around the roller wall of the winding roller 113 near one end of the first side plate 12, a guide rope 115 is fixedly connected to the inner wall of the ring groove 114, a first sliding block 116 is fixedly connected to both ends of the lifting block 14, a first sliding groove 117 is formed in the inner wall of the first groove 13 corresponding to the first sliding block 116, and the first sliding block 116 is slidably connected inside the first sliding groove 117.

Specifically, supporting component 2 includes second curb plate 21 and second spout 24, the both ends of second curb plate 21 bottom are equallyd divide and are articulated respectively through hinge 22 to have second slider 23, second spout 24 is seted up at the top of base 11, just second spout 24 and the setting of second slider 23 phase-match, second slider 23 sliding connection is in the inside of second spout 24.

Specifically, the transmission assembly 3 includes a first transmission wheel 31 and a fourth rotation shaft 32, the first transmission wheel 31 is fixedly sleeved on a shaft wall of one end of the third rotation shaft 112 far away from the wind-up roll 113, the fourth rotation shaft 32 is fixedly connected on a plate wall of one side of the first side plate 12 far away from the second side plate 21, a second transmission wheel 33 is rotatably sleeved on the shaft wall of the other end of the fourth rotation shaft 32, a third groove 34 is formed on one side of the second transmission wheel 33 close to the first side plate 12, a first meshing tooth 35 is arranged on the inner wall of the third groove 34, a rotation disc 36 is fixedly connected inside the third groove 34, a second meshing tooth 37 is arranged on the side wall of the outer circle side of the rotation disc 36, a third gear 38 is arranged below the rotation disc 36, the third gear 38 is meshed with the first meshing tooth 35 and the second meshing tooth 37, a fifth rotation shaft 39 is fixedly connected on one side of the third gear 38, the fifth rotating shaft 39 is rotatably connected with the first side plate 12, a sixth rotating shaft 310 is rotatably connected to the side wall of the bottom of the first side plate 12, a third driving wheel 311 is fixedly connected to the other end of the sixth rotating shaft 310, and the third driving wheel 311, the second driving wheel 33 and the first driving wheel 31 are in transmission connection through a driving belt 312.

Specifically, the guide assembly 4 includes a second screw rod 41 and three guide rods 42, the three guide rods 42 and the three second screw rods 41 are respectively disposed at four corners of the first side plate 12 close to the side plate wall of the second side plate 21, the second screw rod 41 is rotatably inserted into the side wall of the first side plate 12, the guide rods 42 are fixedly connected to the first side plate 12, one end of the second screw rod 41 penetrating through the first side plate 12 is fixedly connected to a fourth gear 43, the fourth gear 43 is engaged with the third gear 38, a guide block 44 is inserted into a screw thread on the rod wall of the end of the second screw rod 41 far away from the fourth gear 43, the other end of the guide block 44 is slidably connected to the guide rods 42, and a fourth groove 45 is formed in the side wall of the guide block 44 in a penetrating manner.

Specifically, the cleaning assembly 5 includes two springs 51, the two springs 51 are fixedly connected to the inner top and the inner bottom of the fourth groove 45, the adjacent ends of the two springs 51 are fixedly connected to the clamping block 52, the clamping block 52 is slidably connected to the inside of the fourth groove 45, a fifth groove 53 is formed in one end, away from the springs 51, of the clamping block 52, a cleaning roller 54 is arranged inside the fifth groove 53, both ends of the cleaning roller 54 are fixedly connected to a pin shaft 55, the other end of the pin shaft 55 is rotatably connected to the inner wall of the fifth groove 53, a scraping plate 56 is fixedly connected to the inner wall of the fifth groove 53 corresponding to the cleaning roller 54, the other end of the scraping plate 56 is in contact with the roller wall of the cleaning roller 54, both ends of the clamping block 52 are fixedly connected to a third sliding block 57, a third sliding groove 58 is formed in the inner wall of the fourth groove 45 corresponding to the third sliding block 57, the third slider 57 is slidably connected to the inside of the third sliding groove 58.

Specifically, one end of the third rotating shaft 112 penetrating through the first driving wheel 31 is fixedly connected with a second toggle block 313, the diameter of the second toggle block 313 is larger than that of the third rotating shaft 112, and the second toggle block 313 can enable the third rotating shaft 112 to be more convenient and labor-saving during rotation.

When the cable guide device is used, one end of a cable is connected with one end of the guide rope 115, which is far away from the wind-up roll 113, the third rotating shaft 112 is driven to rotate by the second toggle block 313, the third rotating shaft 112 can simultaneously drive the first driving wheel 31 and the wind-up roll 113 to rotate when rotating, the first driving wheel 31 can drive the second driving wheel 33 to rotate by the driving belt 312 when rotating, the second driving wheel 33 can drive the third gear 38 to perform reciprocating forward rotation and reverse rotation by the first meshing tooth 35 and the second meshing tooth 37 when rotating, the third gear 38 can drive the second lead screw 41 to rotate by the meshed fourth gear 43 when rotating, the second lead screw 41 can drive the guide block 44 sleeved on the rod wall by threads to perform reciprocating movement between the first side plate 12 and the second side plate 21 when rotating, so that the cable passing through the fourth groove 45 can be guided, when the cable passes through the fourth groove 45 and is wound on the winding roller 113, the two clamping blocks 52 can drive the cleaning roller 54 to clamp the cable under the elastic force of the spring 51, and when the cable is wound, the cleaning roller 54 can clean dirt on the cable, so that the cable wound on the winding roller 113 can be more conveniently recycled, when the maximum winding length of the winding roller 113 needs to be adjusted, the first poking block 18 is rotated, the first poking block 18 can drive the first rotating shaft 17 to rotate, the first rotating shaft 17 can drive the second gear 110 to rotate through the first gear 16 when rotating, the second gear 110 can drive the first screw rod 111 at the bottom of the second rotating shaft 19 to rotate when rotating, and the first screw rod 111 can drive the lifting block 14 to slide in the first groove 13 when rotating, the lifting block 14 can adjust the distance between the winding roller 113 and the base 11 when lifting and sliding, and the length of the cable which can be wound by the winding roller 113 can be effectively adjusted.

The invention has the beneficial effects that:

The foregoing illustrates and describes the principles, general features, and advantages of the present invention. It will be understood by those skilled in the art that the present invention is not limited to the embodiments described above, and the embodiments and descriptions given above are only illustrative of the principles of the present invention, and various changes and modifications may be made without departing from the spirit and scope of the invention, which fall within the scope of the claims. The scope of the invention is defined by the appended claims and equivalents thereof.

Claims

1. A cable winding device for power cable failure, characterized in that it comprises a winding assembly (1), a support assembly (2), a transmission assembly (3), a guide assembly (4) and a cleaning assembly (5), The support assembly (2), the transmission assembly (3), the guide assembly (4) and the cleaning assembly (5) are all arranged above the winding assembly (1), and the support assembly (2) and the transmission assembly (3) are respectively It is arranged on both ends of the top of the winding assembly (1), the guide assembly (4) is arranged between the support assembly (2) and the transmission assembly (3), and the cleaning assembly (5) is arranged on the guide assembly (4) ); the winding assembly (1) includes a base (11), and one end of the top of the base (11) is fixedly connected with a first side plate (12), and a wall of the first side plate (12) is A first groove (13) and a second groove (15) are formed therethrough, the first groove (13) is arranged below the second groove (15), and the first groove (13) is A lifting block (14) is slidably connected inside, a first gear (16) is arranged inside the second groove (15), and a first rotating shaft (16) is fixedly inserted through the top of the first gear (16). 17), the end of the first rotating shaft (17) away from the first gear (16) extends out of a second groove (15) and is fixedly connected with a first toggle block (18), the first rotating shaft ( 17) Both sides are symmetrically provided with a second rotating shaft (19), the second rotating shaft (19) is rotatably connected to the inner wall of the second groove (15), and the axis of the second rotating shaft (19) A second gear (110) is fixedly sleeved on the wall, the second gear (110) is meshed with the first gear (16), and the bottom of the second rotating shaft (19) passes through the second groove (15) ) extends to the inside of the first groove (13), and the end of the second rotating shaft (19) that extends to the inside of the first groove (13) is fixedly connected with a first screw (111), the first screw rod (111). The end of the lead screw (111) away from the second rotating shaft (19) passes through the lifting block (14), and the first lead screw (111) is threadedly connected with the lifting block (14), and the lifting block (14) side A third rotating shaft (112) is inserted through and rotated on the wall, and a winding roller (113) is fixedly sleeved on the shaft wall of one end of the lifting block (14) through the third rotating shaft (112). A ring groove (114) is formed around the roller wall of the winding roller (113) near one end of the first side plate (12), and a guide rope (115) is fixedly connected to the inner wall of the ring groove (114). Both ends of (14) are fixedly connected with a first sliding block (116), and a first sliding groove (117) is opened on the inner wall of the first groove (13) corresponding to the first sliding block (116). The first sliding block (116) is slidably connected inside the first sliding groove (117).

2 . The cable winding device for faulty power cables according to claim 1 , wherein the support assembly ( 2 ) comprises a second side plate ( 21 ) and a second chute ( 24 ), the Both ends of the bottom of the second side plate (21) are hinged with second sliding blocks (23) through hinges (22) respectively, the second sliding grooves (24) are opened on the top of the base (11), and the The second sliding groove (24) is matched with the second sliding block (23), and the second sliding block (23) is slidably connected inside the second sliding groove (24).

3 . The cable winding device for faulty power cables according to claim 1 , wherein the transmission assembly ( 3 ) comprises a first transmission wheel ( 31 ) and a fourth rotating shaft ( 32 ). The first transmission wheel (31) is fixedly sleeved on the shaft wall of the end of the third rotating shaft (112) away from the take-up roller (113), and the fourth rotating shaft (32) is fixedly connected to the first side plate (12) A second transmission wheel (33) is rotatably sleeved on the plate wall on the side away from the second side plate (21) and the shaft wall at the other end of the fourth rotating shaft (32), and the second transmission wheel (33) The side close to the first side plate (12) is provided with a third groove (34), the inner wall of the third groove (34) is provided with first meshing teeth (35), and the third groove ( 34) is fixedly connected with a rotating disc (36), the side wall of the outer circular side of the rotating disc (36) is provided with a second meshing tooth (37), and a third meshing tooth (37) is provided below the rotating disc (36). A gear (38), the third gear (38) is in meshing connection with the first meshing tooth (35) and the second meshing tooth (37), and a fifth rotating shaft is fixedly connected to one side of the third gear (38). (39), the fifth rotating shaft (39) is rotatably connected with the first side plate (12), and the side wall at the bottom of the first side plate (12) is rotatably connected with a sixth rotating shaft (310), so A third transmission wheel (311) is fixedly connected to the other end of the sixth rotating shaft (310), and the third transmission wheel (311), the second transmission wheel (33) and the first transmission wheel (31) pass through The drive belt (312) drives the connection.

4. A cable winding device for faulty power cables according to claim 1, characterized in that: the guide assembly (4) comprises a second screw rod (41) and three guide rods (42), three The guide rods (42) and the second screw rods (41) are respectively disposed at the four corners of the side wall of the first side plate (12) close to the second side plate (21), and the second screw rods (41) ) is rotated and inserted on the side wall of the first side plate (12), the guide rod (42) is fixedly connected with the first side plate (12), and the second screw rod (41) passes through the first side plate (12). One end of (12) is fixedly connected with a fourth gear (43), the fourth gear (43) is meshed with the third gear (38), and the second screw (41) is away from the fourth gear (43) at one end A guide block (44) is threadedly inserted on the rod wall of the guide block (44), the other end of the guide block (44) is slidably connected with the guide rod (42), and a fourth recess is formed through the side wall of the guide block (44). slot (45).

5 . The cable winding device for faulty power cables according to claim 1 , wherein the cleaning assembly ( 5 ) comprises a spring ( 51 ), and the spring ( 51 ) is provided with two springs ( 51 ). 5 . The springs (51) are respectively fixedly connected to the inner top and the inner bottom of the fourth groove (45), and a clamping block (52) is fixedly connected to the adjacent ends of the two springs (51). The clamping block (52) is slidably connected inside the fourth groove (45), and the end of the clamping block (52) away from the spring (51) is provided with a fifth groove (53), the fifth groove (53) is provided with a cleaning roller (54), both ends of the cleaning roller (54) are fixedly connected with a pin (55), and the other end of the pin (55) is connected to the fifth groove (53). ), the inner wall of the fifth groove (53) is fixedly connected with a scraper (56) at the position corresponding to the cleaning roller (54), and the other end of the scraper (56) is connected to the cleaning roller (54). ) contacting the roller walls of the ), both ends of the clamping block (52) are fixedly connected with a third sliding block (57), and the inner wall of the fourth groove (45) corresponding to the third sliding block (57) is provided with A third chute (58), the third sliding block (57) is slidably connected inside the third chute (58).

6. A cable winding device for faulty power cables according to claim 1, characterized in that: one end of the third rotating shaft (112) passing through the first transmission wheel (31) is fixedly connected with a second dial A moving block (313), and the diameter of the second toggle block (313) is larger than the diameter of the third rotating shaft (112).