CN107728254B

CN107728254B - Optical cable high altitude fusion splicing apparatus

Info

Publication number: CN107728254B
Application number: CN201710964568.9A
Authority: CN
Inventors: 项晓元; 刘成莹; 杨振亚
Original assignee: Anhui Communications Services Co Ltd
Current assignee: Anhui Communication Industry Service Co., Ltd.
Priority date: 2017-10-17
Filing date: 2017-10-17
Publication date: 2020-04-21
Anticipated expiration: 2037-10-17
Also published as: CN107728254A

Abstract

The invention belongs to the technical field of optical cable fusion devices, and particularly relates to an optical cable high-altitude fusion device which comprises a base, wherein a plurality of control devices are arranged at the lower end of the base, the lower ends of the base on the left side and the right side of the control devices are respectively and rotatably connected with a moving mechanism, a groove is arranged at the upper end of the base, a first sliding mechanism is arranged at the bottom of the groove, a first cylindrical barrel is rotatably connected to the bottom of the groove, the opening of the first cylindrical barrel is upward, the side wall of one end, close to the first sliding mechanism, of the first cylindrical barrel is rotatably connected with one end of a first linkage rod, the other end of the first linkage rod is rotatably connected with the first sliding mechanism, a rotating device is arranged at the bottom of the first cylindrical barrel, a lifting mechanism is arranged in the first cylindrical barrel and is in transmission connection with the rotating device. Has the advantages that: the invention not only can process the fault in time, but also the welding device is convenient to carry.

Description

Optical cable high altitude fusion splicing apparatus

Technical Field

The invention belongs to the technical field of optical cable fusion splicing devices, and particularly relates to an optical cable high-altitude fusion splicing device.

Background

The optical cable is a main transmission tool of various information networks, and due to the limitation of the production length of the optical cable, in order to ensure long-distance transmission, the optical cable is separated from a tower overhead laying process of an electric power high-voltage line by a certain distance, and an optical cable splicing box is installed. Meanwhile, for the convenience of daily operation and maintenance, partial optical cables, namely residual cables, can be reserved at the position of the tower where the aerial optical cable junction box is located, when the optical cables near the junction box break down, the reserved residual cables are spread and subjected to fault treatment, and then optical fibers in the junction box are welded again.

At present, a method for completing fault treatment of an optical cable by building a scaffold also exists in the prior art, the scaffold needs more materials, and the building time is long. And the scaffold needs to be built again for fault treatment at each time, the height of different towers is required to be met, the time consumption is high, the maintenance period is long, the fault cannot be timely treated, and the scaffold is inconvenient to carry.

To this end, we propose an overhead fusion splicing device for optical cables to solve the above problems.

Disclosure of Invention

The invention aims to solve the problems and provides the portable optical cable high-altitude fusion splicing device which can timely process faults.

In order to achieve the purpose, the invention adopts the following technical scheme: an optical cable high-altitude fusion splicing device comprises a base, wherein a plurality of control devices are arranged at the lower end of the base, the lower ends of the base at the left side and the right side of the control devices are respectively and rotatably connected with a moving mechanism, a groove is arranged at the upper end of the base, a first sliding mechanism is arranged at the bottom of the groove, a first cylindrical barrel is rotatably connected at the bottom of the groove, the opening of the first cylindrical barrel is upward, the side wall of one end, close to the first sliding mechanism, of the first cylindrical barrel is rotatably connected with one end of a first linkage rod, the other end of the first linkage rod is rotatably connected with the first sliding mechanism, a rotating device is arranged at the bottom of the first cylindrical barrel, a lifting mechanism is arranged in the first cylindrical barrel and is in transmission connection with the rotating device, a support rod is arranged at the upper end of the lifting mechanism, a support plate, the one end that the bracing piece was kept away from to the backup pad is equipped with the rope ladder, the lower extreme of backup pad rotates and is connected with the second trace, be equipped with second slide mechanism on the lateral wall of bracing piece, and second slide mechanism is located the below of backup pad, the one end that the backup pad was kept away from to the second trace is rotated with second slide mechanism and is connected, the upper end of bracing piece is equipped with the butt fusion platform.

In the optical cable high-altitude fusing device, the control device comprises a second cylindrical barrel arranged at the lower end of the base, the opening of the second cylindrical barrel is arranged downwards, a first through hole communicated with the inside and the outside is arranged on the side wall of the front end of the second cylindrical barrel, a worm rod penetrates through the first through hole, a first lifting plate is arranged in the second cylindrical barrel, the left end and the right end of the first lifting plate are slidably connected with the inner walls of the left end and the right end of the second cylindrical barrel, a first threaded hole communicated with the upper part and the lower part is arranged on the first lifting plate, a first threaded rod is connected with the first threaded hole in a threaded manner, the upper end of the first threaded rod is rotatably connected with the top surface of the second cylindrical barrel, a worm wheel is fixedly sleeved on the first threaded rod and positioned above the first lifting plate, the worm wheel is meshed with the worm rod, second through holes communicated with the inside and the outside are arranged on the, and a moving rod penetrates through the second through hole, the lower end of the moving rod is rotatably connected with the upper end of a third linkage rod, the third linkage rod is arranged at one end of the moving rod, which is positioned in the second cylindrical barrel, and the lower end of the third linkage rod is rotatably connected with the upper end of the first lifting plate.

In the above optical cable high-altitude fusing device, the moving mechanism includes a rotating block arranged at the lower end of the base, the rotating block is rotatably connected with the base, the side wall of the rotating block is rotatably connected with one end of the moving rod, which is located outside the second cylindrical barrel, the lower end of the rotating block is connected with a telescopic rod, a spring is sleeved on the telescopic rod, and the lower end of the telescopic rod is connected with a roller.

In the above optical cable high-altitude fusing device, the first sliding mechanism includes a first sliding groove horizontally arranged at the bottom of the groove, a first sliding block is arranged in the first sliding groove, the upper end of the first sliding block is rotatably connected with one end, away from the first cylindrical barrel, of the first linkage rod, the inner wall of one end, away from the first cylindrical barrel, of the first sliding groove is connected with one end of the first hydraulic cylinder, and the other end of the first hydraulic cylinder is connected with the side wall of the first sliding block.

In the above optical cable high-altitude fusion device, the rotating device includes a rotating motor disposed at the bottom of the first cylindrical barrel, a driving shaft of the rotating motor is disposed vertically upward, a first chain disc is sleeved on the driving shaft of the rotating motor, and the first chain disc is in transmission connection with the lifting mechanism.

In foretell optical cable high altitude melting device, elevating system is including setting up the second lifter plate in first cylinder bucket, both ends about the second lifter plate respectively with first cylinder bucket about both ends inner wall sliding connection, be equipped with the second screw hole of intercommunication from top to bottom on the second lifter plate, and second screw hole female connection has the second threaded rod, the lower extreme of second threaded rod rotates with the bottom of first cylinder bucket to be connected, cup jointed the second chain dish on the second threaded rod, and the second chain dish is located the below of second lifter plate, the second chain dish is connected with first chain dish transmission.

In the above optical cable high-altitude fusing device, the second sliding mechanism includes a second sliding groove vertically arranged on the side wall of the supporting rod, the second sliding groove is located below the supporting plate, a second sliding block is arranged in the second sliding groove, the side wall of the second sliding block is rotatably connected with one end, away from the supporting plate, of the second linkage rod, a second hydraulic cylinder is arranged at the bottom of the second sliding groove, and the upper end of the second hydraulic cylinder is connected with the lower end of the second sliding block.

In the above optical cable high-altitude fusion device, the fusion platform comprises an operation board arranged at the upper end of the support rod, a placing groove is arranged at the upper end of the operation board, and a cover plate is rotatably connected to the side wall of one end of the placing groove.

Compared with the prior art, the high-altitude fusion splicing device for the optical cable has the advantages that: the invention drives the moving rod to move in the horizontal direction through the rotating worm, the moving mechanism can be driven to rotate, when the moving mechanism is contacted with the ground, the welding device can be conveniently moved, the flexibility of the welding device is improved, the welding device can be rapidly moved to a designated position according to welding requirements, the fault treatment efficiency is improved, the telescopic rod and the spring enable the welding device to stably move on the uneven ground, the influence of external force on the welding device is reduced, the rotating motor works to drive the welding platform to lift, the height of the welding platform is convenient to adjust, the welding device can be suitable for towers with different heights, the first hydraulic cylinder works to drive the first cylindrical barrel to rotate, the second hydraulic cylinder works to drive the supporting plate to rotate, the welding device is convenient to store through the action of the first hydraulic cylinder and the second hydraulic cylinder, and the welding device is convenient to carry, not only can make the butt fusion device portable, can be timely moreover handle the trouble, improve fault handling's efficiency.

Drawings

FIG. 1 is a perspective view of an overhead fusion splice for fiber optic cables according to the present invention;

FIG. 2 is an enlarged view of a portion of FIG. 1 at A;

FIG. 3 is an enlarged view of a portion of FIG. 1 at B;

fig. 4 is a schematic front view of an overhead fusion splicing device for optical cables according to the present invention.

In the figure, 1 base, 2 control device, 3 moving mechanism, 4 grooves, 5 first sliding mechanism, 6 first cylindrical barrel, 7 first linkage rod, 8 rotating device, 9 lifting mechanism, 10 support rod, 11 support plate, 12 rope ladder, 13 second linkage rod, 14 second sliding mechanism, 15 welding platform, 16 second cylindrical barrel, 17 worm, 18 first lifting plate, 19 first threaded rod, 20 worm wheel, 21 moving rod, 22 third linkage rod, 23 rotating block, 24 telescopic rod, 25 spring, 26 idler wheel, 27 first sliding chute, 28 first sliding block, 29 first hydraulic cylinder, 30 rotating motor, 31 first chain plate, 32 second lifting plate, 33 second threaded rod, 34 second chain plate, 35 second sliding chute, 36 second sliding block, 37 second hydraulic cylinder, 38 operating plate, 39 placing groove and 40 cover plate.

Detailed Description

The following examples are for illustrative purposes only and are not intended to limit the scope of the present invention.

Examples

As shown in figures 1-4, an optical cable high-altitude fusion splicing device comprises a base 1, a plurality of control devices 2 are arranged at the lower end of the base 1, the lower ends of the base 1 at the left side and the right side of each control device 2 are rotatably connected with a moving mechanism 3, a groove 4 is arranged at the upper end of the base 1, a first sliding mechanism 5 is arranged at the bottom of the groove 4, a first cylindrical barrel 6 is rotatably connected with the bottom of the groove 4, the opening of the first cylindrical barrel 6 is upward arranged, the side wall of one end, close to the first sliding mechanism 5, of the first cylindrical barrel 6 is rotatably connected with one end of a first linkage rod 7, the other end of the first linkage rod 7 is rotatably connected with the first sliding mechanism 5, a rotating device 8 is arranged at the bottom of the first cylindrical barrel 6, a lifting mechanism 9 is arranged in the first cylindrical barrel 6, the lifting mechanism 9 is in transmission connection with the rotating device 8, a support rod 10 is arranged, the one end that the bracing piece 11 was kept away from to backup pad 11 is equipped with rope ladder 12, and rope ladder 12 is convenient for the workman to climb to backup pad 11 on, and the lower extreme of backup pad 11 rotates and is connected with second trace 13, is equipped with second slide mechanism 14 on the lateral wall of bracing piece 10, and second slide mechanism 14 is located the below of backup pad 11, and the one end that backup pad 11 was kept away from to second trace 13 rotates with second slide mechanism 14 to be connected, and the upper end of bracing piece 10 is equipped with butt fusion platform 15.

Wherein, the control device 2 comprises a second cylindrical barrel 16 arranged at the lower end of the base 1, the opening of the second cylindrical barrel 16 is arranged downwards, the side wall of the front end of the second cylindrical barrel 16 is provided with a first through hole which is communicated with the inside and the outside, a worm 17 penetrates through the first through hole, one end of the worm 17 positioned outside the second cylindrical barrel 16 is connected with a hand wheel, the worm 17 is convenient to rotate, a first lifting plate 18 is arranged in the second cylindrical barrel 16, the left and the right ends of the first lifting plate 18 are in sliding connection with the inner walls of the left and the right ends of the second cylindrical barrel 16, the first lifting plate 18 is provided with a first threaded hole which is communicated with the top and the bottom, the first threaded hole is internally threaded with a first threaded rod 19, the upper end of the first threaded rod 19 is rotatably connected with the top surface of the second cylindrical barrel 16, a worm wheel 20 is fixedly sleeved on the first threaded rod 19, the worm wheel 20 is positioned above the first lifting, the lateral wall all is equipped with the second through-hole of inside and outside intercommunication about the second cylinder bucket 16 on, and runs through in the second through-hole and be equipped with the carriage release lever 21, and the lower extreme of carriage release lever 21 rotates with the upper end of third trace 22 to be connected, and third trace 22 sets up and is located one of second cylinder bucket 16 in carriage release lever 21 and serve, and the lower extreme of third trace 22 rotates with the upper end of first lifter plate 18 to be connected.

More specifically, moving mechanism 3 is including setting up in turning block 23 of base 1 lower extreme, and turning block 23 rotates with base 1 to be connected, and the lateral wall of turning block 23 rotates with the one end that carriage release lever 21 is located the outside second cylinder bucket 16 to be connected, and the lower extreme of turning block 23 is connected with telescopic link 24, has cup jointed spring 25 on the telescopic link 24, and the lower extreme of telescopic link 24 is connected with gyro wheel 26.

The first sliding mechanism 5 comprises a first sliding chute 27 horizontally arranged at the bottom of the groove 4, a first sliding block 28 is arranged in the first sliding chute 27, the upper end of the first sliding block 28 is rotatably connected with one end, away from the first cylindrical barrel 6, of the first linkage rod 7, the inner wall of one end, away from the first cylindrical barrel 6, of the first sliding chute 27 is connected with one end of a first hydraulic cylinder 29, and the other end of the first hydraulic cylinder 29 is connected with the side wall of the first sliding block 28.

Wherein, the rotating device 8 comprises a rotating motor 30 arranged on the bottom of the first cylindrical barrel 6, the rotating motor 30 is a servo motor, which is convenient for driving a second threaded rod 33 to rotate clockwise and anticlockwise, a driving shaft of the rotating motor 30 is vertically arranged upwards, a first chain disc 31 is sleeved on the driving shaft of the rotating motor 30, the first chain disc 31 is in transmission connection with a lifting mechanism 9, the lifting mechanism 9 comprises a second lifting plate 32 arranged in the first cylindrical barrel 6, the left and right ends of the second lifting plate 32 are respectively in sliding connection with the inner walls of the left and right ends of the first cylindrical barrel 6, a second threaded hole which is communicated up and down is arranged on the second lifting plate 32, a second threaded rod 33 is in threaded connection with the second threaded hole, the lower end of the second threaded rod 33 is rotatably connected with the bottom of the first cylindrical barrel 6, a second chain disc 34 is sleeved on the second threaded rod 33, and the second chain disc 34 is positioned below the second lifting plate 32, the second chain wheel 34 is in driving connection with the first chain wheel 31 via a chain.

The second sliding mechanism 14 includes a second sliding groove 35 vertically disposed on the side wall of the support rod 10, the second sliding groove 35 is located below the support plate 11, a second sliding block 36 is disposed in the second sliding groove 35, the side wall of the second sliding block 36 is rotatably connected with one end of the second linkage rod 13 far away from the support plate 11, a second hydraulic cylinder 37 is disposed at the bottom of the second sliding groove 35, and the upper end of the second hydraulic cylinder 37 is connected with the lower end of the second sliding block 36.

Wherein, the butt fusion platform 15 is including setting up the operation panel 38 in the bracing piece 10 upper end, places the cable splice box on the operation panel 38 and carries out the butt fusion again, and the upper end of operation panel 38 is equipped with standing groove 39, can place the instrument that the butt fusion needs in standing groove 39, not only is convenient for take, has also reduced workman's intensity of labour, rotates on the one end lateral wall of standing groove 39 and is connected with apron 40.

The invention drives the worm 17 to rotate by rotating the hand wheel, the worm 17 is meshed with the worm wheel 20, the first threaded rod 19 is driven to rotate, so that the first lifting plate 18 slides in the second cylindrical barrel 16, the moving rod 21 is driven to move in the horizontal direction by the action of the third linkage rod 22, the moving mechanism 3 can be driven to rotate, when the roller 26 is in contact with the ground, the welding device is convenient to move, when the second cylindrical barrel 16 is in contact with the ground, the welding device is convenient to be fixed on the ground, the rotating motor 30 is operated to drive the first chain disc 31 to rotate, as the first chain disc 31 is in transmission connection with the second chain disc 34, the second threaded rod 33 is driven to rotate, so that the second lifting plate 32 slides in the first cylindrical barrel 6, the operating plate 38 is driven to lift, the height of the operating plate 38 is convenient to adjust, the first hydraulic cylinder 29 is operated to drive the first sliding block 28 to slide in the first sliding groove 27, then, the first cylinder barrel 6 is driven to rotate through the first linkage rod 7, when the first cylinder barrel 6 is rotated to the bottom of the operating plate 38 and the bottom of the groove 4 to be abutted, the first cylinder barrel 6 is convenient to store into the groove 4, the second hydraulic cylinder 37 drives the second sliding block 36 to slide in the second sliding groove 35, the support plate 11 is driven to rotate through the second linkage rod 13, the support plate 11 is driven to rotate to be close to the support rod 10, and the welding device is convenient to store and carry.

Although the base 1, the control device 2, the moving mechanism 3, the groove 4, the first sliding mechanism 5, the first cylindrical barrel 6, the first linkage rod 7, the rotating device 8, the lifting mechanism 9, the support rod 10, the support plate 11, the rope ladder 12, the second linkage rod 3, the second sliding mechanism 14, the welding platform 15, the second cylindrical barrel 16, the worm 17, the first lifting plate 18, the first threaded rod 19 and the worm wheel 20 are more used herein, the terms of the moving rod 21, the third linkage 22, the rotating block 23, the telescopic rod 4, the spring 25, the roller 26, the first sliding slot 27, the first sliding block 28, the first hydraulic cylinder 29, the rotating motor 30, the first chain disc 31, the second lifting plate 32, the second threaded rod 33, the second chain disc 34, the second sliding slot 35, the second sliding block 36, the second hydraulic cylinder 37, the operating plate 38, the placing slot 39 and the cover plate 40 are used, but the possibility of using other terms is not excluded. These terms are used merely to more conveniently describe and explain the nature of the present invention; they are to be construed as being without limitation to any additional limitations that may be imposed by the spirit of the present invention.

Claims

1. An optical cable high-altitude fusion splicing device comprises a base (1) and is characterized in that a plurality of control devices (2) are arranged at the lower end of the base (1), the lower ends of the base (1) at the left side and the right side of each control device (2) are rotatably connected with a moving mechanism (3), a groove (4) is formed in the upper end of the base (1), a first sliding mechanism (5) is arranged at the bottom of the groove (4), a first cylindrical barrel (6) is rotatably connected to the bottom of the groove (4), an opening of the first cylindrical barrel (6) is arranged upwards, the side wall of one end, close to the first sliding mechanism (5), of the first cylindrical barrel (6) is rotatably connected with one end of a first linkage rod (7), the other end of the first linkage rod (7) is rotatably connected with the first sliding mechanism (5), a rotating device (8) is arranged at the bottom of the first cylindrical barrel (6), a lifting mechanism (9) is arranged in the first cylindrical barrel (6), the lifting mechanism (9) is in transmission connection with a rotating device (8), a supporting rod (10) is arranged at the upper end of the lifting mechanism (9), a supporting plate (11) is rotatably connected to the side wall of the supporting rod (10), a rope ladder (12) is arranged at one end, away from the supporting rod (11), of the supporting plate (11), a second linkage rod (13) is rotatably connected to the lower end of the supporting plate (11), a second sliding mechanism (14) is arranged on the side wall of the supporting rod (10), the second sliding mechanism (14) is located below the supporting plate (11), one end, away from the supporting plate (11), of the second linkage rod (13) is rotatably connected with the second sliding mechanism (14), and a welding platform (15) is arranged at the upper end of the supporting rod (10);

the control device (2) comprises a second cylindrical barrel (16) arranged at the lower end of the base (1), an opening of the second cylindrical barrel (16) is arranged downwards, a first through hole communicated with the inside and the outside is formed in the side wall of the front end of the second cylindrical barrel (16), a worm (17) penetrates through the first through hole, a first lifting plate (18) is arranged in the second cylindrical barrel (16), the left end and the right end of the first lifting plate (18) are connected with the inner walls of the left end and the right end of the second cylindrical barrel (16) in a sliding manner, a first threaded hole communicated with the upper portion and the lower portion is formed in the first lifting plate (18), a first threaded rod (19) is connected with the first threaded hole in a threaded manner, the upper end of the first threaded rod (19) is rotatably connected with the top surface of the second cylindrical barrel (16), a worm wheel (20) is connected onto the first threaded rod (19), and the worm wheel (20) is located above the first lifting plate (18), the worm wheel (20) is meshed with the worm (17), the left side wall and the right side wall of the second cylindrical barrel (16) are respectively provided with a second through hole which is communicated with the inside and the outside, a moving rod (21) penetrates through the second through holes, the lower end of the moving rod (21) is rotatably connected with the upper end of a third linkage rod (22), the third linkage rod (22) is arranged at one end of the moving rod (21) in the second cylindrical barrel (16), and the lower end of the third linkage rod (22) is rotatably connected with the upper end of the first lifting plate (18);

the moving mechanism (3) comprises a rotating block (23) arranged at the lower end of the base (1), the rotating block (23) is rotatably connected with the base (1), the side wall of the rotating block (23) is rotatably connected with one end, outside the second cylindrical barrel (16), of the moving rod (21), the lower end of the rotating block (23) is connected with a telescopic rod (24), a spring (25) is sleeved on the telescopic rod (24), and the lower end of the telescopic rod (24) is connected with a roller (26);

the first sliding mechanism (5) comprises a first sliding groove (27) horizontally arranged at the bottom of the groove (4), a first sliding block (28) is arranged in the first sliding groove (27), the upper end of the first sliding block (28) is rotatably connected with one end, away from the first cylindrical barrel (6), of the first linkage rod (7), the inner wall of one end, away from the first cylindrical barrel (6), of the first sliding groove (27) is connected with one end of a first hydraulic cylinder (29), and the other end of the first hydraulic cylinder (29) is connected with the side wall of the first sliding block (28);

the rotating device (8) comprises a rotating motor (30) arranged at the bottom of the first cylindrical barrel (6), a driving shaft of the rotating motor (30) is arranged vertically upwards, a first chain disc (31) is sleeved on the driving shaft of the rotating motor (30), and the first chain disc (31) is in transmission connection with the lifting mechanism (9);

the lifting mechanism (9) comprises a second lifting plate (32) arranged in the first cylindrical barrel (6), the left end and the right end of the second lifting plate (32) are respectively in sliding connection with the inner walls of the left end and the right end of the first cylindrical barrel (6), a second threaded hole which is communicated up and down is formed in the second lifting plate (32), a second threaded rod (33) is connected to the second threaded hole in an internal thread mode, the lower end of the second threaded rod (33) is rotatably connected with the bottom of the first cylindrical barrel (6), a second chain disc (34) is sleeved on the second threaded rod (33), the second chain disc (34) is located below the second lifting plate (32), and the second chain disc (34) is in transmission connection with the first chain disc (31);

the second sliding mechanism (14) comprises a second sliding groove (35) vertically arranged on the side wall of the supporting rod (10), the second sliding groove (35) is located below the supporting plate (11), a second sliding block (36) is arranged in the second sliding groove (35), the side wall of the second sliding block (36) is rotatably connected with one end, away from the supporting plate (11), of the second linkage rod (13), a second hydraulic cylinder (37) is arranged at the bottom of the second sliding groove (35), and the upper end of the second hydraulic cylinder (37) is connected with the lower end of the second sliding block (36);

the welding platform (15) comprises an operation plate (38) arranged at the upper end of the support rod (10), a placing groove (39) is formed in the upper end of the operation plate (38), and a cover plate (40) is rotatably connected to one end side wall of the placing groove (39).