CN113972592A

CN113972592A - Automatic laying equipment for ultra-long cable

Info

Publication number: CN113972592A
Application number: CN202111284837.XA
Authority: CN
Inventors: 刘鹏岗; 何小冬; 侯杉; 周宏博; 褚旭亮
Original assignee: Beijing Urban Construction North Equipment Installation Co ltd; Beijing Urban Construction Group Co Ltd
Current assignee: Beijing Urban Construction North Equipment Installation Co ltd; Beijing Urban Construction Group Co Ltd
Priority date: 2021-11-01
Filing date: 2021-11-01
Publication date: 2022-01-25
Anticipated expiration: 2041-11-01
Also published as: CN113972592B

Abstract

The invention discloses automatic laying equipment for an ultra-long cable, which comprises a box body, wherein a brush block is fixedly connected to the top of the inner wall of the box body, a small roller is in contact with the bottom of the brush block, a rotating rod is fixedly connected to the inner wall of the small roller, two ends of the rotating rod are in rotary connection with the front side and the back side of the inner wall of the box body through bearings, a cable is in contact with the bottom of the small roller, a roller is in contact with the bottom of the cable, a connecting rod is fixedly connected to the inner wall of the roller, one end of the connecting rod is in rotary connection with the front side of the inner wall of the box body through a bearing, and a gravity rotary cleaning mechanism is arranged in the roller. This automatic laying equipment for overlength cable is through setting up the rotatory clean mechanism of gravity to make when laying the conveying to the cable conductor, automatic release is cleaned at the friction of brush outer wall, clears up and collects the recovery in a concentrated way, and reciprocal circulation carries out the clean conveying of adhesion to the cable conductor and lays work.

Description

Automatic laying equipment for ultra-long cable

Technical Field

The invention relates to the technical field of cables, in particular to automatic laying equipment for an ultra-long cable.

Background

The cable laying refers to a process of laying and installing cables along the checked route to form a cable line. According to the use occasion, the method can be divided into a plurality of laying modes such as overhead, underground (pipelines and direct burial), underwater, walls, tunnels and the like. The reasonable selection of the laying mode of the cable is very important for ensuring the transmission quality, reliability, construction maintenance and the like of the line, and the direct-buried laying mode is generally adopted for the long-distance communication cable in order to ensure the safe and reliable communication. The main cables (trunk cables for relays and users) in cities generally adopt a pipeline laying mode to ensure safe and reliable communication, convenient installation and replacement, beautiful appearance and the like. The distribution cable in the city can adopt an overhead and wall laying mode, and is gradually replaced by a pipeline laying mode along with the development of modern city construction. At present when cable laying, lay to the assigned position through artifical pulling after the gyro wheel conveying, but at present in acting as go-between to the overlength cable, the cable overlength is too much to make the cable outer wall also more because the residue that the transportation carried, lead to applying a large amount of residues in the inslot and pile up, thereby the mutual extrusion of cable leads to the cable exocuticle to take place the damaged condition of friction to appear easily.

Disclosure of Invention

Aiming at the defects of the prior art, the invention provides automatic laying equipment for an ultra-long cable, which solves the problems that a large amount of residues are accumulated in a wire laying groove, and the friction damage is easily caused on the outer surface of the cable due to the mutual extrusion of the cables.

In order to achieve the purpose, the invention is realized by the following technical scheme: an automatic laying device for an ultra-long cable comprises a box body, wherein a brush block is fixedly connected to the top of the inner wall of the box body, a small roller is contacted with the bottom of the brush block, a rotating rod is fixedly connected to the inner wall of the small roller, two ends of the rotating rod are rotatably connected with the front surface of the inner wall of the box body and the back surface of the inner wall of the box body through bearings, a cable is contacted with the bottom of the small roller, a roller is contacted with the bottom of the cable, a connecting rod is fixedly connected to the inner wall of the roller, one end of the connecting rod is rotatably connected with the front surface of the inner wall of the box body through a bearing, a motor is fixedly connected to the other end of the connecting rod, the back surface of the motor is fixedly connected with the back surface of the inner wall of the box body, and a gravity rotation cleaning mechanism is arranged inside the roller;

the gravity rotating cleaning mechanism comprises a rubber pad, a sliding block, a pushing block, an elastic plate A, a lifting block, a connecting pipe and an air groove, wherein the inner wall of the rubber pad is fixedly connected with the outer wall of a roller, a sliding cavity is formed in the roller, the outer wall of the sliding block is slidably connected with the inner wall of the sliding cavity, the outer wall of the pushing block is slidably connected with the inner wall of the sliding cavity, an elastic rope is fixedly connected with the outer wall of the pushing block, one end of the elastic rope is fixedly connected with the inner wall of the sliding cavity, the outer wall of the pushing block is fixedly connected with one end of the elastic plate A, the other end of the elastic plate A is fixedly connected with the outer wall of the lifting block, the outer wall of the lifting block is slidably connected with the inner wall of the pushing block, the inner wall of the lifting block is fixedly connected with the outer wall of the connecting pipe, the air groove is formed in the lifting block, the top of the hairbrush is contacted with the outer wall of the rubber pad, and a vertical lifting mechanism is arranged in the roller, the bottom of the roller is provided with a magnetic vibration shaking-off mechanism.

Preferably, vertical lift mechanism includes elastic plate B, little bull stick, connecting block, magnetic path A, magnetic path B, dead lever, elastic plate B one end sliding chamber inner wall fixed connection, the elastic plate B other end and connecting block outer wall fixed connection, connecting block outer wall and little bull stick outer wall fixed connection, little bull stick both ends are connected with sliding chamber inner wall openly, the inner wall back passes through the bearing rotation respectively, connecting block inner wall and magnetic path A outer wall fixed connection, the connecting block inner wall is articulated with dead lever one end, dead lever inner wall and magnetic path B outer wall fixed connection.

Preferably, magnetism vibrations shake off mechanism includes little magnet A, brush, little magnet B, lifter plate, gag lever post, little elastic plate, little magnet A outer wall and lifter plate inner wall fixed connection, the contact of brush top and gyro wheel bottom, brush bottom and lifter plate top fixed connection, little magnet B outer wall and lifter plate inner wall fixed connection, lifter plate inner wall and gag lever post outer wall sliding connection, lifter plate top and brush bottom fixed connection, gag lever post one end and box inner wall bottom fixed connection, lifter plate bottom and little elastic plate one end fixed connection, the little elastic plate other end and box inner wall bottom fixed connection.

Preferably, the inside of the air groove is communicated with the inside of the connecting pipe, and the inside of the air groove is communicated with the outside of the lifting block, so that air can be communicated.

Preferably, the opposite side of the magnetic block B and the magnetic block A is opposite in magnetic polarity, so that opposite poles attract each other.

Preferably, the magnetic properties of the small magnet a and the small magnet B are homopolar, so that the homopolar poles repel each other.

Preferably, the outer wall of the sliding block is provided with a groove, so that the fixing rod can move from space through the groove.

Preferably, open slots are formed in two sides of the box body, so that the cable is placed into the box body through the open slots.

The invention provides automatic laying equipment for an ultra-long cable. The method has the following beneficial effects:

(1) this automatic laying equipment for overlength cable, through setting up the rotatory clean mechanism of gravity, thereby make when laying the conveying to the cable conductor, along with the rotation of gyro wheel, make and to carry out normal conveying in the conveying cable, when the ejector pad rotates to the gyro wheel bottom along with the gyro wheel, release that can be automatic is cleaned the friction at the brush outer wall, make the rubbish after will gluing clear up and collect the recovery in a concentrated way, keep the cleanness of elevator outer wall, and reciprocating circulation carries out the clean conveying of adhesion to the cable conductor and lays work.

(2) This automatic laying equipment for overlength cable, through setting up the rotatory clean mechanism of gravity, thereby make when the ejector pad is released inside the elevator block also can be released in the bounce of elastic plate A along with the inertia of self, can carry out reciprocal vibrations simultaneously under elastic plate A's bounce, thereby further carry out more efficient with the residue and the rubbish of elevator block outer wall adhesion and shake off, the cleanliness of elevator block has been promoted, also promote simultaneously and carry out the clear efficiency of cable conductor adhesion.

(3) This automatic laying equipment for overlength cable is through setting up the rotatory clean mechanism of gravity to make can be when the elevator is released and shakes through self inertia, can spout the intractable rubbish of elevator surface adhesion through the reciprocal jet-propelled of gas tank, avoid the unable condition appearance that shakes off of residue that the adhesion is stronger.

(4) This automatic laying equipment for overlength cable is through setting up vertical lift mechanism to can guarantee to be in the fastest speed at the slider whereabouts at every turn and strike the ejector pad, guarantee the speed that the ejector pad was released every time, it is long with vibrations duration also further to promote the vibration frequency of the inside elevator of ejector pad, further guarantees the clean efficiency to the elevator surface.

(5) This automatic laying equipment is used to overlength cable, shake off the mechanism through setting up the magnetism vibrations, in the elevator in the gyro wheel bottom, the inside little magnet A of elevator is continuous relative with little magnet B and repel each other through homopolar magnetism, thereby continuous promotion lifter plate, the lifter plate then slides at the gag lever post outer wall and descends and constantly carries out the over-and-under type vibrations under little springboard's bounce, thereby constantly shake through the brush and clean with the gyro wheel outer wall, thereby promote the contact dynamics of brush and elevator outer wall and rubber pad outer wall, very big promotion to the outside whole clean effect of whole gyro wheel, the residue that also can sweep the brush simultaneously shakes it on the lifter plate through the shake of self, the clean effect of brush has been guaranteed.

Drawings

FIG. 1 is a schematic structural view of the present invention;

FIG. 2 is a front cross-sectional view of the present invention;

FIG. 3 is an enlarged view taken at A of FIG. 2 according to the present invention;

FIG. 4 is an enlarged view of FIG. 3 at B according to the present invention;

fig. 5 is an enlarged view of fig. 3 at C according to the present invention.

In the figure: 1 cable wire, 2 rollers, 3 gravity rotary cleaning mechanisms, 301 rubber pads, 302 sliding blocks, 303 pushing blocks, 304 elastic plates A, 305 lifting blocks, 306 connecting pipes, 307 air grooves, 4 vertical lifting mechanisms, 401 elastic plates B, 402 small rotating rods, 403 connecting blocks, 404 magnetic blocks A, 405 magnetic blocks B, 406 fixing rods, 5 magnetic vibration shaking-off mechanisms, 501 small magnets A, 503 brushes, 504 small magnets B, 505 lifting plates, 506 limiting rods, 507 small elastic plates, 6 connecting rods, 7 boxes, 8 brush blocks, 9 rotating rods and 10 small rollers.

Detailed Description

Referring to fig. 1-5, the present invention provides a technical solution: an automatic laying device for an ultra-long cable comprises a box body 7, open slots are formed in two sides of the box body 7, a brush block 8 is fixedly connected to the top of the inner wall of the box body 7, a small roller 10 is in contact with the bottom of the brush block 8, a rotating rod 9 is fixedly connected to the inner wall of the small roller 10, two ends of the rotating rod 9 are in rotating connection with the front side of the inner wall of the box body 7 and the back side of the inner wall through bearings, a cable 1 is in contact with the bottom of the small roller 10, a roller 2 is in contact with the bottom of the cable 1, a connecting rod 6 is fixedly connected to the inner wall of the roller 2, one end of the connecting rod 6 is in rotating connection with the front side of the inner wall of the box body 7 through bearings, a motor is fixedly connected to the back side of the motor and the back side of the inner wall of the box body 7, and a gravity rotating cleaning mechanism 3 is arranged inside the roller 2;

the gravity rotating cleaning mechanism 3 comprises a rubber pad 301 and a sliding block 302, wherein the outer wall of the sliding block 302 is provided with a groove, a push block 303, an elastic plate A304, a lifting block 305, a connecting pipe 306 and an air groove 307, the inside of the air groove 307 is communicated with the inside of the connecting pipe 306, the inside of the air groove 307 is communicated with the outside of the lifting block 305, the inner wall of the rubber pad 301 is fixedly connected with the outer wall of a roller 2, the inside of the roller 2 is provided with a sliding cavity, the outer wall of the sliding block 302 is slidably connected with the inner wall of the sliding cavity, the outer wall of the push block 303 is slidably connected with the inner wall of the sliding cavity, one end of the elastic rope is fixedly connected with the inner wall of the sliding cavity, the outer wall of the push block 303 is fixedly connected with one end of the elastic plate A304, the other end of the elastic plate A304 is fixedly connected with the outer wall of the lifting block 305, the outer wall of the lifting block 305 is slidably connected with the inner wall of the push block 303, the inner wall of the lifting block 305 is fixedly connected with the connecting pipe 306, the other end of the connecting pipe 306 is fixedly connected with the inner wall of the push block 303, the air groove 307 is arranged inside the lifting block 305, the top of the brush 503 is in contact with the outer wall of the rubber pad 301, the vertical lifting mechanism 4 is arranged inside the roller 2, and the magnetic vibration shaking-off mechanism 5 is arranged at the bottom of the roller 2.

The vertical lifting mechanism 4 comprises an elastic plate B401, a small rotating rod 402, a connecting block 403, a magnetic block A404 and a magnetic block B405, the magnetism of one side of the magnetic block B405 opposite to the magnetic block A404 is heteropolar, a fixing rod 406, the inner wall of a sliding cavity at one end of the elastic plate B401 is fixedly connected, the other end of the elastic plate B401 is fixedly connected with the outer wall of the connecting block 403, the outer wall of the connecting block 403 is fixedly connected with the outer wall of the small rotating rod 402, two ends of the small rotating rod 402 are respectively connected with the front side of the inner wall of the sliding cavity and the back side of the inner wall through bearings in a rotating mode, the inner wall of the connecting block 403 is fixedly connected with the outer wall of the magnetic block A404, the inner wall of the connecting block 403 is hinged to one end of the fixing rod 406, and the inner wall of the fixing rod 406 is fixedly connected with the outer wall of the magnetic block B405.

The magnetic vibration shaking-off mechanism 5 comprises a small magnet A501, the magnetism of the opposite side of the small magnet A501 and the small magnet B504 is homopolar, a brush 503, a small magnet B504, a lifting plate 505, a limiting rod 506 and a small elastic plate 507, the outer wall of the small magnet A501 is fixedly connected with the inner wall of a lifting block 305, the top of the brush 503 is contacted with the bottom of a roller 2, the bottom of the brush 503 is fixedly connected with the top of the lifting plate 505, the outer wall of the small magnet B504 is fixedly connected with the inner wall of the lifting plate 505, the inner wall of the lifting plate 505 is slidably connected with the outer wall of the limiting rod 506, the top of the lifting plate 505 is fixedly connected with the bottom of the brush 503, one end of the limiting rod 506 is fixedly connected with the bottom of the inner wall of a box body 7, the bottom of the lifting plate 505 is fixedly connected with one end of the small elastic plate 507, and the other end of the small elastic plate 507 is fixedly connected with the bottom of the inner wall of the box body 7.

When the cable conveying device is used, a cable 1 is placed into a box body 7 through an open slot on one side of the box body 7, then the cable 1 is placed between a roller 2 and a small roller 10, then a starting motor drives a connecting rod 6 to rotate, the connecting rod 6 drives the roller 2 to rotate, the roller 2 is tightly attached to the cable 1 through a rubber pad 301 on the outer wall, and the cable 1 is tightly attached to the small roller 10, so that the cable 1 is conveyed along with the rotation of the roller 2, meanwhile, the small roller 10 is also driven by the cable 1 to rotate, so that the cable 1 is clamped, stabilized and slowly conveyed, then when the cable 1 slowly rotates, a sliding block 302 in the cable 1 rotates from top to bottom, the sliding block 302 slides in a sliding cavity along with the self gravity and pushes a pushing block 303, the pushing block 303 can be pushed to fall, so that an elastic rope is pulled to deform, and meanwhile, when the pushing block 303 is impacted and ejected downwards, a large amount of dust and debris adhered to the outer wall of the cable 1 are quickly pushed out by the surface of the lifting block 305 to be in contact with the brush 503 so as to be swept away by the brush 503, meanwhile, when the pushing block 303 is quickly pushed out, the lifting block 305 inside the pushing block 303 is also pushed out at the same time and passes through the elastic force of the elastic plate A304 so as to perform reciprocating vibration at the bottom of the roller 2, further, a large amount of garbage adhered to the outer wall of the cable 1 is cleaned by the pushing-out vibration of the lifting block 305 and the pushing block 303, the cleanness of the cable 1 during laying is ensured, meanwhile, when the lifting block 305 performs reciprocating vibration, air between the lifting block 305 and the pushing block 303 enters an air groove 307 through a connecting pipe 306, then the lifting block 305 is subjected to reciprocating air injection, residues with strong adhesion are sprayed out, and meanwhile, when the sliding block 302 rotates from the top of the roller 2 to the bottom of the roller 2 along with the roller 2 in a half circle, the sliding block 302 falls down and is lapped on the fixed rod 406 along with the self gravity, when the sliding cavity outside the sliding block 302 is vertical, the self gravity of the sliding block 302 completely falls on the fixed rod 406, so that the elastic plate B401 is extruded on the connecting block 403 held by the fixed rod 406, the rebound force of the elastic plate B401 is smaller than the gravity of the sliding block 302, so that the elastic plate B401 is extruded to deform, the sliding block 302 falls off the fixed rod 406, then the sliding block 302 quickly impacts the pushing block 303 with the acceleration, then the sliding block 302 pushes the fixed rod 406 from one side of the fixed rod 406 along with the half-turn rotation of the roller 2 again, so that the gravity is larger than the magnetism of the magnetic block A404 of the magnetic block B405, the fixed rod 406 is separated from the connecting block 403, then the sliding block returns to the original position, when the sliding block 302 is at the top of the roller 2, the sliding block 302 is at the bottom in the cavity, and reciprocates, thereby ensuring that the sliding block 303 is impacted at the fastest speed when the sliding block 302 falls each time, the pushing speed of the pushing block 303 is ensured each time, the vibration frequency and the vibration duration of the lifting block 305 inside the pushing block 303 are further improved, the cleaning efficiency of the surface of the lifting block 305 is further ensured, meanwhile, when the lifting block 305 is arranged at the bottom of the roller 2, the small magnet A501 inside the lifting block 305 continuously faces the small magnet B504 and repels each other through the magnetism of the same polarity, so that the lifting plate 505 is continuously pushed, the lifting plate 505 slides down on the outer wall of the limiting rod 506 and continuously performs lifting vibration under the counter-elastic force of the small elastic plate 507, so that the outer wall of the roller 2 is wiped through the continuous vibration of the hairbrush 503, the contact force between the outer wall of the lifting block 503 and the outer wall of the rubber pad 301 is improved, the integral cleaning effect of the whole outer part of the roller 2 is greatly improved, and meanwhile, residues removed by the hairbrush 503 can be shaken down onto the lifting plate 505 through the self-shaking, the cleaning effect of the fur brush 503 is ensured.

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 an automatic laying equipment is used to overlength cable, includes box (7), its characterized in that: the top of the inner wall of the box body (7) is fixedly connected with a brush block (8), the bottom of the brush block (8) is contacted with a small roller (10), the inner wall of the small roller (10) is fixedly connected with a rotating rod (9), two ends of the rotating rod (9) are rotatably connected with the front side and the back side of the inner wall of the box body (7) through bearings, the bottom of the small roller (10) is contacted with a cable (1), the bottom of the cable (1) is contacted with a roller (2), the inner wall of the roller (2) is fixedly connected with a connecting rod (6), one end of the connecting rod (6) is rotatably connected with the front side of the inner wall of the box body (7) through a bearing, the other end of the connecting rod (6) is fixedly connected with a motor, the back side of the motor is fixedly connected with the back side of the inner wall of the box body (7), and a gravity rotating cleaning mechanism (3) is arranged inside the roller (2);

the gravity rotating cleaning mechanism (3) comprises a rubber pad (301), a sliding block (302), a pushing block (303), an elastic plate A (304), a lifting block (305), a connecting pipe (306) and an air groove (307), wherein the inner wall of the rubber pad (301) is fixedly connected with the outer wall of a roller (2), a sliding cavity is formed in the roller (2), the outer wall of the sliding block (302) is slidably connected with the inner wall of the sliding cavity, the outer wall of the pushing block (303) is slidably connected with the inner wall of the sliding cavity, an elastic rope is fixedly connected with the outer wall of the pushing block (303), one end of the elastic rope is fixedly connected with the inner wall of the sliding cavity, the outer wall of the pushing block (303) is fixedly connected with one end of the elastic plate A (304), the other end of the elastic plate A (304) is fixedly connected with the outer wall of the lifting block (305), the outer wall of the lifting block (305) is slidably connected with the inner wall of the pushing block (303), and the inner wall of the lifting block (305) is fixedly connected with the outer wall of the connecting pipe (306), connecting pipe (306) other end and ejector pad (303) inner wall fixed connection, set up inside elevator (305) in gas groove (307), brush (503) top and rubber pad (301) outer wall contact, gyro wheel (2) inside is provided with vertical lift mechanism (4), gyro wheel (2) bottom is provided with magnetism vibrations shake-off mechanism (5).

2. An automated cabling apparatus for ultra-long cables, as claimed in claim 1, wherein: vertical lift mechanism (4) include elastic plate B (401), little bull stick (402), connecting block (403), magnetic block A (404), magnetic block B (405), dead lever (406), elastic plate B (401) one end sliding chamber inner wall fixed connection, the elastic plate B (401) other end and connecting block (403) outer wall fixed connection, connecting block (403) outer wall and little bull stick (402) outer wall fixed connection, little bull stick (402) both ends are passed through the bearing rotation with the sliding chamber inner wall is positive, the inner wall back respectively and are connected, connecting block (403) inner wall and magnetic block A (404) outer wall fixed connection, connecting block (403) inner wall is articulated with dead lever (406) one end, dead lever (406) inner wall and magnetic block B (405) outer wall fixed connection.

3. An automated cabling apparatus for very long cables, as claimed in claim 2, wherein: the magnetic vibration shaking-off mechanism (5) comprises a small magnet A (501), a brush (503), a small magnet B (504), a lifting plate (505), a limiting rod (506) and a small elastic plate (507), the outer wall of the small magnet A (501) is fixedly connected with the inner wall of the lifting block (305), the top of the hairbrush (503) is contacted with the bottom of the roller (2), the bottom of the brush (503) is fixedly connected with the top of the lifting plate (505), the outer wall of the small magnet B (504) is fixedly connected with the inner wall of the lifting plate (505), the inner wall of the lifting plate (505) is connected with the outer wall of the limiting rod (506) in a sliding way, the top of the lifting plate (505) is fixedly connected with the bottom of the hairbrush (503), one end of the limiting rod (506) is fixedly connected with the bottom of the inner wall of the box body (7), the bottom of the lifting plate (505) is fixedly connected with one end of a small elastic plate (507), the other end of the small elastic plate (507) is fixedly connected with the bottom of the inner wall of the box body (7).

4. An automated cabling apparatus for ultra-long cables, as claimed in claim 3, wherein: the inside of the air groove (307) is communicated with the inside of the connecting pipe (306), and the inside of the air groove (307) is communicated with the outside of the lifting block (305).

5. An automated cabling apparatus for very long cables, as claimed in claim 4, wherein: and the opposite side of the magnetic block B (405) and the magnetic block A (404) is opposite in magnetism.

6. An automated cabling apparatus for ultra-long cables, as claimed in claim 5, wherein: the magnetic property of the small magnet A (501) and the magnetic property of the small magnet B (504) are homopolar.

7. An automated cabling apparatus for ultra-long cables, as claimed in claim 6, wherein: the outer wall of the sliding block (302) is provided with a groove.

8. An automated cabling apparatus for ultra-long cables, as claimed in claim 7, wherein: open slots are formed in two sides of the box body (7).