CN114336426A - Looped network cable laying device - Google Patents

Abstract

The invention relates to a ring network cable laying device, comprising: the pay-off rack structure comprises at least one wire rack assembly and at least one first guide assembly, wherein the first guide assembly is arranged at the output end of the wire rack assembly and is used for guiding the cable output by the wire rack assembly; the paying-off arm structure comprises a paying-off assembly, a second guide assembly and a ribbon part, wherein the ribbon part and the second guide assembly are respectively arranged at two ends of the paying-off assembly, and the second guide assembly can convey the cable to the ribbon part through the paying-off assembly and is bundled by the ribbon part; and the cable conveying structure is arranged between the pay-off rack structure and the pay-off arm structure and is used for conveying the cable in the first guide assembly to the second guide assembly. The cable paying-off machine has the advantages that the mechanical construction of cable paying-off is realized, the working efficiency is improved, the labor intensity of operators is reduced, and the ring network cable laying work is facilitated.

Description

Looped network cable laying device

Technical Field

The invention relates to the technical field of cable laying equipment, in particular to a ring network cable laying device.

Background

With the development of society, the use of electricity has become ubiquitous. In life, some looped network cables are often seen for power network transmission. Current looped netowrk cable laying device lays the operation when carrying out the looped netowrk cable, at first places the cable support to the cable, rotates the cable erection arrangement behind drum output looped netowrk cable and the unwrapping wire through the manpower. The whole process needs about ten people to accomplish the unwrapping wire operation, and this mode can only put a cable once, and the unwrapping wire is efficient, and construction work intensity is big, and construction cost is high, is unfavorable for laying of looped netowrk cable.

Disclosure of Invention

Therefore, it is necessary to provide a looped network cable laying device capable of improving work efficiency and reducing work intensity, aiming at the problem that the construction work intensity of the conventional cable laying device is high and low.

A looped network cable laying apparatus comprising:

the pay-off rack structure comprises at least one wire rack assembly and at least one first guide assembly, wherein the first guide assembly is arranged at the output end of the wire rack assembly and is used for guiding the cable output by the wire rack assembly;

the paying-off arm structure comprises a paying-off assembly, a second guide assembly and a ribbon part, wherein the ribbon part and the second guide assembly are respectively arranged at two ends of the paying-off assembly, and the second guide assembly can convey the cable to the ribbon part through the paying-off assembly and is bundled by the ribbon part; and

and the cable conveying structure is arranged between the pay-off rack structure and the pay-off arm structure and is used for conveying the cable in the first guide assembly to the second guide assembly.

In one embodiment, the paying-off arm structure further comprises a first plate body and a first support, the paying-off assembly comprises a tower body, a tower cap and a tower arm, the first plate body is placed on a reference surface, the first support is placed on the first plate body, one end of the tower arm is connected with the tower cap, the other end of the tower arm is provided with the ribbon part, one end of the tower cap and the second guide assembly are arranged at intervals, the second guide assembly can enable the cable to pass through the inside of the tower cap and the inside of the tower arm, the tower body is arranged on the first support, and the tower body is rotatably connected with the side face of the tower cap.

In one embodiment, the looped network cable laying device further comprises an angle adjusting structure, wherein the angle adjusting structure is connected with the first bracket, the tower body and the tower arm and is used for the pitch angle and the rotation angle of the tower arm;

the angle adjusting structure comprises a power assembly, a rotation adjusting assembly and a pitching adjusting assembly, the rotation adjusting assembly is connected with the first support and the tower body and is connected with the power assembly, and the power assembly drives the rotation adjusting assembly to drive the tower body and the tower arm to rotate relative to the first support; the pitching adjusting component is connected with the tower body and the tower cap and drives the tower arm to pitch relative to the tower body.

In one embodiment, the pitch adjustment assembly comprises a first fixing plate, a second fixing plate and a driving member, the first fixing plate is disposed on the tower body, the second fixing plate is disposed on the first fixing plate, one end of the driving member is hinged to the tower cap, and the other end of the driving member is mounted on the second fixing plate.

In one embodiment, the pay-off arm structure further comprises a second plate body and a rotating member, the rotating member is rotatably arranged on the second plate body, the second plate body is arranged on the first support, and the tower body is mounted on the rotating member;

the power assembly comprises a power source, the rotary adjusting assembly comprises a first transmission piece and a second transmission piece, the first transmission piece is arranged on the first support, the top of the first transmission piece is provided with the second plate body, the second transmission piece is arranged on the tower body through the power source, and the first transmission piece is in transmission connection with the second transmission piece.

In one embodiment, the pay-off arm structure further comprises a third fixing plate, the third fixing plate is arranged on the tower body and has a preset distance with the end part of the tower cap far away from the tower arm, the second guiding assembly comprises a third shell and two second rollers, the third shell is arranged on the third fixing plate, the two second rollers are rotatably arranged in the third shell, and the second rollers are used for guiding the cable passing through the third shell;

the number of the second guide assemblies is multiple, and the second guide assemblies are arranged on the third fixing plate at intervals along the length direction of the tower arm.

In one embodiment, the pay-off rack structure further comprises a third plate body, the third plate body is arranged on the reference surface and located on the side surface of the pay-off arm structure, the wire frame assembly comprises a second bracket and a wire coil rotatably arranged in the second bracket, the wire coil is used for winding the cable, and the first guide assembly is located on the side surface of the second bracket and used for guiding the cable released by the wire coil;

the first guide assembly comprises a third support, a third shell and two first rollers, the two first rollers are rotatably arranged in the third shell and are arranged along the vertical direction and are arranged at a preset interval, the cable passes through the two first rollers, and the third shell is arranged on the third support.

In one embodiment, the cable conveying structure comprises a conveying component and a third guiding component, wherein the third guiding component is arranged on at least one side of the conveying component and can guide the cable output by the first guiding component into the conveying component, and/or the third guiding component can guide the cable in the conveying component into the second guiding component;

the delivery assembly provides power for the cable transport, rotating the drum relative to the second support to release the cable and deliver the cable into the payout assembly.

In one embodiment, the conveying assembly comprises a second housing, two power members, two conveying members and two protection members, wherein the two power members are symmetrically arranged, the two conveying members are respectively sleeved on the outer sides of the corresponding power members, the protection members are arranged on the outer sides of the conveying members, a conveying space exists between the two conveying members, and the cable is located in the conveying space and abuts against the protection members;

the third guide assembly comprises a fifth support, a fourth shell and third rollers, the third rollers are rotatably arranged in the fourth shell and are arranged in the vertical direction at preset intervals, the cables penetrate through the third rollers, and the fourth shell is arranged on the fifth support.

In one embodiment, the pay-off arm structure further comprises a fourth guide assembly disposed in the tower arm for guiding the cable in the tower arm;

the fourth guide assembly includes a plurality of fifth fixing plates and a plurality of fourth rollers, the fifth fixing plates are disposed at inner sides of the tower arms, the fourth rollers are rotatably disposed at the fifth fixing plates, and a plurality of accommodating spaces for the cables to move are defined by the fourth rollers.

After the technical scheme is adopted, the invention at least has the following technical effects:

according to the looped network cable laying device, the cable conveying structure can provide power for the conveying of cables, when the cables released by the wire frame assembly in the pay-off frame structure are led into the cable conveying structure through the first guide assembly, the cable conveying structure can provide dragging force for the cables, so that the wire frame assembly can continuously release the cables, the cables are led into the second guide assembly of the pay-off arm structure and conveyed into the binding belt component through the pay-off assembly through the second guide assembly, the cables are bound through the binding belt component, and the looped network laying of the cables is facilitated. The looped network cable laying device is simple in structure and convenient to operate, can complete the paying-off operation of looped network cables by two or three persons, simplifies the operation flow, realizes the mechanical construction of cable paying-off, effectively solves the problem that the construction operation intensity of the existing cable laying device is high and the efficiency is low, improves the working efficiency, reduces the labor intensity of operators, and facilitates the laying work of the looped network cables.

Drawings

Fig. 1 is a front view of a ring network cable laying apparatus according to an embodiment of the present invention;

fig. 2 is a top view of the looped network cabling arrangement shown in fig. 1;

fig. 3 is an enlarged view of a pay-off arm structure and an angle adjustment structure in the looped network cable laying device shown in fig. 1;

fig. 4 is a partial enlarged view of the looped network cable laying device shown in fig. 1 at a;

FIG. 5 is a schematic view of a first guide assembly of the looped network cable laying apparatus shown in FIG. 1;

FIG. 6 is a schematic view of a third guide assembly of the looped network cable laying apparatus shown in FIG. 1;

fig. 7 is a schematic view of a conveying assembly in the looped network cabling arrangement shown in fig. 1;

fig. 8 is a schematic diagram of a tower arm of the looped network cable laying device shown in fig. 1 cut open.

Wherein: 100. a pay-off arm structure; 110. a first plate body; 120. a first bracket; 130. a pay-off assembly; 131. a tower cap; 132. a tower arm; 133. a tower body; 140. a second guide assembly; 141. a third housing; 142. a second drum; 150. a strap member; 160. a second plate body; 170. a rotating member; 180. a third fixing plate; 190. a fourth guide assembly; 191. a fifth fixing plate; 192. a fourth drum; 200. a cable transport structure; 210. a delivery assembly; 211. a conveying space; 212. a second housing; 220. a third guide assembly; 221. a fourth housing; 222. a third drum; 230. a fourth bracket; 240. a fifth support; 300. a pay-off rack structure; 310. a wire frame assembly; 311. a second bracket; 312. wire coils; 320. a first guide assembly; 321. a first housing; 322. a first drum; 330. a third plate body; 340. a third support; 400. an angle adjustment structure; 410. a power assembly; 411. a power source; 412. a power supply unit; 420. a rotation adjustment assembly; 421. a first transmission member; 422. a second transmission member; 430. a pitch adjustment assembly; 431. a first fixing plate; 432. a second fixing plate; 433. a drive member; 434. a fourth fixing plate; 500. an electrical cable.

Detailed Description

In order to make the aforementioned objects, features and advantages of the present invention comprehensible, embodiments accompanied with figures are described in detail below. In the following description, numerous specific details are set forth in order to provide a thorough understanding of the present invention. This invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein.

In the description of the present invention, it is to be understood that the terms "central," "longitudinal," "lateral," "length," "width," "thickness," "upper," "lower," "front," "rear," "left," "right," "vertical," "horizontal," "top," "bottom," "inner," "outer," "clockwise," "counterclockwise," "axial," "radial," "circumferential," and the like are used in the orientations and positional relationships indicated in the drawings for convenience in describing the invention and to simplify the description, and are not intended to indicate or imply that the referenced device or element must have a particular orientation, be constructed and operated in a particular orientation, and are not to be considered limiting of the invention.

Furthermore, the terms "first", "second" and "first" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance or implicitly indicating the number of technical features indicated. Thus, a feature defined as "first" or "second" may explicitly or implicitly include at least one such feature. In the description of the present invention, "a plurality" means at least two, e.g., two, three, etc., unless specifically limited otherwise.

In the present invention, unless otherwise expressly stated or limited, the terms "mounted," "connected," "secured," and the like are to be construed broadly and can, for example, be fixedly connected, detachably connected, or integrally formed; can be mechanically or electrically connected; they may be directly connected or indirectly connected through intervening media, or they may be connected internally or in any other suitable relationship, unless expressly stated otherwise. The specific meanings of the above terms in the present invention can be understood by those skilled in the art according to specific situations.

In the present invention, unless otherwise expressly stated or limited, the first feature "on" or "under" the second feature may be directly contacting the first and second features or indirectly contacting the first and second features through an intermediate. Also, a first feature "on," "over," and "above" a second feature may be directly or diagonally above the second feature, or may simply indicate that the first feature is at a higher level than the second feature. A first feature being "under," "below," and "beneath" a second feature may be directly under or obliquely under the first feature, or may simply mean that the first feature is at a lesser elevation than the second feature.

It will be understood that when an element is referred to as being "secured to" or "disposed on" another element, it can be directly on the other element or intervening elements may also be present. When an element is referred to as being "connected" to another element, it can be directly connected to the other element or intervening elements may also be present. The terms "vertical," "horizontal," "upper," "lower," "left," "right," and the like as used herein are for illustrative purposes only and do not denote a unique embodiment.

Referring to fig. 1 to 3, the present invention provides a looped network cable laying apparatus. This looped netowrk cable laying device is used for realizing laying of cable 500 for cable 500 can tie up together, is convenient for lay looped netowrk cable 500, with the demand of guaranteeing the power supply. Of course, in other embodiments of the present invention, the ring network cabling device may also be used to cable other types of cables 500, so that the cables 500 can be bundled together to meet the use requirement. In the present invention, the ring network cable laying apparatus laying cable 500 is described as an example.

It can be understood that, present looped netowrk cable laying device lays the operation when carrying out looped netowrk cable 500, at first places the cable on cable support, rotates the cable erection arrangement behind drum output looped netowrk cable and the unwrapping wire through the manpower. The whole process needs about ten people to accomplish the unwrapping wire operation, and this mode can only put a cable once, and the unwrapping wire is efficient, and construction work intensity is big, and construction cost is high, is unfavorable for laying of looped netowrk cable.

Therefore, the novel looped network cable laying device is simple in structure and convenient to operate, the paying-off operation of the looped network cable 500 can be completed by two to three persons, the operation flow is simplified, the mechanical construction of paying-off of the cable 500 is realized, the working efficiency is improved, the labor intensity of operators is reduced, and the laying work of the looped network cable 500 is facilitated. The following describes the specific structure of the looped network cabling 500 device.

Referring to fig. 1 to 3, in an embodiment, the looped network cable laying device includes a pay-off stand structure 300, a cable conveying structure 200, and a pay-off arm structure 100. The pay-off rack structure 300 comprises at least one wire rack assembly 310 and at least one first guiding assembly 320, wherein the first guiding assembly 320 is arranged at the output end of the wire rack assembly 310 and is used for guiding the cables 500 output by the wire rack assembly 310. The pay-off arm structure 100 includes a pay-off assembly 130, a second guide assembly 140, and a band-binding member 150, the band-binding member 150 and the second guide assembly 140 are respectively disposed at two ends of the pay-off assembly 130, and the second guide assembly 140 can convey the cable 500 to the band-binding member 150 through the pay-off assembly 130 and bind the cable with the band-binding member 150. A cable conveying structure 200 is disposed between the pay-off stand structure 300 and the pay-off arm structure 100, and the cable conveying structure 200 is used for conveying the cable 500 in the first guide assembly 320 to the second guide assembly 140.

Pay off rack structure 300 is the structure of cable 500 storage among the looped netowrk cable laying device, can release cable 500 through the rotation mode, can reduce cable 500's storage space. The cable conveying structure 200 is a power structure of the looped network cable laying device and provides power for conveying the cable 500. The pay-off arm structure 100 is a bundling part of the looped network cable 500 conveying device, and after the cable 500 is bundled by the pay-off arm structure 100, the cable 500 is laid and is convenient to use.

The cable conveying structure 200 is located between the pay-off rack structure 300 and the pay-off arm structure 100, and the cable 500 in the pay-off rack structure 300 is conveyed to the pay-off arm structure 100 through the cable conveying structure 200. As shown in fig. 1, the cable conveying structure 200 is located in the middle, the pay-off stand structure 300 is located at the right side of the cable conveying structure 200, and the pay-off arm structure 100 is located at the left side of the cable conveying structure 200. Of course, in other embodiments of the present invention, the cable conveying structure 200 may be located in the middle, the pay-off rack structure 300 is located at the left side of the cable conveying structure 200, and the pay-off arm structure 100 is located at the right side of the cable conveying structure 200. Moreover, the cable conveying structure 200, the pay-off rack structure 300 and the pay-off arm structure 100 are disposed on a reference surface, which is a ground surface, but of course, the reference surface may also be a bearing surface under other operating conditions.

After the cable 500 in the pay-off rack structure 300 is introduced into the cable conveying structure 200, the cable conveying structure 200 can apply a dragging force to the cable 500, drag the cable 500 in the pay-off rack structure 300, so that the cable 500 can be released by the pay-off rack structure 300, meanwhile, the cable conveying structure 200 can also introduce the cable 500 into the pay-off arm structure 100, and the cable 500 is bundled by the pay-off arm structure 100, so that the laying of the cable 500 is realized. The cable conveying structure 200 continuously provides power for conveying the cable 500, so that the pay-off rack structure 300 continuously releases the cable 500, and the cable conveying structure 200 continuously conveys the cable 500 into the pay-off arm structure 100, thereby realizing continuous laying of the cable 500.

Referring to fig. 1 to 3, in particular, the pay-off rack structure 300 includes at least one wire rack assembly 310 and at least one first guide assembly 320, the first guide assembly 320 is disposed at an output end of the wire rack assembly 310, and the cable 500 released from the wire rack assembly 310 is guided by the first guide assembly 320. The storage cables 500 may be rotated in the bobbin assembly 310 and the cables 500 released from the bobbin assembly 310 may be extended through the first guide assembly 320. First direction subassembly 320 can lead cable 500, avoids cable 500 and the contact of other parts of pay off rack structure 300, and then avoids cable 500 to be scratched, guarantees cable 500's performance.

Optionally, the pay-off stand structure 300 includes a stand assembly 310 and a first guide assembly 320. After the cable 500 output from one of the bobbin assemblies 310 is conveyed to the cable conveying structure 200 by the first guide assembly 320, the cable conveying structure 200 provides power for conveying the cable 500, so that the cable 500 can be continuously conveyed to the pay-off arm structure 100. After the cable 500 is conveyed by the wire arm structure 100, a single cable 500 may be used as it is, or the cable 500 may be cut and bundled for use.

Optionally, the pay-off stand structure 300 includes a plurality of stand assemblies 310 and a plurality of first guide assemblies 320, and an output end of each stand assembly 310 corresponds to one first guide assembly 320. The plurality of wire frame assemblies 310 are arranged at intervals along the conveying direction of the cables 500, the cables 500 released by the wire frame assembly 310 at the rear end are conveyed into the corresponding first guide assembly 320, the cables 500 released by the wire frame assembly 310 at the front end are conveyed into the corresponding first guide assembly 320, and the first guide assembly 320 at the rear end can introduce the cables 500 therein into the first guide assembly 320 at the front end, at this time, two guides are provided in the first guide assembly 320 at the front end. The number of cables 500 in the first guide member 320 at the foremost end is equal to the number of bobbin members 310.

It will be appreciated that the looped network cabling installation requires several cables 500 to be bundled and several wire frame assemblies 310 and several first guide assemblies 320 are correspondingly provided. Generally, the ring network cabling device uses three cables 500 for cabling. Accordingly, the number of the bobbin assemblies 310 is three, and the number of the first guide assemblies 320 is three. The three bobbin assemblies 310 are spaced apart from each other on the reference surface, and the three first guide assemblies 320 are disposed corresponding to the three bobbin assemblies 310, respectively. As shown in fig. 1, a first guide member 320 is provided at the left side of each bobbin assembly 310.

The cables 500 of the right-hand bobbin assembly 310 are fed into the corresponding right-hand first guide assembly 320, guided by the first guide assembly 320, and introduced into the middle first guide assembly 320, the cables 500 of the middle bobbin assembly 310 are fed into the corresponding middle first guide assembly 320, the middle first guide assembly 320 is capable of introducing two of the cables 500 into the right-hand first guide assembly 320, and the cables 500 of the right-hand bobbin assembly 310 are fed into the corresponding right-hand first guide assembly 320. At this time, there are three cables 500 in the right first guide assembly 320. The first guide assembly 320 on the right is capable of conveying the cable 500 into the cable conveying structure 200.

The wire arm structure 100 includes a wire releasing assembly 130, a second guide assembly 140, and a band part 150, the wire releasing assembly 130 is disposed on a reference surface, the second guide assembly 140 is located at one end of the wire releasing assembly 130 and disposed toward the cable conveying structure 200, and the band part 150 is disposed at the other end of the wire releasing assembly 130. The cable feeding structure 200 can feed the cable 500 into the second guide assembly 140, guide the cable 500 through the second guide assembly 140 to feed the cable 500 into the wire unwinding assembly 130, feed the cable 500 into the tape part 150 through the wire unwinding assembly 130, and bind the cable 500 through the tape part 150 to facilitate the laying of the cable 500.

The second guide assembly 140 is located at an end of the wire releasing assembly 130 away from the strap portion 150, and the second guide assembly 140 may be directly disposed at an end of the wire releasing assembly 130 or may be spaced apart from the end of the wire releasing assembly 130 by a predetermined distance. In the present invention, a predetermined distance between the second guiding element 140 and the wire releasing element 130 is taken as an example for explanation. The second guiding assembly 140 can guide the cable 500 output by the cable conveying structure 200, so that the cable 500 can be conveyed to the wire releasing assembly 130, and the cable 500 is prevented from being scratched.

When the looped network cable laying device is used, the cable conveying structure 200 applies dragging force to the cable 500, so that the cable 500 is continuously released by the cable frame assembly 310, the cable 500 released by the cable frame assembly 310 is guided by the first guide assembly 320 to enter the cable conveying structure 200, the cable conveying structure 200 provides power for conveying the cable 500, so that the cable 500 enters the pay-off assembly 130 through the guide of the second guide assembly 140, enters the band part 150 through the pay-off assembly 130, and is bound through the band part 150.

The looped network cable laying device in the above embodiment, simple structure convenient operation can accomplish looped network cable 500's unwrapping wire operation by two to three people, has simplified the operation flow, has realized the mechanized construction of cable 500 unwrapping wire, and effectual solution cable 500 laying device construction strength problem with big inefficiency at present has improved work efficiency, has reduced operating personnel's intensity of labour, the laying work of looped network cable 500 of being convenient for.

Optionally, the strap means 150 is an automatic strap binding machine. Of course, in other embodiments of the present invention, the strap portion 150 may also be other portions that enable bundling of the cables 500.

Referring to fig. 1 to 3, in an embodiment, the pay-off arm structure 100 further includes a first plate 110 and a first bracket 120, the pay-off assembly 130 includes a tower body 133, a tower cap 131 and a tower arm 132, the first plate 110 is placed on a reference surface, the first bracket 120 is disposed on the first plate 110, one end of the tower arm 132 is connected to the tower cap 131, the other end of the tower arm 132 is disposed with the strap part 150, one end of the tower cap 131 is spaced from the second guide assembly 140, the second guide assembly 140 can guide the cable 500 through the inside of the tower cap 131 and the inside of the tower arm 132, the tower body 133 is disposed on the first bracket 120, and the tower body 133 is rotatably connected to a side surface of the tower cap 131.

First plate body 110 is the bearing bottom plate of unwrapping wire arm structure 100, and unwrapping wire arm structure 100 sets up on the reference surface through first plate body 110, and first support 120 plays the supporting role, props off unwrapping wire subassembly 130 through first support 120 from the ground for there is certain height between unwrapping wire subassembly 130 apart from the ground, when making things convenient for cable 500 to lay, can also be convenient for the adjustment of unwrapping wire arm structure 100 angle. The bottom of the first bracket 120 is disposed on the first plate 110, and the top of the first bracket 120 is mounted with a wire releasing assembly 130. Alternatively, the first plate body 110 is a plate-shaped structure, but of course, in other embodiments of the present invention, the first plate body 110 may also be another structure capable of bearing. Optionally, the first bracket 120 is fixed to the first plate 110 by welding; of course, the first bracket 120 may be fixed to the first plate 110 by a screw connection or the like, which can achieve a reliable connection.

The cable releasing assembly 130 includes a tower body 133, a tower arm 132, and a tower cap 131, wherein the tower arm 132 and the tower cap 131 extend along the length direction of the cable 500, the tower cap 131 is disposed at one end of the tower arm 132, and the cable tie member 150 is disposed at the other end of the tower arm 132. The tower cap 131 and the tower arm 132 are hollow, and the cable 500 can pass through the tower cap 131 and the tower arm 132. The second guide assembly 140 can deliver the cable 500 through the tower cap 131 into the tower arm 132 and further into the strap portion 150, with the cable 500 being bundled by the strap portion 150. The tower 133 is disposed below the tower cap 131 and rotatably connected to a sidewall of the tower cap 131, the tower 133 is disposed on the first bracket 120, and the tower arm 132 is supported by the connection between the tower 133 and the tower cap 131. Moreover, the tower arm 132 can rotate relative to the tower body 133 through the tower cap 131, and the pitch angle of the tower arm 132 can be adjusted to meet the laying requirements of different angles.

Referring to fig. 1 to 3, in an embodiment, the looped network cable laying apparatus further includes an angle adjusting structure 400, where the angle adjusting structure 400 connects the first support 120, the tower 133 and the tower arm 132, and is used for a pitch angle and a rotation angle of the tower arm 132.

The angle adjusting structure 400 can adjust the pitch angle and the rotation angle of the pay-off assembly 130, so that the pay-off assembly 130 is located at different heights and positions to meet the laying requirements of different working conditions. The angle adjustment structure 400 can drive the tower arm 132 to perform a pitching motion relative to the tower body 133, so as to adjust the height of the tower arm 132. The angle adjustment structure 400 is also capable of rotating the tower arm 132 in a horizontal plane to adjust the position of the tower arm 132 in the horizontal plane.

Referring to fig. 1 to 3, in an embodiment, the angle adjustment structure 400 includes a power assembly 410, a rotation adjustment assembly 420 and a pitch adjustment assembly 430, the rotation adjustment assembly 420 connects the first bracket 120 and the tower body 133 and connects the power assembly 410, and the power assembly 410 drives the rotation adjustment assembly 420 to rotate the tower body 133 and the tower arm 132 relative to the first bracket 120; the pitch adjustment assembly 430 connects the tower body 133 and the tower cap 131, and drives the tower arm 132 to pitch relative to the tower body 133.

The power assembly 410 provides power for pitch angle adjustment as well as rotational angle adjustment of the tower arm 132. One end of the pitch adjustment assembly 430 is connected to the tower body 133, and the other end of the pitch adjustment assembly 430 is rotatably connected to the tower cap 131. The pitch adjustment assembly 430 is connected to the power assembly 410, and the pitch adjustment assembly 430 is powered by the power assembly 410 to control the tower arm 132 to perform a pitch operation with respect to the first plate 110, so as to adjust the distance between the end of the tower arm 132 and the first plate 110, thereby adjusting the height of the tower arm 132. The rotation adjustment assembly 420 is rotatably disposed between the tower body 133 and the first support 120, the rotation adjustment assembly 420 is further connected with the power assembly 410, and the power assembly 410 provides power for the rotation of the rotation adjustment assembly 420 to control the rotation of the tower body 133 relative to the first support 120, so that the tower arm 132 can rotate in a horizontal plane, and the position of the tower arm 132 in the horizontal plane is adjusted.

Optionally, power assembly 410 includes a power source 411 and a power supply set 412. A power source 411 and a rotation adjustment assembly 420, the power source 411 providing power for the rotation of the rotation adjustment assembly 420. The power supply unit 412 is disposed on the first board body 110. Alternatively, the power source 411 is a reduction motor. Of course, in other embodiments of the present invention, the power source 411 may also be other components capable of driving the rotary adjustment assembly 420 to output rotary motion.

Optionally, the power supply unit 412 is electrically connected to the power source 411, and the power source 411 is supplied with power through the power supply unit 412. Optionally, the power supply unit 412 is further electrically connected to the pitch adjustment assembly 430 to supply power to the pitch adjustment assembly 430, so that the pitch adjustment assembly 430 can drive the tower arm 132 to perform a pitch motion. Optionally, the power supply unit 412 is also electrically connected to the strap member 150 to provide power to the strap member 150 so that the strap member 150 can bundle the cable 500. Optionally, the power supply unit 412 is a diesel generator. Of course, in other embodiments of the present invention, the power supply unit 412 may also be other devices capable of generating power.

Referring to fig. 1 to 4, in an embodiment, the pitch adjustment assembly 430 includes a first fixing plate 431, a second fixing plate 432, and a driving member 433, the first fixing plate 431 is disposed on the tower 133, the second fixing plate 432 is disposed on the first fixing plate 431, one end of the driving member 433 is hinged to the tower cap 131, and the other end of the driving member 433 is mounted on the second fixing plate 432.

The first fixing plate 431 extends away from the tower 133 to form a cantilever structure. A second fixed plate 432 is disposed on the first fixed plate 431 and a driving member 433 powers the pitch operation of the pitch adjustment assembly 430. One end of the driving member 433 is fixedly disposed on the second fixing plate 432, and the other end of the driving member 433 is rotatably connected to the bottom of the tower cap 131. The driving member 433 can output a telescopic motion, and when the driving member 433 extends, the driving member 433 can drive the tower arm 132 to perform a pitching motion so as to adjust the height of the tower arm 132.

The driving member 433 is electrically connected to the power supply unit 412, and supplies power to the driving member 433 through a power supply mechanism. Optionally, the driving member 433 is a hydraulic cylinder, and a piston of the hydraulic cylinder is hinged to the lower surface of the tower cap 131. Of course, in other embodiments of the present invention, the driving member 433 may be a telescopic motor. It should be noted that the form of the first fixing plate 431 and the second fixing plate 432 is not limited in principle as long as the installation function can be achieved.

It should be noted that the connection in the present invention may be welding, or may be bolt connection, so long as the connection is reliable.

Referring to fig. 1 to 3, in an embodiment, the pitch adjustment assembly 430 further includes a fourth fixing plate 434, one end of the fourth fixing plate 434 is disposed on the first fixing plate 431, and the other end of the fourth fixing plate 434 is connected to the tower 133. First fixing plate 431 is connected with tower body 133 in a supporting mode through first fixing plate 431, stability between first fixing plate 431 and tower body 133 can be improved, and first fixing plate 431 is prevented from shaking. Optionally, the fourth fixing plate 434 is connected to the first fixing plate 431 by welding, and the fourth fixing plate 434 is connected to the tower body 133 by welding.

In an embodiment, the pay-off arm structure 100 further includes a second plate 160 and a rotating member 170, the rotating member 170 is rotatably disposed on the second plate 160, the second plate 160 is disposed on the first bracket 120, and the tower 133 is mounted on the rotating member 170. The rotation adjusting assembly 420, the second plate 160 and the rotating member 170 are disposed between the first bracket 120 and the tower body 133, so that the tower body 133 can rotate relative to the first bracket 120, and further the tower arm 132 can rotate in a horizontal plane, and the position of the tower arm 132 in the horizontal plane can be adjusted.

The top of the first bracket 120 is provided with a part of the rotation adjusting assembly 420, the top of the part of the rotation adjusting assembly 420 is provided with a second plate 160, the second plate 160 is rotatably provided with a rotating member 170, and the rotating member 170 is provided with a tower body 133. Thus, the tower 133 can be rotated with respect to the lower first bracket 120 by the rotation member 170.

In an embodiment, the power assembly 410 includes a power source 411, the rotation adjusting assembly 420 includes a first transmission member 421 and a second transmission member 422, the first transmission member 421 is disposed on the first bracket 120, the second plate 160 is disposed on the top of the first transmission member 421, the second transmission member 422 is disposed on the tower 133 through the power source 411, and the first transmission member 421 is in transmission connection with the second transmission member 422.

The power source 411 is disposed on the tower body 133, an output end of the power source 411 is connected to the second transmission member 422, the first transmission member 421 is fixedly disposed on the first bracket 120, the top of the first transmission member 421 is fixedly disposed on the first plate 110, the rotating member 170 is rotatably mounted on the first plate 110, and the tower body 133 is mounted on the rotating member 170. The first transmission member 421 is in transmission connection with the second transmission member 422.

When the power source 411 outputs power, the power source 411 can drive the second transmission member 422 to rotate, and the first transmission member 421 is engaged with the second transmission member 422, so that the second transmission member 422 can drive the first transmission member 421 to move synchronously. However, since the first transmission member 421 is fixedly disposed, when the second transmission member 422 rotates, the first transmission member 421 reacts on the second transmission member 422, so that the second transmission member 422 can rotate relative to the first transmission member 421, and further, when the second transmission member 422 rotates, the power source 411 and the tower body 133 can be driven to rotate, so as to control the tower arm 132 to rotate in the horizontal plane, thereby achieving the position adjustment of the tower arm 132 in the horizontal plane.

Optionally, the first transmission member 421 is a first gear, and the second transmission member 422 is a second gear. Of course, in other embodiments of the present invention, the first transmission member 421 and the second transmission member 422 may also be a synchronous belt transmission structure, a chain transmission structure, or the like. Optionally, the rotating member 170 is a bearing.

Referring to fig. 1 to 3, in an embodiment, the pay-off arm structure 100 further includes a third fixing plate 180, the third fixing plate 180 is disposed on the tower 133 and has a predetermined distance from an end of the tower cap 131 far away from the tower arm 132, the second guiding assembly 140 includes a third housing 141 and two second rollers 142, the third housing 141 is disposed on the third fixing plate 180, the second rollers 142 are rotatably disposed in the third housing 141, and the two second rollers 142 are used for guiding the cable 500 passing through the third housing 141.

The third fixing plate 180 is a bearing plate of the second guiding component 140, so that the second guiding component 140 is fixedly arranged on the tower body 133, and thus, when the tower body 133 drives the tower arm 132 to rotate on the horizontal plane, the tower body 133 can drive the third fixing plate 180 to rotate synchronously, and then the third fixing plate 180 can drive the second guiding component 140 thereon to rotate synchronously, so that the second guiding component 140 can accurately guide the cable 500 into the tower cap 131 and the tower arm 132.

The second guide assembly 140 includes a second housing 212 and a second roller 142, the second housing 212 is fixedly disposed on the second plate 160, the two second rollers 142 are rotatably disposed in the second housing 212, and the two second rollers 142 are vertically disposed with a certain distance therebetween. The cable 500 can pass between the two second rollers 142.

After the cable 500 is introduced into the second guiding component by the cable conveying structure 200, the cable 500 can pass through the two second rollers 142 and extend out of the two second rollers 142, the cable 500 is respectively contacted with the upper second roller 142 and the lower second roller 142, the cable 500 can drive the upper second roller 142 and the lower second roller 142 to rotate in the conveying process of the cable 500, and the cable 500 is guided by the rotating second rollers 142, so that the cable 500 can be accurately conveyed to the tower cap 131 and the tower arm 132.

In one embodiment, the second roller 142 is made of a rubber material. This can prevent the outer wall of the cable 500 from being scratched. Of course, in other modes of the present invention, a rubber sleeve may also be covered on the outer side of the second roller 142, and the rubber sleeve plays a role in protection, so as to prevent the outer wall of the cable 500 from being scratched.

Referring to fig. 1 to 3, in an embodiment, the number of the second guide assemblies 140 is multiple, and a plurality of the second guide assemblies 140 are disposed at intervals on the third fixing plate 180 along the length direction of the tower arm 132. The plurality of second guiding assemblies 140 simultaneously guide the cable 500, thereby ensuring the guiding effect of the cable 500. The plurality of second guide assemblies 140 are disposed at intervals on the third fixing plate 180 along the conveying direction of the cable 500, and after the cable 500 is output by the cable conveying structure 200, the cable 500 can sequentially pass through the plurality of third guide assemblies 220 and extend into the tower cap 131 and the tower arm 132. Illustratively, the number of second guide assemblies 140 is three.

Referring to fig. 1 and 2, in an embodiment, the pay-off stand structure 300 further includes a third plate 330, and the third plate 330 is disposed on the reference surface and located at a side of the pay-off arm structure 100. A third plate 330 is disposed at one side of the first plate 110, and the third body is also disposed on the reference surface. As shown in fig. 1, the third plate body 330 is located at the right side of the first plate body 110. The components of the pay-off stand structure 300 are carried by the third plate body 330.

In one embodiment, the bobbin assembly 310 includes a second holder 311 and a drum 312 rotatably disposed in the second holder 311, the drum 312 is used for winding the cable 500, and the first guiding assembly 320 is disposed at a side of the second holder 311 for guiding the cable 500 released from the drum 312.

The second holder 311 is provided on the third plate body 330 for rotatably supporting the wire coil 312. The cable 500 is wound on the wire coil 312, so that the cable 500 is stored. The drum 312 is capable of releasing or winding the cable 500 as the drum 312 rotates. When the coil 312 is rotated in a direction in the second holder 311, the coil 312 can wind the cable 500; when the reel 312 is rotated in the other direction in the second holder 311, the reel 312 can release the cable 500.

When the looped network cable laying device is used, the cable 500 is placed in the first guide assembly 320, and the cable 500 is dragged by the cable conveying structure 200, so that the cable 500 drives the wire coil 312 to rotate towards the other direction, and the cable 500 is released. When the cable 500 in the drum 312 is released, the drum 312 may be removed and replaced with another drum 312 full of cable 500. Of course, the rotation of the drum 312 in a direction may also be controlled so that the cable 500 is wound around the drum 312.

Referring to fig. 1, 2 and 5, in an embodiment, the first guiding assembly 320 includes a third bracket 340, a third housing 141, and two first rollers 322, two first rollers 322 are rotatably disposed in the third housing 141, two first rollers 322 are disposed in a vertical direction and have a predetermined distance, the cable 500 passes between the two first rollers 322, and the third housing 141 is disposed on the third bracket 340.

The third bracket 340 supports the third casing 141 from the ground, so that the third casing 141 has a certain height from the ground, and the cable 500 is guided by the first roller 322 in the third casing 141. The third housing 141 is disposed above the third bracket 340, and two first rollers 322 are rotatably mounted on the third housing 141, the two first rollers 322 are disposed along a vertical direction, a certain distance exists between the two first rollers 322, and the cable 500 can pass through the two first rollers 322.

After the wire coil 312 released from the wire coil 312 enters the first guiding assembly 320, the cable 500 can pass through the two first rollers 322 and extend out, the cable 500 is respectively contacted with the upper first roller 322 and the lower first roller 322, the cable 500 can drive the upper first roller 322 and the lower first roller 322 to rotate in the conveying process of the cable 500, and the cable 500 is guided by the rotating first rollers 322, so that the cable 500 can be prepared to be conveyed. Meanwhile, the upper first roller 322 and the lower first roller 322 can also support the cable 500, so that the cable 500 is prevented from falling off, and the cable 500 is further prevented from being scratched.

In an embodiment, a rod and a bearing are respectively disposed at two ends of the first roller 322, and the first roller 322 is rotatably disposed in the third casing 141 through the rod and the bearing. In one embodiment, the first roller 322 is made of a rubber material. This can prevent the outer wall of the cable 500 from being scratched. Of course, in other embodiments of the present invention, a rubber sleeve may be covered on the outer side of the first roller 322, and the rubber sleeve plays a role in protection, so as to prevent the outer wall of the cable 500 from being scratched.

Referring to fig. 1, 2 and 7, in an embodiment, the cable conveying structure 200 includes a conveying assembly 210 and a third guiding assembly 220, the third guiding assembly 220 is disposed on at least one side of the conveying assembly 210, the third guiding assembly 220 is capable of guiding the cable 500 output by the first guiding assembly 320 into the conveying assembly 210, and/or the third guiding assembly 220 is capable of guiding the cable 500 in the conveying assembly 210 into the second guiding assembly 140. The delivery assembly 210 provides power for the transport of the cable 500, causing the drum 312 to rotate relative to the second support 311 to release the cable 500 and deliver the cable 500 into the payout assembly 130.

The transport assembly 210 is a power source for the cable transport structure 200 and provides power for the transport of the cable 500. Specifically, after the cable 500 is introduced into the cable conveying structure 200 by the first guide assembly 320, the cable 500 can extend out through the conveying assembly 210, the conveying assembly 210 abuts against the cable 500, when the conveying assembly 210 moves, the conveying assembly 210 can drag the cable 500 to drive the cable 500 to move synchronously, the cable 500 can be released by the cable 500 due to the dragging force of the cable 500, and meanwhile, the conveying assembly 210 can convey the cable 500 to the second guide assembly 140 to convey the cable 500.

The third guide assembly 220 may be disposed at one side of the conveying assembly 210, that is, the third guide assembly 220 may be disposed between the conveying assembly 210 and the first guide assembly 320, or may be disposed between the conveying assembly 210 and the second guide assembly 140. Of course, the third guide assembly 220 may also be disposed on both sides of the conveying assembly 210, i.e., the third guide assembly 220 is disposed between the conveying assembly 210 and the first guide assembly 320, and between the conveying assembly 210 and the second guide assembly 140. The present invention will be described by taking the third guide assemblies 220 disposed on both sides of the conveying assembly 210 as an example. The cable 500 output from the first guide assembly 320 passes through the third guide assembly 220, enters the conveying assembly 210, extends out of the conveying assembly 210, passes through the third guide assembly 220 and enters the second guide assembly 140.

In an embodiment, the conveying assembly 210 includes a second housing 212, and two power members, two conveying members and two protection members disposed in the second housing 212, the two power members are symmetrically disposed, the two conveying members are respectively sleeved outside the corresponding power members, the protection members are disposed outside the conveying members, a conveying space 211 exists between the two conveying members, and the cable 500 is located in the conveying space 211 and abuts against the protection members.

The two power parts are symmetrically arranged in the second shell 212, the conveying part is sleeved outside the power parts, and the power parts can drive the conveying part to synchronously rotate when rotating. The shielding member is disposed outside the conveying member, and the conveying member is in contact with the cable 500 through the shielding member, thereby preventing damage to the cable 500. Two conveying members are arranged behind the corresponding power member, a conveying space 211 is formed between the two conveying members, and when the cable 500 extends out through the conveying assembly 210, the cable 500 can extend out through the conveying space 211.

Further, the outer wall of the cable 500 can abut against the guard on the conveying member, so that the two guards can sandwich the cable 500. When the two power members rotate in opposite directions, the two power members can clamp the cable 500 through the conveying member and the shielding member and drive the cable 500 to move. As cable 500 moves, cable 500 can exert a pulling force on drum 312, on the one hand, causing cable 500 to release cable 500, and on the other hand, causing cable 500 to be fed into second guide assembly 140.

Optionally, the power member is an electric motor. Alternatively, the conveying member is a conveyor belt or a chain or the like. Optionally, the guard is made of a rubber material. Optionally, the conveying assembly 210 is a conveyor. Of course, in other embodiments of the present invention, the conveying assembly 210 may also have other structures that enable conveying. Optionally, the cable transportation structure 200 further includes a fourth bracket 230, the fourth bracket 230 is disposed on the first plate 110, and the fourth bracket 230 is used for supporting the transportation assembly 210.

Referring to fig. 1, 2 and 6, in an embodiment, the third guiding assembly 220 includes a fifth bracket 240, a fourth housing 221 and third rollers 222, two of the third rollers 222 are rotatably disposed in the fourth housing 221, two of the third rollers 222 are disposed in a vertical direction and at a predetermined interval, the cable 500 passes between the two third rollers 222, and the fourth housing 221 is disposed on the fifth bracket 240.

The fifth support 240 supports the fourth casing 221 off the ground, so that the fourth casing 221 has a certain height from the ground, and the third roller 222 in the fourth casing 221 is convenient to guide the cable 500. The fourth housing 221 is disposed above the fifth support 240, and two third rollers 222 are rotatably mounted on the fourth housing 221, the two third rollers 222 are disposed in a vertical direction with a certain distance therebetween, and the cable 500 can pass between the two third rollers 222.

After the wire coil 312 released from the wire coil 312 enters the third guiding assembly 220, the cable 500 can pass through the two third rollers 222 to extend out, the cable 500 is respectively contacted with the upper third roller 222 and the lower third roller 222, the cable 500 can drive the upper third roller 222 and the lower third roller 222 to rotate in the conveying process of the cable 500, and the cable 500 is guided by the rotating third rollers 222, so that the cable 500 can be prepared to be conveyed. Meanwhile, the upper and lower third rollers 222 can also support the cable 500, so that the cable 500 is prevented from falling off, and the cable 500 is further prevented from being scratched.

In one embodiment, a rod and a bearing are respectively disposed at two ends of the third roller 222, and the third roller 222 is rotatably mounted in the fourth housing 221 through the rod and the bearing. In one embodiment, the third roller 222 is made of a rubber material. This can prevent the outer wall of the cable 500 from being scratched. Of course, in other embodiments of the present invention, a rubber sleeve may be covered on the outer side of the third roller 222, and the rubber sleeve plays a role in protection, so as to prevent the outer wall of the cable 500 from being scratched.

Referring to fig. 1, 2 and 8, in one embodiment, the pay-off arm structure 100 further includes a fourth guide assembly 190, and the fourth guide assembly 190 is disposed in the tower arm 132 for guiding the cable 500 in the tower arm 132. The fourth guide assembly 190 is disposed inside the tower arm 132, and the fourth guide assembly 190 can protect and guide the cable 500 in the tower arm 132, so as to guide the cable 500, prevent the cable 500 from contacting with the inside of the tower arm 132, and prevent the cable 500 from being scratched.

In one embodiment, the fourth guiding assembly 190 includes a plurality of fifth fixing plates 191 and a plurality of fourth rollers 192, the fifth fixing plates 191 are disposed inside the tower arms 132, the fourth rollers 192 are rotatably disposed on the fifth fixing plates 191, and the plurality of fourth rollers 192 enclose an accommodating space for the cable 500 to move.

Every two fifth fixing plates 191 are symmetrically disposed at the inner side of the tower arm 132, and both ends of the fourth drum 192 are rotatably mounted on the fifth fixing plates 191, respectively. The plurality of fourth rollers 192 enclose an accommodating space in which the cable 500 is positioned after the cable 500 is transferred to the tower arm 132. In this way, the cable 500 can contact the fourth drum 192 without contacting the tower arm 132, thereby preventing the cable 500 from being scratched.

Alternatively, the number of the fourth rollers 192 is three, and three of the fourth rollers 192 enclose a triangular accommodation space. Of course, in other embodiments of the present invention, the number of the fourth rollers 192 may be more, such as four, etc. Accordingly, the number of the fifth fixing plates 191 is twice the number of the fourth rollers 192.

Optionally, the fourth roller 192 is made of a rubber material. This can prevent the outer wall of the cable 500 from being scratched. Of course, in other embodiments of the present invention, a rubber sleeve may be covered on the outer side of the fourth roller 192, so as to protect the outer wall of the cable 500 from being scratched. Optionally, a sponge sleeve is arranged on two rollers to scrape the cable 500, so that the cable 500 is cleaned.

Referring to fig. 1 to 3, in use, the looped network cable laying device of the present invention moves the device to a use position, passes the cable 500 on three coils 312 between two first rollers 322, then passes the cable 500 through a fourth housing 221, and passes the cable 500 through a third roller 222, then passes the cable 500 through a second housing 212, and simultaneously passes the cable 500 between two transports, then contacts the cable 500 with a second roller 142, passes through a tower cap 131, then passes through a tower arm 132, and finally passes the cable 500 through a band part 150. When power component drive was carried a rotation, carried the piece and can press from both sides tight cable 500 through the protector, when power component drive was carried a rotation, carried the piece and can drive cable 500 and remove, and the power of dragging that cable 500 produced can drive drum 312 and rotate, drives cable 500 and carries out the unwrapping wire. Meanwhile, the conveying member can continuously convey the cables 500 into the tower arm 132, and bundle and fix the three cables 500 by the band member 150, thereby laying the cables 500.

When needs are adjusted cable 500's the angle of laying, power supply unit 412's front surface has the switch group, control power supply 411 through the switch group, ribbon part 150 and driving piece 433 start and close, start power supply 411 through the switch group, power supply 411 drives second driving piece 422 and rotates, cooperation through second driving piece 422 and first driving piece 421, make second driving piece 422 drive tower body 133 and rotate, thereby adjust the angle of tower arm 132, start driving piece 433 through the switch group, driving piece 433 jacks up tower cap 131, thereby adjust the angle of elevation of tower arm 132, lay the angle to cable 500 and adjust.

The looped network cable laying device is simple in structure and convenient to operate, can complete the paying-off operation of three looped network cables 500 by two to three persons, simplifies the operation flow, realizes the mechanical construction of paying-off of the cables 500, improves the working efficiency, reduces the labor intensity of operators, meanwhile, enables the construction operation to be more standardized and specialized, realizes the autonomous paying-off function through the rotation of the wire reel 312, and is convenient to use.

The technical features of the embodiments described above may be arbitrarily combined, and for the sake of brevity, all possible combinations of the technical features in the embodiments described above are not described, but should be considered as being within the scope of the present specification as long as there is no contradiction between the combinations of the technical features.

The above-mentioned embodiments only express several embodiments of the present invention, and the description thereof is more specific and detailed, but not construed as limiting the scope of the invention. It should be noted that, for a person skilled in the art, several variations and modifications can be made without departing from the inventive concept, which falls within the scope of the present invention. Therefore, the protection scope of the present patent shall be subject to the appended claims.

Claims (10)

1. A looped network cable laying apparatus, comprising:

the pay-off rack structure comprises at least one wire rack assembly and at least one first guide assembly, wherein the first guide assembly is arranged at the output end of the wire rack assembly and is used for guiding the cable output by the wire rack assembly;

the paying-off arm structure comprises a paying-off assembly, a second guide assembly and a ribbon part, wherein the ribbon part and the second guide assembly are respectively arranged at two ends of the paying-off assembly, and the second guide assembly can convey the cable to the ribbon part through the paying-off assembly and is bundled by the ribbon part; and

and the cable conveying structure is arranged between the pay-off rack structure and the pay-off arm structure and is used for conveying the cable in the first guide assembly to the second guide assembly.

2. The looped network cable laying device of claim 1, wherein the paying-off arm structure further comprises a first plate and a first support, the paying-off assembly comprises a tower body, a tower cap and a tower arm, the first plate is placed on a reference surface, the first support is placed on the first plate, one end of the tower arm is connected with the tower cap, the other end of the tower arm is provided with the cable tie component, one end of the tower cap is spaced from the second guide assembly, the second guide assembly can enable the cable to pass through the inside of the tower cap and the inside of the tower arm, the tower body is arranged on the first support, and the tower body is rotatably connected with the side surface of the tower cap.

3. The looped network cabling arrangement of claim 2, further comprising an angle adjustment structure connecting the first bracket, the tower body and the tower arm for pitch and swivel angles of the tower arm;

the angle adjusting structure comprises a power assembly, a rotation adjusting assembly and a pitching adjusting assembly, the rotation adjusting assembly is connected with the first support and the tower body and is connected with the power assembly, and the power assembly drives the rotation adjusting assembly to drive the tower body and the tower arm to rotate relative to the first support; the pitching adjusting component is connected with the tower body and the tower cap and drives the tower arm to pitch relative to the tower body.

4. A looped network cable laying device according to claim 3, wherein the pitch adjusting component includes a first fixing plate, a second fixing plate and a driving member, the first fixing plate is disposed on the tower body, the second fixing plate is disposed on the first fixing plate, one end of the driving member is hinged to the tower cap, and the other end of the driving member is mounted on the second fixing plate.

5. A looped network cabling arrangement as claimed in claim 3, wherein the paying out arm structure further comprises a second plate and a rotating member, the rotating member is rotatably disposed on the second plate, the second plate is disposed on the first bracket, and the rotating member is mounted with the tower body;

the power assembly comprises a power source, the rotary adjusting assembly comprises a first transmission piece and a second transmission piece, the first transmission piece is arranged on the first support, the top of the first transmission piece is provided with the second plate body, the second transmission piece is arranged on the tower body through the power source, and the first transmission piece is in transmission connection with the second transmission piece.

6. The looped network cabling device of claim 2, wherein the paying-off arm structure further comprises a third fixing plate disposed on the tower body at a predetermined distance from the end of the tower cap away from the tower arm, the second guiding assembly comprises a third housing disposed on the third fixing plate and two second rollers rotatably disposed in the third housing for guiding the cable passing through the third housing;

the number of the second guide assemblies is multiple, and the second guide assemblies are arranged on the third fixing plate at intervals along the length direction of the tower arm.

7. A looped network cabling arrangement as claimed in any one of claims 2 to 6, wherein the pay-off stand structure further includes a third plate arranged on the datum level and to the side of the pay-off arm structure, the wire frame assembly including a second support and a wire spool rotatably arranged in the second support, the wire spool being adapted to wind the cable, the first guide assembly being arranged to the side of the second support and being adapted to guide the cable released from the wire spool;

the first guide assembly comprises a third support, a third shell and two first rollers, the two first rollers are rotatably arranged in the third shell and are arranged along the vertical direction and are arranged at a preset interval, the cable passes through the two first rollers, and the third shell is arranged on the third support.

8. The looped network cabling device of claim 7, wherein the cable transport structure includes a transport assembly and a third guide assembly, the third guide assembly being disposed on at least one side of the transport assembly, the third guide assembly being capable of guiding the cable output by the first guide assembly into the transport assembly, and/or the third guide assembly being capable of guiding the cable in the transport assembly into the second guide assembly;

the delivery assembly provides power for the cable transport, rotating the drum relative to the second support to release the cable and deliver the cable into the payout assembly.

9. The looped network cable laying device as claimed in claim 8, wherein the conveying assembly includes a second housing, and two power members, two conveying members and two protection members, the two power members are symmetrically arranged, the two conveying members are respectively sleeved outside the corresponding power members, the protection member is arranged outside the conveying members, a conveying space exists between the two conveying members, the cable is located in the conveying space and abuts against the protection member;

the third guide assembly comprises a fifth support, a fourth shell and third rollers, the third rollers are rotatably arranged in the fourth shell and are arranged in the vertical direction at preset intervals, the cables penetrate through the third rollers, and the fourth shell is arranged on the fifth support.

10. The looped network cabling arrangement of any one of claims 2 to 6, wherein the payoff arm structure further comprises a fourth guide assembly disposed in the tower arm for guiding the cables in the tower arm;

the fourth guide assembly includes a plurality of fifth fixing plates and a plurality of fourth rollers, the fifth fixing plates are disposed at inner sides of the tower arms, the fourth rollers are rotatably disposed at the fifth fixing plates, and a plurality of accommodating spaces for the cables to move are defined by the fourth rollers.

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