WO2019127986A1 - Mooring rope guiding device - Google Patents

Abstract

A mooring rope guiding device, comprising a mounting support (10) connected to a truss; a winding wheel (20), the winding wheel (20) being pivotally connected to the mounting support (10), and a winding groove (21) being circumferentially provided on the winding wheel (20); a limiting frame (30), the limiting frame (30) comprising a first pivoting arm and a second pivoting arm parallel to each other, the first pivoting arm and the second pivoting arm being respectively located at the two axial sides of the winding wheel (20), the limiting frame (30) further comprising a connection structure (31), a first end of the first pivoting arm and a first end of the second pivoting arm being connected by means of the connection structure (31), and a rope passing area being formed between the first end of the first pivoting arm and the first end of the second pivoting arm; and a rotating mechanism (40), the first pivoting arm and the second pivoting arm being both pivotally connected to a rotating shaft (22) of the winding wheel (20) by means of the rotating mechanism (40), the rotating mechanism (40) being provided with at least one shock absorbing member (41), the shock absorbing member (41) being disposed between the first pivoting arm and the winding wheel (20) and/or between the second pivoting arm and the winding wheel (20). The present invention solves the problem in the prior art of easy release of a photoelectric mooring rope from a guiding pulley.

Description

Cable guide Technical field

The utility model relates to the technical field of lifting and recycling of a tethered balloon, in particular to a cable guiding device.

Background technique

The mooring system is used for the lifting and recovery of the tethered balloon, and the mooring balloon is anchored by the mooring system through the optical cable when it is fixed in the air. The tethered balloon sways in the air, and the position of the optical cable is constantly changing. In order to ensure that the position of the optical cable into the lift recovery system remains unchanged, a cable guide is required to introduce the optical cable with the offset angle into the fixed line. Empty recycling system.

technical problem

Under the action of balloon buoyancy and wind disturbance, the optical cable can drive the guide pulley to swing left and right, which can easily cause the optical cable to wear or undulate.

Technical solution

The main object of the present invention is to provide a cable guiding device to solve the problem that the optical cable rope in the prior art is easily detached from the guiding pulley.

In order to achieve the above object, the present invention provides a cable guiding device, comprising a mounting bracket for connecting with a truss; a reel, the reel is pivotally connected to the mounting bracket, and the reel is circumferentially disposed a winding frame; a limiting frame comprising a first pivoting arm and a second pivoting arm parallel to each other, the first pivoting arm and the second pivoting arm respectively located on two axial sides of the reel, the limiting frame The first structure of the first pivoting arm and the first end of the second pivoting arm are connected by a connecting structure, and the first end of the first pivoting arm and the first end of the second pivoting arm Forming a line region; the rotating mechanism, the first pivoting arm and the second pivoting arm are pivotally connected to the rotating shaft of the reel through a rotating mechanism, the rotating mechanism has at least one shock absorbing member, and the damping member is disposed at the first Between the pivot arm and the reel and/or between the second pivot arm and the reel.

Further, the mounting bracket includes a first supporting plate and a second supporting plate disposed opposite to each other, and a mounting gap is formed between the first supporting plate and the second supporting plate, the reel is located in the mounting gap and parallel to the first supporting plate, and The restraining frame is located on the outside of the mounting bracket.

Further, the connecting structure comprises two spaced-apart first wire wheels, and a line area is formed between the two first wire wheels, and the two ends of each of the first wire wheels are respectively connected to the first pivoting arm and the second pivoting arm connection.

Further, the connecting structure comprises two spaced apart second wire wheels, the second wire wheel is perpendicular to the first wire wheel, the two first wire wheels constitute a first reference plane, and the two second wire wheels constitute a second reference plane The first reference plane is parallel to the second reference plane.

Further, the rotating mechanism comprises a housing, the housing has a receiving cavity, the rotating shaft of the reel is located in the receiving cavity, and the damping component is located between the housing and the rotating shaft of the reel; the bearing component, the bearing component is disposed in the receiving cavity And contacting with the rotating shaft of the reel; the first bearing, the first pivoting arm is connected to the housing through the first bearing; the second bearing, the second pivoting arm is connected to the housing through the second bearing.

Further, the rotating mechanism further includes a connecting shaft extending from the housing and connected to the first pivoting arm and the second pivoting arm, the connecting shaft does not rotate relative to the housing, and the first bearing is disposed on the connecting shaft and the first Between a pivoting arm, a second bearing is disposed between the connecting shaft and the second pivoting arm, and the shock absorbing member is supported between the connecting shaft and the rotating shaft of the reel.

Further, the cable guiding device further comprises two cover assemblies, wherein the two cover assemblies are located in the receiving cavity, and the two ends of the rotating shaft of the reel are respectively fixedly provided with a cover assembly, and the damping member is supported between the connecting shaft and the cover assembly .

Further, each of the cover assemblies includes a stacked support cover and a first end cover. The first end cover is adjacent to the rotation axis of the reel relative to the support cover, and the shock absorbing member is supported between the support cover and the connecting shaft.

Further, the cable guiding device further comprises at least one guiding column, the two ends of the guiding column are respectively connected with the housing and the supporting cover, and the damping component is sleeved on the guiding column.

Further, the housing includes a flange support; two second end covers, two second end covers respectively disposed at two ends of the flange support and forming a receiving cavity between the three, each of the second end caps A through hole for the connecting shaft is provided, and the inner wall of the flange support is in contact with the bearing member, and the flange support is fixedly connected with the mounting bracket.

Further, the cable guiding device further includes a weight structure, and the weight structure is disposed at a lower portion of the mounting bracket.

Further, the opposite ends of the mounting bracket are provided with a slewing support structure, the connecting lines of the two slewing support structures are perpendicular to the rotating shaft of the reel, and the slewing support structure is pivotally connected with the fixing plate of the truss.

Further, the cable guide device further includes a reinforcing plate connected to the swing support structure and the mounting bracket.

Beneficial effect

Applying the technical solution of the utility model, both ends of the mounting bracket are connected with the truss, and the reel on the mounting bracket can guide the cable of the mooring balloon to facilitate recovery or release of the cable, and the limiting bracket is disposed on the mounting bracket On both sides, the cable is further guided before the cable enters the wire wheel to avoid grooving, and a rotating mechanism is arranged between the limiting frame and the reel, and the rotating mechanism can make the limiting frame and the reel relatively independent Rotate to ensure that the function of the restraining frame is functioning properly. At the same time, a damping member is also arranged in the rotating mechanism, and the shock absorbing member can absorb the vibration and impact caused by the external load, and prevent the axial movement of the reel and its rotating shaft from affecting the limiting frame and the mounting bracket, and avoiding the cable. The detachment from the reel takes place.

DRAWINGS

The accompanying drawings, which are incorporated in the claims of the claims In the drawing:

1 is a schematic structural view of a cable guiding device of the present invention;

Figure 2 shows a front view of the cable guide of Figure 1;

Figure 3 is a cross-sectional view taken along line A-A of Figure 2;

Figure 4 shows a left side view of the cable guide of Figure 1;

Figure 5 shows a top view of the cable guide of Figure 1;

FIG. 6 shows an enlarged view of P at FIG.

Wherein, the above figures include the following reference numerals:

10, mounting bracket; 11, installation clearance; 20, reel; 21, winding trough; 22, rotating shaft; 30, restraining frame; 31, connecting structure; 40, rotating mechanism; 41, shock absorber; Body; 421, flange support; 422, second end cover; 43, bearing member; 44, first bearing; 45, second bearing; 46, connecting shaft; 47, cover assembly; 471, support cover; One end cover; 48, guide column; 50, weight structure; 60, slewing support structure; 70, reinforcing plate; 80, fixed plate.

Embodiments of the invention

It should be noted that the embodiments in the present application and the features in the embodiments may be combined with each other without conflict. The present invention will be described in detail below with reference to the drawings in conjunction with the embodiments.

It is to be noted that all technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs, unless otherwise indicated.

In the present invention, the orientation words such as "up, down, top, and bottom" are generally used in the directions shown in the drawings, or in the vertical direction of the components themselves, without being otherwise described. Similarly, in the direction of vertical or gravity; for the sake of understanding and description, "inside and outside" refer to the inside and outside of the contour of each component, but the above orientation words are not intended to limit the present invention.

In order to solve the problem that the optical cable rope in the prior art is easily detached from the guide pulley, the utility model provides a cable guiding device.

A cable guiding device as shown in FIGS. 1 to 5 includes a mounting bracket 10 for connecting with a truss, a reel 20, a restraining frame 30 and a rotating mechanism 40, and the reel 20 is pivotally mounted to the mounting bracket 10, the winding wheel 20 is provided with a winding groove 21 in the circumferential direction; the limiting frame 30 includes a first pivoting arm and a second pivoting arm parallel to each other, and the first pivoting arm and the second pivoting arm are respectively located around The axial direction of the reel 20 further includes a connecting structure 31. The first end of the first pivoting arm and the first end of the second pivoting arm are connected by the connecting structure 31, and the first pivoting arm A line region is formed between the first end and the first end of the second pivot arm; the first pivot arm and the second pivot arm are pivotally connected to the rotating shaft 22 of the reel 20 by the rotating mechanism 40, and rotate The mechanism 40 has at least one shock absorbing member 41 disposed between the first pivot arm and the reel 20 and/or between the second pivot arm and the reel 20 .

Specifically, both ends of the mounting bracket 10 are connected to the truss, and the reel 20 on the mounting bracket 10 can guide the cable of the captive balloon to facilitate recovery or release of the cable, and the limiting bracket 30 is disposed on the mounting bracket 10. On both sides, the cable is further guided before the cable enters the wire wheel to avoid grooving, and a rotating mechanism 40 is provided between the limiting frame 30 and the reel 20, and the rotating mechanism 40 can cause the limiting frame 30 and The reel 20 rotates relatively independently to ensure that the function of the restraining frame 30 is functioning properly. At the same time, a damping member 41 is further disposed in the rotating mechanism 40, and the damping member 41 can absorb the vibration and impact caused by the external load, and prevent the axial movement of the reel 20 and the rotating shaft 22 against the limiting bracket 30 and the mounting bracket. 10 has an effect to prevent the cable from being detached from the reel 20 .

Optionally, the mounting bracket 10 includes a first supporting plate and a second supporting plate disposed opposite to each other, and a mounting gap 11 is formed between the first supporting plate and the second supporting plate, and the reel 20 is located in the mounting gap 11 and parallel to the first A support plate, and the restriction frame 30 is located outside the mounting bracket 10.

Specifically, the mounting bracket 10 is composed of two supporting plates of a first supporting plate and a second supporting plate. The two supporting plates are spaced apart, and the reel 20 is disposed in the mounting gap 11 formed by the supporting plate, so that the reel 20 The first support plate and the second support plate can be restrained to prevent a large swing of the reel 20 during the rotation process, and even cause the reel 20 to derail, thereby ensuring the normal operation of the cable guide device.

Optionally, the connecting structure 31 includes two spaced-apart first wire wheels, and a line area is formed between the two first wire wheels, and the two ends of each of the first wire wheels are respectively connected to the first pivot arm and the second pivot Connect the arms.

Specifically, the two first wire guides of the connection structure 31 form a line area through which the cable passes to enable the cable to enter the reel 20 in a predetermined manner while the first wire wheel is connected Between a pivot arm and a second pivot arm, the first wire wheel can function to connect the first pivot arm and the second pivot arm. In this embodiment, the first pivoting arm and the second pivoting arm are disposed at a relatively close bending structure at the protruding mounting bracket 10, and the first reel 20 is a roller, the inner ring of the roller and the limiting frame 30 connection, the outer ring of the roller can rotate freely under the action of the cable to realize the guiding effect on the cable.

Further optionally, the connecting structure 31 comprises two spaced apart second wire wheels, the second wire wheel is perpendicular to the first wire wheel, the two first wire wheels constitute a first reference plane, and the two second wire wheels constitute a first A second reference plane, the first reference plane being parallel to the second reference plane.

Specifically, in the embodiment, the connecting structure 31 further includes a set of second wire wheels. The second wire wheel is disposed under the first wire wheel along the extending direction of the limiting frame 30, and the second wire wheel is formed with a rectangular shape. The line area is perpendicular to the rectangular line area that the first wire wheel is intended to be, that is, the first wire wheel and the second wire wheel form a footprint in the direction of movement of the cable, so that the connection structure 31 Can fully limit the cable. Moreover, the second wire wheel and the first wire wheel are both rollers, and the roller is convenient to install and inexpensive.

As shown in FIG. 6, the rotating mechanism 40 includes a housing 42, a bearing member 43, a first bearing 44, and a second bearing 45. The housing 42 has a receiving cavity, and the rotating shaft 22 of the reel 20 is located in the receiving cavity and is shock absorbing. The member 41 is located between the housing 42 and the rotating shaft 22 of the reel 20; the bearing member 43 is disposed in the receiving cavity and is in contact with the rotating shaft 22 of the reel 20; the first pivoting arm passes through the first bearing 44 and the housing 42 The second pivot arm is coupled to the housing 42 via the second bearing 45.

Specifically, the bearing member 43 is a rolling bearing, the shaft 22 of the reel 20 is provided with a rotating shaft 22, and the rotating shaft 22 is interference-fitted with the reel 20, and when the reel 20 rotates, the rotating shaft 22 communicates with the reel 20 Rotating together, a bearing member 43 is disposed on the rotating shaft 22, the inner ring of the bearing member 43 is engaged with the rotating shaft 22, and the outer ring is engaged with the housing 42 so that the rotating shaft 22 can move relative to the housing 42, and the housing 42 and the limiting frame 30 is coupled by the first bearing 44 and the second bearing 45 such that the restraining frame 30 can be smoothly rotated while the housing 42 can be fixed to the mounting bracket 10 to facilitate the mounting of the rotating mechanism 40.

Optionally, the rotating mechanism 40 further includes a connecting shaft 46 extending from the inside of the housing 42 and connected to the first pivoting arm and the second pivoting arm, and the connecting shaft 46 does not rotate relative to the housing 42. A bearing 44 is disposed between the connecting shaft 46 and the first pivoting arm, a second bearing 45 is disposed between the connecting shaft 46 and the second pivoting arm, and the damping member 41 is supported by the connecting shaft 46 and the reel 20 Between the shafts 22.

Specifically, a connecting shaft 46 is further disposed between the casing 42 and the wire. One end of the connecting shaft 46 is connected to the inner ring of the first bearing 44 and the second bearing 45, and the other end of the connecting shaft 46 is fixed to the casing 42. The damper member 41 is disposed between the connecting shaft 46 and the rotating shaft 22 so that the axial sway of the rotating shaft 22 can be offset by the damper of the damper member 41. In the present embodiment, the damper member 41 is a damper spring.

Optionally, the cable guide device further includes two cover assemblies 47. The two cover assemblies 47 are located in the accommodating cavity, and the two ends of the rotating shaft 22 of the reel 20 are respectively fixedly provided with a cover assembly 47, and the damper member 41 is supported at Between the connecting shaft 46 and the cover assembly 47.

Specifically, a cover assembly 47 is screwed to both ends of the rotating shaft 22, and the damper member 41 is disposed between the cover assembly 47 and the connecting shaft 46 to prevent the rotation of the rotating shaft 22 from affecting the damper member 41.

Optionally, each cover assembly 47 includes a stacked support cover 471 and a first end cover 472. The first end cover 472 is adjacent to the support shaft 471 near the rotation shaft 22 of the reel 20, and the shock absorbing member 41 is supported on the support cover. 471 is between the connecting shaft 46.

Specifically, the cover assembly 47 has a two-layer structure, which is a support cover 471 and a first end cover 472, respectively. The first end cover 472 is screwed to both ends of the rotating shaft 22, and the first end cover 472 is covered on the outside of the support cover 471. And relative rotation between the support cover 471 and the first end cover 472 can occur.

Optionally, the cable guide device further includes at least one guiding post 48. The two ends of the guiding post 48 are respectively connected to the housing 42 and the supporting cover 471, and the damping member 41 is sleeved on the guiding post 48.

Specifically, a guide post 48 is disposed between the support cover 471 and the housing 42. In the embodiment, the guide post 48 is a connecting screw, and three connecting screws are evenly arranged along the circumferential direction of the support cover 471, and the connecting screw covers the shell. The body 42 is coupled to the support cover 471 such that the support cover 471 can rotate together with the housing 42. At the same time, the connecting screw can guide the sleeve on the same, so that the moving direction of the damper spring is the same as the moving direction of the rotating shaft 22, and other deformation of the damper spring is prevented.

Optionally, the housing 42 includes a flange support 421 and two second end caps 422. The two second end caps 422 are respectively disposed at two ends of the flange support 421 and form a receiving cavity between the three. The two end caps 422 are each provided with a through hole for the connecting shaft 46 to pass through. The inner wall of the flange support 421 is in contact with the bearing member 43, and the flange support 421 is fixedly coupled to the mounting bracket 10.

Specifically, the flange support 421 of the housing 42 is sleeved on the outer ring of the rolling bearing, and the flange support 421 itself is directly fixedly connected to the mounting, so that the flange support 421 can maintain the same position relative to the mounting bracket 10, and the flange support The 421 circumferentially uniformly is provided with six screw holes so that the end surface of the flange support 421 and the second end cover 422 can be connected by screws, and a receiving cavity is formed therebetween, the bearing member 43, the support cover 471, and the first The end cap 472 and the damper member 41 are all disposed in the accommodating chamber to protect most of the components of the rotating mechanism 40. At the same time, the second end cover 422 is provided with a through hole to facilitate the passage of the connecting shaft 46. In the embodiment, one end of the connecting shaft 46 is connected to the rotating shaft and connected to the limiting frame 30, and the other end is an end surface structure for shock absorption. The member 41 abuts on the connecting shaft 46.

As shown in FIGS. 1 and 2, the cable guide device further includes a weight structure 50 disposed at a lower portion of the mounting bracket 10.

Specifically, the reel 20 is a guiding pulley and the guiding pulley is provided with a winding groove 21, so that the guiding pulley can fully guide the cable, and the weight structure 50 is disposed at the bottom of the cable guiding device, so that The guide pulley can maintain balance at any position where the left and right swings, and in the case where the swing external force is eliminated, the center of gravity is lowered by the weight structure 50, so that the guide pulley can automatically return to the front.

In this embodiment, the bottom of the cable guide device is provided with an inverted L-shaped slot, the lateral portion of the slot is used for connecting the weight structure 50, and the longitudinal portion is used as the slot for the slot to facilitate the installation of the weight structure 50. The top of the weight structure 50 is provided with a connecting rod, and the connecting rod is also L-shaped. The connecting rod is inserted in the slot so that the weight structure 50 can be connected with the mounting bracket 10, and a limit screw is arranged at the entrance of the slot, so that The weight structure 50 does not slip out of the slot.

Optionally, the opposite ends of the mounting bracket 10 are provided with a slewing support structure 60. The connecting lines of the two slewing support structures 60 are perpendicular to the rotating shaft 22 of the reel 20, and the slewing support structure 60 and the fixing plate 80 of the truss are pivoted. Transfer connection.

Specifically, a swing support structure 60 is disposed between the mounting bracket 10 and the fixed plate 80 of the truss, and the swing support structure 60 is fixedly coupled to the mounting bracket 10, and the swing support structure 60 is provided with a plurality of mounting holes through the swing support structure. The different mounting holes on the 60 are connected to the fixing plate 80 to adjust the angle of the slewing support structure 60, so that the mounting bracket 10 can adjust the angle according to actual conditions and improve the adaptability of the cable guiding device. The slewing support structure 60 in this embodiment has a simple structural form, and the mounting bracket 10 can be fixed on the truss by means of bolt connection, and at the same time, the slewing support structure 60 is disposed at both ends of the guide pulley, that is, the simple support is adopted. The structure of the beam can reduce the force and moment that the slewing support structure 60 is subjected to, and transfer the dangerous section to the mounting bracket 10 to ensure the reliability of the installation of the cable guide device.

Further optionally, the cable guide device further includes a reinforcing plate 70 that is coupled to the swing support structure 60 and the mounting bracket 10.

Specifically, a reinforcing plate 70 is disposed between the mounting bracket 10 and the slewing support structure 60, and the reinforcing plate 70 makes the connection between the mounting bracket 10 and the slewing support structure 60 more secure, in the reinforcing plate 70 and the mounting bracket Reinforcing ribs are provided between 10 to further enhance the reliability of the connection between the mounting bracket 10, the reinforcing plate 70 and the slewing support structure 60.

From the above description, it can be seen that the above embodiments of the present invention achieve the following technical effects:

1. Solving the problem that the optical cable rope in the prior art is easily detached from the guiding pulley;

2. The overall structure is simple, the installation is quick and convenient, and the connection reliability is high;

3. The rotating mechanism 40 allows the restraining frame 30 and the reel 20 to move relatively independently while reducing the influence of the swing of the reel 20 on the restraining frame 30.

It is apparent that the embodiments described above are merely a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments obtained by those skilled in the art based on the embodiments of the present invention without creative efforts shall fall within the scope of protection of the present invention.

It is to be noted that the terminology used herein is for the purpose of describing particular embodiments, and is not intended to limit the exemplary embodiments. As used herein, the singular " " " " " " There are features, steps, operations, devices, components, and/or combinations thereof.

It should be noted that the terms "first", "second" and the like in the specification and claims of the present application and the above-mentioned drawings are used to distinguish similar objects, and are not necessarily used to describe a specific order or order. It is to be understood that the data so used may be interchanged where appropriate, so that the embodiments of the present application described herein can be implemented in a sequence other than those illustrated or described herein.

The above description is only for the preferred embodiment of the present invention, and is not intended to limit the present invention. For those skilled in the art, various modifications and changes can be made in the present invention. Any modifications, equivalent substitutions, improvements, etc. made within the spirit and scope of the present invention are intended to be included within the scope of the present invention.

Claims (13)

A cable guiding device, comprising: Mounting bracket (10) for connection to the truss; a reel (20), the reel (20) is pivotally connected to the mounting bracket (10), the winding wheel (20) is provided with a winding groove (21) in the circumferential direction; a limiting frame (30), the limiting frame (30) comprising a first pivoting arm and a second pivoting arm parallel to each other, the first pivoting arm and the second pivoting arm respectively located at the winding The axial side of the wheel (20), the limiting frame (30) further includes a connecting structure (31), the first end of the first pivoting arm and the first end of the second pivoting arm pass The connecting structure (31) is connected, and a line region is formed between the first end of the first pivoting arm and the first end of the second pivoting arm; a rotating mechanism (40), wherein the first pivoting arm and the second pivoting arm are pivotally connected to a rotating shaft (22) of the reel (20) by the rotating mechanism (40), The rotating mechanism (40) has at least one shock absorbing member (41) disposed between the first pivoting arm and the reel (20) and/or disposed in the The second pivot arm is between the reel (20) and the reel. The cable guide device according to claim 1, wherein the mounting bracket (10) includes a first support plate and a second support plate disposed opposite to each other, and the first support plate and the second support plate Forming a mounting gap (11), the reel (20) is located in the mounting gap (11) and parallel to the first support plate, and the restraining frame (30) is located in the mounting bracket (10) The outside of the). The cable guiding device according to claim 1, wherein the connecting structure (31) comprises two spaced-apart first wire wheels, and the line-crossing region is formed between the two first wire wheels, Two ends of each of the first wire wheels are respectively connected to the first pivoting arm and the second pivoting arm. The cable guiding device according to claim 3, wherein said connecting structure (31) comprises two spaced apart second wire wheels, said second wire wheel being perpendicular to said first wire wheel, two The first wire wheel constitutes a first reference plane, and the two second wire wheels constitute a second reference plane, the first reference plane being parallel to the second reference plane. The cable guide device of claim 1 wherein said rotating mechanism (40) comprises: a housing (42) having a receiving cavity, a rotating shaft (22) of the reel (20) is located in the receiving cavity, and the damping member (41) is located in the housing Between the body (42) and the rotating shaft (22) of the reel (20); a bearing member (43), the bearing member (43) is disposed in the receiving cavity and in contact with a rotating shaft (22) of the reel (20); a first bearing (44), the first pivot arm being coupled to the housing (42) by the first bearing (44); a second bearing (45), the second pivot arm being coupled to the housing (42) by the second bearing (45). The cable guide device according to claim 5, wherein said rotating mechanism (40) further comprises a connecting shaft (46), said connecting shaft (46) being extended from said housing (42) and The first pivot arm and the second pivot arm are connected, the connecting shaft (46) does not rotate relative to the housing (42), and the first bearing (44) is disposed on the connecting shaft (46) between the first pivoting arm, the second bearing (45) is disposed between the connecting shaft (46) and the second pivoting arm, the shock absorbing member (41) Supported between the connecting shaft (46) and the rotating shaft (22) of the reel (20). The cable guide device according to claim 6, wherein said cable guide device further comprises two cover assemblies (47), two of said cover assemblies (47) are located in said receiving chamber, and said winding The cover assembly (47) is fixedly disposed at two ends of the rotating shaft (22) of the reel (20), and the damping member (41) is supported on the connecting shaft (46) and the cover assembly (47) between. The cable guide device of claim 7 wherein each of said cover assemblies (47) includes a stacked support cover (471) and a first end cover (472), said first end cover (472) a damping member (41) supported on the support cover (471) and the connecting shaft (46) with respect to the support cover (471) near the rotating shaft (22) of the reel (20) between. The cable guide device according to claim 8, wherein said cable guide device further comprises at least one guide post (48), and both ends of said guide post (48) are respectively associated with said housing (42) and The support cover (471) is connected, and the shock absorbing member (41) is sleeved on the guide post (48). The cable guide device of claim 6 wherein said housing (42) comprises: Flange support (421); Two second end caps (422), two of the second end caps (422) are respectively disposed at two ends of the flange support (421) and form the receiving cavity between the three, each of the a second end cover (422) is provided with a through hole for the connecting shaft (46) to pass through, an inner wall of the flange support (421) is in contact with the bearing member (43), and the flange The support (421) is fixedly coupled to the mounting bracket (10). The cable guide device of claim 1 wherein said cable guide device further comprises a weight structure (50) disposed at a lower portion of said mounting bracket (10). The cable guiding device according to any one of claims 1 to 11, characterized in that the opposite ends of the mounting bracket (10) are provided with a slewing support structure (60), and the two slewing support structures The wire of (60) is perpendicular to the rotating shaft (22) of the reel (20), and the slewing support structure (60) is pivotally coupled to the fixing plate (80) of the truss. The cable guide device according to claim 12, wherein said cable guide device further comprises a reinforcing plate (70), said reinforcing plate (70) and said slewing support structure (60) and said mounting The bracket (10) is connected.