CN217823650U - Wiring device and debugging equipment - Google Patents

Abstract

The utility model provides a wiring device and debugging equipment, the wiring device comprises a supporting assembly, the supporting assembly comprises a frame and an installation component, the installation component is arranged in the frame, and the installation component is used for being connected with the tail end of a cable; the working assembly comprises a flat cable assembly and a driving assembly, the flat cable assembly is located in the frame and used for placing a plurality of cables at intervals, and the driving assembly is in driving connection with the cables and used for driving the cables to move in or out of the frame. The utility model discloses a frame is used for placing the cable, can be convenient for the storage of cable, simultaneously, is equipped with drive assembly, can be convenient for the immigration of cable and shift out, does benefit to wiring efficiency and cable and retrieves, promotes electromechanical device debugging efficiency, and is equipped with installation component and winding displacement subassembly, can avoid taking place to twine between the cable when avoiding the cable to break away from the frame, promotes the recovery efficiency of cable and deposits the orderliness.

Description

Wiring device and debugging equipment

Technical Field

The utility model relates to a technical field of cable transmission particularly, relates to a termination and debugging equipment.

Background

During the debugging work of the electromechanical device, the electromechanical device needs to be wired, that is, a cable is connected to the electromechanical device, so as to perform specific debugging on the electromechanical device.

At present, the cable is generally accessed manually, that is, the cable is pulled manually to move to the electromechanical device, and the electromechanical device is debugged after being connected with the cable. This wiring method has certain disadvantages: firstly, the efficiency that artifical pulling cable accomplished the wiring operation is lower, influences equipment debugging efficiency, secondly the wiring debugging accomplishes the back, and the operation is withdrawed complicacy to the cable, and the cable winding easily appears hinders to deposit and reuse.

SUMMERY OF THE UTILITY MODEL

In order to solve at least one of the above problems, in one aspect, the present invention provides a wiring device, including:

the supporting assembly comprises a frame and a mounting component, the mounting component is arranged in the frame, and the mounting component is used for being connected with the tail end of the cable;

the working assembly comprises a flat cable assembly and a driving assembly, the flat cable assembly and the driving assembly are located in the frame, the flat cable assembly is used for placing the cables at intervals, the driving assembly is in driving connection with the cables, and the driving assembly is used for driving the cables to move in or out of the frame.

Optionally, the driving assembly includes a first power member, a wire guiding roller and a power roller, the first power member is in driving connection with the power roller, the wire guiding roller and the power roller are arranged in the frame 11 at an interval, the cable is located between the wire guiding roller and the power roller, and the power roller drives the cable to move through cooperation of the first power member and the wire guiding roller.

Optionally, the drive assembly further comprises:

first spacers arranged on the guide rollers at intervals in an axial direction of the guide rollers, the first spacers being used for correspondingly placing the cables therebetween;

second spacers which are arranged on the power rollers at intervals along the axial direction of the power rollers, and are used for correspondingly placing the cables;

the first spacers and the second spacers are in one-to-one correspondence.

Optionally, the flat cable assembly includes a flat cable roller and third spacers, the flat cable roller is mounted in the frame, the third spacers are disposed on the flat cable roller at intervals along an axial direction of the flat cable roller, and the third spacers are used for correspondingly placing the cables.

Optionally, the winding displacement assembly further comprises a bearing seat, the bearing seat is arranged on the frame, and the end of the wire conveying roller is located in the bearing seat.

Optionally, the work assembly further comprises a wiring assembly, the wiring assembly comprising:

a wiring board mounted within the frame;

and the wiring holes are arranged on the wiring board at intervals and used for the cables to pass through.

Optionally, the mounting assembly includes a connecting member, the connecting member is mounted in the frame and has connecting holes at intervals thereon, and the connecting holes are used for connecting the tail ends of the cables.

Optionally, the work assembly further comprises a tensioning assembly, the tensioning assembly comprising:

a bracket located within the frame and located to one side of the drive assembly;

the second power part is arranged on the bracket;

the transmission structure is respectively connected with the bracket and the second power piece and is used for driving the bracket to move towards or away from the driving assembly along the transmission structure through the second power piece;

the wire harness block is arranged on the support at intervals, and a wire harness hole is formed in the wire harness block to allow the cable to penetrate through.

Optionally, the support assembly further comprises:

a protection plate installed at an outer side of the frame;

a wire connection port located between the frame and the fender and corresponding to the drive assembly, the wire connection port being for movement of the cable into or out of the frame;

a weight located within the frame;

a base, the frame being located on the base.

Compared with the prior art, the utility model discloses a termination's beneficial effect includes: the frame is used for storing the cable, so that the cable can be integrally moved to the electromechanical equipment to be wired and debugged during wiring operation, the cable can be conveniently stored after the wiring debugging is finished, and the cable can be conveniently used in the next wiring operation; in addition, the driving assembly used for driving the cable to move into and out of the frame is arranged, so that the efficiency of the cable in moving out and the convenience of the cable in recycling are greatly improved, and further the efficiency of wiring operation is improved; finally, the installation assembly used for connecting the tail end of the cable and the wire arranging assembly used for placing the cable at intervals are arranged in the frame, the installation assembly can prevent the cable from completely moving out of the frame, the driving assembly can drive the cable to move into the frame for storage, meanwhile, the wire arranging assembly can space a plurality of cables moving into or out of the frame, winding among the plurality of cables is avoided, obstacles are caused when the cables move in and out, and then the efficiency of wiring operation is improved.

On the other hand, the utility model also provides a debugging equipment, include as above termination, termination's cable is used for being connected with electromechanical device.

Compared with the prior art, the utility model discloses a debugging equipment's beneficial effect includes: the cable is quickly output through the driving assembly, the cable and the electromechanical device are quickly installed, preparation work for debugging the electromechanical device is reduced, and debugging efficiency of the electromechanical device is improved.

Drawings

FIG. 1 is a schematic view of a view angle according to an embodiment of the present invention;

fig. 2 is a schematic view of a part of another view angle in the embodiment of the present invention;

fig. 3 is a schematic structural view of a view angle of a tension assembly according to an embodiment of the present invention;

fig. 4 is a schematic structural view of another angle of the tension assembly in the embodiment of the present invention;

FIG. 5 is a schematic view of another embodiment of the present invention;

fig. 6 is a schematic structural diagram of a support assembly according to an embodiment of the present invention.

Description of the reference numerals:

1-a support assembly; 11-a frame; 12-a mounting assembly; 121-a connector; 122-connection holes; 13-protective plate; 14-lifting lugs; 15-a counterweight block; 16-a base; 2-a work assembly; 21-a flat cable assembly; 211-transfer roll; 212-a third spacer; 213-a bearing seat; 22-a drive assembly; 221-a first power member; 222-a wire guide roller; 223-powered rollers; 224-a first spacer; 225-a second spacer; 23-a wiring assembly; 231-a wiring board; 232-wiring holes; 24-a tensioning assembly; 241-a support; 242-a second power member; 243-a transmission structure; 244-beam line block; 245-a bundle hole; 3-a cable.

Detailed Description

In order to make the aforementioned objects, features and advantages of the present invention more comprehensible, embodiments accompanied with figures are described in detail below.

In the coordinate system XYZ provided herein, the forward direction of the X axis represents the right direction, the reverse direction of the X axis represents the left direction, the forward direction of the Y axis represents the rear direction, the reverse direction of the Y axis represents the front direction, the forward direction of the Z axis represents the upper direction, and the reverse direction of the Z axis represents the lower direction. Also, it is noted that the terms "first," "second," and the like in the description and claims of the present invention and in the above-described drawings are used for distinguishing between similar elements and not necessarily for describing a particular sequential or chronological order. It is to be understood that the data so used is interchangeable under appropriate circumstances such that the embodiments of the invention described herein are capable of operation in sequences other than those illustrated or otherwise described herein.

In order to solve the above technical problem, an aspect of the present invention provides a wiring device, including: the supporting assembly 1, the supporting assembly 1 includes the frame 11 and installs the assembly 12, install the assembly 12 and locate in frame 11, install the assembly 12 and is used for connecting with the tail end of the cable 3; the working assembly 2 comprises a flat cable component 21 and a driving component 22, the flat cable component 21 is located in the frame 11, the flat cable component 21 is used for placing a plurality of cables 3 at intervals, the driving component 22 is in driving connection with the cables 3, and the driving component 22 is used for driving the cables 3 to move into or out of the frame 11.

As shown in fig. 1, in this embodiment, the mounting assembly 12 in the frame 11 is connected to the tail of the cable 3, the driving assembly 22 disposed in the frame 11 is in driving connection with the cable 3 and is used for driving the cable 3 to move into or out of the frame 11, so that, when wiring of the electromechanical device is performed, the frame 11 is moved to the electromechanical device to be wired and debugged, the cable 3 can be moved out of the frame 11 only by forward opening the driving assembly 22, an operator can directly operate the cable 3 to complete wiring without manual dragging, the operation efficiency is high, and the tail of the cable 3 is connected to the mounting assembly 12, so that the cable 3 is not separated from the frame 11, the cable 3 cannot be recovered due to separation and falling of the cable 3 from the frame 11, and the subsequent cable 3 recovery is facilitated; simultaneously, set up winding displacement subassembly 21 in frame 11, winding displacement subassembly 21 is used for the interval to place cable 3, like this, at the in-process that cable 3 moved in and moved out frame 11, has the interval between many cables 3, and difficult emergence winding is favorable to the smoothness when cable 3 removes to further promote the efficiency when using 3 wiring of cable, and also difficult emergence winding of many cables 3 when depositing in frame 11 is favorable to depositing and reuse.

It should be noted that, in this embodiment, the frame 11 may be formed by connecting a plurality of support rods, such as triangular steel, through a fixed connection manner, such as welding, or a detachable connection manner, such as bolt connection, and the frame 11 may support the mounting assembly 12, the flat cable assembly 21, and the driving assembly 22, which is beneficial to ensuring stability of the three.

It should be noted that, in this embodiment, considering that the wiring of most electromechanical devices is higher, the driving assembly 22 may be disposed on one side of the upper end of the frame 11, so that the cable 3 may be directly moved out from one side of the upper end of the frame 11, and the cable 3 may be directly connected to the electromechanical device, and meanwhile, when the cable 3 moves outside the frame 11, the cable 3 may droop under the action of gravity, and when the cable 3 is manually pulled, the cable 3 needs to be manually lifted, that is, the cable 3 is manually lifted to avoid friction with the ground, and in this embodiment, the cable 3 and the plane where the frame 11 is located have a certain distance, so that the cable 3 may droop to be less prone to friction with the plane where the frame 11 is located, and the cable 3 does not need to be manually lifted, and also may be prevented from being damaged during friction, which may facilitate prolonging the service life of the cable 3 and may save a lot of manpower. Of course, in the utility model discloses in other embodiments, also can specifically set up the position of drive assembly 22 at frame 11 according to the electromechanical device that needs the debugging to do benefit to the convenience when promoting the wiring of cable 3, promote wiring efficiency.

It should be noted that, in this embodiment, the mounting assembly 12 may be disposed below the driving assembly 22, and the cable arrangement assembly 21 is disposed on one side of the driving assembly 22 at the same height, so that the cable 3 connected to the mounting assembly 12 enters the driving assembly 22 through the cable arrangement assembly 21, and under the action of gravity, the cable 3 between the cable arrangement assembly 21 and the driving assembly 22 may hang down, and the distance between the cable arrangement assembly 21 and the bottom end inside the frame 11 may enable the frame 11 to store longer cables 3, which may meet the requirement that the driving cable 3 completes wiring under the condition that some electromechanical devices are not easy to approach the wiring.

It should be noted that, in the present embodiment, the mounting assembly 12, the driving assembly 22 and the flat cable assembly 21 are all fixedly connected to the frame 11 by welding, for example, and the structural stability of the whole wiring device is high. In other embodiments of the present invention, the mounting assembly 12, the driving assembly 22 and the cable assembly 21 can be detachably connected to the frame 11 by means of bolts, and the positions of the mounting assembly 12, the driving assembly 22 and the cable assembly 21 on the frame 11 can be adjusted according to the specific requirements of the electromechanical device to be wired and debugged.

Optionally, the driving assembly 22 includes a first power member 221, a wire guiding roller 222 and a power roller 223, the first power member 221 is in driving connection with the power roller 223, the wire guiding roller 222 and the power roller 223 are arranged in the frame 11 at intervals, the cable 3 is located between the wire guiding roller 222 and the power roller 223, and the power roller 223 drives the cable 3 to move by the cooperation of the first power member 221 and the wire guiding roller 222.

As shown in fig. 1 and fig. 2, in this embodiment, the power roller 223 is in driving connection with the first power member 221, the power roller 223 and the wire guiding roller 222 are arranged at an interval, and the cable 3 can be placed between the power roller 223 and the wire guiding roller 222, both ends of the power roller 223 and the wire guiding roller 222 are rotatably connected with the frame 11, so that under the driving action of the first power member 221, the power roller 223 rotates, both the power roller 223 and the wire guiding roller 222 have pressure on the cable 3, at this time, the power roller 223 is a driving roller, the wire guiding roller 222 is a driven roller, and the rotation of the power roller 223 can drive the movement of the cable 3 and the reverse rotation of the wire guiding roller 222, so as to achieve the purpose of driving the cable 3 to move into and out of the frame 11, and for manual dragging, the matching driving of the power roller 223 and the wire guiding roller 222 is beneficial to improving the convenience of the movement of the cable 3, and improving the efficiency of the wiring operation.

It should be noted that, in this embodiment, for example, considering that the frame 11 is generally moved to one side of the electromechanical device, the power roller 223 and the wire guiding roller 222 are disposed on one side of the upper end of the frame 11, both the power roller 223 and the wire guiding roller 222 are parallel to the plane of the frame 11, and the wire guiding roller 222 is located below the power roller 223, so that the cable 3 can be directly moved out from one side of the frame 11 to the electromechanical device under the driving of the power roller 223 and the wire guiding roller 222, which is convenient for the operator to perform the wire connection operation. Of course, in other embodiments of the present invention, the power roller 223 and the wire guide roller 222 may be disposed perpendicular to the plane of the frame 11, or the moving-in and moving-out positions of the cable 3 composed of the power roller 223 and the wire guide roller 222 may be disposed on other positions of the frame 11, such as the top end surface or the lower end side surface, as required.

It should be noted that, in this embodiment, the first power member 221 is exemplarily a servo motor, the servo motor is disposed on the frame 11, and the output end of the servo motor is connected to the power roller 223.

It should be noted that, in the present embodiment, structures such as mounting holes or bearings may be provided on the frame 11 for mounting both end portions of the power roller 223 and the wire guide roller 222, for example.

Optionally, the drive assembly 22 further comprises: first spacers 224, the first spacers 224 being provided on the guide rollers 222 at intervals in the axial direction of the guide rollers 222, the first spacers 224 being used to place the cables 3 correspondingly therebetween; second spacers 225, wherein the second spacers 225 are arranged on the power rollers 223 along the axial direction of the power rollers 223 at intervals, and the second spacers 225 are used for correspondingly placing the cables 3; the first spacers 224 correspond to the second spacers 225 one to one.

As shown in fig. 1 and 2, in the present embodiment, the cables 3 are located between the wire guiding roller 222 and the power roller 223, the first spacers 224 are spaced on the wire guiding roller 222, the second spacers 225 are spaced on the power roller 223, the cables 3 are placed between the first spacers 224 and the second spacers 225, and the first spacers 224 and the second spacers 225 are in one-to-one correspondence, so that when the power roller 223 and the wire guiding roller 222 cooperate to drive the cables 3 to move, the cables 3 are spaced by the first spacers 224 and the second spacers 225, and when the cables 3 move into and out of the frame 11 at the same time, the cables 3 are not easily twisted with each other, which is beneficial to ensuring the smoothness when the cables 3 move into and out of the frame 11, and when the cables 3 are connected, the operator does not need to spend time to loosen the twist between the cables 3, thereby improving the efficiency of the operator in the wire connecting operation.

In the present embodiment, in order to improve the continuity of the action of the spacing between the wires 3, the first spacers 224 may be provided on the roller axial surface of the wire guide roller 222 at intervals in the axial direction of the wire guide roller 222 so as to cover the entire circumference of the axial surface of the wire guide roller 222, and the second spacers 225 may be positioned relative to the power roller 223 so as to space the wires 3 from each other throughout the movement of the wires 3 driven by the rotation of the power roller 223 and the wire guide roller 222, thereby further reducing the possibility of the wires 3 being entangled with each other.

It should be noted that, as shown in fig. 2, the first spacer 224 and the second spacer 225 are both ring structures, and a plurality of ring structures are sleeved on the rolling surfaces of the power roller 223 and the wire guiding roller 222 at intervals along the axial direction of the power roller 223 and the wire guiding roller 222, so that a circular wire slot coinciding with the rolling axial surfaces of the power roller 223 and the wire guiding roller 222 is formed between the ring structures, the cable 3 is located in the wire slot, the ring structures block the movement of the cable 3 along the axial direction of the power roller 223 and the wire guiding roller 222, and further reduce the possibility of winding between the cables 3, wherein, in order to be suitable for placing cables 3 with different sizes, threads can be arranged on the rolling surfaces of the power roller 223 and the wire guiding roller 222, the ring structures can be detachably mounted on the wire guiding roller 222 and the power roller 223 through the threads, and the purpose of adjusting the distance between the ring structures is achieved by adjusting the number of turns of the ring structures around the threads. Of course, in other embodiments of the present invention, the cable 3 may be isolated by directly providing grooves on the rolling surfaces of the power roller 223 and the wire guide roller 222.

It should be noted that, in the present embodiment, the plurality of cables 3 are spaced apart one by the first spacers 224 and the second spacers 225, and in other embodiments of the present invention, the number of cables 3 placed between the first spacers 224 and between the second spacers 225, such as two or three, may also be adjusted according to actual needs.

Optionally, the traverse assembly 21 includes traverse rollers 211 and third spacers 212, the traverse rollers 211 are mounted in the frame 11, the third spacers 212 are disposed on the traverse rollers 211 at intervals along the axial direction of the traverse rollers 211, and the third spacers 212 are disposed therebetween for correspondingly placing the cables 3.

As shown in fig. 1 and 2, in the present embodiment, the wire roller 211 is disposed in the frame 11, the third spacer 212 is disposed on the curved surface of the wire roller 211 at an interval along the axial direction of the wire roller 211, the cable 3 enters the wire roller 211 from the mounting assembly 12, the cables 3 are separated by the third spacer 212 on the wire roller 211, and the cable 3 enters between the wire roller 222 and the power roller 223 from the wire roller 211, so that when the cable 3 moves under the driving action of the wire roller 222 and the power roller 223, the wire roller 211 can support the movement of the cable 3, the cables 3 can be isolated from each other on the wire roller 211, the wire roller 211 can cooperate with the power roller 223 and the wire roller 222 to further reduce the possibility of the cable 3 being wound, and the wire roller 211 has a curved surface structure, which can make the movement of the cable 3 between the power roller 223 and the mounting assembly 12 turn to a more smooth direction without damaging the cable 3,

it should be noted that, as shown in fig. 2, in the present embodiment, the number of the wire transferring rollers 211 is two, and the wire transferring rollers 211 are disposed at an interval at one side of the driving assembly 22 and are located at the same height as the driving assembly 22, so that when the wire 3 is retracted after the wire connecting operation is completed, the wire 3 between the wire transferring rollers 211 can naturally hang down and enter the lower end portion inside the frame 11 for storage, and the wire 3 is not separated from the wire transferring rollers 211, which is convenient for use in the next wire connecting operation.

It should be noted that, as shown in fig. 2, in this embodiment, the third spacer 212 is a wire bunching wheel, a through hole having the same diameter as the curved surface of the wire transfer roller 211 is disposed at a center of the wire bunching wheel, the wire bunching wheel is sleeved on the wire transfer roller 211 through the through hole at intervals along the axial direction of the wire transfer roller 211, and the wire bunching wheel can be used for forming an interval between the cables 3 and preventing the cables 3 from being deviated along the axial direction of the wire transfer roller 211 during the moving process to wind the cables 3. In other embodiments of the present invention, a groove may be directly formed on the transfer roller 211 as the third spacer 212.

In order to ensure smooth correspondence when the cables 3 move, in the present embodiment, the number of the third spacers 212 is set to be equal to the number of the first spacers 224 and the second spacers 225, and the third spacers 212 correspond to the first spacers 224 and the second spacers 225, respectively, one by one.

Optionally, the wire arranging assembly 21 further includes a bearing seat 213, the bearing seat 213 is disposed on the frame 11, and the end of the wire feeding roller 211 is located in the bearing seat 213.

As shown in fig. 1 and 2, in the present embodiment, both ends of the wire roller 211 are located on the bearing seats 213, and the bearing seats 213 are disposed in the frame 11, so that when the cable 3 moves on the wire roller 211, there is a static friction force along the tangential direction of the curved surface of the wire roller 211, and under the action of the static friction force, the wire roller 211 rotates, and the cable 3 continues to move while rotating, so as to avoid the damage to the surface of the cable 3 and the influence on the service life of the cable 3 caused by the friction between the cable 3 and the wire roller 211 when the wire roller 211 moves without movement.

It should be noted that, while the wire transfer roller 211 rotates, since the wire guide wheels as the third spacers 212 are in a closed loop structure, the wire transfer roller 211 rotates to any position, and the wire guide wheels thereon can play a role in spacing the cables 3.

Optionally, the work assembly 2 further comprises a wiring assembly 23, the wiring assembly 23 comprising: a wiring board 231, the wiring board 231 being mounted in the frame 11; wiring holes 232, the wiring holes 232 are provided on the wiring board 231 at intervals, the wiring holes 232 are used for the cables 3 to pass through.

In this embodiment, as shown in fig. 1, the wiring board 231 is installed in the frame 11 and located below the two wire transfer rollers 211, the wiring hole 232 is a strip-shaped hole, and the length direction of the strip-shaped hole is parallel to the moving direction of the cable 3 between the wire transfer rollers 211, so that when the cable 3 between the wire transfer rollers 211 hangs down, a single cable can directly enter one wiring hole 232, the wiring board 231 plays a role in isolating the cable 3 hanging down between the wire transfer rollers 211, when the cable 3 is too long or the cable 3 is stored after being moved into the frame 11, the cable 3 hanging down between the wire transfer rollers 211 cannot be easily wound, the regularity of the cable 3 during storage and movement of the cable 3 is further improved, and the smooth degree of movement of the cable 3 during wiring operation is favorably improved.

In other embodiments of the present invention, the wiring board 231 may be disposed at other positions such as between the mounting assembly 12 and the wire roller 211, and the wiring hole 232 may be a hole having other structures such as a circular hole suitable for the cable 3 to pass through.

In the present embodiment, in order to ensure the smooth correspondence when the cables 3 move, the number of the wiring holes 232 is set to be equal to the number of the third spacers 212, and the wiring holes 232 correspond to the third spacers 212 one-to-one in the present embodiment.

It should be noted that, in this embodiment, the wiring board 231 is connected to the frame 11 by a fixing means such as welding, and in other embodiments of the present invention, a detachable connection means such as bolt connection may be used to connect to the frame 11, so that the position of the wiring board 231 in the frame 11 can be adjusted as required.

Optionally, the mounting assembly 12 includes a connecting member 121, the connecting member 121 is mounted in the frame 11 and spaced apart from the frame by a connecting hole 122, and the connecting hole 122 is used for connecting the tail end of the cable 3.

As shown in fig. 1 and 4, in the present embodiment, the connecting member 121 is installed on one side of the lower end of the inside of the frame 11, and the tail ends of the cables 3 are respectively disposed in the connecting holes 122 of the connecting member 121, so that when the cables 3 move into and out of the frame 11, the cables 3 are constantly connected with the inside of the frame 11, and the cables 3 are prevented from being excessively moved out, so that the cables 3 are separated from the wire-transferring roller 211 or the driving assembly 22, which is not beneficial to the subsequent recovery and storage of the cables 3.

It should be noted that, in the present embodiment, the connecting member 121 is a plate-shaped structure, such as a copper bar, and is disposed in the frame 11 by a fixed connection manner, such as welding, and the connecting holes 122 are through holes disposed on the connecting member 121 at intervals, and the tail end of the cable 3 penetrates through the through holes and is connected to the connecting member 121 through a limiting member, such as a bolt, so as to facilitate stability of the cable 3 when moving into and out of the frame 11.

Optionally, the work assembly 2 further comprises a tensioning assembly 24, the tensioning assembly 24 comprising: a bracket 241, the bracket 241 is positioned in the frame 11 and positioned at one side of the driving assembly 22; a second power member 242, the second power member 242 being mounted on the bracket 241; a transmission structure 243, wherein the transmission structure 243 is respectively connected with the bracket 241 and the second power member 242, and the transmission structure 243 is used for driving the bracket 241 to move towards or away from the driving assembly 22 along the transmission structure 243 through the second power member 242; and a wire harness block 244, wherein the wire harness block 244 is arranged on the support 241 at intervals, and a wire harness hole 245 is arranged on the wire harness block 244 for the cable 3 to pass through.

As shown in fig. 1 and fig. 2, in the present embodiment, the transmission structure 243 is disposed between the driving assembly 22 and the flat cable assembly 21, the support 241 is disposed on the transmission structure 243, the second power element 242 is mounted on the support 241 and connected to the transmission structure 243, the transmission structure 243 can drive the support 241 to move along the transmission structure 243 between the driving assembly 22 and the flat cable assembly 21 through the second power element 242, the support 241 is spaced by a wire tying block 244, a wire tying hole 245 is disposed on the wire tying block 244, the cable 3 enters the driving assembly 22 from the flat cable assembly 21 through the wire tying hole 245 for the driving assembly 22 to drive the cable 3 to move into and out of the frame 11, so that when the driving assembly 22 drives the cable 3 out of the frame 11, the second power element 242 is positively actuated, the support 241 moves from the flat cable assembly 21 towards the driving assembly 22, at this time, the cable 3 is located in the wire tying hole 245, and when the support 241 moves, the cable 3 between the flat cable assembly 21 and the driving assembly 22 is pulled by the cable-bunching hole 245 towards the driving assembly 22, the cable 3 between the flat cable assembly 21 and the driving assembly 22 is tensioned and moved out of the frame 11 through the driving assembly 22, and in the process, a plurality of cables 3 are combed and separated again by the cable-bunching hole 245, so that the problem that the cable 3 between the flat cable assembly 21 and the driving assembly 22 is loosened and twined with each other to obstruct the movement of the cable 3 out of the frame 11 when the driving assembly 22 drives the cable 3 to move out of the frame 11 is avoided, similarly, when the driving assembly 22 drives the cable 3 to move into the frame 11, the second power element 242 is reversely started, so that the bracket 241 can be moved towards the flat cable assembly 21 by the driving assembly 22, and thus the problem that the cable 3 in the frame 11 is loosened and twined with each other to obstruct the movement of the cable 3 into the frame 11 when the cable 3 moves into the frame 11 can be avoided, thereby improving the smoothness of the movement of the cable 3 out of and into the frame 11 and thus the efficiency of the wiring work.

It should be noted that, as shown in fig. 3 and fig. 4, in this embodiment, exemplarily, the second power component 242 is a servo motor, the transmission structure 243 is a first slide rail, a rack and a second slide rail that are connected to the frame 11 and are arranged in parallel at an interval on one side of the driving assembly 22, the support 241 is arranged on the first slide rail, the rack and the second slide rail, a first slider that is connected to the first slide rail in a sliding manner and a second slider that is connected to the second slide rail in a sliding manner are arranged below the support 241, an output end of the servo motor is arranged below the support 241 and is provided with a gear that is engaged with the rack, when it is necessary to move the support 241, the servo motor is started, the gear rotates, the rack remains stationary, and the gear moves along the rack, thereby driving the servo motor and the support 241 to move along the rack, and achieving the purpose of moving the bunch block 244 on the support 241, thereby achieving the purpose of tensioning and combing the bunch hole 245 on the bunch block 244 to the cable 3, meanwhile, the first slider slides along the first slide rail, and the second slider slides along the second slide rail 241, so that the stability when the support moves is higher.

It should be noted that, as shown in fig. 2 and fig. 3, a buffer block (not shown) is disposed on one side end surface of the support 241 facing the driving component 22, and a limiting plate (not shown) corresponding to the buffer block is disposed on the frame 11, so that when the support 241 moves toward the driving component 22 and the support 241 moves to approach the driving component 22, the buffer block impacts the limiting plate, and the limiting plate limits the movement of the support 241 to prevent the support 241 from impacting the driving component 22, thereby ensuring the working stability of the driving component 22 when the support 241 moves, of course, the buffer block may also be disposed on one side end surface of the support 241 facing the traverse component 21, and the limiting plate corresponding to the buffer block is disposed on the frame to ensure the stability of the traverse component 21 when the support 241 moves.

It should be noted that, in other embodiments of the present invention, a stepping servo motor can also be used as the second power member 242, an electric cylinder is used as the transmission structure 243, the stepping servo motor is electrically connected to the electric cylinder, one end of the electric cylinder is connected to the frame 11, the bracket 241 is installed on the electric cylinder, and the stepping servo motor can drive the electric cylinder to move, so as to achieve the purpose of driving the bracket 241 to move.

It should be noted that, in the present embodiment, the number of the wire harness blocks 244 matches the number of the cables 3 for the front-rear correspondence when the cables 3 sequentially pass through the traverse assembly 21, the tension assembly 24, and the drive assembly 22.

It should be noted that, in this embodiment, the aperture of the wire harness hole 245 matches the diameter of the cable 3, and the wire harness block 244 is connected to the support 241 by a detachable connection means such as a bolt connection, so that when tensioning and combing are performed on cables 3 with different diameters, the wire harness block 244 on the support 241 is replaced by the wire harness block 244 on which the aperture of the wire harness hole 245 matches the diameter of the cable 3, so as to achieve the purpose of being used for different cables 3.

Optionally, the support assembly 1 further comprises: a shielding plate 13, the shielding plate 13 being installed at an outer side of the frame 11; the wiring port is positioned between the frame 11 and the protection plate 13 and corresponds to the driving assembly 22, and is used for moving the cable 3 into or out of the frame 11; the counterweight block 15, the counterweight block 15 locates in frame 11; a base 16, and the frame 11 is positioned on the base 16.

As shown in fig. 1 and 6, in this embodiment, in order to protect each component in the frame 11 and prevent the component from being affected by the outside of the frame 11 and causing damage, a protection plate 13 covering the frame 11 is disposed on the outside of the frame 11, and of course, in order to facilitate the movement of the cable 3 into and out of the frame 11, a wiring port (not shown) is disposed between the protection plate 13 and the frame 11 and is disposed corresponding to the driving component 22, so that the cable 3 can be directly moved out of and into the frame 11 through the wiring port by being driven by the driving component 22, and the wiring operation is facilitated.

As shown in fig. 1 and 5, in this embodiment, in order to ensure the stability of the frame 11 on the plane where the frame 11 is located when the cables 3 move in and out by the operation of each component in the frame 11, a weight block 15 may be disposed at the lower end inside the frame 11, so that the frame 11 may maintain the stability when receiving a force in the horizontal direction, and further improve the stability during the wiring operation, and at the same time, a base 16 may be disposed for placing the frame 11, so that the frame 11 may maintain the stability when receiving a force in the vertical direction.

It should be noted that, in order to facilitate the frame 11 to move to one side of the motor equipment requiring wiring rapidly, as shown in fig. 1 and fig. 6, in this embodiment, a plurality of lifting lugs 14 are disposed on two side surfaces of the upper end of the frame 11, and the hoisting equipment may be connected to the lifting lugs 14 through a connection line, so as to achieve the purpose of hoisting the frame 11 to the motor equipment requiring wiring; of course, in other embodiments of the present invention, a moving member such as a moving wheel for moving the frame 11 may be further provided on the side of the lower end portion of the frame 11, so that the frame 11 can be directly moved to the electromechanical device.

It should be noted that, in this embodiment, the protection plates 13 are connected to the frame 11 through a detachable connection manner such as a bolt connection, so that when a component inside the frame 11 needs to be replaced or needs to be maintained, the corresponding protection plate 13 can be directly detached, which is convenient for an operator to perform related operations.

On the other hand, an embodiment of the utility model also provides a debugging device, including above-mentioned termination, termination's cable 3 is used for being connected with electromechanical device.

As shown in fig. 1, in the present embodiment, the cable 3 is quickly output to the outside of the frame 11 by the driving assembly 22, so as to complete quick installation of the cable 3 and the electromechanical device, reduce preparation work for debugging the electromechanical device, and improve efficiency of debugging the electromechanical device.

As shown in fig. 1, in this embodiment, a PLC control board (not shown) and a contactor may be further disposed in the frame 11, and after the cable 3 is connected to the electromechanical device, the electromechanical device is debugged through the PLC control board and the contactor.

Although the present disclosure has been described above, the scope of the present disclosure is not limited thereto. Various changes and modifications may be made by those skilled in the art without departing from the spirit and scope of the present disclosure, and these changes and modifications are intended to fall within the scope of the present disclosure.

Claims (10)

1. A wiring device, comprising:

the supporting assembly (1), the supporting assembly (1) comprises a frame (11) and a mounting assembly (12), the mounting assembly (12) is arranged in the frame (11), and the mounting assembly (12) is used for being connected with the tail end of the cable (3);

work assembly (2), work assembly (2) include winding displacement subassembly (21) and drive assembly (22), winding displacement subassembly (21) are located in frame (11), winding displacement subassembly (21) are used for the interval to place many cable (3), drive assembly (22) with cable (3) drive connection just drive assembly (22) are used for the drive cable (3) immigration or shift out frame (11).

2. The wiring lug of claim 1,

the driving assembly (22) comprises a first power part (221), a wire guiding roller (222) and a power roller (223), the first power part (221) is in driving connection with the power roller (223), the wire guiding roller (222) and the power roller (223) are arranged in the frame (11) at intervals, the cable (3) is located between the wire guiding roller (222) and the power roller (223), and the power roller (223) drives the cable (3) to move through the cooperation of the first power part (221) and the wire guiding roller (222).

3. The wiring lug of claim 2, wherein the drive assembly (22) further comprises:

first spacers (224), the first spacers (224) being arranged on the guide rollers (222) at intervals along the axial direction of the guide rollers (222), the first spacers (224) being used for correspondingly placing the cables (3);

second spacers (225), wherein the second spacers (225) are arranged on the power rollers (223) at intervals along the axial direction of the power rollers (223), and the second spacers (225) are used for correspondingly placing the cables (3);

wherein the first spacers (224) correspond to the second spacers (225) one to one.

4. The wiring device of claim 3,

the winding displacement assembly (21) comprises a transmission roller (211) and third spacing pieces (212), the transmission roller (211) is installed in the frame (11), the third spacing pieces (212) are arranged on the transmission roller (211) at intervals along the axial direction of the transmission roller (211), and the third spacing pieces (212) are used for correspondingly placing the cables (3).

5. The wiring device of claim 4,

the winding displacement subassembly (21) still includes bearing frame (213), bearing frame (213) are located on frame (11), the tip of biography line roller (211) is located in bearing frame (213).

6. The wiring lug according to claim 5, wherein the work assembly (2) further comprises a wiring assembly (23), the wiring assembly (23) comprising:

a wiring board (231), the wiring board (231) being mounted within the frame (11);

wiring holes (232), the wiring holes (232) being provided at intervals on the wiring board (231), the wiring holes (232) being used for the cables (3) to pass through.

7. The wiring device of claim 6,

the mounting assembly (12) comprises a connecting piece (121), the connecting piece (121) is mounted in the frame (11) and is provided with connecting holes (122) at intervals, and the connecting holes (122) are used for connecting the tail ends of the cables (3).

8. The wiring lug according to any one of claims 1 to 7, wherein the work assembly (2) further comprises a tensioning assembly (24), the tensioning assembly (24) comprising:

a bracket (241), the bracket (241) being located within the frame (11) and on one side of the drive assembly (22);

a second power member (242), the second power member (242) being mounted on the bracket (241);

a transmission structure (243), wherein the transmission structure (243) is respectively connected with the bracket (241) and the second power member (242), and the transmission structure (243) is used for driving the bracket (241) to move towards or away from the driving assembly (22) along the transmission structure (243) through the second power member (242);

the cable bundling device comprises a wire bundling block (244), wherein the wire bundling block (244) is arranged on the support (241) at intervals, and a wire bundling hole (245) is formed in the wire bundling block (244) for the cable (3) to pass through.

9. The wiring lug according to claim 8, wherein the support assembly (1) further comprises:

a shielding plate (13), the shielding plate (13) being installed at an outer side of the frame (11);

a connection port located between the frame (11) and the protection plate (13) and corresponding to the drive assembly (22), for the movement of the cable (3) into or out of the frame (11);

a weight (15), the weight (15) being located within the frame (11);

a base (16), the frame (11) being located on the base (16).

10. Commissioning device comprising a wiring device according to any one of claims 1 to 9, the cable (3) of said wiring device being intended to be connected to an electromechanical device.

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