CN219967969U

CN219967969U - Debugging maintenance platform

Info

Publication number: CN219967969U
Application number: CN202320888652.8U
Authority: CN
Inventors: 许青川; 梁雨松
Original assignee: Inner Mongolia Mengdong Energy Co ltd; National Energy Group Guoyuan Power Co Ltd
Current assignee: Inner Mongolia Mengdong Energy Co ltd; National Energy Group Guoyuan Power Co Ltd
Priority date: 2023-04-19
Filing date: 2023-04-19
Publication date: 2023-11-07
Anticipated expiration: 2033-04-19

Abstract

The present disclosure relates to a debugging maintenance platform, the platform includes: the standing board assembly comprises a fixed standing board and two telescopic standing boards, wherein the two telescopic standing boards are symmetrically arranged on two sides of the fixed standing board along a first direction and can respectively stretch and retract relative to the fixed standing board along the first direction; the telescopic frame is used for supporting the bottom of the standing board assembly in the vertical direction; the output end of the first driving component is connected with the telescopic frame and is configured to drive the telescopic frame to stretch along the vertical direction; and the second driving assembly is used for being connected with the two telescopic station plates, and is configured to drive the two telescopic station plates to stretch and retract relative to the fixed station plate along the first direction respectively. The maintenance platform in the embodiment of the disclosure not only can meet a larger operation range when in use, but also has smaller volume when not in use, so that a larger placing space is not required to be occupied, and the flexibility of use is fully increased.

Description

Debugging maintenance platform

Technical Field

The disclosure relates to the technical field of electrical equipment debugging and maintenance platforms, in particular to a debugging and maintenance platform.

Background

The electric equipment consists of a large number of electronic elements such as transistors, integrated circuits, resistors, capacitors and the like, most faults do not have any sign before occurrence, the most important link in maintenance work is to search the fault point of the equipment on site, and meanwhile, most of the electric equipment is installed at a higher place and needs to be debugged and maintained through a related maintenance platform. When the existing maintenance platform is used, hydraulic pressure is generally adopted to push upwards, so that the maintenance platform is lifted.

However, the current debugging and maintaining platform is too limited, so that the fault point is not found at the position after lifting or the fault point is not found at the position, the position needs to be changed for processing, and if the maintaining platform is not lowered, the maintaining platform is possibly unstable due to the fact that the position of the maintaining platform is directly moved, and the risk of injury is caused to staff.

Disclosure of Invention

It is an object of the present disclosure to provide a commissioning repair platform capable of solving, at least in part, technical problems existing in the related art.

To achieve the above object, the present disclosure provides a debug maintenance platform including:

the station board assembly comprises a fixed station board and two telescopic station boards, wherein the two telescopic station boards are symmetrically arranged on two sides of the fixed station board along a first direction and can respectively stretch and retract relative to the fixed station board along the first direction;

the telescopic frame is used for supporting the bottom of the standing board assembly in the vertical direction;

the output end of the first driving component is connected with the telescopic frame and is configured to drive the telescopic frame to stretch in the vertical direction; and

and the output end of the second driving assembly is used for being connected with the two telescopic station plates and is configured to be capable of driving the two telescopic station plates to extend and retract relative to the fixed station plate along the first direction respectively.

Optionally, the second driving assembly includes a first cylinder and a first cylinder rod that can stretch out or retract back in the first cylinder, the first cylinder is along first direction symmetry sets up the both sides of fixed station board, the one end of first cylinder rod with flexible station board is connected, the height of connecting plate is higher than the second driving assembly.

Optionally, the standing board assembly further comprises a connecting plate, wherein the top end of the connecting plate is used for being supported at the bottom of the telescopic standing board, and the bottom end of the connecting plate is used for being connected with the first cylinder rod.

Optionally, the debugging maintenance platform still include the bottom surface with the backup pad that the expansion bracket is connected, and set up the rail in the backup pad, standing board subassembly with second drive assembly sets up inside the rail, and be supported on the top surface of backup pad.

Optionally, a guide rail extending along the first direction is arranged at the top of the fence, and a guide groove matched with the guide rail is arranged on the telescopic standing board, so that the telescopic standing board can stretch and retract along the guide rail.

Optionally, a first guardrail is fixed to a top edge of the fixed station plate extending along the first direction, a second guardrail is fixed to a top edge of the telescopic station plate extending along a second direction and away from the fixed station plate, and the second direction is perpendicular to the first direction.

Optionally, the expansion bracket comprises a plurality of groups of movable rod groups, each group of movable rod groups is provided with two movable rods with middle cross points hinged with each other and the movable rod groups are constructed into an X-shaped movable rod, and the plurality of groups of movable rod groups are sequentially hinged.

Optionally, the first driving assembly includes the second cylinder and can stretch out or retract in the second cylinder pole of second cylinder, the second cylinder is followed the first direction symmetry sets up the expansion bracket both sides, the one end of second cylinder pole with the movable rod is connected.

Optionally, the debugging maintenance platform further comprises a base for supporting the telescopic frame, and the bottom end of the second cylinder rod is connected with the base.

Optionally, the bottom of the base is provided with wheels, and the wheel outside cover is provided with a wheel frame connected with the base.

Through above-mentioned technical scheme, use the debugging maintenance platform that this disclosure provided, with standing board subassembly bearing to predetermined height through first drive assembly drive expansion bracket, then two flexible standing boards of rethread second drive assembly drive respectively towards stretching out or retracting to predetermined area for the different directions of fixed standing board to change the holding area and the holding range to the staff, and then satisfy debugging maintenance demand. The maintenance platform in the embodiment of the disclosure not only can meet a larger operation range when in use, but also has smaller volume when not in use, so that a larger placing space is not required to be occupied, and the flexibility of use is fully increased.

Additional features and advantages of the present disclosure will be set forth in the detailed description which follows.

Drawings

The accompanying drawings are included to provide a further understanding of the disclosure, and are incorporated in and constitute a part of this specification, illustrate the disclosure and together with the description serve to explain, but do not limit the disclosure. In the drawings:

FIG. 1 is a schematic diagram of a maintenance and debugging platform provided by an exemplary embodiment of the present disclosure;

FIG. 2 is a schematic diagram of a partial structure of a maintenance and debugging platform provided in an exemplary embodiment of the present disclosure;

fig. 3 is a schematic partial structure view of a maintenance and debugging platform according to another exemplary embodiment of the present disclosure.

Description of the reference numerals

10-standing board assembly; 11-a fixed station board; 12-telescoping station plates; 13-connecting plates; 20-telescoping rack; 21-a movable rod group; 21 a-a movable bar; 30-a first drive assembly; 31-a second cylinder; 32-a second cylinder rod; 40-a second drive assembly; 41-a first cylinder; 42-a first cylinder rod; 50-a base; 51-wheels; 52-wheel frame; 61-supporting the plate; 62-fencing; 63-a guide rail; 71-a first rail; 72-second guard rail.

Detailed Description

Specific embodiments of the present disclosure are described in detail below with reference to the accompanying drawings. It should be understood that the detailed description and specific examples, while indicating and illustrating the disclosure, are not intended to limit the disclosure.

In the present disclosure, unless otherwise indicated, terms of orientation such as "inner" and "outer" are used with respect to the outline of the corresponding component itself; the used azimuth words such as "up", "down", "top", "bottom", "horizontal", "vertical", "left" and "right" are defined based on the usage habit of the debugging and maintenance platform provided by the present disclosure, and specifically reference may be made to the direction of the drawing plane shown in fig. 1. The terms such as "first," "second," and the like, as used in this disclosure, are used for distinguishing one element from another and not necessarily for order or importance. Furthermore, the following description, when taken in conjunction with the accompanying drawings, like reference numerals designate the same or similar elements in different drawings.

Referring to fig. 1-3, the present disclosure provides a commissioning repair platform that may include a standing board assembly 10 and a telescoping rack 20, and a first drive assembly 30 and a second drive assembly 40. Wherein, the standing board assembly 10 can include fixed standing board 11 and two flexible standing boards 12, and two flexible standing boards 12 can be along first direction symmetry setting in fixed standing board 11 both sides, and can be respectively along first direction for fixed standing board 11 is flexible to change the support area and the support scope of flexible standing board 12, and then changed the support scope of standing board assembly 10 to the staff, satisfy the user demand. In this embodiment provided in the present disclosure, the first direction may be a left-right direction of the drawing direction shown in fig. 2, and the second direction described below may be an up-down direction of the drawing direction shown in fig. 2. The telescopic frame 20 may be used to be supported at the bottom of the standing board assembly 10 in a vertical direction so that the fixed standing board 11 and the telescopic standing board 12 are far from the ground and have a certain height. The output end of the first driving assembly 30 may be used to be connected with the telescopic frame 20, and the first driving assembly 30 may be configured to be able to drive the telescopic frame 20 to be telescopic in a vertical direction so as to be able to change the supporting heights of the fixed and telescopic standing boards 11 and 12 according to the use requirements, thereby supporting the worker to a predetermined height. The output of the second drive assembly 40 may be adapted to be connected to two telescoping station plates 12, and the second drive assembly 40 may be configured to drive the two telescoping station plates 12 in a first direction relative to the fixed station plate 11, respectively, and also to limit continued telescoping of the telescoping station plates 12 when the telescoping station plates 12 are driven into place, thereby ensuring stability of the telescoping station plates 12 in use and support.

Through above-mentioned technical scheme, use the debugging maintenance platform that this disclosure provided, with the support of standing board subassembly 10 to predetermined height through first drive assembly 30 drive expansion bracket 20, then two piece flexible standing boards 12 of rethread second drive assembly 40 drive respectively towards stretching out or withdraw to predetermined area for fixed standing board 11's different directions to change the holding area and the holding range to the staff, and then satisfy debugging maintenance demand. The maintenance platform in the embodiment of the disclosure not only can meet a larger operation range when in use, but also has smaller volume when not in use, so that a larger placing space is not required to be occupied, and the flexibility of use is fully increased.

Referring to fig. 1 and 3, the second driving assembly 40 may include a first cylinder 41 and a first cylinder rod 42 extendable or retractable within the first cylinder 41, the first cylinder 41 may be symmetrically disposed at both sides of the fixed station plate 11 in a first direction, and one end of the first cylinder rod 42 may be connected with the telescopic station plate 12. According to an embodiment provided by the present disclosure, the protruding directions of the first cylinders 41 disposed at both sides 41 of the fixed station plate 11 may be away from each other. Specifically, in the initial position, the telescopic standing plates 12 and the first cylinder rods 42 provided on both sides of the fixed standing plate 11 are both close to the fixed standing plate 11 and in the contracted state, and when the first cylinder 41 provided on the left side of the fixed standing plate 11 is extended toward the left side, the telescopic standing plate 12 provided on the left side of the fixed standing plate 11 can be driven to extend in the first direction to expand the supporting area. Meanwhile, the first cylinder 41 provided at the right side of the fixed station plate 11 may be maintained at a relative position, and when the telescopic station plate 12 at the left side is extended to a predetermined area, the first cylinder 41 at the left side drives the telescopic station plate 12 at the left side to stop extension. The first air cylinders 41 arranged on the two sides of the fixed standing plate 11 can simultaneously provide support for the standing plate assembly 10, limit the standing plate assembly 10 to be unchanged in the current support area, effectively ensure the support strength and the support stability of the standing plate assembly 10, and enable the debugging and maintenance platform to have stronger reliability. Meanwhile, the telescopic standing plates 12 on two sides of the fixed standing plate 11 are respectively driven to stretch and retract through the two first air cylinders 41, so that the adjusting efficiency of the standing plate assembly 10 can be effectively improved, and the use requirement is further met.

Referring to fig. 1 and 3, the standing board assembly 10 further includes a connection board 13, wherein a top end of the connection board 13 may be used to be supported at a bottom of the telescopic standing board 12, a bottom end may be used to be connected with the first cylinder rod 42, and a height of the connection board 13 may be higher than that of the second driving assembly 40. The height of the connecting plate 13 along the vertical direction can be higher than that of the first cylinder 41, when the maintenance and debugging platform is provided with the supporting plate 61, the connecting plate 13 can be higher than that of the supporting plate 61, so that interference with other parts when the first cylinder rod 42 drives the telescopic standing plate 12 to stretch and retract can be effectively avoided, the telescopic standing plate 12 is prevented from being impacted to other parts to shake, and the stability and safety of the telescopic standing plate 12 in the telescopic process are effectively improved.

Referring to fig. 1 and 3, the debugging and maintenance platform further includes a support plate 61, which may be coupled to the expansion bracket 20 at a bottom surface, and a rail 62 provided on the support plate 61, and the standing board assembly 10 and the second driving assembly 40 may be provided inside the rail 62 and supported on a top surface of the support plate 61. By providing the support plate 61 and the rail 62, the reliability of the installation positions of the second driving assembly 40 and the station board assembly 10 can be effectively improved. According to the embodiment provided by the present disclosure, the supporting plate 61 may have a receiving groove formed on the top surface thereof, and the second driving assembly 40 may be received inside the receiving groove, which may protect the second driving assembly 40, while also making the integrity between the structures stronger. In the embodiment provided in the present disclosure, when the debugging and maintenance platform has the above-mentioned connection plate 13, the height of the connection plate 13 may be not lower than the depth of the accommodation groove, so that the telescopic standing board 12 does not interfere with the edge of the accommodation groove when telescopic. Meanwhile, when the height of the connecting plate 13 is the same as the height of the edge of the accommodating groove, the accommodating groove can also play a supporting role on the telescopic standing plate 12 when the telescopic standing plate 12 moves to the edge of the accommodating groove, so that the stability of the supporting of the telescopic standing plate 12 is ensured.

Referring to fig. 1, the rail 62 may be formed by sequentially connecting a plurality of connecting rods, the top of the rail 62 may be provided with a guide rail 63 extending along a first direction, the guide rail 63 may be fixed on a connecting rod having a height along a vertical direction matched with a height of the telescopic standing board 12, and the telescopic standing board 12 may be provided with a guide groove matched with the guide rail 63, so that the telescopic standing board 12 may stretch along the guide rail 63, thereby ensuring that the telescopic standing board 12 may find an offset when stretching along the first direction, effectively defining a telescopic track of the telescopic standing board 12, and ensuring stability of a telescopic process of the telescopic standing board.

Referring to fig. 1 and 2, the top edge of the fixed station plate 11 extending along the first direction may be fixed with a first guard rail 71, which may protect a worker, and improve safety, and the extending length of the first guard rail 71 along the first direction may be not less than the length of the telescopic station plate 12 at two sides of the fixed station plate 11 when the telescopic station plate 12 extends completely, so that the telescopic station plate 12 may also protect the worker to a certain extent during the moving process, and further improve safety and reliability of the station plate assembly 10. The top edge of the telescopic standing board 12 extending along the second direction and far away from the fixed standing board 11 may be fixed with the second guard rail 72, so that the second guard rail 72 can move along with the telescopic standing board 12 in the moving process of the telescopic standing board 12, so as to play a role in protecting staff. The second direction in this disclosure can be perpendicular to first direction, through set up the guardrail respectively in first direction and second direction, can play diversified protection to the staff. In addition, first guardrails 71 may be provided at both sides of the second direction of the fixed station plate 11, and second guardrails 72 may be provided at both sides of the first direction, so that a closed protection structure can be formed by the two first guardrails 71 and the two second guardrails 72, so that the safety of the debugging and maintenance platform is effectively enhanced. In addition, the specific heights of the first rail 71 and the second rail 72 are not limited in the present disclosure, and may be sufficient for safety.

Referring to fig. 1, the expansion bracket 20 may include a plurality of movable rod groups 21, each movable rod group 21 may have two movable rods 21a with middle crossing points hinged to each other and having the movable rod groups 21 constructed as an X-type, so that stability of support of the movable rod groups 21 may be ensured, the supporting height of the movable rod groups 21 may be changed by driving the two movable rods 21a to rotate to change the included angle of the X-type, and simultaneously, the plurality of movable rod groups 21 may be sequentially hinged, the overall height of the expansion bracket 20 may be changed by changing the supporting height of the one movable rod group 21, so that expansion efficiency of the expansion bracket 20 is improved, and the two movable rod groups 21 close to each other may be mutually supported, so that the expansion bracket 20 has stronger reliability.

Referring to fig. 1, the first driving assembly 30 may include a second cylinder 31 and a second cylinder rod 32 that may extend or retract from the second cylinder 31, the second cylinder 31 may be symmetrically disposed at two sides of the expansion bracket 20 along the first direction, and one end of the second cylinder rod 32 is connected with the movable rod 21a, so that the movable rod 21a may be pushed to rotate by the expansion of the second cylinder rod 32, thereby changing an included angle of the X-shaped movable rod group 21, and further expanding and contracting the entire expansion bracket 20, so as to ensure expansion and contraction switching efficiency of the expansion bracket 20. Meanwhile, when the current position of the second cylinder rod 32 is kept unchanged, the telescopic frame 20 can be supported and limited, and the telescopic frame 20 is prevented from telescoping again when being debugged at a preset position, so that the debugging and maintenance platform has stronger reliability.

Referring to fig. 1, the debugging and maintenance platform further includes a base 50 for supporting the expansion bracket 20, and the bottom end of the second cylinder rod 32 is connected with the base 50, so that stability of the installation position of the second cylinder rod 32 and the overall effect of the debugging and maintenance platform are effectively improved, and according to some embodiments provided by the present disclosure, the bottom end of the second cylinder rod 32 may be hinged with the base 50, so that the second cylinder rod 32 may rotate, and further the supporting range is enlarged.

Referring to fig. 1, wheels 51 may be provided at the bottom of the base 50, so that the entire debugging and maintenance platform may be conveniently moved, thereby achieving the effects of improving movement efficiency and saving power. The wheel 51 can be provided with the wheel frame 52 connected with the base 50 in an outside cover manner, and the wheel frame 52 can play a role in protecting the wheel 51, so that the stability of the debugging and maintenance platform in the moving process is effectively ensured, and meanwhile, the service life of the wheel 51 is prolonged.

The preferred embodiments of the present disclosure have been described in detail above with reference to the accompanying drawings, but the present disclosure is not limited to the specific details of the above embodiments, and various simple modifications may be made to the technical solutions of the present disclosure within the scope of the technical concept of the present disclosure, and all the simple modifications belong to the protection scope of the present disclosure.

In addition, the specific features described in the foregoing embodiments may be combined in any suitable manner, and in order to avoid unnecessary repetition, the present disclosure does not further describe various possible combinations.

Moreover, any combination between the various embodiments of the present disclosure is possible as long as it does not depart from the spirit of the present disclosure, which should also be construed as the disclosure of the present disclosure.

Claims

1. A commissioning repair platform, the commissioning repair platform comprising:

2. The debugging and repairing platform according to claim 1, wherein the second driving assembly comprises a first cylinder and a first cylinder rod which can extend or retract in the first cylinder, the first cylinder is symmetrically arranged on two sides of the fixed station plate along the first direction, and one end of the first cylinder rod is connected with the telescopic station plate.

3. The commissioning and repair platform of claim 2, wherein the standing board assembly further comprises a connection board, a top end of the connection board being for supporting on a bottom of the telescoping standing board, a bottom end of the connection board being for connection with the first cylinder rod, a height of the connection board being higher than the second drive assembly.

4. The debugging and maintenance platform of claim 1 further comprising a support plate having a bottom surface connected to the telescoping rack and a rail disposed on the support plate, the standing board assembly and the second drive assembly being disposed within the rail and supported on the top surface of the support plate.

5. The debugging and maintenance platform of claim 4 wherein the top of the rail is provided with a guide rail extending in the first direction and the telescoping station plate is provided with a guide slot that mates with the guide rail to enable telescoping of the telescoping station plate along the guide rail.

6. The debugging and maintenance platform of claim 1 wherein a first guardrail is secured to a top edge of the fixed station plate extending in the first direction and a second guardrail is secured to a top edge of the telescoping station plate extending in a second direction and away from the fixed station plate, the second direction being perpendicular to the first direction.

7. The debugging and repairing platform according to claim 1, wherein the telescopic frame comprises a plurality of movable rod groups, each movable rod group is provided with two movable rods with middle crossing points hinged to each other and configured into an X-shaped structure, and the movable rod groups are sequentially hinged.

8. The debugging and repairing platform according to claim 7, wherein the first driving assembly comprises a second cylinder and a second cylinder rod which can extend or retract in the second cylinder, the second cylinder is symmetrically arranged on two sides of the telescopic frame along the first direction, and one end of the second cylinder rod is connected with the movable rod.

9. The commissioning repair platform of claim 8, further comprising a base for supporting the telescoping shelf, the bottom end of the second cylinder rod being connected to the base.

10. The debugging and maintenance platform of claim 9 wherein the base bottom is provided with wheels and the wheel outer cover is provided with a wheel frame connected to the base.