CN219106800U - High-voltage power distribution cabinet with insulating platform at bottom - Google Patents

Abstract

The utility model discloses a high-voltage power distribution cabinet with an insulating platform at the bottom, which comprises a high-voltage power distribution cabinet, wherein an insulating device is inserted in the side surface of the bottom end of the high-voltage power distribution cabinet in a sliding manner, an insulating plate is fixedly arranged in the insulating device, clamping grooves are symmetrically formed in the edges of the upper surfaces of two ends of the insulating plate, a plug-in block is fixedly connected to the inner center of each clamping groove, first connecting ropes are fixedly connected to the inner surfaces of the edges of the two ends of each clamping groove, connecting columns are fixedly connected to the top ends of the first connecting ropes, grooves are formed in the outer surfaces of the edges of the two ends of each connecting column, and a connecting plate is fixedly connected to one end surface of each connecting column. According to the utility model, the insulating device is arranged at the bottom of the high-voltage power distribution cabinet, so that an insulating effect can be achieved between the feet of the staff and the ground, and electric shock accidents are prevented when the staff overhauls the inside of the high-voltage power distribution cabinet.

Description

High-voltage power distribution cabinet with insulating platform at bottom

Technical Field

The utility model relates to the technical field of high-voltage power distribution cabinet equipment, in particular to a high-voltage power distribution cabinet with an insulating platform at the bottom.

Background

The high-voltage power distribution cabinet is used for performing on-off, control or protection in power generation, power transmission, power distribution, electric energy conversion and consumption of a power system, so that normal operation of a circuit is guaranteed, the circuit can be well controlled and managed in a centralized manner, but the existing high-voltage power distribution cabinet has some defects in the use process, such as: the existing high-voltage power distribution cabinet is inconvenient to play an insulating role between the feet of a worker and the ground when in use, so that the worker can easily generate an electric shock accident when overhauling the high-voltage power distribution cabinet, and the high-voltage power distribution cabinet with the insulating platform at the bottom is needed to solve the problem set forth in the above.

Disclosure of Invention

The utility model aims to provide a high-voltage power distribution cabinet with an insulating platform at the bottom, which solves the problems in the background art.

In order to achieve the above purpose, the present utility model provides the following technical solutions: the utility model provides a high-voltage distribution cabinet that bottom has insulating platform, includes the high-voltage distribution cabinet, inside slip grafting of bottom side of high-voltage distribution cabinet has insulating device, insulating device's inside fixed mounting has the insulation board, the joint groove has been seted up to the both ends upper surface edge symmetry of insulation board, the inside center fixedly connected with grafting piece of joint groove, the equal fixedly connected with of both ends edge internal surface of joint groove is first connecting rope, the top fixedly connected with spliced pole of first connecting rope, the recess has all been seted up to the both ends edge surface of spliced pole, an end fixedly connected with connecting plate of spliced pole, the spacing strut of both ends edge surface symmetry fixedly connected with of connecting plate, the grafting groove has been seted up at the middle part bottom surface center of spliced pole, the one end edge surface sliding joint of spliced pole has the stopper, the one end side fixedly connected with second connecting rope of stopper, the one end fixedly connected with reference column of second connecting rope, the one end surface symmetry slip grafting of reference column has the spacing guide pillar, the surface of spacing strut has the surface fixedly connected with spliced pole, the tight spring of side of inner fixed mounting limit post of side edge.

Preferably, the limit slide way is offered at the side bottom center of high-voltage distribution cabinet, one side both ends edge symmetry fixedly connected with extrusion post of limit slide way, the spliced pole is through the stopper of one end surface and the one end contact extrusion of extrusion post.

Preferably, the insulating board is in sliding connection with the bottom of the side face of the high-voltage power distribution cabinet through a limiting slideway.

Preferably, the connecting column is clamped with the upper surfaces of the two ends of the insulating plate through the clamping groove, and the top outer surface of the plug-in block is arranged in a wedge shape.

Preferably, the clamping groove is in sliding connection with the inside of the inserting groove through an inserting block on the inner surface, and the positioning column is in sliding connection with the side center of the inserting block at the side center of the inserting groove.

Preferably, the connecting plate is in sliding clamping connection with a limiting slide way at the bottom of the side surface of the high-voltage power distribution cabinet through limiting slide posts on the outer surfaces of the two ends.

Compared with the prior art, the utility model has the following beneficial effects:

according to the utility model, the first connecting rope is connected between the insulating plate and the connecting column, so that the insulating plate and the connecting column can be prevented from being completely separated, and meanwhile, the insulating plate can be clamped with the outer surface of the connecting column through the clamping groove, so that the connecting column is clamped with the two ends of the insulating plate in an anastomotic way, the second connecting rope is limited by the limiting column, the positioning column is ensured to receive horizontal traction force, and meanwhile, the stable transverse reciprocating sliding of the positioning column is ensured.

According to the utility model, the insulating device is arranged at the bottom of the high-voltage power distribution cabinet, so that an insulating effect can be achieved between the feet of the staff and the ground, and electric shock accidents are prevented when the staff overhauls the inside of the high-voltage power distribution cabinet.

Drawings

FIG. 1 is a schematic diagram of the main structure of the present utility model;

FIG. 2 is a main body development schematic of the present utility model;

FIG. 3 is a schematic view of an insulation device according to the present utility model;

fig. 4 is an enlarged partial schematic view at a of the present utility model.

In the figure: the high-voltage power distribution cabinet comprises a 1-high-voltage power distribution cabinet, a 2-insulating device, a 3-clamping groove, a 4-connecting column, a 5-groove, a 6-connecting plate, a 7-limiting sliding column, an 8-limiting block, a 9-first connecting rope, a 10-inserting block, an 11-insulating plate, a 12-limiting guide column, a 13-second connecting rope, a 14-limiting column, a 15-inserting groove, a 16-positioning column and a 17-tensioning spring.

Detailed Description

The following description of the embodiments of the present utility model will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present utility model, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the utility model without making any inventive effort, are intended to be within the scope of the utility model.

Referring to fig. 1-4, an embodiment of the present utility model is provided: the utility model provides a high-voltage distribution cabinet with insulating platform in bottom, including high-voltage distribution cabinet 1, the inside slip grafting of bottom side of high-voltage distribution cabinet 1 has insulating device 2, insulating device 2's inside fixed mounting has insulation board 11, joint groove 3 has been seted up to insulation board 11's both ends upper surface edge symmetry, joint groove 3's inside center fixedly connected with grafting piece 10, joint groove 3's both ends edge internal surface all fixedly connected with first connecting rope 9, the top fixedly connected with spliced pole 4 of first connecting rope 9, recess 5 has all been seted up to spliced pole 4's both ends edge surface, spliced pole 4's an end fixedly connected with connecting plate 6, spliced groove 15 has been seted up at spliced pole 4's middle part bottom surface center, spliced pole 4's one end edge surface slip joint has stopper 8, stopper 8's one end side fixedly connected with second connecting rope 13, second connecting rope 13's one end fixedly connected with reference column 16, the one end surface symmetry slip grafting of reference column 16 has spacing guide pillar 12, spacing guide pillar 12's surface has cup jointed tight spring 17's of rising, center connection spring 17 one side fixedly installed spacing post 14.

Limiting slide ways are arranged at the centers of the bottoms of the side faces of the high-voltage power distribution cabinet 1, the edges of two ends of one side of each limiting slide way are symmetrically and fixedly connected with extrusion columns, and the connecting columns 4 are extruded in contact with one ends of the extrusion columns through limiting blocks 8 on the outer surfaces of one ends, so that the insulating plates 11 can be automatically separated from the connecting columns 4.

The insulating board 11 is in sliding connection with the bottom of the side face of the high-voltage power distribution cabinet 1 through the limiting slide way, so that the high-voltage power distribution cabinet 1 can conveniently store the insulating board 11.

The connecting column 4 is clamped with the upper surfaces of the two ends of the insulating plate 11 through the clamping groove 3, the top outer surface of the plug block 10 is arranged in a wedge shape, and the plug block 10 can squeeze and retract one end of the positioning column 16.

The clamping groove 3 is in sliding connection with the inside of the inserting groove 15 through the inserting block 10 on the inner surface, so that the insulating plate 11 is connected with the connecting column 4 conveniently, the positioning column 16 is in sliding connection with the side center of the inserting block 10 at the side center of the inserting groove 15, and the insulating plate 11 and the connecting column 4 can be connected into a whole.

The connecting plate 6 is in sliding clamping connection with a limiting slide way at the bottom of the side surface of the high-voltage power distribution cabinet 1 through limiting slide posts 7 on the outer surfaces of the two ends, so that the connecting plate 6 can be prevented from sliding off the inside of the bottom end of the high-voltage power distribution cabinet 1.

Working principle: before a worker overhauls the inside of the high-voltage power distribution cabinet 1, the side end center of the insulating plate 11 is pulled firstly, so that the insulating plate 11 drives the connecting plate 6 to synchronously slide transversely in the limiting slide way, the connecting plate 6 drives the connecting columns 4 at two ends to synchronously slide transversely, the connecting columns 4 drive the limiting blocks 8 at the outer surface of one end edge to slide in the limiting slide way until one end side surface of the limiting blocks 8 contacts with the extrusion columns in the limiting slide way, the extrusion columns extrude the limiting blocks 8 to slide on the outer surface of the connecting columns 4, the limiting blocks 8 drive the positioning columns 16 at one end to retract and slide through the second connecting ropes 13 while sliding transversely, one end of the positioning columns 16 is separated from the side surface center of the inserting blocks 10, the inserting blocks 10 extrude the tensioning springs 17 at one end to shrink on the outer surface of the limiting guide columns 12, meanwhile, the insulating plate 11 drives the plug-in block 10 to be separated from the interior of the plug-in groove 15 under the action of gravity until the bottom surface of the insulating plate 11 is contacted with the bottom surface, then a worker can open a cabinet door of the high-voltage power distribution cabinet 1, the worker can stand on the upper surface of the insulating plate 11 to repair the interior of the high-voltage power distribution cabinet 1, when the worker stands on the upper surface of the insulating plate 11, the ground corresponds to a zero line, only when a live wire is connected with the zero line, current is generated, an electric shock accident can occur, the worker stands on the insulating body and corresponds to disconnection of the live wire and the zero line, the worker cannot generate the electric shock accident, then when the maintenance of the high-voltage power distribution cabinet 1 is completed, the worker pulls the insulating plate 11 to ascend, and simultaneously plugs the plug-in block 10 in the clamping groove 3 into the plug-in groove 15, meanwhile, the top of the plug-in block 10 can extrude one end of the positioning column 16 to transversely slide until one end of the positioning column 16 is aligned with the center of the side face of the plug-in block 10, the positioning column 16 can be plugged in with the plug-in block 10 under the pushing of the tensioning spring 17, two ends of the insulating plate 11 are connected with the connecting column 4, and the center of the side face of the insulating plate 11 is pushed to retract completely towards the bottom of the side face of the high-voltage power distribution cabinet 1, so that an insulating effect can be achieved between the feet of a worker and the ground through the insulating device 2 installed at the bottom of the high-voltage power distribution cabinet 1, and electric shock accidents are prevented from occurring when the worker overhauls the inside of the high-voltage power distribution cabinet 1.

Although embodiments of the present utility model have been shown and described, it will be understood by those skilled in the art that various changes, modifications, substitutions and alterations can be made therein without departing from the principles and spirit of the utility model, the scope of which is defined in the appended claims and their equivalents.

Claims (6)

1. The utility model provides a high-voltage distribution cabinet that bottom has insulating platform, includes high-voltage distribution cabinet (1), its characterized in that: the utility model discloses a high-voltage distribution cabinet, including insulating device (2) is pegged graft in inside slip of bottom side of high-voltage distribution cabinet (1), insulating device (2)'s inside fixed mounting has insulation board (11), joint groove (3) have been seted up to insulation board (11) both ends upper surface edge symmetry, joint groove (3) inside center fixedly connected with grafting piece (10), first connecting rope (9) of equal fixedly connected with in both ends edge internal surface of joint groove (3), the top fixedly connected with spliced pole (4) of first connecting rope (9), recess (5) have all been seted up at spliced pole (4)'s both ends edge surface, spliced pole (4) one end fixedly connected with connecting plate (6), spliced groove (15) have been seted up at spliced pole (4) middle part bottom surface center, spliced pole (4) one end edge surface slip joint has stopper (8), second connecting rope (13) are connected with to stopper (8) one end side fixedly connected with second connecting rope (13), second connecting rope (16) one end surface fixedly connected with spacing slide column (7) of spliced pole (16), peg-shaped positioning spring (12), and a limit column (14) is fixedly arranged at the edge of one side of the inner center of the connecting column (4).

2. The high voltage power distribution cabinet with an insulating platform at the bottom according to claim 1, wherein: limiting slide ways are arranged in the center of the bottom of the side face of the high-voltage power distribution cabinet (1), extrusion columns are symmetrically and fixedly connected to edges of two ends of one side of each limiting slide way, and the connecting columns (4) are in contact extrusion with one ends of the extrusion columns through limiting blocks (8) on the outer surface of one end.

3. The high voltage power distribution cabinet with an insulating platform at the bottom according to claim 2, wherein: the insulating plate (11) is in sliding connection with the bottom of the side face of the high-voltage power distribution cabinet (1) through a limiting slideway.

4. A high voltage power distribution cabinet with insulating platform at bottom according to claim 3, characterized in that: the connecting column (4) is clamped with the upper surfaces of the two ends of the insulating plate (11) through the clamping groove (3), and the top outer surface of the plug-in block (10) is arranged in a wedge shape.

5. The high voltage power distribution cabinet with an insulating platform at the bottom according to claim 4, wherein: the clamping groove (3) is in sliding connection with the inside of the inserting groove (15) through the inserting block (10) on the inner surface, and the positioning column (16) is in sliding connection with the side center of the inserting block (10) at the side center of the inserting groove (15).

6. The high-voltage power distribution cabinet with an insulating platform at the bottom according to claim 5, wherein: the connecting plates (6) are in sliding clamping connection with limiting slide ways at the bottoms of the side faces of the high-voltage power distribution cabinet (1) through limiting slide columns (7) on the outer surfaces of the two ends.

Images