CN220139049U - Explosion-proof type high-voltage board - Google Patents

Abstract

The utility model discloses an explosion-proof high-voltage cabinet which comprises a base, two explosion-proof supports and a high-voltage cabinet, wherein the top of the base is tightly contacted with the bottoms of the two explosion-proof supports, and the tops of the two explosion-proof supports are fixedly connected with the bottom of the high-voltage cabinet. According to the explosion-proof high-voltage cabinet, the base, the explosion-proof support, the high-voltage cabinet, the fixing blocks, the protruding blocks, the cavity, the connecting components and other structural components are arranged, through the use of the connecting components in the cavity, the two connecting blocks can move into the two protruding blocks, so that the base and the explosion-proof support are fixed, through the cooperation of the pushing components and the connecting components, the two connecting blocks can move out of the two protruding blocks, the explosion-proof support and the base can be separated, and the explosion-proof high-voltage cabinet has the advantage of being capable of quickly disassembling and assembling the explosion-proof high-voltage cabinet.

Description

Explosion-proof type high-voltage board

Technical Field

The utility model belongs to the technical field of explosion-proof high-voltage cabinets, and particularly relates to an explosion-proof high-voltage cabinet.

Background

The high-voltage cabinet is used for generating, transmitting, distributing, converting electric energy and consuming in an electric power system and plays roles of on-off, control or protection, the explosion-proof high-voltage cabinet is a type of high-voltage cabinet with explosion-proof performance, combustible substances are isolated from an ignition source, the purpose of explosion prevention is achieved, in order to enable the use effect of the explosion-proof high-voltage cabinet to be better, an explosion-proof support is arranged at the bottom, the explosion-proof high-voltage cabinet is fixed on the ground or other supporting pieces through the explosion-proof support, a plurality of bolts are required to be screwed by a user through a special tool in the existing installation mode, so that the explosion-proof high-voltage cabinet is fixed, the installation of the bolts is complicated, the explosion-proof high-voltage cabinet is not rapid, and time is consumed, the problems in the prior art are that: the explosion-proof high-voltage cabinet cannot be quickly assembled and disassembled on the ground or other supporting pieces, so that the explosion-proof high-voltage cabinet is provided for solving the problems.

Disclosure of Invention

Aiming at the problems existing in the prior art, the utility model provides an explosion-proof high-voltage cabinet, which has the advantage of being capable of quickly disassembling and assembling the explosion-proof high-voltage cabinet, and solves the problem that the explosion-proof high-voltage cabinet cannot be quickly disassembled and assembled with the ground or other supporting pieces.

The utility model discloses an explosion-proof high-voltage cabinet, which comprises a base, two explosion-proof supports and a high-voltage cabinet, wherein the top of the base is tightly contacted with the bottoms of the two explosion-proof supports, the tops of the two explosion-proof supports are fixedly connected with the bottoms of the high-voltage cabinet, the front side and the rear side of the top of the explosion-proof support are fixedly connected with fixed blocks, the front side and the rear side of the inside of the explosion-proof support are respectively connected with two convex blocks in an inserting way, the bottoms of the two convex blocks are fixedly connected with the top of the base, a cavity is formed in the inside of the fixed block at the front side, and a connecting component and a pushing component are respectively arranged in the cavity.

As the preferred connecting assembly of the utility model, the connecting assembly comprises two connecting blocks, the surfaces of the two connecting blocks are movably connected with the inside of the cavity, the opposite ends of the two connecting blocks are fixedly connected with extrusion springs, the front sides of the inside of the two connecting blocks are respectively provided with a movable hole, the two connecting blocks can move to the inside of the two convex blocks through the cavity by arranging the connecting assembly, and the two connecting blocks can automatically rebound to the original position after moving through the use of the extrusion springs.

As the preferred push assembly of the utility model, the push assembly comprises two pull rods, the surfaces of the two pull rods are movably connected with the inside of the cavity, the front sides of the two pull rods are fixedly connected with elastic springs, the opposite ends of the tops of the two pull rods are movably connected with short rods, one side opposite to the two short rods is movably connected with a rotating rod, the front sides of the bottoms of the two rotating rods are rotatably connected with supporting blocks, the front sides of the two supporting blocks are fixedly connected with the front sides of the inner walls of the cavity, the two connecting blocks can be moved out from the inside of the two convex blocks through the push assembly, and the two pull rods, the two short rods and the two rotating rods can be automatically rebounded to the original position after moving through the use of the two elastic springs.

As the preferable mode of the utility model, the surfaces of the opposite sides of the two connecting blocks are respectively and movably connected with a control block, one side of the two control blocks, which is close to the inner wall of the cavity, is fixedly connected with the cavity, and the two connecting blocks can only move leftwards or rightwards through the two control blocks in the cavity by arranging the two control blocks.

As the preferable mode of the utility model, the two pull rods are internally and slidably connected with the L-shaped blocks, one sides of the two L-shaped blocks, which are close to the inner wall of the cavity, are fixedly connected with the cavity, and the two pull rods can only move forwards or backwards in the cavity through the two L-shaped blocks by arranging the two L-shaped blocks.

As the utility model, the opposite sides of the two connecting blocks sequentially penetrate through the fixing block and the two convex blocks through the cavity and extend to the interiors of the two convex blocks, and the two connecting blocks are arranged to move from the interiors of the cavity to the interiors of the two convex blocks, so that the explosion-proof bracket and the base are fixed.

As the utility model is preferable, the surfaces of the two connecting blocks are respectively in close contact with the fixing blocks and the interiors of the two convex blocks, and the two connecting blocks are arranged, so that the fixing effect of the base and the explosion-proof bracket is better, and the looseness of the joint of the explosion-proof bracket and the base is avoided.

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

1. according to the utility model, through arranging the base, the explosion-proof support, the high-voltage cabinet, the fixing blocks, the protruding blocks, the cavity, the connecting assembly and other structural components, the two connecting blocks can move to the inside of the two protruding blocks through the use of the connecting assembly in the cavity, so that the base and the explosion-proof support are fixed, and the two connecting blocks can move out of the inside of the two protruding blocks through the cooperation of the pushing assembly and the connecting assembly, so that the explosion-proof support and the base can be separated, and the explosion-proof high-voltage cabinet can be quickly disassembled.

2. According to the utility model, through arranging structural components such as the base, the explosion-proof support, the high-voltage cabinet, the fixing block, the protruding blocks, the cavity, the connecting component and the like, when the explosion-proof support is required to be separated from the base, the two pull rods are pushed to move forwards by manpower and move forwards by the two short rods, the two short rods can rotate in the moving process, so that the rear sides of the two rotating rods move towards opposite ends through the two supporting blocks, the two connecting blocks move towards opposite ends and move out of the two protruding blocks, the high-voltage cabinet can be moved upwards and the explosion-proof support can be moved upwards, the separation of the explosion-proof support and the base is realized, the two elastic springs can generate a deformation force in the moving process, after the two pull rods are loosened, the two elastic springs can give the same force to the two pull rods, the two short rods and the two rotating rods are driven to rebound to the original positions, the two connecting blocks can generate a deformation force in the moving process, and after the two connecting blocks are loosened, the two elastic springs can give the same force to the two connecting blocks, and the two explosion-proof support can be fixed to the base.

Drawings

FIG. 1 is a schematic diagram of a structure provided by an embodiment of the present utility model;

FIG. 2 is a perspective view of a base and explosion-proof bracket separated according to an embodiment of the present utility model;

FIG. 3 is an enlarged view of FIG. 2A provided by an embodiment of the present utility model;

FIG. 4 is a top cross-sectional view of a securing block provided by an embodiment of the present utility model;

fig. 5 is a detailed perspective view of a partial structure provided by an embodiment of the present utility model.

In the figure: 1. a base; 2. an explosion-proof bracket; 3. a high-voltage cabinet; 4. a fixed block; 5. a bump; 6. a cavity; 7. a connection assembly; 701. a connecting block; 702. extruding a spring; 703. a movable hole; 8. a pushing assembly; 801. a pull rod; 802. an elastic spring; 803. a short bar; 804. a rotating rod; 805. a support block; 9. a control block; 10. l-shaped block.

Detailed Description

For a further understanding of the utility model, its features and advantages, reference is now made to the following examples, which are illustrated in the accompanying drawings.

The structure of the present utility model will be described in detail with reference to the accompanying drawings.

As shown in fig. 1 to 5, the explosion-proof high-voltage cabinet provided by the embodiment of the utility model comprises a base 1, explosion-proof brackets 2, a high-voltage cabinet 3, a fixed block 4, a protruding block 5, a cavity 6, a connecting component 7, a connecting block 701, an extrusion spring 702, a movable hole 703, a pushing component 8, a pull rod 801, an elastic spring 802, a short rod 803, a rotating rod 804, a supporting block 805, a control block 9 and an L-shaped block 10, wherein the top of the base 1 is tightly contacted with the bottoms of the two explosion-proof brackets 2, the tops of the two explosion-proof brackets 2 are fixedly connected with the bottom of the high-voltage cabinet 3, the front side and the rear side of the top of the left explosion-proof bracket 2 are fixedly connected with the fixed block 4, the front side and the rear side of the inside of the explosion-proof bracket 2 are respectively connected with the two protruding blocks 5, the bottoms of the two protruding blocks 5 are fixedly connected with the top of the base 1, the cavity 6 is formed in the front side of the fixed block 4, and the inside of the cavity 6 is respectively provided with the connecting component 7 and the pushing component 8.

Referring to fig. 4, the connection assembly 7 includes two connection blocks 701, the surfaces of the two connection blocks 701 are movably connected with the inside of the cavity 6, the opposite ends of the two connection blocks 701 are fixedly connected with extrusion springs 702, and movable holes 703 are formed in the front sides of the inside of the two connection blocks 701.

The scheme is adopted: by providing the connection assembly 7, the two connection blocks 701 can be moved to the inside of the two bumps 5 through the cavity 6, and the use of the pressing spring 702 can enable the two connection blocks 701 to automatically rebound to the original position after being moved.

Referring to fig. 4, the pushing component 8 includes two pull rods 801, the surfaces of the two pull rods 801 are movably connected with the inside of the cavity 6, the front sides of the two pull rods 801 are fixedly connected with elastic springs 802, opposite ends of the tops of the two pull rods 801 are movably connected with short rods 803, opposite sides of the two short rods 803 are movably connected with rotating rods 804, front sides of bottoms of the two rotating rods 804 are rotatably connected with supporting blocks 805, and the front sides of the two supporting blocks 805 are fixedly connected with the front sides of the inner walls of the cavity 6.

The scheme is adopted: by providing the pushing assembly 8, the two connection blocks 701 can be moved out of the two bumps 5, and the two tension rods 801, the two short rods 803 and the two rotating rods 804 can be automatically rebounded to the original positions after being moved by the two elastic springs 802.

Referring to fig. 4 and 5, the surfaces of opposite sides of the two connecting blocks 701 are respectively and movably connected with a control block 9, and one side of the two control blocks 9 close to the inner wall of the cavity 6 is fixedly connected with the cavity 6.

The scheme is adopted: by providing two control blocks 9, the two connection blocks 701 can be moved only in the left or right direction inside the cavity 6 by the two control blocks 9.

Referring to fig. 4 and 5, the two tie rods 801 are slidably connected with L-shaped blocks 10, and one sides of the two L-shaped blocks 10, which are close to the inner wall of the cavity 6, are fixedly connected with the cavity 6.

The scheme is adopted: by providing two L-shaped blocks 10, the two tie rods 801 can be moved only in the forward or backward direction inside the cavity 6 by passing through the two L-shaped blocks 10.

Referring to fig. 1, opposite sides of the two connection blocks 701 sequentially penetrate the fixing block 4 and the two protrusions 5 through the cavity 6 and extend to the inside of the two protrusions 5.

The scheme is adopted: by providing two connection blocks 701, the explosion-proof bracket 2 is fixed to the base 1 by moving from the inside of the cavity 6 to the inside of the two projections 5.

Referring to fig. 1, the surfaces of the two connection blocks 701 are in close contact with the interiors of the fixing block 4 and the two protrusions 5, respectively.

The scheme is adopted: through setting up two connecting blocks 701, make the fixed effect of base 1 and explosion-proof support 2 better, avoid explosion-proof support 2 and the junction of base 1 to appear not hard up.

The working principle of the utility model is as follows:

when the explosion-proof support 2 is required to be separated from the base 1 in use, the two pull rods 801 are pushed by manpower to move forward and the two short rods 803 are pushed to move forward, the two short rods 803 can rotate the two rotating rods 804 in the moving process, so that the rear sides of the two rotating rods 804 move towards opposite ends through the two supporting blocks 805, the two connecting blocks 701 move towards opposite ends and move out of the two convex blocks 5, the high-voltage cabinet 3 can be enabled to move upwards and the explosion-proof support 2 is enabled to move upwards, separation of the explosion-proof support 2 from the base 1 is achieved, the two pull rods 801 can enable the two elastic springs 802 to generate deformation force in the moving process, after the two pull rods 801 are released, the two elastic springs 802 can enable the two pull rods 801 to drive the two short rods 803 and the two rotating rods 804 to rebound to be in situ, the two connecting blocks 701 can enable the two connecting springs 702 to generate deformation force in the moving process, after the two pull rods 801 are released, the two elastic springs 702 can enable the two elastic springs 702 to be enabled to enable the two connecting blocks to be enabled to generate the same deformation force, and the two connecting blocks 701 to rebound to be enabled to be fixed to the inside the base 1.

To sum up: this explosion-proof type high-voltage board through setting up base 1, explosion-proof support 2, high-voltage board 3, fixed block 4, lug 5, cavity 6, coupling assembling 7, connecting block 701, extrusion spring 702, movable hole 703, pushing component 8, pull rod 801, elasticity spring 802, quarter butt 803, bull stick 804, supporting shoe 805, control block 9 and L shape piece 10's cooperation use, has solved the problem that current can not be with the explosion-proof type high-voltage board with fixed or other supports on the ground carry out the dismouting fast.

It is noted that relational terms such as first and second, and the like are used solely to distinguish one entity or action from another entity or action without necessarily requiring or implying any actual such relationship or order between such entities or actions. Moreover, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus.

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 (7)

1. The utility model provides an explosion-proof type high-voltage board, includes base (1), two explosion-proof supports (2) and high-voltage board (3), the top of base (1) and the bottom in close contact of two explosion-proof supports (2), the bottom fixed connection of two explosion-proof supports (2) top and high-voltage board (3), its characterized in that: the left side both sides all fixedly connected with fixed block (4) around explosion-proof support (2) top, the inside front and back both sides of explosion-proof support (2) are all pegged graft and are connected with two lug (5), the bottom of two lug (5) all with the top fixed connection of base (1), the front side cavity (6) have been seted up to the inside of fixed block (4), the inside of cavity (6) is provided with coupling assembling (7) and pushing component (8) respectively.

2. An explosion-proof high-voltage board according to claim 1, wherein: the connecting assembly (7) comprises two connecting blocks (701), the surfaces of the two connecting blocks (701) are movably connected with the inside of the cavity (6), the opposite ends of the two connecting blocks (701) are fixedly connected with extrusion springs (702), and movable holes (703) are formed in the front sides of the inside of the two connecting blocks (701).

3. An explosion-proof high-voltage board according to claim 2, wherein: the pushing assembly (8) comprises two pull rods (801), the surfaces of the two pull rods (801) are movably connected with the inside of the cavity (6), elastic springs (802) are fixedly connected to the front sides of the two pull rods (801), short rods (803) are movably connected to the opposite ends of the tops of the two pull rods (801), rotating rods (804) are movably connected to the opposite sides of the two short rods (803), supporting blocks (805) are rotatably connected to the front sides of the bottoms of the two rotating rods (804), and the front sides of the two supporting blocks (805) are fixedly connected with the front sides of the inner walls of the cavity (6).

4. An explosion-proof high-voltage board according to claim 2, wherein: the surfaces of the opposite sides of the two connecting blocks (701) are respectively and movably connected with a control block (9), and one side of the two control blocks (9) close to the inner wall of the cavity (6) is fixedly connected with the cavity (6).

5. An explosion-proof high-voltage board according to claim 3, wherein: the inside of two pull rods (801) is connected with an L-shaped block (10) in a sliding way, and one side, close to the inner wall of the cavity (6), of the two L-shaped blocks (10) is fixedly connected with the cavity (6).

6. An explosion-proof high-voltage board according to claim 2, wherein: opposite sides of the two connecting blocks (701) sequentially penetrate through the fixing block (4) and the two protruding blocks (5) through the cavity (6) and extend to the inner parts of the two protruding blocks (5).

7. An explosion-proof high-voltage board according to claim 2, wherein: the surfaces of the two connecting blocks (701) are respectively in close contact with the interiors of the fixed block (4) and the two convex blocks (5).