CN211377308U - Anti-collision structure of intelligent power distribution station - Google Patents

Abstract

The embodiment of the utility model discloses an anticollision structure of intelligent power distribution station, including a plurality of fixed mounting at power distribution station around the anticollision roof beam, install the fixed cover between two adjacent anticollision roof beams, be equipped with the decompression mechanism that is used for unloading power in the fixed cover, this equipment realizes decompression anticollision operation through setting up at power distribution station around the anticollision roof beam and installing the decompression mechanism on the anticollision roof beam, when it is implemented, in case pressure strikes on unloading the board, the fender power post will most pressure transmission to ground buried block at once, make it lead to the underground, rather than absorbing the impact force through the pressure release subassembly, part pressure also can be absorbed by the anticollision roof beam and can not directly act on the cabinet body simultaneously, avoided buffering shock attenuation unit to receive the number of times of impact more, make its wearing and tearing volume can increase, the absorptive impact force reduces, make the normal use that the cabinet body received receive the condition of influence take place, and each part of the equipment has simple structure and convenient assembly and low cost during maintenance.

Description

Anti-collision structure of intelligent power distribution station

Technical Field

The embodiment of the utility model provides a power distribution station protection field, concretely relates to anticollision structure of intelligent power distribution station.

Background

Its main function of power distribution station is for receiving the electric energy, the distribution, control and protection, but do not carry out the vary voltage to the electric energy, main task is with electric power transmission to consumer or user when in actual use promptly, power distribution station is comparatively common in the downtown area now, because of downtown population density is big, consumer and consumer are many, in order to make the downtown power consumption not influenced, the power distribution station can all be adopted in the past, and power distribution station often can set up a plurality of regulator cubicle and be used for installing electrical components, the event is when the use, in order to avoid it can not receive the influence by external part and all can install an anticollision institution all around power distribution station sales counter.

However, the current anti-collision mechanisms are directly installed around the power distribution station when in use, and once the anti-collision mechanisms are impacted by pressure, impact force is removed through pressure relief assemblies such as springs, for example, in the utility model patent of a building electrical power distribution cabinet with an anti-collision fence with the patent application number of CN201822198672, the anti-collision mechanisms are mainly characterized in that a buffering and damping unit is installed on the side surface of a counter, and the buffering and damping unit is used for absorbing most impact force.

SUMMERY OF THE UTILITY MODEL

Therefore, the embodiment of the utility model provides an intelligent power distribution station's crashproof structure to solve among the prior art because buffering shock attenuation unit is direct mount in the sales counter side, the event still has partial effort to reach the cabinet body, if buffering shock attenuation unit receives the number of times of strikeing more, its wearing and tearing volume just can increase, and the strength that absorbs the impact reduces gradually, and this just makes the problem that the impact that the cabinet body received increases.

In order to achieve the above object, the embodiments of the present invention provide the following technical solutions:

an anti-collision structure of an intelligent power distribution station comprises a plurality of anti-collision beams fixedly arranged on the periphery of the power distribution station, a fixed cover is arranged between every two adjacent anti-collision beams, and a pressure reducing mechanism for unloading force is arranged in each fixed cover;

the utility model discloses a pressure reducing mechanism, including bury the piece and install the spliced pole of burying a lateral wall with ground the lateral wall of spliced pole is connected with supplementary buried block, the one end of burying the piece with ground is connected with the buried post, just bury the surface mounting of piece with ground has the power of keeping off post screens groove has been seted up on the power of keeping off post, the inner wall in screens groove has been seted up and has been led to the draw-in groove, and the screens inslot is provided with unloads the board the lead to draw-in groove in-connection has the carrier block that is used for supporting to unload the board, the one end and the fixed cover of carrier block are connected, just the other end and the buried block of carrier block are connected, bury the one end of piece far from the buried post and install spacing screens piece to the carrier.

As a preferred scheme of the utility model, unload the one end lateral wall that the power board kept away from fixed cover and seted up the spread groove the inner wall connection of spread groove has the secondary to unload the power post, the lateral wall that buries the piece with the secondary is unloaded power post and is corresponded position department and seted up the power post draw-in groove.

As an optimized scheme of the utility model, the constant head tank has been seted up to the lateral wall of spliced pole, the constant head tank in-connection has the location platform, the tip of location platform with install the promotion spring between the inner wall of constant head tank.

As a preferred scheme of the utility model, supplementary lateral wall and the spliced pole of burying the piece correspond position department and seted up the sliding tray, the inclined groove has been seted up to the tip of sliding tray, and is in the fixed station groove has been seted up to the inner wall of sliding tray.

As a preferred scheme of the utility model, bury the embedding power post that the post includes tip and the buried block is connected bury the lateral wall of embedding power post has cup jointed the jack-post cover the lateral wall of jack-post cover has cup jointed the protection main cover.

The utility model discloses an embodiment has following advantage:

this equipment realizes decompression anticollision operation through setting up at power distribution station anticollision roof beam all around with install the mechanism of decompression on the anticollision roof beam, during its concrete implementation, in case there is pressure impact on unloading the power board, then keep off the power post and can transmit most pressure to buried block immediately, make its leading-in underground, rather than absorbing the impact force through pressure release components such as springs, partial pressure also can be absorbed and can not directly be used in on the cabinet body by the anticollision roof beam simultaneously, avoided buffering shock attenuation unit to receive the number of times of impact more from this, make its wearing and tearing volume just can increase, absorptive impact force reduces, the condition that normal use that the cabinet body received receives the influence takes place, and each part simple structure of equipment assembles conveniently, it is with low costs during the maintenance.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below. It should be apparent that the drawings in the following description are merely exemplary, and that other embodiments can be derived from the drawings provided by those of ordinary skill in the art without inventive effort.

The structure, ratio, size and the like shown in the present specification are only used for matching with the content disclosed in the specification, so as to be known and read by people familiar with the technology, and are not used for limiting the limit conditions which can be implemented by the present invention, so that the present invention has no technical essential significance, and any structure modification, ratio relationship change or size adjustment should still fall within the scope which can be covered by the technical content disclosed by the present invention without affecting the efficacy and the achievable purpose of the present invention.

Fig. 1 is a schematic overall structure diagram of an embodiment of the present invention;

fig. 2 is a schematic structural view of the auxiliary embedded block according to the embodiment of the present invention during installation;

fig. 3 is a schematic side view of the force-blocking column according to the embodiment of the present invention;

fig. 4 is a right partial sectional view of the buried block according to the embodiment of the present invention.

In the figure:

1-an anti-collision beam; 2-fixing the cover; 3-a pressure reducing mechanism;

301-buried block; 302-connecting column; 303-auxiliary buried block; 304-ground buried pillar; 305-a force-blocking column; 306-a retaining groove; 307-card slot; 308-a force-releasing plate; 309-carrying block; 310-a block of stuck bits; 311-a connecting groove; 312-secondary force-relief post; 313-force post clamp slot; 314-a positioning slot; 315-a positioning table; 316-a push spring; 317-a sliding groove; 318-inclined groove; 319-fixed platform groove; 320-embedded force column; 321-a clamping column sleeve; 322-protective main cover.

Detailed Description

The present invention is described in terms of specific embodiments, and other advantages and benefits of the present invention will become apparent to those skilled in the art from the following disclosure. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative work belong to the protection scope of the present invention.

As shown in fig. 1, the utility model provides an intelligent power distribution station's crashproof structure, it realizes decompression anticollision operation through setting up at power distribution station anticollision roof beam 1 all around and the mechanism 3 of decompression of installing on anticollision roof beam 1, when pressure impact on unloading board 308, can transmit most pressure to ground buried block, make it leading-in underground, rather than absorb the impact force through pressure release components such as springs, partial pressure also can be absorbed by anticollision roof beam 1 and can not directly be used in on the cabinet body simultaneously, avoided buffering shock attenuation unit from this to receive the number of times of impact more, make its wearing and tearing volume just can increase, absorptive impact force reduces, make the normal use that the cabinet body received receive the condition emergence of influence.

As shown in fig. 1, the anti-collision device comprises a plurality of anti-collision beams 1 fixedly arranged around a power distribution station, wherein a fixed cover 2 is arranged between every two adjacent anti-collision beams 1, and a pressure reducing mechanism 3 for unloading force is arranged in each fixed cover 2.

When the equipment is used, the anti-collision beam 1 can be fixed around a power distribution station, then the pressure reducing mechanism 3 is arranged on the anti-collision beam 1, once the pressure reducing mechanism 3 bears pressure, most of the pressure can be transmitted to the underground buried block, the underground buried block is led in, and meanwhile, part of the pressure can be absorbed by the anti-collision beam 1 and cannot be directly acted on the cabinet body.

As shown in fig. 2, 3 and 4, the pressure reducing mechanism 3 includes an underground block 301 and a connecting column 302 installed on a side wall of the underground block 301, an auxiliary embedded block 303 is connected on a side wall of the connecting column 302, an underground column 304 is connected at one end of the underground block 301, a force blocking column 305 is installed on a surface of the underground block 301, a locking groove 306 is opened on the force blocking column 305, a through locking groove 307 is opened on an inner wall of the locking groove 306, a force releasing plate 308 is arranged in the locking groove 306, a bearing block 309 for supporting the force releasing plate 308 is connected in the through locking groove 307, the bearing block 309 can move up and down in the through locking groove 307 to facilitate subsequent maintenance and replacement, and then the bearing block 309 is fixed by a nut, and the specific structure thereof can be as shown in fig. 3, one end of the bearing block 309 is connected with the fixed cover 2, and the other end of the bearing block 309 is connected with the underground block 301, one end of the buried block 301 far away from the buried column 304 is provided with a clamping block 310 for limiting the bearing block 309.

When the pressure reducing mechanism 3 is assembled, a plurality of auxiliary embedding blocks 303 are sleeved on the side wall of a connecting column 302 at certain intervals, then the ground embedding columns 304 on the ground embedding blocks 301 are driven into the ground (because the structures of the auxiliary embedding blocks 303 and the ground embedding blocks 301 are the same, but sliding grooves 317 are formed in the auxiliary embedding blocks 303 and are used for being connected with the connecting column 302, when the auxiliary embedding blocks 303 are connected with the connecting column 302, the ground embedding columns 304 on the auxiliary embedding blocks 303 can be driven into the ground in sequence), then a user can connect one end of a first force releasing plate 308 with a fixed cover 2, the other end of the first force releasing plate 308 is connected with the ground embedding blocks 301 and limited through clamping blocks 310 (the force releasing plate 308 can be connected with the ground embedding blocks 301 and the clamping blocks 310 through pins), then the force blocking columns 305 are fixed on the surface of the ground embedding blocks 301, then the bearing blocks 309 in the clamping grooves 307 are moved, the stress relief plates 308 are supported, so that the first stress relief plate 308 is installed, and then the stress relief plates 308 are installed on the auxiliary blocks 303 in a one-to-one correspondence mode according to the operation until the whole power distribution station is surrounded.

When the pressure reducing mechanism 3 is stressed, the external force directly acts on the force unloading plate 308, so once the force unloading plate 308 is stressed, the bearing block 309 can bear all the force, most of the force is transmitted to the buried block 301 through the force blocking column 305 at this time, so that the force is led into the ground, the impact force is not absorbed through a pressure relief component such as a spring, and meanwhile, part of the pressure is transmitted to the anti-collision beam 1 through the force blocking column 305, and is absorbed by the anti-collision beam 1 and does not directly act on the cabinet body.

Specifically, as shown in fig. 1, a connection groove 311 is formed in a side wall of one end of the stress relief plate 308, which is far away from the fixed cover 2, a secondary stress relief column 312 is connected to an inner wall of the connection groove 311, and a stress column clamping groove 313 is formed in a position of a side wall of the buried block 301, which corresponds to the secondary stress relief column 312.

When the buried block 301 or the auxiliary buried block 303 is nailed, the secondary force-releasing column 312 is firstly clamped into the force-column clamping groove 313, then the force-releasing plate 308 is inserted, so that the secondary force-releasing column 312 is inserted into the connecting groove 311, then the secondary force-releasing column 312 is fixed with the buried block 301 and the clamping block 310 through the pin, therefore, when external force acts on the force-releasing plate 308, the ground-gripping force of the buried block 301 is better, and in order to prevent the secondary force-releasing column 312 from being easily pulled out, the structure can be shown in fig. 1, the cross section of the structure is in an L-shaped structure, meanwhile, an inclined table is installed at one end far away from the clamping block 310, and the end far away from the buried column 304 of the ground-buried block 301 cannot be easily tilted when being stressed.

As shown in fig. 2 and 4, the side wall of the connecting column 302 is provided with a positioning groove 314, the positioning groove 314 is connected with a positioning table 315, a pushing spring 316 is installed between the end of the positioning table 315 and the inner wall of the positioning groove 314, when the auxiliary embedded block 303 is inserted, because the sliding groove 317 is formed at the position of the side wall of the auxiliary embedded block 303 corresponding to the connecting column 302, the end of the sliding groove 317 is provided with an inclined groove 318, and the inner wall of the sliding groove 317 is provided with a positioning groove 319, the connecting column 302 can be inserted into the sliding groove 317, when the inclined groove 318 contacts the positioning table 315, the positioning table 315 can move towards the positioning groove 314, the pushing spring 316 is compressed, and then the auxiliary embedded block 303 continues to move until the positioning table 315 corresponds to the positioning groove 319, at this time, the pushing spring 316 will reset, and the positioning table 315 will be pushed into the positioning groove 319 by the pushing spring 316.

As shown in fig. 1 and 4, the buried pole 304 includes a buried pole 320 whose end is connected to the buried block 301, a column sleeve 321 is sleeved on a side wall of the buried pole 320, the column sleeve 321 may be composed of a fixed sleeve and a guard pole fixed on a side wall of the fixed sleeve, a pole through slot is opened at a position of a side wall of the guard pole 322 corresponding to the guard pole, a guard pole sleeve 322 is sleeved on a side wall of the column sleeve 321, the column sleeve 321 can be fully inserted into soil when the buried pole 320 is nailed, once the buried block 301 is stressed, the buried pole 320 is pushed to make the column sleeve 321 move towards one side of the guard pole sleeve 322, and at this time, the movable buried pole 320 can make the guard pole pass through the pole through slot, so that the ground holding power of the buried pole 304 is better.

Although the invention has been described in detail with respect to the general description and the specific embodiments, it will be apparent to those skilled in the art that modifications and improvements can be made based on the invention. Therefore, such modifications and improvements are intended to be within the scope of the invention as claimed.

Claims (5)

1. The anti-collision structure of the intelligent power distribution station is characterized by comprising a plurality of anti-collision beams (1) fixedly arranged on the periphery of the power distribution station, a fixed cover (2) is arranged between every two adjacent anti-collision beams (1), and a pressure reducing mechanism (3) for unloading force is arranged in each fixed cover (2);

the decompression mechanism (3) comprises an underground block (301) and a connecting column (302) mounted on the side wall of the underground block (301), the side wall of the connecting column (302) is connected with an auxiliary embedded block (303), and one end of the underground block (301) is connected with an underground column (304);

a force blocking column (305) is installed on the surface of the underground block (301), a clamping groove (306) is formed in the force blocking column (305), a through clamping groove (307) is formed in the inner wall of the clamping groove (306), a force unloading plate (308) is arranged in the clamping groove (306), and a bearing block (309) used for supporting the force unloading plate (308) is connected in the through clamping groove (307);

one end of the bearing block (309) is connected with the fixed cover (2), the other end of the bearing block (309) is connected with the buried block (301), and the clamping block (310) limiting the bearing block (309) is installed at one end, far away from the buried column (304), of the buried block (301).

2. The anti-collision structure of the intelligent power distribution station, according to claim 1, characterized in that a connecting groove (311) is opened on a side wall of one end of the force-releasing plate (308) far away from the fixed cover (2), a secondary force-releasing column (312) is connected to an inner wall of the connecting groove (311), and a force-column clamping groove (313) is opened on a side wall of the buried block (301) at a position corresponding to the secondary force-releasing column (312).

3. The anti-collision structure of the intelligent power distribution station is characterized in that a positioning groove (314) is formed in the side wall of the connecting column (302), a positioning table (315) is connected in the positioning groove (314), and a pushing spring (316) is installed between the end of the positioning table (315) and the inner wall of the positioning groove (314).

4. The anti-collision structure of the intelligent power distribution station according to claim 1, wherein a sliding groove (317) is formed in a position, corresponding to the connecting column (302), of a side wall of the auxiliary embedded block (303), an inclined groove (318) is formed in an end portion of the sliding groove (317), and a fixed groove (319) is formed in an inner wall of the sliding groove (317).

5. The crash-proof structure of the intelligent power distribution station according to claim 1, wherein the buried pillar (304) comprises a buried force pillar (320) with an end connected with the buried block (301), a pillar sleeve (321) is sleeved on a side wall of the buried force pillar (320), and a main protection sleeve (322) is sleeved on a side wall of the pillar sleeve (321).

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