CN220341741U - Outdoor power distribution cabinet - Google Patents

Abstract

The utility model provides an outdoor power distribution cabinet, comprising: the novel rain shielding roof comprises a rain shielding roof body, a water guide groove, water guide strips and a heat dissipation net, wherein the water guide groove is formed in the upper end of the rain shielding roof body, the water guide strips are arranged on the inner side of the water guide groove, a box body is arranged at the lower end of the rain shielding roof body, a side leakage net is arranged on the left side of the box body, a water inlet pipe is arranged at the lower end of the side leakage net, a bin gate is arranged at the front end of the box body, a water outlet pipe is arranged at the lower end of the right side of the box body, and an insulating layer is arranged on the inner side of the box body. Through using the rain top that hides, can carry out the water conservancy diversion to the rainwater at box top, through using equipment bin and heat dissipation net, can dispel the heat fast to equipment bin inside, through using the insulating layer, can carry out insulating treatment to the electric energy of box inside, through using ASF1513 type guide pump, water guiding coil and cooling collar, can carry out the water-cooling to equipment bin inside.

Description

Outdoor power distribution cabinet

Technical Field

The utility model belongs to the technical field of power distribution cabinets and relates to an outdoor power distribution cabinet.

Background

A power distribution cabinet is a device for power distribution and control, which plays an important role in a power system. However, power distribution cabinets also have some problems and drawbacks.

First, the switch board can not outdoor hide rain. Power distribution cabinets for outdoor use are often required to face a variety of severe weather conditions, such as rain, snow, sand wind, and the like. However, some current power distribution cabinets are not designed to take these weather factors into consideration, and cannot effectively shield internal devices from rain. This can lead to moisture ingress into the switchgear interior equipment, causing equipment shorting, damage and even fire. Meanwhile, moisture invasion can also lead to the reduction of the insulation performance of the power distribution cabinet, increase the risks of electric shock and electric leakage and threaten personal safety.

Secondly, the power distribution cabinet cannot exchange heat rapidly. In the operation process of the power distribution cabinet, the electrical equipment can generate a large amount of heat, if the heat cannot be timely and effectively dissipated, the temperature of the equipment is too high, and then the normal operation of the equipment is affected. However, the heat dissipation design of some power distribution cabinets is not reasonable, and cannot provide enough heat dissipation capability. This may cause the device to overheat, causing the device to malfunction or reducing the lifetime of the device. Meanwhile, the high-temperature environment can damage and age electric elements in the power distribution cabinet, and stability and reliability of equipment are affected.

In addition, problems with the power distribution cabinet include potential safety hazards and maintenance difficulties. Because of the high-voltage power supply and the high-current equipment in the power distribution cabinet, once faults or improper operation occur, serious accidents such as electric shock and fire disaster can be caused. In addition, because the switch board is installed in comparatively narrow and small space generally, to maintenance and maintenance, operating space is narrow and small, is inconvenient for the staff to maintain and overhaul, has increased the degree of difficulty and the risk of maintaining.

In summary, the power distribution cabinet has the problems and defects that outdoor rain shielding and rapid heat dissipation exchange are not realized. In order to solve these problems, we have now demanded an outdoor type power distribution cabinet to solve the above problems.

Disclosure of Invention

Aiming at the defects in the prior art, the utility model aims to provide an outdoor power distribution cabinet which solves the problems in the background art.

The utility model is realized by the following technical scheme: an outdoor power distribution cabinet comprising: the rain shielding roof comprises a rain shielding roof, a water guide groove, a water guide strip, a box body, a side leakage net, a bin gate, a water inlet pipe, an insulating layer, a distributor, a built-in plate, an inner interlayer, a water guide coil, a heat conducting fan, a cooling ring pipe and a heat dissipation net, wherein the water guide groove is formed in the upper end of the rain shielding roof;

the inner side of the water guide groove is provided with a water guide strip, the lower end of the rain shielding top is provided with a box body, the left side of the box body is provided with a side leakage net, the lower end of the side leakage net is provided with a water inlet pipe, the front end of the box body is provided with a bin gate, the lower end of the right side of the box body is provided with a water outlet pipe, the inner side of the box body is provided with an insulating layer, and the inner side of the insulating layer is provided with a built-in plate;

the inner side of the built-in plate is provided with a distributor, the lowest end of the built-in plate is provided with a group of inner interlayers, the right side of the water inlet pipe is provided with a water guide coil, the rear end of the water guide coil is provided with a heat conducting fan, the upper end of the water guide coil is provided with a cooling ring pipe, and the rear end of the box body is provided with a heat dissipation net.

As a preferable implementation mode, the rain shielding roof is fixedly connected with the box body through bolts, the cross section of the rain shielding roof is of a herringbone structure, and the rain shielding roof is made of an aluminum alloy material.

As a preferred implementation mode, the rain shielding top and a plurality of groups of water guide strips are an integrated forming mechanism, a plurality of groups of water guide grooves are formed, equipment bins are formed in the box body, the equipment bins are communicated with the inside of the side leakage net, and rainwater at the top of the box body can be guided through the rain shielding top.

As a preferred implementation mode, the equipment bin is communicated with the heat dissipation net, the box body and the bin door are movably connected through a hinge, the water inlet pipe and the water outlet pipe penetrate through the box body, and the equipment bin and the heat dissipation net can be used for rapidly dissipating heat in the equipment bin.

As a preferred implementation mode, the inner interlayer is provided with a plurality of groups, the inner interlayers of the groups are movably embedded and connected with the inside of the equipment bin, the inside of the box body is embedded and connected with the insulating layer, the insulating layer is made of a rubber material, and the insulating layer can be used for insulating electric energy in the box body.

As a preferred implementation mode, the right side of the water inlet pipe and the left side of the water outlet pipe are respectively provided with a group of ASF1513 type flow guide pumps, the two groups of ASF1513 type flow guide pumps are mutually communicated through water guide coils, the two groups of ASF1513 type flow guide pumps are correspondingly communicated with a group of cooling loops respectively, and the inside of the equipment bin can be cooled by water through the ASF1513 type flow guide pumps, the water guide coils and the cooling loops.

As a preferred implementation mode, the heat conduction fan is in contact with the flow guide annular pipe, the flow guide annular pipe is made of an aluminum alloy material, and the rear end of the heat conduction fan is communicated with the heat dissipation net.

After the technical scheme is adopted, the utility model has the beneficial effects that: through using the rain top that hides, can carry out the water conservancy diversion to the rainwater at box top, through using equipment bin and heat dissipation net, can dispel the heat fast to equipment bin inside, through using the insulating layer, can carry out insulating treatment to the electric energy of box inside, through using ASF1513 type guide pump, water guiding coil and cooling collar, can carry out the water-cooling to equipment bin inside.

Drawings

In order to more clearly illustrate the embodiments of the utility model or the technical solutions of the prior art, the drawings which are used in the description of the embodiments or the prior art will be briefly described, it being obvious that the drawings in the description below are only some embodiments of the utility model, and that other drawings can be obtained according to these drawings without inventive faculty for a person skilled in the art.

Fig. 1 is a schematic structural diagram of an outdoor power distribution cabinet according to the present utility model;

fig. 2 is a front view of the inside of an outdoor power distribution cabinet according to the present utility model;

fig. 3 is a front view of a water guiding coil and a heat conducting fan in an outdoor power distribution cabinet;

fig. 4 is a front view of the rear end of the box in the outdoor power distribution cabinet;

in the figure: 100-rain shielding roof, 110-water guide groove, 120-water guide strip, 130-box, 140-side leakage net, 150-bin gate, 160-water inlet pipe, 170-water outlet pipe, 180-insulating layer, 190-distributor, 200-built-in board, 210-inner interlayer, 220-water guide coil, 230-heat conducting fan, 240-cooling ring pipe and 250-heat dissipation net.

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 outdoor power distribution cabinet includes: the rain shielding roof 100, the water guide grooves 110, the water guide strips 120 and the heat dissipation net 250, wherein the water guide grooves 110 are formed in the upper end of the rain shielding roof 100;

the inner side of the water guide groove 110 is provided with a water guide strip 120, the lower end of the rain shielding top 100 is provided with a box body 130, the left side of the box body 130 is provided with a side leakage net 140, the lower end of the side leakage net 140 is provided with a water inlet pipe 160, the front end of the box body 130 is provided with a bin gate 150, the lower end of the right side of the box body 130 is provided with a water outlet pipe 170, the inner side of the box body 130 is provided with an insulating layer 180, and the inner side of the insulating layer 180 is provided with a built-in plate 200;

the inside of the built-in board 200 is provided with a distributor 190, the lower end of the built-in board 200 at the lowest end is provided with a group of inner interlayers 210, the right side of the water inlet pipe 160 is provided with a water guide coil 220, the rear end of the water guide coil 220 is provided with a heat conducting fan 230, the upper end of the water guide coil 220 is provided with a cooling ring pipe 240, and the rear end of the box 130 is provided with a heat dissipation net 250.

The rain shielding roof 100 and the box 130 are fixedly connected through bolts, the cross section of the rain shielding roof 100 is of a herringbone structure, and the rain shielding roof 100 is made of an aluminum alloy material.

The rain shielding top 100 and the water guide strips 120 are integrated into a whole, the water guide groove 110 is provided with a plurality of groups, the inside of the box 130 is provided with a device cabin, the inside of the device cabin is mutually communicated with the inside of the side leakage net 140, and the rainwater at the top of the box 130 can be guided through the rain shielding top 100.

The inside of the equipment bin is communicated with the inside of the heat dissipation net 250, the box body 130 is movably connected with the bin door 150 through a hinge, the water inlet pipe 160 and the water outlet pipe 170 penetrate through the inside of the box body 130, and the inside of the equipment bin can be quickly dissipated through the equipment bin and the heat dissipation net 250.

The inner interlayer 210 is provided with a plurality of groups, the inner interlayer 210 of the groups is movably embedded and connected with the inside of the equipment bin, the inside of the box 130 is embedded and connected with the insulating layer 180, the insulating layer 180 is made of a rubber material, and electric energy inside the box 130 can be insulated through the insulating layer 180.

The right side of the water inlet pipe 160 and the left side of the water outlet pipe 170 are respectively provided with a group of ASF1513 type guide pumps, the two groups of ASF1513 type guide pumps are mutually communicated through the water guide coil 220, the two groups of ASF1513 type guide pumps are correspondingly communicated with a group of cooling ring pipes 240 respectively, and the inside of the equipment bin can be cooled by water through the ASF1513 type guide pumps, the water guide coil 220 and the cooling ring pipes 240.

The heat conduction fan 230 is in contact with the flow guide ring pipe, the flow guide ring pipe is made of an aluminum alloy material, and the rear end of the heat conduction fan 230 is communicated with the heat dissipation net 250.

As a first embodiment of the present utility model: in order to solve the problem that the power distribution cabinet used outdoors generally needs to face various severe weather conditions, such as rainwater, snow, sand and the like, which can lead to the fact that the internal equipment of the power distribution cabinet is easy to be invaded by moisture, short circuit, damage and even fire disaster occur, meanwhile, the moisture invasion can also lead to the reduction of the insulation performance of the power distribution cabinet, the risks of electric shock and electric leakage are increased, and the threat to personal safety is caused.

As a second embodiment of the present utility model: based on the above description of the embodiment, further, in the operation process of the power distribution cabinet, a great amount of heat is generated by the electrical equipment, if heat cannot be effectively dissipated in time, the temperature of the equipment is too high, and the normal operation of the equipment is affected, which may cause equipment to be overheated, and cause equipment failure or reduce the service life of the equipment, firstly, a worker introduces external cooling water into the water inlet pipe 160, since a group of ASF1513 type diversion pumps are respectively arranged on the right side of the water inlet pipe 160 and the left side of the water outlet pipe 170, the two groups of ASF1513 type diversion pumps are mutually communicated through the water inlet pipe 220, the two groups of ASF1513 type diversion pumps are started, and external cooling water is introduced into the water inlet pipe 160 and the cooling loop 240 through the water inlet pipe 160, so that the cooling water cools the water inlet pipe 220 and the cooling loop 240, and the heat conducting fan 230 can be further cooled by the water conducting loop body when the heat conducting fan 230 is started, and the heat conducting fan 230 can be stably operated for a long time.

The foregoing description of the preferred embodiments of the utility model is not intended to be limiting, but rather is intended to cover all modifications, equivalents, alternatives, and improvements that fall within the spirit and scope of the utility model.

Claims (7)

1. An outdoor power distribution cabinet comprising: rain shielding top (100), guiding gutter (110), water guiding strip (120) and heat dissipation net (250), its characterized in that: the upper end of the rain shielding roof (100) is provided with a water guide groove (110);

the rain shielding roof is characterized in that a water guide strip (120) is arranged on the inner side of the water guide groove (110), a box body (130) is arranged at the lower end of the rain shielding roof (100), a side leakage net (140) is arranged on the left side of the box body (130), a water inlet pipe (160) is arranged at the lower end of the side leakage net (140), a bin gate (150) is arranged at the front end of the box body (130), a water outlet pipe (170) is arranged at the lower end of the right side of the box body (130), an insulating layer (180) is arranged on the inner side of the box body (130), and a built-in plate (200) is arranged on the inner side of the insulating layer (180);

the inside distributor (190) that is equipped with of built-in board (200), the lower extreme built-in board (200) lower extreme is equipped with a set of interlayer (210), inlet tube (160) right side is equipped with water guiding coil (220), water guiding coil (220) rear end is equipped with heat conduction fan (230), water guiding coil (220) upper end is equipped with cooling ring pipe (240), box (130) rear end is equipped with heat dissipation net (250).

2. An outdoor power distribution cabinet according to claim 1, characterized in that: the rain shielding roof (100) is fixedly connected with the box body (130) through bolts, the cross section of the rain shielding roof (100) is of a herringbone structure, and the rain shielding roof (100) is made of an aluminum alloy material.

3. An outdoor power distribution cabinet according to claim 2, characterized in that: the rain shielding roof (100) and the water guide strips (120) are integrated into a whole, the water guide grooves (110) are provided with a plurality of groups, the inside of the box body (130) is provided with a device cabin, and the inside of the device cabin is communicated with the inside of the side leakage net (140).

4. An outdoor power distribution cabinet according to claim 3, characterized in that: the equipment bin is communicated with the heat dissipation net (250), the box body (130) is movably connected with the bin door (150) through a hinge, and the water inlet pipe (160) and the water outlet pipe (170) penetrate through the box body (130).

5. An outdoor power distribution cabinet according to claim 1, characterized in that: the inner interlayer (210) is provided with a plurality of groups, the inner interlayers (210) of the groups are movably embedded and connected with the inside of the equipment bin, the inside of the box body (130) is embedded and connected with the insulating layer (180), and the insulating layer (180) is made of a rubber material.

6. An outdoor power distribution cabinet as claimed in claim 4, wherein: the right side of the water inlet pipe (160) and the left side of the water outlet pipe (170) are respectively provided with a group of ASF1513 type guide pumps, the two groups of ASF1513 type guide pumps are mutually communicated through a water guide coil (220), and the two groups of ASF1513 type guide pumps are respectively correspondingly communicated with a group of cooling annular pipes (240).

7. An outdoor power distribution cabinet according to claim 1, characterized in that: the heat conduction fan (230) is in contact with the flow guide ring pipe, the flow guide ring pipe is made of an aluminum alloy material, and the rear end of the heat conduction fan (230) is communicated with the heat dissipation net (250).