CN219659257U - Power distribution room monitoring facilities - Google Patents

Abstract

The utility model discloses power distribution room monitoring equipment, and belongs to the technical field of power distribution room monitoring. The utility model provides a distribution room monitoring facilities, includes the room body, fixedly connected with distribution subassembly in the room body still includes: the heat conducting plate is fixedly connected to the power distribution assembly; the temperature sensor is fixedly connected to the heat conducting plate; the monitoring box is fixedly connected to the temperature sensor, and one end, far away from the heat conducting plate, of the temperature sensor is spliced in the monitoring box; the cooling fan is rotationally connected to the house body and transmits heat emitted by the power distribution assembly through the heat conducting plate and the temperature sensor in the device, so that the sliding plug can be pushed to slide, the power supply can be driven to move, the power supply supplies power for the driving motor, the cooling fan is rotated, and external cool air can be effectively inhaled to cool the power distribution assembly; the device is used for cooling the power distribution assembly, and the cooling fan can be turned off after cooling, so that energy sources are saved, and the use cost is reduced.

Description

Power distribution room monitoring facilities

Technical Field

The utility model relates to the technical field of monitoring of power distribution rooms, in particular to monitoring equipment of a power distribution room.

Background

The power distribution room is also called a power distribution substation, and is an indispensable part of a power supply system;

in the prior art, in the use process of the power distribution room, certain heat can be emitted due to the fact that some power distribution elements in the power distribution room work, internal elements can be burnt out due to the fact that heat is not emitted timely, in order to conduct heat dissipation treatment on the power distribution room in the prior art, a cooling fan is generally adopted for conducting blowing and cooling, but the cooling fan in the prior art can be always in a blowing state, under the condition that the power distribution room does not need to dissipate heat, the power distribution room can still be in a working blowing state, damage to the fan can be easily caused due to long-time work, and meanwhile cost can be increased due to long-time work of the fan.

Disclosure of Invention

The utility model provides a power distribution room monitoring device which aims to solve the problem that the cost is increased due to the fact that power distribution room heat dissipation devices in the prior art can work for a long time.

In order to achieve the above purpose, the present utility model adopts the following technical scheme:

the utility model provides a distribution room monitoring facilities, includes the room body, fixedly connected with distribution subassembly in the room body still includes:

the heat conducting plate is fixedly connected to the power distribution assembly;

the temperature sensor is fixedly connected to the heat conducting plate;

the monitoring box is fixedly connected to the temperature sensor, and one end, far away from the heat conducting plate, of the temperature sensor is spliced in the monitoring box;

a heat radiation fan rotatably connected to the house;

when the temperature of the monitoring box is monitored to rise, the cooling fan is driven to rotate, and the cooling fan blows cooling wind into the house body, so that the power distribution assembly is cooled.

Preferably, the connecting rod is fixedly connected with on the room body, fixedly connected with driving motor on the connecting rod, driving motor drive end is connected with the bull stick, radiator fan fixed connection is on the bull stick.

Preferably, an electrode plate is fixedly connected in the house body, a wire is connected to the electrode plate, one end, away from the electrode plate, of the wire is electrically connected to the driving motor, a power supply is connected to the monitoring box in a sliding mode, and the power supply corresponds to the electrode plate.

Further, a sliding plug is connected in the monitoring box in a sliding way, the power supply is fixedly connected to the sliding plug, a through hole is formed in the monitoring box, and the through hole is matched with the power supply in size; the temperature sensor is electrically connected with an electric telescopic rod, and the driving end of the electric telescopic rod is fixedly connected with the sliding plug.

In order to enable the sliding plug to quickly reset, the sliding plug is further fixedly connected with a spring, and one end, away from the sliding plug, of the spring is fixedly connected to the inner side wall of the monitoring box.

In order to ensure the radiating effect, further, the first magnet is fixedly connected with the sliding plug, the second magnet is fixedly connected with the inner side wall of the monitoring box, and the first magnet and the second magnet are attracted.

Compared with the prior art, the utility model provides the power distribution room monitoring equipment, which has the following beneficial effects:

1. according to the monitoring equipment for the power distribution room, the heat emitted by the power distribution assembly is transmitted through the heat conducting plate and the temperature sensor in the device, so that the sliding plug can be pushed to slide, the power supply can be driven to move, the power supply supplies power for the driving motor, the cooling fan is rotated, and external cool air can be effectively inhaled to cool the power distribution assembly; the device is used for cooling the power distribution assembly, and the cooling fan can be turned off after cooling, so that energy sources are saved, and the use cost is reduced.

Drawings

Fig. 1 is a schematic diagram of a front view structure of a monitoring device for a power distribution room according to the present utility model;

fig. 2 is a schematic diagram of a rear view structure of a monitoring device for a power distribution room according to the present utility model;

fig. 3 is a schematic cross-sectional view of a monitoring device for a power distribution room according to the present utility model;

fig. 4 is a schematic diagram of a cross-sectional structure of a monitoring device for a power distribution room according to the present utility model;

fig. 5 is a schematic diagram of an internal structure of a monitoring device for a power distribution room according to the present utility model;

fig. 6 is a schematic diagram of a connection structure of a monitoring box and a temperature sensor in a monitoring device for a power distribution room according to the present utility model;

fig. 7 is an enlarged schematic structural diagram of a portion a of a monitoring device for a power distribution room according to the present utility model.

In the figure: 1. a house body; 101. a wind groove; 102. a power distribution assembly; 2. a driving motor; 201. a rotating rod; 2011. a heat radiation fan; 202. a wire; 2021. an electrode plate; 203. a connecting rod; 3. a monitoring box; 301. a through hole; 302. a second magnet; 303. a sliding plug; 304. a spring; 305. a first magnet; 306. a power supply; 4. a heat conductive plate; 401. a temperature sensor.

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.

Example 1:

referring to fig. 1-7, a power distribution room monitoring device, including a room body 1, a power distribution assembly 102 fixedly connected to the room body 1, further includes:

a heat conducting plate 4 fixedly connected to the power distribution assembly 102;

a temperature sensor 401 fixedly connected to the heat conductive plate 4;

the monitoring box 3 is fixedly connected to the temperature sensor 401, and one end, far away from the heat conducting plate 4, of the temperature sensor 401 is spliced in the monitoring box 3;

a heat radiation fan 2011 rotatably connected to the house 1;

the two groups of cooling fans 2011 are symmetrically arranged on the house body 1, one group of cooling fans 2011 is an induced draft fan 2011, and the other group is an air blowing fan 2011.

When the temperature of the monitoring box 3 is monitored to increase, the cooling fan 2011 is driven to rotate, and the cooling fan 2011 blows cooling air into the room body 1, so as to cool the power distribution assembly 102.

Fixedly connected with connecting rod 203 on the room body 1, fixedly connected with driving motor 2 on the connecting rod 203, driving motor 2 drive end is connected with bull stick 201, radiator fan 2011 fixed connection is on bull stick 201.

The house body 1 is provided with a wind groove 101, and the wind groove 101 is matched with a cooling fan 2011.

An electrode plate 2021 is fixedly connected in the house body 1, a lead 202 is connected to the electrode plate 2021, one end, far away from the electrode plate 2021, of the lead 202 is electrically connected to the driving motor 2, a power supply 306 is connected to the monitoring box 3 in a sliding mode, and the power supply 306 corresponds to the electrode plate 2021.

The monitoring box 3 is slidably connected with a sliding plug 303, a power supply 306 is fixedly connected to the sliding plug 303, a through hole 301 is formed in the monitoring box 3, and the size of the through hole 301 is matched with that of the power supply 306; the temperature sensor 401 is electrically connected with an electric telescopic rod 4011, and the driving end of the electric telescopic rod 4011 is fixedly connected with the sliding plug 303.

The sliding plug 303 is fixedly connected with a spring 304, and one end of the spring 304 far away from the sliding plug 303 is fixedly connected to the inner side wall of the monitoring box 3.

Referring to fig. 6-7, the return speed of the spool 303 can be increased by providing a spring 304.

Referring to fig. 7, a first magnet 305 is fixedly connected to the sliding plug 303, a second magnet 302 is fixedly connected to the inner side wall of the monitoring box 3, and the first magnet 305 and the second magnet 302 attract each other.

The first magnet 305 and the second magnet 302 are arranged to attract each other, so that the heat radiation effect can be improved.

Referring to fig. 1-7, in the use, through the power distribution and power supply operation of the power distribution assembly 102, the power distribution assembly 102 operates for a long time, heat emitted by the power distribution assembly 102 will be transmitted through the heat conducting plate 4, the transmitted heat will be transmitted to the electric telescopic rod 4011 through the induction of the temperature sensor 401, the electric telescopic rod 4011 will push the sliding plug 303 connected with the driving end to move, the sliding plug 303 will drive the power supply 306 fixedly connected with the sliding plug 303 to move, after a certain distance is moved, the sliding plug 303 slides to the maximum limit, at this time, the power supply 306 stretches out of the through hole 301, the stretched power supply 306 abuts against the electrode plate 2021, at this time, the power supply 306, the electrode plate 2021, the lead 202 and the driving motor 2 will form a complete passage, at this time, the driving motor 2 will rotate, the rotation of the driving motor 2 will drive the rotating rod 201 to rotate, the fan 2011 fixedly connected with the rotating rod, the rotating fan 2011 can suck external cool wind into the room body 1, and the other group of fans 2011 can blow the cool wind into the room body 1, the power distribution assembly 102 can effectively cool down the power distribution assembly 102, thereby the power distribution assembly can be prevented from being damaged, and the service life of the power distribution assembly can be prolonged.

Referring to fig. 6 to 7, when the power source 306 is completely pushed out, the first magnet 305 and the second magnet 302 will attract each other, and the heat dissipation time can be increased by attracting the first magnet 305 and the second magnet 302, so that the heat dissipation effect is ensured.

After the heat dissipation is completed, the temperature sensor 401 reduces the temperature of the induction heat-conducting plate 4, so that the electric telescopic rod 4011 is driven to work to drive the sliding plug 303 to reset, and the heat dissipation fan 2011 is powered off;

the model of the temperature sensor 401 is LM-PT100.

The heat emitted by the induction power distribution assembly 102 is transmitted through the heat conducting plate 4 and the temperature sensor 401 in the device, so that the sliding plug 303 can be pushed to slide, the power supply 306 can be driven to move, the power supply 306 supplies power for the driving motor 2, the heat radiating fan 2011 is rotated, and external cool wind can be effectively sucked to cool the power distribution assembly 102; the device is used for cooling the power distribution assembly 102, and the cooling fan 2011 can be turned off after cooling, so that energy sources are saved, and the use cost is reduced.

The present utility model is not limited to the above-mentioned embodiments, and any person skilled in the art, based on the technical solution of the present utility model and the inventive concept thereof, can be replaced or changed within the scope of the present utility model.

Claims (6)

1. The utility model provides a distribution room monitoring facilities, includes the room body (1), fixedly connected with distribution subassembly (102) in the room body (1), its characterized in that still includes:

the heat conducting plate (4) is fixedly connected to the power distribution assembly (102);

the temperature sensor (401) is fixedly connected to the heat conducting plate (4);

the monitoring box (3) is fixedly connected to the temperature sensor (401), and one end, far away from the heat conducting plate (4), of the temperature sensor (401) is spliced in the monitoring box (3);

and the cooling fan (2011) is rotatably connected to the house body (1).

2. The power distribution room monitoring device according to claim 1, wherein a connecting rod (203) is fixedly connected to the room body (1), a driving motor (2) is fixedly connected to the connecting rod (203), a rotating rod (201) is connected to the driving end of the driving motor (2), and the cooling fan (2011) is fixedly connected to the rotating rod (201).

3. The power distribution room monitoring device according to claim 2, wherein an electrode plate (2021) is fixedly connected in the room body (1), a wire (202) is connected to the electrode plate (2021), one end, away from the electrode plate (2021), of the wire (202) is electrically connected to the driving motor (2), a power supply (306) is slidingly connected to the monitoring box (3), and the power supply (306) corresponds to the electrode plate (2021).

4. A power distribution room monitoring device according to claim 3, wherein a sliding plug (303) is slidingly connected in the monitoring box (3), the power supply (306) is fixedly connected to the sliding plug (303), a through hole (301) is formed in the monitoring box (3), and the size of the through hole (301) is matched with that of the power supply (306); an electric telescopic rod (4011) is electrically connected to the temperature sensor (401), and the driving end of the electric telescopic rod (4011) is fixedly connected with the sliding plug (303).

5. The power distribution room monitoring device according to claim 4, wherein a spring (304) is fixedly connected to the sliding plug (303), and one end of the spring (304) away from the sliding plug (303) is fixedly connected to the inner side wall of the monitoring box (3).

6. The power distribution room monitoring device according to claim 4, wherein a first magnet (305) is fixedly connected to the sliding plug (303), a second magnet (302) is fixedly connected to the inner side wall of the monitoring box (3), and the first magnet (305) and the second magnet (302) attract each other.