CN212806000U - Energy-saving and electricity-saving temperature control system for power distribution room - Google Patents

Abstract

The application relates to the field of temperature control of power distribution rooms, in particular to an energy-saving and electricity-saving temperature control system of a power distribution room, which comprises a detection module, a control module and a cooling module; the detection module comprises a first temperature module and is used for generating indoor temperature data; the cooling module comprises a first ventilation module, a second ventilation module and an air conditioning module; the control module comprises a processing module, the processing module is used for enabling the first ventilation module and the second ventilation module to be started when the indoor temperature data exceed a first preset temperature threshold, and enabling the air conditioning module to convey cold air to the interior of the power distribution room and simultaneously close the first ventilation module and the second ventilation module when the received indoor temperature data exceed a second preset temperature threshold. When needing the cooling, cool down through first ventilation module and second ventilation module earlier, then the rethread air conditioning module cools down, and power consumption is few. This application has the effect of saving the electric energy, green.

Description

Energy-saving and electricity-saving temperature control system for power distribution room

Technical Field

The application relates to the field of temperature control of power distribution rooms, in particular to an energy-saving and electricity-saving temperature control system of the power distribution rooms.

Background

Temperature is one of the important factors affecting the safe operation and service life of electrical equipment in a power distribution room. After the electrical equipment is over-heated, equipment protection is stopped, and normal operation of the equipment is influenced; meanwhile, the problems of insulation aging, contact loosening and the like can be accelerated. In order to guarantee normal use of the electrical equipment in the power distribution room, the interior of the power distribution room is cooled in a manual intervention mode, so that the heat dissipation efficiency of the electrical equipment is accelerated.

Among the prior art, reduce the inside temperature of block terminal room through the mode of installation air conditioner to guarantee electrical equipment's radiating efficiency, make electrical equipment temperature be difficult for too high.

In view of the above-mentioned related art, the inventors consider that the use of an air conditioner is large in power consumption and insufficient in energy saving.

SUMMERY OF THE UTILITY MODEL

In order to reduce power consumption and save energy and environment, the application provides an energy-saving and electricity-saving temperature control system for a power distribution room.

The application provides a join in marriage energy-conserving economize on electricity temperature control system of electrical room adopts following technical scheme:

a power distribution room energy-saving and electricity-saving temperature control system comprises a detection module, a control module and a cooling module;

the detection module comprises a first temperature module and a second temperature module, wherein the first temperature module is used for detecting the internal temperature of the power distribution room and generating indoor temperature data;

the cooling module comprises a first ventilation module and a second ventilation module, wherein the first ventilation module is used for forming airflow from air outside the power distribution room and conveying the airflow to the inside of the power distribution room;

the second ventilation module is used for forming air flow in the power distribution room and conveying the air flow to the outside of the power distribution room;

the air conditioning module is used for conveying cold air to the interior of the power distribution room;

the control module comprises a processing module, and the processing module is connected with the first temperature module, the first ventilation module, the second ventilation module and the air conditioning module; the processing module is used for receiving indoor temperature data, the processing module is further used for transmitting a first starting instruction to the first ventilation module and the second ventilation module when the received indoor temperature data exceed a preset first temperature threshold value, so that the first ventilation module and the second ventilation module are started, and transmitting a second starting instruction to the air conditioning module when the received indoor temperature data exceed a preset second temperature threshold value, so that the air conditioning module conveys cold air to the inside of a power distribution room, and the first ventilation module and the second ventilation module are closed simultaneously.

Through adopting above-mentioned technical scheme, join in marriage the indoor temperature of electrical room and rise the back, preferentially use first ventilation module and second ventilation module to dispel the heat, compare in air conditioning module, first ventilation module and second ventilation module power consumption are lower, and energy-concerving and environment-protective saves the electric energy. When first ventilation module and second ventilation module can't satisfy the heat dissipation requirement, close first ventilation module and second ventilation module, reduce the power consumption on the one hand, reduce inside outside air enters into the power distribution room on the one hand, use air conditioning module to cool down. The cooling efficiency of the air conditioning module is ensured, and electricity and energy are saved.

Preferably, the control module further comprises a timing module; the processing module is used for transmitting a timing instruction to the timing module when transmitting a second starting instruction to the air conditioning module; the timing module is used for timing when receiving a timing instruction, and transmitting a stop signal to the processing module when the timing time exceeds a preset timing threshold; the processing module is used for judging whether the indoor temperature data exceeds a first temperature threshold value or not when receiving the shutdown signal, transmitting a shutdown instruction to the air conditioning module if the indoor temperature data does not exceed the first temperature threshold value, enabling the air conditioning module to be closed, and transmitting the shutdown instruction to the air conditioning module until the indoor temperature data is lower than the first temperature threshold value if the indoor temperature data exceeds the first temperature threshold value.

By adopting the technical scheme, after the air conditioner module is started, the timing module performs timing, and the processing module cannot close the air conditioner module within the timing threshold time. The frequent starting and braking of the air conditioning module are avoided, and the electric energy consumption is avoided.

Preferably, the detection module further comprises a second temperature module, which is used for detecting the external temperature of the power distribution room and generating outdoor temperature data; the second temperature module is connected with the processing module and is used for transmitting the generated outdoor temperature data to the processing module; the processing module is used for canceling transmission of the first starting instruction and directly transmitting the second starting instruction to the air conditioning module when the received outdoor temperature data exceeds a preset first temperature threshold.

Through adopting above-mentioned technical scheme, the second temperature module detects the outside temperature of joining in marriage electrical room, and when outside temperature was higher than first temperature threshold value, in time opened first ventilation module and second ventilation module, also hardly played the effect that reduces the inside temperature of joining in marriage electrical room. Therefore, the air conditioning module is directly started, and electric energy required when the first ventilation module and the second ventilation module are started is saved.

Preferably, the control module further comprises a temperature adjusting module for adjusting the set temperature of the air conditioning module; the temperature adjusting module is connected with the processing module and used for presetting time when the air conditioning module is cooled per continuous work preset, and the set temperature of the air conditioning module is increased by 1 degree centigrade or 2 degrees centigrade or 3 degrees centigrade.

By adopting the technical scheme, the temperature set by the air conditioning module is gradually increased along with the prolonging of the opening time of the air conditioning module, the consumption of electric energy is reduced, and the air conditioning module is energy-saving and environment-friendly.

Preferably, the first ventilation module is located at a lower height than the second ventilation module.

Through adopting above-mentioned technical scheme, the cold air is located the hot-air below, and the first module that ventilates is located highly low, makes more cold air enter into and joins in marriage the electrical room inside, and the second module that ventilates is located highly high, makes the hot-air in joining in marriage the electrical room preferentially arrange the external world. The cooling effect of the first ventilation module and the second ventilation module is improved, the use times and the use time of the air conditioner module are reduced, and the air conditioner module is energy-saving and environment-friendly.

Preferably, the first ventilation module comprises a first ventilation hole formed in the wall of the power distribution room, a first fan is arranged in the first ventilation hole, a first sealing plate used for plugging the first ventilation hole is arranged on one side of the first ventilation hole, and the first sealing plate is connected with a first driver; the first fan and the first driver are both connected with the processing module;

the second ventilation module comprises a second ventilation hole formed in the wall of the power distribution room, a second fan is arranged in the second ventilation hole, a second sealing plate used for plugging the second ventilation hole is arranged on one side of the second ventilation hole in a sliding mode, and the second sealing plate is connected with a second driver; and the second fan and the second driver are both connected with the processing module.

Through adopting above-mentioned technical scheme, first fan is used for to the inside air current that carries of electricity distribution room, and the second fan is used for carrying the air current to the electricity distribution room outside, and first closing plate and second closing plate are used for improving the sealed degree of electricity distribution room, guarantee air conditioner module's cooling efficiency. The cold air output by the air conditioning module is prevented from flowing to the outside of the power distribution room from the first ventilation hole or the second ventilation hole, and the energy conservation and the environmental protection are realized.

Preferably, a first sun visor connected with a wall is arranged above the first vent hole; and a second sun shield connected with the wall is arranged above the second ventilation hole.

Through adopting above-mentioned technical scheme, first sunshading board and second sunshading board reduce the sunshine volume that enters into the power distribution room inside, play the cooling effect, energy-concerving and environment-protective.

Preferably, a first filter screen is arranged in the first vent hole, and a second filter screen is arranged in the second vent hole.

Through adopting above-mentioned technical scheme, first filter screen is protected first fan, also helps avoiding joining in marriage the outside debris of electrical room and enter into simultaneously and join in marriage electrical room.

In summary, the present application includes at least one of the following beneficial technical effects:

1. when the temperature needs to be reduced, the temperature is reduced through the first ventilation module and the second ventilation module, and then the temperature is reduced through the air conditioning module, so that the electric energy consumption is low, and the energy is saved and the environment is protected;

2. the timing module reduces the starting frequency of the air conditioning module, reduces the power consumption, and is energy-saving and environment-friendly.

Drawings

FIG. 1 is a block diagram of a power-saving temperature control system for a power distribution room;

FIG. 2 is a schematic structural diagram of an energy-saving and electricity-saving temperature control system of a power distribution room;

FIG. 3 is an enlarged partial schematic view of portion A of FIG. 2;

fig. 4 is a partially enlarged schematic view of a portion B in fig. 2.

Description of reference numerals: 1. a detection module; 11. a first temperature module; 12. a second temperature module; 2. a control module; 21. a processing module; 22. a timing module; 23. a temperature adjustment module; 3. a cooling module; 31. a first ventilation module; 311. a first vent hole; 312. a first fan; 313. a first sealing plate; 314. a first driver; 315. a first visor; 316. a first filter screen; 32. a second ventilation module; 321. a second vent hole; 322. a second fan; 323. a second sealing plate; 324. a second driver; 325. a second visor; 326. a second filter screen; 33. an air conditioning module; 4. a power distribution room; 41. a wall; 42. a distribution box.

Detailed Description

The present application is described in further detail below with reference to figures 1-2.

The power distribution room 4 is of a house structure and is provided with a wall 41, a door and a window, a plurality of power distribution boxes 42 are installed in the power distribution room 4, and a plurality of electrical devices used for adjusting current or voltage are arranged in each power distribution box 42.

The embodiment of the application discloses a power distribution room energy-saving and electricity-saving temperature control system. Referring to fig. 1 and 2, the power-saving and energy-saving temperature control system for the power distribution room comprises a detection module 1, a control module 2 and a cooling module 3. The detection module 1 is used for detecting the temperature inside and outside the power distribution room 4; the control module 2 is used for receiving the detection result of the detection module 1 and controlling the cooling module 3 according to the detection result so as to realize energy-saving cooling; the cooling module 3 is used for cooling the inside of the power distribution room 4, and ensures that the electric equipment in the power distribution room 4 is at normal working temperature.

Referring to fig. 1 and 2, the detection module 1 includes a first temperature module 11 and a second temperature module 12, the first temperature module 11 being configured to detect an internal temperature of the power distribution room 4 and generate indoor temperature data; the second temperature module 12 is used for detecting the temperature outside the power distribution room 4 and generating outdoor temperature data. The control module 2 comprises a processing module 21, a timing module 22 and a temperature adjustment module 23. The cooling module 3 comprises a first ventilation module 31, a second ventilation module 32 and an air conditioning module 33, wherein the first ventilation module 31 is used for forming air flow from the outside of the power distribution room 4 and conveying the air flow into the power distribution room 4; the second ventilation module 32 is used for forming air flow to convey air inside the power distribution room 4 to the outside of the power distribution room 4; the air conditioning module 33 is used to supply cool air to the inside of the power distribution room 4.

Referring to fig. 1 and 2, the first temperature module 11 and the second temperature module 12 are each provided as a temperature sensor. The first temperature modules 11 are installed inside the power distribution room 4, and one of the first temperature modules 11 may be provided. A worker sets the first temperature module 11 close to the center of the power distribution room 4, so that the indoor temperature data generated by the first temperature module 11 can accurately represent the internal temperature of the power distribution room 4, and the heating condition of each electrical device can be accurately represented; in addition, the first temperature module 11 may be provided in plurality. The worker sets the plurality of first temperature modules 11 at each corner and center of the power distribution room 4, or in the vicinity of a place where each electric device is likely to generate heat, respectively, to obtain the indoor temperature data in an averaging manner. The second temperature module 12 is installed outside the power distribution room 4, and in particular, the second temperature module 12 is installed on a wall 41 outside the power distribution room 4.

Referring to fig. 1 and 2, the processing module 21 is provided as a PLC controller, and the processing module 21 may be installed in a worker's work room or inside the distribution room 4. The processing module 21 is connected with the first temperature module 11, the second temperature module 12, the timing module 22, the temperature adjusting module 23, the first ventilation module 31, the second ventilation module 32 and the air conditioning module 33, and the connection mode can be communication connection or signal line connection. The first temperature module 11 transmits the generated indoor temperature data to the processing module 21, and after receiving the indoor temperature data, the processing module 21 compares the indoor temperature data with a preset first temperature threshold. If the indoor temperature data is greater than the first temperature threshold, the processing module 21 transmits a first start instruction to the first ventilation module 31 and the second ventilation module 32, so that the first ventilation module 31 and the second ventilation module 32 are started; if the indoor temperature data is less than or equal to the first temperature threshold, the processing module 21 does not operate.

Referring to fig. 1 and 2, a second temperature threshold is also preset in the processing module 21, and the second temperature threshold is greater than the first temperature threshold. When the indoor temperature data received by the processing module 21 is greater than the second temperature threshold, the processing module 21 transmits a second start instruction to the air conditioning module 33, so that the air conditioning module 33 delivers cool air into the power distribution room 4, and transmits a braking instruction to the first ventilation module 31 and the second ventilation module 32, so that the first ventilation module 31 and the second ventilation module 32 are turned off. It should be noted that the first temperature threshold and the second temperature threshold are set according to the requirements of the operating environment of the electrical equipment in the power distribution room 4. Since the first temperature module 11 detects the temperature inside the power distribution room 4, not the heating place of the electrical equipment. Therefore, when the first temperature threshold and the second temperature threshold are set, the requirements of the working environment of the electrical equipment are required to be smaller, and the electrical equipment can be timely cooled after being heated. In this embodiment, the first temperature threshold is set to 25 degrees celsius and the second temperature threshold is set to 35 degrees celsius.

Referring to fig. 1, while the processing module 21 receives the indoor temperature data, the second temperature module 12 transmits the generated outdoor temperature data to the processing module 21. The processing module 21 compares the received outdoor temperature data with the first temperature threshold, and if the outdoor temperature data is greater than the first temperature threshold, cancels the transmission of the first start instruction, directly transmits the second start instruction to the air conditioning module 33, and simultaneously transmits the braking instruction to the first ventilation module 31 and the second ventilation module 32. Referring to fig. 2, the second temperature module 12 prevents the outdoor hot air from entering the inside of the power distribution room 4, which affects the cooling efficiency.

Referring to fig. 1 and 2, the timing module 22 may be a timer, a chip with a timing function, or an independent timing system. When the control module 2 transmits the second start instruction to the air conditioning module 33, a timing instruction is generated and transmitted to the timing module 22. The timing module 22 starts timing after receiving the timing instruction, and transmits a stop signal to the processing module 21 when the timing time exceeds a preset timing threshold. After receiving the shutdown signal, the processing module 21 compares the received indoor temperature data with the first temperature threshold, and transmits a shutdown instruction to the air conditioning module 33 if the indoor temperature data is less than or equal to the first temperature threshold. After receiving the stop instruction, the air conditioning module 33 stops supplying the cool air to the inside of the power distribution room 4 and turns off. If the indoor temperature data is greater than the first temperature threshold, the processing module 21 transmits a shutdown instruction to the air conditioning module 33 until the indoor temperature data subsequently received by the processing module 21 is greater than the first temperature threshold. Until the processing module 21 does not receive the shutdown signal, the processing module 21 does not transmit a shutdown command to the air conditioning module 33.

Since the air conditioning module 33 needs to consume a large amount of electric energy when being started, in order to avoid frequent starting of the air conditioning module 33, the time interval between two consecutive starts of the air conditioning module 33 is limited by setting the timing module 22 and the timing threshold, so as to achieve the purpose of saving electric energy. The timing threshold is set according to the power consumption condition of the air conditioner starting, namely the larger the power consumption when the air conditioner is started, the larger the value of the timing threshold is. In this embodiment, the timing threshold is set to 3600 seconds. That is, the processing module 21 does not shut down the air conditioning module 33 within 3600 seconds after the air conditioning module 33 is started.

Referring to fig. 1, the temperature adjustment module 23 may be a control chip or a PLC controller. When the processing module 21 transmits the second start instruction to the air conditioning module 33, a temperature adjustment instruction is generated and transmitted to the temperature adjustment module 23. The temperature adjusting module 23 starts timing after receiving the temperature adjusting instruction, and transmits a temperature increasing instruction to the air conditioning module 33 whenever the timing duration of the temperature adjusting module 23 is equal to the preset cooling preset duration, so that the set temperature of the air conditioning module 33 is increased by 1 degree centigrade, 2 degrees centigrade or 3 degrees centigrade. The set temperature of the air conditioning module 33 is the temperature set when the air conditioning module 33 is started, and in this embodiment, the temperature set when the air conditioning module 33 is turned on is 20 degrees celsius, and the temperature adjusting module 23 increases the set temperature of the air conditioning module 33 by 1 degree celsius each time.

Referring to fig. 2, the air conditioning module 33 is provided as a wall-mounted air conditioner or a floor air conditioner, and is installed inside the power distribution room 4. The first ventilation module 31 is located at a lower height than the second ventilation module 32. Referring to fig. 3, the first ventilation module 31 includes a first ventilation hole 311 opened in the wall 41 of the power distribution room 4, a first fan 312 is installed in the first ventilation hole 311, the first fan 312 is activated, and the first fan 312 forms an airflow to convey air outside the power distribution room 4 to the inside of the power distribution room 4. A first driver 314 connected to the wall 41 is provided at one side of the first vent hole 311, and the first driver 314 is configured as a hydraulic cylinder. The output end of the first driver 314 is connected with a first sealing plate 313 slidably disposed on the wall 41, and the first sealing plate 313 is used for blocking the first vent hole 311. The first fan 312 and the first driver 314 are both connected to the processing module 21, and when the processing module 21 transmits a first start instruction to the first ventilation module 31, the first fan 312 is started, and the first driver 314 drives the first sealing plate 313 to move, so that the first ventilation hole 311 is opened; when the processing module 21 transmits a braking instruction to the first ventilation module 31, the first fan 312 brakes, and the first driver 314 drives the first sealing plate 313 to close the first ventilation hole 311.

Referring to fig. 2 and 3, a first filter screen 316 is disposed at an end of the first vent hole 311 near the outside of the power distribution room 4, and a first shade 315 connected to the outer wall 41 of the power distribution room 4 is disposed above the first vent hole 311.

Referring to fig. 4, the second ventilation module 32 includes a second ventilation hole 321 opened in the wall 41 of the power distribution room 4, a second fan 322 is installed in the second ventilation hole 321, the second fan 322 is started, and the second fan 322 forms an airflow to convey the air inside the power distribution room 4 to the outside of the power distribution room 4. A second actuator 324 connected to the inner wall 41 of the distribution room 4 is provided at one side of the second vent hole 321, and the second actuator 324 is a hydraulic cylinder. The output end of the second driver 324 is connected with a second sealing plate 323 arranged in a sliding manner with the wall 41, and the second sealing plate 323 is used for sealing the second vent hole 321. Referring to fig. 2, the second fan 322 and the second driver 324 are both connected to the processing module 21, and when the processing module 21 transmits a first start instruction to the second ventilation module 32, the second fan 322 is started, and the second driver 324 drives the second sealing plate 323 to move, so that the second ventilation hole 321 is opened; when the processing module 21 transmits a braking instruction to the second ventilation module 32, the second fan 322 brakes, and the second driver 324 drives the second sealing plate 323 to seal the second ventilation hole 321.

Referring to fig. 4, a second filter 326 is disposed at one end of the second vent hole 321 near the outside of the power distribution room 4, and a second shade 325 connected to the outer wall 41 of the power distribution room 4 is disposed above the second vent hole 321.

The implementation principle of the power-saving and energy-saving temperature control system of the power distribution room in the embodiment of the application is as follows: after receiving the indoor temperature data, the processing module 21 compares the indoor temperature data with a first temperature threshold and a second temperature threshold, and if the indoor temperature data is between the first temperature threshold and the second temperature threshold, the processing module 21 starts the first ventilation module 31 and the second ventilation module 32; if the indoor temperature data exceeds the second temperature threshold, the processing module 21 turns off the first and second ventilation modules 31 and 32 and turns on the air conditioning module 33. According to 4 inside temperatures in the room that join in marriage, the cooling mode of preferred use comparatively power saving saves the electric energy, green.

The above embodiments are preferred embodiments of the present application, and the protection scope of the present application is not limited by the above embodiments, so: all equivalent changes made according to the structure, shape and principle of the present application shall be covered by the protection scope of the present application.

Claims (8)

1. The utility model provides a join in marriage energy-conserving economize on electricity temperature control system of electrical room which characterized in that: comprises a detection module (1), a control module (2) and a cooling module (3);

the detection module (1) comprises a first temperature module (11) for detecting the internal temperature of the power distribution room (4) and generating indoor temperature data;

the cooling module (3) comprises a first ventilation module (31) which is used for forming airflow for conveying air outside the power distribution room (4) to the interior of the power distribution room (4);

the second ventilation module (32) is used for forming air flow inside the power distribution room (4) and conveying the air flow outside the power distribution room (4);

an air conditioning module (33) for delivering cold air to the interior of the power distribution room (4);

the control module (2) comprises a processing module (21), and the processing module (21) is connected with the first temperature module (11), the first ventilation module (31), the second ventilation module (32) and the air conditioning module (33); the processing module (21) is used for receiving indoor temperature data, the processing module (21) is further used for transmitting a first starting instruction to the first ventilation module (31) and the second ventilation module (32) when the received indoor temperature data exceed a first preset temperature threshold value, so that the first ventilation module (31) and the second ventilation module (32) are started, transmitting a second starting instruction to the air conditioning module (33) when the received indoor temperature data exceed a second preset temperature threshold value, so that the air conditioning module (33) conveys cold air to the inside of the power distribution room (4), and simultaneously the first ventilation module (31) and the second ventilation module (32) are closed.

2. The power-saving and electricity-saving temperature control system for the power distribution room according to claim 1, characterized in that: the control module (2) further comprises a timing module (22); the processing module (21) is used for transmitting a timing instruction to the timing module (22) when transmitting a second starting instruction to the air conditioning module (33); the timing module (22) is used for timing when receiving a timing instruction, and transmitting a stop signal to the processing module (21) when the timing time exceeds a preset timing threshold; the processing module (21) is used for judging whether the indoor temperature data exceeds a first temperature threshold value or not when receiving the shutdown signal, transmitting a shutdown instruction to the air conditioning module (33) if the indoor temperature data does not exceed the first temperature threshold value, enabling the air conditioning module (33) to be closed, and transmitting the shutdown instruction to the air conditioning module (33) until the indoor temperature data is lower than the first temperature threshold value if the indoor temperature data exceeds the first temperature threshold value.

3. The power-saving and electricity-saving temperature control system for the power distribution room according to claim 2, characterized in that: the detection module (1) further comprises a second temperature module (12) for detecting the external temperature of the power distribution room (4) and generating outdoor temperature data; the second temperature module (12) is connected with the processing module (21), and the second temperature module (12) is used for transmitting the generated outdoor temperature data to the processing module (21); the processing module (21) is used for canceling the transmission of the first starting instruction and directly transmitting the second starting instruction to the air conditioning module (33) when the received outdoor temperature data exceeds a preset first temperature threshold.

4. The power-saving and electricity-saving temperature control system for the power distribution room according to claim 3, characterized in that: the control module (2) further comprises a temperature adjusting module (23) for adjusting the set temperature of the air conditioning module (33); the temperature regulation module (23) is connected with the processing module (21), and the temperature regulation module (23) is used for presetting time length when the preset temperature reduction of each continuous work of the air conditioning module (33) is realized, so that the set temperature of the air conditioning module (33) is increased by 1 degree centigrade or 2 degrees centigrade or 3 degrees centigrade.

5. The power-saving and electricity-saving temperature control system for the power distribution room according to claim 1, characterized in that: the first ventilation module (31) is located at a lower height than the second ventilation module (32).

6. The power-saving and electricity-saving temperature control system for the power distribution room according to claim 5, characterized in that: the first ventilation module (31) comprises a first ventilation hole (311) formed in a wall (41) of the power distribution room (4), a first fan (312) is arranged in the first ventilation hole (311), a first sealing plate (313) used for blocking the first ventilation hole (311) is arranged on one side of the first ventilation hole (311), and a first driver (314) is connected to the first sealing plate (313); the first fan (312) and the first driver (314) are both connected with the processing module (21);

the second ventilation module (32) comprises a second ventilation hole (321) formed in a wall (41) of the power distribution room (4), a second fan (322) is arranged in the second ventilation hole (321), a second sealing plate (323) used for sealing the second ventilation hole (321) is arranged on one side of the second ventilation hole (321) in a sliding mode, and the second sealing plate (323) is connected with a second driver (324); the second fan (322) and the second driver (324) are both connected with the processing module (21).

7. The power-saving and electricity-saving temperature control system for the power distribution room according to claim 6, characterized in that: a first sun shield (315) connected with a wall (41) is arranged above the first vent hole (311); and a second sun shield (325) connected with the wall (41) is arranged above the second ventilation hole (321).

8. The power-saving and electricity-saving temperature control system for the power distribution room according to claim 6, characterized in that: a first filter screen (316) is arranged in the first vent hole (311), and a second filter screen (326) is arranged in the second vent hole (321).

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