CN118137325A - Temperature real-time supervision formula intelligent power distribution cabinet based on thing networking - Google Patents

Abstract

The invention relates to the technical field of power distribution cabinets, in particular to a temperature real-time monitoring type intelligent power distribution cabinet based on the Internet of things, which comprises a power distribution cabinet body, an adjusting structure, a temperature sensor, a limiting structure, an opening and closing structure, a ventilation structure, a cooling structure, an air pump and a fan, wherein the adjusting structure is convenient to adjust the position of the temperature sensor, is convenient to monitor the temperature of local components in the power distribution cabinet, improves the accuracy of temperature monitoring, can effectively avoid the shielding between the temperature sensor and the components, is convenient to detach the temperature sensor for maintenance, is convenient to control the circulation of gas, realizes the purpose of controlling the circulation of gas to cool after the temperature abnormality is monitored, saves energy sources, has strong flexibility, and is convenient to cool the components with the temperature abnormality due to the setting of the cooling structure, and is simple and convenient to operate.

Description

Temperature real-time supervision formula intelligent power distribution cabinet based on thing networking

Technical Field

The invention relates to the technical field of power distribution cabinets, in particular to an intelligent power distribution cabinet based on real-time temperature monitoring of the Internet of things.

Background

The power distribution cabinet is upper-layer power distribution equipment of the power distribution cabinet, is multipurpose in centralized power supply, is complete switch equipment and control equipment, is mainly used as a power center and a main power distribution device, and is mainly used for controlling, monitoring, measuring and the like of a power line and main electric equipment.

The temperature of components in the power distribution cabinet needs to be monitored in real time in the use process of the traditional power distribution cabinet, however, the temperature sensor is usually arranged at a designated position, and because the number of the components in the power distribution cabinet is large, when the temperature of the local components rises due to loosening of a power line connector, the temperature sensor is constant in position, and the internal space of the power distribution cabinet is large, so that the temperature of the components at different positions is inconvenient to monitor;

When the power distribution cabinet radiates heat, the internal air is usually caused to flow through the two fans inside, so that the internal heat gas is taken away to achieve the heat radiation effect, but if the local components inside the power distribution cabinet are overheated, the local components are difficult to achieve the effect of cooling immediately only through the flowing gas, and the heat radiation effect is poor;

And temperature sensor installs on the switch board lateral wall through a plurality of bolts, when needing to regularly overhaul and maintain temperature sensor, because the bolt is installed at the lateral wall, the inner space is less, and the bolt receives to shelter from easily, leads to inconvenient dismouting.

Disclosure of Invention

Aiming at the problems in the prior art, the invention provides a temperature real-time monitoring type intelligent power distribution cabinet based on the Internet of things.

The technical scheme adopted for solving the technical problems is as follows: the utility model provides a temperature real-time supervision formula intelligent power distribution cabinet based on thing networking, includes the switch board body, install in adjust structure on the switch board body, install in temperature sensor on adjust structure, locate limit structure on the adjust structure, install in on-off structure on adjust structure, locate ventilation structure on adjust structure, locate the cooling structure on adjust structure, install air pump on the switch board body and install the fan on the switch board body;

The utility model provides a temperature sensor, including the switch board body, the switch board body is installed to the switch board body, the inside fixedly connected with of switch board body is two mounting brackets, left the first motor of mounting bracket bottom mounting, the output shaft fixedly connected with second lead screw of first motor, the top of second lead screw rotates to be connected in the mounting bracket, threaded connection has first slider on the second lead screw, first slider sliding connection is in the mounting bracket, the right side sliding connection has the second slider on the mounting bracket, equal sliding connection has a slide bar on first slider and the second slider, left side slide bar front end threaded connection has a connecting cap, right side slide bar front end sliding connection has a connecting cap, two be connected with the installation pole between the connecting cap, the second motor is installed in the left side of installation pole, the output shaft fixedly connected with first lead screw of second motor, the other end of first lead screw rotates to be connected in the installation pole, threaded connection has the installation piece on the first lead screw, installation piece sliding connection is in the installation piece, install temperature sensor on the installation piece.

Specifically, the installation rod is rotationally connected with the left connecting cap and is fixedly connected with the right connecting cap.

Specifically, the installation piece is "protruding" font structure, cooperate with limit structure on the first slider.

Specifically, limit structure includes spacing and is fixed in the arm-tie on the spacing, sliding connection has spacing on the first slider, fixedly connected with extension spring between first slider and the arm-tie, a plurality of spacing holes have been seted up on the slide bar, spacing block is in one of them spacing hole.

Specifically, the opening and closing structure includes the second guide bar and sets up the first air cavity on the second guide bar, the right side fixedly connected with second guide bar on the mounting bracket, sliding connection has a plurality of rubber plugs on the second guide bar, the outside rotation of rubber plug is connected with the ball, fixedly connected with spring between the inboard of rubber plug and the second guide bar, sliding connection has the second slider on the second guide bar, the second air cavity has been seted up on the second slider, fixedly connected with connecting net on the lateral wall of second air cavity and the contact of second guide bar, connecting net sliding connection is in the second guide bar.

Specifically, the first air cavity is communicated with the air outlet hole of the air pump through a pipeline, and the rubber plug is of a truncated cone-shaped structure.

Specifically, the ventilation structure comprises a first connecting pipe and a rubber pipe connected to the first connecting pipe, the first connecting pipe is fixedly connected to the second sliding block, one wire distribution frame is fixedly connected to the second sliding block and the mounting rod, and the rubber pipe penetrates through the two wire distribution frames respectively.

Specifically, the first connecting pipe is communicated with the second air cavity, and the other end of the rubber pipe is connected with the cooling structure.

Specifically, the cooling structure includes the go-between and sets up in the inside third air cavity of go-between, fixedly connected with go-between on the installation piece, the air vent has been seted up on the go-between, the air vent communicates in the third air cavity, fixedly connected with second connecting pipe on the go-between, the second connecting pipe communicates in the third air cavity, be connected with the rubber tube on the second connecting pipe.

Specifically, fixedly connected with support ring on the second connecting pipe, the rubber tube runs through in the support ring, the air vent is "T" font structure.

The beneficial effects of the invention are as follows:

(1) According to the intelligent power distribution cabinet based on the temperature real-time monitoring of the Internet of things, the regulating structure is arranged on the power distribution cabinet body, the temperature sensor is arranged on the regulating structure, the position of the temperature sensor is conveniently regulated by the setting of the regulating structure, the monitoring of the temperature of local components in the power distribution cabinet is facilitated, and the accuracy of temperature monitoring is improved.

(2) According to the temperature real-time monitoring type intelligent power distribution cabinet based on the Internet of things, the limiting structure is arranged on the adjusting structure, the limiting structure can effectively prevent the temperature sensor and the components from shielding each other, and meanwhile the temperature sensor is convenient to detach and maintain.

(3) According to the intelligent power distribution cabinet based on the real-time temperature monitoring of the Internet of things, the opening and closing structure is arranged on the adjusting structure, the opening and closing structure is arranged to control the circulation of gas conveniently, the purpose of controlling the circulation of gas to cool after the abnormal temperature is monitored is achieved, energy sources are saved, and the flexibility is high.

(4) According to the intelligent power distribution cabinet based on the real-time temperature monitoring of the Internet of things, the ventilation structure is arranged on the adjusting structure and is matched with the cooling structure for use, and the cooling structure is convenient to cool and treat components with abnormal temperature, so that the operation is simple and convenient.

Drawings

The invention will be further described with reference to the drawings and examples.

Fig. 1 is a schematic diagram of the overall structure of a preferred embodiment of an intelligent power distribution cabinet based on real-time temperature monitoring of the internet of things;

FIG. 2 is a schematic diagram of a connection structure between a mounting frame and a first slider according to the present invention;

FIG. 3 is an enlarged schematic view of the portion A shown in FIG. 2;

FIG. 4 is an enlarged schematic view of the structure of the portion B shown in FIG. 2;

FIG. 5 is a schematic diagram of a connection structure of a first slider and a slider according to the present invention;

FIG. 6 is a schematic view of the connection structure of the mounting rod and the connecting ring according to the present invention;

FIG. 7 is a schematic view of a connection structure between a first screw and a mounting block according to the present invention;

FIG. 8 is a schematic diagram of a connection structure of a connection ring and a second connection pipe according to the present invention;

FIG. 9 is a schematic diagram of a connection structure between a second slider and a second guide bar according to the present invention;

Fig. 10 is an enlarged schematic view of the C-section structure shown in fig. 9.

In the figure: 1. a power distribution cabinet body; 2. an adjustment structure; 201. a mounting frame; 202. a first guide bar; 203. a first motor; 204. a first slider; 205. a second slider; 206. a slide bar; 207. a connecting cap; 208. a mounting rod; 209. a second motor; 210. a first screw rod; 211. a mounting block; 212. a second screw rod; 3. a temperature sensor; 4. a limit structure; 401. a limit bar; 402. pulling a plate; 403. a tension spring; 404. a limiting hole; 5. an opening and closing structure; 501. a second guide bar; 502. a first air chamber; 503. a rubber stopper; 504. a ball; 505. a spring; 506. a second air chamber; 507. a connecting net; 6. a ventilation structure; 601. a first connection pipe; 602. a rubber tube; 603. a wire distribution frame; 7. a cooling structure; 701. a connecting ring; 702. a third air chamber; 703. a vent hole; 704. a second connection pipe; 705. a support ring; 8. an air pump; 9. a fan.

Detailed Description

The invention is further described in connection with the following detailed description in order to make the technical means, the creation characteristics, the achievement of the purpose and the effect of the invention easy to understand.

As shown in fig. 1-10, the real-time temperature monitoring type intelligent power distribution cabinet based on the internet of things comprises a power distribution cabinet body 1, an adjusting structure 2 arranged on the power distribution cabinet body 1, a temperature sensor 3 arranged on the adjusting structure 2, a limiting structure 4 arranged on the adjusting structure 2, an opening and closing structure 5 arranged on the adjusting structure 2, a ventilation structure 6 arranged on the adjusting structure 2, a cooling structure 7 arranged on the adjusting structure 2, an air pump 8 arranged on the power distribution cabinet body 1 and a fan 9 arranged on the power distribution cabinet body 1, wherein the temperature sensor 3 is arranged on the adjusting structure 2; the adjusting structure 2 comprises a mounting frame 201 and a first guide rod 202 arranged on the mounting frame 201, two mounting frames 201 are fixedly connected in the power distribution cabinet body 1, a first motor 203 is arranged at the bottom of the mounting frame 201 on the left side, a second screw rod 212 is fixedly connected with an output shaft of the first motor 203, the top end of the second screw rod 212 is rotationally connected with the mounting frame 201, a first sliding block 204 is connected with the second screw rod 212 in a threaded manner, the first sliding block 204 is connected with the mounting frame 201 in a sliding manner, a second sliding block 205 is connected with the mounting frame 201 on the right side in a sliding manner, a sliding rod 206 is slidably connected to the first sliding block 204 and the second sliding block 205, a connecting cap 207 is screwed at the front end of the left sliding rod 206, a connecting cap 207 is slidably connected to the front end of the right sliding rod 206, a mounting rod 208 is connected between the two connecting caps 207, a second motor 209 is mounted on the left side of the mounting rod 208, a first screw rod 210 is fixedly connected to an output shaft of the second motor 209, the other end of the first screw rod 210 is rotatably connected to the mounting rod 208, a mounting block 211 is screwed on the first screw rod 210, the mounting block 211 is slidably connected to the mounting rod 208, the temperature sensor 3 is mounted on the mounting block 211, the mounting rod 208 is rotatably connected with the left connecting cap 207 and fixedly connected with the right connecting cap 207, the mounting block 211 is in a convex structure, and the first sliding block 204 is matched with the limiting structure 4; after the installation of components in the power distribution cabinet body 1 is completed, the temperature sensor 3 monitors the temperature of the internal space and the components in real time when the power distribution cabinet body 1 works, firstly, the first motor 203 drives the second screw rod 212 to rotate, because the second screw rod 212 is connected with the first sliding block 204 in a threaded manner, and then the second screw rod 212 drives the first sliding block 204 to move downwards along the first guide rod 202, the first sliding block 204 drives the sliding rod 206 and the connecting cap 207 to move downwards, because the first sliding block 204 is indirectly connected with the second sliding block 205 through the mounting rod 208, and then the second sliding block 205 is driven to move downwards along the inner wall of the mounting rack 201 in the downward moving process of the first sliding block 204, thereby driving the temperature sensor 3 arranged on the mounting rod 208 to move downwards, simultaneously driving the first screw rod 210 to rotate by the second motor 209 in the mounting rod 208, driving the mounting block 211 to slide left and right together with the temperature sensor 3 by the first screw rod 210, when the mounting rod 208 moves downwards to the component mounting position, driving the mounting block 211 and the temperature sensor 3 to move rightwards by the second motor 209, thereby effectively monitoring the temperature of the component joint in the moving direction of the temperature sensor 3, when the temperature of the component joint in the moving direction is normal, continuously driving the temperature sensor 3 to move downwards by the first motor 203 to monitor the temperature of the component joint in the next row, meanwhile, the second motor 209 drives the temperature sensor 3 to transversely move to check the temperature of all the joints of the components in the transverse direction, so that the temperature of the joints of the local components is effectively monitored by moving the position of the temperature sensor 3, the temperature monitoring accuracy is improved, and the flexibility is high.

Specifically, as shown in fig. 4 and fig. 5, the limiting structure 4 includes a limiting bar 401 and a pull plate 402 fixed on the limiting bar 401, the first slider 204 is slidably connected with the limiting bar 401, a tension spring 403 is fixedly connected between the first slider 204 and the pull plate 402, a plurality of limiting holes 404 are formed in the sliding bar 206, and the limiting bar 401 is engaged with one of the limiting holes 404; when components with different sizes are installed, in order to avoid the shielding between the installation rod 208 and the components, only the pull plate 402 is pulled upwards, the pull plate 402 stretches the tension spring 403 and drives the limit bar 401 to separate from the limit hole 404 on the slide bar 206, the installation rod 208 is pulled outwards again, the pull plate 402 is loosened after the installation rod 208 is pulled to a proper position, the limit bar 401 is driven to be clamped with another limit hole 404 on the slide bar 206 under the reset action of the tension spring 403, so that the position of the installation rod 208 is effectively fixed, and the connecting cap 207 on the left side of the knob is used for accurately adjusting the distance between the temperature sensor 3 and the components due to the threaded connection between the connecting cap 207 on the left side and the end part of the slide bar 206, and the monitoring precision of the temperature sensor 3 is improved.

Specifically, as shown in fig. 9 and 10, the opening and closing structure 5 includes a second guide rod 501 and a first air cavity 502 formed on the second guide rod 501, the right side is fixedly connected with the second guide rod 501 on the mounting rack 201, the second guide rod 501 is slidably connected with a plurality of rubber plugs 503, the outer side of the rubber plugs 503 is rotatably connected with balls 504, a spring 505 is fixedly connected between the inner side of the rubber plugs 503 and the second guide rod 501, the second guide rod 501 is slidably connected with a second slider 205, a second air cavity 506 is formed on the second slider 205, a connecting net 507 is fixedly connected on a side wall of the second air cavity 506 contacted with the second guide rod 501, the connecting net 507 is slidably connected with the second guide rod 501, the first air cavity 502 is mutually communicated with air outlet holes of the air pump 8 through pipelines, and the rubber plugs 503 are in a truncated cone-shaped structure; the inside two fans 9 of installing in switch board body 1 make the inside space gas flow of switch board body 1 after the operation, simultaneously when temperature sensor 3 monitors that a certain components and parts joint department is unusual, this moment second slider 205 no longer takes place relative slip with second guide bar 501, because first air cavity 502 has been seted up to the inside of second guide bar 501, and second guide bar 501 corresponds the department with components and parts mounted position and all is equipped with rubber buffer 503, when temperature sensor 3 detects the temperature unusual, this moment first motor 203 stops rotating, and air pump 8 begins to move, thereby air pump 8 carries gas to first air cavity 502, first motor 203 no longer drives the ball 504 in the outside of second slider 205, make rubber buffer 503 inwards squeeze spring 505, because rubber buffer 503 is round platform shape structure this moment, there is the space between the inner wall of rubber buffer 503 and second guide bar 501 this moment, first air cavity 502 communicates each other through this department gap and connecting net 507 and second air cavity 506, thereby be convenient for follow-up through the gas to carry out the local circulation to the air pump 8 through the component joint to the position that has realized the heat dissipation effect of cooling down when the second is realized to the component joint, therefore the local circulation of air pump 8 has been realized.

Specifically, as shown in fig. 3, 9 and 10, the ventilation structure 6 includes a first connection pipe 601 and a rubber pipe 602 connected to the first connection pipe 601, the second slider 205 is fixedly connected with the first connection pipe 601, the second slider 205 and the mounting rod 208 are both fixedly connected with a wire distribution frame 603, the rubber pipe 602 respectively penetrates through the two wire distribution frames 603, the first connection pipe 601 is communicated with the second air cavity 506, and the other end of the rubber pipe 602 is connected to the cooling structure 7; the gas flows into the rubber tube 602 through the first connecting tube 601, and meanwhile, the arrangement of the wire distribution frame 603 and the supporting ring 705 can avoid the problem of winding the rubber tube 602 caused by the movement of the connecting ring 701.

Specifically, as shown in fig. 2, fig. 4, fig. 6, fig. 7, and fig. 8, the cooling structure 7 includes a connection ring 701 and a third air cavity 702 formed inside the connection ring 701, the connection ring 701 is fixedly connected to the mounting block 211, a vent hole 703 is formed in the connection ring 701, the vent hole 703 is communicated with the third air cavity 702, a second connection pipe 704 is fixedly connected to the connection ring 701, the second connection pipe 704 is communicated with the third air cavity 702, a rubber pipe 602 is connected to the second connection pipe 704, a support ring 705 is fixedly connected to the second connection pipe 704, the rubber pipe 602 penetrates through the support ring 705, and the vent hole 703 is in a T-shaped structure; after the external air flows into the second air cavity 506, the external air flows into the rubber tube 602 through the first connecting tube 601, flows into the third air cavity 702 inside the connecting ring 701 through the rubber tube 602 and the second connecting tube 704, and is blown out through the vent holes 703 obliquely arranged on the connecting ring 701, so that the local component joint is effectively cooled, and the cooling effect is improved.

When the temperature sensor device is used, after components in the power distribution cabinet body 1 are installed, the temperature sensor 3 in the power distribution cabinet body 1 monitors the temperature of an inner space and components in real time during operation, first, the first motor 203 drives the second screw rod 212 to rotate, as the first screw rod 204 is connected with the second screw rod 212 through threads, and then the second screw rod 212 drives the first slide rod 204 to move downwards along the first guide rod 202, the first slide rod 204 drives the slide rod 206 and the connecting cap 207 to move downwards, and as the first slide rod 204 is connected with the second slide rod 205 indirectly through the mounting rod 208, the second slide rod 205 is driven to move downwards along the inner wall of the mounting frame 201 in the process of downward movement of the first slide rod 204, so that the temperature sensor 3 mounted on the mounting rod 208 is driven to move downwards, and meanwhile, the first screw rod 210 drives the mounting block 211 and the temperature sensor 3 to slide left and right, and when the mounting rod 208 moves downwards to the components, the temperature sensor 3 is driven to move upwards, and the temperature sensor 3 is driven to move downwards along the inner wall of the mounting frame 201, and the temperature sensor 3 is driven to move downwards, and the temperature sensor 3 is detected to move horizontally, and the temperature sensor 3 is detected;

When components with different sizes are installed, in order to avoid the mutual shielding between the installation rod 208 and the components, only the pull plate 402 is pulled upwards, so that the pull plate 402 stretches the tension spring 403 and drives the limit bar 401 to separate from the limit hole 404 on the slide bar 206, then the installation rod 208 is pulled outwards, when the installation rod 208 is pulled to a proper position, the pull plate 402 is loosened, the limit bar 401 is driven to be clamped with the other limit hole 404 on the slide bar 206 under the reset action of the tension spring 403, thereby effectively fixing the position of the installation rod 208, and then the distance between the temperature sensor 3 and the components is accurately adjusted and the monitoring precision of the temperature sensor 3 is improved through the connecting cap 207 on the left side of the knob due to the threaded connection between the connecting cap 207 on the left side and the end part of the slide bar 206;

The two fans 9 arranged in the power distribution cabinet body 1 run to enable gas in the internal space of the power distribution cabinet body 1 to flow, meanwhile, when the temperature sensor 3 monitors that the temperature of a joint of a certain component is abnormal, the second slider 205 does not slide relative to the second guide rod 501, because the first air cavity 502 is formed in the second guide rod 501, and the corresponding parts of the second guide rod 501 and the component mounting position are respectively provided with the rubber plug 503, when the temperature sensor 3 detects that the temperature is abnormal, the first motor 203 stops rotating, the air pump 8 starts to run, the air pump 8 conveys gas into the first air cavity 502, the first motor 203 does not drive the second slider 205 to slide downwards, meanwhile, the connecting net 507 arranged on the second slider 205 is abutted against the balls 504 on the outer side of the rubber plug 503, so that the rubber plug 503 is inwards extruded with the spring 505, and because the rubber plug 503 is of a round table-shaped structure, a gap exists between the rubber plug 503 and the inner wall of the second guide rod 501, the first air cavity 502 is communicated with the second air cavity 506 through the gap and the connecting net 507, when the temperature sensor 3 detects the temperature is abnormal, the first air pump 203 stops rotating, the air pump 8 starts to run, the air pump 8 is conveyed into the first air cavity 502, the air pump is not conveniently, the heat dissipation effect is improved, and the air pump is cooled down, and the air is cooled down by the local cooling effect is realized, and the air is not cooled down by the special position, and the air pump is conveniently cooled down when the air is realized, and the air is cooled down by the special when the position is at the position of the air pump, and the air pump is cooled down;

After external air flows into the second air cavity 506, the external air flows into the rubber tube 602 through the first connecting tube 601, flows into the third air cavity 702 inside the connecting ring 701 through the rubber tube 602 and the second connecting tube 704, and is blown out through the vent holes 703 obliquely arranged on the connecting ring 701, so that the local component joint is effectively cooled, the cooling effect is improved, and meanwhile, the problem that the rubber tube 602 is wound due to the movement of the connecting ring 701 can be avoided due to the arrangement of the wire distribution frame 603 and the supporting ring 705.

It will be evident to those skilled in the art that the invention is not limited to the details of the foregoing illustrative embodiments, and that the present invention may be embodied in other specific forms without departing from the spirit or essential characteristics thereof. The present embodiments are, therefore, to be considered in all respects as illustrative and not restrictive, the scope of the invention being indicated by the appended claims rather than by the foregoing description, and all changes which come within the meaning and range of equivalency of the claims are therefore intended to be embraced therein. Any reference sign in a claim should not be construed as limiting the claim concerned.

Furthermore, it should be understood that although the present disclosure describes embodiments, not every embodiment is provided with a separate embodiment, and that this description is provided for clarity only, and that the disclosure is not limited to the embodiments described in detail below, and that the embodiments described in the examples may be combined as appropriate to form other embodiments that will be apparent to those skilled in the art.

Claims (10)

1. The utility model provides a temperature real-time supervision formula intelligent power distribution cabinet based on thing networking, its characterized in that, including switch board body (1), install in adjust structure (2) on switch board body (1), install in temperature sensor (3) on adjust structure (2), locate limit structure (4) on adjust structure (2), install in open and close structure (5) on adjust structure (2), locate ventilation structure (6) on adjust structure (2), locate cooling structure (7) on adjust structure (2), install air pump (8) on switch board body (1) and install fan (9) on switch board body (1);

the adjusting structure (2) comprises a mounting frame (201) and a first guide rod (202) arranged on the mounting frame (201), two mounting frames (201) are fixedly connected to the inside of the power distribution cabinet body (1), a first motor (203) is arranged at the bottom of the mounting frame (201) on the left side, a second screw rod (212) is fixedly connected to an output shaft of the first motor (203), the top end of the second screw rod (212) is rotationally connected to the mounting frame (201), a first sliding block (204) is connected to the second screw rod (212) in a threaded manner, the first sliding block (204) is slidingly connected to the mounting frame (201), a second sliding block (205) is slidingly connected to the right side on the mounting frame (201), a sliding rod (206) is slidingly connected to the first sliding block (204) and the second sliding block (205), a connecting cap (207) is connected to the front end of the sliding rod (206) on the right side in a threaded manner, a first connecting cap (207) is slidingly connected to the front end of the sliding rod (206), a second screw rod (210) is connected to the other end of the second connecting cap (208), the first screw rod (210) is connected with a mounting block (211) in a threaded mode, the mounting block (211) is connected with a mounting rod (208) in a sliding mode, and the mounting block (211) is provided with a temperature sensor (3).

2. The intelligent power distribution cabinet based on real-time temperature monitoring of thing networking of claim 1, its characterized in that: the mounting rod (208) is rotationally connected with the left connecting cap (207) and is fixedly connected with the right connecting cap (207).

3. The intelligent power distribution cabinet based on real-time temperature monitoring of thing networking of claim 1, its characterized in that: the mounting block (211) is of a convex structure, and the first sliding block (204) is matched with the limiting structure (4).

4. The intelligent power distribution cabinet based on real-time temperature monitoring of thing networking according to claim 3, wherein: the limiting structure (4) comprises a limiting strip (401) and a pulling plate (402) fixed on the limiting strip (401), the limiting strip (401) is connected to the first slider (204) in a sliding mode, a tension spring (403) is fixedly connected between the first slider (204) and the pulling plate (402), a plurality of limiting holes (404) are formed in the sliding rod (206), and the limiting strip (401) is clamped in one of the limiting holes (404).

5. The intelligent power distribution cabinet based on real-time temperature monitoring of thing networking of claim 1, its characterized in that: the opening and closing structure (5) comprises a second guide rod (501) and a first air cavity (502) formed in the second guide rod (501), the second guide rod (501) is fixedly connected to the right side of the mounting frame (201), a plurality of rubber plugs (503) are connected to the second guide rod (501) in a sliding mode, balls (504) are connected to the outer sides of the rubber plugs (503) in a rotating mode, springs (505) are fixedly connected between the inner sides of the rubber plugs (503) and the second guide rod (501), a second slider (205) is connected to the second guide rod (501) in a sliding mode, a second air cavity (506) is formed in the second slider (205), and a connecting net (507) is fixedly connected to the side wall, in contact with the second guide rod (501), of the second air cavity (506).

6. The intelligent power distribution cabinet based on real-time temperature monitoring of thing networking of claim 5, its characterized in that: the first air cavity (502) is communicated with the air outlet hole of the air pump (8) through a pipeline, and the rubber plug (503) is of a truncated cone-shaped structure.

7. The intelligent power distribution cabinet based on real-time temperature monitoring of thing networking of claim 1, its characterized in that: the ventilation structure (6) comprises a first connecting pipe (601) and a rubber pipe (602) connected to the first connecting pipe (601), the first connecting pipe (601) is fixedly connected to the second sliding block (205), one wire distribution frame (603) is fixedly connected to the second sliding block (205) and the mounting rod (208), and the rubber pipe (602) penetrates through the two wire distribution frames (603) respectively.

8. The intelligent power distribution cabinet based on real-time temperature monitoring of internet of things of claim 7, wherein: the first connecting pipe (601) is communicated with the second air cavity (506), and the other end of the rubber pipe (602) is connected with the cooling structure (7).

9. The intelligent power distribution cabinet based on real-time temperature monitoring of thing networking of claim 1, its characterized in that: the cooling structure (7) comprises a connecting ring (701) and a third air cavity (702) formed in the connecting ring (701), the connecting ring (701) is fixedly connected to the mounting block (211), an air vent (703) is formed in the connecting ring (701), the air vent (703) is communicated with the third air cavity (702), a second connecting pipe (704) is fixedly connected to the connecting ring (701), the second connecting pipe (704) is communicated with the third air cavity (702), and a rubber pipe (602) is connected to the second connecting pipe (704).

10. The intelligent power distribution cabinet based on real-time temperature monitoring of internet of things of claim 9, wherein: the second connecting pipe (704) is fixedly connected with a supporting ring (705), the rubber pipe (602) penetrates through the supporting ring (705), and the vent hole (703) is of a T-shaped structure.