CN116471796A - Industrial Internet of things switch control cabinet capable of efficiently radiating heat - Google Patents

Abstract

The invention relates to the technical field of industrial Internet of things gateway equipment, in particular to an industrial Internet of things gateway control cabinet capable of efficiently radiating heat, which comprises a cabinet body and a cooling device; the radiating water tank is arranged below the cabinet body, and cooling water is filled in the radiating water tank; the circulating device is arranged on the side wall of the radiating water tank, and the cooling water is pumped out from the radiating water tank under the action of the circulating device and flows through the interior of the cabinet body and finally flows back into the radiating water tank; the water inlet and outlet assembly is arranged on the side wall of the radiating water tank; the first temperature sensor is arranged at the bottom of the radiating water tank and is used for monitoring the temperature of cooling liquid in the radiating water tank, the cabinet body is provided with a controller, and the first temperature sensor controls the water inlet and outlet assembly to operate through the controller; the water level sensor is arranged on the inner wall of the radiating water tank and is used for monitoring the liquid level height of cooling liquid in the radiating water tank, and the water level sensor controls the operation of the water inlet and outlet assembly through the controller, so that the stability of the cooling effect of the cooling device is ensured.

Description

Industrial Internet of things switch control cabinet capable of efficiently radiating heat

Technical Field

The invention relates to the technical field of industrial Internet of things gateway equipment, in particular to an industrial Internet of things gateway control cabinet capable of efficiently radiating heat.

Background

The industrial internet of things gateway equipment is also called an internet of things box, an internet of things terminal and the like, but the required product functional characteristics are different according to the specific requirements of each industry. With the development of industrial Internet of things industry, products are gradually subdivided, and the industrial Internet of things equipment is suitable for all industries. In the whole Internet of things solution, the industrial Internet of things gateway device plays roles of front-end data acquisition, data processing, transmission and the like, and the cost and reliability of the whole system can be greatly reduced by the proper Internet of things gateway device, and meanwhile, the processing capacity of the cloud server can be greatly reduced. The industrial internet of things switch control cabinet needs to be ventilated and radiated in the use process, and the existing industrial internet of things switch control cabinet is generally simple in setting radiating holes to radiate heat, so that the radiating efficiency is low.

Chinese patent CN217591426U discloses an industry thing networking switch control cabinet, including the cabinet body, landing leg and place the board, place the board and fixedly locate in the cabinet body, place evenly be equipped with a plurality of louvres on the board, still include: the bottom end of the cabinet body is uniformly provided with a plurality of vent holes, and the vent holes are internally provided with the filter screen; the support frame is fixedly arranged at the bottom side outside the cabinet body; the motor is fixedly connected with the support frame, the output end of the motor is fixedly connected with a first rotating shaft, the first rotating shaft movably penetrates through the support frame, and one end, close to the cabinet body, of the first rotating shaft is provided with a fan blade; the second rotating shaft is supported on the peripheral side of the cabinet body and is connected with the first rotating shaft through a belt; the heat dissipation cylinder is fixedly connected with the cabinet body at one end and is communicated with the interior of the cabinet body, a first one-way valve is arranged at the connecting end of the heat dissipation cylinder and the cabinet body, and a second one-way valve is also arranged on the heat dissipation cylinder outside the cabinet body; the piston is arranged in the heat dissipation cylinder in a sealing sliding manner; the reciprocating driving assembly is connected with the piston and the second rotating shaft and used for driving the piston to reciprocate left and right; the motor drives the first rotation of pivot, the first rotation of pivot drives the flabellum and rotates, the flabellum from the bottom of the cabinet body to the internal portion of cabinet is bloied, simultaneously, the first rotation of pivot drives the second rotation of pivot through the belt, the second rotation of pivot passes through reciprocating drive subassembly drive the piston carries out the left and right reciprocating motion, through the cooperation use of the left and right reciprocating motion of piston and check valve one, check valve two, has realized the internal heat of cabinet is quick to be arranged outward.

The cooling effect is not obvious, because the air around the cabinet body is also influenced by the cabinet body, the air around the cabinet body is higher than the actual outdoor temperature, the water cooling technology is adopted in the prior art to cool, but the water cooling self also needs to cool, so that the effect is also reduced after a period of use.

Disclosure of Invention

To above-mentioned problem, but high-efficient radiating industry thing networking switch board is provided, dispel the heat to circulating device cooling water through the cooling water tank, utilize first temperature sensor to monitor the temperature of the cooling water in the cooling water tank, monitor the temperature of the cooling water in the cooling water tank through level sensor simultaneously, when the temperature of the cooling water in the cooling water tank that monitors and too high or lack the cooling, advance drainage subassembly and just can start, change the cooling water in the cooling water tank, guaranteed the stability of heat sink cooling effect.

In order to solve the problems in the prior art, the invention adopts the following technical scheme:

an industrial internet of things switch control cabinet capable of efficiently radiating heat comprises a cabinet body and a cooling device; the cooling device comprises a circulating device, a radiating water tank, a water inlet and outlet assembly, a first temperature sensor and a water level sensor; the radiating water tank is arranged below the cabinet body, and cooling water is filled in the radiating water tank; the circulating device is arranged on the side wall of the radiating water tank, and the cooling water is pumped out from the radiating water tank under the action of the circulating device and flows through the interior of the cabinet body and finally flows back into the radiating water tank; the water inlet and outlet assembly is arranged on the side wall of the radiating water tank and is used for replacing cooling water in the radiating water tank; the first temperature sensor is arranged at the bottom of the radiating water tank and is used for monitoring the temperature of cooling liquid in the radiating water tank, the cabinet body is provided with a controller, and the first temperature sensor controls the water inlet and outlet assembly to operate through the controller; the water level sensor is arranged on the inner wall of the radiating water tank and is used for monitoring the liquid level height of the cooling liquid in the radiating water tank, and the water level sensor controls the water inlet and outlet assembly to operate through the controller.

Preferably, the circulating device comprises a pump body, a heat absorbing pipe and an extension pipe; the pump body is arranged on one side of the radiating water tank and is connected with the radiating water tank through a connecting pipe; the two extension pipes are vertically arranged at two sides of the radiating water tank respectively, one extension pipe is communicated with the pump body, and a safety valve is arranged on the lower side part of the other extension pipe; the plurality of heat absorption pipes are arranged as a group of heat absorption components, the plurality of heat absorption components are arranged, the heat absorption pipes in each group of heat absorption components are horizontally arranged along the width direction of the cabinet body, the heat absorption components are uniformly arranged along the height direction of the cabinet body, and the heat absorption pipes are communicated with the extension pipes.

Preferably, the water inlet assembly comprises a first switch valve and a second switch valve; the first switch valve is arranged on the side wall of the radiating water tank; the second switch valve is arranged on the side wall of the radiating water tank at one side of the first switch valve.

Preferably, the cooling device further comprises a first auxiliary device, wherein the first auxiliary device comprises a transmission device, a fan and a heat radiation port; the transmission device is arranged on the extension pipe, and water flowing in the extension pipe can drive the transmission assembly to rotate; the bottom of the cabinet body is provided with an air inlet, the fan can be rotatably arranged on the air inlet, and the transmission device is used for driving the fan to rotate; the cooling port is arranged on the side wall of the cabinet body and is used for discharging hot air in the cabinet body.

Preferably, the drive assembly comprises a turbine, a first bevel gear, a second bevel gear and a drive assembly; the turbine is arranged on the extension pipe, water flow in the extension pipe can drive the turbine to rotate, and the output end of the turbine is horizontally arranged; the first bevel gear is fixedly arranged on the output end of the turbine; the second bevel gear is arranged on one side of the first bevel gear, and the first bevel gear is meshed with the second bevel gear; the transmission assembly is connected with the second bevel gear and the fan respectively, and the second bevel gear drives the fan to rotate through the transmission assembly.

Preferably, the transmission assembly comprises a synchronizing wheel and a synchronous belt; the two synchronizing wheels are respectively arranged on the second bevel gear and the fan; the synchronous belt is sleeved on the two synchronous wheels and is in transmission fit with the synchronous road.

Preferably, the first auxiliary device further comprises a partition; a first gap is reserved between the upper part of the radiating water tank and the fan, the partition board is arranged in the first gap, a second gap is reserved between the partition board and the radiating water tank, and a third gap is reserved between the partition board and the fan.

Preferably, the blocking net is arranged in the second gap, and the upper part and the lower part of the blocking net are respectively and fixedly connected with the lower part of the partition plate and the upper part of the radiating water tank.

Preferably, the cooling device comprises a driving device, a second temperature sensor, a rotating shaft, a shutter plate and a driving rod; the driving device is arranged at the upper part of the cabinet body; the second temperature sensor is arranged in the cabinet body and is used for monitoring the temperature in the cabinet body; the plurality of rotating shafts are arranged, and the rotating shafts are fixedly arranged on the heat dissipation openings along the width direction of the cabinet body; the rotating shafts are uniformly arranged on the heat dissipation openings along the height direction of the cabinet body; the shutter plate can be rotatably arranged on the rotating shaft; the vertical setting of actuating lever is in the inside of the cabinet body, and the actuating lever is articulated with the one end that the tripe board is located the cabinet body, and drive arrangement can drive the actuating lever and follow the direction of height of the cabinet body and remove.

Preferably, the driving means comprises a linear driver and a push plate; the linear driver is fixedly arranged at the upper part of the cabinet body, and the output end of the linear driver is vertically downward; the fixed setting of push plate is on the output of linear drive, is provided with the articulated shaft on the upper portion lateral wall of actuating lever, and the lower part level of push plate is provided with the spout, and the articulated shaft runs through in the spout, articulated shaft and spout sliding fit, linear drive lever through the push plate and remove along the direction of height of the cabinet body.

Compared with the prior art, the invention has the beneficial effects that:

according to the invention, the circulating device, the radiating water tank, the water inlet and outlet assembly, the first temperature sensor and the water level sensor are arranged, the radiating water tank is used for radiating the cooling water of the circulating device, the first temperature sensor is used for monitoring the temperature of the cooling water in the radiating water tank, and the water level sensor is used for monitoring the temperature of the cooling water in the radiating water tank, so that when the temperature of the cooling water in the radiating water tank is monitored to be too high or the cooling is lack, the water inlet and outlet assembly is started, the cooling water in the radiating water tank is replaced, and the stability of the cooling effect of the cooling device is ensured.

Drawings

FIG. 1 is a schematic perspective view of an industrial Internet of things switch control cabinet capable of efficiently dissipating heat;

FIG. 2 is a front view of an industrial Internet of things switch control cabinet with a cabinet door removed for efficient heat dissipation;

FIG. 3 is a front view of an industrial Internet of things gateway control cabinet with cabinet doors and gateway equipment removed for efficient heat dissipation;

FIG. 4 is an enlarged schematic view of a portion of the industrial Internet of things switch control cabinet of FIG. 3A with efficient heat dissipation;

FIG. 5 is an enlarged schematic view of a portion of the industrial Internet of things switch control cabinet of FIG. 3B with efficient heat dissipation;

FIG. 6 is a perspective view of an industrial Internet of things switch control cabinet with a cabinet door removed, capable of efficiently dissipating heat;

FIG. 7 is a schematic perspective view of an industrial Internet of things gateway control cabinet with a cabinet door, a cabinet body and a gateway removed for efficient heat dissipation;

FIG. 8 is a side view of an industrial Internet of things gateway control cabinet with a gateway, a cabinet body and a cabinet door removed for efficient heat dissipation;

FIG. 9 is a schematic cross-sectional view of the industrial Internet of things switch control cabinet of FIG. 8 at C-C with efficient heat dissipation;

FIG. 10 is a schematic view of a portion of the industrial Internet of things switch control cabinet with efficient heat dissipation at D in FIG. 9;

FIG. 11 is a perspective view of an industrial Internet of things gateway control cabinet with a driving device, a cabinet door, a cabinet body and a gateway removed for efficient heat dissipation;

FIG. 12 is an enlarged schematic view of a portion of the industrial Internet of things switch control cabinet of FIG. 11 at E, which is capable of efficient heat dissipation;

fig. 13 is a schematic perspective view of a radiating water tank of an industrial internet of things switch control cabinet with a transmission device, a pump body, a water inlet and outlet assembly, a baffle plate and a blocking net.

The reference numerals in the figures are:

1-a cabinet body;

2-a cooling device;

21-a circulation device; 211-a pump body; 212-a heat absorbing pipe; 213-extension tube;

22-a radiating water tank;

23-a water inlet and outlet assembly; 231-a first switching valve; 232-a second switching valve;

24-a first auxiliary device; 241-transmission; 2411-a turbine; 2412-a first bevel gear; 2413-a second bevel gear; 2414-synchronizing wheel; 2415-a synchronous belt; 242-fans; 243-heat dissipation port; 244-separator;

25-a second auxiliary device; 251-driving means; 2511—linear drive; 2512—push plate; 252-a second temperature sensor; 253-shutter board; 254-drive rod;

26-blocking net.

Detailed Description

The invention will be further described in detail with reference to the drawings and the detailed description below, in order to further understand the features and technical means of the invention and the specific objects and functions achieved.

Referring to fig. 1-13: an industrial internet of things switch control cabinet capable of efficiently radiating heat comprises a cabinet body 1 and a cooling device 2; the cooling device 2 comprises a circulating device 21, a radiating water tank 22, a water inlet and outlet assembly 23, a first temperature sensor and a water level sensor; the radiating water tank 22 is arranged below the cabinet body 1, and cooling water is contained in the radiating water tank 22; the circulation device 21 is arranged on the side wall of the radiating water tank 22, and the cooling water is pumped out from the radiating water tank 22 under the action of the circulation device 21 and flows through the interior of the cabinet body 1 and finally flows back into the radiating water tank 22; the water inlet and outlet assembly 23 is arranged on the side wall of the radiating water tank 22, and the water inlet and outlet assembly 23 is used for replacing cooling water in the radiating water tank 22; the first temperature sensor is arranged at the bottom of the radiating water tank 22 and is used for monitoring the temperature of the cooling liquid in the radiating water tank 22, a controller is arranged on the cabinet body 1, and the first temperature sensor controls the water inlet and outlet assembly 23 to run through the controller; the water level sensor is arranged on the inner wall of the radiating water tank 22 and is used for monitoring the liquid level height of the cooling liquid in the radiating water tank 22, and the water level sensor controls the water inlet and outlet assembly 23 to run through the controller.

The cabinet body 1 is internally provided with a plurality of layers of placing plates, the placing plates are provided with a plurality of gateways, when the gateway control cabinet is started to be used, the circulating device 21 can pump out water in the radiating water tank 22, the circulating device 21 surrounds the inside of the cabinet body 1, after the circulating device 21 pumps out cooling water in the radiating water tank 22, water flow can flow through the circulating device 21 positioned in the cabinet body 1, the water flow can cool the temperature in the cabinet body 1, then the water flow is guided by the circulating device 21 to flow back to the radiating water tank 22, quantitative cooling water is stored in the radiating water tank 22, the cooling water drained into the radiating water tank 22 can be mixed with the original cooling water in the radiating water tank 22, meanwhile, the upper part of the radiating water tank 22 is provided with an opening, the cooling water in the radiating water tank 22 can cool down through the opening by itself, along with the continuous operation of the control cabinet of the industrial Internet of things, the temperature around the cabinet body 1 will rise, at this moment, the cooling burden of the circulation device 21 is increased, when the heat dissipation speed of the heat dissipation water tank 22 does not catch up with the heat absorption speed of the cooling water in the circulation device 21, the temperature of the cooling water in the heat dissipation water tank 22 will rise, the temperature of the cooling water in the heat dissipation water tank 22 will be always in a threshold value before rising, the threshold value will be called as the preset temperature here, at this moment, the cooling effect of the cooling device 2 will be affected, the temperature of the cooling water in the heat dissipation water tank 22 can be detected through the first temperature sensor arranged in the heat dissipation water tank 22, if the temperature of the cooling water in the heat dissipation water tank 22 is monitored to be higher than the preset temperature, the water inlet and outlet assembly 23 will be started, and the water inlet and outlet assembly 23 will automatically replace the cooling water in the heat dissipation water tank 22; because the natural evaporation phenomenon can necessarily appear in the radiator tank 22 when the heat dissipation, will appear the loss of cooling water like this, in order to guarantee the normal work of radiator tank 22, when level sensor monitors the cooling water in the radiator tank 22 too low, advance drainage subassembly 23 and just can start, advance drainage subassembly 23 and can carry out moisturizing to radiator tank 22, guaranteed the stability of heat sink 2 cooling effect.

Referring to fig. 2 and 11: the circulation device 21 includes a pump body 211, a heat absorbing pipe 212, and an extension pipe 213; the pump body 211 is arranged at one side of the radiating water tank 22, and the pump body 211 is connected with the radiating water tank 22 through a connecting pipe; the two extension pipes 213 are provided, the two extension pipes 213 are vertically provided at both sides of the radiating water tank 22, respectively, one extension pipe 213 is communicated with the pump body 211, and a safety valve is provided at a lower side portion of the other extension pipe 213; the plurality of heat absorbing pipes 212 are arranged as a group of heat absorbing components, the plurality of heat absorbing components are arranged, the heat absorbing pipes 212 in each group of heat absorbing components are horizontally arranged along the width direction of the cabinet body 1, the heat absorbing components are uniformly arranged along the height direction of the cabinet body 1, and the heat absorbing pipes 212 are communicated with the extension pipes 213.

When the cabinet body 1 needs to be cooled, the pump body 211 can be started, the pump body 211 can pump out cooling water in the radiating water tank 22 and discharge the cooling water into the extension pipe 213, then the cooling water flows into the heat absorption pipe 212 through the extension pipe 213, the cooling water in the heat absorption pipe 212 can absorb heat in the cabinet body 1 and then is discharged back into the radiating pipe through the other extension pipe 213, and a safety valve is arranged on the extension pipe 213 which is not directly connected with the pump body 211, so that when the control cabinet is not operated any more, water flow in the extension pipe 213 can be ensured not to flow back into the radiating water tank 22, and only when the pump body 211 is started, the pressure in the extension pipe 213 rises at the moment, and the safety valve can be opened at the moment, so that the smoothness of the flow of the cooling water in the circulating device 21 is ensured.

Referring to fig. 2 and 8: the water inlet assembly includes a first switch valve 231 and a second switch valve 232; the first switching valve 231 is provided on a sidewall of the radiating water tank 22; the second switching valve 232 is provided on a sidewall of the radiating water tank 22 at one side of the first switching valve 231.

The end of the first switch valve 231 far away from the radiating water tank 22 is provided with a water inlet pipe, the end of the second switch valve 232 far away from the radiating water tank 22 is provided with a water outlet pipe, and when water is required to be replenished, the first switch valve 231 is started; when the temperature of the cooling water in the cooling water tank 22 exceeds the preset temperature, the first switch valve 231 and the second switch valve 232 are opened at the same time, the first switch valve 231 discharges new cooling water into the cooling water tank 22, and the second switch valve 232 discharges cooling water in the cooling water tank 22, so that the cooling water in the cooling water tank 22 is replaced.

Referring to fig. 3, 6 and 10: the cooling device 2 further comprises a first auxiliary device 24, wherein the first auxiliary device 24 comprises a transmission device 241, a fan 242 and a cooling port 243; the transmission device 241 is arranged on the extension pipe 213, and the water flow flowing in the extension pipe 213 can drive the transmission assembly to rotate; the bottom of the cabinet body 1 is provided with an air inlet, a fan 242 can be rotatably arranged on the air inlet, and a transmission device 241 is used for driving the fan 242 to rotate; the heat dissipation port 243 is disposed on a side wall of the cabinet 1, and the heat dissipation port 243 is used for exhausting hot air in the cabinet 1.

Because the transmission device 241 is disposed on the extension tube 213, when the pump body 211 is started, the water flow in the extension tube 213 will flow, and at this time, the transmission device 241 will be driven, so that the transmission assembly drives the fan 242 to rotate, under the action of the fan 242, the outside air can be blown into the cabinet body 1, and the air in the cabinet body 1 will be discharged through the heat dissipation port 243, thereby assisting the cooling function of the circulation device 21.

Referring to fig. 3 and 5: the drive assembly includes a turbine 2411, a first bevel gear 2412, a second bevel gear 2413, and a drive assembly; the turbine 2411 is arranged on the extension pipe 213, the water flow in the extension pipe 213 can drive the turbine 2411 to rotate, and the output end of the turbine 2411 is horizontally arranged; a first bevel gear 2412 is fixedly disposed on the output end of the turbine 2411; the second bevel gear 2413 is disposed at one side of the first bevel gear 2412, and the first bevel gear 2412 is intermeshed with the second bevel gear 2413; the transmission assembly is respectively connected with the second bevel gear 2413 and the fan 242, and the second bevel gear 2413 drives the fan 242 to rotate through the transmission assembly.

When the water flow in the extension pipe 213 starts to flow, the turbine 2411 is driven, and since the first bevel gear 2412 is disposed on the output end of the turbine 2411, the first bevel gear 2412 is driven by the turbine 2411, and meanwhile, the first bevel gear 2412 and the second bevel gear 2413 are meshed with each other, and when the first bevel gear 2412 rotates, the second bevel gear 2413 is driven to rotate, so as to drive the transmission assembly connected with the second bevel gear 2413 to rotate, thereby enabling the fan 242 to be driven to rotate.

Referring to fig. 13: the transmission assembly includes a synchronizing wheel 2414 and a synchronizing belt 2415; two synchronizing wheels 2414 are provided, and the synchronizing wheels 2414 are respectively provided on the second bevel gear 2413 and the fan 242; the synchronous belt 2415 is sleeved on two synchronous wheels 2414, and the synchronous belt 2415 is in transmission fit with the synchronous road.

When the second bevel gear 2413 rotates, the second bevel gear 2413 drives the synchronizing wheel 2414 to rotate, and the synchronizing belt 2415 drives the synchronizing wheel 2414 disposed at the fan 242 to rotate after the synchronizing wheel 2414 disposed at the second bevel gear 2413 rotates due to the driving cooperation of the synchronizing belt 2415 and the synchronizing wheel 2414.

Referring to fig. 13: the first auxiliary device 24 further includes a diaphragm 244; a first space is formed between the upper portion of the radiator tank 22 and the fan 242, the partition 244 is disposed in the first space, a second space is formed between the partition 244 and the radiator tank 22, and a third space is formed between the partition 244 and the fan 242.

The provision of the partition 244 prevents the fan 242 from sucking vapor evaporated in the radiator tank 22 into the cabinet 1, thereby ensuring the drying property in the cabinet 1.

Referring to fig. 13: the barrier net 26 is disposed in the second space, and the upper and lower portions of the barrier net 26 are fixedly connected to the lower portion of the partition 244 and the upper portion of the radiator tank 22, respectively.

By providing the blocking net 26, external impurities can be prevented from entering the radiating water tank 22, and normal heat dissipation of the radiating water tank 22 is not affected.

Referring to fig. 4, 7, 8 and 9: the cooling device 2 comprises a driving device 251, a second temperature sensor 252, a rotating shaft, a shutter 253 and a driving rod 254; the driving device 251 is arranged at the upper part of the cabinet body 1; the second temperature sensor 252 is arranged inside the cabinet body 1, and the second temperature sensor 252 is used for monitoring the temperature inside the cabinet body 1; the number of the rotating shafts is multiple, and the rotating shafts are fixedly arranged on the heat dissipation port 243 along the width direction of the cabinet body 1; the rotating shafts are uniformly arranged on the heat dissipation openings 243 along the height direction of the cabinet body 1; the shutter 253 is rotatably arranged on the rotating shaft; the driving rod 254 is vertically arranged in the cabinet body 1, the driving rod 254 is hinged with one end of the shutter 253 positioned in the cabinet body 1, and the driving device 251 can drive the driving rod 254 to move along the height direction of the cabinet body 1.

Since the cooling function of the circulating device 21 is operated by relying on the pump body 211, when the pump body 211 fails, the cooling function of the circulating device 21 is stopped, and a certain time is required even if the manual maintenance is notified, if the industrial internet of things switch control cabinet cannot automatically provide emergency measures at this time, the damage phenomenon of gateway equipment in the industrial internet of things switch control cabinet can be caused, in order to reduce the maintenance cost, after the pump body 211 stops operating and the second temperature sensor 252 senses that the temperature in the cabinet body 1 gradually rises, the driving device 251 is started, the driving device 251 drives the driving rod 254 to move along the height direction of the cabinet body 1, so that the shutter 253 gradually tends to be horizontal, and since the heat dissipation openings 243 are respectively formed in two sides of the cabinet body 1, when the shutter 253 is completely opened, the heat dissipation openings 243 can play a role in ventilation for the cabinet body 1, and the purpose of setting the shutter 253 is to avoid excessive dust entering the interior of the cabinet body 1 when the pump body 211 normally works.

Referring to fig. 8 and 9: the driving device 251 includes a linear driver 2511 and a push plate 2512; the linear driver 2511 is fixedly arranged at the upper part of the cabinet body 1, and the output end of the linear driver 2511 is vertically downward; the pushing plate 2512 is fixedly arranged at the output end of the linear driver 2511, a hinge shaft is arranged on the side wall of the upper portion of the driving rod 254, a sliding groove is horizontally arranged at the lower portion of the pushing plate 2512, the hinge shaft penetrates through the sliding groove, the hinge shaft is in sliding fit with the sliding groove, and the linear driver 2511 drives the driving rod 254 to move along the height direction of the cabinet body 1 through the pushing plate 2512.

The linear driver 2511 can drive the pushing plate 2512 to move along the height direction of the cabinet 1, and when the output end of the linear driver 2511 extends, the pushing plate 2512 can drive the driving rod 254 to move downward along the height direction of the cabinet 1.

The foregoing examples merely illustrate one or more embodiments of the invention, which are described in greater detail and are not to be construed as limiting the scope of the invention. It should be noted that it will be apparent to those skilled in the art that several variations and modifications can be made without departing from the spirit of the invention, which are all within the scope of the invention. Accordingly, the scope of protection of the present invention is to be determined by the appended claims.

Claims (10)

1. An industrial internet of things switch control cabinet capable of efficiently radiating heat comprises a cabinet body (1) and a cooling device (2);

the cooling device (2) is characterized by comprising a circulating device (21), a radiating water tank (22), a water inlet and outlet assembly (23), a first temperature sensor and a water level sensor;

the radiating water tank (22) is arranged below the cabinet body (1), and cooling water is contained in the radiating water tank (22);

the circulating device (21) is arranged on the side wall of the radiating water tank (22), and the cooling water is pumped out of the radiating water tank (22) under the action of the circulating device (21) and flows through the interior of the cabinet body (1) and finally flows back into the radiating water tank (22);

the water inlet and outlet assembly (23) is arranged on the side wall of the radiating water tank (22), and the water inlet and outlet assembly (23) is used for replacing cooling water in the radiating water tank (22);

the first temperature sensor is arranged at the bottom of the radiating water tank (22) and is used for monitoring the temperature of cooling liquid in the radiating water tank (22), a controller is arranged on the cabinet body (1), and the first temperature sensor controls the water inlet and outlet assembly (23) to operate through the controller;

the water level sensor is arranged on the inner wall of the radiating water tank (22), and is used for monitoring the liquid level height of the cooling liquid in the radiating water tank (22), and the water level sensor controls the water inlet and outlet assembly (23) to operate through the controller.

2. The industrial internet of things switch control cabinet capable of efficiently dissipating heat according to claim 1, wherein the circulating device (21) comprises a pump body (211), a heat absorption pipe (212) and an extension pipe (213);

the pump body (211) is arranged on one side of the radiating water tank (22), and the pump body (211) is connected with the radiating water tank (22) through a connecting pipe;

the two extension pipes (213) are respectively and vertically arranged at two sides of the radiating water tank (22), one extension pipe (213) is communicated with the pump body (211), and a safety valve is arranged on the lower side part of the other extension pipe (213);

the plurality of heat absorption pipes (212) are arranged into a group of heat absorption components, the plurality of heat absorption components are arranged, the heat absorption pipes (212) in each group of heat absorption components are horizontally arranged along the width direction of the cabinet body (1), the heat absorption components are uniformly arranged along the height direction of the cabinet body (1), and the heat absorption pipes (212) are communicated with the extension pipes (213).

3. The industrial internet of things switch control cabinet capable of efficiently dissipating heat according to claim 1, wherein the water inlet assembly comprises a first switch valve (231) and a second switch valve (232);

the first switch valve (231) is arranged on the side wall of the radiating water tank (22);

the second switching valve (232) is provided on a side wall of the radiator tank (22) on one side of the first switching valve (231).

4. The industrial internet of things switch control cabinet capable of efficiently dissipating heat according to claim 2, wherein the cooling device (2) further comprises a first auxiliary device (24), and the first auxiliary device (24) comprises a transmission device (241), a fan (242) and a heat dissipation port (243);

the transmission device (241) is arranged on the extension pipe (213), and water flowing in the extension pipe (213) can drive the transmission assembly to rotate;

an air inlet is formed in the bottom of the cabinet body (1), a fan (242) is rotatably arranged on the air inlet, and a transmission device (241) is used for driving the fan (242) to rotate;

the heat dissipation port (243) is arranged on the side wall of the cabinet body (1), and the heat dissipation port (243) is used for discharging hot air in the cabinet body (1).

5. The industrial internet of things switch control cabinet capable of efficiently dissipating heat according to claim 4, wherein the transmission assembly comprises a turbine (2411), a first bevel gear (2412), a second bevel gear (2413), and a transmission assembly;

the turbine (2411) is arranged on the extension pipe (213), the water flow in the extension pipe (213) can drive the turbine (2411) to rotate, and the output end of the turbine (2411) is horizontally arranged;

the first bevel gear (2412) is fixedly arranged on the output end of the turbine (2411);

the second bevel gear (2413) is arranged at one side of the first bevel gear (2412), and the first bevel gear (2412) is meshed with the second bevel gear (2413);

the transmission assembly is respectively connected with the second bevel gear (2413) and the fan (242), and the second bevel gear (2413) drives the fan (242) to rotate through the transmission assembly.

6. The industrial internet of things switch control cabinet capable of efficiently dissipating heat according to claim 5, wherein the transmission assembly comprises a synchronizing wheel (2414) and a synchronizing belt (2415);

two synchronizing wheels (2414) are arranged, and the synchronizing wheels (2414) are respectively arranged on the second bevel gear (2413) and the fan (242);

the synchronous belt (2415) is sleeved on the two synchronous wheels (2414), and the synchronous belt (2415) is in transmission fit with the synchronous road.

7. The industrial internet of things switch control cabinet capable of efficiently dissipating heat in accordance with claim 4, wherein the first auxiliary device (24) further comprises a spacer (244);

a first gap is formed between the upper part of the radiating water tank (22) and the fan (242), a partition plate (244) is arranged in the first gap, a second gap is formed between the partition plate (244) and the radiating water tank (22), and a third gap is formed between the partition plate (244) and the fan (242).

8. The industrial internet of things switch control cabinet capable of efficiently radiating according to claim 7, wherein the blocking net (26) is arranged in the second gap, and the upper part and the lower part of the blocking net (26) are fixedly connected with the lower part of the partition plate (244) and the upper part of the radiating water tank (22) respectively.

9. The industrial internet of things switch control cabinet capable of efficiently dissipating heat according to claim 4, wherein the cooling device (2) comprises a driving device (251), a second temperature sensor (252), a rotating shaft, a shutter plate (253) and a driving rod (254);

the driving device (251) is arranged at the upper part of the cabinet body (1);

the second temperature sensor (252) is arranged in the cabinet body (1), and the second temperature sensor (252) is used for monitoring the temperature in the cabinet body (1);

the plurality of rotating shafts are arranged, and the rotating shafts are fixedly arranged on the heat dissipation openings (243) along the width direction of the cabinet body (1); the rotating shafts are uniformly arranged on the heat dissipation openings (243) along the height direction of the cabinet body (1);

the shutter plate (253) can be rotatably arranged on the rotating shaft;

the driving rod (254) is vertically arranged in the cabinet body (1), the driving rod (254) is hinged with one end of the shutter plate (253) positioned in the cabinet body (1), and the driving device (251) can drive the driving rod (254) to move along the height direction of the cabinet body (1).

10. The industrial internet of things switch control cabinet capable of efficiently dissipating heat according to claim 9, wherein the driving device (251) comprises a linear driver (2511) and a pushing plate (2512);

the linear driver (2511) is fixedly arranged at the upper part of the cabinet body (1), and the output end of the linear driver (2511) is vertically downward;

the pushing plate (2512) is fixedly arranged at the output end of the linear driver (2511), a hinge shaft is arranged on the side wall of the upper portion of the driving rod (254), a sliding groove is horizontally arranged at the lower portion of the pushing plate (2512), the hinge shaft penetrates through the sliding groove, the hinge shaft is in sliding fit with the sliding groove, and the linear driver (2511) drives the driving rod (254) to move along the height direction of the cabinet body (1) through the pushing plate (2512).