CN116901661A - Vehicle-mounted radar shelter modular cooling unit - Google Patents

Abstract

The invention discloses a vehicle-mounted radar shelter modular cooling unit, which relates to the technical field of ventilation and humidification and comprises the following components: the device comprises a mounting plate, wherein a first shelter module and a second shelter module are respectively fixed at the positions, close to two sides, of the top of the mounting plate, and a humidity sensor is arranged on the front surface of the first shelter module. This on-vehicle radar shelter modular cooling unit, when using, when humidity transducer detects that humidity in the first shelter module is less than normal scope, just give the controller with unusual signal transmission, the controller is control after receiving the signal and is started the water pump, under the pressurized action of water pump, the inlet tube is taken out the water in the water tank, again send out from the conveyer pipe, in carrying the intercommunication jar, finally spout from the nozzle, through humidifying air, can improve the humidity of air, reduce thermal dissipation speed, help keeping the radar main part in normal operating temperature scope, have the guard action to equipment.

Description

Vehicle-mounted radar shelter modular cooling unit

Technical Field

The invention relates to the technical field of ventilation and humidification, in particular to a vehicle-mounted radar shelter modular cooling unit.

Background

The vehicle radar is a radar system installed on a vehicle, and can be used for monitoring the surrounding environment of the vehicle in real time by being installed on the vehicle, including detecting front obstacles, tracking other vehicles, measuring the speed of the vehicle, etc., the cooling unit is a device for controlling and reducing the temperature of the device or the system, and the shelter module type refers to a structural mode in which the whole system or the device is divided into a plurality of independent modules or units, each module or unit has a specific function and structure, and can be independently assembled and disassembled.

In general, in a vehicle-mounted radar shelter modular cooling unit, the cooling unit is a part for reducing the temperature of radar equipment, the shelter is a closed space for installing the radar equipment and the cooling unit, and the shelter can be designed as an independent module and is connected with the cooling unit module, so that the cooling unit and the shelter can be independently assembled and disassembled, and are convenient to install and maintain, but the radar equipment can generate a large amount of heat during operation, and in some dry environments, the dry air can accelerate the dissipation of heat, so that the equipment temperature is too low.

We have therefore proposed a vehicle-mounted radar shelter modular cooling unit in order to solve the problems set out above.

Disclosure of Invention

The invention aims to provide a vehicle-mounted radar shelter modular cooling unit, which aims to solve the problems that the radar equipment provided by the background art can generate a large amount of heat during operation, and in some dry environments, the heat dissipation can be accelerated by dry air, so that the equipment temperature is too low.

In order to achieve the above purpose, the present invention provides the following technical solutions: a vehicle-mounted radar shelter modular cooling unit, comprising: the water tank is arranged on the inner bottom surface of the second shelter module, the water pump is arranged on the inner bottom surface of the second shelter module close to the water tank, a water inlet of the water pump is fixedly communicated with a water inlet pipe through a flange plate, a water outlet of the water pump is fixedly communicated with a conveying pipe through a flange plate, and a mounting port is formed in the rear surface of the second shelter module; a cooling assembly disposed between the interiors of the first and second shelter modules; the humidifying component comprises a communicating tank, one end of the conveying pipe penetrates through the communicating tank, a nozzle is fixedly communicated with the bottom end of the communicating tank, a plurality of bottom spray holes are formed in the bottom of the nozzle, and a plurality of side spray holes are formed in the outer surface of the nozzle.

Preferably, the vent has been seted up to the front surface of second shelter module, the inside bottom surface of first shelter module is provided with the radar main part, the top of first shelter module is connected with first protective cover through the hinge rotation, the top of second shelter module is connected with the second protective cover through the hinge rotation, a plurality of fixed slots have all been seted up to the surface of first protective cover and the surface of second protective cover, a plurality of buckles have all been seted up to the inside looks of first shelter module's inner wall and second shelter module one side of keeping away from mutually, every the inner wall of buckle respectively with the surface looks block of a plurality of fixed slots, the inner wall of first shelter module and the inside looks of second shelter module are close to one side and are all fixedly connected with limit baffle.

Preferably, the back surface of first shelter module is close to top department fixed mounting has the support frame, one side fixedly connected with snap ring of support frame, the top fixedly connected with connecting block of intercommunication jar, the snap ring block is at the surface of connecting block.

Preferably, the limiting groove is formed in the inner wall of the communicating tank, a plurality of limiting shafts are movably connected to the inner wall of the limiting groove, each limiting shaft is fixedly connected with a spiral blade at one end opposite to the limiting shaft, a plurality of rotating shafts are fixedly connected between the spiral blades, a connecting plate is fixedly mounted at the bottom end of the rotating shaft, and side baffles are fixedly connected to four sides of the connecting plate.

Preferably, a positioning groove is formed in the middle of the inner bottom surface of the nozzle, the bottom of the connecting plate is fixedly connected with a positioning magnetic block, and the outer surface of the positioning groove is matched with the outer surface of the positioning magnetic block.

Preferably, the clamping groove is formed in the middle of the bottom of the nozzle, the bottom of the nozzle is fixedly connected with the fixed shaft, the bottom end of the fixed shaft is fixedly connected with the stop block, the outer surface of the fixed shaft is rotatably sleeved with the adjusting block, the position, close to one side, of the top of the adjusting block is fixedly provided with the same-direction magnet, and the position, close to the other side, of the top of the adjusting block is fixedly provided with the reverse magnet.

Preferably, the cooling assembly is provided with two, two the cooling assembly is all including U type heat pipe, two the top of U type heat pipe has all welded the enhancement heat pipe, two the both ends of U type heat pipe are all run through first shelter module to inside the second shelter module, and the both ends of two U type heat pipe all movable sleeve is equipped with the connection heat pipe, four the connection heat pipe is equally divided into two sets, every group all be provided with a plurality of heat radiation fins between the surface of connection heat pipe.

Preferably, a protection net is fixedly installed between the inner walls of the installation openings, a blowing assembly is fixedly installed at one end of each installation opening, each blowing assembly comprises an installation pipe, a supporting rod is fixedly installed between the inner walls of each installation pipe, a servo motor is arranged on one side of each supporting rod, an output shaft of each servo motor penetrates through the supporting rod to the outside, a driving shaft is fixedly installed at the output shaft of each servo motor, and a plurality of fan blades are fixedly installed on the outer surface of each driving shaft.

Preferably, one end of the installation pipe is fixedly communicated with a ventilation pipe, the front surface of the ventilation pipe is fixedly communicated with a plurality of air outlet pipes, and one ends of the air outlet pipes are fixedly communicated with an air outlet cavity.

Preferably, a plurality of dead levers are fixedly installed on the inner wall of one side of the second shelter module, every two dead levers are in a group, clamping blocks are fixedly connected between one ends of the dead levers in each group, and the inner walls of the clamping blocks are in clamping connection with the outside of the ventilation pipe.

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

1. when the humidity sensor detects that the humidity in the first shelter module is lower than the normal range, an abnormal signal is transmitted to the controller, the controller controls the starting of the water pump after receiving the signal, the water in the water tank is pumped out by the water inlet pipe under the pressurizing action of the water pump and then is sent out from the conveying pipe to the communicating tank, finally the water is sprayed out from the nozzle, the humidity of the air can be increased, the heat dissipation speed is reduced, the radar main body is kept in the normal working temperature range, the equipment is protected, when the humidity sensor detects that the humidity in the first shelter module reaches the normal range, the signal is transmitted to the controller, and the controller controls the water pump to be closed, so that the water pump stops pumping water, and the humidifying operation is stopped.

2. When the fan is used, heat is concentrated through the reinforced heat pipe and then sequentially transferred to the U-shaped heat pipe and the connecting heat pipe, so that the heat is transferred to the second shelter module, the heat on the connecting heat pipe is released to the surrounding air by the plurality of heat dissipation fins, the shape of the heat dissipation fins is curved, the contact area between the surface of the heat dissipation fins and the outside is increased, heat dissipation is accelerated, the servo motor is started, the output shaft of the servo motor drives the driving shaft to rotate, the fan blades are driven to rotate by the rotation of the driving shaft, wind enters the ventilation pipe from the mounting pipe, and then is blown out from each air outlet cavity, the outlets of the air outlet cavities face different positions of the heat dissipation fins, the air flow can be increased, the heat transmission and dissipation are accelerated, the heat on the heat dissipation fins is taken away by the air flow generated by the rotation of the fan blades, the heat on the heat dissipation fins is discharged from the ventilation opening, and cooling can be accelerated.

3. When the spray nozzle is used, the surfaces of the first shelter module and the second shelter module are coated with the heat scattering coating, the heat scattering coating can rapidly spread heat to the surrounding environment through increasing the radiation capacity of the surfaces, so that the surface temperature of an object is reduced, the reverse magnet is separated from the clamping groove and clamped into the clamping groove through rotating the adjusting block, the positioning magnet and the same-direction magnet are separated from the positioning groove under the action of homopolar repulsion and are positioned above the positioning groove, the spiral blade can be rotated when impacted by water flow through the communicating tank, the rotating shaft and the connecting plate are driven to rotate, the side baffle is further enabled to move along the inner wall of the nozzle, the side spray hole can continuously spray water mist outwards, the humidifying effect can be effectively improved, when the reverse magnet is clamped into the clamping groove, the water flow impacts the spiral blade to enable the spiral blade to rotate, the positions of the positioning magnet and the positioning magnet are adjusted, the positions of the reverse magnet are matched, the positioning magnet can absorb the positioning spray hole, the positioning magnet is clamped into the positioning groove, the opposite side position of the connecting plate can be limited, the opposite side position of the connecting plate is blocked, and the side baffle can only spray water mist from the bottom through the side baffle can be sprayed out, and the range of water mist can be reduced.

Drawings

FIG. 1 is a front perspective view of a vehicle-mounted radar shelter modular cooling unit of the present invention;

FIG. 2 is a rear perspective view of a modular cooling unit for a vehicle-mounted radar shelter of the present invention;

FIG. 3 is an expanded top perspective view of a first shelter module portion of a vehicle-mounted radar shelter modular cooling unit according to the present invention;

FIG. 4 is an expanded front perspective view of a second shelter module portion of a vehicle-mounted radar shelter module cooling unit according to the present invention;

FIG. 5 is a perspective view, partially in section, of a humidification assembly of a vehicle radar shelter modular cooling unit of the present invention;

FIG. 6 is an enlarged view of FIG. 5A in accordance with the present invention;

FIG. 7 is a cutaway bottom perspective view of a humidification assembly of a vehicle radar shelter modular cooling unit of the present invention;

FIG. 8 is an expanded top perspective view of a nozzle structure of a vehicle-mounted radar shelter modular cooling unit according to the present invention;

FIG. 9 is an expanded bottom perspective view of a nozzle structure of a vehicle-mounted radar shelter modular cooling unit according to the present invention;

FIG. 10 is an expanded perspective view of a part of the cooling assembly structure of a vehicle-mounted radar shelter modular cooling unit according to the present invention;

FIG. 11 is a cutaway perspective view of a blower assembly of a vehicle radar shelter modular cooling unit of the present invention;

fig. 12 is a perspective view of a water tank portion of a vehicle radar shelter modular cooling unit according to the present invention.

In the figure:

1. a mounting plate; 2. a humidification assembly; 201. a nozzle; 202. a side nozzle; 203. side baffles; 204. a connecting plate; 205. a communicating tank; 206. a rotating shaft; 207. a limit groove; 208. spiral leaves; 209. a limiting shaft; 210. a bottom jet orifice; 211. a clamping groove; 212. an adjusting block; 213. a magnet of the same direction; 214. a fixed shaft; 215. a stop block; 216. a reverse magnet; 217. a positioning groove; 218. positioning a magnetic block; 3. a cooling assembly; 301. u-shaped heat conducting pipes; 302. reinforcing the heat conduction pipe; 303. connecting a heat conduction pipe; 304. a heat radiation fin; 4. a blowing assembly; 401. a fixed rod; 402. clamping blocks; 403. a ventilation pipe; 404. an air outlet pipe; 405. an air outlet cavity; 406. installing a pipe; 407. a support rod; 408. a servo motor; 409. a drive shaft; 410. a fan blade; 5. a protective net; 6. a first shelter module; 7. a second shelter module; 8. a controller; 9. a vent; 10. a water tank; 11. a humidity sensor; 12. a support frame; 13. a delivery tube; 14. a first protective cover; 15. a second protective cover; 16. a mounting port; 17. a limit baffle; 18. a buckle; 19. a fixing groove; 20. a clasp; 21. a water inlet pipe; 22. a water pump; 23. a connecting block; 24. a radar body.

Detailed Description

The following description of the embodiments of the present invention will be made clearly and fully with reference to the accompanying drawings, in which it is evident that the embodiments described are only some, but not all embodiments of the invention. All other embodiments, which can be made by those skilled in the art based on the embodiments of the invention without making any inventive effort, are intended to be within the scope of the invention.

Referring to fig. 1-12, the present invention provides a technical solution: a vehicle-mounted radar shelter modular cooling unit, comprising: the device comprises a mounting plate 1, wherein a first shelter module 6 and a second shelter module 7 are respectively fixed at positions, close to two sides, of the top of the mounting plate 1, a humidity sensor 11 is arranged on the front surface of the first shelter module 6, a controller 8 is arranged on one side of the second shelter module 7, a water tank 10 is arranged on the inner bottom surface of the second shelter module 7, a water pump 22 is arranged on the inner bottom surface of the second shelter module 7, close to the water tank 10, a water inlet of the water pump 22 is fixedly communicated with a water inlet pipe 21 through a flange, a water outlet of the water pump 22 is fixedly communicated with a conveying pipe 13 through the flange, and a mounting opening 16 is formed in the rear surface of the second shelter module 7; a cooling assembly 3, the cooling assembly 3 being arranged between the interiors of the first shelter module 6 and the second shelter module 7; the humidifying component 2, the humidifying component 2 comprises a communicating tank 205, one end of the conveying pipe 13 penetrates through the communicating tank 205, a nozzle 201 is fixedly communicated with the bottom end of the communicating tank 205, a plurality of bottom spray holes 210 are formed in the bottom of the nozzle 201, and a plurality of side spray holes 202 are formed in the outer surface of the nozzle 201.

As shown in fig. 1-4, the front surface of the second shelter module 7 is provided with a ventilation opening 9, the inner bottom surface of the first shelter module 6 is provided with a radar main body 24, the top of the first shelter module 6 is rotationally connected with a first protective cover 14 through a hinge, the top of the second shelter module 7 is rotationally connected with a second protective cover 15 through a hinge, the outer surface of the first protective cover 14 and the outer surface of the second protective cover 15 are provided with a plurality of fixing grooves 19, the inner wall of the first shelter module 6 and the inner side far away from the second shelter module 7 are provided with a plurality of buckles 18, the inner wall of each buckle 18 is respectively buckled with the outer surfaces of the plurality of fixing grooves 19, the inner wall of the first shelter module 6 and the inner side of the second shelter module 7, which are close to each other, are fixedly connected with limit baffles 17, a radar main body 24 is installed in the first shelter module 6, a first protection cover 14 and a second protection cover 15 are respectively installed at the tops of the first shelter module 6 and the second shelter module 7, the first shelter module and the second shelter module can be turned over to be opened and closed, when the first shelter module and the second shelter module are closed, pressure is applied downwards, each buckle 18 can be clamped into a fixing groove 19 at a corresponding position, meanwhile, the two limit baffles 17 can block the corresponding first protection cover 14 and the corresponding second protection cover 15, so that the radar main body cannot fall down when the first shelter module 6 and the second shelter module 7 are coated with a heat scattering coating.

As shown in fig. 1, 2, 5 and 7, the back surface of the first shelter module 6 is fixedly installed at a position close to the top, a clamping ring 20 is fixedly connected to one side of the supporting frame 12, a connecting block 23 is fixedly connected to the top of the communicating tank 205, the clamping ring 20 is clamped on the outer surface of the connecting block 23, the opening of the clamping ring 20 is clamped outside the connecting block 23, and the section of the connecting block 23 is T-shaped, so that the installation of the communicating tank 205 by the supporting frame 12 is completed.

As shown in fig. 1-9, a limit groove 207 is formed in the inner wall of the communication tank 205, a plurality of limit shafts 209 are movably connected to the inner wall of the limit groove 207, spiral blades 208 are fixedly connected to opposite ends of each limit shaft 209, a rotating shaft 206 is fixedly connected between opposite ends of the spiral blades 208, a connecting plate 204 is fixedly mounted at the bottom end of the rotating shaft 206, side baffles 203 are fixedly connected to four sides of the connecting plate 204, and the spiral blades 208 can stably rotate in the communication tank 205 through the movement of the limit shafts 209 in the limit groove 207.

As shown in fig. 1-9, a positioning slot 217 is formed in the middle of the inner bottom surface of the nozzle 201, a positioning magnetic block 218 is fixedly connected to the bottom of the connecting plate 204, the outer surface of the positioning slot 217 is matched with the outer surface of the positioning magnetic block 218, the positioning magnetic block 218 is clamped into the positioning slot 217, and the positioning magnetic block 218 and the positioning slot 217 are matched polygons, so that the position of the connecting plate 204 can be limited.

As shown in fig. 1-9, a clamping groove 211 is formed in the middle of the bottom of the nozzle 201, a fixing shaft 214 is fixedly connected to the bottom of the nozzle 201, a stop block 215 is fixedly connected to the bottom end of the fixing shaft 214, an adjusting block 212 is rotatably sleeved on the outer surface of the fixing shaft 214, a same-direction magnet 213 is fixed at the position, close to one side, of the top of the adjusting block 212, a reverse magnet 216 is fixed at the position, close to the other side, of the top of the adjusting block 212, in an initial state, the reverse magnet 216 is embedded into the clamping groove 211, materials in the clamping groove 211 are thin and cannot influence magnetism, the reverse magnet 216 can absorb the positioning magnet 218, the positioning magnet 218 is clamped into the positioning groove 217, the reverse magnet 216 is separated from the clamping groove 211, the same-direction magnet 213 is clamped into the clamping groove 211, and the positioning magnet 218 and the same-direction magnet 213 are separated from the positioning groove 217 under the action of homopolar repulsion.

As shown in fig. 1, fig. 3, fig. 4 and fig. 10, two cooling assemblies 3 are provided, each cooling assembly 3 comprises two U-shaped heat conducting pipes 301, the top parts of the two U-shaped heat conducting pipes 301 are welded with reinforcing heat conducting pipes 302, two ends of the two U-shaped heat conducting pipes 301 penetrate through the first shelter module 6 to the inside of the second shelter module 7, two ends of the two U-shaped heat conducting pipes 301 are movably sleeved with connecting heat conducting pipes 303, four connecting heat conducting pipes 303 are equally divided into two groups, a plurality of heat radiating fins 304 are arranged between the outer surfaces of each group of connecting heat conducting pipes 303, heat is transmitted to the U-shaped heat conducting pipes 301 and the connecting heat conducting pipes 303 after being concentrated through the heat conducting effect of the reinforcing heat conducting pipes 302 in the first shelter module 6, so that the heat on the connecting heat conducting pipes 303 is released to the surrounding air by the plurality of heat radiating fins 304, the shape of the heat radiating fins 304 is curved, the contact area between the surface and the outside is increased, and the heat radiating effect is accelerated.

As shown in fig. 2 and 11, a protection net 5 is fixedly installed between the inner walls of the installation opening 16, one end of the installation opening 16 is fixedly installed with a blowing component 4, the blowing component 4 comprises an installation pipe 406, a supporting rod 407 is fixedly installed between the inner walls of the installation pipe 406, a servo motor 408 is arranged on one side of the supporting rod 407, an output shaft of the servo motor 408 penetrates through the supporting rod 407 to the outside, a driving shaft 409 is fixedly installed on the output shaft of the servo motor 408, a plurality of fan blades 410 are fixedly installed on the outer surface of the driving shaft 409, the output shaft of the servo motor 408 is enabled to rotate by starting the servo motor 408, the driving shaft 409 is driven to rotate, and the fan blades 410 are driven to rotate by the rotation of the driving shaft 409.

As shown in fig. 11, one end of the installation tube 406 is fixedly connected with a ventilation tube 403, the front surface of the ventilation tube 403 is fixedly connected with a plurality of air outlet tubes 404, one ends of the plurality of air outlet tubes 404 are fixedly connected with an air outlet cavity 405, air enters the ventilation tube 403 from the installation tube 406, the ventilation tube 403 and the plurality of air outlet tubes 404 are all communicated, then the air is blown out from each air outlet cavity 405, and the outlets of the air outlet cavities 405 are opposite to different positions of the heat dissipation fins 304, so that the air flow can be increased, the heat transmission and dissipation can be accelerated, and the heat on the heat dissipation fins 304 can be taken away by the air flow generated by the rotation of the fan blades 410, and the air is discharged from the ventilation opening 9, so that the cooling can be accelerated.

As shown in fig. 11, a plurality of fixing rods 401 are fixedly mounted on an inner wall of one side of the second shelter module 7, each two of the plurality of fixing rods 401 are in a group, clamping blocks 402 are fixedly connected between one ends of each group of fixing rods 401, inner walls of the plurality of clamping blocks 402 are respectively clamped and connected to the outside of the ventilation pipe 403, and the ventilation pipe 403 is clamped through the clamping blocks 402, so that the ventilation pipe 403 is positioned on the inner wall of the second shelter module 7.

The application method and the working principle of the device are as follows: in use, the radar body 24 is firstly installed in the first shelter module 6, then the installation of the first shelter module 6 and the second shelter module 7 is realized by installing the installation plate 1 on an automobile, the first shelter module 6 and the second shelter module 7 are relatively independent and are not mutually interfered, the first shelter module 6 and the second shelter module 7 can be independently disassembled during maintenance, the use of equipment in the other module is not influenced, the first protective cover 14 and the second protective cover 15 are respectively installed on the top of the first shelter module 6 and the second shelter module 7 and can be turned over and opened and closed, when the first shelter module and the second shelter module are closed, pressure is applied downwards, each buckle 18 can be clamped into a fixing groove 19 at a corresponding position, meanwhile, the two limiting baffles 17 can block the corresponding first protective cover 14 and the second protective cover 15, so that the corresponding first protective cover 14 and the second protective cover 15 can not fall down during closing, wherein, the surfaces of the first shelter module 6 and the second shelter module 7 are coated with a heat scattering coating, the heat scattering coating can radiate heat to the surrounding environment more quickly by increasing the radiation capacity of the surfaces, so that the surface temperature of an object is reduced, the conventional heat scattering coating is coated with silicon carbide, the conventional heat scattering coating has higher heat conductivity and good heat radiation characteristics, the heat radiation efficiency can be effectively improved, when the radar main body 24 is in use, the heat is radiated in the first shelter module 6, the heat is concentrated and then sequentially transmitted to the U-shaped heat conducting pipe 301 and the connecting heat conducting pipe 303 through the heat conduction effect of the air heat conduction and the reinforcing heat conducting pipe 302 positioned in the first shelter module 6, the heat on the connecting heat conducting pipe 303 is released to the surrounding air by the plurality of heat radiating fins 304, the shape of the heat radiating fins 304 is bent, the contact area between the surface of the fan and the outside is increased, heat dissipation is accelerated, at this time, by starting the servo motor 408, the output shaft of the servo motor 408 rotates, thereby driving the driving shaft 409 to rotate, the rotation of the driving shaft 409 drives the fan blades 410 to rotate, the distribution of the fan blades 410 is uniformly distributed along the circumferential direction, the blades of each fan blade 410 are larger and keep inclined, the wind is stronger when the fan blades 410 rotate, then the wind enters the ventilation pipe 403 from the installation pipe 406, the ventilation pipe 403 and the plurality of air outlet pipes 404 are communicated, then the wind is blown out from each air outlet cavity 405, the outlets of the air outlet cavities 405 are opposite to different positions of the heat dissipation fins 304, the air flow can be increased, the heat transmission and dissipation are accelerated, the heat on the heat dissipation fins 304 is taken away by the air flow generated by the rotation of the fan blades 410, the heat is discharged from the ventilation opening 9, the cooling can be quickened, at this moment, when the humidity sensor 11 detects that the humidity in the first shelter module 6 is lower than the normal range, an abnormal signal is transmitted to the controller 8, the controller 8 is electrically connected with the humidity sensor 11 and the water pump 22 and is electrically connected with an external power supply, the controller 8 controls to start the water pump 22 after receiving the signal, the water in the water tank 10 is pumped out by the water inlet pipe 21 under the pressurizing action of the water pump 22 and is then sent out from the conveying pipe 13 to the communicating tank 205, the opening of the clamping ring 20 is clamped outside the connecting block 23, the cross section of the connecting block 23 is T-shaped, thereby the installation of the supporting frame 12 on the communicating tank 205 is completed, the supporting frame 12 is installed outside the first shelter module 6 by using bolts, the humidifying component 2 is positioned above the radar main body 24, the first protecting cover 14 is a net-shaped cover, the water mist can enter the first shelter module 6 for humidification, the reverse magnet 216 is embedded into the clamping groove 211 in the initial state, the material in the clamping groove 211 is thin and does not influence magnetism, the reverse magnet 216 can absorb the positioning magnet block 218, the positioning magnet block 218 is clamped into the positioning groove 217, the positioning magnet block 218 and the positioning groove 217 are matched polygons, the position of the connecting plate 204 can be limited, water can only be sprayed out from the bottom spray hole 210 through shielding of the side baffle 203 and the side spray hole 202, the water mist spraying range is small, the reverse magnet 216 is separated from the clamping groove 211 through rotating the adjusting block 212, the same-direction magnet 213 is clamped into the clamping groove 211, the positioning magnet block 218 and the same-direction magnet 213 are separated from the positioning groove 217 and are positioned above the positioning groove 217 under the action of homopolar repulsion, through the water flow passing through the communicating tank 205, the spiral blade 208 is impacted to rotate the spiral blade 208, so that the rotating shaft 206 and the connecting plate 204 are driven to rotate, the side baffle 203 moves along the inner wall of the nozzle 201, the side spray holes 202 continuously spray water mist outwards, the humidifying effect can be effectively improved, when the reverse magnet 216 is clamped into the clamping groove 211, the water flow impacts the spiral blade 208 to rotate, the positions of the positioning magnet 218 and the positioning groove 217 can be adjusted to be correspondingly matched, when the humidity sensor 11 detects that the humidity in the first shelter module 6 reaches the normal range, a signal is transmitted to the controller 8, and the controller 8 controls the water pump 22 to be closed, so that the water pump 22 stops pumping water, and the humidifying operation is stopped;

the humidity sensor 11 is a prior art, the structure and the working principle of the humidity sensor 11 are not described in detail herein, generally, the composition structure of the humidity sensor 11 mainly includes a first humidity sensing element, the humidity sensing element is a core component of the humidity sensor 11, and is capable of measuring humidity in an environment, a second temperature sensing element, the humidity sensor 11 is generally integrated with a temperature sensing element and is used for compensating accuracy of humidity measurement, because the humidity is closely related to temperature, a third signal processing circuit, a humidity signal measured by the humidity sensing element needs to be processed by the signal processing circuit to amplify, filter and convert the humidity signal into an accurate humidity value, a fourth power circuit, and the humidity sensor 11 generally needs to be powered to normally work, so that the power circuit is integrated, a direct current power supply is generally used, the working principle of the humidity sensor 11 is that when the environment humidity is increased, the capacitance value is increased by utilizing the principle that a capacitance value between a pair of metal electrodes changes along with humidity, when the environment humidity is increased, when the environment humidity is decreased, the capacitance value is reduced, and the humidity sensor can be calculated to accurately change the humidity value through the humidity sensor through the measurement, and the humidity sensor can be processed into the accurate humidity value.

The wiring diagrams of the servo motor 408, the controller 8, the humidity sensor 11 and the water pump 22 in the present invention are common knowledge in the art, and the working principle thereof is a known technology, and the model thereof is selected to be a proper model according to actual use, so that the control manner and wiring arrangement will not be explained in detail for the servo motor 408, the controller 8, the humidity sensor 11 and the water pump 22.

Although the present invention has been described with reference to the foregoing embodiments, it will be apparent to those skilled in the art that modifications may be made to the embodiments described, or equivalents may be substituted for elements thereof, and any modifications, equivalents, improvements and changes may be made without departing from the spirit and principles of the present invention.

Claims (10)

1. A vehicle-mounted radar shelter modular cooling unit, comprising:

the water tank (16) is arranged on the inner bottom surface of the second shelter module (7), the water pump (22) is arranged on the inner bottom surface of the second shelter module (7) close to the water tank (10), the water inlet of the water pump (22) is fixedly communicated with the water inlet pipe (21) through a flange plate, the water outlet of the water pump (22) is fixedly communicated with the conveying pipe (13) through the flange plate, and the mounting opening (16) is formed in the rear surface of the second shelter module (7);

-a cooling assembly (3), the cooling assembly (3) being arranged between the interior of the first shelter module (6) and the second shelter module (7);

humidification subassembly (2), humidification subassembly (2) are including intercommunication jar (205), the inside to intercommunication jar (205) is run through to the one end of conveyer pipe (13), the bottom fixed intercommunication of intercommunication jar (205) has nozzle (201), a plurality of bottom orifice (210) have been seted up to the bottom of nozzle (201), a plurality of side orifice (202) have been seted up to the surface of nozzle (201).

2. The vehicle-mounted radar shelter modular cooling unit of claim 1, wherein: the utility model discloses a radar protection system for the automobile, including first shelter module (7), second shelter module (7), radar main part (24) are provided with on the front surface of second shelter module (7), the inside bottom surface of first shelter module (6) is provided with radar main part (24), the top of first shelter module (6) is connected with first protective cover (14) through the hinge rotation, the top of second shelter module (7) is connected with second protective cover (15) through the hinge rotation, a plurality of fixed slots (19) have all been seted up to the surface of first protective cover (14) and the surface of second protective cover (15), a plurality of buckles (18) have all been seted up to the inside looks of inner wall of first shelter module (6) and second shelter module (7) one side of keeping away from mutually, every the inner wall of buckle (18) respectively with the surface looks block of a plurality of fixed slots (19), the inside of first shelter module (6) and the inside of second shelter module (7) are close to one side and all fixedly connected with limit baffle (17).

3. The vehicle-mounted radar shelter modular cooling unit of claim 2, wherein: the rear surface department that is close to the top of first shelter module (6) fixedly mounted with support frame (12), one side fixedly connected with snap ring (20) of support frame (12), the top fixedly connected with connecting block (23) of intercommunication jar (205), snap ring (20) block is at the surface of connecting block (23).

4. A vehicle-mounted radar shelter modular cooling unit as claimed in claim 3, wherein: limiting grooves (207) are formed in the inner wall of the communicating tank (205), a plurality of limiting shafts (209) are movably connected to the inner wall of the limiting grooves (207), spiral blades (208) are fixedly connected to opposite ends of the limiting shafts (209), rotating shafts (206) are fixedly connected between opposite ends of the spiral blades (208), connecting plates (204) are fixedly mounted at the bottom ends of the rotating shafts (206), and side baffles (203) are fixedly connected to four sides of each connecting plate (204).

5. The vehicle-mounted radar shelter modular cooling unit of claim 4, wherein: a positioning groove (217) is formed in the middle of the inner bottom surface of the nozzle (201), a positioning magnetic block (218) is fixedly connected to the bottom of the connecting plate (204), and the outer surface of the positioning groove (217) is matched with the outer surface of the positioning magnetic block (218).

6. The vehicle-mounted radar shelter modular cooling unit of claim 5, wherein: clamping grooves (211) are formed in the middle of the bottom of the nozzle (201), a fixed shaft (214) is fixedly connected to the bottom of the nozzle (201), a stop block (215) is fixedly connected to the bottom end of the fixed shaft (214), an adjusting block (212) is rotatably sleeved on the outer surface of the fixed shaft (214), a homodromous magnet (213) is fixed on the top of the adjusting block (212) close to one side, and a reverse magnet (216) is fixed on the top of the adjusting block (212) close to the other side.

7. The vehicle-mounted radar shelter modular cooling unit of claim 6, wherein: the cooling assembly (3) is provided with two, two the cooling assembly (3) all is including U type heat pipe (301), two the top of U type heat pipe (301) all welds and strengthens heat pipe (302), two the both ends of U type heat pipe (301) all run through inside first shelter module (6) to second shelter module (7), two the both ends of U type heat pipe (301) all movable sleeve is equipped with connects heat pipe (303), four connect heat pipe (303) average divide into two sets of, every group all be provided with a plurality of heat radiation fins (304) between the surface of connecting heat pipe (303).

8. The vehicle-mounted radar shelter modular cooling unit of claim 7, wherein: the utility model discloses a fan, including installation mouth (16), fixed mounting has protection network (5) between the inner wall of installation mouth (16), the one end fixed mounting of installation mouth (16) has subassembly (4) of blowing, subassembly (4) are including installation tube (406) of blowing, fixed mounting has bracing piece (407) between the inner wall of installation tube (406), one side of bracing piece (407) is provided with servo motor (408), the output shaft of servo motor (408) runs through bracing piece (407) to outside, the output shaft fixed mounting of servo motor (408) has drive shaft (409), the surface fixed mounting of drive shaft (409) has a plurality of flabellum (410).

9. The vehicle-mounted radar shelter modular cooling unit of claim 8, wherein: one end of the installation pipe (406) is fixedly communicated with a ventilation pipe (403), the front surface of the ventilation pipe (403) is fixedly communicated with a plurality of air outlet pipes (404), and one ends of the air outlet pipes (404) are fixedly communicated with an air outlet cavity (405).

10. The vehicle-mounted radar shelter modular cooling unit of claim 9, wherein: one side inner wall of second shelter module (7) fixed mounting has a plurality of dead levers (401), and a plurality of every two of dead lever (401) are a set of, every group all fixedly connected with clamp splice (402) between the one end of dead lever (401), a plurality of the equal block connection of inner wall of clamp splice (402) is in the outside of ventilation pipe (403).