CN116826349A - Ship radar cover ring control liquid cooling source unit - Google Patents

Abstract

The invention discloses a ship radar cover environmental control liquid cooling source unit, which relates to the technical field of ship radar covers and comprises a cold source unit mechanism, wherein the cold source unit mechanism is provided with a treatment mechanism, the treatment mechanism comprises a sealing box, two circular pipes and a connecting plate, a refrigerant pump is arranged at the top of the sealing box, first electric valves are arranged at the opposite ends of the two circular pipes, a refrigerant detector is arranged on the surface of the connecting plate, a second electric valve is arranged at the air outlet of a mounting hole, a fan body is arranged at the top of the sealing box, and a check valve is arranged at the output end of the L-shaped pipe.

Description

Ship radar cover ring control liquid cooling source unit

Technical Field

The invention relates to the technical field of ship radar covers, in particular to a ship radar cover ring control liquid cooling source unit.

Background

The naval vessel is commonly called as a warship, is also called as a naval vessel, and refers to naval vessel with weaponry, and can perform combat tasks in the ocean, and is the main naval equipment, wherein a radome is a window for electromagnetic waves, and is used for protecting a radar antenna of the naval vessel, and a loop control liquid cooling source unit is also equipment for cooling the radome.

In the actual use process of the prior annular control liquid cooling source unit for the ship radome, although the radome can be cooled, the service life of an antenna used in the radome is ensured, but the refrigerant replaced by the cooling source unit cannot be treated, and the main reason is that the refrigerant after long-time use can undergo chemical reaction and continuously emit harmful gas, and at the moment, if the refrigerant is replaced, the harmful gas emitted by the refrigerant can be scattered into the environment, pollute the environment and be inhaled by staff, the health of human bodies can be influenced, and then the use effect of the annular control liquid cooling source unit is reduced, namely the use efficiency of the annular control liquid cooling source unit is reduced.

Therefore, we propose a ship radar cover ring control liquid cooling source unit so as to solve the problems set forth above.

Disclosure of Invention

The invention aims to provide a ship radar cover ring-control liquid cooling source unit, which aims to solve the problems that the existing ring-control liquid cooling source unit cannot treat the refrigerant replaced from the cold source unit, and the main reason is that the refrigerant after long-time use can be subjected to chemical reaction and continuously emit harmful gas, and if the refrigerant is replaced, the harmful gas emitted by the refrigerant can be scattered into the environment to pollute the environment and be inhaled by workers, and the health of the human body is also influenced, so that the use effect of the ring-control liquid cooling source unit is reduced, namely the use efficiency of the ring-control liquid cooling source unit is reduced.

In order to achieve the above purpose, the present invention provides the following technical solutions: the ship radar cover ring control liquid cooling source unit comprises a cold source unit mechanism, wherein a processing mechanism is arranged on the cold source unit mechanism;

the processing mechanism comprises a sealing box, two circular pipes and a connecting plate, wherein a sealing plate is arranged on the front surface of the sealing box, a refrigerant pump is arranged at the top of the sealing box, a first liquid guide pipe is arranged at the input end of the refrigerant pump, two first electric valves are arranged at the opposite ends of the circular pipes, a refrigerant detector is arranged on the surface of the connecting plate, a second liquid guide pipe is arranged at the output end of the refrigerant pump, a first processing box is arranged in the sealing box, a mounting hole is formed in the top of the sealing box, a second electric valve is arranged at the air outlet of the mounting hole, a fan body is arranged at the top of the sealing box, a first air guide pipe is arranged at the input end of the fan body, a second air guide pipe is arranged at the output end of the fan body, a second processing box is arranged in the output end of the sealing box, two symmetrical L-shaped blocks are arranged at the bottom of the second processing box, a hose is arranged at the output end of the second air guide pipe, a filter screen is arranged at the output end of the hose, a second processing box is fixedly provided with an L-shaped air guide pipe, and a third non-return valve is arranged at the output end of the sealing box.

Preferably, the output end of one of the first electric valves is installed with the input end of the first liquid guide pipe, the output end of the second liquid guide pipe is fixedly penetrating through the top of the sealing box, the input end of the first air guide pipe is fixedly penetrating through the top of the sealing box, the top of the first processing box and the bottom of the output end of the second liquid guide pipe at the bottom of the input end of the first air guide pipe are in the same horizontal plane, and the output end of the second air guide pipe is fixedly penetrating through the top of the sealing box.

Preferably, the top of the second processing box is contacted with the top of the inner wall of the sealing box, the output end of the third air duct is close to the bottom of the inner wall of the third processing box, the second processing box is positioned between the first processing box and the third processing box, and the two L-shaped blocks are respectively arranged on the outer wall of the first processing box and the outer wall of the third processing box.

Preferably, the cold source unit mechanism comprises a bottom plate, the top at the bottom plate is fixed to the seal box, first water pump is installed at the top of first bottom plate, the feed liquor pipe is installed to the input of first water pump, the evaporimeter is installed at the top of bottom plate, two the outer wall that runs through the evaporimeter is all fixed to the relative one end of pipe, the connecting plate is fixed at the outer wall of evaporimeter, the outer wall at the evaporimeter is installed to the probe of refrigerant detector, and the inside that the probe of refrigerant detector extends to the evaporimeter.

Preferably, the output end of the first water pump is provided with a first connecting pipe, the output end of the first connecting pipe is arranged with the cooling liquid inlet of the evaporator, the top of the bottom plate is provided with a second water pump, and the input end of the second water pump is provided with a second connecting pipe.

Preferably, the input end of the second connecting pipe is installed with the cooling liquid outlet of the evaporator, the output end of the second water pump is provided with a liquid outlet pipe, the liquid inlet of the evaporator is provided with a one-way valve, and the air outlet of the evaporator is provided with a first air pipe.

Preferably, the top of bottom plate is installed the compressor, first tracheal output is installed with the input of compressor mutually, the second trachea is installed to the output of compressor, the top of bottom plate is provided with the condenser, the input of condenser is installed with the tracheal output of second mutually, the casing is all installed to the front surface and the rear surface of condenser.

Preferably, rectangular holes are formed in two opposite sides of the shell, air inlets are formed in the upper sides of the two shells, heat dissipation fans are mounted on the opposite sides of the two shells, air inlet ends of the two heat dissipation fans are located in the two rectangular holes respectively, and a throttle valve is mounted at the output end of the condenser.

Preferably, the output end of the throttle valve is provided with a first water pipe, the top of the bottom plate is provided with a third water pump, the input end of the third water pump is provided with the output end of the first water pipe, the output end of the third water pump is provided with a second water pipe, and the output end of the second water pipe is provided with the input end of the one-way valve.

Preferably, a controller is arranged at the top of the bottom plate, and the first water pump, the second water pump, the compressor, the two heat dissipation fans, the third water pump, the refrigerant pump, the two first electric valves, the refrigerant detector, the second electric valve and the fan body are electrically connected with the controller.

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

1. according to the invention, the processing mechanism is arranged, so that the harmful gas emitted by the refrigerant liquid to be replaced can be disposed, and the situation that the harmful gas emitted by the refrigerant is scattered into the environment, pollutes the environment and is inhaled by workers when the refrigerant is replaced can be effectively avoided, namely the use effect of an effective environment-friendly liquid cooling source unit is affected, when the refrigerant in the evaporator needs to be replaced through the cooperation of the refrigerant detector and the controller, the refrigerant pump, the first liquid guide tube, the second liquid guide tube, the circular tube, the first electric valve and the controller are utilized at the moment, so that the refrigerant liquid to be replaced can be conveyed into the first processing box for collection and storage.

2. According to the invention, through the cooperation of the refrigerant pump, the first liquid guide pipe, the second liquid guide pipe, the circular pipe, the first electric valve, the controller, the fan body, the first air guide pipe, the second air guide pipe, the hose and the filter screen, the refrigerant liquid which needs to be replaced in the evaporator can be pumped out, harmful gas scattered in the evaporator is given out and guided into the second processing box, and then under the cooperation of the second electric valve, the fan body, the first air guide pipe, the second air guide pipe, the hose and the filter screen, the harmful gas scattered between the first processing box and the sealing box can be guided into the second processing box, and then under the cooperation of the L-shaped pipe, the check valve and the third air guide pipe, the residual CFC gas can be guided into sodium hydroxide solution stored in the third processing box for reaction removal.

3. According to the invention, the cooling operation can be performed on the ship radome by arranging the cold source unit mechanism, namely, the use effect and the service life of an antenna in the radome are effectively ensured, and when the cooling operation is required on the radome, the cooling operation can be continuously performed on the radome by firstly utilizing the cooperation of the cooling liquid, the first water pump, the liquid inlet pipe, the first connecting pipe, the evaporator, the refrigerant, the second connecting pipe, the second water pump and the liquid outlet pipe, and then, under the cooperation of the evaporator, the first air pipe, the compressor, the second air pipe, the condenser, the shell, the air inlet hole, the heat dissipation fan, the throttle valve, the first water pipe, the third water pump, the second water pipe and the one-way valve, the evaporated and gasified refrigerant can be enabled to be led back to the inside of the evaporator, so that the heat in the cooling liquid with heat continuously entering the inside the evaporator can be absorbed.

Drawings

FIG. 1 is a perspective view of a ship radar cover ring control liquid cooling source unit of the invention;

FIG. 2 is a partial perspective view of a processing mechanism of a ship radar cover ring control liquid cooling source unit of the invention;

FIG. 3 is a schematic perspective view of a hose and a filter screen of a ship radar cover ring control liquid cooling source unit of the invention;

FIG. 4 is a bottom perspective view of a portion of a liquid cooling source unit for environmental control of a ship radar cover according to the present invention;

FIG. 5 is an enlarged perspective view of the liquid cooling source unit of FIG. 4A of the environmental control type radar cover of the ship in accordance with the present invention;

FIG. 6 is a top perspective view of a ship radar enclosure environmental control liquid cooling source unit according to the present invention;

FIG. 7 is a schematic diagram of a top view angle structure of a ship radar cover ring control liquid cooling source unit according to the present invention;

fig. 8 is a partial perspective view of a cold source unit mechanism of a ship radar cover ring control liquid cooling source unit of the invention.

In the figure: 1. a cold source unit mechanism; 101. a bottom plate; 102. a first water pump; 103. a liquid inlet pipe; 104. an evaporator; 105. a first connection pipe; 106. a second water pump; 107. a second connection pipe; 108. a liquid outlet pipe; 109. a one-way valve; 110. a first air tube; 111. a compressor; 112. a second air pipe; 113. a condenser; 114. a housing; 115. a rectangular hole; 116. an air inlet hole; 117. a heat radiation fan; 118. a throttle valve; 119. a first water pipe; 120. a third water pump; 121. a second water pipe; 122. a controller; 2. a processing mechanism; 201. a seal box; 202. a sealing plate; 203. a refrigerant pump; 204. a first catheter; 205. a first electrically operated valve; 206. a round tube; 207. a connecting plate; 208. a refrigerant detector; 209. a second catheter; 210. a first process cartridge; 211. a mounting hole; 212. a second electrically operated valve; 213. a fan body; 214. a first air duct; 215. a second air duct; 216. a second process cartridge; 217. an L-shaped block; 218. a hose; 219. a filter screen; 220. an L-shaped tube; 221. a non-return valve; 222. a third air duct; 223. and a third process cartridge.

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. 1-8, the present invention provides a technical solution: the ship radar cover ring control liquid cooling source unit comprises a cold source unit mechanism 1, wherein a processing mechanism 2 is arranged on the cold source unit mechanism 1;

the processing mechanism 2 comprises a sealing box 201, two circular pipes 206 and a connecting plate 207, wherein a sealing plate 202 is installed on the front surface of the sealing box 201, a refrigerant pump 203 is installed at the top of the sealing box 201, a first liquid guide pipe 204 is installed at the input end of the refrigerant pump 203, a first electric valve 205 is installed at the opposite ends of the two circular pipes 206, a refrigerant detector 208 is installed on the surface of the connecting plate 207, a second liquid guide pipe 209 is installed at the output end of the refrigerant pump 203, a first processing box 210 is arranged in the sealing box 201, a mounting hole 211 is formed at the top of the sealing box 201, a second electric valve 212 is installed at the air outlet of the mounting hole 211, a fan body 213 is installed at the top of the sealing box 201, a first air guide pipe 214 is installed at the input end of the fan body 213, a second air guide pipe 215 is installed at the output end of the fan body 213, a second processing box 216 is arranged in the sealing box 201, two symmetrical L-shaped blocks 217 are arranged at the bottom of the second processing box 216, a hose 218 is installed at the output end of the second air guide pipe 215, a third L-shaped valve 221 is installed at the output end of the second processing box 219, a filter screen 220 is installed at one side of the second processing box 216, and a third stop valve 221 is installed at the output end of the filter screen 220.

According to the embodiments shown in fig. 1, fig. 2, and fig. 4 to fig. 7, the output end of one of the first electric valves 205 is installed with the input end of the first liquid guide tube 204, the output end of the second liquid guide tube 209 is fixedly penetrating through the top of the sealing box 201, the input end of the first air guide tube 214 is fixedly penetrating through the top of the sealing box 201, the top of the first processing box 210 and the bottom of the output end of the second liquid guide tube 209 are at the same level, the output end of the second air guide tube 215 is fixedly penetrating through the top of the sealing box 201, and the harmful gas emitted by the refrigerant liquid to be replaced is conveniently fed into the activated carbon particles inside the second processing box 216 under the cooperation of the second air guide tube 215, the fan body 213, the hose 218, the filter screen 219 and the first air guide tube 214, so as to perform adsorption removal treatment.

As shown in fig. 1, 2, 4, 6 and 7, the top of the second process cartridge 216 is in contact with the top of the inner wall of the sealing cartridge 201, the output end of the third air duct 222 is close to the bottom of the inner wall of the third process cartridge 223, the second process cartridge 216 is located between the first process cartridge 210 and the third process cartridge 223, and two L-shaped blocks 217 are respectively installed on the outer wall of the first process cartridge 210 and the outer wall of the third process cartridge 223, so that the top of the second process cartridge 216 can be conveniently and tightly contacted with the top of the inner wall of the sealing cartridge 201 under the action of the L-shaped blocks 217.

According to fig. 1 and fig. 4-7, the cold source unit mechanism 1 includes a bottom plate 101, a sealing box 201 is fixed at the top of the bottom plate 101, a first water pump 102 is installed at the top of the first bottom plate 101, a liquid inlet pipe 103 is installed at the input end of the first water pump 102, an evaporator 104 is installed at the top of the bottom plate 101, opposite ends of two circular pipes 206 are all fixed to penetrate through the outer wall of the evaporator 104, a connecting plate 207 is fixed to the outer wall of the evaporator 104, a probe of a refrigerant detector 208 is installed on the outer wall of the evaporator 104, and the probe of the refrigerant detector 208 extends into the evaporator 104, so that whether the property of the refrigerant in the evaporator 104 changes can be monitored at any time under the action of the refrigerant detector 208.

According to the embodiments shown in fig. 1 and fig. 4-7, the output end of the first water pump 102 is provided with a first connecting pipe 105, the output end of the first connecting pipe 105 is installed with the cooling liquid inlet of the evaporator 104, the top of the bottom plate 101 is provided with a second water pump 106, the input end of the second water pump 106 is provided with a second connecting pipe 107, and the cooled cooling liquid is conveniently guided back into the radar cover under the cooperation of the second water pump 106, the second connecting pipe 107 and the liquid outlet pipe 108.

According to the embodiments shown in fig. 1 and fig. 4 to fig. 7, the input end of the second connecting pipe 107 is installed with the cooling liquid outlet of the evaporator 104, the output end of the second water pump 106 is installed with the liquid outlet pipe 108, the liquid inlet of the evaporator 104 is installed with the one-way valve 109, the air outlet of the evaporator 104 is installed with the first air pipe 110, so that the heat in the cooling liquid with heat entering the interior of the evaporator 104 can be absorbed conveniently under the cooperation of the evaporator 104 and the refrigerant, and the refrigerant can be evaporated and gasified.

According to fig. 1 and 4-8, a compressor 111 is installed at the top of a base plate 101, an output end of a first air pipe 110 is installed with an input end of the compressor 111, a second air pipe 112 is installed at an output end of the compressor 111, a condenser 113 is arranged at the top of the base plate 101, an input end of the condenser 113 is installed with an output end of the second air pipe 112, a shell 114 is installed on the front surface and the rear surface of the condenser 113, and refrigerant vapor entering the interior of the condenser 113 can be liquefied into liquid under the cooperation of the shell 114, a heat dissipation fan 117 and an air inlet 116.

According to the embodiments shown in fig. 1 and fig. 6 to fig. 8, rectangular holes 115 are formed on opposite sides of the two housings 114, air inlets 116 are formed on upper sides of the two housings 114, heat dissipation fans 117 are mounted on opposite sides of the two housings 114, air inlet ends of the two heat dissipation fans 117 are respectively located inside the two rectangular holes 115, a throttle valve 118 is mounted at an output end of the condenser 113, and a pressure difference between the condenser 113 and the evaporator 104 can be ensured under the action of the throttle valve 118, so that refrigerant flowing back into the evaporator 104 is suitable for load change.

According to the embodiments shown in fig. 1 and fig. 4 to 7, the first water pipe 119 is installed at the output end of the throttle valve 118, the third water pump 120 is installed at the top of the bottom plate 101, the input end of the third water pump 120 is installed with the output end of the first water pipe 119, the second water pipe 121 is installed at the output end of the third water pump 120, and the output end of the second water pipe 121 is installed with the input end of the check valve 109, so that the refrigerant steam can be prevented from entering the second water pipe 121 conveniently under the action of the check valve 109.

As shown in fig. 1, 2 and 4-7, the top of the bottom plate 101 is provided with a controller 122, and the first water pump 102, the second water pump 106, the compressor 111, the two heat dissipation fans 117, the third water pump 120, the refrigerant pump 203, the two first electric valves 205, the refrigerant detector 208, the second electric valve 212 and the fan body 213 are electrically connected with the controller 122, so that any one or more devices electrically connected with the controller 122 can be controlled to perform on-off operation under the action of the controller 122.

The whole mechanism achieves the following effects: when the radome needs to be cooled, the input end of the liquid inlet pipe 103 is connected with the liquid outlet of the radome, the output end of the liquid outlet pipe 108 is connected with the liquid inlet of the radome, the controller 122 is connected with an external power supply, the sealing plate 202 is removed, the two L-shaped blocks 217 are removed, a proper amount of activated carbon particles are injected into the second processing box 216, the second processing box 216 is fixed by the two L-shaped blocks 217, a proper amount of sodium hydroxide solution is directly injected into the third processing box 223 after the fixing operation of the second processing box 216 is finished, the sealing plate 202 is installed to the initial position after the injection of the sodium hydroxide solution is finished, when everything is ready, the controller 122 is used for opening the other first electric valve 205, a proper amount of refrigerant is directly injected into the evaporator 104, the controller 122 is used for closing the other first electric valve 205, and the controller 122 is used for starting the compressor 111, the two fans 117, the third water pump 120, the first water pump 120 and the first water pump 102 are synchronously started, and the first heat dissipation pump 106 is startedThe water pump 102 directly pumps the cooling liquid in the radome through the matching of the liquid inlet pipe 103, the pumped cooling liquid directly takes away the heat in the radome, then flows into the first connecting pipe 105, and then is directly conveyed into the evaporator 104, when the cooling liquid with heat enters the evaporator 104, the refrigerant in the evaporator 104 directly absorbs the heat in the cooling liquid with heat, then the refrigerant absorbing heat is directly evaporated, the cooled cooling liquid is directly guided into the liquid outlet pipe 108 through the matching of the started second water pump 106 and the second connecting pipe 107, then flows back into the radome, so that the temperature in the radome can be taken away, and the cooling operation of the radome is realized, the antenna inside the radome is ensured to be used, meanwhile, the started compressor 111 directly sucks the refrigerant steam into the inside 111 of the compressor under the cooperation of the first air pipe 110, when the refrigerant steam reaches the inside of the compressor 111, the pressure of the refrigerant steam is directly increased to the condensation pressure corresponding to the condensation temperature under the action of the compressor 111, so that the refrigerant steam can be condensed and liquefied at normal temperature, then the refrigerant steam with the increased proper pressure can be directly guided into the condenser 113 under the action of the second air pipe 112, when the refrigerant steam reaches the inside of the condenser 113, the refrigerant steam passing through the inside of the condenser 113 is directly liquefied into normal temperature liquid under the cooperation of the two started heat dissipation fans 117 and the two air inlets 116, and then the refrigerant steam passing through the inside of the condenser 113 is directly liquefied into normal temperature liquid under the cooperation of the throttle valve 118, the third water pump 120, the first water pipe 119, the second water pipe 121 and the check valve 109 cooperate to directly guide the normal-temperature refrigerant liquid back to the interior of the evaporator 104, so that the refrigerant liquid with temperature can be continuously cooled down, and at the same time, the refrigerant detector 208 also monitors the property of the refrigerant in the interior of the evaporator 104 at any time, and the monitored property data is transmitted to the interior of the controller 122 in an electrical signal mode, and then displayed on a screen of the controller 122, when the data displayed on the screen of the controller 122 exceeds the existing refrigerationWhen the refrigerant pump 203 is started, the refrigerant pump 203 started at this time directly pumps the refrigerant liquid to be replaced in the evaporator 104 to the inside of the first processing box 210 under the cooperation of the first liquid guide tube 204, the two first liquid guide tubes 205 and the two round tubes 206, and directly guides the refrigerant liquid to be replaced to the inside of the first processing box 210 under the action of the second liquid guide tube 209, at the same time, the started fan body 213 directly pumps away harmful gases such as CFC, HFC and ammonia gas emitted from the refrigerant liquid to be replaced under the cooperation of the first air duct 214, then directly guides the harmful gases into the hose 218 under the action of the second air duct 215, then passes through the mesh of the filter screen 219, and is discharged into the activated carbon particles stored in the second processing box 216, when the harmful gases contact the activated carbon particles, the activated carbon particles directly adsorb and remove HFC and ammonia gas in the harmful gases, and also adsorb and remove a part of CFC gas, then the processed gases directly enter the inside of the L-shaped tube 220, then enter the inside of the check valve 221, then enter the inside of the third air duct 222, and then enter the sodium hydroxide solution stored in the third processing box 223, when the gas contacts sodium hydroxide solution, the residual CFC gas in the gas directly reacts with sodium hydroxide solution to generate NaCl, naF and H ₂ O, when the refrigerant liquid in the evaporator 104 is completely pumped out, the controller 122 is used to close the two first electric valves 205 and the refrigerant pump 203, and then the controller 122 is used to open the second electric valve 212, and then the harmful gas emitted by the refrigerant liquid to be replaced can be fed and transported away and entered under the cooperation of the second electric valve 212 and the fan body 213When the refrigerant liquid does not emit harmful gas, the controller 122 directly closes the second electric valve 212 and the fan body 213, and the first process cartridge 210 is taken out of the sealed cartridge 201 to perform post-treatment

The refrigerant detector 208 is a refrigerant property detector, and is a detecting refrigerant property detector, which can detect chemical components and properties of the refrigerant, and when the detection result shows that the refrigerant property changes, the old refrigerant needs to be discharged and a new refrigerant needs to be refilled;

the first water pump 102, the second water pump 106, the check valve 109, the compressor 111, the condenser 113, the heat dissipation fan 117, the throttle valve 118, the third water pump 120, the controller 122 (PLC controller), the refrigerant pump 203, the first electric valve 205, the second electric valve 212, the fan body 213, the filter screen 219, and the check valve 221 are all conventional technologies, and will not be explained here too much.

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. The utility model provides a ship radar cover environmental control liquid cooling source unit which characterized in that: the cold source unit comprises a cold source unit mechanism (1), wherein a processing mechanism (2) is arranged on the cold source unit mechanism (1);

the processing mechanism (2) comprises a sealing box (201), two circular tubes (206) and a connecting plate (207), wherein a sealing plate (202) is arranged on the front surface of the sealing box (201), a refrigerant pump (203) is arranged at the top of the sealing box (201), a first liquid guide tube (204) is arranged at the input end of the refrigerant pump (203), first electric valves (205) are arranged at the opposite ends of the two circular tubes (206), a refrigerant detector (208) is arranged on the surface of the connecting plate (207), a second liquid guide tube (209) is arranged at the output end of the refrigerant pump (203), a first processing box (210) is arranged in the sealing box (201), a mounting hole (211) is formed in the top of the sealing box (201), a second electric valve (212) is arranged at the air outlet of the mounting hole (211), a fan body (213) is arranged at the top of the sealing box (201), a first air guide tube (214) is arranged at the input end of the fan body (213), a second air guide tube (215) is arranged at the output end of the fan body (213), a second processing box (216) is symmetrically arranged at the bottom of the second processing box (216), the hose (218) is installed to the output of second air duct (215), filter screen (219) is installed to the output of hose (218), one side of second processing box (216) is fixed to be run through has L type pipe (220), check valve (221) are installed to the output of L type pipe (220), third air duct (222) are installed to the output of check valve (221), the inside of sealing box (201) is provided with third processing box (223).

2. The ship radar cover ring control liquid cooling source unit according to claim 1, wherein: one of them the output of first motorised valve (205) is installed with the input of first catheter (204), the top of sealed box (201) is fixed to run through in second catheter (209) output, the top of sealed box (201) is fixed to run through in the input of first air duct (214), the top of first processing box (210) and the output bottom of the equal second catheter (209) in input bottom of first air duct (214) are in same horizontal plane, the top of sealed box (201) is fixed to run through in the output of second air duct (215).

3. The ship radar cover ring control liquid cooling source unit according to claim 1, wherein: the top of the second processing box (216) is contacted with the top of the inner wall of the sealing box (201), the output end of the third air duct (222) is close to the bottom of the inner wall of the third processing box (223), the second processing box (216) is positioned between the first processing box (210) and the third processing box (223), and the two L-shaped blocks (217) are respectively arranged on the outer wall of the first processing box (210) and the outer wall of the third processing box (223).

4. The ship radar cover ring control liquid cooling source unit according to claim 1, wherein: the cold source unit mechanism (1) comprises a bottom plate (101), the top at bottom plate (101) is fixed to seal box (201), first water pump (102) are installed at the top of first bottom plate (101), feed liquor pipe (103) are installed at the input of first water pump (102), evaporimeter (104) are installed at the top of bottom plate (101), two the outer wall that runs through evaporimeter (104) is all fixed to the relative one end of pipe (206), connecting plate (207) are fixed at the outer wall of evaporimeter (104), the outer wall at evaporimeter (104) is installed to the probe of refrigerant detector (208), and the inside that the probe of refrigerant detector (208) extends to evaporimeter (104).

5. The ship radar cover ring control liquid cooling source unit according to claim 4, wherein: the output end of the first water pump (102) is provided with a first connecting pipe (105), the output end of the first connecting pipe (105) is installed with a cooling liquid inlet of the evaporator (104), the top of the bottom plate (101) is provided with a second water pump (106), and the input end of the second water pump (106) is provided with a second connecting pipe (107).

6. The ship radar cover ring control liquid cooling source unit according to claim 5, wherein: the input end of the second connecting pipe (107) is installed with the cooling liquid outlet of the evaporator (104), the output end of the second water pump (106) is provided with a liquid outlet pipe (108), the liquid inlet of the evaporator (104) is provided with a one-way valve (109), and the air outlet of the evaporator (104) is provided with a first air pipe (110).

7. The ship radar cover ring control liquid cooling source unit according to claim 6, wherein: the top of bottom plate (101) is installed compressor (111), the output of first trachea (110) is installed with the input of compressor (111) mutually, second trachea (112) are installed to the output of compressor (111), the top of bottom plate (101) is provided with condenser (113), the input of condenser (113) is installed with the output of second trachea (112) mutually, casing (114) are all installed to the front surface and the rear surface of condenser (113).

8. The ship radar cover ring control liquid cooling source unit according to claim 7, wherein: rectangular holes (115) are formed in opposite sides of the two shells (114), air inlets (116) are formed in the upper sides of the two shells (114), heat dissipation fans (117) are mounted on opposite sides of the two shells (114), air inlet ends of the two heat dissipation fans (117) are respectively located in the two rectangular holes (115), and a throttle valve (118) is mounted at the output end of the condenser (113).

9. The ship radar cover ring control liquid cooling source unit according to claim 8, wherein: the output end of the throttle valve (118) is provided with a first water pipe (119), the top of the bottom plate (101) is provided with a third water pump (120), the input end of the third water pump (120) is provided with the output end of the first water pipe (119), the output end of the third water pump (120) is provided with a second water pipe (121), and the output end of the second water pipe (121) is provided with the input end of the one-way valve (109).

10. The ship radar cover ring control liquid cooling source unit according to claim 9, wherein: the top of bottom plate (101) is provided with controller (122), first water pump (102), second water pump (106), compressor (111), two radiator fan (117), third water pump (120), refrigerant pump (203), two first motorised valves (205), refrigerant detector (208), second motorised valve (212) and fan body (213) all with controller (122) electric connection.