CN218826524U - Radiating structure of large-current high-frequency water-cooled reactor - Google Patents

Abstract

The utility model relates to a heavy current high frequency water-cooling reactor heat radiation structure, including the water-cooling reactor body, the lower fixed surface of water-cooling reactor body has the pillar, be equipped with air cooling mechanism on the water-cooling reactor body, be equipped with water-cooling mechanism in the air cooling mechanism, air cooling mechanism is including fixing the heat conduction frame in the water-cooling reactor body outside. This heavy current high frequency water-cooling reactor heat radiation structure, be provided with air-cooled mechanism and water-cooling mechanism, mutually support between each structure of air-cooled mechanism and water-cooling mechanism, can effectually dispel the heat for the reactor, at first derive the heat that the reactor work produced through the heat conduction frame, dispel the heat by a plurality of fin again, the fan makes circulation of air around the fin simultaneously, make the rate of heat dissipation of fin promote, still make the water of water tank into cold water through the refrigeration piece, inputing cold water to the circulating pipe through the water pump, and dispel the heat for the heat conduction frame when the circulating pipe circulates.

Description

Radiating structure of large-current high-frequency water-cooled reactor

Technical Field

The utility model relates to a water-cooling reactor technical field specifically is a heavy current high frequency water-cooling reactor heat radiation structure.

Background

At present, with the rapid development of wind power generation and light energy power generation systems, in order to ensure that a power generation system can continuously output stable sine waves, a high-current high-frequency water-cooled reactor is more and more widely applied.

When the large-current high-frequency water-cooling reactor is used, a large amount of heat can be generated due to the operation of components, if the heat is not dissipated as soon as possible in time, the normal work of the water-cooling reactor can be influenced, the water-cooling reactor can be damaged even, however, a heat dissipation assembly arranged in the traditional water-cooling reactor is difficult to dissipate heat for the water-cooling reactor, the heat dissipation effect is poor, only partial heat can be dissipated during heat dissipation, partial heat is still gathered in the water-cooling reactor, and once the time process is completed, the work of the water-cooling reactor can be influenced.

SUMMERY OF THE UTILITY MODEL

Not enough to prior art, the utility model provides a heavy current high frequency water-cooling reactor heat radiation structure possesses advantages such as the radiating effect is good, has solved the problem that can only have partial heat to dispel when the heat dissipation.

In order to achieve the above object, the utility model provides a following technical scheme: a heat dissipation structure of a large-current high-frequency water-cooled reactor comprises a water-cooled reactor body, wherein a supporting column is fixed on the lower surface of the water-cooled reactor body, an air cooling mechanism is arranged on the water-cooled reactor body, and a water cooling mechanism is arranged on the air cooling mechanism;

the air cooling mechanism comprises a heat conduction frame fixed on the outer side of the water-cooling reactor body, a mounting frame is fixed on the upper surface of the heat conduction frame, box bodies are fixed on the front surface and the back surface of the mounting frame, fans are fixed inside the box bodies, a protective net is fixed inside the box bodies, the outer sides of the box bodies are communicated with at least two air guide pipes, one ends, far away from the box bodies, of the air guide pipes are communicated with guide covers, and cooling fins are fixed on the front surface and the back surface of the heat conduction frame.

Further, water-cooling mechanism is including fixing the water tank at the mounting bracket upper surface, the last fixed surface of mounting bracket has the water pump, the end intercommunication of intaking of water pump has the inlet tube, and the other end runs through and extends to the inside of water tank, the play water end intercommunication of water pump has the outlet pipe, the one end intercommunication that the water pump was kept away from to the outlet pipe has the circulating pipe, and fixes the outside at the heat conduction frame, the one end intercommunication that the outlet pipe was kept away from to the circulating pipe has the back flow, and the other end runs through and extends to the inside of water tank, be equipped with the refrigeration piece on the water tank.

Further, the shape of heat conduction frame is the cuboid that inside cavity and top surface and bottom surface all lacked, two are no less than to the quantity of fin.

Furthermore, an air hole is formed in the outer side of the box body, and the outer diameter of the air pipe is matched with the inner diameter of the air hole.

Furthermore, a sealing ring is fixed on the outer side of the circulating pipe, and the water outlet pipe and the return pipe are both communicated inside the sealing ring.

Furthermore, the shape of the circulating pipe is spiral, and the refrigeration piece is a semiconductor refrigeration piece.

Furthermore, the refrigeration piece comprises an outer machine and an inner machine, the outer machine is fixed on the left side of the water tank, and the inner machine is fixed on the inner left wall of the water tank.

Compared with the prior art, the technical scheme of the application has the following beneficial effects:

1. this heavy current high frequency water-cooling reactor heat radiation structure is provided with air-cooling mechanism, mutually supports between each structure of air-cooling mechanism, can effectually dispel the heat for the reactor, at first derives the heat that the reactor work produced through heat conduction frame, is dispelled the heat by a plurality of fin again, and the fan makes circulation of air around the fin simultaneously, makes the rate of heat dissipation of fin promote.

2. The large-current high-frequency water-cooled reactor heat dissipation structure is provided with the water cooling mechanism, the water cooling mechanism is matched with each structure, water in the water tank is made into cold water through the refrigerating sheet, the cold water is input into the circulating pipe through the water pump, and the heat is dissipated for the heat conduction frame when the circulating pipe circulates, so that heat of the reactor can be dissipated as soon as possible.

Drawings

FIG. 1 is a schematic structural view of the present invention;

FIG. 2 is a schematic view of the air cooling mechanism of the present invention;

fig. 3 is a schematic view of the water cooling mechanism of the present invention.

In the figure: the water cooling reactor comprises a support 1, a water cooling reactor body 2, an air cooling mechanism 3, a heat radiating fin 301, a heat conducting frame 302, an air pipe 303, a protective net 304, a fan 305, a box 306, a guide cover 307, a mounting rack 308, a water cooling mechanism 4, a water tank 401, a water outlet pipe 402, a circulating pipe 403, a return pipe 404, a refrigerating piece 405, a water pump 406 and a water inlet pipe 407.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative efforts all belong to the protection scope of the present invention.

Referring to fig. 1, the heat dissipation structure of the large-current high-frequency water-cooled reactor in the embodiment includes a water-cooled reactor body 2, a pillar 1 is fixed on a lower surface of the water-cooled reactor body 2, an air cooling mechanism 3 is disposed on the water-cooled reactor body 2, and a water cooling mechanism 4 is disposed on the air cooling mechanism 3.

Through the cooperation of water-cooling mechanism 4 and air-cooling mechanism 3, can effectual improvement water-cooling reactor body 2's radiating effect.

Referring to fig. 2, the air cooling mechanism 3 in this embodiment includes a heat conducting frame 302 fixed outside the water-cooled reactor body 2, the heat conducting frame 302 has a good heat conducting effect, so that the heat conducting frame 302 guides heat out of the water-cooled reactor body 2, an installation frame 308 is fixed on an upper surface of the heat conducting frame 302, the installation frame 308 is U-shaped, a box 306 is fixed on both front and back surfaces of the installation frame 308, a fan 305 is fixed inside the box 306, the fan 305 runs to blow air in the direction of the protective net 304, the air duct 303 and the guide cover 307 generate negative pressure in the area of the heat sink 301, the protective net 304 is fixed inside the box 306, at least two air guiding ducts 303 are communicated outside the box 306, one end of the air guiding duct 303, which is far away from the box 306, is communicated with the guide cover 307, the guide cover 307 faces the direction of the heat sink 301, the heat sink 301 is fixed on both front and back surfaces of the heat conducting frame 302, and the heat sink 301 dissipates heat guided out by the heat conducting frame 302.

The shape of heat conduction frame 302 is the cuboid of inside cavity and the equal disappearance of top surface and bottom surface, and two are no less than to the quantity of fin 301, and the wind hole has been seted up in the outside of box body 306, and the external diameter of tuber pipe 303 and the internal diameter looks adaptation in wind hole.

The heat of the water-cooled reactor body 2 is conducted out through the heat conduction frame 302, the heat is dissipated by the heat dissipation fins 301, and the fan 305 circulates air around the heat dissipation fins 301, so that the speed of the heat dissipation fins 301 is increased.

The air cooling mechanism 3 can effectively dissipate heat of the reactor through mutual matching of the structures, firstly, heat generated by the operation of the reactor is led out through the heat conducting frame 302, then, the heat is dissipated through the plurality of radiating fins 301, and meanwhile, the fan 305 enables air around the radiating fins 301 to circulate, so that the heat dissipation rate of the radiating fins 301 is improved.

Referring to fig. 3, the water cooling mechanism 4 in this embodiment includes a water tank 401 fixed on the upper surface of the mounting frame 308, a water pump 406 is fixed on the upper surface of the mounting frame 308, the water pump 406 transports cold water from the water tank 401 through a water inlet pipe 407, a water inlet end of the water pump 406 is communicated with the water inlet pipe 407, and the other end penetrates and extends to the inside of the water tank 401, a water outlet end of the water pump 406 is communicated with a water outlet pipe 402, the water outlet pipe 402 transports the cold water into a circulating pipe 403, one end of the water outlet pipe 402, which is far away from the water pump 406, is communicated with a circulating pipe 403, the circulating pipe 403 is spiral, which enables the circulation time of the cold water in the circulating pipe 403 to be prolonged, and is fixed outside the heat conducting frame 302, one end of the circulating pipe 403, which is far away from the water outlet pipe 402, is communicated with a return pipe 404, and the other end penetrates and extends to the inside of the water tank 401, a cooling fin 405 is disposed on the water tank 401, and the cooling fin 405 works to make the water in the water tank 401 into cold water.

A sealing ring is fixed on the outer side of the circulating pipe 403, the water outlet pipe 402 and the return pipe 404 are both communicated inside the sealing ring, the circulating pipe 403 is spiral, the refrigerating sheet 405 is a semiconductor refrigerating sheet 405, the refrigerating sheet 405 comprises an outer machine and an inner machine, the outer machine is fixed on the left side of the water tank 401, and the inner machine is fixed on the inner left wall of the water tank 401.

The water in the water tank 401 is refrigerated through the refrigerating sheet 405, and the water is transported into the circulating pipe 403 by the water pump 406, so that the cold water cools the heat conducting frame 302 and the heat radiating fins 301, and the heat in the water-cooled reactor body 2 can be rapidly dissipated.

The water cooling mechanism 4 is matched with each other through the structures, water in the water tank 401 is made into cold water through the refrigerating sheet 405, the cold water is input into the circulating pipe 403 through the water pump 406, and heat is dissipated for the heat conducting frame 302 when the circulating pipe 403 circulates, so that heat of the reactor can be dissipated as soon as possible.

The working principle of the above embodiment is as follows:

(1) Make air-cooling mechanism 3 and water-cooling mechanism 4 operation after the reactor begins to work, can produce a large amount of heats at the in-process of reactor work, heat conduction frame 302 has good heat conduction effect, thereby make heat conduction frame 302 derive the heat in the water-cooling reactor body 2, and the heat that is derived by fin 301 with heat conduction frame 302 after the heat is derived is dispelled, thereby promote the heat conduction effect of water-cooling reactor body 2, open fan 305 simultaneously, fan 305 moves and bloies to protection network 304 direction, tuber pipe 303 and guide cover 307 make the regional negative pressure that produces of fin 301, make the air of fin 301 department circulate, thereby improve the rate of heat dissipation of fin 301.

(2) After the air cooling mechanism 3 starts to operate, the chilling plate 405 and the water pump 406 are operated, the chilling plate 405 works to make water in the water tank 401 into cold water, the water pump 406 transports the cold water out of the water tank 401 through the water inlet pipe 407, the cold water is transported into the circulating pipe 403 through the water outlet pipe 402 to circulate in the circulating pipe 403, the cold water circulates in the circulating pipe 403, the temperature of the heat conduction frame 302 can be reduced, the temperature of the radiating fins 301 can be reduced, heat in the reactor water cooling body 2 can be dissipated as soon as possible, the circulating pipe 403 is spiral, the circulation time of the cold water circulation can be prolonged, the cold water reduces the temperature of the heat conduction frame 302 and the radiating fins 301, the temperature of the cold water rises, the return pipe 404 guides the heated cold water into the water tank 401, the cold water is cooled by the chilling plate 405, the circulation is repeated, the cold water continuously circulates in the circulating pipe 403, and the reactor water cooling body 2 cannot be affected by the heat.

It is noted that, herein, relational terms such as first and second, and the like may be used solely to distinguish one entity or action from another entity or action without necessarily requiring or implying any actual such relationship or order between such entities or actions. Also, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus. Without further limitation, an element defined by the phrases "comprising a," "8230," "8230," or "comprising" does not exclude the presence of additional like elements in a process, method, article, or apparatus that comprises the element.

Although embodiments of the present invention have been shown and described, it will be appreciated by those skilled in the art that changes, modifications, substitutions and alterations can be made in these embodiments without departing from the principles and spirit of the invention, the scope of which is defined in the appended claims and their equivalents.

Claims (7)

1. The utility model provides a big current high frequency water-cooling reactor heat radiation structure, includes water-cooling reactor body (2), its characterized in that: a support column (1) is fixed on the lower surface of the water-cooling reactor body (2), an air-cooling mechanism (3) is arranged on the water-cooling reactor body (2), and a water-cooling mechanism (4) is arranged on the air-cooling mechanism (3);

the air cooling mechanism (3) comprises a heat conduction frame (302) fixed on the outer side of a water-cooling reactor body (2), wherein a mounting rack (308) is fixed on the upper surface of the heat conduction frame (302), a box body (306) is fixed on the front side and the back side of the mounting rack (308), a fan (305) is fixed inside the box body (306), a protective net (304) is fixed inside the box body (306), the outer side of the box body (306) is communicated with at least two air guide pipes (303), one ends, far away from the box body (306), of the air guide pipes (303) are communicated with a guide cover (307), and cooling fins (301) are fixed on the front side and the back side of the heat conduction frame (302).

2. The large-current high-frequency water-cooled reactor heat dissipation structure according to claim 1, characterized in that: water-cooling mechanism (4) are including fixing water tank (401) at mounting bracket (308) upper surface, the last fixed surface of mounting bracket (308) has water pump (406), the end intercommunication of intaking of water pump (406) has inlet tube (407), and the other end runs through and extends to the inside of water tank (401), the play water end intercommunication of water pump (406) has outlet pipe (402), the one end intercommunication that water pump (406) were kept away from in outlet pipe (402) has circulating pipe (403), and fixes the outside at heat conduction frame (302), the one end intercommunication that outlet pipe (402) were kept away from in circulating pipe (403) has back flow (404), and the other end runs through and extends to the inside of water tank (401), be equipped with refrigeration piece (405) on water tank (401).

3. The heat dissipation structure of the large-current high-frequency water-cooling reactor as recited in claim 1, wherein: the shape of heat conduction frame (302) is the cuboid that inside cavity and top surface and bottom surface all lacked, two are no less than to the quantity of fin (301).

4. The large-current high-frequency water-cooled reactor heat dissipation structure according to claim 1, characterized in that: an air hole is formed in the outer side of the box body (306), and the outer diameter of the air pipe (303) is matched with the inner diameter of the air hole.

5. The heat dissipation structure of the large-current high-frequency water-cooling reactor as recited in claim 2, wherein: and a sealing ring is fixed on the outer side of the circulating pipe (403), and the water outlet pipe (402) and the return pipe (404) are both communicated in the sealing ring.

6. The large-current high-frequency water-cooled reactor heat dissipation structure according to claim 2, characterized in that: the circulating pipe (403) is spiral in shape, and the refrigerating sheet (405) is a semiconductor refrigerating sheet (405).

7. The heat dissipation structure of the large-current high-frequency water-cooling reactor as recited in claim 2, wherein: the refrigeration piece (405) comprises an outer machine and an inner machine, the outer machine is fixed on the left side of the water tank (401), and the inner machine is fixed on the inner left wall of the water tank (401).

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