CN223007781U - Water-collecting cold air-cooling integrated radiator structure - Google Patents

Abstract

The utility model relates to the technical field related to radiators, in particular to a water-collecting cold air-cooling integrated radiator structure which comprises a bottom plate and a cooling mechanism, wherein the cooling mechanism is arranged on one side of the surface of the bottom plate. This radiator structure based on cold integration of catchment cold wind, through cooling mechanism's setting, when needing to dispel the heat, firstly add the coolant liquid in the cooling storehouse through the water inlet, afterwards through the contact with the cooling stick, absorb the heat, after the cooling is accomplished, start first water pump, flow the coolant liquid in the cold water storehouse from the apopore, send the cooling tube through the connecting tube pump, the cooling tube closely laminates with the heating panel, absorb the heat on the heating panel, simultaneously, the motor drives the flabellum and rotates, and then reduce the temperature of cooling tube, improve radiating efficiency, start the second water pump at last, and then after absorbing thermal coolant liquid through connecting tube, flow back to the cold water storehouse through the return water hole, thereby constitute a closed circulation loop.

Description

Water-collecting cold air-cooling integrated radiator structure

Technical Field

The utility model relates to the technical field related to radiators, in particular to a water-collecting cold air-cooling integrated radiator structure.

Background

The radiator is a device for radiating excessive heat generated by electronic equipment, mechanical equipment or other heat sources, and transfers the heat from the inside of the equipment to the external environment in a conduction, convection or radiation mode to prevent the equipment from overheating, improve the running stability and service life, and common radiators comprise air-cooled radiators, water-cooled radiators and the like, are widely applied to the fields of computers, automobiles, industrial equipment and the like, and along with the development of scientific technology, the requirements on the radiator are also higher and higher, so that a radiator structure integrating water collection, cold air cooling and the like is particularly needed.

However, most of existing radiator structures adopt a single or water-cooled or air-cooled mode to radiate heat, the radiating function is single, the radiating effect is poor, and the local radiating work cannot be stably performed.

Disclosure of utility model

The utility model aims to provide a water-collecting cold air-cooling integrated radiator structure, which aims to solve the problems that the existing radiator structure based on the water-collecting cold air-cooling integrated radiator structure provided in the background art mostly adopts a single or water-cooling or air-cooling mode to radiate heat, has a single radiating function, has poor radiating effect and cannot stably conduct local radiating work.

In order to achieve the aim, the utility model provides the technical scheme that the radiator structure integrating water collection, cold air and cold air comprises a bottom plate and a cooling mechanism, wherein one side of the surface of the bottom plate is provided with the cooling mechanism;

The cooling mechanism comprises a first support frame, a second support frame, a heat radiation plate, a cold water bin, a first mounting groove, a second mounting groove, a water inlet, a water outlet, a water return hole, a cooling rod, fan blades, a motor, a first water pump, a second water pump, a connecting pipeline and a heat radiation pipeline, wherein the first support frame is fixedly connected to one side of the surface of the bottom plate, the second support frame is fixedly connected to one side of the surface of the bottom plate, the heat radiation plate is mounted on one side of the bottom plate, the cold water bin is mounted on one side of the surface of the first support frame, the first mounting groove is formed in one side of the second support frame, the water inlet is formed in one side of the cold water bin, the water outlet is formed in the surface of the cold water bin, the water return hole is formed in two sides of the cold water bin, the cooling rod is mounted in the inner part of the cold water bin, the fan blades are mounted in the inner part of the first mounting groove, the motor is mounted on one side of the water outlet, the second water pump is mounted on one side of the second water pump, and the heat radiation pipeline is connected to the other side of the water return hole.

Preferably, the heat dissipation pipeline is aligned with the heat dissipation plate, and the heat dissipation pipeline is attached to the heat dissipation plate.

Preferably, the second water pump is provided with four groups, and the other side of the second water pump is connected with a connecting pipeline.

Preferably, the fan blades are provided with two groups, and two sides of the motor are connected with the fan blades.

Preferably, six groups of cooling rods are arranged, and the cooling rods are distributed at equal intervals in the cold water bin.

Preferably, the heat dissipation pipeline is arranged on the heat dissipation plate in a U-shaped mode, and the first water pump, the second water pump, the connecting pipeline and the heat dissipation pipeline form a closed circulation loop.

Preferably, the heat dissipation pipelines are symmetrically distributed on the bottom plate, and the water inlets are arranged in a threaded structure.

Compared with the prior art, the radiator structure based on the integration of water collection and cold air cooling has the advantages that the cooling mechanism combines water cooling and air cooling through the arrangement of the cooling mechanism, the advantages of water cooling and air cooling are combined, the radiating efficiency and stability can be remarkably improved, the radiator structure is suitable for the radiating requirement of high-power equipment, the noise is reduced, the service life of the equipment is prolonged, and the attractiveness and the flexibility of a system are improved.

Drawings

FIG. 1 is a schematic diagram of a side view of the present utility model;

FIG. 2 is a schematic top view of the present utility model;

FIG. 3 is a schematic diagram of a cross-sectional exploded structure of parts such as a cold water sump of the present utility model;

FIG. 4 is a schematic view of a part of the cooling mechanism of the present utility model in an exploded view;

Fig. 5 is an enlarged schematic view of the structure of fig. 3 a according to the present utility model.

The cooling device comprises a base plate 1, a cooling mechanism 2, a first support frame 201, a second support frame 202, a 203, a heat dissipation plate 204, a cold water bin 205, a first installation groove 206, a second installation groove 207, a water inlet 208, a water outlet hole 209, a water return hole 210, a cooling rod 211, fan blades 212, a motor 213, a first water pump 214, a second water pump 215, a connecting pipeline 216 and a heat dissipation pipeline.

Detailed Description

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

Referring to fig. 1-5, the utility model provides a technical scheme that a radiator structure integrating water collection, cold air and cold air comprises a bottom plate 1 and a cooling mechanism 2, wherein the cooling mechanism 2 is arranged on one side of the surface of the bottom plate 1;

The cooling mechanism 2 comprises a first supporting frame 201, a second supporting frame 202, a heat radiation plate 203, a cold water bin 204, a first mounting groove 205, a second mounting groove 206, a water inlet 207, a water outlet 208, a water return hole 209, a cooling rod 210, fan blades 211, a motor 212, a first water pump 213, a second water pump 214, a connecting pipeline 215 and a heat radiation pipeline 216, wherein the first supporting frame 201 is fixedly connected to one side of the surface of the bottom plate 1, the second supporting frame 202 is fixedly connected to one side of the surface of the bottom plate 1, the heat radiation plate 203 is arranged on one side of the bottom plate 1, the cold water bin 204 is arranged on one side of the surface of the first supporting frame 201, the first mounting groove 205 is arranged on one side of the second supporting frame 202, the second mounting groove 206 is arranged at one end of the second supporting frame 202, the water inlet 207 is arranged on one side of the cold water bin 204, the water outlet 208 is arranged on the surface of the cold water bin 204, the water return holes 209 are arranged on two sides of the cold water bin 204, the cooling bar 210 is arranged in the cold water bin 204, the fan blade 211 is arranged in the first mounting groove 205, the motor 212 is arranged in the second mounting groove 206, the first water pump 213 is arranged on one side of the water outlet 208, the second water pump 214 is arranged on one side of the water return hole 209, the connecting pipeline 215 is connected to the other side of the first water pump 213, the heat dissipation pipeline 216 is connected to the other side of the connecting pipeline 215, the generated heat is absorbed through the arrangement of the first supporting frame 201, the second supporting frame 202, the heat dissipation plate 203, the cold water bin 204, the first mounting groove 205, the second mounting groove 206, the water inlet 207, the water outlet 208, the water return hole 209, the cooling bar 210, the fan blade 211, the motor 212, the first water pump 213, the second water pump 214, the connecting pipeline 215 and the heat dissipation pipeline 216, when heat dissipation is required, firstly, the cooling liquid is added into the cooling bin 204 through the water inlet 207, and then the generated heat is absorbed through the contact with the cooling bar 210, after cooling is completed, the first water pump 213 is started, after the cooling fluid in the cold water bin 204 flows out from the water outlet 208, and then is pumped to the heat dissipation pipeline 216 through the connecting pipeline 215, the heat dissipation pipeline 216 is tightly attached to the heat dissipation plate 203, and then the heat on the heat dissipation plate 203 is absorbed, meanwhile, the motor 212 is started, the motor 212 drives the fan blades 211 to rotate, and then the temperature of the heat dissipation pipeline 216 is reduced, the heat dissipation efficiency is improved, finally, the second water pump 214 is started, and then the cooling fluid with absorbed heat flows back to the cold water bin 204 through the water return hole 209 after passing through the connecting pipeline 215, so that a closed circulation loop is formed, the cooling fluid is ensured to continuously circulate in the system, efficient heat absorption, heat conduction and heat dissipation are realized, and low-temperature operation of a heat source is ensured under high load.

Further, the heat dissipation pipeline 216 is aligned with the position of the heat dissipation plate 203, the heat dissipation pipeline 216 is attached to the heat dissipation plate 203, through the arrangement of the heat dissipation plate 203, the heat brought by the cooling liquid is rapidly dissipated to the surrounding environment, through the large-area surface contact, the heat dissipation plate 203 can effectively increase the contact area with the air, so that the heat dissipation efficiency is improved, the heat dissipation plate 203 is attached to the heat dissipation pipeline 216, and when the cooling liquid flows in the heat dissipation pipeline 216, the cooling liquid is in close contact with the heat dissipation plate 203, in this way, the heat of the cooling liquid can be effectively transferred to the heat dissipation plate 203, and further is diffused into the air through the heat dissipation plate 203.

Further, the second water pump 214 is provided with four groups, the other side of the second water pump 214 is connected with a connecting pipeline 215, through the arrangement of the second water pump 214, the second water pump 214 is responsible for refluxing the cooling liquid in the cooling pipeline 216 to the cold water bin 204, the cooling liquid can smoothly return to the cold water bin 204 for recirculation after the cooling process is completed by providing power, the second water pump 214 and the first water pump 213 cooperate to ensure that the cooling liquid in the whole cooling system keeps constant flow and proper pressure, and the stable operation of the system is maintained, and the reduction of the cooling efficiency caused by insufficient flow rate of the cooling liquid or uneven local pressure is prevented.

Further, two groups of fan blades 211 are arranged, two sides of the motor 212 are connected with the fan blades 211, the motor 212 drives the fan blades 211 to rotate through the arrangement of the motor 212 and the fan blades 211, air flow is generated, heat on the heat dissipation plate 203 is rapidly taken away, and cooling liquid in the heat dissipation pipeline 216 is further cooled, so that the overall cooling efficiency is improved.

Further, the cooling bars 210 are provided with six groups, the cooling bars 210 are distributed at equal intervals inside the cold water bin 204, and the cooling bars 210 transfer the absorbed heat to the surrounding cooling liquid, and the cooling liquid temperature is lowered and flows through the arrangement of the cooling bars 210. The cooled coolant circulates to the outlet 208 of the cold water sump by convection within the cold water sump 204 and is pumped by the first water pump 213 to the heat sink 216.

Further, the heat dissipation pipeline 216 is disposed in a U-shape on the heat dissipation plate 203, the first water pump 213, the second water pump 214, the connecting pipeline 215 and the heat dissipation pipeline 216 form a closed circulation loop, through the arrangement of the heat dissipation pipeline 216, the heat dissipation pipeline 216 has the main function of conducting and dissipating heat in the cooling liquid, the cooling liquid flows out of the cold water bin 204, when passing through the heat dissipation pipeline 216, the carried heat is transferred to the heat dissipation plate 203 or other heat dissipation components through the pipeline, and the heat dissipation pipeline 216 forms a main channel for the cooling liquid to circulate in the system. It is connected with components such as cold water bin 204, heating panel 203, first water pump 213 and second water pump 214, ensures that the coolant can flow smoothly in whole cooling system, and U type cooling pipeline 216 is in order to increase the area of contact with air or other cooling medium to improve radiating efficiency.

Furthermore, the heat dissipation pipes 216 are symmetrically distributed on the bottom plate 1, the water inlets 207 are arranged in a threaded structure, and through the arrangement of the water inlets 207, the water inlets 207 are main channels for cooling liquid to enter the cold water bin 204, and provide an interface for the cooling system for connecting an external cooling liquid source, so that the cooling liquid can enter the system smoothly, the water inlets 207 allow the cooling liquid to be supplemented into the cold water bin 204 from the outside, and proper liquid level and flow of the cooling liquid in the system are maintained, which is very important for maintaining normal operation and efficient heat dissipation of the cooling system.

When heat dissipation is needed, firstly, cooling liquid is added into the cooling bin 204 through the water inlet 207, and then the generated heat is absorbed through contact with the cooling rod 210, after cooling is finished, the first water pump 213 is started, after the cooling is finished, the cooling liquid in the cooling bin 204 flows out of the water outlet 208, and is further pumped to the heat dissipation pipeline 216 through the connecting pipeline 215, the heat dissipation pipeline 216 is closely attached to the heat dissipation plate 203, and then the heat on the heat dissipation plate 203 is absorbed, meanwhile, the motor 212 is started, the fan blades 211 are driven to rotate by the motor 212, and then the temperature of the heat dissipation pipeline 216 is reduced, the heat dissipation efficiency is improved, and finally, the second water pump 214 is started, and finally, the cooling liquid after the heat absorption is finished, flows back to the cooling bin 204 through the water return hole 209, so that a closed circulation loop is formed, the cooling liquid is ensured to be continuously circulated in the system, efficient heat absorption, heat conduction and heat dissipation are realized, and the heat source is ensured to keep running at a low temperature under a high load.

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

Claims (7)

1. A radiator structure integrating water cooling and air cooling, comprising a bottom plate (1) and a cooling mechanism (2), characterized in that: the cooling mechanism (2) is arranged on one side of the surface of the bottom plate (1); The cooling mechanism (2) comprises a first support frame (201), a second support frame (202), a heat sink (203), a cold water bin (204), a first mounting groove (205), a second mounting groove (206), a water inlet (207), a water outlet (208), a water return hole (209), a cooling rod (210), a fan blade (211), a motor (212), a first water pump (213), a second water pump (214), a connecting pipe (215) and a heat dissipation pipe (216); one side of the surface of the bottom plate (1) is fixedly connected to the first support frame (201); one side of the surface of the bottom plate (1) is fixedly connected to the second support frame (202); one side of the bottom plate (1) is installed with a heat sink (203); one side of the surface of the first support frame (201) is installed with a cold water bin (204); one side of the second support frame (202) is provided with a first mounting groove (205), a second mounting groove (206) is provided at one end of the second support frame (202), a water inlet (207) is provided on one side of the cold water bin (204), a water outlet hole (208) is provided on the surface of the cold water bin (204), and return water holes (209) are provided on both sides of the cold water bin (204), a cooling rod (210) is installed inside the cold water bin (204), a fan blade (211) is installed inside the first mounting groove (205), a motor (212) is installed inside the second mounting groove (206), a first water pump (213) is installed on one side of the water outlet hole (208), a second water pump (214) is installed on one side of the return water hole (209), the other side of the first water pump (213) is connected to a connecting pipe (215), and the other side of the connecting pipe (215) is connected to a heat dissipation pipe (216). 2. According to the radiator structure integrating water cooling and air cooling as described in claim 1, it is characterized in that: the positions of the heat dissipation pipe (216) and the heat dissipation plate (203) are relatively positive, and the heat dissipation pipe (216) and the heat dissipation plate (203) are in close contact. 3. According to the radiator structure integrating water cooling and air cooling as described in claim 1, it is characterized in that: the second water pump (214) is provided with four groups, and the other side of the second water pump (214) is connected to a connecting pipe (215). 4. A radiator structure integrating water cooling and air cooling according to claim 1, characterized in that: the fan blades (211) are provided in two groups, and both sides of the motor (212) are connected to the fan blades (211). 5. The radiator structure integrating water cooling and air cooling according to claim 1 is characterized in that: six groups of cooling rods (210) are arranged, and the cooling rods (210) are evenly spaced and distributed inside the cold water tank (204). 6. According to claim 1, a radiator structure integrating water cooling and air cooling is characterized in that: the heat dissipation pipe (216) is arranged in a U shape on the heat dissipation plate (203), and the first water pump (213), the second water pump (214), the connecting pipe (215) and the heat dissipation pipe (216) form a closed circulation loop. 7. A radiator structure integrating water cooling and air cooling according to claim 1, characterized in that: the heat dissipation pipes (216) are symmetrically distributed on the bottom plate (1), and the water inlet (207) is set as a threaded structure.