CN218376647U - Turbulence structure in heat dissipation core - Google Patents

Abstract

The utility model discloses a vortex structure in radiating core relates to radiating core technical field, including the support body, the inside of support body is equipped with radiator unit, and radiator unit includes radiating groove, auxiliary structure, first hydroecium, second hydroecium, first catheter, first cooling tube and second cooling tube, and the radiating groove is seted up in the inside of support body, and the inside of radiating groove is equipped with auxiliary structure, and first hydroecium has been seted up on the top of radiating groove, and the second hydroecium has been seted up to the bottom of radiating groove, the beneficial effects of the utility model are that: carry out the water guide respectively through first hydroecium and second hydroecium and contain hot liquid phase and derive the cooling liquid phase, use the first cooling tube of first catheter direction simultaneously, use the first cooling tube of platykurtic simultaneously to be convenient for make the faster water conservancy diversion of liquid, improve water conservancy diversion efficiency, use the curved spoiler of a plurality of to carry out the vortex to the water guide simultaneously, improve the radiating efficiency of liquid, use the further cooling of second cooling tube.

Description

Turbulence structure in heat dissipation core

Technical Field

The utility model relates to a vortex structure, in particular to vortex structure in heat dissipation core belongs to heat dissipation core technical field.

Background

The automobile radiator consists of three parts, including water inlet chamber, water outlet chamber, radiator core, etc. The coolant flows in the radiator core, and the air passes outside the radiator. The hot coolant cools down by dissipating heat to the air, and the cold air heats up by absorbing the heat dissipated by the coolant.

The 'automobile radiator core body' disclosed by the application number 'CN 201620988023.2' is an increasingly mature technology, and comprises a cooling pipe, wherein foam metal wraps the periphery of the cooling pipe, the aperture of a through hole of the foam metal is 1.1-6 mm, and the porosity is more than 90%. Due to the existence of the foam metal, the airflow disturbance of cooling air can be effectively enhanced by utilizing the larger surface area and the complex three-dimensional through hole structure of the foam metal, and meanwhile, the foam metal can tightly wrap the cooling pipe, so that the heat exchange efficiency is improved. The device can be used as the core body of the automobile radiator, and the use of the device is safe and reliable, but the device has the following defects in actual use.

1) The heat dissipation structure is single, and cooling liquid cannot flow in a turbulent mode when flowing, so that the heat dissipation efficiency is influenced;

2) The stability is relatively poor, receive collision extrusion easily and cause the damage.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide a vortex structure in radiating core to current radiating core heat radiation structure single influence radiating effect who proposes in solving above-mentioned background art, and the relatively poor problem of stable strength.

In order to achieve the above object, the utility model provides a following technical scheme: the utility model provides a vortex structure in radiating core, includes the support body, the inside of support body is equipped with radiator unit, radiator unit includes radiating groove, auxiliary structure, first hydroecium, second hydroecium, first catheter, first cooling tube and second cooling tube, the radiating groove is seted up the inside of support body, the inside of radiating groove is equipped with auxiliary structure, first hydroecium has been seted up on the top of radiating groove, the second hydroecium has been seted up to the bottom of radiating groove, the bottom mounting of first hydroecium is equipped with first catheter, the fixed first cooling tube that is equipped with of one end of first catheter, the one end of first cooling tube and the one end fixed connection of second cooling tube.

Preferably, the other end of second cooling tube pass through the second catheter with the top fixed connection of second hydroecium, first cooling tube is the platykurtic, the fixed a plurality of spoiler that is equipped with in inside of first cooling tube, a plurality of the top and the bottom of spoiler are the arc, the fixed two spoiler bars that are equipped with in inside of second cooling tube, two the surface of spoiler bar all is fixed and is equipped with a plurality of spoiler piece, a plurality of the position of spoiler piece all corresponds each other.

Preferably, the auxiliary structure includes a plurality of auxiliary rod, two protection networks, a plurality of accessory plate and two heat-conducting plates, a plurality of the auxiliary rod is fixed the setting respectively and is in the bottom of radiating groove, a plurality of the auxiliary rod is the arc, a plurality of the top of auxiliary rod all with the top fixed connection of radiating groove, a plurality of one side of auxiliary rod respectively with two one side fixed connection of protection network, a plurality of one side of auxiliary rod all is fixed and is equipped with the accessory plate, a plurality of the accessory plate is the slope form, two the heat-conducting plate is all fixed the setting and is in the both sides side of radiating groove.

Preferably, two one side of heat-conducting plate all is fixed and is equipped with the heat dissipation frame, two the inside of heat dissipation frame all is fixed and is equipped with a plurality of radiating fin, a plurality of radiating fin is the slope form.

Preferably, the two sides of the top end of the frame body are both fixedly provided with a lifting ring, and the two sides of the two lifting rings are both fixedly provided with a connecting plate.

Preferably, a water inlet pipe is fixedly arranged at the top end of the first water chamber, and a water outlet pipe is fixedly arranged on one side of the second water chamber.

Preferably, the surface of the frame body is coated with a high temperature resistant coating.

Compared with the prior art, the utility model provides a pair of vortex structure in heat dissipation core has following beneficial effect:

1. the first water chamber and the second water chamber are used for conducting water guide and hot liquid containing phase and guiding out cooling liquid phase respectively, the first liquid guide pipe is used for guiding the first cooling pipe, the flat first cooling pipe is used for facilitating the faster flow guide of liquid, the flow guide efficiency is improved, meanwhile, the plurality of arc-shaped spoilers are used for disturbing the water guide to improve the heat dissipation efficiency of the liquid, so that the heat dissipation effect is improved, the second cooling pipe is used for further cooling, and meanwhile, the spoiler bars and the plurality of spoiler blocks are used for being matched with each other to improve the spoiler effect, so that the better heat dissipation effect is achieved in a matching manner;

2. the stability of being convenient for improve the support body through the curved auxiliary rod of a plurality of, avoid receiving the extrusion collision and cause the damage to influence the heat dissipation and use, use the auxiliary rod to be convenient for fixed protection network simultaneously, thereby avoid dust impurity to get into to block up and influence the circulation of air and influence the radiating effect, use the cooperation of a plurality of slope form auxiliary plate to be convenient for to carry out the wind-guiding use, use the heat-conducting plate to be convenient for cooperate a plurality of radiating fin to further improve the radiating effect.

Drawings

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

fig. 2 is a schematic sectional structure of the present invention;

FIG. 3 is a schematic side sectional view of the present invention;

fig. 4 is an enlarged schematic structural view of a in fig. 2 according to the present invention.

In the figure: 1. a frame body; 2. a spoiler; 3. a spoiler bar; 4. a heat dissipating component; 41. a heat sink; 42. an auxiliary structure; 43. a first water chamber; 44. a second water chamber; 45. a first catheter; 46. a first cooling pipe; 47. a second cooling pipe; 421. an auxiliary lever; 422. a protective net; 423. an auxiliary plate; 424. a heat conducting plate; 5. a flow disturbing block; 6. a second catheter; 7. a heat dissipation frame; 8. a heat dissipating fin; 9. a lifting ring; 10. a connecting plate; 11. a water inlet pipe; 12. and (5) discharging a water pipe.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying 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 work belong to the protection scope of the present invention.

Example 1:

referring to fig. 1-4, the utility model provides a turbulent flow structure in heat dissipation core, including support body 1, the inside of support body 1 is equipped with heat dissipation assembly 4, heat dissipation assembly 4 includes heat dissipation groove 41, auxiliary structure 42, first hydroecium 43, second hydroecium 44, first catheter 45, first cooling tube 46 and second cooling tube 47, heat dissipation groove 41 is seted up in the inside of support body 1, the inside of heat dissipation groove 41 is equipped with auxiliary structure 42, the top of heat dissipation groove 41 is equipped with first hydroecium 43, the bottom of heat dissipation groove 41 is equipped with second hydroecium 44, the bottom of first hydroecium 43 is fixed with first catheter 45, one end of first catheter 45 is fixed with first cooling tube 46, one end of first cooling tube 46 and one end fixed connection of second cooling tube 47;

the other end of the second cooling pipe 47 is fixedly connected with the top end of the second water chamber 44 through a second liquid guide pipe 6, the first cooling pipe 46 is flat, a plurality of spoilers 2 are fixedly arranged inside the first cooling pipe 46, the top ends and the bottom ends of the spoilers 2 are both arc-shaped, two spoiler bars 3 are fixedly arranged inside the second cooling pipe 47, a plurality of spoiler blocks 5 are fixedly arranged on the surfaces of the two spoiler bars 3, the positions of the spoiler blocks 5 correspond to each other, water guide is disturbed through the spoilers 2 to improve the heat dissipation efficiency of liquid, and meanwhile, the spoiler bars 3 and the spoiler blocks 5 are matched with each other to further improve the disturbing flow effect;

the two sides of the top end of the frame body 1 are both fixedly provided with a lifting ring 9, the two sides of the two lifting rings 9 are both fixedly provided with a connecting plate 10, the frame body 1 can be conveniently lifted and taken through the lifting rings 9 to be installed or maintained for use, and meanwhile the connecting plate 10 is used for fixing the frame body 1 for use;

a water inlet pipe 11 is fixedly arranged at the top end of the first water chamber 43, a water outlet pipe 12 is fixedly arranged at one side of the second water chamber 44, and cooling liquid is respectively led in and led out through the water inlet pipe 11 and the water outlet pipe 12;

the surface of the frame body 1 is coated with a high-temperature resistant coating, and the high-temperature resistant strength of the frame body 1 is improved by coating the high-temperature resistant coating;

specifically, as shown in fig. 1, fig. 2, fig. 3, fig. 4, at first can be through 11 water guide of inlet tube to first hydroecium 43 when using, then through the leading-in first cooling tube 46 of first catheter 45 with liquid, the first cooling tube 46 through the platykurtic is convenient for liquid and circulates fast, and cooperate a plurality of curved spoiler 2 to improve liquid vortex effect, make vortex liquid carry out the heat dissipation treatment fast, then inside liquid circulation reaches second cooling tube 47, and rethread vortex pole 3 and vortex block 5 cooperate, make liquid further improve the vortex effect, be convenient for cooperate and improve the radiating efficiency, at last derive the use through outlet pipe 12.

Example 2:

the auxiliary structure 42 comprises a plurality of auxiliary rods 421, two protective nets 422, a plurality of auxiliary plates 423 and two heat conducting plates 424, the plurality of auxiliary rods 421 are respectively and fixedly arranged at the bottom ends of the heat dissipation grooves 41, the plurality of auxiliary rods 421 are all arc-shaped, the top ends of the plurality of auxiliary rods 421 are all fixedly connected with the top ends of the heat dissipation grooves 41, one sides of the plurality of auxiliary rods 421 are respectively and fixedly connected with one sides of the two protective nets 422, the auxiliary plates 423 are respectively and fixedly arranged at one side of the plurality of auxiliary rods 421, the plurality of auxiliary plates 423 are all inclined, and the two heat conducting plates 424 are respectively and fixedly arranged at the two sides of the heat dissipation grooves 41;

a heat dissipation frame 7 is fixedly arranged on one side of each heat conduction plate 424, a plurality of heat dissipation fins 8 are fixedly arranged inside each heat dissipation frame 7, the plurality of heat dissipation fins 8 are inclined, and the heat dissipation effect is improved through the cooperation of the plurality of heat dissipation fins 8;

specifically, as shown in fig. 1, fig. 2, fig. 3, and fig. 4, when in use, the frame body 1 may be protected by the fixing protective net 422 through the plurality of auxiliary rods 421, so as to prevent dust and impurities from entering and blocking the frame body to affect heat dissipation, and then the frame body may be used by guiding wind through the cooperation of the plurality of inclined auxiliary plates 423, and then the heat of the heat dissipation groove 41 may be further conducted out and dissipated by the cooperation of the plurality of heat dissipation fins 8 and the heat conduction plate 424.

The working principle is as follows: when specifically using, the utility model relates to a vortex structure in radiating core, at first can be through 11 water guide of inlet tube to first hydroecium 43 when using, then through first catheter 45 with the leading-in first cooling tube 46 of liquid, the first cooling tube 46 through the platykurtic is convenient for liquid fast circulation, and cooperate the curved spoiler 2 of a plurality of to improve liquid vortex effect, make vortex liquid carry out the heat dissipation fast and handle, then liquid circulation arrives second cooling tube 47 inside, and rethread vortex pole 3 and vortex piece 5 cooperate, make liquid further improve the vortex effect, be convenient for cooperate and improve the radiating efficiency, derive the use through outlet pipe 12 at last, can protect support body 1 through the fixed protection network 422 of a plurality of auxiliary rod 421 when using, avoid dust impurity to get into the jam and influence the heat dissipation and use, then can cooperate the wind-guiding use through the accessory plate 423 cooperation wind-guiding of a plurality of slope form, then cooperate through a plurality of radiating fin 8 and heat-conducting plate 424 and further derive the heat dissipation groove 41 heat and give off.

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 vortex structure in radiating core, includes support body (1), its characterized in that, the inside of support body (1) is equipped with radiator unit (4), radiator unit (4) are including radiating groove (41), auxiliary structure (42), first hydroecium (43), second hydroecium (44), first catheter (45), first cooling tube (46) and second cooling tube (47), radiator groove (41) are seted up the inside of support body (1), the inside of radiating groove (41) is equipped with auxiliary structure (42), first hydroecium (43) have been seted up on the top of radiating groove (41), second hydroecium (44) have been seted up to the bottom of radiating groove (41), the bottom mounting of first hydroecium (43) is equipped with first catheter (45), the one end mounting of first catheter (45) is equipped with first cooling tube (46), the one end of first cooling tube (46) and the one end fixed connection of second cooling tube (47).

2. The internal turbulator structure of a heat dissipating core of claim 1, wherein: the other end of second cooling tube (47) pass through second catheter (6) with the top fixed connection of second hydroecium (44), first cooling tube (46) are the platykurtic, the inside of first cooling tube (46) is fixed and is equipped with a plurality of spoiler (2), a plurality of the top and the bottom of spoiler (2) are the arc, the inside of second cooling tube (47) is fixed and is equipped with two spoiler bars (3), two the surface of spoiler bar (3) all is fixed and is equipped with a plurality of spoiler block (5), a plurality of the position of spoiler block (5) all corresponds each other.

3. The internal turbulator structure of a heat dissipating core of claim 1, wherein: the auxiliary structure (42) comprises a plurality of auxiliary rods (421), two protective nets (422), a plurality of auxiliary plates (423) and two heat-conducting plates (424), the plurality of auxiliary rods (421) are respectively and fixedly arranged at the bottom ends of the heat-radiating grooves (41), the plurality of auxiliary rods (421) are both arc-shaped, the top ends of the auxiliary rods (421) are fixedly connected with the top ends of the heat-radiating grooves (41), one sides of the auxiliary rods (421) are respectively and fixedly connected with one sides of the two protective nets (422), the auxiliary plates (423) are fixedly arranged on one sides of the auxiliary rods (421), the auxiliary plates (423) are inclined, and the two heat-conducting plates (424) are fixedly arranged on two sides of the heat-radiating grooves (41).

4. The internal fin structure of claim 3, wherein: two one side of heat-conducting plate (424) all is fixed and is equipped with heat dissipation frame (7), two the inside of heat dissipation frame (7) all is fixed and is equipped with a plurality of radiating fin (8), a plurality of radiating fin (8) are the slope form.

5. The internal turbulator structure of a heat dissipating core of claim 1, wherein: both sides of the top end of the frame body (1) are fixedly provided with lifting rings (9), and both sides of the two lifting rings (9) are fixedly provided with connecting plates (10).

6. The internal turbulator structure of a heat dissipating core of claim 1, wherein: the top end of the first water chamber (43) is fixedly provided with a water inlet pipe (11), and one side of the second water chamber (44) is fixedly provided with a water outlet pipe (12).

7. The internal turbulator structure of a heat dissipating core of claim 1, wherein: the surface of the frame body (1) is coated with a high-temperature resistant coating.

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