CN109341374B - High-efficiency radiator - Google Patents

Abstract

The invention relates to a high-efficiency radiator, comprising: the base is provided with a plurality of slots; the bottom of each radiating fin is provided with an inserting part which is in inserting fit with the slot, and the inserting part is provided with at least one accommodating opening with one side opening; and a heat-conducting tube group carried by the heat-radiating fins; wherein, the heat conduction pipe group includes: the first heat conduction pipe penetrates through the accommodating port, a plurality of first clamping grooves corresponding to the slots are formed in the first heat conduction pipe, the radiating fins are clamped with the first clamping grooves, and the first heat conduction pipe is attached to the base; the second heat conduction pipe is connected with the first heat conduction pipe, is L-shaped, and the first side of the second heat conduction pipe is propped against the upper ends of the radiating fins; and, connecting the pipes. The radiator can integrally disassemble and assemble all the radiating fins, and the installation process is simple and quick.

Description

High-efficiency radiator

Technical Field

The invention relates to the technical field of radiators, in particular to a high-efficiency radiator.

Background

The radiator is generally composed of radiating fins and a base which is in contact with the heating body, and in order to improve the heat conduction performance of the radiating fins, a heat conduction pipe is generally embedded in the base, wherein the quantity and the area of the radiating fins are one of main factors influencing the heat dissipation performance of the radiator, and generally, the more the quantity of the radiating fins is, the better the heat dissipation effect is; in order to facilitate production, the radiating fins and the base are usually arranged to be detachable, but the process of sequentially assembling the radiating fins on the base is complicated due to the large number of the radiating fins, and particularly, when the radiating fins are required to be removed and replaced on other bases for recycling.

Disclosure of Invention

In order to solve the technical problems, the invention provides the efficient radiator which has the advantage of more convenience in assembling and disassembling the heat fins.

In order to achieve the above purpose, the technical scheme of the invention is as follows:

a high efficiency heat sink comprising:

the base is provided with a plurality of slots;

the bottom of each radiating fin is provided with an inserting part which is in inserting fit with the corresponding slot, and the inserting part is provided with at least one accommodating opening with one side opening; the method comprises the steps of,

a heat-conducting tube group carried by the heat-radiating fins;

wherein the heat conduction pipe group includes:

the first heat conduction pipe penetrates through the accommodating port, a plurality of first clamping grooves corresponding to the slots are formed in the first heat conduction pipe, the heat dissipation fins are clamped with the first clamping grooves, and the first heat conduction pipe is attached to the base;

the second heat conduction pipe is connected with the first heat conduction pipe, is L-shaped, and the second side of the second heat conduction pipe is propped against the upper ends of the radiating fins; the method comprises the steps of,

the connecting pipe is arranged between the first heat conduction pipe and the second heat conduction pipe, is positioned on one side of the radiating fin opposite to the first side of the second heat conduction pipe and is used for connecting the first heat conduction pipe and the second heat conduction pipe.

When the radiator is assembled, the radiating fins are correspondingly clamped in the first clamping grooves of the first heat conducting pipes, after the radiating fins are completely installed, the second heat conducting pipes are connected with the first heat conducting pipes, the first sides of the second heat conducting pipes are propped against the upper ends of the radiating fins, the first heat conducting pipes and the second heat conducting pipes are integrally combined to form a U-shaped integral structure, the radiating fins are clamped and fixed, the connecting pipes are connected with the first heat conducting pipes and the second heat conducting pipes, so that an integral frame-shaped structure is formed, a plurality of radiating fins are integrally formed, and finally all the radiating fins are directly correspondingly spliced on the slots, so that the radiator is completed; when each radiating fin is required to be dismounted and mounted on the base of other equipment, all radiating fins are required to be dismounted integrally and then mounted integrally, and the mounting process is simple and quick; meanwhile, the first ingress pipe can transfer heat on the base to the end parts of the radiating fins rapidly, so that the heat can be scattered on the radiating fins rapidly, and radiating efficiency and radiating effect are improved.

As a preferable scheme of the invention, one end of the first heat conduction pipe, which is close to the second heat conduction pipe, is provided with an inverted U-shaped connecting section, and the connecting section is connected with the first side of the second heat conduction pipe through a first connecting sleeve.

As a preferable scheme of the invention, the connecting pipe is in a C shape, the first horizontal section of the connecting pipe is connected with the first heat conduction pipe through a second connecting sleeve, and the second horizontal section of the connecting pipe is connected with the second side of the second heat conduction pipe through a third connecting sleeve.

According to the technical scheme, the first heat conduction pipe, the second heat conduction pipe and the third heat conduction pipe are connected through the first connecting sleeve, the second connecting sleeve and the third connecting sleeve to form a whole, and the first connecting sleeve is arranged in a numerical value mode, and the second connecting sleeve and the third connecting sleeve are horizontally arranged, so that the first heat conduction pipe and the second heat conduction pipe are not easy to separate, and the connection of the first heat conduction pipe and the second heat conduction pipe is firmer.

As a preferable mode of the present invention, the vertical section of the connecting pipe is attached to the outermost heat radiating fin.

By means of the technical scheme, the connecting pipe can be conveniently used for conducting heat, and the heat dissipation efficiency is further improved.

As a preferable scheme of the invention, the base is provided with a heat conducting groove matched with the first heat conducting pipe, and the first heat conducting pipe is embedded in the heat conducting groove.

The technical scheme is realized, so that the contact area between the first heat conduction pipe and the base is larger, and the heat on the base can be transferred to the first heat conduction pipe more quickly.

As a preferable scheme of the invention, a second clamping groove matched with the first clamping groove is formed on the second side of the second heat conduction pipe, and the upper end of the heat dissipation fin is clamped into the second clamping groove.

As a preferable scheme of the invention, the upper end of the radiating fin is provided with a bayonet matched with the second clamping groove.

According to the technical scheme, the second heat conduction pipe and the radiating fins are clamped tightly through the second clamping groove and the clamping opening, so that the radiating fins are fixed more firmly.

As a preferable scheme of the invention, a first caulking groove matched with the first connecting sleeve is formed on the first side of the first heat-conducting pipe and the first side of the second heat-conducting pipe, a second caulking groove matched with the second connecting sleeve is formed on the first horizontal section of the first heat-conducting pipe and the first horizontal section of the connecting pipe, and a third caulking groove matched with the third connecting sleeve is formed on the second side of the second heat-conducting pipe and the second horizontal section of the connecting pipe.

The technical scheme is realized, so that the first heat conduction pipe, the second heat conduction pipe and the connecting pipe are connected more stably and are not easy to slip.

As a preferable mode of the present invention, the heat radiation fin is wavy.

By the aid of the technical scheme, the radiating area of the radiating fins is increased, and radiating effect is improved.

In summary, the invention has the following beneficial effects:

the embodiment of the invention provides a high-efficiency radiator, which comprises the following components: the base is provided with a plurality of slots; the bottom of each radiating fin is provided with an inserting part which is in inserting fit with the corresponding slot, and the inserting part is provided with at least one accommodating opening with one side opening; and a heat-conducting tube group carried by the heat-radiating fins; wherein the heat conduction pipe group includes: the first heat conduction pipe penetrates through the accommodating port, a plurality of first clamping grooves corresponding to the slots are formed in the first heat conduction pipe, the heat dissipation fins are clamped with the first clamping grooves, and the first heat conduction pipe is attached to the base; the second heat conduction pipe is connected with the first heat conduction pipe, is L-shaped, and the first side of the second heat conduction pipe is propped against the upper ends of the radiating fins; and a connecting pipe arranged between the first heat conduction pipe and the second heat conduction pipe and positioned on one side of the radiating fin opposite to the first side of the second heat conduction pipe and used for connecting the first heat conduction pipe and the second heat conduction pipe. When the radiator is assembled, each radiating fin is correspondingly clamped in each first clamping groove of the first heat conducting pipe, after all radiating fins are installed, the second heat conducting pipe is connected with the first heat conducting pipe, the first side of the second heat conducting pipe is pressed against the upper ends of the radiating fins, the first heat conducting pipe and the second heat conducting pipe are integrally combined to form a U-shaped integral structure, each radiating fin is clamped and fixed, a connecting pipe is connected with the first heat conducting pipe and the second heat conducting pipe, so that an integral frame-shaped structure is formed, a plurality of radiating fins are formed into an integral body, and finally all the radiating fins are directly and correspondingly spliced on the slots, so that the finished radiator can be formed; when each radiating fin is required to be dismounted and mounted on the base of other equipment, all radiating fins are required to be dismounted integrally and then mounted integrally, and the mounting process is simple and quick; meanwhile, the first ingress pipe can transfer heat on the base to the end parts of the radiating fins rapidly, so that the heat can be scattered on the radiating fins rapidly, and radiating efficiency and radiating effect are improved.

Drawings

In order to more clearly illustrate the embodiments of the invention or the technical solutions in the prior art, the drawings that are required in the embodiments or the description of the prior art will be briefly described, it being obvious that the drawings in the following description are only some embodiments of the invention, and that other drawings may be obtained according to these drawings without inventive effort for a person skilled in the art.

Fig. 1 is a front view of an embodiment of the present invention.

Fig. 2 is a side view of an embodiment of the present invention.

Fig. 3 is a schematic structural diagram of a heat sink fin according to an embodiment of the invention.

Fig. 4 is a schematic structural diagram of a first heat pipe according to an embodiment of the invention.

Fig. 5 is a schematic structural diagram of a second heat pipe according to an embodiment of the invention.

Corresponding part names are indicated by numerals and letters in the drawings:

1. a base; 11. a slot; 12. a heat conduction groove; 2. a heat radiation fin; 21. an insertion part; 22. a receiving port; 23. a bayonet; 31. a first heat conduction pipe; 311. a first clamping groove; 312. a connection section; 32. a second heat conduction pipe; 321. a first side; 322. a second side; 323. a second clamping groove; 33. a connecting pipe; 331. a first horizontal segment; 332. a second horizontal segment; 333. a vertical section; 34. a first connection sleeve; 341. a first caulking groove; 35. a second connecting sleeve; 351. a second caulking groove; 36. a third connecting sleeve; 361. and a third caulking groove.

Detailed Description

The following description of the embodiments of the present invention 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 invention, but not all embodiments. 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.

Examples

A high efficiency heat sink, as shown in fig. 1-5, comprising: the base 1, the base 1 is provided with a plurality of slots 11; the bottom of each radiating fin 2 is provided with an inserting part 21 which is in inserting fit with the slot 11, and the inserting part 21 is provided with at least one accommodating opening 22 with one side open; and a heat conduction tube group carried by the heat radiation fins 2.

Specifically, the heat dissipation fins 2 are wavy, and the heat dissipation area of the heat dissipation fins 2 is increased by the wavy heat dissipation surface, so that the heat dissipation effect is improved, the insertion portion 21 can be dovetail-shaped, T-shaped or L-shaped, and the like, in this embodiment, the insertion portion 21 is U-shaped with elastic deformation capability, and when the insertion portion 21 is inserted into the slot 11, the insertion portion can be elastically deformed and clamped in the slot 11.

The heat conduction pipe group includes: the first heat-conducting tube 31 is arranged in the accommodating opening 22 in a penetrating way, a plurality of first clamping grooves 311 corresponding to the slots 11 are formed in the first heat-conducting tube 31, the heat-radiating fins 2 are clamped with the first clamping grooves 311, and the first heat-conducting tube 31 is attached to the base 1; the second heat conducting tube 32 is connected with the first heat conducting tube 31, the second heat conducting tube 32 is L-shaped, and the second side 322 of the second heat conducting tube 32 is propped against the upper ends of the heat radiating fins 2; and a connection pipe 33 disposed between the first heat conduction pipe 31 and the second heat conduction pipe 32 and located at a side of the heat radiation fin 2 opposite to the first side 321 of the second heat conduction pipe 32 for connecting the first heat conduction pipe 31 and the second heat conduction pipe 32; in this embodiment, the heat-conducting tube groups are arranged in two groups, and the two groups of heat-conducting tube groups are respectively arranged at positions near two ends of the heat-dissipating fins 2.

One end of the first heat conduction pipe 31, which is close to the second heat conduction pipe 32, is provided with an inverted U-shaped connecting section 312, the connecting section 312 is connected with the first side 321 of the second heat conduction pipe 32 through a first connecting sleeve 34, the connecting section 312 is integrally formed with the first heat conduction pipe 31, the connecting pipe 33 is C-shaped, a first horizontal section 331 of the connecting pipe 33 is connected with the first heat conduction pipe 31 through a second connecting sleeve 35, and a second horizontal section 332 of the connecting pipe 33 is connected with the second side 322 of the second heat conduction pipe 32 through a third connecting sleeve 36; the first connecting sleeve 34, the second connecting sleeve 35 and the third connecting sleeve 36 are rubber sleeves or metal sleeves, and the first heat conduction pipe 31, the second heat conduction pipe 32 and the connecting pipe 33 are hooped; the first heat conduction pipe 31, the second heat conduction pipe 32 and the third heat conduction pipe are connected to form a whole through the first connecting sleeve 34, the second connecting sleeve 35 and the third connecting sleeve 36, and the first connecting sleeve 34 is arranged in a numerical value, and the second connecting sleeve 35 and the third connecting sleeve 36 are horizontally arranged, so that the first heat conduction pipe 31 and the second heat conduction pipe 32 are not easy to separate, and the connection of the first heat conduction pipe 31 and the second heat conduction pipe 32 is firmer.

In general, when the connection pipe 33 is connected to the first heat pipe 31 and the second heat pipe 32, the vertical section 333 of the connection pipe 33 is attached to the outermost heat dissipation fin 2, so that the connection pipe 33 can conduct heat conveniently, and the heat dissipation efficiency is further improved.

In order to make the connection of the first heat-conducting tube 31, the second heat-conducting tube 32 and the connecting tube 33 more stable, a first caulking groove 341 matched with the first connecting sleeve 34 is arranged on the first side 321 of the first heat-conducting tube 31 and the second heat-conducting tube 32, a second caulking groove 351 matched with the second connecting sleeve 35 is arranged on the first horizontal section 331 of the first heat-conducting tube 31 and the connecting tube 33, a third caulking groove 361 matched with the third connecting sleeve 36 is arranged on the second side 322 of the second heat-conducting tube 32 and the second horizontal section 332 of the connecting tube 33, the first connecting sleeve 34 is embedded in the first caulking groove 341, the second connecting sleeve 35 is embedded in the second caulking groove 351, and the third connecting sleeve 36 is embedded in the third caulking groove 361, so that the connecting tube 34, the second connecting sleeve 35 and the third connecting sleeve 36 can be removed only when the first connecting sleeve 34, the second connecting sleeve 35 and the third connecting sleeve 36 are outwards opened.

Further, a second clamping groove 323 matched with the first clamping groove 311 is formed in the second side 322 of the second heat conduction pipe 32, the upper end of the heat dissipation fin 2 is clamped into the second clamping groove 323, and correspondingly, a bayonet 23 matched with the second clamping groove 323 is formed in the upper end of the heat dissipation fin 2; the second heat conducting pipe 32 and the radiating fins 2 are clamped tightly through the second clamping groove 323 and the bayonet 23, so that the radiating fins 2 are fixed firmly.

Further, a heat conducting groove 12 matched with the first heat conducting pipe 31 is formed in the base 1, the first heat conducting pipe 31 is embedded in the heat conducting groove 12, and the contact area between the first heat conducting pipe 31 and the base 1 is larger through the heat conducting groove 12, so that heat on the base 1 can be transferred to the first heat conducting pipe 31 more rapidly.

When assembling, firstly, each heat-radiating fin 2 is correspondingly embedded in each first clamping groove 311 of the first heat-conducting tube 31, after the heat-radiating fins 2 are completely installed, the second heat-conducting tube 32 is connected with the first heat-conducting tube 31, the first side 321 of the second heat-conducting tube 32 is propped against the upper end of the heat-radiating fin 2, the first heat-conducting tube 31 and the second heat-conducting tube 32 are integrally combined to form a U-shaped integral structure, the heat-radiating fins 2 are clamped and fixed, and then the connecting tube 33 is connected with the first heat-conducting tube 31 and the second heat-conducting tube 32, so that an integral frame structure is formed, a plurality of heat-radiating fins 2 are integrally formed, and finally, all the heat-radiating fins 2 are directly correspondingly spliced on the slot 11, so that a finished radiator can be formed; when each radiating fin 2 is required to be dismounted and mounted on the base 1 of other equipment, all radiating fins 2 are required to be dismounted integrally and then mounted integrally, and the mounting process is simple and quick; meanwhile, the first ingress pipe can transfer heat on the base 1 to the end parts of the radiating fins 2 quickly, so that the heat can be spread on the radiating fins 2 quickly, and the radiating efficiency and radiating effect are improved.

The previous description of the disclosed embodiments is provided to enable any person skilled in the art to make or use the present invention. Various modifications to these embodiments will be readily apparent to those skilled in the art, and the generic principles defined herein may be applied to other embodiments without departing from the spirit or scope of the invention. Thus, the present invention is not intended to be limited to the embodiments shown herein but is to be accorded the widest scope consistent with the principles and novel features disclosed herein.

Claims (6)

1. A high efficiency heat sink comprising:

the base is provided with a plurality of slots;

the bottom of each radiating fin is provided with an inserting part which is in inserting fit with the corresponding slot, and the inserting part is provided with at least one accommodating opening with one side opening; the method comprises the steps of,

a heat-conducting tube group carried by the heat-radiating fins;

wherein the heat conduction pipe group includes:

the first heat conduction pipe penetrates through the accommodating port, a plurality of first clamping grooves corresponding to the slots are formed in the first heat conduction pipe, the heat dissipation fins are clamped with the first clamping grooves, and the first heat conduction pipe is attached to the base;

the second heat conduction pipe is connected with the first heat conduction pipe, is L-shaped, and the second side of the second heat conduction pipe is propped against the upper ends of the radiating fins; the method comprises the steps of,

the connecting pipe is arranged between the first heat conduction pipe and the second heat conduction pipe, is positioned on one side of the radiating fin opposite to the first side of the second heat conduction pipe and is used for connecting the first heat conduction pipe and the second heat conduction pipe;

one end of the first heat conduction pipe, which is close to the second heat conduction pipe, is provided with an inverted U-shaped connecting section, and the connecting section is connected with the first side of the second heat conduction pipe through a first connecting sleeve;

the connecting pipe is C-shaped, the first horizontal section of the connecting pipe is connected with the first heat conduction pipe through a second connecting sleeve, and the second horizontal section of the connecting pipe is connected with the second side of the second heat conduction pipe through a third connecting sleeve;

the vertical section of the connecting pipe is attached to the outermost radiating fin.

2. The efficient radiator of claim 1, wherein the base is provided with a heat conducting groove matched with the first heat conducting pipe, and the first heat conducting pipe is embedded in the heat conducting groove.

3. The efficient heat sink as recited in claim 1 wherein a second slot is provided on a second side of the second heat pipe that mates with the first slot, the upper ends of the heat fins being snapped into the second slot.

4. The efficient heat sink as recited in claim 3 wherein the upper ends of the heat sink fins are provided with bayonets adapted to the second card slots.

5. The efficient radiator of claim 1, wherein a first caulking groove matched with the first connecting sleeve is formed in a first side of the first heat-conducting pipe and a first horizontal section of the connecting pipe, a second caulking groove matched with the second connecting sleeve is formed in a first horizontal section of the first heat-conducting pipe and the connecting pipe, and a third caulking groove matched with the third connecting sleeve is formed in a second side of the second heat-conducting pipe and a second horizontal section of the connecting pipe.

6. The efficient heat sink of claim 1, wherein the heat sink fins are corrugated.