CN211044166U - Quick heat conduction type radiating fin for notebook computer - Google Patents

Abstract

The utility model discloses a quick heat conduction type radiating fin for a notebook computer, which comprises a rectangular frame and a plurality of radiating fins, wherein a supporting plate is arranged on the rectangular frame, and the plurality of radiating fins are arranged on the supporting plate; the rectangular frame is provided with a mounting structure and an auxiliary heat dissipation structure; the auxiliary heat dissipation structure includes: the device comprises a bearing, a slideway, a micro motor and a blade; the utility model relates to a fin technical field, the effectual radiating problem of fin that mentions in the solution background art, through the supplementary heat radiation structure of this device, can carry out reasonable heat dissipation when the fin of being convenient for uses, improve the effect of fin to can not obstruct the fin use, the arrangement structure is convenient for this device reasonable settle, thereby adjustment position height uses more in a flexible way.

Description

Quick heat conduction type radiating fin for notebook computer

Technical Field

The utility model relates to a fin technical field specifically is a quick heat conduction formula fin for notebook.

Background

The electronic element is cooled when the cooling fin is used, the traditional cooling fin is single in structure, the cooling effect can be achieved when the cooling fin is used, the cooling effect is slow, the electronic element used at a high temperature can not be cooled immediately, the electronic element still works at a high temperature, the using effect of the cooling fin is reduced, and the electronic element is lost.

SUMMERY OF THE UTILITY MODEL

The utility model provides a not enough to prior art, the utility model provides a quick heat conduction formula fin for notebook dispels the heat to electronic component when having solved current fin purpose, and traditional fin structure is single, when using, can reach the radiating effect, but the radiating effect is slow, can't reach the radiating effect immediately to the electronic component who lasts the use of high temperature.

In order to achieve the above purpose, the utility model discloses a following technical scheme realizes: the cooling device comprises a rectangular frame and a plurality of cooling fins, wherein a supporting plate is arranged on the rectangular frame, and the plurality of cooling fins are arranged on the supporting plate;

the rectangular frame is provided with a mounting structure and an auxiliary heat dissipation structure;

the auxiliary heat dissipation structure includes: the device comprises a bearing, a slideway, a micro motor and a blade;

the improved blade-mounted type wind power generator is characterized in that a strip-shaped groove is formed in the rectangular frame, the slide way is arranged inside the strip-shaped groove, a slide block is mounted on the slide way, a support is arranged on the upper wall surface of the slide block, a circular groove is formed in the support, the bearing is arranged inside the circular groove, a support rod is arranged in the bearing, a support is mounted at the top end of the support rod, a driving mounting seat is mounted on the support, the micro motor is arranged on the driving mounting seat, a connecting rod is mounted at the driving end of the micro motor.

Preferably, the mounting structure comprises: the support plate, the upright post, the sleeve and the base plate;

the support plate is arranged at the top end of the rectangular frame, the positions of the support plate correspond to those of the support plate, the stand columns are arranged on the support plate, the sleeves are respectively sleeved on the lower wall surface of each stand column, the base plate is arranged on the lower wall surface of each sleeve, first threaded holes are formed in the lower wall surface of each base plate, and first screws are inserted in the first threaded holes.

Preferably, the left side wall surface and the right side wall surface of the sliding block are both fixed with gaskets corresponding in position, the side wall surface of each gasket is provided with a second threaded hole, the side wall surface of the rectangular frame is provided with first threaded grooves which are matched with the second threaded holes in position and are arranged at equal intervals, and a second screw which is lapped with the first threaded grooves is inserted in each second threaded hole.

Preferably, the bar-shaped grooves are internally provided with support rods penetrating through the sliding blocks.

Preferably, the supporting rod is sleeved with an annular gasket, a third threaded opening is formed in the annular gasket, second threaded openings which correspond to the third threaded opening in position and are arranged annularly are formed in the upper wall surface of the support, and third screws which are overlapped with the second threaded grooves are inserted in the third threaded openings.

Preferably, a fourth threaded hole is formed in the side wall surface of the sleeve, and a fourth screw lapped with the stand column is inserted into the fourth threaded hole.

Advantageous effects

The utility model provides a notebook is with quick heat conduction formula fin. The method has the following beneficial effects: the problem of the radiating fin heat dissipation mentioned in the background art has effectually been solved, through the supplementary heat radiation structure of this device, can carry out reasonable heat dissipation when the fin of being convenient for uses, improve the effect of fin to can not obstruct the fin use, the arrangement structure is convenient for this device reasonable to settle, thereby adjustment position height, it is more nimble to use.

Drawings

Fig. 1 is a schematic structural view of the fast heat-conducting heat sink for notebook computer.

Fig. 2 is a top view of the fast heat-conducting heat sink for notebook computer.

In the figure: 1-a rectangular frame; 2-a heat sink; 3-a support plate; 4-a bearing; 5-a slideway; 6-a micro motor; 7-a blade; 8-a slide block; 9-support; 10-a strut; 11-a scaffold; 12-a drive mount; 13-a fourth screw; 14-a connecting rod; 15-a support plate; 16-a column; 17-a sleeve; 18-a backing plate; 19-a second screw; 20-a support bar; 21-a ring gasket; 22-a third screw; 23-first screw.

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.

Referring to fig. 1-2, the present invention provides a technical solution: a quick heat conduction type cooling fin for a notebook computer comprises a rectangular frame 1 and a plurality of cooling fins 2, wherein a support plate 3 is mounted on the rectangular frame 1, and the plurality of cooling fins 2 are arranged on the support plate 3;

the rectangular frame 1 is provided with a mounting structure and an auxiliary heat dissipation structure;

the auxiliary heat dissipation structure includes: the device comprises a bearing 4, a slideway 5, a micro motor 6 and a blade 7;

the rectangular frame 1 is provided with a strip-shaped groove, the slide rail 5 is arranged in the strip-shaped groove, the slide rail 5 is provided with a slide block 8, the upper wall surface of the slide block 8 is provided with a support 9, the support 9 is provided with a circular groove, the bearing 4 is arranged in the circular groove, a support rod 10 is arranged in the bearing 4, the top end of the support rod 10 is provided with a support 11, the support 11 is provided with a driving installation seat 12, the micro motor 6 is arranged in the driving installation seat 12, the driving end of the micro motor 6 is provided with a connecting rod 14, and the blade 7 is arranged on the connecting rod 14.

It should be noted that: rectangular frame 1 plays the supporting role, be used for supporting plate 3, and fin 2 in supporting plate 3, be convenient for install and play the radiating effect on electronic component, slider 8 that slide 5 settled on rectangular frame 1 can the back-and-forth movement, thereby reach blade 7 and remove, blade 7 drives through micro motor 6, when micro motor 6 drive end rotates, blade 7 on the drive connecting rod 14 rotates, micro motor 6 supports through support 11 that bearing 4 supported on support 9, bearing 4 self can rotate, drive branch 10 and rotate, thereby when not using blade 7, with its horizontal, it is vertical to rotate during the use, aim at blade 7 and fin 2, later micro motor 6 work drives blade 7 and rotates, drive the air flow, blow fin 2, thereby reach the quick scattered of fin heat, improve the heat conduction effect.

The mounting structure includes: a support plate 15, a column 16, a sleeve 17 and a backing plate 18;

the support plate 15 is installed at the top end of the rectangular frame 1, the positions of the support plate 15 correspond to those of the rectangular frame 1, the upright columns 16 are installed on the support plate 15, the sleeves 17 are respectively sleeved on the lower wall surface of each upright column 16, the cushion plate 18 is installed on the lower wall surface of each sleeve 17, first threaded holes are formed in the lower wall surface of the cushion plate 18, and first screws 23 are inserted into each first threaded hole.

It should be noted that: the column 16 on the plate 15 is used for supporting the sleeve 17, and when the sleeve 17 can be pulled up and down on the column 16 to adjust the position of the sleeve 17, the first screw 23 on the backing plate 18 on the sleeve 17 facilitates the fixed connection of the device.

As a preferred technical solution, further, spacers corresponding in position are fixed on both side wall surfaces of the left and right sides of the slider 8, a second threaded hole is formed on each side wall surface of the spacer, first threaded grooves matched in position with the second threaded holes and arranged at equal intervals are formed on the side wall surfaces of the rectangular frame 1, and a second screw 19 lapped with the first threaded groove is inserted into each second threaded hole; a second screw 19 is arranged on the gasket on the sliding block 8 and screwed to fix the sliding block 8, so that the position of the blade 7 is fixed.

As a preferable technical scheme, furthermore, the bar-shaped grooves are internally provided with support rods 20 penetrating through the sliding block 8; the support rod 20 penetrates the slider 8 so that the slider 8 does not fall off when moved.

As a preferable technical solution, further, an annular gasket 21 is sleeved on the supporting rod 10, a third threaded hole is formed in the annular gasket 21, a third threaded hole which corresponds to the third threaded hole in position and is annularly arranged is formed in the upper wall surface of the support 9, and a third screw 22, which is overlapped with the third threaded groove, is inserted into the third threaded hole;

it should be noted that: a second screw 19 in a third threaded opening in the annular washer 21 is screwed in order to fix the strut 10 and thus the angle of the rotated blade 7.

As a preferable technical solution, further, a fourth threaded hole is formed in a side wall surface of the sleeve 17, and a fourth screw 13 overlapping the upright column 16 is inserted into the fourth threaded hole; the use height of the sleeve 17 is convenient to fix by screwing the fourth screw 13.

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. The use of the phrase "comprising one of the elements does not exclude the presence of other like elements in the 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 (6)

1. A quick heat conduction type radiating fin for a notebook computer comprises a rectangular frame (1) and a plurality of radiating fins (2), and is characterized in that a supporting plate (3) is mounted on the rectangular frame (1), and the plurality of radiating fins (2) are arranged on the supporting plate (3);

the rectangular frame (1) is provided with a mounting structure and an auxiliary heat dissipation structure;

the auxiliary heat dissipation structure includes: the device comprises a bearing (4), a slide way (5), a micro motor (6) and a blade (7);

the improved blade-type fan blade is characterized in that a strip-shaped groove is formed in the rectangular frame (1), the slide rail (5) is arranged in the strip-shaped groove, a slide block (8) is installed on the slide rail (5), a support (9) is arranged on the upper wall surface of the slide block (8), a circular groove is formed in the support (9), the bearing (4) is arranged in the circular groove, a support rod (10) is arranged in the bearing (4), a support (11) is installed at the top end of the support rod (10), a driving installation seat (12) is installed on the support (11), the micro motor (6) is arranged in the driving installation seat (12), a connecting rod (14) is installed at the driving end of the micro motor (6), and the blade (7) is arranged on the.

2. A quick heat transfer fin for a notebook computer as recited in claim 1 wherein said mounting structure comprises: a support plate (15), a column (16), a sleeve (17) and a cushion plate (18);

the supporting plate (15) is installed at the top end of the rectangular frame (1) and corresponds in position, the stand columns (16) are installed on the supporting plate (15), the sleeves (17) are respectively sleeved on the lower wall surface of each stand column (16), the backing plate (18) is installed on the lower wall surface of each sleeve (17), first threaded openings are formed in the lower wall surface of the backing plate (18), and first screws (23) are inserted into each first threaded opening.

3. The quick heat conduction type heat sink for the notebook computer as claimed in claim 1, wherein the left and right side wall surfaces of the slider (8) are fixed with spacers corresponding in position, each of the side wall surfaces of the spacer is provided with a second threaded hole, the side wall surfaces of the rectangular frame (1) are provided with first threaded grooves matching with the second threaded holes in position and arranged at equal intervals, and each of the second threaded holes is internally inserted with a second screw (19) overlapping with the first threaded groove.

4. The heat sink as claimed in claim 1, wherein the bar-shaped grooves are each provided with a support rod (20) penetrating the slider (8).

5. The quick heat conduction type cooling fin for the notebook computer according to claim 1, wherein the supporting rod (10) is sleeved with an annular gasket (21), the annular gasket (21) is provided with a third threaded hole, the upper wall surface of the support (9) is provided with second threaded holes which are arranged in an annular shape and correspond to the third threaded hole, and a third screw (22) which is overlapped with the second threaded groove is inserted into the third threaded hole.

6. The quick heat conduction type heat sink for the notebook computer as claimed in claim 2, wherein a fourth threaded hole is formed on the side wall surface of the sleeve (17), and a fourth screw (13) overlapping the upright column (16) is inserted into the fourth threaded hole.

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