CN213545136U - All-in-one heat radiation structure - Google Patents

Abstract

The utility model relates to an all-in-one heat radiation structure technical field, concretely an all-in-one heat radiation structure, including the main part, maintain device and heat abstractor, the inner wall bottom fixed mounting of main part maintains the device, inner wall one side fixed mounting of main part has heat abstractor, it includes the bracing piece to maintain the device, the inner wall bottom fixed mounting of main part has the bracing piece, the spout has been seted up to one side of bracing piece, the opposite side of bracing piece is seted up flutedly, the inner wall bottom fixed mounting of recess has the spring, inner wall one side sliding connection of recess has the fixture block, one side sliding connection that the bracing piece is close to the recess has. The utility model discloses, maintain the device through setting up for the user can dismantle the flabellum in the radiator fan fast, thereby makes the user clear up or change the flabellum, has improved radiator fan's radiating effect effectively, has also reduced user's intensity of labour simultaneously effectively.

Description

All-in-one heat radiation structure

Technical Field

The utility model relates to an all-in-one heat radiation structure technical field especially relates to an all-in-one heat radiation structure.

Background

The all-in-one computer is a new computer integrating a host and a display together, and due to the advantages of small size, convenience in carrying and the like, the all-in-one computer mainly adopts a PC-like design, heat dissipation is mainly carried out by a heat dissipation fan, and multiple groups of fans are usually needed for heat dissipation.

Traditional radiator fan is after long-time work, and the flabellum among the radiator fan is possible to accumulate a large amount of dust to radiator fan's radiating effect has been influenced, nevertheless because the flabellum among the radiator fan is difficult for dismantling, makes the user can not clear up and maintain it better, thereby need consume a large amount of time of user and physical power, increased user's intensity of labour.

SUMMERY OF THE UTILITY MODEL

The utility model aims at solving the defects existing in the prior art and providing an all-in-one machine heat radiation structure.

In order to achieve the above purpose, the utility model adopts the following technical scheme: the utility model provides an all-in-one heat radiation structure, includes the main part, maintains device and heat abstractor, the inner wall bottom fixed mounting of main part has the maintenance device, inner wall one side fixed mounting of main part has heat abstractor.

The maintenance device comprises a supporting rod, a supporting rod is fixedly mounted at the bottom of the inner wall of the main body, a sliding groove is formed in one side of the supporting rod, a groove is formed in the other side of the supporting rod, a spring is fixedly mounted at the bottom of the inner wall of the groove, a clamping block is slidably connected to one side of the inner wall of the groove, a rotating ring is slidably connected to one side of the supporting rod, a sliding rail is formed in one side of the rotating ring, a clamping groove is formed in the other side of the rotating ring, and fan blades are slidably connected to.

Preferably, heat abstractor is including leading to the groove, logical groove has been seted up to one side of main part, inner wall one side sliding connection who leads to the groove has the filter plate, one side fixed mounting that the main part is close to logical groove has the fixed block, the inner wall top fixed mounting of fixed block has the pressure spring, one side sliding connection of fixed block has the movable block, the bayonet socket has been seted up at the top of filter plate.

Preferably, the end, far away from the groove, of the spring is fixedly connected with the clamping block, and the fan blade is connected with the sliding rail in a sliding mode.

Preferably, one end, far away from the fixed block, of the pressure spring is fixedly connected with the movable block, and the movable block is connected with the bayonet in a sliding mode.

Preferably, one side of the clamping block is connected with the clamping groove in a sliding mode, and the shape and the size of the outer wall of one side of the supporting rod are matched with the shape and the size of the inner wall of the rotating ring.

Preferably, a sliding rod is fixedly mounted on one side of the through groove, and one side of the sliding rod is connected with the filter plate in a sliding mode.

Compared with the prior art, the utility model has the advantages and positive effects that,

1. in the utility model, through the maintenance device, when the fan blade needs to be disassembled, the user can press the fixture block to make the fixture block extruding spring slide towards the inner wall of the groove, when the fixture block slides to a certain position, the user rotates the swivel to make the swivel rotate at one end of the support rod, when the swivel rotates to a corresponding position, the slide rail is aligned with the slide groove, the user pulls the fan blade to make the fan blade slide out from the slide groove to the slide rail, when the fan blade needs to be installed, the user inserts the fan blade from one end of the swivel to make the fan blade slide on the inner wall of the slide rail, when the fan blade slides to the corresponding position, the user rotates the swivel to make the swivel rotate at one end of the support rod, when the fan blade needs to be installed, the fixture block loses the extrusion force and is influenced by the resilience force of the spring to slide out from the inner wall of the, through setting up the device for the user can dismantle the flabellum among the radiator fan fast, thereby makes the user clear up or change the flabellum, has improved radiator fan's radiating effect effectively, has also reduced user's intensity of labour simultaneously effectively.

2. In the utility model, by arranging the heat dissipation device, when the filter plate of the heat dissipation fan needs to be cleaned, the user slides the movable block to enable the movable block to extrude the pressure spring to slide upwards in the fixed block, when the movable block slides to a certain position, the clamping block slides out of the bayonet, a user pulls the filter plate to cause the filter plate to slide out of the inner wall of the through groove, when the filter plate is required to be installed, a user slides the movable block, so that the movable block extrudes the pressure spring to slide upwards in the fixed block, when the movable block slides to a certain position, a user inserts one end of the filter plate into the through groove, when the filter plate slides to a certain position, the user loosens the movable block to enable the movable block to rebound under the influence of the resilience force of the pressure spring, thereby the bayonet socket is gone into to the card inside fixes the filter plate, through setting up the device for the user can clear up the filter plate, thereby makes radiator fan can be better the heat dissipation.

Drawings

Fig. 1 is a schematic perspective view of a heat dissipation structure of an all-in-one machine according to the present invention;

fig. 2 is a schematic side view of the heat dissipation structure of the integrated machine according to the present invention;

fig. 3 is a schematic cross-sectional structural view of a maintenance device of an all-in-one machine heat dissipation structure according to the present invention;

fig. 4 is the utility model provides a structural schematic diagram of a place in fig. 2 of an all-in-one machine heat radiation structure.

Illustration of the drawings:

1. a main body; 2. a maintenance device; 201. a support bar; 202. a chute; 203. a groove; 204. a spring; 205. a clamping block; 206. rotating the ring; 207. a slide rail; 208. a card slot; 209. a fan blade; 3. a heat sink; 301. a through groove; 302. filtering the plate; 303. a fixed block; 304. a pressure spring; 305. a movable block; 306. and (4) a bayonet.

Detailed Description

In order to make the above objects, features and advantages of the present invention more clearly understood, the present invention will be further described with reference to the accompanying drawings and examples. It should be noted that the embodiments and features of the embodiments of the present application may be combined with each other without conflict.

In the following description, numerous specific details are set forth in order to provide a thorough understanding of the present invention, however, the present invention may be practiced in other ways than those specifically described herein, and therefore the present invention is not limited to the limitations of the specific embodiments of the present disclosure.

Referring to fig. 1-4, the present invention provides a technical solution: the utility model provides an all-in-one heat radiation structure, includes main part 1, maintains device 2 and heat abstractor 3, and the inner wall bottom fixed mounting of main part 1 has to maintain device 2, and the inner wall one side fixed mounting of main part 1 has heat abstractor 3.

The maintenance device 2 comprises a supporting rod 201, a supporting rod 201 is fixedly mounted at the bottom of the inner wall of the main body 1, a sliding groove 202 is formed in one side of the supporting rod 201, a groove 203 is formed in the other side of the supporting rod 201, a spring 204 is fixedly mounted at the bottom of the inner wall of the groove 203, a clamping block 205 is slidably connected to one side of the inner wall of the groove 203, a rotating ring 206 is slidably connected to one side of the supporting rod 201 close to the groove 203, a sliding rail 207 is formed in one side of the rotating ring 206, a clamping groove 208 is formed in the other side of.

In this embodiment: when the fan blades 209 need to be detached, a user presses the fixture block 205 to enable the fixture block 205 to extrude the spring 204 to slide towards the inner wall of the groove 203, when the fixture block 205 slides to a certain position, the user rotates the rotary ring 206 to enable the rotary ring 206 to rotate at one end of the supporting rod 201, when the rotary ring 206 rotates to a corresponding position, the sliding rail 207 is aligned with the sliding groove 202, the user pulls the fan blades 209 to enable the fan blades 209 to slide out from the sliding groove 202 to the sliding rail 207, when the fan blades 209 need to be installed, the user inserts the fan blades 209 from one end of the rotary ring 206 to enable the fan blades 209 to slide on the inner wall of the sliding rail 207, when the fan blades 209 slide to a corresponding position, the user rotates the rotary ring 206 to enable the rotary ring 206 to rotate at one end of the supporting rod 201, when the rotary ring rotates to a corresponding position, the fixture block 205 loses the extrusion force influenced by the resilience force of the spring 204 and slides out, through setting up the device for the user can dismantle flabellum 209 among the radiator fan fast, thereby makes the user clear up or change flabellum 209, has improved radiator fan's radiating effect effectively, has also reduced user's intensity of labour simultaneously effectively.

Specifically, heat abstractor 3 has been seted up logical groove 301 including leading to groove 301, one side of main part 1, and the inner wall one side sliding connection who leads to groove 301 has filter plate 302, and main part 1 is close to one side fixed mounting who leads to groove 301 has fixed block 303, and the inner wall top fixed mounting of fixed block 303 has pressure spring 304, and one side sliding connection of fixed block 303 has movable block 305, and bayonet socket 306 has been seted up at the top of filter plate 302.

In this embodiment: when the filter plate 302 of the cooling fan needs to be cleaned, a user slides the movable block 305, so that the movable block 305 presses the pressure spring 304 to slide upwards in the fixed block 303, when the movable block 305 slides to a certain position, the fixture block 205 slides out of the bayonet 306, the user pulls the filter plate 302, so that the filter plate 302 slides outwards on the inner wall of the through groove 301, when the filter plate 302 needs to be installed, the user slides the movable block 305, so that the movable block 305 presses the pressure spring 304 to slide upwards in the fixed block 303, when the movable block 305 slides to a certain position, the user inserts one end of the filter plate 302 into the through groove 301, when the filter plate 302 slides to a certain position, the user releases the movable block 305, so that the movable block 305 rebounds under the influence of the rebounding force of the pressure spring 304, and is clamped into the bayonet 306 to fix the filter plate 302, and by the arrangement of the device, the user can, thereby enabling the heat dissipation fan to dissipate heat better.

Specifically, one end of the spring 204 away from the groove 203 is fixedly connected to the latch 205, and the fan blade 209 is slidably connected to the sliding rail 207.

In this embodiment: so that the latch 205 can drive the spring 204 to slide up and down on the inner wall of the groove 203, and the fan blade 209 can slide on the inner wall of the sliding rail 207.

Specifically, one end of the pressure spring 304, which is far away from the fixed block 303, is fixedly connected with the movable block 305, and the movable block 305 is slidably connected with the bayonet 306.

In this embodiment: so that the movable block 305 can drive the pressure spring 304 to move inside the fixed block 303, and the movable block 305 can slide out of the bayonet 306.

Specifically, one side of the fixture block 205 is slidably connected with the fixture groove 208, and the shape and size of the outer wall of one side of the support rod 201 are matched with the shape and size of the inner wall of the rotating ring 206.

In this embodiment: so that the latch 205 can slide on the inner wall of the slot 208, and the rotating ring 206 can rotate at one end of the supporting rod 201.

Specifically, a slide rod is fixedly mounted on one side of the through groove 301, and one side of the slide rod is slidably connected with the filter plate 302.

In this embodiment: so that the filter plate 302 can slide back and forth on the slide rod.

The working principle is as follows: when the fan blades 209 need to be detached, a user presses the fixture block 205 to enable the fixture block 205 to extrude the spring 204 to slide towards the inner wall of the groove 203, when the fixture block 205 slides to a certain position, the user rotates the rotary ring 206 to enable the rotary ring 206 to rotate at one end of the supporting rod 201, when the rotary ring 206 rotates to a corresponding position, the sliding rail 207 is aligned with the sliding groove 202, the user pulls the fan blades 209 to enable the fan blades 209 to slide out from the sliding groove 202 to the sliding rail 207, when the fan blades 209 need to be installed, the user inserts the fan blades 209 from one end of the rotary ring 206 to enable the fan blades 209 to slide on the inner wall of the sliding rail 207, when the fan blades 209 slide to a corresponding position, the user rotates the rotary ring 206 to enable the rotary ring 206 to rotate at one end of the supporting rod 201, when the rotary ring rotates to a corresponding position, the fixture block 205 loses the extrusion force influenced by the resilience force of the spring 204 and slides out, when the filter plate 302 of radiator fan needs to be cleaned, the user slides the movable block 305, make the movable block 305 extrude the pressure spring 304 and upwards slide in the fixed block 303, when the movable block 305 slides to a certain position, make the fixture block 205 slide out from the bayonet 306, the user pulls the filter plate 302, make the filter plate 302 outwards slide out in through groove 301 inner wall, when the filter plate 302 needs to be installed, make the user slide the movable block 305, make the movable block 305 extrude the pressure spring 304 and upwards slide in the fixed block 303, when the movable block 305 slides to a certain position, the user injects the one end of the filter plate 302 into the through groove 301, when the filter plate 302 slides to a certain position, the user loosens the movable block 305, make the movable block 305 rebound under the influence of the resilience force of the pressure spring 304, thereby the bayonet 306 is inside to fix the filter plate 302.

The above description is only exemplary of the present invention and should not be construed as limiting the present invention, and any modifications, equivalents and improvements made within the spirit and principles of the present invention are intended to be included within the scope of the present invention.

Claims (6)

1. The utility model provides an all-in-one heat radiation structure, includes main part (1), maintains device (2) and heat abstractor (3), its characterized in that: the maintenance device (2) is fixedly installed at the bottom of the inner wall of the main body (1), and the heat dissipation device (3) is fixedly installed on one side of the inner wall of the main body (1);

the maintenance device (2) comprises a supporting rod (201), a supporting rod (201) is fixedly mounted at the bottom of the inner wall of the main body (1), a sliding groove (202) is formed in one side of the supporting rod (201), a groove (203) is formed in the other side of the supporting rod (201), a spring (204) is fixedly mounted at the bottom of the inner wall of the groove (203), a clamping block (205) is slidably connected to one side of the inner wall of the groove (203), a rotating ring (206) is slidably connected to one side, close to the groove (203), of the supporting rod (201), a sliding rail (207) is formed in one side of the rotating ring (206), a clamping groove (208) is formed in the other side of the rotating ring (206), and fan blades (209) are.

2. The all-in-one machine heat dissipation structure of claim 1, wherein: heat abstractor (3) are including leading to groove (301), logical groove (301) have been seted up to one side of main part (1), inner wall one side sliding connection who leads to groove (301) has filter plate (302), one side fixed mounting that main part (1) are close to logical groove (301) has fixed block (303), the inner wall top fixed mounting of fixed block (303) has pressure spring (304), one side sliding connection of fixed block (303) has movable block (305), bayonet socket (306) have been seted up at the top of filter plate (302).

3. The all-in-one machine heat dissipation structure of claim 1, wherein: one end, far away from the groove (203), of the spring (204) is fixedly connected with the clamping block (205), and the fan blade (209) is in sliding connection with the sliding rail (207).

4. The all-in-one machine heat dissipation structure of claim 2, wherein: one end, far away from the fixed block (303), of the pressure spring (304) is fixedly connected with the movable block (305), and the movable block (305) is in sliding connection with the bayonet (306).

5. The all-in-one machine heat dissipation structure of claim 1, wherein: one side of the clamping block (205) is in sliding connection with the clamping groove (208), and the shape and the size of the outer wall of one side of the supporting rod (201) are matched with the shape and the size of the inner wall of the rotating ring (206).

6. The all-in-one machine heat dissipation structure of claim 2, wherein: and a sliding rod is fixedly arranged on one side of the through groove (301), and one side of the sliding rod is connected with the filter plate (302) in a sliding manner.

Images