CN212846696U - Novel CPU radiator - Google Patents

Abstract

The utility model discloses a novel CPU radiator, it is including the heat dissipation base, the shaping has multi-disc radiating fin on the heat dissipation base, install the wind scooper on the heat dissipation base, on the equipment casing was located to wind scooper one end, the wind scooper both sides shaping respectively has first, second shell fragment buckle, the shaping has first respectively in heat dissipation base both sides, the second back-off groove, it is first, second shell fragment buckle respectively with first, the second back-off groove block is fixed, make the wind scooper be fixed in on the heat dissipation base, and first, second shell fragment buckle upper end all stretches out outside the wind scooper up end. When the heat generated by the CPU is guided up by the heat dissipation base, the air is directly blown into the air guide cover, passes through the heat dissipation fins on the heat dissipation base and is directly exhausted out of the equipment shell along the air guide cover, and the effects of rapid heat dissipation and heat dissipation are achieved. The wind scooper and the heat dissipation base are of a detachable structure, the upper ends of the first elastic sheet buckle and the second elastic sheet buckle are directly pushed outwards, and the first elastic sheet buckle and the second elastic sheet buckle can be separated from the first reverse buckle groove and the second reverse buckle groove respectively, so that the wind scooper can be detached.

Description

Novel CPU radiator

The technical field is as follows:

the utility model relates to a radiator product technical field refers in particular to a novel CPU radiator.

Background art:

a Central Processing Unit (CPU), which is one of the main devices of an electronic computer, is a core accessory in the computer. Its functions are mainly to interpret computer instructions and to process data in computer software. The CPU is the core component of the computer responsible for reading, decoding and executing instructions. The central processor mainly comprises two parts, namely a controller and an arithmetic unit, and also comprises a cache memory and a bus for realizing data and control of the connection between the cache memory and the arithmetic unit. The three major core components of the computer are the CPU, internal memory, and input/output devices. The central processing unit mainly has the functions of processing instructions, executing operations, controlling time and processing data.

The CPU can generate a large amount of heat when working, if the heat is not dissipated in time, the heat is easy to crash, the CPU can be burnt out, and the CPU radiator is used for radiating the CPU. The radiator plays a decisive role in the stable operation of the CPU, and it is very important to choose a good radiator when assembling the computer.

The existing CPU radiator generally comprises a radiating base and a radiating fan arranged on the radiating base, the lower end face of the radiating base is attached to the CPU, the CPU radiator with the structure cannot immediately discharge hot air out of an equipment shell, so that the hot air is circulated in the equipment shell, the radiating effect is not ideal enough, and the running speed of high-performance equipment is influenced.

In view of the above, the present inventors propose the following.

The utility model has the following contents:

an object of the utility model is to overcome prior art not enough, provide a novel CPU radiator.

In order to solve the technical problem, the utility model discloses a following technical scheme: the novel CPU radiator comprises a radiating base, a plurality of radiating fins are formed on the radiating base, an air guide cover is installed on the radiating base, one end of the air guide cover is arranged on an equipment shell, a first elastic sheet buckle and a second elastic sheet buckle are formed on two sides of the air guide cover respectively, a first inverted buckle groove and a second inverted buckle groove are formed on two sides of the radiating base respectively, the first elastic sheet buckle and the second elastic sheet buckle are fixed with the first inverted buckle groove and the second inverted buckle groove in a clamped mode respectively, the air guide cover is fixed on the radiating base, and the upper ends of the first elastic sheet buckle and the second elastic sheet buckle are extended out of the upper end face of the air guide cover.

Furthermore, in the above technical solution, the second elastic sheet fastener includes a second elastic sheet body integrally injection-molded on one side of the air guiding cover and a second fastening portion formed on an inner side of the second elastic sheet body, the second fastening portion extends into the air guiding cover and is fastened in the second inverted fastening groove, and an upper end of the second elastic sheet body extends out of an upper end surface of the air guiding cover.

Furthermore, in the above technical solution, the second elastic sheet body is in an inverted U shape.

Further, in the above technical solution, the structure of the second elastic sheet buckle is the same as the structure of the first elastic sheet buckle.

Furthermore, in the above technical solution, a plurality of foam blocks are arranged on the inner wall of the wind scooper and the outer portion of the upper end of the heat dissipation base.

Furthermore, in the above technical solution, a fool-proof rib is formed on a side surface of the wind scooper, a fool-proof groove is formed on a side surface of the heat dissipation base, and the fool-proof rib is embedded in the fool-proof groove.

Furthermore, in the above technical solution, a first wind deflector and a second wind deflector are respectively formed on two sides of the heat dissipation base, the heat dissipation fin is located between the first wind deflector and the second wind deflector, the first undercut groove is formed on the outer side surface of the first wind deflector, and the second undercut groove is formed on the outer side surface of the second wind deflector; the fool-proof groove is formed in the outer side face of the second wind baffle.

Furthermore, in the above technical scheme, the boss for contacting with the CPU is formed on the lower end face of the heat dissipation base, the first support and the second support are further mounted on two sides of the lower end face of the heat dissipation base through screws, the first studs are mounted at two ends of the first support, and the second studs are mounted at two ends of the second support.

Furthermore, in the above technical solution, two ends of the wind scooper are respectively formed with a first wind guiding opening and a second wind guiding opening, the first wind guiding opening and the second wind guiding opening are located at two ends of the heat dissipation base and are communicated with a heat dissipation gap formed between the heat dissipation fins, the first wind guiding opening is disposed on the equipment enclosure, and a foam pad is disposed between the first wind guiding opening and the equipment enclosure.

Furthermore, in the above technical scheme, a positioning convex rib in a right-angle shape is formed on the inner side of the wind scooper, and the positioning convex rib is buckled at the corner of the upper end of the heat dissipation base.

After the technical scheme is adopted, compared with the prior art, the utility model has following beneficial effect: the utility model discloses install the wind scooper on the heat dissipation base, this wind scooper one end sets up on the equipment casing, and this wind scooper other end corresponds with radiator fan, and this heat dissipation pedestal mounting is on CPU, and after the heat guide that the heat base produced CPU came, wind directly blew in the wind scooper, behind the radiating fin on the heat dissipation base, directly outside the wind scooper discharge equipment casing of following to this reaches the efficiency of quick heat dissipation, heat extraction. The wind scooper is fixed with the first inverted groove and the second inverted groove on two sides of the heat dissipation base through the first elastic sheet buckle and the second elastic sheet buckle of the wind scooper, the wind scooper is fixed on the heat dissipation base and is of a detachable structure, the upper ends of the first elastic sheet buckle and the second elastic sheet buckle extend out of the upper end face of the wind scooper, so that the upper ends of the first elastic sheet buckle and the second elastic sheet buckle are directly pushed outwards, the first elastic sheet buckle and the second elastic sheet buckle can be separated from the first inverted groove and the second inverted groove respectively, and the wind scooper is convenient to disassemble and assemble.

Description of the drawings:

fig. 1 is a perspective view of the present invention;

fig. 2 is a perspective view of another perspective of the present invention;

fig. 3 is an exploded view of the present invention;

fig. 4 is a perspective view of the wind scooper of the present invention;

fig. 5 is a cross-sectional view of the present invention.

The specific implementation mode is as follows:

the present invention will be further described with reference to the following specific embodiments and accompanying drawings.

As shown in fig. 1-5, the novel CPU heat sink includes a heat dissipation base 1, a plurality of heat dissipation fins 11 are formed on the heat dissipation base 1, an air guiding cover 2 is mounted on the heat dissipation base 1, one end of the air guiding cover 2 is disposed on an equipment enclosure, a first elastic sheet buckle 21 and a second elastic sheet buckle 22 are respectively formed on two sides of the air guiding cover 2, a first inverted buckle groove 12 and a second inverted buckle groove 13 are respectively formed on two sides of the heat dissipation base 1, the first elastic sheet buckle 21 and the second elastic sheet buckle 22 are respectively fixed with the first inverted buckle groove 12 and the second inverted buckle groove 13 in a clamping manner, so that the air guiding cover 2 is fixed on the heat dissipation base 1, and the upper ends of the first elastic sheet buckle 21 and the second elastic sheet buckle 22 extend out of the upper end surface of the air guiding cover 2. The utility model discloses install wind scooper 2 on heat dissipation base 1, 2 one ends of this wind scooper set up on the equipment casing, the 2 other ends of this wind scooper correspond with radiator fan, this heat dissipation base 1 is installed on CPU, after the heat that CPU produced was guided to the heat dissipation base 1, wind directly blows in wind scooper 2, behind radiating fin 11 on the heat dissipation base 1, directly outside the equipment casing of 2 discharge along the wind scooper, reach the efficiency of quick heat dissipation, heat extraction with this. The wind scooper 2 is fixed with the first and second inverse- buckling grooves 12 and 13 at two sides of the heat dissipation base 1 through the first and second elastic sheet buckles 21 and 22, respectively, so that the wind scooper 2 is fixed on the heat dissipation base 1, and is of a detachable structure, and the upper ends of the first and second elastic sheet buckles 21 and 22 are extended out of the upper end surface of the wind scooper 2, so as to directly push the upper ends of the first and second elastic sheet buckles 21 and 22 outwards, and the first and second elastic sheet buckles 21 and 22 can be separated from the first and second inverse- buckling grooves 12 and 13, and the detachment is very convenient.

The second elastic piece buckle 22 includes a second elastic piece body 221 integrally formed on one side of the air guiding cover 2 by injection molding and a second buckle part 222 formed on the inner side of the second elastic piece body 221, the second buckle part 222 extends into the air guiding cover 2 and is buckled in the second reverse buckle groove 13, and the upper end of the second elastic piece body 221 extends out of the upper end surface of the air guiding cover 2. The second elastic piece 221 is in an inverted U shape.

The first elastic sheet buckle 21 comprises a first elastic sheet body integrally formed on one side of the air guiding cover 2 in an injection molding mode and a first buckle part formed on the inner side of the first elastic sheet body, the first buckle part extends into the air guiding cover 2 and is buckled in the first reverse buckle groove, and the upper end of the first elastic sheet body extends out of the upper end surface of the air guiding cover 2. The first elastic sheet body is in an inverted U shape.

A plurality of foam blocks 3 are arranged on the inner wall of the air guide cover 2 and the outer part of the upper end of the heat dissipation base 1, and the foam blocks 3 can improve the stability of the assembly of the air guide cover 2 and the heat dissipation base 1 and also play a role in shock absorption.

The side surface of the air guide cover 2 is formed with a fool-proof convex rib 23, the side surface of the heat dissipation base 1 is formed with a fool-proof groove 14, the fool-proof convex rib 23 is embedded in the fool-proof groove 14 in a clamping mode, the structure can achieve the fool-proof effect, and the effect of improving the stability of the assembly structure can be achieved.

A first wind shield 15 and a second wind shield 16 are respectively formed on two sides of the heat dissipation base 1, the heat dissipation fins 11 are located between the first wind shield 15 and the second wind shield 16, the first undercut groove 12 is formed on the outer side surface of the first wind shield 15, and the second undercut groove 13 is formed on the outer side surface of the second wind shield 16; the fool-proof groove 14 is formed on the outer side surface of the second wind deflector 16.

The lower end surface of the heat dissipation base 1 is provided with a boss 10 for contacting with a CPU, two sides of the lower end surface of the heat dissipation base 1 are provided with a first support 4 and a second support 5 through screws, two ends of the first support 4 are provided with first studs 41, and two ends of the second support 5 are provided with second studs 51.

The two ends of the wind scooper 2 are respectively formed with a first wind guide opening 201 and a second wind guide opening 202 which are inclined, the first wind guide opening 201 and the second wind guide opening 202 are located at the two ends of the heat dissipation base 1 and are communicated with a heat dissipation gap formed between the heat dissipation fins 11, the first wind guide opening 201 is arranged on the equipment casing, and a foam pad 203 is arranged between the first wind guide opening 201 and the equipment casing. The second air guiding opening 202 is disposed beside the heat dissipating fan.

The inner side of the wind scooper 2 is formed with a positioning convex rib 24 in a right-angle shape, and the positioning convex rib 24 is buckled at the corner of the upper end of the heat dissipation base 1, so that the stability of the assembly structure is ensured.

The utility model discloses install wind scooper 2 on heat dissipation base 1, 2 one ends of this wind scooper set up on the equipment casing, the 2 other ends of this wind scooper correspond with radiator fan, this heat dissipation base 1 is installed on CPU, after the heat that CPU produced was guided to the heat dissipation base 1, wind directly blows in wind scooper 2, behind radiating fin 11 on the heat dissipation base 1, directly outside the equipment casing of 2 discharge along the wind scooper, reach the efficiency of quick heat dissipation, heat extraction with this. The wind scooper 2 is fixed with the first and second inverse- buckling grooves 12 and 13 at two sides of the heat dissipation base 1 through the first and second elastic sheet buckles 21 and 22, respectively, so that the wind scooper 2 is fixed on the heat dissipation base 1, and is of a detachable structure, and the upper ends of the first and second elastic sheet buckles 21 and 22 are extended out of the upper end surface of the wind scooper 2, so as to directly push the upper ends of the first and second elastic sheet buckles 21 and 22 outwards, and the first and second elastic sheet buckles 21 and 22 can be separated from the first and second inverse- buckling grooves 12 and 13, and the detachment is very convenient.

Of course, the above description is only an exemplary embodiment of the present invention, and not intended to limit the scope of the present invention, and all equivalent changes and modifications made by the constructions, features, and principles of the present invention in accordance with the claims of the present invention are intended to be included in the scope of the present invention.

Claims (10)

1. A novel CPU radiator comprises a radiating base (1), a plurality of radiating fins (11) are formed on the radiating base (1), it is characterized in that the heat dissipation base (1) is provided with an air guide cover (2), one end of the air guide cover (2) is arranged on the equipment shell, a first elastic sheet buckle (21) and a second elastic sheet buckle (22) are respectively formed at two sides of the wind scooper (2), a first inverted buckle groove (12) and a second inverted buckle groove (13) are respectively formed on two sides of the heat dissipation base (1), the first elastic sheet buckle (21) and the second elastic sheet buckle (22) are respectively clamped and fixed with the first inverse buckle groove (12) and the second inverse buckle groove (13) to ensure that the air guide cover (2) is fixed on the heat dissipation base (1), and the upper ends of the first elastic sheet buckle (21) and the second elastic sheet buckle (22) extend out of the upper end surface of the wind scooper (2).

2. The novel CPU heat sink of claim 1, wherein: the second elastic sheet buckle (22) comprises a second elastic sheet body (221) which is integrally formed on one side of the air guide cover (2) in an injection molding mode and a second buckle part (222) which is formed on the inner side of the second elastic sheet body (221), the second buckle part (222) extends into the air guide cover (2) and is buckled in the second reverse buckle groove (13), and the upper end of the second elastic sheet body (221) extends out of the upper end surface of the air guide cover (2).

3. The novel CPU heat sink of claim 2, wherein: the second elastic sheet body (221) is in an inverted U shape.

4. The novel CPU heat sink of claim 3, wherein: the structure of the second elastic sheet buckle (22) is the same as that of the first elastic sheet buckle (21).

5. The novel CPU heat sink according to any one of claims 1-4, wherein: a plurality of foam blocks (3) are arranged on the inner wall of the air guide cover (2) and the outer part of the upper end of the heat dissipation base (1).

6. The novel CPU heat sink of claim 5, wherein: the side surface of the wind scooper (2) is provided with a fool-proof convex rib (23), the side surface of the heat dissipation base (1) is provided with a fool-proof groove (14), and the fool-proof convex rib (23) is clamped and embedded in the fool-proof groove (14).

7. The novel CPU heat sink of claim 6, wherein: a first wind shield (15) and a second wind shield (16) are respectively formed on two sides of the heat dissipation base (1), the heat dissipation fins (11) are located between the first wind shield (15) and the second wind shield (16), the first inverted buckle groove (12) is formed on the outer side surface of the first wind shield (15), and the second inverted buckle groove (13) is formed on the outer side surface of the second wind shield (16); the fool-proof groove (14) is formed in the outer side face of the second wind deflector (16).

8. The novel CPU heatsink of claim 7, wherein: the heat dissipation base is characterized in that a boss (10) used for being in contact with a CPU is formed in the lower end face of the heat dissipation base (1), a first support (4) and a second support (5) are further mounted on two sides of the lower end face of the heat dissipation base (1) through screws, first studs (41) are mounted at two ends of the first support (4), and second studs (51) are mounted at two ends of the second support (5).

9. The novel CPU heatsink of claim 7, wherein: the air guide cover (2) is characterized in that a first inclined air guide opening (201) and a second inclined air guide opening (202) are formed at two ends of the air guide cover (2) respectively, the first air guide opening (201) and the second inclined air guide opening (202) are located at two ends of the heat dissipation base (1) and are communicated with a heat dissipation gap formed between the heat dissipation fins (11), the first air guide opening (201) is arranged on an equipment shell, and a foam pad (203) is arranged between the first air guide opening (201) and the equipment shell.

10. The novel CPU heatsink of claim 7, wherein: and a positioning convex rib (24) in a right-angle shape is formed on the inner side of the air guide cover (2), and the positioning convex rib (24) is buckled at the corner part of the upper end of the heat dissipation base (1).

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