CN-224218701-U - Built-in guiding gutter fin radiator

CN224218701UCN 224218701 UCN224218701 UCN 224218701UCN-224218701-U

Abstract

The utility model relates to the technical field of heat dissipation, in particular to a fin radiator with a built-in diversion trench, wherein a dustproof mechanism (2) is arranged on a radiator main body (1), the dustproof mechanism (2) comprises a chute (21), a sliding block (22), a shell (23), a mounting groove (24) and a dustproof net (25), the chute (21) is formed in the outer wall of the radiator main body (1), the sliding block (22) is mounted in the chute (21), the shell (23) is fixed on the outer wall of the sliding block (22), the mounting groove (24) is formed in the outer wall of the shell (23), and the dustproof net (25) is arranged in the mounting groove (24). A fin radiator with a built-in diversion trench is provided with a dustproof mechanism and an installation mechanism, so that dust of the dustproof mechanism can be well blocked outside the radiator when the fin radiator is in radiating work, and meanwhile, the installation mechanism is matched, so that the installation of the dustproof mechanism becomes simple and rapid, and the working efficiency of the fin radiator is further improved.

Inventors

Zhang Linpin

Assignees

东莞市诚光实业有限公司

Dates

Publication Date: 20260508
Application Date: 20250506

Claims (5)

1. The fin radiator with the built-in diversion trenches comprises a radiator main body (1) and is characterized in that a dustproof mechanism (2) is arranged on the radiator main body (1); The dustproof mechanism (2) comprises a sliding groove (21), a sliding block (22), a shell (23), a mounting groove (24) and a dustproof net (25), wherein the sliding groove (21) is formed in the outer wall of the radiator main body (1), the sliding block (22) is mounted in the sliding groove (21), the shell (23) is fixed to the outer wall of the sliding block (22), the mounting groove (24) is formed in the outer wall of the shell (23), and the dustproof net (25) is arranged in the mounting groove (24).
2. The radiator with built-in diversion trench fins according to claim 1, wherein the radiator body (1) comprises a base (11), radiating fins (12), diversion trenches (13) and a radiating fan (14), the radiating fins (12) are fixed on the base (11), the diversion trenches (13) are formed in the outer walls of the radiating fins (12), and the radiating fan (14) is installed on the outer walls of the base (11).
3. The fin radiator with the built-in diversion trench of claim 1, wherein the dustproof mechanism (2) is provided with a mounting mechanism (3), the mounting mechanism (3) comprises a mounting hole (31), a connecting rod (32), a spring (33), a latch (34) and a limit groove (35), the mounting hole (31) is formed in the outer wall of the sliding block (22), the connecting rod (32) is arranged in the mounting hole (31), the spring (33) is sleeved on the outer wall of the connecting rod (32), one end of the connecting rod (32) is fixedly provided with the latch (34), and the limit groove (35) is formed in the inner wall of the sliding groove (21).
4. The fin radiator with built-in diversion trenches according to claim 1, wherein an auxiliary fan (26) is arranged in the installation trench (24).
5. The fin radiator with built-in diversion trenches of claim 3, wherein one end of the connecting rod (32) is fixed with a poking block (36).

Description

Built-in guiding gutter fin radiator Technical Field The utility model relates to the technical field of heat dissipation, in particular to a fin radiator with a built-in diversion trench. Background Heat dissipation is a critical element in electronic devices, which is related to the performance and lifetime of the device. The good heat dissipation system can effectively dissipate heat generated during the operation of the equipment, and performance degradation and even damage caused by overheating are avoided. The heat dissipation modes are various, including passive heat dissipation and active heat dissipation. Passive heat dissipation mainly depends on hardware devices such as a radiating fin and a radiator, while active heat dissipation may involve more complex devices such as a fan and a liquid cooling system, and fin heat dissipation is a common heat dissipation mode, so that in order to efficiently perform heat dissipation by using fins, a fin heat radiator with a built-in diversion trench is particularly required. When a machine is cooled by a fin radiator, dust and dirt are likely to accumulate on the surface of the radiator, heat transfer and dissipation are affected to cause incongruity between the heat dissipation efficiency and the expected heat dissipation efficiency, and once the incongruity between the heat dissipation efficiency and the expected heat dissipation efficiency occurs, related workers clean the fin radiator, but the problem that dust and dirt are likely to accumulate on the surface of the radiator cannot be quickly solved by the aid of the method, and the workload of the related workers is increased. Disclosure of utility model The utility model aims to provide a fin radiator with a built-in diversion trench, which solves the problems in the background technology. In order to achieve the purpose, the utility model provides the technical scheme that the radiator with the built-in diversion trench fins comprises a radiator main body, wherein a dustproof mechanism is arranged on the radiator main body; The dustproof mechanism comprises a sliding groove, a sliding block, a shell, a mounting groove and a dustproof net, wherein the sliding groove is formed in the outer wall of the radiator main body, the sliding block is mounted in the sliding groove, the shell is fixed to the outer wall of the sliding block, the mounting groove is formed in the outer wall of the shell, and the dustproof net is arranged in the mounting groove. Preferably, the radiator main body comprises a base, radiating fins, a diversion trench and a radiating fan, the radiating fins are fixed on the base, the diversion trench is arranged on the outer wall of each radiating fin, and the radiating fan is arranged on the outer wall of the base. Preferably, the dustproof mechanism is provided with a mounting mechanism, the mounting mechanism comprises a mounting hole, a connecting rod, a spring, a latch and a limiting groove, the mounting hole is formed in the outer wall of the sliding block, the connecting rod is arranged in the mounting hole, the spring is sleeved on the outer wall of the connecting rod, one end of the connecting rod is fixed with the latch, and the limiting groove is formed in the inner wall of the sliding groove. Preferably, an auxiliary fan is arranged in the mounting groove. Preferably, a shifting block is fixed at one end of the connecting rod. Compared with the prior art, the fin radiator with the built-in diversion trenches has the beneficial effects that by arranging the dustproof mechanism and the installation mechanism, when the fin radiator performs heat dissipation work, dust can be well blocked outside the radiator by the dustproof mechanism, and meanwhile, the installation of the dustproof mechanism is simple and quick by matching with the installation mechanism, so that the working efficiency of the fin radiator is further improved. Drawings FIG. 1 is a schematic view of the overall appearance structure of the present utility model; FIG. 2 is a schematic view of a dust-proof mechanism according to the present utility model; FIG. 3 is a schematic view of the mounting mechanism of the present utility model; fig. 4 is an enlarged schematic view of the structure of fig. 2 a according to the present utility model. The radiator comprises a radiator main body, 11, a base, 12, radiating fins, 13, a diversion trench, 14, a radiating fan, 2, a dustproof mechanism, 21, a chute, 22, a sliding block, 23, a shell, 24, a mounting trench, 25, a dustproof net, 26, an auxiliary fan, 3, a mounting mechanism, 31, a mounting hole, 32, a connecting rod, 33, a spring, 34, a clamping bolt, 35, a limit trench, 36 and a shifting block. Detailed Description The following description of the embodiments of the present utility model 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 utility