CN216491687U - OPL36 radiator unit in ray apparatus - Google Patents

Abstract

The utility model discloses an OPL36 heat dissipation assembly in an optical machine, belonging to the field of radiators, and the OPL36 heat dissipation assembly in the optical machine comprises an optical machine body, wherein a lens disassembly and assembly is fixedly assembled at one side of the optical machine body, an assembly frame is fixedly installed at the other side of the optical machine body, a processor heat dissipation assembly is fixedly assembled at the other end of the assembly frame, a processor is fixedly assembled at one side of the processor heat dissipation assembly, a turbine radiator is fixedly assembled at one side of the processor heat dissipation assembly, which is far away from the assembly frame, an assembly cavity is fixedly formed at one side of a main heat dissipation fin, which is far away from the optical machine body, and an auxiliary heat dissipation fin is movably embedded in the assembly cavity, so that the heat dissipation efficiency can be improved, the disassembly and assembly work of the auxiliary heat dissipation fin is convenient, dust and impurities in the fin can be easily removed, the installation space is reasonably utilized, in addition, when the lens is protected, and the light machine body is convenient to disassemble.

Description

OPL36 radiator unit in ray apparatus

Technical Field

The utility model relates to the field of radiators, in particular to an OPL36 radiating component in an optical machine.

Background

The heat radiator is a device or an instrument which transfers heat generated by machinery or other appliances in the working process in time so as to avoid influencing the normal work of the machinery or other appliances, and common heat radiators can be divided into various types such as air cooling, heat pipe radiators, liquid cooling, semiconductor refrigeration, compressor refrigeration and the like according to a heat dissipation mode;

however, the heat dissipation assembly in the optical engine usually only dissipates heat through the heat dissipation fins, and the heat dissipation effect of the method is too poor, so that the service life of the processor is seriously shortened, but the heat dissipation assembly is directly installed in the turbo fan, occupies a large amount of space, and also increases the cleaning difficulty of the heat dissipation fins.

SUMMERY OF THE UTILITY MODEL

1. Technical problem to be solved

Aiming at the problems in the prior art, the utility model aims to provide an OPL36 heat dissipation assembly in an optical machine, which can improve the heat dissipation efficiency, facilitate the disassembly and assembly work of auxiliary heat dissipation fins, easily remove dust and impurities in the fins, reasonably utilize the installation space, protect a lens and simultaneously facilitate the disassembly of the optical machine body.

2. Technical scheme

In order to solve the above problems, the present invention adopts the following technical solutions.

An OPL36 heat dissipation assembly in an optical machine comprises an optical machine body;

a lens dismounting assembly is fixedly assembled on one side of the optical machine body, an assembly frame is fixedly installed on the other side of the optical machine body, a processor heat dissipation assembly is fixedly assembled on the other end of the assembly frame, a processor is fixedly assembled on one side of the processor heat dissipation assembly, and a turbine radiator is fixedly assembled on one side of the processor heat dissipation assembly, which is far away from the assembly frame;

the processor radiating assembly further comprises a main radiating fin, an assembly cavity is fixedly formed in one side, away from the optical engine body, of the main radiating fin, screw columns are fixedly arranged on two sides of the inner wall of the assembly cavity, auxiliary radiating fins are movably embedded in the assembly cavity, the screw columns respectively penetrate through two sides of the auxiliary radiating fins, and springs are sleeved on the outer surfaces of the screw columns, located on the outer walls of the auxiliary radiating fins;

the turbine radiator further comprises a fan, and the fan is movably assembled on the outer wall of the auxiliary radiating fin inside the assembling cavity.

Further, mounting nail holes are fixedly formed in the main radiating fins and the auxiliary radiating fins.

Further, the inside motor that installs that rotates of fan, interior motor outer wall equidistance is fixed and is provided with the fan blade.

Furthermore, the outer walls of the two sides of the fan are fixedly provided with assembling fin plates, and mounting screws in threaded connection with the screw columns are mounted inside the assembling fin plates.

Further, the optical engine body further comprises a working engine body, a lens is fixedly assembled on the outer wall of one side of the working engine body, protruding blocks are fixedly arranged on two sides of the outer wall of the lens, and optical engine radiating fins are fixedly arranged on one side of the outer wall of the working engine body, which is located on the lens.

Further, camera lens dismouting subassembly still includes the camera lens cover, the movable cover of camera lens cover is established the surface of camera lens, the L type guide slot has all been fixed to camera lens cover both sides, the lug activity embedding is in the inside of L type guide slot, the fixed outer pinion rack that is provided with in camera lens cover outer wall one side.

Furthermore, a micro motor is fixedly assembled on the outer wall of the working machine body, a gear is fixedly assembled at the output end of the micro motor, and the gear is meshed with the outer gear plate.

3. Advantageous effects

Compared with the prior art, the utility model has the advantages that:

(1) in this scheme, when assisting radiating fin and main radiating fin equipment, according to heat-conducting principle, assist radiating fin and also can accomplish radiating work, and after assisting radiating fin and main radiating fin split, can be convenient for clear up both this moment, easily detach the dust debris in the fin, convenient maintenance work.

(2) In the scheme, after the inner motor is electrified, the fan blades can be driven to rotate, so that a pneumatic heat dissipation effect is realized, the heat dissipation efficiency of the heat dissipation assembly of the processor is improved, and the service life of the processor is prolonged; in addition, the fan is embedded into the assembly cavity, so that a certain space can be saved.

(3) This scheme is accomplished the installation back at the fan, and the equipment fin board will extrude the spring, and the spring will reverse extrusion assist radiating fin, and then guarantees to assist radiating fin and hug closely main radiating fin's inner wall, when guaranteeing high heat conduction efficiency, still does not need other parts to make to assist radiating fin and main radiating fin to hug closely, has made convenient radiating fin's dismouting work.

(4) Through being provided with camera lens dismouting subassembly in this scheme, the setting of lens hood plays the effect of protection camera lens, in addition, starts and makes the rotatory back of lens hood when micro motor, still can be convenient for dismantle the camera body.

Drawings

FIG. 1 is a schematic rear perspective view of the present invention;

FIG. 2 is an exploded view of the turbine heat sink of the present invention;

FIG. 3 is an exploded view of the heat sink assembly of the present invention;

FIG. 4 is a schematic perspective view of the present invention;

fig. 5 is a partially enlarged structural view of a portion a in fig. 4.

The reference numbers in the figures illustrate:

1. an optical body; 101. a working machine body; 102. a lens; 103. a bare engine heat dissipation fin; 104. a bump; 2. an assembly frame; 3. a processor heat dissipation assembly; 301. a primary heat dissipating fin; 302. auxiliary radiating fins; 303. a screw post; 304. a spring; 305. installing a nail hole; 306. assembling a cavity; 4. a processor; 5. a turbine radiator; 501. a fan; 502. an inner motor; 503. a fan blade; 504. assembling the fin plate; 505. mounting screws; 6. a lens disassembling and assembling component; 601. a micro motor; 602. a lens cover; 603. a gear; 604. an outer toothed plate; 605. and an L-shaped guide groove.

Detailed Description

The technical solution in the embodiments of the present invention will be clearly and completely described below with reference to the accompanying drawings in the embodiments of the present invention; it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all embodiments, and all other embodiments obtained by those skilled in the art without any inventive work are within the scope of the present invention.

Example 1:

referring to fig. 1-5, an in-optical-machine OPL36 heat dissipation assembly includes an optical machine body 1.

Referring to fig. 1, a lens assembling and disassembling component 6 is fixedly assembled on one side of an optical engine body 1, an assembling frame 2 is fixedly installed on the other side of the optical engine body 1, a processor heat dissipation component 3 is fixedly assembled on the other end of the assembling frame 2, a processor 4 is fixedly assembled on one side of the processor heat dissipation component 3, and a turbine heat sink 5 is fixedly assembled on one side of the processor heat dissipation component 3, which is far away from the assembling frame 2.

Referring to fig. 3, the processor heat sink assembly 3 further includes a main heat sink fin 301, heat generated by the operation of the processor 4 is directly absorbed by the main heat sink fin 301, an assembly cavity 306 is fixedly formed on one side of the main heat sink fin 301 away from the optical engine body 1, screw posts 303 are fixedly disposed on two sides of an inner wall of the assembly cavity 306, an auxiliary heat sink fin 302 is movably embedded in the assembly cavity 306, when the auxiliary heat sink fin 302 is assembled with the main heat sink fin 301, the auxiliary heat sink fin 302 can also perform heat dissipation, when the auxiliary radiating fins 302 and the main radiating fins 301 are detached, the auxiliary radiating fins 302 and the main radiating fins 301 can be cleaned conveniently, dust and sundries in the fins are easy to remove, the screw columns 303 respectively penetrate through two sides of the auxiliary radiating fins 302, the outer wall of the outer surfaces of the screw columns 303, which are located on the auxiliary radiating fins 302, is sleeved with the springs 304, and the inner parts of the main radiating fins 301 and the inner parts of the auxiliary radiating fins 302 are fixedly provided with the mounting nail holes 305.

Referring to fig. 2, the turbine heat sink 5 further includes a fan 501, the fan 501 is movably assembled inside the assembly cavity 306 and located on the outer wall of the auxiliary heat dissipating fin 302, an inner motor 502 is rotatably installed inside the fan 501, fan blades 503 are fixedly installed on the outer wall of the inner motor 502 at equal intervals, after the fan 501 is installed inside the assembly cavity 306, the inner motor 502 starts to drive the fan blades 503 to rotate after being powered on, so as to achieve the effect of pneumatic heat dissipation, and improve the heat dissipating efficiency, the assembly fins 504 are fixedly installed on the outer walls of both sides of the fan 501, the assembly fins 504 are internally provided with mounting screws 505 in threaded connection with the screw posts 303, during the installation of the fan 501, the mounting screws 505 are assembled with the screw posts 303, at this time, the assembly fins 504 will squeeze the springs 304, and the springs 304 will reversely squeeze the auxiliary heat dissipating fins 302, so as to ensure that the auxiliary heat dissipating fins 302 are tightly attached to the inner wall of the main heat dissipating fin 301, while ensuring high heat dissipating efficiency, and other parts are not needed to enable the auxiliary radiating fins 302 to be tightly attached to the main radiating fins 301, so that the disassembly and assembly work of the auxiliary radiating fins 302 is facilitated.

Referring to fig. 4, the optical body 1 further includes a working body 101, a lens 102 is fixedly assembled on an outer wall of one side of the working body 101, a bump 104 is fixedly disposed on both sides of an outer wall of the lens 102, an optical engine heat dissipation fin 103 is fixedly disposed on one side of the outer wall of the working body 101, which is located on the lens 102, and the optical engine heat dissipation fin 103 is used for dissipating heat generated by the operation of the lens 102.

Referring to fig. 5, the lens disassembling and assembling assembly 6 further includes a lens cover 602, the lens cover 602 is movably sleeved on the outer surface of the lens 102, both sides of the lens cover 602 are fixedly provided with L-shaped guide slots 605, the protrusion 104 is movably embedded inside the L-shaped guide slots 605, one side of the outer wall of the lens cover 602 is fixedly provided with an outer toothed plate 604, the outer wall of the working machine body 101 is fixedly assembled with a micro motor 601, an output end of the micro motor 601 is fixedly assembled with a gear 603, the micro motor 601 drives the gear 603 to rotate after being started, the gear 603 is engaged with the outer toothed plate 604, and then the lens cover 602 is driven to rotate on the outer surface of the lens 102, at this time, the protrusion 104 relatively moves in the L-shaped guide slots 605, and finally the lens cover 602 is directly separated from the lens 102 along the direction of the L-shaped guide slots 605, so as to protect the lens 102 and facilitate the disassembly of the optical machine body 1.

When in use: firstly, heat generated by the operation of the processor 4 is directly absorbed by the main radiating fins 301, when the auxiliary radiating fins 302 are assembled with the main radiating fins 301, the auxiliary radiating fins 302 can also complete the radiating operation according to the heat conduction principle, and when the auxiliary radiating fins 302 are disassembled from the main radiating fins 301, the auxiliary radiating fins 302 and the main radiating fins 301 can be conveniently cleaned, so that dust and impurities in the fins are easily removed; in addition, after the fan 501 is installed inside the assembly cavity 306, the inner motor 502 starts to drive the fan blades 503 to rotate after being electrified, so that a pneumatic heat dissipation effect is achieved, and the heat dissipation efficiency of the processor heat dissipation assembly 3 is improved; in addition, in the installation process of the fan 501, the installation screws 505 are assembled with the screw columns 303, at this time, the assembly fin plates 504 extrude the springs 304, and the springs 304 reversely extrude the auxiliary radiating fins 302, so that the auxiliary radiating fins 302 are ensured to be tightly attached to the inner walls of the main radiating fins 301, high heat conduction efficiency is ensured, meanwhile, other parts are not needed to enable the auxiliary radiating fins 302 to be tightly attached to the main radiating fins 301, and the disassembly and assembly work of the auxiliary radiating fins 302 is facilitated;

finally, the micro motor 601 will drive the gear 603 to rotate after being started, and since the gear 603 is meshed with the external gear plate 604, the lens cover 602 is driven to rotate on the outer surface of the lens 102, at this time, the protrusion 104 will move relatively in the L-shaped guide groove 605, and finally the lens cover 602 is directly separated from the lens 102 along the direction of the L-shaped guide groove 605, so as to protect the lens 102 and facilitate the detachment of the optical engine body 1.

The foregoing is only a preferred embodiment of the present invention; the scope of the utility model is not limited thereto. Any person skilled in the art should be able to cover the technical scope of the present invention by equivalent or modified solutions and modifications within the technical scope of the present invention.

Claims (7)

1. The utility model provides an OPL36 radiator unit in ray apparatus, includes ray apparatus body (1), its characterized in that:

a lens disassembling and assembling assembly (6) is fixedly assembled on one side of the optical machine body (1), an assembling frame (2) is fixedly installed on the other side of the optical machine body (1), a processor heat dissipation assembly (3) is fixedly assembled on the other end of the assembling frame (2), a processor (4) is fixedly assembled on one side of the processor heat dissipation assembly (3), and a turbine radiator (5) is fixedly assembled on one side of the processor heat dissipation assembly (3) away from the assembling frame (2);

the processor heat dissipation assembly (3) further comprises a main heat dissipation fin (301), an assembly cavity (306) is fixedly formed in one side, away from the optical engine body (1), of the main heat dissipation fin (301), screw columns (303) are fixedly arranged on two sides of the inner wall of the assembly cavity (306), auxiliary heat dissipation fins (302) are movably embedded in the assembly cavity (306), the screw columns (303) respectively penetrate through two sides of the auxiliary heat dissipation fins (302), and springs (304) are sleeved on the outer wall, located on the auxiliary heat dissipation fins (302), of the outer surfaces of the screw columns (303);

the turbine radiator (5) further comprises a fan (501), and the fan (501) is movably assembled inside the assembling cavity (306) and is positioned on the outer wall of the auxiliary radiating fin (302).

2. The in-light engine OPL36 heat dissipation assembly of claim 1, wherein: and mounting nail holes (305) are fixedly formed in the main radiating fins (301) and the auxiliary radiating fins (302).

3. The in-light engine OPL36 heat dissipation assembly of claim 2, wherein: an inner motor (502) is rotatably arranged inside the fan (501), and fan blades (503) are fixedly arranged on the outer wall of the inner motor (502) at equal intervals.

4. The in-light engine OPL36 heat dissipation assembly of claim 3, wherein: the fan (501) is characterized in that assembling fin plates (504) are fixedly arranged on the outer walls of two sides of the fan (501), and mounting screws (505) in threaded connection with the screw columns (303) are mounted inside the assembling fin plates (504).

5. The in-light engine OPL36 heat dissipation assembly of claim 1, wherein: the optical engine body (1) further comprises a working engine body (101), a lens (102) is fixedly assembled on the outer wall of one side of the working engine body (101), protruding blocks (104) are fixedly arranged on two sides of the outer wall of the lens (102), and optical engine heat dissipation fins (103) are fixedly arranged on one side, located on the lens (102), of the outer wall of the working engine body (101).

6. The in-light engine OPL36 heat dissipation assembly of claim 5, wherein: lens dismouting subassembly (6) still include lens hood (602), lens hood (602) movable sleeve is established the surface of camera lens (102), lens hood (602) both sides are all fixed and have been seted up L type guide slot (605), lug (104) activity embedding is in the inside of L type guide slot (605), lens hood (602) outer wall one side is fixed and is provided with outer pinion rack (604).

7. The in-light engine OPL36 heat dissipation assembly of claim 6, wherein: the outer wall of the working machine body (101) is fixedly assembled with a micro motor (601), the output end of the micro motor (601) is fixedly assembled with a gear (603), and the gear (603) is meshed with the outer toothed plate (604).

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