CN218974757U - Ray apparatus of external heat radiation structure - Google Patents

Abstract

The utility model discloses an optical machine with an external heat radiation structure, which comprises A40 heat-insulating glass and an A40-C reflecting hopper, wherein one side of the A40 heat-insulating glass is provided with an A40 rear phenanthrene mirror, one side of the A40 rear phenanthrene mirror is provided with an optical hopper fixing piece, the A40-C reflecting hopper is arranged at the rear end of the optical hopper fixing piece, one side of the A40-C reflecting hopper is provided with an A40-CLED lamp panel, one side of the A40-CLED lamp panel is provided with an A40-C radiator, a camera fixing piece penetrates through the upper side of the A40-C radiator, and an optical hopper cover is arranged above the camera fixing piece. This external heat radiation structure's ray apparatus, when the whole embedding of the A40 heat-proof glass of equipment and A40 back phenanthrene mirror is installed inside A40-C reflector, A40 heat-proof glass can keep apart air heat, avoids light heat to circulate in inside light fill lid and the dustproof net glue piece, and A40 heat-proof glass carries out independent thermal insulation, prevents too circulation between the inside subassembly of airtight ray apparatus, avoids heat to concentrate on the inside damage components and parts of the inside subassembly of airtight ray apparatus.

Description

Ray apparatus of external heat radiation structure

Technical Field

The utility model relates to the technical field of airtight optical machines, in particular to an optical machine with an external heat dissipation structure.

Background

The enclosed optical machine is characterized in that the inside of an optical path of the optical machine is of a closed structure, the optical machine is assembled in a dust-free workshop which at least reaches the ten-thousand-level dust-proof standard, the inside air of the optical machine is guaranteed to reach the dust-free standard, the inside of the optical path of the optical machine is not communicated with the outside after the assembly is completed, the light source is subjected to heat radiation on the outside of the optical machine, the inside of the optical path of the optical machine is subjected to air internal circulation, the temperature of HTPS is reduced through ingenious heat radiation design, but the heat radiation circulation inside the enclosed optical machine is not smooth, and the optical machine lenses are too closed and have concentrated heat.

The heat generated by the too circulation among the inner components of the airtight ray machine in the market is concentrated on the inner sides of the inner components of the airtight ray machine, the single-structure lens is not easy to adjust the focal length of the outer lens, the light on two sides is not easy to adjust left and right, the dustproof effect of the outer lens is not good, and the like.

Disclosure of Invention

The utility model aims to provide an optical engine with an external heat dissipation structure, so as to solve the problems that the internal components of the sealed optical engine on the market provided in the background art are too circulated, generated heat is concentrated on the inner side of the internal components of the sealed optical engine, single-structure lenses are difficult to adjust the focal length of the external lenses, the light on two sides is difficult to adjust left and right, the dustproof effect of the external lenses is poor, and the like.

In order to achieve the above purpose, the present utility model provides the following technical solutions: the utility model provides an external heat radiation structure's ray apparatus, includes A40 heat-proof glass and A40-C reflector, one side of A40 heat-proof glass is provided with the back fei mirror of A40, and the light fight mounting is installed to one side of the back fei mirror of A40, A40-C reflector sets up in the rear end of light fight mounting, A40-CLED lamp plate is installed to one side of A40-C reflector, and A40-C radiator is installed to one side of A40-CLED lamp plate, the top of A40-C radiator runs through there is the camera mounting, and installs the light fight lid in the top of camera mounting, the below of light fight mounting is provided with the dust screen glue spare, and the wind path lid is installed to the below of dust screen glue spare, and the inside of wind path lid is provided with A40-C dust screen, the drain pan is installed to wind path lid one side, and the one side of light machine drain pan is settled 8030 fan.

Furthermore, the A40 heat-insulating glass is attached to the A40 rear phenanthrene mirror, and the A40 rear phenanthrene mirror is in threaded connection with the optical bucket fixing piece.

Further, the A40-C radiator is movably connected with the A40-CLED lamp panel, and the A40-CLED lamp panel is in threaded connection with the A40-C reflector.

Further, the optical engine bottom shell comprises an A40-C adjusting ring fixing piece, an A40-C focusing ring, a phenanthrene mirror cover, a lens decoration ring, a stepping motor, an A40-C lens main body, concave-convex parts, a lens front frame, a biconcave lens, a lens rear frame and a convex viewing lens, wherein the stepping motor is arranged in the phenanthrene mirror cover, the A40-C adjusting ring fixing piece is arranged below the stepping motor, the A40-C focusing ring is arranged below the A40-C adjusting ring fixing piece, the lens decoration ring is arranged below the A40-C focusing ring, and concave-convex parts are arranged below the A40-C lens main body.

Further, the concave-convex cover is internally provided with a lens front frame, the inside of the lens front frame is provided with a biconcave lens, the inside of the biconcave lens is provided with a lens rear frame, and the inside of the lens rear frame is provided with a convex viewing lens.

Further, the biconcave lens is attached to the rear lens frame, and the biconcave lens and the convex lens form a threaded structure through the rear lens frame.

Further, the front lens frame comprises an A40-C reflector, an A40 front phenanthrene mirror, an A40-C screen frame B and a 2.69 liquid crystal screen, wherein the 2.69 liquid crystal screen is arranged outside the front lens frame, the A40-C screen frame B is arranged on one side of the 2.69 liquid crystal screen, the A40 front phenanthrene mirror is arranged on one side of the A40-C screen frame B, and the A40-C reflector is arranged on one side of the A40 front phenanthrene mirror.

Further, the A40-C reflector is movably connected with the A40 front phenanthrene mirror, and the A40-C reflector and the A40-C screen frame B form a clamping structure through the A40 front phenanthrene mirror.

Compared with the prior art, the utility model has the beneficial effects that: this external heat radiation structure's ray apparatus, when the whole embedding of the A40 heat-proof glass of equipment and A40 back phenanthrene mirror is installed inside A40-C reflector, A40 heat-proof glass can keep apart air heat, avoids light heat to circulate in inside light fill lid and the dustproof net glue piece, and A40 heat-proof glass carries out independent thermal insulation, prevents too circulation between the inside subassembly of airtight ray apparatus, avoids heat to concentrate on the inside damage components and parts of the inside subassembly of airtight ray apparatus.

1. The utility model can assemble the built-in A40-C focusing ring and A40-C adjusting ring fixing piece on the phenanthrene mirror cover and the stepping motor, can penetrate the A40-C focusing ring and the A40-C adjusting ring fixing piece, directly approach to the inside of the biconcave lens and the lens rear frame, change the single-structure lens, be beneficial to the focal length adjustment of the external lens, and adjust the built-in biconcave lens and the lens rear frame left and right by the lamplight at two sides.

2. The utility model can keep a certain focal distance between the front lens frame 23 and the external A40-C reflecting mirror as well as between the front lens frame A40 and the rear lens frame A, is convenient for embedding, protecting and installing the biconcave lens and the rear lens frame, improves the external dustproof effect of the lens and avoids the excessively concentrated sealing of the optical machine lens.

Drawings

FIG. 1 is a schematic diagram of an explosive structure according to the present utility model;

FIG. 2 is a schematic perspective view of the present utility model;

fig. 3 is an exploded view of the chassis of the present utility model.

Fig. 4 is an exploded view of the front lens frame of the present utility model.

In the figure: 1. a40 insulating glass; 2. a40, a rear phenanthrene mirror; 3. a light bucket cover; 4. a camera fixing member; 5. a40-C heat sink; 6. A40-CLED lamp panel; 7. A40-C light reflecting hopper; 8. a light bucket fixing piece; 9. a dust-proof net glue piece; 10. an air path cover; 11. A40-C dustproof net; 12. A40-C adjusting ring fixing piece; 13. A40-C focusing ring; 14. a phenanthrene mirror cover; 15. a lens decorative ring; 16. a stepping motor; 17. a40-C lens body; 18. concave-convex; 19. a40-C mirror; 20. a40 front phenanthrene mirror; 21. a40-C screen frame B; 22. 2.69 liquid crystal screen; 23. a lens front frame; 24. biconcave lenses; 25. a lens rear frame; 26. a convex viewing lens; 27. 8030 fans; 28. and a bottom shell of the optical machine.

Detailed Description

As shown in fig. 1-2, the present utility model provides a technical solution: the optical engine with the external heat radiation structure comprises A40 heat insulation glass 1 and A40-C light reflecting hopper 7, wherein one side of the A40 heat insulation glass 1 is provided with an A40 rear phenanthrene mirror 2, one side of the A40 rear phenanthrene mirror 2 is provided with a light hopper fixing piece 8, the A40-C light reflecting hopper 7 is arranged at the rear end of the light hopper fixing piece 8, one side of the A40-C light reflecting hopper 7 is provided with an A40-CLED lamp panel 6, one side of the A40-CLED lamp panel 6 is provided with an A40-C heat radiator 5, the upper side of the A40-C heat radiator 5 is penetrated with a camera fixing piece 4, the upper side of the camera fixing piece 4 is provided with a light hopper cover 3, the lower side of the light hopper fixing piece 8 is provided with a dustproof net glue piece 9, the lower side of the dustproof net glue piece 9 is provided with an air path cover 10, the inside of the air path cover 10 is provided with an A40-C dustproof net 11, one side of the air path cover 10 is provided with an optical engine bottom shell 28, one side of the optical engine bottom shell 28 is provided with an 8030 fan 27, A40 heat-insulating glass 1 is attached to A40 rear phenanthrene mirror 2, A40 rear phenanthrene mirror 2 is in threaded connection with optical bucket fixing piece 8, A40 heat-insulating glass 1 is attached to A40 rear phenanthrene mirror 2 and movably installed inside the A40 rear phenanthrene mirror 2, so that the optical bucket fixing piece 8 is in threaded connection, reinforcement and assembly are facilitated, the assembled A40 heat-insulating glass 1 and A40 rear phenanthrene mirror 2 are integrally embedded and installed inside A40-C reflecting bucket 7, A40 heat-insulating glass 1 and A40 rear phenanthrene mirror 2 are embedded into the optical bucket fixing piece 8, A40-C reflecting bucket 7 is in light adjustment and assembly, movable connection is arranged between A40-C radiator 5 and A40-CLED lamp panel 6, A40-CLED lamp panel 6 is in threaded connection with A40-C reflecting bucket 7, A40-CLED lamp panel 6 is movably installed on A40-C reflecting bucket 7, light beams are beaten on A40 heat-insulating glass 1 and A40 rear phenanthrene mirror 2 by means of A40-CLED lamp panel 6, meanwhile, the A40-C radiator 5 carries out heat radiation treatment on the A40-CLED lamp panel 6 and the A40-C reflector 7, when the assembled A40 heat-insulating glass 1 and the A40 rear phenanthrene mirror 2 are integrally embedded and installed in the A40-C reflector 7, the A40 heat-insulating glass 1 can insulate air heat, so that lamplight heat is prevented from flowing in the light bucket cover 3 and the dustproof net glue piece 9, the A40 heat-insulating glass 1 carries out independent heat insulation treatment, excessive circulation among internal components of the airtight optical machine is prevented, and the heat is prevented from being concentrated on the inner side of the internal components of the airtight optical machine to damage components.

As shown in fig. 3, the present utility model provides a technical solution: the optical engine with an external heat radiation structure comprises an optical engine bottom shell 28, an A40-C adjusting ring fixing piece 12, an A40-C focusing ring 13, a phenanthrene mirror cover 14, a lens decoration ring 15, a stepping motor 16, an A40-C lens main body 17, a concave-convex part 18, a lens front frame 23, a biconcave lens 24, a lens rear frame 25 and a convex viewing lens 26, wherein the stepping motor 16 is arranged in the interior of the phenanthrene mirror cover 14, the A40-C adjusting ring fixing piece 12 is arranged below the stepping motor 16, the A40-C focusing ring 13 is arranged below the A40-C adjusting ring fixing piece 12, the lens decoration ring 15 is arranged below the A40-C focusing ring 13, the concave-convex part 18 is arranged below the A40-C lens main body 17, the lens front frame 23 is arranged in the concave-convex part 18, the biconcave lens 24 is arranged in the lens front frame 23, the biconcave lens 24 is arranged in the biconcave lens rear frame 25, the lens rear frame 25 is internally provided with a convex viewing lens 26, the A40-C adjusting ring fixing piece 12 is sleeved in the A40-C focusing ring 13 in a threaded manner, the lens decoration ring 15 and the A40-C lens main body 17 which are assembled in a threaded manner are integrally sleeved in the A40-C focusing ring 13 and the A40-C adjusting ring fixing piece 12, the three lens concave-convex parts 18, the lens front frame 23 and the biconcave lens 24 are integrally embedded in the A40-C focusing ring 13 and the A40-C adjusting ring fixing piece 12, a user manually adjusts the A40-C focusing ring 13 and the A40-C adjusting ring fixing piece 12 to adjust the focal length, the biconcave lens 24 is attached to the lens rear frame 25, the biconcave lens 24 and the convex viewing lens 26 form a threaded structure through the lens rear frame 25, the convex viewing lens 26 is assembled in a threaded manner and buckled on the biconcave lens 24 and the lens rear frame 25, the double-concave lens 24 and the lens rear frame 25 are convenient for a user to manually assemble, the user can assemble the built-in A40-C focusing ring 13 and the A40-C adjusting ring fixing piece 12 on the phenanthrene mirror cover 14 and the stepping motor 16, can penetrate through the A40-C focusing ring 13 and the A40-C adjusting ring fixing piece 12 and directly approach the inside of the double-concave lens 24 and the lens rear frame 25, changes the single-structure lens, is beneficial to the focal length adjustment of an external lens, and adjusts the built-in double-concave lens 24 and the lens rear frame 25 left and right by lamplight at two sides.

As shown in fig. 4, the present utility model provides a technical solution: the optical machine with the external heat dissipation structure comprises a lens front frame 23, wherein the lens front frame 23 comprises an A40-C reflector 19, an A40 front phenanthrene mirror 20, an A40-C screen frame B21 and a 2.69 liquid crystal screen 22, the 2.69 liquid crystal screen 22 is arranged outside the lens front frame 23, the A40-C screen frame B21 is arranged on one side of the 2.69 liquid crystal screen 22, the A40-C reflector 20 is arranged on one side of the A40-C screen frame B21, the A40-C reflector 19 is arranged on one side of the A40 front phenanthrene mirror 20, the A40-C reflector 19 is movably connected with the A40 front phenanthrene mirror 20, the A40-C reflector 19 forms a clamping structure with the A40-C screen frame B21 through the A40 front phenanthrene mirror 20, the 2.69 liquid crystal screen 22 is packaged on the lens front frame 23, the A40-C screen frame B21 is integrally arranged in the 2.69 liquid crystal screen 22, the A40-C reflector 19 and the A40 front phenanthrene mirror 20 are integrally arranged on the front frame 23 in a protective way, the front frame 23 can enable the front frame 23 and the A40-C reflector 20 to be conveniently embedded into the front concave optical machine with the front lens frame 20 at a certain distance, the front concave lens 20 is prevented from being too far away from being too far from being embedded into the outer frame 25, and the front lens 20 is prevented from being too far from being too far embedded into the front.

In sum, the optical machine with the external heat radiation structure is used, when the optical machine is in use, the A40-CLED lamp panel 6 is movably arranged on the A40-C reflector 7, the A40-CLED lamp panel 6 is used for shining light beams on the A40 heat insulation glass 1 and the A40 rear phenanthrene mirror 2, meanwhile, the A40-C radiator 5 is used for carrying out heat radiation treatment on the A40-CLED lamp panel 6 and the A40-C reflector 7, when the assembled A40 heat insulation glass 1 and the A40 rear phenanthrene mirror 2 are integrally embedded and arranged in the A40-C reflector 7, the A40 heat insulation glass 1 can isolate air heat, the light heat is prevented from flowing in the optical bucket cover 3 and the dustproof screen glue piece 9, the 2.69 liquid crystal screen 22 is packaged on the lens front frame 23, the A40-C screen frame B21 is integrally arranged in the 2.69 liquid crystal screen 22, the A40-C reflector 19 and the A40 front phenanthrene mirror 20 are integrally mounted on the lens front frame 23 in a protective manner, so that the lens front frame 23, the external A40-C reflector 19 and the A40 front phenanthrene mirror 20 can keep a certain focal distance, the biconcave lens 24 and the lens rear frame 25 are conveniently embedded in the protective mounting manner, the convex lens 26 is assembled and buckled on the biconcave lens 24 and the lens rear frame 25 in a threaded manner, a user can conveniently assemble the biconcave lens 24 and the lens rear frame 25 manually, the user can assemble the built-in A40-C focusing ring 13 and A40-C adjusting ring fixing pieces 12 on the phenanthrene mirror cover 14 and the stepping motor 16, and can penetrate through the A40-C focusing ring 13 and the A40-C adjusting ring fixing pieces 12 to be directly close to the insides of the biconcave lens 24 and the lens rear frame 25, and the single-structure type lens is changed.

Claims (8)

1. An optical machine with an external heat radiation structure comprises A40 heat insulation glass (1) and an A40-C light reflecting hopper (7), and is characterized in that; a40 heat-insulating glass (1) one side is provided with behind the A40 fei mirror (2), and one side of behind the A40 fei mirror (2) is installed light and is fought mounting (8), A40-C reflector (7) set up in the rear end of light and fight mounting (8), A40-CLED lamp plate (6) are installed to one side of A40-C reflector (7), and A40-C radiator (5) are installed to one side of A40-CLED lamp plate (6), camera mounting (4) are run through to the top of A40-C radiator (5), and light and fight lid (3) are installed to the top of camera mounting (4), the below of light and fight mounting (8) is provided with dust screen glue piece (9), and dust screen glue piece (9) installs wind path lid (10) in the below, and the inside of wind path lid (10) is provided with A40-C lamp plate (11), wind path lid (10) one side is installed drain pan (28), and is settled fan (27) one side of the drain pan (28).

2. The bare engine with external heat dissipation structure according to claim 1, wherein: the A40 heat-insulating glass (1) is attached to the A40 rear phenanthrene mirror (2), and the A40 rear phenanthrene mirror (2) is in threaded connection with the light bucket fixing piece (8).

3. The bare engine with external heat dissipation structure according to claim 1, wherein: the A40-C radiator (5) is movably connected with the A40-CLED lamp panel (6), and the A40-CLED lamp panel (6) is in threaded connection with the A40-C reflector (7).

4. The bare engine with external heat dissipation structure according to claim 1, wherein: the optical chassis (28) comprises an A40-C adjusting ring fixing piece (12), an A40-C focusing ring (13), a phenanthrene mirror cover (14), a lens decoration ring (15), a stepping motor (16), an A40-C lens main body (17), a concave-convex part (18), a lens front frame (23), a biconcave lens (24), a lens rear frame (25) and a convex lens (26), the stepping motor (16) is arranged in the inner part of the phenanthrene mirror cover (14), the A40-C adjusting ring fixing piece (12) is arranged below the stepping motor (16), the A40-C focusing ring (13) is arranged below the A40-C adjusting ring fixing piece (12), the lens decoration ring (15) is arranged below the A40-C focusing ring (13), and the concave-convex part (18) is arranged below the A40-C lens main body (17).

5. The bare engine with external heat dissipation structure according to claim 4, wherein: the concave-convex type lens is characterized in that a lens front frame (23) is arranged in the concave-convex type lens 18, a biconcave lens (24) is arranged in the lens front frame (23), a lens rear frame (25) is arranged in the biconcave lens (24), and a convex viewing lens (26) is arranged in the lens rear frame (25).

6. The bare engine with external heat dissipation structure according to claim 4, wherein: the biconcave lens (24) is attached to the rear lens frame (25), and the biconcave lens (24) and the convex lens (26) form a threaded structure through the rear lens frame (25).

7. The bare engine with external heat dissipation structure according to claim 4, wherein: the lens front frame (23) comprises an A40-C reflecting mirror (19), an A40 front phenanthrene mirror (20), an A40-C screen frame B (21) and a 2.69 liquid crystal screen (22), wherein the 2.69 liquid crystal screen (22) is arranged outside the lens front frame (23), the A40-C screen frame B (21) is arranged on one side of the 2.69 liquid crystal screen (22), the A40 front phenanthrene mirror (20) is arranged on one side of the A40-C screen frame B (21), and the A40-C reflecting mirror (19) is arranged on one side of the A40 front phenanthrene mirror (20).

8. The bare engine with external heat dissipation structure according to claim 7, wherein: the A40-C reflecting mirror (19) is movably connected with the A40 front phenanthrene mirror (20), and the A40-C reflecting mirror (19) and the A40-C screen frame B (21) form a clamping structure through the A40 front phenanthrene mirror (20).

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