CN220451108U - Integral type LED photoelectricity glass mounting structure - Google Patents

Abstract

The utility model belongs to the technical field of LED photoelectric glass, in particular to an integrated LED photoelectric glass mounting structure, aiming at the problems that the existing integrated LED photoelectric glass mounting structure is complex in mounting and inconvenient to use, the utility model provides a scheme which comprises a mounting seat and a photoelectric glass body, wherein a framework is arranged in the mounting seat, the photoelectric glass body is arranged in the framework, an inner box is fixedly arranged on the inner wall of one side of the mounting seat, a driven rack is connected to one side of the inner box in a sliding manner, an auxiliary plate is fixedly connected to the driven rack, tension springs are connected to the two auxiliary plates, one ends of the two tension springs are connected with the inner wall of one side of the inner box, an inner rotating rod is connected to the inner box in a rotating manner, a gear shaft is fixedly connected to the inner rotating rod, and the gear shaft is meshed with the driven rack. The utility model has simple structure, is convenient for installing and fixing a plurality of photoelectric glasses and is convenient for people to use.

Description

Integral type LED photoelectricity glass mounting structure

Technical Field

The utility model relates to the technical field of LED photoelectric glass, in particular to an integrated LED photoelectric glass mounting structure.

Background

At present, common toughened glass commonly used in the market cannot play images to meet the demands of people, so that a plurality of people design photoelectric glass capable of being used for playing images, and in order to meet the demands, a plurality of enterprises completely detach the common toughened glass to be replaced by novel photoelectric glass, but the mode causes that a large amount of resources are wasted, manual detachment is time-consuming and labor-consuming, and the use of the common toughened glass is inconvenient; and currently when a single photovoltaic glass cannot meet our needs, multiple photovoltaic glasses need to be mounted together.

The existing integrated LED photoelectric glass mounting structure is complex in mounting of a plurality of photoelectric glasses, and is inconvenient for us to use.

Disclosure of Invention

The utility model aims to solve the defects that the installation of a plurality of pieces of photoelectric glass is complex and the use of the photoelectric glass is inconvenient in the existing integrated LED photoelectric glass installation structure.

In order to achieve the above purpose, the present utility model adopts the following technical scheme:

the utility model provides an integral type LED photoelectricity glass mounting structure, includes mount pad and photoelectricity glass body, be equipped with the skeleton in the mount pad, in the skeleton was located to photoelectricity glass body, fixedly mounted has inside case on one side inner wall of mount pad, one side sliding connection of inside case has passive rack, fixedly connected with accessory plate on the passive rack, all be connected with tension spring on two accessory plates, one end of two tension springs all is connected with one side inner wall of inside case, inside incasement rotation is connected with inside bull stick, fixedly connected with gear shaft on the inside bull stick, the gear shaft meshes with passive rack mutually, be equipped with two extrusion chamber, two fixed chambeies and two solution accuse chambeies in the mount pad, all be equipped with fixed establishment in two fixed chambeies.

Preferably, the first springs are arranged in the two control cavities, the control boards are connected to the two first springs, the control rods are fixedly connected to the two control boards, the fixing clamping rods are fixedly connected to the bottoms of the two control boards, the discs are fixedly connected to the inner rotating rods, and the discs are provided with clamping grooves.

Preferably, the two fixing mechanisms comprise two convex plates, two inclined rods, two inclined blocks, two second springs, two push rods and two clamping seats, wherein the two convex plates are fixedly connected with two ends of the two inner rotary rods respectively, the two convex plates are positioned in the two extrusion cavities respectively, the two inclined rods are connected with the two extrusion cavities in a sliding mode respectively, and the two inclined rods are attached to the two convex plates respectively.

Preferably, the two inclined blocks are respectively connected with the two fixed cavities in a sliding manner, the two inclined blocks are respectively attached to the other ends of the two inclined rods, the two second springs are respectively connected with the two inclined blocks, the two push rods are respectively fixedly connected with the two inclined blocks, and the two clamping seats are respectively fixedly connected with one ends of the two push rods.

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

according to the scheme, as the two inclined rods are arranged to extrude the two inclined blocks to move, the two inclined blocks drive the two push rods to move downwards, the two push rods drive the two clamping seats to move downwards, and the framework is limited, so that the aim of being convenient to install and fix is fulfilled.

The utility model has simple structure, is convenient for installing and fixing a plurality of photoelectric glasses and is convenient for people to use.

Drawings

Fig. 1 is a schematic structural diagram of an integrated LED photovoltaic glass mounting structure according to the present utility model;

fig. 2 is a schematic perspective view of a disc of an integrated LED photovoltaic glass mounting structure according to the present utility model;

fig. 3 is a schematic structural diagram of a portion a of an integrated LED photovoltaic glass mounting structure according to the present utility model;

fig. 4 is a schematic perspective view of a card holder of an integrated LED photovoltaic glass mounting structure according to the present utility model.

In the figure: 1. a mounting base; 2. a skeleton; 3. an optoelectronic glass body; 4. an inner box; 5. a passive rack; 6. an auxiliary plate; 7. a tension spring; 8. an inner rotating rod; 9. a gear shaft; 10. a fixed cavity; 11. a solution control cavity; 12. a first spring; 13. a control board; 14. a solution control rod; 15. fixing the clamping rod; 16. a disc; 17. a convex plate; 18. a diagonal rod; 19. a sloping block; 20. a second spring; 21. a push rod; 22. a clamping seat.

Detailed Description

The technical solutions of the present embodiment will be clearly and completely described below with reference to the drawings in the present embodiment, and it is apparent that the described embodiments are only some embodiments of the present embodiment, not all embodiments.

Example 1

Referring to fig. 1-4, an integral type LED photoelectric glass mounting structure, including mount pad 1 and photoelectric glass body 3, be equipped with skeleton 2 in the mount pad 1, photoelectric glass body 3 locates in the skeleton 2, fixed mounting has interior case 4 on the inner wall of one side of mount pad 1, one side sliding connection of interior case 4 has passive rack 5, fixedly connected with accessory plate 6 on the passive rack 5, all be connected with tension spring 7 on two accessory plates 6, the one end of two tension springs 7 all is connected with one side inner wall of interior case 4, the internal box 4 internal rotation is connected with inside bull stick 8, fixed connection gear shaft 9 on the internal bull stick 8, gear shaft 9 meshes with passive rack 5 mutually, be equipped with two extrusion chamber in the mount pad 1, two fixed chambers 10 and two control chambers 11 are separated to be equipped with fixed establishment in two fixed chambers 10.

In this embodiment, the first springs 12 are all provided in the two solutions control chambers 11, the solutions control boards 13 are all connected to the two first springs 12, solutions control rods 14 are all fixedly connected to the two solutions control boards 13, the bottoms of the two solutions control boards 13 are all fixedly connected with fixing clamping rods 15, a disc 16 is fixedly connected to the inner rotating rod 8, and the disc 16 is provided with a clamping groove.

In this embodiment, the two fixing mechanisms include two convex plates 17, two diagonal rods 18, two diagonal blocks 19, two second springs 20, two push rods 21 and two clamping seats 22, the two convex plates 17 are respectively fixedly connected with two ends of the two inner rotating rods 8, the two convex plates 17 are respectively located in the two extrusion cavities, the two diagonal rods 18 are respectively in sliding connection with the two extrusion cavities, and the two diagonal rods 18 are respectively attached to the two convex plates 17.

In this embodiment, two inclined blocks 19 are slidably connected with two fixed cavities 10, two inclined blocks 19 are respectively attached to the other ends of two inclined rods 18, two second springs 20 are respectively connected with two inclined blocks 19, two push rods 21 are respectively fixedly connected with two inclined blocks 19, and two clamping seats 22 are respectively fixedly connected with one ends of two push rods 21.

In this embodiment, when the photoelectric glass body 3 needs to be installed, the skeleton 2 is pushed to move, the skeleton 2 drives the photoelectric glass body 3 to move, the skeleton 2 pushes the driven rack 5 to move, the driven rack 5 drives the two auxiliary plates 6 to move, the two auxiliary plates 6 drive the two tension springs 7 to stretch, meanwhile, the driven rack 5 drives the gear shaft 9 to rotate, the gear shaft 9 drives the inner rotating rod 8 to rotate, the inner rotating rod 8 drives the disc 16 to rotate, meanwhile, the inner rotating rod 8 drives the two convex plates 17 to rotate and extrudes the two inclined rods 18 to move, the two inclined rods 18 extrude the two inclined blocks 19 to move, the two inclined blocks 19 drive the two push rods 21 to move downwards, the two push rods 21 drive the two clamping seats 22 to move downwards and limit the skeleton 2, meanwhile, the clamping grooves on the disc 16 coincide with the fixed clamping rods 15, the first spring 12 releases elasticity to drive the release control plate 13 to move downwards, and the release the control plate 13 to drive the fixed clamping rods 15 to move downwards and to be placed in the clamping grooves, so that an automatic fixing effect is achieved.

Example two

The difference between this embodiment and the first embodiment is that: the one end of solution accuse pole 14 is fixed to be equipped with the pull ring and turns round, the pull ring turns round the top of locating mount pad 1, can stimulate solution accuse pole 14 through the pull ring and reciprocate, solution accuse pole 14 drives solution accuse board 13 upward movement, and compress first spring 12, solution accuse board 13 drives fixed clamping lever 15 and breaks away from the draw-in groove, two tension springs 7 shrink simultaneously, two second springs 20 release elasticity drive two sloping blocks 19 and reciprocate, two sloping blocks 19 drive cassette 22 upward movement through two push rods 21, can accomplish the dismantlement, all structures in this application can carry out the selection of material and length according to the in-service use condition, the drawing is the schematic structure diagram, specific actual size can make appropriate adjustment.

The foregoing is only a preferred embodiment of the present utility model, but the scope of the present utility model is not limited thereto, and any person skilled in the art will be able to apply equally to the technical solution of the present utility model and the inventive concept thereof, within the scope of the present utility model.

Claims (6)

1. The utility model provides an integral type LED photoelectricity glass mounting structure, includes mount pad (1) and photoelectricity glass body (3), its characterized in that, be equipped with skeleton (2) in mount pad (1), in skeleton (2) are located in photoelectricity glass body (3), fixedly mounted has interior case (4) on one side inner wall of mount pad (1), one side sliding connection of interior case (4) has passive rack (5), fixedly connected with accessory plate (6) on passive rack (5), all be connected with tension spring (7) on two accessory plates (6), one end of two tension springs (7) all is connected with one side inner wall of interior case (4), interior case (4) internal rotation is connected with inside bull stick (8), fixedly connected gear shaft (9) mesh with passive rack (5) on inside bull stick (8), be equipped with two extrusion chamber, two fixed chamber (10) and two solution accuse chamber (11) in mount pad (1), all be equipped with fixed establishment in two fixed chamber (10).

2. The integrated LED photoelectric glass mounting structure according to claim 1, wherein first springs (12) are arranged in two control cavities (11), control boards (13) are connected to the two first springs (12), control rods (14) are fixedly connected to the two control boards (13), fixing clamping rods (15) are fixedly connected to the bottoms of the two control boards (13), a disc (16) is fixedly connected to the inner rotating rod (8), and clamping grooves are formed in the disc (16).

3. The integrated LED electro-optical glass mounting structure according to claim 1, wherein the two fixing mechanisms comprise two convex plates (17), two diagonal rods (18), two diagonal blocks (19), two second springs (20), two push rods (21) and two clamping seats (22), the two convex plates (17) are fixedly connected with two ends of the two inner rotary rods (8) respectively, the two convex plates (17) are located in two extrusion cavities respectively, the two diagonal rods (18) are connected with the two extrusion cavities in a sliding mode respectively, and the two diagonal rods (18) are attached to the two convex plates (17) respectively.

4. An integrated LED electro-optical glass mounting structure according to claim 3, wherein two inclined blocks (19) are slidably connected with the two fixing cavities (10), the two inclined blocks (19) are respectively attached to the other ends of the two inclined rods (18), and the two second springs (20) are respectively connected with the two inclined blocks (19).

5. An integrated LED electro-optic glass mounting structure according to claim 3, characterized in that two push rods (21) are fixedly connected with two inclined blocks (19), respectively.

6. The integrated LED electro-optical glass mounting structure according to claim 5, wherein two clamping seats (22) are fixedly connected with one ends of two push rods (21), respectively.