CN220351077U - Anti-shake feeding mechanism of backlight machine - Google Patents

Abstract

The utility model discloses an anti-shake feeding mechanism of a backlight machine, which comprises a driving component, wherein a bracket is arranged on the driving component, a locking component is arranged on the bracket, the locking component is used for locking the positions of the driving component and the bracket, a suction component is arranged on the bracket, the suction component is used for sucking a backlight module component by utilizing vacuum negative pressure, and the driving component is used for driving the bracket to move so as to drive the suction component to move. According to the utility model, through the mutual matching of the driving component, the bracket, the locking component and the suction component, the anti-shake feeding mechanism of the backlight machine is realized, so that automation is realized in the whole feeding process, feeding work is not required to be carried out manually, the workload of workers is reduced, the production quality of the backlight module is ensured, and the working efficiency is high.

Description

Anti-shake feeding mechanism of backlight machine

Technical Field

The utility model relates to the technical field of backlight module processing, in particular to an anti-shake feeding mechanism of a backlight machine.

Background

The backlight module is one of key components of the liquid crystal display panel, and has the functions of supplying enough light sources with uniform brightness and distribution, so that the light sources can normally display images, feeding work is needed in the production process of the backlight module, the feeding process of the conventional backlight machine is mostly manually detected and corrected, the labor intensity is high, the correction effect is poor, and the processing quality is affected.

Disclosure of Invention

The utility model aims to provide an anti-shake feeding mechanism of a backlight machine, which aims to solve the problems in the background technology.

In order to achieve the above purpose, the present utility model provides the following technical solutions: the utility model provides an anti-shake material loading mechanism of backlight, includes drive assembly, be provided with the support on the drive assembly, be provided with locking subassembly on the support, locking subassembly is used for locking the position of drive assembly and support, be provided with on the support and absorb the subassembly, it is used for utilizing vacuum negative pressure to absorb backlight unit component to absorb the subassembly, drive assembly is used for driving the support motion, thereby drives absorb the subassembly motion.

Optionally, the driving assembly includes:

the connecting plate is used for forming a base, and a mounting block is fixedly arranged on the connecting plate;

the linear motor is fixedly arranged at the bottom of the connecting plate;

the moving plate is fixedly arranged on the moving end of the linear motor;

and the hydraulic cylinder is fixedly connected to the moving plate.

Optionally, the locking assembly includes:

the connecting frame is fixedly connected to an output shaft at the bottom of the hydraulic cylinder;

a locking plate disposed inside the connection frame;

the locking rod is fixedly connected to the locking plate, and one end of the locking rod, which is far away from the locking plate, is movably spliced on the bracket;

the acting force providing component is arranged in the connecting frame and is used for providing acting force for the locking plate to move in the direction close to the bracket.

Optionally, the force providing composition includes:

the first telescopic rod is arranged in the connecting frame, and one end of the first telescopic rod, which is close to the locking plate, is fixedly connected with the first telescopic rod;

the spring is sleeved on the surface of the first telescopic rod.

Optionally, the suction assembly includes:

the bottom plate is fixedly connected to the bracket and provided with a through hole;

the vacuum sucker is arranged in the through hole;

the air extraction component is arranged on the bottom plate and is communicated with the vacuum chuck in a sealing way, and the air extraction component is used for extracting air in the vacuum chuck;

and the adjusting component is arranged in the through hole and used for adjusting the position of the vacuum chuck.

Optionally, the pumping composition includes:

the air pump is arranged above the bottom plate, the bottom of the air pump is communicated with a central shell in a sealing way through an air exhaust pipe, and the central shell is fixedly connected to the top of the bottom plate;

the telescopic pipe is fixedly communicated with the center shell, and one side, away from the center shell, of the telescopic pipe is communicated with the vacuum chuck in a sealing manner.

Optionally, the adjusting composition includes:

the rotary fixing piece is fixedly arranged in the through hole, and a threaded rod is arranged on the rotary fixing piece;

the adjusting plate is in threaded connection with the surface of the threaded rod, and one side, close to the vacuum chuck, of the adjusting plate is fixedly connected with the adjusting plate;

the second telescopic rod is fixedly connected to the adjusting plate, and one end of the second telescopic rod, which is far away from the adjusting plate, is fixedly connected with the inner wall of the through hole;

the rotating block is fixedly connected to the threaded rod.

Optionally, the rotation fixing piece is specifically a bearing, the surface of the bearing outer ring is fixedly connected with the bottom plate, and the inner wall of the bearing inner ring is fixedly connected with the surface of the threaded rod.

Compared with the prior art, the utility model has the following beneficial effects:

according to the utility model, through the mutual matching of the driving component, the bracket, the locking component and the suction component, the anti-shake feeding mechanism of the backlight machine is realized, so that automation is realized in the whole feeding process, feeding work is not required to be carried out manually, the workload of workers is reduced, the production quality of the backlight module is ensured, and the working efficiency is high.

According to the utility model, the locking component is arranged, so that the driving component and the bracket can be quickly separated, any tool, such as a screwdriver or a spanner, is not required in the whole separation process, and a worker can conveniently and quickly separate the bracket from the driving component, so that the suction component can be quickly separated from the driving component, and the overhaul and maintenance work is convenient to carry out, and the use is convenient.

According to the utility model, the suction assembly is arranged, the vacuum suction disc is utilized to suck the backlight module element in the process of sucking the backlight module element, the stable suction effect of vacuum negative pressure is utilized, the shaking of the backlight module element in the process of feeding is avoided, the backlight module element is prevented from being bent or damaged, the use is convenient, the production effect is ensured, in addition, in the actual use process, when the backlight module element with other sizes is required to be adapted, the distance between the two corresponding vacuum suction discs can be adjusted by a worker, and thus, the backlight module element with other sizes can be adapted, and the application range is wide.

Drawings

FIG. 1 is a cross-sectional view of a front view of the structure of the present utility model;

FIG. 2 is a cross-sectional view of a front view of the suction assembly of the present utility model;

FIG. 3 is a cross-sectional view of a top view of the suction module of the present utility model;

FIG. 4 is a cross-sectional view of a front view of the locking assembly of the present utility model;

FIG. 5 is a schematic diagram of a perspective view of a bracket according to the present utility model;

fig. 6 is a schematic structural view of a bottom plate, a through hole and an adjusting component of the utility model.

In the figure: the device comprises a driving component 1, a connecting plate 101, a mounting block 102, a linear motor 103, a moving plate 104, a hydraulic cylinder 105, a support 2, a locking component 3, a connecting frame 301, a locking plate 302, a locking rod 303, a telescopic rod I, a spring 305, a sucking component 4, a bottom plate 401, a through opening 402, a vacuum chuck 403, a sucking pump 404, a sucking pipe 405, a central shell 406, a telescopic pipe 407, a rotary fixing piece 408, a threaded rod 409, a regulating plate 410, a telescopic rod II 411 and a rotary block 412.

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 model, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the utility model without making any inventive effort, are intended to be within the scope of the utility model.

Referring to fig. 1-6, an anti-shake feeding mechanism of a backlight machine includes a driving assembly 1, where the driving assembly 1 includes:

the connecting plate 101 is used for forming a base, the connecting plate 101 is fixedly provided with a mounting block 102, and the mounting block 102 is used for being mounted at a working position.

The linear motor 103 is fixedly installed at the bottom of the connecting plate 101, and from the view point of fig. 1, the moving end of the linear motor 103 can drive the moving plate 104 to move laterally.

A moving plate 104 fixedly installed on a moving end of the linear motor 103.

The pneumatic cylinder 105, fixed connection is provided with support 2 on the movable plate 104 on the drive assembly 1, be provided with locking subassembly 3 on the support 2, support 2 comprises a central part and two side boards, the bottom of side board and the top fixed connection of bottom plate 401, the central part is a panel of buckling, and the through-hole with the linking bridge 301 looks adaptation has been seted up at the central part top, through-hole inner wall department still has seted up the notch with locking lever 303 looks adaptation, locking subassembly 3 is used for locking the position of drive assembly 1 and support 2, locking subassembly 3 includes:

the connecting frame 301 is fixedly connected to an output shaft at the bottom of the hydraulic cylinder 105, the connecting frame 301 is opened front and back, and the side surface of the connecting frame 301 is in contact with the bracket 2.

And a locking plate 302 disposed inside the connection frame 301, wherein the top and bottom of the locking plate 302 are respectively in contact with the top and bottom of the inner wall of the connection frame 301, and the locking plate 302 is movable inside the connection frame 301.

The locking rod 303 is fixedly connected to the locking plate 302, one end, away from the locking plate 302, of the locking rod 303 is movably inserted into the support 2, the locking rod 303 is movably connected with the connecting frame 301, and the locking rod 303 is movably connected with the support 2.

A force providing component provided inside the connection frame 301, the force providing component being configured to provide a force for moving the locking plate 302 in a direction close to the bracket 2, the force providing component including:

the first telescopic rod 304 is disposed inside the connecting frame 301, and one end of the first telescopic rod 304, which is close to the locking plate 302, is fixedly connected thereto.

The spring 305 is established on the surface of telescopic link one 304 in the cover, is provided with on the support 2 and absorbs subassembly 4, absorbs subassembly 4 and is used for utilizing vacuum negative pressure to absorb backlight unit component, and drive assembly 1 is used for driving support 2 motion to drive and absorb subassembly 4 motion, absorb subassembly 4 and include:

the bottom plate 401 is fixedly connected to the bracket 2, a through hole 402 is formed in the bottom plate 401, and the through hole 402 is arranged to provide a space for the transverse movement of the vacuum chuck 403.

A vacuum chuck 403 is disposed inside the through opening 402.

The component of bleeding, set up on bottom plate 401, the component of bleeding is sealed to be linked together with vacuum chuck 403, and the component of bleeding is used for extracting the air in the vacuum chuck 403, and the component of bleeding includes:

the aspiration pump 404 is arranged above the bottom plate 401, and the bottom of the aspiration pump 404 is hermetically communicated with the central shell 406 through the aspiration tube 405, the central shell 406 is fixedly connected to the top of the bottom plate 401, the bottom of the aspiration pump 404 is fixedly connected with a cushion block, and the cushion block is fixedly connected to the top of the central shell 406.

The telescopic pipe 407 is fixedly communicated on the center shell 406, one side, far away from the center shell 406, of the telescopic pipe 407 is in sealing communication with the vacuum chuck 403, two ends of the telescopic pipe 407 are hard pipelines, one end of the telescopic pipe is in sealing communication with the air suction pump 404, the other end of the telescopic pipe is in sealing communication with the vacuum chuck 403, the middle part of the telescopic pipe 407 is a soft pipeline, and the telescopic pipe 407 arranged in this way can meet the transverse movement of the vacuum chuck 403.

An adjusting component, disposed in the opening 402, for adjusting the position of the vacuum chuck 403, the adjusting component comprising:

the rotation fixing piece 408 is fixedly arranged in the through hole 402, a threaded rod 409 is arranged on the rotation fixing piece 408, the rotation fixing piece 408 is specifically a bearing, the surface of the outer ring of the bearing is fixedly connected with the bottom plate 401, and the inner wall of the inner ring of the bearing is fixedly connected with the surface of the threaded rod 409.

The adjusting plate 410 is in threaded connection with the surface of the threaded rod 409, and one side of the adjusting plate 410, which is close to the vacuum chuck 403, is fixedly connected with the adjusting plate.

The second telescopic rod 411 is fixedly connected to the adjusting plate 410, and one end of the second telescopic rod 411, which is far away from the adjusting plate 410, is fixedly connected to the inner wall of the through hole 402, the second telescopic rod 411 can be extended and shortened, and the two second telescopic rods 411 are arranged on the same adjusting plate 410 to limit the motion estimation of the adjusting plate 410, so that the second telescopic rod 411 limits the adjusting plate 410 to only move transversely left and right from the view point of fig. 1 and 3.

The rotating block 412 is fixedly connected to the threaded rod 409, and the rotating block 412 is arranged, so that the threaded rod 409 can be rotated conveniently by direct manual operation of a worker.

When the vacuum chuck is used, the linear motor 103 can drive the movable plates and 104 to move transversely, the suction assembly 4 can move, the hydraulic cylinder 105 can drive the suction assembly 4 to move linearly up and down through the locking assembly 3 and the support 2, the air in the vacuum chuck 403 is sucked by the air suction pump 404 through the telescopic tube 407, the vacuum chuck 403 is attached to the backlight module element, the backlight module element can be adsorbed, feeding work can be carried out, when maintenance or repair is required for the suction assembly 4, a worker can enable the two locking plates 302 to move towards directions close to each other, the telescopic rod I304 and the spring 305 can be compressed, the locking plates 302 drive the locking rods 303 to separate from the support 2, the support 2 can be separated from the connecting frame 301, so that the disassembly of the suction assembly 4 is completed, when other backlight module elements are required to be adapted, the worker can rotate the threaded rod 409 through the rotating block 412, the threaded rod 409 can enable the adjusting plate 410 to move, the adjusting plate 410 can drive the vacuum chuck 403 to move, the telescopic rod II 411 can be compressed, and the position of the vacuum chuck 403 can be adjusted.

Although embodiments of the present utility model have been shown and described, it will be understood by those skilled in the art that various changes, modifications, substitutions and alterations can be made therein without departing from the principles and spirit of the utility model, the scope of which is defined in the appended claims and their equivalents.

Claims (8)

1. The utility model provides a shake feed mechanism prevents of backlight, includes drive assembly (1), its characterized in that: the novel vacuum suction device is characterized in that a support (2) is arranged on the driving assembly (1), a locking assembly (3) is arranged on the support (2), the locking assembly (3) is used for locking the positions of the driving assembly (1) and the support (2), a suction assembly (4) is arranged on the support (2), the suction assembly (4) is used for sucking a backlight module component by utilizing vacuum negative pressure, and the driving assembly (1) is used for driving the support (2) to move so as to drive the suction assembly (4) to move.

2. The anti-shake feeding mechanism of a backlight machine according to claim 1, wherein the driving assembly (1) comprises:

the connecting plate (101) is used for forming a base, and a mounting block (102) is fixedly arranged on the connecting plate (101);

the linear motor (103) is fixedly arranged at the bottom of the connecting plate (101);

a moving plate (104) fixedly mounted on a moving end of the linear motor (103);

and the hydraulic cylinder (105) is fixedly connected to the moving plate (104).

3. The anti-shake feeding mechanism of a backlight machine according to claim 2, wherein the locking assembly (3) comprises:

the connecting frame (301) is fixedly connected to an output shaft at the bottom of the hydraulic cylinder (105);

a locking plate (302) provided inside the connection frame (301);

the locking rod (303) is fixedly connected to the locking plate (302), and one end, far away from the locking plate (302), of the locking rod (303) is movably spliced on the bracket (2);

and the acting force providing component is arranged inside the connecting frame (301) and is used for providing acting force for moving the locking plate (302) in the direction close to the bracket (2).

4. A backlight anti-shake loading mechanism according to claim 3, wherein said force providing component comprises:

the first telescopic rod (304) is arranged in the connecting frame (301), and one end of the first telescopic rod (304) close to the locking plate (302) is fixedly connected with the first telescopic rod;

and the spring (305) is sleeved on the surface of the first telescopic rod (304).

5. The anti-shake feeding mechanism of a backlight machine according to claim 4, wherein the suction assembly (4) comprises:

the bottom plate (401) is fixedly connected to the bracket (2), and a through hole (402) is formed in the bottom plate (401);

a vacuum chuck (403) provided inside the through hole (402);

the air extraction component is arranged on the bottom plate (401) and is communicated with the vacuum chuck (403) in a sealing way, and the air extraction component is used for extracting air in the vacuum chuck (403);

and the adjusting component is arranged in the through hole (402) and is used for adjusting the position of the vacuum chuck (403).

6. The anti-shake feeding mechanism of a backlight according to claim 5, wherein the air extraction component comprises:

the air pump (404) is arranged above the bottom plate (401), the bottom of the air pump (404) is communicated with the central shell (406) in a sealing way through the air exhaust pipe (405), and the central shell (406) is fixedly connected to the top of the bottom plate (401);

and the telescopic pipe (407) is fixedly communicated with the center shell (406), and one side of the telescopic pipe (407) away from the center shell (406) is communicated with the vacuum chuck (403) in a sealing way.

7. The anti-shake feeding mechanism of a backlight according to claim 6, wherein the adjusting component comprises:

a rotation fixing piece (408) fixedly arranged in the through hole (402), and a threaded rod (409) is arranged on the rotation fixing piece (408);

the adjusting plate (410) is in threaded connection with the surface of the threaded rod (409), and one side, close to the vacuum chuck (403), of the adjusting plate (410) is fixedly connected with the adjusting plate;

the second telescopic rod (411) is fixedly connected to the adjusting plate (410), and one end, far away from the adjusting plate (410), of the second telescopic rod (411) is fixedly connected with the inner wall of the through hole (402);

and the rotating block (412) is fixedly connected to the threaded rod (409).

8. The anti-shake feeding mechanism of a backlight machine according to claim 7, wherein: the rotation fixing piece (408) is specifically a bearing, the surface of the outer ring of the bearing is fixedly connected with the bottom plate (401), and the inner wall of the inner ring of the bearing is fixedly connected with the surface of the threaded rod (409).