CN113682593A - Semi-automatic assembly module equipment - Google Patents

Abstract

The invention discloses semi-automatic assembly module equipment which comprises a bottom plate, a pressure-bearing assembly arranged on the bottom plate, and two mounting seats arranged on the bottom plate; the film tearing assembly comprises a limiting baffle fixedly arranged on the rotating column, a bearing sleeve fixedly arranged on the limiting baffle, a guide column movably sleeved on the bearing sleeve, a pressing baffle fixed at the first end of the guide column and a vacuum adsorption plate fixed at the second end of the guide column; according to the semi-automatic assembly module equipment provided by the embodiment of the invention, under the condition that the vacuum adsorption plate is close to the pressure-bearing assembly, the downward pressing baffle pushes the vacuum adsorption plate to press the pressure-bearing assembly under the action of external force, and the vacuum adsorption plate realizes adsorption of a protective film placed on the pressure-bearing assembly; the efficient and effective stripping of the LCD protective film is realized on the premise of not damaging the LCD screen.

Description

Semi-automatic assembly module equipment

Technical Field

The embodiment of the invention relates to the field of LCD (liquid crystal display) screens, in particular to semi-automatic assembly module equipment.

Background

Tearing off screen surface protection film is a troublesome problem always, the LCD screen when dispatching from the factory and overhauing, need peel off the protection film on LCD surface, and current display screen size is great, leads to the dynamics of the unable control dyestripping of present full-automatic dyestripping equipment, tears the dynamics and leads to the fact destruction to the LCD screen too greatly easily, and tears the dynamics undersize, can't effectively peel off the protection film on LCD surface again, and adopts the method efficiency of pure artifical peeling off again than low.

Disclosure of Invention

In view of this, an object of the embodiments of the present invention is to provide a semi-automatic module assembling device, which solves the problems of poor film tearing effect and low efficiency of the existing device.

A semi-automatic assembly module equipment for vacuum dyestripping, includes: the bottom plate is arranged on the working platform; the pressure bearing assembly is arranged on the bottom plate; the two mounting seats are mounted on the bottom plate, and a rotating column is movably mounted between the two mounting seats; the film tearing assembly is arranged on the rotating column and overturns along with the rotation of the rotating column;

the tear film assembly includes: one end of the limiting baffle is fixedly arranged on the rotating column; the bearing sleeve is fixedly arranged on the limiting baffle and penetrates from one surface of the limiting baffle to the other surface; the guide post is movably sleeved in the bearing sleeve, and a first end and a second end of the guide post respectively extend out of the bearing sleeve; the pressing baffle is fixedly connected with the first end of the guide post; the vacuum adsorption plate is fixedly connected with the second end of the guide column:

under the condition that the vacuum adsorption plate and the pressure-bearing assembly are close to each other, the downward pressing baffle is used for pushing the guide column to move towards the pressure-bearing assembly under the action of external force, so that the vacuum adsorption plate further presses towards the pressure-bearing assembly, and the vacuum adsorption plate is used for adsorbing a protection film placed on the pressure-bearing assembly.

Preferably, a cavity is arranged in the vacuum adsorption plate, a plurality of air holes penetrating through the cavity are formed in one surface of the vacuum adsorption plate facing the pressure bearing assembly, and negative pressure is generated on the air holes by the vacuum adsorption plate under the condition that air in the cavity is sucked away.

Preferably, the bearing assembly comprises a moving platform mounted on the base plate, a rotating platform mounted on the moving platform, and a positioning platform located on the rotating platform.

Preferably, the rotating platform comprises a fixed seat mounted on the moving platform and a rotating disk movably mounted on the fixed seat, the rotating disk is fixedly connected with the positioning platform, one side of the rotating disk is connected with an angle adjusting ruler, and the angle adjusting ruler is used for adjusting the rotating angle of the rotating disk.

Preferably, the moving platform comprises a fixed block fixed on the bottom plate, a first sliding block movably mounted on the fixed block, and a second sliding block movably mounted on the first sliding block.

Preferably, the mobile platform further includes a first displacement adjusting ruler installed on one side of the first sliding block, and a second displacement adjusting ruler installed on one side of the second sliding block, the first displacement adjusting ruler is used for adjusting a moving position of the first sliding block in a first direction, the second displacement adjusting ruler is used for adjusting a moving position of the second sliding block in a second direction, and the first displacement adjusting ruler and the second displacement adjusting ruler are perpendicular to each other.

Preferably, the bottom plate is further provided with a positioning column, and the limit baffle abuts against the positioning column under the condition that the vacuum adsorption plate is buckled and pressed on the pressure bearing assembly.

Preferably, a limiting block is further installed on the bottom plate, a slope surface is formed on one end face, far away from the bottom plate, of the limiting block, the limiting block is used for limiting a preset angle between the limiting baffle and the pressure bearing assembly, and when the angle between the limiting baffle and the pressure bearing assembly is the preset angle, the limiting baffle abuts against the slope surface.

Preferably, right-angle openings are reserved around the limiting baffle and used for positioning and aligning the outer edge of the protective film with the outer edge line of the limiting baffle.

Preferably, the limiting baffle is further provided with an avoiding groove, a vacuum connector used for externally connecting an air pump is arranged in the avoiding groove, and the vacuum connector is fixed on the vacuum adsorption plate.

According to the semi-automatic assembly module equipment provided by the embodiment of the invention, the vacuum adsorption plate is driven to turn over by the pressing baffle under the action of external force, so that the vacuum adsorption plate carries out vacuum film tearing on the protective film placed on the pressure-bearing assembly; on the premise of not damaging the LCD screen, the LCD protective film can be quickly and effectively peeled off.

Drawings

Fig. 1 is a schematic structural diagram of a semi-automatic assembly module apparatus in a first direction in an open state according to a first embodiment of the present invention;

fig. 2 is a schematic structural diagram of a semi-automatic assembly module apparatus in a second direction in an open state according to a first embodiment of the present invention;

fig. 3 is a schematic structural diagram of a semi-automatic assembly module apparatus in a first direction in a fastening state according to a first embodiment of the present invention;

fig. 4 is a schematic structural view of a semi-automatic assembly module apparatus in a second direction in a fastened state according to a first embodiment of the present invention;

fig. 5 is a schematic structural view of a limit baffle according to a first embodiment of the invention;

FIG. 6 is a schematic diagram illustrating a first orientation of a rotary platform according to a first embodiment of the present invention;

FIG. 7 is a structural diagram of a rotating platform according to a second aspect of the first embodiment of the present invention;

fig. 8 is a schematic structural diagram of a mobile platform according to a first embodiment of the present invention.

The list of elements is as follows:

a base plate 1;

a pressure-bearing assembly 2;

a mounting base 3;

a film tearing component 4;

a rotating post 5;

a positioning column 6;

a limiting block 7;

a mobile platform 21;

a rotary platform 22;

a positioning platform 23;

a limit baffle 41;

the bearing housing 42;

a guide post 43;

pressing down the shutter 44;

a vacuum adsorption plate 45;

a ramp surface 71;

a fixed block 211;

a first slider 212;

a second slider 213;

a first displacement adjusting ruler 214;

a second displacement adjusting ruler 215;

a connecting plate 216;

pin 217

A fixed base 221;

a rotating disk 222;

an angle adjusting ruler 223;

a mounting hole 411;

a right angle opening 412;

an avoidance slot 413;

a vacuum connection 414;

air holes 451;

the ribs 2221;

a connecting seat 2231;

a differential head 2232;

locking screws 2233.

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention more apparent, the present invention is described in further detail below with reference to the accompanying drawings and embodiments. It should be understood that the specific embodiments described herein are merely illustrative of the invention and are not intended to limit the invention. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

The first embodiment is as follows:

as shown in fig. 1, the present embodiment discloses a semi-automatic assembly module device, including: the film tearing device comprises a bottom plate 1, a pressure bearing assembly 2, a mounting seat 3 and a film tearing assembly 4;

the bottom plate 1 is arranged on the working platform; the pressure bearing assembly 2 is arranged on the bottom plate 1; two mounting seats 3 are arranged on the bottom plate 1, and a rotating column 5 is movably mounted between the two mounting seats 3; the film tearing assembly 4 is arranged on the rotating column 5, and the film tearing assembly 4 can turn over along with the rotation of the rotating column; overturn tear behind the membrane module 4, make tear membrane module 4 and tear the membrane operation to the protection film on the pressure-bearing subassembly 2, accomplish and tear the membrane after, through the upset in the opposite direction tear membrane module 4, will tear the LCD FOG board of protection film and remove away from, realized semi-automatic tear membrane through above-mentioned mode.

As shown in fig. 2, the film tearing assembly 4 includes a limiting baffle 41 installed on the rotating column 5, a bearing sleeve 42 fixedly installed on the limiting baffle 41, a guide column 43 movably sleeved on the bearing sleeve 42, and a pressing baffle 44 fixed at a first end of the guide column 43 and a vacuum adsorption plate 45 fixed at a second end of the guide column 43.

Under the condition that the vacuum adsorption plate 45 is close to the pressure-bearing assembly 2, the lower pressure baffle 44 is used for pushing the guide column 43 to move towards the pressure-bearing assembly 2 under the action of external force, so that the vacuum adsorption plate 45 further presses towards the pressure-bearing assembly 2, and the vacuum adsorption plate 45 is used for adsorbing a protective film placed on the pressure-bearing assembly 2.

Preferably, as shown in fig. 5, four mounting holes 411 are formed in the limiting baffle 41, four bearing sleeves 42 are respectively mounted on the four mounting holes 411, the bearing sleeves 42 are preferably linear bearing sleeves, a plurality of rows of balls (not shown) are disposed on an inner side wall of each linear bearing sleeve, so that the guide posts 43 are nested on the bearing sleeves 42, the guide posts 43 can slide back and forth on the bearing sleeves 42, the downward pressing baffle 44 is located above the limiting baffle 41, the vacuum absorbing plate 45 is located below the limiting baffle 41, and the vacuum absorbing plate 45 is disposed on the pressure-bearing assembly 2 by manually turning over the film tearing assembly 4.

Preferably, as shown in fig. 1, a cavity (not shown) is formed in the vacuum adsorption plate 45, and a plurality of air holes 451 penetrating through the cavity are formed in a surface of the vacuum adsorption plate 45 facing the pressure bearing assembly 2, and the vacuum adsorption plate 45 generates negative pressure to the plurality of air holes 451 when air in the cavity is sucked away; specifically, the air holes 451 of the present embodiment are vacuum holes with a diameter of 1mm and are arranged in a grid shape, and the suction force of the vacuum holes to the LCD or FOG protective film reaches 0.04 Mpa; the design of the grid shape ensures that the vacuum holes can ensure the suction force when completely covering the LCD protective film.

Preferably, as shown in fig. 2, the pressure-bearing assembly 2 includes a moving platform 21 mounted on the base plate 1, a rotating platform 22 mounted on the moving platform 21, and a positioning platform 23 located on the rotating platform 22; the moving platform 21 is an optical platform of LY60-RM, the optical platform can be used for fine adjustment of the position of the pressure-bearing assembly 2 on the XY axes, and the stroke range of the optical platform is +/-6.5 mm.

Preferably, as shown in fig. 6 to 7, the rotating platform 22 includes a fixed seat 221 mounted on the moving platform 21 and a rotating disk 222 movably mounted on the fixed seat 221, the rotating disk 222 is fixedly connected to the positioning platform 23, one side of the rotating disk 222 is connected to an angle adjusting ruler 223, the angle adjusting ruler 223 is used for adjusting the rotation angle of the rotating disk 222, specifically, the fine-tuning rotating platform 22 of FR13-85 is preferred in this embodiment, the adjusted angle resolution is 0.1 °, and the adjusted stroke is ± 5 °; specifically, the rotating disc 222 is provided with a protruding strip 2221 protruding to one side, and the angle adjusting ruler 223 includes a connecting seat 2231, a differential head 2232 and a locking screw 2233, wherein the locking screw 2233 is installed on one side of the connecting seat 2231, and the differential head 2232 is movably installed on the other side of the connecting seat 2231; the locking screw 2233 is disposed opposite to the differential head 2232, the protruding strip 2221 is disposed between the locking screw 2233 and the differential head 2232, and the protruding strip 2221 is attached to the differential head 2232, so that the protruding strip 2221 drives the rotating disc 222 to rotate by rotating the differential head 2232.

Preferably, as shown in fig. 8, the moving platform 21 includes a fixed block 211 fixed on the bottom plate 1, a first sliding block 212 movably mounted on the fixed block 211, and a second sliding block 213 movably mounted on the first sliding block 212.

Preferably, the movable platform 21 further includes a first displacement adjusting ruler 214 installed on one side of the first sliding block 212, and a second displacement adjusting ruler 215 installed on one side of the second sliding block 213, the moving position of the first sliding block 212 in the first direction is adjusted by rotating the first displacement adjusting ruler 214, the moving position of the second sliding block 213 in the second direction is adjusted by rotating the second displacement adjusting ruler 215, the first displacement adjusting ruler 214 and the second displacement adjusting ruler 215 are perpendicular to each other, and the position adjusting means of the movable platform 21 belongs to the prior art, and is not described herein again; the moving platform 21 further comprises a connecting plate 216 mounted on the second sliding block, a pin 217 for inserting and matching with the rotating platform 22 is further arranged on the connecting plate 216, and the moving platform 21 and the rotating platform 22 are mounted together through the pin 217.

Preferably, as shown in fig. 1, a positioning column 6 is further installed on the bottom plate 1, and the limiting baffle 41 abuts against the positioning column 6 when the vacuum absorption plate 45 is buckled and pressed on the pressure-bearing assembly 2; the positioning column 6 is used as a mechanical limit structure in the first direction of the semi-automatic assembly module equipment and is used for preventing the vacuum adsorption plate 45 from damaging the LCD/FOG plate when being buckled downwards.

As a preferable scheme, as shown in fig. 3, a limiting block 7 is further installed on the bottom plate 1, an upper end surface of the limiting block 7 is provided with a slope surface 71, the limiting block 7 is used for limiting a maximum opening and closing angle (i.e. a preset angle) between the limiting baffle 41 and the pressure-bearing assembly 2, when the angle between the limiting baffle 41 and the pressure-bearing assembly 2 is the maximum opening and closing angle, the limiting baffle 41 abuts against the slope surface 71, specifically, after the downward pressing baffle 44 finishes tearing the film, the film tearing assembly 4 is turned over, the film tearing assembly 4 abuts against the slope surface 71, and then the LCD/FOG plate is taken out from the positioning platform 23.

Preferably, as shown in fig. 5, right-angle openings 412 are formed around the position-limiting baffle 41, and the purpose of the right-angle openings 412 is to facilitate positioning and aligning the outer edge of the protective film of the LCD/FOG panel with the outer edge of the position-limiting baffle 41.

As a preferred scheme, as shown in fig. 4-5, the spacing baffle 41 is provided with an avoiding groove 413, a vacuum joint 414 for an external air pump is provided in the avoiding groove 413, the vacuum joint 414 is fixed on the vacuum adsorption plate 45 and is communicated with the plurality of air holes 451, after the external air pump is connected on the vacuum joint 414, the air pump is opened, negative pressure is generated at the bottom of the vacuum adsorption plate 45, so that the protective film on the LCD/FOG can be adsorbed, and after the adsorption is completed, the film tearing assembly 4 is turned and torn along the direction away from the pressure-bearing assembly 2, so that the film tearing operation can be completed.

The above-mentioned serial numbers of the embodiments of the present invention are merely for description and do not represent the merits of the embodiments.

The above description is only a preferred embodiment of the present invention, and not intended to limit the scope of the present invention, and all modifications of equivalent structures and equivalent processes, which are made by using the contents of the present specification and the accompanying drawings, or directly or indirectly applied to other related technical fields, are included in the scope of the present invention.

Claims (10)

1. The utility model provides a semi-automatic equipment module equipment for vacuum dyestripping, its characterized in that includes:

the bottom plate is arranged on the working platform;

the pressure bearing assembly is arranged on the bottom plate;

the two mounting seats are mounted on the bottom plate, and a rotating column is movably mounted between the two mounting seats;

the film tearing assembly is arranged on the rotating column and overturns along with the rotation of the rotating column;

wherein, tear film assembly includes:

one end of the limiting baffle is fixedly arranged on the rotating column;

the bearing sleeve is fixedly arranged on the limiting baffle and penetrates from one surface of the limiting baffle to the other surface;

the guide post is movably sleeved in the bearing sleeve, and a first end and a second end of the guide post respectively extend out of the bearing sleeve;

the pressing baffle is fixedly connected with the first end of the guide post;

the vacuum adsorption plate is fixedly connected with the second end of the guide column;

under the condition that the vacuum adsorption plate and the pressure-bearing assembly are close to each other, the downward pressing baffle is used for pushing the guide column to move towards the pressure-bearing assembly under the action of external force, so that the vacuum adsorption plate further presses towards the pressure-bearing assembly, and the vacuum adsorption plate is used for adsorbing a protection film placed on the pressure-bearing assembly.

2. The apparatus of claim 1, wherein a cavity is formed in the vacuum suction plate, a plurality of air holes penetrating through the cavity are formed in a surface of the vacuum suction plate facing the pressure bearing assembly, and the vacuum suction plate generates negative pressure to the plurality of air holes when air in the cavity is sucked away.

3. The semi-automatic assembly die set apparatus of claim 1, wherein the bearing assembly comprises a moving platform mounted on the base plate, a rotating platform mounted on the moving platform, and a positioning platform located on the rotating platform.

4. The semi-automatic assembly die set equipment according to claim 3, wherein the rotating platform comprises a fixed seat mounted on the moving platform and a rotating disk movably mounted on the fixed seat, the rotating disk is fixedly connected with the positioning platform, and an angle adjusting ruler is connected to one side of the rotating disk and used for adjusting the rotating angle of the rotating disk.

5. The semi-automatic assembly die set equipment of claim 3, wherein the moving platform comprises a fixed block fixed on the bottom plate, a first sliding block movably mounted on the fixed block, and a second sliding block movably mounted on the first sliding block.

6. The semi-automatic assembly die set equipment of claim 5, wherein the moving platform further comprises a first displacement adjusting ruler installed on one side of the first sliding block and a second displacement adjusting ruler installed on one side of the second sliding block, the first displacement adjusting ruler is used for adjusting the moving position of the first sliding block in a first direction, the second displacement adjusting ruler is used for adjusting the moving position of the second sliding block in a second direction, and the first displacement adjusting ruler and the second displacement adjusting ruler are perpendicular to each other.

7. The semi-automatic assembly module equipment of claim 1, wherein the bottom plate is further provided with a positioning column, and the limit baffle abuts against the positioning column under the condition that the vacuum adsorption plate is buckled on the pressure bearing assembly.

8. The semi-automatic assembly module equipment according to claim 1, wherein a limiting block is further installed on the bottom plate, one end face, away from the bottom plate, of the limiting block is provided with a slope face, the limiting block is used for limiting a preset angle between the limiting baffle and the pressure bearing assembly, and when the angle between the limiting baffle and the pressure bearing assembly is the preset angle, the limiting baffle abuts against the slope face.

9. The semi-automatic assembly module assembly equipment of claim 1, wherein right-angle openings are reserved around the limit baffle and used for positioning and aligning the outer edge line of the protective film with the outer edge line of the limit baffle.

10. The semi-automatic assembly module equipment of claim 9, wherein the limit baffle is further provided with an avoiding groove, a vacuum joint for externally connecting an air pump is arranged in the avoiding groove, and the vacuum joint is fixed on the vacuum adsorption plate.

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