CN209851584U - Vacuum full-laminating mechanism for cavity without bearing film - Google Patents

Abstract

The utility model relates to the technical field of glass bearing-film-free vacuum full lamination, and discloses a bearing-film-free cavity vacuum full lamination mechanism, which is characterized by comprising an upper cavity for placing glass, an upper cavity turnover mechanism for driving the upper cavity to overturn, a lower cavity, a silica gel vacuum film suction mechanism formed in the lower cavity, a vacuum film supporting mechanism arranged in the lower cavity and used for fixing the silica gel vacuum film suction mechanism, a jacking and stretching lamination mechanism used for upwards extruding the silica gel vacuum film suction mechanism, and a cavity closing limiting mechanism used for locking and fixing the upper cavity and the lower cavity; like this, treat that the glass of laminating diaphragm places in last cavity after, the diaphragm is held in silica gel vacuum film suction mechanism evacuation, and the laminating face of the glass of treating the laminating diaphragm is just to the diaphragm that silica gel vacuum film suction mechanism absorbs, then the laminating mechanism is stretched in the top and upwards extrudees silica gel vacuum film suction mechanism for the diaphragm is laminated with the glass of treating the laminating diaphragm, has realized not having the laminating of carrier film vacuum full, and the laminating is with low costs, and laminating quality is good.

Description

Vacuum full-laminating mechanism for cavity without bearing film

Technical Field

The utility model belongs to the technical field of the technique of glass no carrier film vacuum laminating entirely and specifically relates to no carrier film cavity vacuum laminating mechanism entirely.

Background

Along with the development of science and technology and the improvement of living standard of people, electronic equipment becomes necessary articles for daily life of people gradually, and electronic equipment basically has a shell and a display screen, and along with the development of technology and the pursuit of users for beauty, more and more back shells of electronic equipment are made of glass materials at present.

And the shell of glass material is easy to be broken or scratched because of dropping, and the user experience is seriously influenced, so that a plurality of people can select a layer of explosion-proof film or protective film to be attached to the surface of the glass shell to play a role in protecting the glass shell.

In the prior art, the laminating equipment for laminating glass and membranes needs to use the bearing films to realize the lamination of the glass and the membranes, when the demand for laminating the glass shell is large, the number of the bearing films is very large, each bearing film needs certain cost, and the cost of the bearing films is very high.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide a do not have carrier film cavity vacuum mechanism of laminating entirely, need use the carrier film to lead to problem with high costs when aiming at solving among the prior art glass shell and carrying out the pad pasting.

The utility model discloses a realize like this, do not have full laminating mechanism in carrier film cavity vacuum, including last cavity, the drive that is used for placing glass go up cavity tilting mechanism, lower cavity that the cavity carries out the upset, be formed at the silica gel vacuum in the cavity of resorption inhales membrane mechanism, sets up just be used for fixing in the cavity of resorption the vacuum of silica gel vacuum inhales membrane mechanism holds in the palm membrane mechanism, is used for upwards extruding the laminating mechanism is stretched and is used for locking to the top of silica gel vacuum inhales membrane mechanism and fixes go up the cavity with the chamber stop gear that closes of cavity down.

Furthermore, the upper cavity turnover mechanism comprises a servo motor and a rotating platform in transmission connection with the servo motor, and the rotating platform is fixedly connected with the upper cavity.

Further, the upper cavity is formed with a placing groove for placing glass and a glass clamp for clamping and fixing the glass placed in the placing groove.

Furthermore, the vacuum film supporting mechanism comprises two clamping members which are respectively used for clamping and fixing two sides of the silica gel vacuum film absorbing mechanism and two first air cylinders which are respectively connected with the clamping members, and the first air cylinders drive the clamping members connected with the first air cylinders to move horizontally.

Further, close chamber stop gear including form the embedding piece of last cavity external surface and form the spacing groove of cavity external surface down, the embedding piece can imbed or break away from the spacing groove, the embedding piece with the lateral wall of spacing groove is provided with the jack of just arranging each other respectively, but the inserted block of horizontal displacement is worn to be equipped with in the jack activity, the inserted block is connected with and is used for driving the power component of inserted block horizontal displacement.

Further, the jacking and laminating mechanism comprises a second cylinder, and the second cylinder comprises a longitudinally telescopic piston.

Further, but no carrier film cavity vacuum full laminating mechanism is including horizontal displacement's vision positioning mechanism, vision counterpoint mechanism is used for shooing the counterpoint to glass and the pad pasting of treating laminating on glass simultaneously.

Furthermore, the vision positioning mechanism comprises a CCD camera and a servo linear module which drives the CCD camera to move horizontally.

Further, the vacuum full-lamination mechanism of the cavity without the carrier film comprises a UVW platform alignment mechanism capable of horizontally moving, and the UVW platform alignment mechanism is fixedly connected with the silica gel vacuum film suction mechanism.

Compared with the prior art, the vacuum full-laminating mechanism without the bearing film cavity provided by the utility model has the advantages that the vacuum full-laminating mechanism without the bearing film cavity is provided with the upper cavity for placing glass, the upper cavity turnover mechanism for driving the upper cavity to overturn, the lower cavity, the silica gel vacuum film absorbing mechanism formed in the lower cavity, the vacuum film supporting mechanism arranged in the lower cavity and used for fixing the silica gel vacuum film absorbing mechanism, the jacking laminating mechanism used for upwards extruding the silica gel vacuum film absorbing mechanism and the cavity closing limiting mechanism used for locking and fixing the upper cavity and the lower cavity; like this, drive through last cavity tilting mechanism and go up the cavity and overturn, the operator of being convenient for will wait that the glass of laminating diaphragm is placed in last cavity, wait that the glass of laminating diaphragm is placed in last cavity back, the diaphragm is inhaled in silica gel vacuum film suction mechanism evacuation, vacuum film support mechanism holds in the palm the flat and fixed with silica gel vacuum film suction mechanism, cavity overturns once more in last cavity tilting mechanism drive, make the pad pasting face of the glass of waiting to laminate the diaphragm just to the diaphragm that silica gel vacuum film suction mechanism absorbs, then the laminating mechanism upwards extrudees silica gel vacuum film suction mechanism stretches in the top, make the diaphragm laminate with the glass of waiting to laminate the diaphragm, realized not having the vacuum of carrier film and laminated entirely, the laminating cost is low, the laminating is of high quality.

Drawings

Fig. 1 is a schematic structural view of a vacuum full-lamination mechanism without a carrier film cavity provided in an embodiment of the present invention.

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention more clearly understood, the present invention is further described in 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.

The same or similar reference numerals in the drawings of the present embodiment correspond to the same or similar components; in the description of the present invention, it should be understood that if there are the terms "upper", "lower", "left", "right", etc. indicating the orientation or positional relationship based on the orientation or positional relationship shown in the drawings, it is only for convenience of description and simplification of the description, but it is not intended to indicate or imply that the device or element referred to must have a specific orientation, be constructed in a specific orientation, and be operated, and therefore the terms describing the positional relationship in the drawings are only for illustrative purposes and are not to be construed as limitations of the present patent, and those skilled in the art can understand the specific meanings of the terms according to specific situations.

The following describes the implementation of the present invention in detail with reference to specific embodiments.

Referring to fig. 1, a preferred embodiment of the present invention is provided.

The bearing-film-free cavity vacuum full-laminating mechanism comprises an upper cavity 100 for placing glass, an upper cavity turnover mechanism 200 for driving the upper cavity 100 to overturn, a lower cavity 300, a silica gel vacuum film sucking mechanism 400 formed in the lower cavity 300, a vacuum film supporting mechanism 500 arranged in the lower cavity 300 and used for fixing the silica gel vacuum film sucking mechanism 400, a jacking and stretching laminating mechanism 600 for upwards extruding the silica gel vacuum film sucking mechanism 400 and a cavity closing limiting mechanism for locking and fixing the upper cavity 100 and the lower cavity 300.

The cavity vacuum full-lamination mechanism without the bearing film is provided with an upper cavity 100 for placing glass, an upper cavity turnover mechanism 200 for driving the upper cavity 100 to overturn, a lower cavity 300, a silica gel vacuum film suction mechanism 400 formed in the lower cavity 300, a vacuum film supporting mechanism 500 arranged in the lower cavity 300 and used for fixing the silica gel vacuum film suction mechanism 400, a jacking lamination mechanism 600 for upwards extruding the silica gel vacuum film suction mechanism 400 and a cavity closing limiting mechanism for locking and fixing the upper cavity 100 and the lower cavity 300; like this, cavity 100 overturns in the drive through last cavity tilting mechanism 200, the operator of being convenient for will wait to laminate the glass of diaphragm and place in last cavity 100, wait that the glass of laminating diaphragm places in last cavity 100 after, the diaphragm is inhaled in the silica gel vacuum and the diaphragm is inhaled to membrane mechanism 400 evacuation, vacuum is held in the palm membrane mechanism 500 and is inhaled membrane mechanism 400 with the silica gel vacuum and hold in the palm the tie and fix, cavity 100 overturns once more in last cavity tilting mechanism 200 drive, make the laminating face of the glass of waiting to laminate the diaphragm just to the diaphragm that membrane mechanism 400 absorbs is inhaled in the silica gel vacuum, then the laminating mechanism 600 is stretched in the top and upwards extrudees the silica gel vacuum and inhale membrane mechanism 400, make the diaphragm laminate with the glass of waiting to laminate the diaphragm, no carrier film vacuum full lamination has been realized, the laminating.

Specifically, the upper cavity turnover mechanism 200 includes a servo motor 210 and a rotary platform 220 in transmission connection with the servo motor 210, and the rotary platform 220 is fixedly connected with the upper cavity 100; the servo motor 210 drives the rotary platform 220 to rotate, and the rotary platform 220 is fixedly connected with the upper cavity 100, so that the rotation of the rotary platform 220 drives the upper cavity 100 to turn over; the servo motor 210 can control the rotation speed and can precisely control the rotation position.

In this embodiment, the upper chamber 100 is formed with a placement groove for placing glass and a glass clamp for clamping and fixing glass placed in the placement groove; glass anchor clamps are with glass accurate location and fixed, and glass anchor clamps adopt the profile modeling design to having adopted the transparent ya keli of import, having guaranteed hundred printing opacity, being favorable to letting the more accurate shoot of camera get the number, thereby having guaranteed the high yield of glass full lamination, stretching the laminating in-process at the top and letting glass have more holding surfaces, have the production of bubble, light halo, water mark, crackle, frictioning, fold when avoiding glass full lamination, thereby have higher laminating yield.

In this embodiment, the vacuum film supporting mechanism 500 includes two clamping members 510 for clamping and fixing two sides of the silicone vacuum film sucking mechanism 400, and two first air cylinders 520 connected to the clamping members 510, respectively, and the first air cylinders 520 drive the clamping members 510 connected thereto to move horizontally.

The cavity closing limiting mechanism comprises an embedded part 710 formed on the outer surface of the upper cavity 100 and a limiting groove 720 formed on the outer surface of the lower cavity 300, the embedded part 710 can be embedded into or separated from the limiting groove 720, the side walls of the embedded part 710 and the limiting groove 720 are respectively provided with jacks which are arranged oppositely, the jacks are movably penetrated with an insertion block 730 capable of horizontally displacing, and the insertion block 730 is connected with a power element for driving the insertion block 730 to horizontally displace; when glass is just to the diaphragm that silica gel vacuum suction structure absorbs, when also being the cavity 300 finished closing with last cavity 100, imbed spacing groove 720 through embedding part 710, power component drive inserted block 730 inserts the jack, it is fixed with the locking of cavity 300 down to realize, cavity 300 can not be opened by the top about guaranteeing to stretch under the powerful pressure that laminating mechanism 600 carries out the top when stretching like this, the requirement of power when having satisfied glass and diaphragm laminating has simultaneously, and then guaranteed the laminating requirement of diaphragm and glass, including requirements such as pulling force, there is the bubble when the diaphragm avoids glass to laminate completely, the light halo ring, the water wave, the crackle, the frictioning, the production of fold, thereby there is higher laminating yield.

Further, the jacking attaching mechanism 600 includes a second cylinder, and the second cylinder includes a longitudinally telescopic piston; the second cylinder has guaranteed that glass and diaphragm laminating time is sufficient extrusion pressure, lets the deformation volume of silica gel just discharge the bubble, and the drawing force also can reach the requirement simultaneously, has the production of bubble, light halo, water wave, crackle, frictioning, fold when avoiding glass to laminate completely.

In the embodiment, the vacuum full-lamination mechanism without the bearing film cavity comprises a visual positioning mechanism capable of horizontally moving, and the visual alignment mechanism is used for simultaneously photographing and aligning glass and a film to be laminated on the glass; the visual positioning mechanism is used for photographing and positioning the glass and the diaphragm to determine whether the positions of the glass and the diaphragm are accurate and right, so that the deviation rectification processing is facilitated.

Specifically, the visual positioning mechanism comprises a CCD camera and a servo linear module for driving the CCD camera to move horizontally; the CCD camera has the advantages of high sensitivity, strong light resistance, small distortion and the like, so that the visual positioning result is more accurate, the servo linear module can drive the CCD camera to move horizontally, the CCD camera is convenient to perform visual photographing positioning, and after the positioning is finished, the servo linear module drives the CCD camera to move away.

Furthermore, the vacuum full-lamination mechanism of the cavity without the carrier film comprises a UVW platform alignment mechanism capable of horizontally moving, and the UVW platform alignment mechanism is fixedly connected with the silica gel vacuum film suction mechanism 400; like this, when vision counterpoint mechanism detects that diaphragm and glass do not have accurate counterpoint, UVW platform counterpoint mechanism's horizontal migration drives the silica gel vacuum and inhales the horizontal motion of membrane mechanism 400, and then drives the horizontal motion of diaphragm for diaphragm and glass realize accurate counterpoint, improve the laminating quality of glass and diaphragm.

The above description is only exemplary of the present invention and should not be taken as limiting the scope of the present invention, as any modifications, equivalents, improvements and the like made within the spirit and principles of the present invention are intended to be included within the scope of the present invention.

Claims (9)

1. There is not bear membrane cavity vacuum laminating mechanism entirely, its characterized in that, including last cavity, the drive that is used for placing glass go up cavity and carry out last cavity tilting mechanism, lower cavity that overturn, form in the silica gel vacuum that goes up the cavity is inhaled membrane mechanism, setting in the cavity is in just be used for fixing down the cavity is inhaled in the silica gel vacuum that membrane mechanism was held in the palm in the vacuum, is used for upwards the extrusion the top that membrane mechanism was inhaled in the silica gel vacuum is stretched laminating mechanism and is used for locking fixed go up the cavity with the chamber stop gear that closes of cavity down.

2. The carrier-film-free cavity vacuum full-lamination mechanism of claim 1, wherein the upper cavity turnover mechanism comprises a servo motor and a rotary platform in transmission connection with the servo motor, and the rotary platform is fixedly connected with the upper cavity.

3. The carrier-film-free chamber vacuum full-lamination mechanism according to claim 1, wherein the upper chamber is formed with a placing groove for placing glass and a glass clamp for clamping and fixing the glass placed in the placing groove.

4. The vacuum full-laminating mechanism for cavity without carrier film of claim 1, wherein the vacuum film supporting mechanism comprises two clamping members for clamping and fixing two sides of the silica gel vacuum film absorbing mechanism respectively, and two first air cylinders connected to the clamping members respectively, and the first air cylinders drive the clamping members connected thereto to move horizontally.

5. The vacuum full-laminating mechanism for the cavity without the carrier film according to claim 1, wherein the cavity-closing limiting mechanism comprises an embedded part formed on the outer surface of the upper cavity and a limiting groove formed on the outer surface of the lower cavity, the embedded part can be embedded into or separated from the limiting groove, the side walls of the embedded part and the limiting groove are respectively provided with jacks arranged oppositely, the jacks are movably penetrated with an insert block capable of horizontally displacing, and the insert block is connected with a power element for driving the insert block to horizontally displace.

6. The carrier-free film cavity vacuum full-lamination mechanism of any one of claims 1 to 5, wherein the top-extension lamination mechanism comprises a second cylinder, and the second cylinder comprises a longitudinally-extending piston.

7. The carrier-free film cavity vacuum full-lamination mechanism of any one of claims 1 to 5, wherein the carrier-free film cavity vacuum full-lamination mechanism comprises a horizontally displaceable visual positioning mechanism, and the visual alignment mechanism is used for simultaneously performing photo alignment on the glass and the film to be laminated on the glass.

8. The carrier-film-free chamber vacuum full-lamination mechanism of claim 7, wherein the visual positioning mechanism comprises a CCD camera and a servo linear module driving the CCD camera to move horizontally.

9. The carrier-free film chamber vacuum full lamination mechanism of any one of claims 1 to 5, wherein the carrier-free film chamber vacuum full lamination mechanism comprises a horizontally displaceable UVW platform alignment mechanism, and the UVW platform alignment mechanism is fixedly connected with the silica gel vacuum film suction mechanism.