CN107139567B - Turning and conveying mechanism for curved glass vacuum inner laminating equipment - Google Patents
Turning and conveying mechanism for curved glass vacuum inner laminating equipment Download PDFInfo
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- CN107139567B CN107139567B CN201710496035.2A CN201710496035A CN107139567B CN 107139567 B CN107139567 B CN 107139567B CN 201710496035 A CN201710496035 A CN 201710496035A CN 107139567 B CN107139567 B CN 107139567B
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- B—PERFORMING OPERATIONS; TRANSPORTING
- B32—LAYERED PRODUCTS
- B32B—LAYERED PRODUCTS, i.e. PRODUCTS BUILT-UP OF STRATA OF FLAT OR NON-FLAT, e.g. CELLULAR OR HONEYCOMB, FORM
- B32B37/00—Methods or apparatus for laminating, e.g. by curing or by ultrasonic bonding
- B32B37/0046—Methods or apparatus for laminating, e.g. by curing or by ultrasonic bonding characterised by constructional aspects of the apparatus
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- B—PERFORMING OPERATIONS; TRANSPORTING
- B32—LAYERED PRODUCTS
- B32B—LAYERED PRODUCTS, i.e. PRODUCTS BUILT-UP OF STRATA OF FLAT OR NON-FLAT, e.g. CELLULAR OR HONEYCOMB, FORM
- B32B37/00—Methods or apparatus for laminating, e.g. by curing or by ultrasonic bonding
- B32B37/10—Methods or apparatus for laminating, e.g. by curing or by ultrasonic bonding characterised by the pressing technique, e.g. using action of vacuum or fluid pressure
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- Re-Forming, After-Treatment, Cutting And Transporting Of Glass Products (AREA)
- Joining Of Glass To Other Materials (AREA)
Abstract
The invention discloses a turning mechanism for curved glass vacuum inner laminating equipment, which is suitable for turning a first vacuum matching cavity for containing one of a curved glass separation layer and an inner film to a position opposite to or staggered with a second vacuum matching cavity for containing the other of the curved glass separation layer and the inner film, and comprises a turning frame body and a turning driver. The turnover frame body is pivoted on a rack of curved glass vacuum inner laminating equipment around a pivoting central line, the turnover frame body is turned over around the pivoting central line in a reciprocating mode relative to the rack, and the first vacuum matching cavity is installed on the turnover frame body; the turnover driver is installed in the rack and drives the turnover frame body to be turned over in a reciprocating mode, the turnover frame body turned over in a reciprocating mode drives the first vacuum matching cavity to be turned over to the position right opposite to or staggered with the second vacuum matching cavity, so that the curved glass or the inner film is placed on the first vacuum matching cavity, the view of the first vacuum matching cavity for operators can be effectively avoided in the placing process, and the placing operation is more convenient.
Description
Technical Field
The invention relates to the field of laminating an inner film on curved glass, in particular to a turning and conveying mechanism for curved glass vacuum inner laminating equipment.
Background
With the continuous development of economy and the continuous progress of society, extremely abundant material consumer products are provided for the life of people, and electronic products are one of numerous material consumer products.
With the popularization of electronic products such as smart phones, tablet computers and watches with touch screens, various manufacturers strive to provide differentiated products to attract the eyes of consumers. At present, a bright spot appears in the market, namely, the front cover and/or the rear cover of the electronic product are designed to be a curved surface, namely, the front cover and/or the rear cover are not flat surfaces any more, but have a 3D curved surface. The electronic product with the curved surface design can be better attached to the hand of a user, and the comfort level of holding and controlling is improved. If the front cover and/or the rear cover of the watch are designed to be curved surfaces, the watch can be better matched with the wrist, and the wearing comfort is improved. When the curved surface design is applied to display, the displayed content has more stereoscopic impression, thereby improving the impression effect.
Due to the texture of glass, glass is more popular as a front cover and/or a rear cover material of electronic products (such as smart phones, mobile phones, tablet computers and the like). And because glass is fragile, when glass is used as a front cover and/or a rear cover material of an electronic product, manufacturers can attach an inner film to the inner surface of the curved glass, and the advantages of the method are as follows: (1) The prevention rate of the curved glass attached with the inner film is better, and the prevention rate capability of the curved glass is enhanced; (2) Various patterns can be printed on the inner film, so that the aesthetic feeling is increased, and the will of manufacturers is expressed; (3) The inner film is used for shielding light, so that a user can not see electronic elements in the electronic product. Therefore, it is necessary to attach the inner film to the inner surface of the curved glass.
At present, in the laminating equipment for laminating the inner film on the inner surface of the curved glass, the laminating equipment comprises an upper vacuum matching cavity for containing the curved glass, a lower vacuum matching cavity for containing the inner film and vertically opposite to the upper vacuum matching cavity, and a lifting mechanism for driving the upper vacuum matching cavity and the lower vacuum matching cavity to be matched in an opening and closing manner, wherein an inlet of the upper vacuum matching cavity is arranged downwards, an inlet of the lower vacuum matching cavity is arranged upwards, and the upper vacuum matching cavity is closed relative to the lower vacuum matching cavity in the laminating process so as to realize the lamination of the inner film on the curved glass. Just because the upper vacuum matching cavity is opposite to the lower vacuum matching cavity in the vertical direction, and the upper vacuum matching cavity can only be in open-close matching relative to the lower vacuum matching cavity, the curved glass is inconvenient to operate on the upper vacuum matching cavity due to the fact that the upper vacuum matching cavity blocks the visual field of an operator in the process of placing the curved glass in the upper vacuum matching cavity, and whether the curved glass is placed is judged by the touch of both hands; in order to know the loading condition of the curved glass in the upper vacuum matching cavity, an operator can observe the curved glass only by squatting down and looking up at the upper vacuum matching cavity, so that the operation is further inconvenient; meanwhile, in the process of loading the curved glass in the upper vacuum matching cavity, the curved glass is easy to fall off from the upper vacuum matching cavity under the action of the curved glass, so that the upper vacuum matching cavity always generates vacuum adsorption force in the process of loading the curved glass, and the energy consumption is high.
Therefore, there is a need for a turning mechanism for curved glass vacuum interior bonding equipment to overcome the above-mentioned drawbacks.
Disclosure of Invention
The invention aims to provide a turning and conveying mechanism for curved glass vacuum inner laminating equipment, so that the curved glass and an inner film can be conveniently placed.
In order to achieve the above purpose, the turning mechanism for curved glass vacuum inner lamination equipment of the invention is suitable for turning a first vacuum matching cavity for containing one of a curved glass separation and an inner film to a position opposite to or staggered with a second vacuum matching cavity for containing the other of the curved glass separation and the inner film, and comprises a turning frame body and a turning driver. The turnover frame body is pivoted on a rack of curved glass vacuum inner laminating equipment around a pivoting central line, the turnover frame body is turned over around the pivoting central line in a reciprocating mode relative to the rack, and the first vacuum matching cavity is installed on the turnover frame body; the turnover driver is installed on the rack and drives the turnover frame body to turn over in a reciprocating mode, and the turnover frame body which turns over in a reciprocating mode drives the first vacuum matching cavity to turn over to a position opposite to or staggered with the second vacuum matching cavity.
Preferably, the turning and conveying mechanism for the curved glass vacuum inner lamination device further comprises a transfer device for driving one of the first vacuum matching cavity and the second vacuum matching cavity to slide to the other one of the first vacuum matching cavity and the second vacuum matching cavity along a direction parallel to the pivot center line.
Preferably, the transfer device is mounted on the turnover frame body or the rack and drives the first vacuum matching cavity to slide in a reciprocating manner.
Preferably, the turnover frame body comprises a first rotary table, a second rotary table, a hollow first shaft sleeve, a hollow second shaft sleeve and a bearing frame body, the first rotary table and the second rotary table are parallel and spaced apart from each other along a direction parallel to the pivot center line, the first shaft sleeve is fixedly penetrated on the first rotary table and mounted on the frame, the second shaft sleeve is fixedly penetrated on the second rotary table and mounted on the frame, the bearing frame body is supported between the first rotary table and the second rotary table along a direction parallel to the pivot center line, the first vacuum fit cavity is slidably arranged on the bearing frame body, and one of the first shaft sleeve and the second shaft sleeve is connected with the turnover driver; the transfer device comprises a rotating motor, a transfer screw rod and a transfer screw nut, one end of the transfer screw rod penetrates through a first shaft sleeve or a second shaft sleeve connected with the turnover driver, the other end of the transfer screw rod penetrates through the first shaft sleeve or the second shaft sleeve which is not connected with the turnover driver and extends outwards to form an extending end, the rotating motor is installed on the rack and connected with the extending end, the transfer screw nut is sleeved on the transfer screw rod in a sliding mode, and the transfer screw nut is further installed on the first vacuum matching cavity.
Preferably, the axial leads of the first shaft sleeve, the second shaft sleeve and the transfer screw rod are coincident.
Preferably, the output shaft of the rotating motor, the first shaft sleeve, the second shaft sleeve and the transfer screw rod have the same axial line.
Preferably, the rack includes a frame body and a first support arm and a second support arm standing on the frame body, the first shaft sleeve is installed on the first support arm, the second shaft sleeve is installed on the second support arm, the first rotary disc and the second rotary disc are located between the first support arm and the second support arm, the first rotary disc is adjacent to the first support arm, the second rotary disc is adjacent to the second support arm, the turnover driver is installed on the first support arm, and the rotation motor is installed on the second support arm.
Preferably, the turnover frame body comprises a first rotary table, a second rotary table, a rotary shaft and a bearing frame body, the first rotary table and the second rotary table are parallel and are spaced apart along a direction parallel to the pivot central line, the rotary shaft passes through the first rotary table and the second rotary table along a direction parallel to the pivot central line and is mounted on the frame, the bearing frame body is supported between the first rotary table and the second rotary table along a direction parallel to the pivot central line, the first vacuum fit cavity is mounted on the bearing frame body, and the turnover driver drives the rotary shaft to rotate.
Preferably, the rack includes a frame body and a first support arm and a second support arm standing on the frame body, one end of the rotating shaft is installed on the first support arm, the other end of the rotating shaft is installed on the second support arm, the first rotary disc and the second rotary disc are located between the first support arm and the second support arm, the first rotary disc is further adjacent to the first support arm, the second rotary disc is further adjacent to the second support arm, and the turnover driver is installed on one of the first support arm and the second support arm.
Preferably, the flipping driver is a rotating motor.
Compared with the prior art, the turnover mechanism for the curved glass vacuum inner laminating equipment comprises a turnover frame body and a turnover driver, wherein the turnover frame body is pivoted on a rack of the curved glass vacuum inner laminating equipment around a pivot center line, the turnover frame body is turned over around the pivot center line in a reciprocating manner relative to the rack, and a first vacuum matching cavity is arranged on the turnover frame body, so that in the process that the turnover driver drives the turnover frame body to turn over in a reciprocating manner, the turnover frame body which is turned over in a reciprocating manner drives the first vacuum matching cavity to turn over to a position opposite to or staggered with a second vacuum matching cavity, therefore, by means of the turnover frame body and the turnover driver, when curved glass or an inner film is loaded in the first vacuum matching cavity, the turnover driver drives the turnover frame body to turn over the first vacuum matching cavity to a position staggered with the second vacuum matching cavity, namely, a loading port of the first vacuum matching cavity is staggered with a loading port of the second vacuum matching cavity, for example, the loading port of the first vacuum matching cavity faces the front of a user, or the loading port of the first vacuum matching cavity is arranged upwards, and the first vacuum matching cavity and the loading port of the first vacuum matching cavity is arranged upwards, so that the first vacuum matching cavity and the second vacuum matching cavity can not be blocked by the curved glass or the inner film when the loading port is loaded in the first vacuum matching cavity, and the curved glass or the curved glass is conveniently operated; meanwhile, as the curved glass or the inner film is staggered with the second vacuum matching cavity in the process of placing the first vacuum matching cavity, more space is made for the second vacuum matching cavity, and the curved glass or the inner film is more favorably placed in the second vacuum matching cavity.
Drawings
Fig. 1 is a schematic plan view of a turning mechanism for a curved glass vacuum interior lamination apparatus according to the present invention when a first vacuum matching chamber is turned over to a position right above the first vacuum matching chamber.
Fig. 2 is a schematic plan view of the turning mechanism for curved glass vacuum interior lamination equipment of the present invention, which is turned over to the right below the first vacuum matching cavity and staggered with the second vacuum matching cavity.
Fig. 3 is a schematic plan view illustrating the structure of the transferring mechanism for the curved glass vacuum inner lamination apparatus in the state shown in fig. 2 when the first vacuum matching chamber is transferred to be opposite to the second vacuum matching chamber.
Fig. 4 is a schematic plan structure view of the turning mechanism for curved glass vacuum interior bonding equipment in the state shown in fig. 3 when the first vacuum matching cavity and the second vacuum matching cavity are closed and bonded.
Fig. 5 is a perspective view of the turning mechanism for curved glass vacuum interior bonding apparatus shown in fig. 4.
Fig. 6 is a schematic perspective view of another angle of the turning mechanism for curved glass vacuum interior bonding equipment in the state shown in fig. 4.
Fig. 7 is a schematic view of the internal structure of curved glass cut along its length direction.
Detailed Description
Embodiments of the present invention will now be described with reference to the drawings, wherein like element numerals represent like elements.
Referring to fig. 1, 5 and 6, the turning mechanism 100 for curved glass vacuum interior lamination apparatus of the present invention is adapted to turn over the first vacuum matching cavity 200 for accommodating the curved glass 500 to a position opposite to or staggered with the second vacuum matching cavity 300 for accommodating the inner film, so as to facilitate the accommodating of the curved glass 500 in the first vacuum matching cavity 200 and the accommodating of the inner film in the second vacuum matching cavity 300; of course, the first vacuum-fit cavity 200 is used for containing the inner film, and the second vacuum-fit cavity 300 is used for containing the curved glass 500 according to actual requirements, so the invention is not limited thereto. For example, as shown in fig. 7, in the present embodiment, the curved glass 500 is composed of a square flat body and curved portions extending from the left and right sides and/or the upper and lower sides of the square flat body, so that the inner surface 510 of the curved glass 500 is an inner concave surface and the outer surface 520 is an outer convex surface. It is understood that, the left and right sides or the upper and lower sides refer to the left side, the right side, the upper side and the lower side of the curved glass 500 when the square flat body faces the user, and the lower side is the upper side and the lower side of the user.
The turning mechanism 100 for curved glass vacuum interior laminating equipment of the present invention includes a turning frame 10 and a turning driver 20. The turnover frame body 10 is pivoted to a rack 400 of curved glass vacuum inner laminating equipment around a pivoting central line L1, and the turnover frame body 10 is turned over around the pivoting central line L1 in a reciprocating mode relative to the rack 400; specifically, in this embodiment, the pivot center line L1 is arranged along the longitudinal direction of the rack 400, that is, the left and right directions of the rack 400, so that the turnover frame body 10 is turned over about the pivot center line L1 relative to the rack 400, and a user can conveniently place the curved glass 500 in the first vacuum fitting cavity 200; of course, in other embodiments, the pivot center line L1 may also be arranged along the front-back direction or the up-down direction of the frame 400, so the invention is not limited thereto. The first vacuum matching cavity 200 is installed on the turning frame body 10, the turning driver 20 is installed on the frame 10 and drives the turning frame body 10 to turn in a reciprocating manner, and the turning frame body 10 which turns in a reciprocating manner drives the first vacuum matching cavity 200 to turn over to a position which is opposite to or staggered with the second vacuum matching cavity 300. The opposite direction means that the loading port of the first vacuum matching cavity 200 and the loading port of the second vacuum matching cavity 300 face to each other and are aligned along the closing direction of the first vacuum matching cavity 200 and the second vacuum matching cavity 300, and the loading ports are staggered except for the opposite direction. For example, as shown in fig. 1, the loading port of the first vacuum-fitting chamber 200 and the loading port of the second vacuum-fitting chamber 300 are both disposed upward, which is a type of dislocation; of course, in other embodiments, the loading port of the first vacuum matching chamber 200 is located at the front and the loading port of the second vacuum matching chamber 300 is located at the top, which is another type of offset, so it is not limited to this example. More specifically, the following:
as shown in fig. 1 to 6, the turning mechanism 100 for curved glass vacuum interior laminating apparatus of the present invention further includes a transferring device 30 for driving the first vacuum matching chamber 200 to slide to the second vacuum matching chamber 300 along a direction parallel to the pivot center line L1, so that the first vacuum matching chamber 200 is staggered with respect to the second vacuum matching chamber 300 along a direction parallel to the pivot center line L1 by means of the transferring device 30, thereby effectively avoiding obstacles caused by each self-supporting pair between the first vacuum matching chamber 200 and the second vacuum matching chamber 300, and further facilitating the loading and unloading of the curved glass 500 and the inner film; of course, in other embodiments, the second vacuum-fitting cavity 300 may be driven by the transfer device 30 to slide to a position of fitting with the first vacuum-fitting cavity 200, and the invention is not limited thereto. Specifically, in the embodiment, the transfer device 30 is mounted on the frame 400 and drives the first vacuum matching chamber 200 to slide back and forth, and of course, the transfer device 30 may be disposed on the turnover frame 10 and drives the first vacuum matching chamber 200 to slide back and forth, which is not limited thereto. More specifically, in the present embodiment, the turning frame 10 includes a first rotary table 11, a second rotary table 12, a hollow first sleeve 13, a hollow second sleeve 14 and a bearing frame 15; the first rotary table 11 is parallel to the second rotary table 12 and is spaced apart from the second rotary table in a direction parallel to the pivot central line L1, and the first shaft sleeve 13 is fixedly penetrated through the first rotary table 11 and is installed on the frame 400, so that the first shaft sleeve 13 is fixed with the first rotary table 11; the second shaft sleeve 14 fixedly penetrates the second rotary table 12 and is mounted on the frame 400, so that the second shaft sleeve 14 and the second rotary table 12 are fixed; the bearing frame body 15 is supported between the first rotating disc 11 and the second rotating disc 12 along the direction parallel to the pivoting central line L1, so that the first rotating disc 11, the second rotating disc 12, the first shaft sleeve 13, the second shaft sleeve 14 and the bearing frame body 15 are fixed together, the weight of the turnover frame body 10 is reduced, the turnover operation of the turnover frame body 10 is facilitated, the arrangement of the first rotating disc 11 and the second rotating disc 12 is facilitated, the dynamic balance is facilitated, and the stable and reliable turnover of the turnover frame body 10 is further ensured; the first vacuum matching cavity 200 is slidably disposed on the support frame 15, such that the first vacuum matching cavity 200 slides along a direction parallel to the pivot center line L1, preferably, a guide rail 40 and a slider 50 are disposed between the first vacuum matching cavity 200 and the support frame 15, such that the stability and reliability of the sliding of the first vacuum matching cavity 200 relative to the support frame 15 are improved by the cooperation of the guide rail 40 and the slider 50, but not limited thereto; the first shaft sleeve 13 is connected to the turning driver 20, and the turning driver 20 drives the first shaft sleeve 13 to rotate, preferably, the turning driver 20 is a rotating motor, but not limited thereto. The transfer device 30 includes a rotation motor 31, a transfer screw 32 and a transfer nut 33; one end of the transfer screw 32 penetrates into the first shaft sleeve 13, the other end of the transfer screw 32 penetrates through the second shaft sleeve 14 and extends outwards to form an extending end 32a, the rotating motor 31 is mounted on the rack 400 and is connected with the extending end 32a, the transfer screw 32 is driven to rotate by the rotating motor 31, and the two ends of the transfer screw 32 are reliably supported by the first shaft sleeve 13 and the second shaft sleeve 14 due to the fact that the transfer screw 32 penetrates into the first shaft sleeve 13 and the second shaft sleeve 14; the transfer screw 33 is slid on the transfer screw rod 32, the transfer screw 33 is further installed on the first vacuum matching cavity 200, so that the transfer screw rod 32 rotates to drive the transfer screw 33 to slide along the axial direction of the transfer screw rod 32, and the first vacuum matching cavity 200 is driven by the sliding transfer screw 33 to slide relative to the support frame body 15, thereby improving the sliding precision, meanwhile, the rotary motor 31 is installed on the rack 400, and the transfer screw rod 32 is driven to move relative to the support frame body 15 by the way that the first vacuum matching cavity 200 is penetrated in the first shaft sleeve 13 and the second shaft sleeve 14, so that the weight of the transfer device 30 is transferred to the rack 400 and supported by the rack 400, thereby effectively reducing the load of the turnover frame body 10 on the transfer device 30. For example, in the present embodiment, the output shaft of the rotating motor 31, the first shaft sleeve 13, the second shaft sleeve 14 and the transfer screw 32 are overlapped with each other so as to be located on the same line, which simplifies the structure and ensures the reliability of the turnover frame 10; of course, the axial lines of the first sleeve 13, the second sleeve 14, and the transfer screw 32 are overlapped as necessary, and thus the present invention is not limited to this example. It can be understood that, when the turnover driver 20 is connected to the second bushing 14, one end of the transfer screw 32 is inserted into the second bushing 14, and the other end of the transfer screw 32 passes through the first bushing 13 and extends outward to form an extended end 32a, that is, the turnover driver 20 and the rotating motor 31 are disposed at opposite sides. Similarly, when the transfer device 30 is mounted on the turning frame body 10, the turning frame body 10 needs to bear the self-gravity of the transfer device 30, so that the power requirement for turning the turning frame body 10 is high, and the control difficulty is high; when the transfer device 30 is mounted on the turning frame 10, the transfer screw 32 is mounted on the support frame 15 in the turning frame 10, the transfer screw 33 is slid on the transfer screw 32 and mounted on the first vacuum matching cavity 200, the rotating motor 31 is mounted on the support frame 15 in the turning frame 10 and drives the transfer screw 32 to rotate, and correspondingly, the first shaft sleeve 13 and the second shaft sleeve 14 in the turning frame 10 are directly made into an integral rotating shaft, and the rotating shaft penetrates through the first rotary table 11 and the second rotary table 12 and is mounted on the frame 400, which is not limited to this example.
As shown in fig. 1 to 6, the frame 400 includes a frame 410, and a first support arm 420 and a second support arm 430 standing on the frame 410. The first bushing 13 is mounted on the first support arm 420, and the first bushing 13 is supported by the first support arm 420, and the second bushing 14 is mounted on the second support arm 430, and the second bushing 14 is supported by the second support arm 430; the first rotary table 11 and the second rotary table 12 are positioned between the first support arm 420 and the second support arm 430, the first rotary table 11 is further arranged adjacent to the first support arm 420, so that the first support arm 420 effectively bears the gravity of the first rotary table 11, and the second rotary table 12 is further arranged adjacent to the second support arm 430, so that the second support arm 430 effectively bears the gravity of the second rotary table 12; the turnover actuator 20 is installed on the first support arm 420, and the rotation motor 31 is installed on the second support arm 430; therefore, the frame 410, and the first supporting arm 420 and the second supporting arm 430 standing on the frame 410 are used to facilitate the installation of the turning mechanism 100 for curved glass vacuum interior laminating apparatus of the present invention on the frame 400, but not limited thereto.
It can be understood that, in other embodiments, when the turning mechanism 100 for curved glass vacuum interior lamination equipment of the present invention only needs the turning function of the first vacuum matching chamber 200 with respect to the second vacuum matching chamber 300, that is, the turning mechanism 100 for curved glass vacuum interior lamination equipment of the present invention does not need to be provided with the transferring device 30, so the turning frame 10 at this time includes the first rotating disc 11, the second rotating disc 12, the rotating shaft and the carrying frame 15; the first rotary table 11 and the second rotary table 12 are parallel to each other and are spaced apart from each other along a direction parallel to a pivot center line L1, the rotating shaft penetrates through the first rotary table 11 and the second rotary table 12 along the direction parallel to the pivot center line L1 and is installed on the rack 400, the bearing frame body 15 is supported between the first rotary table 11 and the second rotary table 12 along the direction parallel to the pivot center line L1, the first vacuum matching cavity 200 is installed on the bearing frame body 15, and the rotating shaft is driven to rotate by the overturning driver 20 so as to drive the first vacuum matching cavity 200 to be opposite to or staggered relative to the second vacuum matching cavity 300; correspondingly, the frame 400 includes a frame body 410, and a first supporting arm 420 and a second supporting arm 430 standing on the frame body 410, wherein one end of the rotating shaft is installed on the first supporting arm 420, the other end of the rotating shaft is installed on the second supporting arm 430, the first rotating disk 11 and the second rotating disk 12 are located between the first supporting arm 420 and the second supporting arm 430, the first rotating disk 11 is further disposed adjacent to the first supporting arm 420, the second rotating disk 12 is further disposed adjacent to the second supporting arm 430, and the flipping actuator 20 is installed on one of the first supporting arm 420 and the second supporting arm 430, so the invention is not limited thereto. That is, the rotating shaft is a long shaft which is inserted behind the first rotating disc 11 and the second rotating disc 12 and both ends of which are mounted on the frame 400, and when the transferring device 30 needs to be installed in the turning mechanism 100 for a curved glass vacuum interior bonding apparatus according to the present invention, the rotating shaft is designed to include the first shaft sleeve 13 and the second shaft sleeve 14 which are spaced apart from each other.
The operation principle of the turning mechanism 100 for curved glass vacuum interior bonding equipment according to the present invention will be described with reference to fig. 1 to 6: as shown in fig. 1, the turnover driver 20 drives the first vacuum matching cavity 200 to turn over to a position right above the second vacuum matching cavity 300 through the turnover frame 10, and the first vacuum matching cavity is staggered with the second vacuum matching cavity 300, so as to facilitate the placement of the curved glass 500 into the first vacuum matching cavity 200 and the placement of the inner film into the second vacuum matching cavity 300; when the first vacuum matching cavity 200 is filled with the curved glass 500 and the second vacuum matching cavity 300 is filled with the inner film, the turning driver 20 drives the first vacuum matching cavity 200 to turn over to the right lower position through the turning frame body 10, and the state is shown in fig. 2; then, the rotating motor 31 drives the first vacuum matching cavity 200 to move rightward through the transfer screw rod 32 and the transfer screw nut 33, so that the first vacuum matching cavity 200 moves to a position right above the second vacuum matching cavity 300, and the state is shown in fig. 3; then, the lifting mechanism in the curved glass vacuum inner attaching device drives the second vacuum fitting cavity 300 to lift upwards, so that the second vacuum fitting cavity 300 and the first vacuum fitting cavity 200 are closed together, and the state is shown in fig. 4, thereby achieving the purpose of attaching the inner film to the inner surface of the curved glass 500.
Compared with the prior art, because the turning mechanism 100 for the curved glass vacuum interior bonding equipment comprises the turning frame body 10 and the turning driver 20, the turning frame body 20 is pivoted on the rack 400 of the curved glass vacuum interior bonding equipment around the pivot center line L1, the turning frame body 10 is turned over around the pivot center line L1 in a reciprocating manner relative to the rack 400, and the first vacuum matching cavity 200 is installed on the turning frame body 10, during the process that the turning driver 20 drives the turning frame body 10 to turn over in a reciprocating manner, the turning frame body 10 which is turned over in a reciprocating manner drives the first vacuum matching cavity 200 to be turned over to a position which is opposite to or staggered with the second vacuum matching cavity 300, therefore, by means of the turning frame body 10 and the turning driver 20, when the curved glass 500 or the inner film is placed in the first vacuum matching cavity 200, the first vacuum matching cavity 200 is turned over to a position which is staggered with the second vacuum matching cavity 300 through the driving of the turning frame body 10, that the loading inlet of the first vacuum matching cavity 200 is staggered with the loading inlet of the second vacuum matching cavity 300, for example, the loading inlet of the first vacuum matching cavity 200 is staggered with the loading inlet of the second vacuum matching cavity 300, so that a user can not block the first vacuum matching cavity 200 in the loading of the curved glass 500 or the curved glass 500 upwards when the first vacuum matching cavity 200 is placed in the first vacuum matching cavity, and the curved glass loading inlet is placed in the first vacuum matching cavity 200, so that the curved glass loading inlet is arranged in the first vacuum matching cavity 200, the curved glass loading inlet is arranged in the first vacuum matching cavity 200 or the first vacuum matching cavity, and the vacuum matching cavity is arranged in the vacuum matching cavity before the vacuum matching cavity 200, and the vacuum matching cavity is arranged in the vacuum matching cavity 200 arranged in the vacuum matching cavity 500 or the vacuum matching cavity, and the vacuum matching cavity, so that the vacuum matching cavity is arranged in the vacuum matching cavity 500 or the vacuum matching cavity in the vacuum matching process that the vacuum matching with the vacuum matching cavity 500, the vacuum matching with the vacuum matching cavity 500 or the vacuum matching cavity is conveniently; meanwhile, the curved glass 500 or the inner film is dislocated with the second vacuum matching cavity 300 in the process of placing the first vacuum matching cavity 200, so that more space is made for the second vacuum matching cavity 300, and the curved glass 500 or the inner film can be placed in the second vacuum matching cavity 300 more conveniently.
The above disclosure is only for the purpose of illustrating the preferred embodiments of the present invention and is not to be construed as limiting the scope of the present invention, therefore, the present invention is not limited by the appended claims.
Claims (3)
1. The utility model provides a laminating equipment is with mechanism that sends that turns over in curved surface glass vacuum, is suitable for and will be used for the splendid attire to have curved surface glass and the interior membrance in one's first vacuum cooperation cavity upset to with be used for the splendid attire to have curved surface glass and the interior membrance in another's second vacuum cooperation cavity just to or staggered position, its characterized in that includes:
the turnover frame body is pivoted to a rack of curved glass vacuum inner laminating equipment around a pivoting central line, the turnover frame body is turned over around the pivoting central line in a reciprocating mode relative to the rack, and the first vacuum matching cavity is installed on the turnover frame body;
the turnover driver is arranged on the rack and drives the turnover frame body to turn over in a reciprocating manner, and the turnover frame body which turns over in a reciprocating manner drives the first vacuum matching cavity to turn over to a position which is opposite to or staggered with the second vacuum matching cavity; and
the transfer device drives the first vacuum matching cavity to slide to a position matched with the second vacuum matching cavity along a direction parallel to the pivoting center line, and the transfer device also enables the first vacuum matching cavity to slide in a reciprocating manner;
the turnover frame body comprises a first rotary table, a second rotary table, a hollow first shaft sleeve, a hollow second shaft sleeve and a bearing frame body, wherein the first rotary table and the second rotary table are parallel and are separated along the direction parallel to the pivoting central line; the transfer device comprises a rotating motor, a transfer screw rod and a transfer screw nut, one end of the transfer screw rod penetrates through a first shaft sleeve or a second shaft sleeve connected with the turnover driver, the other end of the transfer screw rod penetrates through the first shaft sleeve or the second shaft sleeve which is not connected with the turnover driver and extends outwards to form an extending end, the rotating motor is installed on the rack and connected with the extending end, the transfer screw nut is in sliding sleeve with the transfer screw rod, and the transfer screw nut is also installed on the first vacuum matching cavity; the axial leads of the first shaft sleeve, the second shaft sleeve and the transfer screw rod are coincided; the turnover driver is a rotating motor.
2. The turning mechanism for curved glass vacuum inner lamination equipment according to claim 1, wherein the axial leads of the output shaft of the rotating motor, the first shaft sleeve, the second shaft sleeve and the transfer screw rod are coincident.
3. The turning mechanism for curved glass vacuum interior laminating equipment according to claim 1, wherein said frame comprises a frame body and a first supporting arm and a second supporting arm standing on said frame body, said first sleeve is installed on said first supporting arm, said second sleeve is installed on said second supporting arm, said first turntable and said second turntable are located between said first supporting arm and said second supporting arm, said first turntable is further adjacent to said first supporting arm, said second turntable is further adjacent to said second supporting arm, said turning actuator is installed on said first supporting arm, and said rotating motor is installed on said second supporting arm.
Priority Applications (1)
| Application Number | Priority Date | Filing Date | Title |
|---|---|---|---|
| CN201710496035.2A CN107139567B (en) | 2017-06-26 | 2017-06-26 | Turning and conveying mechanism for curved glass vacuum inner laminating equipment |
Applications Claiming Priority (1)
| Application Number | Priority Date | Filing Date | Title |
|---|---|---|---|
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| CN111907050B (en) * | 2020-08-05 | 2022-02-22 | 广东华中科技大学工业技术研究院 | Rotatory multistation curved surface laminating device |
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