CN215744422U

CN215744422U - Double-coating-knife mechanism of laminating equipment

Info

Publication number: CN215744422U
Application number: CN202121916898.9U
Authority: CN
Inventors: 勾林阳
Original assignee: Xiamen Zered Automation Technology Co ltd
Current assignee: Xiamen Zered Automation Technology Co ltd
Priority date: 2021-08-16
Filing date: 2021-08-16
Publication date: 2022-02-08
Anticipated expiration: 2031-08-16

Abstract

The utility model discloses a double-coating-knife mechanism of laminating equipment, which comprises a machine table, a translation module, a translation guide rail, more than two groups of coating devices, a feeding guide rail and a feeding module, wherein the machine table is provided with a plurality of coating devices; the translation module and the translation guide rail are both installed on the machine table, more than two groups of coating devices are connected with the sliding block of the translation module and are in sliding connection with the translation guide rail, and the feeding guide rail and the feeding module are both installed in the middle of the machine table. The translation module can drive more than two groups of coating devices to move back and forth along the translation guide rail, so that two display screen windows on the same cover plate can be coated on one coating station, and the production efficiency is high.

Description

Double-coating-knife mechanism of laminating equipment

Technical Field

The utility model relates to the field of liquid crystal screen production, in particular to a double-coating-knife mechanism of a fitting device.

Background

The touch screen is an induction type liquid crystal display device capable of receiving input signals of a contact and the like, when a graphic button on the screen is contacted, a touch feedback system on the screen can drive various connecting devices according to a pre-programmed program, a mechanical button panel can be replaced, and vivid video and audio effects can be produced by a liquid crystal display picture. Touch-sensitive screen includes display screen and apron, and the display screen need only be a set of through the glue laminating with the apron together, and traditional coating unit mostly has two display screens to the product that has, can't once only coat two display screens, and production efficiency is low.

Disclosure of Invention

The utility model aims to provide a double-coating-knife mechanism of a laminating device with high production efficiency.

In order to achieve the purpose, the technical solution of the utility model is as follows:

the utility model relates to a double-coating-knife mechanism of laminating equipment, which comprises a machine table, a translation module, a translation guide rail, more than two groups of coating devices, a feeding guide rail and a feeding module; the translation module and the translation guide rail are both arranged on the machine table, more than two groups of coating devices are connected with the sliding block of the translation module and are in sliding connection with the translation guide rail, and the feeding guide rail and the feeding module are arranged in the middle of the machine table;

the coating device comprises a translation seat, a lifting module, a lifting seat, a lifting guide rail, a glue feeding horizontal module, a coating frame and a coating knife;

the translation seat is connected to the translation guide rail in a sliding manner and is connected with the sliding block of the translation module, the translation seat moves along the translation guide rail under the driving of the translation module, the lifting module and the lifting guide rail are fixedly arranged on the translation seat, the lifting seat is connected to the lifting guide rail in a sliding manner and is connected with the sliding block of the lifting module, and the lifting seat moves up and down along the lifting guide rail under the driving of the lifting module; the glue feeding horizontal module is installed on the lifting seat, the coating frame is installed on a sliding block of the glue feeding horizontal module and is connected to a coating frame sliding rail in a sliding mode, the coating frame sliding rail is fixed on the lifting seat, and the coating knife is installed on the coating frame.

The coating machine also comprises a frictioning tool setting mechanism, wherein the frictioning tool setting mechanism is arranged on the machine table and is positioned on one side of the coating knife and is connected with the coating knife.

The frictioning tool setting mechanism comprises a frictioning frame, a frictioning guide rail, a rodless cylinder, a frictioning seat and a tool setting sensor; the rubber wiping frame is fixedly installed on the machine table, the rodless cylinder and the rubber wiping guide rail are installed at the top of the rubber wiping frame, the rubber wiping seat is installed on a sliding block of the rodless cylinder and is in sliding connection with the rubber wiping guide rail, the rubber wiping seat moves along the rubber wiping guide rail under the driving of the rodless cylinder, and the tool setting sensor is installed at the top of the rubber wiping frame.

Two tool setting sensors are arranged and are arranged at the top of the rubber wiping frame.

The frictioning tool setting mechanism further comprises a glue collecting frame, wherein the glue collecting frame is a long frame with an upward opening and two closed ends.

The utility model also comprises a gluing thickness detection mechanism, wherein the gluing thickness detection mechanism comprises a detection frame, a detection guide rail, a detection module, a probe frame and a laser gluing detection probe; the detection frame is fixed on the machine table and is bridged over the feeding guide rail, the detection guide rail and the cylinder body of the detection module are both arranged on the top surface of the detection frame, the probe frame is connected with a piston rod of the detection module and is in sliding connection with the detection guide rail, the probe frame moves along the detection guide rail under the driving of the detection module, and the laser glue measuring probe is fixedly arranged on the probe frame and downwards faces the feeding guide rail.

The coating device also comprises a tool setting module, wherein the tool setting module is fixed on the coating frame, one end of the coating knife is hinged to an output shaft of the tool setting module, the other end of the coating knife is hinged to the coating frame, and the tool setting module can drive the coating knife to swing around a hinged point with the coating frame.

After the scheme is adopted, the automatic gluing device comprises a machine table, a translation module, a translation guide rail, more than two groups of coating devices, a feeding guide rail and a feeding module, when a cover plate with two display screen windows to be glued is conveyed to a coating station along the feeding guide rail, the translation module can respectively drive the two groups of coating devices to move back and forth along the translation guide rail, so that the two display screen windows on the same cover plate are glued on one coating station, and the production efficiency is high.

The utility model is further described with reference to the following figures and specific embodiments.

Drawings

FIG. 1 is an isometric view of the present invention;

FIG. 2 is an isometric view of a coating apparatus of the present invention;

fig. 3 is a partially enlarged view of the paste thickness detection mechanism of the present invention.

Detailed Description

As shown in fig. 1 and 2, the present invention is a double-coating-knife mechanism of a bonding apparatus, including a machine table 1, a translation module 2, a translation guide rail 3, more than two groups of coating devices 4, a feeding guide rail 5, and a feeding module 6.

Translation module 2 and translation guide rail 3 all install on board 1, and more than two sets of coating device 4 all are connected with the slider of translation module 2 and sliding connection on translation guide rail 3, and feeding guide rail 5 and feeding module 6 are all installed in the middle part of board 1 for the material loading.

The coating device 4 comprises a translation seat 41, a lifting module 42, a lifting seat 43, a lifting guide rail 44, a glue feeding horizontal module 45, a coating frame 47, a glue wiping tool setting mechanism 48, a glue coating thickness detection mechanism 49 and a coating tool 410;

the translation seat 41 is slidably connected to the translation guide rail 3 and connected to the slider of the translation module 2, the translation seat 41 moves along the translation guide rail 3 under the driving of the translation module 2, the lifting module 42 and the lifting guide rail 44 are both fixedly mounted on the translation seat 41, the lifting seat 43 is slidably connected to the lifting guide rail 44 and connected to the slider of the lifting module 42, and the lifting seat 43 moves up and down along the lifting guide rail 44 under the driving of the lifting module 42; the glue feeding horizontal module 45 is arranged on the lifting seat 43, the coating frame 47 is arranged on a sliding block of the glue feeding horizontal module 45 and is connected to a coating frame sliding rail 420 in a sliding manner, the coating frame sliding rail 420 is fixed on the lifting seat 43, the coating knife 410 is arranged on the coating frame 47, the coating knife 410 is connected with a glue feeding system through a glue feeding pipe 411, and the glue feeding system provides glue for the coating knife 410; the frictioning tool setting mechanism 48 and the gluing thickness detection mechanism 49 are both installed on the machine table 1, the frictioning tool setting mechanism 48 is located on one side of the coating knife 410 and is connected with the coating knife 410, and the gluing thickness detection mechanism 49 is located right above the feeding guide rail 5 so as to detect the gluing thickness.

The utility model also comprises a tool setting module 46, wherein the tool setting module 46 is fixed on the coating frame 47, one end of the coating knife 410 is hinged on an output shaft of the tool setting module 46, the other end of the coating knife 410 is hinged on the coating frame 47, and the tool setting module 46 can drive the coating knife 410 to swing around a hinge point A with the coating frame 47.

The rubber coating tool setting mechanism 48 comprises a rubber coating frame 481, a rubber coating guide rail 482, a rodless cylinder (not shown in the figure), a rubber coating base 484 and a tool setting sensor 485; the glue wiping frame 481 is fixedly arranged on the machine table 1, the rodless cylinder and the glue wiping guide rail 482 are both arranged at the top of the glue wiping frame 481, the glue wiping seat 484 is arranged on a sliding block of the rodless cylinder and is in sliding connection with the glue wiping guide rail 482, and the glue wiping seat 484 is driven by the rodless cylinder to move along the glue wiping guide rail 482 to wipe residual glue on the coating knife; the number of the tool setting sensors 485 is two, and the tool setting sensors are arranged at the top of the rubber wiping frame 481 and used for horizontally correcting the coating knife 410; also comprises a glue collecting frame 483 which is a long strip frame with an upward opening and two closed ends and is used for collecting residual glue.

As shown in fig. 3, the gluing thickness detecting mechanism 49 includes a detecting frame 491, a detecting guide rail 492, a detecting module 493, a probe frame 494, and a laser gluing detecting probe 495; the detection frame 491 is fixed on the machine table 1 and bridged over the feeding guide rail 5, the cylinder bodies of the detection guide rail 492 and the detection module 493 are both installed on the top surface of the detection frame 491, the probe frame 494 is connected with the piston rod of the detection module 49 and is connected on the detection guide rail 492 in a sliding manner, the probe frame 494 moves along the detection guide rail 492 under the driving of the detection module 493, the laser glue measuring probe 495 is fixedly installed on the probe frame 494, the laser glue measuring probe 495 faces downwards to the feeding guide rail 5, and the laser glue measuring probe 495 can move left and right along the detection guide rail 492 under the driving of the detection module 493 so as to detect the glue thickness of the coated cover plate.

The laser knife measuring and controlling head 495 adopts a laser glue measuring probe of a kirschner brand model CL-P015, and because the reflectivity of light on a contact surface between a medium and a medium is different, the actual thickness of the glue can be converted by calculating the distance of difference points on the surface of the laser glue emitted by the laser knife measuring and controlling head when the light passes through an air medium, a glue medium and a glass medium.

The working principle of the utility model is as follows:

when the cover plate with the two display screen windows to be coated is conveyed to a coating station along the feeding guide rail 5, the translation module 2 can respectively drive the two groups of coating devices 4 to move back and forth along the translation guide rail 3, so that the two display screen windows on the same cover plate can be coated on one coating station.

The above description is only a preferred embodiment of the present invention, and therefore should not be taken as limiting the scope of the utility model, which is defined by the appended claims and their equivalents and modifications within the scope of the description.

Claims

1. The utility model provides a two coating knife mechanisms of laminating equipment which characterized in that: comprises a machine table, a translation module, a translation guide rail, more than two groups of coating devices, a feeding guide rail and a feeding module; the translation module and the translation guide rail are both arranged on the machine table, more than two groups of coating devices are connected with the sliding block of the translation module and are in sliding connection with the translation guide rail, and the feeding guide rail and the feeding module are arranged in the middle of the machine table;

2. The double-coating-blade mechanism of a laminating apparatus according to claim 1, wherein: the coating knife device is characterized by further comprising a frictioning knife setting mechanism, wherein the frictioning knife setting mechanism is installed on the machine table and is located on one side of the coating knife and is connected with the coating knife.

3. The double-coating-blade mechanism of a laminating apparatus according to claim 2, wherein: the frictioning tool setting mechanism comprises a frictioning frame, a frictioning guide rail, a rodless cylinder, a frictioning seat and a tool setting sensor; the rubber wiping frame is fixedly installed on the machine table, the rodless cylinder and the rubber wiping guide rail are installed at the top of the rubber wiping frame, the rubber wiping seat is installed on a sliding block of the rodless cylinder and is in sliding connection with the rubber wiping guide rail, the rubber wiping seat moves along the rubber wiping guide rail under the driving of the rodless cylinder, and the tool setting sensor is installed at the top of the rubber wiping frame.

4. The double-coating-blade mechanism of a laminating apparatus according to claim 3, wherein: two tool setting sensors are arranged and are arranged at the top of the rubber wiping frame.

5. The double-coating-blade mechanism of a laminating apparatus according to claim 3, wherein: the frictioning tool setting mechanism further comprises a glue collecting frame, wherein the glue collecting frame is a long frame with an upward opening and two closed ends.

6. The double-coating-blade mechanism of a laminating apparatus according to claim 1, wherein: the glue coating thickness detection mechanism comprises a detection frame, a detection guide rail, a detection module, a probe frame and a laser glue detection probe; the detection frame is fixed on the machine table and is bridged over the feeding guide rail, the detection guide rail and the cylinder body of the detection module are both arranged on the top surface of the detection frame, the probe frame is connected with a piston rod of the detection module and is in sliding connection with the detection guide rail, the probe frame moves along the detection guide rail under the driving of the detection module, and the laser glue measuring probe is fixedly arranged on the probe frame and downwards faces the feeding guide rail.

7. The double-coating-blade mechanism of a laminating apparatus according to claim 1, wherein: the coating device is characterized by further comprising a tool setting module, the tool setting module is fixed on the coating frame, one end of the coating knife is hinged to an output shaft of the tool setting module, the other end of the coating knife is hinged to the coating frame, and the tool setting module can drive the coating knife to swing around a hinged point with the coating frame.