CN219544013U - VR lens vacuum pad pasting device - Google Patents

Abstract

The utility model relates to the technical field of VR lens automatic manufacturing, in particular to a VR lens vacuum film sticking device, which comprises a lower cavity component and an upper cavity component arranged above the lower cavity component; the lower cavity assembly comprises a lower cavity box body, a lens carrying platform arranged in the lower cavity box body, a lower cavity lifting mechanism arranged below the lower cavity box body and driving the lower cavity box body to move up and down, and a lower cavity transfer mechanism arranged below the lower cavity box body and driving the lower cavity box body to move horizontally; the upper cavity assembly comprises an upper cavity box body, an upper cavity jig arranged in the upper cavity box body, and a jig lifting mechanism arranged above the upper cavity box body and driving the upper cavity jig to move up and down. In the bonding process of the diaphragm and the lens, the upper cavity component and the lower cavity component are mutually matched to carry out vacuumizing bonding, so that the diaphragm and the lens are ensured to be completely bonded, the bubble removing effect is realized, the quality of a finished product and the bonding efficiency are improved, and the cost is reduced.

Description

VR lens vacuum pad pasting device

Technical Field

The utility model relates to the technical field of automatic manufacturing of VR lenses, in particular to a VR lens vacuum film sticking device.

Background

VR (virtual reality) is to make a three-dimensional virtual world by using a computer, and provide a visual, tactile and auditory interaction scene for a user, so that the user feels the scene and is immersed in the virtual world, and meanwhile, the user can observe and interact with things in the three-dimensional space. The virtual reality head-mounted display device, VR glasses for short, is a product of a plurality of technical sets such as a simulation technology, a computer graphics man-machine interface technology, a multimedia technology sensing technology network technology and the like, and is a brand-new man-machine interaction means created by means of a computer and the latest sensor technology. VR glasses display portion comprises display module assembly (diaphragm) and LENS (LENS) two parts, in the manufacturing process of VR glasses, needs to laminate diaphragm and LENS together, current laminating equipment, directly pastes the diaphragm on the LENS, and the laminating in-process produces the bubble easily, and finished product quality is relatively poor, laminating inefficiency.

Disclosure of Invention

In order to solve the problems in the background art, the utility model provides a VR lens vacuum film pasting device, which adopts a vacuum pasting technology in the pasting process of a film and a lens, ensures complete pasting of the film and the lens, realizes bubble removal, improves the quality of finished products and pasting efficiency, and reduces cost.

The utility model adopts the following technical scheme:

a VR lens vacuum film sticking device comprises a lower cavity component and an upper cavity component arranged above the lower cavity component; the lower cavity assembly comprises a lower cavity box body, a lens carrying platform arranged in the lower cavity box body, a lower cavity lifting mechanism arranged below the lower cavity box body and driving the lower cavity box body to move up and down, and a lower cavity transfer mechanism arranged below the lower cavity box body and driving the lower cavity box body to move horizontally; the upper cavity assembly comprises an upper cavity box body, an upper cavity jig arranged in the upper cavity box body, and a jig lifting mechanism arranged above the upper cavity box body and driving the upper cavity jig to move up and down.

Further, the lower cavity assembly further comprises a correction platform arranged below the lower cavity box.

Further, the lower cavity transfer mechanism comprises a first sliding rail, a first sliding block horizontally moving on the first sliding rail, and a sliding table fixedly connected with the first sliding block, wherein the sliding table is connected with the lower cavity box.

Further, the lower cavity lifting mechanism comprises two first air cylinders, the cylinder bodies of the first air cylinders are fixedly arranged on the sliding table, and the piston rods of the first air cylinders are fixedly connected with the lower cavity box body.

Further, the lower cavity lifting mechanism further comprises at least two first guide rods and first guide sleeves sleeved outside the first guide rods, the upper ends of the first guide rods are fixedly connected with the lower cavity box, and the first guide sleeves are fixedly connected with the sliding table.

Further, the upper cavity jig comprises a profiling block on the lens, and clamping mechanisms arranged on two sides of the profiling block on the lens, wherein each clamping mechanism comprises two clamping blocks oppositely arranged on two sides of the profiling block on the lens, and two clamping sliding mechanisms respectively driving the two clamping blocks to move oppositely or reversely.

Further, the jig lifting mechanism comprises an upper cavity bracket fixedly connected with the upper cavity box, a second sliding rail vertically and fixedly installed on the upper cavity bracket, a second sliding block vertically sliding on the second sliding rail, and a lifting bracket fixedly connected with the second sliding block, wherein the lifting bracket is connected with the upper cavity jig.

Further, the jig lifting mechanism further comprises a second air cylinder, the cylinder body of the second air cylinder is fixedly connected with the lifting support, and the piston rod of the second air cylinder is fixedly connected with the upper cavity jig.

Further, the lower cavity assembly further comprises a vacuum pipeline arranged below the lower cavity box body, the upper end of the vacuum pipeline is communicated with the lens carrier, and the lower end of the vacuum pipeline is communicated with external vacuumizing equipment.

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

1) In the bonding process of the diaphragm and the lens, the upper cavity component and the lower cavity component are mutually matched to carry out vacuumizing bonding, so that the diaphragm and the lens are ensured to be completely bonded, the bubble removing effect is realized, the quality of a finished product and the bonding efficiency are improved, and the cost is reduced.

2) The upper cavity jig comprises a lens upper profiling block and clamping mechanisms arranged on two sides of the lens upper profiling block, wherein the lens is adsorbed on the lens upper profiling block, and simultaneously the clamping mechanisms clamp the lens to provide double fixing for the lens.

Drawings

For a clearer description of embodiments of the utility model or of solutions in the prior art, the drawings which are used in the description of the embodiments or of the prior art will be briefly described, it being obvious that the drawings in the description below are only some embodiments of the utility model, and that other drawings can be obtained from them without inventive effort for a person skilled in the art.

FIG. 1 is a schematic diagram of the overall structure of a VR lens vacuum film laminating device of the present utility model;

FIG. 2 is a schematic view of the lower chamber assembly of the present utility model;

FIG. 3 is a schematic view of the upper chamber assembly of the present utility model.

In the figure: the device comprises a 1-lower cavity assembly, a 2-upper cavity assembly, a 11-lower cavity box, a 12-lens carrying platform, a 13-lower cavity lifting mechanism, a 14-lower cavity transfer mechanism, a 15-correction platform, a 16-vacuum pipeline, a 21-upper cavity box, a 22-upper cavity jig, a 23-jig lifting mechanism, a 131-first cylinder, a 132-guide rod, a 133-guide sleeve, a 141-first slide rail, a 142-first slide block, a 143-slide table, a 221-lens upper profiling block, a 222-clamping mechanism, a 231-upper cavity bracket, a 232-second slide rail, a 233-second slide block, a 234-lifting bracket, a 235-second cylinder, a 2221-clamping block and a 2222-clamping sliding mechanism.

Detailed Description

The following description of the embodiments of the present utility model will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present utility model, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the utility model without making any inventive effort, are intended to fall within the scope of the utility model.

The utility model is discussed in detail below in conjunction with fig. 1-3 and the specific embodiments:

the embodiment of the utility model provides a VR lens vacuum film sticking device, as shown in figures 1-3, which comprises a lower cavity assembly 1 and an upper cavity assembly 2 arranged above the lower cavity assembly 1, wherein in the sticking process of a film and a lens, the upper cavity assembly 2 and the lower cavity assembly 1 are mutually matched to carry out vacuumizing lamination, so that the film and the lens are ensured to be completely laminated, the bubble removing effect is realized, the quality and the laminating efficiency of a finished product are improved, and the cost is reduced; the lower cavity assembly 1 comprises a lower cavity box 11, a lens carrying platform 12 arranged in the lower cavity box 11, a lower cavity lifting mechanism 13 arranged below the lower cavity box 11 and driving the lower cavity box 11 to move up and down, and a lower cavity transferring mechanism 14 arranged below the lower cavity box 11 and driving the lower cavity box 11 to move horizontally, wherein the lens carrying platform 12 is used for placing a film and a lens which are subjected to simple bonding, the lower cavity transferring mechanism 14 is used for moving the lower cavity box 11 to a vacuum bonding station for vacuum bonding, and the lower cavity lifting mechanism 13 is used for driving the lower cavity box 11 to move upwards to be abutted and bonded and pressed with the upper cavity box 21 so as to perform vacuum pumping and pressurization; the upper cavity assembly 2 comprises an upper cavity box 21, an upper cavity jig 22 arranged in the upper cavity box 21, and a jig lifting mechanism 23 arranged above the upper cavity box 21 and driving the upper cavity jig 22 to move up and down, wherein the upper cavity jig 22 is used for sucking and clamping lenses, and the jig lifting mechanism 23 is used for driving the upper cavity jig 22 to move up and down in the upper cavity box 21 so as to realize close fit with the lens carrier 12, avoid generating bubbles during vacuumizing and fitting, and improve fitting quality.

Further, the lower cavity assembly 1 further comprises a correction platform 15 arranged below the lower cavity box 11, the correction platform 15 is used for adjusting the angle of the lower cavity box 11 in the horizontal plane, and when the lower cavity box 11 is abutted and attached to the upper cavity box 21, the lower cavity box 11 and the upper cavity box 21 are completely overlapped, so that the vacuumizing quality is ensured.

Further, the lower cavity transfer mechanism 14 includes a first slide rail 141, a first slide block 142 horizontally moving on the first slide rail 141, and a slide table 143 fixedly connected with the first slide block 142, where the slide table 143 is connected with the lower cavity box 11, and the first slide block 142 drives the slide table 143 to further drive the lower cavity box 11 to horizontally move on the first slide rail 141.

Further, the lower cavity lifting mechanism 13 comprises two first air cylinders 131, the cylinder bodies of the first air cylinders 131 are fixedly arranged on the sliding table 143, the piston rods of the first air cylinders 131 are fixedly connected with the lower cavity box 11, and the first air cylinders 131 drive the lower cavity box 11 to move upwards to be attached to the upper cavity box 21.

Further, the lower cavity lifting mechanism 13 further comprises at least two first guide rods 132 and a first guide sleeve 133 sleeved outside the first guide rods 132, the upper ends of the first guide rods 132 are fixedly connected with the lower cavity box 11, the first guide sleeve 133 is fixedly connected with the sliding table 143, the first guide rods 132 and the first guide sleeve 133 are arranged to be matched with the first air cylinders 131, and guide is provided for the up-and-down movement of the lower cavity box 11, so that the up-and-down movement of the lower cavity box 11 is stable.

Further, the upper cavity jig 22 includes an upper lens profiling block 221, and clamping mechanisms 222 disposed at two sides of the upper lens profiling block 221, the clamping mechanisms 222 include two clamping blocks 2221 disposed at two sides of the upper lens profiling block 221, and two clamping sliding mechanisms 2222 respectively driving the two clamping blocks 2221 to move in opposite directions or in opposite directions; the lens is attracted to the on-lens profiling block 221 while the clamping blocks 2221 move toward each other to clamp the lens, providing dual fixation for the lens. Specifically, the shape of the lower side surface of the upper profiling block 221 of the lens, which is attached to the upper surface of the lens, is the same as that of the upper surface of the lens, and the middle position of the lower end of the upper profiling block 221 of the lens is provided with an air pumping cavity, the inside of the air pumping cavity is communicated with the outside, and when the lens is sucked, the lens is sucked on the upper profiling block 221 of the lens by external air pumping.

Further, the jig lifting mechanism 23 comprises an upper cavity bracket 231 fixedly connected with the upper cavity box 21, a second sliding rail 232 vertically and fixedly installed on the upper cavity bracket 231, a second sliding block 233 vertically sliding on the second sliding rail 232, and a lifting bracket 234 fixedly connected with the second sliding block 233, wherein the lifting bracket 234 is connected with the upper cavity jig 22, and the second sliding block 233 drives the lifting bracket 234 to drive the upper cavity jig 22 to move up and down in the upper cavity box 21.

Further, the jig lifting mechanism 23 further comprises a second air cylinder 235, a cylinder body of the second air cylinder 235 is fixedly connected with the lifting bracket 234, a piston rod of the second air cylinder 235 is fixedly connected with the upper cavity jig 22, and the second air cylinder 235 provides power for up-and-down movement of the upper cavity jig 22.

Further, the lower cavity assembly 1 further comprises a vacuum pipeline 16 arranged below the lower cavity box 11, the upper end of the vacuum pipeline 16 is communicated with the lens carrier 12, and the lower end of the vacuum pipeline 16 is communicated with external vacuumizing equipment.

The utility model relates to a VR lens vacuum film sticking device, which comprises the following specific working processes:

firstly, a membrane and a lens which are subjected to simple lamination are placed on a lens carrying platform 12, a lower cavity transfer mechanism 14 drives a lower cavity box 11 to move to a vacuum lamination station for vacuum lamination, at the moment, an upper cavity box 21 is directly above the lower cavity box 11, a lower cavity correction platform 15 adjusts the horizontal angle of the lower cavity box 11 to be consistent with that of the upper cavity box 21, a lifting mechanism drives the lower cavity box 11 to move upwards to be abutted with the upper cavity box for lamination, then vacuum equipment is started, when the air pressure reaches 50 Pa-200 Pa, a jig lifting mechanism 23 moves an upper cavity jig 22 downwards to be laminated with the lens, two clamping blocks 2221 clamp and fix the lens, the pressure of the jig lifting mechanism 23 for downwards extruding the lens is kept between 1550N and 1650N for 2-3 seconds, the vacuum equipment stops working, the lower cavity box 11 moves downwards to be abutted with the upper cavity box for lamination, then vacuum equipment is started, the inner space between the upper cavity box 21 and the lower cavity box 11 is vacuumized and pressurized, and the jig lifting mechanism moves to the lens 22 to be separated from the upper cavity box after the lower cavity box is broken, and the lens is continuously laminated to the lower cavity box is continuously moved to the lens.

The utility model has been further described with reference to specific embodiments, but it should be understood that the detailed description is not to be construed as limiting the spirit and scope of the utility model, but rather as providing those skilled in the art with the benefit of this disclosure with the benefit of their various modifications to the described embodiments.

Claims (9)

1. VR lens vacuum pad pasting device, its characterized in that:

comprises a lower cavity component and an upper cavity component arranged above the lower cavity component;

the lower cavity assembly comprises a lower cavity box body, a lens carrying platform arranged in the lower cavity box body, a lower cavity lifting mechanism arranged below the lower cavity box body and driving the lower cavity box body to move up and down, and a lower cavity transfer mechanism arranged below the lower cavity box body and driving the lower cavity box body to move horizontally;

the upper cavity assembly comprises an upper cavity box body, an upper cavity jig arranged in the upper cavity box body and a jig lifting mechanism arranged above the upper cavity box body and driving the upper cavity jig to move up and down.

2. The VR lens vacuum lamination device of claim 1, wherein: the lower cavity assembly further comprises a correction platform arranged below the lower cavity box body.

3. The VR lens vacuum lamination device of claim 1, wherein: the lower cavity transfer mechanism comprises a first sliding rail, a first sliding block horizontally moving on the first sliding rail and a sliding table fixedly connected with the first sliding block, and the sliding table is connected with the lower cavity box body.

4. The VR lens vacuum lamination device of claim 3, wherein: the lower cavity lifting mechanism comprises two first air cylinders, the cylinder bodies of the first air cylinders are fixedly arranged on the sliding table, and the piston rods of the first air cylinders are fixedly connected with the lower cavity box body.

5. The VR lens vacuum lamination device of claim 4, wherein: the lower cavity lifting mechanism further comprises at least two first guide rods and first guide sleeves sleeved outside the first guide rods, the upper ends of the first guide rods are fixedly connected with the lower cavity box body, and the first guide sleeves are fixedly connected with the sliding table.

6. The VR lens vacuum lamination device of claim 1, wherein: the upper cavity jig comprises a lens upper profiling block and clamping mechanisms arranged on two sides of the lens upper profiling block, wherein the clamping mechanisms comprise two clamping blocks which are oppositely arranged on two sides of the lens upper profiling block, and two clamping sliding mechanisms which respectively drive the two clamping blocks to move in opposite directions or in opposite directions.

7. The VR lens vacuum lamination device of claim 1, wherein: the jig lifting mechanism comprises an upper cavity support fixedly connected with the upper cavity box, a second sliding rail vertically and fixedly installed on the upper cavity support, a second sliding block vertically sliding on the second sliding rail, and a lifting support fixedly connected with the second sliding block, wherein the lifting support is connected with the upper cavity jig.

8. The VR lens vacuum lamination device of claim 7, wherein: the jig lifting mechanism further comprises a second air cylinder, the cylinder body of the second air cylinder is fixedly connected with the lifting support, and the piston rod of the second air cylinder is fixedly connected with the upper cavity jig.

9. The VR lens vacuum lamination device of claim 1, wherein: the lower cavity assembly further comprises a vacuum pipeline arranged below the lower cavity box body, the upper end of the vacuum pipeline is communicated with the lens carrying platform, and the lower end of the vacuum pipeline is communicated with external vacuumizing equipment.