KR20220078944A - Manufacturing method of pin mirror of optical system for augmented reality - Google Patents

Abstract

The present invention relates to a method for manufacturing a pin mirror lens, comprising the steps of: manufacturing a pin mirror lens by melting and injection molding a lens material; forming a reflective coating layer on the surface of the pin mirror lens; In a method for manufacturing a pin mirror lens that includes a post-process coating step and a step of bonding the pin mirror lens, and exhibits optical properties applicable to an AR optical system for a micro display mounted high angle of view, high resolution, and ultra-light AR device. it's about

Description

Manufacturing method of pin mirror lens for augmented reality optical system. {MANUFACTURING METHOD OF PIN MIRROR OF OPTICAL SYSTEM FOR AUGMENTED REALITY}

The present invention relates to a method of manufacturing a pin mirror lens for an augmented reality optical system, and more particularly, to a method of manufacturing a pin mirror lens for application to an AR optical system for a micro-display mounted high-angle, high-resolution, ultra-light AR device. .

Recently, as the demand for augmented reality (AR) increases, smart devices to which the AR technology is applied are being actively developed. The core technologies in AR devices are optics and display technologies, and development of high-quality optical and display technologies is required for the convergence of natural virtual images and the real world in a compact and lightweight glasses-type form factor. For this, a technology capable of realizing an ultra-lightweight, ultra-compact, and highly visible AR optical engine is required.

Korean Patent Application Laid-Open No. 10-2020-0105687 discloses an AR optical engine that provides a view of a virtual image rearranged on top of a real-world image to a user who gazes at a substantially transparent medium through a set of pinpoint mirrors. The technology of processing an image through a pinpoint mirror is the core technology of the AR optical engine. In this case, it can be seen that the performance of the AR optical engine is determined by the precision and quality of the pinpoint mirror.

Therefore, through the improvement of the pinpoint mirror, that is, the pin mirror lens, it will be possible to design and manufacture an AR optical engine having the characteristics of a compact size, high angle of view, high resolution, and high transmittance compared to the conventional AR optical engine.

Korean Patent Publication No. 10-2020-0105687

The present invention was devised in view of the problems of the prior art as described above, and an object of the present invention is to provide a pin mirror lens that can be applied to a high-quality AR optical engine by improving a manufacturing method of the pin mirror lens.

The manufacturing method of the pin mirror lens of the present invention for achieving the above object includes the steps of manufacturing a pin mirror lens by melting and injection molding a lens material, forming a reflective coating layer on the surface of the pin mirror lens, the pin It characterized in that it comprises the step of applying a post-process coating to the surface of the mirror lens, and bonding the pin mirror lens.

In addition, the reflective coating layer may be formed by depositing aluminum (Al), silver (Ag), or gold (Au).

Applying the manufacturing method according to the present invention can achieve the effect of manufacturing a pin mirror lens that can be applied to a high-quality AR optical engine.

1 is an injection process flow chart for manufacturing the lens of the present invention.
2 is an exemplary view showing a bonding structure of a pin mirror lens.
3 is a result of measuring the reflectance according to the material of the reflective coating layer.

Hereinafter, the present invention will be described in detail.

The manufacturing method of the pin mirror lens according to the present invention comprises the steps of manufacturing a pin mirror lens by melting and injection molding a lens material, forming a reflective coating layer on the surface of the pin mirror lens, and a post-process on the surface of the pin mirror lens Coating, characterized in that it comprises the step of bonding the pin mirror lens.

The fin mirror lens is manufactured by injection molding by dividing the upper part and the lower part to form a fin structure, and then bonding them.

A step of manufacturing a pin mirror lens by melting and injection molding the lens material with reference to FIG. 1 will be described as follows.

First, the molten lens material is injected into the mold in a closed state (Fig. 1(a)) to fill it (Fig. 1(b)). The mold is cooled to harden the injected lens material (FIG. 1(c)), the mold is opened (FIG. 1(d)), and when the mold is heated, the manufactured pin mirror lens is released (FIG. 1) (e)). After that, by closing the heated mold, the state of FIG. 1(a) is made, and the process of manufacturing the lens again is repeated.

Since the pin mirror lens requires high processing precision, it is essential to select a lens material and design a mold material and design in consideration of releasability. In addition, since the lens manufactured by the extrusion molding is divided into an upper part and a lower part, the upper part and the lower part must be joined as shown in FIG. 2 , and in this case, permeability, adhesion, and reliability are required.

As the lens material, a cycloolefin polymer (COP) or a glass material may be used. An example of this is Zeonex's E48R. The ER48R has a glass transition temperature of 139 ° C, a molten resin temperature of 265 to 295 ° C, and a molding temperature of 95 to 135 ° C. Therefore, a material suitable for applying the manufacturing method of the present invention appeared to be

In addition, the lens molding process using the lens material in the present invention can improve the manufacturing efficiency of the lens depending on the material of the mold. As such a mold, a plastic mold steel can be used. Specifically, carbon steel SM45C is used as the plate forming the mold, any one of the plastic mold steels HP1-A, HP-4A, and HP-4MA is used as the mold base, and XPM, stavax, P20, It was found that if a mold was manufactured using either STD61 or moldmax, defects in the molding and releasing process of the lens material could be minimized.

The method for manufacturing the mold may be manufactured by designing the mold core, processing the mold core, checking the shape value of the manufactured mold, correcting the shape, and surface coating the manufactured mold core. In this case, it is preferable to use a diamond trunning machine (DTM) for ultra-precision processing of the mold core. In addition, the shape degree and surface roughness of the mold are analyzed using analysis devices such as FTS and UA3P. In addition, a release film is formed by coating the mold core, and it was found that, when the lens material is used, defects such as fusion to the mold or cumori phenomenon do not occur.

As a result of evaluating the moldability of the mold made of the tungsten carbide material applied to the manufacturing method of the present invention, it was found that the mold release reactivity was good and internal defects were not observed and thus had excellent physical properties.

The pin mirror lens manufactured by the manufacturing method of the present invention can correspond to an ultra-high-definition (4K) image display device and should be applied to an optical engine of a compact size, high angle of view, high resolution, and high transmittance, specifically manufactured according to the present invention In case of applying a pin mirror lens that has been applied to the optical engine, the viewing angle of the optical engine is 80° or more, 4K resolution is supported, the external light transmittance is 80% or more, the angular resolution is 45 PPD or more, the perspective image astigmatism is 0.125 or less, and the virtual It has been shown that an optical engine with an image color distortion CIExy of 0.1 or less can be obtained. In addition, it has been shown that such a pin mirror lens has a mirror shape precision of 5 μm or less and very precise processing is possible.

The pin mirror lens manufactured by the extrusion molding needs to form a reflective coating layer on the surface, and the reflective coating layer may be formed by depositing aluminum (Al), silver (Ag), or gold (Au).

As a material of the reflective coating layer, aluminum, silver, and gold were deposited and the results of measuring the internal reflectance are shown in FIG. 3 . Referring to the results of FIG. 3 , when aluminum was deposited, high reflectance was exhibited in a wide wavelength range from 200 nm to 5 μm. On the other hand, silver and gold showed high reflectance in wavelength bands of 500 and 600 nm or more, respectively. Therefore, it has been shown that it is most preferable to form a reflective coating layer by depositing aluminum in order to secure reflectivity in a broad band. appear.

After the reflection coating layer is formed on the surface of the pin mirror lens, a post-process coating may be performed on the surface of the pin mirror lens. The post-process coating is an optical coating using an ion beam, and can greatly improve the efficiency of the fin mirror lens by reducing the transmission of the visible light region to 1% or less. In addition, it is possible to manufacture a pin mirror lens without deterioration of optical properties according to the external environment by performing an anti-fog coating treatment in the post-processing coating.

After the post-process coating, the pin mirror lens is divided into an upper part and a lower part as shown in FIG. 2, and this is because it is difficult to manufacture a pinhole by injection molding. By bonding the upper and lower parts of the lens, a pinhole-formed pin-mirror lens is completed. Therefore, it is preferable to use a UV-curable adhesive for the bonding process. A commercially available product such as Norland Optical Adhesive may be used as the UV-curable adhesive.

It was found that the optical engine to which the pin mirror lens manufactured by the manufacturing method of the present invention is applied satisfies all the performance levels required in the optical system for realizing augmented reality and can be applied to various types of augmented reality devices. These performance levels are defined as follows.

First, the viewing angle is the angle between the user's eyes and the top, bottom, left, and right end points of the virtual screen when the user looks at the virtual screen image from the front center of the screen, and is obtained by measuring the angles in the horizontal, vertical, and diagonal directions.

In addition, the resolution is an index indicating the level of detail of the display, and is determined by the number of pixels arranged horizontally and vertically on the screen.

In addition, the external light transmittance is obtained by dividing the intensity of the transmitted light incident on the lens by the intensity of the incident light.

In addition, the weight of the optical system is determined based on the total weight of the optical system including the optical lens, the light source, and a structure supporting the same, and a monocular standard.

In addition, each resolution is obtained by dividing the number of pixels observed within a standard viewing angle of 10 degrees in the horizontal direction of the center of the screen by 10.

In addition, perspective image astigmatism is obtained from the difference in refractive power in the vertical and horizontal directions of the real image observed due to the distortion of the augmented reality lens.

In addition, the virtual image color distortion is obtained from the difference between the CIE 1931 color coordinates of the white box area measured at the reference position of the panel and the color coordinates of the corresponding image measured at the reference position of the virtual image.

In addition, the mirror shape precision is obtained from the degree to which the lens pin mirror shape deviates from the design.

In addition, the PMD measurement precision/measurement time is obtained from the measurement precision and measurement time through the phase measurement deflection method, which measures the deformation of the reflected pattern without forming a pattern on the sample surface.

Based on these performance indicators, it is possible to observe images with a viewing angle of 30 degrees for HDTV recommended by SMPTE (Movie/Television Engineers Association) and a 36-degree viewing angle recommended by THX, a company specializing in high-quality movie equipment, within the horizontal rotation range of the head and eyes within about 100 degrees. When measuring the viewing angle under the available conditions, when the pupil of the camera system is rotated based on the eye relief, the vertical and horizontal rotation angles that see the horizontal and vertical edges of the virtual image are measured and defined as the vertical and horizontal viewing angles, and the measured vertical , the horizontal viewing angle is converted to a diagonal viewing angle through the Pythagorean theorem. The focal length of the camera is fixed as the focal length of the virtual image. It was found that the angle of view of the camera can implement a viewing angle of 2 degrees or more.

In addition, as a result of measuring the resolution through the minimum number of pixels to provide a high-definition image having an angular resolution of 45 PPD or more at the viewing angle, it was found that the resolution was excellent.

In addition, it is possible to obtain the minimum angular resolution value that can be recognized by a person with normal vision of 0.75 or more, and when obtaining the astigmatism of the perspective image from the difference in refractive power in the vertical and horizontal directions of the real image observed due to the distortion of the augmented reality lens, good optics characteristics were shown.

In addition, good optical properties were also confirmed from the result of measuring the color distortion of the virtual image through the difference between the CIE 1931 color coordinates of the white box area measured at the reference position of the panel and the color coordinates of the image measured at the reference position of the corresponding virtual image. .

The present invention described above is not limited by the above-described embodiments, and various substitutions, modifications, and changes are possible within the scope without departing from the technical spirit of the present invention. it is clear to one

Claims (2)

manufacturing a pin mirror lens by melting and injection molding the lens material;
forming a reflective coating layer on the surface of the pin mirror lens;
applying a post-process coating to the surface of the pin mirror lens;
bonding the pin mirror lens;
Method of manufacturing a pin mirror lens comprising a.
The method according to claim 1,
The reflective coating layer is a method of manufacturing a pin mirror lens, characterized in that formed by depositing aluminum (Al), silver (Ag), or gold (Au).

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