KR101195747B1 - Blocker having optical system using grinding lens - Google Patents

Abstract

 In attaching a block pad to a raw spectacle lens, a blocker having an improved image measuring efficiency by obtaining an image of the spectacle lens using an optical system including a grinding lens is disclosed. The blocker may include a light source for irradiating incident light to a lens to be measured; A grinding lens for scattering incident light irradiated from the light source and irradiating uniform diffused light to the retreat lens; A lens image photographing optical system configured to generate the diffused light while passing through the lens under measurement, and receive the measurement light including image information of the lens under measurement, and obtain an image of the lens under measurement; And a lens image detector for detecting an image of a lens under measurement obtained by the lens image photographing optical system.

Description

Blocker with optical system using grinding lens

The present invention relates to a blocker, and more particularly, to attach a block pad to a raw spectacle lens, by using an optical system including a grinding lens to obtain an image of the spectacle lens, thereby improving the efficiency of image measurement. It's about Kerr.

Glasses for correcting a user's vision are manufactured by fitting a lens for correcting vision to a spectacle frame of a predetermined shape. In order to manufacture a lens for correcting vision, the external shape of a lens (commonly referred to as a 'lens blank') sold in a round shape must be processed (polishing) into the shape of a spectacle frame. In such a lens processing, the lens is fixed to a desired size and shape by fixing a pair of axes on both sides of the lens and contacting the side surfaces of the lens with a high-speed rotating diamond wheel while adjusting the position of the axis. Processing. At this time, in order to prevent the shaft and the lens from slipping, the lens is attached to a block pad using a blocker. To attach the block pad to the lens, the blocker detects the shape of the spectacle frame and displays the detected shape of the spectacle frame on the lens. Next, the shape of the lens to be processed around the user's pupil is determined by referring to various optical marks (such as a point) on the lens, the state, position, and size of the lens and the eyeglass frame, and automatically Or attach the block pad manually. Accordingly, the blocker includes an optical system composed of an illumination system for irradiating incident light onto the lens, an image camera for capturing a lens image, and the like, in order to obtain external shape information of the lens.

1 is a view for explaining an optical system structure used in a conventional blocker. As shown in FIG. 1, in a typical blocker, the outgoing light 3 emitted from the light source 5 passes through a beam splitter 4 and is reflected by the mirror 2 to be measured. (9) The following retroreflective plate 1 is reached. The outgoing light 3 is incident on the retroreflective plate 1 and then reflected to form the reflected light 8. The reflected light 8 has an image of the lens 9 to be measured, and the outgoing light 3 traveling path. Proceeding in the reverse direction, the reflection is reflected by the beam splitter 4 and is imaged by the video camera 6. The video image of the lens 9 to be imaged thus formed is detected using a detector 7 at the rear of the video camera 6.

In the optical system, the retroreflective plate 1 plays a role of illumination in which light is returned, and FIG. 2 is a view for explaining the structure of the retroreflective plate 1 shown in FIG. 1. As shown in FIG. 2, the retroreflective plate 1 has a plurality of glass beads 21 having a diameter of about 20 to 50 μm in a planar arrangement, and a reflective material under the glass beads 21. (22) has a coated structure. The glass bead 21 is a kind of ball lens, which functions as a convex lens that collects incident light, and the reflective material 22 reflects the incident light so that the original beam enters. Function to send back. That is, the retroreflective plate 1 serves to return the exiting light 3 back to the light source 5, and the exiting light 3 is refracted in the glass bead 21, and in the reflective material 22. Reflected light 8 reflected and reflected by the reflective material 22 is refracted by the glass bead 21 again to return to the light source 5 direction substantially parallel to the traveling direction of the incident light 3. That is, the mark 25 or the shape information of the lens 9 is received by the incident light 23 and the reflected light 24 blocked by the mark 25 formed on the lens 9 or the shape of the lens 9. As a result, the retroreflective plate 1 serves as diffuse illumination for obtaining an image of the lens 9.

The retroreflective plate 1 serves as diffuse illumination having a uniform illuminance, and in order to image the lens image to the image camera 6 and the detector 7 at a desired resolution without losing lens image information, the retroreflective plate The glass beads 21 of (1) must be tightly and uniformly distributed and must not only have a small particle size of, for example, 20 to 35 [mu] m to be similar to the resolution of the detector 7, but also a reflective material. (22) is to be uniformly coated on the bottom of the glass beads (21). If a part of the glass bead 21 does not exist or the reflecting material 22 does not exist below the glass bead 21, the reflected light 8 may not be properly generated at such a defective part, and the part may be used as a lens. The wrong lens image represented by the mark 25 formed on the lens 9, such as the point of incidence, can be obtained.

In addition, in order to manufacture such a conventional retroreflective plate 1, glass beads 21 having a small size (20 to 35 μm) must be manufactured using glass, and the glass beads 21 are attached to the retroreflective plate 1. In order to distribute evenly and seamlessly, not only expensive special injection equipment should be used, but also the glass bead 21 is injected into the worker's respirator through breathing because the spraying process of the glass beads 21 is performed in a closed space. There is a disadvantage in that the working environment is poor. As described above, since it is difficult to form the glass beads 21 of the retroreflective plate 1 minutely and uniformly, the optical system is configured such that the retroreflective plate 1 is rotated, thereby solving the problem caused by the nonuniformity of the glass beads 21. Reducing methods are also used, but even in this case, there are disadvantages such as complicated apparatuses and increased manufacturing costs.

Accordingly, an object of the present invention is to provide a blocker having an optical system capable of uniformly illuminating the entire measurement range of the lens under measurement without using a retroreflective plate. Another object of the present invention is to provide a blocker having an optical system which is easy to align the optical system and which can measure the optical characteristics and the image of the lens simply and efficiently. Still another object of the present invention is to provide a blocker having an optical system whose structure of the optical system is simple and which can be easily manufactured at low cost.

In order to achieve the above object, the present invention, a light source for irradiating incident light to the lens to be measured; A grinding lens for scattering incident light irradiated from the light source and irradiating uniform diffused light to the retreat lens; A lens image photographing optical system configured to generate the diffused light while passing through the lens under measurement, and receive the measurement light including image information of the lens under measurement, and obtain an image of the lens under measurement; And a lens image detector for detecting an image of a lens under measurement obtained by the lens image photographing optical system.

The blocker according to the present invention has an optical system capable of uniformly illuminating the entire range of the lens under measurement without the use of a retroreflective plate, easy alignment of the optical system, and simple and efficient display of optical characteristics and images of the lens. It can be measured by Accordingly, the blocker according to the present invention not only can accurately measure optical characteristics with respect to various kinds of lenses to be measured, but also has an advantage that the structure of the optical system is simple, efficient, and small in volume.

1 is a view for explaining an optical system structure used in a conventional blocker.
2 is a view for explaining the structure of the retroreflective plate shown in FIG.
3 is a view for explaining the structure of the optical system of the blocker according to an embodiment of the present invention.
4 is a view showing the structure of a grinding lens used in a blocker according to an embodiment of the present invention.
5 is a view showing the structure of a lens imaging optical system used in the blocker according to an embodiment of the present invention.

Hereinafter, with reference to the accompanying drawings, the present invention will be described in detail.

3 is a view for explaining the optical system structure of the blocker according to an embodiment of the present invention. As shown in FIG. 3, the optical system of the blocker according to the present invention includes a light source 30, a grinding lens 32, a lens imaging optical system 40, and a lens imaging detector 50. The light source 30 is an illumination means for irradiating the incident light 62 to the lens 60 to be measured. For example, a conventional white light emitting diode (LED) may be used as the light source 30.

The grinding lens 32 scatters the incident light 62 irradiated from the light source 30, and serves to irradiate the illumination lens 60 with uniform illumination 64. 4 shows the structure of a grinding lens 32 that can be used in the blocker of the present invention. As shown in FIG. 4, if necessary, an anti-reflective coating layer 34 is formed on the side surface of the grinding lens 32 in the direction of the light source 30, and the incident light 62 radiated from the light source 30 is formed . According to the divergence angle of, the loss of the amount of incident light can be reduced. Usually, in the case of the lens 32 in which the antireflective coating layer 34 is not formed, a certain amount of loss occurs before the incident light 62 is refracted through the lens 32. That is, since the sum of the reflection amount and the transmission amount is the same as the total amount of the beam before entering the lens 32, that is, the incident light 62, if the antireflective coating is applied to the portion where the beam enters the lower end of the grinding lens 32, Since the loss can be reduced, the amount of permeation increases. In addition, a grinding layer 36 is formed on a side opposite to the light source 30 of the grinding lens 32, that is, in the direction of the lens 60 to be measured, and incident light 62 is incident on the grinding layer 36. ) Is diffusely reflected to form uniform diffused illumination, that is, diffused light 64 and irradiated to the lens under measurement 60. The grinding layer 36 is a surface on which the upper surface of the grinding lens 32 is ground to form irregularities such that the light source 30 is not visible through the grinding lens 32. The incident light 62 is scattered on the surface which is grind | pulverized like white paper, and the diffused light 64 is formed. The grinding layer 36 refers to a surface on which irregularities having a height of 5 to 20 μm are formed uniformly at a height and a spacing, so as to scatter light. Therefore, when the incident light 62 emitted from the light source 30 enters the coating layer 34 at the bottom of the grinding lens 32 and reaches the grinding layer 36 at the top of the grinding lens 32, the ground upper curvature surface is ground. Diffuse reflection occurs at, and is converted into uniform diffused light 64 from the grinding lens 32 and irradiated to the lens under measurement 60 as if it had self-illumination.

Here, the light source 30 is preferably located at the focal length of the curvature of the grinding lens 32 in the direction of the light source 30. When the light source 30 is positioned at the focal length of the curvature of the grinding lens 32, the incident light 62 uniformly spreads to the edge of the grinding lens 32, and the diffused light 64 incident on the lens 60 to be measured. Since the intensity of the light is less affected by the brightness depending on the angle of the incident light 62 and the loss of the amount of light is also reduced, it is preferable. That is, when the light source 30 is positioned at a position shorter than the focal length of the grinding lens 32, the beam reaching the grinding lens 32 is further diffused to the edge, so that the distribution of light quantity is not uniform, and the center portion is The edges are bright and the edges are dark so that no uniform illumination can be obtained. On the contrary, even if the light source 30 is far from the focal length of the grinding lens 32, the rough surface which made the beam uniform can not be obtained. In addition, since the curvature change of the light source 30 and the lens 60 direction of the grinding lens 32 may be variously designed according to the material of the grinding lens 32, the incident light 62 may be collected more efficiently. And more uniform diffused light 64 can be obtained. Referring again to FIG. 3, as the diffused light 64 output from the grinding lens 32 passes through the lens 60 to be measured, that is, the lens 60 to be measured is illuminated by the diffused light 64. The measurement light 66 including the image information of the lens 60 to be measured is emitted from the lens 60 to be measured. The lens image emitted from the lens 60 under measurement is reflected by the reflection mirror 38 as necessary, and is incident on the lens image photographing optical system 40.

The lens image formed by the lens 60 to be measured is based on the diffused light 64 scattered by the grinding lens 32, and the optical appearance of the lens 60 or the various lenses displayed on the lens 60 to be measured. Includes image information of markers (such as points). The lens image capturing optical system 40 receives the measurement light 66 including the image information of the lens 60 under measurement, and generates an image of the lens 60 under measurement. 5 is a view showing the structure of a lens imaging optical system 40 that can be used in the blocker of the present invention. As shown in FIG. 5, the lens imaging optical system 40 includes a lens 42 for diffusing or focusing the measurement light 66 and / or an aperture 44 for passing only a desired portion of the lens image. The lens image is enlarged, reduced, and partially passed as necessary. At the rear end of the lens image capturing optical system 40, a lens image detector 50 for detecting an image of the lens 60 under measurement obtained by the lens image capturing optical system 40 is provided. The lens image detector 50 may be installed to be movable so that the distance between the lens image detector 50 and the lens image capturing optical system 40 may vary.

In general, when the lens image is enlarged 2 times, the lens image formed by the detector 50 is enlarged 2 times to obtain an enlarged image, but in this case, the resolution of the image is deteriorated. On the other hand, the lens imaging optical system 40 of the present invention adjusts the position and size of the aperture 44 (eg, up and down direction in FIG. 5) and the position of the detector 50 (eg, horizontally in FIG. 5). Direction) to adjust the position of the lens image or the size of the image to be photographed. That is, unlike a normal zoom lens in which the lens portion moves, the position and size of the aperture 44 and the position of the detector 50 vary, so that an image of a desired portion is obtained, the obtained image is enlarged, and the desired area is more precisely. You can shoot (partial). Accordingly, the optical characteristics of the lens 60 to be measured may be variously measured by using images of portions having different characteristics. In this way, by changing the positions and sizes of the diaphragm 44 and the detector 50, the information of the lens 60 to be measured can also be obtained twice or more.

Therefore, the lens image photographing optical system 40 does not further include an additional optical device, and changes the postfocal distance formed by the optical system 40 and the detector 50, so that the lens 60 may be Since the image can be produced, various optical characteristics of the lens 60 to be measured can be measured. For example, by changing the image distance and the image distance of the lens 60 to be measured and the lens image photographing optical system 40, and moving the detector 50, the desired image is not simply enlarged by 2 times, but rather from the lens image. More than one information can be obtained, that is, the characteristics of a multifocal lens having complicated optical characteristics such as a progressive lens can be easily measured.

As described above, in the optical system of the blocker according to the present invention, since the light source 30 directly serves as the illumination of the grinding lens 32, there is an advantage in that the optical axis alignment is easy due to the structure of the optical system. In addition, by moving the optical system 40 and the detector 50 to change the position where the image of the optical system is imaged, not only various image information can be obtained, but also a low-cost CMOS sensor is used as the detector 50, (44) can be used to improve the quality of the image. In the blocker of the present invention, except for the above-described optical system, the configuration, for example, the mechanical configuration for attaching the block pad and the like, is the same as the conventional blocker, and examples of such a blocker are described in Patent Application No. 10-2006-. It is disclosed in detail in 0136355, the entire contents of which are incorporated herein by reference. As described above is only one embodiment of a blocker according to the present invention, the present invention is not limited to the above embodiment, and includes all various modifications that can be carried out by those skilled in the art. do.

Claims (6)

A light source for irradiating incident light to the lens under measurement;
A grinding lens for scattering incident light irradiated from the light source and irradiating uniform diffused light to the lens under measurement;
A lens image photographing optical system configured to generate the diffused light while passing through the lens under measurement, and receive the measurement light including image information of the lens under measurement, and obtain an image of the lens under measurement; And
An optical system including a lens image detector for detecting an image of a lens under measurement obtained by the lens image photographing optical system,
A grinding layer that diffusely reflects the incident light to form uniform diffused light is formed on the side of the lens lens to be measured to be measured, and the grinding layer has irregularities having a height of 5 to 20 μm. Blocker provided with an optical system using a grinding lens. delete delete The blocker with an optical system using a grinding lens according to claim 1, wherein an antireflective coating layer is formed on the light source direction side surface of the grinding lens. The blocker according to claim 1, wherein the lens image photographing optical system includes an aperture through which only a desired portion of the lens image is passed by movement. delete

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