JP3802319B2 - Lens holding device for image pickup device for spectacle lens - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a lens holding device suitable for use in a spectacle lens, particularly a progressive multifocal lens or a spectacle lens image capturing apparatus that images a multifocal lens.
[0002]
[Prior art]
When an unprocessed spectacle lens (hereinafter referred to as a lens) is attached to a spectacle frame desired by the wearer, the lens is trimmed in accordance with the shape of the spectacle frame. At that time, processing is generally performed with the eye point as the processing center so that the center (eye point) of the wearer's pupil coincides with the eye point of the lens. Since the eye point of the lens cannot be displayed directly on the lens surface, in the design of lenses, especially progressive multifocal lenses, a mark called a hidden mark is displayed at a reference position that is a predetermined position away from the geometric center. The position of the hidden mark is used as a reference so that the geometric center of the lens, the distance, the optical center of the near portion, the position of the eye point, and the like can be derived. Normally, the hidden mark is formed in the form of a minute protrusion (for example, about 2 to 4 μm) on the convex surface of the lens at the time of molding.
[0003]
FIG. 4 shows a raw progressive multifocal lens. 1 is a progressive progressive lens made of plastic, 2 is a horizontal reference line (passing through the geometric center O), 3A and 3B are hidden marks, and are equidistant (for example, 17 mm) from the geometric center O on the horizontal reference line 2 It is formed in two places. These hidden marks 3A and 3B are displayed with the same small circle or small circle and letters, and the addition power of the lens 1 (the outer vertex refractive power of the distance portion and the outer portion of the near portion is displayed under each mark. The number 4 for displaying the difference in vertex refractive power and the identification mark 5 for displaying the lens type are also displayed in the form of minute protrusions. The number 4 indicating the addition power is displayed as a three-digit number (for example, 300) under the hidden mark located on the ear side when worn. Therefore, it is possible to identify whether the lens is a left-eye lens or a right-eye lens by knowing whether the three-digit number is displayed below the left or right hidden mark. In this case, FIG. 4 shows a lens for the right eye, and one hidden mark 3A is indicated by a small circle “◯” and the other hidden mark 3B is indicated by a Roman letter “H”.
[0004]
6 is a distance power measurement part, 7 is a near power measurement part, 8 is a part looking far away (distance part), 9 is a part looking near (near part), and 10 is a part whose power changes continuously ( (Progression part), 11 is the position of the eye point. The positions of the distance power measurement portion 6, the near power measurement portion 7 and the eye point 11 vary depending on the lens design, and a predetermined reference position away from the geometric center O, for example, the eye point 11 is above the geometric center O. The distance center 12 is determined in advance at a position separated by a predetermined distance d1 (for example, 2 mm), and the distance center 12 is previously positioned at a position separated by a predetermined distance d2 (for example, 4 mm) from the position of the eye point 11.
[0005]
When the position of the eye point 11 is found from the hidden marks 3A and 3B, the eyeglass store usually finds the hidden mark by visual observation or optically detects it. In the case of visual observation, the lens 1 is held over a light source such as a fluorescent lamp to find the hidden marks 3A and 3B, and the position is marked with a marker. Then, the lens 1 is a sheet for a progressive multifocal lens called a remark chart. Place on top. The remark chart is a full-scale progressive multifocal lens that displays the position of the hidden mark, the geometric center, the distance power measurement part, the near power measurement part, and the eye point position for each lens type. . When the lens 1 is placed on the remark chart, the hidden mark displayed on the remark chart placed on the same type of lens as the lens and the positions of the hidden marks 3A and 3B marked on the lens 1 And the position of the eye point displayed on the remark chart is displayed on the convex surface of the lens 1 with a marker. Then, usually, a processing jig (lens holder) is attached to the position of the marked eye point 11 to trim the lens 1 so that the outer shape matches the frame shape of the spectacle frame.
[0006]
As a method for optically detecting the hidden marks 3A and 3B and positioning the lens and the lens holder, for example, JP-A-8-297262 (hereinafter referred to as Prior Art 1), JP-A-11-295672 (hereinafter referred to as JP-A-11-295672). 2. Description of the Related Art A lens alignment method and apparatus disclosed in Prior Art 2) are known. Prior art 1 arranges a projection type position display means provided with an alignment mark at a predetermined position on the convex surface side of the lens, and irradiates illumination light toward the lens from the rear of the position display means to The projected image of the alignment mark is projected onto the projected image display means arranged on the concave surface side of the lens. Then, the position of the lens is determined by adjusting the position of the lens so that the relative position between the projected image of the hidden mark and the projected image of the alignment mark has a predetermined positional relationship.
[0007]
Prior art 2 performs lens alignment from the positional relationship and positional information of alignment marks (hidden marks, addition power) provided on the convex surface side of the lens, and an illumination adjustment lens between the illumination device and the lens. The lens is illuminated from the concave surface side through the illumination adjustment lens by the light emitted from the illumination device, the convex surface image is captured by an image input means such as a CCD, and the captured image is captured by the image processing device. By performing image processing, alignment marks are detected, and the calculation is performed based on the positional relationship and positional information of these marks so that the direction of the horizontal reference line of the lens and the optical center position are in a predetermined positional relationship. Based on this, the lens 1 is aligned.
[0008]
In the design of the multifocal lens, since the hidden mark is not displayed unlike the progressive multifocal lens 1 described above, the geometric center and the position of the eye point can be obtained on the basis of the upper edge of the small ball. Yes.
[0009]
FIG. 5 shows a plastic bifocal lens 13 for the right eye, 13A is a ball, 13B is a small ball, 14 is a distance power measurement unit, 15 is the center of the near power measurement unit, O is the geometric center, Reference numeral 16 denotes the position of the eye point. In the case of a plastic lens, the small ball 13B is formed on the surface of the base ball 13A so as to protrude in a wedge shape when viewed from the side, and its upper edge 17 is a predetermined distance below a horizontal reference line 18 (through the geometric center). It is formed so as to be separated by d3 (for example, 5 mm). In the case of the right-eye lens, the small ball 13B is formed such that the center 14 of the near vision power measuring unit is shifted from the geometric center O to the right by a predetermined distance d4 (for example, 5 mm). The position of the eye point 16 is determined at a position shifted from the geometric center O to the small ball 13B side by a predetermined distance d5 (for example, 2.5 mm) on the horizontal reference line 18. Therefore, the position of the geometric center O and the eye point 16 can be obtained by visually or optically finding the center of the upper edge 17 of the small ball 13B. In the case of visual observation, a remark chart for a multifocal lens is used in the same way as the progressive multifocal lens 1, and in the case of optical detection, the lens positioning method disclosed in the prior arts 1 and 2 described above and its An apparatus can be used.
[0010]
[Problems to be solved by the invention]
In the progressive multifocal lens 1, the method of finding the position of the eye point 11 from the positions of the hidden marks 3A and 3B using the remark chart and marking the position depends on the manual work of the deceased, and therefore has a large error. was there. Similarly, the multifocal lens 13 has a problem that the error is large for the same reason.
[0011]
In the lens positioning method according to the prior arts 1 and 2 described above, since the projection image of the upper edge 17 of the optically hidden marks 3A and 3B and the small balls 13B is displayed on the projection image display means, a remark chart is used. There is an advantage that the positions of the eye points 11 and 16 can be obtained more accurately than the above. However, there has been a problem in supporting the lens during projection. That is, since the prior arts 1 and 2 both use a transparent glass plate 22 as shown in FIG. 6 and the lens is placed on the concave side thereof, the plus lens A is placed thereon. The height of the convex surface is greatly different between when the minus lens B is placed. For example, the difference in height d between the convex surfaces of the minus lens B of −10D (diopter) and the plus lens A of −6D is 11.3 mm. For this reason, the depth of focus of the optical system must be increased, and as a result, the projected image becomes dark and it becomes difficult to distinguish the hidden marks 13A and 13B and the upper edges of the small balls. Further, if the lens is supported by the glass plate 22, the irradiation light from the light source is reflected on the front and back surfaces to cause halation, which is not practical.
[0012]
The present invention has been made to solve the above-described conventional problems. The object of the present invention is to hold the central portion of the concave surface side of the lens by suction so that the lens can be held stably and reliably, and the depth of focus. It is an object of the present invention to provide a lens holding device for an image pickup apparatus for spectacle lenses that can design a small optical system, obtain a bright and easy-to-see projection image, and prevent the occurrence of halation.
[0013]
[Means for Solving the Problems]
In order to achieve the above object, the present invention provides an optical position of a lens by optically detecting a hidden mark or a small ball of the multifocal lens formed at a predetermined position away from the geometric center of the progressive multifocal lens. A lens holding device used in an image pickup device for spectacle lenses that calculates information, and includes an upper optical element that opens and closes an upper end opening and a lower optical element that closes a lower end opening. A lens barrel that forms an evacuation chamber by being incorporated, a lens support tube that is open at both ends projecting from the center of the upper surface of the upper optical element, and that is provided through the center of the upper optical element. A communication hole that communicates the vacuum exhaust chamber of the cylinder and the central hole of the lens support cylinder, the vacuum exhaust chamber of the lens barrel, the communication hole of the upper optical element, and the central hole of the lens support cylinder; Yo An evacuation device for adsorbing and fixing the central portion of the lens to the upper end opening of the lens support cylinder, and the lens support cylinder is an outside that is sufficiently small so as not to obstruct the imaging of the hidden mark or small ball of the lens. It has a diameter .
[0014]
The center of the concave surface of the lens is placed on the upper surface opening of the lens support tube and fixed by suction. Therefore, even with a positive or negative lens, the convex surface is higher than when supporting the outer peripheral edge of the concave surface. The size does not change greatly. Therefore, an optical system with a small depth of focus can be used, and a bright and easy-to-see projection image can be obtained. Further, since the lens is sucked and fixed to the upper surface opening of the lens support cylinder by evacuating the inside of the lens barrel and the lens support cylinder, the lens can be fixed stably and reliably. By using a lens support cylinder whose radius is smaller than the distance from the horizontal reference line to the small ball, the small ball or the hidden mark is not blocked when the lens is irradiated with light from the light source. Since a lens support tube is used instead of a flat glass plate, halation can be prevented. A convex lens or the like is used as an optical element incorporated in the lens barrel.
[0015]
Hereinafter, the present invention will be described in detail based on embodiments shown in the drawings.
FIG. 1 is a schematic view showing an embodiment of an image pickup device for spectacle lenses provided with a lens holding device according to the present invention, and FIG. 2 is a sectional view of the lens holding device. In these figures, an image pickup device 30 for spectacle lenses includes a light source 31 that irradiates a progressive multifocal lens (hereinafter also referred to as a lens) 1 and a condenser lens disposed in an optical path between the light source 31 and the lens 1. 32, a diaphragm 33, a half mirror 34, a lens holding device 36 for adsorbing and fixing the lens 1, an image of hidden marks 3A and 3B formed on the convex surface a of the lens 1 and an addition power 4 (see FIG. 4). A rotating screen 37, and condensing lenses (plano-convex lenses) 38 and 39 and a projection lens 40 disposed between the rotating screen 37 and the lens 1. Also, an imaging device (projection image display means) 41 such as a CCD that captures the images of the hidden marks 3A and 3B that are reflected back upon the rotary screen 37, and an image processing device 42 that performs image processing on the image from the imaging device 41, A light source 43 for irradiating the multifocal lens 13 (FIG. 5), and a vacuum exhaust device 45 such as a vacuum pump for vacuum exhausting the lens holding device 36.
[0016]
The lens 1 is the same as the progressive multifocal lens shown in FIG. 4, and has two hidden marks 3A and 3B formed at predetermined positions on the convex surface a and the addition power displayed under one hidden mark 3A. It has the number 4 to display. The hidden marks 3A and 3B are formed at reference positions that are equidistant (17 mm) on both sides of the geometric center O on the horizontal reference line 2 as described above, and the interval L is, for example, 34 mm.
[0017]
As the light source 31 used for imaging the lens 1, in order to obtain a sharp image of the hidden marks 3A and 3B, the number 4 indicating the addition power, and the identification mark 5, for example, an LED that emits red light with a narrow wavelength width is used. The lens 1 is disposed on the convex surface a side. As the half mirror 34, for example, one having a transmittance to reflectance ratio of 7 to 3 is used, and the imaging device 41 is disposed correspondingly. The rotating screen 37 has a reflective sheet in which a fine powder such as glass or aluminum is applied to the surface in order to increase the reflectance. Further, in order to make the brightness of the surface uniform, the motor 47 rotates at high speed (for example, 3400 rpm) to project an image of the convex surface a of the lens 1. When this image is reflected by the rotary screen 37, it returns to the original optical path and is reflected by the half mirror 34, thereby forming an image on the light receiving surface of the imaging device 41.
[0018]
As the light source 43 used for imaging of the multifocal lens 13, a red LED is used, and for example, eight LEDs are arranged at equal intervals in the circumferential direction near the outer periphery below the imaging lens 40. . When the multifocal lens 13 is imaged, a focus correction lens 48 is disposed between the half mirror 34 and the imaging device 41. The reason why the light source 43 is arranged on the imaging lens 40 side and the concave surface side of the lens 13 is irradiated is that the shadow of the upper edge 17 of the small ball 13B can be clearly imaged compared to the case of irradiation from the convex surface side. Because.
[0019]
When the image processing device 42 captures the image of the convex surface a of the lens 1 from the imaging device 41, the image processing device 42 performs image processing to detect the hidden marks 3A and 3B and the addition power 4. Further, the geometrical center O of the lens 1, the position of the eye point 11 (FIG. 4), and the like are calculated from the position information of these hidden marks 3A and 3B.
[0020]
In FIG. 2, the lens holding device 36 includes a lens barrel 50 whose both ends are open, the plano-convex lenses 38 and 39 that close the upper end opening 51 and the lower end opening 52 of the lens barrel 50, and these flat lenses. Ring-shaped lens holders 53, 54, 55 for fixing the convex lenses 38, 39, O-rings 56, 57 interposed between the plano-convex lens 38 and the lens holder 53 and between the plano-convex lens 39 and the lens holder 54, respectively. Etc. A sealed space surrounded by the inner peripheral surface of the lens barrel 50 and the plano-convex lenses 38 and 39 forms a vacuum exhaust chamber 58 and is connected to the vacuum exhaust device 45 through a pipe 60.
[0021]
At the center of the outer surface of the upper plano-convex lens 38 that faces the outside of the lens barrel 50, a lens support cylinder 61 that is open at both ends is erected. The upper surface opening of the lens support tube 61 forms a lens placement surface 63 by placing the central portion of the concave surface b of the lens 1 via the O-ring 62. A communication hole 64 is formed in the center of the convex lens 38 so as to pass therethrough, and thereby the vacuum exhaust chamber 58 and the center hole 65 of the lens support tube 61 are communicated with each other. The lens support cylinder 61 has a sufficiently small outer diameter (for example, so as not to interfere with the imaging of the hidden marks 3A and 3B of the progressive multifocal lens 1, the number 4 indicating the addition power, and the small balls 13B of the multifocal lens 13). 8 mmφ). Reference numeral 66 denotes a nozzle that injects compressed air for blowing off dust adhering to the surface of the convex lens 38.
[0022]
In such an image pickup device 30, when detecting the hidden marks 3A and 3B of the progressive multifocal lens 1, the lens 1 is on the convex surface a and the central portion of the concave surface b is on the upper surface of the lens support tube 61. Place. Next, the inside of the vacuum exhaust chamber 58 and the lens support tube 61 is evacuated by the vacuum exhaust device 45, so that the lens 1 is adsorbed and fixed to the upper surface opening of the lens support tube 61. Thereafter, the surface of the lens 1 is irradiated with the irradiation light from the light source 31, and the images of the hidden marks 3 A and 3 B and the number 4 indicating the addition power are condensed by the condenser lenses 38 and 39, and are formed by the imaging lens 40. Project onto the rotating screen 37. The image projected on the rotating screen 37 returns to the original optical path by being reflected by the rotating screen 37, and is projected onto the light receiving surface of the image pickup device 41 when reflected by the half mirror 34. Then, the hidden image 3A, 3B is detected by taking this projection image into the image processing device 42 and processing the image, and the position thereof is calculated. Further, the position of the geometric center O, the eye point 11 and the like are obtained from the information of the hidden marks 3A and 3B by arithmetic processing. Then, the processing center, the mounting angle of the lens holder with respect to the lens, and the like are determined from the obtained lens information, lens frame shape data, and wearer's prescription data.
[0023]
When the upper edge 17 of the small ball 13B of the multifocal lens 13 shown in FIG. 5 is detected, the multifocal lens 13 is placed on the upper surface of the lens support tube 61 in the same manner as the progressive multifocal lens 1 described above and fixed by suction. To do. At this time, the light source 43 is used instead of the light source 31. Further, the focus correction lens 48 is inserted between the half mirror 34 and the imaging device 41 so that the focal point of the imaging device 41 coincides with the convex surface of the lens 13 and the light source 43 is turned on. The light emitted from the light source 43 strikes and is reflected by the rotating screen 37, and then passes through the imaging lens 40 and the projection lenses 38 and 39 to irradiate the multifocal lens 13 from the concave surface b side, and the image of the upper edge 17 of the small ball 13 </ b> B. Is reflected by the half mirror 34 and guided to the imaging device 41. Then, the upper edge 17 is detected by taking the image into the image processing device 42 and processing the image, and the position thereof is calculated. Further, the position of the geometric center O, the eye point 16 and the like are obtained from the position information of the upper edge 17 by arithmetic processing. Then, the processing center, the mounting angle of the lens holder with respect to the lens, and the like are determined from the obtained lens information, lens frame shape data, and wearer's prescription data.
[0024]
Here, in the present invention, since the central portions of the concave surfaces b of the progressive multifocal lens 1 and the multifocal lens 13 are sucked and fixed by the lens holding device 36, the lenses 1 and 13 can be securely fixed. In particular, even when the lens is a plus lens A and a minus lens B as shown in FIG. 3, the height difference d of the convex surface a can be reduced. For example, in the minus lens B of −10D and the plus lens A of + 6D, the height difference d of the convex surface “a” is 6.8 mm, which is approximately ½ compared with the case where the glass plate 22 shown in FIG. 6 is used. Can be. Therefore, the depth of focus of the optical system can be reduced, and a bright and easy-to-see projection image can be obtained. In addition, since the thin lens support cylinder 61 is used, a projected image can be obtained regardless of the position of the mark in any circumferential direction.
[0025]
Further, in the present invention, the hidden mark 3A, 3B of the lens 1 and the image of the number 4 indicating the addition power are not directly captured by the imaging device 41, but are projected on the rotating screen 37 and the image reflected by the rotating screen 37 is captured. Since the image is guided to the device 41, in the case of a lens having an astigmatic axis, the image twist due to the astigmatic axis can be canceled out, and image processing can be performed without particularly complicated correction.
[0026]
【The invention's effect】
As described above, the lens holding device of the image pickup device for spectacle lenses according to the present invention optically applies a hidden mark or a small ball of the multifocal lens formed at a predetermined position away from the geometric center of the progressive multifocal lens. A lens holding device used in a spectacle lens image pickup device that calculates optical position information of a lens by detecting an upper optical element that opens and closes an upper end opening and an upper optical element that opens the upper and lower ends, and a lower end side A lens barrel whose inside forms a vacuum evacuation chamber by incorporating a lower optical element that closes the opening, a lens support cylinder that is open at both ends and projects from the center of the upper surface of the upper optical element, and the upper optical element A communication hole provided through the center of the lens barrel and communicating with the vacuum exhaust chamber of the lens barrel and the central hole of the lens support tube, the vacuum exhaust chamber of the lens barrel, the communication hole of the upper optical element, and the label. A vacuum exhaust device that sucks and fixes the central portion of the lens to the upper end opening of the lens support tube by evacuating the center hole of the lens support tube, and the lens support tube Since the lens has a sufficiently small outer diameter so as not to interfere with imaging , the lens can be securely fixed, especially when detecting marks of progressive multifocal lenses of different types or small balls of multifocal lenses. The difference in surface height of the lens can be reduced as compared with the case where the lens is placed on a flat glass plate. Therefore, an optical system with a small depth of focus can be designed, and a bright and easy-to-view image can be obtained. In addition, since it is not placed on a flat glass plate using a thin glass support tube, halation does not occur and a clear image can be obtained.In particular, the lens processing center is determined for the lens edge processing. It is suitable for use in an apparatus that automatically attaches a lens holder to a processing center.
[Brief description of the drawings]
FIG. 1 is a schematic view showing an embodiment of an image pickup device for spectacle lenses provided with a lens holding device according to the present invention.
FIG. 2 is a cross-sectional view of a lens holding device.
FIG. 3 is a diagram illustrating a difference in height of a lens surface.
FIG. 4 is a diagram showing a positional relationship between a mark and a geometric center of a progressive multifocal lens.
FIG. 5 is a diagram showing a positional relationship between a small lens of a multifocal lens, a geometric center, an eye point and the like.
FIG. 6 is a diagram showing a difference in lens surface height due to conventional lens holding;
[Explanation of symbols]
DESCRIPTION OF SYMBOLS 1 ... Progressive multifocal lens, 2 ... Horizontal reference line, 3A, 3B ... Hidden mark, 4 ... Add power, 11 ... Eye point, 13 ... Multifocal lens, 13B ... Kodama, 16 ... Eye point, 30 ... Image pick-up device , 36: Lens holding device, 38, 39 ... Convex lens, 41 ... Imaging device, 42 ... Image processing device, 45 ... Vacuum exhaust device, 50 ... Lens barrel, 58 ... Vacuum exhaust chamber, 61 ... Lens support tube, 62 ... Seal Member, 64 ... communication hole, 65 ... center hole.

Claims (1)

The imaging apparatus for a spectacle lens to calculate the optical position information of the lens by detecting the Kodama progressive multifocal lens geometric hidden marks formed a predetermined position away from the center or multifocal lens optically A lens holding device used ,
An upper optical element whose upper and lower ends are open and an upper optical element that closes the upper opening is closed, and a lower optical element that closes the lower opening is built in, thereby forming an evacuation chamber inside, and the upper optical element A lens support cylinder open at both ends projecting at the center of the upper surface of the lens, and a communication hole provided penetrating through the center of the upper optical element and communicating the vacuum exhaust chamber of the lens barrel and the center hole of the lens support cylinder; Evacuating the vacuum exhaust chamber of the lens barrel, the communication hole of the upper optical element, and the central hole of the lens support cylinder to vacuum-fix the center of the lens to the upper end opening of the lens support cylinder With the device,
The lens holding device of the image pickup device for spectacle lenses , wherein the lens support tube has a sufficiently small outer diameter so as not to hinder the imaging of the hidden mark or the small ball of the lens.

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