JP4739771B2 - Eyeglass lens suction jig mounting device - Google Patents

Description

  The present invention relates to an eyeglass lens suction jig mounting device in which an attachment position of the suction jig is specified from an image of the eyeglass lens picked up by the imaging means, and the suction jig is arranged at the attachment position of the eyeglass lens. And a method for determining the attachment position of the suction jig.

  For various raw spectacle lenses, the spectacle lens surface is imaged using an imaging device, image processing is performed, the presence or absence of figures is determined, and a suction jig such as a suction cup is attached according to the type of spectacle lens. Various techniques have been proposed for attaching an eyeglass lens suction jig of an eyeglass lens for automatic mounting.

  In particular, those with hidden marks written on fabric lenses such as progressive multifocal lenses, those with mark marks recorded on spectacle lenses, and those with segments (small balls) formed such as bifocal lenses are hidden. A device that picks up a graphic image of a reference mark using marks, print marks, and segments as a reference mark, and attaches a suction jig such as a suction cup to the suction position (optical center) of a spectacle lens that is geometrically related to the reference mark Is known (patent documents 1 to 6).

There is also known an apparatus for capturing a graphic image of a spectacle lens and binarizing an image signal to detect a concealed mark or the like imprinted or printed on the spectacle lens surface or the like, or irregularities or scratches on the spectacle lens surface ( Patent Documents 1-3, 5-7).
JP 2002-296144 A JP 2000-19058 A Utility Model Registration No. 3077054 DE3829488A1 publication JP 2002-139713 A JP 2002-1638 A EP856728A2 publication

  However, some spectacle lenses are colored or coated, such as sunglasses, and some spectacle lenses cannot detect the type or contour of the spectacle lens with the amount of light of a normal illumination light source.

  For this reason, the mounting position of the suction jig (suction cup) in the spectacle lens cannot be specified, which has hindered the processing of the spectacle lens.

  Therefore, the present invention can detect the type or contour of a spectacle lens even in a colored spectacle lens such as sunglasses or a coated spectacle lens, and specify the mounting position of a suction jig (suction cup). An object of the present invention is to provide an apparatus for attaching an eyeglass lens suction jig.

In order to achieve this object, the invention according to claim 1 is a mounting table in which a spectacle lens can be disposed in an opening , a light source that irradiates light to the spectacle lens mounted on the mounting table, and the opening from the light source. A CCD that captures an image of the spectacle lens using light irradiated to the spectacle lens placed on the unit, a standard shooting mode used when the spectacle lens is not a high-density lens, and the spectacle lens is high A high density mode for photographing used in the case of a density lens is provided, and in the high density mode, the CCD exposure time is adjusted by adjusting the exposure start timing of the CCD pixel and the discharge timing from the pixel. by adjusting the progressive method to retrieve the data of the image of one pixel, the mounting position of the spectacle lens and the arithmetic and control circuit for operating the CCD, the suction jig An arrangement makes mounting means provided with a, the arithmetic control circuit, while acquiring the image for identifying the lens type attached to the eyeglass lens from the image of the spectacle lens which is captured by the CCD, the CCD A spectacle lens suction jig mounting device that specifies the mounting position of the suction jig from the image of the spectacle lens imaged by, and controls the mounting means to place the suction jig at the mounting position of the spectacle lens. The arithmetic control circuit, when switched to the high density mode, changes the exposure time of the CCD to an exposure time that can detect the contour of the spectacle lens, and the contour of the spectacle lens is changed to the contour of the spectacle lens. In addition to the detection by the CCD, the mounting position of the suction jig in the spectacle lens is obtained based on the detected outline of the spectacle lens .

  According to the present invention as described above, the type or contour of the spectacle lens is detected even in a colored spectacle lens such as sunglasses or a coated spectacle lens, and the mounting position of the suction jig (suction cup) is specified. be able to.

  Hereinafter, specific embodiments of a lens suction jig mounting device according to the present invention and a lens positioning method used in the device will be described with reference to the drawings.

  First, details of the spectacle lens ML to which the lens suction jig 120 is attached by the lens suction jig mounting apparatus 1 of the present embodiment will be described.

  First, the spectacle lens ML is an unprocessed lens before bordering, and types thereof include a single focus lens, a bifocal lens, and a progressive multifocal lens. The single focus lens ML has a plurality of mark points 410 displayed by printing as shown in FIG. 38A, and a mark point 410 as shown in FIG. There are things that are not.

  Here, the mark point 410 is an index serving as a reference of the position (eye point position) P in the lens ML to which the lens suction jig 120 is attached, and is calculated by an arithmetic control circuit 130 (see FIG. 6) which is an image processing means described later. It is detected after image processing.

  The single focus lens ML without the marking point 410 is measured by the CL measuring device 300 described later to measure the spherical power S, the cylindrical power C, the axial angle A of the cylindrical shaft, the optical center OC, and the like as refractive characteristics. A point position P is determined.

  As shown in FIG. 39, the bifocal lens ML has a so-called small ball 420 having a substantially semicircular shape, and the arithmetic control circuit 130 detects the contour 421 of the small ball 420 by performing image processing, and detects the detected small ball. Based on the outline 421 of 420, a position (eye point position) P in the lens ML to which the lens suction jig 120 is attached is detected.

  The progressive multifocal lens ML has a distance portion 431 and a near portion 432, and is formed such that the focal length continuously changes from the distance portion 431 to the near portion 432, and is formed on the lens surface. 40, a horizontal line 450 (second index) indicating the boundary between the distance portion 431 and the near portion 432 and a + symbol indicating the distance portion 431 side across the horizontal line 450 are printed. Is displayed on the lens surface.

  The progressive multifocal lens ML is engraved with two hidden marks 441 and 442 (first index) as shown in FIG. The hidden marks 441 and 442 are marks that define the horizontal line 450 described above. In addition to the marks, characters and symbols such as numbers indicating a difference in refractive power between the distance portion 431 and the near portion 432, and the like. May be further added.

  Note that additionally formed characters and the like may be used for left and right identification of the lens ML by differently arranging the right eye lens and the left eye lens.

The arithmetic control circuit 130 detects these horizontal lines 450 and the two hidden marks 441 and 442 by performing image processing, and based on the detected horizontal lines 450 and the two hidden marks 441 and 442, the progressive multifocal lens ML. The eye point position P is detected.
[Constitution]
FIG. 1 shows an appearance of a lens suction jig mounting apparatus 1 according to an embodiment of the present invention for mounting a lens suction jig 120 on a spectacle lens.

  The lens suction jig mounting device 1 includes a frame 2 shown in FIG. 8 and an outer case 3 that covers the frame 2.

  The frame 2 includes a bottom plate 4, side plates 5 and 5 that are integrally provided at the center in the front-rear direction of the left and right side edges of the bottom plate 4, and a rear wall 6 that is integrally provided at the rear edge of the bottom plate 4. 10 and 15, reference numeral 4 a denotes a base plate fixed on the bottom plate 4.

  In addition, a bracket 7 is provided above the bottom plate 4 so as to protrude forward. As shown in FIG. 9, the bracket 7 is provided in a continuous manner between the triangular side plate portions 8 and 8 whose rear edge portions are attached to the side plates 5 and 5 and the front edge portions of the side plate portions 8 and 8. It has a plate part 9.

The continuous plate portion 9 is inclined so as to go rearward toward the upper end. An operation panel 10 and a liquid crystal display (display means) 11 are attached to the continuous plate portion 9.
<Operation panel 10>
As shown in FIG. 2, the operation panel 10 includes an operation panel unit 10 a disposed on the right side of the liquid crystal display 11 and an operation panel unit 10 b disposed on the lower side of the liquid crystal display 11.
(Operation panel unit 10a)
The operation panel 10a includes a “stop” switch 12 for stopping the measurement, an “input switching / menu” switch 13 for switching the layout data input method, and a “memory” switch for calling the frame data stored in the memory. 14, a “data request” switch 15 for requesting frame data, an “− +” switch 16 for input setting, and a “▽” switch 17 for moving a cursor.

  The “input changeover / menu” switch 13 can be displayed for a predetermined time (several seconds, for example, 2 seconds) or longer to display a menu screen.

  Further, the “input switch / menu” switch 13 is used for instructing confirmation after manual positioning or position setting when the block 13 is waiting for a block instruction (suction instruction) and is pressed in a stop state after measurement. It can be done.

  When the “memory” switch 14 is pressed in the hidden mark observation mode, the screen of the liquid crystal display 11 is switched to the hidden mark storage screen.

  The “data request” switch 15 is used to request transfer of target lens shape data (θi, ρi) from a frame shape measuring device (not shown) connected to the lens suction jig mounting device 1.

  The “− +” switch 16 is used to increase / decrease the numerical data of the portion displayed on the liquid crystal display 11 and whose display color is highlighted by the “▽” switch 17. The “− +” switch 16 is also used for switching the display magnification of the liquid crystal display 11 during manual alignment.

The “▽” switch 17 is used to move the cursor of the data input unit displayed on the liquid crystal display 11. The cursor here means that any one of the display colors of the plurality of data input frames (data input portions) displayed on the liquid crystal display 11 is reversed or changed to another color. The state in which data can be input.
(Operation panel unit 10b)
The operation panel 10b is provided with function keys F1 to F6 arranged along the lower edge of the liquid crystal display 11. In addition, the operation panel unit 10b is provided with a “left” switch 18L and a “right” switch 18R for specifying the processing for the right eye and the left eye of the spectacle lens and switching the display.
<Function keys F1 to F6>
The function keys F1 to F6 are used at the time of setting related to the processing of the spectacle lens ML, and are also used for response / selection to a message displayed on the liquid crystal display 11 in the processing step.

At the time of processing setting (layout screen), function key F1 is used for lens type input (store area) and progressive lens manufacturer designation, function key F2 is used for lens material input, and function key F3 is The function key F4 is used for inputting a chamfering type, the function key F5 is used for inputting a mirror finish, and the function key F6 is used for selecting a course (mode).
・ Function key F1
As shown in FIG. 4, the lens type input by the function key F1 is “single focus”, “marking point”, “progressive”, “bifocal”, “hidden mark”, “automatic discrimination”, etc. There is. In addition, there are manufacturers M1, M2, M3,... As the progressive lens manufacturers input with the function key F1.
・ Function key F2
As shown in FIG. 4, the lens material input by the function key F2 includes “plastic”, “high plastic”, “glass”, “polycarbonate”, “acrylic”, “light control glass”, and the like. Here, “Pura” means plastic, and “Polycarbonate” means polycarbonate.
・ Function key F3
As shown in FIG. 4, the types of the spectacle frame F input with the function key F3 are “metal”, “cell”, “optil”, “flat”, “grooving (thin)”, “ There are "groove digging (middle)" and "groove digging (thick)".

“Point: front bracket”, “point: rear bracket”, “point: composite bracket”, etc. can also be included.
・ Function key F4
As shown in Fig. 4, the type of chamfering input with function key F4 is "None", "Small (front / rear)", "Medium (front / rear)", "Large (front / rear)", "Special (front / rear) ) ”,“ Small (after) ”,“ middle (after) ”,“ large (after) ”,“ special (after) ”, etc.
・ Function key F5
As shown in FIG. 3, there are “None”, “Available”, “Chamfered portion mirror surface”, and the like as the mirror finish input by the function key F5.
・ Function key F6
As shown in FIG. 3, machining courses input with the function key F6 include “auto”, “trial”, “monitor”, “frame change”, “internal trace”, and the like.
<Layout screen>
As the layout screen, for example, a “layout / suction” mode for displaying a layout screen for attracting a lens suction jig to a spectacle lens as shown in FIG. 4A, FIG. 4B, or FIG. There is a “layout” mode that indicates a state when the lens suction jig is attracted to the spectacle lens hidden in the information (θi, ρi).

  When the “layout” tab TB1 is selected, the message display area E1, the numerical value display area E2, and the state display area E3 are displayed.

  4A, when the function key F1 is used to display a pop-up menu corresponding to F1 in FIG. 3 and “Progress” is selected, “AXIS” in the numerical display area E2 is displayed in FIG. 4A. It changes to “EP” (Eye Point) as shown in FIG. 4B.

  Here, the contents to be input in the display frame corresponding to “EP” in the numerical display area E2 are input when “Auto” is input as shown in FIG. 4A or when “+4.0” is input as shown in FIG. 4B, for example. There is.

  Moreover, the outer case 3 has the front wall 19 as shown in FIG.1 and FIG.8. In the upper part of the front wall 19, an inclined wall portion 19a inclined backward is formed, and a liquid crystal opening 20 is formed in the inclined wall portion 19a. The liquid crystal display 11 and the operation panel 10 are disposed in the liquid crystal opening 20 as shown in FIG. Further, a table intrusion opening 21 is formed in the lower portion of the front wall 19, and a suction plate mounting opening 22 is formed in a portion of the front wall 19 from the right in the vertical middle portion.

Further, as shown in FIG. 6A, the entire detection optical system 100, the hidden mark detection optical system 200, and the CL measurement device 300 for measuring refraction characteristics are disposed in the frame 2.
<Whole detection optical system 100>
The entire detection optical system 100 includes an illumination optical system 101 and an entire observation optical system 102.

  The illumination optical system 101 includes optical members such as a light source 103 such as an infrared light emitting LED, a pinhole plate 104, a collimator lens 105, and a rotary reflection plate 106 in this order. The rotary reflector 106 is attached to a rotary shaft 107 a of a drive motor 107 and is driven to rotate by the drive motor 107.

  In the drive motor 107, the axis O1 of the rotation shaft 107a is inclined with respect to the optical axis O2 of the illumination optical system 101. Thereby, the direction of the surface of the rotary reflecting plate 106 is slightly inclined by the predetermined angle α with respect to the axis O1 oriented in the vertical direction. The predetermined angle α is several degrees (for example, 2 ° to 4 °, preferably 3 °).

  Further, as shown in FIG. 6B, the rotary reflecting plate 106 includes a rotating disc 106a made of a metal plate or a resin plate, and a reflecting sheet 106b attached to the upper surface of the rotating disc 106a. . The reflection sheet 106b is formed by integrally forming a large number of very small corner cubes 108 in the vertical and horizontal directions on the entire surface.

  With such a configuration, the incident light beam 109 incident on the corner cube 108 is reflected in the corner cube 108, and then becomes an emitted light beam 110 that exits from the corner cube 108 and returns along the incident light beam 109. Note that the reflector having such optical characteristics is referred to as a retroreflector or the like.

  On the other hand, the specularly reflected light beam 111 reflected by the surface of the reflection sheet 106b is reflected at a certain angle with respect to the incident light beam 109, so that it does not return along the incident light beam 109 unlike the emitted light beam 110, and the whole No adverse effect on observation or hidden mark detection (no noise light).

The overall observation optical system 102 includes optical members such as a collimator lens 105, a half mirror 112, a diaphragm plate 113, an imaging lens 114, and a CCD (two-dimensional light receiving element, area sensor) 115 in this order.
<Hidden mark detection optical system 200>
The hidden mark detection optical system 200 includes the illumination optical system 101 and the hidden mark observation optical system 201 described above.

  The hidden mark observation optical system 201 includes an optical member such as a collimator lens 105, a half mirror 202, a diaphragm plate 203, and an imaging lens 204, and a CCD 205 serving as an imaging unit arranged in this order.

Of the entire detection optical system 100 and the hidden mark detection optical system 200, the optical members other than the rotating reflector 107 are accommodated in the optical member accommodation case 23 shown in FIG. The optical member storage case 23 is fixed to the frame 2 with a bracket (not shown).
(Other arrangement examples of the entire observation optical system)
The overall observation optical system 102 can also be configured as shown in FIG. 6 is disposed between the half mirror 202 and the diaphragm plate 203, the reflected light beam reflected by the half mirror 202 is reflected by the half mirror 112, and the reflected light beam is reflected on the diaphragm plate. It may be guided to the CCD 115 via the 113 and the imaging lens 114.
<CL measuring device 300>
The CL measuring apparatus 300 is located on the back side (rear wall 6 side) of the frame 2 and is fixed on the base plate 4a, and has a bracket 301 shown in FIG. The bracket 301 has an upper housing 302 and a lower housing 303. The upper housing 302 is provided with the measurement light beam projection system 304 shown in FIG. A light receiving optical system 305 shown in FIG. Reference numeral 306 denotes a conical tube-shaped lens receiver fixed on the lower housing 303.

In the measurement light beam projection system 304, optical members such as a light source 307, a pinhole plate 308, a reflection mirror 309, and a collimator lens 310 are arranged in this order. The light receiving optical system 305 includes an optical member such as a pattern plate 311 and an imaging lens 312 and a CCD 313 arranged in this order.
<Lid mounting structure>
An L-shaped bracket 24 shown in FIGS. 15 and 16 is fixed on the front end portion (end portion on the front wall 19 side) of the base plate 4a. An opening 25 is formed in the upright plate portion 24a of the bracket 24, and flanges 24b and 24b are integrally formed in the side portion of the upright plate portion 24a as shown in FIG.

  The opening 25 is closed with a lid 26. A hinge bracket 27 shown in FIGS. 14 and 15 is fixed to one lower end portion of the inner surface of the lid 26. As shown in FIG. 15, the bracket 27 includes a curved portion 27a that curves in a circular arc toward the rear and lower side, a straight plate portion 27b that linearly extends from the rear end of the curved portion 27a toward the lid 26, and a straight line. It has a stopper plate portion 27c provided continuously downward at a right angle (perpendicular) to the plate portion 27b.

  On the other hand, as shown in FIG. 14, bearing members 28 and 28 positioned below the opening 25 are integrally provided in the vicinity of both side portions of the inner surface of the upright plate portion 24a.

  In the bracket 24, a connection corner portion 27 d between the straight plate portion 27 b and the stopper plate portion 27 c is rotatably held by the bearing members 28 and 28 via the support shaft 29. Further, the bracket 27 is urged to rotate counterclockwise in FIG. 15 by a twisted coil spring 30 wound around the support shaft 29 and interposed between the bracket 27 and the upright plate portion 24a. .

Thereby, the lid 26 is in contact with the front surface of the upright plate portion 24a to close the opening 25 (see FIG. 1). Further, in this state, the lid 26 closes the table retracting opening 21 of the outer case 3.
<Lens clamp release arm>
Further, on one side of the base plate 4a, as shown in FIG. 13, an arm 31 used for releasing the lens clamping is fixed in the vicinity of the lid 26. As shown in FIGS. 11 and 14, the arm 31 includes a standing part 31a, a horizontal part 31b extending from the upper end of the standing part 31a along the lid 26, and a plate part extending from the tip of the horizontal part 31b to the lid 26 side. 31c and the latching claw part 31d extended below from the front-end | tip of the board part 31c.
<Lens holding means moving mechanism>
A lens holding means moving mechanism 32 is disposed on the base plate 4a. As shown in FIGS. 13, 15, and 16, the lens holding mechanism 32 includes a lateral guide rail (X-direction guide rail) 33 positioned near the rear end of the base plate 4 a and the arm 31, and a lateral guide rail. A lateral movement member (X-direction movement member) 34 disposed on 33 and a bearing 35 that supports the lateral movement member 34 on the lateral guide rail 33 so as to be movable in the lateral direction (X direction). Further, the drive motor 107 described above is attached to the lateral movement member 34 as shown in FIG.

  Further, as shown in FIG. 17, the lens holding means moving mechanism 32 is fixed to the front and rear guide rails 36 fixed on both sides of the lateral movement member 34 in the front-rear direction (direction perpendicular to the paper surface of FIG. 17; Y direction). A plate-like front and rear moving member (front and rear moving stage, Y direction moving member) 37 disposed on the guide rail 36, and a bearing 38 that instructs the guide rail 36 to move back and forth freely. Have The drive motor 107 described above is attached to the laterally moving member 34.

  Further, as shown in FIG. 13, a nut member 39 is fixed to the lateral movement member 34, and a lateral feed screw (X feed screw) 40 having an axis line in the lateral direction is screwed to the nut member 39. ing. The lateral feed screw 40 is rotationally driven by a pulse motor (X drive motor) 41 fixed on the base plate 4a.

  On the other hand, a circular light transmitting hole 42 is formed in the front-rear moving member 37 so as to face the rotary reflecting plate 106 attached to the drive motor 107.

Further, as shown in FIG. 15, a nut member 43 is fixed to the front-rear moving member 37 via a bracket 37a and a fixing screw 37b, and the nut member 43 has a front-rear feed screw (with an axis line in the front-rear direction). Y feed screw) 44 is screwed. The front / rear feed screw 44 is rotationally driven by a pulse motor (Y drive motor) 45 fixed on the lateral movement member 34.
<Lens holding means>
As shown in FIGS. 13 to 17, a lens holder (lens holding means) 46 is disposed on the light transmission hole 42 of the front-rear moving member 37 as a lens mounting table.

  As shown in FIG. 16, the lens holder 46 has a ring-shaped gear 47 provided with a support flange 47a at the lower portion of the inner peripheral surface. The ring-shaped gear 47 has a gear portion 47b and an annular groove 47c extending in the circumferential direction on the circumferential surface. Further, as shown in FIGS. 16 and 18, an opening 47 d that penetrates vertically and is concentric with the light transmission hole 42 and slightly smaller than the light transmission hole 42 is formed in the ring-shaped gear 47.

  As shown in FIG. 18B, the annular groove 47c is engaged with a plurality of rollers 37R that are rotatably mounted on the longitudinally moving member 37. The plurality of rollers 37 </ b> R are disposed along the light transmission hole 42, and hold the ring-shaped gear 47 on the front and rear moving member 37 so as to be rotatable.

  The lens holder 46 is fitted in the ring gear 47 and is detachably supported on the support flange 47a. The lens holder 46 projects on the transparent disk 48 at intervals of 120 °. And an axial lens receiver 49 provided. The transparent disk 48 may be glass or plastic.

  On the ring-shaped gear 47, as shown in FIG. 18 (a), six small gears 50 arranged at equal pitches (60 ° intervals) in the circumferential direction are rotatably mounted. A timing belt 51 is stretched around the gear 50. A tension roller 52 rotatably attached to the ring gear 47 is brought into contact with the outer peripheral surface of the timing belt 51.

  Furthermore, one end portion (base end portion) of each arm 53 is fixed to every other small gear 50, and a lens holding shaft (lens holding shaft) extending vertically on the other end portion (tip end portion) of each arm 53. Member) 54 is attached.

  On the ring-shaped gear 47, a spring receiving pin 55 is attached in the vicinity of one end of the arm 53, and a coil spring 56 is interposed between the spring receiving pin 55 and one end of the arm 53. Yes. The coil spring 56 urges the arm 53 so that the tip of the arm 53 rotates toward the center of the ring gear 47.

  One end portions of the small gear 50 and the arm 53 configured as described above are covered with a cover ring 57 as shown in FIGS. The cover ring 57 is fixed to the ring-shaped gear 47 with screws 58.

  Further, engagement notches 59 for engaging the lens holding shaft 54 are formed on the inner peripheral surface of the cover ring 57 at intervals of 120 ° in the circumferential direction. Further, a cutout 60 is formed on the outer peripheral surface of the cover ring 57.

  In addition, an engagement protrusion 53 a that protrudes upward from the notch 60 is formed at one end of each of the three arms 53.

  Further, a mounting angle setting motor 61 composed of a pulse motor or the like is fixed to the longitudinal movement member 37, and a gear 62 is mounted on an output shaft 61 a of the mounting angle setting motor 61. The gear 62 is engaged with the gear portion 47 b of the ring-shaped gear 47. Therefore, the ring-shaped gear 47 is rotated by rotationally driving the gear 62 by the mounting angle setting motor 61.

The forward / backward moving member 37 is covered with a stage cover SC except for the lens holder 46.
<Frame changing lens holder>
Further, in place of the lens-supporting transparent disc 48 having the shaft-shaped lens receiver 49, the frame replacement lens holder 63 shown in FIG. 19 can be detachably mounted in the ring-shaped gear 47 as shown in FIG. It can also be attached to.

  The frame replacement lens holder 63 has a ring-shaped frame 64 having the same outer diameter as that of the transparent disk 48, a transparent disk 64 a fixed in the ring-shaped frame 64, and an equal pitch on the ring-shaped frame 64 ( Three (several) support shafts 65 projecting at intervals of 120 °, a lens holding arm (lens holding member) 66 having one end portion (base end portion) rotatably attached to the support shaft 65, and A coil spring 67 that urges the other end portion (tip portion) of the lens holding arm 66 to rotate toward the center of the ring-shaped frame 64 is provided. The lens holding arm 66 is formed in a tapered shape toward the tip.

  Such a ring-shaped frame 64 is formed to be thicker than the above-described transparent disk 64a, and the lens holding shaft 54 of the above-mentioned arm 53 is contrasted on the ring-shaped gear 47 as shown in FIG. In this state, the ring-shaped gear 47 is detachably fitted. Thereby, the lens holding shaft 54 hits the outer peripheral surface of the ring-shaped frame 64 and does not move into the ring-shaped frame 64. Also at this time, the ring-shaped frame 64 is supported on the flange 47a of the ring-shaped gear 47 of FIG.

In addition, 64b is a through-hole provided in the ring-shaped frame 64 for frame replacement, and is used for detection of the frame replacement lens holder 63.
<Lens adsorption mechanism>
A lens suction mechanism 68 is attached to the side plate 5 of the frame 2 as shown in FIGS.

  The lens suction mechanism 68 has a bracket 69 as shown in FIGS. The bracket 69 is formed in a substantially U shape as a whole by an upper support plate portion 69a, a lower support plate portion 69b, and a vertical plate portion 69c connecting the support plate portions 69a and 69b.

  Further, mounting pieces 69d and 69d are provided integrally and at a right angle on the upper and lower portions on one side of the vertical plate portion 69c. By attaching the attachment pieces 69d and 69d to the side plate 5 provided on the frame 2 in FIGS. 10 and 11 with screws (not shown), the bracket 69 is attached with the vertical plate portion 69c being perpendicular to the side plate 5. Yes.

  The lens suction mechanism 68 includes a fixing arm 70 attached to the front lower portion of the vertical plate portion 69c toward the front, upper and lower ends of the upper and lower support plate portions 69a and 69b, and fixing means such as screws (not shown). A fixed cam cylinder 71 and a female screw cylinder 72 fitted in the cam cylinder 71 shown in FIG. 22 so as to be rotatable and movable up and down (movable up and down). The lower end portion of the female screw cylinder 72 penetrates the lower support plate portion 69b and protrudes downward.

  The cam cylinder 71 is formed with a cam slit (guide slit) 73 extending vertically as shown in FIGS. The cam slit 73 includes an upper vertical slit portion 73a shown in FIG. 21, a helical slit portion 73b formed downwardly while being twisted 90 ° spirally from the lower end of the upper vertical slit portion 73a, A lower vertical slit portion 73c formed linearly from the lower end of the spiral slit portion 73b to the lower portion of the cam cylinder 71.

  A guide roller 74 is rotatably held in the vicinity of the upper end portion of the outer peripheral surface of the female screw cylinder 72, and the guide roller 74 is disposed in the cam slit 73 as shown in FIG.

  Further, a male screw shaft (screw shaft) 75 extending through the upper support plate portion 69a to the lower support plate portion 69b side is rotatably attached to the female screw cylinder 72. The male screw shaft 75 is held by the upper support plate portion 69a so as to be rotatable and immovable in the axial direction (vertical direction).

  A pulley 76 is fixed to the upper end portion of the male screw shaft 75. A drive motor 77 is attached to the lower surface of the upper support plate portion 69a. An output shaft 77a of the drive motor 77 protrudes upward through the upper support plate portion 69a, and a pulley 78 is fixed to the output shaft 77a. A timing belt 79 is wound around the pulleys 76 and 78.

  Further, a horizontally extending movable arm 80 is fixed to the lower end portion of the male screw cylinder 75. The movable arm 80 faces the front when the guide roller 74 is in the upper vertical slit portion 73 a of the cam slit 73, and the guide roller 74 is in the lower vertical slit portion 73 c of the cam slit 73. Sometimes it is in the lateral direction (X direction) and to the left in FIG.

  As shown in FIGS. 21, 23, and 24, a movable bracket (movable member) 82 is attached to a distal end portion of the movable arm 80 via a support shaft 81 that is orthogonal to the extending direction of the movable arm 80 and extends horizontally. Is rotatably held.

  A torsion coil spring 83 wound around a support shaft 81 is interposed between the movable bracket 82 and the movable arm 80 as shown in FIGS. The torsion coil spring 83 urges the movable bracket 82 to be folded in a direction in which the movable bracket 82 is folded toward the lower surface of the distal end portion of the movable arm 80 as shown in FIG.

Further, a roller 84 is rotatably held on the side surface of the base end portion of the movable bracket 82. The roller 84 comes into contact with a horizontal plate portion (stopper plate portion) 70a provided at the lower end of the fixed arm 70 when the movable arm 80 is raised in a state of facing the front, and the movable bracket 82 is moved to the 26th position. As shown in FIG. 21, the torsion coil spring 83 is rotated to a vertical state against the spring force.
(Suction jig holding means)
Further, a suction jig holding means 85 is attached to the movable bracket 82.

  As shown in FIGS. 27A and 29, the suction jig holding means 85 includes a holder main body 86 in which the cylindrical portion 86a is inserted into the through hole 82a of the bracket 82, and a flange 86b of the holder main body 86. 82, screws 87, 87 fixed to the opposing pieces 82b, 82b. The holder body 86 is provided with a cylindrical portion 86a protruding from the through hole 82a, and an outer cylinder 88 is fitted on the outer periphery of the cylindrical portion 86a so as to be movable in the longitudinal direction.

  The outer cylinder 88 is formed with slits 88a as shown in FIGS. 27B and 27C at intervals of 180 °, and each slit 88a has a linear spring whose one end is held by the holder body 86. Bent portions 89a and 89a at the other end of 89 and 89 are provided. As shown in FIGS. 27B and 27C, the bent portion 89a is provided with a straight portion 89b that protrudes into the outer cylinder 88 from the slit 88a, as shown in FIGS.

  In addition, a coil spring 90 is interposed between the holder main body 86 and the outer cylinder 88, and the outer cylinder 88 is urged toward the left in FIG. Yes. In the cylindrical portion 86a of the holder main body 86, a spring support shaft 91 having one end fixed to the end wall 86c of the cylindrical portion 86a is disposed concentrically.

  Further, a bottomed cylindrical slide cylinder 92 is fitted in the cylinder portion 86a so as to be movable in the axial direction, and the spring support shaft 91 is inserted in the slide cylinder 92 with play. .

  One end of the coil spring 93 is inserted into the slide cylinder 92 and is frictionally held. A spring support shaft 91 is inserted into the coil spring 93, and the other end portion of the coil spring 93 is held by an interference fit with the end portion on the end wall 86c side of the spring support shaft 91. .

  Further, as shown in FIGS. 28A and 28B, the cylindrical portion 86a of the holder main body 86 is formed with notch guides 86d and 86d extending in a slit shape at the lower end at intervals of 180 °. . In addition, as shown in FIGS. 27B and 28C, the outer cylinder 88 is formed with a slit-shaped notch guide 88b opened at the upper end.

  As shown in FIGS. 27 and 28 (d), the notch guides 86d and 88b are made to coincide with each other. And the guide shaft 94 attached as shown to FIG. 26, 27 (a) is penetrated by this notch guide 86d, 88b to the outer peripheral surface of the slide cylinder 92. As shown in FIG. Further, as shown in FIG. 30, a positioning pin 95 projects from the end wall 92 a of the slide cylinder 92. A tapered recess 88 c is formed at the outer end of the outer cylinder 88.

  30 and 36, a hook support shaft 96 is screwed and fixed to the flange 86b of the holder main body 86, and a spring receiving screw 97 is screwed adjacent to the hook support shaft 96. ing. Reference numeral 96 a denotes a flange of the hook support shaft 96.

  As shown in FIG. 36, the hook support shaft 96 is inserted into the shaft insertion hole 98a of the plate-like locking hook 98 in a state having play, and supports the locking hook 98 on the flange 86b. A spring locking projection 98b is formed on one side of the locking hook 98, and a slit 98c is formed in the spring locking projection 98.

  Then, both end portions of the coil spring 99 fitted to the outer periphery of the hook support shaft 96 are locked in the spring receiving screw 97 and the slit 98c. The coil spring 99 urges the locking hook 98 to rotate counterclockwise in FIG. 30 and is interposed between the flanges 86b and 96a so that the locking hook 98 is applied to the flange 86b with a light force. Pressed.

  As shown in FIGS. 30 to 32, the locking hook 98 is formed with a locking notch 98d, and is positioned at the edge of the locking notch 98d opposite to the rotational biasing direction. An inclined guide piece 98e is formed. A small-diameter shaft portion 94a at the tip of the guide shaft 94 attached to the outer peripheral surface of the slide cylinder 92 is inserted into the locking notch 98d as shown in FIG.

As shown in FIG. 26, the lens suction jig 120 shown in FIG. 1 includes an attachment shaft 121 and an elastic member such as rubber or soft synthetic resin provided integrally with the attachment shaft 121. And a cup part 122. The attachment shaft portion 121 is formed with a positioning groove 123 that opens to the end surface and the peripheral surface. The mounting shaft 121 is fitted into the outer cylinder 88.
<Control circuit>
The liquid crystal display 11 (display means) described above is controlled by the arithmetic control circuit 130 (display control means, image processing means) shown in FIG.

  The arithmetic control circuit 130 controls the operation of the pulse motor (X drive motor) 41, the pulse motor (Y drive motor) 45, the mounting angle setting motor 61, the light source 103, the drive motor 107, and the light source 307. ing.

  Further, the switch operation signal from the operation panel 10 and the image signals (measurement signals) from the CCDs 115, 205, and 313 are input to the arithmetic control circuit 130.

  The arithmetic control circuit 130 controls the operation of the image processing circuit 131 as image processing means on the basis of the image signals (measurement signals) input from the CCDs 115 and 205, and the single focus shown in FIG. The image detected for the lens ML is subjected to image processing, the mark 410 printed and displayed on the lens surface of the single focus lens ML is detected, and the position (eye point position) on the lens ML to which the lens suction jig 120 is attached. ) Processing for obtaining P or image processing is performed on the image detected for the bifocal lens ML shown in FIG. 39 to detect the outline 421 of the small ball 420 of the bifocal lens ML, and the eye point position P is determined. Image processing is performed on the obtained processing and the image detected for the progressive multifocal lens ML shown in FIG. It detects the set has been hidden marks 441 and 442, performs processing for obtaining the eye point position P.

  Then, the arithmetic control circuit 130 causes the memory 132 to store the coordinates of the eye point position P thus obtained.

Here, the processing for obtaining the eye point position P performed by the arithmetic control circuit 130 is automatically performed according to a preset processing procedure, and the obtained eye point position P is further converted into the lens suction jig 120. The lens ML is automatically moved so as to be in the mounting position.
[Action]
Next, the operation of the lens suction jig mounting device 1 of the present embodiment will be described.
(1) Holding the spectacle lens to the lens holder 46 (exposing the lens holder 46 to the outside of the outer case 3 and placing the lens)
Next, by selecting the automatic discrimination shown in FIG. 4 by operating the function key F1 on the operation panel 10 and selecting either the “left” switch 18L or the “right” switch 18R shown in FIG. Then, the operation is controlled by the arithmetic control circuit 130, the forward / backward feed screw 44 is rotated forward, and the nut member 43 and the forward / backward moving member 37 are moved to the lid 26 side.

  With this movement, the stage cover SC that covers the forward / backward moving member 37 abuts against the lid 26, and then twists the lid 26 against the spring force of the coil spring 30, with the support shaft 29 as the center, the timepiece of FIG. The lens holder 46 attached to the front / rear moving member 37 is exposed through the openings 25, 21 and out of the outer case 3.

  At this time, the engaging protrusion 53a of the lens holder 46 is engaged with the engaging claw portion 31d of the arm 31, and the arm 53 integral with the engaging protrusion 53a of FIG. The lens holding shaft 54 of the arm 53 integrated with the engaging projection 53a is moved toward the notch 60 side of the cover ring 57 in FIG. Moving.

  Accordingly, the timing belt 51 in FIG. 18A is rotated in the clockwise direction, and the other two small gears 50 are also rotated in the clockwise direction by the timing belt 52. The arm 53 integrated with the remaining two small gears 50 is rotated clockwise against the spring force of the coil spring 56, and the lens holding shaft 54 of the remaining two small gears 50 and the arm 53 is rotated. Move to the cutout 60 side of the cover ring 57 in FIG.

In this way, with the three lens holding shafts 54 moved to the cover ring 57 side and opened, as shown in FIG. 18B, on the axial lens receiver 49 of the lens holder 46, The spectacle lens ML is placed.
(Moving the lens holder 46 into the outer case 3 and holding the lens)
Thereafter, the arithmetic control circuit 130 controls the operation of the pulse motor 45 to reversely move the front / rear feed screw 44 and move the nut member 43 and the front / rear moving member 37 into the outer case 3.

  Accordingly, when the stage cover SC that covers the longitudinally moving member 37 is separated from the lid 26, the lid 26 rotates counterclockwise in FIG. 15 about the support shaft 29 by the spring force of the twisted coil spring 30. The opening 25, 21 is closed by the lid 26 by moving and closing.

  At this time, when the engagement protrusion 53 a of the lens holder 46 is separated from the locking claw portion 31 d of the arm 31, the arm 53 integrated with the engagement protrusion 53 a is moved by the spring force of the coil spring 56 in FIG. The lens holding shaft 54 of the arm 53 integrated with the engagement protrusion 53a moves to the center side of the cover ring 57 shown in FIG.

  Accordingly, the timing belt 51 in FIG. 18A is rotated in the counterclockwise direction, and the remaining two small gears 50 are also rotated in the counterclockwise direction by the timing belt 52. The arm 53 integral with the two small gears 50 is rotated counterclockwise by the spring force of the coil spring 56, and the lens holding shaft 54 of the arm 53 integral with the remaining two small gears 50 is obtained. However, it moves to the center side of the cover ring 57 of FIG.

In this way, the three lens holding shafts 54 are moved to the center side of the cover ring 57 and come into contact with the peripheral surface of the spectacle lens ML placed on the shaft-shaped lens receiver 49 of the lens holder 46, As shown in FIG. 34, the eyeglass lens ML is held (held) by three lens holding shafts 54.
(2) Confirmation of Presence / absence of the Eyeglass Lens ML In this way, the arithmetic control circuit 130 moves the lens holder 46 and the rotary reflector 106 in a state where the eyeglass lens ML is held (held) by the three lens holding shafts 54. When the whole detection optical system 100 and the hidden mark detection optical system 200 are moved between the illumination optical system 101, the operation of the pulse motor 45 is stopped.

  Thereafter, the arithmetic control circuit 130 turns on the light source 103 to emit infrared light from the light source 103, and drives and controls the drive motor 34 to rotate the rotary reflector 106.

  The infrared light from the light source 3 passes through the pinhole plate 104 and the half mirrors 112 and 202, enters the collimator lens 105, is converted into a parallel light beam by the collimator lens 105, and is then a spectacle lens ML as a test lens. Is irradiated.

  By this irradiation, the infrared light transmitted through the spectacle lens ML is reflected by the rotary reflecting plate 106 to become reflected light. A part of the reflected light passes through the spectacle lens ML and the half mirror 202 and is then reflected by the half mirror 112, and the image of the spectacle lens ML is passed to the CCD 115 via the diaphragm plate 113 and the imaging lens 114. And an image of the axial lens receiver 49 is formed.

  If the spectacle lens ML has a hidden mark or a paint mark, these images are also formed on the CCD 115. The image signal from the CCD 115 is input to the arithmetic control circuit 130.

  When the arithmetic control circuit 130 receives the image signal from the CCD 115, the arithmetic control circuit 130 displays the image of the lens ML on the liquid crystal display 11.

  Thereafter, the arithmetic control circuit 130 performs a process of determining whether or not the lens ML is actually held by the lens holder 46 (the presence or absence of the lens ML). The type of lens ML that indicates whether the existing lens ML is a single focus lens with a mark, a single focus lens without a mark, a bifocal lens, or a progressive multifocal lens. Judgment processing is performed.

  Then, according to the type of the lens ML obtained by the determination, the eye point position detection process and the lens suction jig 120 mounting process are automatically performed.

When the lens ML is a single-focus lens with no mark, measurement is performed by the CL measurement device 300, and the eye point position detection process and the lens suction jig 120 mounting process are automatically performed. Done.
(3) Light quantity adjustment method and image acquisition method of light source 103 of whole detection optical system 100 By the way, an automatic light quantity adjustment method of light source 103 such as an infrared light emitting LED used in illumination optical system 101 of whole detection optical system 100, An image acquisition method using the CCD (two-dimensional light receiving element, area sensor) 115 will be described. It should be noted that automatic light amount adjustment of the light source 103 and image acquisition by the CCD 115 described below are executed by the arithmetic control circuit 130.
[Light intensity adjustment method]
<Automatic light quantity adjustment method of light source>
In this automatic light amount adjustment method of the light source 103, the maximum value and the minimum value of the light amount are determined in advance, and the light amount is adjusted within the range.

  This light quantity control can be executed by controlling the light emission time (msec) of the light source 103 by the arithmetic control circuit 130 and adjusting the light received light quantity of the CCD 115.

  Here, a case where the above-described infrared light emitting LED (hereinafter simply referred to as LED) is used as the light source 103 will be described.

  Further, when the light amount value set for the LED is an LED set value (or a control value), the LED set value is substantially proportional to the luminance by experiment.

For this reason, in order to detect the optimum light amount position of the LED that is the light source 103, the luminance value of the LED setting value (LED setting value 2 points) is obtained at two different values (different light emission times). The optimal light amount is calculated by using a predetermined linear equation calculated from the proportional relationship between the LED setting value and the luminance value.
(I) Two LED setting values In the entire optical system 100, a predetermined linear equation is calculated based on a luminance value when LED control is performed with predetermined different LED settings.

In the same way, the hidden mark observation system also uses the luminance value when LED control is performed with predetermined different LED setting values.
(Ii) Confirmation of illumination The brightness value is measured using the value calculated by a predetermined linear equation. At this time, if the luminance value is between Max and Min, the process proceeds to image processing as an image with the optimum light amount.

  In such an automatic light amount adjustment method, the optimum luminance position is calculated using the LED set value as an index.

However, it has been found that this method cannot clearly detect the outline of a colored spectacle lens such as sunglasses or a coated spectacle lens. Therefore, the optimum luminance position is calculated using the exposure time (0.1 mSec unit) as an index. Note that the exposure time calculation method for setting the optimal luminance position is the same as the calculation method of the <automatic light quantity adjustment method> described above, and is therefore omitted.
[Image acquisition method]
Furthermore, the image acquisition is performed by a TV mode interlace method (a method of acquiring an image with a scanning line). However, this method has the following problems.

  That is, firstly, since every other scanning line is input, every other scanning line is uneven, which is an obstacle to image analysis.

  Secondly, illumination unevenness due to the slow rotation of the reflection rotating plate with respect to the exposure time is an obstacle to image analysis.

  Thirdly, since the exposure time is fixed, it cannot be applied to a sunglasses lens having a high density.

Therefore, image acquisition is performed by a progressive method in a predetermined mode (method of acquiring an image pixel by pixel) to solve the problem.
[Image acquisition by progressive mode]
<Exposure method>
As described above, the optimal luminance position is calculated using the exposure time (0.1 mSec unit) as an index.
<High density lens support>
Further, by operating the CCD 115 in a predetermined mode, the amount of light can be accumulated in the CCD 115. For example, the amount of light accumulated in the CCD 115 can be adjusted by adjusting the exposure start time of the CCD 115 by adjusting the exposure start timing of the pixel of the CCD 115 and the discharge timing from the pixel by the arithmetic control circuit 130.

For this reason, it has become possible to deal with high-density lenses such as sunglasses, which could not be distinguished conventionally. However, as an adverse effect, a “blooming” phenomenon occurs in which an image of the peripheral portion of the unprocessed circular spectacle lens ML is lost, and the lens outer shape (contour) La of the lens shape L in FIG. The trouble that cannot be taken accurately in the indicated part occurs. In order to avoid this problem, a “high density” mode is newly provided as shown below.
<Mode switching method>
For example, as shown in FIG. 41, when the “lens type” of the function key F1 is pressed and held, a pop-up menu PM for selecting “standard” and “high density” is displayed, and “standard” and “high density” are displayed. Enable switching. When “high density” is selected, the right display of the lens type in the upper right window (display area E2) (for example, in FIG. 41, “bifocal” is displayed, usually in white text)) Displayed in red. This indicates to the operator that the mode is “high density”.
<Operating specifications of "High density"mode>
Further, in the high density mode, the raw spectacle lens ML is measured once with an exposure time in which blooming does not occur, and the data at this time is used for data acquisition of the lens outer shape (contour) La of the lens shape L in FIG. . Specifically, an image exposed with an LED setting value obtained by subtracting 25 msec from the “optimum luminance exposure time” acquired when performing automatic light amount adjustment is used.

In photographing with a hidden mark observation system, since the field of view of observation is narrow and blooming does not occur, processing similar to that in the standard mode is performed even when the high density mode is selected.
<Image processing>
In the past, only the image acquired at the appropriate brightness was passed to the image processing task, but the previous data is also passed before the image processing.
<Display image>
Display the acquired image with appropriate brightness. At this time, even when blooming occurs, the image at that time is displayed as it is.

  Even in this case, since the outer shape (contour) La of the lens shape L shown in FIG. 42 is obtained and calculated in a separate image, blooming occurs and the portion of the arrow Ax where the outer diameter shape La is missing is calculated. The shape can also be displayed with accurate values.

Then, as shown in FIG. 42, the portion of the arrow Ax in which the blooming occurs and the outer diameter shape La is missing is displayed with a dotted line Sa in the outer shape (outline) La of the lens shape L. Even if a lens having a normal density is measured in the high density mode, the concept of brightness adjustment is not different from that in the standard mode, and thus the detection accuracy is not affected.
<Standard lens compatible>
Image acquisition is acquired by the progressive method of 2.

  When a high-density lens is measured in this mode, the outer shape (outline) La of the lens shape L may not be obtained accurately as shown by the part indicated by the arrow Ax as shown in FIG. In this case, it is displayed without any particular correction.

  By the above automatic light quantity adjustment method (exposure time accumulation) and high density mode image acquisition (imaging), for example, as shown in FIG. 42, the lens outer shape (contour) La of the lens shape L of a spectacle lens such as unprocessed sunglasses is obtained. The outer shape (contour) La is accurately captured, and the accurate outer shape (contour) La of the lens shape L of the spectacle lens ML is represented by a circular dotted line Sa corresponding to the portion indicated by the arrow Ax. Can be displayed.

Then, an accurate suction point of the lens suction jig 120 is obtained from the exact outer shape (contour) of the lens shape L indicated by the circular dotted line Sa, and the lens suction jig 120 is determined based on the obtained suction point data. The lens is attracted to the spectacle lens ML by a lens attracting mechanism (lens attracting means) 68.
(4) Attaching the Lens Adsorption Jig 120 to the Eyeglass Lens ML As described above, the arithmetic control circuit 130 detects the presence / absence of the eyeglass lens ML, the type of the eyeglass lens ML, the hidden mark 441, etc., and then the attachment angle. The operation of the setting motor 61 is controlled to rotate the ring-shaped gear 47 of the lens holder 46 so that the hidden mark 441 or the like coincides with a predetermined portion of the positioning cursor 500 (FIG. 41) displayed on the liquid crystal display 11. Thereby, the lens holder 46 is rotated, and the spectacle lens ML held by the lens holder 46 is rotated around the optical axis O2.

  Alternatively, the arithmetic control circuit 130 measures the refractive characteristics of the spectacle lens ML with the CL measuring device 300, and then turns the spectacle lens ML into the illumination optics of the rotary reflector 106, the entire detection optical system 100, and the hidden mark detection optical system 200. When moved to the system 101, when there is a cylindrical shaft or the like, the mounting angle setting motor 61 is controlled and the ring-shaped gear 47 of the lens holder 46 is rotated to rotate the lens holder 46. Thus, the spectacle lens ML held by the lens holder 46 is rotated around the optical axis.

  Further, in the case of a spectacle lens such as sunglasses, the arithmetic control circuit 130 accurately obtains an accurate outer shape (contour) of the lens shape L of the spectacle lens ML as described above, and accurately calculates the lens suction jig 120. After obtaining an appropriate suction point, the liquid crystal display 11 accurately displays the exact outer shape (contour) of the lens shape L of the spectacle lens ML as indicated by the circular dotted line Sa. Then, an accurate suction point of the lens suction jig 120 is obtained from the accurate outer shape (contour) of the lens shape L indicated by the circular dotted line Sa.

  Thereafter, the arithmetic control circuit 130 controls the operation of the drive motor 77, transmits the rotation of the drive motor 77 to the male screw shaft 75 via the pulley 78, the timing belt 79 and the pulley 76, and rotates the male screw shaft 75. Then, the female screw cylinder 72 is moved downward.

  Accordingly, the movable arm 80 integrated with the female screw cylinder 72 is lowered, the roller 84 at the tip of the movable arm 80 is separated from the horizontal plate portion 70a of the fixed arm 70, and the movable bracket 80 is shown in FIG. By the spring force of the torsion coil spring 83, the movable arm 80 is rotated to the lower surface side.

  Then, finally, as shown in FIG. 23, the lens suction jig 120 faces downward so that the lens suction jig 120 faces downward.

  On the other hand, with this operation, the guide roller 74 attached to the female screw cylinder 72 moves from the upper vertical slit portion 73a to the lower vertical slit portion 73c via the spiral slit portion 73b, and integrally with the female screw cylinder 72, The movable arm 80 is rotated by 90 ° toward the lens holder 46, and the lens suction jig 120 is moved above the spectacle lens ML.

  Thereafter, the female screw cylinder 72 and the movable arm 80 are further lowered, and the suction cup 122 of the lens suction jig 120 at the tip of the movable arm 80 is placed on the shaft-shaped lens receiver 49 as shown in FIGS. It is made to contact | abut to the spectacle lens ML.

  Then, the arithmetic control circuit 130 controls the operation of the drive motor 77, further lowers the female screw cylinder 72 and the movable arm 80, and further pushes the mounting shaft portion 121 of the lens suction jig 120 into the outer cylinder 88. Thus, the slide cylinder 92 is slightly moved toward the end wall 86c of the holder main body 86 against the spring force of the coil spring 93, and the lens adsorption jig 120 is adsorbed to the spectacle lens ML.

  Along with this, the locking hook 98 rotates counterclockwise in FIG. 30 by the spring force of the coil spring 99, and the inclined guide piece 98e becomes the small diameter shaft of the guide shaft 94 as shown in FIG. It moves on the part 94a. Thereby, the locking hook 98 is inclined as shown in FIG. 37B, and the inclined guide piece 98e is also inclined in the width direction.

  Thereafter, the arithmetic control circuit 80 reverses the drive motor 77 to raise the movable arm 80 integral with the female screw cylinder 72.

  Accordingly, the slide cylinder 92 is moved to the lens mounting shaft 121 side by the spring force of the coil spring 93, and the small diameter shaft portion 94a of the guide shaft 94 attached to the slide cylinder 92 is connected to the slide cylinder 92. It is moved integrally along the inclined guide piece 98e to the front end side of the locking hook 98.

  At this time, as shown in FIG. 37 (d), the small-diameter shaft portion 94a acts on the inclined guide piece 98e with the rotational force F directed in the opposite direction, such as the rotational biasing direction of the locking hook 98 by the coil spring 99. Let Accordingly, the locking hook 98 is slightly rotated in the clockwise direction against the spring force of the coil spring 99 of FIG. 30, and the small-diameter shaft portion 94 a of the guide shaft 94 is engaged with the locking hook 98. It is moved into the notch 98d.

  On the other hand, when the slide cylinder 92 is moved toward the lens attachment shaft portion 121 by the spring force of the coil spring 93, the attachment shaft portion 121 is pressed via the slide cylinder 92 by the spring force of the coil spring 93, and the outer cylinder. 88, the mounting shaft 121 is moved away from the linear portion 89b of the linear spring 89. In this state, the mounting shaft 121 is easily detached from the outer cylinder 88.

  When the arithmetic control circuit 80 further raises the female screw cylinder 72 and the movable arm 80, the roller 74 attached to the female screw cylinder 72 is raised in the lower vertical slit portion 73c, and the lens suction jig 120 is moved to the movable arm. It leaves the outer cylinder 88 at the tip of 80 and remains in the state of being attracted to the spectacle lens ML.

  Thereafter, the roller 74 attached to the female screw cylinder 72 is moved from the lower vertical slit portion 73c to the upper vertical slit portion 73a via the spiral slit portion 73b, and the movable arm 80 is rotated to the side plate 5 side by 90 °. Thus, the movable arm 80 is retracted from above the spectacle lens ML.

  When the movable arm 80 is raised and the roller 74 is raised in the upper vertical slit portion 73a, the roller 84 of the movable bracket 82 is moved to the horizontal plate portion 70a of the fixed arm 70 as shown in FIG. The movable bracket 80 is directed downward as shown in FIG. 21 against the spring force of the torsion coil spring 83 shown in FIG. As a result, as shown in FIG. 1, the movable bracket 80 faces the suction disk mounting opening 22, and a new lens suction jig 120 can be mounted.

  As described above, the spectacle lens suction jig mounting device according to the embodiment of the present invention has the mounting table (lens holder 46) on which the spectacle lens can be placed in the opening (47d), and the opening (47d). Imaging means (CCD 115) for taking an image of the spectacle lens placed on the lens, and position determining means (arithmetic control) for specifying the attachment position of the suction jig (lens suction jig 120) from the captured image of the eyeglass lens Circuit 130) and a mounting means (lens suction mechanism 68) for arranging a suction jig (lens suction jig 120) at the mounting position of the spectacle lens. In addition, the position determining means (arithmetic control circuit 130) adjusts the light quantity of the image pickup means (CCD 115), changes the exposure time according to the type of the spectacle lens, detects the contour of the spectacle lens, and cannot capture the image. For example, the position where the suction jig is mounted on the spectacle lens based on the detected outline (outer diameter shape La) of the spectacle lens. It comes to ask for.

  According to such a configuration, for example, the type or contour of the spectacle lens is detected even in a colored spectacle lens such as sunglasses or a coated spectacle lens, and the mounting position of the suction jig (suction cup) is specified. Can do.

  In addition, although the part (part shown by arrow Ax) which was not able to be imaged is displayed by dotted line Sa, the part (part shown by arrow Ax) which could not be imaged can be identified other than red, such as red and green It can be displayed with a color identification line or the like, or by changing the inner and outer colors of the portion indicated by the dotted line Sa, the portion (the portion indicated by the arrow Ax) that could not be imaged without using the dotted line Sa. An outline can also be displayed.

  Further, the image pickup means (CCD 115) has different exposure times so that an image for identifying the lens type of the spectacle lens and an image for identifying the contour of the spectacle lens can be appropriately processed. It is controlled to take an image.

  According to such a configuration, for example, the type or contour of the spectacle lens is detected even in a colored spectacle lens such as sunglasses or a coated spectacle lens, and the mounting position of the suction jig (suction cup) is specified. Can do.

1 shows an appearance of a lens suction jig mounting device according to the present invention. It is explanatory drawing of the liquid crystal display of FIG. It is a figure which shows the other structural example of a whole observation optical system. It is explanatory drawing of the display content of the liquid crystal display of FIG. It is explanatory drawing which shows the other example of the display content of the liquid crystal display of FIG. It is explanatory drawing which shows the other example of the display content of the liquid crystal display of FIG. It is explanatory drawing which shows the other example of the display content of the liquid crystal display of FIG. It is explanatory drawing which shows the other example of the display content of the liquid crystal display of FIG. FIG. 2 is a control circuit diagram of the lens suction jig mounting device shown in FIG. 1. It is a disassembled perspective view which shows the relationship between the outer case and frame of the lens adsorption jig mounting apparatus of FIG. It is a top view of the flame | frame of FIG. It is a schematic explanatory drawing inside the lens adsorption | suction jig mounting apparatus shown in FIG. It is effect | action explanatory drawing of FIG. FIG. 12 is a perspective view of the CL measuring device of FIGS. 10 and 11. It is a perspective view for demonstrating the lens holder of FIG. 10, FIG. FIG. 14 is a plan view of FIG. 13. It is sectional drawing which follows the A1-A1 line | wire of FIG. It is sectional drawing which follows the A3-A3 line | wire of FIG. It is sectional drawing which follows the A2-A2 line | wire of FIG. (A) is a schematic perspective view for the principal part description of a lens holder, (b) is a schematic sectional drawing of the lens holder of (a). It is a schematic perspective view of the lens holder for frame replacement. It is a schematic perspective view which shows the state which mounted | wore the ring-shaped gear of the lens holder of FIG. 17 with the lens holder for frame replacement of FIG. It is a side view of the lens adsorption | suction mechanism shown in FIG. FIG. 22 is a partial schematic exploded perspective view of the lens suction mechanism shown in FIG. 21. It is action | operation explanatory drawing of the lens adsorption | suction mechanism shown to FIG. It is action | operation explanatory drawing of the lens adsorption | suction mechanism shown to FIG. FIG. 22 is a side view of the suction jig holding means shown with a part of the movable bracket of FIG. 21 cut away. It is explanatory drawing which showed the adsorption jig holding means of FIG. 21 partially cut along the centerline. 20A is a sectional view of the suction jig holding means of FIG. 20 along the center line, FIG. 20B is a plan view of the outer cylinder of FIG. 20A, and FIG. 21C is a partial perspective view of the outer cylinder of FIG. . 26A is a perspective view of the holder main body of FIG. 26, FIG. 26B is a plan view of the holder main body of FIG. 26A viewed from the cylinder side, and FIG. 26C is a sectional view taken along the axis of the outer cylinder of FIG. d) It is sectional drawing when the cylinder part of (a) and the outer cylinder of (c) are fitted. FIG. 28 is a cross-sectional view of the suction jig holding means in a state where the mounting shaft portion of the lens suction jig of FIG. 27 is further pushed in. It is a perspective view explaining the latching hook of the suction jig holding means of FIG. It is a front view of the latching hook of FIG. It is sectional drawing which follows the B1-B1 line | wire of FIG. FIG. 32 is a plan view of FIG. 31. It is a perspective view which shows the state which has mounted | worn with the lens suction jig on the spectacle lens on a lens holder by the suction jig holding means of FIG. It is a fragmentary sectional view which shows the relationship between the suction jig holding means of FIG. 34, a lens suction jig, and a spectacle lens. It is a fragmentary sectional view which follows the B2-B2 line of FIG. It is explanatory drawing explaining the effect | action of the latching hook of FIG. 30 and FIG. (A) is a figure which shows the single focus lens by which the mark point was printed and displayed, and (b) is a figure which respectively shows the single focus lens without the mark point. It is a figure which shows a bifocal lens. It is a figure which shows a progressive multifocal lens. It is explanatory drawing which shows the other example of the display content of the liquid crystal display of FIG. It is explanatory drawing which shows the other example of the display content of the liquid crystal display of FIG.

Explanation of symbols

47d ... Opening 46 ... Lens holder (mounting table)
115 ... CCD (imaging means)
120 ... Lens adsorption jig (adsorption jig)
130. Arithmetic control circuit (position determining means)
ML ... Eyeglass lens Ax ... Arrow (location where imaging was not possible)
Sa ... dotted line (outline)
L ... Lens shape (lens shape of spectacle lens ML)
La ... Outer diameter shape (contour)

Claims (4)

A mounting table in which the spectacle lens can be placed in the opening;
A light source for irradiating the spectacle lens mounted on the mounting table with light;
A CCD that captures an image of the spectacle lens using light emitted from the light source to the spectacle lens placed in the opening;
A standard photographing mode used when the spectacle lens is not a high density lens and a high density mode of photographing used when the spectacle lens is a high density lens are provided. An arithmetic control circuit that operates the CCD in a progressive manner that adjusts the exposure start timing of the CCD pixels and the discharge timing from the pixels to adjust the CCD exposure time to acquire image data of each pixel; ,
A mounting means which makes placing the suction jig to the mounting position of the spectacle lens,
With
The arithmetic control circuit obtains an image for identifying the lens type attached to the spectacle lens from the image of the spectacle lens captured by the CCD, while from the image of the spectacle lens captured by the CCD. A spectacle lens suction jig mounting device that specifies a mounting position of the suction jig , controls the mounting means, and places the suction jig at the mounting position of the spectacle lens ,
The arithmetic control circuit changes the exposure time of the CCD to an exposure time capable of detecting the contour of the spectacle lens when the mode is switched to the high density mode, and detects the contour of the spectacle lens by the CCD. An apparatus for attaching an eyeglass lens suction jig, wherein the attachment position of the suction jig in the eyeglass lens is obtained based on the detected outline of the eyeglass lens. 2. The apparatus for attaching a spectacle lens suction jig according to claim 1, wherein the arithmetic control circuit is configured to provide spectacles with an exposure time that does not cause blooming in which the peripheral image of the spectacle lens is lost in the high density mode. An apparatus for attaching an eyeglass lens suction jig , wherein a lens is measured and the data at this time is used to acquire the contour data . 3. The spectacle lens suction jig mounting device according to claim 2, wherein the arithmetic control circuit is configured to calculate two set values obtained when the light source emits light at two different light emission times and a luminance value of the light source. An apparatus for attaching an eyeglass lens suction jig, wherein an automatic light quantity adjustment of the light source is performed by obtaining a predetermined linear equation from a proportional relationship and calculating an optimum luminance position that provides an optimum light quantity from the linear equation. 4. The spectacle lens suction jig mounting device according to claim 1, wherein an exposure time of the CCD for obtaining an image for identifying an outline of the spectacle lens, and an attachment to the spectacle lens. An apparatus for attaching an eyeglass lens suction jig, wherein the exposure time of the CCD for obtaining an image for identifying the lens type is varied.

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