WO2019026416A1 - 眼鏡枠形状測定装置、及びレンズ加工装置 - Google Patents
眼鏡枠形状測定装置、及びレンズ加工装置 Download PDFInfo
- Publication number
- WO2019026416A1 WO2019026416A1 PCT/JP2018/021700 JP2018021700W WO2019026416A1 WO 2019026416 A1 WO2019026416 A1 WO 2019026416A1 JP 2018021700 W JP2018021700 W JP 2018021700W WO 2019026416 A1 WO2019026416 A1 WO 2019026416A1
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- WO
- WIPO (PCT)
- Prior art keywords
- eyeglass frame
- rim
- groove
- light
- cross
- Prior art date
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Classifications
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- G—PHYSICS
- G01—MEASURING; TESTING
- G01B—MEASURING LENGTH, THICKNESS OR SIMILAR LINEAR DIMENSIONS; MEASURING ANGLES; MEASURING AREAS; MEASURING IRREGULARITIES OF SURFACES OR CONTOURS
- G01B11/00—Measuring arrangements characterised by the use of optical techniques
- G01B11/24—Measuring arrangements characterised by the use of optical techniques for measuring contours or curvatures
- G01B11/25—Measuring arrangements characterised by the use of optical techniques for measuring contours or curvatures by projecting a pattern, e.g. one or more lines, moiré fringes on the object
-
- G—PHYSICS
- G01—MEASURING; TESTING
- G01B—MEASURING LENGTH, THICKNESS OR SIMILAR LINEAR DIMENSIONS; MEASURING ANGLES; MEASURING AREAS; MEASURING IRREGULARITIES OF SURFACES OR CONTOURS
- G01B11/00—Measuring arrangements characterised by the use of optical techniques
- G01B11/24—Measuring arrangements characterised by the use of optical techniques for measuring contours or curvatures
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- B—PERFORMING OPERATIONS; TRANSPORTING
- B24—GRINDING; POLISHING
- B24B—MACHINES, DEVICES, OR PROCESSES FOR GRINDING OR POLISHING; DRESSING OR CONDITIONING OF ABRADING SURFACES; FEEDING OF GRINDING, POLISHING, OR LAPPING AGENTS
- B24B9/00—Machines or devices designed for grinding edges or bevels on work or for removing burrs; Accessories therefor
- B24B9/02—Machines or devices designed for grinding edges or bevels on work or for removing burrs; Accessories therefor characterised by a special design with respect to properties of materials specific to articles to be ground
- B24B9/06—Machines or devices designed for grinding edges or bevels on work or for removing burrs; Accessories therefor characterised by a special design with respect to properties of materials specific to articles to be ground of non-metallic inorganic material, e.g. stone, ceramics, porcelain
- B24B9/08—Machines or devices designed for grinding edges or bevels on work or for removing burrs; Accessories therefor characterised by a special design with respect to properties of materials specific to articles to be ground of non-metallic inorganic material, e.g. stone, ceramics, porcelain of glass
- B24B9/14—Machines or devices designed for grinding edges or bevels on work or for removing burrs; Accessories therefor characterised by a special design with respect to properties of materials specific to articles to be ground of non-metallic inorganic material, e.g. stone, ceramics, porcelain of glass of optical work, e.g. lenses, prisms
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- B—PERFORMING OPERATIONS; TRANSPORTING
- B24—GRINDING; POLISHING
- B24B—MACHINES, DEVICES, OR PROCESSES FOR GRINDING OR POLISHING; DRESSING OR CONDITIONING OF ABRADING SURFACES; FEEDING OF GRINDING, POLISHING, OR LAPPING AGENTS
- B24B9/00—Machines or devices designed for grinding edges or bevels on work or for removing burrs; Accessories therefor
- B24B9/02—Machines or devices designed for grinding edges or bevels on work or for removing burrs; Accessories therefor characterised by a special design with respect to properties of materials specific to articles to be ground
- B24B9/06—Machines or devices designed for grinding edges or bevels on work or for removing burrs; Accessories therefor characterised by a special design with respect to properties of materials specific to articles to be ground of non-metallic inorganic material, e.g. stone, ceramics, porcelain
- B24B9/08—Machines or devices designed for grinding edges or bevels on work or for removing burrs; Accessories therefor characterised by a special design with respect to properties of materials specific to articles to be ground of non-metallic inorganic material, e.g. stone, ceramics, porcelain of glass
- B24B9/14—Machines or devices designed for grinding edges or bevels on work or for removing burrs; Accessories therefor characterised by a special design with respect to properties of materials specific to articles to be ground of non-metallic inorganic material, e.g. stone, ceramics, porcelain of glass of optical work, e.g. lenses, prisms
- B24B9/148—Machines or devices designed for grinding edges or bevels on work or for removing burrs; Accessories therefor characterised by a special design with respect to properties of materials specific to articles to be ground of non-metallic inorganic material, e.g. stone, ceramics, porcelain of glass of optical work, e.g. lenses, prisms electrically, e.g. numerically, controlled
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- G—PHYSICS
- G02—OPTICS
- G02C—SPECTACLES; SUNGLASSES OR GOGGLES INSOFAR AS THEY HAVE THE SAME FEATURES AS SPECTACLES; CONTACT LENSES
- G02C13/00—Assembling; Repairing; Cleaning
Definitions
- the present disclosure relates to an eyeglass frame shape measuring device for obtaining the shape of an eyeglass frame, and a lens processing device for processing the periphery of a lens using the eyeglass frame shape measuring device.
- an eyeglass frame shape measuring apparatus which traces the contour of a rim and measures the shape of the rim by inserting a measuring element in the rim of the eyeglass frame and moving the measuring element against the rim by moving the element (for example, Patent Document 1).
- a shape (target shape) for fitting the spectacle lens to the rim is obtained based on the measurement result (trace data) of the rim obtained by the spectacle frame shape measuring device.
- the contour shape of the spectacle lens is determined based on the shape, and the rim of the lens is processed by the spectacle lens processing device.
- the shape of the rim and the contour shape of the lens after processing are closer.
- the measurement of the rim shape using the measuring element is easy to perform the measurement at the position where the measuring element is pressed (for example, the measurement of the bottom portion of the rim), the cross section of the groove of the rim It was difficult to get the shape.
- the present disclosure provides an eyeglass frame shape measuring device and a lens processing device capable of easily and accurately acquiring the cross-sectional shape of the rim of the eyeglass frame regardless of the type of eyeglass frame. It is a technical issue.
- this indication is characterized by having the following composition.
- An eyeglass frame shape measuring device for measuring the shape of an eyeglass frame, including a light source, and the light source directed toward the groove of the rim of the eyeglass frame
- the projection optical system emits measurement light
- the detector is irradiated by the projection optical system toward the groove of the rim of the eyeglass frame and reflected by the groove of the rim of the eyeglass frame
- a light receiving optical system that receives the reflected light of the measurement light by the detector, and an acquisition unit that acquires the cross-sectional shape of the groove of the rim of the eyeglass frame based on the reflected light received by the detector;
- brightness control means for controlling the brightness level of the reflected light received by the detector.
- a lens processing apparatus is a lens processing apparatus for processing the peripheral edge of a lens, which comprises the rim of the eyeglass frame obtained by the eyeglass frame shape measuring apparatus of (1). It is characterized by comprising processing control means for processing the peripheral edge of the lens based on the sectional shape of the groove.
- FIGS. 1 to 13 are diagrams for explaining the configuration of the eyeglass frame shape measuring apparatus according to the present embodiment.
- the depth direction of the spectacle frame shape measuring apparatus 1 (vertical direction of the spectacle frame when the spectacles are arranged) is perpendicular to the Y direction and the depth direction (in the case of the spectacle frame when the spectacles are arranged
- the horizontal direction on the horizontal plane is taken as the X direction
- the vertical direction front and back direction of the eyeglass frame when the glasses are arranged
- the rim portion of the eyeglass frame F is disposed in the downward direction, and the temple portion of the eyeglass frame F is in the upward direction. That is, when the eyeglass frame F is disposed in the eyeglass frame shape measuring apparatus 1, the left and right rims FL, FR of the eyeglass frame F are downward, and the left and right temples FTL, FTR of the eyeglass frame F are upward.
- a configuration in which the rim portion of the eyeglass frame F is disposed downward and the temple portion of the eyeglass frame F is disposed upward is described as an example. It is not limited to this.
- the rim portion of the eyeglass frame F may be disposed in the upward direction, and the temple portion of the eyeglass frame F may be disposed in the downward direction.
- the upper ends of the left and right rims FL and FR of the eyeglass frame F are downward, and the lower ends of the left and right rims FL and FR of the eyeglass frame F are upward
- the eyeglass frame F is disposed in the eyeglass frame shape measuring device 1
- the upper ends of the left and right rims FL and FR of the eyeglass frame F are upward, and the lower ends of the left and right rims FL and FR of the eyeglass frame F are downward It may be arranged to be
- the eyeglass frame shape measuring apparatus measures the shape of the eyeglass frame.
- the eyeglass frame shape measuring apparatus includes a light projecting optical system (for example, a light projecting optical system 30a).
- the eyeglass frame shape measuring apparatus includes a light receiving optical system (for example, a light receiving optical system 30b).
- the eyeglass frame shape measurement apparatus includes an acquisition unit (for example, the control unit 50).
- the projection optical system has a light source (for example, the light source 31).
- the projection optical system emits measurement light (measurement light flux) from the light source toward the groove of the rim of the eyeglass frame.
- at least one light source may be used as the light source.
- one light source may be used.
- a plurality of light sources may be used.
- the light receiving optical system includes a detector (for example, detector 37).
- the light receiving optical system is irradiated toward the groove of the rim of the eyeglass frame by the light projecting optical system, and the reflected light (reflected light flux) of the measurement light reflected by the groove of the rim of the eyeglass frame is received by the detector.
- at least one detector may be used as the detector.
- one detector may be used.
- multiple detectors may be used.
- the acquisition means processes the reflected light of the measuring light reflected by the groove of the rim of the eyeglass frame, and based on the reflected light of the measuring light received by the detector, the sectional shape of the groove of the rim of the eyeglass frame To get
- the eyeglass frame shape measuring apparatus emits light toward the rim of the eyeglass frame by the light projecting optical system that emits measurement light from the light source toward the rim of the eyeglass frame
- the light receiving optical system receives the reflected light of the measurement light reflected by the rim of the eyeglass frame by the detector, and the acquiring means processes the reflected light to acquire the cross-sectional shape of the rim of the eyeglass frame.
- the cross-sectional shape of the rim of the eyeglass frame can be easily and accurately obtained.
- measurement can be performed quickly.
- the projection optical system may have an optical member.
- the measurement light emitted from the light source may be irradiated toward the groove of the rim of the eyeglass frame through each optical member.
- the optical member at least one of a lens, a mirror, a diaphragm, and the like may be used.
- the depth of focus can be increased by using a stop.
- an optical member it is not limited to the said optical member, A different optical member may be used.
- the projection optical system may have a configuration in which the measurement light emitted from the light source is irradiated toward the groove of the rim of the eyeglass frame.
- it may be configured to have at least a light source.
- the measurement light emitted from the light source may be irradiated toward the groove of the rim of the eyeglass frame via a member different from the optical member.
- the measurement light irradiated toward the groove of the rim of the eyeglass frame by the projection optical system may be irradiated with a spot of measurement light.
- the measurement light irradiated toward the groove of the rim of the eyeglass frame by the projection optical system may be measurement light having a width (for example, measurement light in the form of a slit).
- the projection optical system may irradiate measurement light from the light source toward the groove of the rim of the eyeglass frame to form a light cutting surface on the groove of the rim.
- the light receiving optical system detects reflected light (eg, scattered light, specular light, etc.) of the groove of the rim obtained by reflection (eg, scattering, specular reflection, etc.) on the groove of the rim of the light cutting surface
- reflected light eg, scattered light, specular light, etc.
- reflection e.g. scattering, specular reflection, etc.
- a light source that emits a slit-like light beam may be used.
- a point light source may be used.
- the measurement light having a width may be irradiated by arranging a plurality of point light sources side by side.
- the measurement light having a width may be irradiated by scanning a spot-like light beam emitted from a point light source.
- the measurement light having a width may be irradiated by diffusing the spot-like measurement light emitted from the point light source by the optical member.
- the light source for example, various types of light sources different from the above light source may be used to emit measurement light having a width.
- the light receiving optical system may have an optical member.
- the reflected light of the measurement light reflected by the groove of the rim of the eyeglass frame may be received by the detector through each optical member.
- the optical member at least one of a lens, a mirror, a diaphragm, and the like may be used.
- an optical member it is not limited to the said optical member, A different optical member may be used.
- the light receiving optical system may have a configuration in which the reflected light of the measurement light reflected by the groove of the rim of the eyeglass frame is received by the detector.
- the configuration may have at least a detector.
- the detector may be configured to receive the reflected light of the measurement light reflected by the groove of the rim of the mirror frame via a member different from the optical member.
- the acquisition means processes the reflected light of the measurement light reflected by the groove of the rim of the eyeglass frame to acquire the cross-sectional shape of the groove of the rim of the eyeglass frame.
- the acquisition unit may acquire the cross-sectional shape from the light reception position of the reflected light in the detector.
- the cross-sectional shape may be an image (image data). That is, the cross-sectional shape may be a cross-sectional image.
- the cross-sectional shape may be a signal (signal data). That is, the cross-sectional shape may be signal data of the cross-sectional shape.
- the two-dimensional cross-sectional shape is a cross-sectional shape obtained by irradiating the measurement light to the groove of the rim at one radial angle and receiving the reflected light.
- the two-dimensional cross-sectional shape is obtained by cutting the groove of the rim in the direction (the Z direction in the present embodiment) perpendicular to the radial direction (the XY direction in the present embodiment) of the eyeglass frame It is the shape of a surface.
- the two-dimensional cross-sectional shape may be acquired by scanning the measurement light along the cross position (in the present embodiment, the Z direction).
- the three-dimensional cross-sectional shape is a cross-sectional shape acquired by acquiring a two-dimensional cross-sectional shape for each radius vector angle.
- the three-dimensional cross-sectional shape may be acquired by scanning the measurement light for acquiring the two-dimensional cross-sectional shape in the radial plane direction (in the present embodiment, the XY plane direction) of the eyeglass frame .
- the loss of light from the light reception result of the reflected light at a position around the lost position may be interpolated.
- the missing portion may be interpolated by approximating the cross-sectional shape.
- the cross-sectional shape may be re-acquired so that the lost portion is obtained.
- the secondary cross-sectional shape is a rim at at least one location (one radius angle position) of the entire circumference of the rim of the eyeglass frame (all portions where the rim is formed at each radius angle)
- a two-dimensional cross-sectional shape of the groove of may be acquired.
- the two-dimensional cross-sectional shape may be obtained all around the rim of the spectacle frame.
- the two-dimensional cross-sectional shape may be acquired at a plurality of positions (for example, the left end, the right end, the upper end, the lower end, etc.) of the rim of the eyeglass frame.
- the two-dimensional cross-sectional shape may be acquired at a position of one radial angle all around the rim of the eyeglass frame.
- the three-dimensional shape of the groove of the rim in at least a part of the entire circumference of the rim of the eyeglass frame (all portions where the rim is formed at each radial angle) may be acquired.
- the three-dimensional cross-sectional shape may be obtained all around the rim of the spectacle frame.
- the three-dimensional cross-sectional shape is obtained in a plurality of areas (for example, the left end area, the right end area, the upper end area, the lower end area, etc.) of the rim of the eyeglass frame May be Also, in this case, for example, the three-dimensional cross-sectional shape may be acquired in a partial region over the entire circumference of the rim of the eyeglass frame.
- the two-dimensional cross-sectional shape of the rim of the eyeglass frame is acquired with respect to the entire circumference of the rim of the eyeglass frame.
- the three-dimensional cross-sectional shape of the entire circumference of the rim of the eyeglass frame may be acquired by performing interpolation based on the two-dimensional cross-sectional shape (three-dimensional cross-sectional shape) of the part.
- the eyeglass frame shape measuring apparatus may include a first changing unit (for example, the moving unit 210, the rotating unit 260).
- the first changing means changes the irradiation position of the measurement light to the groove of the rim of the eyeglass frame.
- the eyeglass frame shape measuring apparatus may include a first control unit (for example, the control unit 50) that controls the first changing unit.
- the eyeglass frame shape measuring apparatus includes a first change unit that changes the irradiation position of the measurement light with respect to the groove of the rim of the eyeglass frame, and a first control unit that controls the first change unit. This makes it possible to irradiate the measurement light to the position of the groove of any rim in the eyeglass frame, and to obtain the cross-sectional shape of the groove of the rim at any position.
- the first changing unit may be configured to change the relative position between the irradiation position of the measurement light and the groove of the rim of the eyeglass frame.
- the first changing means may be configured to change the position of at least one of the irradiation position of the measurement light and the position of the groove of the rim of the eyeglass frame.
- the first changing unit may be configured to change the position of the groove of the rim of the eyeglass frame with respect to the irradiation position of the measurement light. That is, the first changing unit may be configured to change the position of the eyeglass frame with respect to the irradiation position of the measurement light.
- the first changing unit may change the irradiation position of the measurement light with respect to the position of the groove of the rim of the eyeglass frame.
- the first changing unit may be configured to change both the position of the groove of the rim of the eyeglass frame and the irradiation position of the measurement light.
- the position of the projection optical system may be the position of the optical axis (for example, the optical axis L1) of the projection optical system. That is, for example, the first changing unit changes the relative position between the position of the optical axis of the light projecting optical system and the groove of the rim of the eyeglass frame, so that the relative position between the irradiation position of the measurement light and the groove of the rim of the eyeglass frame The position may be changed.
- the position of the projection optical system for example, the position of the optical axis of the projection optical system
- the position of the projection optical system and the spectacle frame The position of at least one of the position of the groove of the rim may be changed.
- the position of the groove of the rim of the eyeglass frame relative to the position of the projection optical system may be changed.
- the projection optical with respect to the position of the groove of the rim of the eyeglass frame It may be configured to change the position of the system.
- the position of the light projection optical system and the position of the groove of the rim of the eyeglass frame the position of the light projection optical system and the position of the groove of the rim of the eyeglass frame The position of both may be changed.
- the position of at least one member (for example, a light source, an optical member, other members, etc.) included in the light projection optical system is changed. It is also good. That is, for example, the first changing unit changes the position of the light projecting optical system with respect to the groove of the rim of the eyeglass frame by changing the position of at least a part (a part of the members) of the light projecting optical system. It may be. In this case, for example, the first control means changes the position of at least a part of the light projecting optical system by changing the first changing means, and changes the irradiation position of the measurement light to the groove of the rim of the eyeglass frame You may do so.
- the first changing unit changes the position of the light projecting optical system with respect to the groove of the rim of the eyeglass frame by changing the position of at least a part (a part of the members) of the light projecting optical system. It may be.
- the first control means changes the position of at least a part of the light projecting optical system by changing the first changing
- the first changing means is a first changing means for moving at least a part of the light projecting optical system
- the first control means controls the first changing means to At least a part of the projection optical system is moved with respect to the groove of the rim of the frame to change the irradiation position of the measurement light with respect to the groove of the rim of the spectacle frame.
- an X direction driving unit having a drive source (for example, a motor) and moving the position of at least a portion of the light projecting optical system in the X direction
- a Y direction driving means having a drive source (for example, a motor) and moving the position of at least a part of the light projecting optical system in the Y direction
- a Z direction driving unit having a drive source (for example, a motor) and moving the position of at least a part of the light projecting optical system in the Z direction
- a drive source for example, a motor
- rotational driving means for example
- the configuration for changing the position of at least a part of the light projecting optical system may be at least one of an X direction driving unit, a Y direction driving unit, a Z direction driving unit, and a rotation driving unit.
- the configuration for changing the position of at least a part of the light projecting optical system is not limited to the above driving means, and the driving means is used in a direction different from the above direction for at least a part of the light projecting optical system. It may be a configuration.
- a scanning unit that has an optical scanner and scans the optical scanner may be used.
- the irradiation position of the measurement light may be changed by changing the angle of the light scanner. That is, for example, the irradiation position of the measurement light may be changed by changing the position of the light scanner.
- an X-direction drive unit having a drive source (for example, a motor) and moving the eyeglass frame in the X direction may be used.
- Y-direction drive means may be provided which has a drive source (for example, a motor) and moves the eyeglass frame in the Y direction.
- Z-direction drive means having a drive source (for example, a motor) and moving the eyeglass frame in the Z direction may be used.
- a rotational drive means having a drive source (for example, a motor) and rotating the eyeglass frame may be used.
- the configuration of changing the position of the groove of the rim of the eyeglass frame may be at least one of an X direction drive unit, a Y direction drive unit, a Z direction drive unit, and a rotation drive unit.
- the configuration for changing the position of the groove of the rim of the eyeglass frame is not limited to the above drive means, and the drive means is used in a direction different from the above direction for the position of the groove of the rim of the eyeglass frame It is also good.
- the eyeglass frame shape measuring apparatus may be provided with a second changing unit (for example, the moving unit 210, the rotating unit 260).
- the second changing unit changes the light receiving position of the reflected light by the light receiving optical system.
- the eyeglass frame shape measuring apparatus may include a second control unit (for example, the control unit 50) that controls the second changing unit.
- the eyeglass frame shape measuring apparatus includes a second changing unit that changes the light receiving position of the reflected light by the light receiving optical system, and a second control unit that controls the second changing unit.
- the light receiving position can be changed to a position where the cross-sectional shape of the groove of the rim can be favorably acquired, and the cross-sectional shape of the rim of the eyeglass frame can be acquired more accurately.
- the second changing unit may change the relative position between the position of the light receiving optical system and the groove of the rim of the eyeglass frame to change the light receiving position of the reflected light by the light receiving optical system.
- the position of the light receiving optical system may be the position of the optical axis (for example, the optical axis L2) of the light receiving optical system. That is, for example, the second changing unit changes the relative position between the position of the optical axis of the light receiving optical system and the groove of the rim of the eyeglass frame to obtain the relative position between the irradiation position of the measurement light and the groove of the rim of the eyeglass frame May be changed.
- the second changing unit may change at least one of the position of the light receiving optical system and the position of the groove of the rim of the eyeglass frame.
- the second changing unit may be configured to change the position of the groove of the rim of the eyeglass frame with respect to the position of the light receiving optical system. That is, the second changing unit may be configured to change the position of the eyeglass frame with respect to the position of the light receiving optical system.
- the second changing unit may be configured to change the position of the light receiving optical system with respect to the position of the groove of the rim of the eyeglass frame.
- the second changing unit may be configured to change both the position of the groove of the rim of the eyeglass frame and the position of the light receiving optical system.
- the second changing unit is configured to change the position of the light receiving optical system with respect to the groove of the rim of the eyeglass frame by changing the position of at least a part (a part of the members) of the light receiving optical system. It is also good.
- the second control means changes the position of at least a part of the light receiving optical system by controlling the second changing means, and changes the light receiving position of the reflected light by the light receiving optical system. Good.
- an X direction driving unit having a drive source (for example, a motor) and moving the position of at least a part of the light receiving optical system in the X direction.
- a drive source for example, a motor
- Y direction driving unit that has a drive source (for example, a motor) and moves the position of at least a part of the light receiving optical system in the Y direction.
- a Z direction driving unit having a drive source (for example, a motor) and moving the position of at least a part of the light receiving optical system in the Z direction.
- a rotational drive unit having a drive source (for example, a motor) and rotating at least a part of the light receiving optical system may be used.
- the configuration for changing the position of at least a part of the light receiving optical system may be at least one of an X direction drive unit, a Y direction drive unit, a Z direction drive unit, and a rotation drive unit.
- the configuration for changing the position of at least a part of the light receiving optical system is not limited to the above driving means, and the driving means is used in a direction different from the above direction for at least a part of the light receiving optical system. It may be.
- a scanning unit that has an optical scanner and scans the optical scanner may be used.
- the light receiving position of the reflected light by the light receiving optical system may be changed by changing the angle of the light scanner. That is, for example, the light receiving position of the reflected light by the light receiving optical system may be changed by changing the position of the light scanner.
- control of the first changing unit and the control of the second changing unit may be controlled at different timings.
- control of the first change means and the control of the second change means may be controlled integrally.
- at least a part of the members of the configuration of the first changing unit and the configuration of the second changing unit may be used in common.
- the eyeglass frame shape measuring apparatus may acquire the shape (shape data) of the eyeglass frame.
- the eyeglass frame shape measuring apparatus may include an analysis unit (for example, the control unit 50).
- the first control means may control the first changing means to irradiate the measurement light to the groove of the rim at a plurality of radius vector angles of the eyeglass frame.
- the acquisition means may acquire the cross-sectional shape of the groove of the rim at a plurality of radius vector angles of the eyeglass frame.
- the analysis means detects the bottom of the groove of the rim at a plurality of radius angles of the eyeglass frame from the cross-sectional shape of the groove of the rim at a plurality of radius angles of the eyeglass frame, and detects the glasses based on the detection result
- the shape of the frame may be acquired.
- the shape of the eyeglass frame may be a two-dimensional shape (two-dimensional shape data).
- the two-dimensional shape is represented by data in the radial direction (XY direction) of the eyeglass frame.
- the shape of the eyeglass frame may be a three-dimensional shape (three-dimensional shape data).
- the three-dimensional shape is represented by data in a radial direction (XY direction) of the eyeglass frame and a direction (Z direction) perpendicular to the radial direction.
- the analysis unit may detect the position of the groove of the rim in the X and Y directions from the three-dimensional shape to acquire the two-dimensional shape.
- the two-dimensional shape may be obtained by projecting the three-dimensional shape onto the XY plane.
- the first control means controls the first changing means to irradiate the measurement light to the groove of the rim at a plurality of radius vector angles of the eyeglass frame.
- An acquisition means acquires the cross-sectional shape of the groove
- the eyeglass frame shape measuring apparatus detects the bottom of the groove of the rim at a plurality of radius vector angles of the eyeglass frame from the cross-sectional shape of the groove of the rim at a plurality of radius vector angles of the eyeglass frame.
- An analysis means for acquiring the shape of the eyeglass frame is provided. This makes it possible to prevent the measuring element from coming off the groove of the lens frame and making it impossible to measure depending on the eyeglass frame as in the conventional case, and the eyeglass frame can be accurately and easily for eyeglass frames of various shapes. You can get the shape of.
- the shape of the eyeglass frame may be obtained in at least a partial region of the entire circumference of the rim of the eyeglass frame (all portions where the rim is formed at each radial angle).
- the shape of the eyeglass frame may be obtained all around the rim of the eyeglass frame.
- the shape of the eyeglass frame is obtained in a plurality of areas (for example, the left end area, the right end area, the upper end area, the lower end area, etc.) of the entire rim of the eyeglass frame. May be Also, in this case, for example, the shape of the eyeglass frame may be acquired in a partial region around the entire circumference of the rim of the eyeglass frame.
- the shape of the eyeglass frame was acquired when it is desired to acquire the shape of the eyeglass frame all around the rim of the eyeglass frame
- the shape of the entire circumference of the rim of the eyeglass frame may be acquired by performing interpolation based on the shape of the part.
- the eyeglass frame shape measuring apparatus may acquire a three-dimensional cross-sectional shape.
- the first control means controls the first changing means to irradiate the measurement light to the groove of the rim at a plurality of radius vector angles of the eyeglass frame.
- the acquiring unit may acquire the three-dimensional cross-sectional shape by acquiring cross-sectional shapes of the groove of the rim at a plurality of radius vector angles of the eyeglass frame.
- the first control means controls the first changing means to irradiate measurement light to the groove of the rim at a plurality of radius vector angles of the eyeglass frame.
- An acquisition means acquires the cross-sectional shape of the groove
- the three-dimensional cross-sectional shape of the eyeglass frame can be easily and accurately obtained.
- the inventors irradiate measurement light toward the groove of the rim of the eyeglass frame, receive the reflected light of the measurement light reflected by the groove of the rim of the eyeglass frame, and based on the reflected light, the eyeglass frame
- the eyeglass frame shape measuring apparatus provided with the structure which acquires the cross-sectional shape of the groove
- the luminance level of the reflected light received is not good, and it is difficult to accurately obtain the cross-sectional shape of the groove of the rim I found it to be.
- a configuration for solving this problem will be described.
- the eyeglass frame shape measuring apparatus may include brightness control means (for example, the control unit 50).
- the brightness control means controls (changes) the brightness level (brightness value) of the reflected light received by the detector.
- the eyeglass frame shape measuring device is directed to the rim of the eyeglass frame by the projection optical system that emits measurement light from the light source toward the rim of the eyeglass frame and the projection optical system A light receiving optical system that receives the reflected light of the measurement light that is irradiated and reflected by the rim of the eyeglass frame, and an acquisition unit that acquires the cross-sectional shape of the rim of the eyeglass frame based on the reflected light received by the detector And.
- the eyeglass frame shape measuring apparatus further includes: brightness control means for controlling the brightness level of the reflected light received by the detector.
- the brightness control means may control the brightness level by controlling at least one of the members included in the eyeglass frame shape measuring apparatus.
- each member may be at least one of a light source, a detector, a lens, a reflecting member, and the like.
- the brightness control means may control the brightness level of the reflected light received by the detector by controlling the projection light amount of the measurement light from the light source.
- control of the luminance level can be performed with a simple configuration.
- the brightness control means may control the brightness level of the reflected light received by the detector by controlling the gain of the detector.
- control of the luminance level can be performed with a simple configuration.
- the brightness control means may be configured to provide a member for adjusting the light amount of the measurement light in the light path from the light source to the detector (in the light path of the light projecting optical system and the light receiving optical system).
- a dedicated member for adjusting the amount of light may be provided.
- a dedicated member a light quantity adjustment filter or an optical attenuator may be used.
- any one of the light emitting optical system and the light receiving optical system may be used as the light amount adjusting member.
- the brightness control means may control the brightness level of the reflected light received by the detector by controlling the exposure time in the detector. Also, for example, the brightness control means may control the brightness level of the reflected light received by the detector by controlling the light emission time of the light source.
- the brightness control unit is not limited to the above configuration.
- the brightness control means may be configured to be able to control the brightness level of the reflected light received by the detector.
- the brightness control unit may be at least one of the above configurations.
- the brightness control means may be configured to include one of the above configurations.
- the brightness control unit may combine a plurality of configurations among the above configurations.
- the brightness control means may perform control of the projection light amount of the measurement light from the light source and adjustment of the gain of the detector.
- the brightness control means may control the brightness level based on the brightness level of the reflected light.
- the brightness control means may control the brightness level based on the brightness level of the reflected light received by the detector.
- the brightness control means may perform control of the brightness level so that at least a part of a shoulder of the rim and at least a part of a slope of a groove of the rim in the eyeglass frame can be detected.
- the shoulders of the rim may be shoulders on the front of the rim and shoulders on the rear of the rim. More preferably, the brightness control means may control the brightness level so that the end of the rim shoulder is detected.
- the slope of the groove of the rim may be the front slope of the groove of the rim and the back slope of the groove of the rim.
- the cross-sectional shape of the rim can be obtained by being able to detect at least a portion of the shoulder of the rim and at least a portion of the slope of the groove of the rim.
- the luminance level of the reflected light may be detected from the signal of the reflected light.
- the brightness control unit may control the brightness level based on the brightness level detected from the signal of the reflected light.
- the brightness level of the reflected light may be detected from the cross-sectional image by acquiring the cross-sectional image from the signal of the reflected light.
- the acquisition unit may acquire a cross-sectional image as the cross-sectional shape.
- the eyeglass frame shape measuring apparatus may be provided with a luminance analysis unit (for example, the control unit 50) that detects a luminance level from the cross-sectional image.
- the brightness control unit may control the brightness level based on the brightness level detected by the brightness analysis unit. Note that, for example, when the luminance analysis unit detects the luminance level from the cross-sectional image, the luminance level may be detected from at least a part of the cross-sectional image.
- the luminance level can be controlled based on the acquired cross-sectional image, the luminance level can be controlled easily and accurately.
- the luminance level of the reflected light may be detected by a configuration different from the above configuration.
- control may be performed on the basis of a parameter.
- an allowable level for example, a predetermined threshold
- the luminance control means controls the luminance level such that the luminance level satisfies the allowable level. It is also good.
- the eyeglass frame shape measuring apparatus includes a determination unit (for example, the control unit 50) that determines whether the luminance level is an allowable level, and the luminance control unit is based on the determination result of the determination unit.
- the brightness level may be controlled.
- the brightness level is controlled based on, for example, the determination of whether or not the brightness level of the reflected light is a brightness level at which the cross-sectional shape of the groove of the rim can be favorably obtained. It can be carried out. That is, the luminance level can be controlled more accurately.
- the above-mentioned permissible level may be a preset permissible level.
- an allowable level may be set in advance in which the luminance level is determined to be good by simulation, experiment, or the like.
- the acceptable level may be set to a brightness level that allows detection of at least a portion of a shoulder of the rim and at least a portion of a slope of a groove of the rim in the eyeglass frame.
- the permissible level may be configured to be arbitrarily set by the examiner.
- the allowable level may be set based on the acquired cross-sectional image.
- the brightness control means may control the brightness level by the operation of the operation unit (for example, the switch unit 4) by the operator.
- the eyeglass frame shape measuring apparatus includes receiving means for receiving an operation signal for changing the brightness level from the operation unit, and the brightness control means receives the brightness level based on the operation signal received by the receiving means. It may be controlled.
- guide information for assisting the operation of the luminance level may be presented.
- the guide information is at least one of warning information indicating that the brightness level does not satisfy the tolerance level, information prompting confirmation of the brightness level, information indicating the brightness level, and information indicating the tolerance level. It is also good.
- the guide information is not limited to the above configuration, and may be information that can confirm whether the luminance level satisfies the allowable level.
- the brightness control means may control the brightness level based on the eyeglass frame type information.
- the eyeglass frame type information acquiring means for acquiring eyeglass frame type information is provided, and the luminance control means controls the luminance level based on the eyeglass frame type information acquired by the eyeglass frame type information acquiring means.
- the brightness control means sets the eyeglass frame type information acquired by the eyeglass frame type information acquisition means as information for controlling the luminance level, and controls the luminance level based on the set eyeglass frame type information. You may do it.
- the luminance level can be controlled according to the eyeglass frame type, and without performing analysis processing such as image processing, regardless of the type of eyeglass frame, the sectional shape of the rim of the eyeglass frame Can be easily acquired accurately.
- the eyeglass frame type in the eyeglass frame type information may be at least one of the shape of the eyeglass frame, the material of the eyeglass frame, the color of the eyeglass frame, the design of the eyeglass frame, and the configuration information of the eyeglass frame.
- the shape of the eyeglass frame may be any shape such as Full lim, Two point, and Nylor.
- the shape of the eyeglass frame may be different from that described above.
- any of metal, plastic, optyl, etc. may be used.
- the material of the eyeglass frame may be a material different from the above.
- the color of the eyeglass frame may be at least one of red, blue, yellow, black, gray and the like.
- the design of the eyeglass frame may be at least one of a dot, a border, and the like.
- the design of the eyeglass frame may be different from the above.
- the configuration information of the eyeglass frame at least one of a lens shape of the eyeglass frame, a sled angle of the eyeglass frame, an anteversion angle of the eyeglass frame, and the like may be used.
- the configuration information of the eyeglass frame may be configuration information different from the above.
- the eyeglass frame of the type which has a rim generally is mentioned.
- a rimless eyeglass frame in which a temple or a bridge is directly attached to an eyeglass lens.
- a type of spectacle frame without a rim there is a type of spectacle frame without a rim. In this case, the eyeglass lens is fixed to a portion without a rim by nylon thread or the like.
- the eyeglass frame type information may be associated with a plurality of eyeglass frame type information.
- a predetermined eyeglass frame type for example, the shape of the eyeglass frame
- the eyeglass frame type of the other item for example, eyeglass frame material
- the shape of the eyeglass frame may be obtained as a full rim. In this case, it is preferable to associate the eyeglass frame types in advance.
- spectacles frame type it is not limited to these types, Various types of spectacles frame can be set.
- eyeglass frame type may be configured to be optionally added or deleted by the examiner.
- the composition inputted by operation of an examiner is mentioned.
- the examiner operates from the configuration in which the examiner operates the operation unit to directly input the eyeglass frame type information or the eyeglass frame type information stored in the memory of the eyeglass frame shape measuring device
- the eyeglass frame type information is selected by operating the unit.
- the eyeglass frame type information acquisition means in the eyeglass frame shape measuring apparatus, a frame detection means for detecting the eyeglass frame is provided, and based on the detection result of the frame detection means (for example, thickness of the eyeglass frame)
- the eyeglass frame type information may be acquired.
- a configuration for acquiring the eyeglass frame type information there is a configuration in which the eyeglass frame type information input by an apparatus different from the eyeglass frame shape measuring apparatus separately is received by the receiving unit.
- the brightness control means may control the brightness level based on the measurement position in the eyeglass frame.
- the brightness control means may detect the irradiation position of the measurement light and control the brightness level according to the irradiation position of the measurement light (for example, the bridge peripheral position, the temple peripheral position, etc.) .
- the luminance control means when controlling the luminance level, may be implemented before starting the measurement.
- the acquiring unit acquires the cross-sectional shape of the groove of the rim of the eyeglass frame based on the reflected light received by the detector after the luminance level is controlled and changed by the luminance control unit.
- pre-measurement is performed to irradiate the measurement light and receive the reflected light at at least one or more measurement positions in the eyeglass frame.
- the brightness control means controls the brightness level based on the brightness level of the reflected light acquired by the pre-measurement.
- the acquiring means acquires the cross-sectional shape of the groove of the rim of the eyeglass frame based on the reflected light received by the detector after the luminance level is controlled and changed.
- the measurement may be performed at the same measurement position (the number of points) as the main measurement.
- a measurement position where the brightness level is not good may be detected in advance from the result of the pre-measurement, and the brightness level may be controlled at the measurement position where the brightness level is not good at the time of main measurement.
- the brightness control means may be implemented after the measurement is started.
- the control of the luminance level is performed based on the luminance level of the reflected light acquired by the measurement.
- the control of the luminance level may be performed based on the luminance level of the reflected light at at least one or more measurement positions.
- the brightness level of the reflected light at the one or more measurement positions may be detected, and the brightness level may be controlled based on the detected brightness level.
- the luminance level at the measurement position where the luminance level is detected may be controlled, or the luminance level at all the measurement positions of the main measurement may be controlled.
- the luminance level is detected, and when the luminance level is not good, the control of the luminance level is performed.
- measurement may be performed again, and the measurement result before the luminance level control may be replaced with the measurement result after the luminance level control.
- the measurement result may be replaced when controlling the brightness level at all measurement positions where measurement is performed.
- the brightness level is detected at each measurement position, and measurement is performed again at a position where the brightness level is not good.
- the measurement results May be replaced with the measurement result after the brightness level control.
- the measurement result may be replaced when the measurement is performed again at another position where the luminance level is not good.
- the timing at which the brightness control means controls the brightness level is not limited to the above timing.
- the brightness level may be controlled at a timing different from the above.
- the brightness control means may control the brightness level both before starting the measurement and after starting the measurement.
- At least one of an acquisition unit, a first control unit, a second control unit, an analysis unit, a luminance control unit, a luminance analysis unit, and a determination unit is used. It is also good. Furthermore, for example, the acquisition unit, the first control unit, the second control unit, and the analysis unit may be separately provided.
- the cross-sectional shape of the groove of the rim of the eyeglass frame acquired by the eyeglass frame shape measuring apparatus may be used for processing of the lens.
- the lens processing apparatus for example, the lens processing apparatus 300 which processes the periphery of a lens acquires the cross-sectional shape of the groove of the rim of the eyeglass frame acquired by the eyeglass frame shape measuring apparatus.
- the eyeglass frame shape measuring apparatus may have transmitting means, and the transmitting means may transmit the sectional shape of the groove of the rim of the eyeglass frame to the lens processing apparatus.
- the lens processing apparatus may have a receiving unit to receive the cross-sectional shape of the groove of the rim of the eyeglass frame transmitted from the eyeglass frame shape measuring apparatus.
- the lens processing device may be configured to include the eyeglass frame shape measuring device.
- the lens processing device and the eyeglass frame shape measuring device may be separate devices.
- the cross-sectional shape of the groove of the rim of the eyeglass frame may be transmitted from the eyeglass frame shape measuring device to the lens processing device by at least one of wired and wireless.
- the lens processing apparatus may include processing control means (for example, the control unit 310).
- the processing control means may process the periphery of the lens based on the cross-sectional shape of the groove of the rim of the eyeglass frame acquired by the eyeglass frame shape measuring device.
- the processing control means may control the lens holding means for holding the lens and the processing tool to process the periphery of the lens based on the cross-sectional shape of the groove of the rim of the eyeglass frame.
- the lens processing apparatus includes processing control means for processing the periphery of the lens based on the cross-sectional shape of the groove of the rim of the eyeglass frame.
- processing control means for processing the periphery of the lens based on the cross-sectional shape of the groove of the rim of the eyeglass frame.
- FIG. 1 is a schematic view of an eyeglass frame shape measuring apparatus.
- FIG. 2 is a top view of the frame holding unit with the eyeglass frame held.
- the eyeglass frame shape measuring apparatus 1 includes the frame holding unit 10 and the measuring unit 20.
- the frame holding unit 10 holds the eyeglass frame F in a desired state.
- the measurement unit 20 emits measurement light toward the grooves of the rims of the eyeglass frame F (for example, the left rim FL, the right rim FRs) held by the frame holding unit 10, and receives the reflected light. , And is used to obtain the cross-sectional shape of the groove of the rim of the eyeglass frame F.
- the measurement unit 20 is disposed below the frame holding unit 10.
- a switch unit 4 having a switch for starting measurement and the like is disposed on the front side of the casing of the eyeglass frame shape measuring apparatus 1.
- a touch panel type display 3 is disposed on the rear side of the casing of the eyeglass frame shape measuring apparatus 1.
- layout data of the lens with respect to the lens-shaped data, processing conditions of the lens, and the like are input by the panel unit 3.
- the acquisition result (cross-sectional shape of groove of rim, eyeglass frame shape, etc.) obtained by the eyeglass frame shape measuring device 1 and the data input by the display 3 are transmitted to the lens processing device.
- the eyeglass frame shape measuring apparatus 1 may be configured to be incorporated in a lens processing apparatus, as in Japanese Patent Laid-Open No. 2000-314617 and the like.
- a measurement unit 20 is provided below the frame holding unit 10.
- the front slider 102 and the rear slider 103 for holding the eyeglass frame F horizontally are placed on the holding portion base 101.
- horizontal may be substantially horizontal.
- the front slider 102 and the rear slider 103 are slidably disposed opposite to each other on the two rails 111 with the center line CL at the center, and always in the direction toward the both center lines CL by the spring 113 It is being pulled.
- clamp pins 130a and 130b for clamping the rim of the eyeglass frame F from its thickness direction are disposed at two positions.
- clamp pins 131a and 131b for clamping the rim of the eyeglass frame F from its thickness direction are disposed at two positions.
- a known template holding jig is disposed at a predetermined mounting position 140 and used.
- the configuration of the frame holding unit 10 for example, a known one described in Japanese Patent Laid-Open No. 2000-314617 or the like can be used.
- the lower side of the rim at the time of wearing is positioned on the front slider 102 side, and the upper side of the rim is positioned on the rear slider 103 side.
- the eyeglass frame F is held in a predetermined measurement state by clamp pins located on the lower and upper sides of the left and right rims, respectively.
- the configuration of the clamp pins 130a and 130b and the clamp pins 131a and 131b has been described as an example of the configuration for regulating the position of the rim in the front-rear direction, but the present invention is not limited thereto.
- Well known mechanisms may be used.
- a configuration may be employed in which contact members (regulating members) having V-shaped grooves are respectively provided for the left and right rims.
- the measurement unit 20 includes an eyeglass frame measurement optical system 30.
- the eyeglass frame measuring optical system 30 includes a light projecting optical system 30a and a light receiving optical system 30b.
- the projection optical system 30a and the light receiving optical system 30b are used to obtain the shape of the eyeglass frame and the cross-sectional shape of the groove of the rim of the eyeglass frame (details will be described later).
- the measurement unit 20 includes a holding unit 25 that holds the light projecting optical system 30a and the light receiving optical system 30b.
- the measurement unit 20 includes a moving unit 210 that moves the holding unit 25 in the XYZ directions (see, for example, FIGS. 3 to 5).
- the measurement unit 20 includes a rotation unit 260 that rotates the holding unit 25 around the rotation axis L0 (see, for example, FIG. 6).
- the XY direction is parallel to the measurement plane (radial radius direction of the rim) of the eyeglass frame F held by the frame holding unit 10, and the Z direction is the direction perpendicular to the measurement plane.
- FIGS. 3 to 5 illustrate the configuration of the mobile unit 210.
- FIG. 3 shows a perspective view of the moving unit 210 as viewed from above.
- FIG. 4 shows a perspective view of the moving unit 210 as viewed from below.
- FIG. 5 shows a top perspective view of the Z moving unit 220 and the Y moving unit 230 (a perspective view with the X moving unit 240 and the base portion 211 removed).
- the moving unit 210 roughly includes a Z moving unit (Z direction driving unit) 220, a Y moving unit (Y direction driving unit) 230, and an X moving unit (X direction driving unit) 240.
- the Z moving unit (Z direction driving means) 220 moves the holding unit 25 in the Z direction.
- the Y moving unit 230 holds the holding unit 25 and the Z moving unit 220 and moves them in the Y direction.
- the X moving unit 240 moves the holding unit 25 together with the Z moving unit 220 and the Y moving unit 230 in the X direction.
- the X mobile unit 240 is roughly configured as follows.
- the X moving unit 240 includes a guide rail 241 extending in the X direction below the base portion 211 having a rectangular frame extended in the horizontal direction (XY direction).
- the Y base 230 a of the Y moving unit 230 is attached movably in the X direction along the guide rail 241.
- a motor (drive source) 245 is attached to the base portion 211.
- a feed screw 242 extending in the X direction is attached to the rotation shaft of the motor 245.
- a nut portion 246 fixed to the Y base 230 a is screwed into the feed screw 242.
- the Y base 230a is moved in the X direction.
- the movement range of the X movement unit 240 in the X direction moves the Y base 230a on which the holding unit 25 is mounted to the left or right width of the eyeglass frame to enable measurement of the left and right lens frames of the eyeglass frame. It may have a possible length.
- the Y movement unit 230 is roughly configured as follows.
- a guide rail 231 extending in the Y direction is attached to the Y base 230a.
- the Z base 220 a is mounted movably in the Y direction along the guide rail 231.
- a Y movement motor (drive source) 235 and a feed screw 232 extending in the Y direction are rotatably attached to the Y base 230a.
- the rotation of the motor 235 is transmitted to the feed screw 232 via a rotation transmission mechanism such as a gear.
- a nut 227 attached to the Z base 220a is screwed into the feed screw 232.
- the X moving unit 240 and the Y moving unit 230 constitute an XY moving unit.
- the range in which the holding unit 25 is moved in the X and Y directions is larger than the measurable radius of the rim.
- the movement position of the holding unit 25 in the XY direction is detected by the number of pulses for driving the motors 245 and 235 by the control unit 50 described later, and the first XY for detecting the position of the holding unit 25 in the XY direction.
- the position detection unit is constituted by the motors 245 and 235 and the control unit 50.
- a sensor such as the XY position detection unit of the holding unit 25, in addition to detection by pulse control of the motors 245 and 235, a sensor such as an encoder attached to the respective rotation shafts of the motors 245 and 235 may be used.
- the Z moving unit 220 is roughly configured as follows.
- a guide rail 221 extending in the Z direction is formed on the Z base 220a, and a moving base 250a to which the holding unit 25 is attached is held movably in the Z direction along the guide rail 221.
- a pulse motor 225 for Z movement is attached to the Z base 220a, and a feed screw (not shown) extending in the Z direction is rotatably attached.
- a feed screw (not shown) extending in the Z direction is rotatably attached.
- it is screwed into a nut attached to the base 250 a of the holding unit 25.
- the rotation of the motor 225 is transmitted to the feed screw 222 via a rotation transmission mechanism such as a gear, and the rotation of the feed screw 222 moves the holding unit 25 in the Z direction.
- the movement position of the holding unit 25 in the Z direction is detected by the number of pulses by which the motor 225 is driven by the control unit 50 described later, and the Z position detection unit detects the position of the holding unit 25 in the Z direction. It consists of 50.
- a sensor such as an encoder attached to the rotation shaft of the motor 225 may be used.
- each movement mechanism of the above X direction, Y direction, and Z direction is not restricted to an Example, A well-known mechanism is employable.
- the holding unit 25 instead of moving the holding unit 25 linearly, the holding unit 25 may be moved by arc activation with respect to the center of the rotation base (see, for example, JP-A-2006-350264).
- FIG. 6 is a diagram for explaining the rotation unit 260.
- the holding unit 25 is provided with an opening 26.
- the opening 26 allows the measurement light from the light projecting optical system 30a to pass and also allows the reflected light reflected by the eyeglass frame F to pass.
- the opening 26 may be provided with a transparent panel that covers the opening 26.
- the opening 26 emits measurement light emitted from the projection optical system 30 a from the inside of the holding unit 25 to the outside. That is, the measurement light from the light projecting optical system 30 a passes through the opening 26 and is irradiated toward the groove of the rim of the eyeglass frame F.
- the opening 26 allows the reflected light reflected by the groove of the rim of the eyeglass frame F to pass from the outside of the holding unit 25 toward the light receiving optical system 30 b inside the holding unit 25. That is, the reflected light reflected by the groove of the rim of the eyeglass frame F passes through the opening 26 and is received by the light receiving optical system 30b.
- the rotation unit 260 changes the XY direction in which the opening 26 faces by rotating the holding unit 25 around the rotation axis LO extending in the Z direction.
- the rotation unit 260 includes a rotation base 261.
- the holding unit 25 is attached to the rotation base 261.
- the rotation base 261 is rotatably held around a rotation axis LO extending in the Z direction.
- a large diameter gear 262 is formed on the outer periphery of the lower portion of the rotation base 261.
- the rotation unit 260 has a mounting plate 252.
- a motor (drive source) 265 is attached to the mounting plate 252.
- the pinion gear 266 is fixed to the rotation shaft of the motor 265, and the rotation of the pinion gear 266 is transmitted to the large diameter gear 262 via the gear 263 rotatably provided on the mounting plate 252.
- the rotation of the motor 265 causes the rotation base 261 to rotate about the rotation axis LO.
- the rotation of the motor 265 is detected by an encoder (sensor) 265a integrally attached to the motor 265, and the rotation angle of the rotation base 261 (ie, the holding unit 25) is detected from the output of the encoder 265a.
- the origin position of the rotation of the rotation base 261 is detected by an origin position sensor (not shown).
- each moving mechanism of the above rotation units 260 is not restricted to an Example, A well-known mechanism is employable.
- the rotation axis LO of the rotation unit 260 is set as an axis passing through the light source 31 of the light projecting optical system 30a described later. That is, the rotation unit 260 rotates around the light source 31 of the light projecting optical system 30a.
- the rotation axis of the rotation unit 260 may have different positions as the rotation axis.
- the rotation axis LO of the rotation unit 260 may be set to an axis passing through the detector 37 of the light receiving optical system 30b described later.
- FIG. 7 is a schematic block diagram showing the eyeglass frame measurement optical system 30.
- the eyeglass frame measurement optical system 30 is used to acquire an eyeglass frame F.
- the eyeglass frame measurement optical system 30 is used to obtain the cross-sectional shape of the groove of the rim of the eyeglass frame F.
- the eyeglass frame measurement optical system 30 is used to measure the shape of the eyeglass frame F.
- the eyeglass frame measurement optical system 30 is disposed inside the holding unit 25.
- the eyeglass frame measuring optical system 30 is configured of a light projecting optical system 30a and a light receiving optical system 30b.
- the light projecting optical system 30a has a light source, and irradiates the measurement light from the light source toward the groove of the rim of the eyeglass frame F.
- the light receiving optical system 30b has a detector, is irradiated by the light emitting optical system 30a toward the groove of the rim of the eyeglass frame F, and reflects the reflected light of the measurement light reflected by the groove of the rim of the eyeglass frame F Light is received by the detector.
- the eyeglass frame measurement optical system 30 is configured to acquire the cross-sectional shape of the groove of the rim of the eyeglass frame F based on the principle of Shine Pluke.
- the projection optical system 30a irradiates slit light to the groove of the rim of the eyeglass frame.
- the light receiving optical system 30b has an optical axis L2 inclined with respect to the optical axis L1 to which the slit light is irradiated, and includes a lens and a detector which are disposed based on the principle of Shine Pluke.
- the eyeglass frame measurement optical system 30 is not an optical system based on the principle of Shine Pluke, but optical systems of different configurations may be used.
- the eyeglass frame measurement optical system 30 may be any optical system in which the cross-sectional shape of the groove of the rim of the eyeglass frame F is acquired.
- the configuration in which the light projecting optical system 30a and the light receiving optical system 30b move integrally is described as an example, but the present invention is not limited to this.
- the projection optical system 30a and the light receiving optical system 30b are separately moved in at least one of the driving units of the X moving unit 240, the Y moving unit 230, the Z moving unit 220, and the rotating unit 260. It may be a configuration.
- the light projecting optical system 30 a includes the light source 31, the lens 32, and the slit plate 33.
- the measurement light emitted from the light source 31 is collected by the lens 32 to illuminate the slit plate 33.
- the measurement light illuminating the slit plate 33 becomes measurement light limited in a narrow slit shape by the slit plate 33 and is irradiated to the groove FA of the rim of the eyeglass frame F. That is, for example, slit light is applied to the groove FA of the rim of the eyeglass frame F.
- the groove FA of the rim of the eyeglass frame F is illuminated in the form of being light-cut by the slit light.
- the light receiving optical system 30 b includes a lens 36 and a detector (for example, a light receiving element) 37.
- the light receiving optical system 30 b is configured to obtain a cross-sectional shape from an oblique direction with respect to the groove FA of the rim of the eyeglass frame F.
- the light receiving optical system 30b is configured to obtain the cross-sectional shape of the groove FA of the rim of the eyeglass frame F based on the principle of Shine Pluke.
- the lens 36 detects the reflected light of the groove FA of the rim (for example, the scattered light of the groove FA of the rim, the specularly reflected light of the groove FA of the rim, etc.) obtained by the reflection at the groove FA of the rim Lead.
- the detector 37 has a light receiving surface disposed at a position substantially conjugate with the groove FA of the rim of the eyeglass frame F.
- the light receiving optical system 30b has an imaging optical axis L2 inclined with respect to the light projection optical axis L1 of the light projection optical system 30a, and has a lens 36 and a detector 37 which are disposed based on the principle of Shine Pluke. There is.
- the light receiving optical system 30b is disposed such that the optical axis (imaging optical axis) L2 intersects with the optical axis L1 of the light projecting optical system 30a at a predetermined angle.
- the light receiving surface (light receiving position) of the detector 37 is arranged in a relation of a shine-plough.
- FIG. 8 is a control block diagram of the eyeglass frame shape measuring apparatus 1.
- a non-volatile memory (storage means) 52, a display 3, a switch unit 4 and the like are connected to the control unit 50.
- control unit 50 includes a CPU (processor), a RAM, a ROM, and the like.
- the CPU of the control unit 50 includes each unit (for example, light source 31, detector 37, encoder 265a) and drive means for each unit (for example, drive source for frame holding unit 100, each motor 225, 235, 245, 265), etc. Take control of the entire device.
- control unit 50 functions as an operation unit (analysis unit) that performs various operations (for example, operation of the shape of the eyeglass frame based on output signals and the like from each sensor).
- the RAM temporarily stores various information.
- the ROM of the control unit 50 stores various programs for controlling the operation of the entire apparatus, initial values, and the like.
- the control unit 50 may be configured by a plurality of control units (that is, a plurality of processors).
- the non-volatile memory (storage means) 52 is a non-transitory storage medium capable of holding stored contents even when the supply of power is shut off.
- a hard disk drive, a flash ROM, a USB memory detachably attached to the eyeglass frame shape measuring apparatus 1 or the like can be used as the non-volatile memory (memory) 52.
- control unit 50 is connected to a lens processing device 300 that processes the peripheral edge of the lens.
- various data acquired by the eyeglass frame shape measuring device 1 is transmitted to the control unit 310 of the lens processing device 300.
- the control unit 310 of the lens processing device 300 controls the drive means of each unit and each unit of the lens processing device 300 based on the received various data, and performs lens processing.
- the lens processing apparatus 300 and the eyeglass frame shape measuring apparatus 1 may be an integrated apparatus.
- a touch panel type display is used as the display 3. That is, in the present embodiment, since the display 3 is a touch panel, the display 3 functions as an operation unit (operation unit).
- the control unit 50 receives an input signal by the touch panel function of the display 3 and controls the display and the like of figures and information of the display 3.
- the eyeglass frame shape measuring apparatus 1 may be separately provided with an operation unit. In this case, for example, at least one of a mouse, a joystick, a keyboard, a touch panel, and the like may be used as the operation unit.
- both the display 60 and the operation unit may be used to operate the eyeglass frame shape measuring apparatus 1.
- the structure provided with the switch part (operation part) 4 separately is mentioned as an example, and is demonstrated.
- the operator causes the frame holding unit 100 to hold the eyeglass frame F.
- the operator causes the frame holding unit 100 to hold the eyeglass frame F such that the left and right rims FL and FR of the eyeglass frame F are downward and the left and right temples FTL and FTR of the eyeglass frame F are upward.
- the control unit 50 drives the holding unit 25 by driving at least one of the X moving unit 240, the Y moving unit 230, the Z moving unit 220, and the rotating unit 260.
- the projection of the rim of the eyeglass frame F is started by moving (the light projecting optical system 30a and the light receiving optical system 30b).
- the measurement of the rim is started from the right rim FR. of course. The measurement may be started from the left rim FL.
- control unit 50 moves the holding unit 25 to measure the rim contour of the eyeglass frame by measuring the eyeglass frame measurement optical system 30 (the projection optical system 30a and the light receiving optical system 30b). Get the cross-sectional shape of the rim groove of the.
- the light projecting optical system 30a and the light receiving optical system 30b are moved with respect to the eyeglass frame F in a state in which the relationship between Shine Pluke is maintained. That is, the sectional shape of the groove of the rim of the eyeglass frame F can be acquired by moving the eyeglass frame measurement optical system 30 with respect to the groove of the rim of the eyeglass frame F so as to have a fixed positional relationship.
- the control unit 50 controls driving of the moving unit 210 (at least one of the X moving unit 240, the Y moving unit 230, and the Z moving unit 220) and the rotation unit 260.
- the holding unit 25 placed at the retracted position is moved to the initial position of the measurement start.
- the initial position of the measurement start is set at the central position of the clamp pins 130a and 130b at the lower end side of the right rim FR and the clamp pins 131a and 131b of the holding unit 25.
- the initial position of the measurement start can be set to any position.
- control unit 50 turns on the light source 31. Then, along with the lighting of the light source 31, the control unit 50 controls the driving of at least one of the moving unit 210 and the rotating unit 260 in order to irradiate the measurement light to the groove of the rim of the predetermined position of the eyeglass frame F. .
- FIGS. 9A and 9B are diagrams for explaining the case where the rotation unit 260 is controlled to acquire the cross-sectional shape of the rim at different radial angles.
- 9A and 9B acquire the cross-sectional shape of the rim at different radial angles.
- the control unit 50 controls the rotation unit 260 to rotate the optical axis L1 of the light projecting optical system 30a on the XY plane to move the optical axis L1 of the light projecting optical system 30a in the circumferential direction of the rim .
- control unit 50 controls the X rotation unit 260 to change the radius vector angle for acquiring the cross-sectional shape of the groove of the rim. For example, by controlling the rotation unit 260, the irradiation position T1 of the light projecting optical system 30a is changed to the irradiation position T2 of the light projecting optical system 30a.
- the moving unit 210 when the cross-sectional shape of the groove of the rim is acquired and the irradiation position of the measurement light with respect to the groove of the rim is changed, the moving unit 210 (X moving unit 240, Y moving unit 230, Z The moving position of at least one of the moving units 220 is controlled to change the irradiation position of the measurement light so that the groove of the rim is irradiated with the measurement light.
- the setting of the position for acquiring the cross-sectional shape of the groove of the rim and the change of the irradiation position of the measurement light to the groove of the rim may be simultaneously performed.
- the rotation unit 260 not only the rotation unit 260 but also at least one of the X moving unit 240, the Y moving unit 230, and the Z moving unit 220 may be used to set the position for acquiring the cross-sectional shape of the groove of the rim.
- the setting of the position for acquiring the cross-sectional shape of the groove of the rim may be performed by at least one of the X moving unit 240, the Y moving unit 230, and the Z moving unit 220.
- the rotating unit 260 may be used to change the irradiation position of the measurement light with respect to the groove of the rim.
- the change of the irradiation position of the measurement light to the groove of the rim may be configured such that only the rotation unit 260 is used.
- the control unit 50 acquires a two-dimensional cross-sectional shape of the groove of the rim of the eyeglass frame based on the reflected light received by the detector 37.
- a cross-sectional image is acquired as the cross-sectional shape.
- the cross-sectional shape may be a configuration obtained as a signal.
- the control unit 50 performs drive control to irradiate the measurement light to the groove of the rim of the eyeglass frame F.
- drive control for irradiating measurement light to the groove of the rim of the eyeglass frame F will be described.
- FIG. 10 is a diagram showing the light reception result before moving the holding unit 25 so that the measurement light is irradiated to the groove of the rim of the eyeglass frame F.
- FIG. 11 is a diagram showing the light reception result after moving the holding unit 25 so that the measurement light is irradiated to the groove of the rim of the eyeglass frame F.
- the irradiation position T3 of the projection optical system 30a is not located in the groove of the rim. For this reason, the reflected light from the groove of the rim of the eyeglass frame F can not be received.
- the control unit 50 acquires a cross-sectional image in a state in which the reflected light can not be received, the cross-sectional image is not displayed on the image 40 indicating the acquisition result.
- the irradiation position T4 of the light projecting optical system 30a is located in the groove of the rim. For this reason, the reflected light from the groove of the rim of the spectacles frame F can be received.
- the control unit 50 acquires a cross-sectional image in a state in which the reflected light is received, the cross-sectional image 41 is displayed on the image 40 indicating the acquisition result.
- the control unit 50 controls the moving unit 210 based on the light reception result. For example, the control unit 50 controls the moving unit 210 based on whether or not a cross-sectional image can be acquired. For example, the control unit 50 analyzes the acquired image 40, and controls the moving unit 210 so that a cross-sectional image is detected when the cross-sectional image can not be detected.
- the control unit 50 can detect whether or not a cross-sectional image has been acquired by detecting a change in luminance value. For example, when a cross-sectional image is acquired, a constant luminance value is detected. That is, since the reflected light can be detected by the detector, the luminance value is increased.
- FIG. 12 is a diagram for explaining detection of a luminance value.
- the control unit 50 detects luminance values in the order of the scanning line S1, the scanning line S2, the scanning line S3,..., The scanning line Sn on the acquired cross-sectional image to obtain a luminance distribution. That is, the control unit 50 can extract the cross-sectional image of the rim from the image by detecting the luminance value.
- the luminance level of the reflected light to be received may not be good, and it may be difficult to accurately obtain the cross-sectional shape of the groove of the rim.
- the control unit 50 controls the luminance level. Thereby, the cross-sectional shape of the groove of the rim can be obtained with high accuracy.
- control of the luminance level will be described.
- the structure which controls the light projection light quantity of the light source 31 is mentioned as an example, and is demonstrated as a structure which controls a luminance level.
- the configuration for performing control of the luminance level is not limited to the above configuration.
- a configuration for controlling the brightness level a configuration for controlling the gain of the detector 37, a configuration for providing a member for adjusting the light quantity of measurement light in the light path from the light source 31 to the detector 37, a detector 37 At least one of a configuration for controlling the exposure time and a configuration for controlling the light emission time of the light source 31 may be used.
- the control unit 50 performs pre-measurement (measurement before main measurement) after performing control so that a cross-sectional image can be detected.
- the control unit 50 performs pre-measurement at an initial position of measurement start to acquire a cross-sectional image.
- the control unit 50 detects a luminance level (luminance value) from the cross-sectional image, and controls the luminance level based on the detected luminance level.
- the control unit 50 determines whether the luminance level is the allowable level, and controls the luminance level when it determines that the luminance level does not satisfy the allowable level.
- the position at which the pre-measurement is performed is not limited to the initial position.
- an arbitrary position may be selected by the operator and set as a position at which pre-measurement is performed.
- pre-measurement may be performed at a plurality of positions. In this case, for example, when it is determined that the pre-measured luminance level does not satisfy the allowable level at at least one of the plurality of positions where the pre-measurement is performed, the luminance level is controlled. It is also good. In addition, when it is determined that the pre-measured luminance level does not satisfy the allowable level at all positions, the luminance level may be controlled.
- the control unit 50 detects the luminance value from the cross-sectional image, and a predetermined evaluation value is used as an index indicating the luminance level.
- the control unit 50 detects luminance values in the order of the scanning line S1, the scanning line S2, the scanning line S3,..., The scanning line Sn on the acquired cross-sectional image to obtain a luminance distribution.
- the control unit 70 calculates the maximum value of the luminance value (hereinafter referred to as the maximum luminance value) from the luminance distribution corresponding to each scanning line. Then, the control unit 70 calculates an average value of the maximum luminance values in each scanning line as the maximum luminance value in the cross-sectional image. Then, the control unit 70 calculates the average value of the luminance values of the background area in each scanning line as the average luminance value of the background area in the cross-sectional image.
- the maximum luminance value hereinafter referred to as the maximum luminance value
- the control unit 50 determines whether the evaluation value of the cross-sectional image acquired as described above satisfies a predetermined threshold.
- the predetermined threshold may be a preset threshold.
- a threshold that is determined to be good in luminance level by simulation, experiment, or the like may be set in advance.
- the threshold may be set arbitrarily by the examiner.
- the threshold may be set based on the acquired cross-sectional image.
- control unit 50 controls (changes) the light projection light amount of the light source 76 based on the determination result. For example, when it is determined that the evaluation value of the cross-sectional image does not satisfy the predetermined threshold (for example, smaller than the predetermined threshold), the control unit 50 performs control such that the luminance level becomes high. For example, when it is determined that the evaluation value of the cross-sectional image does not satisfy the predetermined threshold, the control unit 50 increases the projection light amount of the light source 31 so that the evaluation value of the cross-sectional image satisfies the predetermined threshold.
- the predetermined threshold for example, smaller than the predetermined threshold
- the control unit 50 determines that the evaluation value of the cross-sectional image satisfies the predetermined threshold (for example, the predetermined threshold or more), the control unit 50 does not control the brightness level, and the projection light quantity of the light source 31 Maintain.
- the control unit 50 may control the luminance level so as to obtain a more appropriate luminance level.
- the cross-sectional shape of the rim of the eyeglass frame may be difficult to detect due to the luminance level of the cross-sectional image becoming too high. Therefore, when the evaluation value satisfies a predetermined threshold and the difference between the evaluation value and the threshold is larger than a predetermined value, the brightness level may be controlled so that the difference is equal to or less than the predetermined value. .
- a determination method at the time of controlling a luminance level it is not restricted to the said method.
- a determination method it may be determined whether an integrated value (sum of luminance values for each pixel) obtained by integrating the luminance values for each pixel in the cross-sectional image satisfies an allowable level.
- an average value weighted average of all luminances obtained by dividing the sum of luminance values for each pixel in the cross-sectional image by the number of pixels satisfies an allowable level. May be That is, any determination method may be used as long as it can be determined whether the luminance level affects the detection of the cross-sectional shape of the rim based on the luminance distribution in the cross-sectional image.
- the control unit 50 starts main measurement.
- a cross-sectional image of the groove of the rim at a predetermined position can be obtained.
- the control unit 50 controls the rotation unit 260 to obtain a cross-sectional image of the groove of the rim while changing the radial angle around the rotation axis (the axis passing through the light source 31 in the present embodiment) LO. I will change the position.
- the position at which the cross-sectional image of the rim is acquired is moved in the circumferential direction of the rim.
- the control unit 50 controls the moving unit 210 every time the position at which the cross-sectional image of the rim is obtained is changed, and changes the irradiation position so that the measurement light is irradiated to the groove of the rim.
- the control unit 50 stores the cross-sectional image in the memory 52 for each predetermined rotation angle. Further, the position at which each cross-sectional image is acquired is calculated from at least one of the pulse number of the motor 225, the pulse number of the motor 235, the pulse number of the motor 245, and the detection result of the encoder 265a.
- the position at which the cross-sectional image of the rim is acquired is obtained. It can be identified.
- control unit 50 can acquire the position (acquisition position information) at which the tomographic image of the groove of the rim is acquired.
- the acquisition position information can be used when acquiring a three-dimensional cross-sectional image of a groove of a rim, a shape of an eyeglass frame, and the like.
- the control unit 50 can acquire various parameters regarding the groove of the rim by analyzing and processing the acquired cross-sectional image.
- FIG. 13 is a diagram for explaining parameters acquired from the cross-sectional image of the groove of the rim.
- the control unit 50 can acquire the parameter of the groove of the rim by acquiring the luminance distribution of the cross-sectional image by image processing.
- the control unit 50 sets the distance K1 to the bottom of the groove of the rim, the left and right slope angles ⁇ 1 and ⁇ 2 of the groove of the rim, and the left and right slope lengths K2 and K3 of the groove of the rim as parameters of the groove of the rim.
- Rim shoulder length K4, K5, etc. can be obtained.
- control unit 50 can acquire a cross-sectional image of the groove of the rim in the entire circumference of the rim by repeating the above control over the entire circumference of the rim. For example, when the acquisition of the cross-sectional image of the groove of the rim in the entire circumference of the rim is completed, the control unit 50 calls the sectional image of the entire circumference of the rim stored in the memory 52 and the acquired position information thereof, performs arithmetic processing, Acquire a cross-sectional image. For example, the control unit 50 stores the acquired three-dimensional cross-sectional image in the memory 52.
- control unit 50 can acquire the shape (shape data) of the eyeglass frame from the acquired cross-sectional image.
- the control unit 50 detects the bottom of the groove of the rim at a plurality of radial angles of the eyeglass frame from the cross-sectional images of the grooves of the rim at the plurality of radial angles of the eyeglass frame. Get the shape of the glasses frame.
- the control unit 50 detects the position of the bottom of the groove of the rim by acquiring the luminance distribution of the cross-sectional image by image processing. As illustrated in FIG. 12, for example, the control unit 50 detects luminance values in the order of scan line S1, scan line S2, scan line S3, ... scan line Sn on the acquired cross-sectional image. , Get the luminance distribution. For example, the control unit 50 may detect, as the bottom of the groove of the rim, a position at which the luminance value is detected at the lowermost position in the obtained luminance distribution.
- the control unit 50 processes each of the cross-sectional images acquired for each radial angle, and detects the position of the bottom of the groove of the rim on the image. For example, the control unit 50 acquires the position information of the bottom of the groove of the rim from the position of the bottom of the groove of the rim on the image detected from the cross-sectional image and the acquired position information of the acquired sectional image. For example, the control unit 50 detects the position of the bottom of the groove of the rim on the image from the cross-sectional image obtained for each radial angle, and the position of the bottom of the groove of the rim on the detected image The position information of the bottom of the groove of the rim for each radius vector angle is acquired from the acquired position information for acquiring the cross-sectional image.
- the three-dimensional shape of the eyeglass frame Fn may be acquired over the entire circumference of the rim, or may be acquired in a partial area of the entire circumference of the rim. As described above, the shape of the eyeglass frame F can be obtained.
- the configuration for acquiring the three-dimensional shape of the eyeglass frame has been described as an example by acquiring the position information of the bottom of the groove of the rim for each radius vector angle, but the present invention is not limited thereto .
- the position of the bottom of the groove of the rim is not acquired at each radial angle, the position of the bottom of the groove of the rim at the peripheral angle of radius
- the position information of the bottom of the groove of the rim may be obtained by interpolation based on the information.
- the position of the bottom of the rim groove is not acquired at each radius angle, the bottom of the rim groove at the peripheral radius angle It may be made to interpolate from the result of approximation of position information on
- the control unit 50 controls the drive of the X moving unit 240 to move the holding unit 25 to a predetermined position for measurement of the left rim FL.
- acquisition of the cross-sectional shape of the right rim FR and the shape of the eyeglass frame are acquired.
- Cross sectional images and shapes of the right rim FR and the left rim FL are stored in the memory 52.
- various parameters may be acquired based on the acquired three-dimensional shape of the eyeglass frame.
- the two-dimensional shape may be acquired from the three-dimensional shape of the eyeglass frame.
- the two-dimensional shape can be obtained by projecting the three-dimensional shape onto the XY plane in the front direction of the eyeglass frame F.
- the two-dimensional shape mentioned the structure acquired from a three-dimensional shape as an example it is not limited to this.
- control unit 50 transmits the cross-sectional shape of the groove of the rim, the shape of the eyeglass frame, and the like acquired by the eyeglass frame shape measuring device 1 to the lens processing device 300.
- control unit 310 of the lens processing device 300 receives the cross-sectional shape of the groove of the rim acquired by the spectacle frame shape measuring device 1, the shape of the spectacle frame, and the like.
- the lens processing apparatus 300 includes a lens rotating unit that holds a lens on a lens chuck shaft and rotates it, and a processing tool rotating unit that rotates a processing tool attached to a processing tool rotation shaft.
- the control unit 310 of the lens processing apparatus acquires acquired information acquired by the eyeglass frame shape measuring apparatus 1 (for example, the sectional shape of the groove of the rim of the eyeglass frame, the shape of the eyeglass frame, etc.) Based on the lens rotation means and the processing tool rotation means, the peripheral edge processing of the lens is performed.
- the control unit 310 of the lens processing apparatus may be configured to be also used as the control unit of the eyeglass frame shape measuring apparatus 1, or separately provided with the control unit 310 for performing various controls of the lens processing apparatus. May be configured.
- the eyeglass frame shape measuring apparatus emits light toward the rim of the eyeglass frame by the light emitting optical system that emits measurement light from the light source toward the rim of the eyeglass frame,
- the light receiving optical system for receiving the reflected light of the measurement light reflected by the rim of the frame by the detector, and the acquiring means for acquiring the cross-sectional shape of the rim of the eyeglass frame based on the reflected light received by the detector .
- the cross-sectional shape of the rim of the eyeglass frame can be easily and accurately obtained.
- measurement can be performed quickly.
- the eyeglass frame shape measuring apparatus comprises: first changing means for changing the irradiation position of the measurement light with respect to the groove of the rim of the eyeglass frame; and first control means for controlling the first changing means. Equipped with This makes it possible to irradiate the measurement light to the position of the groove of any rim in the eyeglass frame, and to obtain the cross-sectional shape of the groove of the rim at any position.
- the eyeglass frame shape measuring apparatus is a changing means for moving the position of at least a part of the light projecting optical system by the first changing means
- the first control means is the first changing means Is controlled to change the position of at least a part of the projection optical system with respect to the groove of the rim of the eyeglass frame, and change the irradiation position of the measurement light with respect to the groove of the rim of the eyeglass frame.
- the eyeglass frame shape measuring apparatus includes a second changing unit that changes the light receiving position of the reflected light by the light receiving optical system, and a second control unit that controls the second changing unit.
- the light receiving position can be changed to a position where the cross-sectional shape of the groove of the rim can be favorably acquired, and the cross-sectional shape of the rim of the eyeglass frame can be acquired more accurately.
- the first control means controls the first changing means to irradiate the measurement light to the groove of the rim at a plurality of radius vector angles of the eyeglass frame .
- An acquisition means acquires the cross-sectional shape of the groove
- the eyeglass frame shape measuring apparatus detects the bottom of the groove of the rim at a plurality of radius vector angles of the eyeglass frame from the cross-sectional shape of the groove of the rim at a plurality of radius vector angles of the eyeglass frame.
- An analysis means for acquiring the shape of the eyeglass frame is provided. This makes it possible to prevent the measuring element from coming off the groove of the lens frame and making it impossible to measure depending on the eyeglass frame as in the conventional case, and the eyeglass frame can be accurately and easily for eyeglass frames of various shapes. You can get the shape of.
- the first control means controls the first changing means to irradiate the measurement light to the groove of the rim at a plurality of radius vector angles of the eyeglass frame .
- An acquisition means acquires the cross-sectional shape of the groove
- the three-dimensional cross-sectional shape of the eyeglass frame can be easily and accurately obtained.
- the lens processing apparatus includes processing control means for processing the peripheral edge of the lens based on the cross-sectional shape of the groove of the rim of the eyeglass frame.
- the cross-sectional shape and the shape of the eyeglass frame may be displayed on the display 3.
- it may be displayed on the display of the lens processing device 300 (not shown).
- the cross-sectional shape and the shape of the eyeglass frame may be displayed on different screens on the display 3.
- the cross-sectional shape and the shape of the eyeglass frame may be switched and displayed by switching the screen.
- the cross-sectional shape and the shape of the eyeglass frame may be displayed on the same screen. In this case, for example, the cross-sectional shape and the shape of the eyeglass frame may be arranged side by side on the same screen.
- a display may be made to indicate the acquisition position of the cross-sectional shape such that the acquisition position of the cross-sectional shape can be identified.
- the cross-sectional shape and the shape of the eyeglass frame may be superimposed and displayed.
- the superimposed display is performed, the cross-sectional shape and the shape of the eyeglass frame may be aligned based on the acquisition position information of the cross-sectional shape and the acquisition position of the cross-sectional shape of the rim groove.
- the luminance level may be controlled based on the eyeglass frame type information.
- the setting for controlling the luminance level may be previously set for each of the eyeglass frame types.
- the control unit 50 performs control setting of the luminance level corresponding to the selected eyeglass frame type.
- the control unit 50 sets the projection light amount of the light source 31 to the projection light amount corresponding to the selected eyeglass frame type.
- control of the luminance level based on spectacles frame type information is not limited to control of the projection light quantity of a light source.
- the configuration for controlling the gain of the detector 37 based on the eyeglass frame type information the configuration for providing a member for adjusting the light quantity of the measurement light in the light path from the light source 31 to the detector 37, the exposure time in the detector 37 It may be at least one of a configuration to control and a configuration to control the light emission time of the light source 31.
- the configuration for controlling the brightness level based on the eyeglass frame type information the configuration may be different from the above-described configuration as long as the brightness level can be controlled.
- the shape of the spectacles frame at least one of the shape of the spectacles frame, the material of the spectacles frame, the color of the spectacles frame, the design of the spectacles frame, etc. may be set.
- the eyeglass frame type may be set for each item.
- the eyeglass frame shape may be set to nylol
- the eyeglass frame material may be metal
- the eyeglass frame may be set to gray (gray).
- an eyeglass frame type of another item may be set in addition to the selected eyeglass frame type.
- the material of the eyeglass frame is selected from metal, plastic or optic
- the shape of the eyeglass frame may be set as a full rim.
- the eyeglass frame types may be associated in advance.
- spectacles frame type it is not limited to these types, Various types of spectacles frame can be set.
- eyeglass frame type may be configured to be optionally added or deleted by the examiner.
- the control unit 50 may control the luminance level to be higher than the luminance level when the material of the eyeglass frame is metal.
- the control unit 50 may perform control to increase the projection light amount of the light source 31 more than the projection light amount of the light source 31 for measuring metal.
- the control unit 50 may control the gain of the detector 37 to be higher than the gain of the detector 37 for measuring the metal.
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Abstract
Description
(2) 本開示に係る第2様態に係るレンズ加工装置は、レンズの周縁を加工するレンズ加工装置であって、(1)の眼鏡枠形状測定装置によって取得された前記眼鏡フレームの前記リムの溝の断面形状に基づいてレンズの周縁を加工する加工制御手段を備えることを特徴とする。
本開示の実施形態に係る眼鏡枠形状測定装置(例えば、眼鏡枠形状測定装置1)の概要について説明する。例えば、本実施形態に関わる眼鏡枠形状測定装置は、眼鏡フレームの形状を測定する。例えば、眼鏡枠形状測定装置は、投光光学系(例えば、投光光学系30a)を備える。例えば、眼鏡枠形状測定装置は、受光光学系(例えば、受光光学系30b)を備える。例えば、眼鏡枠形状測定装置は、取得手段(例えば、制御部50)を備える。
例えば、受光光学系は、検出器(例えば、検出器37)を有する。例えば、受光光学系は、投光光学系によって眼鏡フレームのリムの溝に向けて照射され、眼鏡フレームのリムの溝によって反射された測定光の反射光(反射光束)を検出器によって受光する。なお、例えば、検出器は、少なくとも1つ以上の検出器が用いられてもよい。例えば、1つの検出器が用いられてもよい。また、例えば、複数の検出器が用いられてもよい。
例えば、投光光学系は、光学部材を有してもよい。この場合、例えば、光源から出射された測定光が各光学部材を介して眼鏡フレームのリムの溝に向けて照射されるようにしてもよい。例えば、光学部材としては、レンズ、ミラー、絞り、等の少なくともいずれかを用いてもよい。例えば、絞りを用いることによって、焦点深度を深くすることができる。もちろん、光学部材としては、上記光学部材に限定されず、異なる光学部材が用いられてもよい。
例えば、受光光学系は、光学部材を有してもよい。この場合、例えば、眼鏡フレームのリムの溝によって反射された測定光の反射光が各光学部材を介して、検出器に受光されるようにしてもよい。例えば、光学部材としては、レンズ、ミラー、絞り、等の少なくともいずれかを用いてもよい。もちろん、光学部材としては、上記光学部材に限定されず、異なる光学部材が用いられてもよい。
例えば、取得手段は、眼鏡フレームのリムの溝によって反射された測定光の反射光を処理して、眼鏡フレームのリムの溝の断面形状を取得する。例えば、取得手段は、検出器における反射光の受光位置から断面形状を取得してもよい。例えば、断面形状は、画像(画像データ)であってもよい。すなわち、断面形状は、断面画像であってもよい。また、例えば、断面形状は、信号(信号データ)であってもよい。すなわち、断面形状は、断面形状の信号データであってもよい。
例えば、眼鏡枠形状測定装置は、第1変更手段(例えば、移動ユニット210、回転ユニット260)を備えてもよい。例えば、第1変更手段は、眼鏡フレームのリムの溝に対する測定光の照射位置を変更する。また、例えば、眼鏡枠形状測定装置は、第1変更手段を制御する第1制御手段(例えば、制御部50)を備えてもよい。
例えば、眼鏡枠形状測定装置は、第2変更手段(例えば、移動ユニット210、回転ユニット260)を備えてもよい。例えば、第2変更手段は、受光光学系による反射光の受光位置を変更する。例えば、眼鏡枠形状測定装置は、第2変更手段を制御する第2制御手段(例えば、制御部50)を備えてもよい。
例えば、眼鏡枠形状測定装置は、眼鏡フレームの形状(形状データ)を取得するようにしてもよい。この場合、例えば、眼鏡枠形状測定装置は、解析手段(例えば、制御部50)を備えてもよい。例えば、第1制御手段は、第1変更手段を制御して、眼鏡フレームの複数の動径角におけるリムの溝に対して測定光を照射してもよい。例えば、取得手段は、眼鏡フレームの複数の動径角におけるリムの溝の断面形状をそれぞれ取得してもよい。例えば、解析手段は、眼鏡フレームの複数の動径角におけるリムの溝の断面形状から眼鏡フレームの複数の動径角におけるリムの溝の底をそれぞれ検出し、検出した検出結果に基づいて、眼鏡フレームの形状を取得するようにしてもよい。
例えば、眼鏡枠形状測定装置は、三次元断面形状を取得してもよい。例えば、第1制御手段は、第1変更手段を制御して、眼鏡フレームの複数の動径角におけるリムの溝に対して測定光を照射する。例えば、取得手段は、眼鏡フレームの複数の動径角におけるリムの溝の断面形状をそれぞれ取得することによって、三次元断面形状を取得するようにしてもよい。
ここで、発明者らは、眼鏡フレームのリムの溝に向けて測定光を照射し、眼鏡フレームのリムの溝によって反射された測定光の反射光を受光し、反射光に基づいて、眼鏡フレームのリムの溝の断面形状を取得する構成を備える眼鏡枠形状測定装置について検討した。例えば、このような眼鏡枠形状測定装置を用いる場合に、眼鏡フレームのタイプによっては、受光される反射光の輝度レベルが良好でなく、リムの溝の断面形状を精度よく取得することが困難であることがわかった。以下、この課題を解決する構成について説明する。
例えば、眼鏡枠形状測定装置によって取得された眼鏡フレームのリムの溝の断面形状をレンズの加工に用いてもよい。例えば、レンズの周縁を加工するレンズ加工装置(例えば、レンズ加工装置300)は、眼鏡枠形状測定装置によって取得された眼鏡フレームのリムの溝の断面形状を取得する。
本開示の典型的な実施例の1つについて、図面を参照して説明する。図1は、眼鏡枠形状測定装置の外観略図である。例えば、図2は、眼鏡フレームが保持された状態のフレーム保持ユニットの上面図である。例えば、本実施例において、眼鏡枠形状測定装置1は、フレーム保持ユニット10と、測定ユニット20と、を備える。例えば、フレーム保持ユニット10は、眼鏡フレームFを所期する状態に保持する。例えば、測定ユニット20は、フレーム保持ユニット10に保持された眼鏡フレームFのリム(例えば、左側リムFL、右側リムFRs)の溝に向けて測定光を照射し、その反射光を受光することにより、眼鏡フレームFのリムの溝の断面形状を取得するために用いられる。例えば、測定ユニット20はフレーム保持ユニット10の下に配置されている。
例えば、フレーム保持ユニット10の下側には、測定ユニット20が備えられている。例えば、保持部ベース101上には眼鏡フレームFを水平に保持するための前スライダー102と後スライダー103が載置されている。なお、例えば、水平とは略水平であってもよい。例えば、前スライダー102と後スライダー103は、その中心線CLを中心に2つのレール111上を対向して摺動可能に配置されていると共に、バネ113により常に両者の中心線CLに向かう方向に引っ張られている。
以下、測定ユニット20の構成について説明する。例えば、測定ユニット20は、眼鏡フレーム測定光学系30を備える。例えば、眼鏡フレーム測定光学系30は、投光光学系30aと、受光光学系30bと、で構成される。例えば、投光光学系30a及び受光光学系30bは、眼鏡フレームの形状及び眼鏡フレームのリムの溝の断面形状を取得するために用いられる(詳細は後述する)。
以下、移動ユニット210について説明する。例えば、図3~図5は、移動ユニット210の構成を説明する図である。例えば、図3は、移動ユニット210を上方から見た斜視図を示している。例えば、図4は、移動ユニット210の下方から見た斜視図を示している。例えば、図5は、Z移動ユニット220とY移動ユニット230の上面斜視図(X移動ユニット240とベース部211を取り外した状態の斜視図)を示している。
次いで、回転ユニット260について説明する。例えば、図6は、回転ユニット260について説明する図である。
次いで、保持ユニット25に保持された眼鏡フレーム測定光学系30について説明する。例えば、図7は、眼鏡フレーム測定光学系30について示す概略構成図である。例えば、眼鏡フレーム測定光学系30は、眼鏡フレームFを取得するために用いられる。例えば、本実施例において、眼鏡フレーム測定光学系30は、眼鏡フレームFのリムの溝の断面形状を取得するために用いられる。また、例えば、本実施例において、眼鏡フレーム測定光学系30は、眼鏡フレームFの形状を測定するために用いられる。
例えば、投光光学系30aは、光源31と、レンズ32と、スリット板33と、を備える。例えば、光源31より出射された測定光は、レンズ32によって集光してスリット板33を照明する。例えば、スリット板33を照明した測定光は、スリット板33により細いスリット状に制限された測定光となり眼鏡フレームFのリムの溝FAに照射される。すなわち、例えば、スリット光が眼鏡フレームFのリムの溝FAに照射される。これにより、眼鏡フレームFのリムの溝FAは、スリット光により光切断された形で照明される。
例えば、受光光学系30bは、レンズ36と、検出器(例えば、受光素子)37と、を備える。例えば、受光光学系30bは、眼鏡フレームFのリムの溝FAに対して、斜め方向から断面形状を取得する構成となっている。例えば、受光光学系30bは、シャインプルークの原理に基づいて眼鏡フレームFのリムの溝FAの断面形状を取得する構成となっている。
図8は、眼鏡枠形状測定装置1に関する制御ブロック図である。制御部50には、不揮発性メモリ(記憶手段)52、ディスプレイ3、スイッチ部4等が接続されている。
以上のような構成を持つ装置の動作を説明する。例えば、操作者は、フレーム保持ユニット100に眼鏡フレームFを保持させる。例えば、操作者は、眼鏡フレームFの左右リムFL,FRが下方向、眼鏡フレームFの左右のテンプルFTL,FTRが上方向となるように、フレーム保持ユニット100に眼鏡フレームFを保持させる。
例えば、制御部50は、回転ユニット260を制御して、投光光学系30aの光軸L1をXY平面上で回転させて、投光光学系30aの光軸L1をリムの周方向に移動させる。すなわち、制御部50は、X回転ユニット260を制御して、リムの溝の断面形状を取得する動径角を変更する。例えば、回転ユニット260が制御されることによって、投光光学系30aの照射位置T1が投光光学系30aの照射位置T2へと変更される。
制御部50は、輝度レベルを制御する。これによって、リムの溝の断面形状が精度よく取得できる。以下、輝度レベルの制御について説明する。なお、本実施例においては、輝度レベルの制御を行う構成として、光源31の投光光量を制御する構成を例に挙げて説明する。もちろん、輝度レベルの制御を行う構成としては、上記構成に限定されない。
なお、プレ測定を行う位置は初期位置に限定されない。例えば、操作者によって任意の位置を選択し、プレ測定を行う位置として設定してもよい。また、例えば、プレ測定は、複数の位置で行われるようにしてもよい。この場合、例えば、プレ測定を行った複数の位置において、少なくとも1つ以上の位置でプレ測定輝度レベルが許容レベルを満たしていないという判定結果を得た場合に、輝度レベルを制御するようにしてもよい。また、すべての位置でプレ測定輝度レベルが許容レベルを満たしていないという判定結果を得た場合に、輝度レベルを制御するようにしてもよい。
3 ディスプレイ
4 スイッチ部
10 フレーム保持ユニット
20 測定ユニット
25 保持ユニット
30 眼鏡フレーム測定光学系
30a 投光光学系
30b 受光光学系
31 光源
37 検出器
50 制御部
52 メモリ
210 移動ユニット
220 Z移動ユニット
230 Y移動ユニット
240 X移動ユニット
260 回転ユニット
300 レンズ加工装置
310 制御部
Claims (12)
- 眼鏡フレームの形状を測定する眼鏡枠形状測定装置であって、
光源を有し、眼鏡フレームのリムの溝に向けて前記光源から測定光を照射する投光光学系と、
検出器を有し、前記投光光学系によって前記眼鏡フレームの前記リムの溝に向けて照射され、前記眼鏡フレームの前記リムの溝によって反射された前記測定光の反射光を前記検出器によって受光する受光光学系と、
前記検出器によって受光された前記反射光に基づいて、前記眼鏡フレームの前記リムの溝の断面形状を取得する取得手段と、
前記検出器によって受光される前記反射光の輝度レベルを制御する輝度制御手段と、
を備えることを特徴とする眼鏡枠形状測定装置。 - 請求項1の眼鏡枠形状測定装置において、
前記輝度制御手段は、前記検出器によって受光された前記反射光の前記輝度レベルに基づいて、前記輝度レベルを制御することを特徴とする眼鏡枠形状測定装置。 - 請求項2の眼鏡枠形状測定装置において、
前記取得手段は、前記断面形状として断面画像を取得し、
前記断面画像から前記輝度レベルを検出する輝度解析手段を備え、
前記輝度制御手段は、前記輝度解析手段によって検出された前記輝度レベルに基づいて、前記輝度レベルを制御することを特徴とする眼鏡枠形状測定装置。 - 請求項2又は3の眼鏡枠形状測定装置において、
前記輝度レベルが許容レベルであるか否かを判定する判定手段を備え、
前記輝度制御手段は、前記判定手段の判定結果に基づいて、前記輝度レベルを制御することを特徴とする眼鏡枠形状測定装置。 - 請求項1の眼鏡枠形状測定装置において、
眼鏡フレームタイプ情報を取得する眼鏡フレームタイプ情報取得手段を備え、
前記輝度制御手段は、前記眼鏡フレームタイプ情報取得手段によって取得された前記眼鏡フレームタイプ情報に基づいて、前記輝度レベルを制御することを特徴とする眼鏡枠形状測定装置。 - 請求項1~5のいずれかの眼鏡枠形状測定装置において、
前記輝度制御手段は、前記光源からの前記測定光の投光光量を制御することによって、前記輝度レベルを制御することを特徴とする眼鏡枠形状測定装置。 - 請求項1~6のいずれかの眼鏡枠形状測定装置において、
前記輝度制御手段は、前記検出器のゲインを制御することによって、前記輝度レベルを制御することを特徴とする眼鏡枠形状測定装置。 - 請求項1~7のいずれかの眼鏡枠形状測定装置において、
前記取得手段は、前記輝度制御手段によって前記輝度レベルが制御されて変更された後、前記検出器によって受光された前記反射光に基づいて、前記眼鏡フレームの前記リムの溝の断面形状を取得することを特徴とする眼鏡枠形状測定装置。 - 請求項1~8のいずれかの眼鏡枠形状測定装置において、
前記眼鏡フレームの前記リムの溝に対する前記測定光の照射位置を変更する第1変更手段と、
前記第1変更手段を制御する第1制御手段と、
を備えることを特徴とする眼鏡枠形状測定装置。 - 請求項9の眼鏡枠形状測定装置において、
前記第1制御手段は、前記第1変更手段を制御して、前記眼鏡フレームの複数の動径角における前記リムの溝に対して前記測定光を照射し、
前記取得手段は、前記眼鏡フレームの複数の動径角における前記リムの溝の断面形状をそれぞれ取得し、
前記眼鏡フレームの複数の動径角における前記リムの溝の断面形状から前記眼鏡フレームの複数の動径角における前記リムの溝の底をそれぞれ検出し、検出した検出結果に基づいて、前記眼鏡フレームの形状を取得する解析手段と、
を備えることを特徴とする眼鏡枠形状測定装置。 - 請求項1~10のいずれかの眼鏡枠形状測定装置において、
前記受光光学系による前記反射光の受光位置を変更する第2変更手段と、
前記第2変更手段を制御する第2制御手段と、
を備えることを特徴とする眼鏡枠形状測定装置。 - レンズの周縁を加工するレンズ加工装置であって、
請求項1~11のいずれかの眼鏡枠形状測定装置によって取得された前記眼鏡フレームの前記リムの溝の断面形状に基づいてレンズの周縁を加工する加工制御手段を備えることを特徴とするレンズ加工装置。
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EP3978863A1 (en) | 2020-09-30 | 2022-04-06 | Nidek Co., Ltd. | Eyeglass frame shape measurement apparatus and control program for eyeglass frame shape measurement apparatus |
JP7517045B2 (ja) | 2020-09-30 | 2024-07-17 | 株式会社ニデック | 眼鏡枠形状測定装置及び眼鏡枠形状測定装置の制御プログラム |
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Also Published As
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JPWO2019026416A1 (ja) | 2020-05-28 |
US11226196B2 (en) | 2022-01-18 |
CN110998225B (zh) | 2022-06-03 |
EP3663708A1 (en) | 2020-06-10 |
KR102557105B1 (ko) | 2023-07-20 |
CN110998225A (zh) | 2020-04-10 |
JP2022176220A (ja) | 2022-11-25 |
EP3663708A4 (en) | 2021-04-21 |
US20200158496A1 (en) | 2020-05-21 |
KR20200032106A (ko) | 2020-03-25 |
EP3663708B1 (en) | 2022-12-28 |
JP7147763B2 (ja) | 2022-10-05 |
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