JP2009241155A - Device for manufacturing spectacle lens, and method for manufacturing spectacle lens - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a device for manufacturing a spectacle lens, in which grooves, projections, etc., can be processed at high precision. <P>SOLUTION: The device comprises a lens processing part to process a lens 100 that is to be the spectacle lens, and a detection part to detect the outer form and/or the size of the lens 100. The lens processing part comprises a tool 41 to form a groove on an edge surface of the lens 100, for example. The detection part comprises measurement elements 11 and 12 for measuring the outer form and the edge thickness of the lens 100, for example. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention relates to a spectacle lens manufacturing apparatus and a spectacle lens manufacturing method.

Glasses having a configuration in which a spectacle lens is fixed to a frame with a wire or the like are known.
In this configuration, a groove for inserting a wire or the like is formed on the edge surface of the spectacle lens (the cutting surface of the lens).
Further, in order to fit the spectacle lens into the frame, a bank-like protrusion may be formed on the edge surface.

At this time, it is desired that the depth and the formation position of the groove or the height and the formation position of the protrusion have high accuracy.
For this reason, it is desirable to perform processing for forming grooves and protrusions in a state in which the positional accuracy and dimensions (edge thickness, etc.) of the spectacle lens are high.

  Conventionally, dimensions such as the edge thickness of the lens (lens thickness on the edge surface) are measured before grinding or other processing on the lens (see Patent Documents 1 to 3).

Japanese Utility Model Publication No. 5-86456 JP 2006-305698 A JP 2003-145400 A

  However, the position of the lens relative to the lens holder (horizontal x and x) is determined depending on the lens holding state when measuring the lens edge thickness and other dimensions, and the lens holding state when processing to form grooves and protrusions. When the y and the inclination angle θ are different, the groove depth and the protrusion height may not be formed uniformly.

Conventionally, after measuring the circumference, shape, and the like of a lens in an apparatus having a measuring instrument, the lens is transferred to another apparatus for processing to perform processing.
For this reason, the holding state of the lens differs depending on the apparatus, and the position of grooves and protrusions formed by processing may be shifted due to the influence of the lens holding state.

  Moreover, in the dimension measuring method described in the said patent document 2 or the said patent document 3, the thickness of a lens is measured in the part inside a concave surface or a convex surface rather than an edge surface, without measuring edge thickness directly. ing. Therefore, it is considered that the edge thickness is estimated from the measured lens thickness and the designed concave and convex curved surface shapes. At this time, if there is a difference between the designed curved surface shape and the actual curved surface shape, a correct edge thickness cannot be obtained.

  In order to solve the above-described problems, the present invention provides a spectacle lens manufacturing apparatus and a spectacle lens manufacturing method capable of performing processing with high accuracy when processing grooves and protrusions. It is.

  The spectacle lens manufacturing apparatus of the present invention includes a lens processing unit that processes a lens to be a spectacle lens, and a detection unit that detects the outer shape and / or dimensions of the lens.

In the eyeglass lens manufacturing apparatus of the present invention, the lens processing unit may have a tool for forming a groove on the edge surface of the lens.
In the eyeglass lens manufacturing apparatus of the present invention, the detection unit can detect the concave and convex outer shapes of the lens and the edge thickness of the lens.
In the spectacle lens manufacturing apparatus according to the present invention, the lens processing position may be set based on the outer shape and / or dimensions of the lens detected by the detection unit. It is.

  The spectacle lens manufacturing method of the present invention includes a detection process for detecting the outer shape and / or dimensions of a lens while holding a lens to be a spectacle lens, and a processing process for processing the lens. The lens holding state is maintained, and the lens processing position is set based on the outer shape and / or dimensions of the lens obtained in the detection step, and the processing step is performed.

  Further, in the method for manufacturing a spectacle lens of the present invention, it is possible to form a groove on the edge surface of the lens or form a bevel on the edge surface of the lens in the processing step.

According to the manufacturing apparatus of the present invention described above, the detection unit includes a lens processing unit that processes a lens that becomes a spectacle lens and a detection unit that detects the outer shape and / or dimensions of the lens. After detecting the shape and / or dimensions, the lens processing unit can process the lens.
Thereby, the precision of the position which processes a lens can be raised, without producing the error by the difference in the holding position of the lens for every apparatus.

According to the manufacturing method of the present invention described above, the lens outer shape obtained in the detection step is provided by the detection step of detecting the outer shape and / or size of the lens and maintaining the lens holding state in the detection step. Based on the shape and / or dimensions, a position for processing the lens is set, and a processing step is performed.
Thereby, the lens can be processed with increased accuracy of the position where the lens is processed.

Therefore, according to the present invention, the lens can be processed with high accuracy.
Then, it is possible to improve the production yield of spectacle lenses and to stably mass-produce high quality spectacle lenses.

1 and 2 are schematic configuration diagrams of an embodiment of a spectacle lens manufacturing apparatus according to the present invention.
FIG. 1 is a side view seen from a direction perpendicular to the longitudinal direction of the apparatus, and FIG. 2 is a side view seen from the longitudinal direction of the apparatus.

  This device is composed of a lens fixing part for fixing a lens to be a spectacle lens, a detection part for detecting the shape and dimensions of the lens, and a lens processing part for grooving the lens. Yes.

The lens fixing unit includes lens chucks 31 and 32 for fixing the lens 100 serving as a spectacle lens by sandwiching it from the left and right.
The left lens chuck 31 is configured to contact the convex surface of the lens 100, and the right lens chuck 32 is configured to contact the concave surface of the lens 100.

As shown in FIG. 1, the detection unit includes measuring elements 11 and 12 for performing measurement by being hooked on the edge of the edge of the lens 100, two support bars 24 that hold the measuring elements 11 and 12, and Left and right motors 23 for moving the measuring elements 11 and 12 and left and right edge position sensors 21 and 22 for measuring the position of the edge surface from the amount of movement of the measuring elements 11 and 12 are provided.
Further, as shown in FIG. 2, the detection unit includes a detection sensor 27 and a spring 28 for moving the probe up and down.

Each of the left and right edge position sensors 21 and 22 includes a fixed rail 25 and a sensor main body 26 that slides and moves along the rail 25.
The sensor body 26 of each edge position sensor 21, 22 moves in conjunction with the support bar 24.

  Although not shown in detail, the support rod 24 is configured to slide in the horizontal direction when the motor 23 is driven. Thereby, the measuring elements 11 and 12 hold | maintained at the support rod 24 can be moved to right and left. At this time, the movement amounts of the measuring elements 11 and 12 can be measured by the edge position sensors 21 and 22 interlocked with the support rod 24.

The lens processing unit includes a groove digging tool 41 that performs a process of digging a groove on the edge surface of the lens 100.
The groove digging tool 41 is configured to perform a process of digging a groove by rotating around an axis.

3 and 4 are enlarged views of the measuring elements 11 and 12 shown in FIG.
FIG. 3 shows a probe 11 for measuring a concave surface on the left side of FIG. 3A shows a side view and FIG. 3B shows a top view.
FIG. 4 shows a probe 12 for measuring a convex surface on the right side of FIG. 4A shows a side view and FIG. 4B shows a top view.

Each measuring element 11, 12 has a thick portion 13 for securing strength and a thin plate-like thin portion 14 for hooking on a lens to ensure accuracy.
The thick portion 13 has holes for attaching the measuring elements 11 and 12 to the support rod 24.
The edge of the thin portion 14 on the side hooked to the lens 100 has a rising surface 15 and an inclined surface 16 inclined downward.
Then, the edge of the edge surface of the lens 100 is hooked on the boundary line between the rising surface 15 and the inclined surface 16. Accordingly, the rising surface 15 faces the concave or convex surface of the lens 100, and the inclined surface 16 faces the edge surface of the lens 100.

In the probe 11 for measuring the concave surface, the rising angle of the rising surface 15 (angle with respect to the upward direction) is 30 °. Further, the inclined surface 16 is provided with an inclination angle of 5 ° (an inclination angle with respect to a horizontal plane) deeper than the flatness angle 0 ° to 2.5 ° of the lens 100.
On the other hand, in the probe 12 for measuring the convex surface, the rising angle of the rising surface 15 (angle with respect to the upward direction) is 45 °. Thereby, it is possible to measure up to a curvature radius of 45 mm of the convex curve for a lens having a diameter of 60 mm. Further, the inclined surface 16 is provided with an inclination angle of 5 ° (an inclination angle with respect to a horizontal plane) deeper than the flatness angle 0 ° to 2.5 ° of the lens 100.

By setting the rising angle and the inclination angle of each of the measuring elements 11 and 12 as described above, the rising surface 15 and the inclined surface 16 do not hit the edge surface, concave surface, or convex surface of the lens 100, and the rising is performed. The measuring elements 11 and 12 can be hooked on the lens 100 at the boundary line between the surface 15 and the inclined surface 16.
Thereby, the edge thickness of the lens 100 (the thickness of the lens 100 on the edge surface) can be measured without scratching the edge surface, the concave surface, or the convex surface of the lens 100.

  Next, the operation of the apparatus during measurement will be described with reference to FIGS. FIG. 5 shows a state in which the right probe 12 is hooked on the edge on the convex side of the edge surface of the lens 100. FIG. 6 shows a state in which the left measuring element 11 is hooked on the edge on the concave surface side of the edge surface of the lens 100.

5 and 6, the measuring elements 11 and 12 are hooked on the edge of the edge surface of the lens 100, and the tension in the upward direction by the spring 28 and the lateral direction by the motor 23 is always applied as indicated by the arrows. Make measurements in the state. In this state, by rotating the shaft 33 of the lens chucks 31 and 32, the lens 100 is rotated, and the entire circumference of the lens 100 is measured.
At this time, as the lens 100 rotates, the edge surface of the lens 100 moves up and down following the pattern shape of the lens 100.

The edge thickness of the lens 100 can be obtained (calculated) from the result of each measurement using the left and right measuring elements 11 and 12.
Further, since the lens 100 is rotated by the rotation of the shaft 33, the thickness distribution of the entire edge surface of the lens 100 and the outer shapes of the concave and convex surfaces can be obtained.
Note that the concave and convex outer shapes of the lens 100 are measured in advance with a circumference measuring machine and controlled so that the measuring elements 11 and 12 move according to the measured outer shape data. Since the lens 100 is rotated by the rotation of the shaft 33, if there is a slight deviation when the lens 100 is chucked, the tracing stylus 11 and 12 move along the chucked lens 100 while correcting the trajectory. . At this time, the detection sensor 27 shown in FIG. 2 detects the vertical movement of the support rod 24 that accompanies the vertical movement of the right probe 12, thereby shifting the state of the chuck of the lens 100 by the lens chucks 31 and 32. Can be detected.
The detection sensor 27 is provided only for the support rod 24 of the right probe 12 in FIGS. 1 and 2, but a detection sensor is provided for the support rod 24 of both the measurement probes 11 and 12 on the left and right. Alternatively, a detection sensor may be provided only for the support rod 24 of the left probe 11.

  Note that each measurement in FIG. 5 and FIG. 6 cannot be performed at the same time, so either measurement is performed first. Either measurement may be performed first.

  In each measurement shown in FIGS. 5 and 6, the measuring elements 12 and 11 that are not performing measurement are stored in a place that does not interfere with the measuring elements 11 and 12 that are performing the measurement.

Next, a method for manufacturing a spectacle lens using the apparatus shown in FIGS. 1 and 2 will be described.
First, as in the conventional case, the lens 100 is cut to form concave, convex, and edge surfaces.
Next, after cutting the lens 100, before moving to the apparatus shown in FIGS. 1 and 2, the circumference and the outer shape of the cut lens 100 are measured with a circumference measuring machine.
Next, the lens 100 is fixed between the lens chucks 31 and 32 by moving to the apparatus shown in FIGS.
Next, the edge thickness of the lens 100 is measured using the measuring elements 11 and 12 by the procedure as described above, and an error between the outer shape data measured by the circumference measuring machine and the state chucked by this apparatus is calculated. taking measurement.
Next, the deviation from the measurement result of the outer shape by the circumference measuring machine is fed back, and the groove digging tool 41 of the lens processing portion is set to a position corresponding to the amount of deviation. Thus, by setting the groove digging tool 41 to a position corresponding to the amount of displacement, it becomes possible to form a groove with high accuracy at an accurate position. At this time, the holding state of the lens 100 by the lens chucks 31 and 32 is maintained in the same holding state as when the edge thickness and the outer shape of the lens 100 are measured.
Then, the groove digging tool 41 is used to dig a groove having a predetermined depth on the edge surface of the lens 100.
In this way, the lens 100 having a groove formed on the edge surface can be manufactured.

According to the above-described apparatus of the present embodiment, the lens processing unit that performs groove processing and the detection unit that measures the edge thickness and outer shape of the lens 100 are provided. The lens 100 can be maintained in the same holding state as when the thickness and outer shape are measured, and the groove processing can be performed by the lens processing unit.
Thereby, it is possible to accurately perform grooving at a precise position with a uniform groove depth without causing an error due to a difference in holding position of the lens 100 for each apparatus.

Therefore, with the apparatus of the present embodiment, it is possible to perform processing for forming grooves in the lens 100 with high accuracy.
Then, it is possible to improve the production yield of spectacle lenses and to stably mass-produce high quality spectacle lenses.

  Further, according to the apparatus of the present embodiment, the measurement by the measuring elements 11 and 12 is performed while rotating the lens 100 by the rotation of the shaft 33, and therefore the position of the edge surface of the lens 100 and the outer shape of the lens 100 are determined. Can be measured simultaneously. As a result, the time required for measurement can be shortened.

In the apparatus according to the above-described embodiment, the edge thickness of the lens 100 is measured using the measuring elements 11 and 12 and the edge position measuring sensors 21 and 22.
In the present invention, instead of measuring the lens edge thickness, the detection unit of the manufacturing apparatus may be configured to detect whether the lens edge thickness is within a predetermined range.
Thus, when detecting whether the edge thickness of the lens is within a predetermined range, for example, the measuring elements 11 and 12 and the edge position measuring sensors 21 and 22 shown in FIG. It can also be used as a sensor. At this time, the control unit or control program of the edge position detection sensor may be configured so that the edge position detection sensor detects whether or not the edge position detection sensor is within a predetermined range with reference to a predetermined design value.

In the apparatus of the above-described embodiment, the lens processing unit of the apparatus is configured to include the grooving tool 41 and perform grooving to form a groove in the lens 100.
In the device of the present invention, a lens processing unit configured to form a bevel on the lens or a lens processing unit configured to perform other processing on the lens can be used.

In the apparatus of the above-described embodiment, the outer shape and edge thickness of the lens 100 are measured by the detection unit having the measuring elements 11 and 12.
The present invention is not limited to the configuration for measuring the outer shape and edge thickness of the lens, but may be other configurations for measuring or detecting the outer shape and / or dimensions of the lens.

  In the present invention, the detector used for measurement and detection is not limited to the configuration of the measuring elements 11 and 12 shown in FIG. 3 and FIG. Any other configuration can be used as long as it can detect the above.

  The present invention is not limited to the above-described embodiment, and various other configurations can be taken without departing from the gist of the present invention.

BRIEF DESCRIPTION OF THE DRAWINGS It is a schematic block diagram (side view) of one Embodiment of the spectacle lens manufacturing apparatus of this invention. It is the side view seen from the longitudinal direction of the apparatus of FIG. A and B are enlarged views of a measuring element for measuring the left concave surface of FIG. 1. A and B are enlarged views of a measuring element for measuring the convex surface on the right side of FIG. It is a figure explaining the state which is measuring with the probe on the right side of FIG. It is a figure explaining the state which is measuring with the probe of the left side of FIG.

Explanation of symbols

  11 (for concave lens surface), 12 (for convex lens surface), 15 riser surface, 16 inclined surface, 21 and 22 edge position measurement sensor, 23 motor, 27 detection sensor, 28 for vertical movement of probe Spring, 31, 32 Lens chuck, 41 Groove tool, 100 Lens

Claims (6)

A spectacle lens manufacturing apparatus,
A lens processing unit for processing the lens to be the eyeglass lens;
A spectacle lens manufacturing apparatus, comprising: a detection unit that detects an outer shape and / or dimension of the lens.   The spectacle lens manufacturing apparatus according to claim 1, wherein the lens processing unit includes a tool that forms a groove on the edge surface of the lens.   2. The spectacle lens manufacturing apparatus according to claim 1, wherein the detection unit is configured to detect a concave surface and a convex outer shape of the lens and an edge thickness of the lens. 3.   The spectacle lens manufacturing apparatus according to claim 1, wherein a position where the lens is processed is set in the lens processing unit based on an outer shape and / or a dimension of the lens detected by the detection unit. A detection step of holding an eyeglass lens and detecting the outer shape and / or dimensions of the lens;
A processing step of processing the lens,
Maintaining the holding state of the lens in the detection step, setting a position for processing the lens based on the outer shape and / or dimensions of the lens obtained in the detection step, and the processing step A method of manufacturing a spectacle lens.   The method for manufacturing a spectacle lens according to claim 5, wherein in the processing step, a groove is formed on the edge surface of the lens, or a bevel is formed on the edge surface of the lens.

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