KR20080072860A - Appliance for tactile sensing a spectacle frame and related grinding machine - Google Patents

Abstract

The invention concerns an appliance (11) comprising means (23) for positioning a spectacle frame, a tactile sensor probe (25) including a support (31) and a tactile sensing blade (33), and means (27) for relatively moving the support (31) with respect to the positioning means (23), about an axis of rotation (C-C'), along said axis (C-C') and radially relative to said axis (C-C'). The appliance (11) comprises means (95, 61) for measuring, for each angular position of the blade (33) about the axis of rotation (C-C'), the radial and axial position of the blade (33). The blade (33) has on its edge a tactile sensing ridge (37) converging away from the support (31) in the direction of the radial axis (B-B'). The tactile sensing ridge (37) is designed to be contacted with the frame (15). The tactile sensing ridge (37) forms, by projection on a plane perpendicular to the radial axis (B-B'), a concave line. The invention is applicable to tactile sensing of spectacles with concavo-convex lenses.

Description

APPLICATION FOR TACTILE SENSING A SPECTACLE FRAME AND RELATED GRINDING MACHINE}

The present invention relates to an apparatus for inspecting an eyeglass frame, the apparatus comprising:

Disposition means for disposing the spectacle frame;

A filler comprising a support and a filler blade attached to the support;

Relative moving means for moving the support about the axis of rotation about the axis of rotation, along the axis and radially with respect to the axis; And

Is of a type comprising measuring means for measuring the radial and axial position of the blade with respect to each angular position of the filler blade about the axis of rotation,

The filler blade has a filler edge at its end face that converges away from the support along the radial axis, and the filler edge is designed to contact the frame.

This device is intended for inspecting flat or non-planar frames, in particular for inspecting glasses with curved, ie non-planar bezels.

French patent publication FR-A-2 777 817 discloses a filler device of this type which makes it possible to measure the exact profile of the bezel formed on a spectacle frame containing a lens. The profile thus obtained by inspecting the frame is transferred to a dehumidifier forming an optical lens that exactly fits the size of the frame.

The filler of the device is formed by a planar blade with pointed ends that comes into contact with the bottom of the bezel during inspection.

Such an assembly does not provide full satisfaction. The sharp end of the blade is held in the bezel, especially when there is surface irregularity, for example at the closure of the rim of the rim.

In order to solve this problem, it is known to use flat filler blades with rounded ends.

Nevertheless, if the frame is curved, this type of blade tends to deviate from the bezel during inspection, thus degrading the reliability of the inspection.

It is therefore an object of the present invention to provide a filler device for inspecting spectacle frames, which can reliably and reproducibly inspect every shape of a rim, in particular a curved rim.

To this end, the present invention provides a filler device of this type, characterized in that the filler edge projecting in a plane perpendicular to the radial axis forms a concave line.

The filler device of the present invention may include one or more of the following features, taken separately or in a technically suitable combination.

Concave lines are capable of substantially continuous differentiation.

The concave line is substantially inverted U-shaped.

Concave lines have an inverted V shape.

The filler edge protruding in a plane perpendicular to the axis of rotation forms a bend that is capable of substantially continuous differentiation.

The curve is substantially semicircular.

The filler blade has a concave section along its radial axis substantially in its entire length and in an area in the plane perpendicular to the radial axis.

The arrangement means comprises means for orienting the concave spectacle frame such that the concave side faces in the direction opposite to the concave side of the concave line of the filler edge.

The axis of rotation is a substantially vertical axis with the concave side of the concave line facing downward.

The present invention also provides an optical lens dehumidifier comprising the filler device defined above.

The invention is better understood by reading the following description, given by way of example only and with reference to the accompanying drawings.

1 is a perspective view of a fragmentary 3/4 side in a first filler device of the present invention.

FIG. 2 is a fragmentary cross-sectional view on a vertical plane through the rim of the frame to be inspected in the device of FIG. 1.

3 is a fragmentary plan view of a filler blade of the apparatus of FIG. 1.

4A and 4B are cross-sectional views of the blade of FIG. 3 in two angular positions for inspecting the frame shown in FIG. 1.

5A and 5B are views similar to FIGS. 4A and 4B showing the filler blades of the second device of the present invention.

FIG. 6 is a schematic diagram showing details of FIG. 1 at four consecutive positions of the filler blades during movement around the rim of the rim. FIG.

The first filler device 11 of the present invention partially shown in FIG. 1 is for measuring the exact profile of the bezel 13 formed on the spectacle frame 15 prior to the edge processing of the lens mounted on the frame.

This filler device 11 is arranged, for example, in an optical lens chaser of the type described in application FR-A-2 852 878.

As shown in FIGS. 1 and 2, the rim 15 includes a rim 18 of the rim with a bezel 13 formed therein. Rim 18 is laterally closed by closure 19.

The rim 18 of the frame is curved, ie not planar. In this example, the rim substantially inscribes the sphere.

Thus, if the rim 18 of the rim is horizontal, with its branches or temples (not shown) facing upwards, at least two upwardly inclined portions 21 turning clockwise and at least two, It has the lower part 22 inclined downward.

The rim 18 of the frame thus has an upwardly concave shape in the illustrated example.

As shown in FIG. 2, a bezel 13 is provided inside the rim 18 of the rim about the entire circumference of the rim 18. It has a substantially V-shaped cross section.

Referring to FIG. 1, the filler device 11 includes a placement means 23 for arranging the frame 15, a filler 25, a relative movement means 27 for moving the filler 25 with respect to the placement means 23, And a control and measurement unit 29 for controlling and measuring movement of the filler 25.

The positioning means 23 comprise a frame retaining clamp as described, for example, in application FR-A-2 754 356. These clamps are adapted to keep the rim 15 substantially horizontal over the moving means 27.

The pillar 25 includes a vertical support rod 31 extending along the vertical axis A-A 'and a pillar blade 33 mounted at a fixed position of the upper end of the rod 31.

The blade 33 comprises a body 35 extending radially substantially horizontally away from the rod 31.

For example, the body 35 is formed of a stamped metal plate that is smaller in thickness than its length and width.

Over its entire length, the body 35 has a concave region facing downward in the plane of the region perpendicular to its axis B-B '.

The concave side of the zone of the body 35 thus faces in a direction opposite to the concave side of the rim 18 of the frame.

As shown in FIG. 3, the body 35 has a filler edge 37 radially converging toward the radial axis B-B 'on a free end face away from the support 31. The edge 37 is for contacting the bottom of the bezel 13 during inspection of the frame as described below.

As shown in Fig. 3, the edge 37 protruding in the horizontal plane perpendicular to the vertical axis A-A 'forms a curved portion capable of substantially continuous differentiation in the form of a semicircle. The filler edge 37 therefore has no pointed parts, thus limiting the extent to which it is held in the rough part of the rim 15, especially near the closure 19. In a variant, the edge 37 forms a parabolic curve with an outline that is corrected so that the distance between the contact point between the frame and the edge 37 and the rod 31 can be accurately determined.

4A, the filler edge 37 which protrudes on the perpendicular | vertical surface perpendicular | vertical to a radial axis forms the line which is not flat but concave upward.

The concave lines are substantially flat inverted U-shaped.

The concave line is capable of substantially continuous differentiation and forms an angle of 120 ° to 170 ° between its tip and the lateral ends. The vertical plane including the radial axis B-B 'forms a left region 39 and a right region 41 which are symmetrical with respect to the plane on the edge 37.

As shown in Fig. 1, the moving means 27 comprises a horizontal circular rotary table 45 rotatable about a vertical axis CC ', a support frame 47 attached to the rotary table 45, and a radially filler 25 And a sleeve 50 for guiding the filler 25 in the axial direction.

The rotary table 45 is provided at its periphery with teeth 51 which allow it to be driven to rotate around axis C-C '.

The frame 47 holds two parallel horizontal rods 53 mounted on both sides of the diameter of the turntable 45.

The slider 49 is mounted to move freely in the radial direction along the rod 53.

Sleeve 50 is mounted in a fixed position on slider 49. It projects vertically from the slider 49 and has a central guide passage for the rod 31, which rod 31 is mounted therein to slide along axis A-A '.

The control and measurement unit 29 comprises drive means 55 for driving the rotary table 45 to rotate about the axis BB ', drive means 59 for translationally driving the slider 49 along the radial axis, and a sleeve ( Drive means 61 for translating the rod 31 along the vertical axis A-A 'within 50).

The unit 29 further includes a sensing sensor 63 for sensing each position of the rotary table about the axis CC 'and the radial of the rod 31 relative to the axis C-C' based on the position of the slider 49. A measuring sensor 65 for measuring the position, and a measuring sensor 67 for measuring the vertical position of the rod 31 on the axis AA '.

In a variant, the unit 29 comprises an angular stepper actuator which allows the angular position of the rotary table 45 about the axis C-C 'to be calculated. The unit does not have a sensor 63 at this time.

The inspection of the curved eyeglass frame 15 in the first filler device 11 of the present invention will be described below.

First, the rim 15 is mounted to the clamp 23 with the branches (not shown) facing upwards, and is held in a substantially horizontal position on the means 27 for moving the pillar 25.

Then, at the initial angular position of the rotary table 45 around the axis CC 'with the aid of the radial drive means 59 and the axial drive means 61, the filler blade 23 is in contact with the bottom of the bezel 13. Contact.

Thereafter, the filler edge 37 is pressed against the bottom of the bezel 13.

Thereafter, the turntable 45 is rotated around the axis C-C '. The unit 29 then moves the slider 49 and the rod 31 to maintain contact between the filler edge 37 and the bottom of the bezel 13 for each angular position of the blade 33 around the axis CC '. Control the movement of

The unit 29 then records the axial and radial positions of the rod 31 for each angular position of the turntable 45 around axis C-C '. Thereafter, the profile of the bezel 13 is calculated based on the position measured by the rod 31 and the average length of the filler blade 33.

As shown in FIGS. 4A and 4B, the concave shape of the filler edge 37 projecting in a vertical plane perpendicular to the radial axis B-B 'and in the direction opposite to the concave shape of the rim 18 of the rim is a blade. Allow 33 to be continuously pressed against bezel 13 while limiting the risk of leaving it from bezel 13.

As shown in FIG. 6, when the blade 33 moves clockwise with respect to the frame 15, the left side of the filler edge 37 at the raised portion 21 (upper right and bottom left) of the frame 15. The area 39 is in contact with the bezel 13, while in the lower portion 22 (top left and bottom right), the right area 41 is in contact with the bottom of the bezel 13.

Thus, as the edge 37 moves around the rim 18 of the rim, the point of contact between the filler edge 37 and the rim 18 of the rim is at the edge 37 between the left region 39 and the right region 41. To move.

As a result, as shown in FIGS. 4A and 4B, the area 39 or 41 of the filler edge 37 in contact with the rim 18 has an angle of inclination substantially the same as the rim 18 of the rim 18. Irrespective of the position of the blade 33 around the rim 18.

As shown in Figs. 5A and 5B, in the second filler device with the filler blades 33, the filler edges 37 projecting in a plane perpendicular to the radial axis B-B 'form a flat inverted V-shaped line. Form.

In the above-described invention, the concave shape of the filler edge 37 protruding in a plane perpendicular to the radial axis B-B 'and the rounded shape protruding with the blade perpendicular to the rotation axis C-C' of the filler 25 are the blades. The filler blade 33 is curved without risk of being caught at the bottom of the bezel 13, particularly near the closure 19 of the rim 18 of the rim, while limiting the risk that the 33 may escape from the bezel 13. It is possible to inspect the frame 15.

Claims (10)

In the filler device 11 for inspecting the spectacle frame 15, Arranging means (23) for arranging the spectacle frame (15); A filler (25) comprising a support (31) and a filler blade (33) attached to the support (31); With respect to the positioning means 23, the support part 31 is moved radially around the rotation axis C-C ', along the rotation axis C-C' and radially with respect to the rotation axis C-C '. Relative moving means (27); And Measuring means (59, 61) for measuring the radial and axial positions of the pillar blade (33) with respect to each angular position of the pillar blade (33) about the axis of rotation (C-C '), The filler blade 33 has a filler edge 37 at its end face that converges away from the support part 31 along the radial axis B-B ', and the filler edge 37 has the eyeglass frame 15. ) Is designed to come in contact with Filler device, characterized in that the filler edge (37) projecting in a plane perpendicular to the radial axis (B-B ') forms a concave line. The method according to claim 1, And the concave line is capable of substantially continuous differentiation. The method according to claim 2, And the concave line is substantially inverted U-shaped. The method according to claim 1, And the concave line has an inverted V shape. The method according to any one of claims 1 to 4, Filler device characterized in that the filler edge (37) projecting in a plane perpendicular to the axis of rotation (C-C ') to form a curved portion that is capable of substantially continuous differentiation. The method according to claim 5, And the curved portion is substantially a semicircle. The method according to any one of claims 1 to 6, The filler blade 33 is characterized by having a concave region along the radial axis B-B 'substantially in full length and in an area in a plane perpendicular to the radial axis B-B'. Filler device. The method according to any one of claims 1 to 7, And the arrangement means (23) comprises means for orienting the concave spectacle frame (15) such that the concave side faces the concave side of the concave line of the filler edge (27). The method according to any one of claims 1 to 8, The said rotation axis (C-C ') is a substantially vertical axis, The filler apparatus characterized by the recessed side of the said recessed line facing downward. An edger machine for an optical lens, comprising the filler device (11) according to any one of claims 1 to 9.

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