EP0855248A1 - Method and apparatus for NC shaping of spectacle lenses - Google Patents

Abstract

The method involves determining the shape of facettes on the edges of lenses and controlling lens processing accordingly. Shape data are entered for a frame aperture or shape plate into a CNC lens processing machine's computer. Personal optometric data are entered. The radii of the front and rear surfaces and the thickness of the raw lens are entered or derived from the optometric data. The front and rear edge curves are derived from the shape data and optometric data or from the shape data, radii and thickness. The spatial shape of a suitable facette between the forward and rear edge curves is derived and the lens processing machine is controlled according to the shape data and the spatial shape of the facette.

Description

The invention relates to a method and an apparatus for Determine the course of the facets on the edge of lenses to be shaped and to control the Form processing according to the determined facet course.

The course of the facets on the edge of those to be machined Eyeglass lenses should be determined in such a way that shape-worked glasses without reworking into a corresponding selected glasses frame can and should be used aesthetic reasons on the peripheral edge of the ground Glasses the same distance from wherever possible Have front edge, even if the lens is one of the circular shape has a very different shape to the Glasses frame does not differ in the forward direction survive.

When CNC-controlled mold machining, especially machining the optical surfaces and the subsequent shaping of the The peripheral edge and the roof facet of a lens are the Shape of the lens and personal optometric data of the glasses wearer in the form of a quantity of data with which can control a lens molding machine so that a Raw glass according to the personal optometric data of the Glasses wearer with regard to the optical surfaces as well according to the shape of the selected frame edged and the roof facet so on the peripheral edge of the molded lens is placed on the entire circumference runs on the circumferential edge and for example a certain distance from the front edge of the machined Observes glasses.

The data relating to the shape of the eyeglass frame can be in the form a quantity of data provided by the eyeglass frame manufacturer are present or can be obtained in that the glasses frame in a device for scanning the facet groove used and the Amount of data can be recorded in three-dimensional form. Here it should be noted that the faceted groove in a spectacle frame due to manufacturing tolerances or shape deviations must necessarily lie on a spherical surface.

A device for three-dimensional scanning of Eyeglass frames are in German utility model 86 08 201 U1 Applicant described.

In the German patent application DE 34 10 040 A1 the another a CNC-controlled lens edge grinding machine described in which the outer surface and the inner surface one clamped in the lens edge grinding machine, already finished with regard to the optical surfaces machined, circular raw glass on one of the glasses shape corresponding curve through two spring-loaded, pin-shaped Sensor is scanned, which is constantly directly on the glass apply and the axial position of which is communicated to potentiometers, the values and data determined by these potentiometers be passed on to a computer or a data storage device which from this the spatial course of the leading and trailing edge of the Spectacle lenses and the respective lens thickness calculated and from a stored amount of women from different roof facets selects the roof facet that is on the circumferential edge of the can be attached to shape-cut glasses without the Leaving the peripheral edge at any point. The one described Measuring device is in the CNC controlled Glasses edge grinding machine integrated and the scanning of the Raw glass is always the first step of the Machining process by the CNC-controlled Spectacle lens edge grinding machine. This is while scanning The raw glass cannot be shaped.

When measuring a lens after one in the German Patent specification DE 38 42 601 C2 of the applicant described Procedure in which the leading or trailing edge of a pre-ground glasses during the machining process is measured by a probe, is not an additional one Time required for measuring the spectacle lens required, however deviations of the lens from the spherical shape the measurement. Such deviations can arise from a spherical cut superimposed on prismatic or cylindrical Cut and result from the arrangement of a close part. Also the Decentration of the optical axis of the lens with reference to the geometric axis of the lens or the geometric The center of the frame plays a role.

The invention is based on the problem of a method for Determine the course of the facets on the edge of lenses to be shaped and to control the Form processing according to the determined facet course create with which the exploitation of a CNC-controlled Eyeglass lens molding machine and the accuracy of the Increase facet course and simplify operation.

• Eingeben der Formdaten r (γ, z) einer Brillengestellöffnung oder der Formdaten r (γ) einer Formscheibe in einen Rechner einer CNC-gesteuerten Brillenglasformbearbeitungsmaschine,
• Eingeben der persönlichen optometrischen Daten des Brillenträgers in den Rechner,
• Eingeben des Radius R1 der Vorderfläche und des Radius R2 der Rückfläche sowie der Dicke d des Rohglases oder Berechnen der Radien R1, R2 und der Dicke d des Rohglases aus den optometrischen Daten,
• Berechnen der vorderen und hinteren Randkurven des Brillenglases aus den Formdaten und den persönlichen optometrischen Daten oder aus den Formdaten und den Radien R1 und R2 sowie der Glasdicke d,
• Berechnen des räumlichen Verlaufs einer geeigneten Dachfacette auf dem Umfangsrand zwischen der entsprechend den eingegebenen Werten berechneten, vorderen oder hinteren Randkurve,
• Steuern der Bearbeitung der optischen Oberflächen und/oder des Randes mittels der Brillenglasformbearbeitungsmaschine entsprechend den Formdaten und
• Steuern der Formbearbeitung der Facette entsprechend dem berechneten räumlichen Verlauf der geeigneten Dachfacette oder
• Eingeben der Formdaten r (γ, z) einer Brillengestellöffnung oder der Formdaten r (γ) einer Formscheibe in einen Rechner einer CNC-gesteuerten Brillenglasformbearbeitungsmaschine,
• Eingeben der persönlichen optometrischen Daten des Brillenträgers in den Rechner,
• Messen der Dicke d eines Rohglases sowie der vorderen und hinteren Raumkurve des Brillenglases entsprechend den Formdaten der Brillengestellöffnung oder der Formscheibe in einer von der Brillenglasformbearbeitungsmaschine getrennten Meßvorrichtung oder
• Messen des Radius R1 der Vorderfläche und/oder des Radius R2 der Rückfläche und der Dicke d des Rohglases in einer von der Brillenglasformbearbeitungsmaschine getrennten Meßvorrichtung oder
• Messen der Dicke d des Rohglases in einer von der Brillenglasformbearbeitungsmaschine getrennten Meßvorrichtung oder mittels einer mit einer Brillenglashaltewelle in der Brillenglasformbearbeitungsmaschine zusammenwirkenden Meßvorrichtung,
• Übertragen der Meßwerte in den Rechner,
• ggf. Berechnen der vorderen und hinteren Randkurven des Brillenglases aus den Formdaten und den persönlichen optometrischen Daten oder aus den Formdaten und den Radien R1 und R2 sowie der Glasdicke d,
• Berechnen des räumlichen Verlaufs einer geeigneten Dachfacette auf dem Umfangsrand zwischen der gemessenen oder entsprechend den eingegebenen Werten berechneten, vorderen oder hinteren Randkurve,
• Steuern der Bearbeitung der optischen Oberflächen und/oder des Randes mittels der Brillenglasformbearbeitungsmaschine entsprechend den Formdaten und
• Steuern der Formbearbeitung der Facette entsprechend dem berechneten räumlichen Verlauf der geeigneten Dachfacette.

Based on this task, a method is proposed which according to the invention consists of the following steps:

• Entering the shape data r (γ, z) of an eyeglass frame opening or the shape data r (γ) of a shape disk into a computer of a CNC-controlled eyeglass lens processing machine,
• Entering the personal optometric data of the glasses wearer into the computer,
• Entering the radius R1 of the front surface and the radius R2 of the rear surface and the thickness d of the raw glass or calculating the radii R1, R2 and the thickness d of the raw glass from the optometric data,
• Calculating the front and rear edge curves of the spectacle lens from the shape data and the personal optometric data or from the shape data and the radii R1 and R2 and the lens thickness d,
• Calculating the spatial profile of a suitable roof facet on the peripheral edge between the front or rear edge curve calculated according to the entered values,
• Controlling the processing of the optical surfaces and / or the edge by means of the lens processing machine in accordance with the shape data and
• Controlling the shape processing of the facet according to the calculated spatial course of the suitable roof facet or
• Entering the shape data r (γ, z) of an eyeglass frame opening or the shape data r (γ) of a shape disk into a computer of a CNC-controlled eyeglass lens processing machine,
• Entering the personal optometric data of the glasses wearer into the computer,
• Measuring the thickness d of a raw lens as well as the front and rear space curve of the lens according to the shape data of the eyeglass frame opening or the shaped disk in a measuring device or separated from the lens molding machine
• Measuring the radius R1 of the front surface and / or the radius R2 of the rear surface and the thickness d of the raw glass in a measuring device or a separate from the lens molding machine
• Measuring the thickness d of the raw lens in a measuring device separate from the lens processing machine or by means of a measuring device interacting with a lens holding shaft in the lens processing machine,
• Transfer of the measured values to the computer,
• if necessary, calculate the front and rear edge curves of the spectacle lens from the shape data and the personal optometric data or from the shape data and the radii R1 and R2 and the lens thickness d,
• Calculating the spatial course of a suitable roof facet on the peripheral edge between the measured or calculated according to the entered values, front or rear edge curve,
• Controlling the processing of the optical surfaces and / or the edge by means of the lens processing machine in accordance with the shape data and
• Controlling the shape processing of the facet according to the calculated spatial course of the suitable roof facet.

The invention is based on the consideration that for Spectacle lens processing machine dead times can be avoided and should therefore only perform machining operations in order to to achieve the highest level of utilization while all for the Perform the necessary preparatory steps outside the machine but in close connection with the machine should expire. Accordingly, all measurements that require a special additional step outside of Spectacle lens processing machine performed. Functions only, the processing steps required anyway connect, are in the Eyeglass lens molding machine performed without the Extend dead times. This includes measuring the thickness d of the Raw glass that can be carried out in the machine, if that Raw glass is clamped in the spectacle lens holding shaft because the Movement of the spectacle lens holding shaft during clamping to measure the Can use thickness d of the raw glass.

Furthermore, the performance of the to control the Spectacle lens processing machine used exploited to take into account all the values entered and measured data to perform itself program and execute at high computer speed to let. An additional mainframe or central computer is not necessary for this, as a correspondingly programmed Calculator, which is also in the lens processing machine integrate and use for the CNC control, completely is sufficient.

The computer can, for example, determine the spatial course of a suitable roof facet on the peripheral edge between the front and calculate the rear edge curve of the lens by on the one hand the personal, optometric data of the Spectacle wearer like diopter number, the axis position of one cylindrical or prismatic cut, the location of a near part and the decentration values of the given outline shape with reference entered on the optical axis of the raw glass and the thickness d of a raw glass as well as the front and rear edge curve of the Eyeglass lenses according to the shape data of the eyeglass frame opening or the form disk, which is also in the form of a data set in the calculator can be entered in one of the Spectacle lens molding machine separate measuring device are determined and transmitted to the computer, whereupon the Calculates the spatial course of a suitable roof facet calculated. Or it will only be the radius R1 of the front surface and / or the radius R2 of the back surface and the thickness d of the Raw glass in a lens processing machine separate measuring device measured and together with the rest Data to calculate the spatial course of a suitable one Roof facet used.

Finally, it may also be enough to put all the values in the calculator enter, whereupon the calculator then using a suitable algorithm first the front and rear optical Surface and from it the front and rear edge curve of the Glasses from the shape data and the personal optometric data or from the shape data and the radii R1 and R2 and the entered or measured glass thickness d are calculated and then the spatial course of a suitable one Roof facet on the peripheral edge between the front and the trailing edge curve is calculated, after which these values are used to control the Processing of optical surfaces and / or edge processing by means of the shape processing machine according to the shape data and to control the shaping of the facet according to the calculated spatial course of the suitable roof facet be used. It may be sufficient to use only one radius R1 or R2 as well as the glass thickness d because the second radius of the Glasses are usually known and directly in the calculator can be entered.

Advantageously, the radii R1, R2 and the thickness d or the front and rear space curve using a Laser beam measuring system or by means of a mechanical or a opto-mechanical measuring system can be measured, either as independent measuring device next to the Spectacle lens processing machine may be present, or else into an automatic device for picking up and inserting Raw lenses integrated in the lens processing machine can be.

The eyeglass lens molding machine with one spectacle lens holding shaft to be shaped into raw glass can advantageously a the feed path of an axial sliding half of the eyeglass holding shaft for measuring the Thickness d of the clamped raw glass measuring device have, so that the thickness of the raw glass automatically at Clamping into the spectacle lens holding shaft results and sent to the computer is forwarded.

Fig. 1

eine schematische, perspektivische Ansicht einer Anlage zum CNC-gesteuerten Formbearbeiten von Brillengläsern und

Fig. 2

eine schematische, perspektivische Darstellung einer Meßvorrichtung zum Messen des Radius R1 der Vorderfläche und/oder des Radius R2 der Rückfläche und der Dicke d des Rohglases sowie ggf. der vorderen und hinteren Randkurve des Brillenglases entsprechend den Formdaten der Brillengestellöffnung oder der Formscheibe.

The invention is explained below with reference to an embodiment shown in the drawing. The drawing shows:

Fig. 1

is a schematic, perspective view of a system for CNC-controlled shaping of glasses and

Fig. 2

is a schematic, perspective view of a measuring device for measuring the radius R1 of the front surface and / or the radius R2 of the rear surface and the thickness d of the raw lens and possibly the front and rear edge curve of the lens according to the shape data of the eyeglass frame opening or the shaped disc.

An inventive system for processing the peripheral edge of Eyeglass lenses have a CNC-controlled Spectacle lens edge processing machine 1 with an input keyboard 2, a flap 3 with a window, one behind the flap 3 arranged spectacle lens holding shaft 4 in which a raw lens 5 is held is that its CNC-controlled by means of a grinding wheel 6 Receives shape grinding. A calculator 7, the desktop calculator outside the spectacle lens edge grinding machine 1 is shown in however, this can also be integrated, causes shape grinding of the raw glass 5 according to the data entered for the Eyeglass lens shape.

The input keyboard 2 can of course outside of Spectacle lens edge processing machine 1, in particular in connection with the desktop computer 7, which also have a screen 38 to display the entered data and the like, be arranged.

A box 8 with two supports 9 for flat raw glass, namely a left raw glass 10 and a right raw glass 11, leaves by means of a transport device, not shown Guide rails 12 in the area of a handling device 13 bring. This handling device 13 is fixed by means of a Stand 14 anchored and has one at the upper end of the stand 14 pair of arms 15 pivotable about vertical axes. At the free end one of the pivotable arms 15 is a rotatable and displaceable Guide rod 16 in one with a corresponding drive provided head 21 arranged. At the bottom of the Guide rod 16 is another head part 17, which as Support for a vertical, with respect to the head part 17th fixed suction cups 18 and for six around a horizontal axis rotatable suction cups arranged in a crescent shape on a ring segment 19 serves. A suction line 20 leads from each of the suction devices 19 into the Head part 17 and from there via sensors, not shown, to one Vacuum tank or to a vacuum pump. A corresponding Suction line is also available for the suction device 18.

By means of a control device 22, which is connected to the computer 7 is connected and also be formed as part of the computer 7 can, the head part 17 in the area of Eyeglass lens edge grinder 1, box 8 and one opto-electronic detection system 23 for spectacle lenses bring. The opto-electronic detection system 23 has one Housing 30 with an upward opening 31. The Opening is surrounded by a shield 26, from which three pins 24 protrude a three-point support for a raw glass 25.

On one side of the housing 30 is an upstanding support 32 arranged on which a swivel arm 33 is mounted. This Swivel arm 33 has an axially displaceable at its free end Guide rod 34 with a flexible head 35 on her free end on. This flexible head 35 can be Swiveling the swivel arm 33 to above the raw glass 25 swivel. By lowering the guide rod 34 comes the soft elastic head 35 to rest on the raw glass 25 and holds this on the three-point edition 24. On the carrier 32 is the further attached a lighting 37 for a Oblique lighting of the raw glass 25 ensures.

One is not in the housing 30 below the opening 31 shown CCD camera arranged an electronic Image processing and evaluation system in a control unit 36 and with the control device 22 of the handling device 13 connected is. The control device 36 can also be in the computer 7 be integrated.

There is also one in the working area of the handling device 13 Laser beam measuring device arranged, the base plate 41st has, on which a turntable 42 is arranged. This Rotary table 42 is with a suction cup for holding one side Raw glass 51 provided. Protective walls 43 are around the base plate 41 arranged which the work space above the base plate 41st to lock. On a laterally attached to the base plate 41 Stand 44 is a holding head 50 is arranged axially movable telescopic arm 46 carries. On the free arm of the Telescopic arm 46 is arranged a guide 47, one in it lifting and lowering spindle 48 carries. At the lower end of the spindle 48 there is a laser beam source 49, of which a measuring beam 100 going out.

Around the radius R1 or R2 of the laser beam source 49 facing It is sufficient to measure the surface of the raw glass 51 Laser beam source 49 by axially displacing the telescopic arm 46 to move once across the raw glass 51 and thereby the to record differences in height measured on the surface. Out of this The computer 7 calculates the radius R1 or R2 depending on which one Side of the raw glass 51 is directed to the laser beam source 49. Both radii R1 and R2 are turned over in this way measured, the respective results directly from this Raw glass thickness d in the optical center.

With the measuring device shown in Fig. 2 can also the front and rear space curve of the lens accordingly measure the shape of the eyeglass frame opening or the shaped disc, when the movement of the computer 7 via the control device 45 Telescopic arm 46 while rotating the turntable 43 so is controlled that the measuring beam 100 the surface of the raw glass 51 leaves according to the shape of the lens.

Instead of the laser beam measuring device shown can also use a mechanical or opto-mechanical measuring system that performs the measurements in the top of the raw glass.

The raw glass 51 is inserted into the Measuring device inserted and removed from this and leaves closing in the opto-electronic detection system 23 insert or can directly into the lens holder shaft 4 of the Spectacle lens processing machine 1 can be used.

The computer 7 calculates on the basis of the measurement data and the input Data referring to the personal optometric data of the Glasses wearer the shape of the glasses frame opening or Obtain a shaped disc, the spatial course of a suitable Roof facet on the peripheral edge of the lens between the front and rear edge curves and controls editing of the raw glass 5 according to these values. This will start with the raw glass 5 into the shape according to the shape data of the Eyeglass frame opening or the molded disc and is then the roof facet on the peripheral edge between the front and rear edge curve processed so that they the Demands for an aesthetically appealing arrangement of the Eyeglass lenses in the selected eyeglass frame corresponds to it inserting the molded lens into the selected glasses frame allows without difficulty.

Since the lens processing machine 1 only the Machining processes, however, no measuring processes that lead additional dead times, has to be carried out Increase machine utilization. Operation of the Spectacle lens edge processing machine 1 is very simplified because only the available personal optometric data of the Wear the glasses in the alphanumeric keyboard 2, while the further process by the computer 7 automatically is controlled.

All entered and measured data can be viewed using a Check the display on the screen 38 so that a incorrect operation or incorrect processing excluded are.

The opto-electronic detection system 23 with its electronic image processing and evaluation system 36 contributes to simplified handling and for precise work of the Eyeglass lens edge grinding machine 1, since the image processing and Evaluation system 36 so accurate data for the control of the Handling device 13 provides that raw glasses in the CNC controlled spectacle lens edge processing machine 1 extreme can be edited exactly and without reworking into that Have the eyeglass frame inserted, according to whose data the eyeglass lens was ground. The for the respective glasses wearer from Optician to determine the decentration values of the optical Center of the lenses with reference to the geometric The center of the lens openings in the frame can be either from the CNC control of the eyeglass lens grinding machine 1 take into account arithmetically, or the handling device 13 sets not only a raw glass in the spectacle lens edge grinding machine 1 angularly with respect to the position of the axis of a cylindrical or prismatic cut or the location of a near part, but also still offset by the decentration values, so that a conversion the data of the lens shape taking into account the Decentration values are not required.

In addition to the CNC-controlled one shown Eyeglass lens edge processing machine 1 can also be a machine for CNC controlled processing of optical surfaces be set up with the same data to edit the optical surfaces through the computer 7 CNC-controlled performed, wherein the handling device 13 can serve the automatic transfer of the raw glass between the Spectacle lens edge processing machine and the not shown Surface processing machine.

When editing the optical surfaces and the edge including the facet in a unified machine is integrated, the implementation is not necessary.

Claims (6)

Method for determining the course of the facets on the edge of spectacle lenses to be shaped and for controlling the shaping according to the determined course of the facets with the steps: Entering the shape data r (γ, z) of an eyeglass frame opening or the shape data r (γ) of a shape disk into a computer of a CNC-controlled eyeglass lens processing machine, Entering the personal optometric data of the glasses wearer into the computer, Entering the radius R1 of the front surface and the radius R2 of the rear surface and the thickness d of the raw glass or calculating the radii R1, R2 and the thickness d of the raw glass from the optometric data, Calculating the front and rear edge curves of the spectacle lens from the shape data and the personal optometric data or from the shape data and the radii R1 and R2 and the lens thickness d, Calculating the spatial course of a suitable roof facet on the peripheral edge between the measured or calculated according to the entered values, front or rear edge curve, Controlling the processing of the optical surfaces and / or the edge by means of the lens processing machine in accordance with the shape data and Controlling the shape processing of the facet according to the calculated spatial course of the suitable roof facet. Method for determining the course of the facets on the edge of spectacle lenses to be shaped and for controlling the shaping according to the determined course of the facets with the steps: Entering the shape data r (γ, z) of a spectacle frame opening or the shape data r (γ) of a shaping disc into a computer of a CNC-controlled spectacle lens shaping machine, Entering the personal optometric data of the glasses wearer into the computer, Measuring the thickness d of a raw lens as well as the front and rear space curve of the lens according to the shape data of the eyeglass frame opening or the shaped disk in a measuring device or separated from the lens molding machine Measuring the radius R1 of the front surface and / or the radius R2 of the rear surface and the thickness d of the raw glass in a measuring device or a separate from the lens molding machine Measuring the thickness d of the raw lens in a measuring device separate from the lens processing machine or by means of a measuring device interacting with a lens holding shaft in the lens processing machine, Transfer of the measured values to the computer, if necessary, calculate the front and rear edge curves of the spectacle lens from the shape data and the personal optometric data or from the shape data and the radii R1 and R2 and the lens thickness d, Calculating the spatial course of a suitable roof facet on the peripheral edge between the measured or calculated according to the entered values, front or rear edge curve, Controlling the processing of the optical surfaces and / or the edge by means of the lens processing machine in accordance with the shape data and Controlling the shape processing of the facet according to the calculated spatial course of the suitable roof facet. Method according to claim 1 or 2, characterized in that the measurement of the radii R1, R2, the thickness d or the front and rear space curve is carried out by means of a laser beam measuring device. Method according to Claim 1 or 2, characterized in that the measurement of the radii R1, R2 of the thickness d is carried out by means of a mechanical or an opto-mechanical measuring system in the apex of the raw glass. Method according to Claim 1, 2, 3 or 4, characterized in that the measurement of the radii R1, R2, the thickness d or the front and rear edge curve takes place in an automatic device for picking up and inserting raw lenses into the lens processing machine. Eyeglass lens molding machine with one raw glass (5) to be shaped Spectacle lens holding shaft (4) and an axial feed path displaceable half of the spectacle lens holding shaft (4) for measuring the thickness of the clamped raw glass (5) Measuring device (39).

Images