FR2901031A1 - METHOD FOR CENTERING AN OPHTHALMIC LENS ON A CAMBREE EYEWEAR MOUNT - Google Patents

Abstract

The invention relates to a method for centering an ophthalmic lens (10) on an eyeglass frame (20), comprising positioning a reference frame of the ophthalmic lens with respect to a reference frame of the spectacle frame.According to the invention, said positioning is performed according to at least one characteristic value of the camber of the frame and / or the camber of the ophthalmic lens.

Description

TECHNICAL FIELD TO WHICH THE INVENTION RELATES The present invention

  relates generally to the field of eyewear and more specifically the mounting of ophthalmic lenses of a pair of corrective glasses on a frame.

  It relates more particularly to a method of centering an ophthalmic lens on a spectacle frame, comprising positioning a reference frame of the ophthalmic lens relative to a reference frame of the spectacle frame. The invention finds a particularly advantageous application in the centering of strongly arched lenses. BACKGROUND ART The technical part of the optician's profession consists in mounting a pair of ophthalmic lenses on a frame selected by a wearer. This assembly is broken down into five main operations: -the reading of the outline of the bevels of the circles of the frame selected by the wearer, that is to say the contour of the grooves that run through the inside of each frame of the frame, said reading providing an image of the shape of the final contour according to which each ophthalmic lens will be cut off; - The centering of each lens which consists in determining the position that each lens will occupy on the frame so as to be properly centered facing the pupil of the wearer's eye so that it properly exerts the optical function for which it was conceived; - The probing of each lens which consists in determining the coordinates of points on each of the faces of the lens characterizing the shape of the final contour of each ophthalmic lens; and - the trimming of each lens which consists of machining or cutting according to the final contour palpated, given the defined centering parameters. In the context of the present invention, we are interested in the second so-called centering operation. It is, in concrete terms, for the optician, to define the position that the final contour will have to occupy relative to the optical reference of said lens, typically its usual marks or its optical centering point, so that the lens is suitably positioned facing the pupil of the eye of the wearer to best perform the optical function for which it was designed. For this, at first, the optician equips the wearer of a spectacle frame identical to the frame chosen by the wearer and provided with presentation lenses, and then determines on each presentation lens the position of the pupil point. arranged opposite the pupil of the corresponding eye of the wearer, as well as the shape of each of the circles of the frame, that is to say the shape of the final contours according to which the lenses will be cut out. More precisely, it measures or acquires, in the general plane of the frame (plane orthogonal to the plane of symmetry of the frame and its two branches), two parameters related to the morphology of the wearer, namely the interpupillary half-gaps defined as the distances between each of the wearer's pupils and the center of the nose, as well as the heights of his pupils relative to the final contour. The knowledge of these parameters allows him to locate the position of the final contour relative to the pupillary point of each lens. Then, in a second step, the optician superimposes the pupillary point on the point of optical centering of the lens and reports on the lens the position of the final contour with respect to the pupillary point. He carries out this report in the plane of tangency of each lens (that is to say the plane tangent to the ophthalmic lens and passing through its optical centering point). He thus fixes on the ophthalmic lens the position of the final contour according to which the lens will have to be cut off. The Applicant has found that, despite the care taken in measuring the position of the pupil points and the final contour, it happens that the ophthalmic lenses are not correctly centered, which can cause visual discomfort for the wearer. OBJECT OF THE INVENTION An object of the present invention is to provide a centering method to avoid or at least reduce the centering error of the ophthalmic lenses on the eyeglass frame chosen by the wearer.

  More particularly, it is proposed according to the invention a centering method as defined in the introduction, wherein the positioning is performed according to at least one characteristic value of the camber of the eyeglass frame and / or the camber of the ophthalmic lens.

  The applicant has analyzed, in the course of his research, that the origin of the errors of centering came from the fact that the measurement of the position of the pupillary point with respect to the final contour was carried out in the general plane of the frame, then that the postponement of measured pupillary distances was made in the plane of tangency of each lens. However, the general plane of the frame and the plane of tangency being inclined with respect to each other, and the postponement of the pupil distances not taking into account this inclination, this report induces a centering error directly function of said tilt. Thus, thanks to the invention, the postponement of pupillary distances takes into account the importance of this inclination by determining the camber of the eyeglass frame and / or the camber of the ophthalmic lens when it is positioned on said frame, then positioning the reference frame of the lens relative to that of the frame according to this camber. According to a first advantageous characteristic of the centering method according to the invention, the positioning is performed as a function of at least one characteristic value of the camber of the ophthalmic lens and the camber of the spectacle frame. The ophthalmic lens, because of its own camber, has a plane tangent to its front face and passing through its optical centering point, which is not generally orthogonal to light rays from infinity. The inclination of this plane with respect to the light rays coming from infinity thus induces a deviation of these rays within the ophthalmic lens. This deviation causes a shift between the ray passing through the pupil point and being supposed to impact the pupil of the eye of the wearer and the ray actually impacting the pupil of the eye of the wearer. The method then proposes to take this offset into account in order to correct it. According to another advantageous characteristic of the centering method according to the invention, the positioning is calculated in order to take into account the deviations which the direction of the gaze undergoes through the ophthalmic lens taking into account said at least one characteristic value of the camber of the eye. ophthalmic lens and / or the camber of the spectacle frame. The spectacle frame being curved, the light rays coming from infinity (along an axis parallel to the axis of the pupil of the eye of the wearer) arrive on each lens with a non-zero incidence. Ophthalmic lenses having significant thicknesses, the light rays passing through the lens are deflected in the thickness of the glass. Moreover, the frame being curved, the report of the distances measured on the presentation glasses induces, as we have already explained, a shift between the radius that actually impacts the pupil's pupil and that which would have impacted his pupil if the frame had not been shapely. Thus, this method proposes to determine the optical paths of the light rays intended to impact the pupil of the wearer so as to know precisely the positions that the final contours on the ophthalmic lenses must occupy so that the latter are correctly centered with respect to the frame. Advantageously, the positioning comprises a correction of the relative or absolute position of a pupillary point associated with the eyeglass frame or an optical centering point of the ophthalmic lens, as a function of said at least one characteristic value of the camber of the eye. the eyeglass frame and / or the camber of the ophthalmic lens. By relative positioning of the pupillary point or the optical centering point is meant the positioning of one of these points relative to the other during the mapping of the reference frame of the ophthalmic lens with the reference frame of the spectacle frame. By absolute positioning of the pupil point is meant the positioning of the pupillary point relative to the reference frame of the frame, or in other words, the positioning of the pupillary point relative to the frame itself. The correction of the absolute position of the pupillary point thus causes a shift between its corrected position and its position determined by the optician. By absolute positioning of the optical centering point is meant the positioning of the optical centering point relative to the reference of the ophthalmic lens. The correction of the absolute position of the optical centering point thus causes a shift between its corrected position and the position of the point of the lens to be positioned opposite the eye of the wearer. According to a first embodiment of the centering method according to the invention, the positioning comprises the correction of the relative position of the pupillary point or the optical centering point, this correction consisting of an offset of the pupillary point relative to the optical centering point. , or conversely, according to said at least one characteristic value of the camber of the spectacle frame and / or the camber of the ophthalmic lens. Thus, in order to position the reference frame of the lens relative to that of the frame, the pupillary point is taken as a reference point of the reference frame of the frame and the optical centering point is taken as a reference point of the reference frame of the lens. The positioning of the repository is therefore achieved by the relative positioning of one of these points relative to the other. Two variants of this first embodiment of the invention can be implemented. It is possible either to directly calculate the position that the pupil point on the ophthalmic lens will have to occupy to take into account the camber of the frame and / or the camber of the lens and then to position the pupillary point on the lens according to this position. calculated to either superimpose conventionally the pupillary point and the optical centering point and then shift one of these points relative to the other to take into account the camber of the eyeglass frame and / or the camber of the ophthalmic lens. According to a second embodiment of the centering method according to the invention, the positioning comprises the correction of the absolute position of the pupillary point relative to the spectacle frame or the absolute position of the optical centering point with respect to the ophthalmic lens. according to said at least one characteristic value of the camber of the spectacle frame and / or the camber of the ophthalmic lens, and then the superimposition of the pupillary point and the optical centering point.

  Thus, according to this second embodiment of the invention, the optical centering point is first shifted relative to its normal position in the reference frame of the lens (as defined by an optical measurement of the lens or by the markings of the lens. the lens) or the pupillary point relative to its normal position in the frame reference frame (as measured on the wearer). In a second step, the pupil point on the optical centering point is conventionally superimposed. The offset of the optical centering point and / or the pupillary point makes it possible to take into account the camber of the spectacle frame and / or the camber of the ophthalmic lens.

  Other advantageous and nonlimiting features of the centering method according to the invention are the following: the correction of the absolute or relative position of the pupillary point or the optical centering point is carried out according to an offset vector which is a function of said at least one a characteristic value of the camber of the ophthalmic lens and / or the camber of the spectacle frame; the offset vector is parallel to a plane of tangency which passes through the optical centering point of the ophthalmic lens and which is tangent to the ophthalmic lens; the offset vector having a horizontal component and a vertical component, a characteristic angle of the camber of the spectacle frame is measured in the horizontal plane, and the horizontal component of the offset vector is calculated as a function of said characteristic angle; a characteristic angle of the camber of the spectacle frame and the ophthalmic lens is measured in the horizontal plane, and the horizontal component of the offset vector is calculated as a function of said characteristic angle; a characteristic angle of the camber of the spectacle frame is measured in the vertical plane, and the vertical component of the offset vector is calculated as a function of said characteristic angle; and - a characteristic angle of the camber of the spectacle frame and the ophthalmic lens is measured in the vertical plane, and the vertical component of the offset vector is calculated as a function of said characteristic angle.

  According to another advantageous characteristic of the method according to the invention, the positioning of the reference frame of the ophthalmic lens with respect to the reference frame of the spectacle frame is calculated as a function of more than the index of the material of the ophthalmic lens and the thickness of the ophthalmic lens at an optical centering point of the ophthalmic lens.

  The ophthalmic lens having a non-zero thickness, each light ray arriving on the front face of the lens with a non-zero incidence is deflected inside the lens according to the index of the material of the lens. This deviation induces a shift of the radius between its point of arrival on the front face of the lens and its point of exit on the rear face of the lens. This shift is therefore a function of the incidence and the thickness of the lens. According to this method, it is planned to calculate the length of the offset induced by these two characteristics of the lens in order to take it into account when positioning the final contour on the ophthalmic lens.

  Advantageously, the positioning of the reference frame of the ophthalmic lens relative to the reference frame of the eyeglass frame is calculated according to more prismatic deviations of the direction of gaze through the ophthalmic lens. An ophthalmic lens has optical faces inclined relative to each other almost at any point of the lens. Therefore, a light beam arriving on an ophthalmic lens with a first angle of incidence emerges from the latter with another angle of incidence, so that the light beam impacts the wearer's eye at a point offset from the point on which it would have impacted if the two optical faces of the lens had been parallel. This is why the method takes into account prismatic deviations by calculating the offset between these two points, in order to improve the accuracy of the centering of the lens on its frame. Advantageously, the method comprises providing an operator with at least one characteristic value of the positioning of the reference frame of the ophthalmic lens relative to the reference frame of the eyeglass frame, made as a function of said at least one characteristic value of the camber of the eyeglass. eyeglass frame and / or the camber of the ophthalmic lens, for a subsequent step of verifying the centering of the ophthalmic lens in the spectacle frame.

  If the device used to check the centering of the lens performs its verifications in the plane of tangency of the lens and not in the general plane of the frame, the offset corrected by the present method will not be taken into account during the step checking the centering of the ophthalmic lens in its mount. Specifically, the verification device will incorrectly indicate that a centering error has been made. Providing the optician with this characteristic value will enable him to verify that this centering error seen by the verification device corresponds to the correction made by this method.

  DETAILED DESCRIPTION OF AN EXEMPLARY EMBODIMENT The following description with reference to the accompanying drawings given by way of non-limiting examples, will make it clear what the invention consists of and how it can be achieved.

  In the accompanying drawings: - Figure 1 is a schematic front view of an ophthalmic lens not cut away; - Figure 2 is a schematic side view of a circled spectacle frame; - Figure 3 is a schematic sectional view along the plane A-A of the spectacle frame of Figure 2; FIG. 4 is a projection in the general plane of the frame of the outline of a circle of the spectacle frame of FIG. 2; FIG. 5 is a schematic view of detail of the zone V of FIG. 3 showing the ophthalmic lens of FIG. 1 traversed by a light beam; FIGS. 6 to 8 are detailed views of zone VI of FIG. 3 for three different types of ophthalmic lenses; and - Figure 9 is a schematic front view of a spectacle frame pierced.

  As a preliminary, it will be noted that, from one figure to another, the identical or similar elements of the different embodiments of the invention will, as far as possible, be referenced by the same reference signs and will not be described. Everytime. The objective of the centering method according to the invention is to determine the position that two ophthalmic lenses 10, namely a left ophthalmic lens and a right ophthalmic lens, must occupy on a spectacle frame 20 in order to be properly centered with respect to each other. eye pupils of the wearer, so that they perform properly the optical functions for which they were designed. The centering method used to center the left ophthalmic lens on the frame 20 will be described more precisely here. As shown in FIG. 1, it is concretely for the optician to define the position of the final contour 3, according to FIG. which should be cut off the ophthalmic lens 10, with respect to the optical reference of said lens (typically, its usual marks or its optical centering point CO). The implementation of the method finds a particularly advantageous application by the implementation, in a software integrated in a centering machine provided with a processing unit and a control screen, of a program capable of executing the steps of FIG. centering method described. According to a first embodiment of the invention, the spectacle frame 20 is of the rim type. Prior to the implementation of the centering method, the optician has the future wearer choose the shape of the frame 20 he desires. This choice is made among spectacle frames 20 that the optician possesses. Alternatively, this choice can be made in a database register. As shown more particularly in Figures 2 and 3, each spectacle frame 20 comprises two circles 23 each intended to receive one of the right and left ophthalmic lenses 10 whose optical powers are adapted to correct the vision defects of the wearer. These two circles 23 are connected to each other by a bridge or bridge 22. Each circle 23 is further provided with a branch 21. There is defined relative to the frame 20 a substantially horizontal plane H corresponding to the plane passing through the two branches 21 of the frame 20 when in the unfolded position. There is also defined a vertical plane S corresponding to the plane of symmetry of the mount 20. Finally, the general plane P of the frame 20 is defined as the plane passing through the top of the bridge 22 of the frame 20 and which is orthogonal, d firstly, at the vertical plane S of the frame 20, and secondly at the horizontal plane H of the frame 20. As a result of this choice of frame, the optician acquires the geometry of the inner contour of each of the circles 23 of the frame 20 by means of an edge reading device such as for example that described in US Patent 5,802,731. An example of such an apparatus is that marketed by Essilor International under the trademark Kappa or Kappa CT. The position of a horizon line of the frame is stored with the geometry of the inner contour of the circles 23 of the frame 20 to allow the identification of its angular orientation. The contour reading device also stores the position of the horizontal plane H relative to the geometry of the inner contour of each of the circles 23 of the frame 20. This position is for example entered by the operator who has previously measured it at Measuring instrument means as described in WO 9321819. Once this geometry acquired, the shape of the final contour 3 according to which the left ophthalmic lens 10 should be cut off is stored. As shown in FIG. 4, this shape corresponds to the projection of the geometry of the inner contour of the left circle 23 of the frame 20 in the general plane P. By convention, for the ophthalmic lens 10 is defined a box 11 called boxing which is known to those skilled in the art and which corresponds to the virtual rectangular frame circumscribing the final contour 3, each of whose four edges is tangent to the final contour 3 at least at a point P1, P2, P3, P4. The points P1 and P2 are the two points of the final contour 3 which are horizontally the furthest apart from each other. The points P3 and P4 are for their part the two points of the final contour 3 which are vertically the furthest apart from each other. As shown in FIGS. 2 and 3, four other points P1 ', P2', P3 ', P4' belonging to the bezel of the left circle 23 of the eyeglass frame 20 are also defined and whose projections in the general plane P are the four points P1, P2, P3, P4. The optician then proceeds to locate the position of the pupil point PP with respect to the final contour 3. This pupillary point PP corresponds to the point placed opposite the pupil of the eye of the wearer. The position of the pupillary point PP is more particularly 11. For this purpose, the optician equips the wearer of the frame 20 of the presentation glasses (which is identical to that which the wearer has chosen), then he manually points on each of the lenses of the presentation glasses. pupillary point PP corresponding to the point positioned opposite the pupil of the eye of the wearer. With reference to FIG. 4, in order to identify the position of the pupillary point PP with respect to the frame 11, the optician measures, using a rule, in the general plane P of the frame 20, two parameters related to the morphology of the carrier. It acquires the half-interpupillary gap Eg defined as the distance between the wearer's nose and his left pupil. He deduces the distance Eg 'corresponding to the distance horizontally separating the pupillary point PP from the point P2 of the frame 11. It also acquires the height h of the left pupil of the wearer by determining the distance vertically separating the pupillary point PP from the point P4 of the frame 11. The knowledge of these two parameters Eg ', h allows it to locate, for the left ophthalmic lens 10, the position of the final contour 3 relative to the pupillary point PP. It can also use a pupillometer to acquire with greater precision each pupillary half-distances of the wearer.

  Alternatively, the optician can perform this operation using a digital image acquisition and processing software as described in US 5617155A and ES 2043546 and realizing an identification of the pupil point PP from a digital photo of the wearer's face equipped with presentation glasses. The software thus directly acquires the position of the pupil point PP and the horizon line with respect to the frame 11 and the final contour 3. As shown in FIG. 1, the optician also has an ophthalmic lens 10 cut off, the geometries of the front faces 12 and rear 13 determine the optical correction power. The optical correction power of a corrective ophthalmic lens is defined by its spherical, cylindrical and prismatic refractive properties. Among these refractive properties, spherical optical power is first defined as the size which characterizes the magnifying effect of the lens. This power corresponds to the inverse of the focal length. The point of the lens where the magnifying effect is zero (that is, in the case of a lens having an exclusively spherical optical power, the point where e incident ray arriving perpendicularly to the lens and the ray transmitted have same axis) is called optical centering point CO. The cylindrical optical power is further defined as the magnitude which is intended to correct the astigmatism and which characterizes, to some extent, the effect of deformation of the image along an axis passing through the optical centering point CO, commonly known as the cylinder. Finally, the prismatic optical power is defined as the magnitude which characterizes the effect of deflection of the image. This deviation is achieved by the inclination of the front face 12 of the lens relative to its rear face 13 at the optical centering point CO. The ophthalmic lens 10 not cut off has an initial contour of known shape, generally circular, and an optical centering point CO of known position. The ophthalmic lens 10 not cut off is spotted in space by its optical centering point CC) and by a virtual registration line 4 for locating its angular position around its optical centering point CO. With reference to FIGS. 2 and 3, a tangency plane T is defined as the plane tangent to the front face 12 of the ophthalmic lens 10, at the optical centering point CO. The detection of the position of the optical centering point CO of the ophthalmic lens 10 (generally distinct from its geometric center) and that of its virtual registration line 4 may be performed by various techniques depending on the equipment available to the optician. . For example, this technique can be of the deflectometric, interferometric or image processing type. To this end, it is possible to use a device for automatically detecting the characteristics of an ophthalmic lens as described in US Pat. No. 6,888,626. An example of such an apparatus is that marketed by Essilor International under the trademark Kappa or Kappa CT. The technique used also makes it possible to determine the value of the optical powers of the lens and, in the case where its cylindrical optical power is non-zero, the orientation of its cylinder axis with respect to its virtual registration line. at this stage, the processing software has in memory the characteristics of the ophthalmic lens 10 not cut off (its initial contour, the position of its optical centering point CO and its virtual registration line 4, possibly with its optical powers and the angular orientation of the cylinder axis) as well as the characteristics of the final contour 3 (its shape, the position of the pupillary point PP with respect to the frame 11 and that of the horizon line). With reference to FIGS. 1 and 2, the optician also acquires characteristic values of the curvature of the frame 20 chosen by the wearer. To measure this curve, we define characteristic angles of this curve. The processing software can thus calculate the angle formed, in projection in the horizontal plane H, by the general plane P of the frame 20 and the straight line D1 passing through the two points P1 ', P2' of the bezel of the left circle 23 of 20. This Al-shaped curvature angle is characteristic of the curvature of the frame 20 in the horizontal plane H. This angle is more precisely calculated from data provided by the contour reading apparatus relating to the geometry read. of the inner contour of each of the circles 23 of the frame 20.

  In a variant. the treatment software can determine a characteristic angle not only of the curve of the frame 20 but also of the curve of the ophthalmic lens 10. The ophthalmic lens 10 has in fact a spherical front face 12 whose radius of curvature is known so that the The processing software can determine what will be the position of the tangency plane T of the ophthalmic lens 10 with respect to the spectacle frame 20, once the lens is mounted on the frame. The processing software can therefore calculate the angle that forms, in the horizontal plane H, the general plane P of the frame 20 with the plane of tangency T of the ophthalmic lens 10. This other curve angle A2 is characteristic of the curve of the frame 20 and the curve of the ophthalmic lens 10 in the horizontal plane H. Moreover, the processing software also determines a characteristic value of the camber of the frame 20 in the vertical plane S of the frame 20.

  To fit the shape of the wearer's face, the mount 20 is in fact generally inclined so that the line D2 passing through the two points P3 ', P4' of the bezel of the left circle 23 of the frame 20 is inclined relative to the plane General P of the mount 20. The processing software then determines the angle B1 that forms, in projection in the vertical plane S, this line D2 with the general plane P of the frame 20. This angle is commonly called pantoscopic angle B1; it is characteristic of the inclination of the frame 20 in the vertical plane S, that is to say with respect to the general plane P. Alternatively, the processing software can determine a characteristic angle not only of the curve of the frame 20 but also the curve of the ophthalmic lens 10, in the vertical plane S. The processing software can therefore calculate the angle B2 that forms, in the vertical plane S, the general plane P of the frame 20 with the plane of tangency T. This angle B2 is indeed characteristic of the curve of the frame 20 and the ophthalmic lens 10 in the vertical plane S.

  As a variant, these different angles can be entered manually by the optician if he knows them, or else read by the processing software in a database register, each record of which includes an identifier of a frame associated with the value of d. at least one of these characteristic angles of the camber of the frame and / or the camber of the ophthalmic lens.

  Anyway, the processing software then proceeds to the positioning of the reference of the ophthalmic lens 10 with respect to the frame of the spectacle frame 20. For this, it launches a step of superposition of the pupillary point PP, whose position is associated with that of the final contour 3, on the optical centering point CO of the ophthalmic lens 10. The implementation of this superposition is performed on the ophthalmic lens 10 not cut off, in its plane of tangency T, so as to position virtually the final contour 3 on the ophthalmic lens 10. This step is performed in the plane of tangency T because it corresponds to the plane in which the ophthalmic lens 10 is blocked. If the ophthalmic lens 10 not cut off has a zero cylindrical power, this positioning is carried out so that the horizon line of the final contour 3 is parallel to the registration line 4 of the ophthalmic lens 10 not cut off.

  On the other hand, if the ophthalmic lens 10 has a non-zero cylindrical optical power, this positioning is performed such that the orientation of the cylinder axis of the ophthalmic lens 10 relative to the horizon line of the final contour 3 corresponds to at the direction prescribed for the wearer. With reference to FIGS. 1 and 5, the curvature angle of the frame A1 and the pantoscopic angle B1 being known, the processing software initiates a step of determining an offset vector V which is a function of these two angles A1 , B1. This offset vector is intended to be used to shift the pupillary point PP, and therefore the final contour 3, with respect to the optical centering point CO. Indeed, the measurements of the position of the pupillary point PP relative to the final contour 3 were made in the general plane P of the frame 20, whereas the superposition of the pupillary point PP (associated with the final contour 3) with the centering point CO optic was made in the plane of tangency T of the ophthalmic lens 10. However, the frame 20 being curved, the general plane P of the frame 20 and the plane of tangency T of the ophthalmic lens 10 are intended, once the lens mounted in the frame 20, to be inclined relative to each other. To take account of this inclination, the processing software shifts the final contour 3 with respect to the optical centering point CO by shifting the pupillary point PP (which is therefore no longer intended to be arranged opposite the pupil of the eye of the wearer, contrary to the optical centering point CO). More precisely, as shown in FIG. 5, after having superimposed the optical centering point CO with the pupil point PP and reported the distance Eg 'and the height h in the plane of tangency T of the ophthalmic lens 10 to determine the position of the final contour 3, the processing software then shifts the pupillary point PP (and the final contour 3) according to the offset vector V. Thus, the light ray arriving from the infinite and impacting the pupil of the wearer corresponds, no longer to the radius luminous R2 passing through the pupillary point PP of the lens, but rather to the light ray R1 passing through the optical centering point CO. The offset vector V is parallel to the plane of tangency T. As shown in FIG. 1, it comprises a horizontal component V1, which is a function at least of the angle of curve of the frame Al, and a vertical component V2, a function at least of the pantoscopic angle B1.

  The processing software then calculates the horizontal component V1 of the offset vector V using the formula: V1 = Eg '. (1 / cos (A1) - 1) + VI ', V1' being the inaccuracy error in the determination of the horizontal component V1 of the offset vector V due to the assumptions made (such as the choice of the angle of curve of the mount Al to represent the camber of the mount). In the same way, the processing software calculates the vertical component V2 of the offset vector V using the formula: V2 = h. (1 / cos (B1) - 1) + V2 ', V2' being the inaccuracy error in the determination of the vertical component V2 of the offset vector V.

  In a second case in which it is desired to refine the accuracy of the determination of the offset vector V, the processing software can take into account the deviations which the gaze direction undergoes through the ophthalmic lens 10 taking into account the curvature angles. of the frame 20. More specifically, as shown in Figures 6 and 7, the processing software can also take into account the index n of the material of the ophthalmic lens 10 and its thickness E at the optical centering point CO. Taking into account these two characteristics n, E of the ophthalmic lens 10 is even more important that the frame is curved.

  According to Descartes' law, at the passage of an interface separating two media of distinct refractive indices (diopter), and under any incidence different from the normal incidence, the light ray will change direction and propagate so as to to form an angle to the normal plane of the diopter different from the angle of incidence of the ray of light in relation to the normal. However, as shown in Figure 5, the frame being curved, the light ray R1 from infinity arrives with a non-zero incidence on the ophthalmic lens, so that it is deflected in the thickness of the glass. As shown more precisely in FIG. 6, if the light beam R1 arrives with an angle of incidence C1 substantially equal to the curve angle of the frame Al, it enters the ophthalmic lens 10 with an angle C2 different from the This refraction causes the light ray R1 to be shifted by a distance D1, in the plane of tangency T. The processing software then calculates the distance D1 using the formula: D1! = E. [tan (Al) tan (C2)], and C2 = arcsin (sin Al / n). In the same way, he calculates D2 using the formula: 1D21 = E. [tan (B1) tan (F2)], with F2 = arcsin (sin B1 / n). It will be noted, as illustrated in FIG. 7, that the calculation of this distance D1 remains the same regardless of the prismatic optical power of the ophthalmic lens. Thus, the processing software performs a refined calculation of the horizontal component VI of the offset vector V using the formula: V1 = Eg '. (1 / cos (A1) - 1) - D1 + V1 ", V1" being the inaccuracy error in the determination of the horizontal component V1 of the offset vector V. In the same way, the processing software proceeds with a refined calculation of the vertical component V2 of the offset vector V using the formula: V2 = h. (1 / cos (B1) - 1) - D2 + V2 ", V2" being the inaccuracy error in the determination of the vertical component V2 of the offset vector V. With reference to FIG. 8, in a third case figure in which it is desired to determine the value of the offset vector with optimal precision, the processing software can consider in its calculations the prismatic deviations of the direction of gaze through the ophthalmic lens due to the fact that the front faces 12 and back 13 are not flat at the optical centering point CO. For this, the processing software determines, in the horizontal plane H, the angle R that forms the axis of the light ray R1 arriving on the lens with the axis of this same light ray R1 when it comes out of the lens, as well as the distance separating the eye from the wearer of the ophthalmic lens. These two values enable it to determine the offset of the light beam R1 in the horizontal plane H due to this prismatic deflection, and consequently the value of the new remaining error V1 "of the horizontal component V1 of the shift vector V. The software of processing also determines, in the vertical plane S, the angle formed by the axis of the light ray R1 arriving on the lens with the axis of the same light ray R1 when it comes out of the lens, as well as the distance separating the These two values enable it to determine the offset of the light beam RI in the vertical plane S due to this prismatic deflection, and consequently the value of the new remaining error V2 "of the vertical component V2 of the offset vector V. As shown in FIG. 1, knowing precisely then the two components V1, V2 of the shift vector V, the processing software proceeds, in the last Step, the offset of the position of the pupil point PP relative to the point of optical centering CO according to the offset V vector in the plane of tangency T of the lens. The final contour 3 also shifted is then correctly positioned on the lens so that the optical centering point CO is disposed, once the ophthalmic lens 10 mounted in the frame 20, facing the pupil of the eye of the wearer. The treatment software then supplies the optician, via the control screen, with characteristic values of the positioning of the reference frame of the lens relative to the reference frame of the frame, namely here the length and the orientation of the lens. offset vector V, in view of a subsequent step of verifying the centering of the ophthalmic lens 10 in the frame 20. In fact, if the device used to check the centering of the lens performs its verifications in the plane of tangency of the lens and not in the general plane of the frame, the offset corrected by the present method will not be taken into account during the step of checking the centering of the ophthalmic lens in its mount. More specifically, the verification device will indicate that a centering error has been made. Providing the optician with the offset vector will enable it to verify that this centering error seen by the verification device corresponds to the shift vector. According to an alternative embodiment of the invention, the processing software can characterize the shift vector. V in a repository no longer Cartesian but rather cylindrical. More precisely, it can determine its length and its angular position in the plane of tangency T of the ophthalmic lens. For this, it determines the position of the line which belongs to the plane of tangency T of the lens, which passes through the optical centering point CO, and which is intended to be the most inclined relative to the general plane P of the frame 20 With the offset vector V belonging to this straight line, it deduces the angular position of the shift vector V in the plane of tangency T. Then, according to calculations identical to the previous calculations, it determines the length of the shift vector V which has no more here only one component depending on the angle formed by said straight line with the general plane P of the frame 20. The present invention is not limited to the embodiments described and shown, but the skilled person will know bring any variant that fits his mind.

  As a variant of this first embodiment of the centering method according to the invention, the positioning of the reference frame of the ophthalmic lens 10 with respect to the reference frame of the spectacle frame 20 is achieved by means of a relative positioning of the associated pupillary point PP to the spectacle frame 20 with respect to the optical centering point CO of the ophthalmic lens 10.

  More specifically, the processing software proceeds, using calculations similar to those presented in the first embodiment, to the determination of the coordinates of the pupillary point PP in the reference frame of the ophthalmic lens 10 so that once mounted on the eyeglass frame 20, the optical centering point CO of the ophthalmic lens is directly positioned facing the pupil of the eye of the wearer, without requiring a step of shifting the pupillary point PP relative to the optical centering point CO . These analogous calculations are here also designed to take into account the deviations that the gaze direction undergoes through the ophthalmic lens 10 taking into account the characteristic values of the camber of the ophthalmic lens 10 and / or the camber of the spectacle frame. 20. According to a second embodiment of the centering method according to the invention, the processing software, after having proceeded to the determination of the characteristics of the ophthalmic lens 10, the spectacle frame 20, and the characteristic angles of their camber A1, A2, B1, B2, corrects the absolute position of the pupillary point PP relative to the final contour 3. To carry out this correction, it carries out the translation of the pupillary point according to the offset vector V from its initial position determined by the optician compared to the frame 11, to a new position with respect to the frame 11. Then, in a second step, the processing software realizes e conventionally the step of superposition of the optical centering point CO and the pupillary point PP, so that the final contour 3 is correctly placed on the ophthalmic lens 10 so that the latter can be cut in a contour taking into account the arching of the spectacle frame 20 and / or the camber of the ophthalmic lens 10. As a variant, the processing software can correct, not the absolute position of the pupil point PP with respect to the frame 11, but rather the absolute position of the point CO optical centering on the ophthalmic lens 10 by shifting it according to a vector of the same standard as the offset vector V but opposite direction. According to a third embodiment of the invention shown in FIG. 9, the spectacle frame 20 is of the pierced type. The frame 20 is therefore devoid of a circle, and the ophthalmic lenses 10 are intended to be pierced at attachment points 24 of the frame 20. These attachment points 24 are here eight in number. More specifically, each lens is intended to be pierced with two attachment points 24 of the bridge 22 located one above the other, and two attachment points 24 of one of the branches 21, also located on the outside. one above the other.

  A method of centering lenses on such a mount is described in detail in the French patent application FR 05 03326. According to this embodiment of the invention, the location of the pupillary point is determined, not in relation to the contour. end of the ophthalmic lens 10, but relative to a remarkable point corresponding here to one of the attachment points 24 of the frame 20. To do this, the optician determines the height hi of the pupillary point corresponding to the gap, according to the vertical plane S, between the pupillary point and the remarkable point chosen. The optician also determines the distance Eg1 corresponding to the difference, according to the horizontal plane H, between the pupillary point and the remarkable point chosen. The superimposition of the pupil point on the optical centering point CO of the ophthalmic lens 10, and the transfer of these distances hi, Eg1 from the optical centering point CO makes it possible to determine the initial position of the remarkable point on the ophthalmic lens 10 ( before its offset according to the offset vector). The measurement of the curve angle of the frame is also different. The processing software may for this purpose calculate the angle formed, in projection in the horizontal plane H, by the general plane P of the frame 20 and the line D3 passing through one of the attachment points 24 of the bridge 22 and one of the points 24 of one of the branches 21 of the frame 20. This mounting angle of the curve is characteristic of the curve of the frame 20 in the horizontal plane H. To determine the pantoscopic angle, the processing software can calculate the formed angle, in projection in the vertical plane S, by the general plane P of the frame 20 and the straight line D4 passing through the two attachment points 24 of the bridge 22 of the frame 20. Knowing the position of the remarkable point and the values of the angle of curvature of the frame and the pantoscopic angle, the processing software can calculate each of the components of the offset vector before proceeding to shift the remarkable point on the ophthalmic lens 10. Thus, once pierced in hook points e 24 whose positions are a function of the position of the remarkable point and that of the optical centering point, the lens can be mounted on the frame 20 so as to be properly positioned facing the pupil of the eye of the wearer to exercise at best the optical function for which it was designed.

Claims (15)

  1. A method of centering an ophthalmic lens (10) on an eyeglass frame (20), comprising positioning a reference frame of the ophthalmic lens (10) relative to a reference frame of the spectacle frame (20), characterized in that said positioning is performed as a function of at least one characteristic value (A1; A2, B1; B2) of the camber of the spectacle frame (20) and / or the camber of the ophthalmic lens (10) .   2. A method of centering according to the preceding claim, wherein said positioning is performed according to at least one characteristic value (A2, B2) of the camber of the ophthalmic lens (10) and the camber of the spectacle frame ( 20).   3. A method of centering according to one of the preceding claims, wherein said positioning is calculated to take into account the deviations that the direction of gaze through the ophthalmic lens (10), taking into account said at least one characteristic value. (Al A2, B1, B2) of the camber of the ophthalmic lens (10) and / or the camber of the spectacle frame (20).   4. Centering method according to one of the preceding claims, wherein said positioning comprises a correction of the relative or absolute position of a pupillary point (PP) associated with the spectacle frame (20) or a centering point. optical device (CO) of the ophthalmic lens (10), according to said at least one characteristic value (A1; A2, B1; B2) of the camber of the spectacle frame (20) and / or the camber of the lens ophthalmic (10).   5. Centering method according to the preceding claim, wherein said positioning comprises the correction of the relative position of the pupil point (PP) or the optical centering point (CO), this correction consisting of a shift of the pupillary point (PP) by to the optical centering point (CO), or vice versa, based on said at least one characteristic value (A1; A2, B1; B2) of the camber of the spectacle frame (20) and / or the camber of the ophthalmic lens (10).   6. Centering method according to claim 4, wherein said positioning comprises the correction of the absolute position of the pupillary point (PP) relative to the spectacle frame (20) or the absolute position of the optical centering point (CO). relative to the ophthalmic lens (10), depending on said at least one characteristic value (A1; A2, B1; B2) of the camber of the eyeglass frame (20) and / or the camber of the ophthalmic lens (10). ), then the superposition of the pupil point (PP) and the optical centering point (CO).   7. A method of centering according to one of the three preceding claims, wherein the correction of the relative or absolute position of the pupillary point (PP) or the optical centering point (CO) is performed according to an offset vector (V) function said at least one characteristic value (A1; A2, B1; B2) of the camber of the ophthalmic lens (10) and / or the camber of the spectacle frame (20).   8. A method of centering according to the preceding claim, wherein the offset vector (V) is parallel to a plane of tangency (T) which passes through the optical centering point (CO) of the ophthalmic lens (10) and which is tangent to the ophthalmic lens (10).   9. The method of centering according to one of the two preceding claims, wherein, the offset vector (V) having a horizontal component (VI) and a vertical component (V2), a characteristic angle (Al) of the camber is measured. of the spectacle frame (20) in a horizontal plane (H), and the horizontal component (V1) of the offset vector (V) is calculated as a function of said characteristic angle (A1).   10. A method of centering according to the preceding claim, wherein a characteristic angle (A2) of the camber of the spectacle frame (20) and the camber of the ophthalmic lens (10) is measured in the horizontal plane (H), and calculating the horizontal component (V1) of the offset vector (V) as a function of said characteristic angle (A2).   11. A method of centering according to one of the four preceding claims, wherein, the offset vector (V) having a horizontal component (V1) and a vertical component (V2), a characteristic angle (B1) of the camber is measured. of the spectacle frame (20) in the vertical plane (S), and the vertical component (V2) of the offset vector (V) is calculated as a function of said characteristic angle (B1).   12. A method of centering according to the preceding claim, wherein a characteristic angle (B2) of the camber of the spectacle frame (20) and the camber of the ophthalmic lens (10) is measured in the vertical plane (S). andcalculating the vertical component (V2) of the offset vector (V) as a function of said characteristic angle (B2).   13. Centering method according to one of the preceding claims, wherein the positioning of the reference of the ophthalmic lens (10) relative to the reference frame of the spectacle frame (20) is calculated according to more than the index (n ) the material of the ophthalmic lens (10) and the thickness (E) of the ophthalmic lens (10) at an optical centering point (CO) of the ophthalmic lens (10).   14. A method of centering according to one of the preceding claims, wherein the positioning of the reference of the ophthalmic lens (10) relative to the reference frame of the spectacle frame (20) is calculated according to more prismatic deviations of the direction look through the ophthalmic lens (10).   15. Centering method according to one of the preceding claims, comprising the provision to an operator of at least one characteristic value of the positioning of the reference frame of the ophthalmic lens (10) relative to the reference frame of the spectacle frame (20), performed according to said at least one characteristic value (A1; A2, B1; B2) of the camber of the spectacle frame (20) and / or the camber of the ophthalmic lens (10), in view of a step subsequent checking of the centering of the ophthalmic lens (10) in the spectacle frame (20).