FR2902033A1 - DEVICE AND METHOD FOR DETOURING A LENS COMPRISING THE VERIFICATION OF THE ADEQUACY OF A LOCKING ADAPTER OF SAID LENS WITH A CHARACTERISTIC OF THIS LENS OR ITS WISHED CONTOUR - Google Patents

Abstract

The present invention relates to a method of trimming an optical lens, comprising machining a lens (100) according to a desired contour (120) in accordance with a programmed machining cycle, the lens being held by at least one adapter blocking device (101, 102) applied to one side (108, 109) of said lens. Prior to this machining, at least one geometrical characteristic (115, 125) of the blocking adapter is acquired, and the adequacy of said acquired geometrical characteristic of the blocking adapter with the desired contour of the lens is checked. characteristic of the lens. The invention also relates to a device for implementing such a method.

Description

TECHNICAL FIELD TO WHICH THE INVENTION RELATES The present invention

  It relates generally to the mounting of ophthalmic lenses of a pair of corrective eyeglasses on a frame and more particularly to a device and a method of trimming a lens held by a locking adapter. BACKGROUND TECHNOLOGY The trimming of a lens, for mounting in or on the frame chosen by the future carrier, is to modify the contour of the lens to adapt it to this frame and / or the lens shape desired.

  Usually, the trimming of the lens is performed on a numerically controlled grinder which has means for holding and rotating the lens and several grinding wheels appropriate for the different operations to be performed. The lens is first locked on the holding and driving means in a known configuration so that its optical reference is known and operations can be performed accurately with reference to this reference. It is understood that this blocking, accompanied by the storage of the optical reference system, makes it possible to define and physically materialize on the lens a geometric reference system in which the points and directions characteristic of the lens, necessary for the coherence of this with the position of the pupil, as well as the clipping values so that these points and characteristic directions are properly positioned in the frame. The means for holding and rotating drive generally comprise means for supporting the lens and an adapter attached to the support means and applied to the face or faces of the lens to ensure its locking without slippage. There are several sizes of adapters and the adapter to be used is chosen according to the geometric characteristics (size and shape) of the final desired contour of the lens and the position of the adapter with respect to this contour, as well as depending on the characteristics of the machining cycle (in particular the torque exerted on the lens by the machining tool). However, in case of handling errors, the adapter placed on the lens may not correspond to the desired adapter to perform the intended machining cycle and obtain the desired contour.

  In particular, if the size of the adapter applied is greater than the size of the desired contour on at least a portion of this desired contour, the adapter will be machined by the machining tool. On the other hand, if the size of the adapter applied is smaller than the size of the adapter provided, the adapter may not be able to correctly rotate the lens and, because of the torque exerted on it by the machining tool, the lens may slip relative to the lens lock adapter. As a result, the centering of the lens, in particular the axis (that is to say, the angular orientation of the lens in the reference frame of the grinder) is then modified and the resulting contour of the lens is different. , relative to its optical reference, the desired final contour after clipping. OBJECT OF THE INVENTION The object of the present invention is to allow efficient, accurate and reliable clipping of lenses. For this purpose, there is provided according to the invention a method of trimming an optical lens, comprising machining a lens according to a desired contour in accordance with a programmed machining cycle, the lens being held by at least one adapter blocking device applied on one side of said lens, in which it is provided, prior to this machining: - an acquisition of at least one geometrical characteristic of the locking adapter, - a verification of the adequacy of said acquired geometric characteristic of the blocking adapter with at least one of the following parameters: the desired contour of the lens, a characteristic of the lens.

  The subject of the invention is also a device for trimming a lens comprising means for supporting the lens, means for machining the lens, means for relative transverse displacement of the lens relative to the machining means and electronic processing means adapted to drive the displacement means for trimming the lens according to a desired contour according to a programmed machining cycle, the support means comprising at least one lens locking adapter applied to a face of said lens, in which probing means are provided, with or without contact of the adapter and in which the electronic processing means are able to control these probing means so that they perform an acquisition of at least one characteristic geometric blocking adapter. Acquiring a geometric feature of the adapter determines the size and geometric configuration of the adapter relative to the lens. It is then possible to verify that the geometrical configuration of the adapter relative to the lens allows, on the one hand, the contouring according to the desired contour without machining the adapter and, on the other hand, the rotational drive of the lens without slip. This verification of the adequacy between the lens and the adapter makes it possible to achieve efficient, precise and reliable clipping of the lenses. According to a first advantageous characteristic of the invention, said verification of suitability comprises determining the radial extent of the locking adapter relative to the desired final contour of the lens. The determination of the radial extent makes it possible to know the diameter of the adapter and thus to verify, taking into account the position of the adapter with respect to the lens, that, on the one hand, the diameter of this adapter does not overflow not beyond the desired contour of the lens and, secondly, that this diameter is sufficient to ensure friction between the adapter and the lens adapted to drive the rotation of the lens without sliding.

  According to another advantageous characteristic of the invention, said verification of suitability comprises carrying out the test according to which, if the radial extent of the locking adapter exceeds a threshold of proximity of the desired final contour of the lens to at least part of this desired contour, the adapter is replaced by another of smaller radial extent.

  The taking into account of a threshold of proximity of the desired final contour makes it possible to ensure that, after the completion of a roughing blank, it is still possible to machine the edge of the lens in order to achieve a trimming finish such as beveling. for example, without machining the adapter. According to another advantageous characteristic of the invention, there is provided the conditional step according to which, if said adequacy check results in a negative result, at least one of the following operations is performed: replacement of the blocking adapter by another blocking adapter, modifying at least one characteristic of the machining cycle of the lens, trimming the lens, at least in part, by cutting in the material of said lens. According to another advantageous characteristic of the invention, there is provided the conditional step according to which, if said adequacy check results in a positive result, the lens is machined by grinding the edge of the lens, without replace the adapter or change the programmed machining cycle. According to another advantageous characteristic of the invention, said adequacy check comprises verifying the adequacy of said acquired geometric characteristic of the locking adapter with the wettability angle of the corresponding face of the lens. According to another advantageous characteristic of the invention, there is provided the conditional step according to which if said acquired geometric characteristic of the blocking adapter is not in adequacy with the angle of wettability of the lens, it replaces the blocking adapter by another larger radial expansion blocking adapter and / or modifying at least one characteristic of the machining cycle of the lens and / or the lens is trimmed at least in part by cutting in full matter of said lens. In the case where the wettability angle is too large relative to the diameter of the adapter to prevent slippage, the diameter of the adapter can be increased to increase the friction surface between the adapter and the lens. One can also play on the characteristics of the machining cycle such as the machining speed to limit the sliding of the lens. Finally, it is possible to use a cutting tool which, compared with a conventional tool for machining the edge of the lens, generates a much smaller torque on the lens. Indeed, the cutting tool is much smaller diameter than a machining tool such as a grinding wheel and the cutting tool is machining inside the lens which allows to quickly approach the desired contour with a minimum of energy dissipated between the cutting tool and the lens. According to another advantageous characteristic of the invention, there is provided the conditional step according to which if said acquired geometric characteristic of the locking adapter is in adequacy with the angle of wettability of the lens, machining of the lens by grinding the edge of the lens without replacing the adapter or changing the programmed machining cycle.

  In the case where the wettability angle is sufficiently small relative to the diameter of the adapter to prevent slippage of the lens, it can proceed directly to the machining of the lens by grinding with a risk of slippage of the limited lens .

  DETAILED DESCRIPTION OF AN EXEMPLARY EMBODIMENT The following description with reference to the accompanying drawings of several embodiments, given by way of non-limiting examples, will make it clear what the invention consists of and how it can be implemented. In the accompanying drawings: FIG. 1 is a perspective view of a device for trimming an optical lens provided with probing means; FIG. 2 is a side view of the optical lens clamped between two adapters and controlled probing means according to a first embodiment; FIG 3 is a side view of the optical lens clamped between two adapters and controlled probing means according to a second embodiment. In Figure 1 there is shown a digital trimming device 6 adapted to modify the contour of the ophthalmic lens to adapt to that of the frame or "circle" of a selected frame. This device comprises a flip-flop 611, which is freely pivotally mounted about a first axis A1, in practice a horizontal axis, on a frame. For the immobilization and the rotational drive of an ophthalmic lens to be machined, flip-flop 611 is equipped with support means able to clamp and rotate an ophthalmic lens 100. These support means, or holding means, comprise two 612, 613. These two shafts 612, 613 are aligned with each other along a second axis A2, called the locking pin, parallel to the first axis A1. The two shafts 612, 613 are rotated synchronously by a motor (not shown), via a common drive mechanism (not shown) embedded on the flip-flop 611. Each of the shafts 612, 613 has a free end facing the other and which is adapted to receive an adapter 101, 102 for locking the lens on the shaft 612, 613. In this case, the adapter 102 is adhered to the convex front face 108 of the lens 100 to materialize the lens. reference frame of the lens, before it is transferred to the trimming device 6. The other adapter 101 is applied to the concave rear face 109 of the lens 100 to hold the lens tight between the two adapters 101, 102 and allow it to be rotated without slip. The shaft 613 is movable in translation along the blocking axis A2, opposite the other shaft 612, to effect clamping in axial compression of the lens between the two blocking adapters. The shaft 613 is controlled for this axial translation by a drive motor via an actuating mechanism (not shown). The other shaft 612 is fixed in translation along the blocking axis A2. The trimming device 6 comprises a grinder 610 which comprises a train of several grinding wheels 614 mounted coaxially on the third axis A3, for roughing and finish of the edging of the ophthalmic lens 100 to be machined. These different grinding wheels are each adapted to the material of the cut-out lens and the type of operation performed (roughing, finishing, mineral or synthetic material, etc.). The grinding wheel is attached to a common shaft of axis A3 ensuring their rotational drive during the edging operation. This common shaft, which is not visible in the figures shown, is rotated by an electric motor 620. The wheel train 614 is also movable in translation along the axis A3 and is controlled in this translation by a motorization driven. Concretely, the entire wheel train 614, its shaft and its motor is carried by a carriage 621 which is itself mounted on slides 622 secured to the frame for sliding along the third axis A3. The translational movement of the wheel trolley 621 is referred to as transfer and is denoted TRA in FIG. 1. This transfer is controlled by a motorized drive mechanism (not shown), such as a screw and nut or rack system. In order to allow a dynamic adjustment of the distance between the axis A3 of the grinding wheels 614 and the axis A2 of the lens during the edging, the pivoting capacity of the lever 611 around the axis A1 is used. effect a displacement, here substantially vertical, of the lens 100 sandwiched between the shafts 612, 613 which brings the lens closer to or away from the grinding wheels 614. This mobility, which makes it possible to restore the form of trimming (or trimming) desired and programmed in a system electronic and computer, is called restitution and is noted RES. The trimming device 6 comprises an electronic and computer processing unit 199, for controlling the various members, here consisting of an electronic card designed to control in coordination the different mobilities of the working tools and the clamping and rotating drive means. of the lens in accordance with the automated trimming method to be discussed later. The electronic and computer system 199 comprises for example conventionally a motherboard, a microprocessor, a random access memory and a permanent mass memory. The mass memory contains a program for executing, on the one hand, the machining cycle of each lens according to the desired final contour, and, on the other hand, the verification method which will be described later. This mass memory is preferably rewritable and is advantageously removable to allow its rapid replacement or programming on a remote computer via a standard standard interface. There are also means for memorizing the desired final contour 120 of the lens, a user interface (for example a keyboard and a screen), means of communication with another local or remote device, such as a centering device, an outline reading device or a microcomputer executing software for assisting the trade of the optician or optometrist. For the machining of the ophthalmic lens 100 following a given contour, the restitution movement RES of the flip-flop 611 and the rotational movement ROT of the lens support shafts 613, 612 are controlled in coordination by the electronic and computer system 199 , duly programmed for this purpose, so that all the points of the contour of the ophthalmic lens 100 are successively brought back to the right radius. For its mechanical interfacing with the shafts 613, 612 of the trimming means 6, each locking adapter 101, 102 cooperates with the free end 616, 615 of the corresponding shaft 613, 612, by a male part interlocking system. and complementary female performing, by form cooperation, a rotation drive without play. As shown in Figures 2 and 3, each locking adapter 101, 102 comprises, on the one hand, a sleeve 113, 123 adapted to cooperate with the free end 616, 615 of the shaft 613, 612 with which it is associated and, secondly, a bearing washer 114, 124 having a front face 111, 121 applied to the lens 100 and a rear face 112, 122 opposite. The bearing washer 114, 124 of each adapter has a diameter substantially greater than that of its sleeve 113, 123 and thus has an overflow portion or flange. The washer 114, 124 of each adapter 101, 102 is elastically deformable to conform to the shape of the corresponding face of the lens 100 under the effect of an axial clamping force. Such axial clamping force is applied together with the two adapters 101, 102, in opposition, by the trees 613, 612 at the time of their approximation for the final locking of the lens on said shafts. The trimming device 6 also comprises probing means 900. These probing means 900 comprise two scanning legs 90 and 91 which are substantially rectilinear and which each end with a free angled end forming a probing nose 92, 93. The two beaks 92, 93 of the two branches 90, 91 point towards each other. On each of the two nozzles 92 and 93 are mounted mechanical feelers known in themselves, operating by simple mechanical contact. One and / or the other of the two branches 90 and 91, in this case the two branches 90 and 91 are movable in translation along an axis parallel to the axis A2 of the shafts 612, 613. This translation makes it possible to the branches 90, 91 are respectively controlled independently of one another by electric motors (not shown). The two branches 90 and 91 are also movable transversely to the axis A2 axis of the shafts 612, 613 relative to said shafts 612, 613. There is also provided a cutting tool 637 for making a blank of the clipping by cutting in full matter of the lens 100 (see Figure 1). Cutting in full material consists of penetrating the entire diameter of the tool into the lens and moving the tool in the lens along a cutting path to obtain the desired cut. The cutting in full matter is distinguished from the machining of the edge of the lens in the sense that, according to the latter, only a small part of the diameter of the machining tool is engaged in the material of the edge of the lens and the whole material, located between the periphery (or edge) raw lens and the outline of draft to be machined. The cutting tool is here a milling cutter, or cutter, axis A6 substantially parallel to the axis A2 of the shafts 612, 613 (that is to say, the axis of the lens). Alternatively, this cutting tool may be constituted by a drill or a grinding wheel, smaller in diameter than the grinding wheel or roughing cutter, or a laser beam. It can also be considered that the diameter of the cutter 637 is on average from 1 to 6% of the radius of the lens 100 (which is typically of the order of 70 mm). The positioning of the cutting cutter is achieved by means of two pre-existing degrees of mobility which are the retraction on the one hand and the transfer TRA on the other hand. Once positioned, the cutter 637 is then moved transversely to the axis of the lens 100 to obtain the desired cutting contour. The electronic and computer system 199 also comprises means for verifying the adequacy between, on the one hand, the lens 100 or the desired contour of this lens and, on the other hand, at least one of the blocking adapters 101, 102. the lens 100.

  The electronic and computer system 199 also comprises selection means for selecting, depending on the result of the adequacy check, either a tool for machining the edge of the lens 100 such as a wheel of the wheel set 614, or the cutting tool 637 of the lens 100, for at least one given clipping operation.

  The fit check operation is described below. The lens 100 is previously centered (to locate its reference) and held between two blocking adapters 101, 102 and then placed on the shafts 612, 613 as described above. According to a first embodiment shown in FIG. 2, the match between the lens 100 and a single adapter is checked. This embodiment is preferably applied in the case where the adapters are arranged in pairs and where a handling error envisaged relates to one pair of adapters with respect to another pair of adapters, and not each adapter taken individually. This first embodiment also applies to the case where the lens is held and driven in rotation by only one adapter, on one of its faces, its other face being left free or receiving the support of a standard adapter small diameter not risking any machining conflict and little or no participation in frictional retention of the lens.

  The acquisition of at least one geometric characteristic 125 of the adapter 102 is then performed. Here the acquisition is carried out by the probing means 91, 93. The acquired geometric characteristic of the blocking adapter 102 is at least one part of the outer contour 125 of the rear face 122 of the washer 124 of the locking adapter 102, that is to say the joining edge between the side face and the rear face of the adapter. The probing of the edge 125 of the adapter 102 is carried out by bringing the probing means 93 against the rear face 122 of the washer 124 of the locking adapter 102 and then moving the feeler means 93 in sliding relative to the to the blocking axis A2 of the lens until it escapes from the rear face 122 of the locking adapter 102. The escape position is then stored. This probing operation, possibly repeated on several radii, makes it possible to determine the edge 125 of desired junction. The geometrical configuration of the blocking adapter 102 is then determined from the junction edge 125 of the blocking adapter 102 and its radial extent is determined relative to the desired final contour 120 of the lens 100. position of the locking pin of the lens, that is to say the position of the adapter, relative to the desired contour, is taken into account. The radial extent of the blocking adapter is then compared to a threshold of proximity of the desired final contour, for example 1 mm. This ensures that the adapter is positioned more than 1 mm from the desired final contour. Taking into account a threshold of proximity of the desired final contour makes it possible to ensure that the blocking adapter 102 is not machined. In the case where the adapter 102 for locking extends transversely to the A2 axis beyond the threshold of proximity of the desired contour 120 of the lens, on at least a portion of this desired contour 120, the electronic processing system and computer 199 diagnostics an error (the result of the adequacy check is negative) and prompt to replace the adapter with another of smaller diameter.

  The adequacy between the lens 100 and the blocking adapter 102 is also verified by verifying that the diameter of the blocking adapter 102 is adapted to the wettability angle of the corresponding face 108 of the lens to limit the sliding of the lens. The lens. By considering a drop of water present on the face of the lens concerned, the wettability angle is defined as the angle formed between, on the one hand, the plane tangent to the surface of the water droplet. a point of contact of this surface with the lens and, secondly, the plane tangent to the surface of the face of the lens at said point of contact with the surface of the drop of water. The larger this angle is, the lower the surface energy and therefore the more the lens will tend to slide during its machining. This verification can be performed from curves or charts obtained empirically. In the case where the diameter of the planned blocking adapter is too small relative to the wettability angle to prevent slippage of the lens, the result of the fit check is negative and the electronic and computer processing system 199 prompts the operator, via the display screen of the trimming device, to replace the blocking adapter with another larger diameter blocking adapter, and / or to modify the machining cycle of the lens in such a manner as to to reduce the force torque exerted on the lens, and / or to change the type of machining tool.

  The modification of the machining cycle of the lens to reduce the force torque exerted on the lens consists, for example, in reducing the machining speed. When the computer and electronic processing system 199 invites to change the type of machining tool, he proposes to proceed to cutting in full material of the lens by means of the cutting tool 637, the operator having to confirm the choice 637 cutting tool or cancel it. It can also be provided that the computer and electronic processing system 199 directly selects the cutting tool 637 without asking for confirmation. Once the cutting tool has been selected, the roughing of the lens is carried out according to a cutting contour whose shape corresponds to the desired final contour, but of slightly larger size. During cutting, the electronic processing system controls, in appropriate coordination, the transfer mobilities TRA and the retraction of the cutting tool 637, the restitution RES of the clamping shafts and the rotational drive 612, 613 and rotational shafts ROT of the lens to obtain the mobilities of the cutting tool with respect to the lens necessary for the realization of the cutting of the lens. The finishing is then carried out by grinding on a finishing wheel of the wheel set 614. The transfer mobilities TRA of the finishing wheel and the restitution mobilities RES and ROT of rotation of the lens are controlled so as to reach the desired final contour by removing the small amount of material between the blank contour obtained by cutting in full material and the desired final contour. The grain of the finishing wheel being fine, the desired final contour is reached precisely. As a variant, it is also possible to cut the lens directly according to the desired final contour if the cutting tool is sufficiently precise. When the electronic and computer processing system 199 prompts to change the diameter of the adapter and once the new adapter is applied to the lens, the verification process is performed again to ensure that there has been no change in the diameter of the adapter. handling errors and that the new adapter is large enough to allow rotation of the lens and to prevent the lens from sliding relative to said adapter. Once the match between the adapter and the validated lens, the lens is trimmed according to the desired final contour.

  For a positive result of the adequacy check, ie if the geometric configuration of the blocking adapter is in adequacy with the desired contour of the lens and the angle of wettability of the lens, then proceed directly to the machining of the lens by grinding with a risk of slipping of the limited lens and without machining the locking adapter. In this case it is not necessary to perform a cutting step in full material of the lens. According to another embodiment, shown in FIG. 3, said acquisition and said verification of the match between the lens 100 and the locking adapter are carried out for the two blocking adapters 101, 102. This is done by simultaneously probing the two adapters 101, 102 in a manner analogous to the probing method described above with reference to FIG. 2. The electronic processing unit controls the two probing branches 90, 91 to sliding the probes 92, 93 against the rear faces 112, 122 of the washers 114, 124 of the adapters 101, 102 transversely to the locking axis A2 of the lens until they escape at the edge 115, 125 The escape position is then memorized. The operation, possibly repeated on several shelves of the washers 114, 124, makes it possible to determine the position of the edge 115, 125 with respect to the lens. From this measurement, the electronic processing unit carries out, for the two adapters, the aforementioned adequacy checks. The present invention is not limited to the embodiments described and shown, but the skilled person will be able to make any variant within his mind.

  As a variant, the acquisition of the geometrical characteristic of the blocking adapter may not be performed by physical probing of the adapter or adapters, but may be performed remotely (without contact) by optical recognition of the geometric characteristics of the adapter or adapters. Whatever the embodiment described above or one of these variants, the adapter may be a locking tassel having an adhesive layer applied to one side of the lens. At least a portion of a geometric characteristic of this glans is then acquired. It can also be provided that the adapter applied to a lens face comprises a first adapter and an acorn, the glans being directly applied to one side of the lens and fitted into the first adapter and that the adapter applied to the other Lens face has only one adapter.

Claims (11)

  A method of trimming an optical lens, comprising machining a lens (100) in a desired contour (120) in accordance with a programmed machining cycle, the lens being held by at least one locking adapter ( 101, 102) applied on one face (108, 109) of said lens (100), characterized in that it comprises, prior to this machining: - an acquisition of at least one geometric characteristic (115, 125) of the blocking adapter (101, 102), - checking the adequacy of said acquired geometric characteristic of the blocking adapter (101, 102) with at least one of the following parameters: the desired contour (120) of the lens, a feature of the lens (100).   2. Method according to the preceding claim, wherein said verification of adequacy comprises determining the radial extent of the locking adapter (101, 102) relative to the desired final contour (120) of the lens (100). .   3. Method according to the preceding claim, wherein said verification of adequacy comprises carrying out the test according to which if the radial extent of the locking adapter (101, 102) exceeds a threshold of proximity of the final contour (120). of the lens (100) on at least a portion of this desired contour (120), the adapter is replaced by another of smaller radial extent.   4. Method according to one of the preceding claims, comprising the conditional step according to which, if said adequacy check results in a negative result, at least one of the following operations is performed: replacement of the blocking adapter ( 101, 102) by another locking adapter, modifying at least one characteristic of the machining cycle of the lens, at least partially trimming the lens by cutting in the material of said lens.   5. Method according to one of the preceding claims, comprising the conditional step according to which, if said adequacy check results in a positive result, the lens is machined by grinding the edge of the lens, without replacing the adapter or modify the programmed machining cycle.   The method according to one of the preceding claims, wherein said adequacy checking comprises verifying the adequacy of said acquired geometric feature of the locking adapter (101, 102) with the wettability angle of the face. corresponding lens (100).   7. Method according to the preceding claim, comprising the conditional step according to which if said acquired geometric characteristic of the locking adapter (101, 102) is not in adequacy with the wettability angle of the lens (100), replacing the blocking adapter (101, 102) with another larger radial extent blocking adapter and / or modifying at least one characteristic of the machining cycle of the lens and / or trimming of the lens, at least in part, by cutting in the material of said lens.   8. Method according to one of the two preceding claims, comprising the conditional step according to which said acquired geometric characteristic of the locking adapter (101, 102) is in adequacy with the angle of wettability of the lens (100). the lens is machined by grinding the edge of the lens without replacing the adapter or modifying the programmed machining cycle.   The method according to one of the preceding claims, wherein said adequacy checking comprises verifying the adequacy of said acquired geometric feature of the blocking adapter (101, 102) with the programmed machining cycle.   10. Device for trimming a lens (100), comprising lens support means (612, 613), lens machining means, relative transverse displacement means of the lens relative to the lens means. machining and electronic processing means able to control the moving means for trimming the lens according to a desired contour (120) according to a programmed machining cycle, the support means comprising at least one locking adapter (101) 102) of the lens (100) applied to one face (108, 109) of said lens (100), characterized in that it comprises probing means (92, 93) with or without contact of the adapter and in that the electronic processing means are able to control these probing means so that they perform an acquisition of at least one geometrical characteristic (115, 125) of the locking adapter (101, 102).   11. Device according to the preceding claim, wherein the electronic processing means are adapted to perform calculation instructions adapted to verify the adequacy of said acquired geometric feature of the locking adapter (101, 102) with one to the least of the following parameters: the desired contour (120) of the lens, the programmed machining cycle, a characteristic of the lens (100).