Method for controlling a manufacturing device used in an optical lens manufacturing process

Abstract

A method for controlling a manufacturing device used in an optical lens manufacturing process. The method including providing optical lens data, the optical lens data representing the nominal and effective values of at least one optical lens parameter of an optical lens manufactured according to a manufacturing process using a manufacturing device, providing manufacturing data identifying at least the manufacturing device used to manufacture the optical lens, determining the difference between the nominal and effective values of the at least one optical lens parameter of the optical lens, determining a recommended value of a manufacturing parameter of the manufacturing device identified by the manufacturing data, the recommended value of the manufacturing parameter being determined based on the difference between the nominal and effective values of the at least one optical lens parameter.

Claims

1. A method implemented by processing circuitry for controlling a manufacturing device used in an optical lens manufacturing process, the method comprising the following steps: an optical lens data providing step, during which optical lens data is provided, the optical lens data represents the nominal and effective values of at least one optical lens parameter of an optical lens manufactured according to a manufacturing process using a manufacturing device, the optical lens being adapted for a wearer; a manufacturing data providing step during which manufacturing data identifying at least the manufacturing device used to manufacture the optical lens is provided, the manufacturing data further comprising a value of at least one manufacturing parameter of the manufacturing device; a difference determining step during which the difference between the nominal and effective values of the at least one optical lens parameter of the optical lens is determined; a manufacturing device parameter determining step during which a recommended value of the at least one manufacturing parameter of the manufacturing device identified by the manufacturing data is determined, the recommended value of the at least one manufacturing parameter is determined based on the difference between the nominal and effective values of the at least one optical lens parameter; a recording step during which the value of the at least one manufacturing parameter and the difference between the nominal and effective values of the at least one optical lens parameter of the corresponding optical lens are recorded; a relating step during which the different values of the at least one manufacturing parameter are related to the differences between the nominal and effective values of the at least one optical lens parameter of the corresponding optical lenses; and a transmitting step during which the recommended value of the at least one manufacturing parameter is transmitted to the manufacturing device to adjust the at least one manufacturing parameter to the recommended value.

2. The method according to claim 1, wherein the optical lens is manufactured at a manufacturing side and the method for controlling the manufacturing device is implemented at a controlling side, the controlling side being remote from the manufacturing side.

3. The method according to claim 1, wherein the at least one optical lens parameter is an optical and/or geometrical parameter of the optical lens and/or the weight of the optical lens.

4. The method according to claim 1, wherein the optical lens is a progressive addition lens and wherein the at least one optical lens parameter is an optical and/or a geometrical parameter in the far and/or the near vision zone.

5. The method according to claim 1, wherein the optical lens parameter is measured using a foccimeter.

6. The method according to claim 1, wherein the optical lens parameter is measured using an optical mapping device.

7. The method according to claim 1, wherein the optical lens parameter is obtained by using an image of a specific pattern through the optical lens.

8. The method according to claim 1, wherein the manufacturing device is selected in the list consisting of surfacing devices, polishing devices, edging devices, molding devices, additive manufacturing devices, blocking devices, and mounting devices.

9. A method of manufacturing an optical lens using at least one manufacturing device, wherein the method of manufacturing is remotely controlled by the method according to claim 1.

10. A non-transitory computer readable medium including computer executable instructions, wherein the instructions, when executed by a computer, cause the computer to perform a method for controlling a manufacturing device used in an optical lens manufacturing process, the method comprising: providing optical lens data, the optical lens data representing the nominal and effective values of at least one optical lens parameter of an optical lens manufactured according to a manufacturing process using a manufacturing device, the optical lens being adapted for a wearer; providing manufacturing data identifying at least the manufacturing device used to manufacture the optical lens, the manufacturing data further comprising a value of at least one manufacturing parameter of the manufacturing device; determining the difference between the nominal and effective values of the at least one optical lens parameter of the optical lens; determining a recommended value of a manufacturing parameter of the manufacturing device identified by the manufacturing data, the recommended value of the manufacturing parameter being determined based on the difference between the nominal and effective values of the at least one optical lens parameter; recording the value of the at least one manufacturing parameter and the difference between the nominal and effective values of the at least one optical lens parameter of the corresponding optical lens; relating the different values of the at least one manufacturing parameter to the differences between the nominal and effective values of the at least one optical lens parameter of the corresponding optical lenses; and transmitting the recommended value of the at least one manufacturing parameter to the manufacturing device to adjust the at least one manufacturing parameter to the recommended value.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

(1) Non limiting embodiments of the invention will now be described with reference to the accompanying drawings in which:

(2) FIG. 1 is flowchart representing the steps of a method according to an embodiments of the invention,

(3) FIG. 2 represents a system implementing the method according to the invention.

DETAILED DESCRIPTION OF THE DRAWINGS

(4) According to an embodiment of the invention illustrated on FIG. 1, the method for controlling a manufacturing device used in an optical lens manufacturing process comprises: an optical lens data providing step S1, a manufacturing data providing step S2, a difference determining step S3, and a manufacturing device parameter determining step S4.

(5) The manufacturing device controlled by the method of the invention, can be of any type that is used in the manufacturing process of an optical lens. For example the manufacturing device may be one or a plurality of devices selected in the list consisting of surfacing devices, polishing devices, edging devices, molding devices, additive manufacturing devices, blocking devices. The method according to the invention may also be used to control mounting devices.

(6) Although, the whole method of the invention may be implemented at the lens manufacturer side, according to an embodiment of the invention the method of the invention is a remote control method in the sense that it involves a controlling step carried out in a different place than the manufacturer side.

(7) In other words, according to an embodiment of the invention, the optical lens is manufactured at a manufacturing side whereas the method for controlling the manufacturing device is implemented at a controlling side, the controlling side being remote from the manufacturing side.

(8) Advantageously, such embodiment of the invention allows a centralized control of different manufacturing devices, thus reducing the need of quality control expertise at the manufacturer side and an increase expertise at the controlling side that may collect data from different manufacturing sides. Therefore, the overall cost of the manufacturing process may be reduced while increasing the quality of the control of the manufacturing devices and of the manufactured optical lenses.

(9) In the following detailed description of the invention, the method of the invention is described as a remote control method although such method could be implemented at the manufacturer side.

(10) As illustrated on FIG. 2, an optical lens is manufactured using a manufacturing device 12 at a lens manufacturer side 10.

(11) During the optical lens data providing step S1, optical lens data is provided to the manufacturing device.

(12) The optical lens data represents the nominal and effective values of at least one optical lens parameter of an optical lens manufactured according to a manufacturing process using a manufacturing device.

(13) The optical lens parameter can be an optical and/or geometrical and/or the weight of the optical lens.

(14) In the following, one finds non-limiting examples of such geometrical parameter: local height (z), local curvature, local sphere value, local cylinder, local cylinder axis, local thickness , local prism, . . . , as a minimum value, maximum value or mean value over the whole surface, or as a local derivation (slope, gradient, . . . );

(15) In the following, one finds non-limiting examples of such optical parameter: local ray deviation, local power, local astigmatism, astigmatism axis orientation, un local magnification (evaluated from a foccimeter or by a wearer . . . ), as a minimum value, maximum value or mean value over the whole surface, or as a local derivation (slope, gradient, . . . ).

(16) The effective value of the optical lens parameter can be measured at the manufacturing side 10 using measuring means 14.

(17) Such measurement can be done directly by using measuring means such as a foccimeter or an optical mapping device for optical parameters.

(18) The geometrical parameters can be measured using any type of surface measuring means such as mechanical sensors.

(19) The weight of the optical lens may be measured by using a scale.

(20) The effective value of the optical lens parameter may be deduces from an indirect measure. For example, an image of a specific pattern trough the manufactured optical lens may be provided. From the deformation of the image of a specific pattern trough the manufactured optical lens it is possible to determine the effective value of some parameters of the manufactured optical lens.

(21) The nominal value of the optical parameter corresponds to the target value of the optical lens parameter. Such value corresponds to the desired value for such parameter.

(22) During the manufacturing data providing step manufacturing data identifying at least the manufacturing device used to manufacture the optical lens is provided.

(23) The manufacturing data may identify the manufacturing device itself or may provide a reference of the type of manufacturing device. Advantageously, more precisely the manufacturing device is identified the more relevant and accurate the method of the invention may be.

(24) According to an embodiment, the effective value and the manufacturing data may be sent directly to the controlling side 22.

(25) According to an alternative embodiment of the invention, the manufacturing data and the effective value of the optical lens parameter may be sent to a remote storing entity 20 together with an identifier of the manufactured lens.

(26) According to a further embodiment, the effective value of the optical lens parameter is determined at the controlling side. The manufacturing side sends either to the remote storing entity or to the controlling side data relating to measurements carried out on the optical lens. For example, the manufacturing side may send a picture of one of the surfaces of the optical lens in specific conditions. The value of the effective optical parameter may be determined from such picture at the controlling side.

(27) The nominal value of the optical lens parameter may be sent from the manufacturing side directly to the controlling side or via the remote storing entity, for example, in response to a data request including the identifier.

(28) According to an alternative embodiment, the controlling side may receive the nominal value directly from an optical lens designer or may be the lens designer himself.

(29) During the difference determining step S3, the difference between the nominal and effective values of the optical lens parameter is determined. The difference determining step is preferably carried out at the controlling side 22.

(30) During the manufacturing device parameter determining step S4, a recommended value of at least one manufacturing parameter of the manufacturing device identified by the manufacturing data is determined.

(31) The recommended value of the manufacturing parameter is determined based on the difference between the nominal and effective value of the optical lens parameter. The recommended value is specific to the manufacturing device used for manufacturing the lens. Therefore, the more precisely the manufacturing device is identified by the manufacturing data the more accurate the recommended value may be.

(32) To determine a recommended value, the controller at the controlling side 22 may use a database 24 of differences between the nominal and effective values of the optical lens parameter and there relation with manufacturing parameters.

(33) For example, the wear of the polishing tool used in the optical lens manufacturing process can be detected by controlling an image of the manufactured surface of the optical lens with an arc lamp. Indeed, signs of the machining tool observed on the surface using an arc lamp can be related to the need of changing the polishing tool.

(34) In such case, although the manufactured optical lens may fulfill the standard quality requirements, the controlling side could recommend changing the polishing tool. Therefore, avoiding that further optical lens manufactured using the same polishing device would not fulfill the standard quality requirements.

(35) According to a further example, the wear of the machining tool used in the optical lens manufacturing process can be detected by controlling the image of the manufactured surface of the optical lens with an arc lamp. Indeed, dark rings can be observed on the surface using an arc lamp when the machining tool is starting to wear out.

(36) In such case, although the optical lens may fulfill the standard quality requirements, the controlling side could recommend changing the machining tool. Therefore, avoiding that further optical lens manufactured using the same machining device would not fulfill the standard quality requirements.

(37) According to a further example, a deviation of the temperature of the polishing bath can be detected by controlling the polished surface. If said temperature is too high or too low, it generates either a lack of polishing or an over-polishing causing an undesired deformation of the surface.

(38) In such case, although the optical lens may fulfill the standard quality requirements, the controlling side could recommend checking the temperature of the polishing bath used in polishing operation.

(39) According to an embodiment of the invention, the controlling side recommendation can comprise different level of recommendation. Such level of recommendation may provide an indication of the percentage of risk that further optical lenses manufactured by such device would not fulfill the standard quality. Such level of recommendation may be determined based on the difference between the effective and nominal value of the optical lens parameter and on the complexity indication of the surface of the manufactured optical lens.

(40) According to an embodiment of the invention, the manufacturing data further comprises the value of at least one manufacturing parameter of the manufacturing device and the method further comprises: a recording step, and a relating step.

(41) During the recording step the value of the at least one manufacturing parameter and the difference between the nominal and effective values of the at least one optical lens parameter of the corresponding optical lens are recorded.

(42) During the relating step, the different values of the manufacturing parameter are related to the differences between the nominal and effective values of the at least one optical lens parameter of the corresponding optical lenses.

(43) Advantageously, such embodiment allows determining links between optical parameters and manufacturing device parameter. Furthermore, such embodiment allows determining a drift of a parameter of the manufacturing device. Indeed, a drift in the difference between the effective and nominal value of the optical lens parameter is an indication of the drift of at least one manufacturing parameter from its nominal value. Upon detection of such drift the controlling side may inform the manufacturing side that an action is to be carried out to correct the manufacturing parameters.

(44) As illustrated on FIG. 1, the method according to the invention may comprise a feedback step S5 during which the recommended value of the manufacturing parameter is sent to the manufacturing side.

(45) The invention has been described above with the aid of embodiments without limitation of the general inventive concept.

(46) While in the embodiments described in detail the method of controlling is carried out remotely, the method may be carried out at the manufacturing side.

(47) Furthermore, while in the detail description the controlling side controls one manufacturing side, the method according to the invention allows a controlling side to control a plurality of manufacturing sides. The manufacturing side could also have address to different controlling sides. The chose between the different controlling sides could be based on the type of manufacturing device to be controlled and/or the design of the manufactured optical lens.

(48) Many further modifications and variations will suggest themselves to those skilled in the art upon making reference to the foregoing illustrative embodiments, which are given by way of example only and which are not intended to limit the scope of the invention, that being determined solely by the appended claims.

(49) In the claims, the word comprising does not exclude other elements or steps, and the indefinite article a or an does not exclude a plurality. The mere fact that different features are recited in mutually different dependent claims does not indicate that a combination of these features cannot be advantageously used. Any reference signs in the claims should not be construed as limiting the scope of the invention.