法国专利FR3019459A1 VISUAL COMPENSATION GLASSES AND METHOD FOR SUBJECTIVE REFRACTION OF AN INDIVIDUAL WITH THE SUNGLASSE

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专利摘要:
The invention relates to visual compensation glasses comprising support means (130, 140, 152) on a face of a carrier and at least one optical subassembly (110, 120) mounted on the support means (130, 140, 152) facing at least one of the eyes of the wearer. The optical subassembly (110, 120) comprises three optical elements mounted on the support means in series along an optical axis: a first cylindrical optical power element for a direction of gaze of the wearer along the optical axis, a second element cylindrical power optics for said viewing direction and a third variable spherical power optical element for said viewing direction. The first optical element and the second optical element are adjustable in rotation about the optical axis independently of one another.
公开号:FR3019459A1
申请号:FR1453130
申请日:2014-04-08
公开日:2015-10-09
发明作者:Stephane Boutinon；Del Rio Vincent Tejedor；Michel Nauche
申请人:Essilor International Compagnie Generale dOptique SA；
IPC主号:

专利说明:

[0001] TECHNICAL FIELD TO WHICH THE INVENTION RELATES The present invention relates to the field of optometry. It relates more particularly to visual compensation glasses, for example test glasses, and a method of subjective refraction of an individual wearing these glasses. BACKGROUND ART In the context of measuring the visual acuity of a patient, it has already been proposed to simulate the visual compensation to be provided, for example by means of test glasses or a refractor, such as a refraction head. In the refraction head, test lenses are placed on several disks, driven in rotation manually or with the aid of a motorized mechanism. However, it is understood that such an object has a large size and weight, related to the number of glasses placed on each disc.
[0002] The test glasses are less bulky. It is expected that they will successively receive test lenses with different corrections, until finding the correct correction for the patient. This solution is however quite impractical, in particular because it requires the separate storage of test lenses in dedicated boxes. It further involves lens changes that cause undesired and non-continuous correction power transitions. OBJECT OF THE INVENTION In this context, the present invention provides visual compensation glasses comprising support means on a face of a carrier and at least one optical subassembly mounted on the support means facing at least one of the eyes of the wearer, characterized in that the optical subassembly comprises three optical elements mounted on the support means in series along an optical axis, including a first cylindrical optical power element for a direction of gaze of the carrier according to the optical axis, a second cylindrical optical power element for said viewing direction and a third optical spherical power element variable for said viewing direction, the first optical element and the second optical element being adjustable in rotation about the optical axis independently one of the other. It is thus possible to obtain a wide variety of corrections on glasses: in fact, by the proposed combination of the three optical elements mentioned above, it is possible to vary the spherical power, the cylindrical power and the cylinder angle generated by the optical subassembly. . In the embodiment described, the optical axis is perpendicular to the cylinder axis of the first and second optical elements and the first and second optical elements exert no spherical power for said direction of gaze of the wearer. For example, it is provided that each of the first, second and third optical elements is a lens having a diameter greater than or equal to 20 mm, which makes it possible to obtain an optical subassembly of sufficient size to easily place an eye opposite. The optical subassembly comprises, for example, an electronic card designed to control the spherical power of the third optical element, the position of the first optical element around the optical axis and the position of the second optical element in rotation around the optical axis. setpoint information function. It can further be provided that the optical subassembly comprises an inclinometer and / or a range finder; the electronic card can then determine the setpoint information based in particular on inclination information received from the inclinometer and / or the rangefinder. One can also consider using a button actuated by the carrier, so that the electronic card can change the spherical power of the third optical element when pressing the button. In addition, a receiving module can be provided for receiving the setpoint information over a wireless link. This avoids the presence of son that would interfere with the wearer of glasses. It can therefore have a natural posture when wearing the visual compensation glasses. The support means comprise, for example, a nasal support. The optical subassembly can also be mounted on a mounting element, possibly adjustably along a horizontal axis. The nasal support can be mounted adjustably on the mounting element. The support means may further comprise at least one limb of adjustable length.
[0003] The glasses may also comprise an energy storage system (for example electrical) for powering (electrically) means designed to adjust the spherical power of the third optical element and / or the position of the first optical element around the axis optical and / or the position of the second optical element rotated about the optical axis, to make the device autonomous. The invention also proposes a method of subjective refraction of an individual wearing spectacles as proposed above and comprising the following steps: determining a type of vision (near vision, intermediate vision or far vision) by use inclinometer or range finder; determination, by the electronic card, of at least one setpoint information associated with the determined type of vision; adjusting the optical power of the third optical element, the position of the first optical element or the position of the second optical element as a function of the determined setpoint information. To determine the type of vision, one uses for example the distance of sight (distance of the object looked at according to the line of sight) determined thanks to the inclinometer or thanks to the rangefinder; ranges of sighting distance values are associated with different types of vision. Such a method may also comprise the following steps: detection of a pressing of the button; - adjustment of the optical power according to the data received from the control card.
[0004] DETAILED DESCRIPTION OF AN EXEMPLARY EMBODIMENT The following description with reference to the accompanying drawings, given as non-limiting examples, will make it clear what the invention consists of and how it can be achieved. In the accompanying drawings: - Figure 1 shows schematically the optical elements used in an exemplary implementation of the invention; FIG. 2 represents a sectional view of an example of a visual compensation device that can be used in the context of the invention; - Figure 3 shows a cutaway view of the visual compensation device of Figure 2 cylindrical lens side; - Figure 4 is a broken view of the visual compensation device of Figure 2 variable spherical lens side; - Figure 5 schematically shows a control element of the visual compensation device of Figure 2; - Figure 6 shows a side view of a pair of test glasses using two visual compensation devices of the type shown in Figures 2 to 4; - Figure 7 shows a front view of the pair of test glasses of Figure 6; FIG. 8 shows a conventional example of use of the test spectacles of FIGS. 6 and 7. FIG. 1 is a schematic representation of the main optical elements of an example of a visual compensation device used, as described later, in FIG. visual compensation glasses according to the teachings of the invention. These optical elements comprise a convex plane-cylinder lens 2, cylindrical power Co, a concave plane-cylinder lens 4, negative cylindrical power -Co, and a lens 6 of variable spherical power Sv.
[0005] The absolute value (or modulus), here Co, of the cylindrical power (here -Co) of the concave plane-cylinder lens 4 is therefore equal to the absolute value (Co) (or modulus) of the cylindrical power (Co) of the convex plane-cylinder lens 2. It could alternatively be envisaged that the respective cylindrical powers of the concave plane-cylinder lens 4 and the convex plane-cylinder lens 2 are (slightly) different in absolute value, but are in any case cause such that the resulting cylindrical power, generated by the combination of these two lenses, has a negligible value (for example less than 0.1 diopter in absolute value) in at least one relative position of these two lenses.
[0006] The three lenses 2, 4, 6 are placed on the same optical axis X. Precisely, each of the three lenses 2, 4, 6 has a generally cylindrical external shape, centered on the optical axis X. In the example described here, the lenses 2, 4, 6 respectively have the following dimensions (measuring their dimensions): 25 mm, 25 mm, 20 mm.
[0007] It should be noted that it is preferable to use this visual compensation device 10 by positioning the patient's eye on the side of the variable spherical power lens 6 so that the cylindrical power lenses 2, 4, moreover large diameter, do not limit the field of vision defined by the variable spherical power lens 6, which is itself wide because of the proximity of the patient's eye. Each of the three lenses 2, 4, 6 comprises a first plane face, perpendicular to the optical axis X, and a second face, opposite to the first face and optically active: the optically active face of the lens 2 is cylindrical in shape convex (the axis Y1 of the cylinder defining this face being perpendicular to the optical axis X); the optically active face of the lens 4 is of concave cylindrical shape (the axis Y2 of the cylinder defining this face being perpendicular to the optical axis X); the optically active face of the lens 6 of variable spherical power Sv is deformable and can thus take a convex spherical shape (as illustrated in dashed lines in FIG. 1), a planar shape or a concave spherical shape (as shown in solid lines) .
[0008] The lens 6 of variable spherical power Sv is, for example, a lens of the type described in document EP 2 034 338. Such a lens comprises a cavity closed by a transparent deformable membrane and a movable transparent flat wall; the cavity contains a transparent liquid of constant volume which is more or less constrained by the moving face, in order to deform the membrane which is therefore a spherical concave surface, a flat surface, or a spherical convex surface. In the lens used, a transformation of movement carried out by a screw nut system makes it possible to ensure the translation-rotation movement transformation. In the example described here, the lens 6 has a variable focal length between -40 mm and 40 mm, or a spherical power Sv variable between -25D and 25D (D being the diopter, unit of measurement of the vergence, inverse of the focal length expressed in meters). Moreover, the plane-cylinder lenses 2, 4 respectively have already indicated a cylindrical power -Co and Co, here with Co = 5D. As explained in more detail below, the concave plane-cylinder lens 4 and the convex plane-cylinder lens 2 are rotatably mounted about the X axis (rotation centered on the X axis). The axis Y1 of the convex cylinder formed on the optically active face of the convex plane-cylinder lens 2 can thus form a variable angle α1 with a reference axis Y0 (fixed and perpendicular to the optical axis X). Likewise, the axis Y2 of the concave cylinder formed on the optically active face of the concave plane-cylinder lens 4 can form a variable angle a2 with the reference axis Yo. By calculating the vergence on the various meridians, the following formulas are obtained for the spherical power S, the cylindrical power C and the angle of astigmatism a of the optical subassembly formed of the three optical elements 2, 4, 6 which comes to be described: sin 2a, - sin 26 (1 cos (a + a2) tan 2a = (formula 1) cos 2a, - cos 2a1 C = Co (cos 2 (a - a2) - cos 2 (a - al )) (formula 2) s = s, - -c. (formula 3) 2 Note that the term (-C / 2) in formula 3 corresponds to a spherical power generated by the resultant of the two cylindrical power lenses By controlling the rotational position of the convex plane-cylinder lens 2 and the rotational position of the concave plane-cylinder lens 4, independently of one another, as hereinafter described, one can independently vary each angles ai, a2 from 0 ° to 360 ° and thus obtain a cylindrical power C adjustable between -2.00 and 2.00 (here between -10D and 10D), and for any angle adjustable astigmatism between 0 ° and 360 ° achieved by simultaneous control of both lenses. As indicated by the formula number 3, the spherical power resultant induced by the resultant of the orientation of the 2 cylindrical lenses is compensated by means of the spherical lens of variable power. Moreover, by varying the spherical power Sv of the spherical lens 6, it is possible to adjust the spherical power S of the subset formed by the three lenses 2, 4, 6. According to one conceivable variant, the lenses with fixed cylindrical power could have the same cylindrical power Co (positive or negative): it sin (al + a2) could be two convex plane-cylinder lenses, possibly identical, or, alternatively, two concave plane-cylinder lenses, possibly identical. Indeed, in this case, the spherical power S, the cylindrical power C and the astigmatism angle α of the subset formed of these two lenses and a variable spherical power lens are given by the following formulas: tan 2a = sin 2a2 + sin 2a1 (formula 4) cos 2a, + cos 2a1 C = Co (cos 2 (a - a2) + cos 2 (a -al)) (formula 5) s = y + c0 - - vs-. (formula 6) 2 The term Co - C / 2 corresponds to the spherical power induced by the combination of the two cylindrical power lenses. It is therefore also possible in this case to adjust the spherical power S, the cylindrical power C and the angle of astigmatism a, in particular so that the cylindrical power C is zero, by rotating the cylindrical power lenses (independently of the one of the other) and varying the spherical power of the variable spherical power lens. An example of a visual compensation device 10 which uses the optical elements which have just been described is represented in FIG. 2.
[0009] In the description which follows, in order to clarify the explanation, terms such as "superior" or "inferior" that define an orientation in FIGS. 2, 3 and 4 will sometimes be used. It will be understood that this orientation is not necessarily applicable to the use that may be made of the device described, in particular that of Figures 6 to 8.
[0010] The visual compensation device 10 comprises a housing 12 formed of a first portion 14, a second portion 16 and a third portion 18, which extend successively along the optical axis X and are assembled in pairs at level of planes perpendicular to the optical axis X. A first gear 22 is mounted in rotation centered on the optical axis X in the first portion 14 of the housing 12 and carries at its center, in an opening provided for this purpose, the convex plane-cylinder lens 2. The first gear 22 and the convex plane-cylinder lens 2 are coaxial; in other words, in section in a plane perpendicular to the optical axis X, the outer circumference of the first toothed wheel 22 and the circumference of the convex plane-cylinder lens 2 form concentric circles centered on the optical axis X. Likewise a second gearwheel 24 is mounted in rotation centered on the optical axis X in the second part 16 of the housing 12 and carries at its center, in an opening provided for this purpose, the concave plane-cylinder lens 4. The second wheel toothed 24 and the concave plane-cylinder lens 4 are coaxial; in other words, in section in a plane perpendicular to the optical axis X, the outer circumference of the second gear 24 and the circumference of the concave plane-cylinder lens 4 form concentric circles centered on the optical axis X. A third gearwheel 27 is mounted in rotation centered on the optical axis X in the third portion 18 of the housing 12. The third gear 27 is integral with a ring provided on the circumference of a housing 26 which carries the power lens 6 spherical variable and allowing the control of spherical power S. The housing 26 of the lens 6 of variable spherical power is mounted in the third portion 18 of the housing 12. As clearly visible in Figure 3, the first gear wheel 22 is rotated (around the optical axis X) by means of a first motor 42, a drive shaft carries a first worm 32 which meshes with the first toothed wheel 22. The first mote ur 42 is for example mounted in the first portion 14 of the housing 12. The current position of the first gear 22 is monitored by a first optical cell 52.
[0011] Similarly, the second gear wheel 24 is rotated about the optical axis X by means of a second motor 44, a drive shaft carries a second worm 34 which meshes with the second gear wheel 24. The second motor 44 is for example mounted in the second portion 16 of the housing 12. The current position of the second gear 24 is monitored by a second optical cell 54. As shown in Figure 4, the third gear 27 is in turn driven in rotation (about the optical axis X) by means of a third motor 46 which has a drive shaft on which is mounted a third worm 36 which meshes with the third gear 27. The third motor 46 is for example mounted in the third portion 18 of the housing 12. The current position of the third gear 27 is monitored by a third optical cell 56. The first, second and third motors 42, 44, 46 are for example of s stepper motors, a resolution of 20 steps / turn, driven here in 8th step (hereinafter micro-step). Alternatively, these engines could be controlled in 16th step. The internal volume of the housing 12 (as also the internal volume of each of the first, second and third parts 14, 16, 18 in the same way) can be subdivided into a receiving space of the motors 42, 44, 46 (region upper case 12 in Figures 2, 3 and 4) and a receiving space of the optical elements 2, 4, 6 (lower region of the housing 12 in Figures 2, 3 and 4). The receiving space of the motors 42, 44, 46 has a substantially parallelepipedal shape, open (downwards in the figures) in the direction of the receiving space of the optical elements 2, 4, 6 and closed on the opposite side ( upwards in the figures) by an upper face 19 of the housing 12 (the upper face 19 of the housing 12 being formed by the assembly of respective upper faces of the first, second and third parts 14, 16, 18 of the housing 12). The arrangement of the motors 42 44 and 46 is such that it allows to benefit from a 180 ° circular geometry centered on the optical axis closest to the effective radius of the lenses. The receiving space of the optical elements 2, 4, 6 has, opposite the motor receiving space, a cylindrical shape (delimited by the walls of the housing 12) which matches that of the third gear 27 on half of the circumference of it. In other words, the housing 12 (and consequently each of the first, second and third parts 14, 16, 18 of the housing 12) has, at the receiving space of the optical elements 2, 4, 6, a cylindrical shape of diameter (perpendicular to the optical axis X) of the same order as, and slightly greater than, that of the third gear wheel 27. The respective diameters of the gear wheels 22, 24, 27 are adapted to promote the conservation of the field by despite the thickness of the optical subassembly. The first motor 42 and the first worm 32 extend in the housing 12 in a direction Z perpendicular to the upper face of the housing 12 (and therefore in particular perpendicular to the optical axis X) so that the first motor 42 is housed in the engine receiving space while the first worm 32 extends into the receiving space of the optical elements. The second motor 44 and the second worm 34 extend in turn in the housing 12 in the same direction, but opposite the first motor 42 and the first worm 34 relative to the cylindrical power lenses. 2, 4. The second motor 44 is housed in the engine receiving space while the second worm 34 extends into the receiving space of the optical elements. Note that thus the first worm 32 and the second worm 34 are located on either side of the assembly formed by the first gear 22 and the second gear 24, and that the lateral space (along a Y axis perpendicular to the aforementioned X and Z axes) of these different parts (first worm 32, second worm 34, first or second gear 22, 24) is smaller than the diameter of the third gear 27 of so that the first and second worm 32, 34 contain in the receiving space optical elements without the need for growth to accommodate them. Moreover, the first and second motors 42, 44 each have a space along the optical axis X greater than that of each of the first and second gears 22, 24, and even greater than that of each of the first and second parts 14, However, since these first and second motors 42, 44 are placed as just indicated on each side of the housing 12 (relative to the Z axis), they can each occupy a space which extends along the optical axis X to the right of the first portion 14 and the second portion 16 of the housing 12. For example, each of the first and second motors 42, 44 has a lateral size (external diameter of the motor) between 6 and 12, for example 10 mm, while the first and second gears 22, 24 each have a thickness (size along the X axis) of between 1 and 4, for example 2.5 mm. On the other hand, the third motor 46 and the third worm 36 are located in the engine receiving space, in the region that extends along the X axis to the right of the third portion 18 of the housing 12. third worm gear 36 engages the third gearwheel 27 in an upper part thereof, which allows the housing 12 to match the shape of the housing 12 in the lower part of the third gearwheel 27, as already indicated. In the example described, as visible in FIG. 4, the axis of the third motor 46 and of the third worm 36 is slightly inclined with respect to the upper face of the housing 12 (precisely with respect to the aforementioned Y axis) . For example, it is provided that the thickness of the third gear 27 is between 0.3 mm and 2 mm. This arrangement of the various elements makes it possible to obtain a relatively thin package, typically having a thickness of between 15 and 20 mm.
[0012] The housing 12 also comprises, for example in the upper region of the engine receiving space, a control element 50, here formed of several integrated circuits carried by a common printed circuit. Furthermore, a battery-type electrical energy storage device 58 (or, alternatively, a super capacity) is provided to make the device 20 autonomous. For example, non-contact charging elements of the energy storage device 58 are also provided for example. The battery 58 makes it possible in particular to power the motors 42, 44, 46 and the control element 50. control and control elements will be selected preferentially for their low consumption. The main elements of such a control element 50, as well as their connection to the aforementioned motors 42, 44, 46 and optical cells 52, 54, 56, are shown schematically in FIG. 5. The control element 50 comprises a reception module 60 designed to receive, here through a wireless link, the setpoint information, that is to say information indicative of the values desired by the user for the spherical power S, the cylindrical power C and the angle of astigmatism a which define the compensation generated by the optical subset formed by the optical elements 2, 4, 6. The reception module 60 is for example an infrared reception module which receives this set of information from an infrared remote control manipulated by the user. As a variant, provision may be made for this setpoint information to be received from a personal computer via a wireless link, for example a wireless local area network; the user could in this case choose values of spherical power S, cylindrical power C and angle of astigmatism a for the visual compensation device by interactive selection on the computer. The reception module 60 transmits the setpoint information S, C, a received to a computer 66 (constituted for example by a processor executing a computer program so as to implement the functions of the computer described hereinafter), specifically to a calculation module 68 implemented by this computer 66. The calculation module 68 calculates the values of the angles α1, α2 and the spherical power value Sv required to obtain the received setpoint values S, C, a. in input, on the basis of the formulas exposed above. In the case where the plane-cylinder lenses 2 and 4 respectively have a cylindrical power - Co and Co, the following formulas are used, for example: ## EQU1 ## Cit a2 = a + -arcsin + - 2 2C 0 CS, = S + - 2 The computer 66 also implements a control module 70 which receives as input the values of angle α1, α2 and of calculated spherical power Sv by the calculation module 68 and sends control signals to the motors 42, 44, 46 in order to control each of the motors 42, 44, 46 independently of the others so as to obtain respective positions of the gears 22, 24, 27 which make it possible to obtain the desired values: the control module 70 controls the first motor 42 so as to rotate the first gearwheel 22 around the optical axis X to the position where the axis Y1 of the surface Optically active cylindrical lens convex plane-cylinder 2 (carried by the first wheel tooth 22) forms an angle α1 with the reference direction Y0; the control module 70 controls the second motor 44 so as to rotate the second gear 24 around the optical axis X to the position where the axis Y2 of the optically active cylindrical surface of the plane-cylinder lens concave 4 (carried by the second gear 24) forms an angle a2 with the reference direction Yo; the control module 70 controls the third motor 46 so as to rotate the third gear 27 around the optical axis X to the position where the control ring of the variable spherical power 10 controls the calculated spherical power Sv by the calculation module 68. The position of each toothed wheel 22, 24, 27 is known at each instant, respectively, thanks to the optical cells 52, 54, 56 which each measure, on the toothed wheel to which each is associated, the number of teeth having passed through the optical cell with respect to a reference point on the circumference of the wheel concerned (eg toothless). In the example described here, the first motor assembly 42-first worm gear 32-first gearwheel 22, as the second motor assembly 44-second worm gear 34-second gearwheel 24, generates a gear ratio such as a toothed wheel revolution 22, 24 corresponds to 15040 microstep of the associated motor 42, 44. The resolution (rotation angle of the toothed wheels 22, 24 for a micro-step) is therefore 0.024 ° for the angles ai and a2. The third motor assembly 46-third worm 36-third gear 46 generates meanwhile a reduction of 16640 micro-steps per revolution. The control ring of the variable spherical power is adjustable over an angular range of 120 ° (corresponding to 5547 micro steps) to obtain the spherical power variation of -25D to 25D (ie a range of variation of 50D). The resolution (spherical power variation Sv for a micro step) is therefore 0.009D. It is expected that, when passing initial setpoints al, 30 a2, Sv to new setpoints a'1, a'2, S'y, each of the first, second and third motors 42, 44, 46 are actuated during the same duration T (in seconds), which may possibly depend on the amplitude of one of the setpoint changes (for example of the variation, in absolute value, of spherical power I S'y - Sv I, where I x I is the absolute value of x).
[0013] For this purpose, the computer 66 determines, for example, the number pi of micro-pitch of the motor 42 allowing the passage of the angle α1 to the angle α'i, the number p2 of the micro-pitch of the motor 44 allowing the passage of the angle a2 at the angle a'2 and the number p3 of the micro-pitch of the motor 46 allowing the passage of the spherical power Sv to the spherical power Sv, the computer 66 then controlling the rotation of the motor 42 at a speed of pi / T micro-step per second, the rotation of the motor 44 at a speed of p2 / T micro-step per second and the rotation of the motor 46 at a speed of p3 / T micro-step per second. The control element 50 also comprises a temperature sensor 62, which delivers a measured ambient temperature information, and an inclinometer 64, for example realized in the form of an accelerometer and which delivers an orientation information of the visual compensation device. 10, for example with respect to the vertical. In the application described hereinafter with reference to FIGS. 6 to 8, the orientation information can be used to determine the position of the visual compensation device, and consequently which eye is corrected by this visual compensation device, and / or the inclination of the visual compensation device relative to the vertical to determine whether the user is viewing in far vision, intermediate vision or near vision. The computer 66 receives the temperature information from the temperature sensor 62 and the orientation information from the inclinometer 64 and uses at least one of this information in the context of the determination of the commands to be sent. to the motors 42, 44, 46. In the example described, the control module 70 uses the temperature information to compensate for the spherical power variations of the lens 6 due to the temperature (which are of the order of 0 , 06D / ° C in the example described) and the orientation information in order to compensate for any disturbances of the drive system (motors, worm gear, gears) due to changes in the orientation of the compensation device 10. Unlike the case of the description of FIGS. 2 to 4 above, the following description of FIGS. 6 and 7 refers to directions (horizontal and vertical in particular) and to relative positions ("below "or" superior) which correspond to the use of the visual compensation glasses (here test glasses) for the measurement of visual acuity of the wearer. Figures 6 and 7 show, respectively in side view and in front view, a pair of test glasses using two visual compensation devices 110, 120 of the type which has just been described with reference to Figures 1 to 5. The two visual compensation devices 110, 120 are here identical but mounted on support means on the face of a wearer, as explained in more detail below, so as to be arranged symmetrically with respect to a plane. median vertical M which corresponds to the sagittal plane of the wearer. Specifically, the visual compensation device 110 for the wearer's right eye is arranged such that its space (here parallelepipedic) for receiving the motors 112 is situated laterally and outward (that is to say on the right seen from the carrier) of its space (here cylindrical) for receiving the optical elements 114 (that is to say the eyepiece 111 of the visual compensation device 110). In other words, the axis Z1 of the visual compensation device 110 (which corresponds to the Z axis of FIGS. 2 to 4 for the visual compensation device 110) is perpendicular to the median plane M (the sagittal plane of the wearer) and the The receiving space of the optical elements 114 (or the eyepiece 111) is situated between the receiving space of the motors 112 and the median plane M. Similarly, the visual compensation device 120 intended for the wearer's left eye is disposed such that its space (here parallelepipedic) for receiving the motors 122 is located laterally and outwardly (that is to say on the left as seen from the carrier) of its space (here cylindrical) for receiving the optical elements 124 ( that is to say the eyepiece 121 of the visual compensation device 120). In other words, the axis Z2 of the visual compensation device 120 (which corresponds to the Z axis of FIGS. 2 to 4 for the visual compensation device 120) is perpendicular to the median plane M (the sagittal plane of the wearer) and the The receiving space of the optical elements 124 (or the eyepiece 121) is located between the receiving space of the motors 122 and the median plane M. The pair of spectacles 100 comprises two arms 130, 140 respectively mounted on the visual compensation device 110 and on the visual compensation device 120, each on a lateral end face of the visual compensation device 110, 120 concerned and by means of a lateral attachment 132, 142.
[0014] Each leg 130, 140 comprises an angled portion (positioning the ear of the wearer) at its end opposite to the visual compensation device 110, 120 concerned. Each branch 130, 140 is further adjustable in length by means of a suitable adjustment system 131 (for example a possibility of sliding between two half branches forming the branch 130, 140 concerned) in order to adjust the distance between the eyes of the patient and the visual compensation devices 110, 120. Each leg 130, 140 is mounted on the corresponding lateral attachment 132, 142 with a possibility of adjustment in rotation about a horizontal axis (parallel to the axis Z1, Z2 defined above) for example by means of a wheel 133, 143 in order to adjust the pantoscopic angle. As already indicated, the lateral fastener 132, 142 is fixed on the lateral end wall (referenced 19 in FIGS. 3 and 4) of the visual compensation device concerned 110, 120 (that is, for the lateral attachment 132, to the right of the visual compensation device 110 for the wearer's right eye and, for the lateral attachment 142, to the left of the visual compensation device 120 intended for the wearer's left eye). On each side, the receiving space of the motors 112, 122 is therefore located between the lateral attachment 132, 142 and the receiving space of the optical elements 114, 124 (or the eyepiece 111, 121).
[0015] The visual compensation devices 110, 120 are both mounted on a crosspiece 150 forming a mounting element, on either side of the median plane M, respectively by means of a first slide 136 and a second slide 146. The position of each of the first and second slides 136, 146 is adjustable in translation in the direction of extension of the cross member 150 (for example by means of a wheel 137, 147 provided for this purpose), which allows adjustment according to a horizontal direction perpendicular to the median plane M (that is to say the sagittal plane of the wearer) of the position of each visual compensation device 110, 120. It is thus possible to adapt (independently of one another) the positions respective of the visual compensation devices 110, 120 at half-distances pupillary right side and left side of the wearer. A nasal support 152 (designed to bear on the upper part of the nose of the wearer) is mounted on the crosspiece 150, in the middle thereof (that is to say at the median plane M), by the intermediate of a central fastener 154 provided with an oblong opening which receives a pin secured to the cross member 150 to allow adjustment in a vertical direction of the relative position of the nasal support 152 and the cross 150. This setting s' performs for example by means of a wheel 156 provided for this purpose.
[0016] Provision can also be made for a possibility of rotation of the central fastener 154 around the horizontal axis of extension of the cross-member 150 in order to adjust the position of the nasal support 152 at depth (that is to say according to FIG. optical axis of the visual compensation devices 110, 120). Reference will now be made to FIG. 8 of a conventional example of the use of the test glasses 100 which have just been described. The test glasses 100 are placed on the patient's face, adjusting the various settings described above to the morphology of the patient, in the state of the art. The visual examination can then begin.
[0017] The practitioner sends instructions (information indicative of the values desired by the user for the spherical power S, the cylindrical power C and the astigmatism angle a) for the right eye and for the left eye by means of the link wireless mentioned above. To do this, it uses for example as already indicated infrared remote control 200 designed to send data representative of the instructions to the control elements 50 via the receiving modules 60 respectively implanted in the visual compensation device 110 and in the visual compensation device 120. As already indicated, the practitioner could alternatively use a computer 300, designed for example to establish a wireless local area network (or "Wireless Local Area Network") with the reception modules 60 (which are in this variant modules of radio reception). It is also possible that the data representative of the instructions are issued by an electronic device having made an ametropia measurement of the patient. In this case, the test glasses 100 will be used to validate the refraction resulting from the ametropia measurements. For example, as already mentioned, it is proposed that the electronic device of the practitioner (remote control, computer or ametropia measuring apparatus in the examples which have just been mentioned) emit data representative of the instructions for the two eyes and that the element of control 50 embedded in each visual compensation device 110, 120 determines which instructions are intended for it. To do this, it is provided here that the control element 50 determines, on the basis of the orientation information received from the accelerometer 64, what is the orientation of the visual compensation device 110, 120 concerned and therefore to which this visual compensation device 110, 120 is associated. Indeed, in the example described, the visual compensation devices 110, 120 are identical and are mounted symmetrically with respect to the median plane M, as already indicated.
[0018] As a variant, provision could be made for the control element 50 to memorize information indicative of the position (on the right or left) of the visual compensation device 110, 120 concerned in the pair of spectacles 100. in addition, for each eye and for each parameter (spherical power S, cylindrical power C and astigmatism angle a), several setpoints are transmitted to the visual compensation device 110, 120 concerned, the different values being associated with different angles. inclination of the device concerned relative to the vertical, or to different angular ranges of inclination of the device concerned relative to the vertical, or to different types of vision (far vision, intermediate vision, near vision). For a visual compensation device, vertical inclination (in the context of visual compensation goggles such as those of FIGS. 6 and 7) is understood to mean the angle formed by the Y axis of FIGS. vertical, which corresponds to the inclination relative to the horizontal of the optical axis X of the visual compensation device. When the wearer stands straight and looks away (far vision) this angle is zero or weak (less than 10 °); on the other hand, in near vision, this angle is conventionally 30 °.
[0019] When a visual compensation device 110, 120 (and specifically its control element 50) receives different setpoints (associated with different inclination values) for a parameter, it determines by means of the orientation information received from the accelerometer 64 the current inclination relative to the vertical and controls the optical elements (as explained above with reference to Figure 5) using the values of the parameters associated with the inclination thus determined. Regarding the intermediate vision, it can be provided that the electronic device of the practitioner (remote control, computer) emits specific values of the various parameters for a range of inclination including the inclination of 20 ° (typically associated with the intermediate vision), for example the range of values between 15 ° and 25 °. Alternatively, the control element 50 could calculate values of the different parameters for the intermediate vision from corresponding values received for the far vision and the near vision, and apply these calculated values when it determines, on the based on the orientation information received from the accelerometer 64, that the current inclination is in the above-mentioned range. According to one possible embodiment, it is possible to provide, for example in each visual compensation device 110, 120, a rangefinder designed to measure the distance of the object observed in the viewing direction (for example by means of an ultrasound system or by triangulation). The control element 50 can then adapt the spherical power as a function of the distance of the observed object, for example by increasing the spherical power when the object is near to compensate for a lack of visual accommodation.
[0020] The product is an optical equipment, without particular fragility, but given its portability, it is possible to provide a base for non-contact charging of the two visual compensation devices 110, 120 and / or to verify its calibration using an optical instrument. frontofocometers, to ensure the desired level of results.
[0021] It will be understood from the foregoing description that the test spectacles described above may be used for subjective refraction purposes, whether in far vision, intermediate vision or near vision. These test glasses have the advantage of a very high reactivity compared to traditional test glasses, not having to remove the glasses from the wearer's head to modify the correction, and offer a value of evolutionary correction according to the inclination of the head. It is also possible to use such glasses under controlled field of view conditions, from a screen with mobile stimuli; the accelerometers equipping the visual compensation devices will then allow to record the movements of the patient's head needed to track the target. We can therefore subtract the movements of the head from the theoretical movement that should have caused the target to deduce the intrinsic movement of the eyes. In order to perform a monocular refraction, a not shown occulting device may be placed on the optical window of one of the eyepieces 111, 121. Alternatively, the automation of the device will make it possible to achieve this right / left separation allowing the monocular refraction to by means of a scrambling on the eye to be obscured by adding a predetermined optical power (for example a value of about one diopter). According to another possible use, the visual compensation goggles proposed above may be used as a test fixture allowing for example to reproduce the future correction in the actual conditions of use, for example for a demonstration of use of progressive lenses midway. In this context, it is also possible to provide an additional button on an outer face of the visual compensation devices 110, 120 which, when depressed, allows a predetermined modification of the value of a correction parameter (spherical power S, cylindrical power C or angle of astigmatism a). The wearer of the test glasses can thus obtain (for example by means of several presses on the button) a setting which suits him better.

权利要求:
Claims (17)
[0001]
REVENDICATIONS1. Visual compensation goggles comprising support means (130, 140, 152) on a wearer's face and at least one optical subassembly (110, 120) mounted on the support means (130, 140, 152) in at least one eye of the wearer, characterized in that the optical subassembly (110, 120) comprises three optical elements mounted on the support means in series along an optical axis (X), including a first optical element (2) of cylindrical power for a direction of gaze of the carrier along the optical axis (X), a second optical element (4) of cylindrical power for said direction of view and a third optical element (6) of variable spherical power for said viewing direction, the first optical element (2) and the second optical element (4) being adjustable in rotation about the optical axis (X) independently of one another.
[0002]
2. Glasses according to claim 1, wherein the optical axis (X) is perpendicular to the cylinder axis of the first and second optical elements.
[0003]
3. Glasses according to claim 1 or 2, wherein the first and second optical elements exert no spherical power for said direction of gaze of the wearer.
[0004]
4. Glasses according to one of claims 1 to 3, wherein each of the first, second and third optical elements (2, 4, 6) is a lens of diameter greater than or equal to 20 mm.
[0005]
Glasses according to one of claims 1 to 4, in which the optical subassembly (110, 120) comprises an electronic card (50) designed to control the spherical power of the third optical element (6), the position of the first optical element (2) around the optical axis (X) and the position of the second optical element (4) rotating around the optical axis (X) as a function of setpoint information.
[0006]
The spectacles according to claim 5, wherein the optical subassembly comprises an inclinometer (64) and wherein the electronic card (50) is adapted to determine the set-point information according to tilt information received from the receiver. inclinometer (64).
[0007]
7. Glasses according to claim 5, wherein the optical subset comprises a rangefinder and wherein the electronic card (50) is adapted to determine the setpoint information as a function of distance information received from the range finder.
[0008]
8. Glasses according to one of claims 5 to 7, comprising a button operable by the carrier, wherein the electronic card is designed to change the spherical power of the third optical element when pressing the button.
[0009]
The spectacles according to claim 5, comprising a receiving module adapted to receive the setpoint information through a wireless link.
[0010]
10. Glasses according to one of claims 1 to 9, wherein the support means comprises a nasal support (152).
[0011]
11. Glasses according to one of claims 1 to 10, wherein the optical subassembly (110, 120) is mounted on a frame member (150).
[0012]
The spectacles of claim 11, wherein the optical subassembly (110, 120) is adjustably mounted along a horizontal axis on the mount member (150).
[0013]
The spectacles of claim 11 or 12, claim 11 being dependent upon claim 10, wherein the nasal support (152) is adjustably mounted to the mount member (150).
[0014]
14. Glasses according to one of claims 1 to 13, wherein the support means comprise a branch (130, 140) of adjustable length.
[0015]
15. Glasses according to one of claims 1 to 14 having an energy storage system for supplying means designed to adjust the spherical power of the third optical element (6), the position of the first optical element (2). ) about the optical axis (X) and the position of the second optical element (4) in rotation about the optical axis (X).
[0016]
16. The method of subjective refraction of an individual wearing spectacles according to claim 6 or 7, comprising the following steps: determining a type of vision by using the inclinometer or the rangefinder; determination by the electronic card (50) of at least one setpoint information associated with the determined type of vision; adjusting the optical power of the third optical element (6), the position of the first optical element (2) or the position of the second optical element (4) as a function of the determined setpoint information.
[0017]
17. The method of subjective refraction of an individual wearing spectacles according to claim 8, comprising the following steps: detecting a pressing of the button; - adjustment of the optical power according to the data received from the control card.

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同族专利:

公开号 | 公开日

CN104970764B|2017-11-14|

CN204683563U|2015-10-07|

WO2015155456A1|2015-10-15|

FR3019459B1|2016-04-22|

KR20160140710A|2016-12-07|

EP3128895A1|2017-02-15|

CA2946643A1|2015-10-15|

CN104970764A|2015-10-14|

US20170035289A1|2017-02-09|

US10278573B2|2019-05-07|

JP6588464B2|2019-10-09|

EP3128895B1|2021-06-30|

JP2017513584A|2017-06-01|

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法律状态:
2015-04-17| PLFP| Fee payment|Year of fee payment: 2 |

2016-04-25| PLFP| Fee payment|Year of fee payment: 3 |

2017-04-26| PLFP| Fee payment|Year of fee payment: 4 |

2018-04-25| PLFP| Fee payment|Year of fee payment: 5 |

2018-07-06| TP| Transmission of property|Owner name: ESSILOR INTERNATIONAL, FR Effective date: 20180601 |

2019-04-25| PLFP| Fee payment|Year of fee payment: 6 |

2020-04-27| PLFP| Fee payment|Year of fee payment: 7 |

2021-04-26| PLFP| Fee payment|Year of fee payment: 8 |

优先权:

申请号 | 申请日 | 专利标题

FR1453130A|FR3019459B1|2014-04-08|2014-04-08|VISUAL COMPENSATION GLASSES AND METHOD FOR SUBJECTIVE REFRACTION OF AN INDIVIDUAL WITH THE SUNGLASSES|FR1453130A| FR3019459B1|2014-04-08|2014-04-08|VISUAL COMPENSATION GLASSES AND METHOD FOR SUBJECTIVE REFRACTION OF AN INDIVIDUAL WITH THE SUNGLASSES|

CN201520204373.0U| CN204683563U|2014-04-08|2015-04-07|Vision compensates glasses|

EP15718543.0A| EP3128895B1|2014-04-08|2015-04-07|Corrective eyeglasses and method for subjective refraction by a wearer of said eyeglasses|

US15/302,669| US10278573B2|2014-04-08|2015-04-07|Corrective eyeglasses and method for subjective refraction by a wearer of said eyeglasses|

CA2946643A| CA2946643A1|2014-04-08|2015-04-07|Corrective eyeglasses and method for subjective refraction by a wearer of said eyeglasses|

JP2016561818A| JP6588464B2|2014-04-08|2015-04-07|Vision correction glasses and method of measuring subjective refraction by a wearer of the glasses|

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PCT/FR2015/050890| WO2015155456A1|2014-04-08|2015-04-07|Corrective eyeglasses and method for subjective refraction by a wearer of said eyeglasses|

CN201510161980.8A| CN104970764B|2014-04-08|2015-04-07|Vision compensates glasses and wears the personal subjective refraction method of the glasses|

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