RU2160458C2 - Device for correction of vision - Google Patents

Abstract

FIELD: medicine, medical equipment. SUBSTANCE: invention is related to ophthalmology and is intended for correction of disturbances of vision, for training to normalize vision deviations, to restore vision during rehabilitation period, to remove fatigue and vision stress, for instance, in process and after work on computer. Technical objective of invention lies in increase of accuracy of image transmission thanks to decrease of aberration and thanks to enhanced accuracy of individual selection of degree of vision correction, of individual vision field and depth of sharpness as well as expansion of functional capabilities of device. Spectacles include two diaphragms each having through holes distributed over entire area of diaphragm, additional holes arranged at angle with respect to each other so that their central axes cross in one point located at distance of 1 to 50 cm from central part of internal surface of diaphragm. EFFECT: increased accuracy of image transmission. 17 cl, 28 dwg

Description

 The invention relates to medicine and medical equipment, in particular to the field of ophthalmology, and can be used to correct visual impairment, as well as for training to normalize visual impairment, recovery during rehabilitation, relieve fatigue and eyestrain, for example, during and after work on computers.

Known optical grid for correcting optical aberrations, containing through cells in the form of identical square truncated pyramids, large bases of which are located on the surface of the optical network external in the direction of light, and smaller bases are located on its inner surface facing the lens, the cells of the optical network are formed by two sets rods having a triangular cross section, and in each set, the rods are parallel to each other, and the rods of both sets are mutually perpendicular, while the rods are directed toward the outer surface of the optical network, and the bases of the rods are directed toward its inner surface, and the ratio of the area of the large base of each square truncated pyramid to the area of its smaller base is (2.25-36): 1, and the value of the area of the smaller base is 0.4 - 4 mm ² , while the width of the rods is 1 mm. In addition, a metallized or mirror reflective coating is applied over the entire area of its outer surface. In addition, a matte metallized reflective coating is applied to its inner surface. In addition, it is made flat or concave. In addition, each of the grids contains two lateral rectangular holes with the dimensions of at least several cells of the optical grid, located symmetrically relative to the center of the grid [1].

 A disadvantage of the known device is the low degree of vision correction due to the fact that the area of the holes significantly exceeds the gaps between them, since the latter are made in the form of thin rods and are a grid. In addition, the square profile of the holes alone does not allow their full focusing properties to be used, and the large ratio of the areas of the holes to the spaces does not allow their diaphragmatic properties to be used either. The disadvantages of the known device include low functionality, as they do not allow it to be used for vision training in order to treat visual impairment, to relieve fatigue after and during visual work, for example, in computer operators.

 A device is known - lensless glasses containing two diaphragms mounted in a spectacle frame, each of which contains through holes distributed over the entire area of the diaphragm. In addition, the diameter of the holes in each diaphragm decreases in its area from top to bottom. In addition, in each diaphragm there is a horizontal slit passing through the center of the diaphragm. In addition, the device contains two additional diaphragms - the third and fourth, similar to the first and second, all diaphragms are made round, and the diameter of the third and fourth diaphragms is less than the diameter of the first and second diaphragms by an amount not exceeding the diameter of the largest hole; the third and fourth diaphragms are located adjacent to them in the holder of the frame in front of the first and second diaphragms with the possibility of rotation of the third and fourth diaphragms relative to the rigidly fixed stationary first and second diaphragms around one point located on the periphery of the diaphragms so that when the movable diaphragms are rotated, the holes partially overlap, that is, their area was regulated [2].

 The disadvantages of the known device are the low accuracy of the selection of individual vision correction due to the impossibility of adjusting the relative distances between the holes and the inability to individually select the field of view and depth of field, since the plane of the diaphragms does not have the ability to move relative to the eyes. In addition, the disadvantages include low image transmission accuracy, since the holes are parallel to each other in the diaphragm, which distorts the visible shape of the holes from the center to the periphery of the diaphragm in the projection onto the retina, since the optical axes of the holes do not intersect. The same causes non-ideal diaphragm, since the holes have a cylindrical profile along the cross section of the plate of the diaphragm of finite thickness, and therefore are microcollimators, which creates additional aberrations that cause image distortion.

 Closest to the proposed is a device for correcting vision, containing two diaphragms with through holes inserted into the eyeglass frame, the holes being located at an angle to each other so that their central axes intersect at one point. In addition, the intersection point of the axes is located at the pupil of the user [3].

 A disadvantage of the known device is the low accuracy of the transmission of dynamic images when using the device in a real situation, as well as with constant eye movements when watching TV shows, performing eye exercises and for everyday use. This is because due to the convergence of the axis of the holes exactly to the pupil of the user, this allows the correct visibility of the holes only when the pupil is oriented in the center of the diaphragm. With small deviations from the center, distortions occur immediately across all openings, since the pupil leaves the center of intersection of their axes.

 In addition, the disadvantage of the device is the low accuracy, since due to the rigidly fixed location of the center of intersection of the axes of the holes necessarily on the pupil of the user, the position of the center of intersection of the axes of the holes is not individually selected based on feedback on the patient’s maximum comfort as in a static view , and in dynamics - both with test eye movements.

 In addition, the disadvantages of the device are the low accuracy and flexibility of the device due to the absence of any elements that allow you to adjust the location of the diaphragms relative to the user's eyes directly in the process of using the device. The low accuracy of the known device is also due to the imperfect aperture due to the cylindrical shape of the holes of the diaphragm, which generates internal reflections from the walls of the holes. The insufficiently high functionality of the device is associated with the impossibility of changing the shape of the holes in the diaphragms, and also due to the fact that the combination of diaphragms with eyeglass lenses is not provided.

 The aim of the invention is to increase the static and dynamic accuracy of image transmission by reducing aberrations and by increasing the accuracy of individual selection of the degree of vision correction, individual field of view and depth of field, as well as expanding the functionality of the device by making it possible to use the device for both correction and for rehabilitation training of vision in the treatment of its disorders, in the rehabilitation period, as well as to relieve fatigue and relief of vision e or in the production process related to the long visual work.

 This goal is achieved by the fact that in the known device for vision correction, containing two diaphragms with through holes inserted into the spectacle frame, the holes are located at an angle to each other so that their central axes intersect at one point, in addition, the intersection point of the axes of the holes It is located at a distance from the central part of the inner surface of the diaphragm exactly or in the vicinity of the geometric center of the eyeball or a rotation center close to it. In addition, the diaphragms are made not less than the diameter of the minimum hole. In addition, each hole is made with a variable diameter along its cross section so that its diameter at the outer surface of the diaphragm is less than the diameter at the inner surface with which the hole forms pointed edges. In addition, the holes are made in the form of truncated cones. In addition, each diaphragm is made in the form of a thin film deposited on the surface of the spectacle glass inserted into the spectacle frame. In addition, at least one pair of movable diaphragms pivotally connected to the first and second diaphragms with the possibility of opening or closing each of the latter with one or more additional diaphragms and securing the additional diaphragms in the open position is additionally introduced into it. In addition, the holes in the additional diaphragms are made with a diameter smaller than in the first two, and in each additional pair of diaphragms the holes are made of a smaller diameter than in the previous pair, which it closes. In addition, the holes in each diaphragm are made in the form of slots parallel to each other, and the slots in the different diaphragms covering each other are located at angles. In addition, two spectacle lenses located on the inside of the frame directly behind the diaphragms are additionally introduced into the frame holders. In addition, additional apertures open by turning down. In addition, additional apertures open by turning to the sides. In addition, a spectacle lens is used as each diaphragm with the force necessary to fully or partially correct individual vision. In addition, the lenses are made of tinted glass, such as smoky. In addition, the degree of darkening of the lens is consistent with the diameter and number of holes. In addition, a black bezel is applied on the inside of the diaphragm around each hole. In addition, it additionally introduced two mechanisms for moving the diaphragms for each diaphragm separately, performing their reciprocating motion relative to the frame along the central axes of the diaphragms. In addition, each diaphragm movement mechanism includes a fixed tube containing a longitudinal section, one end of the tube is fixed to the lens holder of the spectacle frame so that the other end of the tube is directed to the outside; on top of the stationary tube is rotatably rotatable sleeve comprising a screw cut; also contains a movable tube inserted inside the stationary tube with the possibility of reciprocating sliding in it, with a diaphragm inserted at the end of the movable tube facing the frame, and a pin directed radially to the outside and inserted simultaneously into the longitudinal section of the stationary tube and a screw section of the rotary sleeve.

 In FIG. 1 shows a General view of the device for vision correction.

 In FIG. 2 schematically shows a cross-section of a diaphragm made according to the proposed device with a schematic representation of the information of the central axes of the holes.

 In FIG. 3 shows a diagram of a cross section of the diaphragm of the prototype device.

 In FIG. 4 shows a diagram of the visibility of the diaphragm of the prototype device from the side of the observer.

 In FIG. 5 shows a diagram of the collimator effect in the aperture of the prototype device.

 In FIG. 6 shows a cross section of the diaphragm according to the invention with holes in the form of truncated cones.

 In FIG. 7-9 are diagrams of hole variants of the invention.

 In FIG. 10 shows a diagram of a diaphragm made in the form of a thin film deposited on a transparent glass.

 In FIG. 11,12 shows the image perception scheme in the prototype device with the central position of the pupil of the user's eye and, accordingly, when it deviates from the central position.

 In FIG. 13, 14 - the same for the proposed device.

 In FIG. 15 shows a variant of selecting the most favorable location of the intersection point of the axes of the holes in the region of the geometric center of the eye, which is the center of its rotation.

 In FIG. 16, 17 shows a diagram of combining the diaphragm with holes and spectacle optics.

 In FIG. 18-20 shows a diagram of a device with reclining diaphragms, respectively, up, down and to the sides.

 In FIG. 21 is a plan view of a vision correction device with diaphragms locked in latches and opening to the sides in an open position.

 In FIG. 22 shows a diagram of a device with a pair of fixed and two pairs of diaphragms opening to the sides with slots located at an angle to each other.

 In FIG. 23 shows the formation of holes when applying the diaphragms in FIG. 17 on top of each other.

 In FIG. 24 shows a diagram of a device with spectacle optics and three pairs of movable diaphragms that open to the sides.

 In FIG. 25 shows the implementation of the diaphragm in the form of spectacle optics.

 In FIG. 26 depicts the same as in FIG. 19 in plan with black rims applied around the holes to improve fixation of sight on the holes.

 In FIG. 27 shows a variant of the device with mechanisms for reciprocating movement of the diaphragms assembly.

 In FIG. 28 shows the mechanism for moving the diaphragm in an exploded state.

 The device for vision correction (Fig. 1) contains a spectacle frame 1 with diaphragms 2 inserted into its lens holders, each of which contains through holes 3, holes 3 in the diaphragms 2 are made so that their central axes 4 (Fig. 2) are located under angles to each other and converged at one point 5, located at a distance from the central part of the inner surface of the diaphragm 2 approximately in the vicinity or exactly coinciding with the geometric center of the eyeball or the center of rotation of the user's eye close to it; the diaphragms 2 are made of opaque material, and their thickness is not less than the diameter of the holes 3, the frequency of the holes 3 is selected so that the gaps 6 between them exceed their diameter; the holes 3 in the diaphragms 2 are made with a variable diameter (Fig. 6-9) so that their diameter on the outer surface is larger than on the inner surface, for example in the form of truncated cones (Fig. 6); the diaphragm 2 can be made in the form of a thin opaque film 7 (Fig. 10) with holes 3, deposited on a transparent glass 8.

 The device for correcting vision (Fig. 15.16) may also contain conventional spectacle lenses 9 located in the lens holders of the frame 1 so that the diaphragms 2 are located in front of them; the sign and strength of the lens is selected based on the complete or partial correction of the vision of a particular patient; the diaphragm 2 can be made in the form of tilting up (Fig. 17), down (Fig. 18) or to the sides (Fig. 19, 20) visors fully or partially covering the lens 9 in the lens holder of the frame 1 and pivotally mounted respectively with the upper or lower sides of the lens holders and fixed in the open position, for example, latches 10 (Fig. 20).

 The device for correcting vision (Fig. 21-23) may contain several opening diaphragms 2, each of which contains slots 11 located at angles on the diaphragms 2 located in one lens holder so that when they are superimposed on each other at the intersection of the slots 11 form holes 3 of a tetrahedral shape when two diaphragms 2 are superimposed on each other, hexagonal shapes - when three diaphragms 2 are superimposed or an octagonal shape when four diaphragms 2 are superimposed (Figs. 22, 23). All diaphragms can be locked in the open position with latches 10.

 The device for correcting vision (Fig. 24) may include diaphragms 2 combined with lenses 9, that is, the role of diaphragms 2 is played by lenses 9, in which holes 3 according to the invention are made directly; to improve vision fixation on the holes 3 around each of them can be applied a black rim 12 (Fig. 25).

 A device for correcting vision (Fig. 26, 27), containing the mechanisms of reciprocating movement of the diaphragms 2, contains a spectacle frame 1, two rotating sleeves 13, each of which contains a screw section 15; two movable tubes 16, on one edge of each of which from the outer surface there is a pin 15 directed outward from the tube 16; two stationary tubes 17, each of which is provided with a longitudinal section 18; moreover, the fixed tubes 17 are fixed at one end in the lens holders of the frame 1, a movable tube 16 is inserted into each fixed tube 17, a diaphragm 2 with holes 3, made according to any embodiment of the invention, is inserted at the edge of the closest to the rim, and rotatable over each fixed tube 16 a rotating sleeve 13 is located so that the pin 15 of the fixed tube 16 is simultaneously in the screw section 14 of the sleeve 13 and in the longitudinal section 18 of the fixed tube 17.

 For aesthetic reasons, in embodiments of the device where opaque diaphragms 2 are used, patterns of different brightness and different colors can be applied on the outside of the latter.

 A device for correcting vision (Fig. 1) is used as follows.

A spectacle frame 1 with diaphragms 2 inserted into it with holes 3 is worn instead of glasses and used to:
- constant wearing instead of lens optics, since the present invention implements improved properties of a pinhole camera for correcting visual impairment, including those that are difficult to correct with conventional lens optics (astigmatism, some forms of strabismus and diplopia);
- periodic use for the purpose of training vision when performing visual exercises to enhance their effect in the case of the treatment of visual impairment and during rehabilitation procedures;
- according to indications and subjective sensations for unloading of vision in the process of performing intensive visual work, for example, computer operators or for relieving eye fatigue immediately after performing visual work;
- to reduce the brightness of the light flux, for example, as sunglasses or when watching television programs, or to work on displays.

 Due to the execution of the axes 4 of the holes 3 at an angle to each other so that they intersect at one point 5 (Fig. 1, 2), the visibility of the shape of the holes 3 is not distorted, as is the case with the known devices (Fig. 3), where due to the parallelism of the central axes 4 of all holes 3 there is no reduction of them on the retina. As a result of this, in known analogues, the visibility of the shape of the hole 3 from the center to the periphery of the diaphragm 2 is distorted, that is, due to a decrease in the angle of view α (Fig. 3) to the periphery of the diaphragm 2, the holes 3 appear more and more elliptical, and the larger axis of the ellipse remains equal to the diameter of the hole , and the small axes are reduced (Fig. 4), which leads to a narrowing of the field of view and distortion of the image at the edges, since the optical effect of "reducing" the holes 3 makes them unplanned less than the calculated optimal diameter and violates the ratio of dia meters of holes 3 with the dimensions of the solid sections 6 of the diaphragm 2. The fineness of the thickness of the diaphragm 2 leads to the same effects in the prototype device, which also causes a collimator effect in the holes 3 (Fig. 5), which consists in the reflection of rays from the walls of the cylindrical hole 3 and also leading to image distortion, including in the form of a double image on the contour. In the proposed device, the distortions caused by the microcollimators of the holes 3 are completely eliminated by performing them with a variable diameter and pointed edges from the inside of the diaphragms 2 facing the user's eyes, for example in the form of truncated cones (Fig. 6) or other shapes (Fig. 7, 8, 9), for example, caused by technological considerations. This embodiment of the holes 3 avoids these undesirable phenomena at any thickness of the diaphragm 2, regardless of its specific size. The same can be achieved by the implementation of the diaphragms 2 of the device in the form of thin opaque films 7 (Fig. 10) with holes 3 deposited on the surface of the transparent glass 8.

 The location of the point of information of the axes of the holes 3 within the proposed range, and not in a rigidly fixed form on the pupil of the user, as in the prototype device, can reduce aberrations that occur when the visibility of the shape of the holes is distorted when the user's eyes move. Indeed, in the case of the prototype, the slightest deviation of the user's pupil from the central orientation (Fig. 11, 12) causes a violation of the correct visibility of all the holes at once, similar to that described above. In the case of the location of the axis of the axis of information behind the pupil (Fig. 13), its deviation from the central position produces a kind of “scanning” of the axes of the holes and at the same time always some part of them, which is central at that time, that is, located in the most important the zone of central vision for the new position of the pupil is perceived without distortion, which provides the corresponding more accurate image transmission (Fig. 34). Thus, the device allows you to increase dynamic accuracy with constant eye movement, which is always observed in real conditions.

 The location of the information points of the axes of the holes 3 within the range of distances allows for the individual selection of its position in the most favorable zone of the geometric center of rotation of the camera of the eye (Fig. 15). This allows you to achieve equidistance distances from the diaphragm 6 to the retina and to ensure, thereby, the most undistorted transmission of images. The monotony of the perception of the holes 3 in this case, unlike the prototype and other known devices, provides the most rapid adaptation to glasses and the inclusion of the effect of "invisibility" of the diaphragms.

 The combination of collimatorless diaphragms 2 with optical spectacle glasses 9 (Fig. 15, 16) makes it possible to increase the depth of field of the image, regardless of the optical power of the lenses, necessary for full vision correction, and allows you to distribute in any proportions the degree of correction between optical glass 9 and aperture 2 and thus reduce addiction to glasses. When using lenses 9, the total optical power necessary for complete vision correction in the lens system 9 - aperture 2, the use of a diaphragm 2 with holes 3 in combination with optical glasses 9 reduces the luminous component of the light flux, and due to the use of aperture 2, a more complete correction with a wider pupil than with one lens, which greatly expands the dynamic range of the corrected visual perception. In addition, the combination of collimatorless diaphragms 2 with optical glasses 9 allows to reduce lens aberrations and to reduce distortions caused by spectacle optics and inaccuracy of its selection in accordance with individual characteristics, as well as the fit of glasses depending on the type and shape of the frame.

 When making diaphragms 2 in the form of visors tilting up, down or sideways (Fig. 17-19) during operation of the device, the lens system 9 — diaphragm 2 and the normal mode in which only spectacle glasses 9 are used can be used as necessary In this case, the diaphragm 2, in addition to training the eyesight properties, increasing the depth of field and improving the optics of optics qualities, can be used as sunscreens for glasses, which are activated as needed and at the same time do not impair visual perception The term while reducing image brightness. In this case, in the case of opening the diaphragms 2 up or down (Fig. 17, 18), the diaphragms 2 can be both interconnected (Fig. 17), in which case they open simultaneously or independently (Fig. 18.19) , in this case, at the request of the user, you can open them both together and separately (for example, only on one side). In all cases, the diaphragm is locked in the open position by latches 10 (Fig. 20).

 In the variants (Figs. 21-23) with several opening diaphragms 2, it is possible to change the profile of the holes 3 formed at the intersection of the slots 11. This allows you to transform the hole 3 from a quadrangular shape to hexagonal, and octagonal in the case of four pairs of overlapping diaphragms (Fig. 22).

 In an embodiment of the device in which the role of the diaphragms 2 is played by the lenses 9 themselves (Fig. 24), that is, the holes 3 are made directly in the lenses 9, due to this, the visual perception creates the possibility of constant switching of vision with correction by optical glass to correction by lensless optics according to the camera principle об pinhole with holes 3, which also causes positive stimulation of vision according to the type of Bates training technique [4]. This, in turn, prevents addiction to glasses and reduces eye fatigue during visual work with glasses, especially in the case of watching dynamic scenes, such as, for example, on a computer screen. An additional reinforcement of this effect is facilitated by the black rims 12 around the holes 3 on the lenses 9 in the device variant (Fig. 25). This is due to better fixation of the gaze on the holes 3 with eye movement within the field of view from the hole to the hole.

 The possibility of using smoky glasses 9 of various optical densities makes it possible, if necessary, to coordinate the luminance parameters of the light flux passing through the glass 9 and through the openings 3, which makes it possible to purposefully vary the parameters of switching vision according to the luminance characteristics and set the required levels of stimulation of visual perception by setting the range of changes in the brightness of the perceived Images. This coordination is carried out by experimental selection of the degree of darkness of the glass 9 with respect to the diameter of the holes 3, the frequency and the order of their location on the glass 9.

 When performing the device with the possibility of reciprocating movement of the diaphragms 2 (Fig. 26, 27), the range of selecting the optimal distance of the diaphragms 2 to the retina of the eye increases significantly, taking into account the individuality of a particular patient, and also taking into account the fit of the spectacle frame in each case and even in a specific point in time, since with this design the position of each of the diaphragms 2 is easily changed. To do this, rotate the external freely rotating sleeve 13 with a screw cut 14, while the force is transmitted to the pin 15 fixed in the movable tube 16 with the diaphragm 2 fixed inside it, as a result of which the movable tube 16 makes a reciprocating movement in the stationary tube 17, since the pin 15 simultaneously slides along the longitudinal section 18 in the tube 17, which also prevents their mutual rotation. As a result of this, each diaphragm 2 can be approached or removed relative to each fixed tube 17, i.e., relative to the spectacle frame on which they are fixed, and therefore relative to the patient’s eye. This movement is carried out independently for each diaphragm 2 by turning the corresponding sleeve 13 in the necessary direction. Moving the diaphragm 2 allows you to adjust the degree of reduction of the central axes 4 of the holes 3 on the retina individually in each case, separately for each eye.

The invention in comparison with known analogues, including the prototype, has the following advantages:
- higher accuracy of the lensless optics effect, because due to the proposed innovations it is possible to realize uniform visibility of all holes on the diaphragms corresponding to their true geometric dimensions, which allows, unlike the prototype, to purposefully program the magnitude of the achieved lensless optics effect, which makes it possible to more accurately correct vision , including in difficult cases;
- higher accuracy of image transmission due to the introduction of additional elements to reduce aberration and completely eliminate the effect of microcollimators in the holes, which consists in the reflection from the walls of the holes and bifurcation of images;
- a significantly wider field of view and depth of field due to the introduction of additional elements connected in the proposed manner, including when combining diaphragms with holes with lens optics, which also allows them to be used for vision correction in complex cases, including when only lens correction optics is not achieved, and also can significantly reduce addiction to glasses;
- wider functional capabilities, since the device also allows it to be used for training visual perception in order to treat various visual impairments, as well as to relieve fatigue and unloading of visual tension both immediately after production activity and in its process, for example, when working on displays computer operators;
- significantly greater accuracy in the selection of device parameters depending on the individual patient, the setting of the frame and the conditions and characteristics of the operation of the device, as well as high mobility and ease of adjustment of parameters that allow you to track a quick change in the operating modes of the device;
- simplicity and high technology, as well as the original appearance.

Sources of information
1. USSR author's certificate N 1286118, IPC ⁶ G 02 C 7/00, 7/16, 1987.

 2. US Patent N19591915, 1934.

3. Application of France N 2505513, IPC ⁶ G 02 C 7/16, 1982.

 4. Bates U.G., Corbett M.D. Improvement of vision without glasses according to the Bates method. How to get good vision without glasses. Collection, Vilnius: Polina, 1990.

Claims (17)

 1. A device for correcting vision, comprising two diaphragms with through holes inserted in a spectacle frame, the holes being located at an angle to each other so that their central axes intersect at one point, characterized in that the intersection point of the axes of the holes is at a distance from 3 to 50 cm from the central part of the inner surface of the diaphragm, and each hole is made with a variable diameter along its cross section so that its diameter at the outer surface of the diaphragm is less than the diameter at the inner surface , Which forms a hole sharpened edges.  2. The device for correcting vision according to claim 1, characterized in that the diaphragms are made with a thickness of at least the diameter of the minimum hole.  3. A device for correcting vision according to claims 1 and 2, characterized in that the holes are made in the form of truncated cones.  4. The device for correcting vision according to claim 1, characterized in that each diaphragm is made in the form of a thin film deposited on the surface of the spectacle glass inserted into the spectacle frame.  5. A device for correcting vision according to claims 1 to 4, characterized in that at least one pair of movable diaphragms is pivoted into it, pivotally connected to the first and second diaphragms with the possibility of opening or closing each of the last one or more additional diaphragms and fixing additional diaphragms in the open position.  6. The device for vision correction according to claim 5, characterized in that the holes in the additional diaphragms are made smaller in diameter than in the first two, and in each additional pair of diaphragms the holes are made in a smaller diameter than in the previous pair that it closes.  7. The device for correcting vision according to claim 5, characterized in that the holes in each diaphragm are made in the form of parallel slots of the other, and the slots in different diaphragms covering one another are located at angles.  8. A device for correcting vision according to claims 1 to 5, characterized in that two spectacle lenses located on the inside of the frame directly behind the diaphragms are additionally inserted into the frame holders.  9. The device for correcting vision according to claim 5, characterized in that the additional diaphragms open by turning upward.  10. The device for correcting vision according to claim 5, characterized in that the additional diaphragms open by turning downward.  11. The device for correcting vision according to claim 5, characterized in that the additional diaphragms open, turning to the sides.  12. A device for correcting vision according to claims 1 to 3, characterized in that a spectacle lens is used as each diaphragm with the force necessary for full or partial correction of individual vision.  13. The device for correcting vision according to item 12, wherein the lenses are made of tinted glass, such as smoky.  14. The device for correcting vision according to item 13, wherein the degree of darkening of the lens is consistent with the diameter and number of holes.  15. A device for correcting vision according to claims 12 and 13, characterized in that a black rim is applied on the inside of the diaphragm around each hole.  16. The device for correcting vision according to claims 1 to 4, 12 to 15, characterized in that it additionally introduces two mechanisms for moving the diaphragm for each diaphragm separately, which perform their reciprocating motion relative to the frame along the central axes of the diaphragm.  17. The device for correcting vision according to clause 16, characterized in that each diaphragm movement mechanism contains a fixed tube containing a longitudinal section, one end of the tube is mounted on the lens holder of the spectacle frame so that the other end of the tube is directed to the outside, on top of the fixed tube with the possibility of free rotation, the rotating sleeve containing a screw cut also contains a movable tube inserted inside the stationary tube with the possibility of reciprocating sliding in it, and on A movable tube facing the rim is fitted with a diaphragm, and a pin is radially located on the outer surface, directed to the outside and inserted simultaneously into the longitudinal section of the fixed tube and the screw section of the rotating sleeve.

Images