RU2737350C1 - Contact lens for sighting and device for installation thereof - Google Patents

Abstract

FIELD: weapons; optics.SUBSTANCE: invention can be used, for example, in firing from firearms, billiards, kerning, darts and other sports. Contact lens comprises an optical part with an aiming net, the elements of which are oriented in a vertical plane. Centre of the aiming net is aligned with the visual axis of the eye passing through the centre of the yellow spot fossa and the target. Device for installation of contact lens comprises holder of contact lens and handle at angle to plane of contact lens. Contact lens holder is equipped with a transparent area, the aiming net of the contact lens is aligned with the visual axis of the eye and an external sighting point located at a distance from the holder.EFFECT: technical result is higher accuracy of aiming, versatility of use and accuracy of installation.10 cl, 8 dwg

Description

The group of inventions relates to sighting devices, specifically to contact lenses for aiming and devices for their installation (implementation) and can be used, for example, in shooting from firearms and pneumatic weapons, billiards, curling, darts, bowling, golf, archery and in activities that require the construction of sighting lines. It can be used in the training process and in real conditions. It can be used in medicine to diagnose eye movements.

When aiming, the physiology of vision is as follows.

The macula of the eye has the greatest visual ability, which has a diameter of about 5 mm and is the zone of clear vision, and the fossa of the macula has a diameter of about 0.4 mm and is the zone of the clearest vision, www.traditio.wiki The macula (version Mig) - Tradition, para. 1, 2. The decrease in the clarity of vision in the transition from the fossa of the macula to the edge of the macula is gradual, without a sharp border. The eye sees a significant part of the macula almost as clearly as the fossa of the macula - this provides central vision.

The visual axis of the eye passes through the center of the macular fossa and the center of the lens at a gamma angle to the optical axis of the eye, the optical axis passes through the centers of the lens, pupil and cornea. The gamma angle can be from -3 to +8 degrees, the total range is 11 degrees, while most people have a typical angle of +5 degrees, a small part of 0 degrees, while the gamma angle for a particular eye is constant. The visual axis at any angles gamma passes through the center of the lens without refraction and, at a gamma angle not equal to 0 degrees, crosses the cornea at a point displaced from the center of the cornea and the center of the pupil, www.eyepress.ru In which direction the eye looks, para. 7, fig. 1, 2, Yu.V. Kuznetsov With various rotations of the eyeball and tilts of the head, the macular fossa can take any position relative to the optical axis of the eye - to the left, to the right, below, above.

On the first object of the group of inventions "contact lens for aiming" there are known open sights containing a rear sight and a front sight, which must be located on the line of sight with a target, www.arsenal-info.ru Features of aiming with an open sight / Art of a sniper /.

When aiming, the yellow spot of the aiming (leading) eye is combined with the aiming line, www.webohrannik.ru Aiming, para. 6.

But it is not enough to combine the yellow spot with the aiming line, since the center of the macular fossa must be aligned with the aiming line, only then the visual axis will align with the centers of the rear sight slot, front sight and the target - aiming is accurate.

Separately on each of the three points - on the rear sight, or on the front sight, or on the target, the center of the macular fossa is set precisely and involuntarily, www.ru.wikipedia.org Eye movement - Wikipedia, para. 3, www.eyepress.ru In which direction does the eye look, par. 6, fig. 2, Kuznetsov Yu.V.

When building a common aiming line with the combination of three points, the eye moves with the visual axis, mutual displacements of points in the vertical and horizontal planes relative to the center of the yellow spot pit for the location of all points in the vertical aiming plane, including the movement of the weapon, www.shooting-ua. com Dumping weapons, fig. 331. When any of the three points are displaced from the visual axis at the time of the shot, aiming is inaccurate, FIG. 1. For example, when the front sight is displaced from the center of the macular fossa, for example, by 0.2 mm, to the edge of the fossa, and the distance from the macular fossa to the front sight is 800 mm, the bullet displacement at every 800 mm of the distance from the front sight to the target will be 0.2 mm. With such an offset, for example, in biathlon even with a diopter sight, (www.singhts-review.ru Dioptric sight and its use, drawing), similar to an open sight, but more accurate, at a firing distance of 50 m, the bullet offset from the center of the target will be 50 m / 800 mm (0.2 mm = 12.4 mm. With a maximum target diameter of 45 mm, the allowable offset from the center of the target is 22.5 mm. Thus, 12.4 mm / 22.5 mm (100% = 50.5% of the allowable target, the bullet displacement will be lost only due to the displacement of the aiming line from the center of the macular fossa by 0.2 mm, and with a displacement of 0.37 mm, the bullet will not even hit the target.

The macular fossa physiologically cannot simultaneously and involuntarily control, visualize and set on several moving targets (points), especially since when aiming, any two points out of three are blurred due to different focal lengths to the points. In this case, the lines from all three points not aligned with each other come to three different points of the yellow spot.

The visual axis is involuntarily set to one target, but even though the athlete does not physiologically feel and does not know the exact location of the macular fossa, the athlete does not have any objective means of monitoring the exact position of the eyeball and macular fossa in space, for example, one can see one's own pupil only in the mirror. As a result, the athlete sees only the outer part of the aiming line - the target, but does not know and does not feel where exactly the beginning of the inner part of the aiming line is located - the center of the macular fossa. Accordingly, between the visible target and the invisible center of the macular fovea, it is possible to draw an aiming line only presumably and approximately with a probable shift of the aiming line from the center of the macular fovea to the macula, including because the area of the macula is approximately 100 times larger than the area macular pits. The process of drawing the aiming line is verified by experiment - an attempt to draw a line from a visible point on the wall (from the target) to the center of the macular fossa - many lines are visible, which of them comes to the center of the macular fossa cannot be determined with the required accuracy. The same result when drawing a return line from the center of the macular fovea to the target.

When controlling the visual axis by three points, the problem becomes many times more complicated - it is necessary to combine two intermediate points with an undefined aiming line. As a result, when aiming, the athlete is forced to control the visual axis and build the aiming line indirectly - according to the relative position of the three external visible aiming points, which requires years of training.

In addition, central vision has the greatest acuity (clarity) at an angle of view of 2.5 degrees, above which the clarity of vision begins to gradually decrease, while the field of central vision in total with the field of peripheral vision along the vertical is 150 degrees, therefore the vertical aiming plane through the field vision of the eye can only be constructed with the involvement of peripheral vision. At the same time, the horizontal plane affects the construction of the vertical plane as an additional reference point.

Thus, the disadvantages of an open sight are:

- the athlete does not physiologically know where at the moment of aiming the macular fossa (visual axis), which is not visible to the athlete, is located in relation to the aiming line - to the left, right, below, above.

- an indirect way to control the position and visualization of the macular fossa and the visual axis that are not visible to the athlete relative to the aiming line - by the relative position of the visible recess of the rear sight, front sight and target.

- absence of visible vertical and horizontal lines, which are the orientation base for central and peripheral vision when constructing a line and a vertical aiming plane similar to the lines of the telescopic sight reticle, www.yandex.ru Pictures. Sighting reticle. At the same time, the greater part of the field of view is occupied by the reticle, the larger the base, the more accurate aiming.

- not versatility of use, since the open sight cannot be used in other sports where line of sight is required.

At the same time, any gamma angle in an open sight does not affect the aiming accuracy.

There is a universal method of aiming in various sports by drawing aiming lines through intermediate targets (similar to intermediate rear sight and front sight in an open sight), for example, in billiards through the visible part of the cue, cue ball and aiming ball, www.iknigi.net Alphabet of billiards, p. 5, fig. 39, A. L. Loshakov. Similarly: in curling through a granite stone, in darts through a dart, in archery through a bowstring and an arrow, in golf through a ball and a club head.

A common feature is that the aiming eye, intermediate targets and the target are located at different heights in relation to each other, but are located in the same vertical aiming plane, in which the aiming line moving along the height is located.

For example, in billiards the aiming eye, intermediate targets - the visible part of the cue, the cue ball and the aiming ball are located at different heights from the table surface and not on one straight line. Therefore, an aiming line moving along the height is drawn between them, but in one common vertical aiming plane. This is only possible with the simultaneous use of central and peripheral vision.

The disadvantages of this aiming method repeat the disadvantages of the previous analogue:

- the athlete does not physiologically know where, at the moment of aiming, the macular fossa (visual axis) is located invisible to the athlete.

- an indirect way to control the position and visualization of the macular fossa and the visual axis invisible to the athlete relative to the aiming line.

- absence of visible vertical and horizontal aiming guidelines for building a line and vertical aiming plane.

At the same time, any gamma angle in this method does not affect the aiming accuracy.

Known contact lenses for vision correction, containing the optical part in the form of masks with apertures of different light transmittance, with elements of various shapes and sizes with the ability to visualize objects in the field of view of the apertures, while the center of the apertures is located in the center of the pupil, patent US 3794414, description, par. 15, patent US 5980040, description, Summary of the invention, para. 3.

No patent descriptions, but presumably these contact lenses can be used as aiming lenses.

The advantage of medical contact and implantable lenses with masks and apertures when aiming will be that the athlete sees the aperture, the eyeball moves with the aperture - it is possible to control the positions and movements of the visual axis of the eye along the visible aperture, while the gamma angle is an essential condition for aiming.

A common disadvantage of lenses when aiming is that the center of the aperture is set in the center of the pupil and the center of the cornea, therefore, when the gamma angle is not equal to 0 degrees, the center of the aperture is set offset from the visual axis of the eye. As a result, the visual axis cannot go through the center of the aperture - aiming is not accurate.

With a total gamma angle range of 11 degrees (-3 ... + 8 degrees), the mathematical probability of equal 0 degrees gamma angle, at which the visual axis passes through the center of the pupil, is 1/12 × 100% = 8.3%. And since most people have a typical gamma angle of 5 degrees, the likelihood of a gamma angle of 0 degrees is even less. At any gamma angle, the center of the aperture can be accidentally aligned with the visual axis, but this is even less likely. It is possible to combine the center of the aperture and the visual axis of the eye only with the participation of an ophthalmologist and using medical devices, for example, on a surgical microscope, similar to RU 2673953, description, para. [0041], or on an ophthalmoscope, www.glazamed.ru 18.2.1.2 Imaginary squint.

Disadvantages when aiming are:

- the impossibility of the athlete's self-alignment of the center of the contact lens aperture and the visual axis of the eye.

- the athlete does not physiologically know where, at the moment of aiming, the macular fossa (visual axis) invisible to the athlete is located.

- an indirect method of position control and visualization of the macular fossa invisible to the athlete and the visual axis relative to the aiming line.

- peripheral vision is obstructed by an opaque area.

- not universality of application.

Known intraocular lens for the treatment of presbyopia, containing an optical part in the form of an annular mask with an aperture, the optical axis of which during installation can be offset by 1 mm from the geometric axis, patent RU 2673953 or EP 3199127 (A1).

The patent specification is not contained, but presumably this lens can be used as an aiming lens.

The advantage is that during installation, the optical axis of the aperture can be aligned by rotation of the lens with the visual axis of the eye, description of patent RU 2673953, para. [0040], para. [0041].

The disadvantages are:

- For athletes with normal vision, surgery is not acceptable.

- absence of visible vertical and horizontal aiming guidelines when building a line and vertical aiming plane.

The closest technical solution is a contact lens for aiming when firing a firearm. The optical part of the contact lens is made of different light transmittance in the form of an opaque zone with elements in the form of several holes with the ability to visualize intermediate targets and targets, US patent 10473430, 2019.

The disadvantage is that the center of the optical part of the contact lens is set in the center of the pupil of the eye, as described in the description of the patent para. [0044] sentence 6, fig. 11A and 11B indicate, "The user's eyes have pupils (not shown) aligned with line of sight 1206 through the openings of optics 1204. Line of sight 1206A may begin at the pupil ...".

In the description, there is no information about the gamma angle, about the need to take into account the influence of the location of the visual axis relative to the optical axis and the center of the cornea, about how to align the visual axis and the line of sight.

Therefore, in this contact lens for aiming, the center of the optical part is set in the center of the pupil and the center of the cornea, therefore, at a gamma angle not equal to 0 degrees, the center of the hole in the optical part is set with an offset relative to the visual axis, which is equivalent to the offset of the center of the hole in the diopter sight from the target and creates one-sided aberrations, www.meanders.ru Aberrations in optics: definition, types and differences. As a result of this displacement, the visual axis cannot pass through the center of the optical part - aiming is not accurate. In this case, the probability of equality of the gamma angle of 0 degrees is 8.3% (characteristic of the analogue of US 3794414). At any gamma angle, the center of the optical part may accidentally coincide with the visual axis, but this is even less likely.

As a result, the disadvantages of analogues remain and new ones are added:

- one-sided aberrations are created when aiming.

- the impossibility of the athlete's self-alignment of the center of the optical part of the contact lens and the visual axis of the eye.

- the athlete does not know exactly where, at the moment of aiming, the macular fossa invisible to the athlete (visual axis) is located.

- an indirect way to control the position and visualization of the macular fossa invisible to the athlete and the visual axis relative to the aiming line

- peripheral vision is obstructed by an opaque area.

- not universality of application, since it cannot be used in various sports, where central and peripheral vision is required when aiming.

The problem to be solved by the invention is as follows.

When aiming, the movement of the visual axis is controlled indirectly by the relative position of three visible points on the aiming line.

An intraocular lens for the treatment of presbyopia according to patent RU 2673953, if used as an aiming lens, will allow only a small number of operated athletes to control the visual axis along the visible aperture moving with the eye, but without control in the vertical and horizontal plane.

Specifically, the task is to develop a contact lens with an optical part with the possibility of precise objective control by the athlete of the positions and movements of the visual axis in the vertical and horizontal planes when building the aiming line.

The technical results to be achieved when solving the problem are as follows:

- increased aiming accuracy.

- increasing the versatility of using a contact lens for aiming.

The specified technical results in the implementation of the invention are achieved by the fact that in the known contact lens for aiming, containing a contact lens with an optical part of different light transmittance with the possibility of visualizing intermediate targets and targets, the feature is that the optical part is made in the form of an aiming reticle, the elements of the aiming reticle oriented in the vertical plane, while the center of the reticle is aligned with the visual axis of the eye passing through the center of the macular fossa and the target.

In addition, the reticle is designed as vertical and horizontal lines.

In addition, the reticle is designed as two vertical and two horizontal lines with or without a central point.

In addition, the reticle is made in the form of a single vertical line with a central hole.

In addition, the contact lens is made with position stabilization zones and with a predetermined position of the visual axis and the center of the aiming reticle relative to the geometric center of the lens.

In addition, the reticle elements are partially translucent.

The essential feature "contact lens" is expressed by a general concept, since it includes many types of known contact lenses, for example, without diopters, soft, hard, transparent, darkened, taking into account the features of the corneal surface, toric, scleral, iridescent, of various thicknesses and various diameters, single-focus, multifocal, with position stabilization elements, their well-known numerous combinations, for example, some of them according to GOST R 53941-2010 Ophthalmic optics.

The essential feature "the optical part is made in the form of an aiming reticle" is expressed by a general concept, since it includes many known types of reticle with various elements, for example, www.yandex.ru Types of reticle. And also reticle can include some elements of masks, apertures, optical parts of known medical contact lenses and the prototype, for example, holes, recesses, grooves. Some of the elements and unknown types of reticle are given in the embodiments of the present invention.

The rules for choosing a contact lens and a reticle for a sighting device are as follows:

- technical feasibility of performing reticle elements on the contact lens.

- individual features of the athlete's vision.

- features of a particular sport.

Specific combinations of contact lens types and reticle for contact lenses for aiming are selected by performing experiments with different contact lenses and reticle.

The essential feature "the optical part is made in the form of an aiming reticle, the elements of the aiming reticle are oriented in the vertical plane" in all forms of execution is in a causal relationship with the achieved technical results:

- with the technical result "Increased aiming accuracy", since when the aiming line is constructed (by aligning the visible center of the aiming reticle with the visual axis of the eye and the target), two intermediate targets must be combined with the aiming line, while positioning the weapon barrel and the visual axis in the same vertical plane along the visible vertical line of the reticle, using the horizontal line of the reticle as an additional reference point in space, which ensures the achievement of technical results.

- with the technical result "Increasing the versatility of using a contact lens for aiming", since accurate determination of the position of the visual axis relative to the line and the vertical plane of aiming can be applied in various sports, including those using peripheral vision.

The essential feature "the center of the reticle is aligned with the visual axis of the eye" is in a causal relationship with the achieved technical results:

- with the technical result "Increased aiming accuracy", since when the center of the aiming reticle is aligned with the visual axis of the eye, the athlete is able to see the beginning of the aiming line and control the movement of the visual axis of the eye along the visible center and lines of the aiming reticle, for which it is sufficient to move the eye vertically and horizontally align the visible center of the reticle with the target, while the deviation of intermediate targets relative to the aiming line is now determined not indirectly - by their relative position, but objectively by the deviation of each of them from the visible center, reticle lines and the target.

- with the technical result "Increasing the versatility of the aiming device", since a contact lens for aiming with the ability to accurately determine the position of the visual axis relative to the aiming line and intermediate targets in the vertical aiming plane, which does not interfere with the athlete, can be used in various sports where it is required drawing the line and vertical plane of aiming, including using peripheral vision.

Thus, each essential feature individually achieves, and in the aggregate, they increase the indicated technical results.

FIG. 1 shows a diagram of aiming with the right eye with a shift of the visual axis of the eye by a gamma angle of 5 degrees from the optical axis of the eye and a shift of the sighting line from the center of the macular fossa, top view.

FIG. 2 shows a form of execution "reticle is made in the form of vertical and horizontal lines", front view.

FIG. 3 shows the form of execution "the reticle is made in the form of two vertical and two horizontal lines without a central point", front view.

FIG. 4 shows the form of execution "the reticle is made in the form of one vertical line with a central hole", front view.

Information confirming the possibility of manufacturing and operability of a contact lens for aiming in all forms of performance with the achievement of the specified technical results are as follows.

Aiming diagram with an offset of the sighting line from the fossa of the macula, Fig. 1, contains an eyeball 1, a macula 2 (enlarged for clarity) with a fossa 3, visual axis 4 passing through the center of the lens 5, optical axis 6, cornea 7, line of sight 8, not aligned with the visual axis 4 - aiming is not accurate ...

The essential feature "the center of the aiming reticle is aligned with the visual axis of the eye" is possible using medical devices to determine the position of the visual axis of the eye relative to the optical axis of the eye, for example, a surgical microscope similar to RU 2673953, description, para. [0041], or ophthalmoscope, www.glazamed.ru 18.2.1.2 Fictitious squint. At the same time, an ophthalmologist sets up a contact lens to target the athlete's cornea. Since a contact lens for aiming during use during blinking of the eye can move on the cornea and it is required to return it to its original position, for example, during exercise in the gym, the participation of an ophthalmologist and the use of medical devices during installation becomes unacceptable. Self-installation of a contact lens for aiming by an athlete with the alignment of the center of the aiming reticle with the visual axis of the eye provides the second object of the group of inventions - "a device for setting a contact lens for aiming", which is disclosed in the second independent claim.

In the embodiment of the essential feature "the reticle is made in the form of vertical and horizontal lines", FIG. 2, a contact lens for aiming contains a known contact lens 9, for example, soft, without diopters (www.ochkov.net What are the contact lenses by diopters, paragraph 6), for one or two eyes, with a diameter of 13 ... 15 mm with an aiming grid 10 with the center 11 of the intersection of the vertical and horizontal lines, which is aligned with the visual axis 4 of the eyeball 1 (Fig. 1). Contact lens 9 is located on the cornea 7, that is, closer to the anterior focal length of the eye (www.glazamed.ru) 5. Optical system and refraction of the eye, para. 7), therefore, the lines of the reticle 10 will be not clearly visible, indistinct, but with smooth, distinguishable boundaries, similar to the boundaries of masks and apertures of analogs. With a small thickness of lines and other elements of the aiming reticle 10, for example, points, depressions, grooves, approximately 0.5 ... 1 mm, light rays under the action of diffraction (www.ens.tru.ru Fresnel diffraction from the simplest obstacles. Diffraction from a disk, Fig. 9.4) bypass the elements of the aiming reticle 10, connect behind them and are perceived by vision as “passing through the elements”, while the elements of the aiming reticle 10 become “translucent” with smooth, distinguishable boundaries, which is sufficient for seeing and visualizing space, intermediate targets and targets located behind the element. The sizes of 0.5 ... 1 mm of the elements of the aiming reticle 10 are selected taking into account the fact that when the contact lens 9 is located on the cornea 7, the elements of the aiming reticle 10 become visible to the athlete when the size is greater than 0.5 mm (RU 2444334, paragraph 2 of the formula). It is possible to decrease and increase the thickness of the elements, which can be determined experimentally and taking into account the individual characteristics of the athlete's vision. To apply the sighting reticle 10 to the outer or inner side of the contact lens, known paints are used, for example, containing a vinyl copolymer and a dye, patent RU 2074409, description, para. 1, or laser, patent RU 2444334, description to FIG. 5, stage 1. After applying the reticle to the contact lens, it is possible to cover it with a hydrogel layer.

A contact lens 9 for aiming works as follows.

For accurate aiming with a weapon or in other sports, the aiming eye is directed at the target, while the beginning of the aiming line is the visual axis 4 and the center 11 aligned with it, determined by the point of intersection of the lines with the even, distinguishable boundaries of the aiming reticle 10, will align with the target precisely and involuntarily, forming an aiming line 8. Then, by movements of the weapon vertically and horizontally relative to the constructed aiming line, focusing on the vertical and horizontal lines of the aiming reticle 10, two intermediate targets are aligned with the center 11 of the aiming reticle 10 and the target, as a result, the center 3 of the yellow spot 2 , visual axis 4, two intermediate targets and the target will be combined on the same line of sight 8. At the same time, the control of the movements of the visual axis 4 and the construction of the aiming line 8 are carried out not indirectly along two visible intermediate targets and the target, but on the contrary - two intermediate targets are combined with already built aiming line 8, easily controlled by the target reticle 10 and the center 11. Then a shot is fired.

Thus, the construction of the aiming line in the vertical and horizontal planes and an increase in aiming accuracy, as well as an increase in the versatility of the use of the contact lens 9 in various sports, are achieved.

In the subsequent forms of the fulfillment of the essential feature, various elements of the aiming reticle are used, including without the use of diffraction, the parameters of which are indicated approximately and depend on the individual characteristics of the athlete's vision and the sport, while the indicated technical results are achieved in all forms of execution.

In the embodiment "the reticle is made in the form of two vertical and two horizontal lines with or without a central point", FIG. 3, the aiming reticle 10 is distinguished by the specific implementation of the above-described elements and the passage of the visual axis 4 and the aiming line 8 in the center without a central point between two vertical and two horizontal lines of the reticle 10 without using diffraction, while the center 11 of the aiming reticle 10 is determined by the athlete by equality the distances between the four corners of the vertical and horizontal lines, similar to determining the center in the aperture of a diopter sight. The distance between the lines is 0.5 ... 0.7 mm. The aiming reticle 10 with a center point uses diffraction.

In the embodiment "the reticle is made in the form of one vertical line with a central hole", FIG. 4, the aiming reticle 10 is characterized by the specific implementation of the elements described above, while the vertical aiming plane is built along one vertical line of the reticle 10, while the diameter of the central hole is 0.6 ... 0.7 mm. This form of execution complicates the construction of the aiming line and is applicable for athletes with an advanced level of skill before switching to aiming without a contact lens 8.

In the embodiment "the contact lens is made with stabilization zones and with a predetermined position of the visual axis and the center of the aiming reticle relative to the geometric center of the lens", the contact lens 9 is equipped with known stabilization zones, similarly, for example, to the stabilization zones of toric lenses or RU 2533324 for specific features of the structure and movement eyeball in specific sports and individual characteristics of an athlete's vision. In this case, the coordinates of the location of the point of intersection of the visual axis 4 with the cornea 7 vertically and horizontally, coinciding with the center of the sighting reticle 11, are determined prior to the manufacture of the lens on a surgical microscope similarly to RU 2673953, description, para. [0041], or on an ophthalmoscope, www.glazamed.ru 18.2.1.2 Imaginary squint. According to the results of determining the location, a contact lens 9 is made with an aiming reticle 10 with a given offset center 11 and the orientation of the lines of the aiming reticle 10 in the vertical plane relative to the geometric center of the contact lens and installed on the cornea 7, while the center 11 of the reticle 10 coincides with the visual axis 4 eyes and is offset from the geometric center of the stabilized lens. Stabilizing elements can be made on contact lenses for aiming various types and purposes, including sports and medical, and the use of the second object of the group of inventions - "a device for installing a contact lens for aiming" may not be required, depending on the reliability of stabilization.

In the form of execution "the elements of the aiming reticle are made partially translucent" the elements of the aiming reticle are made with paint with a low concentration of dye, providing partial light transmission of the elements, for example, 10 ... 20%, while the concentration of the dye is selected experimentally. Due to this, partial light transmission of the elements will be added to the action of diffraction, which, if necessary, will increase the clarity of vision of intermediate goals and targets.

Thus, the above information confirms that the first object of the group of inventions "contact lens for aiming" is intended for aiming in all forms of performing essential features, confirms their feasibility with the achievement of the specified technical results.

According to the second object of the group of inventions "a device for installing a contact lens for aiming" is intended for implementation, specifically for self-installation by an athlete on the cornea of the eye of the first object of the group of inventions "contact lens for aiming" with exact alignment of the center of the aiming reticle with the visual axis of the eye and orientation of the aiming lines grids in the vertical and horizontal planes.

Known medical devices for determining the position of the visual axis of the eye relative to the optical axis of the eye, which can be used when an ophthalmologist installs a contact lens for aiming at the athlete's cornea, for example, a surgical microscope similar to RU 2673953, description, para. [0041], or ophthalmoscope, www.glazamed.ru 18.2.1.2 Fictitious squint.

The disadvantage is that to install a contact lens, you need to go to a medical institution, and since a contact lens for aiming during use during blinking of the eye can be displaced on the cornea and it must be returned to its original position, for example, during exercise in a gym, then going to a medical facility becomes unacceptable.

There is a known method of installing a contact lens on the cornea, in which the contact lens is placed on a finger, www.medportal.ru Installation of contact lenses.

The disadvantage is insufficiently reliable retention of the contact lens on the finger with contact only in the center of the contact lens with possible partial deformation of the contact lens.

Known devices for installing a contact lens, containing a contact lens holder in the form of a nipple located in the center of the contact lens, a ring to prevent the eyelids from closing and a handle, US 3781050, US 3645576.

A device for installing a contact lens is known, comprising a contact lens holder in the form of a nipple located in the center of the contact lens, RU 2048797.

Closest to the claimed invention is a device for installing a contact lens on the cornea, containing a contact lens holder in the form of a nipple, located in the center of the contact lens with a diameter of 1 ... 3 mm less than the diameter of the contact lens, handle at an angle to the plane of the contact lens with a pump and air duct , www.gallus.ru Lens suction cup DMV 45.

A common disadvantage of the method and devices, except for medical ones, when installing a contact lens for aiming at the cornea is that when approaching the eye, a finger or nipple located in the center of the contact lens overlaps and darkens the central zone of the eye's field of view, so the visual axis of the eye has to be oriented only on the approaching darkened poorly visible center, vertical and horizontal lines of the reticle of the contact lens for aiming. However, the use of a mirror does not improve visibility in the central zone of the eye's field of view. Under such conditions, it is almost impossible to draw a line between the macular fossa and the center of the reticle and align them on the visual axis.

The problem to be solved by the invention is to develop a device for self-installation by an athlete of a contact lens for aiming at the cornea with precise alignment of the center of the reticle with the visual axis of the eye and creating landmarks for constructing a vertical aiming plane by eliminating a technical problem - overlapping by a contact lens holder for aiming the central zone of the visual field.

In this case, the darkening of the contact lens will be eliminated and the possibility of a clear vision of the space located further than the contact lens with an increase in the orientation base of the reticle in the vertical and horizontal plane will be created.

The technical result to be achieved with the implementation of the invention consists in "increasing the accuracy of alignment of the center and lines of the reticle of the contact lens for aiming with the visual axis of the eye in the vertical and horizontal plane without the use of medical devices."

An additional technical result is an increase in the accuracy of installing medical and sports contact lenses with masks and apertures relative to the visual axis.

The specified technical results in the implementation of the invention is achieved by the fact that in the known device for installing a contact lens, containing a contact lens holder and a handle at an angle to the plane of the contact lens, the feature is that the contact lens holder for aiming is provided with a light-transmitting zone, the sighting reticle of the contact lens aligned with the visual axis of the eye and an external sighting reference located at a distance from the holder.

In addition, the contact lens holder is configured as a contact lens support ring.

In addition, the contact lens holder is made in the form of a support ring for a contact lens, the support ring is equipped with a nipple with an air duct, and the handle is equipped with a pump.

In addition, the external sighting landmark, located at a distance from the holder, is made in the form of any external point on the vertical line from those available at a distance of 1 ... 2 m on the wall covering, or pre-selected, for example, on wallpaper, or in the corner of the room, or fixed on the wall or on the mirror of a plasticine ball with a diameter of 2 ... 3 mm, or a cord with an external point and a weight attached to the wall, or an additional aiming reticle shown on a sheet of A0 paper and fixed on the wall.

The essential feature "light-transmitting zone" is expressed by a general concept, so it is not possible to determine its exact maximum and minimum dimensions, while taking into account the design of the holders, it should be the largest possible size, for example, with a diameter of 5 ... 7 mm, and in a particular form of execution in the form of a light-transmitting sphere should be as light-transmitting as possible, for example, more than 90% to visualize the space behind the holder.

The essential feature "the holder of the contact lens for aiming is equipped with a light-transmitting zone":

- is expressed by a general concept, since there are two possible forms of its implementation with different designs of parts.

- is in a causal relationship with the technical results, since the translucent zone in the holder makes it possible to clearly see any external point located further than the contact lens, for example, at a distance of 1 ... 2 m on the wall, while the visual axis is precisely and involuntarily set on external point (not shown in the figures), www.ru.wikipedia.org Eye movement - Wikipedia, para. 3, www.eyepress.ru In which direction does the eye look, par. 6, last sentence of the paragraph, fig. 2, Kuznetsov Yu.V. At the same time, for the exact alignment of the center of the aiming reticle with the visual axis and the goal, it is enough for the athlete to align the center of the reticle vertically and horizontally with a clearly visible outer point. In addition, the light-transmitting area of the holder makes it possible to increase the accuracy of the installation of medical and sports contact lenses with masks and apertures along the outer point, including in front of the mirror. This ensures the achievement of the specified technical results.

An essential feature "and an external sighting landmark located at a distance from the holder" (not shown in the figure):

- is expressed by a general concept, since seven forms of its implementation with various designs of parts are possible.

- is in a causal relationship with the technical and additional technical result, since it is an external goal, on which the visual axis of the eye is precisely and involuntarily set, and is also a reference point in the vertical plane for the elements of the reticle.

FIG. 5 shows a device for installing a contact lens for aiming in the form of execution "the holder of a contact lens is made in the form of a support ring for a contact lens" eyes, front view from the side of an athlete, M1: 1.

FIG. 6 - the same, side view.

FIG. 7 shows a device for installing a contact lens for aiming in the form of execution "the contact lens holder is made in the form of a support ring for a contact lens, the support ring is equipped with a nipple with an air duct, and the handle is equipped with a pump", in the handle position at 45 degrees, front view, M2: 1.

FIG. 8 - the same, side view.

Information confirming the possibility of manufacturing and operability of the device for installation in all forms of execution with the achievement of the specified technical results are as follows.

In an embodiment of the essential feature "the contact lens holder is in the form of a contact lens support ring", FIG. 5, 6, the device contains a support ring 12 made of a flexible elastic material, for example, medical silicone rubber, with a hole diameter of 5 ... 7 mm, with an outer diameter less than the diameter of the contact lens 9 by 1 ... 2 mm, for example, 12 mm, thickness 2 ... 2.5 mm, the profile of the inner surface of the support ring 12 corresponds to the profile of the contact lens 9, handle 13. The device is made according to the technology of the analogue "Suction cup for lenses DMV 45", but without an air duct and pump.

The device works as follows.

The athlete places the contact lens 9 on the support ring 12, while the axis of the handle 13 is positioned at an angle of 45 degrees to the lines of the reticle 10 so that the handle 13 does not coincide with the vertical and horizontal lines of the reticle 10 when the contact lens 9 approaches the cornea 7 and does not overlap in these places, the vertical and horizontal areas of peripheral vision. Since the contact lens 9 is stored in a disinfectant solution before installation, during installation it is in a wet state and adhesion (adhesion) acts between the surface of the contact lens 9 and the inner surface of the support ring 12 when they contact, (www.ru.wikipedia.org Adhesion ), which is practically sufficient to hold the contact lens 9 in the support ring 12 in an upright position. For example, a contact lens 9 is held on a vertical finger (analog).

Then he brings the support ring 12 with a contact lens 9, with his left hand to the left eye, with the fingers of his right hand holds the eyelids of the left eye in an open position and directs his gaze horizontally to any external point on a vertical line from those available at a distance of 1 ... 2 m on the wall covering, or pre-selected, for example, on the wallpaper, or in the corner of the room, or on a plasticine ball with a diameter of 2 ... 3 mm fixed on a wall or mirror, or on a cord with an external point and a weight attached to the wall, or on the center of an additional aiming reticle shown on the sheet paper of size A0 and mounted on the wall.

Then he aligns the center 11 (Fig. 2), defined as the point of intersection of lines with smooth, distinguishable boundaries of the aiming reticle 10 with an external point on the wall, while, since the visual axis 4 is also involuntarily directed to an external point on the wall, and the center 11 is at the minimum possible distance from the center of the fossa 3 of the yellow spot 2 at the beginning of the aiming line 8 (Fig. 1), then the center 11 of the many possible lines from the outer point on the wall to the yellow spot 2 will be combined precisely with the visual axis 4 and the center of the fossa 3 of the macula 2. At the very least, the alignment is done in a controlled, controlled manner and with a high probability of the required accuracy. Then the lines of the reticle 10 are aligned with the outer point and the vertical line on the wall. When they are combined, sets the contact lens 9.

With a possible partial tilt and / or turn of the head forward or to the side to the position required for aiming in specific sports, for example, billiards, the contact lens 9 is preferably mounted on the cornea 7 in this specific position of the head with the targeting reticle 10 oriented vertically. It is possible by rotating the eyeball 1 to restore the position of the installed sighting reticle 10 in the vertical aiming plane.

The procedure for installing a contact lens 9 on the cornea 7 using this device is rather complicated, therefore, in the beginning, in a certain number of attempts, inaccurate alignment and training is possible. But, even a few tests and short-term use of a contact lens 9 with a reticle 10 give the athlete sensations, knowledge and a mechanism for precise visualized control of the movements of the fossa 3 of the macula 2, the visual axis 4 and the eyeball 1 in the vertical and horizontal planes and relative to the aiming line. Over time, an athlete, taking into account the individual characteristics of vision or the peculiarities of the position of the head when aiming in various sports, may come to a decision, for example, to set one of the lines of the reticle 10 not vertically, but return it to a vertical position by rotating the eyeball 1 relative to the visual axis 4, or at the last stage, before installation, align the visual axis 4 first with the vertical line of the reticle 10 and then with the outer point by moving the visual axis 4 and the center 11 of the reticle 10 vertically and then install the contact lens 9 on the cornea 7, or develop another one for yourself individual control procedure for the visual axis 4 and the aiming reticle 10 using the present invention. In any case, these actions represent a conscious, visible, controlled and precise control of the visual axis 4 to improve aiming accuracy. As a result, in the process of training, the alignment of the center 11 of the aiming reticle 10 and the visual axis 4 will become accurate and reliable with all the features of aiming, which ensures the achievement of the indicated technical results.

In an embodiment of the essential feature "the contact lens holder is made in the form of a support ring for a contact lens, the support ring is equipped with a nipple with an air duct, and the handle is equipped with a pump", FIG. 7, 8, the device contains a support ring 12 with a hole diameter of 5 ... 6 mm, the outer diameter is 1 ... 2 mm less than the diameter of the contact lens 9, made of a flexible elastic material, for example, from medical silicone rubber, a nipple 14 with an air duct to enhance retention contact lens 9. Support ring 12 with air duct are made according to, for example, casting technology www.top-plast.ru Production of plastic products, or according to the technology of analogue "Suction cup for lenses DMV 45", or according to the technology www.youtube.com Example of printing on 3d printer Chos Creator 2.0. The support ring 12 is connected to the handle 13, which is equipped with a pump 15. The support ring 12 with a nipple 14 and an air duct can be made as a separate part from the pump 15 and then sealed.

The device works as follows.

The athlete places the contact lens 9 on the support ring 12 similarly to the previous embodiment, then, due to the vacuum created by the pump 15, holds the contact lens 9, including the nipple 14, and directs his gaze horizontally to the outer point. Further, similar to the previous form of execution.

After installing the contact lens 9 on the cornea 7 with a pump 15, the vacuum is removed, air is supplied and the contact lens 9 is left on the cornea 7.

This ensures the achievement of the specified technical results.

Thus, the above information confirms that the "device for installing a contact lens for aiming" is intended for installing a contact lens for aiming at the cornea with alignment of the center of the aiming reticle with the visual axis of the eye and orienting the lines of the aiming reticle in the vertical and horizontal plane in all forms of performing essential signs, confirm their feasibility with the achievement of the specified technical results.

The claimed group of inventions meets the requirement of unity of invention, since the group of inventions forms a single design concept, while the second object of the group of inventions - "device for installing a contact lens for aiming" is intended to implement the first object of the group of inventions - "contact lens for aiming". In this case, the second object of the group of inventions ensures the implementation of all essential features of the first object and the achievement of the specified technical results.

Claims (10)

1. A contact lens for aiming, containing a contact lens with an optical part of different light transmittance with the possibility of visualizing intermediate targets and a target, characterized in that the optical part is made in the form of an aiming reticle, the elements of the aiming reticle are oriented in the vertical plane, while the center of the aiming reticle is aligned with the visual axis of the eye, passing through the center of the macular fossa and the target. 2. The contact lens of claim. 1, characterized in that the reticle is made in the form of vertical and horizontal lines. 3. The contact lens of claim. 1, characterized in that the reticle is made in the form of two vertical and two horizontal lines with a central point or without a central point. 4. The contact lens of claim. 1, characterized in that the reticle is made in the form of one vertical line with a central hole. 5. A contact lens according to claim 1, characterized in that the contact lens is made with position stabilization zones and with a predetermined position of the visual axis and the center of the aiming reticle relative to the geometric center of the lens. 6. A contact lens according to claim 2, or 3, or 4, or 5, characterized in that the elements of the aiming reticle are partially translucent. 7. A device for installing a contact lens, containing a contact lens holder and a handle at an angle to the plane of the contact lens, characterized in that the contact lens holder for aiming is provided with a light-transmitting zone, the reticle of the contact lens is aligned with the visual axis of the eye and an external sighting landmark located on distance from the holder. 8. The device according to claim 7, characterized in that the contact lens holder is made in the form of a contact lens support ring. 9. The device according to claim. 7, characterized in that the contact lens holder is made in the form of a support ring for a contact lens, is equipped with a nipple with an air duct, and the handle is equipped with a pump. 10. The device according to claim 7, characterized in that the external sighting landmark located at a distance from the holder is made in the form of any external point on a vertical line from those available at a distance of 1 ... 2 m on the wall covering, or preselected, for example, on wallpaper, or in the corner of the room, or a plasticine ball with a diameter of 2 ... 3 mm fixed on the wall or a mirror, or a cord with an external point and a weight attached to the wall, or an additional aiming reticle shown on a sheet of A0 paper and fixed on the wall.

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