RU2803543C1 - Device for training binocular vision and method of using it - Google Patents

Abstract

FIELD: medicine.

SUBSTANCE: group of inventions relates to a device for training binocular vision and a method of training with its help. The device includes an apparatus for training binocular vision and a control unit. The device contains a working part and a chin rest with the ability to adjust to the size of the patient's face, as well as a support plate. On the front panel of the working part there are two holes for the eyes and a hole for the nose. The front part of the body bottom and lid has a concave headrest. Two vertical slots are formed in the rear wall of the housing, while in the near vertical slot there is a movable nozzle made with two straight slots, one of which is made vertically and the other is made horizontally. In the middle of the straight slots there are keyhole-shaped slots for a double-sided key. Spotlights are located in the far vertical slot of the rear wall of the case. LED strips are attached to the inside of the rear wall of the case with the ability to blink. On both sides of the longitudinal partition, backlight LEDs are attached to the bottom of the housing with the ability to illuminate the slots of the movable nozzle. The control unit contains an electronic circuit that ensures the operation of the device according to a computer program, which includes a board, an encoder with the ability to change data and settings, a piezo emitter with the ability to send an audio signal, a connecting cable connected to spotlights, LED strips, backlight LEDs and a power adapter. The front panel of the control unit contains the following: a display, an encoder shaft, buttons for controlling the spotlights and the current blinking cycle. To train binocular vision, the height of the working part and the chin rest is adjusted to the size of the patient’s face. Then the brightness of the LED strips on the control unit; light time; number of blinking cycles of LED strips; interval between them are also adjusted. The patient's chin is placed on the chin rest, the movement of the forehead is limited by the head support, the position of the eyes and nose is correlated with the holes intended for them. When the patient is positioned in such a way that the gaze of each eye is directed to the center of the slot in the form of a keyhole for a double-sided key, located in the center of a straight slot on the movable nozzle, two lights are made — one for each eye by turning on the spotlights, for which the corresponding buttons are turned on and off control the spotlights on the front panel of the control unit for a specified time. The LED strips are turned on and the countdown timer is started by turning on the corresponding control buttons for the current flashing cycle for a predetermined time. When the number of flashes reaches the number of flashes set in the settings, the piezo emitter emits a customized signal indicating the end of the course of flashes.

EFFECT: quality and convenience of training binocular vision is improved due to the design features of the device and the possibility of automating the training process.

4 cl, 3 dwg, 2 ex

Description

The claimed invention relates to medical equipment, in particular to devices for ophthalmology, and can be used as training for binocular vision in case of strabismus.

Strabismus is the deviation of one of the eyes from the joint point of fixation, which is accompanied by impaired binocular vision.

The brain of those who squint receives asymmetrical visual information and in 90% of them develops the habit of “cross-eyed vision.” The earlier the disease occurred, the later its treatment began, the stronger this habit is. Attempts to eliminate such strabismus only through surgery are doomed to failure. After it, the brain, which does not have the skill of “straight-eyed vision”, due to its habit of “cross-eyed vision”, will give a command to the eye muscles to restore the original, habitual “squinting” position of the eyes. Therefore, before surgery in such a patient, it is necessary to weaken the abnormal habit as much as possible by constantly blocking (occlusion) of one or the other eye and, against this background, teach him normal, “direct-eyed vision.” Training begins with the use of the method of sequential images.

If you first look for some time with your right eye at the center of a bright, horizontally located, linear light source, and then with your left eye at the center of a vertically located one, then immediately after such illumination, non-squinting faces with good vision with their eyes closed for a certain period of time (from several seconds up to 1-5 minutes) they see light stripes that form the shape of a cross. Those with strabismus, complicated by “cross-eyed vision,” see either only one of the stripes, or both stripes located in different places.

The well-known method of Prof. Pospelov, aimed at developing correct vision with two eyes, made, for example, based on a flash lamp (hereinafter referred to as the lamp) [https://zreni.ru/articles/narodnaya-medicina/708-roditelyam-i-pacientam-o-sliyanii -posledovatelnyh-obrazov-po-metodu-prof-vi-pospelova.html].

The light opening of the lamp is covered first with white paper - tracing paper, then, on top of it, with an opaque screen made, for example, of cardboard. A hole in the form of a keyhole is first made in the screen for a double-sided key. The diameter of the central circle in this hole is made 5-10 mm, the width of the side slots should be less - 3-5 mm, the length of the slots does not matter. In the center of the round part of the hole, a mark is applied to tracing paper with a pencil or pen to fix the gaze in the form of a clearly visible point.

The training is carried out as follows. The patient closes his left eye tightly, and a lamp is placed in front of him at a distance of 15-20 cm from the right eye so that the holes in the screen are horizontal. The patient is asked to fixate the fixation mark with his right eye, after which, pressing the lamp switch, a flash is made. Then the patient tightly closes the illuminated right eye and opens the left. The lamp is rotated 90° so that the slots in the screen are vertical. The patient is asked to gaze at the fixation mark with the left eye and the same flash is made.

After exposure, the patient closes both eyes and observes the so-called sequential image. In this case, 3 options for its perception are possible. With normal “straight-eyed” perception, he sees vertical and horizontal stripes that form the figure of a cross. When normal perception is suppressed, he sees either a horizontal strip or a vertical one. In this case, the strips replace each other in one place. With “cross-eyed vision,” vertical and horizontal stripes are visible simultaneously, but they are located in different places. After some time, the patient stops seeing either the entire sequential image or part of it (horizontal or vertical stripe). Thus ends one flash.

At the beginning of treatment, it is necessary to determine the duration of vision of a sequential image in order to then determine the number of exposures performed daily. For example, if a consistent image is maintained for 2 minutes, and treatment is recommended for 60 minutes, then, therefore, 30 exposures need to be done daily (60:2 = 30).

If you have “cross-eyed” vision, the patient should exercise daily for a total of at least 60 minutes. Having closed his eyes after the light, he should strive to fix his attention as quickly as possible either on the center of the vertical or on the center of the horizontal strip so that each of them, while fixing attention on it, is perceived as located not only directly in front of the eye, but also directly in front of him . In some cases this can be helped this way. The light from a table lamp is directed onto the patient's face. The patient, keeping his eyes closed, additionally covers one or the other eye with his hand. In other cases, it works better if the patient additionally closes both eyes tightly with his palms. As the speed of alternating fixation increases, the strips come closer to each other and after some time “merge”, forming a “cross” figure as a whole. As soon as this happens, the patient must continue alternately fixing the strips, but now he needs to look not at their center, but at the side protrusions (ends of the cross), for example, like this: top - right - bottom - left - top and so on. After some time, the “cross” figure will begin to appear in him immediately after the light is illuminated and his eyes are closed. To consolidate the resulting normal perception, daily exercises must be continued with the same duration (at least 60 minutes per day) for another month, after which the training time is reduced by 3-4 times. Then these exercises are carried out for 15-20 minutes daily until the end of strabismus treatment and for about 3 more years after the occlusion is cancelled.

The disadvantage of this known method is the need for the participation of a second person (doctor or parents) to carry out treatment due to the lack of automation of the training process.

Known eye exercises using the method of Prof. T.P. Kashchenko [http://vizhusuper.ru/uprazhneniya-dlya-glaz-po-kashhenko/?ysclid=ljbw6euhqr74284034] is a system of eye training for concomitant (convergent) strabismus, which is accompanied by diplopia. The essence is a method in which, under the supervision of a doctor, illumination of the diseased eye is carried out using a special medical device “Mirage”. The device is placed on the table, the patient is seated on a chair in front of it and asked to cover the healthy eye so that light does not fall on it. The affected eye needs to look forward. Then the device is turned on, a flash occurs, and the retina of the eye is illuminated. The duration of the lesson is several minutes.

There is a known patent for a utility model for the Mirage device RU No. 113655 “Device for training binocular vision”, the essence is a device for training binocular vision by the method of negative sequential visual images, including two independent light sources with opaque racket-shaped marks glued to them, “ handles facing in opposite directions, characterized in that it is additionally equipped with a screen, a screen illuminator, controls for light sources and a screen illuminator in the form of push-button switches located on the base of the device, while the light sources and the screen illuminator are made on flat LED matrices, covered with a matte diffusing mask, and placed in separate rectangular housings, fixed in a vertical plane perpendicular to the base and parallel to the screen, with the possibility of angular movement of each of them around the longitudinal axis.

The disadvantage of the known method of Prof. T.P. Kashchenko and, accordingly, the well-known patent RU No. 113655 is insufficient quality and convenience of the training process due to:

- partial lack of automation of the training process due to the lack of a control unit with an installed computer program;

- the impossibility of conducting training in universal conditions, since it is necessary to do flashing in a dark room due to the lack of a device body;

- lack of a chin rest and forehead rest, which is inconvenient for the patient, and leads to the risk of “defective” highlights (which contain double images) due to involuntary movement of the patient’s head;

- impossibility of use at any angle of strabismus, which reduces the number of patients, since in the presence of a strabismus angle of more than 5 degrees, abnormal retinal correspondence and pathological (asymmetric) binocular vision may develop.

There are known photoflashes with attached filters for merging successive negative images according to the method of Prof. Pospelov, for example:

- flash lamps for the diagnosis and treatment of anomalies of retino-cortical correspondence (Krasnoyarsk) and visual fixation according to Küppersug: Krasnodar, Laboratory of Vision Protection and Rehabilitation - U20 “Compact Mini”, V24 “Home+”, P30 “Prof Clinic”, V36 “Maxi Light” [http://zreniedetey.ru/?page_id=45];

- flash with changing attachments, Ulyanovsk, manufacturer Oksana Ivanovna Sofronova [https://oftalab.ru/11-2/zasvet];

- flash lamps [https://www.youtube.com/watch?app=desktop&v=uWtDjiqOqUU], manufactured by Mikhail Smolin.

The disadvantage of the known devices (flashes) is that they only allow you to create an image, in contrast to the stated technical solution, which makes it possible to increase the convenience of training by automating its process.

The identified analogues coincide with the declared technical solution according to individual matching features, therefore the prototype has not been identified and the claims are drawn up without a restrictive part.

The technical result of the claimed technical solution is the development of a device for training binocular vision, which improves the quality and convenience of training binocular vision compared to known analogues due to:

- automation of the training process thanks to the declared design and electronic circuit of the control unit, working according to the applicant’s computer program, which allows:

set a specific blinking time for the LED strips, while an automatic timer counts down the time and produces a sound notification about the end of the blinking cycle, while the counter displays the total number of blinking cycles and the time of the current blinking cycle,

• set the brightness, as well as the blinking frequency or constant lighting of the light strips,

• display all data and settings, for example, blinking cycle time, number of blinking cycles completed, brightness settings, interval between blinking, etc. (when using previously described devices - photo flashes in analogues), the timer is started manually or the hourglass is turned over and monitored them, while manually marking the total number of blinking cycles on paper),

• set the patient’s favorite melody (especially important for a child) after completing all blinking cycles, which stimulates him to complete the entire course in order to quickly hear the melody;

- minimizing the participation of a second person in the process of performing the training - the patient can successfully perform it independently thanks to the presence of a control unit operating under a computer program;

- the ability to conduct training in universal conditions, allowing you to make exposures in a room with any lighting, including during daylight hours, thanks to the presence of the device body;

- the possibility of fixing the patient’s head due to the presence of a chin rest 8 and a headrest 9, which is convenient for the patient and additionally leads to a reduction in the risk of “defective” exposures (in which double images are present) due to the absence of the risk of involuntary movement of the hand of the second person ( for example, a doctor) holding a flashlight, or a patient's head shaking;

- the possibility of use for any amount of strabismus, which expands the range of patients, in contrast to the Mirage device, when used, in the presence of a strabismus angle of more than 5 degrees, abnormal retinal correspondence and pathological (asymmetric) binocular vision can develop.

The essence of the claimed technical solution is device for training binocular vision,containing device for training binocular vision and control unit; wherein the apparatus for binocular training contains a working part and a support plate connected to each other by pins with the ability to move the working part and the chin rest up and down along the pins to adjust to the size of the patient's face; the studs contain fasteners with the ability to fix the working part and the chin rest; the working part contains a body with a longitudinal partition and a removable lid, on the front panel of the case there are two holes for the eyes and a hole for the nose, the front part of the bottom of the case and the lid has a concave head rest with the possibility of a tight fit of the patient's face to the front panel of the case; the rear wall of the housing is made triple with the formation of two vertical slots, while in the near vertical slot there is a movable nozzle made with two straight slots, one of which is made vertically and the other horizontally, while in the middle of the straight slots there are keyhole-shaped slots for double-sided key; at the same time, spotlights are placed in the far vertical slot of the rear wall of the housing; LED strips are attached to the inside of the rear wall of the case with the ability to ensure their blinking; on both sides of the longitudinal partition, backlight LEDs are attached to the bottom of the housing with the ability to illuminate the slots of the movable nozzle; Below the body, on the front studs, there is a movable chin rest for the patient; on the front part of the base plate there is a clamp for attaching the apparatus for training binocular vision to a horizontal surface; the control unit contains an electronic circuit that ensures the operation of the device for training binocular vision according to a computer program, while the electronic circuit contains an Arduino board, a display with the ability to visually monitor training parameters and settings, an encoder with the ability to change data and settings, a piezo emitter with the ability to send an audio signal about the end of the cycle of flashing and playing music at the end of the session, connecting cable connected to spotlights, LED strips, backlight LEDs; power adapter; The front panel of the control unit contains: display, encoder shaft, spotlight control buttons, control buttons for the current blinking cycle; the control unit is connected to a 220 V network with an electrical cord; The power adapter is designed to convert a voltage of 220 V into a voltage of 5 V, which is necessary for the operation of the electronic circuit. Device for training binocular vision according to claim 1.characterized by the fact that The studs are made smooth or threaded. Device for training binocular vision according to claim 1.characterized by the fact that fastening elements are made in the form of screws or wing nuts. Method of using a device for training binocular vision according to claim 1,consisting in the fact that adjust the height of the working part and the chin rest to the size of the patient’s face by moving them along the studs and then fixing them with fasteners; by rotating the encoder, they move through the menu items and configure the parameters necessary for training on the control unit: the brightness of the LED strips; the time during which successive images are stored - the exposure time; number of blinking cycles required; the interval between them; then exit the settings menu and save them by pressing the encoder, while the settings are written to the internal memory of the Arduino board and are not erased when rebooting; in this case, moving through menu items, changing and saving them are reflected on the display; turning on and off the spotlights is carried out using the spotlight control buttons, and the type of the current blinking cycle - either alternate blinking, or joint blinking, or no blinking, is configured using the buttons for controlling the current blinking cycle with alternating blinking, controlling the current blinking cycle with joint blinking, controlling the current blinking cycle with no blinking, respectively, in accordance with the computer program algorithm; the patient places his chin on the chin rest, with forehead movement limited by the headrest, with the patient's eyes looking into the eye holes and the nose placed into the nose hole; when the device for training binocular vision is connected to the network, the backlight LEDs automatically light up; the patient looks with each eye at the center of the slot in the form of a keyhole for a double-sided key, located in the center of a straight slot on the movable nozzle, and makes two “lights” - one for each eye, for which he turns on and off the corresponding spotlight control buttons on the front panel of the unit control for the required time, while the spotlights are turned on and the light passes from them through a slot in the form of a keyhole for a double-sided key to the patient’s eye; then the patient turns on the corresponding control buttons for the current blinking cycle for a predetermined time, while the LED strips turn on, thereby ensuring the blinking of sequential images, and the countdown timer starts, at the same time, if the control button for the current blinking cycle with alternating blinking is pressed, the LED strips begin to blink alternately, if the control button for the current blinking cycle with joint blinking is pressed, the LED strips begin to blink together if the control button for the current blinking cycle with no blinking is pressed. as a result of illumination with the help of spotlights, the image turned out to be blurry - the LED strips do not blink; after a specified time has elapsed, a sound signal is emitted using a piezo emitter, indicating the end of the current blinking cycle, and 1 is added to the number of flashes, which is equal to zero when turning on the device for training binocular vision, and if the control button for the current blinking cycle with no blinking is pressed, then there is no addition to the number of highlights; after the number of flashes reaches the number of flashes set in the settings, the piezo emitter emits a customized signal notifying the end of the course of flashes for today, while information about the remaining time of the current blinking cycle, as well as the number of flashing cycles already completed, is automatically displayed on the display with the ability for the patient to self-monitor the progress of the training in accordance with the computer program algorithm; after reaching the required number of lights, pre-selected music begins to play from the piezo emitter.

The claimed technical solution is illustrated in Figure 1 - Figure 4.

Figure 1 shows a general view of the claimed device.

Figure 2 shows a view of the claimed device with the cover removed: on the left is a top view, on the right is a ¾ side view.

Figure 3 shows the electronic circuit of the control unit.

Figure 4 shows the conclusion of an ophthalmologist.

Positions in Figure 1 - Figure 3 indicate :

1 - apparatus for training binocular vision,

2 - control unit,

3 - working part,

4 - base plate,

5 - studs,

6 - chin rest,

7 - fastening elements,

8 - body,

9 - longitudinal partition,

10 - removable cover,

11 - holes for the eyes,

12 - hole for the nose,

13 - head support,

14 - movable nozzle,

15 - spotlights,

16 - LED strips,

17 - backlight LEDs,

18 - clamp for fastening,

19 - Arduino board,

20 - display,

21 - encoder,

22 - piezo emitter,

23.1, 23.2 - control buttons for spotlights 15,

23.3 - control button for the current blinking cycle with alternating blinking,

23.4 - control button for the current blinking cycle with combined blinking,

23.5 - control button for the current blinking cycle with no blinking,

24 - connecting cable.

25 - power adapter.

Next, the applicant provides a description of the claimed technical solution.

The claimed device for training binocular vision (hereinafter referred to as the claimed device) contains (Figure 1, Figure 2):

- apparatus for training binocular vision 1 (hereinafter referred to as the apparatus),

- control unit 2.

In this case, the apparatus 1 contains a working part 3 and a base plate 4, connected to each other by pins 5 with the ability to move the working part 3 and the chin rest 6 up and down along the pins 5 to adjust to the size of the patient's face. On the studs 5 there are fastening elements 7 with the possibility of fixing the working part 3 and the chin rest 6.

In particular cases, the studs 5 can be smooth or threaded, and the fastening elements are made in the form of screws or wing nuts, respectively.

The working part 3 contains a housing 8 with a longitudinal partition 9 and a removable cover 10. The parts of the housing 8 are made, for example, of plastic, wood, etc. and are connected to each other, for example, by gluing, a screw connection, etc. In a particular case, the working part part can be made using additive technology on a 3D printer.

On the front panel of the housing 8 there are two holes for the eyes 11 and a hole for the nose 12, the front part of the bottom of the housing 8 and the lid 10 has a concave head rest 13 with the possibility of a tight fit of the patient's face to the front panel of the housing 8.

The rear wall of the housing 8 is made triple with the formation of two vertical slits. In the near vertical slot, a movable nozzle 14 is placed by articulation, made with two straight slots, one of which is made vertically and the other horizontally, while in the middle of the straight slots there are slots in the form of a keyhole for a double-sided key (hereinafter referred to as “keyholes”) (this During further treatment, after the development of binocularity has been achieved, the movable nozzle can be replaced with another one, with other shapes of slits).

In the far vertical slot of the rear wall of the housing 8, spotlights 15 are placed, for example, by gluing, with the possibility of illuminating the patient’s eyes.

On the inside of the rear wall of the housing 8, LED strips 16 are attached, for example, by gluing, with the ability to ensure their blinking, which stimulates the blinking of successive images in the patient.

On both sides of the partition 9, illumination LEDs 17 are attached to the bottom of the housing 8, for example, by gluing, screw connection, etc., with the ability to illuminate the slots of the movable nozzle 14.

Below the body 8, on the front studs 5, there is a movable stand 6 for placing the patient’s chin.

On the front part of the base plate 4 there is a clamp 18 with the possibility of rigidly mounting the apparatus for training binocular vision 1 on a horizontal surface, for example, a table.

Control unit 2 contains an electronic circuit (Figure 3) that ensures the operation of the claimed device according to a computer program developed by the applicant, protected by the Certificate of State Registration of Computer Program No. 2023664515 dated 07/05/2023 “Program for automating the process of merging sequential images using the method of Professor Pospelov.”

The electronic circuit contains: an Arduino 19 board with the ability to change data and settings, for example, blinking cycle time, number of blinking cycles completed, brightness settings, interval between blinking, etc.; display 20 with the ability to visually monitor training parameters and settings; encoder 21 with the ability to control settings of the Arduino board 19; piezo emitter 22 with the ability to give a sound signal about the end of the blinking cycle and playing music at the end of the session; connecting cable 24 connected to spotlights 15, LED strips 16, backlight LEDs 17; power adapter 25.

The front panel of control unit 2 contains: display 20, encoder shaft 21, buttons 23.1, 23.2 for controlling spotlights 15, buttons 23.3, 23.4, 23.5 for controlling the current blinking cycle.

The control unit is connected to a 220 V network with an electrical cord (not indicated in Fig.).

The power adapter 25 is configured to convert a voltage of 220 V into a voltage of 5 V, necessary for the operation of the electronic circuit.

Next, the applicant presents the claimed method of using the claimed device.

The claimed device is assembled according to the algorithm described above.

The base plate 4 is attached to a horizontal surface, for example, a table using a clamp 18. The control unit 2 is connected to the housing 8 using a cord 24.

The height of the working part 3 and the stand 6 is adjusted to the size of the patient’s face by moving them along the studs 5 and then fixing them with fasteners 7.

By rotating the encoder 21, you navigate through the menu items and configure on the control unit 2 the parameters necessary for training: the brightness of the LED strips 16; the time during which successive images are stored (exposure time); number of blinking cycles required; the interval between them; then exit the settings menu and save them by pressing encoder 21. In this case, the settings are written to the internal memory of the microcontroller and are not erased when rebooting. Moving through the menu items, changing and saving them are reflected on the display 20. The spotlights 15 are turned on and off using buttons 23.1 and 23.2, and the type of the current blinking cycle (either alternate blinking, or joint blinking, or no blinking) is configured with buttons 23.3, 23.4, 23.5, located on the front panel of control unit 2, in accordance with the algorithm of the computer program, protected by the Certificate of State Registration of the Computer Program No. 2023664515 dated 07/05/2023.

The patient places his chin on the stand 6, while the movement of the forehead is limited by the stop 13. In this case, the patient's eyes look into the holes 11, and the nose is placed in the hole 12. Moreover, thanks to the presence of the body 8, training can be carried out at any time of the day, including during daylight hours time.

When the device is connected to the network, the backlight LEDs 17 automatically light up.

Due to the backlight LEDs 17, the “keyholes” are illuminated, the patient looks with each eye at the center of such a “keyhole” located in the center of the slot on the nozzle 14, and makes two “illuminations” - one for each eye, for which he turns on and off the corresponding buttons 23.1, 23.2 on the front panel of the control unit 2 for the required time, recommended by the ophthalmologist, while the spotlights 15 are automatically turned on and the light passes from them through the “keyhole” of the nozzle 14 to the patient’s eye.

Then the patient turns on the corresponding buttons 23.3, 23.4, 23.5 for the time specified in the settings, while the LED strips 16 are turned on, which ensures flashing of sequential images, and the countdown timer starts, in this case, if button 23.3 is pressed, the LED strips 16 begin to blink alternately, if button 23.4 is pressed, they blink together, if button 23.5 is pressed, if as a result of illumination with the help of spotlights 15, the image is blurry, the LED strips 16 do not blink. After the time specified in the settings has elapsed, a sound signal is emitted using the piezo emitter 22, notifying the end of the current blinking cycle, the blinking of the LED strips 16 stops, and the backlight LEDs 17 turn on again, and 1 is added to the number of lights on the display 20 (when the device is turned on, the number of lights on display 20 equals zero). Moreover, if button 23.5 is pressed, then no addition to the total number of highlights occurs.

After the number of flashes reaches the one set in the settings, the piezo emitter 22 emits a customized signal indicating the end of the course of flashes for today.

In this case, information about the remaining time of the current blinking cycle, as well as the number of cycles already completed, is automatically displayed on the display 20 with the ability for the patient to self-monitor the progress of the training in accordance with the computer program algorithm.

After reaching the required (configured) number of lights from the piezo emitter 22, pre-selected music begins to play.

Next, the applicant provides examples of specific implementation of the claimed technical solution.

Example 1. Using the claimed device according to the claimed method when making the studs are made smooth, the fastening elements are in the form of screws.

The claimed device was assembled according to the algorithm described above, while the studs were made smooth, and the fastening elements were made in the form of screws.

Patient V., 12 years old, squint 15 degrees. The ophthalmologist prescribed exercises according to the method of Prof. Pospelov daily for 60 minutes.

Patient V. worked out daily for 60 minutes according to the algorithm described above, while training on the claimed device using the claimed method allowed her to independently:

• use an encoder to set a certain blinking time for the LED strips, for example, 3 minutes, while the automatic timer counted down the time and produced a sound notification about the end of the blinking cycle, while the display reflected the total number of blinking cycles, for example, 20 cycles, and the time current flashing cycle counting down from 3 min. up to 0 min;

• set the brightness using the encoder, for example, 50% of the maximum recommended by the orthoptist,

• set the blinking frequency using the encoder, for example, 3.5 blinks/sec, or set no blinking if the image is blurry as a result of the spotlight shining on the eye,

• set a favorite melody, for example, “Smile,” after completing all the blinking cycles, which stimulated her to complete the entire course in order to quickly hear the melody.

At the same time, all data and settings were displayed on the display, for example, the blinking cycle time, for example, 3 minutes, the number of blinking cycles completed, for example, 20 cycles, brightness settings, for example, 50% of the maximum recommended by the orthoptist, blinking frequency, for example, for example, 3.5 blinks/sec, etc.

In this case, patient V. did not require the participation of a second person in the process of performing the training - the patient successfully completed it independently thanks to the presence of a control unit operating under a computer program.

At the same time, patient V. carried out training daily in any light conditions - both in the dark and in the daylight, thanks to the presence of the device body.

At the same time, it was convenient for patient V. to carry out training due to the presence of a support under her head, which additionally led to a reduction in the risk of “defective” lights (in which double images are present) due to the absence of the risk of involuntary movement of the hand of the second person holding the flash or flinching of the patient’s head.

At the same time, it is possible to use it when the magnitude of strabismus is more than 5 degrees (in patient V. - 15 degrees), in contrast to the method of Prof. T.P. Kashchenko, where in the presence of a strabismus angle of more than 5 degrees, abnormal retinal correspondence and pathological (asymmetric) binocular vision can develop.

Example 2. Using the claimed device according to the claimed method when making threaded studs, fasteners in the form of wing nuts.

The claimed device was assembled according to the algorithm described above, while the studs were threaded, and the fastening elements were made in the form of wing nuts.

Patient M., 17 years old, squint 12 degrees. The ophthalmologist prescribed exercises according to the method of Prof. Pospelov daily for 60 minutes.

Patient M. worked out daily for 60 minutes according to the algorithm described above, while training on the claimed device using the claimed method allowed him to independently:

• use an encoder to set a certain blinking time for the LED strips, for example, 2.5 minutes, while the automatic timer counted down the time and produced a sound notification about the end of the blinking cycle, while the display reflected the total number of blinking cycles, for example, 24 cycles, and the time of the current flashing cycle counting down from 2.5 minutes. up to 0 min;

• set the brightness using the encoder, for example, 75% of the maximum recommended by the orthoptist,

• set the blinking frequency using the encoder, for example, 3.0 blinks/sec, or set no blinking if the image is blurry as a result of the spotlight shining on the eye,

• set a melody, such as a fanfare.

At the same time, all data and settings were displayed on the display, for example, the blinking cycle time, for example, 2.5 minutes, the number of blinking cycles completed, for example, 24 cycles, brightness settings, for example, 75% of the maximum recommended by an orthoptist, blinking frequency, for example, for example, 3.0 blinks/sec, etc.

At the same time, patient M. did not require the participation of a second person in the process of performing the training - the patient successfully completed it independently thanks to the presence of a control unit operating under a computer program.

At the same time, patient M. carried out training daily in any light conditions - both in the dark and in the daylight, thanks to the presence of the device body.

At the same time, it was convenient for patient M. to carry out training due to the presence of a support under his head, which additionally led to a reduction in the risk of “defective” lights (in which double images are present) due to the absence of the risk of involuntary movement of the hand of the second person holding the flash or flinching of the patient’s head.

At the same time, it is possible to use it when the magnitude of strabismus is more than 5 degrees (in patient M. - 12 degrees), in contrast to the method of Prof. T.P. Kashchenko, where in the presence of a strabismus angle of more than 5 degrees, abnormal retinal correspondence and pathological (asymmetric) binocular vision can develop.

From the above we can conclude that the applicant has achieved the stated technical result , namely, a device has been developed for training binocular vision, which improves the quality and convenience of training binocular vision compared to known analogues, due to:

- automation of the training process thanks to the declared design and electronic circuit of the control unit, working according to the applicant’s computer program, which allows:

• set a specific blinking time for the LED strips, with an automatic timer counting down the time and producing a sound notification about the end of the blinking cycle, while the counter displays the total number of blinking cycles and the time of the current blinking cycle,

• set the brightness, as well as the blinking frequency or constant lighting of the light strips,

• display all data and settings, for example, blinking cycle time, number of blinking cycles completed, brightness settings, interval between blinking, etc. (when using previously described devices (photo flashes in analogues), the timer is started manually or the hourglass is turned over and monitored them, while manually marking the total number of blinking cycles on paper),

• set the patient’s favorite melody (especially important for a child) after completing all blinking cycles, which stimulates him to complete the entire course in order to quickly hear the melody;

- minimizing the participation of a second person in the process of performing the training - the patient can successfully perform it independently thanks to the presence of a control unit operating under a computer program;

- the ability to conduct training in universal conditions, allowing you to make exposures in a room with any lighting, including during daylight hours, thanks to the presence of the device body;

- the presence of a headrest, which is convenient for the patient and additionally leads to a reduction in the risk of “defective” lights (in which double images are present) due to the absence of the risk of involuntary movement of the hand of the second person holding the flash or the patient’s head shaking;

- the possibility of use for any size of strabismus, which expands the range of patients, in contrast to the method of Prof. T.P. Kashchenko, where in the presence of a strabismus angle of more than 5 degrees, abnormal retinal correspondence and pathological (asymmetric) binocular vision can develop.

The characteristics of the claimed technical solution and the design of the slits and flash are safe for the retina and do not harm vision. A positive conclusion was received from the ophthalmologist surgeon of the Nizhny Novgorod clinic Vizus-1 Alexander Vladimirovich Shcherbakov (Figure 4), which, in the applicant’s opinion, confirms the achievement of the patentability condition “industrial applicability”.

Claims (23)

1. A device for training binocular vision, containing an apparatus for training binocular vision and a control unit; the apparatus for training binocular vision contains a working part and a support plate connected to each other by pins with the ability to move the working part and the chin rest up and down along the pins to adjust to the size of the patient's face; the studs contain fasteners with the ability to fix the working part and the chin rest; the working part contains a body with a longitudinal partition and a removable cover, on the front panel of the body there are two holes for the eyes and a hole for the nose, the front part of the bottom of the body and the lid has a concave head rest with the possibility of the patient's face adhering to the front panel of the body; the rear wall of the housing is made triple with the formation of two vertical slots, while in the near vertical slot there is a movable nozzle made with two straight slots, one of which is made vertically and the other horizontally, while in the middle of the straight slots there are keyhole-shaped slots for double-sided key; at the same time, spotlights are placed in the far vertical slot of the rear wall of the housing; LED strips are attached to the inside of the rear wall of the case with the ability to ensure their blinking; on both sides of the longitudinal partition, backlight LEDs are attached to the bottom of the housing with the ability to illuminate the slots of the movable nozzle; Below the body, on the front studs, there is a movable chin rest for the patient; on the front part of the base plate there is a clamp for attaching the apparatus for training binocular vision to a horizontal surface; the control unit contains an electronic circuit that ensures the operation of the device for training binocular vision according to a computer program, while the electronic circuit contains a board, a display with the ability to visually monitor training parameters and settings, an encoder with the ability to change data and settings, a piezo emitter with the ability to provide an audio signal at the end of the cycle of flashing and playing music at the end of the session, a connecting cable connected to spotlights, LED strips, backlight LEDs; power adapter; The front panel of the control unit contains: display, encoder shaft, spotlight control buttons, control buttons for the current blinking cycle; the control unit is designed to be connected to a 220 V network with an electrical cord; The power adapter is designed to convert a voltage of 220 V to a voltage of 5 V. 2. The device according to claim 1, characterized in that the pins are smooth or threaded. 3. The device according to claim 1, characterized in that the fastening elements are made in the form of screws or wing nuts. 4. A method for training binocular vision using the device according to claim 1, consisting in the fact that adjust the height of the working part and the chin rest to the size of the patient’s face by moving them along the studs and then fixing them with fasteners; by rotating the encoder, you move through the menu items and adjust the parameters on the control unit: the brightness of the LED strips; exposure time during which successive images are stored; number of blinking cycles of LED strips; the interval between them; then exit the settings menu and save them by pressing the encoder; turning on and off the spotlights is carried out using the spotlight control buttons, and the type of the current blinking cycle - either alternating blinking, or combined blinking, or no blinking, is configured using the buttons for controlling the current blinking cycle with alternating blinking, controlling the current blinking cycle with combined blinking, controlling the current blinking cycle with no blinking, respectively, in accordance with the computer program algorithm; place the patient's chin on a chin rest, the movement of the forehead is limited by the head support, the position of the eyes and nose is correlated with the holes intended for them; connect the device for training binocular vision to the network; with the patient in a position in which the gaze of each eye is directed to the center of the slot in the form of a keyhole for a double-sided key, located in the center of a straight slot on the movable nozzle, two lights are made - one for each eye by turning on the spotlights, for which the corresponding buttons are turned on and off control the spotlights on the front panel of the control unit for a specified time, turn on the LED strips and start the reverse timer by turning on the corresponding control buttons for the current blinking cycle for a predetermined time; after a set time has elapsed, a sound signal is emitted using a piezo emitter, indicating the end of the current blinking cycle; after the number of flashes reaches the number of flashes set in the settings, the piezo emitter emits a customized signal notifying the end of the course of flashes.