RU232277U1 - GLASSES FOR RESTORING VISUAL FUNCTION - Google Patents

Abstract

The utility model relates to medical equipment, in particular to ophthalmology. More specifically, a device in the form of glasses is presented, intended for light therapy for the purpose of restoring visual function. The technical result of the claimed utility model is the creation of a wearable device with visual acuity correction with a simultaneous function of relieving eye fatigue. Glasses for restoring visual function contain a frame with built-in light sources and a power source, optical lenses. At the same time, an image with the ability to determine the focal point of the gaze is applied to the optical lenses. 4 s.p. f-ly, 3 fig.

Description

The utility model relates to medical technology, in particular to ophthalmology. More specifically, a device in the form of glasses is presented, intended for light therapy for the purpose of restoring visual function.

Currently, various methods and various video trainers designed to relieve any type of eye fatigue are widely known and used in practice.

For example, for training the periorbital muscles that rotate the eyeball in different directions, a "Video Trainer" device is proposed, containing a means for alternately switching on objects of tracking, made in the form of an indication unit controlled by a pulse generator that has the ability to adjust the required predetermined frequency of pulse generation, the direct and inversion outputs of which are connected to the corresponding inputs of the indication unit. Two light-emitting diodes are connected to the outputs of the indication unit, which are essentially alternately switched on objects of tracking. The light-emitting diodes are located at the ends of an arc-shaped frame movably mounted on a base to ensure the possibility of installing it at eye level. Control of the objects of tracking is performed automatically, with a predetermined frequency that can be adjusted. Electric power is supplied to the device from a power supply. Visual tracking with the eyes of the alternately switched on objects of tracking creates a training effect on the periorbital muscles. Training of the periorbital muscles helps reduce visual fatigue and prevents visual refractive disorders, in particular, myopia and hyperopia (RU 1802704 C1, published 15.03.1993, A61F 9/00, A61H 5/00).

The disadvantage of this device is the low efficiency of training the periorbital muscles, since the trainer does not provide the ability to track objects, and the eyes only make circular movements or movements along other trajectories. Also, effective training of the intraocular (ciliary) muscle of the eye and clear vision of the objects of tracking themselves are not provided.

Other known methods and devices are designed to relieve two types of eye fatigue simultaneously. In particular, the eye trainer developed at the All-Russian Research Institute of Physical Culture and Sports (see Demirchoglyan G.G. "How to Preserve and Improve Vision", Coll. Moscow: KRON-PRESS, 1995) contains a tracking object (in particular, a certain text), a set of weak optical lenses, and a device for automatic, alternate lens change. During the training, a person (the operator) reads the text through automatically replaceable lenses; alternating negative and positive lenses makes reading easier or more difficult, respectively. In this case, the ciliary muscles of the eye contract or relax, i.e., they are trained, as a result of which accommodative fatigue is relieved. Such optical massage of the intraocular muscles can additionally prevent the progression of myopia or hyperopia.

However, the above-mentioned known devices are not mobile and do not provide the possibility of continuous therapy throughout the day.

The prior art discloses a method for diagnosing visual function disorders, a method for restoring visual functions, and a device for implementing them, which consists of placing a light-protective spectacle frame in front of the patient's eyes with LEDs built into the front panel, connected to a pulse generator, supplying light pulses of green, blue, and red color, and performing diagnostics of the functional state of visual functions. The frequency of light pulses is changed from lower to higher values, the critical flicker fusion frequency (CFFF) is determined alternately for each eye and sequentially for the three main colors of light pulses - green, blue, red, based on the CFFF indicators, diagnostics of the functional state of the central zone of the retina and pathology of the optic nerve are carried out according to the following conditions: if the CFFF for red is reduced to a greater extent than for green, and to a greater extent than normal, then a dysfunction of the central zone of the retina is diagnosed, if the CFFF for green is reduced to a greater extent than for red, then pathology of the optic nerve and visual pathway is diagnosed (RU 2189168 C2, published 20.09.2002, A61B 3/00, A61F 9/00).

The disadvantage of this method is the lack of the ability to correct vision under conditions of constant (daily) wearing of the device (mask) due to the lack of optical lenses and the design features of the mask.

Also known from the prior art is a color therapy LED device comprising a housing worn on the head with a light source in the form of LEDs, a power supply unit and a control unit. The LEDs are divided into groups with red, blue, green emission spectra and white glow light. The control unit contains a microprocessor system with a LED group switch, LED brightness regulators, a common LED brightness regulator, a unit for interfacing with a personal computer with a program for generating color combinations, pulse duration and brightness. In the device according to the first version, the housing is made in the form of a visor located above the face. The LEDs are located in the lower part at the base of the visor, fixed on a belt. In the device according to the second version, the housing is made in the form of glasses with lenses made of transparent plastic and a frame. The frame consists of two sidewalls and the plastic is located along an arc between the sidewalls. The LEDs are placed in the sidewalls on both sides in the end parts of the plastic so that the light flux from them is directed inward and toward the center of the plastic. To form moving colored light spots on the surface, it is made of transparent material and bent along an arc. Light sources are placed between the layers of material at the ends on both sides inside the surface. Their light flows are directed towards each other and the magnitude of the light flow and the color of each light source are regulated according to different laws (RU 2330693 C2, published 10.08.2008, A61N 5/06, A61M 21/00).

The disadvantage of this device is the lack of the ability to continuously wear the device to correct vision and relieve eye fatigue.

The closest analogue of the claimed technical solution is a phototherapy system including spectacle frames and contact lenses. Spectacles used together with contact lenses to provide phototherapy to the user. Spectacle lenses or frames contain a built-in light source in a logical and electrical connection with a power source, sensors, processors and other components built into the spectacle (RU 2580983 C2, published 10.04.2016, A61N 5/06).

The lenses of glasses or frames project light onto additional contact lenses, which perform refraction, diffraction or reflection of light onto the user's eyes. The group of inventions described above makes it possible to increase the comfort of the procedure and to carry out phototherapy more rationally.

The disadvantage of this device is the lack of the ability to create luminous objects on the lenses to correct vision, namely strabismus, as well as the ability to control therapy.

The technical problem to be solved is to eliminate the shortcomings of existing analogues.

The technical result of the claimed utility model is the creation of a wearable device with visual acuity correction and a simultaneous eye fatigue relieving therapy function.

The stated technical result is achieved by the fact that glasses for restoring visual function contain a frame with built-in light sources and a power source, optical lenses, according to the utility model, an image is applied to the optical lenses with the ability to determine the point of focus of the gaze.

In a particular case of implementation, a light-emitting diode, laser light-emitting diode or side-emitting fiber-optic cable is used as a light source; the light source is controlled by a mobile device; the image is a point, circle or square. The image can be made with the ability to change color depending on the light source emission spectrum. A button with a controller for switching on the counting source with the ability to change the light source emission spectrum and its frequency can be located on the frame.

The utility model is illustrated by graphic images, where:

Fig. 1 shows glasses, side view;

Fig. 2 - glasses, top view;

Fig. 3 - glasses, front view.

The claimed utility model is made as follows. The glasses include a frame 1 (see Fig. 1) with built-in light sources 2 and a power source 4, optical lenses 3.

An image is applied to the optical lenses 3 with the ability to determine the focal point of the gaze.

Light source 2 can be a LED, laser LED or side-illuminated fiber optic cable. Light source 2 is controlled primarily by a mobile device.

The image used to determine the focal point of the gaze can be a dot, a circle, or a square.

Light source 2 is fixed on the frame above the corresponding optical corrective lens 3.

Power source 4 can be fixed either to the frame 1 of the glasses or made separately.

The image applied to the optical lens 3 becomes visible when the light source 2 is switched on. Switching on and off of the light source 2 can be done by means of a button or, in some cases, controlled wirelessly from a mobile device (phone, tablet), for example, using Bluetooth. The program for switching on and off the light source 2, the brightness, and the color of its glow are set using the mobile device.

The device operates as follows. The stated glasses are an eye trainer for restoring visual function. A corrective lens 3 is installed in frame 1 of the glasses, and another corrective lens 3 or simple glass is installed in the second part of the frame (for the second eye), if treatment of the second eye is not required. An image in the form of a circle, square or other symbol is applied to the corrective lens. A light source 2 is installed on frame 1. Light source 2 is switched on in the mode of the required radiation spectrum: red, blue, green and white glow color.

When light source 2 is turned on, the specified image is illuminated and vision focuses on it. The image can change color depending on the spectrum of the light source. Depending on where the eye is squinting, an image is applied to the lens from the opposite side of the lens so that when the light source is turned on and the image is illuminated on the lens, the eye focuses on it. The image will direct the gaze in the right direction and over time will allow vision to be corrected (for example, strabismus).

In one embodiment, the light source can be switched on and off using a button (not shown in the drawing) installed on the frame of the glasses; in some cases, the light source can be switched on and off using a mobile device, such as a phone or tablet. The mobile device is connected to the light source via Bluetooth, which allows you to control the switching on and off of the light source, as well as the required emission spectrum. The button can be connected to the counting source via a controller programmed to switch the light source on and off and change the emission spectrum of the light source with a certain frequency.

Thus, a daily-wearable device in the form of glasses with optical lenses allows for improving visual acuity, and an installed light source with different emission spectra and an image applied to the lenses allows for light therapy.

The declared device fully realizes its purpose and allows for effective therapy to restore visual function.

Claims (5)

1. Glasses for restoring visual function, comprising a frame with built-in light sources and a power source, optical lenses, wherein an image is applied to the optical lenses, made with the possibility of changing color depending on the spectrum of the light source and made with the possibility of focusing the gaze on it. 2. Glasses according to item 1, characterized in that a light-emitting diode, a laser light-emitting diode, or a side-illuminated fiber-optic cable is used as a light source. 3. Glasses according to item 1, characterized in that the light source is controlled by a mobile device. 4. Glasses according to item 1, characterized in that the image is a dot, circle, square. 5. Glasses according to item 1, characterized in that the frame has a button with a controller for turning on the light source with the ability to change the spectrum of the light source and its frequency.