UA16979U - Optical device for protecting eyes - Google Patents

Abstract

The proposed optical device for protecting eyes is designed as an optical filter with a lens that contains a zone with the low light transmission coefficient and a zone with the high light transmission coefficient. Between these zones, an intermediate zone is provided. The intermediate zone starts at a distance from the edge of the lens that is equal to one-third part of the lens. The area of the intermediate zone does not exceed one-third part of the lens area.

Description

Description of the invention

The useful model belongs to optics, in particular to glasses designed to protect human eyes from 2 differences in the intensity of optical radiation in a large range, in particular, to protect the eye with frequent changes in brightness, as well as from blinding lighting by the headlights of oncoming traffic in the dark.

At the current stage of the development of optics, glasses are widely used to protect human eyes from powerful light sources, the glass of which is made of smoky, blue-gray or greenish-gray color 70 Yediv.: Popular medical encyclopedia. - Ed. 7th, stereotypical. - Moscow: Soviet Encyclopedia, 1969. - P.568-570).

The disadvantage of the known technical solution is that it is practically unsuitable for preventing the blinding of the driver of a moving vehicle in the dark.

Another way of combating the blinding effect of headlights is physical action on the light flux 12 directly near the driver's eyes. For example, creating a device that protects the driver's eyes from direct headlights.

The well-known design of anti-dazzle glasses on a liquid crystal (ZO 1413577 1988. The principle of operation of which is that under the action of the photoflow coming from the source of glare, the liquid crystal darkens in the corresponding narrow strip, which screens the direct rays from the headlights. In this case, the darkened the stripes are dynamic and appear only in the necessary area of the driver's field of vision depending on the number of blinding sources.

The disadvantage of this device is the very complex design of the glasses and the need for an additional power source. In addition, this device is very inertial with respect to the activation time.

As the closest analogue of the useful model, an optical element for eye protection is taken, |described in patent O5 5975695), which is a light filter that has a zone with a high light transmission coefficient and a zone with a low light transmission coefficient. In it, there is a clearly pronounced sharp transition from a section with a lower light transmission coefficient to a section with a higher light transmission coefficient, forming a transition line of transmittance at the border. The light filter is monochrome. The area with greater light transmission does not exceed 805960, and the transition line of transmittance runs in the middle.

The disadvantage of this device is that the sharp transition does not reduce the time of dark or light adaptation of the eyes, which increases their stress. In a monochrome light filter, there is no neutralization of the unfavorable part - the radiation range, namely, in blue-violet.

The creation of a useful model is based on the task of developing an optical element for eye protection, in which, by changing the parameters of light transmission across the entire plane of the light filter and creating opportunities to transfer the central line of sight from one area to another through the transition zone of light transmission, a reduction in the tension of the adaptation mechanisms of the eye is achieved. normal operation of photochemical processes on the retina of the eye is ensured with frequent changes in brightness and increased loads during tempo and light adaptation. In addition, the optical element has an additional technical result, namely, it allows prevention of visual disturbances. "

The task is solved by the fact that the optical element for eye protection, which is a light filter C that has a zone with a high light transmission coefficient and a zone with a low light transmission coefficient, c according to a useful model, additionally between these zones there is a transition zone that begins at the level

From" the third part of the lens and does not exceed a third of the total area of the optical element.

The optical element for eye protection has a coating with 9095 reflection of ultraviolet radiation, especially in the range of 288-290nm, and with the ability to absorb the visible spectrum of optical radiation in the blue-violet region in the range of 400-50О0nm, and provide chromatic transmittance in the range - 5Б6О-58ОНМ.

Ge") In addition, the zone with a low light transmission coefficient has a coating with the possibility of correcting the visible area of optical radiation in the range of 480-56 Ohm. o The transition zone has a light transmission coefficient of 50-60905. -and 20 The light transmission coefficient of the zone with a low light transmission coefficient does not exceed 7905.

The light transmission coefficient of the zone with a large light transmission coefficient is in the range of 80-95960. c The optical element for eye protection is polychrome. The light transmission coefficient of the zone changes gradually. Figure 1 shows an optical element on the background of the eye, where 1 is a zone of an optical element with a low coefficient of light transmission, 2 is a zone of an optical element with a high coefficient of light transmission, C is a transition zone, 4 is the pupil of the eye. c They make an optical element as follows. A colorless lens is immersed in a hot aqueous solution of a light-filtering composition of organic dyes. The lens can be made both zero and optical, which is made individually taking into account the needs of vision correction. At the same time, the first layer of light-filtering compositions is applied, which provides 9095 reflection of ultraviolet radiation, especially in the 288-290nm range, absorbs the visible spectrum of optical radiation in the blue-violet region in the 400-500nm range, and provides chromatic transmittance in the 560-58Ohm range. Then, similarly, a second layer of light-filtering paint is applied, which delays the visible area of optical radiation only in the upper third of the optical element in the range of 490-5bOhm, and with a light transmission coefficient of no more than 795. After that, dipping the lens, darken the transition zone to a light transmission coefficient of 50-6095. The lower zone of the optical element remains unchanged with a light penetration coefficient of 80-9590.

During the patient's optometry, the finished optical element is installed in such a way that the upper part of the lens, which has a low light transmission coefficient, was on the upper edge of the pupil.

The use of an optical element is possible in glasses, masks or protective individual screens.

The optical element is used as follows.

To protect the eyes from intense lighting by tilting the head by 12-15 degrees, the direction of vision is transferred from the zone with a high coefficient of light transmission to the zone with a low coefficient of light transmission gradually through the transition zone, which ensures a smooth inertial transition of perception, reducing the load on the macular region of the retina, gives time for the eye to adapt to a change in the intensity of the light flux, which provides light and dark adaptation of the eye.

All this provides

7/0 improvement of visual acuity, function of contrast sensitivity of the eye, as well as prevention of the development of macular dystrophy and degenerative changes in the central and peripheral part of the retina.

Claims (9)

The formula of the invention y y , y s. 1. An optical element for eye protection, which is a light filter that has a zone with a high light transmission coefficient and a zone with a low light transmission coefficient, which is distinguished by the fact that additionally between these zones there is a transition zone that begins at the level of the third part of the lens and does not exceed a third of the total area of the optical element. 2. An optical element for eye protection according to claim 1, characterized in that it has a coating with at least 9090 reflectance of ultraviolet radiation in the range of 280-400 nm, especially in the range of 288-290 nm, and with the ability to absorb the visible spectrum of optical radiation in the blue- violet region in the range of 400-500 nm and provide chromatic transmittance in the range of 560-580 nm. 3. An optical element for eye protection according to claims 1, 2, which is characterized by the fact that the zone with a low light transmission coefficient has a coating capable of delaying the visible region of optical radiation. 4. An optical element for eye protection according to claims 1,2, which is characterized by the fact that the zone with a low coefficient of light transmission has a coating with the possibility of delaying radiation in the range of 490-560 nm. 5. An optical element for eye protection according to claims 1-3, characterized in that the transition zone has a light transmission coefficient of 50-6090. b zo 6. An optical element for eye protection according to claims 1-4, which is characterized by the fact that the light transmission coefficient of the zone with a low light transmission coefficient does not exceed 7905. c. 7. An optical element for eye protection according to claims 1-5, which is characterized by the fact that the light transmission coefficient of the zone with a high light transmission coefficient is in the range of 80-9590. 8. An optical element for eye protection according to claims 1-6, which is distinguished by the fact that it is made polychrome. (Se) 9. An optical element for eye protection according to claims 1-7, which is characterized by the fact that the light transmission coefficient "- changes gradually. - . and? - (o) se) -i iChe) 60 b5