RU2273039C2 - Counter-dazzling glasses - Google Patents

Abstract

FIELD: optical engineering, in particular, engineering of counter-dazzling means, possible use for screening eyes of driver from dazzling light, in particular from cars moving in opposite direction.

SUBSTANCE: counter-dazzling glasses have frame with glasses, protective screen with cells and a matrix of light-sensitive elements, electrically connected to protective screen, additionally included is infrared eye pupil position indicator, generating signal under effect from infrared radiation from pupil, gate matrix with normally darkened cells and slit formed in it imitating eye pupil position, adjusting assemblies. Gate matrix is electrically connected to infrared pupil position indicator through adjustment assemblies, is mounted with possible letting of dazzling radiation through slit formed in it onto matrix of light-sensitive elements and following transmission of signal to it for darkening of protective screen cells for protecting pupil from dazzling radiation.

EFFECT: possible alteration of light-protective layer of glasses with consideration of diameter and mobility of driver eye pupil.

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Description

The present invention relates to safety systems for driving a car and may find application in its operation, as well as in other systems that are in conditions of unpredictable radiating effects.

A device is known - anti-glare glasses (see RF patent No. 2036496, G 02 C 7/16, published on 08.27.95, Bull.15). These anti-glare glasses contain a frame, eyepieces, transparent electrodes located on two parallel substrates, between which there are liquid crystals, a line of photosensitive elements. Moreover, a second line of photosensitive elements, perpendicular to the first, a power source and two cylindrical lenses located in the same plane, perpendicular to one another, was introduced into the glasses. Both lines of photosensitive elements are located behind the cylindrical lenses at a distance of the focus of the lenses and are made in the form of a cylindrical surface, and the transparent electrodes located on one substrate are perpendicular to the transparent electrodes located on the other substrate and connected through the control nodes to the photosensitive elements of the corresponding line.

There is an option according to which the anti-glare glasses contain a frame, eyepieces, transparent electrodes located on two parallel substrates, a liquid crystal, a line of photosensitive elements, and a power source. Each photosensitive element is made in the form of a matrix of individual cells interconnected perpendicular to one another. In addition, a short-focusing collecting lens placed in front of the matrix at a distance of its focus is additionally introduced into the glasses. The liquid crystal is also made of separate cells, each of which is connected to the corresponding cell of the matrix of the photosensitive element through the control nodes. From this device, a control unit for light-protective mask masks is known, comprising a matrix of photosensitive elements from which at least the aforementioned lines are formed.

It is selected as a prototype, as it has the largest number of common essential features with the claimed invention and is the latest development in relation to it.

Its significant drawback is the low efficiency of controlling the light-protective layer of glasses due to the inability to take into account the mobility of the pupil of the driver’s eye, since the basis for creating such a well-known block is taken, apparently, the idea of the immobility of the pupil of the eye relative to the glasses.

The objective of the present invention is to provide a new control unit for light-protective mask of glasses, which would allow you to change the light-protective layer of glasses taking into account the size and movement of the pupil of the driver’s eye.

The problem is solved in such a way that a position sensor of the protected object is inserted into a known control unit for light-protective mask masks of glasses, according to the present invention, and a shutter (for example, liquid crystal) matrix is installed next to the light-sensitive elements. The said sensor is connected with the gate matrix with the ability to control the transparency of its cells, forming a gap in them that simulates the position of the protected object and projecting the fluxes of the observed radiation onto the cells of the matrix of photosensitive elements.

This technical solution with a whole new set of essential features makes it possible to obtain a control unit for light-protective mask masks that can take into account the position and mobility of the pupil of the driver’s eye while protecting it from sources of blinding light.

Compared with the prototype of the claimed technical solution has significant differences. In addition, the analysis of patent and scientific and technical information, carried out on behalf of the author, showed that these essential features were not found. Therefore, the claimed invention can be considered new.

The present invention meets the criterion of "inventive step", as it is for a specialist of average skill is not obvious from the achieved level of technology and it does not follow logically. Here, the use of rays transmitted through the simulator of the object to be protected takes place to form or as a control signal the formation of a layer that is protective against blinding radiation.

In the prior art it was not proposed and approaches to such a solution were not outlined (see prototype).

The essence of the claimed technical solutions is illustrated by drawings.

Figure 1. The control unit for light-protective mask of glasses (option 1), the element of the control unit for light-protective mask of glasses and a method for creating a light-protective mask in glasses.

Figure 2. The control unit for light-protective mask of glasses (option 2), the element of the control unit for light-protective mask of glasses and a method for creating a light-protective mask in glasses.

The proposed control unit (option No. 1) with light-shielding masks of glasses that have a light-shielding controlled layer (for example, on a liquid crystal base or close to it), contains (see Fig. No. 1) a matrix 1 of photosensitive elements 2 (for example, photocells or the like ) Next to it, a shutter (liquid crystal or similar, for example, chromophore) matrix 3 is installed and a sensor 4 (for example, infrared) of the position of the protected object, for example, the moving pupil of the eye 5 (shown in the drawing in Fig. No. 1 conditionally), is introduced. As a movable protected object can be not only the eye 5, but also a skin area, temperature sensors or other valuable movable object (not shown in the drawing). The said sensor 4 is connected by optoelectronic or electronic communication 6 through the regulation nodes 6 * to the gate matrix 3 with the possibility of controlling the transparency of its cells 7, forming a gap 8 in them, simulating the position of the protected object 5 and projecting part 9 of the radiation flux 16 onto the cells 10 of the photosensitive matrix 1 elements 2, while these (specifically, 10) elements are illuminated and provide, through communications 11 and control nodes 12, signals to darken the corresponding cells 13 of the light-protective layer 14 of the protective screen 15 (in the drawing from imagined conditionally).

The proposed unit operates as a part of light protection glasses having a controllable (for example, liquid crystal) light protection layer 14 (Fig. 1 is conventionally shown in the drawing).

Blinding radiation 16 from the observed source 17 falls on the protected object 5 (pupil of the eye) and, as a rule, displays it temporarily from the operating state, which can lead to an emergency situation as a whole. In our case, 5 * reflected infrared radiation is used, which corresponds to the physiological properties of the eye. This reflected radiation enters the sensor (s) 4 of the position of the pupil 5 of the eye. This sensor 4 generates a signal that, through optoelectronic (electronic) communications 6 and control nodes 6a, acts on the gate liquid crystal matrix 3 of normally darkened cells 7. As a result, a lumen 8 is formed and its position corresponds to the position of the pupil of the eye 5 at the moment. This position of the pupil will change, and other cells of the liquid crystal matrix will be enlightened 3. Moreover, the new enlightenment will correspond to the new position of the pupil of the eye 5. These enlightened cells 8 project part 9 of the stream (or streams, although the drawing shows conditionally one blinding stream) of blinding radiation 16 on cells 10 of the photosensitive elements 2 of the matrix of photosensitive elements 1. And already these cells 10 generate a potential that serves as a signal for dimming the corresponding cells 13 of the light-protective layer 14 total screen 15 (shown in the drawing conditionally). As a result, the protective screen 15 forms protective masks 13, which shield the pupil of the eye from blinding radiation, without interfering with the overview of the environment, since the said masks are temporary local in nature and have limited dimensions, which correspond to the sizes of the sources of blinding radiation 17, 17 *, etc., visible to the pupil at any given time.

The proposed technical solution allows you to create a number of devices for this purpose, as well as the technology for creating such devices.

The control unit of the light-protective mask of glasses (option No. 1), containing a matrix of photosensitive elements, characterized in that a shutter (e.g., liquid crystal) matrix is installed next to the matrix of photosensitive elements and a sensor (e.g. infrared) for the position of the protected object (eye pupil) is inserted, associated with the shutter matrix with the ability to control the transparency of its cells for the formation of a gap in them, simulating the position of the protected object and projecting part of the radiation fluxes onto the light matrix real elements, highlighting, thus, the rays that serve as sources of signals for the formation of protective masks in the lenses of glasses.

The control unit for light-protective mask of glasses (option No. 2), containing a matrix of photosensitive elements generating signals for creating protective masks in the glasses of glasses, characterized in that behind the matrix of photosensitive elements there is a shutter (for example, liquid crystal) matrix that covers the retroreflective layer, and a sensor is introduced the position of the protected object, which is associated with the shutter matrix with the ability to control the transparency of its cells to form a gap in them that mimics the position of the protection object and transmitting the streams of radiation irradiating it to the reflective layer and back to the cells of the matrix of photosensitive elements. In this case, the matrix of photosensitive elements is made of discrete cells shielded from direct radiation, oriented to the reflective layer and allowing the passage of radiation fluxes to the gate matrix.

An element of the control unit of one and / or several light-protective structures (for example, liquid crystal) of glasses, contact lenses, comprising a reflective layer, characterized in that a contact lens with a reflective layer covering the iris of the eye or part of it or the pupil is used as said layer in the form, for example, triple prisms.

1. A method of creating a light-shielding mask in controlled light-shielding structures (liquid crystal, chromophore, etc.), including the arrangement of a matrix of photosensitive elements next to the operator’s eye, characterized in that they generate signals that control protective actions (the formation of protective masks) of some harmful radiation passing through the lumen-simulator of the protected object, formed in the gate layer by the signals of the position sensor of the protected object.

2. A method of creating a light-protective mask in glasses of glasses (in contact lenses), comprising arranging a matrix of photosensitive elements in front of the operator’s protected eye, characterized in that the iris of the protected eye or part of it and / or its pupil is covered with a reflective layer of the contact lens, wherein photosensitive elements are performed in glasses lenses (contact lenses) from discrete photosensitive cells shielded from direct radiation, oriented to the reflective layer, and liquid crystal (or the like) cells, providing the creation of light-protective masks by the signals of the photosensitive elements, are performed with optical duty cycle in the corresponding spectrum range, sufficient for the operation of the photosensitive elements.

In essence, it is possible to create a complex of devices and a method, united by a single inventive concept, which also follows from the brief description below, for example, control unit No. 2 with light-protective mask glasses.

It contains a matrix of photosensitive elements 1. A shutter (for example, liquid crystal) matrix is installed behind it. 3. A reflective layer 18 is located behind the last matrix. There is also a position sensor of the protected object 4. It is better to place this sensor on the frames of glasses or in the zone of the least information content of their glasses. It is connected by links 6 through the nodes of regulation 6 * with the gate matrix 3 with the ability to control the transparency of its cells 7, 8. Thanks to this control, a gap is formed in them from cells 8, simulating the position of the protected object 5 and transmitting radiation flux 9 to the reflective layer 18 and back (beam 9 *), on cells 10 of the matrix of photosensitive elements 1. Moreover, the matrix of photosensitive elements 1 is made of discrete cells 2, 10, shielded from direct radiation, oriented to the reflective layer and allowing x emissions flow passage 9 to the gate array 3.

This block works as follows (see Figure 2). The protected object 5 (pupil of the eye) with its reflected radiation 5 * (for example, infrared) acts on the sensor (s) of its position 4, which, through the control connections 6 and nodes 6a, act on the gate matrix 3 normally darkened in working condition (for example, liquid crystal, chromophore, etc.) cells 7, 8, causing enlightenment of those of them (in this case, 8) that correspond to the position of the protected object 5. In turn, the enlightened cells 8 pass part of the flow (for example, one blinding source, although their number is not limited by anything and the formation of protective masks occurs simultaneously) of radiation 9 to the reflective layer (for example, triple prisms) 18 located after the gate matrix 3, and the rays 9 * reflected by it illuminate those photosensitive cells 10 of the matrix of photosensitive elements 1, which correspond to the current position of the protected object 5, and the potential developed by them becomes through the circuit 11 and control nodes 12 a signal to those cells 13 (for example, liquid crystal) of the protective layer 14 points 15, which currently obscure the movable protected object 5 from harmful emissions 16.

In the present invention, there is also the following feature, which is associated with the creation of a control element of one or more light-shielding (for example, liquid crystal, etc.) structures (layers) of glasses. It contains a reflective layer. It should be noted that in the inventive device, it is possible to use the said layer of a contact lens as a carrier with a reflective layer covering part of the iris and / or part of the pupil of the eye and made in the form of, for example, triple-prisms. The principle of its operation is similar to the previously presented devices and does not require special explanation.

By virtue of the previously described features of the claimed invention, it should be noted that on their basis a method of creating a light-protective mask in glasses, contact lenses is possible. Such a method includes the preliminary creation of a matrix of photosensitive elements, which are usually placed in front of the operator’s protected eye. In our case, it becomes possible to block part of the iris and / or part of the pupil of the protected eye with a retroreflective layer of the contact lens. In this case, the matrix of photosensitive elements can be made in glasses of glasses (contact lens) from discrete cells shielded from direct radiation and allowing the passage of radiation fluxes between themselves, and the light-protective layer of liquid crystal (or the like) cells, providing the creation of light-protective masks according to the signals of the light-sensitive elements, to place glasses in the glasses (contact lenses) with a duty cycle that allows the operation of photosensitive elements.

The implementation of this method in specific conditions is not in doubt due to the consistency of the above-described proposed devices.

Claims (1)

Anti-glare glasses containing a frame with glasses, a protective screen with cells and a matrix of photosensitive elements, electrically connected with a protective screen, characterized in that they additionally contain an infrared eye pupil position sensor that generates a signal under the influence of infrared radiation from the pupil of the eye, a shutter matrix with normal darkened cells and a lumen formed in it, simulating the position of the pupil of the eye, control nodes, and the shutter matrix is electrically connected to infrared The sensor of the position of the pupil of the eye through the control nodes is installed with the possibility of transmitting blinding radiation through the gap formed in it to the matrix of photosensitive elements and then transmitting a signal from it to darken the cells of the protective screen to protect the pupil of the eye from blinding radiation.

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