SU1005787A1 - Antidazzling spectacles - Google Patents

Abstract

ANTI-SURFACE RCHKI, containing a mandrel with orifices, placed in the latter modulators of the luminous flux, including polarization filters, and a power source, which are characterized by the fact that, in order to automatically adjust the luminous flux in the local area at the exit of the eyelets, the modulators of the illuminant The fluxes additionally contain transparent substrates between polarization F1U1 of layers with transparent electrodes deposited on their inner surfaces and between them enclosed on their surfaces. and successively arranged along the direction of propagation of the luminous flux layers of the photoconductor and the lematic liquid crystal, with polarization filters applied to the outer sides of the substrates. CL 00 "h Fig. /

Description

The invention relates to medical instrumentation, namely, glasses used to protect against high-intensity light radiation: electric arc during electric welding, molten metal of blast furnaces and open-hearth furnaces, searchlights of various types, including automobile headlights, laser radiation, etc. These glasses automatically control the transmission of the luminous flux incident on them, consisting of a rim, ocul tori with polar filters, a photoelectric cell and two electromagnets 1. A disadvantage of the known anti-glare glasses is the inability to locally control the transmission of the luminous flux. Most importantly, and to the inventors by their technical essence and the achieved positive effect, are antidazzle glasses, containing eyeglasses placed in the latter moduli of the luminous flux. , including polarization filters, and the power source C21. The disadvantage of these anti-glare glasses is also the impossibility of local adjustment of the transmission capacity. In addition, the reliability of such points is low. The aim of the invention is to provide automatic adjustment of the luminous flux in the local area at the exit of the oculars. This goal is achieved by the fact that in antidazzle glasses containing a frame with eyelets, modulators of the luminous flux placed in the latter, including polarization filters to the power source, the modulators of the light flux contain transparent substrates marked with polarization filters coated on them. internal surfaces with transparent electrodes and layers of the photoconductor and nematic liquid crystal deposited on their surfaces and successively arranged in the direction of propagation of the light flux, with polarization filters applied on the outside of the transparent surfaces under. spoons. FIG. I depicts antidazzle glasses, a general view; in fig. 2 is a section A-A in FIG. I. The antidazzle goggles of an imitation I. with oculators 2 and a power source 3. In the envelopes 2 there are placed light flow modulators, including polarization filters 4 between which the OTMs are transparent sublingually 5, on the surfaces of which are deposited transparent electrodes 6, and the layers of the photoconductor 7 and the nematic liquid crystal 8 that are sandwiched between the latter and successively arranged in the direction of propagation of the luminous flux. The thickness of the liquid crystal 8 is determined by a dielectric pad 9. They work against Blinding glasses as follows: Crossover polarization filters 4, made in the form of polar films, included at the entrance and exit of the eyepieces — polarizer and analyzer — are designed to produce a darker eyeball effect. As a result of rotation of the light polarization plane by the liquid crystal layer 8 under the action of an electrical voltage applied to it through a layer of photoproducibility 7 with a diminishing resistance under the action of light. The light entering the polarizer is generally not polarized. Pass the analyzer, only vertically polarized light rolls are extracted from it. Due to the fact that the polarization filters are crossed, and the liquid crystal molecules in the initial state rotate the plane of polarization of light by 90 °, the ocular in the initial state is transparent. The voltage drop across the liquid crystal 8 varies locally due to the fact that under the action of local illumination the resistance of the layer of the photoconductor 7 in the limited illuminated area rather than the entire surface also decreases significantly locally. On the other, less illuminated areas of the photoconductor, its resistance remains quite large. Therefore, in a liquid crystal 8, the rotation of the plane of polarization of light, leading to a darkening of the ocular, will be; performed only in the local area. If the entire photoconductor layer is illuminated with a sufficiently intense light, this will lead to a darkening of the ocular over the entire surface. In this way, the invention allows for automatic dimming of the eyes of the dazzle glasses, due to which it is carried out from the light of high intensity light.

Claims (1)

ANTI-BLINDING GLASSES containing a mandrel with eyepieces located in the last light flux modulators, including polarizing filters, and a power source, which are repaired by the fact that, in order to automatically adjust the light flux in the local area at the eyepiece output, the light flux modulators additionally contain between polarizing ftsltra transparent substrates with transparent electrodes deposited on their inner surfaces and enclosed between the latter, deposited on their surface and layers of a photoconductor and a nematic liquid crystal located in the direction of propagation of the light flux, with polarizing filters deposited on the outer sides of the substrates. Fig. /