RU136610U1 - MULTIFUNCTIONAL ELECTRONIC VIDEO ENLARGE - Google Patents

Abstract

1. A multifunctional electronic video enlarger containing at least one light source, as well as at least one light-scattering element, characterized in that the light-scattering element is coated with a light-transmitting coating, and this coating is made in such a geometric shape that inscribed in it the circle has a diameter of not less than the product of the double distance between the light source and the light scattering element and the tangent of half the angle of divergence of the light flux emanating from light source, while the center of the inscribed circle lies in the same axis as the light source, and the number of such coatings is not less than the number of light sources. 2. The multifunctional electronic video enlarger according to claim 1, characterized in that the light-transmitting coating can be made with a light-scattering element as a whole.

Description

The utility model relates to information reading devices, namely, to electronic video magnifiers.

It is preferable to use the claimed utility model in the field of rehabilitation of people with impaired vision.

From the prior art, a device is known - an electronic manual video enlarger (Patent of the Russian Federation No. 85710 s. 12/22/2008, op. 10.08.2009). This analogue consists of a housing, an annular support ledge, a printed circuit board, an operating mode switch connected by connecting wires to the printed circuit board, LEDs and an imager connected to and mounted on the printed circuit board.

A disadvantage of the analogue is that when illuminated by light sources, areas of illumination of varying degrees of intensity are formed on the read surface, depending on the reflectivity of the read surface, which are displayed on an external monitor, degrade image quality.

A device is known as an electronic manual video enlarger (Patent of the Russian Federation No. 115944 c. 12/29/2011, op. 10.05.2012), consisting of a housing, inside which there is a hollow support ledge made on the lower wall of the housing, while in the lower part a housing window bounded by a hollow support protrusion, a through window is made, a printed circuit board is mounted on the hollow support protrusion, comprising an image receiver located inside the hollow support protrusion of the lens and at least one light source, and inside the hollow support protrusion and between the light source and the plane of the through window, at least one light-scattering element is installed in which a through hole is made, the size of which corresponds to the diameter of the lens.

The specified device is taken as a prototype, as the closest in its technical essence.

The disadvantage of the prototype is that when reading images from glossy or other reflective, for example, laminated surfaces, light spots are formed on the resulting image, the number of which is equal to the number of light sources used in the device, and the intensity of the light spots depends on the selected display mode. Moreover, these spots of illumination impair the quality of the image due to the inability to read it.

The formation of these spots of illumination is the result of an uneven light flux emanating from light sources, its reflection from the read surface, and then through the lens into the image receiver.

The use of a prototype light-diffusing element made of frosted glass or light-transmitting plastic, does not completely get rid of the exposed areas if the read surface has a high degree of reflectivity.

The task to which the claimed claimed utility model is directed is to improve the quality of the image received by the device.

The technical result, which is achieved by the claimed utility model, is to improve the quality of the image formed by the device by obtaining a uniform light flux from the light source over the entire area of the read surface.

The technical result is achieved by the fact that the light-scattering element of the device is performed with light-transmitting elements made in a certain way.

A multifunctional electronic video enlarger containing at least one light source and at least one light-scattering element on which a light-impermeable coating is applied, and this coating is made in such a geometric shape that the circle inscribed in it has a diameter of at least a double distance between the light source and the light-scattering element and the tangent of half the angle of divergence of the light flux, while the center of the inscribed circle lies in the same axis as the source axis lighting source, and the number of such coatings is not less than the number of light sources.

The light-scattering element may be made of any light-transmitting materials having a light-scattering effect, for example, frosted glass or light-transmitting plastic.

The light-impervious coating can be made of any material that does not transmit light rays, for example, light-tight plastic or paint or any other material that has similar properties.

The utility model is illustrated by drawings.

The figure 1 schematically shows the reading node of a multifunctional electronic video enlarger, with elements located therein.

The figure 2 shows a light-scattering element with light-transmitting elements.

A multifunctional electronic video enlarger containing at least one light source 1, as well as at least one light-scattering element 2, characterized in that the light-scattering element 2 is coated with a light-impermeable coating 3, and this coating is made in such a geometric shape, that the circle inscribed in it has a diameter of not less than the product of the double distance between the light source and the light-scattering element and the tangent of half the angle of divergence of the light flux emanating from from the light source 1, while the center of the inscribed circle lies in the same axis as the light source 1, and the number of such coatings is not less than the number of light sources.

The size of the light-impervious coating, characterized as having the ability to fit a circle into it, the diameter of which is determined by multiplying the double distance between the light source and the light-scattering element and the tangent of half the angle of divergence of the light flux emanating from the light source, due to the fact that the light spot from the source Lighting incident on the light scattering element is determined by the specified formula.

The operation of the device is as follows. Inside the hollow support ledge 4 of the multifunctional electronic video enlarger, the light sources 1 are turned on. The light flux emitted by the light sources 1 falls, including, onto the light-impermeable coating 3.

Due to the diffraction of light waves, secondary waves formed behind a light-impermeable coating, that is, at the interface between the air-light-scattering element, propagate in all directions except for creating light spots on the read surface.

Reflecting from the surface being read, light waves enter the lens 5.

Thus, the claimed utility model can significantly improve the quality of the resulting image formed by the device in comparison with the known technical solutions.

Claims (2)

1. A multifunctional electronic video enlarger containing at least one light source, as well as at least one light-scattering element, characterized in that the light-scattering element is coated with a light-transmitting coating, and this coating is made in such a geometric shape that inscribed in it the circle has a diameter of not less than the product of the double distance between the light source and the light scattering element and the tangent of half the angle of divergence of the light flux emanating from light source, while the center of the inscribed circle lies in the same axis as the light source, and the number of such coatings is not less than the number of light sources. 2. The multifunctional electronic video enlarger according to claim 1, characterized in that the light-transmitting coating can be made with a light-scattering element as a whole.

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