RU115944U1 - ELECTRONIC MANUAL VIDEO ENLARGE - Google Patents

Abstract

1. Electronic manual video enlarger, including a housing, a hollow support protrusion located inside the housing, made on the lower wall of the housing, while in the part of the lower wall of the housing bounded by the hollow support protrusion, a through window is made, a printed circuit board installed on the hollow support protrusion containing an image receiver located inside the hollow support protrusion lens and at least one light source, characterized in that inside the hollow support protrusion between the light source and the plane of the through window is installed at least one light-scattering element, in which a through hole is made, the size of which corresponds to the lens diameter. ! 2. Electronic manual video magnifier according to claim 1, characterized in that the light diffusing element is made of frosted glass. ! 3. Electronic manual video magnifier according to claim 1, characterized in that the light-scattering element is made of light-transmitting plastic.

Description

The utility model relates to devices for reading information, namely, electronic manual video magnifiers and can be used by visually impaired people for comfortable reading graphic information in the form of texts and images, such as books, magazines, labels.

Electronic hand-held video enlargers must be able to read graphic information from the medium for subsequent transmission of its enlarged image to a display device, such as a television or monitor. At the same time, the quality of the image formed by the electronic manual video enlarger should be equally high over the entire area of the reading area, in order to ensure its easy recognition in the future by visually impaired people.

Known multifunctional electronic manual video enlarger [1], containing a housing located on the base, inside the housing on this base fixed main and additional support projections on which the main elements of the video enlarger are located, characterized in that the following are introduced: a control panel with buttons for switching operation modes located on the case, an additional printed circuit board mounted on an additional support ledge located on the base, on this board are actually mode switches works that allow you to perform the following functions: "Zoom" mode, image capture mode - "Freeze frame", color or black-and-white image mode.

The disadvantage of this design of an electronic video enlarger is that when the reading area is illuminated by discrete light sources, regions with different light flux intensities are formed on its surface, as a result of which the reading area has illuminated areas, which impairs the perception of information subsequently output to the display device.

Known electronic manual video enlarger [2] (prototype), comprising a housing located on the base, an annular support protrusion made on the base of the housing and located inside the housing, a printed circuit board connected to the imaging device mounted on the annular support ledge and connected to the mode switch, LEDs and an imager connected to the printed circuit board and installed on it, while the mode switch is in contact with the plunger a through window is made in the opening of the housing, and in the part of the housing base limited by the annular support protrusion, in addition, a lens is placed in the annular support protrusion, towards which the image-receiving surface of the imaging device and LEDs are facing, an additional support protrusion located on the base of the housing is located inside the case in which the operating mode switch is connected, connected to the printed circuit board by means of connecting wires, and means connected to the printed circuit board are introduced m of connecting wires, a power switch connected to the base of the housing and an audible warning device located on the ring support ledge.

This device also does not ensure the uniformity of the light flux from the light sources over the entire area of the reading area, and therefore it also has all of the above disadvantages of the electronic manual video enlarger [1].

The technical result of the proposed utility model is to improve the quality of the image generated by the electronic manual video enlarger due to the alignment of the light flux from the light source over the entire area of the video enlarger reading area.

The technical result is achieved by the fact that it is proposed an electronic manual video enlarger, including a housing, a hollow support protrusion located inside the housing on the bottom wall of the housing, while a through window is installed in the part of the lower wall of the housing limited by the hollow support protrusion, and a printed circuit board containing a receiver is installed on the hollow support protrusion images located inside the hollow support protrusion of the lens and at least one light source, characterized in that inside the hollow support protrusion between the light source and the plane of the through window, at least one light-scattering element is installed in which a hole is made, the size of which corresponds to the diameter of the lens.

In this case, the light-scattering element can be made of various materials, such as frosted glass or light-transmitting plastic. The light-scattering element can be made, for example, in the form of a flat plate in which a circular hole is made coaxially with the image receiver and the lens, the diameter of which corresponds to the external diameter of the lens.

Due to the fact that in the proposed electronic manual video enlarger, a light-scattering element is installed between the light source and the plane of the through window made in the lower wall of the housing, the light flux from the light source before it enters the reading area is scattered and aligned over the area, and as a result, the illuminated plots and significantly improves the quality of the image obtained using the electronic hand magnifier.

The utility model is illustrated by drawings, which show a preferred embodiment of the proposed electronic manual video enhancer.

In Fig.1 shows a schematic representation of the proposed electronic manual video enlarger in section.

Figure 2 shows a schematic view of the bottom of the proposed electronic manual video enlarger.

Figure 1 is a schematic sectional view of the proposed electronic manual video enhancer. The housing 1 is designated, inside the housing there is a hollow support protrusion 2 made on the bottom wall of the housing 1, a through window 3 is made in the part of the lower wall of the housing 1 bounded by the hollow support protrusion 2, a printed circuit board of the imager 4 containing the electric circuit of the imager is installed on the hollow support protrusion 2 and an image receiver 5, inside the hollow support protrusion 2 there is a lens 6 and light sources 7, an additional protrusion 8 is made inside the housing, a printed circuit board 9 is installed on it, containing an electric e switches 10 operating modes of the electronic manual video enlarger, allowing to carry out the mode of changing the degree of increase, high-contrast image mode, color or black-and-white image mode, there is a power switch 11 on the side wall of the housing, inside the hollow support ledge 2 between the light sources 7 and the plane of the through window 3, a light-scattering element 12 is installed in which a through hole is made, the size of which corresponds to the diameter of the lens.

Figure 2 schematically shows a bottom view of the proposed electronic manual video enlarger, the following positions are indicated: body 1, lens 6, through window 3 made in the bottom wall of the body 1, light-scattering element 12, power cable and video signal 13.

The proposed electronic manual video enhancer works as follows. By means of a power cable and video signal 13, a video enlarger is connected to a power source and an information display device having a video input (TV, monitor, etc.) and then placed on a storage medium. The power switch 11 is placed in the "on" position. Inside the hollow support protrusion 2, the light sources 7 are turned on, the light flux from them passing through the diffuser 12 is aligned over the area, and then through the through window 3 it enters the information carrier within the reading area bounded by the hollow support protrusion 2. Moreover, due to the uniform distribution the luminous flux over the area of the reading area eliminates the exposed areas. The light flux reflected from the information carrier passes through the lens 6 and enters the image receiver 5 located on the printed circuit board 4 coaxially with the lens 6. Then, by means of the electric circuit of the driver, a video signal is generated, which is transmitted via cable 13 to the display device. In the process, the user can move the electronic manual video enlarger on the surface of the information medium, and also, using the switches 10, change its operation modes: change the degree of increase, turn on the high-contrast image mode, turn on the color or black-and-white image modes.

Thus, the proposed utility model allows to obtain a significant improvement in the quality of the image formed by the electronic manual video enlarger, in comparison with analogues.

Information sources.

1. RF patent No. 106413 IPC G06K 7/10, priority 10.07.2011;

2. RF patent No. 85710 IPC G06K 9/00, G06K 9/36, priority December 22, 2008.

Claims (3)

1. An electronic manual video enlarger, comprising a housing, a hollow support protrusion located inside the housing, made on the bottom wall of the housing, while a through window mounted on the hollow support protrusion of a printed circuit board containing an image receiver is formed in a part of the lower housing wall bounded by the hollow support protrusion located inside the hollow support protrusion of the lens and at least one light source, characterized in that inside the hollow support protrusion between the light source and the plane through 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. 2. The electronic manual video enlarger according to claim 1, characterized in that the diffuser is made of frosted glass. 3. The electronic manual video enhancer according to claim 1, characterized in that the light-scattering element is made of light-transmitting plastic.