RU211334U1 - STATIONARY OPTICAL SCANNER - Google Patents

Abstract

The utility model relates to devices for reading information carriers. The technical result is to reduce the number of errors when reading the encoded information. The technical result is achieved due to the fact that a stationary optical scanner containing a base, a scanning unit hinged to the base, also contains scanning control buttons arranged in a row on the upper part of the scanning unit. The line connecting the central parts of the buttons is parallel to the axis of rotation. Straight lines in the direction in which the buttons move when they are used intersect the axis of rotation. The scanning unit contains upper and lower light diffusers. The planes of the diffusers are made parallel to the axis of rotation. The rear part of the lens of the scanning unit is directed to the scanning matrix fixed on the electronic board, and the front part is pushed forward relative to the rear edge of the lens hood, made with a hole behind which there is an LED indicator fixed on the electronic board to form a light signal on the surface located near the focal plane of the scanning lens. On the electronic board there are two groups of backlight LEDs for uniform effective illumination of diffusers. 1 w.p. f-ly, 3 ill.

Description

The utility model relates to devices for reading data from information carriers, mainly designed to read one-dimensional (1D) and two-dimensional (2D) barcodes, and can be used in a trade and service enterprise for electronic transmission of information as part of a transaction for the goods or services provided, also for production and warehouse accounting in the production, receipt, sale and inventory of inventory items, as well as for authentication and withdrawal from circulation of marked goods in the state information system "Honest Sign" (GIS MT).

In the prior art, a portable reader is known for reading and decoding character marks of direct application, including those from mirror surfaces (RF patent RU 120798, publ. made of matt material with built-in LEDs and mounted on the outside of the lighting chamber to increase the area illuminated by diffuse light in combination with diffuse lighting in general.

The specified device is intended mainly for reading character marks of direct application from cylindrical and tubular surfaces and its main disadvantage is the uneven intensity of the scattered field and the predominantly direct direction of the indicatrix of the scattered light flux, which leads to the formation of an intense reflected light flux in the direction of the photodetector and, accordingly, the instability of his work.

A device for reading luminescent symbols and images is known (RF patent RU2430414, publ. 27.09.2011 G06K7/10), consisting of a porthole with an array of LEDs that excite luminescence and an optical system that projects the read information onto the scanner sensor, an optoelectronic system consisting of an electronic control circuit, an optical filter and a lens with a light-guiding illuminator provided with an output window and connected to the body of the data collection terminal or scanner by means of a constructive connector and switching connections for controlling the device LEDs, moreover, the switching connections between the scanner and the device are made optically by means of scanners receiving light pulses installed in the body devices of photosensors that control the porthole and the aiming system. The specified device was chosen as a prototype of the claimed utility model.

The specified device is intended primarily for reading information from labels, images, barcodes applied using specialized luminescent compositions, which limits its scope. It is theoretically possible to read standard printed characters by removing the specialized attachment, but the reading efficiency is reduced due to the need for precise positioning of the optical device in the process of reading optical information from a short distance for successful image capture.

The technical result achieved in the implementation of the claimed utility model is to reduce the number of errors when reading the encoded information.

This result is achieved by eliminating the effect of glare on the scanning results, the possibility of more accurate positioning of the information carrier, as well as eliminating the possibility of unwanted movement of the device when using the control keys. At the same time, an increase in the uniformity of illumination of the scattered field and an improvement in the ergonomics of the device are achieved.

The claimed technical result is achieved through the use of a scanner design containing a base, one edge of which is designed to be attached to a fixed surface, and the other side of the base is pivotally attached to the lower part of the scanning unit housing with the possibility of rotation about one axis of rotation, while on the upper part of the scanning unit the scanning control buttons are arranged in a row so that a straight line connecting the central parts of the buttons is parallel to the axis of rotation, and at least one of the straight lines passing in the direction of movement of the buttons when they are used would cross the axis of rotation;

on the lower part of the housing there is a multi-interface connector designed to connect the scanner to external devices so that the connection of the mating parts of the connector is made from the side of the lower part of the scanner housing, the housing contains the rear and side parts combined with the upper and lower parts, and the front part of the scanner housing is made in the form of a transparent window, behind which the functional elements of the scanner are located, fixed relative to the scanner body, so that the electronic board with the electrical elements of the scanner fixed on it is located near and parallel to the back of the case, near the front of the scanner there are upper and lower light diffusers, each of which is made in the form of translucent matte planes, so that the planes of the diffusers are parallel to the axis of rotation, the upper edge of the upper diffuser and the lower edge of the lower diffuser are located near the front of the housing, and the lower edge of the upper diffuser The diffuser and the upper edge of the lower diffuser are located near the front edge of the hood, the rear edge of which is located near the front surface of the electronic board,

perpendiculars to the central points of the diffusers intersect on the optical axis of the scanning lens at a distance equal to the focal length of the scanning lens located on the front surface of the electronic board so that the back of the lens is directed to the scanning matrix fixed on the electronic board, and the front of the lens is extended forward relative to the rear hood edges;

two groups of backlight LEDs are located on the electronic board to ensure uniform effective illumination of the corresponding diffusers, the hood is made with a hole near the rear edge, behind which there is an LED indicator fixed on the electronic board so that when the LED indicator is operating, a light signal is formed on the surface located near the focal plane of the scanning lens.

Further, the solution is explained by reference to the figures, which show the following.

Fig. 1 - general view of the scanner.

Fig. 2 - general view of the scanner base.

Fig. 3 - cross section of the scanner, side view.

As shown in FIG. 1, a stationary optical scanner contains a base or stand 1, the lower edge of which is intended for fastening to a fixed surface, on the upper edge of the stand, using a hinged fastening 2, with the possibility of rotation about the axis of rotation passing through the hinged fastenings, there is a scanning unit 3, the lower part body of which is attached to the base. The body contains a back and side parts, combined with the top and bottom parts. The housing contains an optical-computing module made in the form of an electronic board 7. On the upper part of the housing of the scanning unit 3, there are buttons 4 for scanning control in a row, and on the lower part of the housing there is a multi-interface connector 5 designed to connect the scanner to external devices. The front part of the scanner body is made in the form of a transparent window, behind which the electronic board 7 with the electric elements of the scanner fixed on it is fixed fixed relative to the body and parallel to its rear part. Near the front of the scanner, there are upper and lower light diffusers 16, each of which is made in the form of translucent matte planes 8 and 9, while the planes of the diffusers are parallel to the axis of rotation of the scanning unit 3. The upper edge of the upper diffuser and the lower edge of the lower diffuser are located near the front parts of the housing, and the lower edge of the upper diffuser and the upper edge of the lower diffuser are located near the front edge of the lens hood 10, the rear edge of which is located near the front surface of the electronic board 7, on which the scanning lens 11 is located in such a way that its rear part is directed to the scanning matrix 12, mounted on the electronic board 7, and the front of the lens is pushed forward relative to the rear edge 14 of the hood.

Perpendiculars to the central points of the diffusers 8, 9 intersect on the optical axis of the scanning lens 11 at a distance equal to the focal length of the scanning lens.

Two groups of backlight LEDs 13 are connected to the electronic board to ensure uniform effective illumination of the corresponding diffusers 8, 9.

The lens hood 12 is made with a hole near the rear edge, behind which there is an LED indicator 17 fixed on the electronic board 7 so that during its operation a light signal is formed on the surface located near the focal plane of the scanning lens 11.

In a particular case of the implementation of the utility model, two image sensors (not shown in Fig.) are located in front in the middle of the scanner window 10, one for reading bar codes, the second for recognizing the authenticity of banknotes and recognizing weight goods. The glass surface 15, which covers the lenses of the image sensors, is recessed into the body of the unit 3 and surrounded by a hood 12 with a surface made in the form of miniature steps.

In a particular case of the implementation of the utility model of the group, diffusers 16 used to illuminate the scanned product are made in the form of planes of frosted plexiglass. To increase the performance of the scanner when reading a barcode from glare surfaces (for example, from under a film), alternate exposure of images of the scanned scene is used with alternately turned on the upper and lower illumination planes.

The lower luminous plane is also used as an indication of the recognition result and, if successful, is highlighted in green. When checking banknotes, if authenticity is not confirmed, the lower plane lights up in red.

In a particular case of the implementation of the utility model, upon successful reading of a barcode or checking a banknote, in addition to igniting the lower plane 13 with a green light, a green spot is projected onto the surface of the scanned product from a narrow-angle green LED, which is activated in case of successful reading.

Mirror reflectors 18 are located between the front surface of the electronic board and the outer edges of the diffusers, providing more efficient illumination of the scanned object.

The claimed technical solution has the following design advantages:

The glass of the image sensors is not illuminated by the backlight LEDs, it is recessed deep and protected from external contaminants.

All electronic components of the device are located on one board (with the exception of optional buttons and indicators on the upper surface of the scanner). The absence of connectors increases reliability, serviceability and reduces the cost of the product.

The illumination intensity is evenly distributed over the entire area of the upper and lower illumination plane due to the fact that the emitting LEDs are located at a considerable distance from them on the electronic board of the scanner. The absence of local bright sources in the operator's field of vision reduces fatigue, and also allows reading even damaged or dirty barcodes.

An adaptive backlight algorithm is used for confident reading from surfaces made of highly reflective materials.

The design of the case and the placement of control buttons on the top of it reduces the likelihood of accidental movement of the scanner to the side during use. Unlike a hand-held scanner, the claimed device is intended for stationary use, and the user brings the product with a barcode to the scanning window on his own. The scanner scans in several planes at once and from a greater distance, so precise positioning is not required, which speeds up the scanning procedure, increasing the productivity of the scanner - this is especially important in sales areas where there are many buyers and a high speed of service is required.

When the device is operating, LED 17 provides the formation of a light spot, the location of which indicates the area from which scanning is performed, while the implementation of the lens hood prevents the formation of bright glare during the operation of the LED, since the light flux passes through the lens hood and is not reflected from the elements of the device. The presence and location of light diffusers, as well as the use of LEDs, which usually have a low turn-on and turn-off inertia, provide the possibility of effective successive illumination of the scanned surface. In this case, the glare generated by the scatterers is located on different parts of the scanned surface. Synchronization of the scanning matrix with the operation of LEDs makes it possible to use selected parts of frames for recognition, which show surface areas without glare formed by diffusers. In addition, when using the scanning control buttons, the forces generated by pressing the buttons pass through the axis of rotation of the body relative to the support, and therefore the change in the position of the scanning unit in space is excluded, which also increases the speed and quality of scanning.

Claims (2)

1. A stationary optical scanner containing a base, one edge of which is designed for attachment to a fixed surface, and the other side of the base is pivotally attached to the lower part of the scanning unit housing with the possibility of rotation about one axis of rotation, while buttons are located in a row on the upper part of the scanning unit scanning control so that a straight line connecting the central parts of the buttons is parallel to the axis of rotation, and at least one of the straight lines passing in the direction of movement of the buttons when using them would cross the axis of rotation, a multi-interface connector is located on the bottom of the case , designed to connect the scanner to external devices in such a way that the connection of the mating parts of the connector is made from the side of the lower part of the scanner housing, the housing contains the back and side parts combined with the upper and lower parts, and the front part of the scanner housing is made in the form of a transparent window, behind which located functional elements of the scanner, fixed relative to the body of the scanner so that the electronic board with the electric elements of the scanner fixed on it is located near and parallel to the rear part of the body, near the front part of the scanner there are upper and lower light diffusers, each of which is made in the form of translucent matte planes so that the planes of the diffusers are parallel to the axis of rotation, the upper edge of the upper diffuser and the lower edge of the lower diffuser are located near the front of the housing, and the lower edge of the upper diffuser and the upper edge of the lower diffuser are located near the front edge of the hood, the rear edge of which is located near the front surface of the electronic board , perpendicular to the central points of the diffusers, intersect on the optical axis of the scanning lens at a distance equal to the focal length of the scanning lens located on the front surface of the electronic board so that h then the back of the lens is directed to the scanning matrix fixed on the electronic board, and the front of the lens is pushed forward relative to the rear edge of the hood; two groups of backlight LEDs are located on the electronic board to ensure uniform effective illumination of the corresponding diffusers, the hood is made with a hole near the rear edge, behind which there is an LED indicator fixed on the electronic board so that when the LED indicator is operating, a light signal is formed on the surface located near the focal plane of the scanning lens. 2. Stationary optical scanner according to claim 1, characterized in that mirror reflectors are located between the front surface of the electronic board and the outer edges of the diffusers.

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