KR101247218B1 - Optical Device for Information Detection Apparatus and Information Detection Apparatus Comprising the Same - Google Patents

Abstract

The present invention relates, in particular, to an optical device for use in a device for detecting information of a continuous individual value located at a long distance or at high speed, and to an information detecting device according to the present invention. A collimating optical unit which includes a light emitting unit and a light receiving unit having an optical system, and collimates the light emitted from the sensor unit capable of scanning and recognizing a code applied to an object and converting the collimated light into a first infinite optical system; A reflector reflecting light of the first infinite optical system to form a second infinite optical system; And a diverging optical unit converting the light of the second infinite optical system into a second finite optical system, wherein the reflecting unit and the diverging optical unit are relatively movable with respect to the collimating optical unit.

Description

Optical device for information detection device and information detection device including the same {Optical Device for Information Detection Apparatus and Information Detection Apparatus Comprising the Same}

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an optical device for an information detection device and an information detection device including the same. It is about.

An information detection device that recognizes a value assigned to the object from a particular object and detects information embedded in the value, for example, a barcode scanner device that recognizes a barcode attached to a product to detect information contained in the barcode Operates on objects that are stationary at close range.

The recognition distance can be increased to some extent by adjusting the light output or wavelength of the laser light source mainly used for the barcode scanner, but it is difficult to recognize the barcode attached to the moving object without stopping.

In particular, it is difficult to recognize and identify all the barcodes of the vertically stacked products when the barcoded products are vertically stacked and moving in the horizontal direction, as is commonly seen in logistics sites.

However, in order to increase the logistics efficiency, it is indispensable that a technology capable of recognizing and identifying all barcodes of stacked products without stopping moving goods.

The present invention has been made to solve the above problems, and an object of the present invention is to recognize and recognize all of the barcodes attached to a plurality of stacked products without stopping the movement of the goods when the horizontal movement of the plurality of products stacked It is to provide a means of identifying.

In order to achieve the above object, the optical device for information detecting apparatus according to the present invention comprises a light emitting portion and a light receiving portion having a first finite optical system, and the light emitted from the sensor portion capable of scanning and recognizing a code applied to the object Collimating the collimating optical unit to convert into a first infinite optical system; A reflector reflecting light of the first infinite optical system to form a second infinite optical system; And a diverging optical unit converting the light of the second infinite optical system into a second finite optical system, wherein the reflecting unit and the diverging optical unit are relatively movable with respect to the collimating optical unit.

In one embodiment, the reflecting portion and the diverging optical portion are movable in the same direction as the optical path of the first infinite optical system.

In another embodiment, the reflecting unit and the diverging optical unit are rotatable to change an angle formed by the optical paths of the first infinite optical system and the second infinite optical system.

In another embodiment, the diverging optical portion is relatively movable with respect to the reflecting portion in the same direction as the optical path of the second infinite optical system.

In another embodiment, the diverging optical unit is configured to adjust the light divergence angle of the second finite optical system.

In this case, the diverging optical unit may include a second zoom optical unit configured by two or more optical lenses.

In an embodiment, the apparatus may further include a first zoom optical unit disposed in at least one of the first finite optical system or the first infinite optical system.

In one embodiment, the length of the first finite optical system is smaller than the effective recognition distance of the sensor unit.

The present invention also provides an information detecting apparatus in which the above-described optical apparatus for information detecting apparatuses is used, wherein the information detecting apparatus according to the present invention comprises a light emitting portion having a first finite optical system and a light receiving portion and a code applied to an object. A sensor unit capable of scanning and recognizing the scan; A collimating optical unit collimating the light emitted from the sensor unit and converting the collimated light into a first infinite optical system; A reflector reflecting light of the first infinite optical system to form a second infinite optical system; And a diverging optical unit converting the light of the second infinite optical system into a second finite optical system. The reflecting unit and the diverging optical unit are relatively movable with respect to the sensor unit.

According to the optical device for information detecting apparatus according to the present invention as described above, when moving a plurality of products with barcodes in a stacked state, all of the barcodes attached to the plurality of products without stopping the movement of goods and Since it can be identified, the logistics efficiency is improved and the cost is reduced.

1 is a perspective view schematically showing an example of a conventional information detection apparatus.
2 is a perspective view schematically showing the configuration of an embodiment of an optical apparatus for information detecting apparatus according to the present invention.
3 is a conceptual diagram showing in more detail the configuration of the embodiment of the optical device for information detecting apparatus according to the present invention.
4 is a conceptual diagram showing the configuration of another embodiment of an optical apparatus for information detecting apparatus according to the present invention.

Hereinafter, an embodiment of an optical device for an information detecting apparatus according to the present invention will be described in detail with reference to the accompanying drawings.

First, a configuration of a conventional information detection apparatus will be described with reference to FIG. 1. 1 is a perspective view schematically showing an example of a conventional information detection apparatus, and shows a barcode scanner 10 as an example of the information detection apparatus. Conventional information detection apparatus can be seen that typically consists of a bar code scanner 10 and the laser light 20 to be transmitted from the bar code scanner (10). The laser light 20 used for the barcode scanner 10 has an effective recognition distance f and an azimuth angle θ. The effective recognition distance f is a distance between the barcode scanner 10 and a barcode (not shown), which means the maximum distance that the barcode scanner 10 can recognize and identify the barcode, and is typically about 300-400 mm. The azimuth angle θ is the divergence angle of the laser light 20 emitted by the finite optical system, and barcode scanning is possible only when the barcode is within this angle range. The azimuth angle θ typically has a range of about 40-50 degrees.

The conventional barcode scanner 10 configured as described above has a problem in that the barcode cannot be scanned when the barcode is located outside the effective recognition distance f or outside the range of the azimuth angle θ. In particular, when a barcode scanner is linearly or rotationally moved at high speed to continuously scan a plurality of barcodes attached to a plurality of stacked products, an external force such as vibration or shock is applied to a rotating mirror (not shown) inside the barcode scanner. There is a problem that the recognition rate falls.

Hereinafter, an embodiment of an optical device for information detecting apparatus according to the present invention will be described in detail with reference to FIGS. FIG. 2 is a perspective view schematically showing the configuration of an embodiment of the optical device for information detecting apparatus according to the present invention, and FIG. 3 shows the configuration of the embodiment of the optical device for information detecting apparatus according to the present invention in more detail. A conceptual diagram.

The optical device for information detecting apparatus according to the present invention includes a collimating optical unit 310, a reflecting unit 350, and a diverging optical unit 330.

The collimating optical unit 310 collimates (converts to parallel light) the divergent light emitted from the sensor unit 100 to form a first infinite optical system. The collimating optical unit 310 may include one or more optical lenses of a spherical lens, an aspherical lens, or a cylindrical lens.

In the present embodiment, the light 200 is intended to be a laser light commonly used in bar code scanner, but is not limited thereto. The wavelength of the laser light used in this embodiment is in the range of 400-800 nm.

The sensor unit 100 is not a component of the optical apparatus for information detecting apparatus according to the present invention, but is a component of the information detecting apparatus including the optical apparatus. Therefore, other components are not particularly distinguished for convenience of description. I will explain with you. The sensor unit 100 forms a first finite optical system 210 made of divergent light, and scans and recognizes a code such as a barcode provided to an object such as a product. It is preferable that the length L _f1 of the first finite optical system 210 is smaller than the effective recognition distance f of the sensor unit 100. In the present exemplary embodiment, the sensor unit 100 is intended to be a barcode scanner including a laser light emitting unit (not shown) and a light receiving unit (not shown). However, the sensor unit 100 of the present invention is not limited thereto. It should be understood to encompass all sensor devices capable of recognizing and identifying the information contained in the individual values.

By collimating the divergent light from the collimating optical unit 310 to form the first infinite optical system 250, as described later, the effective recognition distance f of the conventional sensor unit 100, or the first finite optical system 210 It is possible to transmit the light 200 to a distance far greater than the length L _f1 ) of the light emitting device with almost no light output degradation. That is, the first infinite optical system length L _i1 ≫ the first finite optical system length L _f1 is established, which results in a significant increase in the effective recognition distance f of the sensor unit 100.

The reflector 350 reflects the parallel light of the first infinite optical system 250 passing through the collimating optical unit 310 at a predetermined angle and direction, thereby bending the optical path 201 so that the second infinite optical system 260 may be broken. Form. The reflector 350 may be configured by a mirror, a prism, or the like, and may include a beam splitter, a polarization beam splitter, or the like.

The parallel light of the second infinite optical system 260 is converted back into the diverging light while passing through the diverging optical unit 330 to form the second finite optical system 220. The divergent optical unit 330 may include one or more optical lenses of a spherical lens, an aspherical lens, or a cylindrical lens. In addition, the light divergence angle, that is, the azimuth angle θ _r , can be adjusted to be wider or narrower by changing the configuration of the divergent optical unit 330. As an example of adjusting the azimuth by changing the configuration of the divergent optical unit 330, there is a method of including a zoom lens in the divergent optical unit 330.

In order to prevent unnecessary light loss, the diameters (d ₁ and d ₂ ) of the lenses included in the collimating optical unit 310 and the diverging optical unit 330 are parallel to the first and second infinite optical systems 250 and 260. It is preferably formed larger than the diameter or width d _{c of} light.

The divergent light of the second finite optical system 220 is reflected by a barcode attached to an object including a barcode, and then, again, in the order of the diverging optical unit 330, the reflecting unit 350, and the collimating optical unit 310. It returns to the light receiving part of the sensor part 100 in reverse through 201). The sensor unit 100 recognizes a bar code by reading the light 200 received by the light receiving unit. The sensor unit 100 may further include an identification unit (not shown) for identifying the recognized barcode to detect information included in the barcode.

Meanwhile, in the present embodiment, the reflector 350 and the divergent optical unit 330 are configured to be relatively movable with respect to the collimating optical unit 310 or the sensor unit 100. In one embodiment, the reflecting unit 350 and the diverging optical unit 330 are configured to be movable in the same direction A as the optical path 201 of the first infinite optical system 250. In order to continuously recognize a plurality of barcodes attached to a plurality of stacked objects, the sensor unit 100 must be moved along a plurality of stacked objects. However, when the sensor unit 100 moves at high speed, a rapid acceleration and a rapid deceleration are performed. Due to mechanical inertia and shock during high-speed movement, the recognition error is easily generated, and there is a problem that the risk of damage to the sensor unit 100 is increased. In order to solve this problem, in the present embodiment, the sensor unit 100 itself is fixed and the movable optical path 201 is formed, whereby the second finite optical system 220 directly emitted to the barcode for barcode recognition of the object. Position of divergent light can be moved at high speed. This configuration, as mentioned above, can transmit the light 200 to a distance far farther than the effective recognition distance f of the conventional sensor unit 100 or the length L _f1 of the first finite optical system 210. By doing so, a result such as dramatically increasing the effective recognition distance f of the sensor unit 100 is achieved.

In another embodiment, the reflector 350 and the diverging optical unit 330 are rotatable to change the angle formed by the optical path 201 of the first infinite optical system 250 and the second infinite optical system 260. It is configured. When the number of objects stacked is not so large that the reflecting unit 350 and the diverging optical unit 330 have a small range to move, simply by simply rotating the reflecting unit 350 and the diverging optical unit 330 There may be a case where all of a plurality of barcodes can be recognized. In addition, when a plurality of stacked objects are not placed vertically but are placed slightly inclined for some reason, the barcode is recognized by rotating the reflector 350 and the divergent optical unit 330 in accordance with the degree of inclination of the object. The efficiency will be improved.

On the other hand, it is also possible to configure the divergent optical unit 330 to move relative to the reflecting unit 350. That is, the length L _i2 of the second infinite optical system 260 may be configured to vary. When the object to which the barcode is attached moves from a position outside the effective recognition distance of the divergent optical unit 330, the divergent optical unit 330 itself is moved toward the object so that the object is positioned within the effective recognition distance, thereby improving work efficiency. Can be improved. In this case, since the length of the second infinite optical system 260 is extended, the loss of light output due to the length extension is extremely small, and there is no need to worry about the recognition rate deterioration due to the decrease in the light output.

4 is a conceptual diagram showing the configuration of another embodiment of an optical apparatus for information detecting apparatus according to the present invention.

According to the embodiment illustrated in FIG. 4, the divergent optical unit 330 may include a second zoom optical unit 335 configured by two or more optical lenses. The focal length of the light may be changed by the second zoom optical unit 335, thereby adjusting the azimuth angle of the divergent light from the divergent optical unit 330. In addition, depending on the structure of the second zoom optical unit 335, the distance between the divergent optical unit 330 and the reflecting unit 350 may be changed by the zooming operation of the second zoom optical unit. The effective recognition distance of 330 may be changed.

Similarly, the first zoom optical unit 320 may be provided before and after the collimating optical unit 310, that is, on the first finite optical system 210 and / or the first infinite optical system 250.

The optical apparatus for information detecting apparatus and the information detecting apparatus including the same according to the present invention have been described above with reference to the accompanying drawings. However, the scope of the present invention is not limited to the above-described embodiments and the scope of the present invention. It should be noted that is determined solely by the scope of the claims below.

10, 100: barcode scanner 20, 200: laser light
201: optical path 210: first finite optical system
220: second finite optical system 250: first infinite optical system
260: Second Infinite Optical System 310: Collimated Optics
330: divergent optical unit 350: reflecting unit
400: Object A: direction of reflection

Claims (9)

A collimating optical unit that includes a light emitting unit and a light receiving unit having a first finite optical system, and collimates the light emitted from a sensor unit capable of scanning and recognizing a code applied to an object to convert the collimating light into a first infinite optical system. ;
A reflector reflecting light of the first infinite optical system to form a second infinite optical system; And
A diverging optical unit converting the light of the second infinite optical system into a second finite optical system which diverges the light;
And,
And the reflecting unit and the diverging optical unit are movable in the same direction as the optical path of the first infinite optical system with respect to the collimating optical unit. delete The method of claim 1,
And the reflecting unit and the diverging optical unit are rotatable to change an angle formed by the optical paths of the first infinity optical system and the second infinity optical system. The method of claim 1,
And the diverging optical unit is movable with respect to the reflecting unit in the same direction as the optical path of the second endless optical system. The method of claim 1,
The divergent optical unit is an optical device for information detection apparatus, characterized in that configured to adjust the light divergence angle of the second finite optical system. The method of claim 5,
The divergent optical unit includes a second zoom optical unit configured by two or more optical lenses. The method of claim 1,
And a first zoom optical unit disposed in at least one of the first finite optical system and the first infinite optical system. The method of claim 1,
And a length of the first finite optical system is smaller than an effective recognition distance of the sensor unit. A sensor unit including a light emitting unit and a light receiving unit having a first finite optical system and capable of scanning and recognizing a code applied to an object;
A collimating optical unit collimating the light emitted from the sensor unit and converting the collimated light into a first infinite optical system;
A reflector reflecting light of the first infinite optical system to form a second infinite optical system; And
A diverging optical unit converting the light of the second infinite optical system into a second finite optical system which diverges the light;
And,
And the reflecting unit and the diverging optical unit are movable in the same direction as the optical path of the first infinite optical system with respect to the sensor unit.

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