JP2016105313A - Floor-standing type information code reader - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a floor-standing type information code reader capable of improving reading performance for a picked-up image obtained by imaging a visual field range by suppressing polarization of illumination light.SOLUTION: A floor-standing type information code reader 1 includes a light guide member 50 disposed at a position where illumination light from an illumination light source 21 is radiated within a case 3 so as to be configured to guide the illumination light from the illumination light source 21 to be radiated to an outside of the case 3 via an opening region γ of a read port 5. This light guide member 50 guides the illumination light so that illumination light passing through a high illuminance region defined near a peripheral edge portion of a visual field range AR is higher in illuminance than illumination light passing through a center part P1 of the visual field range AR in the opening region γ.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a stationary information code reader.

  Currently, information code readers that read information codes such as barcodes and QR codes (registered trademark) are widely provided, and stationary readers are also used in stores and offices. This stationary information code reader generally has a reading port formed in a case, and an imaging unit made up of a light receiving sensor and the like, and a visual field range that can be imaged by the imaging unit are defined inside the case. An imaging lens is provided. In this type of stationary information code reader, when an information code is deceived toward the reading port within the field of view set outside the case, the information code is picked up by the image pickup unit, and the image is picked up. The code image is decoded by a known decoding method.

JP-A-8-123891

  By the way, in the above-described stationary information code reader, due to the characteristics of the optical system (imaging lens, etc.) that sets the field of view, the light that enters the imaging unit from the field of view is closer to the periphery than the center of the field of view. Often becomes relatively small, and when such a bias of light increases, a decoding failure due to insufficient luminance is likely to occur.

  The present invention is to solve the above-described problems, and provides a stationary information code reader capable of improving reading performance by suppressing bias of illumination light in a captured image obtained by imaging a visual field range. The purpose is to do.

The present invention includes a case in which a reading port serving as a light entrance is formed on one side in a predetermined vertical direction;
An illumination light source that emits illumination light;
It is arranged at a position where the illumination light from the illumination light source is irradiated inside the case, and the illumination light from the illumination light source is irradiated to the outside of the case through an opening area of the reading port. A light guiding member for guiding;
An imaging unit;
The visual field range that can be imaged by the imaging unit is determined, and the light that has entered through the reading port from the outside of the case is guided to the imaging unit, and information within the visual field range is outside the case. An imaging unit that forms an image of the information code on the imaging unit when the code is disposed;
A decoding unit that decodes a code image of the information code when the information code arranged in the visual field range is imaged by the imaging unit;
With
The light guide member includes a pair of first reflecting portions facing each other in a predetermined first direction orthogonal to the vertical direction, and a pair opposing each other in a predetermined second direction orthogonal to the vertical direction and the first direction. A second reflective portion,
In the pair of first reflecting portions, the reflecting surface of one of the first reflecting portions is configured as an inclined surface that becomes a lower position as it approaches the other first reflecting portion in the first direction, and the other first reflecting portion. The reflective surface of the part is configured as an inclined surface that becomes a lower position as it approaches the one first reflective part in the first direction,
In the pair of second reflecting portions, the reflecting surface of one second reflecting portion is configured as an inclined surface that becomes a lower position as it approaches the other second reflecting portion in the second direction, and the other second reflecting portion. The reflective surface of the part is configured as an inclined surface that becomes a lower position as it approaches the one second reflective part in the second direction,
The illumination light source irradiates the illumination light to any one of the one first reflection unit, the other first reflection unit, the one second reflection unit, and the other second reflection unit. To do.

The invention according to claim 1 is configured to guide the illumination light from the illumination light source to the outside of the case through the opening area of the reading port to the position where the illumination light from the illumination light source is irradiated inside the case. A light guide member is arranged. The light guide member includes a pair of first reflecting portions facing each other in a predetermined first direction orthogonal to the vertical direction, and a pair of facing each other in a predetermined second direction orthogonal to the vertical direction and the first direction. A second reflecting portion. And in a pair of 1st reflective parts, the reflective surface of one 1st reflective part is comprised as an inclined surface which becomes a lower position as it approaches the other 1st reflective part in the 1st direction, and the other 1st reflective part The reflecting surface is configured as an inclined surface that becomes a lower position as it approaches one of the first reflecting portions in the first direction. Furthermore, in the pair of second reflecting portions, the reflecting surface of one second reflecting portion is configured as an inclined surface that becomes a lower position as it approaches the other second reflecting portion in the second direction, and the other second reflecting portion. The reflecting surface is configured as an inclined surface that becomes a lower position as it approaches one of the second reflecting portions in the second direction. The illumination light source is configured to irradiate illumination light to any one of the first reflection unit, the other first reflection unit, the one second reflection unit, and the other second reflection unit.
In this configuration, both the first reflecting portions arranged in a pair in the first direction and the reflecting surfaces of both the second reflecting portions arranged in a pair in the second direction have a field-of-view range in the plane direction. The side far from the center position is the upper position, and the side closer to the center position of the visual field range in the plane direction is the lower position. For this reason, since the 1st reflective part and the 2nd reflective part shine brightly as a whole, since the bias | inclination of illumination light is suppressed, reading performance can be improved more reliably.

FIG. 1 is a perspective view schematically showing a stationary information code reader according to the first embodiment. 2 is a perspective view of the stationary information code reader of FIG. 1 as viewed from a direction different from that of FIG. FIG. 3 is a plan view of the stationary information code reader of FIG. FIG. 4 is a schematic cross-sectional view schematically showing the AA cross section of FIG. 3. FIG. 5 is a schematic cross-sectional view schematically showing a BB cross section of FIG. FIG. 6 is a schematic cross-sectional view schematically showing a cross-section CC of FIG. FIG. 7 is a schematic cross-sectional view schematically showing a DD cross section of FIG. 4. FIG. 8 is a schematic cross-sectional view schematically showing a cross section taken along line EE of FIG. FIG. 9 is a block diagram schematically illustrating an electrical configuration of the stationary information code reader of FIG. FIG. 10 is an explanatory diagram for explaining a high illuminance area and the like configured by the stationary information code reader of FIG. FIG. 11 is a schematic cross-sectional view schematically showing a stationary information code reader according to the second embodiment. FIG. 12 is a schematic cross-sectional view schematically showing a stationary information code reader according to the third embodiment. FIG. 13 is a schematic cross-sectional view schematically illustrating a stationary information code reader according to the fourth embodiment. FIG. 14 is an explanatory diagram showing the relationship between the field angle of the wide-angle lens and the field of view. FIG. 15 is a plan view of a stationary information code reader according to the fifth embodiment. FIG. 16A is an explanatory diagram illustrating a state in which the imaging unit is mounted on the substrate such that the longitudinal direction of the light receiving surface is along the vertical direction, and FIG. 16B is a longitudinal direction of the light receiving surface. It is explanatory drawing which shows the state in which the imaging part was mounted in the board | substrate so that it may follow.

[First embodiment]
DESCRIPTION OF EXEMPLARY EMBODIMENTS Hereinafter, a first embodiment in which an optical information reading device of the invention is embodied will be described with reference to the drawings.
(Overall configuration of optical information reader)
The stationary information code reader 1 (hereinafter also referred to simply as the reader 1) shown in FIGS. 1 to 3 and the like has an upper surface such as a desk or a shelf as a placement surface (see the placement surface F in FIGS. 4 and 5). ) As an information code reader for reading an information code such as a one-dimensional code such as a barcode or a two-dimensional code such as a QR code (registered trademark). It has a function.

  The reading device 1 includes a case 3 made of a resin material such as ABS resin. As shown in FIGS. 4 to 6 and the like, the case 3 includes an upper case 4a and a lower case 4b, and the upper case 4a and the lower case 4b are vertically assembled in a box shape as a whole. Is formed. The case 3 accommodates components such as a reflection member 29, an imaging unit 27, an imaging unit 23, and a light guide member 50 described later. Further, as shown in FIG. 3 and the like, a reading port 5 serving as a light entrance / exit is formed in the upper surface portion (reading side wall portion 3a) of the case 3, and light from outside the case is transmitted through the reading port 5 to the case. The light enters the inside, and light from inside the case is emitted outside the case. The optical system including the reflecting member 29, the imaging unit 27, and the imaging unit 23 functions so as to image an information code outside the case through the reading port 5.

  Further, the case 3 configured in a box shape has a bottom wall portion 3b provided on the placement surface side (placement surface F side in the example of FIG. 4) when the stationary information code reader 1 is placed. The reading side wall 3a in which the reading port 5 is formed is provided so as to be opposed to the reading side wall 3a. The bottom wall portion 3b is disposed so as to be supported by the mounting surface F, and the reading side wall portion 3a facing the bottom wall portion 3b is configured as an exposed wall portion on the side where the information code C is held. . In this configuration, the facing direction of the bottom wall portion 3b and the reading side wall portion 3a (that is, the thickness direction of the case 3 and the direction perpendicular to the mounting surface F shown in FIG. 2) is defined as the vertical direction. The side where the mouth 5 is formed (the reading side wall 3a side) is the upper side, and the opposite side (the bottom wall 3b side) is the lower side. The plane direction orthogonal to the vertical direction is the horizontal direction. The thickness direction of the plate 7 (that is, the direction orthogonal to the plate surface of the plate 7) is also the vertical direction, and the direction of the optical axis L2 of the second visual field range AR2 described later is also the vertical direction.

  On the upper surface side of the case 3, the plate 7 is disposed so as to close the opening 4 c formed at the upper end portion of the upper case 4 a. The plate 7 is configured as a flat plate having a predetermined thickness, and is configured by a light-transmitting member (for example, transparent acrylic resin or transparent glass) that can transmit light from the outside of the case 3. Yes. The plate 7 functions as a dustproof plate, and the plate 7 closes the opening 4c formed in the upper case 4a, thereby closing the case 3, and the inside of the case 3 (particularly, the reflecting member). 29, the image forming unit 27, the image capturing unit 23, and the like (containment space), foreign matter (dust, dust, etc.) from outside the case is difficult to enter. In addition, a coating layer 8 made of a light-shielding paint or the like is formed so as to partially cover the upper surface portion of the plate 7 (the plate surface portion exposed to the outside of the case). The covering layer 8 is formed in an annular shape along the peripheral edge of the plate 7, and an opening formed by the inner edge of the covering layer 8 is a reading port 5.

  Next, the electrical configuration of the reading device 1 will be described. As shown in FIG. 9, the reading apparatus 1 mainly includes an optical system such as an illumination light source 21, an imaging unit 27, and an imaging unit 23, and a microcomputer such as a memory 35 and a control circuit 40 (hereinafter referred to as "microcomputer"). And a power supply system such as a power supply unit and a power switch (not shown).

  The optical system is divided into a light projecting optical system and a light receiving optical system. The illumination light source 21 constituting the light projecting optical system functions as a light source capable of irradiating illumination light, and is constituted by, for example, an LED. The illumination light source 21 includes first light sources 21 a and 21 b disposed on one side in the longitudinal direction of the case 3 and second light sources 21 c and 21 d disposed on the other side in the longitudinal direction of the case 3. Each of the light sources 21a and 21b and the second light sources 21c and 21d is configured as a light projecting element such as an LED, and has a function of irradiating illumination light laterally with respect to the vertical direction.

  As shown in FIGS. 1 to 8, the light projecting optical system includes a light guide member 50 that guides light from the illumination light source 21. The light guide member 50 is disposed inside the case 3 at a position where the illumination light from the illumination light source 21 is irradiated, and the illumination light from the illumination light source 21 covers the opening region γ (see FIG. 4 and the like) of the reading port 5. The structure is such that it passes through the case 3 and is irradiated. Details of the light guide member 50 will be described later.

  As shown in FIG. 9, the light receiving optical system includes an imaging unit 23, an image forming unit 27, a reflecting member 29 (FIGS. 1 and 2, etc.), and the like.

  The imaging unit 23 includes a light receiving sensor (area sensor) in which solid-state imaging elements (light receiving elements) such as CCD elements and CMOS elements are two-dimensionally arranged, as shown in FIGS. In addition, a light receiving surface 23 a that can receive light from outside the case is disposed on the side facing the imaging unit 27. The imaging unit 23 is mounted on the substrate so that the light reflected by the reflecting member 29 can receive incident light that passes through the imaging unit 27 and enters the light receiving surface 23a. Then, for example, as shown in FIG. 9, when the reading object R on which the information code C is shown is arranged within the field of view (for example, the surface on the reading object R on which the information code C is displayed is an open area) When arranged so as to be in contact with or close to the plate 7 in γ), the information code C and the reflected light Lr (see FIG. 9) reflected and reflected on the reading object R are received. Further, in the imaging unit 23, a region where light can be detected on the light receiving surface 23a (a region where the solid-state imaging device is disposed) is set as a “predetermined light receiving region”. In FIG. The range of the area is conceptually indicated by reference numeral D1. That is, the light incident on the range D1 on the light receiving surface 23a is detected by the imaging unit 23. In the example illustrated in FIG. 4 and the like, the range of the light receiving region in the imaging unit 23 is, for example, a predetermined range in the vertical direction centered on the optical axis L1 on the light receiving surface 23a, and left and right centered on the optical axis L1. The direction (width direction) is a predetermined range. In the example shown in FIG. 4 and the like, the light receiving surface 23a is disposed substantially orthogonal to the front-rear direction.

  The imaging unit 27 is configured by a known imaging lens and functions as an imaging optical system. The imaging unit 27 defines a field of view range that can be imaged by the imaging unit 23, and light that enters through the reading port 5 from the outside of the case 3 (specifically, the incident light is reflected by the reflecting member 29. The reflected light) is guided to the light receiving area of the imaging unit 23. The imaging unit 27 functions to form an image of the information code C in the light receiving region of the imaging unit 23 when the information code C is disposed within the field of view outside the case 3. In this configuration, the information code C can be imaged while the illumination light irradiated from the illumination light source 21 and guided to the outside of the case by the light guide member 50 is applied to the information code C. When the information code C is arranged within the visual field range (in the imaging area), the reflected light Lr from the information code C is collected and an image of the information code C is formed on the light receiving surface 23a of the imaging unit 23. It is configured to let you. As the imaging unit 27, for example, a wide-angle lens with a short focal length and a wide angle of view can be suitably used.

  As shown in FIG. 9, the microcomputer system includes an amplification circuit 31, an A / D conversion circuit 34, a memory 35, an address generation circuit 36, a synchronization signal generation circuit 38, a control circuit 40, and the like. The image signal of the information code C imaged by the system is configured to perform signal processing. Specifically, data of a captured image when the information code C arranged in the visual field range is captured by the imaging unit 23 is configured to be able to be stored in the memory 35, and the control circuit 40 includes such information. The image data of the code C is analyzed, and the data recorded in the information code C is decoded by a known decoding method. The control circuit 40 corresponds to an example of a decoding unit, and functions to decode the code image of the information code C when the information code C arranged in the visual field range is imaged by the imaging unit 23. .

  Although not shown in FIG. 9 and the like, the reading device 1 may be provided with an operation unit such as a push button. In this case, when the user operates the operation unit, the operation unit responds to the operation. A signal is input to the control circuit. Also, a known communication interface may be provided. With this configuration, information can be transmitted from the reading device 1 to an external device (not shown), and the reading device 1 can receive information from the external device. Become. Further, a display unit such as a lamp or a display device may be provided.

  The information code C to be read includes, for example, a QR code (registered trademark), and may be another two-dimensional code such as a data matrix code or a maxi code as long as it is a known code. Alternatively, a known one-dimensional code such as a barcode may be used. The method for forming the information code C to be read is not particularly limited, and various methods such as printing, direct marking, and image display are assumed. Also, the material and structure of the reading object R (FIG. 9) are various, and various materials such as metal materials, resin materials, and paper are targeted, and portable terminals (portable information processing devices such as mobile phones and smartphones). Or other information processing apparatuses.

(Imaging structure)
Next, the imaging structure and the like will be described in detail.
In this configuration, the reflecting member 29, the imaging unit 27, the imaging unit 23, the illumination light source 21, and the light guide member 50 are accommodated in the case 3. Hereinafter, the reflection member 29, the imaging unit 27, the imaging unit 23, the illumination light source 21, the light guide member 50, and the like will be described in more detail.

  In the present specification, in the plane direction (horizontal direction) orthogonal to the vertical direction, the longitudinal direction of the case 3 is defined as the width direction (horizontal direction), and the short direction (vertical direction) of the case 3 in the plane direction (horizontal direction). The direction orthogonal to the direction and the width direction) is the front-rear direction.

  As shown in FIGS. 4 to 6 and the like, in this configuration, a plate-like and substantially rectangular (substantially rectangular) plate 7 is disposed as the upper surface portion (upper wall portion) of the case 3. Corresponds to the reading side wall 3a. As shown in FIG. 3, a reading port 5 having a substantially rectangular shape (substantially rectangular shape) is formed in the central portion in the longitudinal direction and the central portion in the short direction of the plate 7 when the reading device 1 is viewed in plan. When the reading port 5 is viewed in plan as shown in FIG. 3, the reflection member 29 reflects the opening region γ of the reading port 5 (the region inside the boundary line P <b> 3 shown in FIG. 3, see also FIG. 4). It is formed in a size and position so that the entire area (area of the reflecting surface) can be accommodated. That is, in the width direction shown in FIG. 3, the width direction one end part and the other end part of the reflecting member 29 are arranged between the width direction one end part 5a and the width direction other end part 5b of the reading port 5, as shown in FIG. In the front-rear direction, the front-rear end and the other end of the reflecting member 29 are disposed between the front-rear end one end 5 c and the front-rear end other end 5 d of the reading port 5. In addition, the edge part of the width direction one end part 5a and the width direction other end part 5b of the reading opening 5 has extended linearly in the front-back direction, and the front-rear direction one end part 5c and the other end part in the front-rear direction of the reading opening 5 5d extends linearly in the width direction (left-right direction).

  As shown in FIGS. 4 to 6 and the like, the bottom wall portion 3b of the case 3 is configured in a plate shape as the lower surface portion of the case 3, and when the reading device 1 is placed on the placement surface F, The lower surface side of the bottom wall portion 3b is configured to be supported by the placement surface F. The bottom wall portion 3b has a configuration in which the thickness direction is the vertical direction, and most of the outer surface (lower surface) is configured as a substantially flat surface. And it functions as the bottom of case 3 comprised in box shape. In addition, between the reading side wall part 3a (upper surface part) and the bottom wall part (lower surface part), the accommodation space in the case 3 (the space in which the reflection member 29, the imaging part 27, the imaging part 23, etc. are accommodated). A side wall portion 3c is provided so as to surround the periphery. The side wall portion 3c includes a pair of side walls (both extending in the front-rear direction) disposed on both sides in the width direction and a pair of side walls (both extending in the width direction) disposed on both sides in the front-rear direction. These four side walls are annularly connected and arranged. Reading is performed with a configuration in which the upper side of the side wall portion 3c (circumferential wall portion) arranged in this manner is partially closed (specifically, a configuration in which the opening portion 4c formed by the upper end portion of the side wall portion 3c is closed). A plate 7 corresponding to the side wall portion 3a (upper surface portion) is disposed, and a bottom wall portion 3b (lower surface portion) is disposed so as to close the entire lower side of the side wall portion 3c.

  The plate 7 is disposed so as to close the opening formed at the upper end portion of the upper case 4a, constitutes the upper surface portion of the case 3, and includes a reflecting member 29 accommodated in the case 3, and an imaging portion 27. The light guide member 50 is disposed so as to cover the upper side. When viewed in plan as shown in FIG. 3, the exposed portion of the plate 7 (the portion of the opening region γ (FIG. 4) that is the region inside the boundary line P3 conceptually shown in FIG. 3) passes through the case. The reflection member 29, the image forming unit 27, and the light guide member 50 are visually recognized. The plate 7 is configured, for example, as a transparent and flat plate material, and is arranged substantially horizontally so that the direction perpendicular to the plate surfaces (the upper surface 7a and the lower surface 7b) is the vertical direction. The plate 7 corresponds to an example of a transparent member, and functions to close the reading port 5 configured as the inner peripheral portion of the coating layer 8. In other words, the reading port 5 has a configuration that allows light to enter and exit, but does not allow water or dust to enter due to the blocking of the plate 7.

  The reflection member 29 is configured as a mirror, for example, and is housed inside the case 3 and functions to reflect light entering from the outside of the case 3 through the reading port 5. The reflecting member 29 is arranged such that the reflecting surface 29a (mirror surface) faces diagonally upward and one side in the front-rear direction (on the imaging unit 27 side with respect to the reflecting surface 29a). It is configured to reflect the light entering through the light to one side in the front-rear direction. More specifically, the reflecting surface 29a is configured to be flat, and the reflecting surface 29a is disposed so as to be orthogonal to a virtual plane parallel to the up-down direction and the front-rear direction. For example, the up-down direction and the reflecting surface 29a The angle formed is 45 °, and the light entering parallel to the vertical direction is arranged to reflect horizontally.

  Further, the upper end portion 29c of the reflecting surface 29a of the reflecting member 29 (a mirror surface area capable of reflecting light from the upper side and exposed to the upper side) is disposed at a position near the plate 7 in the vertical direction and is reflected. A lower end portion 29b of the surface 29a is disposed closer to the bottom wall portion 3b in the vertical direction. Further, the reflecting surface 29a of the reflecting member 29 is configured such that the width becomes wider toward the upper side so that the lower end portion 29b has the smallest width and the upper end portion 29c has the largest width.

  As described above, the imaging unit 27 is configured by an imaging lens that functions as a wide-angle lens, and is disposed at a position away from the plate 7 as shown in FIGS. 4, 6, 7, and the like. The image forming unit 27 has a function of guiding the light that has entered from the outside of the case 3 through the reading port 5 and reflected by the reflecting member 29 to the light receiving surface 23 a (light receiving region) of the image pickup unit 23. The field-of-view range that can be imaged by the imaging unit 23 inside and outside the case 3 is determined. Specifically, as shown in FIG. 4, the visual field range includes a first visual field range AR1 configured between the imaging unit 27 and the reflecting member 29, and reflection so as to follow the first visual field range AR1. A second visual field range AR2 configured on the upper side from the member 29 is defined. That is, the light from the visual field range is condensed toward the light receiving region of the imaging unit 23 so that the first visual field range AR1 and the second visual field range AR2 are used as the imaging area. The first visual field range AR1 is a visual field range that is collected by the imaging unit 27 and directly captured by the imaging unit 23, and the second visual field range AR2 is an image captured by the reflecting member 29. It is a field of view range to be imaged. The imaging unit 27 configured as described above has an image of the information code C in the light receiving region of the imaging unit 23 when the information code C is arranged in the second visual field range AR2 set outside the case 3. It functions to form an image.

  The first visual field range AR1 shown in FIG. 4 is a range that is imaged by the imaging unit 23 in the space between the imaging unit 27 and the reflection member 29, and gradually increases as the reflection surface 29a of the reflection member 29 is approached. Is set to The optical axis L1 that is the center of the first visual field range AR1 is in the horizontal direction (specifically, the front-rear direction), and the angle formed with the reflection surface 29a is 45 °. Then, as shown in FIG. 4, when the reading device 1 is cut with a plane passing through the optical axis L1 and parallel to the vertical direction as a cut surface, the first visual field range AR1 is spread most vertically on the cut surface. Yes. And in the cut surface shown in FIG. 4 (the cut surface passing through the optical axis L1 and parallel to the vertical direction), the lower boundary of the first visual field range AR1 becomes lower (lower position) as it approaches the reflection surface 29a of the reflection member 29. The upper limit boundary of the first visual field range AR1 is configured to become a higher position (upper position) as it approaches the reflecting surface 29a of the reflecting member 29. Then, on the cut surface shown in FIG. 4 (the cut surface at the AA position shown in FIG. 3, the cut surface obtained by cutting the reading device 1 in the direction orthogonal to the left-right direction at the center position in the left-right direction). The position at which the lower boundary of AR1 reaches the reflecting surface 29a of the reflecting member 29 (the position where the boundary and the reflecting surface 29a intersect) is the lower end position of the first visual field range AR1. Further, the position at which the upper limit boundary of the first visual field range AR1 reaches the reflecting surface 29a of the reflecting member 29 (the position where the boundary and the reflecting surface 29a intersect) is the upper end position of the first visual field range AR1.

  As shown in FIG. 4, in this configuration, the reflective region of the reflective member 29 (the region where the reflective surface 29a is exposed) is located at least at the lower end of the first visual field range AR1, and from the lower end to the upper end of the first visual field range AR1. It continues until. That is, the reflecting surface 29a of the reflecting member 29 is disposed so as to cover the entire vertical region of the first visual field range AR1 on the cut surface as shown in FIG. For example, in the cut surface illustrated in FIG. 4, the upper end portion 29c of the reflection region (the region of the reflection surface 29a) is the same position as the upper end position of the first visual field range AR1 or a position higher than the upper end position. The lower end portion 29b of the reflecting surface 29a is located at the same position as the lower end position of the first visual field range AR1 or below the lower end position. More specifically, the reflecting surface 29a is arranged so as to be reflected in the entire light receiving region of the imaging unit 23. That is, the boundary on the reflecting member 29 side of the first visual field range AR1 is all on the reflecting surface 29a, and the imaging unit 23 is a portion adjacent to the periphery of the reflecting surface 29a (a portion other than the reflecting surface 29a). The entire second visual field range AR2 can be imaged without imaging.

  The second visual field range AR2 is a visual field range that is folded back by the reflecting member 29 so as to follow the first visual field range AR1, and an object or the like that exists in the second visual field range AR2 is reflected on the reflecting member 29 and imaged. The image is picked up by the unit 23. Conversely, the outside of the second visual field range AR2 is not imaged by the imaging unit 23 except for the first visual field range AR1.

  In this configuration, the reflection surface 29a is inclined at an angle of, for example, 45 degrees with respect to the horizontal direction. The imaging unit 27 is disposed on one side in the front-rear direction with respect to the reflecting member 29, and the optical axis L1 of the first visual field range AR1 extends in the front-rear direction. Accordingly, the optical axis L2 serving as the center of the second visual field range AR2 extends in the vertical direction. The second visual field range AR2 in which the first visual field range AR1 is folded back by the reflecting member 29 is set so that the range becomes wider as it goes upward, and the cross section (optical axes L1, L2 as shown in FIG. 4) is set. In the cross section passing through the second visual field range AR2, the second visual field range AR2 expands forward and backward as it goes upward.

  Specifically, the second visual field range AR2 is set so that the range becomes wider in the front-rear direction as it goes upward with the optical axis L2 as the center, and similarly, the range extends to the left and right as it goes upward with the optical axis L2 as the center. The second visual field range AR2 is set so as to be wide. In addition, the boundary shape of the second visual field range AR2 on the virtual plane obtained by cutting the second visual field range AR2 in the horizontal direction outside the case may be, for example, a circle or a rectangular shape such as a rectangle or a square. Good.

  The imaging unit 27 is disposed at a position outside the second visual field range AR2. Specifically, the imaging unit 27 is disposed at a position that is deviated to one side in the front-rear direction from the boundary B1 on one side in the front-rear direction of the second visual field range AR2. As described above, since a part of the imaging unit 27 is configured not to enter the second visual field range AR2, a part of the imaging unit 27 is reflected on the reflecting member 29 and is captured by the imaging unit 23. In other words, reduction of the imaging area due to such reflection is suppressed. Further, as shown in FIG. 4, the lens portion of the imaging unit 27 is disposed at a position higher than the lower end portion 29b of the reflection surface 29a region (reflection region) of the reflection member 29 and is positioned lower than the upper end portion 29c. Has been placed. Further, one end portion in the front-rear direction of the image forming unit 27 (end portion on the reflecting member 29 side) is disposed between the other end portion 5d in the front-rear direction of the reading port 5 and the optical axis L2 in the front-rear direction. By arranging in this way, it is possible to make use of the area below the reading port 5 while preventing the image forming unit 27 from being reflected.

  Further, as shown in FIG. 4, in a cross section in which a plane passing through the optical axis L1 serving as the center of the first visual field range AR1 and the optical axis L1 serving as the center of the second visual field range AR2 is cut, the second visual field range AR2 Both the boundaries B1 and B2 pass through a position closer to the inner periphery of the reading port 5 (for example, the position of the end portions 5d and 5c or the position close to the end portions 5d and 5c). In the example of FIG. 4, the boundary B1 on the one side in the front-rear direction and the boundary B2 on the other side in the front-rear direction of the second visual field range AR2 are both closer to the inner peripheral portion (end portions 5d and 5c) of the reading port 5. Although it passes a little inside, these boundaries B1 and B2 may pass through the inner periphery (ends 5d and 5c).

  Next, the illumination light source 21 will be described. As shown in FIGS. 3, 4, 6, and 8, the illumination light source 21 is arranged at a position outside the opening region γ (inner region of the boundary line P <b> 3 shown in FIG. 3) in the plane direction perpendicular to the vertical direction. Has been. Note that the boundary line P3 conceptually indicates the boundary of the opening region γ in the planar direction, and the inner edge of the reading port 5 actually becomes the boundary of the opening region γ. The illumination light source 21 includes first light sources 21 a and 21 b disposed near one end in the longitudinal direction of the case 3 (close to one end in the width direction) and a first light source disposed near the other end in the longitudinal direction of the case 3 (closer to the other end in the width direction). It has two light sources 21c and 21d. The first light sources 21a and 21b and the second light sources 21c and 21d are all disposed below the covering layer 8 formed on the plate surface of the plate 7, and the first light source is formed as shown in FIGS. Each of 21a, 21b and the second light sources 21c, 21d is mounted on the lower surface side of a substrate (substrates 91, 92, 93, 94) disposed below the covering layer 8. The substrate 91 and the substrate 92 may be the same substrate or may be separate substrates. Further, the substrate 93 and the substrate 94 may be the same substrate or may be separate substrates.

  As shown in FIGS. 4, 6, and 8, the first light sources 21 a and 21 b and the second light sources 21 c and 21 d are all positioned below the plate 7 in the vertical direction and the upper end position of the light guide member 50 described later. As shown in FIG. 3, it is arranged at a position away from the opening region γ (inner region of the boundary line P3) in the planar direction as shown in FIG. The first light sources 21a and 21b and the second light sources 21c and 21d are irradiated with illumination light in a horizontal direction (horizontal direction) orthogonal to the vertical direction and an oblique horizontal direction inclined with respect to the horizontal direction. The illumination light is applied to the side approaching the opening region γ. For example, as shown in FIGS. 6 and 8, the irradiation surfaces (light emitting surfaces) of the first light sources 21a and 21b arranged on one side in the left-right direction (width direction) correspond to the side surfaces of the first light sources 21a and 21b. At the same time, it is arranged so as to face the other side in the left-right direction (second light source 21c, 21d side), and illumination light is emitted from the first light source 21a, 21b toward the other side in the left-right direction. The irradiation surfaces (light emitting surfaces) of the second light sources 21c and 21d arranged on the other side in the left and right direction (width direction) correspond to the side surfaces of the second light sources 21c and 21d and one side in the left and right direction (first light source). 21a, 21b side), and illumination light is emitted from the second light sources 21c, 21d toward one side in the left-right direction. In addition, each side surface used as the irradiation surface of the 1st light sources 21a and 21b and the 2nd light sources 21c and 21d becomes a surface direction orthogonal to the width direction, for example, and all the 1st light sources 21a and 21b and the 2nd light sources The heights of the irradiation surfaces 21c and 21d in the vertical direction are substantially the same.

  Further, at a position between the illumination light source 21 and the reading port 5 in the vertical direction, at least on the irradiation side of the illumination light from the illumination light source 21, the reading port 5 side (second visual field) from the position of the illumination light source 21 along the plane direction. A light shielding portion (light shielding portions 91a, 92a, 93a, 94a) configured to extend to the range AR2 side is disposed. The light shielding portions 91a, 92a, 93a, and 94a block the illumination light that is going obliquely upward from the illumination light source 21.

  For example, as shown in FIG. 6, at a position between the first light source 21 a and the reading port 5 in the planar direction, at least on the illumination light irradiation side (second light source 21 c side in the width direction) from the first light source 21 a, A light shielding portion 91a is arranged so as to extend in the plane direction from the position of the first light source 21a. The light shielding portion 91a corresponds to a portion on the opening region γ side (side closer to the opening region γ in the planar direction) than the first light source 21a on the substrate 91 on which the first light source 21a is mounted. The light shielding portion 91a blocks light that is directed obliquely upward from the first light source 21a. In the example shown in FIG. 6 and the like, the substrates 91, 92, 93, and 94 are configured such that the thickness direction is the vertical direction, and the plate surface direction is the horizontal direction (surface direction orthogonal to the vertical direction). First light sources 21a and 21b and second light sources 21c and 21d configured as light emitting elements are mounted on the lower surfaces (back surfaces) of the substrates 91, 92, 93 and 94, respectively. For example, in the substrate 91, the mounting surface of the first light source 21a (the lower surface of the substrate 91) is at least near the opening region γ from the position of the first light source 21a in the planar direction (the optical axis L2 of the second visual field range AR2). It is arranged so that the side close to Since it is configured in this way, even if the light immediately after being emitted from the first light source 21a is directed obliquely upward, the light is blocked by the light shielding portion 91a and mostly reflected downward, so that the first light source 21a Most of the light from is less likely to go obliquely upward than the first light source 21a. As a result, most of the light from the first light source 21a is irradiated in the horizontal direction and obliquely downward. Similarly, as shown in FIG. 8, at a position between the first light source 21 b and the reading port 5 in the planar direction, at least from the position of the first light source 21 b on the irradiation light irradiation side from the first light source 21 b in the planar direction. A light shielding portion 92a is arranged to extend (specifically, to extend toward the reading port 5 in the planar direction). The light shielding portion 92a corresponds to a portion of the substrate 92 on which the first light source 21b is mounted that is closer to the opening region γ than the first light source 21b (side closer to the opening region γ in the planar direction). The light which tries to go diagonally upward from the first light source 21b is blocked. More specifically, the mounting surface (the lower surface of the substrate 92) of the first light source 21b is closer to the opening region γ from the position of the first light source 21b at least in the plane direction (close to the optical axis L2 of the second visual field range AR2). Side). Thereby, most of the light from the first light source 21b is irradiated in the horizontal direction and obliquely downward. In the explanatory diagram of FIG. 8, light emitted from the first light source 21b is omitted.

  Further, as shown in FIG. 6, at a position between the second light source 21 c and the reading port 5 in the planar direction, it extends in the planar direction from the position of the second light source 21 c at least on the irradiation light irradiation side from the second light source 21 c. As described above (specifically, the light shielding portion 93a is disposed so as to extend toward the reading port 5 in the planar direction). The light shielding portion 93a corresponds to the portion of the substrate 93 on which the second light source 21c is mounted that is closer to the opening region γ than the second light source 21c (side closer to the opening region γ in the plane direction). Light that is directed obliquely upward from the second light source 21c is blocked. More specifically, the mounting surface (the lower surface of the substrate 93) of the second light source 21c is close to the opening region γ from the position of the second light source 21c at least in the plane direction (close to the optical axis L2 of the second visual field range AR2). Side). Thereby, much of the light from the second light source 21c is irradiated in the horizontal direction and the obliquely downward direction. In the explanatory diagram of FIG. 6, light emitted from the second light source 21c is omitted. Similarly, as shown in FIG. 8, at a position between the second light source 21 d and the reading port 5 in the planar direction, at least from the position of the second light source 21 d on the irradiation light irradiation side from the second light source 21 d in the planar direction. A light-shielding portion 94a is disposed so as to extend (specifically, to extend toward the reading port 5 in the planar direction). The light shielding portion 94a corresponds to a portion of the substrate 94 on which the second light source 21d is mounted that is closer to the opening region γ than the second light source 21d (side closer to the opening region γ in the plane direction). The light that is directed obliquely upward from the second light source 21d is blocked. More specifically, the mounting surface (the lower surface of the substrate 94) of the second light source 21d is close to the opening region γ from the position of the second light source 21d at least in the plane direction (close to the optical axis L2 of the second visual field range AR2). Side). Thereby, most of the light from the second light source 21d is irradiated in the horizontal direction and the obliquely downward direction. Since it is configured in this manner, the light from each illumination light source 21 does not easily enter the eyes of the user, and the light from each illumination light source 21 can be efficiently applied to the light guide member 50 described later.

  And the light guide member 50 is arrange | positioned in the irradiation destination of the illumination light by these illumination light sources 21. FIG. As illustrated in FIG. 10, the light guide member 50 is more than the illuminance of the illumination light passing through the center portion P <b> 1 of the visual field range in the opening region γ of the reading port 5 (the inner region of the boundary line P <b> 3 shown in FIG. 10). The illumination light is guided so that the illuminance of the illumination light passing through a predetermined high illuminance region β defined near the peripheral edge in the visual field range is larger. 4 and 10, the region surrounded by the inner edge portion of the reading port 5 at the position of the upper surface of the plate 7 (the region exposed from the reading port 5 on the upper surface of the plate 7) corresponds to the opening region γ. Yes. In the example of FIG. 10, the annular area along the peripheral edge of the visual field range is the high illuminance area β in the opening area γ, and the high illuminance area β is conceptually shown by hatching.

  The light guide member 50 includes a plurality of reflecting portions 51, 52, 53, and 54 that reflect illumination light from the illumination light source 21. In each of these reflecting portions 51, 52, 53, and 54, the surface on the second visual field range AR 2 side is configured as a reflecting surface that reflects the illumination light from the illumination light source 21. The reflecting surfaces of the reflecting portions 51, 52, 53, 54 are all located in the plane direction perpendicular to the vertical direction at the position of the central portion P 1 of the visual field range in the opening region γ of the reading port 5 (that is, the plate 7 And a position where the optical axis L2 intersects) is formed as an inclined surface that becomes a lower position as it approaches. The reflecting portions 51, 52, 53, and 54 are made of, for example, light-shielding members, and any of the reflecting portions 51, 52, 53, and 54 is an outer surface (that is, illumination light) on the second visual field range AR2 side. Is a predetermined color (for example, a bright color such as white), and both are configured to diffusely reflect light incident on the outer surface on the second visual field range AR2 side.

  As shown in FIGS. 1 to 3, 5, 7, and the like, the light guide member 50 includes a pair of first reflecting portions 53 and 54 that face each other in a predetermined direction (width direction) orthogonal to the vertical direction. Yes. As shown in FIGS. 5 and 7, in the pair of first reflecting portions 53 and 54, the reflecting surface of one first reflecting portion 54 approaches the other reflecting portion 53 in a predetermined direction (width direction). The reflecting surface of the other reflecting portion 53 is configured as an inclined surface that becomes a lower position as it approaches one reflecting portion 54 in a predetermined direction.

  More specifically, as shown in FIGS. 3, 5, and 7, a pair of first reflecting portions 53 and 54 that face each other in the width direction (a predetermined first direction orthogonal to the vertical direction), and FIGS. As shown in FIG. 4, a pair of second reflecting portions 51 and 52 facing each other in the front-rear direction (vertical direction and a predetermined second direction orthogonal to the first direction) are provided. The entire light guide member 50 is disposed along the second visual field range AR2 outside the visual field range, and has a mortar-like structure in which the size of the hole (opening region) becomes narrower as the position is lowered. ing. As described above, the light guide member 50 is annularly disposed outside the second visual field range AR2 so as to surround the second visual field range AR2, and the upper end portion 50a is disposed close to the inner edge of the reading port 5. Has been. The upper end portion 50a of the light guide member 50 has an annular end structure surrounding the second visual field range AR2, and any of the upper end portions 50a configured in this manner is directly below the inner edge portion of the reading port 5. Located in the vicinity, the peripheral edge is closer to the center of the opening region γ at any position of the upper end portion 50a. Further, in any position of the upper end portion 50a, the peripheral edge portion (near the boundary line P2) is closer than the central portion P1 of the visual field range α in the opening region γ.

  As shown in FIGS. 3, 5, and 7, in the pair of first reflecting portions 53 and 54, the reflecting surface of one first reflecting portion 54 is the other first reflecting portion 53 in the width direction (first direction). The reflecting surface of the other first reflecting portion 53 is configured as an inclined surface that becomes a lower position as it approaches one first reflecting portion 54 in the width direction (first direction). It is configured. Further, as shown in FIGS. 3 and 4, in the pair of second reflecting portions 51 and 52, the reflecting surface of one second reflecting portion 51 is opposite to the other second reflecting portion 52 in the front-rear direction (second direction). It is configured as an inclined surface that becomes a lower position as it approaches, and the reflecting surface of the other second reflecting portion 52 is configured as an inclined surface that becomes a lower position as it approaches one second reflecting portion 51 in the front-rear direction (second direction). Has been. And the illumination light source 21 becomes a structure which irradiates illumination light to all of the one 1st reflection part 54, the other 1st reflection part 53, the one 2nd reflection part 51, and the other 2nd reflection part 52. ing. In FIG. 3, the region of one first reflecting portion 54 is conceptually indicated by a two-dot chain line J11, and the region of the other first reflecting portion 53 is conceptually indicated by a two-dot chain line J12. Moreover, the area | region of one 2nd reflection part 51 is shown with the dashed-two dotted line J21, and the area | region of the other 2nd reflection part 52 is shown with the dashed-two dotted line J22. The reflecting portion of the first reflecting portion 53 is disposed on one side in the width direction with respect to the center position in the width direction of the case 3, and is disposed on one side in the width direction with respect to the optical axis L2 of the second visual field range AR2. The end portion (end portion close to the first light sources 21a, 21b) has the largest length in the front-rear direction, and the length in the front-rear direction gradually increases as it approaches the optical axis L2 side of the second visual field range AR2 in the width direction. It is getting smaller. The reflection part of the first reflection part 54 is disposed on the other side in the width direction with respect to the center position in the width direction of the case 3 and is disposed on the other side in the width direction with respect to the optical axis L2 of the second visual field range AR2. The end portion (end portion closer to the second light source 21c, 21d) has the largest length in the front-rear direction, and the length in the front-rear direction gradually increases as it approaches the optical axis L2 side of the second visual field range AR2 in the width direction. It is getting smaller. The reflecting portion of the second reflecting portion 51 is disposed on one side in the front-rear direction from the front-rear center position of the case 3 and is disposed on one side in the front-rear direction with respect to the optical axis L2 of the second visual field range AR2. The position of the end (the end opposite to the optical axis L2) has the largest length in the left-right direction (width direction), and the left-right direction (width) as it approaches the optical axis L2 side of the second visual field range AR2 in the front-rear direction. Direction) is gradually becoming smaller. The reflection part of the second reflection part 52 is disposed on the other side in the front-rear direction than the center position in the front-rear direction of the case 3 and on the other side in the front-rear direction with respect to the optical axis L2 of the second visual field range AR2. The position of the end (the end opposite to the optical axis L2) has the largest length in the left-right direction (width direction), and the left-right direction (width) as it approaches the optical axis L2 side of the second visual field range AR2 in the front-rear direction. Direction) is gradually becoming smaller.

  Specifically, as shown in FIGS. 6, 8, and 10, the first light sources 21 a and 21 b are opposite to the first light sources 21 a and 21 b in the width direction (relative to the center position of the case 3 in the width direction). The first light source 21a, 21b is provided on the opposite side of the first light source 21a and 21b, and is irradiated with illumination light. The second light sources 21c, 21d Illumination light is irradiated toward the other first reflecting portion 53 provided on the opposite side to the two light sources 21c and 21d (the opposite side to the second light sources 21c and 21d with respect to the center position in the width direction of the case 3). It has a configuration. The first light sources 21a and 21b correspond to the other-side light sources arranged closer to the other first reflecting portion 53 than the first reflecting portion 54 in the width direction (first direction). The light sources 21c and 21d correspond to one-side light sources arranged on the side closer to the first reflecting portion 54 than the other first reflecting portion 53 in the width direction (first direction). The illumination light from the second light sources 21c and 21d (one-side light source) is incident on the first reflecting portion 53 side in the other first reflecting portion 53 and the pair of second reflecting portions 51 and 52 (in the width direction of the reading port 5). At least the region above the center position in the vertical direction of the case 3 (preferably almost the entire reflection portion) is irradiated to the portion on the first reflection portion 53 side from the center position. Illumination light from the first light sources 21a and 21b (the other side light source) is on the first reflecting portion 54 side in the first reflecting portion 54 and the pair of second reflecting portions 51 and 52 (in the width direction of the reading port 5). At least a region above the center position in the vertical direction of the case 3 (preferably almost the entirety of each reflection portion) is irradiated to a portion on the first reflection portion 54 side from the center position. In FIG. 10, the illumination light irradiation area from the first light source 21a is conceptually indicated by a thick broken line, and the illumination light irradiation area from the first light source 21b is conceptually indicated by a thick solid line. The illumination light irradiation area from the second light source 21c is conceptually indicated by a thick two-dot chain line, and the illumination light irradiation area from the second light source 21d is conceptually indicated by a thick one-dot chain line. .

  In this way, the illumination light emitted from the first light sources 21a and 21b and the second light sources 21c and 21d is the wall surface of the light guide member 50 configured in a mortar shape (the first reflecting portions 53 and 54 and the second reflecting portion). 51, 52 on the second visual field range AR2 side), the first reflecting portions 53, 54 and the second reflecting portions 51, 52 are generally bright when viewed in plan as shown in FIG. It will shine. Further, as shown in FIGS. 4, 5, and 7, each of the first reflecting portions 53 and 54 and the second reflecting portions 51 and 52 has a lower position on the center (optical axis L2) side of the visual field range AR2 in the planar direction. The side far from the optical axis L2 is the upper position. Therefore, in the opening region γ of the reading port 5 (the region exposed from the reading port 5 on the upper surface of the plate 7), in the visual field range α (the region surrounded by the boundary line P2 in FIG. 10), the peripheral portion Reflected light from the vicinity of the upper end portion 50a (near the upper end portions of the first reflecting portions 53 and 54 and the second reflecting portions 51 and 52) of the light guide member 50 near the vicinity (near the boundary line P2) It becomes easy to reach the vicinity of the line P2. Therefore, in the visual field range α (the region surrounded by the boundary line P2 in FIG. 10) in the opening region γ, the illuminance near the periphery of the visual field range α (near the boundary line P2) is near the center P1 of the visual field range α. It becomes relatively high compared with the illuminance. On the other hand, the central portion P1 of the visual field range α in the opening region γ is far from the first reflecting portions 53 and 54 and the second reflecting portions 51 and 52 compared to the vicinity of the peripheral portion (near the boundary line P2). The illumination light reflected by the first reflecting portions 53 and 54 and the second reflecting portions 51 and 52 is less likely to reach the central portion P1 in the opening region γ than in the peripheral portion of the visual field range α. Therefore, in the visual field range α (the region surrounded by the boundary line P2 in FIG. 10) in the opening region γ, the illuminance near the central portion P1 is relatively lower than the illuminance near the peripheral portion (near the boundary line P2). Become. In FIG. 10, the high illuminance region β in which the illuminance is higher than the illuminance near the central portion P1 of the visual field range α in the opening region γ is conceptually illustrated as a hatched region. In the opening area γ, since the high illuminance area β is configured in this way, when an object is arranged so as to be in close contact with the upper surface of the plate 7 in the opening area γ, the illuminance at the position of the high illuminance area β is reduced in this object. Relatively large, the illuminance near the center portion P1 is relatively small, and the high illuminance region β is relatively brighter than near the center portion P1.

(Main effects of this configuration)
In this configuration, the illumination light from the illumination light source 21 is irradiated to the outside of the case 3 through the opening region γ of the reading port 5 at a position where the illumination light from the illumination light source 21 is irradiated inside the case 3. The light guide member 50 is disposed in a configuration that guides the light. The light guide member 50 passes through a predetermined high illuminance region β defined closer to the peripheral portion in the visual field range α than the illuminance of illumination light passing through the central portion P1 of the visual field range α in the opening region γ. The illumination light is guided so that the illuminance of the illumination light becomes larger.
According to this configuration, at least in the visual field range near the reading port 5, the illuminance in the region near the peripheral portion can be relatively higher than the illuminance near the central portion P <b> 1, and the visual field range is imaged by the imaging unit 23. In the captured image obtained as described above, a decrease in luminance near the peripheral portion can be suppressed. Therefore, it is possible to effectively suppress problems (decoding defects and the like) caused by the luminance near the peripheral portion being significantly lower than that of the central portion P1, and the reading performance can be more reliably improved.

  In the present configuration, the light guide member 50 guides the illumination light so that the annular region along the peripheral edge of the visual field range α in the opening region γ becomes the high illuminance region β. According to this configuration, since the high illuminance region β can be configured so as to surround the central portion P1 of the visual field range α in the opening region γ, in the captured image obtained by imaging the visual field range, the vicinity of the peripheral portion is circular. In this way, high brightness can be achieved. As a result, insufficient brightness and uneven brightness at the image peripheral edge due to the optical system are more easily suppressed.

Moreover, in this structure, the light guide member 50 is provided with the some reflection part which reflects the illumination light from the illumination light source 21, and each reflection part has at least one part area | region of the reflective surface which reflects illumination light. In the plane direction orthogonal to the up-down direction, the inclined surface becomes a lower position as it approaches the position of the central portion P1 of the visual field range α in the opening region γ.
In this configuration, the reflecting surface of each reflecting portion is located on the far side from the position of the central portion P1 of the visual field range α (that is, the position of the optical axis L2) in the planar direction, and the position of the central portion P1 of the visual field range α. The side closer to (the position of the optical axis L2) is the lower position. For this reason, the illumination light reflected at the upper position does not attenuate so much and easily reaches the vicinity of the peripheral edge of the visual field range α in the opening region γ, and the reflection position at each reflective portion is on the center P1 side of the visual field range α. Since the distance from the reflection position to the opening region γ increases as the distance (that is, the optical axis L2 side) approaches, the light easily attenuates before reaching the opening region γ. Since such an effect occurs, the illuminance in the vicinity of the peripheral edge of the visual field range α near the aperture region γ can be more easily increased than the illuminance in the vicinity of the central portion P1 without using a complicated member or special material.

In this configuration, the light guide member 50 includes a pair of reflecting portions (first reflecting portions 53 and 54) that face each other in a predetermined direction orthogonal to the vertical direction, and one of the reflecting portions is the reflecting portion. The reflection surface 54 is configured as an inclined surface that becomes a lower position as it approaches the other reflection portion 53 in a predetermined direction, and the reflection surface of the other reflection portion 53 becomes a lower position as it approaches one reflection portion 54 in the predetermined direction. It is comprised as an inclined surface. The illumination light source 21 includes first light sources 21a and 21b that irradiate one reflection part 54 with illumination light, and second light sources 21c and 21d that irradiate the other reflection part 53 with illumination light.
In this configuration, any reflecting surface of each of the reflecting portions 53 and 54 arranged in a pair has an upper position on the side far from the position of the central portion P1 of the visual field range α (that is, the position of the optical axis L2) in the planar direction. Thus, the side closer to the position of the center portion P1 (position of the optical axis L2) of the visual field range α in the planar direction is the lower position. For this reason, in any one of the reflection part 54 and the other reflection part 53, the illumination light reflected at the upper position does not attenuate so much and easily reaches the vicinity of the peripheral part of the visual field range α. , 54, the closer to the central part P1 side of the visual field range α, the longer the distance from the reflection position to the opening region γ, the more easily the light is attenuated before reaching the opening region γ. Since such an effect occurs, the illuminance at the peripheral edge of the visual field range can be enhanced on both sides in a predetermined direction without using a complicated member or special material, and a wider range in the vicinity of the reading port 5 The high illuminance region β can be configured.

In the present configuration, the light guide member 50 is orthogonal to the pair of first reflecting portions 53 and 54 facing each other in a predetermined first direction (width direction) orthogonal to the vertical direction, and to the vertical direction and the first direction. And a pair of second reflecting portions 51 and 52 facing each other in a predetermined second direction (front-rear direction). And in a pair of 1st reflection parts 53 and 54, the reflective surface of one 1st reflection part 54 is an inclined surface which becomes a lower position as it approaches the other 1st reflection part 53 in the 1st direction (width direction). The reflection surface of the other first reflection portion 53 is configured as an inclined surface that becomes a lower position as it approaches the first reflection portion 54 in the first direction (width direction). Furthermore, in a pair of 2nd reflection parts 51 and 52, the reflective surface of one 2nd reflection part 51 is an inclined surface which becomes a lower position as it approaches the other 2nd reflection part 52 in a 2nd direction (front-back direction). The reflection surface of the other second reflection portion 52 is configured as an inclined surface that becomes a lower position as it approaches one second reflection portion 51 in the second direction (front-rear direction). And the illumination light source 21 becomes a structure which irradiates illumination light to all of the one 1st reflection part 54, the other 1st reflection part 53, the one 2nd reflection part 51, and the other 2nd reflection part 52. ing.
In this configuration, both first reflecting portions 53 and 54 arranged in a pair in the first direction (width direction) and both second reflecting portions 51 arranged in a pair in the second direction (front-rear direction). 52, the far side from the position of the central portion P1 (position of the optical axis L2) of the visual field range α in the plane direction is the upper position, and the side close to the central portion P1 of the visual field range α in the planar direction is the upper position. It is in the lower position. Therefore, the light is reflected at the upper position in any one of the first reflecting portion 54, the other first reflecting portion 53, the one second reflecting portion 51, and the other second reflecting portion 52 arranged in four directions. The illumination light does not attenuate so much and easily reaches the vicinity of the peripheral portion of the visual field range, and the distance from the reflective position to the opening region γ increases as the reflection position at the reflection portion approaches the central portion P1 side of the visual field range. Therefore, the light tends to attenuate before reaching the opening region γ. Since such an effect occurs, the illuminance at the peripheral edge of the visual field range can be emphasized on both sides in the first direction and both sides in the second direction without using a complicated member or special material. In the vicinity of the peripheral edge of the visual field range near the mouth 5, the high illuminance region β can be configured more uniformly in a wider range.

Moreover, in this structure, the illumination light source 21 is arrange | positioned in the 1st direction (width direction) on the side near the 1st reflection part 54 rather than the 1st reflection part 53 of the other side (2nd light source 21c). , 21d). Furthermore, the illumination light source 21 includes the other side light sources (first light sources 21a and 21b) arranged closer to the other first reflecting portion 53 than the first reflecting portion 54 in the first direction (width direction). Also equipped. Then, the illumination light from the one side light source is irradiated to the other first reflection portion 53 and the pair of second reflection portions 51, 52, and the illumination light from the other side light source is directed to the one first reflection portion 54 and the pair of first reflection light. The structure is such that the two reflecting portions 51 and 52 are irradiated.
According to this configuration, it is possible to irradiate light on the four reflecting portions by the one side light source and the other side light source, and it is possible to efficiently generate the high illuminance region β in a wider range.

  Moreover, in this structure, each illumination light source 21 is arrange | positioned in the position outside the opening area | region (gamma) in the plane direction orthogonal to an up-down direction. According to this configuration, it is difficult for the illumination light source 21 to be directly viewed from the outside of the case 3, and strong light caused by illumination light, such as direct light from the illumination light source 21, is difficult to be reflected on the imaging unit 23.

Further, in this configuration, the plate 7 (transparent member) is disposed so as to close the reading port 5, the illumination light source 21 is disposed at a position away from the opening region γ in the planar direction, and at least in the vertical direction. The illumination light is irradiated on the side closer to the opening region γ so that the illumination light is irradiated in the orthogonal transverse direction. In the vertical direction, the light shielding portion is arranged at a position between each illumination light source 21 and the reading opening 5 so as to extend from the position of each illumination light source 21 to the reading opening 5 side at least on the illumination light irradiation side from each illumination light source 21. 91a, 92a, 93a, 94a are arranged. The light shielding portions 91a, 92a, 93a, and 94a are configured to block the illumination light that is directed obliquely upward from each illumination light source 21.
In this configuration, since the illumination light that is going obliquely upward from the illumination light source 21 is blocked by the light shielding portions 91a, 92a, 93a, 94a, the direct light from the illumination light source 21 is specularly reflected by the plate 7 (transparent member). Thus, it is possible to suppress the specular reflection light from being reflected on the imaging unit 23. Moreover, since the direction of the illumination light from each illumination light source 21 can be easily narrowed in the horizontal direction and the obliquely downward direction, it is possible to efficiently irradiate the light guide member 50 with the illumination light while suppressing light leaking upward.

Further, in this configuration, a reflection member 29 (mirror) that is housed inside the case 3 and reflects light entering from the outside of the case 3 through the reading port 5 is provided. Light that passes through the reading port 5 from the outside and is reflected by the reflecting member 29 is guided to the imaging unit 23. Then, as a visual field range that can be imaged by the imaging unit 23, the first visual field range AR1 configured between the imaging unit 27 and the reflective member 29, and the reflective member 29 so as to follow the first visual field range AR1. The second visual field range AR2 configured on the upper side is defined.
In this way, the reflecting member 29 is interposed in the case 3, and the path of the visual field range that extends from the imaging unit 27 to the outside of the case 3 (that is, the path that guides the light entering from the reading port 5 to the imaging unit 27). By being configured to bend inside the case 3, the distance from the optical system to the reading port 5 (light entering from the reading port 5 enters the image forming unit 27 without increasing the thickness of the case 3 so much. It is easy to secure a large length). Thereby, the thickness of case 3 can be reduced and size reduction can be achieved.

  In this configuration, the light guide member 50 is disposed along the second visual field range AR2 outside the visual field range. According to this configuration, the light guide member 50 can be arranged by effectively using the space in the vicinity of the visual field range outside the visual field range, and the light guide member has a configuration that does not enter the visual field range without breaking a large arrangement space. 50 can be arranged efficiently.

  Further, in this configuration, the light guide member 50 is annularly arranged so as to surround the second visual field range AR2 outside the visual field range, and the upper end portion 50a is disposed close to the inner edge portion of the reading port 5. ing. According to this configuration, the annular light guide member 50 can be efficiently arranged outside the visual field range, and a configuration that can increase the overall illuminance of the peripheral portion of the visual field range can be easily realized.

[Second Embodiment]
Next, an optical information reading apparatus according to a second embodiment of the present invention will be described with reference to FIG.
In the first embodiment, as the light guide member, the light guide member 50 configured by the reflection portions 51, 52, 53, and 54 that reflects the illumination light is illustrated, but in the visual field range at the reading port, near the center portion. Various other configurations can be applied as long as the illuminance in the vicinity of the peripheral portion can be relatively higher than the illuminance. For example, in the reading apparatus 200 of FIG. 11, the visual field range AR is determined by the imaging unit 27, and light transmissive diffusion members 250 a and 250 b are provided inside the case 203 along the visual field range AR. ing. Under the diffusion members 250a and 250b, illumination light sources 221a and 221b that irradiate light to the diffusion members 250a and 250b are provided as illumination light sources, and the illumination light from the illumination light sources 221a and 221b is The reading member 205 is irradiated with light through the diffusion members 250a and 250b while diffusing. In this example, a reading port 205 is formed by an opening at the upper end of the case 203, and a transparent plate 207 is provided so as to close the reading port 205. The entire upper surface area of the plate 207 is an open area. In this configuration, light is emitted upward from each of the diffusing members 250a and 250b, and the illuminance is in the vicinity of the inner edge of the reading port 205 near the diffusing members 250a and 250b (near the periphery of the opening region). Increases and the illuminance decreases near the center of the reading port 205 far from each of the diffusing members 250a and 250b (near the center of the opening region). Accordingly, in the opening area of the reading port 205, the illuminance is higher in the peripheral area (high illuminance area) in the field of view than in the center of the field of view. 11 shows a cut surface obtained by cutting the center of the reading device 200 along the vertical direction and a predetermined width direction orthogonal to the vertical direction, but the center of the reading device 200 is orthogonal to the vertical direction and the vertical direction. The diffusing member similar to each of the diffusing members 250a and 250b is also arranged in the front and back on the cut surface cut along the predetermined front-rear direction. These diffusing members are irradiated with illumination light by an illumination light source similar to the light sources 221a and 221b. Thereby, in the opening area of the reading port, an annular high illuminance area is configured such that the illuminance near the peripheral edge of the visual field range is relatively large, and the illuminance near the central part of the visual field range is relatively small.

[Third embodiment]
Next, an optical information reading apparatus according to a third embodiment of the present invention will be described with reference to FIG.
The third embodiment is mainly different from the first embodiment in that an imaging unit 61 and a reflecting member 62 are employed instead of the imaging unit 27 and the reflecting member 29. For this reason, substantially the same components as those in the first embodiment are denoted by the same reference numerals and description thereof is omitted.

  In the present embodiment, the imaging unit 61 is configured as a normal imaging lens having a narrower field angle than the imaging unit 27 configured as a wide-angle lens. In the present embodiment, as the imaging unit 61, an imaging lens having a vertical angle of view in the vertical direction (hereinafter also simply referred to as an angle of view) of, for example, 30 degrees is employed.

  As shown in FIG. 12, the reflecting member 62 is configured as a convex mirror having a convex surface portion 62a that is convex on the image forming portion side as a reflective surface. The reflecting member 62 is disposed so as to reflect the light that enters the case 3 at the convex surface portion 62 a toward the imaging portion 61. In particular, the convex surface portion 62a has an upper end portion 62c of the reflection region that is the same position as or higher than the upper end position of the first visual field range AR1, and the lower end portion 62b of the reflection region has the first visual field range. It is formed to be the same position as the lower end position of the range AR1 or a lower position than the lower end position. The convex surface portion 62a is formed so that the second visual field range AR2 is substantially equivalent to the first embodiment with respect to the visual field range α in the opening region γ.

Here, the effect of the reflecting member 62 having the convex surface portion 62a will be described below.
By adopting a wide-angle lens as an image forming unit that determines a visual field range that can be imaged by the imaging unit 23, the visual field range of the imaging unit 23 can be widened. Thereby, even if the thickness of the case 3 is reduced, a necessary visual field range is ensured, so that the size of the reading device 1 can be reduced. On the other hand, if a wide-angle lens is simply used as the image forming portion, the luminance reduction near the peripheral portion in the captured image becomes more noticeable due to its optical characteristics.

  Therefore, in the present embodiment, the light that enters the case 3 is reflected toward the imaging portion 61 by the convex surface portion 62a. As a result, a wider range of light is reflected toward the imaging unit 61, so that even when a normal imaging lens having a narrower angle of view than the wide-angle lens is adopted, the luminance in the vicinity of the peripheral part in the captured image is reduced. The visual field range (second visual field range AR2) can be widened without any problem. In other words, by adopting the convex surface portion 62a that is convex toward the image forming portion as the reflective surface of the reflective member 62, the reading device can suppress the luminance near the peripheral edge in the captured image from being significantly lower than that near the central portion. 1 can be reduced in size.

[Fourth embodiment]
Next, an optical information reading apparatus according to a fourth embodiment of the present invention will be described with reference to FIGS. In FIG. 13, the first visual field range AR1a and the second visual field range AR2a at an angle of view of 50 degrees are indicated by a two-dot chain line, and the first visual field range AR1b and the second visual field range AR2b at an angle of view of 60 degrees are indicated by one point. Shown with a chain line. In FIG. 14, the first visual field range AR1a and the second visual field range AR2a at an angle of view of 50 degrees are indicated by a two-dot chain line, and the first visual field range AR1c and the second visual field range AR2c at an angle of view of 40 degrees are indicated by a broken line. The first visual field range AR1d and the second visual field range AR2d at an angle of view of 30 degrees are indicated by solid lines. Further, in FIG. 14, for the same opening region γ, the field of view range at an angle of view of 50 degrees is αa, the field of view range at an angle of view of 40 degrees is αc, and the field of view range at an angle of view of 30 degrees is αc. Yes.

  In the configuration of the first embodiment, even if the luminance near the peripheral portion in the captured image is reduced by adopting a wide-angle lens as the imaging unit 27 in order to reduce the size of the reading device 1, the illumination light source 21 The light guide member 50 that reflects the illumination light can suppress a decrease in luminance near the periphery.

  On the other hand, when a wide-angle lens with a wider angle of view, for example, a wide-angle lens with a field angle of 60 degrees is employed as the imaging unit 27, a part of the imaging unit 27 falls within the second visual field range AR2 as shown in FIG. It enters (see the second visual field range AR2b in FIG. 13), and a part of the imaging unit 27 is reflected on the reflecting member 29 and is imaged by the imaging unit 23.

  Furthermore, when the wide-angle lens having a wider angle of view as described above is employed as the imaging unit 27, the upper end portion 29c of the reflecting surface 29a of the reflecting member 29 is increased, and the thickness of the case 3 is increased. On the other hand, when the wide-angle lens is brought close to the reflecting member 29 in order to lower the upper end portion 29c of the reflecting surface 29a, the reflection of a part of the image forming unit 27 on the reflecting member 29 is further deteriorated.

  Therefore, in the present embodiment, as the wide-angle lens having a wide angle of view to such an extent that a part of the image-forming unit 27 does not enter the second visual field range AR2, for example, a wide-angle lens having a field angle of 50 degrees is employed as the image-forming unit 27. Yes. Accordingly, it is possible to prevent a part of the imaging unit 27 from being reflected on the reflecting member 29 and being imaged on the imaging unit 23 (see the second visual field range AR2a in FIG. 13). Since the upper end portion 29c is not as high as when the angle of view is 60 degrees, the size reduction of the reading device 1 is not hindered.

  On the other hand, as can be seen from FIG. 14, when the angle of view of the wide-angle lens is reduced, the visual field range α in the aperture region γ is reduced, so that the visual field range α having a required width is ensured in the aperture region γ. For this purpose, it is necessary to increase the thickness of the case 3 as the angle of view of the wide-angle lens decreases, which hinders downsizing. In the configuration in which a 40-degree wide-angle lens is used as the imaging unit 27, the required width can be obtained only by increasing the thickness of the case 3 to some extent as compared with the configuration in which a 50-degree wide-angle lens is used as the imaging unit 27. Can be ensured. On the other hand, the configuration in which a 30-degree wide-angle lens is used as the imaging unit 27 secures a visual field range α having a necessary width compared to the configuration in which a 50-degree wide-angle lens is used as the imaging unit 27. Therefore, it is necessary to increase the thickness of the case 3 sufficiently.

  For this reason, by adopting a wide-angle lens having an angle of view of 40 degrees or more and less than 60 degrees as the image forming unit 27, it is possible to reduce the size of the reading apparatus 1 while ensuring a field-of-view range α having a necessary width. it can.

[Fifth Embodiment]
Next, an optical information reading apparatus according to a fifth embodiment of the present invention will be described with reference to FIGS.
The fifth embodiment is mainly different from the first embodiment in that the relative position of the imaging unit 23 with respect to the case 3 is changed. For this reason, substantially the same components as those in the first embodiment are denoted by the same reference numerals and description thereof is omitted.

  In the present embodiment, the imaging unit 23 is arranged with respect to the case 3 so that the imaging direction is along the width direction, as shown in FIG. 15, unlike the first embodiment in which the imaging direction is along the front-rear direction. Yes. Further, as shown in FIG. 16A, the imaging unit 23 is mounted on the substrate 20 so that the longitudinal direction of the light receiving surface 23a is along the vertical direction. Even in this case, the light guide member 50 has a predetermined high illuminance region defined closer to the peripheral portion in the visual field range α than the illuminance of the illumination light passing through the central portion P1 of the visual field range α in the opening region γ. By being configured to guide the illumination light so that the illuminance of the illumination light passing through β is larger, the same effect as in the first embodiment can be obtained.

  As shown in FIG. 16B, the imaging unit 23 may be mounted on the substrate 20 so that the longitudinal direction of the light receiving surface 23a is along the front-rear direction.

  Further, in the first embodiment in which the imaging direction of the imaging unit 23 is along the front-rear direction, the imaging unit 23 may be mounted on the substrate such that the longitudinal direction of the light receiving surface 23a is along the vertical direction, or the light receiving surface 23a You may mount on a board | substrate so that a longitudinal direction may follow a front-back direction.

[Other Embodiments]
The present invention is not limited to the embodiments described with reference to the above description and drawings. For example, the following embodiments are also included in the technical scope of the present invention.

  In the first embodiment, the optical axis L1 that is the center of the first visual field range AR1 is in the horizontal direction, and the optical axis L2 that is the center of the second visual field range AR2 is in the vertical direction. Not limited to. For example, the optical axis L1 may be inclined with respect to the horizontal direction, and the optical axis L2 may be inclined with respect to the vertical direction.

  In the above embodiment, an example in which illumination light sources are arranged on both sides in the longitudinal direction of the case 3 with the reading port 5 interposed therebetween is shown. However, illumination light sources are arranged on both sides in the short direction of the case 3 with the reading port 5 interposed therebetween. May be. The illumination light source may be provided only on one side in the longitudinal direction of the case 3 with respect to the reading port 5, or may be provided on only one side in the short direction of the case 3 with respect to the reading port 5.

  In the above embodiment, an example of placing on a placement surface has been shown as a stationary structure, but it is sufficient that a person who performs a reading operation can install and use it in an installation place without holding it, such as a desk. It may be a stationary configuration that is embedded and fixed in a wall, or a stationary structure that is fixed to a wall or the like.

DESCRIPTION OF SYMBOLS 1 ... Stationary type | mold information code reader 3 ... Case 5 ... Reading port 21 ... Illumination light source 21a, 21b ... 1st light source (other side light source)
21c, 21d ... 2nd light source (one side light source)
23 ... Imaging unit 27, 61 ... Imaging unit 29, 62 ... Reflecting member 40 ... Control circuit (decoding unit)
DESCRIPTION OF SYMBOLS 50 ... Light guide member 50a ... Upper end part 51,52 ... A pair of 2nd reflection part (a pair of reflection part)
51 ... One second reflecting portion 52 ... The other second reflecting portion 53, 54 ... A pair of first reflecting portions (a pair of reflecting portions)
53 ... the other first reflecting part 54 ... one first reflecting part 62a ... convex surface part 91a, 92a, 93a, 94a ... light shielding part AR1, AR1a to AR1d ... first viewing field range (viewing field range)
AR2, AR2a to AR2d ... 2nd visual field range (visual field range)
β ... high illuminance region γ ... opening region C ... information code P1 ... center P2 ... periphery

Claims (4)

A case in which a reading port serving as a light entrance is formed on one side in a predetermined vertical direction;
An illumination light source that emits illumination light;
It is arranged at a position where the illumination light from the illumination light source is irradiated inside the case, and the illumination light from the illumination light source is irradiated to the outside of the case through an opening area of the reading port. A light guiding member for guiding;
An imaging unit;
The visual field range that can be imaged by the imaging unit is determined, and the light that has entered through the reading port from the outside of the case is guided to the imaging unit, and information within the visual field range is outside the case. An imaging unit that forms an image of the information code on the imaging unit when the code is disposed;
A decoding unit that decodes a code image of the information code when the information code arranged in the visual field range is imaged by the imaging unit;
With
The light guide member includes a pair of first reflecting portions facing each other in a predetermined first direction orthogonal to the vertical direction, and a pair opposing each other in a predetermined second direction orthogonal to the vertical direction and the first direction. A second reflective portion,
In the pair of first reflecting portions, the reflecting surface of one of the first reflecting portions is configured as an inclined surface that becomes a lower position as it approaches the other first reflecting portion in the first direction, and the other first reflecting portion. The reflective surface of the part is configured as an inclined surface that becomes a lower position as it approaches the one first reflective part in the first direction,
In the pair of second reflecting portions, the reflecting surface of one second reflecting portion is configured as an inclined surface that becomes a lower position as it approaches the other second reflecting portion in the second direction, and the other second reflecting portion. The reflective surface of the part is configured as an inclined surface that becomes a lower position as it approaches the one second reflective part in the second direction,
The illumination light source irradiates the illumination light to any one of the one first reflection unit, the other first reflection unit, the one second reflection unit, and the other second reflection unit. A stationary information code reader. The illumination light source includes a one-side light source disposed closer to the one first reflection unit than the other first reflection unit in the first direction, and the one first reflection unit in the first direction. The other side light source disposed closer to the other first reflection part than the other,
The illumination light from the one-side light source is irradiated to the other first reflecting portion and the pair of second reflecting portions,
2. The stationary information code reader according to claim 1, wherein the illumination light from the other-side light source is applied to the one first reflecting portion and the pair of second reflecting portions.   The stationary information code reader according to claim 1, wherein the illumination light source is disposed at a position outside the opening region in a plane direction orthogonal to the vertical direction.   The case has a box shape and is formed such that a distance between an upper surface portion on which the reading port is formed and a lower surface portion on the other side in the vertical direction is shorter than a short side of the upper surface portion. The stationary information code reading device according to any one of claims 1 to 3, wherein

Images