JP5086576B2 - Optical reader - Google Patents

Description

  The present invention relates to an apparatus for optically reading an information code.

  There are optical reading devices that read information codes such as bar codes and two-dimensional codes. The optical reader irradiates an information code with laser light, visible LED light, infrared LED light, and the like, and images the reflected light with an image sensor. Then, the information recorded in the information code is decoded by analyzing the image captured by the image sensor.

JP 11-39422 A

  The light emitted from the optical reader is reflected by the object surface on which the information code is printed. This reflected light includes regular reflection light and irregular reflection light. When the image sensor of the optical reader receives regular reflection light, it exceeds the light receiving level of the image sensor, making it difficult to read the information code accurately. Therefore, various ideas for accurately reading the information code have been made by receiving irregular reflection light without receiving regular reflection light.

  In order to prevent the regular reflection light from being received, a method is conceivable in which the optical reader itself is inclined with respect to the information code arrangement surface. For example, Patent Document 1 introduces the method using FIG. 6 as a conventional technique. In this prior art, the barcode reader is installed at an angle, and the barcode is imaged from an oblique direction. Thereby, the regular reflection light of the light irradiated from the barcode reader is not received by the image sensor.

  However, the method of inclining the barcode reader is not the best solution because the installation work is complicated and a dead space is created in the installation area.

  Therefore, in Patent Document 1, an angle is given to the laser light projecting unit and the reflected light receiving unit housed in the barcode reader. As a result, the image pickup device is prevented from receiving specularly reflected light without tilting the barcode reader.

  In this way, by providing an angle between the laser light projecting unit and the reflected light receiving unit, it is possible to accurately read the contents of the information code without receiving regular reflection light. However, although it is not necessary to incline the barcode reader itself, there is still a problem that a dead space is formed in the barcode reader because each component must be angled in the barcode reader. . Therefore, there is a demand for making the inclination angle of each component as small as possible.

  Further, as the installation angle of the light projecting unit and the light receiving unit increases, the distance between the barcode reader installation position and the barcode installation position increases. In other words, since the barcode is read at a position shifted in the horizontal direction, not directly under the barcode reader, a large work area is required.

  Therefore, in view of the above problems, the present invention reduces the dead angle in the apparatus and can read the information code even in a narrow work area by reducing the tilt angle required for the components in the optical reading apparatus as much as possible. An object is to provide an apparatus.

To solve the above problems installation, invention of claim 1, wherein, for capturing the image pickup area including the information code, based on the captured image obtained with a function of reading information recorded in said information code In the optical reader of the type, a first surface facing the surface on which the information code is disposed, and a second surface facing the first surface on the opposite side to the surface on which the information code is disposed A substantially rectangular parallelepiped casing provided with third and fourth surfaces arranged substantially orthogonal to the first and second surfaces and facing each other, and facing the first surface in the casing and the fourth surface An imager that is disposed at one end closer to the third surface than the surface, and that captures an image pickup area including the information code, and faces the first surface in the casing, and more than the fourth surface. At one end close to the third surface, the imaging Is located closer to the fourth surface than stage, wherein the illuminating means for irradiating an imaging area, wherein said first of said third than the fourth surface faces the plane in the housing of the imaging device A pointer light irradiating unit disposed at a position closer to the third surface than the imaging unit at one end close to the surface of the imaging unit, the imaging unit having an optical axis thereof In a plane orthogonal to the first and third planes, and is inclined to the third plane side with respect to an axis orthogonal to the first plane.

  According to a second aspect of the present invention, in the optical reading device according to the first aspect, the casing further includes fifth and sixth surfaces facing each other, and the irradiation unit is an arrangement of the imaging unit. It is arranged on the fifth or sixth surface side with respect to the position.

  According to a third aspect of the present invention, in the optical reading device according to the first or second aspect, the pointer light is disposed at a position closer to the third surface than the imaging unit and points to an imaging position of the imaging unit. It has an irradiation means.

  According to a fourth aspect of the present invention, in the optical reading device according to any one of the first to third aspects, the first surface is one end portion on the third surface side, and the end portion is the first portion. It has the inclined surface which inclines in the 2 surface side, It is characterized by the above-mentioned.

According to a fifth aspect of the present invention, in the optical reading apparatus according to the third aspect, the pointer light irradiation means has a bottom surface portion formed in a substantially spherical shape and a top surface portion formed in a cylindrical side surface shape. The optical reading device includes a support member having a concave portion having an approximately circular opening, and a plate that contacts the upper surface portion of the pointer light irradiation means, and the support member has the pointer light in the concave portion. By storing the bottom surface portion of the irradiating means, the pointer light irradiating means is rotatably supported, and the pointer light irradiating means is in a state where the upper surface portion of the pointer light irradiating means is in contact with the plate. The optical axis of the pointer light irradiating means can be adjusted by rotating about an axis substantially perpendicular to the plate.

According to a sixth aspect of the present invention, in the optical reading device according to the third aspect, the pointer light irradiation means has a bottom surface portion formed in a substantially spherical shape and a top surface portion formed in a cylindrical side surface shape. The optical reading device includes a support member having a concave portion having an approximately circular opening, and a plate that contacts the upper surface portion of the pointer light irradiation means, and the support member has the pointer light in the concave portion. By storing the bottom surface portion of the irradiating means, the pointer light irradiating means is rotatably supported, and the pointer light irradiating means is in a state where the upper surface portion of the pointer light irradiating means is in contact with the plate. The optical axis of the pointer light irradiating means can be adjusted by rotating about the cylindrical central axis of the upper surface portion.

According to a seventh aspect of the present invention, in the optical reading device according to the third aspect, the pointer light irradiation means has a bottom surface portion formed in a substantially spherical shape and a top surface portion formed in a substantially spherical shape. The optical reading device includes a support member having a concave portion having an approximately circular opening, and a plate that contacts the upper surface portion of the pointer light irradiation means, and the support member has the pointer light in the concave portion. By storing the bottom surface portion of the irradiating means, the pointer light irradiating means is rotatably supported, and the pointer light irradiating means is in a state where the upper surface portion of the pointer light irradiating means is in contact with the plate. The optical axis of the pointer light irradiating means can be adjusted by rotating about an axis substantially perpendicular to the plate.

According to an eighth aspect of the present invention, in the optical reading apparatus according to the third aspect, the pointer light irradiation means has a bottom surface portion formed in a substantially spherical shape and a top surface portion formed in a substantially spherical shape. The optical reading device includes a support member having a concave portion having an approximately circular opening, and a plate that contacts the upper surface portion of the pointer light irradiation means, and the support member has the pointer light in the concave portion. By storing the bottom surface portion of the irradiating means, the pointer light irradiating means is rotatably supported, and the pointer light irradiating means is in a state where the upper surface portion of the pointer light irradiating means is in contact with the plate. The optical axis of the pointer light irradiating means can be adjusted by rotating about an axis substantially perpendicular to the optical axis of the pointer light irradiating means and substantially parallel to the plate.

According to a ninth aspect of the present invention, in the optical reading device according to the third aspect, the pointer light irradiation means has a bottom surface portion formed in a cylindrical side surface shape and a top surface portion formed in a cylindrical side surface shape. The optical reading device includes a support member having a concave portion having an approximately circular opening, and a plate that contacts the upper surface portion of the pointer light irradiation means, and the support member has the pointer light in the concave portion. By storing the bottom surface portion of the irradiating means, the pointer light irradiating means is rotatably supported, and the pointer light irradiating means is in a state where the upper surface portion of the pointer light irradiating means is in contact with the plate. The optical axis of the pointer light irradiating means can be adjusted by rotating about an axis substantially perpendicular to the plate.

According to a tenth aspect of the present invention, in the optical reading device according to the third aspect, the pointer light irradiation means has a bottom surface portion formed in a cylindrical side surface shape and a top surface portion formed in a cylindrical side surface shape. The optical reading device includes a support member having a concave portion having an approximately circular opening, and a plate that contacts the upper surface portion of the pointer light irradiation means, and the support member has the pointer light in the concave portion. By storing the bottom surface portion of the irradiating means, the pointer light irradiating means is rotatably supported, and the pointer light irradiating means is in a state where the upper surface portion of the pointer light irradiating means is in contact with the plate. The optical axis of the pointer light irradiating means can be adjusted by rotating about the cylindrical central axis of the upper surface portion.

  In the optical reading apparatus of the present invention, the optical axis of the imaging unit is tilted, and the irradiation unit is arranged in a direction opposite to the tilting direction. It is possible to reduce the inclination angle of the image pickup means necessary for preventing the image pickup means from receiving the regular reflection light of the light irradiated by the irradiation means.

  Since the inclination angle of the imaging means can be reduced, the dead space in the optical reader can be reduced. In addition, since the deviation between the position of the image pickup means and the position where the barcode to be read is arranged can be reduced, the work area can be reduced.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings. FIG. 1 is a perspective view of a barcode reader 1 according to the present embodiment. 2 is a front view of the barcode reader 1, FIG. 3 is a rear view, and FIG. 4 is a left side view.

  The barcode reader 1 is a small device having a substantially rectangular parallelepiped shape having a height of about 60 mm, a width of about 45 mm, and a depth of about 25 mm. The information recorded on the barcode can be read by being installed on the top.

  As shown in FIGS. 1 to 4, the barcode reader 1 has an external appearance formed by attaching a box-shaped cover 10 to a plate 11 on the back side. That is, the cover 10 and the plate 11 constitute a casing of the barcode reader 1. And the imaging unit 3, the pointer light irradiation device 4, the LED light illumination device 5, the printed circuit board 7 (illustrated in FIG. 5) and the like are accommodated in this casing.

  The cover 10 includes a front portion 10a disposed substantially parallel to the plate 11, an inclined portion 10b inclined to the front portion 10a at the upper portion of the front portion 10a, and side portions 10c on both the left and right sides. 10c, the plane part 10d, and the bottom face part 10e. The left and right side surface portions 10c and 10c are disposed to face each other substantially in parallel, and the flat surface portion 10d and the bottom surface portion 10e are disposed to face each other substantially in parallel.

  As shown in FIG. 4, the inclined portion 10 b is disposed with an inclination angle α with respect to the front portion 10 a. In the present embodiment, the inclination angle α is approximately 20 degrees. An opening 10f is formed in the inclined portion 10b, and an opening 10g is formed in the flat portion 10d. As shown in FIG. 5, a transparent member 12 is attached to the opening 10 f, and the internal imaging unit 3, the pointer light irradiation device 4, and the LED light illumination device 5 can be visually recognized through the transparent member 12. It has become. The pointer light irradiation device 4 and the LED light illumination device 5 irradiate the object surface or the like with laser light or LED light through the transparent member 12. Further, the imaging unit 3 receives reflected light from the barcode via the transparent member 12 and captures a barcode image. In addition, the operation panel portion 6 housed in the casing is fitted into the opening portion 10g.

  5 is a cross-sectional view taken along line AA in FIG. 2, and FIG. 6 is a cross-sectional view taken along line BB. As shown in the figure, the imaging unit 3 and the LED light illumination device 5 are also inclined and arranged in accordance with the inclination angle of the inclined portion 10b. Specifically, it is arranged so that the optical axis of the imaging means provided in the imaging unit 3 is orthogonal to the inclined portion 10b. In other words, the element arrangement surface of the image pickup element provided in the image pickup unit 3 is arranged so as to be substantially parallel to the inclined portion 10b. As will be described later, the left and right pointer light irradiation devices 4 and 4 are attached so as to be incorporated in the imaging unit 3, and the optical axis of the pointer light output from the pointer light irradiation devices 4 and 4 captures the image. It is adjusted to meet at the focal position of the device. In FIG. 6, hatched portions indicate the LED light irradiation range by the LED light illumination device 5. Moreover, the broken line in the figure indicates the field of view range of the imaging apparatus.

  The cable 2 extends from the bottom surface portion 10e. The cable 2 is connected to a printed circuit board 7 in the casing, and transfers the barcode information read by the barcode reader 1 to an external computer or the like. FIG. 7 is an exploded view of the barcode reader 1. Thus, the imaging unit 3 and the like are accommodated between the plate 11 on the back side of the barcode reader 1 and the cover 10.

  FIG. 8 is a partially broken perspective view of the barcode reader 1 as seen from a plane oblique direction. As shown in the figure, the bar code 9 is irradiated by the left and right pointer light irradiation devices 4 and 4. Then, the image of the barcode 9 is picked up by the image pickup unit 3 in a state where the two point lights overlap on the printing surface of the barcode 9. By imaging in such a state, the focus of the imaging means provided in the imaging unit 3 coincides with the printing surface of the barcode 9, and the barcode 9 can be read accurately.

  FIG. 9 is also a partially broken perspective view of the barcode reader 1 as viewed from the plane oblique direction. As shown in the figure, the LED light is irradiated to the barcode 9 by the left and right LED light illumination devices 5 and 5. The imaging unit 3 captures an image of the barcode 9 by receiving light emitted from the LED light illumination device 5 and irregularly reflected by the barcode 9. In the figure, hatched portions indicate the LED light irradiation range by the LED light illumination device 5.

  As described with reference to the drawings, the barcode reader 1 according to the present embodiment has the imaging unit 3 and the LED light illumination device 5 disposed in the inclined portion 10b, but is lower than the imaging unit 3. The LED light illuminating device 5 is disposed on the surface. In other words, in the inclined portion 10b, the imaging unit 3 is disposed on the side close to the flat surface portion 10d, and the LED light illumination device 5 is disposed on the side close to the bottom surface portion 10e. In the inclined portion 10b, the pointer light irradiation device 4 is disposed closer to the flat surface portion 10d than the imaging unit 3. As shown in FIG. 5, the optical axis L of the imaging means of the imaging unit 3 is closer to the flat surface portion 10d than the axis K orthogonal to the front surface portion 10a in the plane orthogonal to the front surface portion 10a and the flat surface portion 10d. It is arranged with an inclination (in this embodiment, it is arranged with an angle α inclination).

  The merit of taking such an arrangement relationship between the imaging unit 3 and the LED light illumination device 5 will be described. For example, as shown in FIG. 10, consider a case where LED light illumination devices 5 a and 5 b are arranged on both upper and lower sides of the imaging unit 3. The imaging unit 3 includes an optical unit 32 and an imaging element 341 that is an imaging means. Assume that the optical axis L of the image sensor 341 is orthogonal to the printing surface of the barcode 9 as shown in FIG. In this case, the specularly reflected light emitted from the upper and lower LED light illumination devices 5a and 5b is within the field of view of the image sensor 341 and is received by the image sensor 341. That is, the light sources of the two LED light illuminators 5a and 5b are reflected in the image incident on the image sensor 341 as they are. In this case, since extremely strong light is included in the captured image, it is difficult to accurately read the barcode.

  Therefore, as shown in FIG. 11, a case is considered in which a component group including the imaging unit 3 and the LED light illumination devices 5a and 5b is arranged at an inclination. That is, the inclined portion 10b is inclined by the angle α1, and the optical axis of the image sensor 341 orthogonal to the inclined portion 10b is also inclined by the angle α1. In this case, since the illumination from the LED light illuminating device 5a is within the imaging range, it is reflected in the barcode 9. However, the illumination from the LED light illuminating device 5b is outside the imaging range, and the barcode 9 There is no reflection. That is, since the regular reflection light of the light output from the LED light illumination device 5a is directly incident on the image sensor 341, the light source is reflected in the captured image, but the regular reflection of the light output from the LED light illumination device 5b. Light is no longer incident on the image sensor 341.

  Further, as shown in FIG. 12, the inclination angle of the component group including the imaging unit 3 and the LED light illumination devices 5a and 5b is increased. That is, the inclined portion 10b is inclined by an angle α2 larger than the angle α1 shown in FIG. 11, and the optical axis of the image sensor 341 orthogonal to the inclined portion 10b is also inclined by the angle α2. As a result, the regular reflection light of the light emitted from the LED light illumination devices 5a and 5b is outside the imaging range, and neither is incident on the imaging element 341, and neither light source is reflected in the captured image. . In such a state, the barcode reader 1 can read the barcode 9 accurately.

  As described above, when the LED light illumination device 5a is arranged on the upper side (that is, the flat surface portion 10d side) with respect to the imaging unit 3, in order to prevent the imaging element 341 from receiving regular reflection light, imaging is performed. The tilt angle of the optical axis of the element 341 has to be increased. In other words, by arranging the optical axis of the imaging unit to be inclined, it is possible to avoid the incidence of specularly reflected light on the imaging unit. If the irradiating means is disposed, the inclination angle of the imaging means must be increased.

  Therefore, in the barcode reader 1 according to the present embodiment, as shown in FIGS. 1 to 6 and the like, the LED light illumination devices 5 and 5 are disposed on the lower side (that is, the bottom surface portion 10e side) with respect to the imaging unit 3. It is arranged. That is, the LED light illumination devices 5 and 5 are arranged on the bottom surface portion 10e side opposite to the direction in which the optical axis L of the image sensor 341 is inclined. Thereby, the inclination angle of the optical axis L of the image sensor 341 can be reduced, and the dead space in the apparatus can be reduced. In addition, since the inclination angle of the inclined portion 10b can be reduced, the casing can be brought close to a rectangular parallelepiped shape, so that the dead space in the installation environment is small and the configuration is less wasteful. Specifically, by arranging the LED light illumination device 5 below the imaging unit 3 as in the barcode reader 1 of the present embodiment, the angle formed by the front portion 10a and the inclined portion 10b is It can be in the range of 10 degrees to 30 degrees.

  In the barcode reader 1 of the present embodiment, the pointer light irradiation device 4 is arranged on the upper side of the imaging unit 3 and the LED light illumination device 5 is arranged on the lower side. Wiring between the two is easy. That is, if the pointer light irradiation device 4 or the LED light illumination device 5 is divided and arranged above and below the imaging unit 3, the wiring becomes complicated, and it is necessary to devise such as making the printed circuit board 7 larger. With the above configuration, wiring can be performed efficiently. Further, the LED light illumination devices 5 and 5 are arranged on the left and right with the imaging unit 3 as the center. As a result, the LED light is irradiated evenly in the imaging area.

  Next, the configuration of the imaging unit 3 and the pointer light irradiation device 4 will be described in detail. FIG. 13 is a perspective view of the imaging unit 3. In this way, the imaging unit 3 is configured by incorporating the two pointer light irradiation devices 4 and 4. FIG. 14 is a front view of the imaging unit 3.

  As shown in the drawing, the imaging unit 3 includes a main body member 31, an optical unit 32 incorporated in the central portion of the main body member 31, a metal plate 33 attached to the upper portion of the main body member 31, and the back side of the main body member 31. And a sensor unit 34 attached to the head. Two pointer light irradiation devices 4 and 4 are mounted so as to be sandwiched between the main body member 31 and the metal plate 33.

  FIG. 15 is an assembly view of the imaging unit 3 as seen from the plane, and FIG. 16 is an assembly view as seen from the side. As shown in the drawing, the imaging unit 3 is assembled from the front side in the order of the optical unit 32, the main body member 31, the filter 36, the sponge 35, and the sensor unit 34 including the imaging element 341, and is fixed with bolts 38 from the back side. Is done. Further, as shown in FIG. 16, a metal plate 33 is placed on the upper part of the main body member 31 and is fixed by bolts 37.

  As shown in FIGS. 13 and 14, the optical unit 32 is a substantially cylindrical member, and a light incident hole 321 for receiving reflected light is formed at the center thereof. The imaging unit 3 receives reflected light from the barcode through the light incident hole 321, passes the lens in the optical unit 32, and then receives the light on the imaging element 341.

  FIG. 17 is a perspective view of the main body member 31. That is, the optical unit 32, the metal plate 33, the sensor unit 34, the pointer light irradiation device 4 and the like are removed from the imaging unit 3. 18 is a front view of the main body member 31, FIG. 19 is a rear view, FIG. 20 is a right side view, and FIG. 21 is a plan view.

  As shown in FIG. 17 and the like, the main body member 31 includes an insertion portion 311 of the optical unit 32 provided substantially at the center, wing portions 312 and 312 extending to the left and right, and an upper mounting member 316 extending to the upper portion. It is configured with. Further, side attachment members 314 and 314 extend from the left and right wing portions 312 and 312 toward the outside.

  As shown in FIGS. 17 and 21, support holes 313 and 313 having substantially circular shapes in plan view are formed in the left and right wings 312 and 312, respectively. The left and right pointer light irradiation devices 4 and 4 are placed in the support holes 313 and 313, respectively.

  The side mounting member 314 is provided with a bolt hole 315, the upper mounting member 316 is provided with a bolt hole 317, and a bolt is inserted into each of the holes 315 and 317, and a bolt groove (not shown) on the plate 11 side is shown. The imaging unit 3 is fixed to the plate 11 by screwing the bolts to the plate 11. Further, cylindrical members 318 and 318 are provided on the left and right of the upper mounting member 316. Bolt grooves 319 and 319 are formed in the cylindrical members 318 and 318, and the bolt 37 described above is screwed therein.

  FIG. 22 is a perspective view of the pointer light irradiation device 4. 23 is a front view of the pointer light irradiation device 4, FIG. 24 is a right side view, and FIG. 25 is a plan view.

  As shown in FIG. 22 and the like, the pointer light irradiation device 4 has a laser light irradiation unit 41 disposed at the center, and two rotating sliding portions 42 and 42 having a cylindrical side surface formed on the upper portion. Has been. Further, substantially cylindrical projecting portions 43 and 43 are provided on both the left and right sides of the laser light irradiation unit 41. The protrusions 43 and 43 are provided with adjustment tool insertion holes 44 and 44, respectively.

  Further, as shown in FIG. 24, a substantially spherical bottom surface portion 47 is formed below the laser light irradiation portion 41. The bottom surface portion 47 is placed in the support hole 313 of the wing 312 described above. Since the diameter of the bottom surface portion 47 is larger than the diameter of the support hole 313, only a part of the bottom surface portion 47 is inserted into and supported by the upper portion of the support hole 313 as shown in FIG.

  A lead wire 45 extends on the back side of the laser beam irradiation unit 41 and is connected to the printed circuit board 46 on the back side. Furthermore, the printed circuit board 46 is connected to the printed circuit board 7 via lead wires (not shown). In such a configuration, the laser beam irradiation unit 41 that receives the control signal from the printed circuit board 7 irradiates the laser beam from an internal light source (not shown).

  As described above, the pointer light irradiation device 4 configured as described above is placed in the support hole 313 provided in the wing portion 312 of the main body member 31. With the pointer light irradiation devices 4, 4 placed in the left and right support holes 313, 313, the metal plate 33 is further placed in contact with the upper portions of the pointer light irradiation devices 4, 4 and fixed with bolts 37. . At this time, the rotational sliding portions 42, 42 that are the upper surface of the pointer light irradiation device 4 come into contact with the lower surface of the metal plate 33.

  In this state, the adjustment tool 40 is inserted into the adjustment tool insertion hole 44 provided in the projecting portion 43. As the adjustment tool 40, for example, a thin metal rod may be used. Then, as shown in FIG. 26, the pointer light irradiation device 4 is rotated in the vertical direction by rotating the adjustment tool 40 in the vertical direction. That is, the bottom surface portion 47 of the pointer light irradiation device 4 is in contact with the annular edge at the upper portion of the support hole 313, and the rotary sliding portion 42 as the upper surface is in contact with the lower surface of the metal plate 33. In this state, when the adjustment tool 40 is rotated in the vertical direction, the pointer light irradiation device 4 is rotated in the vertical direction along the cylindrical upper surface of the rotary sliding portion 42.

  As shown in FIG. 26, the rotary sliding portion 42 has an arcuate outer shape in a side view. When the center of the arc is a center point 4c, the pointer light irradiation device 4 is centered on the center point 4c. It rotates in the vertical direction. The center point 4c also coincides with the center of the sphere of the bottom surface portion 47 formed in a spherical shape. Therefore, by rotating the adjustment tool 40 in the vertical direction, the bottom surface portion 47 also rotates around the center point 4c.

  As shown in FIG. 27, when the adjustment tool 40 is inserted into the adjustment tool insertion hole 44 and rotated in the left-right direction, the pointer light irradiation device 4 rotates in the left-right direction. That is, the pointer light irradiation device 4 rotates in the horizontal direction with the apex of the rotary sliding portion 42 in contact with the lower surface of the metal plate 33. Further, at this time, as shown in FIG. 28, the bottom surface portion 47 rotates in the horizontal direction in a state where it abuts on the annular edge of the support hole 313. And also when the adjustment tool 40 is rotated in a horizontal direction (left-right direction), the pointer light irradiation device 4 is rotated in the horizontal direction (left-right direction) around the center point 4c.

  On the other hand, as shown in FIG. 29, the pointer light irradiation device 4 rotates in the direction of the arrow C in the figure because the two left and right rotational sliding portions 42 and 42 are in contact with the metal plate 33. There is nothing. That is, the rotational movement around the optical axis of the laser light irradiation unit 41 is regulated by the metal plate 33.

  With such a configuration, the pointer light irradiation device 4 rotates in the vertical direction and the horizontal direction, but does not rotate in the direction of arrow C in the figure. The two left and right pointer light irradiation devices 4 need to be adjusted so as to indicate the focal position of the sensor unit 34 that is an imaging means, depending on the point where the two pointer lights intersect. For this purpose, it is sufficient for the pointer light irradiation device 4 to be able to rotate in the vertical direction and the horizontal direction, and it is not necessary to rotate the optical axis of the pointer light. That is, since the imaging unit 3 and the pointer light irradiation device 4 of the present embodiment are configured to rotate only in the direction necessary for adjusting the pointer light, the member rotates in an unnecessary direction during the adjustment. Therefore, the adjustment operation can be easily performed.

  Or you may adjust so that the pointer light irradiation apparatus 4 may show the visual field range of the sensor unit 34. FIG. That is, the optical axes indicated by the left and right pointer light irradiation devices 4 may be adjusted so as to spread on both the left and right sides, and the vicinity of the outer periphery of the visual field range of the image sensor 341 may be indicated.

  As long as the metal plate 33 in the present embodiment is an elastic member having a flat surface, another kind of material can be replaced. By applying a part of the main body member 31 to the member, the number of assembly steps and the number of parts can be reduced. be able to.

  In the above embodiment, the upper surface portion of the pointer light irradiation device 4 is formed in a cylindrical side surface shape, and the bottom surface portion is formed in a substantially spherical shape, but both the upper surface portion and the bottom surface portion are formed in a spherical shape. It may be formed. Alternatively, both the upper surface portion and the bottom surface portion may be formed in a cylindrical side surface shape.

  In the above embodiment, the optical axis of the pointer light irradiation device 4 is adjusted so that the support hole 313 of the wing 312 rotatably supports the bottom surface of the pointer light irradiation device 4. A substantially circular concave portion may be formed in the plate portion with which the upper surface portion of the pointer light irradiation device 4 abuts, and the pointer light irradiation device 4 may be rotatably supported by the concave portion.

  When the adjustment tool 40 is rotated in the vertical direction or the horizontal direction to adjust the rotation position of the left and right pointer light irradiation devices 4, 4, an adhesive is poured from the back side of the support holes 313, 313, and the bottom surface portions 47, 47. Is fixed in the support holes 313 and 313.

  Here, as shown in FIG. 30, an injection hole 471 for the adhesive 472 may be provided below the bottom surface portion 47. With such a configuration, the adhesion area is widened, and the pointer light illumination device 4 after the optical axis adjustment can be sufficiently fixed. The cross section of the injection hole 471 may be circular or rectangular such as a square. Or a cross section etc. may be sufficient. Alternatively, it may be composed of a plurality of small round holes, or may be a long and thin shape. Conversely, the bottom surface 47 may have a protrusion. The cross section of the protrusion may be a circle, a square, a cross, or the like, or may be composed of a plurality of small round protrusions. Or you may comprise by the elongate processus | protrusion. This also makes it possible to increase the bonding area. And thereby, the intensity | strength to the rotation direction of the pointer light irradiation apparatus 4 can be raised.

  In this way, the imaging unit 3 is housed in the casing and assembled as the barcode reader 1 with the position of the pointer light irradiation devices 4, 4, that is, the optical axis adjusted. In the present embodiment, the support holes 313 and 313 are through-holes having a cylindrical space. However, it is essential that a recess capable of supporting the bottom surface portion 47 is formed. Then, it is only necessary to provide an insertion hole through which the adhesive can be poured into the recess.

  Further, the metal plate 33 may be removed after the pointer light irradiation device 4 is bonded and fixed. As described with reference to FIG. 12 and the like, the metal plate 33 is fixed by the bolt 37 and is detachable. FIG. 31 is a perspective view of the imaging unit 3 with the metal plate 33 removed. FIG. 32 is a plan view of the imaging unit 3 with the metal plate 33 removed, and FIG. 33 is a front view. That is, in the imaging unit 3 shown in these drawings, the optical axis of the pointer light irradiation device 4 is adjusted, and the metal plate 33 is removed after the position and angle of the pointer light irradiation device 4 are bonded and fixed. It is. In this way, the imaging unit 3 with the metal plate 33 removed may be housed in a casing composed of the plate 11 and the cover 10.

  The optical reader according to the present invention has been described by taking the barcode reader 1 as an example. However, the optical reader according to the present invention is not limited to a barcode reader, but can be applied to an apparatus that reads a two-dimensional code such as a QR code. Is possible.

It is a perspective view of a barcode reader. It is a front view of a barcode reader. It is a rear view of a barcode reader. It is a left view of a barcode reader. It is arrow AA sectional drawing of a barcode reader. It is arrow BB sectional drawing of a barcode reader. It is an assembly exploded view of a barcode reader. It is a partially broken perspective view of a barcode reader. It is a partially broken perspective view of a barcode reader. FIG. 4 is a state diagram in which LED light illumination devices are arranged above and below the image sensor, and the optical axis of the image sensor and the barcode surface are orthogonal to each other. FIG. 4 is a state diagram in which LED light illumination devices are arranged above and below the image sensor, and the optical axis of the image sensor and the barcode surface are inclined. FIG. 4 is a state diagram in which LED light illumination devices are arranged above and below the image sensor, and the optical axis of the image sensor and the barcode surface are inclined. It is a perspective view of an imaging unit. It is a front view of an imaging unit. It is a plane assembly drawing of an imaging unit. It is a side assembly drawing of an imaging unit. It is a perspective view of an imaging unit main body member. It is a front view of an imaging unit main body member. It is a rear view of an imaging unit main body member. It is a right view of an imaging unit main body member. It is a top view of an imaging unit main body member. It is a perspective view of a pointer light irradiation apparatus. It is a front view of a pointer light irradiation apparatus. It is a right view of a pointer light irradiation device. It is a top view of a pointer light irradiation apparatus. It is a figure which shows the adjustment method of the up-down direction of a pointer light irradiation apparatus. It is a figure which shows the adjustment method of the horizontal direction of a pointer light irradiation apparatus. It is a figure which shows the adjustment method of the horizontal direction of a pointer light irradiation apparatus. It is a figure which shows the direction in which rotation of a pointer light irradiation apparatus is controlled. It is a figure which shows the adhesion | attachment form of a pointer light irradiation apparatus. It is a perspective view of the imaging unit which removed the metal plate. It is a top view of the imaging unit which removed the metal plate. It is a front view of the imaging unit which removed the metal plate.

Explanation of symbols

1 Barcode reader 3 Imaging unit 4 Pointer light irradiation device 5 LED light illumination device

Claims (9)

In an installation-type optical reader having a function of imaging an imaging area including an information code and reading information recorded in the information code based on the obtained captured image ,
A first surface facing the surface on which the information code is disposed, a second surface facing the first surface on the side opposite to the surface on which the information code is disposed, and the first and second surfaces A substantially rectangular parallelepiped casing provided with third and fourth surfaces that are arranged substantially orthogonal to each other and face each other;
An imaging unit that faces the first surface in the casing and is disposed at one end closer to the third surface than the fourth surface, and that captures an imaging area including the information code;
In the casing, the one end facing the first surface and closer to the third surface than the fourth surface is disposed closer to the fourth surface than the imaging means, Illumination means for illuminating the imaging area ;
The one end facing the first surface in the casing and closer to the third surface than the fourth surface is disposed closer to the third surface than the imaging means, Pointer light irradiation means for indicating the imaging position,
The imaging means is arranged such that an optical axis thereof is inclined with respect to the third surface side with respect to an axis orthogonal to the first surface in a surface orthogonal to the first and third surfaces. An optical reader. The optical reader according to claim 1,
The casing further includes fifth and sixth surfaces facing each other, and the illumination unit is disposed on the fifth or sixth surface side with respect to the arrangement position of the imaging unit. An optical reader. The optical reading device according to claim 1 or 2 ,
The optical reading apparatus according to claim 1, wherein the first surface has one end portion on the third surface side, and an end surface of the first surface is inclined toward the second surface side. The optical reader according to any one of claims 1 to 3 ,
The pointer light irradiation means
A bottom surface formed in a substantially spherical shape;
An upper surface formed in a cylindrical side surface;
Have
The optical reader is
A support member having an approximately circular recess in the opening;
A plate in contact with the upper surface of the pointer light irradiation means;
With
The support member accommodates the bottom surface portion of the pointer light irradiation means in the recess so as to rotatably support the pointer light irradiation means, and the upper surface portion of the pointer light irradiation means abuts against the plate. An optical reading apparatus characterized in that the optical axis of the pointer light irradiating means can be adjusted by rotating the pointer light irradiating means about an axis substantially perpendicular to the plate in this state. The optical reader according to any one of claims 1 to 3 ,
The pointer light irradiation means
A bottom surface formed in a substantially spherical shape;
An upper surface formed in a cylindrical side surface;
Have
The optical reader is
A support member having an approximately circular recess in the opening;
A plate in contact with the upper surface of the pointer light irradiation means;
With
The support member accommodates the bottom surface portion of the pointer light irradiation means in the recess so as to rotatably support the pointer light irradiation means, and the upper surface portion of the pointer light irradiation means abuts against the plate. An optical reading apparatus characterized in that the optical axis of the pointer light irradiating means can be adjusted by rotating the pointer light irradiating means about the cylindrical central axis of the upper surface portion in the state of being made. The optical reader according to any one of claims 1 to 3 ,
The pointer light irradiation means
A bottom surface formed in a substantially spherical shape;
An upper surface formed in a substantially spherical shape;
Have
The optical reader is
A support member having an approximately circular recess in the opening;
A plate in contact with the upper surface of the pointer light irradiation means;
With
The support member accommodates the bottom surface portion of the pointer light irradiation means in the recess so as to rotatably support the pointer light irradiation means, and the upper surface portion of the pointer light irradiation means abuts against the plate. An optical reading apparatus characterized in that the optical axis of the pointer light irradiating means can be adjusted by rotating the pointer light irradiating means about an axis substantially perpendicular to the plate in this state. The optical reader according to any one of claims 1 to 3 ,
The pointer light irradiation means
A bottom surface formed in a substantially spherical shape;
An upper surface formed in a substantially spherical shape;
Have
The optical reader is
A support member having an approximately circular recess in the opening;
A plate in contact with the upper surface of the pointer light irradiation means;
With
The support member accommodates the bottom surface portion of the pointer light irradiation means in the recess so as to rotatably support the pointer light irradiation means, and the upper surface portion of the pointer light irradiation means abuts against the plate. In this state, the optical axis of the pointer light irradiation means is adjusted by rotating the pointer light irradiation means about an axis substantially perpendicular to the optical axis of the pointer light irradiation means and substantially parallel to the plate. An optical reader characterized by being made possible. The optical reader according to any one of claims 1 to 3 ,
The pointer light irradiation means
A bottom surface formed in a cylindrical side surface;
An upper surface formed in a cylindrical side surface;
Have
The optical reader is
A support member having an approximately circular recess in the opening;
A plate in contact with the upper surface of the pointer light irradiation means;
With
The support member accommodates the bottom surface portion of the pointer light irradiation means in the recess so as to rotatably support the pointer light irradiation means, and the upper surface portion of the pointer light irradiation means abuts against the plate. An optical reading apparatus characterized in that the optical axis of the pointer light irradiating means can be adjusted by rotating the pointer light irradiating means about an axis substantially perpendicular to the plate in this state. The optical reader according to any one of claims 1 to 3 ,
The pointer light irradiation means
A bottom surface formed in a cylindrical side surface;
An upper surface formed in a cylindrical side surface;
Have
The optical reader is
A support member having an approximately circular recess in the opening;
A plate in contact with the upper surface of the pointer light irradiation means;
With
The support member accommodates the bottom surface portion of the pointer light irradiation means in the recess so as to rotatably support the pointer light irradiation means, and the upper surface portion of the pointer light irradiation means abuts against the plate. An optical reading apparatus characterized in that the optical axis of the pointer light irradiating means can be adjusted by rotating the pointer light irradiating means about the cylindrical central axis of the upper surface portion in the state of being made.

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