JP5917579B2 - Image sensor unit and image reading apparatus - Google Patents

Description

  The present invention relates to an image sensor unit and an image reading apparatus. In particular, the present invention relates to an image sensor unit that reads paper sheets such as banknotes and an image reading apparatus to which the image sensor unit is applied.

  An image reading unit for reading paper such as banknotes incorporates an image sensor unit for discriminating the type of paper, counting, and authenticity. In such an image reading apparatus, there are ones in which two sets of contact image sensor units are arranged to face each other with a paper sheet conveyance path interposed therebetween (see Patent Document 1). In the contact image sensor unit used in such an embodiment, it is preferable that the size of the paper sheet in the transport direction is small in order to suppress the occurrence of paper jams.

  The contact-type image sensor unit includes a light source module that emits light toward a paper sheet, a light collecting body that collects light from the paper sheet, and an image sensor that detects light collected by the light collecting body. And have. The light source module, the condenser, and the image sensor are accommodated in the frame, and a cover member such as a glass plate is attached to the frame. The cover member and the frame are bonded to each other with a sealing material in order to prevent or suppress entry of foreign matter into the frame.

  By the way, in the image sensor unit, the irradiation intensity of the light source module may change due to an environmental change (such as a temperature change in the use environment) or aged deterioration. Therefore, in order to correct this, a white reference is provided in the image sensor unit, a white correction value is acquired before the actual use of the image sensor unit, and an irradiation intensity (lighting time) is adjusted based on the acquired white correction value. The method of doing is used. Then, as described above, in the two sets of contact image sensor units arranged to face each other across the paper sheet conveyance path, one image sensor unit uses the white reference of the other image sensor unit. Some correct the irradiation intensity of the light source module.

JP 2000-113269 A JP 2003-87564 A

  When the cover member and the frame are bonded using a sealing material, it is preferable that the application area of the sealing material is large from the viewpoint of workability. Further, in the configuration in which the irradiation intensity is corrected using the white reference of the image sensor units arranged opposite to each other, it is preferable that the size of the white reference is large in consideration of variations in the assembly position of the contact image sensor unit. However, the frame size increases when the sealing material application area is increased or the white reference dimension is increased. As described above, it has been difficult to achieve both reduction in the size of the frame (particularly, the size in the conveyance direction of the paper sheet) and increase in the size of the application area of the sealing material and the white reference.

  In view of the above situation, the problem to be solved by the present invention is to reduce the size in the width direction (the size in the moving direction relative to the paper sheet), and to increase the coating area of the sealing material and the white reference. Is to achieve both.

The image sensor unit of the present invention is an image sensor unit that is disposed and used facing each other so as to be able to read both sides of a sheet to be read, and which irradiates light toward the sheet And a light collecting body for collecting light from the paper sheets, an image sensor for detecting light collected by the light collecting body, the light source module, the light collecting body, and the image sensor. A cover member that covers the frame, the cover member being joined to the frame by an adhesive material, and the condensing of the other image sensor unit facing the at least part of the adhesive material. It includes a white portion provided so as to be located on the optical axis of the body.

  ADVANTAGE OF THE INVENTION According to this invention, coexistence with size reduction of the width direction dimension (relative movement direction with paper sheets) of an image sensor unit and the enlargement of the application | coating area | region of a sealing material and a white reference | standard can be aimed at.

FIG. 1 is an exploded perspective view schematically showing a configuration example of an image sensor unit. FIG. 2 is a cross-sectional view schematically showing a configuration example of the image sensor unit. FIG. 3 is a diagram illustrating an example of the relationship between the adhesive material and the frame. FIG. 4 is a plan view schematically showing an example of a range in which the adhesive material is provided. FIG. 5 is a cross-sectional view schematically showing a configuration example of the paper sheet identification apparatus.

Embodiments of the present invention will be described below in detail with reference to the drawings. An embodiment of the present invention is a contact image sensor unit having a 1 × optical system and an image reading apparatus having the image sensor unit. In each figure, three-dimensional directions are indicated by X, Y, and Z arrows. The X direction is the main scanning direction of the image sensor unit. The Y direction is the sub-scanning direction of the image sensor unit. The Z direction is the vertical direction of the image sensor unit. The sub-scanning direction is the direction of relative movement between the image sensor unit and the paper sheet, and the width direction of the image sensor unit.
In the embodiment of the present invention, “light” includes not only visible light but also electromagnetic waves in a wavelength range other than visible light (for example, electromagnetic waves having wavelengths in the infrared wavelength range or in the ultraviolet wavelength range).

(Image sensor unit)
The overall configuration of the image sensor unit 1 will be described with reference to FIGS. 1 and 2. FIG. 1 is an exploded perspective view schematically showing a configuration example of the image sensor unit 1. FIG. 2 is a cross-sectional view schematically showing the structure of the image sensor unit 1, and shows a cross section cut along a plane perpendicular to the main scanning direction. As shown in FIGS. 1 and 2, the image sensor unit 1 includes a frame 11, a cover member 12, a light source 13, a light guide body 14, a light collector 15, and a sensor substrate 16. The

  The frame 11 is a housing of the image sensor unit 1. The frame 11 is configured, for example, in a rod shape that is long in the main scanning direction. The frame 11 is made of a resin material that is colored black and has a light shielding property. For example, polycarbonate can be used as the resin material. The frame 11 has a side wall 111 that is an outer shell of the image sensor unit 1. A light guide housing chamber 113 capable of housing the light guide body 14 and a light collector housing chamber 114 capable of housing the light collector 15 are formed in the upper part of the region surrounded by the side wall 111 in the Z direction. A substrate accommodation chamber 115 that can accommodate the sensor substrate 16 is formed in the lower portion in the Z direction of the region surrounded by the side wall 111. The light collector housing chamber 114 and the substrate housing chamber 115 are connected by an opening through which light can pass. Furthermore, a light source accommodation chamber 112 that can accommodate the light source 13 is formed at the end portion in the main scanning direction (longitudinal direction) of the region surrounded by the side wall 111.

The cover member 12 is provided so as to cover the upper side of the frame 11. The cover member 12 has a function of protecting the light guide body 14 and the light collecting body 15 and a function of maintaining the paper sheet S on a flat surface by contacting the paper sheet S. The cover member 12 is a flat member. For the cover member 12, for example, a glass plate or a transparent resin plate having the same strength as the glass plate can be applied.
The cover member 12 is joined to the upper side of the frame 11 by the adhesive material 2. The adhesive material 2 and the joining structure will be described later.

  The light source 13 is disposed at a distance from an incident surface 141 (described later) that is an end surface of the light guide 14 in the main scanning direction, and irradiates light toward the incident surface 141 of the light guide 14. The light source 13 includes, for example, a light emitting element that emits light of each wavelength of red (R), green (G), and blue (B) that are sequentially turned on. The light source 13 may have either or both of a light emitting element that emits infrared rays (Ir) and a light emitting element that emits ultraviolet rays (UV) in addition to the light emitting elements of the respective colors. Various known LEDs can be applied to each light emitting element. The light source 13 may be an LED package having pin-shaped terminals for connecting to the LED and the sensor substrate 16 or a surface-mounted LED package.

The light guide 14 is an optical member that linearizes the light emitted from the light source 13, and has a rod-like configuration elongated in the main scanning direction as a whole. The light guide 14 is made of a transparent resin material such as acrylic resin, and is integrally formed by injection molding or the like.
An incident surface 141 on which light emitted from the light source 13 is incident is provided on the end surface of the light guide 14 in the main scanning direction (longitudinal direction). If the image sensor unit 1 has a set of light sources 13 and the set of light sources 13 is provided only at one end portion of the light guide 14, an incident surface 141 is provided on the one end surface. The opposite end face is provided with a reflecting surface 144 that reflects light. If the image sensor unit 1 has two sets of light sources 13 and each of the two sets of light sources 13 is provided at both ends of the light guide 14, incident surfaces are formed on both ends of the light guide 14 in the main scanning direction. 141 is provided. In each drawing, an example of a configuration in which the image sensor unit 1 has one set of light sources 13 is shown, but a configuration having two sets of light sources 13 may be used.
Furthermore, an exit surface 142 and a diffusion surface 143 (see FIG. 2) are provided on the side surface of the light guide 14.
The emission surface 142 is a surface that emits the light incident from the incident surface 141 and the light reflected by the reflection surface toward the paper sheet S. The exit surface 142 is provided in the form of an elongated band extending in the main scanning direction. Since the emission surface 142 emits light toward the reading line O (see FIG. 2) of the paper sheet S, the emission surface 142 is formed, for example, in a curved surface that is convex toward the reading line O of the paper sheet S. .
The size of the exit surface 142 in the main scanning direction is set according to the size of the paper sheet S to be read. For example, when the banknote is read as the paper sheet S while being conveyed in the longitudinal direction, the dimension of the emission surface 142 in the main scanning direction is set to a dimension corresponding to the short side dimension of the banknote.
The diffusion surface 143 is a surface that reflects and diffuses light incident from the incident surface 141. The diffusion surface 143 is provided so as to face the emission surface 142. For example, a plurality of prismatic diffusion portions are provided on the diffusion surface 143 at a predetermined interval. The interval between the plurality of diffusion portions decreases as the distance from the incident surface 141 increases.
In addition, as a spreading | diffusion part, the structure to which the printing pattern which consists of a light reflective paint by silk printing etc. is applied may be sufficient, for example. In this case, the density of the print pattern decreases as it approaches the incident surface 141 and increases as it increases. According to such a configuration, the illuminance distribution of the light emitted from the emission surface 142 becomes non-uniform, in particular, the light emission intensity decreases as the distance from the incident surface 141 increases, and the entire light guide 14 is It is possible to prevent or suppress the illuminance distribution of light from becoming uneven.
The other surfaces of the outer peripheral surface of the light guide 14 each act as a reflecting surface that reflects light.

The light source 13 and the light guide 14 constitute a light source module 17, and light in a predetermined wavelength range is applied to the reading line O of the paper sheet S in a state where it is incorporated in the frame 11 of the image sensor unit 1. Irradiate. The reading line O is set on the optical axis L _O of the light collector 15 on the transport path A of the paper sheet S.

  The light collector 15 is an optical member that forms an image of light from the paper sheet S on the surface of an image sensor 161 (described later). For example, a rod lens array is applied to the light collector 15. The rod lens array has, for example, a configuration in which a plurality of erecting equal-magnification imaging elements (rod lenses) are linearly arranged in the main scanning direction. The light collector 15 may have any configuration in which the imaging elements are arranged in a straight line, and the specific configuration is not limited. For example, the light collector 15 may have a configuration in which a plurality of imaging elements are arranged. Note that various known optical members having a condensing function, such as various known microlens arrays, can be applied to the light collector 15. The image sensor unit 1 is provided with an equal-magnification optical system by applying an equal-magnification imaging element to the condenser 15.

  The sensor board 16 is a rectangular circuit board that is long in the main scanning direction. The image sensor 161 and the light source 13 are mounted on the upper surface (the upper surface in the Z direction) of the sensor substrate 16. The light source 13 is mounted in the vicinity of one or both ends in the main scanning direction of the sensor substrate 16 so that light can be emitted toward the incident surface 141 of the light guide 14. When the light source 13 is a surface-mounted LED package, another small circuit board on which the surface-mounted LED package is mounted is connected to stand up on the sensor board 16. The image sensor 161 is mounted with the light receiving surface facing upward in the Z direction so that light from the light collector 15 can be received. In addition, the sensor board 16 is mounted with connectors for connecting wiring with the outside.

  The image sensor 161 converts the light imaged by the light collector 15 into an electrical signal. For example, an image sensor IC array is applied to the image sensor 161. The image sensor IC array is configured by mounting a plurality of image sensor ICs linearly on the surface of the sensor substrate 16 in the main scanning direction. The image sensor IC is composed of a plurality of light receiving elements (sometimes referred to as photoelectric conversion elements) corresponding to the reading resolution of the image sensor unit 1. Thus, the image sensor 161 is configured by arranging a plurality of image sensor ICs (light receiving elements) in a straight line in the main scanning direction. The image sensor 161 only needs to have a configuration in which a plurality of image sensor ICs are arranged in a straight line, and other configurations are not particularly limited. For example, the image sensor ICs may be arranged in a plurality of rows like a staggered arrangement. Note that various well-known image sensor ICs having sensitivity to visible light and infrared light can be applied to the image sensor ICs constituting the image sensor IC array as the image sensor 161.

  In addition, the image sensor unit 1 is provided with an attachment portion for attachment to an image reading apparatus (described later), a connector for electrical connection to the image reading apparatus, and the like. In addition, the structure of an attaching part or a connector is not specifically limited. The attachment portion may be any configuration as long as the image sensor unit 1 can be attached to the image reading apparatus. The connector may be configured to connect the image sensor unit 1 and a predetermined device of the image reading apparatus so as to be able to transmit and receive power and electric signals.

The assembly structure of the image sensor unit 1 is as follows.
The light guide 14 is housed in the light guide housing chamber 113 of the frame 11. The light collector 15 is housed in the light collector housing chamber 114 of the frame 11. Further, the sensor substrate 16 on which the light source 13 and the image sensor 161 are mounted is accommodated in the substrate accommodating chamber 115. When the light guide 14 is accommodated in the light guide accommodating chamber 113 and the sensor substrate 16 on which the light source 13 is mounted is accommodated in the substrate accommodating chamber 115, the light source 13 is accommodated in the light source accommodating chamber 112. Opposite to the incident surface 141 provided on the end surface in the main scanning direction. Therefore, the light emitted from the light source 13 can be incident on the incident surface 141 provided on the end surface of the light guide 14. The cover member 12 is joined to the upper side of the frame 11 by the adhesive material 2. The adhesive material 2 has a function as an adhesive that joins the cover member 12 and the frame 11, and also has a function as a sealing material that bonds the cover member 12 and the frame 11. That is, the adhesive material 2 blocks the gap between the cover member 12 and the frame 11 and prevents or suppresses foreign matter from entering the image sensor unit 1.
As shown in FIG. 2, the light collector 15 and the light guide 14 are arranged side by side in the sub-scanning direction. And the condensing body 15 is provided in the position deviated from the center to one side about the sub scanning direction (short direction).

  Here, the operation of the image sensor unit 1 will be described. Before actually reading the paper sheet S, the image sensor unit 1 detects the reflected light from the first adhesive 2a functioning as a white reference, and stores the illuminance of the detected reflected light in advance. Compare with white reference value. Then, a white correction value is calculated based on the comparison result, and the irradiation intensity of the light source 13 is corrected using the calculated white correction value. A conventionally known method can be applied as a specific method for correcting the irradiation intensity of the light source 13 using the white reference. Therefore, the description is omitted.

In actual reading of the paper sheet S, the light source 13 sequentially turns on each light emitting element. The light emitted from the light source 13 is incident on the inside from the incident surface 141 of the light guide 14 and propagates in the interior by being reflected on the diffusing surface 143 and other reflecting surfaces. Then, the light propagating through the light guide 14 is emitted from the emission surface 142 toward the reading line O of the paper sheet S. The reflected light from the reading line O of the paper sheet S forms an image on the surface of the image sensor 161 by the light collecting body 15. The image sensor 161 converts the optical image formed by the light collector 15 into an electrical signal. As described above, the light emitted from the light source 13 includes visible light of each color of red (R), green (G), and blue (B). Furthermore, when the light source 13 has either or both of an element that emits infrared rays and an element that emits ultraviolet rays, the light emitted from the light source 13 includes either or both of infrared rays and ultraviolet rays in addition to visible light.
The image sensor unit 1 periodically repeats the operation of irradiating the paper sheet S with light in each wavelength range and detecting reflected light in a short time. The image sensor unit 1 reads a predetermined pattern (for example, a hologram) provided on the paper sheet S as a visible light image by such an operation. Further, the paper sheet S is read as an infrared image or an ultraviolet image.

  In addition, about the part which abbreviate | omitted illustration and description among the image sensor units 1, the same structure as the conventionally well-known image sensor unit 1 is applicable.

(Adhesive composition)
Next, the structure of the adhesive material 2 is demonstrated.
The adhesive material 2 is interposed between the upper surface of the side wall 111 of the frame 11 and the peripheral edge portion of the lower surface of the cover member 12. Thereby, the cover member 12 is joined to the upper side of the frame 11 by the adhesive material 2. The pressure-sensitive adhesive material 2 has a function as an adhesive for joining the cover member 12 to the frame 11 and a function as a sealing material for preventing or suppressing foreign matter from entering the image sensor unit 1. Furthermore, a part of the adhesive material 2 has a function as a white reference for correcting the irradiation intensity of the light source module 17.

  The adhesive material 2 is made of a substantially white material in order to realize a function as a white reference. The adhesive material 2 has a normal optical density (OD value) of 0.1 or more in the normal direction of the cover member 12 in a state where the cover member 12 is bonded to the frame 11. With such a configuration, it becomes easy to correct the irradiation intensity of the light source 13 using the reflected light from the adhesive material 2. Note that the above-described optical density value is an example, and is not limited to this value. The optical density only needs to be equal to or higher than a predetermined value, and is appropriately set according to the accuracy of correction. As such an adhesive material 2, for example, a white silicone resin is applied. Since the silicone resin has high weather resistance, its aging change such as OD value is small. For this reason, it is suitable for correction of the secular change of the irradiation intensity of the light source 13. Further, since the silicone resin has elasticity, even when the frame 11 and the cover member 12 are thermally deformed (thermal expansion), they are deformed according to the difference in thermal expansion amount. For this reason, it can suppress that the cover member 12 peels from the upper surface of the side wall 111 of the flame | frame 11. FIG. In addition, a double-sided pressure-sensitive adhesive tape in which an adhesive is applied to both surfaces of a white sheet-like base material can be applied as the pressure-sensitive adhesive material 2. In this case, a polyethylene terephthalate (PET) sheet can be applied as the white sheet-like substrate, and an acrylic adhesive can be applied as the adhesive.

  In addition, the structure which emits the light of the wavelength range different from the light of the incident wavelength range may be sufficient as the adhesive material 2. FIG. In order to obtain such an action, a configuration in which a phosphor is included in the adhesive material 2 can be applied. For example, the adhesive 2 may include a phosphor that emits visible light or infrared light when excited by ultraviolet light, or a phosphor that emits visible light when excited by infrared light. As such a phosphor, the phosphor described in JP-A No. 06-25660 and JP-A No. 2005-82770 can be applied. And by using such an adhesive material 2, not only visible light but irradiation intensity | strength of infrared rays and an ultraviolet-ray can be correct | amended.

  As shown in FIG. 2, the adhesive material 2 is provided at both ends of the frame 11 and the cover member 12 in the sub-scanning direction (short direction) (that is, the upper surface of the long side wall 111). As described above, the light collector 15 is disposed at a position biased to one side of the frame 11 in the sub-scanning direction. For convenience of explanation, among the side walls 111 of the frame 11, the side wall 111 farther from the light collector 15 is referred to as “first side wall 111 a”, and the side wall 111 closer to the light collector 15 is referred to as “second side wall 111 b. ". The adhesive material 2 provided on the upper side of the first side wall 111a is referred to as “first adhesive material 2a”, and the adhesive material 2 provided on the upper side of the second side wall 111b is referred to as “second adhesive material 2b”. I write.

When two sets of image sensor units 1 having the same configuration are made to face each other with their positions in the sub-scanning direction aligned, the first adhesive material 2a of each image sensor unit 1 becomes the light collecting body 15 of the opposite image sensor unit 1. Located on the optical axis L _o of the. Specifically, the 1st adhesive material 2a shall be formed over the range of length La from the outer peripheral surface of the 1st side wall 111a. Further, the distance from the outer peripheral surface of the second side wall 111b to the optical axis L _O of the light collector 15 is Lc. In this case, if La> Lc, the first adhesive material 2a and the light collector 15 satisfy the above positional relationship. Thus, the sub-scanning direction dimension La of the first adhesive 2a is set from the outer circumferential surface of the second sidewall 111b to dimensions greater than the distance Lc to the optical axis L _O of the light collector 15. With such a configuration, in each image sensor unit 1, the light emitted from the light source module 17 is reflected by the first adhesive material 2 a of the opposing image sensor unit 1 and enters the light collector 15. Therefore, the image sensor unit 1 can use the light reflected by the first adhesive material 2 a of the other image sensor unit 1 for correcting the irradiation intensity of the light source 13.

  The second adhesive material 2b may not have the optical characteristics as described above. For example, the 2nd adhesive material 2b can apply the structure by which the inner peripheral surface (side surface near the condensing body 15) is colored black. With such a configuration, reflection of light on the surface of the second adhesive material 2b can be suppressed, so that unnecessary light can be prevented from entering the light collector 15. In addition, the second adhesive material 2b may be entirely colored black. The sub-scanning direction dimension Lb of the second adhesive material 2b is set to be smaller than the sub-scanning direction dimension La of the first adhesive material 2a.

Here, the relationship between the 1st adhesive material 2a and the 1st side wall 111a is demonstrated.
As shown in FIG. 2, the sub-scanning direction dimension La of the first adhesive material 2a is larger than the sub-scanning direction dimension (that is, thickness) of the first side wall 111a, and the application region of the first adhesive material 2a. May extend into the frame 11 from the inner peripheral surface of the first side wall 111a.
However, the relationship between the 1st adhesive material 2a and the 1st side wall 111a is not limited to the structure shown in FIG. 3A and 3B are cross-sectional views schematically showing another example of the relationship between the first adhesive material 2a and the first side wall 111a. As shown in FIG. 3A, a hook-like structure (hereinafter referred to as “joining portion 116”) extending in the sub-scanning direction is integrated with the first side wall 111a at the upper end of the first side wall 111a. The first adhesive material 2a may be provided on the upper surface of the joint portion 116 (the upper surface serves as a coating region). In this case, a configuration in which the dimension of the upper surface of the joint portion 116 in the sub-scanning direction is substantially the same as that of the first adhesive material 2a can be applied. 3A shows a configuration in which the hook-shaped joint portion 116 extends to the inner peripheral side in the sub-scanning direction, the joint portion 116 is not limited to such a configuration. For example, the hook-shaped joint portion 116 may extend to the outer peripheral side in the sub-scanning direction, or may extend to both the outer peripheral side and the inner peripheral side in the sub-scanning direction. Further, as shown in FIG. 3B, the sub-scanning direction dimension of the first adhesive material 2a and the thickness of the first side wall 111a may be substantially the same. In this case, the upper surface of the first side wall 111a coincides with the application region of the first adhesive material 2a.
As described above, the dimension of the first adhesive material 2a in the sub-scanning direction is the same as the thickness of the first side wall 111a or larger than the thickness of the first side wall 111a.

Next, the range in which the first adhesive material 2a is provided will be described. 4A to 4C are plan views as viewed in the Z-axis direction schematically showing an example of a range in which the first adhesive material 2a is provided. In the figure, the area | region which gave the lattice-like hatching is an area | region (application | coating area | region) in which the 1st adhesive material 2a is provided. Specifically, FIG. 4A to FIG. 4C are opposed to the first adhesive material 2a of one image sensor unit 1 in a state where the two image sensor units 1 are opposed to each other. It is a figure which overlaps and shows the condensing body 15 (it shows with a broken line in the figure) of the other image sensor unit 1. FIG. In FIG. 4, the cover member 12 is omitted.
FIG. 4A shows an example of a configuration in which the first adhesive material 2 a is provided so as to face the entire light collector 15 of the other image sensor unit 1. That is, the example shown in FIG. 4A is an example in which the first adhesive material 2a is provided over the entire upper surface of the first side wall 111a or the upper surface of the bonding portion 116 (the entire length in the main scanning direction). According to the configuration shown in FIG. 4A, since the first adhesive material 2a is provided in the entire reading area, the irradiation intensity of the entire area can be corrected for each scanning by comparing with the reference data. Further, it is possible to correct a decrease in irradiation intensity due to LED degradation or the like.
FIG. 4B shows a configuration in which the first adhesive material 2 a is provided so as to face one end of the light collector 15 of the other image sensor unit 1 in the main scanning direction. According to the configuration shown in FIG. 4B, since the first adhesive material 2a is provided only at one end portion, a decrease in irradiation intensity due to LED deterioration or the like can be corrected by comparing with the reference data. In addition, even if it is the structure by which the 1st adhesive material 2a is provided in the side close | similar to the light source 13, irradiation intensity | strength correction is possible similarly.
FIG. 4C shows a configuration in which the first adhesive material 2 a is provided so as to face both ends of the light collector 15 of the other image sensor unit 1. According to the configuration shown in FIG. 4C, the correction data is generated for each of the first adhesive materials 2a at both ends, and the generated correction data is complemented, for example, in a straight line, thereby the first adhesive material 2a. It is possible to correct a decrease in irradiation intensity including a region where no is provided.
Thus, the 1st adhesive material 2a may be provided so that the whole condensing body 15 of the other image sensor unit 1 may be opposed, and may be provided so that it may partially oppose. . That is, if the first adhesive material 2a is configured to face at least part of the light collector 15 of the other image sensor unit 1, the two sets of image sensor units 1 face each other. The light from the first adhesive material 2a of the image sensor unit 1 can be condensed and the irradiation intensity of the light source 13 can be corrected.

  4A to 4C are examples of the range of the first adhesive material 2a, and the present invention is not limited to these configurations. For example, the first pressure-sensitive adhesive material 2a (that is, the pressure-sensitive adhesive material having the predetermined optical characteristics described above) is entirely on the upper surface of the side wall 111 of the frame 11 (including the upper surface if the bonding portion 116 is provided). The structure provided over the periphery may be sufficient.

(Image reading device)
An image reading apparatus to which the image sensor unit 1 is applied will be described with reference to FIG. FIG. 5 is a cross-sectional view schematically showing a configuration of a main part of the image reading apparatus, and is a view showing a cross section in a plane perpendicular to the main scanning direction. Here, a bill is shown as an example of the sheet S to be read. As an example of the image reading apparatus, a paper sheet identification apparatus 5 that reads banknotes and determines the type and authenticity is shown as an example. The paper sheet identification device 5 irradiates the paper sheet S with light, reads the light from the paper sheet S, and identifies the type and authenticity of the paper sheet S using the read light.

As shown in FIG. 5, the paper sheet identification device 5 includes two sets of image sensor units 1 and a conveyance roller 51 that conveys banknotes. The two sets of image sensor units 1 have substantially the same size in the sub-scanning direction (that is, the width direction size). A banknote transport path A is set between the transport rollers 51 and between the two sets of image sensor units 1. The two sets of image sensor units 1 are arranged so as to face each other across the banknote transport path A so that both sides of the banknote can be read. The focal point of the light collector 15 of the two sets of image sensor units 1 is set at the center in the thickness direction of the banknote transport path A. The two sets of image sensor units 1 are arranged such that the first adhesive material 2a of each image sensor unit 1 is positioned on the optical axis L _O of the light collecting body 15 of the other image sensor unit 1 facing each other. Be placed. For example, if the two sets of image sensor units 1 have substantially the same size in the sub scanning direction, they are arranged so that the positions of the frames 11 in the sub scanning direction are aligned.

The operation of the paper sheet identification device 5 having such a configuration is as follows. The light sources 13 of the two sets of image sensor units 1 sequentially turn on the light emitting elements of visible light of each color. When the light source 13 further includes one or both of a light emitting element that emits infrared light and a light emitting element that emits ultraviolet light, the light source 13 is sequentially turned on including those light emitting elements. Visible light rays or the like irradiated on the paper sheet from the light source module 17 of one image sensor unit 1 are reflected by one surface of the paper sheet S and enter the light collecting body 15 of the one image sensor unit 1. Then, an image is formed on the surface of the image sensor 161 of the one image sensor unit 1. The image sensor 161 of the one image sensor unit 1 acquires a visible light image by reflected light from one surface of the banknote by converting the formed optical image into an electric signal. Depending on the configuration of the light source 13, one or both of an infrared image and an ultraviolet image is acquired in addition to the visible light image. Similarly, the other image sensor unit 1 acquires a visible light image or the like by reflected light from the other surface of the bill. In this way, the two sets of image sensor units 1 read both sides of a bill.
After that, the paper sheet identification device 5 determines the authenticity of the banknote by comparing the genuine note banknote image prepared in advance with the visible light image of the banknote to be determined at the time of authenticity determination. This is because the bill that is a genuine note is provided with regions in which images obtained from visible light, infrared light, and ultraviolet light are different from each other. The genuine note banknote image is a banknote image obtained by irradiating a bill that is a genuine note with visible light or the like, and is stored in the paper sheet identification device 5 in advance.

  In addition, about the part which abbreviate | omitted description and illustration, the same structure as the conventional paper sheet identification device is applicable.

  According to the embodiment of the present invention, the adhesive material has the function of the adhesive, the function of the sealing material, and the function of the white reference, so that it is not necessary to arrange them separately. Accordingly, it is possible to reduce both the size in the width direction of the image sensor unit (the size in the direction of movement relative to the paper sheet) and the size of the application area of the sealing material and the white reference. In addition, the number of components and the assembly configuration can be reduced as compared with a configuration in which an adhesive, a sealing material, and a member used for white reference are separately used.

  As mentioned above, although embodiment of this invention was described with reference to drawings, this invention is not limited to these embodiment at all. The present invention can be variously modified without departing from the spirit of the invention.

  The present invention is a technique effective for an image sensor unit. And according to this invention, coexistence with size reduction of the width direction dimension of an image sensor unit and the enlargement of the application | coating area | region of a sealing material and a white reference | standard can be aimed at.

1: image sensor unit, 11: frame, 111: side wall (111a: first side wall, 111b: second side wall), 112: light source housing chamber, 113: light guide housing chamber, 114: light collector housing chamber 115: Substrate accommodation chamber, 116: junction, 12: cover member, 13: light source, 14: light guide, 141: entrance surface, 142: exit surface, 143: diffusing surface, 15: light collector, 16: Sensor substrate, 161: image sensor, 17: light source module, 2: adhesive material (2a: first adhesive material, 2b: second adhesive material), 5: paper sheet identification device, A: transport of paper sheets Path, L _O : optical axis of light collector, O: reading line, S: paper sheet

Claims (12)

An image sensor unit that is used so as to be opposed to be able to read both sides of a sheet to be read,
A light source module that emits light toward the paper sheet;
A light collector that collects light from the paper,
An image sensor for detecting the light collected by the condenser;
A frame in which the light source module, the condenser, and the image sensor are housed;
A cover member covering the frame;
Have
The cover member is bonded to the frame with an adhesive material,
An image sensor unit comprising a white portion provided at least on a part of the adhesive material so as to be positioned on an optical axis of the light collecting body of the other image sensor unit facing each other. The condenser is provided at a position biased to one side of the frame in the sub-scanning direction;
2. The image sensor unit according to claim 1, wherein the adhesive material is provided at least at an end portion of the frame farther from the light collector in the sub-scanning direction.   The size of the adhesive material in the sub-scanning direction provided at the end of the frame in the sub-scanning direction on the side far from the light collector is the light of the light collector from the outer peripheral surface of the frame near the light collector. The image sensor unit according to claim 2, wherein the image sensor unit is larger than a distance to the shaft.   The image sensor unit according to claim 1, wherein the adhesive material is provided at both ends of the frame in the sub-scanning direction.   The adhesive material provided at the end of the frame in the sub-scanning direction near the light collector is more than the adhesive material provided at the end of the frame in the sub-scanning direction far from the light collector. The image sensor unit according to claim 4, wherein the dimension in the sub-scanning direction is small. The image sensor unit according to claim 1, wherein the adhesive material is provided so that there is no gap around the entire periphery of the frame . The white portion of the adhesive material is provided so as to face one end or both ends of the light collecting body of the other image sensor unit facing each other in the main scanning direction. The image sensor unit according to any one of claims 1 to 6 . The white portion of the adhesive material is provided so as to face the entire main scanning direction of the light collecting body of the other image sensor unit facing each other. the image sensor unit according to any one of claims. The image sensor unit according to claim 1, wherein the adhesive material is a silicone resin. The image sensor unit according to claim 1, wherein the adhesive material includes a phosphor. Two sets of image sensor units according to any one of claims 1 to 10,
An image reading apparatus, wherein two sets of the image sensor units are arranged to face each other so as to be able to read both sides of a sheet.   12. The image reading apparatus according to claim 11, wherein two sets of the image sensor units have the same size in the sub-scanning direction, and the two sets of the image sensor units are arranged at the same position in the sub-scanning direction. .

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