JP2013243635A - Document scanner - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a document scanner capable of properly reading an object to be read whose position is varied in thickness direction, and decreasing size.SOLUTION: A document scanner is equipped with an image sensor module 111 including an illumination unit 300; a sensor IC 500 having a plurality of light-receiving portions arranged in a main scanning direction; and a lens unit 400 having a plurality of rod lenses 410 arranged in the main scanning direction and respectively having first end surfaces 410a and second end surfaces 410b, and forming an object 890 to be read on a sensor IC 500 by erecting equal magnification. When dimensions in thickness direction orthogonal to both of the main scanning direction and a sub scanning direction of a feeding space 800 is made to be G, arranging pitches of the plurality of light-receiving portions are made to be P, the minimum thickness of the object 890 to be read is made to be t, and opening angles on the first end surfaces 410a of the rod lenses 410 are made to be θ, an expression θ≤arctan[8 P/(G-t)] is satisfied.

Description

  The present invention relates to a document scanner.

  Document scanners that generate electronic data by reading a reading object sent in the sub-scanning direction are widely used. The document scanner disclosed in Patent Document 1 includes a feed mechanism that feeds an object to be read and an image sensor module. The feeding mechanism feeds a reading object such as printed paper in the sub-scanning direction. The image sensor module includes an illumination unit that illuminates a reading object, a sensor IC having a plurality of light receiving units arranged in a main scanning direction, and an optical unit that forms an image of light from the reading object on the plurality of light receiving units. Prepare.

  In order to read a plurality of types of reading objects having different thicknesses, it is necessary to increase the size of the feed space in which the reading objects are sent to some extent. When a reading object made of relatively thin paper is fed into such a feeding space, the position of the reading object in the thickness direction tends to vary. The optical unit has a plurality of concave mirrors and the like, and is configured as a so-called reduction optical system for the purpose of appropriately imaging light from a reading object whose position varies with the plurality of light receiving units. . By employing the optical unit configured as a reduction optical system, the optical path length from the reading object to the plurality of light receiving units can be increased. Thereby, the light from the reading object whose position varies in the thickness direction can be appropriately imaged on the plurality of light receiving units.

  However, in order to accommodate the optical unit configured as a reduction optical system, a relatively large space is required. For this reason, there has been a problem that the image sensor module, and thus the document scanner, becomes large.

JP 2011-225328 A

  The present invention has been conceived under the circumstances described above, and provides a document scanner that can appropriately read a reading object whose position varies in the thickness direction and can be downsized. The task is to do.

A document scanner provided by the present invention includes a feeding space in which a reading object is sent in the sub-scanning direction, illumination means for emitting light toward the reading object in the feeding space, and a plurality of arranged in the main scanning direction. And a plurality of rod lenses arranged in the main scanning direction, each having a first end surface and a second end surface opposite to the first end surface. The light from the reading object incident from the end face is emitted from the second end face and received by the plurality of light receiving sections, and the image on the reading object is connected to the reading means at an erecting equal magnification. An image sensor module including a lens unit for imaging, and a dimension in the thickness direction perpendicular to both the main scanning direction and the sub-scanning direction of the feeding space. G, the plurality of the array pitch of the light receiving portion P, and the minimum thickness of the reading object t, the angular aperture in the first end surface of each rod lens is taken as theta,
θ ≦ arctan [8P / (G−t)]
It is characterized by satisfying.

  In a preferred embodiment of the present invention, (P / tan θ) ≦ G−t is satisfied.

  In a preferred embodiment of the present invention, G ≧ 1 mm and θ ≦ 19 °.

  In a preferred embodiment of the present invention, G ≧ 2 mm and θ ≦ 10 °.

  In a preferred embodiment of the present invention, each of the rod lenses has a cylindrical shape and has a refractive index distribution in which the refractive index increases in the radial direction toward the central portion with respect to the peripheral portion.

  In a preferred embodiment of the present invention, each of the rod lenses has a uniform refractive index distribution from the first end surface to the second end surface.

  In another preferred embodiment of the present invention, each of the rod lenses has a non-uniform distribution of the refractive index distribution from the first end surface to the second end surface, and includes a peripheral portion, a central portion, and a center portion. The refractive index difference is larger toward the second end surface side than the first end surface side.

  In a preferred embodiment of the present invention, the illuminance distribution in the thickness direction by the illumination means has a peak at a position farther from the lens unit than a position where the MTF (Modulation Transfer Function) of the lens unit is maximum. Have.

  In a preferred embodiment of the present invention, the lens unit is provided with reflecting means for reflecting the light coming from the reading object so as to be directed in the sub-scanning direction, and the optical axis of the rod lens is sub-scanned. The posture is along the direction.

  In a preferred embodiment of the present invention, an additional illumination unit disposed on the opposite side of the illumination unit with the lens unit sandwiched in the sub-scanning direction is provided.

  In a preferred embodiment of the present invention, the image sensor module includes two image sensor modules arranged opposite to each other with the feeding space interposed therebetween, and the two image sensor modules read the front and back surfaces of the reading object.

  According to such a configuration, even if the position of the reading object in the thickness direction varies in the feeding space, the lens unit appropriately forms an image on the reading object on the plurality of light receiving units. Can be made. The lens unit as an optical system does not include, for example, a plurality of concave mirrors and is relatively compact. Therefore, it is possible to appropriately read an object to be read and to reduce the size of the document scanner.

  Other features and advantages of the present invention will become more apparent from the detailed description given below with reference to the accompanying drawings.

It is a principal part top view which shows the document scanner based on 1st Embodiment of this invention. It is a principal part front view which shows the document scanner of FIG. It is a principal part bottom view which shows the document scanner of FIG. It is principal part sectional drawing in alignment with the IV-IV line of FIG. FIG. 2 is a plan view of a principal part showing a sensor IC of the document scanner of FIG. 1. It is sectional drawing which shows the lens unit of the document scanner of FIG. It is a MTF curve of the lens unit of the document scanner of FIG. It is principal part sectional drawing which shows the document scanner based on 2nd Embodiment of this invention. It is principal part sectional drawing which shows the document scanner based on 3rd Embodiment of this invention. It is principal part sectional drawing which shows the document scanner based on 4th Embodiment of this invention. It is principal part sectional drawing which shows the document scanner based on 5th Embodiment of this invention. It is principal part sectional drawing which shows the document scanner based on 6th Embodiment of this invention. It is sectional drawing which shows the lens unit of the document scanner of FIG. It is explanatory drawing of an example of the manufacturing method of the lens unit applicable to the document scanner of FIG. It is explanatory drawing of the other example of the manufacturing method of the lens unit applicable to the document scanner of FIG.

  Hereinafter, preferred embodiments of the present invention will be specifically described with reference to the drawings.

  1 to 4 show a document scanner according to a first embodiment of the present invention. The document scanner 101 of this embodiment includes an image sensor module 111, a case 710, and a plurality of rollers 720. The document scanner 101 is a so-called sheet feed type document scanner that feeds a reading object 890 in the feed space 800 along the sub-scanning direction y and takes in a pattern and characters represented on the reading object 890 as electronic data. It is configured.

  The case 710 is made of, for example, resin or metal and accommodates the image sensor module 111. In the present embodiment, a gap between the case 710 and the image sensor module 111 is a feed space 800.

  The plurality of rollers 720 are for allowing the reading object 890 to pass through the feed space 800 along the sub-scanning direction y. One of the rollers 720 is driven by a driving source such as a motor (not shown).

  The image sensor module 111 includes a case 200, a cover glass 250, an illumination unit 300, a lens unit 400, a sensor IC 500, and a substrate 600. As an example of the dimensions of the image sensor module 111, the main scanning direction x dimension is about 235 mm, the sub scanning direction y dimension is about 12.8 mm, and the thickness direction z dimension is about 20 mm.

  The case 200 has a substantially rectangular parallelepiped shape that extends long in the main scanning direction x, and forms the outer shape of the image sensor module 111. The case 200 is made of, for example, black resin and accommodates other components of the image sensor module 111. A recess 210 is formed in the case 200. The recess 210 opens downward in the thickness direction z and extends long in the main scanning direction x. By forming the recess 210, the bending rigidity of the case 200 is enhanced.

  The cover glass 250 is made of, for example, transparent glass, and is attached to the upper end of the case 200 in the thickness direction z. A gap between the upper surface of the cover glass 250 in the thickness direction z and the case 710 serves as a feed space 800.

  The illumination unit 300 is for irradiating the reading object 890 with light that realizes reading processing, and includes an LED chip 310 and a light guide 320. The LED chip 310 is disposed near one end of the case 200 in the main scanning direction x. In the present embodiment, for example, three LED chips 310 that emit red light, green light, and blue light are employed. As the LED chip 310, one that emits light having a wavelength suitable for reading the reading object 890 may be used as appropriate. As another example, an LED chip 310 that emits blue light may be employed, and a fluorescent resin that covers the LED chip 310 may be used. White light is obtained by mixing the blue light from the LED chip 310 and the yellow light emitted when the fluorescent resin is excited by the blue light.

  The light guide 320 is for converting the light from the LED chip 310 into linear light extending in the main scanning direction x and emitting it, and is made of, for example, a transparent acrylic resin. The light guide 320 has a shape that extends long in the main scanning direction x and has a substantially rectangular cross-sectional shape. One end surface of the light guide 320 in the main scanning direction x faces the LED chip 310. This end surface is an incident surface on which light from the LED chip 310 is incident. In addition, the light guide 320 has a reflection surface 321 and an emission surface 322. The reflecting surface 321 extends in the main scanning direction x and reflects the light traveling from the incident surface toward the emitting surface 322. The reflecting surface 321 may be any surface that can appropriately reflect the light traveling from the incident surface toward the emitting surface 322. For example, the reflecting surface 321 may be a surface having a plurality of grooves, a white resin film, a metal film, or the like. The surface is provided with a reflective film. The emission surface 322 is a surface that extends long in the main scanning direction x and emits the light traveling from the reflection surface 321 toward the reading object 890 in the sending space 800.

  The sensor IC 500 has a photoelectric conversion function, and is an example of a reading unit referred to in the present invention. The sensor IC 500 extends long in the main scanning direction x and has a plurality of light receiving portions 510 as shown in FIG. The plurality of light receiving portions 510 are arranged in the main scanning direction x and are portions that perform a function of converting received light into electric charges. In the present embodiment, the plurality of light receiving portions 510 are arranged in a line at the pitch P along the main scanning direction x.

  The substrate 600 is, for example, a wiring substrate made of glass epoxy resin, or a ceramic substrate having a base material made of ceramics and a wiring pattern formed on the base material. The substrate 600 is attached to the lower end of the case 200 in the thickness direction z so as to close the recess 210. A sensor IC 500 is mounted on the substrate 600. As shown in FIGS. 2 and 3, a connector 610 is provided on the substrate 600. The connector 610 is used to electrically connect the image sensor module 111 to other components such as a control unit (not shown) and a power supply unit (not shown) of the document scanner 101.

  The lens unit 400 collects the light reflected by the reading object 890 on the plurality of light receiving units 510 of the sensor IC 500 and forms an image on the reading object 890 on the plurality of light receiving units 510. And a plurality of rod lenses 410 and a lens case 420. Each of the plurality of rod lenses 410 has a cylindrical shape extending long in the thickness direction z, and is arranged in a line along the main scanning direction x. As shown in FIG. 6A, the rod lens 410 is an optical system that condenses the light emitted from the reading center RC set in the feeding space 800 on the light receiving unit 510. In the present embodiment, the rod lens 410 causes the contents of the reading object 890 placed at the reading center RC to form an image at a plurality of light receiving units 510 at an equal magnification. As an example of the specific configuration of the rod lens 410, the rod lens 410 has a cylindrical shape having a first end surface 410a located on the reading center RC side and second end surfaces 410b located on the plurality of light receiving portions 510 side. In addition, as shown in FIG. 6B, in the radial direction, the fiber lens has a refractive index distribution in which the refractive index increases toward the center with respect to the peripheral edge. The rod lens 410 according to this embodiment has a uniform refractive index distribution from the first end surface 410a to the second end surface 410b. The rod lens 410 is made of, for example, transparent resin or glass. The half angle of view of the region where the rod lens 410 can form an image, that is, the half angle of view of the first end surface 410a of the rod lens 410 is the opening angle θ referred to in the present invention. As an example of the dimensions of the rod lens 410, the diameter is about 1.75 mm, and the length in the thickness direction z is about 8.82 mm. The distance from the reading center RC to the upper end (first end surface 410a) in the thickness direction z of the rod lens 410 and the distance from the lower end (second end surface 410b) in the thickness direction z of the rod lens 410 to the light receiving unit 510 are Both are about 4.74 mm. In this case, the distance from the light receiving unit 510 to the reading center RC is about 18.3 mm.

  FIG. 7 is an MTF (Modulation Transfer Function) curve of the rod lens 410. The horizontal axis is the distance d from the upper surface of the cover glass 250 in the thickness direction z. The position where the MTF is maximum is set as the reading center RC. In order to properly use the image reading module used in the image sensor module 111, it is one guideline to secure about 30% as the MTF. A black circle of 3 pairs / mm is an MTF curve for a test pattern in which three black-and-white lines are written per 1 mm, and a white circle of 6 pairs / mm is for a test pattern in which six black-and-white lines are written per 1 mm. It is a MTF curve. In the rod lens 410, an area where the MTF is 30% or more can be secured in the thickness direction z of about 1.2 mm in the case of 6 pairs / mm and about 2.7 mm in the case of 3 pairs / mm.

  As shown in FIG. 4, in the present embodiment, the thickness direction z dimension of the feeding space 800 is the dimension G, and the thickness of the thinnest object to be read 890 is the thickness t. The dimensions G and t, the opening angle θ, and the pitch P satisfy the relationship θ ≦ arctan [8P / (G−t)]. This is because when the reading center RC is set at the center of the feeding space 800 in the thickness direction z, so-called scattering is performed on the reading object 890 located near the upper end in the thickness direction z or the lower end in the thickness direction z. The circle is intended to be within 4 times the pitch P. For example, when the pitch P is about 42.3 μm and the thickness t, which is the minimum thickness of the reading object 890, is about 0.07 mm, the opening angle θ is about 10 ° or less in order to set the dimension G to 2 mm. In the present embodiment, the opening angle θ is about 8 °. In order to set the dimension G to 1 mm, the opening angle θ may be set to about 19 ° or less.

  In the present embodiment, the dimension G and dimension t, the opening angle θ, and the pitch P satisfy (P / tan θ) ≦ G−t. This is a condition that the scattering circle is not smaller than one pitch P.

  In FIG. 4, an alternate long and short dash line extending from the light guide 320 to the reading object 890 schematically indicates a position where the luminance distribution of the linear light emitted from the illumination unit 300 is a peak. As understood from the figure, the position at which the luminance distribution of the linear light from the illumination unit 300 is peaked on the optical axis CL of the rod lens 410 is shifted upward in the thickness direction z with respect to the reading center RC. ing.

  Next, the operation of the document scanner 101 will be described.

  According to the present embodiment, even if the position of the reading object 890 in the thickness direction z varies in the feed space 800, the lens unit 400 causes images (characters and images) on the reading object 890 to be a plurality of the sensor IC 500. An image can be appropriately formed on the light receiving unit 510. The lens unit 400 as an optical system does not include, for example, a plurality of concave mirrors and is relatively compact. Therefore, the image on the reading object 890 can be appropriately read and the document scanner 101 can be downsized.

  As a result of the inventors' research, the sensor IC 500 uses the sensor IC 500 to place the scattering circle of the rod lens 410 within four times the pitch P in the reading object 890 positioned near the upper end or the lower end in the thickness direction z of the feed space 800. It was found that the obtained electronic data can have a resolution composed of pixels arranged at a pitch P. Then, by setting the opening angle θ on the first end face 410a side of the rod lens 410 to the above-described angle, the focal depth of the rod lens 410 is deepened, and the dimension G is set to a relatively large dimension such as 1 mm or 2 mm. It has become possible. In order to realize such a large dimension G, conventionally, for example, a reduction optical system composed of a plurality of concave mirrors has been indispensable. Compared to such a configuration, the document scanner 101 can be significantly reduced in size.

  When the dimensions G and t, the aperture angle θ, and the pitch P satisfy (P / tan θ) ≦ G−t, the imaging performance of the rod lens 410 is unnecessarily enhanced. It can be avoided.

  The peak position of the luminance distribution of the illumination unit 300 is set above the reading center RC in the thickness direction z. On the other hand, the brightness of the image formed by the rod lens 410 becomes darker as the reading object 890 is farther from the rod lens 410, that is, as it is above the thickness direction z. Therefore, even if the position of the reading object 890 varies in the thickness direction z in the feed space 800, it is possible to suppress the brightness of the obtained electronic data from varying.

  8 to 13 show another embodiment of the present invention. In these drawings, the same or similar elements as those in the above embodiment are denoted by the same reference numerals as those in the above embodiment.

  FIG. 8 shows a document scanner according to the second embodiment of the present invention. The document scanner 102 of the present embodiment is different from the above-described embodiment in that the image scanner module 112 having a mirror 480 is provided.

  The mirror 480 is an example of the reflecting means in the present invention, and reflects the light traveling from the reading object 890 toward the lower side in the thickness direction z toward the right in the drawing in the sub-scanning direction y. In addition to the provision of the mirror 480, in the present embodiment, the lens unit 400 is in a posture along the sub-scanning direction y. That is, each rod lens 410 has a longitudinal direction along the sub-scanning direction y. The sensor IC 500 is disposed on the right side of the lens unit 400 in the sub-scanning direction y in the drawing. The substrate 600 is in an upright posture along the thickness direction z.

  In the case 200, the sub-scanning direction y dimension is larger than the thickness direction z dimension. The recess 210 has a larger y dimension in the sub-scanning direction than the z dimension in the thickness direction, and opens to the right in the sub-scanning direction y. In the illumination unit 300, the light guide 320 has a circular cross section. In addition, the lighting unit 300 includes a reflector 340. The reflector 340 is made of, for example, white resin, and holds the light guide 320 so as to cover a lower left portion of the light guide 320 in the drawing. The reflector 340 prevents light from leaking from the light guide 320 inappropriately.

  According to such an embodiment, it is possible to further reduce the z-direction of the image sensor module 112 and thus the document scanner 102 in the thickness direction. Further, by providing the recess 210, high rigidity can be achieved.

  FIG. 9 shows a document scanner according to a third embodiment of the present invention. The document scanner 103 according to this embodiment includes an image sensor module 113. In the image sensor module 113, the concave portion 210 in the image sensor module 112 described above is not formed in the case 200.

  According to such an embodiment, it is possible to further reduce the thickness direction z of the image sensor module 113 and thus the document scanner 103.

  FIG. 10 shows a document scanner according to a fourth embodiment of the present invention. The document scanner 104 according to this embodiment includes an image sensor module 114 having two illumination units 300 and 301.

  In the present embodiment, the two illumination units 300 and 301 are spaced apart from each other with the lens unit 400 interposed therebetween in the sub-scanning direction y. The illumination unit 301 includes an LED chip 311, a light guide 320, and a reflector 340. The LED chip 311 may emit light having the same wavelength as that of the LED chip 310. In this case, since the reading object 890 is illuminated from at least two directions, the reading object 890 can be read more clearly even if the reading object 890 has a crease that is difficult to remove. Moreover, you may employ | adopt what emits the light of a wavelength different from the LED chip 310 as the LED chip 311. FIG. For example, image data having various colors can be obtained by selecting LED chips 311 that emit visible light having different wavelengths. Or if the LED chip 311 which emits infrared light is employ | adopted, the reading object 890 to which the printing which visualizes with infrared light was given can be read appropriately.

  FIG. 11 shows a document scanner according to a fifth embodiment of the present invention. The document scanner 105 according to the present embodiment includes two image sensor modules 115. The two image sensor modules 115 have substantially the same configuration, and one reads the upper surface of the reading object 890 and the other reads the lower surface of the reading object 890. In the present embodiment, the mutual reading positions are shifted in the sub-scanning direction y. As shown in the figure, a gap between the upper end of the image sensor module 115 positioned below and the lower end of the image sensor module 115 positioned above is a feed space 800.

  According to such an embodiment, the front and back surfaces of the reading object 890 can be collectively read.

  12 and 13 show a document scanner according to a sixth embodiment of the present invention. The document scanner 106 of the present embodiment includes an image sensor module 116, and the configuration of the lens unit 400 is different from that of the document scanner 101 (FIGS. 1 to 4) according to the first embodiment.

  That is, as clearly shown in FIG. 12 and FIG. 13A, each rod lens 416 in the lens unit 400 of the present embodiment includes a first portion 411 on the first end surface 416a side and a second end surface. And a second portion 412 on the 416b side. As shown in FIGS. 13B and 13C, the refractive index distribution in the first portion 411 is, for example, the same as that of each rod lens 410 in the document scanner 101 of the first embodiment, while the second portion 412 is the same. The refractive index distribution at is set so that the refractive index difference between the peripheral edge portion in the radial direction and the central portion is larger than the refractive index distribution in the first portion 411 (such a refractive index distribution is longer in the longitudinal direction). Hereinafter, a rod lens that is non-uniform in direction is sometimes referred to as a “refractive index distribution non-uniform rod lens”). The boundary 413 (FIG. 13) between the first portion 411 and the second portion 412 is preferably set at a position where an inverted image of the image on the reading object 890 is formed. This rod lens 416 is also formed of transparent resin or glass. The point that the half angle of view at the first end surface 416a of the rod lens 416 is the opening angle θ referred to in the present invention is also the same as in the first embodiment. As an example of the dimensions of the rod lens 416, the diameter is about 1.75 mm, the length in the thickness direction z is about 6.62 mm, the length of the first portion 411 is about 4.41 mm, from the reading center RC. The distance from the thickness direction z upper end (first end surface 416a) of the rod lens 416 is about 4.74 mm, and the distance from the thickness direction z lower end (second end surface 416b) of the rod lens 416 to the light receiving unit 510 is 2. .About 375 mm. In this case, the distance from the light receiving unit 510 to the reading center RC is about 13.73 mm. As a result, the rod lens 416 has an optical characteristic until the image located at the reading center RC is inverted by the first portion 411 and has a deep focal depth, similar to the rod lens 410 in the first embodiment. Thus, the optical characteristics for further forming an inverted image on the plurality of light receiving units 510 by the second portion 412 are shallower than the first portion 411. According to the rod lens 416, the distance from the light receiving unit 510 to the reading center RC is shorter than that of the rod lens 410 of the first embodiment.

  In FIG. 12, the thickness direction z dimension G of the feed space 800 and the thickness dimension t of the thinnest object to be read 890, the opening angle θ at the first end face 416 a of each rod lens 416, and the light receiving unit 510. The point that the arrangement pitch P satisfies the relationship θ ≦ arctan [8P / (G−t)] is also the same as in the first embodiment.

  In the document scanner 106 according to this embodiment, the distance from the first end face 416a to the reading center RC is secured to maintain a deep focal depth, but the distance from the light receiving unit 510 to the reading center RC is shortened. A lens unit 400 including a uniform rod lens 416 is employed. As a result, the document scanner 106 according to the present embodiment further reduces the z dimension in the thickness direction of the case 200 in addition to the operation described above with respect to the document scanner 101 according to the first embodiment. Miniaturization can be achieved.

  In addition, the lens unit 400 using the refractive index distribution non-uniform rod lens 416 applicable to the document scanner 106 of the sixth embodiment can be produced as follows, for example.

The first method is a method of changing the ion exchange concentration by dividing the section in the longitudinal direction of the resin base material rod in the method by ion exchange treatment. That is, the formation of the refractive index profile of the rod lens is performed by an ion exchange process in which the base material rod 410 ′ is immersed in a high-temperature molten salt. At that time, as shown in FIG. 14, the unit rod lens section L of a predetermined length in the base material rod 410 ′ is further divided into a _first section l ₁ and a second section l ₂ , and the first section l ₁ is divided. Compared to the ion exchange concentration of the molten salt to be immersed, the ion exchange concentration of the molten salt to be immersed in the second section l ₂ is increased. Thus, the refractive index difference between the radial peripheral edge and the central portion in the second section l ₂ becomes larger than the refractive index difference between the radial peripheral edge and the central section in the first section l ₁ . The plurality of base material rods 410 'thus obtained are juxtaposed and inserted into a case material (not shown), and the case material is cut for each unit rod lens section L of the base material rod 410'. Get.

  In the second method, the first portion 411 and the second portion 412 are separately formed, and the first portion 411 and the second portion 412 are arranged in the longitudinal direction and are accommodated and held in the lens case 420. It is. That is, a plurality of first rod lenses 411a having a predetermined refractive index distribution that is uniform in the longitudinal direction, and a refraction of a peripheral portion and a central portion that are uniform in the longitudinal direction in the radial direction than the first rod lens 411a. A plurality of second rod lenses 412a having a refractive index distribution with a large rate difference are prepared. Next, as shown in FIGS. 14A and 14B, the first rod lens 411a and the second rod lens 412a are accommodated in the lens case 420 so as to be arranged in the longitudinal direction. In this example, a diameter difference is provided between the first rod lens 411a and the second rod lens 412a, and the groove width of the lens housing groove in the case 420 is also the same as the portion 421 that houses the first rod lens 411a and the second rod lens 411a. The portion 422 that accommodates the rod lens 412a is provided with a difference corresponding to the difference in diameter between the rod lenses 411a and 412a. Further, the lens case 420 is assembled by combining the half-divided members. By doing so, the position of the inner end of the lens case 420 of the second rod lens 412a can be defined, and as a result, the boundary position between the first rod lens 411a and the second rod lens 412a is aligned. There are advantages that can be made. This method can be applied to both the case where the rod lens 416 is formed of resin and the case where it is formed of glass.

  The document scanner according to the present invention is not limited to the above-described embodiment. The specific configuration of each part of the document scanner according to the present invention can be modified in various ways.

  In the document scanner 106 of the sixth embodiment, the lens unit 400 using the refractive index distribution non-uniform rod lens 416 is applied. However, such a lens using the refractive index distribution non-uniform rod lens 416 is used. The unit 400 can also be applied to the document scanners 102 to 105 of the second to fifth embodiments to further reduce their size.

  Further, the refractive index distribution non-uniform rod lens 416 in the document scanner 106 of the sixth embodiment includes a first portion 411 on the first end surface 416a side and a second portion 412 on the second end surface 416b side. The first portion 411 and the second portion 412 each have a predetermined refractive index distribution that is uniform in the longitudinal direction. However, the second portion 412 from the first end face 416a side The refractive index distribution may be formed stepwise or gradually so that the difference in refractive index between the radial peripheral portion and the central portion increases toward the end surface 416b side. As described above, the rod lens whose refractive index difference increases gradually as described above is a method using an ion exchange treatment, in which a resin base rod immersed vertically in a molten salt having a predetermined ion exchange concentration is used for a certain period of time. It can be created by a method of pulling up a predetermined dimension every time. According to such a method, the lower part of the base material rod, the longer the time of immersion in the molten salt, and the greater the difference in refractive index. Further, a rod lens whose refractive index distribution gradually increases as described above is obtained by using a resin base rod immersed vertically in a molten salt having a predetermined ion exchange concentration in a method using an ion exchange treatment at a constant speed. It can be created by a method such as pulling up. Even by such a method, the time of being immersed in the molten salt becomes longer as the base material rod is located below, and the refractive index difference is increased.

  The dimension G means the size of the gap described above when the shape or the like of the feed space 800 is unchanged in the thickness direction z. Further, in a configuration in which a pressing mechanism that presses the reading object 890 with an elastic force in the thickness direction z is employed, the size of the gap when the pressing mechanism is in a state where the feeding space 800 is minimized is expressed as a dimension G. Can be treated as

x Main scanning direction y Sub scanning direction z Thickness direction 101-106 Document scanner 111-116 Image sensor module 200 Case 250 Cover glass 300, 301 Illumination unit (illumination means)
310, 311 LED chip 320 Light guide 321 Reflecting surface 322 Output surface 340 Reflector 400 Lens unit 410, 416 Rod lens 410a, 416a First end surface 410b, 416b (for rod lens) Second end surface 420 (for rod lens) Lens case 480 Mirror (reflection means)
500 Sensor IC (reading means)
510 Light-Receiving Unit 600 Substrate 610 Connector 710 Case 720 Roller 800 Feeding Space 890 Reading Object

Claims (11)

A feed space in which the reading object is sent in the sub-scanning direction;
Illumination means for emitting light toward the reading object in the feed space, reading means having a plurality of light receiving portions arranged in the main scanning direction, and arrayed in the main scanning direction, each of which is a first end face and the A plurality of rod lenses having a second end surface opposite to the first end surface, and the light from the reading object incident from the first end surface is emitted from the second end surface to An image sensor module including a lens unit that receives light at a plurality of light receiving units and forms an image on the reading object on the reading unit at an equal magnification upright,
The dimension in the thickness direction perpendicular to both the main scanning direction and the sub-scanning direction of the feed space is G, the arrangement pitch of the plurality of light receiving parts is P, the minimum thickness of the reading object is t, When the opening angle at the first end face of each rod lens is θ,
θ ≦ arctan [8P / (G−t)]
Document scanner characterized by satisfying.   The document scanner according to claim 1, wherein (P / tan θ) ≦ G−t is satisfied.   The document scanner according to claim 1, wherein G ≧ 1 mm and θ ≦ 19 °.   The document scanner according to claim 1, wherein G ≧ 2 mm and θ ≦ 10 °.   5. The rod lens according to claim 1, wherein each of the rod lenses has a cylindrical shape and has a refractive index distribution in which a refractive index increases toward a central portion with respect to a peripheral portion in a radial direction. Document scanner.   The document scanner according to claim 5, wherein each of the rod lenses has a uniform refractive index distribution from the first end surface to the second end surface.   Each of the rod lenses has a non-uniform refractive index distribution from the first end surface to the second end surface, and a difference in refractive index between a peripheral portion and a central portion is on the first end surface side. The document scanner according to claim 5, wherein the second end face side is larger than the second scanner.   The illuminance distribution in the thickness direction by the illumination means has a peak at a position farther from the lens unit than a position where the MTF (Modulation Transfer Function) of the lens unit is maximum. Document scanner described in. Reflecting means for directing in the sub-scanning direction by reflecting the light coming from the reading object,
9. The document scanner according to claim 1, wherein the lens unit has a posture in which an optical axis of the rod lens is along a sub-scanning direction. 10.   9. The document scanner according to claim 1, further comprising an additional illumination unit disposed on a side opposite to the illumination unit across the lens unit in the sub-scanning direction. Two image sensor modules arranged opposite to each other across the feeding space,
The document scanner according to claim 1, wherein the two image sensor modules read the front and back surfaces of the reading object.

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