JP2016092566A - Contact image sensor module - Google Patents

Abstract

PROBLEM TO BE SOLVED: To solve such a problem that since a part, where the optical axis of a lens unit intersects the upper surface of a glass, is not irradiated with the light emitted from a light guide, variation of illuminance increases.SOLUTION: A contact image sensor module includes a light guide 4 for guiding light to a document, a lens unit 3 forming an erect unmagnified image by condensing the reflection light from a document, and a frame 2 for supporting the light guide 4 and lens unit 3. A groove A for housing the light guide 4, and a pressing portion 201 having a shape projecting from a corner 214 of the sidewall 210, and arranged on the opposite side from the groove A across the light guide 4, so as to extend in the longitudinal direction X, are formed in the frame 2. The pressing portion 201 is deflection deformable, and has a tip 202 pressing the side face of the light guide 4.SELECTED DRAWING: Figure 2

Description

  The present invention relates to a contact image sensor module.

  Conventionally, a contact image sensor module (hereinafter abbreviated as “CIS module”) is used in image scanners, facsimiles, copiers, financial terminal devices, and the like. The CIS module includes an illuminating unit that illuminates an object to be read, an imaging optical element that forms an erecting equal-magnification image of the object to be read, and an erecting equal-magnification image formed by the imaging optical element. The reflected light from the object to be read illuminated by the illumination means is collected by each lens provided in the lens unit, and an erecting equal-magnification image is formed on the sensor.

  For example, in the CIS module 800 of FIG. 15A disclosed in Patent Document 1, a light guide 801 that is a rod-shaped light guide that guides light from a light source to an object to be read is used as an imaging optical element. The lens unit 802 is arranged in parallel. The frame 803 is formed with slopes 804a and 804b constituting a groove portion 804 extending in the longitudinal direction X. The light guide 801 is in contact with the slope 804a on the reflective surface 801b side, and the light guide 801 is located on the light guide 801 side of the pressing portion 805. It is provided in a state sandwiched between the surfaces 805a and 805b and the inclined surface 804b.

  FIG. 15B is a diagram seen from the longitudinal direction X and is a schematic diagram showing a state in which light emitted from the light guide 801 is irradiated. Light (solid arrow) emitted from the emission surface 801a of the light guide 801 is irradiated to a portion 808 where the optical axis 809 of the lens unit 802 and the upper surface 807a of the glass 807 on which the object 810 to be read is placed intersects. The reflected light reflected by the object to be read 810 is condensed by each lens of the lens unit 802 and an erecting equal-magnification image is formed on the sensor 806.

  In order to irradiate the portion 808 where the optical axis 809 and the upper surface 807a of the glass 807 intersect, the outer peripheral surface of the light guide 801 in FIG. 15A is the entire surface of the inclined surfaces 804a and 804b of the groove portion 804. The position of the light guide 801 is determined. Therefore, it is desirable that the light guide 801 is arranged so that there is no gap between the outer peripheral surface of the light guide 801 and the slopes 804a and 804b of the groove 804.

JP 2013-219450 A

  However, the processing accuracy when forming the surfaces 805a and 805b of the pressing portion 805, that is, the flatness of the surfaces 805a and 805b, the inclination angle, the dimensional accuracy at the distance between the surfaces 805a and 805b and the inclined surface 804b of the groove 804, etc. Variations may occur. For this reason, since the outer peripheral surface of the light guide 801 cannot contact the entire surface of the inclined surfaces 804a and 804b of the groove portion 804, the position of the light guide 801 cannot be determined. Therefore, the light (broken arrow) emitted from the emission surface 801a of the light guide 801 in FIG. 15B is not irradiated to the portion 808 where the optical axis 809 of the lens unit 802 and the upper surface 807a of the glass 807 intersect. There is a problem that variation in illuminance increases.

  SUMMARY An advantage of some aspects of the invention is to solve at least a part of the problems described above, and the invention can be implemented as the following forms or application examples.

  Application Example 1 A light guide that has a light emitting surface that emits light from a light source and a reflective surface that faces the light emitting surface and extends in the longitudinal direction, and that guides light to an object to be read, and the light guide And an imaging optical element that collects reflected light from the object to be read to form an erecting equal-magnification image on the sensor, and supports the light guide and the imaging optical element A first surface that contacts the bottom surface of the light guide on the reflective surface side, and a second surface that contacts a side surface of the light guide that intersects the bottom surface. And having a shape projecting from the wall portion of the frame, and sandwiching the light guide between the groove portion and opposite to the groove portion And an extending portion extending in the longitudinal direction is formed, and the extending portion is provided so as to be able to bend and deform, There contact image sensor module, characterized in that for pressing the opposite side to the side surface of the light guide.

  According to this application example, the extending portion is provided so as to be able to bend and deform, and the tip portion presses the side surface opposite to the side surface of the light guide. As a result, the bottom surface and the first surface of the light guide and the side surface and the second surface of the light guide abut over the entire surface, and the positions of the light guides are the first surface and the second surface. It is decided by. Therefore, the light emitted from the light guide is accurately irradiated to the portion where the optical axis of the imaging optical element and the upper surface of the transparent member on which the object to be read is placed, and the variation in illuminance is reduced. .

  [Application Example 2] A protruding portion that protrudes toward the light guide is formed at the distal end of the extending portion, and the protruding portion presses the opposite side surface of the light guide. The contact image sensor module.

  According to this application example, the portion in contact with the side surface of the light guide can be made smaller than the entire surface of the extending portion on the light guide side. Thereby, the influence of the processing precision at the time of forming the extension part can be made small.

  Application Example 3 The contact image sensor module according to claim 1, wherein a recess extending in a longitudinal direction is formed on the opposite side of the extension portion from the distal end portion on the side opposite to the light guide.

  According to this application example, the range in which the extending portion bends and deforms widens. Thereby, the pressing force which presses a light guide with an extension part is stabilized, and a light guide can be stored in the slot of a frame. Therefore, the bottom surface and the first surface of the light guide and the side surface and the second surface of the light guide are in contact with each other, and the position of the light guide is determined by the first surface and the second surface. It is decided.

  Application Example 4 A through hole is provided on the groove portion side from a portion of the frame where the extended portion is fixed, and the length of the extended portion is shorter than the length of the through hole in the longitudinal direction. The contact image sensor module according to claim 1, wherein the extending portion is disposed at a central portion of the through hole.

  According to this application example, portions that can be twisted and deformed are formed on both sides of the extending portion in the longitudinal direction. Thereby, the pressing force which presses the light guide by the extending portion can be further stabilized, and the light guide can be accommodated in the groove portion of the frame.

  [Application Example 5] The thickness in the width direction of the portion of the frame where the extending portion is fixed is shorter than the thickness in the width direction of the portions on both sides of the frame in which the through holes are formed. The contact image sensor module as described above.

  According to this application example, the torsional deformation of the portion of the frame where the extension is fixed is further increased. Thereby, the pressing force which presses the light guide by the extending portion can be further stabilized, and the light guide can be accommodated in the groove portion of the frame.

  Application Example 6 includes a frame, a first optical member fixed to the frame, and a second optical member that is in contact with a side surface of the first optical member and supported by the frame, The frame has a first surface in contact with the second optical member and a shape protruding from a wall portion of the frame, and is opposite to the first optical member across the second optical member. And an extension part extending in the longitudinal direction is formed, the extension part is provided so as to be able to be bent and deformed, and a tip part is opposite to the first optical member of the second optical member A contact image sensor module characterized by pressing the side surface of the side.

  According to this application example, the extending portion is provided so as to be able to bend and deform, and the tip portion presses the side surface of the second optical member opposite to the first optical member. Thus, the second optical member abuts over the entire first surface of the frame and the side surface of the first optical member, and the position of the second optical member is the same as that of the first surface of the frame. It is determined by the side surface of one optical member.

  Application Example 7 The first optical member is an imaging optical element that extends in the longitudinal direction and collects reflected light from the object to be read to form an erect life-size image on the sensor. The second optical member is a light guide that has an emission surface that emits light from the light source and a reflection surface that faces the emission surface, and that guides light to the object to be read. A contact image sensor module as described above.

  According to this application example, the light emitted from the light guide is accurately irradiated to the portion where the optical axis of the imaging optical element intersects the upper surface of the transparent member on which the object to be read is placed, and the illuminance The variation of is reduced.

The perspective view of a CIS module. The perspective view of one edge part side in the longitudinal direction of a CIS module. The perspective view which shows the part of the frame of the state which removed the lens unit, the light guide, and the printed circuit board. The perspective view which shows the part of the CIS module seen from the side wall side in which the through-hole was formed. (A) is sectional drawing of a CIS module, (b) is sectional drawing which shows the part of the light guide with which the groove part was equipped. Sectional drawing of a CIS module and a glass member. The perspective view of the one end part side in the longitudinal direction of the CIS module in Embodiment 2. FIG. (A) is sectional drawing of a CIS module, (b) is sectional drawing of the part by which the light guide was provided in the groove part. Sectional drawing which shows the shape of another pressing part. Sectional drawing of the CIS module in Embodiment 3. FIG. (A) is a perspective view which shows the LED board fixed to the flame | frame, (b) is the perspective view which looked at the LED board from the side with which the LED part was equipped. (A) is a perspective view which shows the part by which the LED board was fixed to the flame | frame with the fixing member, (b) is a perspective view which shows the state which removed the fixing member from the flame | frame. The perspective view which shows the state which pulled out the fixing member above the flame | frame. (A) is a perspective view which shows the LED board fixed to the flame | frame by the protrusion part, (b) is a perspective view which shows the state which removed the LED board from the flame | frame. (A) is a perspective view which shows the part by which the light guide was provided in the conventional flame | frame, (b) is a schematic diagram which shows a mode that the light radiate | emitted from the conventional light guide is irradiated.

(Embodiment 1)
An embodiment of a contact image sensor module (hereinafter referred to as a CIS module) of the present invention will be described with reference to the drawings. FIG. 1 is a perspective view of the CIS module 1. The CIS module 1 may be provided in a state of being fixed with respect to the transparent member GL such as glass indicated by a broken line, or may be provided in a state of being movable in the width direction Y. When the CIS module 1 is fixed, an image of a document (read object) conveyed in the width direction Y along the upper surface (the upper surface in the drawing) in the height direction Z of the transparent member GL is read. When the CIS module 1 is movably provided, the image of the document placed on the upper surface of the transparent member GL is read while moving.

  The CIS module 1 has a frame 2 extending in the longitudinal direction X. In the frame 2, a light guide 4 as a light guide, a lens unit 3 as an imaging optical element, and a sensor (not shown) are arranged. A printed circuit board 6 is provided extending in the longitudinal direction X. The lens unit 3 is juxtaposed with the light guide 4. An LED substrate 8 indicated by a broken line is provided at one end portion in the longitudinal direction X of the frame 2, and an LED portion 5 as a light source is provided on the light guide 4 side of the LED substrate 8.

  The positions of the LED portion 5 in the width direction Y and the height direction Z are arranged at the positions of the end portions in the longitudinal direction X of the light guide 4. The light emitted from the LED unit 5 enters the light guide 4 from the end of the light guide 4 and is emitted toward the document on the transparent member GL. The reflected light reflected from the original on the transparent member GL is collected by the lens unit 3 to form an erecting equal-magnification image on the sensor. The sensor outputs a signal corresponding to the erect life-size image.

  FIG. 2 is a perspective view of one end side in the longitudinal direction X of the CIS module 1. The light guide 4 includes a transparent member 41 such as a resin molded product and a light shielding film 42. The light shielding film 42 covers the light guide 4 in a state of being in close contact with the reflecting surface 41b and the side surfaces except for the end surface on the side where the emitting surface 41a and the LED unit 5 are provided.

  The frame 2 is provided with an intermediate wall portion 213 extending in the width direction Y and dividing the frame 2 in the height direction Z. One side of the intermediate wall 213 in the height direction Z is provided with the printed circuit board 6, and the other is provided with the light guide 4 and the lens unit 3.

  A side wall 210 erected with respect to the intermediate wall 213 is formed at the right end of the frame 2 in the width direction Y in the drawing. In the central portion of the frame 2 in the width direction Y, standing wall portions 211 and 212 that stand on the opposite side of the printed circuit board 6 with respect to the intermediate wall portion 213 are formed.

  FIG. 3 is a perspective view showing a portion of the frame 2 in a state where the light guide 4, the lens unit 3, and the printed circuit board 6 are removed from the CIS module 1 of FIG. A groove portion A extending in the longitudinal direction X is formed between the side wall 210 and the standing wall portion 211. The groove part A includes a slope 216 formed on the side wall 210 and a slope 217 formed on the standing wall part 211, and a cross-sectional shape viewed from the longitudinal direction X is formed in a V shape.

  Between the standing wall portion 211 and the standing wall portion 212, a groove portion B is formed that extends in the longitudinal direction X and has a rectangular cross-sectional shape when viewed from the longitudinal direction X. As shown in FIG. 2, the reflective surface 41 b side of the light guide 4 is accommodated in the groove portion A, and the intermediate wall portion 213 side of the lens unit 3 is accommodated in the groove portion B.

  The pressing part 201 protrudes from the corner part 214 of the side wall 210 at a position opposite to the groove part A across the light guide 4 and extends in the longitudinal direction X. As shown in FIG. 1, a plurality of pressing portions 201 are formed side by side in the longitudinal direction X.

  FIG. 4 is a perspective view showing a portion of the CIS module 1 viewed from the side wall 210 side where the through hole 215 is formed. A through hole 215 that penetrates the side wall 210 is formed in the side wall 210. As shown in FIG. 1, a plurality of through holes 215 are formed in the side wall 210 side by side in the longitudinal direction X so as to correspond to the pressing portion 201.

  The through hole 215 is a portion where a slide (not shown) is arranged when the pressing part 201 and the slope 217 of FIG. 3 are molded using an upper mold (not shown) and a lower mold (not shown). In the longitudinal direction X of FIG. 4, the length L <b> 1 of the pressing portion 201 is the same as the length L <b> 2 of the through hole 215.

  One inclined surface 217 constituting the V-shaped groove portion A of FIG. 3 is formed continuously with the standing wall portion 211 in the longitudinal direction X. On the other hand, the other inclined surface 216 constituting the V-shaped groove portion A is formed in the longitudinal direction X with a plurality of through holes 215 arranged therebetween.

  FIG. 5A is a cross-sectional view of the CIS module 1 viewed from the longitudinal direction X at the cross-sectional position CC ′ of FIG. A side surface 4d on the light exit surface 41a side of the light guide 4 is provided with a slight gap from the lens unit 3. A light scattering surface that scatters light is formed on the side of the light shielding film 42 that contacts the transparent member 41, and the light emitted from the LED unit 5 in FIG. 1 is the longitudinal direction of the transparent member 41 in FIG. The light enters the end of X, scatters in the transparent member 41, and exits from the exit surface 41a.

  Reflected light from the document is collected by the lens unit 3, passes through a slit 218 provided in the frame 2, and forms an image on a sensor 7 disposed on the printed circuit board 6. As shown in FIG. 3, the slit 218 is formed to extend in the longitudinal direction X.

  The surface shape of the slope 216 in FIG. 5A is formed to be substantially the same as the surface shape of the reflective surface 41 b of the transparent member 41. The surface shape of the inclined surface 217 is formed to be substantially the same as the surface shape of the transparent member 41 on the inclined surface 217 side.

  A concave portion 204 extends in the longitudinal direction X on the surface of the pressing portion 201 opposite to the light guide 4. The concave portion 204 is connected to the surface 204a extending in the direction perpendicular to the upper end surface 214a of the corner portion 214 toward the through-hole 215, the curved surface 204b connected to the surface 204a and recessed, and connected to the curved surface 204b to the inner side in the width direction Y. And has an upper end surface 204c extending in the direction.

  A tip portion 202 of the pressing portion 201 opposite to the corner portion 214 is provided with a protruding portion 203 that protrudes from the lower end surface 204d opposite to the upper end surface 204c of the pressing portion 201 to the light guide 4 side and extends in the longitudinal direction X. . A flat portion 203 a extending in the longitudinal direction X is formed on the protruding portion 203. The flat surface portion 203 a comes into contact with the side surface 4 c of the light guide 4 covered with the light shielding film 42.

  FIG. 5B is a cross-sectional view of a portion where the light guide 4 of FIG. 5A is provided in the groove A (see FIG. 3). A pressing portion 201 indicated by a solid line indicates a state where the light guide 4 is provided in the groove portion A, and a pressing portion 201 indicated by a broken line indicates a state where the light guide 4 is not provided in the groove portion A.

  The amount of interference K1 is the position of the flat surface portion 203a (shown by a broken line) in a state where the light guide 4 is not provided in the groove portion A and the flat surface abutting on the side surface 4c in the state where the light guide 4 is provided in the groove portion A. This is the distance from the position of the portion 203a (shown by a solid line).

  The position of the flat surface portion 203a in a state where the light guide 4 is not provided in the groove portion A is closer to the inclined surface 217 side by the interference amount K1 than the position of the flat surface portion 203a in the state where the light guide 4 is provided in the groove portion A. .

  As indicated by the solid line and the broken line of the pressing part 201, one end side of the pressing part 201 is fixed to the corner part 214 of the frame 2, and the tip part 202 side of the pressing part 201 is provided so as to be deformable. In a state where the light guide 4 is provided in the groove portion A, the flat portion 203a of the pressing portion 201 presses the side surface 4c of the light guide 4 because the pressing portion 201 is bent and deformed by the interference amount K1.

  Accordingly, the bottom surface 4a on the slope 216 side (reflection surface 41b side) of the light guide 4 and the side surface 4b on the slope 217 side of the light guide 4 press the slopes 216 and 217, respectively. Therefore, the bottom surface 4a and the side surface 4b can contact the inclined surfaces 216 and 217 with no gap.

  FIG. 6 is a cross-sectional view of the CIS module 1 and the transparent member GL viewed from the longitudinal direction X. The light emitted from the emission surface 41 a of the light guide 4 is applied to the intersection F between the upper surface GLa of the transparent member GL and the optical axis S of the lens unit 3. The light irradiated to the intersection point F is reflected by the original M, passes through the lens unit 3 along the optical axis S, and forms an erecting equal-magnification image on the sensor 7 disposed on the printed circuit board 6.

  When the light guide 4 is provided in the frame 2 of FIG. 3, the end of the light guide 4 in the longitudinal direction X so as to expand between the pressing portion 201 and the groove portion A at one end in the longitudinal direction X of the frame 2. The light guide 4 is slid along the groove A to the other end in the longitudinal direction X of the frame 2 and inserted.

  As described above, the CIS module 1 of FIG. 1 described in the present embodiment includes the emission surface 41a of FIG. 6 that emits light of the LED unit 5 as a light source, which extends in the longitudinal direction X, and the reflection surface 41b that faces the emission surface 41a. And a light guide 4 as a light guide that guides light to a document M as an object to be read, and a light guide 4, and the reflected light from the document M is collected on the sensor 7. A lens unit 3 as an imaging optical element that forms an erecting equal-magnification image, and a frame 2 that supports the light guide 4 and the lens unit 3 are provided.

  The frame 2 in FIG. 5A is in contact with a slope 216 as a first surface that contacts the bottom surface 4a on the reflecting surface 41b side of the light guide 4 and a side surface 4b that intersects the bottom surface 4a of the light guide 4. A slope 217 as a second surface, a groove portion A (see FIG. 2) that accommodates the reflective surface 41b side of the light guide 4, and a shape protruding from a corner portion 214 of the side wall 210 of the frame 2, A pressing portion 201 is formed as an extending portion that is disposed on the opposite side of the groove portion A with the light guide 4 interposed between the groove portion A and extends in the longitudinal direction X. The pressing portion 201 is provided so as to be able to bend and deform, and the tip portion 202 presses the side surface 4 c opposite to the side surface 4 b of the light guide 4.

  According to this configuration, it is possible to reduce the influence of processing accuracy when forming the pressing portion 201. Therefore, the bottom surface 4a and the inclined surface 216 of the light guide 4 and the side surface 4b and the inclined surface 217 of the light guide 4 abut over the entire surface, and the position of the light guide 4 is determined by the inclined surfaces 216 and 217. Accordingly, the light emitted from the light exit surface 41a of the light guide 4 in FIG. 6 is applied to the portion F where the optical axis S of the lens unit 3 and the upper surface GLa of the transparent member GL on which the document M is placed intersect. The variation in illuminance is reduced.

  In addition, a protruding portion 203 that protrudes toward the light guide 4 is formed at the tip end portion 202 of the pressing portion 201 in FIG. Press.

  According to this configuration, it is possible to make the portion that contacts the side surface 4c of the light guide 4 smaller than the entire surface of the pressing portion 201 on the light guide 4 side. Thereby, the influence of the processing precision at the time of forming the holding | suppressing part 201 can be made small.

  Further, a concave portion 204 extending in the longitudinal direction X is formed on the side of the side wall 210 opposite to the light guide 4 in the holding portion 201 (on the side opposite to the tip portion 202).

  According to this configuration, the design interference amount K1 due to the bending deformation of the pressing portion 201 in FIG. Thereby, even if the actual interference amount K1 varies due to the influence of processing accuracy, the pressing force pressing the light guide 4 by the pressing portion 201 can be stabilized, and the light guide 4 can be accommodated in the groove portion A of the frame 2. Therefore, the bottom surface 4a and the inclined surface 216 of the light guide 4 and the side surface 4b and the inclined surface 217 of the light guide 4 abut over the entire surface, and the position of the light guide 4 is determined by the inclined surfaces 216 and 217.

(Embodiment 2)
In Embodiment 1, as shown in FIG. 4, in the longitudinal direction X, the length L1 of the pressing portion 201 is the same as the length L2 of the through-hole 215 provided in the side wall 210. Now, a CIS module in which the length of the pressing portion is shorter than the length of the through hole provided in the side wall will be described.

  FIG. 7 is a perspective view of one end side in the longitudinal direction X of the CIS module 1a according to the second embodiment. A side wall 220 is formed at the right end in the width direction Y of the frame 2a of the CIS module 1a. A plurality of through holes 221 penetrating the side wall 220 are formed in the side wall 220 in the longitudinal direction X.

  The upper side wall portion 222 is a part of the side wall 220 and constitutes the upper side in the height direction Z of each through hole 221. A pressing portion 225 that protrudes inward in the width direction Y is fixed to the upper side wall portion 222. The pressing portion 225 is formed side by side in the longitudinal direction X so as to correspond to the plurality of through holes 221.

  In the longitudinal direction X, the length L3 of the pressing portion 225 is shorter than the length L4 of the through hole 221. The position of the pressing portion 225 in the longitudinal direction X is disposed at the central portion of the through hole 221.

  The wall portion 223 constitutes a part of the side wall 220 and is formed on both sides in the longitudinal direction X of the through hole 221. A stepped portion 224 is formed at a connection portion between the wall portion 223 and the upper side wall portion 222. That is, the thickness L5 in the width direction Y of the upper side wall portion 222 is thinner than the thickness L6 in the width direction Y of the wall portion 223.

  FIG. 8A is a cross-sectional view of the CIS module 1a viewed from the longitudinal direction X. FIG. A protruding portion 227 that protrudes toward the light guide 4 is formed at the distal end portion 226 of the pressing portion 225. A planar portion 227 a extending in the longitudinal direction X is formed on the protruding portion 227. The flat surface portion 227 a comes into contact with the side surface 4 c of the light guide 4.

  FIG. 8B is a cross-sectional view of a portion in which the light guide 4 of FIG. 8A is provided in the groove A (see FIG. 7). A pressing portion 225 indicated by a solid line indicates a state where the light guide 4 is provided in the groove portion A, and a pressing portion 225 indicated by a broken line indicates a state where the light guide 4 is not provided in the groove portion A.

  The amount of interference K2 is the plane abutting on the position of the flat surface portion 227a (shown by a broken line) when the light guide 4 is not provided in the groove portion A and the side surface 4c when the light guide 4 is provided on the groove portion A. This is the distance from the position of the part 227a (shown by a solid line). The position of the flat surface portion 227a in a state where the light guide 4 is not provided in the groove portion A is closer to the inclined surface 217 side by the interference amount K2 than the position of the flat surface portion 227a in the state where the light guide 4 is provided in the groove portion A. .

  In the CIS module 1a of the present embodiment, a through hole 221 is provided on the side of the groove A from the upper side wall portion 222 where the holding portion 225 of the side wall 220 of the frame 2a is fixed. The length L3 of 225 is formed shorter than the length L4 of the through hole 221, and the pressing portion 225 is disposed at the center of the through hole 221.

  According to this structure, the wall part 222a is formed in the upper side wall part 222 as a part which can be twisted and deformed on both sides in the longitudinal direction X of the part to which the pressing part 225 is connected. That is, the center portion of the upper wall portion 222 to which the pressing portion 225 is fixed is opposite to the both ends in the longitudinal direction X of the upper wall portion 222 fixed to the wall portion 223 in the direction D with the longitudinal direction X as the axis direction. Torsional deformation is possible. Thereby, the design interference amount K2 of FIG. 8B of the present embodiment is further increased by the amount generated by the torsional deformation of the upper side wall portion 222 to the amount generated by the bending deformation of the pressing portion 225.

  Therefore, the amount of interference K2 in FIG. 8B of the present embodiment is larger than the amount of interference K1 of FIG. That is, the pressing force for pressing the light guide 4 by the pressing portion 225 can be further stabilized, and the light guide 4 can be accommodated in the groove portion A of the frame 2a.

  Further, the thickness L5 of the upper side wall 222 in the width direction Y is shorter than the thickness L6 of the wall 223 in the width direction Y. According to this configuration, the torsional deformation in the upper wall portion 222 is further increased. Thereby, the pressing force which presses the light guide 4 by the pressing portion 225 can be further increased, and the light guide 4 can be accommodated in the groove portion A of the frame 2a. Other configurations of the present embodiment are the same as those described in the first embodiment.

  In the first and second embodiments, the protrusions 203 and 227 that protrude toward the light guide 4 are formed at the tip portions 202 and 226 of the pressing portions 201 and 225. However, even if the protruding portion is not formed at the tip portion 231 of the pressing portion 230. Good. The flat portion 231 a formed at the tip portion 231 in FIG. 9A is formed in the same shape as the shape of the side surface 4 c of the light guide 4, and the flat portion 231 a presses the side surface 4 c of the light guide 4.

  In the first and second embodiments, the side surface 4c of the light guide 4 is pressed by the flat portions 203a and 227a formed on the protruding portions 203 and 227 at the tip portions 202 and 226 of the pressing portions 201 and 225. FIG. As shown in b), the side surface 4c of the light guide 4 may be pressed by the curved surface 241a formed at the tip 241 of the pressing portion 240.

(Embodiment 3)
In the first and second embodiments, the position of the light guide 4 is determined by bringing the light guide 4 into contact with the slopes 216 and 217 of the groove A of the frames 2 and 2a. However, in the third embodiment, the light guide 4 is a lens unit. A configuration for determining the position of the light guide 4 by abutting on the lens 3 will be described.

  FIG. 10 is a cross-sectional view of the CIS module 1b as viewed from the longitudinal direction X in the third embodiment. The lens unit 3 is provided on an upper portion of the intermediate wall portion 213, and is fitted between a standing wall portion 211a and a standing wall portion 212 that are provided on the opposite side of the printed circuit board 6 from the intermediate wall portion 213. It is fixed in the state.

  The bottom surface 4 a of the light guide 4 abuts on the slope 216 of the frame 2 b, and the side surface 4 d of the light guide 4 abuts on the side surface 3 a of the lens unit 3. A gap G is provided between the slope 217a of the standing wall 211a and the side surface 4b of the light guide 4, and the side surface 4b of the light guide 4 is not in contact with the slope 217a.

  The CIS module 1b of the present embodiment includes a frame 2b, a lens unit 3 as a first optical member fixed to the frame 2b, and a second surface supported by the frame 2b in contact with the side surface 3a of the lens unit 3. A light guide 4 as an optical member.

  The frame 2b has a slope 216 as a first surface that comes into contact with the bottom surface 4a of the light guide 4 and a shape protruding from the side wall 210 of the frame 2b, on the opposite side of the lens unit 3 with the light guide 4 interposed therebetween. The holding part 201 as an extending part that is disposed and extends in the longitudinal direction X is formed. The pressing portion 201 is provided so as to be able to bend and deform, and the tip portion presses the side surface 4 c of the light guide 4 on the side opposite to the lens unit 3.

  According to this configuration, the light guide 4 abuts over the entire surface of the inclined surface 216 of the frame 2b and the side surface 3a of the lens unit 3, and the position of the light guide 4 is set to the inclined surface 216 of the frame 2b and the side surface of the lens unit 3. Determined by 3a. Other configurations of the present embodiment are the same as those described in the first embodiment.

  Next, a method for fixing the LED substrate 8 including the LED unit 5 of FIG. 1 to the frame will be described. FIG. 11A is a perspective view showing the LED substrate 8 fixed to the frame 2c. Two columnar protrusions 251 are formed at the end in the longitudinal direction X of the frame 2c. The protruding portion 251 is fitted into a through hole 80 formed in the LED substrate 8. Thereby, the position of the width direction Y and the height direction Z of the LED substrate 8 is determined.

  In the frame 2c, groove portions 250 extending in the height direction Z are formed on both sides in the width direction Y, respectively. The LED substrate 8 is provided in a state in which end portions on both sides in the width direction Y have entered the groove portion 250. Thereby, the position of the longitudinal direction X in the LED substrate 8 is determined.

  FIG. 11B shows a state in which the LED substrate 8 of FIG. 11A is pulled out in the height direction Z, and is a perspective view of the LED substrate 8 as seen from the side where the LED unit 5 is provided. The LED unit 5 includes three LEDs (light emitting diodes) 50 arranged in a direction orthogonal to the reflecting surface 41 b of the light guide 4.

  The LED 50 is electrically connected to a wiring circuit (not shown) of the LED substrate 8 by a terminal portion 51. Terminal portions 70 are formed on the LED board 8 and are electrically connected to the printed circuit board 6 of FIG.

  The LED substrate 8 may be fixed to the frame using a fixing member. FIG. 12A is a perspective view showing a portion where the LED substrate 8 is fixed to the frame 2d by the fixing member 9. FIG. The fixing member 9 includes a plate-like portion 91 and support portions 92 that are formed on both sides in the width direction Y and support the plate-like portion 91.

  A pair of support portions 92 are arranged along the side surfaces 256 on both sides of the frame 2d, and are provided so as to sandwich the frame 2d. A hook portion 90 formed on the lower side of the support portion 92 is provided at the lower corner portion of the frame 2d. By locking, the positions of the fixing member 9 in the width direction Y and the height direction Z are fixed.

  FIG. 12B is a perspective view showing a state in which the fixing member 9 of FIG. 12A is removed from the frame 2d. On the frame 2d, ribs 253 are provided on both sides in the width direction Y and are erected from the side surface 256 and extending in the height direction Z. Further, on the lower side of the end portion in the longitudinal direction X of the frame 2d, wall portions 254 and 255 having portions 254a and 255a protruding from the side surface 256 in the width direction Y are formed on both sides in the width direction Y, respectively. Since the support portion 92 is provided between the rib 253 and the protruding portions 254a and 255a of the wall portions 254 and 255, the position of the fixing member 9 in the longitudinal direction X is fixed.

  A pair of columnar protrusions 252 formed at the ends of the frame 2 d in the longitudinal direction X are fitted with through holes 80 formed in the LED substrate 8. Thereby, the position of the width direction Y and the height direction Z of the LED substrate 8 is determined.

  FIG. 13 is a perspective view showing a state in which the fixing member 9 of FIG. 12A is pulled out upward in the height direction Z, as viewed from the side on which the LED substrate 8 is provided. The fixing member 9 is formed with ribs 93 that are erected from the plate-like portion 91 on the frame 2d side in the longitudinal direction X and extend in the height direction Z.

  In the state where the fixing member 9 of FIG. 12A is fixed to the frame 2d, the LED substrate 8 is disposed between the plate-like portion 91 and the frame 2d, and the rib 93 abuts on the LED substrate 8, The position of the LED substrate 8 in the longitudinal direction X is determined.

  As shown to Fig.14 (a), you may make it fix the LED board 8a with the protrusion part 260 provided in the flame | frame 2e. FIG. 14B is a perspective view showing a state where the LED board 8a of FIG. 14A is removed from the frame 2e.

  A pair of through holes 81 is provided in the LED substrate 8a of FIG. Four slit grooves 81 a extending in the width direction Y and the height direction Z are formed at the edge of one through-hole 81.

  The protruding portion 260 includes a cylindrical portion 260b connected to the end surface 261 in the longitudinal direction X of the frame 2e, and a cylindrical portion 260a that is coaxially formed outside the cylindrical portion 260b and has a longer diameter in cross-sectional shape than the cylindrical portion 260b. Have. Since the slit groove 81a is formed at the edge of the through hole 81, the cylindrical portion 260a is inserted so as to expand the through hole 81, and the through hole 81 is fixed at the position of the cylindrical portion 260b.

  With this configuration, the LED substrate 8a is positioned in the width direction Y, the height direction Z, and the longitudinal direction X, and the LED substrate 8a is fixed to the frame 2e. Two protrusions 251 in FIG. 11A, two protrusions 252 in FIG. 12B, and two protrusions 260 in FIG. 14 are formed at the ends of the respective frames 2c, 2d, and 2e. It may be a thing. The LED substrates 8 and 8a are fixed to the frames 2, 2a and 2b of the first to third embodiments using the LED substrate fixing method described above.

  DESCRIPTION OF SYMBOLS 1, 1a ... CIS module, 2, 2a ... Frame, 3 ... Lens unit, 4 ... Light guide, 4a ... Bottom surface, 4b, 4c ... Side surface, 5 ... LED part, 6 ... Printed circuit board, 7 ... Sensor, 41a ... Output surface, 41b ... Reflective surface, 201, 225 ... Holding part, 202, 226, 231, 241 ... Tip, 203, 227 ... Projection, 204 ... Recess, 215, 221 ... Through hole, 216, 217 ... Slope, A: groove, L1 to L6: length, M: document, X: longitudinal direction, Y: width direction.

Claims (7)

A light guide that extends in the longitudinal direction, emits light from a light source, and has a reflective surface facing the light exit surface, and guides light to an object to be read;
An imaging optical element that is arranged in parallel with the light guide and collects reflected light from the object to be read to form an erecting equal-magnification image on the sensor;
A frame that supports the light guide and the imaging optical element,
The frame has a first surface that contacts the bottom surface of the light guide on the reflective surface side, and a second surface that contacts a side surface in a direction intersecting the bottom surface of the light guide, A groove for accommodating the reflecting surface side of the light guide;
A shape projecting from the wall portion of the frame, and disposed on the opposite side of the groove portion with the light guide interposed between the groove portion and an extending portion extending in a longitudinal direction;
The contact portion of the contact image sensor module, wherein the extended portion is provided so as to be able to bend and deform, and a tip portion presses a side surface opposite to the side surface of the light guide. The contact image sensor module according to claim 1,
The contact image sensor is characterized in that a protruding portion that protrudes toward the light guide is formed at the distal end of the extending portion, and the protruding portion presses the opposite side surface of the light guide. module. The contact image sensor module according to claim 1 or 2,
A contact image sensor module, wherein a concave portion extending in a longitudinal direction is formed on a side opposite to the tip portion on the side opposite to the light guide of the extending portion. The contact image sensor module according to any one of claims 1 to 3,
A through hole is provided on the groove portion side from the portion of the frame where the extending portion is fixed, and the length of the extending portion is shorter than the length of the through hole in the longitudinal direction. The contact image sensor module is characterized in that the portion is disposed at a central portion of the through hole. The contact image sensor module according to claim 4,
The contact image according to claim 1, wherein a thickness in a width direction of a portion of the frame to which the extending portion is fixed is shorter than a thickness in a width direction of both sides of the frame in the longitudinal direction where the through holes are formed. Sensor module. Frame,
A first optical member fixed to the frame;
A second optical member that is in contact with a side surface of the first optical member and supported by the frame;
The frame has a first surface in contact with the second optical member and a shape protruding from a wall portion of the frame, and is opposite to the first optical member with the second optical member interposed therebetween. And an extending portion that is disposed on the side and extends in the longitudinal direction,
The extension part is provided so as to be able to bend and deform, and a tip part presses a side surface of the second optical member opposite to the first optical member. The contact image sensor module according to claim 6,
The first optical member is an imaging optical element that extends in the longitudinal direction and collects reflected light from the object to be read to form an erecting equal-magnification image on the sensor.
The second optical member is a light guide that has an emission surface that emits light from a light source and a reflection surface that faces the emission surface, and that guides light to an object to be read. A contact image sensor module characterized by that.

Images