JP4577295B2 - Image reading device - Google Patents

Description

  The present invention relates to an image reading apparatus capable of reading an image only by a so-called sheet-through method, and in particular, an ADF unit containing an automatic document conveying mechanism for conveying an original is provided on the upper surface of the apparatus main body via a hinge. The present invention relates to an image reading apparatus that can be opened and closed.

  Scanners, facsimiles, copiers, etc. are equipped with an image reading device for reading image information of a document. This image reading device is divided into a flat-bed type and a sheet-through type depending on the reading method. Broadly divided. The flat bed method reads image information with a document placed on a platen glass, and is realized by a flat bed scanner (hereinafter referred to as “FBS”). On the other hand, the sheet-through method reads image information at a predetermined position while conveying a document along a predetermined conveyance path, and mainly uses an automatic document conveyance mechanism (auto document feeder, hereinafter referred to as “ADF”). It is realized by.

  FIG. 12 is a schematic perspective view showing a conventional PPF (Plain Paper Facsimile) type image reading apparatus 70 equipped with an ADF and capable of reading an image only by a sheet-through method (see Patent Document 1). In this PPF type image reading apparatus 70, an ADF unit 72 containing an ADF is provided on an apparatus main body 71 containing a scanner unit (not shown), and a document conveyed by the ADF is opened. When passing through 73, the image information is read by the scanner unit through the slit glass 74.

  The PPF type image reading apparatus 70 can easily remove a jammed document when a document jam occurs in the ADF, and can also be accessed from the bottom surface 72a side of the ADF unit 72 during ADF maintenance. Therefore, the ADF unit 72 is usually provided so as to be openable and closable with respect to the apparatus main body 71 via the hinge 75. Here, as an opening / closing direction of the ADF unit 72, a side opening in which the side portion of the ADF unit 72 is supported by the hinge 75 and the bottom surface 72a is exposed to the side surface of the apparatus main body 71 is generally used. However, when the ADF unit 72 is opened from the side, the user needs to reach out to support the back of the ADF unit 72 during the opening / closing operation. Therefore, the document tray 76 for placing the document to be supplied to the ADF is provided. When provided on the side of the ADF unit 72, there is a problem that cuffs of clothes are easily caught on the document tray 76. Therefore, in order to avoid such a problem, the present applicant has proposed a front opening configuration in which the back portion of the ADF unit 72 is supported by the hinge 75 and the bottom surface 72 a is exposed to the front side of the apparatus main body 71.

  In this way, when the ADF unit 72 is front-opened, as shown in FIG. 12, the short side of the ADF unit 72 that is long in plan view is supported by the hinge 75, so the long side is hinged. Since the rotation radius of the ADF unit 72 is larger than that of the side opening supported by 75, the horizontal displacement tends to occur on the rotation tip side, that is, the side opposite to the hinge 75. As a result, the ADF unit 72 is originally arranged so that its longitudinal direction is parallel to the reading line L of the scanner unit, and the document should be conveyed in a direction orthogonal to the reading line. Along with this, there is also a problem that the original is transported with respect to the reading line L, and the reading accuracy is lowered. Further, it is difficult to prevent the positional deviation of the ADF unit 72 only by the configuration of the hinge 75. Therefore, in the image reading apparatus 70, the backlash of the attachment portion to the apparatus main body 71 is allowed with respect to the hinge 75 so that the ADF unit 72 can be accurately positioned with respect to the reading line L. On the other hand, as shown in FIG. Further, a positioning convex portion 77 is projected from the upper surface 71 a of the apparatus main body 71, and a concave portion 78 is formed on the bottom surface 72 a of the ADF unit 72 to fit therewith. Accordingly, by closing the ADF unit 72 so that the convex portion 77 is fitted in the concave portion 78, the initial distortion and assembly error generated in each component constituting the ADF unit 72 are absorbed, and the ADF unit 72 is read. It is possible to accurately position with respect to L.

JP 2005-269448 A

  However, although the conventional PPF type image reading apparatus 70 can absorb the initial distortion and assembly error of the component parts to some extent as described above, there is still a problem that the reading accuracy still depends on the component accuracy. More specifically, FIG. 13A and FIG. 13B are partially enlarged perspective views of the peripheral portion X of the convex portion 77 and the peripheral portion Y of the concave portion 78 in FIG. 77 is integrally formed with the apparatus main body 71 and the recess 78 is integrally formed with the ADF unit 72, and the position thereof cannot be adjusted. Accordingly, when the position of the convex portion 77 or the concave portion 78 is displaced from the design value, the ADF unit 72 is parallel to the reading line L even if the ADF unit 72 is closed so that the convex portion 77 is fitted into the concave portion 78. Not in the state, but also in the document transport direction with respect to the reading line L. Thereby, even when a high reading accuracy is required, a reading accuracy higher than the component accuracy cannot be obtained.

  The present invention has been made in view of such a problem, and can accurately position the ADF unit with respect to the reading line of the scanner unit without being affected by the component accuracy of the convex portion and the concave portion. Thus, a means for maintaining good reading accuracy of the scanner unit is provided.

In order to achieve the above object, an image reading apparatus according to claim 1, wherein an ADF unit containing an automatic document transport mechanism is provided on a main body of the apparatus containing image reading means so as to be openable and closable via a hinge. An image reading apparatus in which one of a convex portion and a concave portion that are fitted to prevent the ADF unit from being displaced in the horizontal direction is provided on the top surface of the apparatus main body, and the other is provided on the bottom surface of the ADF unit. The convex portion is a separate member from the apparatus main body or the ADF unit, and the assembly position to the apparatus main body or the ADF unit can be adjusted, and the upper surface of the apparatus main body or the ADF A dowel for projecting the convex portion to a predetermined assembly position is projected on the bottom surface of the unit, and a fixing screw for fixing the convex portion is screwed. A screw hole is drilled, and the convex portion is attached to the apparatus main body or the ADF unit, a fitting plate protruding from the fitting plate and fitting into the concave portion, and the fitting projection. A pair of elongated holes formed through the mounting plate at positions opposed to each other, and one of the elongated holes has a width dimension substantially equal to the outer diameter of the dowel. In addition, a dowel fitting portion having a shape in which the other elongated hole is formed in a width dimension shorter than the outer diameter of the dowel, and is fitted to the dowel so as to bulge in the width direction of the other elongated hole. It is characterized by being formed .

3. The image reading apparatus according to claim 2, wherein an ADF unit accommodating an automatic document feeding mechanism is provided on an apparatus main body accommodating image reading means so as to be openable and closable via a hinge, and is fitted to the ADF unit. In the image reading apparatus in which either one of the convex portion and the concave portion that prevents the positional deviation in the horizontal direction is provided on the upper surface of the apparatus main body and the other is provided on the bottom surface of the ADF unit, the concave portion includes the It is a separate member from the apparatus main body or the ADF unit, and the assembly position to the apparatus main body or the ADF unit can be adjusted , and the concave portion is formed on the upper surface of the apparatus main body or the bottom surface of the ADF unit. A dowel for positioning at a predetermined assembling position is protruded, and a screw hole for screwing a fixing screw for fixing the recess is formed. A mounting plate that is attached to the apparatus main body or the ADF unit, a fitting recess that is recessed in the mounting plate and fits into the projection, and a facing position across the fitting recess. A pair of elongated holes respectively formed through the mounting plate at a position, and one of the elongated holes is formed to have a width dimension substantially equal to the outer diameter of the dowel, and the other The dowel fitting portion having a shape that fits the dowel so that the elongated hole is formed in a width that is shorter than the outer diameter of the dowel and bulges in the width direction of the other elongated hole is formed. It is a feature .

The image reading apparatus according to claim 3 , wherein the mounting position of the convex portion is adjusted by visually observing a positional relationship with the dowel or the screw hole at at least one edge portion of the pair of long holes. An adjustment scale is provided.

According to a fourth aspect of the present invention, the convex portion is provided on the upper surface of the apparatus main body, and the concave portion is provided on the bottom surface of the ADF unit.

  According to the image reading apparatus according to the present invention, the accuracy of parts such as a convex portion and a concave portion is adjusted by appropriately adjusting the position where the convex portion and the concave portion are assembled to the apparatus main body or the ADF unit according to whether the reading accuracy of the document is good. The ADF unit can be accurately positioned with respect to the reading line of the image reading means without being affected by the above, and the reading accuracy can be kept good.

  Further, according to the image reading apparatus according to the present invention, when the accuracy of parts such as the convex portion and the concave portion is good, the dowel is fitted to the dowel fitting portion formed in one of the long holes. By assembling the convex portion, the convex portion is assembled at the assembly position as designed, and the ADF unit is accurately positioned with respect to the reading line. On the other hand, when the accuracy of the parts of the convex part and the concave part is poor, the dowel is inserted along the long hole by assembling the convex part so that the dowel is inserted into the long hole where the dowel fitting part is not formed. The convex portion can be slid within the guided range. Thereby, the assembly position of the convex portion can be appropriately adjusted so that the ADF unit is accurately positioned on the reading line.

  Further, according to the image reading apparatus according to the present invention, when the accuracy of parts such as the convex portion and the concave portion is good, the dowel is fitted to the dowel fitting portion formed in one of the long holes. By assembling the recess, the recess is assembled at the assembly position as designed, and the ADF unit is accurately positioned with respect to the reading line. On the other hand, when the accuracy of the parts of the convex part and the concave part is poor, the dowel is guided along the long hole by assembling the concave part so that the dowel is inserted into the long hole where the dowel fitting part is not formed. The recessed portion can be slid within the range to be operated. Thereby, the assembly position of the recess can be appropriately adjusted so that the ADF unit is accurately positioned on the reading line.

  Further, according to the image reading apparatus of the present invention, the convex portion can be slid while visually observing the positional relationship between the dowel or the screw hole and the adjustment scale, so that the mounting position of the convex portion is adjusted more accurately. be able to.

  Further, according to the image reading apparatus of the present invention, since the document is lifted when the document is placed on the convex portion, it is easy to notice that the document is left behind. Therefore, when the ADF unit is closed, it is difficult for the convex portion to break through the document.

  Hereinafter, an image reading apparatus 1 according to an embodiment of the present invention will be described with reference to the drawings. The image reading apparatus 1 is a PPF type image reading apparatus 1 equipped with an ADF and reading an image only by a sheet through method. FIG. 1 is a schematic perspective view showing the external appearance of the image reading apparatus 1. The image reading apparatus 1 accommodates a scanner unit (image reading means) (not shown) and includes an apparatus main body 3 having a slit glass 2 disposed on an upper surface thereof, and can be opened and closed on the upper surface of the apparatus main body 3 via a hinge 4. An ADF unit 5 that is provided and accommodates an ADF (not shown), a document tray 6 that is provided adjacent to the side of the ADF unit 5 to place a document to be supplied to the ADF, and A sheet discharge tray 7 provided immediately below for storing documents discharged from the ADF, and an operation panel 8 provided on the front surface of the apparatus main body 3 for various operations by a user are provided.

  According to the image reading apparatus 1 configured as described above, a bundle of documents placed on the document tray 6 is fed one by one from the uppermost sheet and supplied to the ADF, and the conveyance path in the ADF is moved downstream. Be transported. Then, when the original passes through the slit glass 2, the image information is read by the scanner unit, and then the original is conveyed further downstream along the conveyance path, discharged from the ADF, and loaded on the discharge tray 7. It is supposed to be.

  The ADF unit 5 is one in which an ADF is accommodated in a resin frame 9 formed in a hollow casing shape. As shown in FIG. 1, a substantially rectangular reading opening 10 is formed on the bottom surface 9a of the resin frame 9, and a plurality of roller openings 11 are formed adjacent thereto. The reading opening 10 is for exposing one side of a document conveyed by the ADF to the outside of the ADF unit 5, and the exposed document surface is read by the scanner unit. Further, the roller opening 11 is for avoiding interference with the conveying roller 12 that conveys the document along the ADF conveying path, and a part of the conveying roller 12 passes through the roller opening 11 and the ADF unit 5. Protrudes outside.

  Further, a horizontal positioning recess (recess) 13 is formed on the bottom surface 9 a of the resin frame 9 constituting the ADF unit 5 in order to position the ADF unit 5 at a predetermined position on the apparatus main body 3 when the ADF unit 5 is closed. At the same time, a vertical positioning pin 14 is projected. The horizontal positioning concave portion 13 is adapted to prevent the ADF unit 5 from being displaced in the horizontal direction by fitting with a horizontal positioning convex portion 20 of the apparatus main body 3 to be described later. As shown in FIG. 1, the horizontal positioning recess 13 is a bottom surface 9 a of the resin frame 9, and the corner on the rotation tip side of the ADF unit 5 and the side opposite to the document tray 6 is partially concave. It is made. The positions and the number of the horizontal positioning concave portions 13 and the horizontal positioning convex portions 20 can be arbitrarily changed, but they are far from the hinge 4 that is the rotation center of the ADF unit 5 as in this embodiment. It is preferable to provide the ADF unit 5 because the ADF unit 5 can be held more reliably. Further, the horizontal positioning recess 13 can be formed as a through-hole penetrating the bottom surface 9a of the resin frame 9 instead of forming the bottom surface 9a of the resin frame 9 in a concave shape.

  On the other hand, when the ADF unit 5 is closed, the vertical positioning pins 14 come into contact with the apparatus main body 3, so that the original that passes through the reading opening 10 because the rotation front end side of the ADF unit 5 is lifted from the rotation base end side. The entire ADF unit 5 is positioned at a certain height with respect to the apparatus main body 3 so as not to skew. In this embodiment, as shown in FIG. 1, a pair of left and right vertical positioning pins 14 project from the bottom surface 9a of the resin frame 9 at both ends in the width direction on the rotation front end side of the ADF unit 5 and rotate. One vertical positioning pin 14 projects from the central portion in the width direction on the base end side. Here, the protruding lengths of the three vertical positioning pins 14 from the bottom surface 9a of the resin frame 9 are all equal, and when the ADF unit 5 is closed, the vertical positioning pins 14 contact the apparatus main body 3, respectively. By contacting, the entire ADF unit 5 is positioned horizontally at a predetermined height position from the apparatus main body 3. The vertical positioning pins 14 may be provided at three or more locations on the bottom surface 9a of the resin frame 9. However, it is sufficient to position at least three points in order to position the ADF unit 5 horizontally, thereby reducing costs. From the viewpoint of the above, the number is preferably three. Further, the position of each vertical positioning pin 14 can be set to an arbitrary position on the bottom surface 9a of the resin frame 9 as long as the three vertical positioning pins 14 are not aligned. As shown in this embodiment, the ADF unit 5 can be held more stably by providing two width direction both end portions on the rotation front end side and one width direction center portion on the rotation base end side.

  The apparatus main body 3 is configured such that the scanner unit (not shown) is accommodated in a main body cover 15 formed of a resin or the like in a hollow casing shape. As shown in FIG. 1, the upper surface 15a of the main body cover 15 is provided with a document tray 6 and a paper discharge tray 7 on the right side when viewed from the front side of the apparatus, and on the left side when viewed from the front side of the apparatus. An ADF placement surface 16 for placing the unit 5 is formed. On the ADF placement surface 16, the slit glass 2 is disposed at a position corresponding to the reading opening 10 of the ADF unit 5. Although not shown in detail in FIG. 1, the scanner unit is positioned directly below the slit glass 2. It is fixed. This scanner unit is a so-called reduction optical system CCD reading unit comprising a light source, a reflecting mirror, a condenser lens, a charge coupled device, and the like, and passes through a reading opening 10 of the ADF unit 5. A document image is read by irradiating the document to be irradiated with light through the slit glass 2 and converting the reflected light into an electrical signal. As the scanner unit, a so-called contact image sensor can be used instead of the CCD reading unit.

  FIG. 2 is a partially enlarged plan view in which the vicinity of the slit glass 2 in FIG. 1 is enlarged. As indicated by a two-dot chain line in the figure, the reading line L of the scanner unit is located downstream of the slit glass 2 in the document conveying direction. A film 17 having a predetermined thickness is pasted on the slit glass 2 from the upstream end in the document conveying direction to the position before the reading line L. Due to the presence of the film 17, the document passing through the reading opening 10 of the ADF unit 5 passes over the slit glass 2 without directly contacting the position of the reading line L in the slit glass 2. Accordingly, it is possible to prevent the reading accuracy of the scanner unit from being deteriorated due to dirt on the original at the position of the reading line L.

  As shown in FIGS. 1 and 2, a plurality of roller openings 11 are formed on the ADF placement surface 16 of the main body cover 15 on the upstream side of the slit glass 2 in the document conveying direction. Thereby, when the ADF unit 5 is closed, the conveyance roller 12 protruding from the bottom surface 9 a is prevented from interfering with the main body cover 15. Further, a guide rib 18 for guiding the document is provided on the downstream side of the slit glass 2 in the document conveyance direction. As a result, the document that has passed immediately above the slit glass 2 is guided obliquely upward by the guide rib 18 and returned from the reading opening 10 shown in FIG. 1 to the transport path inside the ADF unit 5. ing.

  Further, as shown in FIG. 1, the ADF placement surface 16 of the main body cover 15 is stepped down by a predetermined depth from the ADF placement surface 16 at a position corresponding to the horizontal positioning recess 13 of the ADF unit 5. Thus, a pin mounting portion 19 is formed, and a horizontal positioning convex portion (convex portion) 20 is fixed to the pin mounting portion 19 with a fixing screw 21. FIG. 3 is a schematic perspective view showing the configuration of the horizontal positioning convex portion 20. The horizontal positioning convex portion 20 includes a mounting plate 22 for mounting on the pin mounting portion 19, and a fitting projection 23 that protrudes from the longitudinal central portion of the mounting plate 22 and fits in the horizontal positioning concave portion 13. , Is provided. The mounting plate 22 is a flat plate member whose both ends in the longitudinal direction are formed in a substantially arc shape. The first elongated hole 24 is located on one end side and the second elongated hole 25 is located on the other end side with the fitting projection 23 interposed therebetween. Are penetratingly formed. The first elongated hole 24 has a predetermined width dimension d1 in a plan view, and both end portions in the longitudinal direction are formed in a substantially arc shape. On the other hand, the second long hole 25 has a predetermined width dimension d2 in a plan view, both end portions in the longitudinal direction are formed in a substantially arc shape, and a central portion in the longitudinal direction is bulged in the width direction so as to be doweled. A fitting portion 26 is formed. The dowel fitting portion 26 has an arc shape with an outer diameter d3 in plan view, and the outer diameter d3 is equal to the width dimension d1 of the first elongated hole 24. Further, an adjustment scale 27 for adjusting the fixing position of the horizontal positioning convex portion 20 by visual observation is provided at an edge portion of the second long hole 25 at a predetermined interval.

  As shown in FIG. 5, the pin mounting portion 19 is formed to be stepped down from the ADF placement surface 16 of the main body cover 15, and the stepped depth is that of the mounting plate 22 constituting the horizontal positioning convex portion 20. It is almost equal to the thickness. Further, the pin mounting portion 19 is formed to be substantially the same width as the mounting plate 22 in plan view and longer than the mounting plate 22, and both end portions in the longitudinal direction are formed in an arc shape. The bottom surface 19a of the pin mounting portion 19 is provided with a positioning dowel 28 on one end in the longitudinal direction and a screw hole 29 for screwing the fixing screw 21 on the other end in the longitudinal direction. ing. The dowel 28 has a cylindrical shape, and its outer diameter d4 is substantially equal to the outer diameter d3 of the dowel fitting portion 26 of the second elongated hole 25, and its height dimension is approximately the same as the thickness of the mounting plate 22. It is formed slightly larger. Further, the tip portion of the dowel 28 is formed to have a slightly small diameter, and is easily inserted into the horizontal positioning convex portion 20. On the other hand, the inner diameter d5 of the screw hole 29 is smaller than the width dimension d2 of the second elongated hole 25.

  As shown in FIG. 4, the fixing screw 21 includes a shaft portion 21a in which a male screw that is screwed into a screw hole 29 of the pin mounting portion 19 is cut, and a head portion 21b provided on one end side of the shaft portion 21a. The outer diameter d6 of the head 21b is formed larger than the width dimension d1 of the first elongated hole 24 and the outer diameter d3 of the dowel fitting portion 26 of the second elongated hole 25. Thereby, when fixing the horizontal positioning convex portion 20 with the fixing screw 21, the head 21 b of the fixing screw 21 does not fall into the first long hole 24 or the second long hole 25 of the mounting plate 22. The mounting plate 22 can be securely tightened by the head 21b of the fixing screw 21. Further, the thickness dimension of the head portion 21 b, that is, the dimension in the direction perpendicular to the radial direction is formed to be smaller than the projecting length of the vertical positioning pin 14 of the ADF unit 5 projecting from the resin frame 9. Thereby, as shown in FIG. 4, when closing the ADF unit 5, the head 21 b of the fixing screw 21 protruding upward from the mounting plate 22 of the horizontal positioning convex portion 20 does not interfere with the ADF unit 5. Three vertical positioning pins 14 can be brought into contact with the apparatus main body 3, respectively.

  As shown in FIG. 1, the hinge 4 has a base 30 attached to the main body cover 15 of the apparatus main body 3 and a pair of left and right ADF support portions 31 that support the back of the ADF unit 5 so as to be pivotable. The ADF unit 5 is supported on the ADF placement surface 16 of the apparatus main body 3 so that the ADF unit 5 is opened frontward, that is, the bottom surface 9 a of the resin frame 9 is exposed to the front side of the apparatus main body 3. By making the ADF unit 5 openable and closable with respect to the apparatus main body 3 in this way, when a document jam occurs inside the ADF, the jammed document can be easily removed by opening the ADF unit 5. In addition, it can be accessed from the bottom surface 9a side of the ADF unit 5 during maintenance of the ADF. Further, since the ADF unit 5 is opened from the front, the user only has to support the rotating tip of the ADF unit 5 by hand when the ADF unit 5 is opened and closed. There is an advantage that a cuff of a user's clothes is not easily caught on the tray 6.

  Next, a method for adjusting the assembly position of the horizontal positioning projection 20 will be described with reference to the drawings. In the present invention, the assembly position of the horizontal positioning convex portion 20 to the apparatus main body 3 can be adjusted in order to prevent the reading accuracy of the original from depending on the accuracy of parts such as the horizontal positioning convex portion 20. Specifically, as an assembling mode of the horizontal positioning convex portion 20, there are provided a standard assembling mode for assembling at an assembling position as designed, and an adjustment assembling mode for assembling by shifting the horizontal position from the assembling position as designed. Yes. When the image reading apparatus 1 is manufactured, the horizontal positioning convex portion 20 is first assembled in the standard assembling mode, and then the original reading accuracy is inspected. As a result, when it is determined that the reading accuracy is good and the ADF unit 5 is accurately positioned with respect to the reading line L of the scanner unit, the horizontal positioning convex portion 20 remains assembled in the standard assembly mode. To do. On the other hand, as a result of the inspection, when it is determined that the reading accuracy is poor and the ADF unit 5 is displaced in the horizontal direction with respect to the reading line L of the scanner unit, the horizontal positioning convex portion 20 is moved from the pin mounting portion 19. Remove once and reassemble in adjustment assembly mode. Then, the inspection is performed again, and the assembly position of the horizontal positioning convex portion 20 is adjusted until the reading accuracy becomes good. Hereinafter, the standard assembly mode and the adjustment assembly mode will be described in detail.

  First, the standard assembly mode will be described. 5 and 7A are enlarged views of the peripheral portion Z of the horizontal positioning convex portion 20 in FIG. 1, FIG. 5 is an exploded perspective view, and FIG. 7A is a plan view. As shown in FIG. 5, in this mode, the dowel 28 is first fitted to the dowel fitting portion 26 of the second oblong hole 25 with respect to the pin mounting portion 19 of the apparatus main body 3 in the horizontal positioning convex portion 20. Assemble. Here, as described above, the outer diameter d3 of the dowel fitting portion 26 is substantially equal to the outer diameter d4 of the dowel 28, so that the outer peripheral surface of the dowel 28 is the dowel fitting portion 26 as shown in FIG. The horizontal positioning convex portion 20 is restricted from sliding in the longitudinal direction and in the direction perpendicular thereto. Further, as described above, since the mounting plate 22 constituting the horizontal positioning convex portion 20 is substantially the same width as the pin mounting portion 19, the left and right side surfaces of the mounting plate 22 are in close contact with the inner surface of the pin mounting portion 19. The rotation of the horizontal positioning projection 20 around the position of the dowel 28 is restricted. At this time, since the inner diameter d5 of the screw hole 29 is smaller than the width dimension d2 of the second elongated hole 25 as described above, the screw hole 29 is threaded through the first elongated hole 24 as shown in FIG. The entire hole 29 is exposed. From this state, as shown in FIG. 5 and FIG. 7A, the horizontal positioning convex portion 20 is fixed by inserting the fixing screw 21 through the first long hole 24 and screwing it into the screw hole 29. Thereby, the horizontal positioning convex part 20 is assembled | attached to the assembly position as a design value inside the pin attachment part 19. FIG.

Next, the adjustment assembly mode will be described. 6 and 7 (b) (c) (d) are enlarged views of the peripheral portion Z of the horizontal positioning projection 20 in FIG. 1, FIG. 6 is an exploded perspective view, and FIGS. (D) is a plan view. As shown in FIG. 6, in this mode, first, the horizontal positioning convex portion 20 is assembled to the pin mounting portion 19 of the apparatus main body 3 so that the dowel 28 is inserted through the first long hole 24. Here, as described above, the outer diameter d4 of the dowel 28 is substantially equal to the outer diameter d3 of the dowel fitting portion 26 of the second elongated hole 25, and this outer diameter d3 is equal to the width dimension d1 of the first elongated hole 24. Since they are substantially equal, a part of the outer peripheral surface of the dowel 28 abuts against the inner surface of the first elongated hole 24 as shown in FIG. Further, as described above, the mounting plate 22 constituting the horizontal positioning convex portion 20 is substantially the same width as the pin mounting portion 19, so that the left and right side surfaces of the mounting plate 22 are in close contact with the inner surface of the pin mounting portion 19. To do. As a result, the horizontal positioning convex portion 20 is allowed to slide in the longitudinal direction, but is restricted from sliding in a direction perpendicular thereto. At this time, since the inner diameter d5 of the screw hole 29 is formed smaller than the width dimension d2 of the second elongated hole 25 as described above, the screw hole 29 is threaded through the second elongated hole 25 as shown in FIG. The entire hole 29 is exposed.

  Then, from the state shown in FIG. 7B, the horizontal positioning convex portion 20 is slid by a desired distance in the longitudinal direction. Here, as described above, since the adjustment scale 27 is provided at the edge of the second elongated hole 25, the position of the horizontal positioning convex portion 20 is determined by the positional relationship between the adjustment scale 27 and the screw hole 29. You can know the distance traveled accurately. Then, from the state shown in FIG. 7B, the horizontal positioning convex portion 20 is slid in the direction in which the fitting protrusion 23 is brought closer to the dowel 28 to obtain the state shown in FIG. After the horizontal positioning projection 20 is slid in the direction away from the dowel 28 to the state shown in FIG. 7D, the fixing screw 21 is inserted into the second long hole 25 as shown in FIG. The horizontal positioning convex portion 20 is fixed by being screwed to 29. Thereby, the horizontal direction positioning convex part 20 is assembled | attached in the position which shifted | deviated to the horizontal direction from the assembly position as a design value inside an attachment part.

  In the present embodiment, the adjustment scale 27 is provided at the edge of the second elongated hole 25, but instead of this, the first elongated hole 24 is replaced by a horizontal positioning convex portion 32 shown in FIG. It is also possible to provide the adjustment scale 27 at the edge and measure the moving distance of the horizontal positioning convex portion 20 based on the positional relationship between the dowel 28 inserted through the first long hole 24 and the adjustment scale 27. In this case, as described above, the outer peripheral surface of the dowel 28 abuts on the inner surface of the first slot 24, and no gap is generated between the dowel 28 and the first slot 24. Therefore, as shown in FIG. 7B, the moving distance of the horizontal positioning convex portion 20 is measured by the positional relationship between the screw hole 29 slightly spaced from the edge of the second long hole 25 and the adjustment scale 27. Compared to the case, there is an advantage that visual observation of the positional relationship can be performed more easily. Since the horizontal positioning convex portion 32 is the same as the horizontal positioning convex portion 20 except for the configuration of the adjustment scale 27, the same reference numerals as those in FIG. 3 are given in FIG. 8, and the description thereof is omitted here.

  In the present embodiment, the horizontal positioning convex portion 20 is assembled to the apparatus main body 3 so that the position thereof can be adjusted, and the horizontal positioning concave portion 13 is integrally formed with the ADF unit 5, but conversely, The horizontal positioning convex portion 20 may be formed integrally with the apparatus main body 3 and the horizontal positioning concave portion 13 may be assembled to the ADF unit 5 so that the position can be adjusted. FIG. 9 is a schematic perspective view showing the configuration of the horizontal positioning recess 33 in this case. The horizontal positioning recess 33 includes an attachment plate 22 for attachment to the ADF unit 5 and a fitting recess 34 that protrudes from the bottom surface through the attachment plate 22. Here, since the configuration of the mounting plate 22 is the same as that of the mounting plate 22 of the horizontal positioning convex portion 20, in FIG. 9, the same reference numerals as those in FIG.

  FIG. 10 is a schematic longitudinal sectional view showing a state where the horizontal positioning recess 33 is assembled to the ADF unit 5. As shown in the figure, the horizontal positioning convex portion 35 is integrally formed on the upper surface of the main body cover 15 of the apparatus main body 3, while the resin frame 9 of the ADF unit 5 is located at a position corresponding to the horizontal positioning convex portion 35. A stepped portion 36 is formed by stepping down from the resin frame 9 by a predetermined depth, and an accommodating portion 37 is recessed in the center of the stepped portion 36. The stepped portion 36 is provided with a positioning dowel 38 and a screw hole 39 through which the fixing screw 21 is screwed. Since the structures of the dowels 38 and the screw holes 39 are the same as the dowels 28 and the screw holes 29 provided in the pin mounting portion 19, the description thereof is omitted here. As shown in FIG. 10, the mounting plate 22 is assembled to the stepped-down portion 36 so that the fitting recess 34 is accommodated in the accommodating portion 37. At this time, the dowel 38 of the stepped portion is inserted into one of the first elongated hole 24 and the second elongated hole 25 formed through the mounting plate 22, and either of the other is inserted to fix the fixing screw 21. It is screwed into the screw hole 39. As with the horizontal positioning convex portion 20, the horizontal positioning concave portion 33 can be attached to the ADF unit 5 by adjusting the assembly position of the horizontal positioning concave portion 33. It is possible.

  FIG. 11 is a schematic perspective view showing the configuration of a horizontal positioning recess 40 capable of adjusting the assembly position according to another embodiment. The horizontal positioning concave portion 40 is formed with a fitting concave hole 41 for inserting the horizontal positioning convex portion 35 shown in FIG. 10 as a through-hole penetrating the mounting plate 22 in the longitudinal center portion of the mounting plate 22. It is a thing. Since the other configuration and the method of assembling the ADF unit 5 are the same as those of the horizontal positioning recess 33, description thereof is omitted here.

  In addition, the horizontal positioning convex portion 20 is assembled to the apparatus main body so that the position can be adjusted, and the horizontal positioning concave portions 33 and 40 are also assembled to the ADF unit so that the position can be adjusted. It is also possible to adopt a configuration in which the unit 5 is accurately positioned with respect to the reading line L.

  Further, in the present embodiment, the horizontal positioning convex portion 20 is protruded from the apparatus main body 3 and the horizontal positioning concave portion 13 to be fitted thereto is provided in the ADF unit 5. Of course, it is also possible to project the projection 20 on the ADF unit 5 and provide the horizontal positioning recess 13 in the apparatus main body 3. However, in this case, if the user closes the ADF unit 5 while leaving the document on the apparatus body 3, the horizontal positioning convex portion 20 of the ADF unit 5 may break through the misplaced document. On the other hand, when the horizontal positioning convex portion 20 is projected from the apparatus main body 3 as in the present embodiment, the original is lifted when the original is placed on the horizontal positioning convex portion 20. Therefore, it is easy to notice that the manuscript is misplaced. There is an advantage that when the ADF unit 5 is closed, the document is hardly broken by the horizontal positioning convex portion 20.

  This image reading device is installed in a facsimile machine that has only a facsimile communication function, a copy machine that has only a document copying function, or a copy / facsimile multifunction machine that has both a faxi communication function, an internet fax communication function, and a copying function. Is possible.

FIG. 2 is a schematic perspective view showing an appearance of the image reading apparatus 1. The partial enlarged plan view which expanded the slit glass 2 vicinity in FIG. The schematic perspective view which shows the structure of the horizontal direction positioning convex part 20. FIG. The schematic longitudinal cross-sectional view which shows the relationship between the horizontal direction positioning convex part 20 and the horizontal direction positioning recessed part 13 when the ADF unit 5 is closed. The disassembled perspective view which expanded the peripheral part Z of the horizontal direction positioning convex part 20 in FIG. The disassembled perspective view which expanded the peripheral part Z of the horizontal direction positioning convex part 20 in FIG. The top view which expanded the peripheral part Z of the horizontal direction positioning convex part 20 in FIG. The schematic perspective view which shows the structure of the horizontal direction positioning convex part 32. FIG. The schematic perspective view which shows the structure of the horizontal direction positioning recessed part 33. FIG. FIG. 4 is a schematic longitudinal sectional view showing the relationship between a horizontal positioning convex portion 35 and a horizontal positioning concave portion 33 when the ADF unit 5 is closed. The schematic perspective view which shows the structure of the horizontal direction positioning recessed part 40. FIG. FIG. 10 is a schematic perspective view showing a PPF type image reading apparatus according to a conventional example. FIG. 13 is an enlarged partial perspective view of the peripheral portion X of the convex portion 77 and the peripheral portion Y of the concave portion 78 in FIG. 12.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Image reader 3 Apparatus main body 4 Hinge 5 ADF unit 13 Horizontal direction positioning recessed part (recessed part)
20 Horizontal positioning convex part (convex part)
21 Fixing screw 22 Mounting plate 23 Fitting protrusion 24 First long hole (long hole)
25 Second long hole (long hole)
26 Dowel fitting section 27 Adjustment scale 28, 38 Dowel 29, 39 Screw hole

Claims (4)

An ADF unit containing an automatic document transport mechanism is provided on the apparatus main body containing the image reading means so as to be openable and closable via a hinge, and is fitted together to prevent the ADF unit from being displaced in the horizontal direction. In the image reading apparatus in which either one of the convex portion and the concave portion is provided on the upper surface of the apparatus main body, and the other is provided on the bottom surface of the ADF unit.
The convex portion is a separate member from the apparatus main body or the ADF unit, and the assembly position to the apparatus main body or the ADF unit can be adjusted .
A dowel for positioning the convex portion at a predetermined assembly position protrudes from the upper surface of the apparatus main body or the bottom surface of the ADF unit, and a screw hole for screwing a fixing screw for fixing the convex portion. Is drilled,
The convex portion is attached to the apparatus main body or the ADF unit, a fitting projection that protrudes from the mounting plate and fits into the concave portion, and a position opposite to the fitting projection. A pair of elongated holes each formed through the mounting plate,
Of the elongated holes, one elongated hole is formed to have a width dimension substantially equal to the outer diameter of the dowel, and the other elongated hole is formed to have a width dimension shorter than the outer diameter of the dowel. An image reading apparatus characterized in that a dowel fitting portion having a shape fitting with the dowel is formed so as to bulge in the width direction of the hole. An ADF unit containing an automatic document transport mechanism is provided on the apparatus main body containing the image reading means so as to be openable and closable via a hinge, and is fitted together to prevent the ADF unit from being displaced in the horizontal direction. In the image reading apparatus in which either one of the convex portion and the concave portion is provided on the upper surface of the apparatus main body, and the other is provided on the bottom surface of the ADF unit.
The concave portion is a separate member from the apparatus main body or the ADF unit, and the assembly position to the apparatus main body or the ADF unit can be adjusted .
A dowel for positioning the recess at a predetermined assembly position protrudes from the upper surface of the apparatus main body or the bottom surface of the ADF unit, and a screw hole for screwing a fixing screw for fixing the recess is formed. Established,
The concave portion has a mounting plate attached to the apparatus main body or the ADF unit, a fitting recess formed in the mounting plate and fitted into the convex portion, and opposed to the fitting recess. A pair of elongated holes respectively formed through the mounting plate at a position;
Of the elongated holes, one elongated hole is formed to have a width dimension substantially equal to the outer diameter of the dowel, and the other elongated hole is formed to have a width dimension shorter than the outer diameter of the dowel. An image reading apparatus characterized in that a dowel fitting portion having a shape fitting with the dowel is formed so as to bulge in the width direction of the hole. At least one edge of the pair of long holes is provided with an adjustment scale for adjusting the assembly position of the convex portion by observing the positional relationship with the dowel or the screw hole. The image reading apparatus according to claim 1 or 2 . The image reading apparatus according to claim 1, wherein the convex portion is provided on an upper surface of the apparatus main body, and the concave portion is provided on a bottom surface of the ADF unit.

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