JP6234248B2 - Image reading apparatus, image forming apparatus including the same, and scanning body - Google Patents

Description

  The present invention relates to an image reading apparatus including a contact image sensor, an image forming apparatus including the image reading apparatus, and a scanning body.

  Some conventional image reading apparatuses read an image of a document by scanning a document placed on a document placing table while moving a scanning body having a contact image sensor in the sub-scanning direction.

  In such an image reading apparatus, the contact image sensor usually has an extremely small depth of focus. Therefore, in order to improve the depth of focus accuracy when reading the document placed on the document table, the contact image sensor A fixed focus on the original with the reading unit of the contact image sensor close to the surface facing the contact image sensor of the document placement table by a sliding member that secures a certain distance between the document placement table and the document placement table. The contact image sensor is moved in the sub-scanning direction while securing the distance.

  For example, Patent Document 1 secures a focal length with respect to a document by bringing a sliding member (spacer) provided in the contact image sensor into contact with a surface (guide plate) of the document placement table facing the contact image sensor. The configuration (paragraph [0041] and FIG. 3) is disclosed.

  However, in the invention described in Patent Document 1, it is necessary to perform a process such as providing a sliding member on the contact image sensor, and thus an inexpensive general-purpose product cannot be used as the contact image sensor.

  In Patent Document 2, the sliding member (protrusion) is pushed down by the surface (back surface of the cover glass) facing the contact image sensor of the document placing table, and the flanges of the left and right pressing portions are elastically deformed accordingly. However, a configuration (paragraph [0034] and FIG. 10B) is disclosed in which positioning accuracy is improved by fixing the holder in a state where the holder is pressed down and pressed to a predetermined position of the frame.

  However, in the invention described in Patent Document 2, when the sliding member wears or breaks due to sliding with the surface of the document table facing the contact image sensor, the replacement work for replacing the sliding member is easy. Issues remain in sex.

JP 2006-213353 A JP 2012-70411 A JP 2013-225758 A

  On the other hand, in Patent Document 3, in a scanning base that supports a contact image sensor in a state of being biased toward the document placement table side, it slides in a locking groove provided on one side surface in the sub-scanning direction. The locking projection provided on one end side in the sub-scanning direction of the member is locked, and the other in the sub-scanning direction of the sliding member is inserted into the restriction hole provided on the top surface (upper surface) on the other side in the sub-scanning direction. The structure (paragraph [0067], [0076], [0077] and FIG. 15) which latches the contact convex part provided in the end side is disclosed.

  However, in the invention described in Patent Document 3, the sliding member can be easily replaced without performing a process of providing the sliding member on the contact image sensor, but there are the following disadvantages.

  FIG. 31 is a schematic sectional view showing a conventional scanning body 200 described in Patent Document 3. As shown in FIG.

  In the scanning body 200 described in Patent Document 3 shown in FIG. 31, for example, when the sliding member 202 is attached to the scanning base 201, the sliding member 202 is pushed into the scanning base 201, or an image reading device. When the scanning body 200 is moved in the sub-scanning direction Y, the scanning base 201 moves relative to the side opposite to the document placing table 40 (the lower side in the vertical direction Z) and moves away from the document placing table 40. Since the contact type image sensor 203 is biased toward the document placing table 40 (upward in the vertical direction Z) with respect to the scanning base 201, the sliding member 202 is in contact with the scanning base 201. According to Patent Document 3, the urging force of 203 to the document placement table 40 side (upper side) relatively moves together with the contact image sensor 203 in the direction away from the scanning base 201 side (upper side). In the described invention, the contact convex portion 206 provided on the other end side in the sub-scanning direction Y of the sliding member 202 is engaged with the restriction hole 205 provided on the top surface 204 on the other side in the sub-scanning direction Y. Therefore, due to the frictional resistance between the restriction hole 205 and the contact convex portion 206, the sliding member 202 moves relative to the scanning base 201 in the direction away from the scanning base 201 (upper side). There are things that do not. That is, when the sliding member 202 is pushed into the scanning base 201, the sliding member 202 does not return even when the pushing is released, or the scanning base 201 moves away from the document placement table 40. In other words, the sliding member 202 and the contact image sensor 203 are separated from the document placement table 40 together with the scanning base 201 against the biasing force of the contact image sensor 203 toward the document placement table 40 side (upper side). In this case, the focal length of the contact image sensor 203 with respect to the document G may not be ensured.

  Therefore, the present invention can not only perform the process of providing a sliding member on the contact image sensor, but also easily replace the sliding member, and can reduce the frictional resistance between the scanning base and the sliding member. An object of the present invention is to provide an image reading apparatus, an image forming apparatus, and a scanning body that can be suppressed as much as possible, and that can reliably ensure the focal length of the contact image sensor with respect to the document.

  In order to solve the above problems, the present invention provides the following image reading apparatus, image forming apparatus, and scanning body.

(1) Image reading apparatus comprising: a scanning body provided with a contact image sensor; and a document placement table on which a document is placed, and the document placed on the document placement table while moving the scanning body in a sub-scanning direction. An image reading apparatus that reads an image of the document by scanning the document with the contact image sensor, wherein the scanning body is configured so that the contact image sensor approaches or separates from the document placement table. A scanning base that movably supports the contact image sensor, a biasing member that biases the contact image sensor toward the document placement table, and a space between the contact image sensor and the document placement table. It is moving, and a sliding member is slid in front Symbol document placing table, the sliding member, so as to approach or away from the said document table, and, with respect to the scanning base Is acceptable Further, the scanning base is engaged with both side surfaces of the scanning base in the sub-scanning direction , and is movably engaged with the scanning base in a vertical direction with respect to the document placement base. The contact image sensor and the document placement base And the opposite side of the original platen along the both side surfaces of the scanning base in the sub-scanning direction from both ends in the sub-scanning direction of the sliding portion. A pair of extending portions extending to the side, and an engaging portion is provided on a side surface of the pair of extending portions facing the scanning base, and the sub-scanning of the scanning base Engaged portions that engage with the engaging portions are provided on both side surfaces in the direction, and at least one side surface of the scanning base in the sub-scanning direction is provided with the extended portion. On both sides in the main scanning direction of the installation portion. Image reading apparatus characterized by a pair of guide portions are provided for guiding the movement in the vertical section.

(2) Image forming apparatus An image forming apparatus comprising the image reading apparatus according to the present invention.

(3) Scanning Body The image of the original is scanned by scanning the original placed on the original placing table on which the original is placed while moving the scanning body provided with the close-contact type image sensor in the sub-scanning direction. A scanning base used in an image reading device that reads with an image sensor, and a scanning base that movably supports the contact image sensor so that the contact image sensor approaches or separates from the document placing table. a biasing member for biasing the contact image sensor toward the document table, is provided between the contact image sensor and the document table before SL sliding being slid on the document placing table A moving member, and the sub-scan of the scanning base is arranged such that the sliding member approaches or separates from the document placement table and is allowed to move relative to the scanning base. In direction A sliding portion that is engaged with both side surfaces , is movably engaged with the scanning base in a direction perpendicular to the document placement table, and is disposed between the contact image sensor and the document placement table; A pair of extending portions extending from both ends of the sliding portion in the sub-scanning direction along the both side surfaces of the scanning base in the sub-scanning direction to the side opposite to the document placing table side. An engagement portion is provided on a side surface of the pair of extending portions facing the scanning base, and the engagement is formed on both side surfaces of the scanning base in the sub-scanning direction. An engaged portion that engages with a portion is provided, and at least one side surface of the scanning base in the sub-scanning direction is provided on both sides in the main scanning direction of the extending portion, One that guides the movement of the extension in the vertical direction Scanning body characterized in that the guide portion is provided.

  In the present invention, the sliding member has the pair of extending portions engaged with the scanning base so as to be rotatable about a rotation axis along the sub-scanning direction, and the sliding portion. Is disposed at an end portion in the main scanning direction of the contact image sensor, and one guide portion outside the main scanning direction of the pair of guide portions for guiding the extending portion is the extension portion. An end portion on the side of the original document table in the vertical direction is an end of the other guide portion on the side of the original document table so as to guide at least the portion on the original document table side with respect to the rotation axis The aspect provided so that it may be located in the said document mounting base side rather than a part can be illustrated.

  In the present invention, the sliding member has the pair of extending portions engaged with the scanning base so as to be rotatable about a rotation axis along the sub-scanning direction, and the sliding portion. Is disposed at an end portion in the main scanning direction of the reading unit in the contact image sensor, and one guide portion on the inner side in the main scanning direction of the pair of guide portions for guiding the extending portion is The document mounting table is such that an end portion on the document mounting table side in the vertical direction is at the other guide portion so as to guide at least a portion of the extending portion closer to the document mounting table than the rotation axis. A mode of being provided so as to be positioned closer to the document placing table than the end on the side can be exemplified.

  In the present invention, it is possible to exemplify an aspect in which the other guide portion is provided so as to guide at least a portion of the extending portion on the side opposite to the document placing table side with respect to the rotation axis.

  In the present invention, the sliding member has the pair of extending portions engaged with the scanning base so as to be rotatable about a rotation axis along the sub-scanning direction, and the sliding portion. Are arranged at the end in the main scanning direction of the contact image sensor and at the end in the main scanning direction of the reading unit in the contact image sensor, and the pair of guides for guiding the extending portion The part can be exemplified by an aspect in which each of the extending parts is provided so as to guide at least a part of the original document table with respect to the rotation axis.

  In the present invention, the end of the scanning base on the side of the original document table in the vertical direction is closer to the side of the original document table in the vertical direction than the end portion of the sliding member on the side of the original document table in the vertical direction. The pair of guide portions are provided such that the end portion on the document placement table side in the vertical direction extends to the end portion on the document placement table side in the vertical direction of the scanning base. An aspect can be illustrated.

  In the present invention, it is possible to exemplify an aspect in which the sliding portion is formed in a shape that makes line contact or point contact with the document placing table.

  In the present invention, the engagement of the sliding member with respect to the scanning base can be exemplified as an uneven engagement.

  According to the present invention, the sliding member can be easily replaced without performing the processing of providing the sliding member on the contact image sensor, and the scanning base and the sliding member can be easily replaced. Thus, it is possible to ensure the focal length of the contact image sensor with respect to the original.

1 is a front view illustrating a schematic configuration of an image forming apparatus including an image reading apparatus according to an embodiment of the present invention. It is the schematic sectional drawing which looked at the image reading device shown in Drawing 1 from the front. FIG. 2 is a plan view of a scanning unit viewed from above in a state where a document transport unit is removed from the image reading apparatus shown in FIG. 1. 2A and 2B are diagrams illustrating an internal structure of a scanning unit in the image reading apparatus illustrated in FIG. 1, in which FIG. 1A is a plan view thereof and FIG. 2B is a right side view thereof. It is a disassembled perspective view which decomposes | disassembles and shows the contact | adherence image sensor and scanning base in the scanning body which concerns on 1st Embodiment. BRIEF DESCRIPTION OF THE DRAWINGS It is an external view which shows the state which combined the contact | adherence image sensor and scanning base in the scanning body which concerns on 1st Embodiment, (a) is the top view, (b) is the right view. It is. It is a front view which shows the state which combined the contact type image sensor and scanning base in the scanning body shown in FIG. It is a perspective view of the contact type image sensor in the scanning body concerning a 1st embodiment. It is an external view of the contact | adherence image sensor in the scanning body which concerns on 1st Embodiment, (a) is the top view, (b) is the right view. FIG. 10 is a schematic cross-sectional view of the contact image sensor shown in FIGS. 8 and 9. It is a perspective view of the scanning base in the scanning body concerning a 1st embodiment. It is an external view of the scanning base in the scanning body which concerns on 1st Embodiment, (a) is the top view, (b) is the right view. It is a front view of the scanning base shown in FIG.11 and FIG.12. It is an external view which shows the sliding member in a scanning body, Comprising: (a) is the front view, (b) is the left-right side view. It is a perspective view which shows the scanning body which concerns on 1st Embodiment. It is an external view which shows the scanning body which concerns on 1st Embodiment, Comprising: (a) is the top view, (b) is the right view. It is a front view of the scanning body concerning a 1st embodiment. It is sectional drawing along the arrow DD line shown to Fig.16 (a). It is sectional drawing along the arrow EE line shown to Fig.16 (a). It is sectional drawing which followed the arrow FF shown in Fig.16 (a). It is a perspective view which shows the scanning body which concerns on 2nd Embodiment. It is a top view which expands and shows the both ends in the main scanning direction of the scanning body which concerns on 2nd Embodiment. It is a right view which expands and shows the both ends in the main scanning direction of the scanning body which concerns on 2nd Embodiment. It is a left view which expands and shows the both ends in the main scanning direction of the scanning body which concerns on 2nd Embodiment. It is a top view which expands and shows the both ends in the main scanning direction of the scanning body which concerns on 3rd Embodiment. It is a right view which expands and shows the both ends in the main scanning direction of the scanning body which concerns on 3rd Embodiment. It is a left view which expands and shows the both ends in the main scanning direction of the scanning body which concerns on 3rd Embodiment. It is a top view which expands and shows the both ends in the main scanning direction of the scanning body which concerns on 4th Embodiment. It is a right view which expands and shows the both ends in the main scanning direction of the scanning body which concerns on 4th Embodiment. It is a left view which expands and shows the both ends in the main scanning direction of the scanning body which concerns on 4th Embodiment. It is a schematic sectional drawing which shows the conventional scanning body described in patent document 3.

  Embodiments according to the present invention will be described below with reference to the drawings.

[Image forming apparatus]
FIG. 1 is a front view showing a schematic configuration of an image forming apparatus 1 including an image reading apparatus 2 according to an embodiment of the present invention.

  As shown in FIG. 1, the image forming apparatus 1 includes an image reading device 2 and a device main body 10. Based on image data read by the image reading device 2, a color image is recorded on a recording sheet such as paper by the device main body 10. To form an image.

  The image reading apparatus 2 includes a document conveyance unit 61 and a scanning unit 41, and reads the document G conveyed by the document conveyance unit 61 by the scanning unit 41 or scans the document G placed on the document placement table 40. The image of the original G read by the unit 41 is output as image data. The image reading device 2 will be described in detail later.

  The apparatus main body 10 includes an optical scanning device 11, a developing device 12, a photosensitive drum 13, a drum cleaning device 14, a charger 15, an intermediate transfer belt 21, a fixing device 17, a sheet conveyance path R 1, a paper feed tray 18, and a discharge tray 39. It has.

  A color image is formed by overlapping toner images of black (K), cyan (C), magenta (M), and yellow (Y). For this reason, each of the developing device 12, the photosensitive drum 13, the drum cleaning device 14, and the charger 15 is provided so as to form four types of toner images corresponding to the respective colors, and black, cyan, magenta, respectively. , And yellow, four image stations Pa, Pb, Pc, Pd are configured.

  In each of the image stations Pa, Pb, Pc, and Pd, the same operation as described below is performed. The drum cleaning device 14 removes and collects residual toner on the surface of the photosensitive drum 13. The charger 15 uniformly charges the surface of the photosensitive drum 13 to a predetermined potential. The optical scanning device 11 exposes the surface of the photosensitive drum 13 to form an electrostatic latent image. The developing device 12 develops the electrostatic latent image on the surface of the photosensitive drum 13 to form a toner image on the surface of the photosensitive drum 13. As a result of the series of operations described above, toner images of the respective colors are formed on the surface of each photosensitive drum 13.

  Subsequently, the intermediate transfer belt 21 circulates in the direction of arrow C, the residual toner is removed and collected by the belt cleaning device 25, and the toner images of the respective colors formed on the surfaces of the photosensitive drums 13 are sequentially transferred. As a result, a color toner image is formed on the surface of the intermediate transfer belt 21.

  A nip area is formed between the transfer roller 26a of the secondary transfer device 26 and the intermediate transfer belt 21, and the recording sheet conveyed through the sheet conveyance path R1 is sandwiched and conveyed in the nip area. When the recording sheet passes through the nip region, the toner image on the surface of the intermediate transfer belt 21 is transferred. The fixing device 17 sandwiches the recording sheet on which the toner image is transferred between the heating roller 31 and the pressure roller 32 and heats and presses the recording sheet to fix the toner image on the recording sheet.

  Recording sheets are stacked on the paper feed tray 18. The recording sheet is pulled out from the paper feed tray 18 by the pickup roller 33, transported through the sheet transport path R 1, and discharged to the discharge tray 39 through the secondary transfer device 26 and the fixing device 17 and through the discharge roller 36. The

  In the sheet conveyance path R1, after the recording sheet is stopped once and the leading edge of the recording sheet is aligned, the recording sheet is aligned with the transfer timing of the toner image in the nip region between the intermediate transfer belt 21 and the transfer roller 26a. A registration roller 34 that starts conveyance, a conveyance roller 35 that prompts conveyance of the recording sheet, and a discharge roller 36 are arranged.

  Further, the apparatus body 10 conveys the recording sheet from the discharge roller 36 to the reversing path Rr in the reverse direction when performing image formation on the back surface as well as the front surface of the recording sheet, thereby reversing the front and back of the recording sheet. The toner image is guided again to the registration roller 34, and the toner image is fixed on the back surface of the recording sheet in the same manner as the front surface of the recording sheet, and is discharged to the discharge tray 39.

  In FIG. 1, the symbol X indicates the main scanning direction, the symbol Y indicates the sub-scanning direction Y orthogonal to the main scanning direction X, and the symbol Z indicates the vertical direction with respect to the document table 40 ( Specifically, the vertical direction) is shown.

[Image reading device]
FIG. 2 is a schematic cross-sectional view of the image reading apparatus 2 shown in FIG. 1 viewed from the front. FIG. 3 is a plan view of the scanning unit 41 as seen from above with the document conveying unit 61 removed from the image reading apparatus 2 shown in FIG. FIG. 4 is a diagram showing the internal structure of the scanning unit 41 in the image reading apparatus 2 shown in FIG. 4A shows a plan view thereof, and FIG. 4B shows a right side view thereof.

  The image reading apparatus 2 according to the present embodiment includes a scanning body SU provided with a contact image sensor 48 and a document placement table 40 on which the document G is placed, and the scanning body SU is arranged on one side in the sub-scanning direction Y. The image of the original G is read by the contact image sensor 48 by scanning the original G placed on the original placement table 40 while moving it to the right (in the drawing).

  The image reading apparatus 2 includes a scanning unit 41 provided on the upper surface of the apparatus main body 10 (see FIG. 1) and provided with a scanning body SU and a document placing table 40, and a document conveying unit disposed on the upper surface of the scanning unit 41. 61 (see FIGS. 1 and 2).

  The document transport unit 61 is provided to be rotatable about a pivot shaft along the sub-scanning direction Y on the back side (the side opposite to the operation side) which is one side in the main scanning direction X with respect to the scanning unit 41. The document table 40 in the scanning unit 41 is opened by being opened from the front side (operation side).

  The scanning unit 41 includes, in addition to the scanning body SU and the document placing table 40, a transparent flat plate-like document reading plate (specifically, a document reading glass 42), a transparent flat plate-like document placing plate (specifically, A document placing glass 43), a housing 44, and a driving unit MU (FIGS. 2 and 4) are provided.

  The scanning body SU is provided below the original reading glass 42 and the original placing glass 43 so as to be reciprocally movable along the sub-scanning direction Y with respect to the housing 44 and is driven by the driving unit MU. Yes.

  The image reading device 2 stops the scanning body SU at a position below the document reading glass 42 by the driving unit MU under the instruction of a control unit (not shown), and is transported by the document transporting unit 61 to be scanned by the document reading glass 42. An original movement reading operation for reading an image of the original G passing above, and the scanning body SU placed on the original placement glass 43 while moving the scanning body SU in the sub-scanning direction Y along the lower surface 43a of the original placement glass 43. The document fixing reading operation for reading the image of the original G is performed.

  Specifically, the document transport unit 61 (see FIG. 2) includes a document tray 62 on which the document G is placed, a reading side pickup roller 63 that pulls out the documents G placed on the document tray 62 one by one, and a reading side pickup. A document conveyance path 64 that guides the document G drawn by the roller 63 to the discharge side (below the document tray 62) through the document reading glass 42, and a document-side pickup roller 63 provided on the document conveyance path 64. The upstream intermediate conveyance roller 65 that conveys the drawn document G and the leading edge of the document G that is provided on the document conveyance path 64 and conveyed by the upstream intermediate conveyance roller 65 are aligned, and the document reading glass 42 of the document G is aligned. A reading-side registration roller 66 for adjusting the reading timing at the document, and a downstream intermediate conveyance for conveying the document G provided on the document conveyance path 64 and conveyed from the document reading glass 42. A roller 67, a reading side discharge roller 68 that discharges the original G that is provided on the original conveyance path 64 and is conveyed by the downstream intermediate conveyance roller 67, and is discharged to the outside by the reading side discharge roller 68. A document discharge tray 69 on which the document G is placed is provided.

  In the document transport unit 61 having such a configuration, the document G placed on the document tray 62 is pulled out by the reading-side pickup roller 63 and supplied to the document transport path 64. It is conveyed by the roller 65 toward the reading side registration roller 66. The original G conveyed to the reading side registration roller 66 is conveyed so that the leading edge is aligned by the reading side registration roller 66 and the image surface is in close contact with the upper surface of the original reading glass 42 at a predetermined reading timing. At this time, the contact image sensor 48 in the scanning body SU in a state stopped at a position below the document reading glass 42 reads an image of the document G conveyed along the upper surface of the document reading glass 42. Thereafter, the document G that has passed through the document reading glass 42 is discharged to a document discharge tray 69 by a reading side discharge roller 68 through a downstream intermediate conveyance roller 67.

  The document reading glass 42 is sized so that the reading unit 481 of the contact image sensor 48 can be accommodated (larger than the reading unit 481), and has a long shape (specifically, a rectangular shape). The document placing glass 43 is sized to accommodate the maximum size document G (larger than the large size document G), and has a long shape (specifically, a rectangular shape).

  The housing 44 is provided along the vertical direction Z (up and down direction), and includes side plates 44a and 44a that respectively constitute the front and back surfaces of the scanning unit 41 in the main scanning direction X, and the vertical direction Z (up and down direction). The side plates 44b and 44b that are respectively provided on both sides of the scanning unit 41 in the sub-scanning direction Y, and the upper surface of the scanning unit 41 are provided along the horizontal direction (main scanning direction X and sub-scanning direction Y). And an upper plate 44c having a long shape (specifically, a rectangular shape) opening Q (see FIG. 3) in the sub-scanning direction Y, and a horizontal direction (the main scanning direction X and the sub-scanning direction Y). ) And a bottom plate 44d that constitutes the bottom surface of the scanning unit 41.

  On the upper plate 44c of the housing 44, a document reading glass 42 disposed so that the longitudinal direction thereof faces the main scanning direction X, and a document placement glass 43 disposed so that the longitudinal direction thereof faces the sub scanning direction Y, Are arranged in parallel along the sub-scanning direction Y so as to cover the opening Q. Note that the document placing table 40 is constituted by the document placing glass 43 and the upper plate 44 c of the housing 44.

  Here, the size of the document reading glass 42 in the longitudinal direction (main scanning direction X) and the size of the document placement glass 43 in the short direction (main scanning direction X) are approximately the same, and the opening Q is The size in the short direction is smaller than the size in the longitudinal direction of the document reading glass 42 and the size in the short direction of the document placement glass 43, and the size in the longitudinal direction is the size in the short direction of the document reading glass 42. And the size in the longitudinal direction of the document placement glass 43 is larger than the total size.

  The scanning unit 41 further includes a holding member 45 (see FIGS. 2 and 3) that holds the document reading glass 42 and the document placing glass 43. The holding member 45 is provided so as to restrict any movement of the document reading glass 42 and the document placing glass 43 in the main scanning direction X, the sub-scanning direction Y, and the vertical direction Z with respect to the upper plate 44c of the housing 44. It has been.

  In the present embodiment, the holding member 45 is a rectangular frame member that holds four sides of the document reading glass 42 and one side of the document placing glass 43 on the document reading glass 42 side. The holding member 45 holds a side of the document reading glass 42 on the side of the document placement glass 43, both sides of the document reading glass 42 in the main scanning direction X, and a side of the document placement glass 43 on the side of the document reading glass 42. Part 46 and a second holding part 47 that holds the side of the original reading glass 42 opposite to the original placing glass 43.

  The first holding unit 46 contacts the end surface of the document reading glass 42 on the side of the document placement glass 43, both end surfaces of the document reading glass 42 in the main scanning direction X, and the end surface of the document placement glass 43 on the side of the document reading glass 42. ing. Further, the first holding unit 46 has a first pressing unit 46 a that presses the end of the document placing glass 43 on the side of the document reading glass 42.

  The first holding unit 46 a in the first holding unit 46 also serves as a document guide unit that regulates the movement of the document G placed on the document placement glass 43 toward the document reading glass 42 in the sub-scanning direction Y. The movement of the original G placed on the original placement glass 43 to one side (in this example, the back side) in the main scanning direction X is restricted by a cover member (not shown) that covers the housing 44. .

  The upper surface portion of the first holding unit 46 constitutes a part of a conveyance path that guides the document G conveyed from the document reading glass 42 in the document conveying unit 61 to the downstream side of the document reading glass 42.

  The second holding unit 47 is in contact with the end surface of the document reading glass 42 opposite to the document placing glass 43. The second holding unit 47 includes a second pressing portion 47 a that presses the end of the document reading glass 42 opposite to the document reading glass 42.

  The upper surface portion of the second holding unit 47 constitutes a part of a conveyance path that guides the document G conveyed from the upstream side of the document reading glass 42 to the document reading glass 42 in the document conveying unit 61.

  The first holding unit 46 is bonded to the end surface of the document reading glass 42 on the side of the document placing glass 43 and the end surface and upper surface of the document placing glass 43 on the side of the document reading glass 42. The second holding portion 47 is bonded to the end surface and the upper surface of the document reading glass 42 opposite to the document placement glass 43 side. That is, the document reading glass 42 and the document placement glass 43 are connected and integrated through the holding member 45.

  Further, in the first holding part 46, a part bonded to the upper surface of the document placement glass 43 is a first pressing part 46 a. The first pressing portion 46a is bonded to the document placing glass 43 via a film-like white reference member W (see FIG. 2). However, the present invention is not limited to this. The first pressing portion 46a is formed of a white material, and the first pressing portion 46a itself is used as a white reference member, or a white paint is applied to the back surface of the first pressing portion 46a. It may be applied to form a white reference member.

  In the present embodiment, the document reading glass 42 and the document placing glass 43 have the same thickness (see FIG. 2). The lower surface 42a of the document reading glass 42, the lower surface 43a of the document placement glass 43, the lower surface 46b of the first holding unit 46, and the lower surface 47b of the second holding unit 47 are the same plane, and will be described later in the scanning body SU. The sliding member 100 can slide smoothly.

  The scanning unit 41 further includes a guide unit 80 (not shown in FIGS. 2 and 3, see FIG. 4) that guides the scanning body SU along the sub-scanning direction Y.

  The guide unit 80 is disposed along the sub-scanning direction Y at the center of the housing 44 in the main scanning direction X, and supports the scanning body SU so as to be reciprocally movable along the sub-scanning direction Y. Yes.

  Specifically, the guide portion 80 is a rod-shaped (specifically, columnar) shaft, and spans both side plates 44b and 44b in the sub-scanning direction Y of the housing 44 in parallel with the sub-scanning direction Y. It is fixed.

  A base connection portion 76 is provided at the center in the main scanning direction X on the lower surface of the base bottom plate 72 (see FIGS. 2 and 4B) of the scanning base 71 in the scanning body SU. A guide sliding portion 76 a is formed on the base connection portion 76. The guide sliding portion 76 a has a shape corresponding to the shape of the outer periphery of the guide portion 80 (specifically, a concave portion having a circular arc shape in a plan view facing downward), and has a structure that slides on the guide portion 80. Yes. In this example, the scanning base 71 is placed on the guide part 80 via the base connection part 76 and is slidably supported along the sub-scanning direction Y with respect to the guide part 80. The guide portion 80 is not limited to a rod-shaped shaft, and may be a convex portion that protrudes upward from the bottom plate 44d in the housing 44 and extends in the sub-scanning direction Y, for example. .

  The drive unit MU has a pair of rotating shafts 81 and 82 fixed along the vertical direction Z in a state of being separated from the bottom plate 44 d in the housing 44 in the sub-scanning direction Y, and an axis line to the pair of rotating shafts 81 and 82. One of a pair of small pulleys 83 and 84 supported so as to be freely rotatable, an endless driven belt 85 wound around the pair of small pulleys 83 and 84, and a pair of small pulleys 83 and 84 ( In this example, a small pulley 84 on the side opposite to the initial position side of the scanning body SU in the sub-scanning direction Y (the right side in the drawing) is supported so as to be freely rotatable around the axis line (rotary shaft 82 in this example). A large pulley 86 connected to one small pulley 84, a drive motor 87 fixed to the bottom plate 44d of the housing 44 so that the output shaft 87a is along the vertical direction Z, and an output shaft 87a of the drive motor 87 are fixed. Driving pooh And 88, and a large pulley 86 and wound around an endless to the drive pulley 88 drives a belt 89. The scanning base 71 is fixed to a part of the driven belt 85 in the circumferential direction. Specifically, the scanning base 71 has a connecting portion 76 b that is connected to a part of the driven belt 85. The connecting portion 76b has a fitting groove 76c (see FIG. 4B) into which the driven belt 85 is fitted, and the driven belt 85 is sandwiched from both side surfaces by fitting the driven belt 85 into the fitting groove 76c. To hold.

  In the drive unit MU having such a configuration, the output shaft 87a of the drive motor 87 is rotationally driven under the instruction of a control unit (not shown), whereby the drive pulley 88 is rotated and the drive belt 89 is moved around. The large pulley 86 rotates, and accordingly, the small pulleys 84 and 83 rotate, and the driven belt 85 moves around. Accordingly, the output shaft 87a of the drive motor 87 is rotationally driven in the predetermined rotational direction and the reverse rotational direction, and the driven belt 85 is rotated in the predetermined rotational direction and the reverse rotational direction, thereby moving the scanning body SU in the sub-scanning direction Y. Can be moved back and forth.

  In this embodiment, the base connecting portion 76 including the guide sliding portion 76a and the connecting portion 76b is fixed to the scanning base 71. However, the present invention is not limited to this, and the guide sliding portion 76a and The connecting portion 76b and the base bottom plate 72 may be integrally formed.

  Further, a position sensor 49 is provided at a position corresponding to the detected piece 73 b protruding from the scanning base 71 on the side plate 44 b provided on the initial position side (left side in the drawing) of the scanning body SU in the sub-scanning direction Y. Is provided. In the position sensor 49, the light emitting element and the light receiving element are arranged to face each other, and the detected piece 73b that has entered between the light emitting element and the light receiving element is detected. A control unit (not shown) can position the scanning body SU at an initial position below the document reading glass 42 based on the detection result of the position sensor 49.

[Scanning body]
(First embodiment)
Next, the scanning body SU according to the first embodiment will be described below with reference to FIGS.

  FIG. 5 is an exploded perspective view showing the contact image sensor 48 and the scanning base 71 in the scanning body SU according to the first embodiment in an exploded manner.

  FIG. 6 is an external view showing a state in which the contact image sensor 48 and the scanning base 71 are combined in the scanning body SU according to the first embodiment. FIG. 6 (a) shows a plan view thereof, and FIG. 6 (b) shows a right side view thereof. FIG. 7 is a front view showing a state in which the contact image sensor 48 and the scanning base 71 in the scanning body SU shown in FIG. 6 are combined.

  FIG. 8 is a perspective view of the contact image sensor 48 in the scanning body SU according to the first embodiment. FIG. 9 is an external view of the contact image sensor 48 in the scanning body SU according to the first embodiment. FIG. 9A shows a plan view thereof, and FIG. 9B shows a right side view thereof. FIG. 10 is a schematic sectional view of the contact image sensor 48 shown in FIGS.

  FIG. 11 is a perspective view of the scanning base 71 in the scanning body SU according to the first embodiment. FIG. 12 is an external view of the scanning base 71 in the scanning body SU according to the first embodiment. FIG. 12 (a) shows a plan view thereof, and FIG. 12 (b) shows a right side view thereof. FIG. 13 is a front view of the scanning base 71 shown in FIGS. 11 and 12.

  The scanning body SU according to the present embodiment has the contact-type image sensor 48 so that the contact-type image sensor 48 approaches or separates from the document placement table 40 (see FIG. 2) (in the vertical direction Z in this example). A scanning base 71 that is movably supported and a biasing member 90 that biases the contact image sensor 48 toward the document placement table 40 are further provided. In the present embodiment, the urging member 90 is a pair of urging members 90 and 90 provided apart from each other in the main scanning direction X of the scanning body SU, and can be, for example, a coil spring. .

  The contact image sensor 48 (see FIGS. 5 to 10) is a so-called CIS (Contact Image Sensor), and has a long shape in the main scanning direction X.

  The contact-type image sensor 48 (see FIG. 10) includes a light source 51 that illuminates the original G, a condensing lens array 52 that condenses the reflected light that is illuminated by the light source 51 and reflected from the original G, and a condensing lens. An imaging element 53 is provided that photoelectrically converts reflected light from the original G received through the array 52 and outputs image data. The image sensor 53 includes light receiving elements arranged in the main scanning direction X, scans the document G in the main scanning direction X, and reflects light from the document G at the reading unit 481 on the upper surface 484 of the contact image sensor 48. Is supposed to read.

  Specifically, the contact image sensor 48 includes a housing 482 (specifically, an exterior cover that is an exterior member) that houses the light source 51, the condenser lens array 52, and the imaging element 53. The housing 482 is formed of resin or the like, and has a box shape extending in the main scanning direction X (specifically, a hexahedral shape in which each adjacent surface is a right angle or a substantially right angle), The upper surface 484 has an opening 483 (see FIG. 10) extending along the main scanning direction X. A transparent lens fixing portion 54 that fixes the condenser lens array 52 is provided in the opening 483.

  The contact-type image sensor 48 is provided on one of the side surfaces in the sub-scanning direction Y (in this example, the side surface 48d on the right side when viewed from the front) at a predetermined interval in the main scanning direction X. It has a pair of sensor side supported parts 48a, 48a to be supported. The sensor-side supported portions 48a and 48a are formed with supported portions (supported shafts 48b and 48b in this example) that are supported so as to be movable in the vertical direction Z with respect to the scanning base 71. Specifically, the pair of sensor-side supported portions 48a, 48a protrude from the housing 482 to one side in the sub-scanning direction Y (the right side in the figure), and the pair of supported shafts 48b, 48b The side supported portion 48a protrudes from the end surface on one side (back side in this example) in the main scanning direction X to one side (back side in this example) in the main scanning direction X.

  The contact image sensor 48 is provided with a pair of sensor-side holding portions 48c and 48c (FIGS. 6A and 9) that are provided on the lower surface at a predetermined interval in the main scanning direction X and hold the biasing member 90. See). The sensor side holding portion 48c is formed so as to be recessed above the lower surface of the contact image sensor 48, and one end of the urging member 90 is inserted and held therein.

  The scanning base 71 (see FIGS. 5 to 7 and FIGS. 11 to 13) supports the contact image sensor 48 in a state of being biased toward the document placement table 40 and is long in the main scanning direction X. It is a simple shape.

  The scanning base 71 accommodates the contact image sensor 48 so that the longitudinal direction thereof is directed to the main scanning direction X and the reading unit 481 is directed to the document placement table 40 and is movably supported in the vertical direction Z. It is supposed to be.

  The scanning base 71 corresponds to a pair of sensor-side supported portions 48a and 48a in the contact image sensor 48 on any one side surface in the sub-scanning direction Y (in this example, the right outer surface 74a when viewed from the front). It has a pair of scanning base side support parts 74b and 74b provided in the position. Each of the scanning base side support portions 74b and 74b is formed with a support portion (support holes 74c and 74c in this example) that supports the contact image sensor 48 so as to be movable in the vertical direction Z.

  Specifically, the scanning base 71 has a box shape with an upper surface opened and extending in the main scanning direction X. That is, the scanning base 71 includes a base bottom plate 72 along the horizontal direction, and one base side plate 73 that is vertically or substantially perpendicular to both ends of the base bottom plate 72 in the sub-scanning direction Y and faces each other. And the other side base side plate 74 and a sensor support side plate 75 erected at a right angle or a substantially right angle on one side (the back side in this example) of the base bottom plate 72 in the main scanning direction X. In the present embodiment, the base bottom plate 72, the one side base side plate 73, the other side base side plate 74, and the sensor support side plate 75 are integrally formed to constitute the scanning base 71. The scanning base 71 can be formed of, for example, an acrylonitrile / butadiene / styrene copolymer (ABS resin).

  The other base side plate 74 is provided with a pair of support holes 74c and 74c into which the pair of supported shafts 48b of the contact image sensor 48 are respectively inserted. The support hole 74c is formed along the main scanning direction X, and is a long hole extending in the vertical direction Z that moves the supported shaft 48b in the vertical direction Z. The length of the support hole 74c in the main scanning direction X is larger than the length of the supported shaft 48b in the main scanning direction X, and the width in the sub-scanning direction Y smoothly moves in the vertical direction Z along the supported shaft 48b. This is slightly larger than the diameter of the supported shaft 48b.

  Further, the base bottom plate 72 is provided at a position facing the pair of sensor side holding portions 48c, 48c in the contact image sensor 48 on the upper surface, respectively, and a pair of base side holding portions 72a holding the biasing member 90. 72a (see FIG. 5, FIG. 6 (a), FIG. 11 and FIG. 12 (a)). The base side holding portion 72a is formed to be recessed below the upper surface of the base bottom plate 72, and the other end of the urging member 90 is inserted and held in the base side holding portion 72a. . As a result, the base-side holding portion 72a and the sensor-side holding portion 48c opposite thereto hold the both ends of the urging member 90 (see FIGS. 5 and 6A), so that the contact-type image sensor 48 is removed. Can be positioned.

  In the scanning body SU having such a configuration, when the contact image sensor 48 and the scanning base 71 are combined, first, the other ends of the pair of urging members 90 and 90 are held by the pair of bases on the base bottom plate 72. The contact-type image sensor 48 is held in the portions 72a and 72a, and the contact-type image sensor 48 is placed in an oblique posture around the axis along the main scanning direction X, with the supported shaft 48b facing the support hole 74c. The pair of supported shafts 48b and 48b are inserted into the pair of support holes 74c and 74c, respectively, by moving to one side in the main scanning direction X (back side in this example). Next, the contact-type image sensor 48 is rotated around the supported shaft 48b, and one end of the pair of biasing members 90, 90 is held by the sensor-side holding portions 48c, 48c on the lower surface of the contact-type image sensor 48, The contact image sensor 48 is accommodated in the scanning base 71. Here, since the pair of support holes 74 c inserted into the pair of supported shafts 48 b and 48 b are elongated holes along the vertical direction Z, the contact type image sensor 48 is perpendicular to the scanning base 71. The urging member 90 is sandwiched between the contact image sensor 48 and the scanning base 71, so that the contact image sensor 48 can be supported with respect to the scanning base 71. It can be urged toward the document table 40.

  In the present embodiment, the sensor support side plate 75 is provided on the inner side surface thereof with a sensor support portion 75a that contacts the side surface on one side (in this example, the back side) of the contact image sensor 48 in the main scanning direction X. . In the present embodiment, the sensor support portion 75a is a pair of ribs extending along the vertical direction Z with an interval in the sub-scanning direction Y from the viewpoint of suppressing frictional resistance with the contact image sensor 48. The sensor support side plate 75 is formed so as to protrude inward from the inner side surface.

  A sensor that restricts the movement of the contact image sensor 48 to the other side in the main scanning direction X at the other end of the base bottom plate 72 in the main scanning direction X (the side opposite to the sensor support side plate 75). A movement restricting portion 72b is provided. The sensor movement restricting portion 72 b is formed so as to stand upright at a right angle or substantially at a right angle from the other end portion in the main scanning direction X of the base bottom plate 72.

  5 to FIG. 7 and FIG. 11 to FIG. 13 will be described later with reference numerals not described.

[Sliding member]
FIG. 14 is an external view showing the sliding member 100 in the scanning body SU according to the first embodiment. FIG. 14A shows the front view, and FIG. 14B shows the left and right side views. Since the sliding member 100 has the same shape when viewed from the left and right side surfaces, it is shown in one drawing in FIG.

  FIG. 15 is a perspective view showing the scanning body SU according to the first embodiment. FIG. 16 is an external view showing the scanning body SU according to the first embodiment. FIG. 16 (a) shows a plan view thereof, and FIG. 16 (b) shows a right side view thereof. FIG. 17 is a front view of the scanning body SU according to the first embodiment. FIG. 18 is a cross-sectional view along the arrow DD line shown in FIG. FIG. 19 is a cross-sectional view taken along the line EE shown in FIG. FIG. 20 is a cross-sectional view taken along the line FF shown in FIG.

  The scanning body SU further includes a sliding member 100. The sliding member 100 includes a contact surface (specifically, an upper surface 484) of the contact image sensor 48 and the contact image sensor 48 (refer to FIG. 2) and a contact surface (this surface of the document mount table 40). In the example, it is provided between the lower surface 43a) of the document placing glass 43 and is slid on the surface facing the contact image sensor 48 of the document placing table 40 (in this example, the lower surface 43a of the document placing glass 43). Is.

  The scanning body SU is configured by attaching the sliding member 100 in a state where the contact image sensor 48 and the scanning base 71 are combined (see FIGS. 6 and 7).

  The sliding member 100 is preferably formed of a material having slidability. By doing so, the wear of the sliding member 100 due to frictional resistance can be effectively prevented, and the contact image sensor 48 can be moved smoothly. The sliding member 100 can be made of, for example, polyoxymethylene (POM).

  The sliding member 100 is moved toward or away from the document placing table 40 (in this example, the document placing glass 43) and allowed to move with respect to the scanning base 71 (this). In the example, it is movable in the vertical direction Z) and is related to both side surfaces of the scanning base 71 in the sub-scanning direction Y (in this example, the outer side surface 73a of the one side base side plate 73 and the outer side surface 74a of the other side base side plate 74). Are combined.

  The sliding member 100 preferably has elasticity. By doing so, the sliding member 100 can be easily elastically deformed, whereby the sliding member 100 can be easily attached to the scanning base 71.

  Specifically, the sliding member 100 includes a sliding portion 101 disposed between the contact image sensor 48 and the document placing table 40 (in this example, the document placing glass 43), and the sub scanning direction of the sliding portion 101. A document is placed along both outer surfaces in the sub-scanning direction Y of the scanning base 71 from both ends of Y (in this example, the outer surface 73a of the one side base side plate 73 and the outer side surface 74a of the other side base side plate 74). A pair of extending portions 102 and 103 extending to the opposite side (specifically, the lower side) from the mounting table 40 side are provided.

  Engaging portions 102b and 103b are provided on the side surfaces of the pair of extending portions 102 and 103 facing the scanning base 71 (in this example, the inner side surfaces 102a and 103a facing each other).

  Engaged portions that engage with the engaging portions 102b and 103b are formed on both outer side surfaces in the sub-scanning direction Y of the scanning base 71 (in this example, outside of the one side base side plate 73 and the other side base side plate 74). 73d and 74d are provided.

  Note that the pair of extending portions 102 and 103 extend from both end portions in the sub-scanning direction Y of the sliding portion 101 to both inner side surfaces in the sub-scanning direction Y of the scanning base 71 (in this example, one side base side plate 73 The inner side surface 73e and the inner side surface 74e) of the other base side plate 74 may extend to the side opposite to the document placing table 40 side. In this case, the engaging portions 102b and 103b are provided on the outer side surfaces of the pair of extending portions 102 and 103 in the sub-scanning direction Y, and both inner side surfaces of the scanning base 71 in the sub-scanning direction Y (in this example, one side base) The engaged portions 73d and 74d can be provided on the inner side surface 73e of the side plate 73 and the inner side surface 74e) of the other side base side plate 74.

  In the present embodiment, the engagement of the sliding member 100 with respect to the scanning base 71 is an uneven engagement. For example, the engaging portions 102b and 103b may be convex portions, and the engaged portions 73d and 74d may be concave portions, while the engaging portions 102b and 103b may be concave portions, 73d and 74d may be convex portions. One of the engaging portions 102b and 103b is a convex portion, the other is a concave portion, and one of the engaged portions 73d and 74d is a concave portion and the other is a convex portion. Also good. In this example, the engaging portions 102b and 103b are convex portions, and the engaged portions 73d and 74d are concave portions.

  In the present embodiment, the engaging portions 102 b and 103 b and the engaged portions 73 d and 74 d are configured to guide relative movement of the sliding member 100 in the vertical direction Z with respect to the scanning base 71.

  Specifically, the sliding portion 101 (see FIG. 14) of the sliding member 100 has a linear shape extending in the sub-scanning direction Y, and contacts with the upper surface 484 of the contact image sensor 48. 101a and a sliding contact portion 101b that slidably contacts a surface (in this example, a lower surface 43a of the document placement glass 43) facing the contact image sensor 48 of the document placement table 40. Here, the contact portion 101 a is a flat surface that is in full contact with the flat upper surface 484 of the contact image sensor 48, and the sliding contact portion 101 b in the sliding portion 101 is in line contact or a point with respect to the document placement table 40. The shape in contact with each other, specifically, the end (top) on the side of the document placing table 40 faces the contact type image sensor 48 of the document placing table 40 (in this example, the lower surface 43a of the document placing glass 43) and sub-scanning. The shape is a line contact or a point contact along the direction Y. By doing so, it is possible to suppress the frictional resistance between the sliding contact portion 101b and the surface facing the contact image sensor 48 of the document placing table 40 (in this example, the lower surface 43a of the document placing glass 43).

  The shape of the sliding contact portion 101b that is in line contact with the surface facing the contact image sensor 48 of the document placement table 40 (in this example, the lower surface 43a of the document placement glass 43) along the sub-scanning direction Y is, for example, An aspect formed in a dome shape (arc shape in cross section) along the scanning direction Y and an embodiment formed in a triangular prism shape (triangle shape in cross section) along the sub-scanning direction Y can be exemplified. The shape of the sliding contact portion 101b that makes point contact with the surface of the document placement table 40 facing the contact image sensor 48 (in this example, the lower surface 43a of the document placement glass 43) includes, for example, a plurality of shapes along the sub scanning direction Y. The aspect currently formed in the shape which arranged the spherical protrusion of this in parallel can be mentioned. In this example, the sliding contact portion 101b is formed in a dome shape along the sub-scanning direction Y.

  Further, the upper surfaces of both end portions of the sliding portion 101 in the sub-scanning direction Y are inclined so as to gradually move away from the document placing table 40 toward the both outer sides in the sub-scanning direction Y (downward as going to both outer sides). An inclined surface 101c is formed. As a result, the frictional resistance of the sliding contact portion 101b with the surface facing the contact image sensor 48 of the document placing table 40 (in this example, the lower surface 43a of the document placing glass 43) can be further suppressed, and the second holding. The boundary between the lower surface 47b of the portion 47 (see FIG. 2) and the lower surface 42a of the document reading glass 42, and between the lower surface 42a of the document reading glass 42 and the lower surface 46b of the first holding unit 46 (see FIG. 2). At the boundary portion between the boundary portion and the lower surface 46b of the first holding portion 46 and the facing surface of the contact image sensor 48 of the document placement table 40 (in this example, the lower surface 43a of the document placement glass 43), the scanning body SU is moved to the sub-surface. Smooth reciprocation in the scanning direction Y can be achieved.

  From the viewpoint of further suppressing the frictional resistance between the surface of the sliding contact portion 101b facing the contact image sensor 48 of the document placement table 40 (in this example, the lower surface 43a of the document placement glass 43), the sliding contact portion 101b. In the central portion in the sub-scanning direction Y, a recess (for example, a V-shaped groove) along the main scanning direction X may be formed.

  Each of the pair of extending portions 102 and 103 has a linear shape extending in the vertical direction Z, and has inner side surfaces 102a and 103a facing each other. Here, the inner side surfaces 102a and 103a are perpendicular to or substantially perpendicular to the contact portion 101a, and are formed in parallel or substantially parallel to each other outside the one side base side plate 73 and the other side base side plate 74, respectively. The distance d1 (see FIG. 17) between the inner side surfaces 102a and 103a is such that the sliding member 100 can smoothly move relative to the scanning base 71 so that the outer side surface 73a and the other side of the one side base side plate 73 can be moved. It is slightly larger than the distance d2 (see FIG. 17) of the outer side surface 74a of the base side plate 74.

  The engaging portions 102b and 103b are convex portions projecting inward from the inner side surfaces 102a and 103a at the lower ends of the pair of extending portions 102 and 103. Here, the engaging portions 102b and 103b have a rod-like shape (specifically, a columnar shape) extending along the sub-scanning direction Y. Note that the engaging portions 102b and 103b are not limited to a cylindrical shape, and may have a prismatic shape such as a quadrangular prism.

  The engaging portions 102b and 103b have top portions (tip surfaces 102c and 103c) that are flush or substantially flush with the inner side surface 73e of the one side base side plate 73 and the inner side surface 74e of the other side base side plate 74, or one side base. It is preferable to protrude slightly inward from the inner side surface 73e of the base side plate 73 and the inner side surface 74e of the other side base side plate 74. In this example, the engaging portions 102b and 103b have apexes (tip surfaces 102c and 103c) protruding slightly inward from the inner side surface 73e of the one side base side plate 73 and the inner side surface 74e of the other side base side plate 74. .

  In the present embodiment, the sliding portion 101, the pair of extending portions 102 and 103, and the engaging portions 102b and 103b are integrally formed to constitute the sliding member 100.

  In the present embodiment, the sliding member 100 is provided at both ends of the scanning base 71 in the sub-scanning direction Y. Therefore, the engaged portions 73 d and 74 d provided on the scanning base 71 are located at both ends in the main scanning direction X of the scanning base 71.

  The engaged portions 73d are a pair of concave portions provided at both end portions in the main scanning direction X of the one side base side plate 73. The engaged portion 73 d has a vertical through hole extending upward from the lower end in the vertical direction Z at the lower end portion of the one side base side plate 73, and the vertical penetration at the end portion on the one side base side plate 73 side of the base bottom plate 72. It consists of a horizontal through hole that communicates with the lower end of the hole and extends toward the other base side plate 74 side.

  The engaged portions 74d are a pair of recesses provided at both ends in the main scanning direction X of the other base side plate 74. The engaged portion 74 d has a vertical through hole extending upward from the lower end in the vertical direction Z at the lower end portion of the other base side plate 74, and the vertical penetration at the other base side plate 74 side end portion of the base bottom plate 72. It consists of a horizontal through hole communicating with the lower end of the hole and extending toward the one side base plate 73 side.

  The length of the vertical through hole in the engaged portions 73d and 74d in the vertical direction Z is longer than the distance that the sliding member 100 moves relative to the scanning base 71 in the vertical direction Z. The length of the horizontal through hole in the engaged portions 73d and 74d in the sub-scanning direction Y is larger than the length of the engaging portions 102b and 103b in the sliding member 100 in the sub-scanning direction Y. The sizes of the vertical and horizontal through holes in the engaged portions 73d and 74d in the main scanning direction X are such that the engaging portions 102b and 103b in the sliding member 100 move smoothly relative to the engaged portions 73d and 74d. It is slightly larger than the size of the engaging portions 102b and 103b in the main scanning direction X as much as possible.

  The top portions (upper end portions) of the vertical through holes in the engaged portions 73d and 74d have a shape corresponding to the outer shape of the engaging portions 102b and 103b in the sliding member 100 (specifically, a semicircular shape in a side view). It is formed (see FIG. 11 and FIG. 12B).

  The engaged portions 73d and 74d are not limited to the through holes, and are grooves formed so as to extend in the vertical direction Z outside the one side base side plate 73 and the other side base side plate 74. The engaging portions 102b and 103b may protrude so that the top portions (tip portions) fit within the engaged portions 73d and 74d of the one side base side plate 73 and the other side base side plate 74, respectively.

  In the scanning body SU described above, when the sliding member 100 is attached to the scanning base 71 in a state in which the contact image sensor 48 and the scanning base 71 are combined (see FIGS. 6 and 7), for example, the scanning base The sliding member 100 is disposed above the engaged portions 73d and 74d of the table 71 so as to face the sub-scanning direction Y, and the sliding members 100 are arranged so that the extending portions 102 and 103 open outward in the sub-scanning direction Y. (Specifically, the sliding portion 101 and / or the extending portions 102 and 103) are elastically deformed so that the engaging portions 102b and 103b are arranged on both outer surfaces in the sub-scanning direction Y of the scanning base 71 (specifically, one of them). The outer side surface 73a of the side base side plate 73 and the outer side surface 74a) of the other side base side plate 74 are brought into contact with each other. The engaging portions 102b and 103b are arranged on both outer surfaces in the sub-scanning direction Y of the scanning base 71 (specifically, the outer surface 73a of the one side base side plate 73 and the outer side surface 74a of the other side base side plate 74). When the engaging portions 102b and 103b reach the engaged portions 73d and 74d, the sliding member 100 (specifically, the sliding portion 101 and / or the extending portions 102 and 103) is moved. Returning to the original shape, the engaging portions 102b and 103b are naturally engaged with the engaged portions 73d and 74d. As described above, when the engaging portions 102b and 103b are engaged with the engaged portions 73d and 74d, the engaging portions 102b and 103b are engaged with a simple operation of moving the sliding member 100 downward. Therefore, the sliding member 100 can be easily attached to the scanning base 71, thereby facilitating assembly workability.

  As described above, according to the first embodiment, since the sliding member 100 is provided on the scanning base 71, it is necessary to perform processing such as providing the sliding member 100 on the contact image sensor 48. Absent. Thereby, an inexpensive general-purpose product can be used as the contact image sensor 48. Furthermore, since the sliding member 100 is engaged with the scanning base 71, the sliding member 100 can be easily replaced. In addition, the sliding base 100 is arranged so as to approach or move away from the document placing table 40 (in this example, the document placing glass 43) and to allow movement relative to the scanning base 71. 71 is engaged with both side surfaces in the sub-scanning direction Y, the frictional resistance between the both side surfaces of the scanning base 71 and the sliding member 100 can be made as small as possible. Even if it is pushed into the scanning base 71 or the scanning base 71 is separated from the document placing table 40 (in this example, the document placing glass 43), the sliding member 100 is moved to the contact image sensor. 48 can be smoothly moved relative to the scanning base 71 supporting the original 48 on the original placement table 40 in the approaching direction and the separation direction. It is possible to reliably secure the point distance.

  In the first embodiment, the sliding member 100 is engaged with the scanning base 71 so as to be movable in the vertical direction Z, so that the scanning base 71 is not limited to the document placement table 40 (this example). In this case, the sliding member 100 can be reliably moved in the vertical direction Z with respect to the scanning base 71 even if it is separated from the original placing glass 43). It is possible to easily maintain a state in which the posture is maintained parallel to the.

  In the first embodiment, the sliding member 100 includes a sliding portion 101 disposed between the contact image sensor 48 and the document placing table 40 (document placing glass 43 in this example), and a sliding member. A pair of extending portions 102 and 103 extending from both ends of the portion 101 in the sub-scanning direction Y along the opposite side surfaces of the scanning base 71 in the sub-scanning direction Y to the side opposite to the document placing table 40 side. As a result, the sliding member 100 can be attached to and detached from the scanning base 71 with a simple configuration. Engaging portions 102b and 103b are provided on the side surfaces (in this example, the inner side surfaces 102a and 103a) of the pair of extending portions 102 and 103 that face the scanning base 71, and the scanning base 71 in the sub-scanning direction Y is provided. Engaged portions 73d and 74d that engage with the engaging portions 102b and 103b are provided on both side surfaces (in this example, the outer surface 73a of the one side base side plate 73 and the outer side surface 74a of the other side base side plate 74). Therefore, the movable engagement of the sliding member 100 in the vertical direction Z with respect to the scanning base 71 can be easily realized.

  Further, in the first embodiment, the engagement of the sliding member 100 with respect to the scanning base 71 is an uneven engagement, so that the sliding member 100 is attached to the scanning base 71 with a simple configuration. And can be easily engaged.

[Second to Fourth Embodiments]
Next, the scanning body SU according to the second to fourth embodiments will be described below with reference to FIGS. 21 to 30.

  The scanning body SU according to the second to fourth embodiments is similar to the scanning body SU according to the first embodiment in that at least one side surface of the scanning base 71 in the sub-scanning direction Y (both sides in this example). A pair of guide portions (731, 732), (741, 742) for guiding the movement of the extension portions 102, 103 in the vertical direction Z on both sides of the extension portions 102, 103 in the main scanning direction X. Is provided.

  In the second to fourth embodiments, as described above, the main scanning of the extending portions 102 and 103 on at least one side surface (both side surfaces in this example) of the scanning base 71 in the sub-scanning direction Y is performed. By providing a pair of guide portions (731, 732) and (741, 742) for guiding the movement of the extending portions 102, 103 in the vertical direction Z on both sides in the direction X, the scanning base 71 is supported. Thus, the sliding member 100 can be stably moved relative to the vertical direction Z.

  Specifically, the pair of guide portions (731, 732) and (741, 742) continuously extend along the vertical direction Z so as to be parallel to each other. A distance d3 (see FIG. 22) between the pair of guide portions (731, 732), (741, 742) in the main scanning direction X is an extended portion that allows the extended portions 102, 103 to move smoothly in the vertical direction Z. 102 and 103 are slightly larger than the width d4 (see FIG. 22) in the main scanning direction X. In this embodiment, in addition to the base bottom plate 72, the one side base side plate 73, the other side base side plate 74, and the sensor support side plate 75, a pair of guide portions (731, 732), (741, 742) are provided. The scanning base 71 is formed integrally.

(Second Embodiment)
FIG. 21 is a perspective view showing a scanning body SU according to the second embodiment. FIG. 22 is an enlarged plan view showing both end portions in the main scanning direction X of the scanning body SU according to the second embodiment. FIG. 23 is an enlarged right side view showing both ends in the main scanning direction X of the scanning body SU according to the second embodiment, and FIG. 24 is a main scanning direction X of the scanning body SU according to the second embodiment. FIG.

  By the way, in the scanning body SU according to the first embodiment, from the viewpoint of smoothly moving the sliding member 100 in the vertical direction Z with respect to the scanning base 71, the pair of extending portions 102 and 103 and the scanning base are provided. Reference numeral 71 denotes engaging portions 102 b and 103 b in the pair of extending portions 102 and 103 and engaged portions in the scanning base 71 when the sliding member 100 moves relative to the scanning base 71 in the vertical direction Z. In order to suppress the frictional resistance with 73d and 74d, the contact area between the engaging portions 102b and 103b and the engaged portions 73d and 74d is made as small as possible. In this example, the pair of extending portions 102 and 103 rotate about a rotation axis (specifically, cylindrical engaging portions 102b and 103b) along the sub-scanning direction Y with respect to the scanning base 71. Freely engaged. By doing so, the sliding member 100 can be smoothly moved relative to the scanning base 71 in the vertical direction Z with the frictional resistance suppressed as much as possible.

  In addition, the pair of guide portions (731, 732), (741, 742) are arranged with the extending portions 102, 103 from the viewpoint of smoothly moving the sliding member 100 in the vertical direction Z with respect to the scanning base 71. It is preferable to reduce the contact area as much as possible.

  In addition, the sliding member 100 can be sized in the main scanning direction X of the housing 482 in the contact image sensor 48 from the viewpoint of configuration (for example, from the viewpoint of realizing compactness in the two main scanning directions X of the image reading apparatus). In this example, the sliding portion 101 has an end portion in the main scanning direction X of the contact image sensor 48, more specifically, in the main scanning direction X of the housing 482 in the contact image sensor 48. It is arranged at a position close to (more adjacent to) the exterior edge 48e inside the exterior edge 48e, which is an edge (see FIG. 22). In this case, the pair of extending portions 102 and 103 are rotatable with respect to the scanning base 71 around a rotation axis (specifically, cylindrical engaging portions 102b and 103b) along the sub-scanning direction Y. When engaged, the pair of extending portions 102 and 103 rotate outward in the main scanning direction X around the rotation axis along the sub-scanning direction Y, and the sliding portion 101 of the contact image sensor 48 is rotated. The top surface 484 may fall off. This is because, as in the present embodiment, the sliding contact portion 101b is in line contact or point contact with the document placement table 40, more specifically, the surface of the document placement table 40 facing the contact image sensor 48 ( In this example, the lower surface 43a of the document placement glass 43) is formed in a shape that makes line contact or point contact along the sub-scanning direction Y (in this example, a dome shape along the sub-scanning direction Y). , Especially noticeable.

  In this regard, in the second embodiment, as shown in FIGS. 21 to 24, the sliding portion 101 is an end portion in the main scanning direction X of the contact image sensor 48, specifically, a housing 482 in the contact image sensor 48. Of the pair of guide portions (731, 732) and (741, 742) for guiding the extending portions 102 and 103, when arranged at a position close to the exterior edge 48e inside the exterior edge 48e. One of the guide portions 731 and 741 (see FIGS. 23 and 24) on the outer side in the scanning direction X is independent of the movement of the extending portions 102 and 103 in the vertical direction Z due to the movement of the scanning body SU in the sub-scanning direction Y. In addition, at least the rotation axis of the extended portions 102 and 103 (specifically, the cylindrical engaging portions 102b and 103b) is guided on the portion of the original document table 40 (specifically, the upper side). It is provided. That is, one guide portion 731, 741 on the outer side only needs to be able to guide a portion closer to the document placement table 40 than the rotation axis of the extending portions 102, 103, and more than the rotation axis of the extending portions 102, 103. It may be provided so as to guide only the portion on the document placement table 40 side, or both the portion on the document placement table 40 side and the portion on the opposite side (specifically, the lower side) from the document placement table 40 side. It may be provided to guide.

  In this example, one of the guide portions 731 and 741 on the outer side is the document placement table in the vertical direction Z regardless of the movement of the extending portions 102 and 103 in the vertical direction Z due to the movement of the scanning body SU in the sub-scanning direction Y. 40 end portions (top surfaces 731a and 741a) are located closer to the document placement table 40 than the rotation axes of the extending portions 102 and 103, and are opposite to the document placement table 40 side in the vertical direction Z. (Bottom surfaces 731b and 741b) are provided so as to be located on the opposite side of the original placing table 40 side with respect to the rotation axis of the extending portions 102 and 103.

  One guide portions 731 and 741 on the outer side of the other guide portions 732 and 742 whose end portions (top surfaces 731a and 741a) on the document placement table 40 side in the vertical direction Z are on the inner side in the main scanning direction X are arranged. It is provided so as to be located closer to the document placement table 40 (specifically, the upper side) than the end (top surfaces 732a, 742a) on the document placement table 40 side in the vertical direction Z (left side of FIG. 23 and FIG. 24). reference).

  Further, in the second embodiment, the other guide portions 732 and 742 (see FIGS. 23 and 24) on the inner side are in the vertical direction Z of the extending portions 102 and 103 due to the movement of the scanning body SU in the sub-scanning direction Y. Regardless of the movement, at least the rotation axis of the extending portions 102 and 103 (specifically, the cylindrical engaging portions 102b and 103b) is on the opposite side (specifically, the lower side) from the document placement table 40 side. ) To guide the part. That is, the other guide portions 732 and 742 on the inner side only need to be able to guide a portion of the extending portions 102 and 103 on the side opposite to the document placement table 40 side relative to the rotation axis of the extending portions 102 and 103. It may be provided so as to guide only the portion on the opposite side to the document placement table 40 side from the moving axis, or the portion on the document placement table 40 side (specifically, the upper side) and the document placement table 40 side. May be provided to guide both of the opposite portions.

  In this example, the other guide portions 732 and 742 on the inner side are the document placement table in the vertical direction Z regardless of the movement of the extending portions 102 and 103 in the vertical direction Z due to the movement of the scanning body SU in the sub-scanning direction Y. Ends (bottom surfaces 732b, 742b) opposite to the 40 side are located on the side opposite to the document placing table 40 side with respect to the rotation axes of the extending portions 102, 103, and the document placing table 40 side in the vertical direction Z The end portions (top surfaces 732a and 742a) of the extending portions 102 and 103 are provided so as to be positioned closer to the document placement table 40 than the rotation axes of the extending portions 102 and 103.

  In the second embodiment, the end (top surface 71a) of the scanning base 71 in the vertical direction Z on the side of the document placement table 40 is the end of the sliding member 100 on the side of the document placement table 40 in the vertical direction Z. It is located on the opposite side (specifically, the lower side) of the original document table 40 in the vertical direction Z from the sliding contact portion 101b (in this example, from the upper surface 484 of the contact image sensor 48), and is outside. One of the guide portions 731 and 741 has an end portion (top surface 731a and 741a) on the document placement table 40 side in the vertical direction Z and an end portion (top surface 71a) on the document placement table 40 side in the vertical direction Z of the scanning base 71. ).

  Specifically, one of the guide portions 731 and 741 on the outer side has end portions (top surfaces 731 a and 741 a) on the side of the document placing table 40 in the vertical direction Z at one side base side plate 73 and the other side base side plate 74. Is provided so as to be positioned at an end portion (top surface 71a) on the document placing table 40 side in the vertical direction Z.

  As described above, according to the second embodiment, one of the pair of guide portions (731, 732), (741, 742) for guiding the extending portions 102, 103 is located outside in the main scanning direction X. The guide portions 731 and 741 are configured to guide at least the rotation axis of the extending portions 102 and 103 (specifically, the columnar engaging portions 102b and 103b) closer to the document placing table 40, and The other end portions (top surfaces 731a and 741a) in the vertical direction Z on the side of the document placing table 40 are the end portions on the side of the document placing table 40 in the vertical direction Z of the other guide portions 732 and 742 on the inner side in the main scanning direction X ( The top surface 732a, 742a) is provided so as to be positioned closer to the document placement table 40, so that the contact area with the extended portions 102, 103 of one of the guide portions 731, 741 on the outside is possible. The sliding member 100 can be smoothly moved relative to the scanning base 71 in the vertical direction Z in a state where the number of the extending portions 102 and 103 is reduced, and the rotation axis along the sub-scanning direction Y of the pair of extending portions 102 and 103 The rotation to the outside in the main scanning direction X (specifically, the cylindrical engaging portions 102b and 103b) can be effectively prevented, and thereby the contact type image sensor 48 of the sliding portion 101 can be prevented. Omission from the upper surface 484 can be avoided. This is because, as in the present embodiment, the sliding contact portion 101b is in line contact or point contact with the document placement table 40, more specifically, the surface of the document placement table 40 facing the contact image sensor 48 ( In this example, the lower surface 43a of the document placement glass 43) is formed in a shape that makes line contact or point contact along the sub-scanning direction Y (in this example, a dome shape along the sub-scanning direction Y). , Especially effective.

  Further, in the second embodiment, the other guide portions 732 and 742 on the inner side are at least a rotation axis of the extending portions 102 and 103 (specifically, cylindrical engaging portions 102b and 103b). By being provided so as to guide a portion on the opposite side of the mounting table 40 side, a rotation axis (specifically, a cylindrical engagement) of the pair of extending portions 102 and 103 along the sub-scanning direction Y is provided. It is possible to more effectively prevent outward rotation in the main scanning direction X around the joint portions 102b and 103b).

  In the second embodiment, the end (top surface 71a) of the scanning base 71 in the vertical direction Z on the side of the document placement table 40 is the end of the sliding member 100 on the side of the document placement table 40 in the vertical direction Z. The guide portions 731 and 741 on the outer side are located on the opposite side to the document placement table 40 side in the vertical direction Z with respect to a certain sliding contact portion 101b (in this example, with respect to the upper surface 484 of the contact image sensor 48). The end portions (top surfaces 731a and 741a) on the document placement table 40 side in the vertical direction Z are provided up to the end portions (top surface 71a) on the document placement table 40 side in the vertical direction Z of the scanning base 71. The pair of extending portions 102 and 103 can be reliably prevented from rotating outwardly in the main scanning direction X, and even when the contact image sensor 48 is closest to the document placing table 40, the scanning base 71 and one The guide portions 731 and 741 of the document placement table 40 can be prevented from coming into contact with the surface of the document placement table 40 facing the contact image sensor 48 (in this example, the lower surface 43a of the document placement glass 43). The distance between the contact image sensor 48 and the document placement table 40 (document placement glass 43 in this example) by the sliding portion 101, that is, the focal length of the contact image sensor 48 with respect to the document G can be secured without any trouble. it can.

(Third embodiment)
FIG. 25 is an enlarged plan view showing both end portions in the main scanning direction X of the scanning body SU according to the third embodiment. FIG. 26 is an enlarged right side view showing both ends in the main scanning direction X of the scanning body SU according to the third embodiment, and FIG. 27 is a main scanning direction X of the scanning body SU according to the third embodiment. It is a left view which expands and shows the both ends in FIG.

  By the way, the sliding member 100 can be sized in the main scanning direction X of the housing 482 in the contact image sensor 48 from the viewpoint of configuration (for example, from the viewpoint of realizing the compactness of the image reading device 2 in the main scanning direction X). In this example, the sliding portion 101 is an end portion in the main scanning direction X of the reading unit 481 in the contact type image sensor 48, more specifically, the reading unit 481 (specifically, in the contact type image sensor 48). Specifically, the reading surface on the upper surface 484 is disposed at a position close to (more adjacent to) the reading edge 48f outside the reading edge 48f that is an edge in the main scanning direction X (see FIG. 25). . In this case, the pair of extending portions 102 and 103 are rotatable with respect to the scanning base 71 around a rotation axis (specifically, cylindrical engaging portions 102b and 103b) along the sub-scanning direction Y. When engaged, the pair of extending portions 102 and 103 rotate inward in the main scanning direction X around the rotation axis along the sub-scanning direction Y, and the sliding unit 101 shields the reading unit 481. Sometimes. This is because, as in the present embodiment, the sliding contact portion 101b is in line contact or point contact with the document placement table 40, more specifically, the surface of the document placement table 40 facing the contact image sensor 48 ( In this example, the lower surface 43a of the document placement glass 43) is formed in a shape that makes line contact or point contact along the sub-scanning direction Y (in this example, a dome shape along the sub-scanning direction Y). , Especially noticeable.

  In this regard, in the third embodiment, as shown in FIGS. 25 to 27, the sliding portion 101 is an end portion in the main scanning direction X of the reading portion 481 in the contact image sensor 48, specifically, the contact image sensor 48. A pair of guide portions (731, 732), (741, 742) for guiding the extending portions 102, 103 when arranged at a position close to the reading edge 48f outside the reading edge 48f of the reading portion 481. ) Of the guide portions 732 and 742 (see FIGS. 26 and 27) on the inner side in the main scanning direction X in the vertical direction Z of the extending portions 102 and 103 due to the movement of the scanning body SU in the sub-scanning direction Y. Regardless of the movement, at least the rotation axis of the extended portions 102 and 103 (specifically, the columnar engaging portions 102b and 103b) is closer to the document placement table 40 (specifically, the upper side). It provided the parts so as to guide. In other words, the guide portions 732 and 742 on the inner side only need to be able to guide a portion closer to the document placement table 40 than the rotation axes of the extending portions 102 and 103, and more than the rotation axes of the extending portions 102 and 103. It may be provided so as to guide only the portion on the document placement table 40 side, or both the portion on the document placement table 40 side and the portion on the opposite side (specifically, the lower side) from the document placement table 40 side. It may be provided to guide.

  In this example, one of the guide portions 732 and 742 on the inner side is the document placement table in the vertical direction Z regardless of the movement of the extending portions 102 and 103 in the vertical direction Z due to the movement of the scanning body SU in the sub-scanning direction Y. 40 end portions (top surfaces 732a and 742a) are located closer to the document placement table 40 than the rotation axes of the extending portions 102 and 103, and are opposite to the document placement table 40 side in the vertical direction Z. (The bottom surfaces 732b and 742b) are provided so as to be located on the opposite side to the document placing table 40 side with respect to the rotation axis of the extending portions 102 and 103.

  One guide portions 732 and 742 on the inner side of the other guide portions 731 and 741 whose end portions (top surfaces 732a and 742a) on the document placement table 40 side in the vertical direction Z are on the outer side in the main scanning direction X are arranged. It is provided so as to be positioned closer to the document placement table 40 (specifically, the upper side) than the end (top surfaces 731a, 741a) on the document placement table 40 side in the vertical direction Z.

  In the third embodiment, the other guide portions 731 and 741 (see FIGS. 26 and 27) on the outer side are in the vertical direction Z of the extending portions 102 and 103 due to the movement of the scanning body SU in the sub-scanning direction Y. Regardless of the movement, at least the rotation axis of the extending portions 102 and 103 (specifically, the cylindrical engaging portions 102b and 103b) is on the opposite side (specifically, the lower side) from the document placement table 40 side. ) To guide the part. That is, the other guide portions 731 and 741 on the outer side need only be able to guide a portion of the extending portions 102 and 103 on the side opposite to the document placement table 40 side relative to the rotation axis of the extending portions 102 and 103. It may be provided so as to guide only the portion on the opposite side to the document placement table 40 side from the moving axis, or the portion on the document placement table 40 side (specifically, the upper side) and the document placement table 40 side. May be provided to guide both of the opposite portions.

  In this example, the other guide portions 731 and 741 on the outer side are the document placement table in the vertical direction Z regardless of the movement of the extending portions 102 and 103 in the vertical direction Z due to the movement of the scanning body SU in the sub-scanning direction Y. Ends (bottom surfaces 731b, 741b) opposite to the 40 side are located on the side opposite to the document placement table 40 side with respect to the rotation axes of the extending portions 102, 103, and the document placement table 40 side in the vertical direction Z. The end portions (top surfaces 731 a and 741 a) of the extending portions 102 and 103 are provided so as to be positioned closer to the document placement table 40 than the rotation axes of the extending portions 102 and 103.

  In the third embodiment, the end portion (top surface 71 a) of the scanning base 71 in the vertical direction Z on the original placement table 40 side is the end portion of the sliding member 100 on the original placement table 40 side in the vertical direction Z. It is located on the opposite side (specifically, the lower side) of the original document table 40 in the vertical direction Z from the sliding contact portion 101b (in this example, from the upper surface 484 of the contact image sensor 48), and is on the inner side. One of the guide portions 732 and 742 has an end (top surface 732a, 742a) on the side of the document placing table 40 in the vertical direction Z and an end portion (top surface 71a) on the side of the document placing table 40 in the vertical direction Z of the scanning base 71. ).

  Specifically, one of the guide portions 732 and 742 on the inner side has end portions (top surfaces 732 a and 742 a) on the side of the document placing table 40 in the vertical direction Z at one side base side plate 73 and the other side base side plate 74. Is provided so as to be positioned at an end portion (top surface 71a) on the document placing table 40 side in the vertical direction Z.

  As described above, according to the third embodiment, one of the pair of guide portions (731, 732) and (741, 742) that guide the extending portions 102 and 103 is located inside in the main scanning direction X. The guide portions 732 and 742 guide the portion on the side of the document placing table 40 with respect to at least the rotation axis of the extending portions 102 and 103 (specifically, the cylindrical engaging portions 102b and 103b), and The other end portions (top surfaces 732a and 742a) on the document placement table 40 side in the vertical direction Z are the end portions on the document placement table 40 side in the vertical direction Z of the other guide portions 731 and 741 on the outer side in the main scanning direction X ( The top surface 731a, 741a) is provided so as to be positioned closer to the document placing table 40, so that the contact area with the extended portions 102, 103 of one of the guide portions 732, 742 on the inner side is possible. The sliding member 100 can be smoothly moved relative to the scanning base 71 in the vertical direction Z in a state where the number of the extending portions 102 and 103 is reduced, and the rotation axis along the sub-scanning direction Y of the pair of extending portions 102 and 103 The rotation inward in the main scanning direction X around the cylindrical engaging portions 102b and 103b (specifically, the cylindrical engaging portions 102b and 103b) can be effectively prevented, whereby the reading portion 481 is blocked by the sliding portion 101. It can be avoided. This is because, as in the present embodiment, the sliding contact portion 101b is in line contact or point contact with the document placement table 40, more specifically, the surface of the document placement table 40 facing the contact image sensor 48 ( In this example, the lower surface 43a of the document placement glass 43) is formed in a shape that makes line contact or point contact along the sub-scanning direction Y (in this example, a dome shape along the sub-scanning direction Y). , Especially effective.

  Further, in the third embodiment, the other guide portions 731 and 741 on the outside are the originals at least relative to the rotation axis of the extending portions 102 and 103 (specifically, the cylindrical engaging portions 102b and 103b). By being provided so as to guide a portion on the opposite side of the mounting table 40 side, a rotation axis (specifically, a cylindrical engagement) of the pair of extending portions 102 and 103 along the sub-scanning direction Y is provided. Inward rotation in the main scanning direction X around the joint portions 102b and 103b) can be more effectively prevented.

  In the third embodiment, the end portion (top surface 71 a) of the scanning base 71 in the vertical direction Z on the original placement table 40 side is the end portion of the sliding member 100 on the original placement table 40 side in the vertical direction Z. The guide portions 732 and 742 located on the opposite side of the document placing table 40 in the vertical direction Z from the sliding contact portion 101b (in this example, from the upper surface 484 of the contact image sensor 48) are located on the inner side. The end portions (top surfaces 732a and 742a) on the document placement table 40 side in the vertical direction Z are provided up to the end portions (top surface 71a) on the document placement table 40 side in the vertical direction Z of the scanning base 71. The pair of extending portions 102 and 103 can be reliably prevented from turning inward in the main scanning direction X, and even when the contact image sensor 48 is closest to the document placement table 40, the scanning base 71 and one The guide portions 732 and 742 of the document placement table 40 can be made not to come into contact with the surface of the document placement table 40 facing the contact image sensor 48 (in this example, the lower surface 43a of the document placement glass 43). The distance between the contact image sensor 48 and the document placement table 40 (document placement glass 43 in this example) by the sliding portion 101, that is, the focal length of the contact image sensor 48 with respect to the document G can be secured without any trouble. it can.

(Fourth embodiment)
FIG. 28 is an enlarged plan view showing both end portions in the main scanning direction X of the scanning body SU according to the fourth embodiment. FIG. 29 is an enlarged right side view showing both ends in the main scanning direction X of the scanning body SU according to the fourth embodiment, and FIG. 30 is a main scanning direction X of the scanning body SU according to the fourth embodiment. It is a left view which expands and shows the both ends in FIG.

  By the way, the sliding member 100 can be sized in the main scanning direction X of the housing 482 in the contact image sensor 48 from the viewpoint of the configuration (for example, from the viewpoint of realizing compactness in the two main scanning directions X of the image reading apparatus). In this example, the sliding portion 101 has an end portion in the main scanning direction X of the contact image sensor 48, more specifically, in the main scanning direction X of the housing 482 in the contact image sensor 48. The end portion of the reading unit 481 in the main scanning direction X of the reading unit 481 in the close contact type image sensor 48 at a position close to (more specifically, adjacent to) the outer end edge 48e inside the outer end edge 48e. More specifically, the reading edge outside the reading edge 48f which is the edge in the main scanning direction X of the reading unit 481 in the contact image sensor 48. Close to 8f are arranged on the (still speaking adjacent) position (see FIG. 28). In this case, the pair of extending portions 102 and 103 are rotatable with respect to the scanning base 71 around a rotation axis (specifically, cylindrical engaging portions 102b and 103b) along the sub-scanning direction Y. When engaged, the pair of extending portions 102 and 103 rotate outward in the main scanning direction X around the rotation axis along the sub-scanning direction Y, and the sliding portion 101 of the contact image sensor 48 is rotated. The sliding part 101 shields the reading part 481 by dropping from the upper surface 484 or by turning the pair of extending parts 102 and 103 inward in the main scanning direction X around the rotation axis along the sub-scanning direction Y. Sometimes. This is because, as in the present embodiment, the sliding contact portion 101b is in line contact or point contact with the document placement table 40, more specifically, the surface of the document placement table 40 facing the contact image sensor 48 ( In this example, the lower surface 43a of the document placement glass 43) is formed in a shape that makes line contact or point contact along the sub-scanning direction Y (in this example, a dome shape along the sub-scanning direction Y). , Especially noticeable.

  In this regard, in the fourth embodiment, as shown in FIGS. 28 to 30, the sliding portion 101 is an end portion in the main scanning direction X of the contact image sensor 48, specifically, a housing 482 in the contact image sensor 48. The reading edge 481 of the close contact type image sensor 48 in the main scanning direction X, more specifically, the reading portion 481 of the contact type image sensor 48, is a position close to the external edge 48e inside the external edge 48e. A pair of guide portions (731, 732), (741, 742) for guiding the extending portions 102, 103 when arranged at a position close to the reading edge 48f outside the edge 48f (FIGS. 29 and 30), regardless of the movement of the extending portions 102, 103 in the vertical direction Z caused by the movement of the scanning body SU in the sub-scanning direction Y, both of the extending portions 102, At least pivot axis (specifically, cylindrical engaging portion 102b, 103b) of 03 (specifically, the upper side) document table 40 side than is provided so as to guide the portion of the. That is, the pair of guide portions (731, 732) and (741, 742) on the outer side and the inner side in the main scanning direction X guide a portion closer to the document placement table 40 than the rotation axis of the extending portions 102 and 103. As long as it is possible, it may be provided so as to guide only the portion on the side of the document placement table 40 with respect to the rotation axis of the extending portions 102 and 103, or the portion on the side of the document placement table 40 and the side of the document placement table 40 May be provided so as to guide both the opposite (specifically, lower) portions.

  In this example, the pair of guide portions (731, 732) and (741, 742) on the outer side and the inner side are used to move the extending portions 102, 103 in the vertical direction Z by the movement of the scanning body SU in the sub-scanning direction Y. Regardless, the end portions (top surfaces (731a, 732a), (741a, 742a)) in the vertical direction Z side and the end portions (bottom surface (side surface (731a, 742a)) in the vertical direction Z opposite to the original placement table 40 side. 731b, 732b) and (741a, 742b)) are provided so as to be positioned closer to the document placing table 40 than the rotation axis of the extending portions 102, 103.

  In the fourth embodiment, the end portion (top surface 71a) of the scanning base 71 in the vertical direction Z on the document placement table 40 side is the end portion of the sliding member 100 on the document placement table 40 side in the vertical direction Z. It is located on the opposite side (specifically, on the lower side) of the original document table 40 in the vertical direction Z than the certain sliding contact portion 101b (in this example, on the upper surface 484 of the contact image sensor 48), and outside and inside The pair of guide portions (731, 732) and (741, 742) in FIG. 5 have end portions (top surfaces (731a, 732a), (741a, 742a)) on the side of the document placing table 40 in the vertical direction Z. 71 to the end (top surface 71a) on the document placing table 40 side in the vertical direction Z.

  Specifically, the pair of guide portions (731, 732) and (741, 742) on the outer side and the inner side are end portions (top surfaces (731a, 732a), (741a) on the document placement table 40 side in the vertical direction Z. , 742a)) is provided so as to be located at the end portion (top surface 71a) on the side of the document placing table 40 in the vertical direction Z of the one side base side plate 73 and the other side base side plate 74.

  As described above, according to the fourth embodiment, the pair of guide portions (731, 732) and (741, 742) for guiding the extending portions 102, 103 are both of the extending portions 102, 103. A pair of guide portions (outside and inside) are provided by guiding at least a portion closer to the document placing table 40 than the rotation axis (specifically, the cylindrical engaging portions 102b and 103b). 731, 732) and (741, 742) with respect to the extending portions 102, 103 as small as possible, the sliding member 100 is smoothly moved relative to the scanning base 71 in the vertical direction Z. In addition, the outer side and the inner side in the main scanning direction X around the rotation axis (specifically, the cylindrical engaging portions 102b and 103b) along the sub-scanning direction Y of the pair of extending portions 102 and 103 can be used. Effective prevention of rotation Rukoto can, thereby avoiding the blocking of the reading unit 481 by the sliding unit 101 it is possible to avoid falling off from the upper surface 484 of the contact image sensor 48 of the sliding portion 101. This is because, as in the present embodiment, the sliding contact portion 101b is in line contact or point contact with the document placement table 40, more specifically, the surface of the document placement table 40 facing the contact image sensor 48 ( In this example, the lower surface 43a of the document placement glass 43) is formed in a shape that makes line contact or point contact along the sub-scanning direction Y (in this example, a dome shape along the sub-scanning direction Y). , Especially effective.

  In the fourth embodiment, the end portion (top surface 71a) of the scanning base 71 in the vertical direction Z on the document placement table 40 side is the end portion of the sliding member 100 on the document placement table 40 side in the vertical direction Z. A pair of guide portions (731) located on the outer side and the inner side of the sliding contact portion 101b (on the upper surface 484 of the contact image sensor 48 in this example) on the opposite side of the document placing table 40 in the vertical direction Z. , 732), (741, 742) are the document placement table 40 side ends (top surfaces (731a, 732a), (741a, 742a)) in the vertical direction Z of the scanning base 71 in the vertical direction Z. By being provided up to the end portion (top surface 71a) on the mounting table 40 side, the pair of extending portions 102 and 103 can be reliably prevented from rotating outward and inward in the main scanning direction X, and a contact image. Sensor Even when 8 is closest to the document placing table 40, the scanning base 71 and the pair of guide portions (731, 732), (741, 742) are all connected to the contact image sensor 48 of the document placing table 40. , The contact image sensor 48 by the sliding portion 101 and the document placing table 40 (in this example, the document placing table 40). The distance to the placement glass 43), that is, the focal length of the contact image sensor 48 with respect to the original G can be ensured without hindrance.

  The present invention is not limited to the embodiment described above, and can be implemented in various other forms. Therefore, such an embodiment is merely an example in all respects and should not be interpreted in a limited manner. The scope of the present invention is shown by the scope of claims, and is not restricted by the text of the specification. Further, all modifications and changes belonging to the equivalent scope of the claims are within the scope of the present invention.

DESCRIPTION OF SYMBOLS 1 Image forming apparatus 10 Apparatus main body 100 Sliding member 101 Sliding part 101a Contact part 101b Sliding contact part 101c Inclined surface 102 Extension part 102a Inner side surface 102b Engagement part 103 Extension part 103a Inner side surface 103b Engagement part 2 Image reading Device 40 Document Placement Table 41 Scanning Unit 42 Document Reading Glass 42a Lower Surface 43 Document Placement Glass 43a Lower Surface 48 Contact Type Image Sensor 481 Reading Unit 482 Housing 483 Opening Portion 484 Upper Surface 48a Sensor Side Supported Portion 48b Supported Shaft 48c Sensor Side Holding portion 48d Side surface 48e Exterior edge 48f Reading edge 51 Light source 71 Scan base 71a Top surface 72 Base bottom plate 72a Base side holding portion 72b Sensor movement restricting portion 73 One side base side plate 731 Guide portion 731a Top surface 731b Bottom surface 732 Guide portion 732a Top surface 732b Bottom surface 741 Guide portion 741a Top surface 74 1b bottom surface 742 guide portion 742a top surface 742b bottom surface 73a outer side surface 73d engaged portion 73e inner side surface 74 other side base side plate 74a outer side surface 74b scanning base side support portion 74c support hole 74d engaged portion 74e inner side surface 90 attached Force member G Document SU Scanning body X Main scanning direction Y Sub-scanning direction Z Vertical direction

Claims (10)

A scanning body having a contact image sensor; and a document placement table on which a document is placed, and scanning the document placed on the document placement table while moving the scanning body in a sub-scanning direction. An image reading apparatus that reads an image of the document with the contact image sensor,
The scanning body includes a scanning base that movably supports the contact image sensor so that the contact image sensor approaches or separates from the document placement table; and the contact image sensor that supports the document placement table. comprising an urging member for urging, provided between the contact image sensor and the document table, and a sliding member is slid in front Symbol document placing stand towards,
The sliding member is engaged with both side surfaces of the scanning base in the sub-scanning direction so as to approach or separate from the document placement table and to be allowed to move relative to the scanning base. A sliding portion that is movably engaged with the scanning base in a vertical direction relative to the document placement table, and is disposed between the contact image sensor and the document placement table; A pair of extending portions extending from both ends of the scanning portion in the sub-scanning direction to the opposite side of the document placing table side along the both side surfaces of the scanning base in the sub-scanning direction,
An engaging portion is provided on a side surface of the pair of extending portions facing the scanning base,
Engaged parts that engage with the engaging parts are provided on both side surfaces of the scanning base in the sub-scanning direction,
A pair of at least one side surface of the scanning base in the sub-scanning direction guides the movement of the extending portion in the vertical direction on both sides in the main scanning direction of the extending portion. An image reading apparatus provided with a guide portion . The image reading apparatus according to claim 1 ,
In the sliding member, the pair of extending portions are engaged with the scanning base so as to be rotatable about a rotation axis along the sub-scanning direction, and the sliding portion is the contact type Of the pair of guide portions that are arranged at the end portion in the main scanning direction of the image sensor and guide the extension portion, one guide portion outside the main scanning direction is at least the extension portion. The end portion on the manuscript placement table side in the vertical direction is guided more than the end portion on the manuscript placement table side of the other guide portion so as to guide the portion on the manuscript placement table side with respect to the rotation axis. An image reading apparatus, wherein the image reading apparatus is provided so as to be positioned on a document placing table side. The image reading apparatus according to claim 1 ,
In the sliding member, the pair of extending portions are engaged with the scanning base so as to be rotatable about a rotation axis along the sub-scanning direction, and the sliding portion is the contact type One of the pair of guide portions that are arranged at the end portion in the main scanning direction of the reading portion of the image sensor and guides the extending portion is located on the inner side in the main scanning direction. An end portion on the side of the original document table in the vertical direction so that the end portion on the side of the original document table in the vertical direction is an end portion on the side of the original document table. An image reading apparatus, wherein the image reading apparatus is provided so as to be positioned closer to the document placing table side. The image reading apparatus according to claim 2 or 3 , wherein
2. The image reading apparatus according to claim 1, wherein the other guide portion is provided so as to guide at least a portion of the extending portion on a side opposite to the document placing table side with respect to the rotation axis. The image reading apparatus according to claim 1 ,
In the sliding member, the pair of extending portions are engaged with the scanning base so as to be rotatable about a rotation axis along the sub-scanning direction, and the sliding portion is the contact type Which of the pair of guide portions that are arranged at the end portion in the main scanning direction of the image sensor and at the end portion in the main scanning direction of the reading portion in the contact image sensor, and which guides the extending portion, The image reading apparatus is also provided so as to guide at least a portion of the extension portion closer to the document placing table than the rotation axis. An image reading apparatus according to any one of claims 1 to 5 ,
An end of the scanning base on the side of the original document table in the vertical direction is opposite to an end of the slide member on the side of the original document table in the vertical direction. The pair of guide portions is provided such that an end portion on the document placement table side in the vertical direction is provided to an end portion on the document placement table side in the vertical direction of the scanning base. An image reading apparatus. An image reading apparatus according to any one of claims 1 to 6 ,
2. The image reading apparatus according to claim 1, wherein the sliding portion is formed in a shape that makes line contact or point contact with the document placing table. An image reading apparatus according to any one of claims 1 to 7 ,
The image reading apparatus according to claim 1, wherein the engagement of the sliding member with the scanning base is an uneven engagement. An image forming apparatus comprising the image reading apparatus according to any one of claims 1 to 8. An image in which an image of the original is read by the contact-type image sensor by scanning the original placed on an original placement table on which the original is placed while moving a scanning body including the contact-type image sensor in the sub-scanning direction. A scanning body used in a reading device,
A scanning base that movably supports the contact image sensor so that the contact image sensor approaches or moves away from the document placement table, and biases the contact image sensor toward the document placement table. a biasing member which is provided between the contact image sensor and the document table, and a sliding member is slid in front Symbol document placement table,
The sliding member is engaged with both side surfaces of the scanning base in the sub-scanning direction so as to approach or separate from the document placement table and to be allowed to move relative to the scanning base. A sliding portion that is movably engaged with the scanning base in a vertical direction relative to the document placement table, and is disposed between the contact image sensor and the document placement table; A pair of extending portions extending from both ends of the scanning portion in the sub-scanning direction to the opposite side of the document placing table side along the both side surfaces of the scanning base in the sub-scanning direction,
An engaging portion is provided on a side surface of the pair of extending portions facing the scanning base,
Engaged parts that engage with the engaging parts are provided on both side surfaces of the scanning base in the sub-scanning direction,
A pair of at least one side surface of the scanning base in the sub-scanning direction guides the movement of the extending portion in the vertical direction on both sides in the main scanning direction of the extending portion. A scanning body provided with a guide portion .

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