JP2023114081A - Image reading device and recording device - Google Patents

Abstract

To solve a problem in which a load applied to a document is increased due to the rotation of a document pressing plate when the document is conveyed between the document pressing plate and a reading surface lower guide, and vibration and abnormal noise may occur when the document is conveyed between the document pressing plate and the reading surface lower guide.SOLUTION: An image reading device that reads a document conveyed in the conveying direction includes a document support member having a reading surface that contacts the document, a reading unit that reads the document via the document support member, a pressing portion that faces the reading surface and presses the reading surface, a support portion that is arranged upstream in the conveying direction with respect to a reading area where the reading surface and the pressing portion are in contact with each other, and rotatably supports the pressing portion, a path member that is arranged downstream in the transport direction with respect to the reading area and guides the document, and a regulating portion that is arranged downstream of the reading area in the conveying direction and regulates displacement of the pressing portion.SELECTED DRAWING: Figure 3

Description

The present disclosure relates to an image reading device and a recording device.

2. Description of the Related Art An image reading apparatus is known that presses a document against a lower reading surface guide with a document pressing plate. The document holding plate of the image reading apparatus disclosed in Japanese Patent Application Laid-Open No. 2002-200303 is attached to the document holding plate rotating shaft. The document pressing plate is rotatably attached. The document pressing plate rotating shaft is arranged downstream in the document traveling direction with respect to the reading position range. The reading position range is a region where the document contact surface of the document holding plate contacts the reading surface underside guide through the document. The document presser plate is supported by the document presser plate rotating shaft downstream in the document traveling direction.

JP 2010-269862 A

When the document is conveyed between the document pressing plate and the reading surface lower guide, the load applied to the document increases due to the rotation of the document pressing plate. Also, when the document is conveyed between the document pressing plate and the reading surface lower guide, vibration and abnormal noise may occur.

An image reading apparatus according to the present disclosure is an image reading apparatus that reads a document conveyed in a conveying direction, and includes a document support member having a reading surface that contacts the document, and reads the document via the document support member. a reading unit, a pressing unit that faces the reading surface and presses the reading surface, and a reading area in which the reading surface and the pressing unit are in contact with each other, the pressing unit being arranged upstream in the conveying direction. a support portion that rotatably supports the document, a path member that is arranged downstream of the reading area in the conveying direction and guides the document, and a passage member that is arranged downstream of the reading area in the conveying direction; and a restricting portion that restricts displacement of the pressing portion.

A recording apparatus according to the present disclosure is a recording apparatus that reads a document transported in a transport direction and records an image on a medium, and includes a document support member having a reading surface that contacts the document, and a document support member. a reading unit for reading the document, a pressing unit facing the reading surface and pressing the reading surface, and a reading area where the reading surface and the pressing unit are arranged upstream in the transport direction with respect to the reading area. a support portion that rotatably supports the pressing portion; a path member that is disposed downstream in the transport direction with respect to the reading area and guides the document; A regulating section that is arranged downstream and that regulates the displacement of the pressing section, and a recording section that records the image on the medium based on read data read by the reading section.

3 is an external perspective view of the printer; FIG. 4 is a diagram showing the internal configuration of the scanner unit; FIG. The figure which shows the structure of the periphery of a pressing member. FIG. 10 is a view showing the configuration of the pressing member and the paper guide member viewed from the +Z direction; The figure which shows the structure of a 1st area|region. The figure which shows the structure of a 2nd area|region.

FIG. 1 shows an external perspective view of the printer 100. As shown in FIG. The printer 100 is, for example, an inkjet printer that ejects ink onto recording paper. A printer 100 shown in FIG. 1 includes a recording unit 101 and a scanner unit 1 above the recording unit 101 . The printer 100 is a multifunction machine. The printer 100 corresponds to an example of a recording device. The scanner unit 1 shown in FIG. 1 configures the printer 100, but is not limited to this. The scanner unit 1 may be configured independently.

Each figure including FIG. 1 shows an XYZ coordinate system. The X-axis, Y-axis, and Z-axis are orthogonal to each other. The X-axis is the axis along the width of printer 100 . The -X direction corresponds to the right direction as seen from the user when the front of the device faces the user. The +X direction corresponds to the left direction as seen from the user when the front of the device faces the user. Here, the front side of the apparatus is the side surface on which the operation unit 104 is provided among the side surfaces that configure the periphery of the printer 100 . The Y-axis is the axis along the depth of the printer 100 . The Y axis is the axis along the width of the document G placed on the printer 100 . The +Y direction corresponds to the direction from the back of the device toward the front. The -Y direction corresponds to the direction from the front to the back of the device. The Z-axis is the axis along the height of printer 100 . The +Z direction corresponds to vertically upward. The -Z direction corresponds to vertically downwards.

The scanner unit 1 has a function of reading a document G. As shown in FIG. The scanner unit 1 has a main body 2 and an ADF 3 . ADF3 is an abbreviation for Auto Document Feeder, which is an automatic document feeder. The scanner unit 1 corresponds to an example of an image reading device. The ADF 3 is rotatably supported by a rotation support member (not shown). The ADF 3 takes a posture in which the body portion 2 is closed or a posture in which the body portion 2 is opened by rotating.

The body portion 2 becomes accessible by the user when the ADF 3 assumes the attitude of opening the body portion 2 . The body portion 2 includes a document platen 4, which will be described later. The manuscript table 4 places a manuscript G supplied by a user. The scanner unit 1 can read a document G placed on the document platen 4 of the main body 2 .

FIG. 1 shows a posture in which the ADF 3 closes the main body 2. As shown in FIG. FIG. 1 shows an ADF cover 6, a feed tray 10, a guide portion 12, and a discharge tray 13 as the configuration of the ADF 3. As shown in FIG.

ADF cover 6 is provided on top of ADF 3 . The ADF cover 6 is rotatable around a cover rotation shaft (not shown). The ADF cover 6 is closed or opened by rotating. FIG. 1 shows a state in which the ADF cover 6 is closed. When the ADF cover 6 is open, the user can access the first document transport path F1, which will be described later. The user can remove the document G inside the ADF 3 by opening the ADF cover 6 .

The feed tray 10 holds the document G supplied by the user. The feed tray 10 is configured such that a plurality of originals G can be placed thereon. The document G placed on the feed tray 10 is conveyed inside the ADF 3 . A document G to be read by the scanner unit 1 is placed on the feed tray 10 .

The guide portion 12 guides the document G placed on the feed tray 10 . The guide portion 12 includes a first edge guide 12a and a second edge guide 12b. The first edge guide 12a is slidably supported along the Y-axis. The first edge guide 12a contacts the +Y-direction end surface of the document G placed on the feed tray 10 . The second edge guide 12b is slidably supported along the Y-axis. The second edge guide 12b contacts the end face of the document G placed on the feed tray 10 in the -Y direction.

The discharge tray 13 places the document G discharged from the inside of the ADF 3 . The discharge tray 13 carries a document G read by a reading sensor 7a, which will be described later. The document G conveyed from the feed tray 10 to the inside of the ADF 3 is ejected onto the ejection tray 13 .

The recording unit 101 has a recording function of recording an image on recording paper. A recording sheet corresponds to an example of a medium. The recording unit 101 includes a paper feed section 102 , an operation section 104 , a paper discharge section 105 , a transport path (not shown), and a recording head 108 .

The paper feed unit 102 accommodates recording paper. The paper feed unit 102 shown in FIG. 1 includes a first paper feed cassette 102a and a second paper feed cassette 102b. The first paper feed cassette 102a and the second paper feed cassette 102b accommodate recording sheets of the same size or different sizes. The first paper feed cassette 102a and the second paper feed cassette 102b may accommodate recording paper of different types. The recording paper accommodated in the paper feeding unit 102 is transported to a position facing the recording head 108 by transport means (not shown).

The operation unit 104 is provided on the side surface of the printer 100 . The operation unit 104 is operated by the user. A user performs various operations on the operation unit 104 . The operation unit 104 includes a display unit and a plurality of operation buttons. The operation unit 104 may be configured with a display having a touch input function. The operation unit 104 may be provided tiltably with respect to the side surface of the printer 100 .

A paper discharge unit 105 accommodates recording paper discharged from the recording unit 101 . The paper discharge unit 105 shown in FIG. 1 is provided between the paper feed unit 102 and the operation unit 104 . The paper discharge unit 105 is in the accommodated state or the pulled out state. The housed state is a state in which the paper ejection section 105 is housed inside the recording unit 101 as shown in FIG. The pulled-out state is a state in which the paper ejection section 105 is pulled out in the +Y direction of the recording unit 101 . The user can take out the recording paper from the discharge port 103 by pulling out the paper discharge unit 105 .

The transport path is a path for transporting the recording paper accommodated in the paper feed unit 102 . The transport path is a path from the paper feed unit 102 to the paper discharge unit 105 via a position facing the print head 108 . The transport path includes transport rollers (not shown). The transport roller transports the recording paper along the transport path.

A recording head 108 records an image on a recording sheet. The recording head 108 corresponds to an example of a recording unit. A print head 108 prints an image on a print sheet based on the read data. The read data is data read by a reading unit 7 of the scanner unit 1, which will be described later. A print head 108 is provided on the carriage 107 . A carriage 107 reciprocates the recording head 108 along the X axis.

The recording unit 101 may be provided with a rear cover 106 . The rear cover 106 covers a paper feed port (not shown). The paper feed port is configured to accommodate recording paper supplied from the back of the device. A paper feed port corresponds to an example of the paper feed unit 102 .

FIG. 2 shows the internal configuration of the scanner unit 1. As shown in FIG. FIG. 2 shows a partial configuration of the scanner unit 1. As shown in FIG. FIG. 2 shows a cross-sectional configuration of a portion covered with the ADF cover 6. As shown in FIG. FIG. 2 shows an XZ section of the scanner unit 1. As shown in FIG. FIG. 2 shows part of the main body 2 and part of the ADF 3 .

The body portion 2 includes a document platen 4 and a reading unit 7 . When the ADF 3 assumes the attitude of opening the main body 2, the platen 4 becomes accessible to the user. FIG. 2 shows a posture in which the ADF 3 closes the main body 2, as in FIG.

The platen 4 includes a first transparent glass 4a and a second transparent glass 4b. The first transparent glass 4 a and the second transparent glass 4 b are arranged above the body portion 2 . The first transparent glass 4a and the second transparent glass 4b are arranged side by side along the X-axis.

The first transparent glass 4a is arranged at the -X direction position of the second transparent glass 4b. The first transparent glass 4a is composed of a flat and transparent glass plate. The upper surface of the first transparent glass 4a serves as a document placement surface on which the document G is placed. When the ADF 3 is in the posture of opening the main body 2, the user places the document G on the first transparent glass 4a.

The second transparent glass 4b is arranged at a position facing a pressing member 22, which will be described later. The second transparent glass 4b is composed of a flat and transparent glass plate. A glass upper surface 4s of the second transparent glass 4b constitutes a document G transport path. The glass upper surface 4s comes into contact with the document G being conveyed. The second transparent glass 4b corresponds to an example of a document supporting member. The glass upper surface 4s corresponds to an example of a reading surface.

The reading unit 7 reads the document G conveyed along the conveying path. The reading unit 7 has a reading sensor 7a, which will be described later. The reading sensor 7a is composed of, for example, a CCD (Charge Coupled Devices) type or a CIS (Contact Image Sensor) type optical sensor. The reading unit 7 extends along the Y-axis. The reading unit 7 is moved in the +X direction or the -X direction along the X axis by a moving mechanism (not shown). The reading unit 7 reads the document G through the first transparent glass 4a or the second transparent glass 4b. The reading unit 7 corresponds to an example of a reading section.

The reading unit 7 reads the document G placed on the first transparent glass 4 a or the document G conveyed by the ADF 3 . The reading unit 7 is moved along the X-axis by a moving mechanism when reading the document G placed on the first transparent glass 4a. The reading unit 7 reads the document G when moving along the X axis. When the document G conveyed by the ADF 3 is read, the reading unit 7 stops at a position facing the second transparent glass 4b. The reading unit 7 reads the document G conveyed on the second transparent glass 4b. The direction in which the document G is transported on the second transparent glass 4b is referred to as the transport direction. The conveying direction is the direction from the +X direction side to the −X direction side along the X axis. The reading unit 7 reads the document G to generate read data. The recording head 108 records an image on the recording paper based on the read data generated by the reading unit 7 .

The ADF 3 conveys the document G placed on the feed tray 10 to the discharge tray 13 . The ADF 3 internally bends and inverts the document G placed on the feed tray 10 . The ADF 3 conveys the curved and inverted document G onto the second transparent glass 4b. The ADF 3 discharges the document G conveyed onto the second transparent glass 4 b toward the discharge tray 13 .

The ADF 3 conveys the document G along the conveying path. FIG. 2 shows a first document transport path F1 and a second document transport path F2 as transport paths. FIG. 2 shows the first document transport path F1 with a dashed line. FIG. 2 shows the second document transport path F2 with a chain double-dashed line. The first document transport path F<b>1 is a transport path for transporting the document G placed on the feed tray 10 to the discharge tray 13 . The second document transport path F2 is a transport path used when the document G is reversely transported.

The ADF 3 includes a feed tray 10, a feed roller 15, a separation section 16, a first transport roller pair 19, a support roller 20, and a second transport roller pair 21 along the first document transport path F1. , a pressing member 22 , a paper guide member 23 , a flap 24 and a pair of discharge rollers 25 .

The feed tray 10 holds the document G supplied by the user. The feed tray 10 includes a first feed member 10a and a second feed member 10b. A plurality of documents G can be placed on the first feeding member 10a and the second feeding member 10b as shown in FIG. The first feeding member 10a is arranged at the -X direction position of the second feeding member 10b.

The feed roller 15 feeds the document G placed on the feed tray 10 . The feeding roller 15 is arranged above the second feeding member 10b. The feed roller 15 is rotationally driven by a drive mechanism (not shown). The feeding roller 15 contacts the uppermost document G among the plurality of documents G placed on the feeding tray 10 . The feeding roller 15 feeds the contacting document G in the +X direction.

The separation unit 16 separates the plurality of originals G when the plurality of originals G are fed by the feeding roller 15 . The separation unit 16 includes a separation roller 16a and a separation member 16b. The separation roller 16a is rotationally driven by a drive mechanism (not shown). The driving mechanism for rotating the separation roller 16 a may be the driving mechanism for rotating the feeding roller 15 . The feed roller 15 and the separation roller 16a may be rotationally driven by different drive mechanisms. The separating member 16b is arranged below the separating roller 16a. The separation roller 16 a and the separation member 16 b nip the document G fed by the feeding roller 15 . The document G separated by the separation unit 16 is conveyed toward the first conveying roller pair 19 by driving the separation roller 16a.

The feed roller 15 and the separation roller 16a are supported by a roller support member 17. As shown in FIG. The roller support member 17 supports the feed roller 15 so as to swing. The roller support member 17 supports the feed roller 15 so as to swing around the center of rotation of the separation roller 16a. By swinging the feeding roller 15 with the roller support member 17 , the feeding roller 15 approaches or separates from the document G placed on the feeding tray 10 .

The first transport roller pair 19 transports the document G transported by the separation roller 16a along the first document transport path F1. The first transport roller pair 19 includes a first drive roller 19a and a first driven roller 19b. The first drive roller 19a is rotationally driven by a drive mechanism (not shown). The first driven roller 19b contacts the first drive roller 19a with the document G therebetween. The first driven roller 19b is driven to rotate by the rotational driving of the first driving roller 19a.

The support roller 20 supports the document G transported by the first transport roller pair 19 . The support roller 20 is driven to rotate. The support roller 20 is positioned at the curved portion of the first document transport path F1. The support roller 20 guides the document G to the second conveying roller pair 21 .

The second transport roller pair 21 transports the document G guided by the support rollers 20 . The second transport roller pair 21 includes a second drive roller 21a and a second driven roller 21b. The second drive roller 21a is rotationally driven by a drive mechanism (not shown). The second driven roller 21b contacts the second drive roller 21a with the document G therebetween. The second driven roller 21b is driven to rotate by the rotational driving of the second drive roller 21a. The second transport roller pair 21 is arranged above the pressing member 22 . The second transport roller pair 21 is arranged at a position in the +X direction of the pressing member 22 in the +Z direction. The second transport roller pair 21 supplies the document G to the nip position between the pressing member 22 and the second transparent glass 4b. The second transport roller pair 21 corresponds to an example of a supply roller pair.

Document detection means (not shown) may be provided along the first document transport path F<b>1 between the second transport roller pair 21 and the pressing member 22 . The document detecting means detects the leading edge and the trailing edge of the document G. FIG.

The pressing member 22 is arranged at a position facing the glass upper surface 4s of the second transparent glass 4b. The pressing member 22 presses the document G conveyed by the second conveying roller pair 21 toward the second transparent glass 4b. The pressing member 22 has a contact surface 22a facing the second transparent glass 4b. The contact surface 22a of the pressing member 22 presses the glass upper surface 4s of the second transparent glass 4b with the document G interposed therebetween. The pressing member 22 presses the document G against the second transparent glass 4b to prevent the document G from floating from the second transparent glass 4b. The pressing member 22 corresponds to an example of a pressing portion. The contact surface 22a corresponds to an example of a pressing surface.

The paper guide member 23 guides the document G that has passed through the nip position between the pressing member 22 and the second transparent glass 4b. The paper guide member 23 is arranged adjacent to the pressing member 22 in the −X direction. The paper guide member 23 is arranged above the first transparent glass 4a. The paper guide member 23 is fixedly arranged on the ADF 3 . The paper guide member 23 corresponds to an example of a path member.

The flap 24 is provided at the −X direction position of the paper guide member 23 . The flap 24 is supported by a flap swing shaft 24a. The flap 24 is swingably supported around a flap swing shaft 24a. The flap 24 closes the first document transport path F1 by its own weight and opens the second document transport path F2 as shown in FIG. The flap 24 is pushed up by the leading edge of the document G advancing toward the discharge roller pair 25 from the nip position between the pressing member 22 and the second transparent glass 4b.

The discharge roller pair 25 conveys the document G that has passed through the flap 24 . The discharge roller pair 25 is provided at a position in the −X direction and +Z direction of the pressing member 22 . The discharge roller pair 25 is arranged above the contact surface 22 a of the pressing member 22 . The discharge roller pair 25 includes a first discharge roller 25a and a second discharge roller 25b. The first discharge roller 25a is rotationally driven by a drive mechanism (not shown). The second discharge roller 25b contacts the first discharge roller 25a with the document G interposed therebetween. The second discharge roller 25b is driven to rotate by the rotational driving of the first discharge roller 25a. The discharge roller pair 25 nips the document G conveyed from the nip position between the pressing member 22 and the second transparent glass 4b. When the leading edge of the document G is nipped by the discharge roller pair 25, the document G is pressed against the second transparent glass 4b by the pressing member 22. As shown in FIG.

The second discharge roller 25b is supported by a support member 27. As shown in FIG. The support member 27 is supported by a support member swing shaft 27a. The support member 27 is swingably supported around a support member swing shaft 27a. The support member 27 is placed in the first posture or the second posture by driving means (not shown). When the support member 27 is in the first posture, the second ejection roller 25b contacts the first ejection roller 25a as shown in FIG. When the support member 27 is in the second posture, the second discharge roller 25b is separated from the first discharge roller 25a.

When the scanner unit 1 reads one side of the document G, the document G whose first side has been read is discharged to the discharge tray 13 by the discharge roller pair 25 . When the scanner unit 1 reads both sides of the document G, the document G whose first surface has been read is discharged by the discharge roller pair 25 in a predetermined length. The document G ejected by a predetermined length is kept nipped by the ejection roller pair 25 . The document G ejected by a predetermined length is switchback-conveyed by driving the ejection roller pair 25 in the reverse direction. The switchback-conveyed document G passes over the flap 24 and is conveyed to the second document conveying path F2. When the document G transported to the second document transport path F2 is nipped by the first transport roller pair 19, the posture of the support member 27 is switched. The support member 27 assumes the second posture, and the second discharge roller 25b is separated from the first discharge roller 25a. The document G transported to the second document transport path F2 is transported to the nip position between the pressing member 22 and the second transparent glass 4b. The reading unit 7 reads the second surface of the document G conveyed to the nip position between the pressing member 22 and the second transparent glass 4b. The document G whose second surface has been read is discharged to the discharge tray 13 by the discharge roller pair 25 .
However, a reading unit for reading the second side of the document G may be provided separately, and the second side of the document G may be read when reading the first side of the document G. FIG.

The first document transport path F1 shown in FIG. 2 includes a first transport roller pair 19, a second transport roller pair 21, a pressing member 22, a paper guide member 23, and a flap from the nip position between the separation roller 16a and the separation member 16b. 24 to reach the nip position between the first discharge roller 25a and the second discharge roller 25b. A second document transport path F2 is a transport path from the flap 24 to the first transport roller pair 19 .

FIG. 3 shows the configuration around the pressing member 22. As shown in FIG. FIG. 3 is an enlarged view of the periphery of the pressing member 22 shown in FIG. FIG. 3 shows a state in which the ADF 3 is conveying the document G. As shown in FIG. As shown in FIG. 3, the pressing member 22 is provided with a pressure member 35 .

The reading sensor 7a reads the document G in the scanning area RA where the contact surface 22a of the pressing member 22 and the glass top surface 4s of the second transparent glass 4b are in contact. The scan area RA corresponds to the nip position between the pressing member 22 and the second transparent glass 4b. A sensor portion (not shown) of the reading sensor 7a faces the pressing member 22 in the scanning area RA. A scan area RA corresponds to an example of a reading area.

The pressing member 22 is supported by a support shaft 31 . The support shaft 31 is arranged at a position in the +X direction of the pressing member 22 and in the +Z direction of the second transparent glass 4b. The support shaft 31 supports the pressing member 22 so as to be rotatable about the support shaft 31 . The pressing member 22 is rotated by the transport of the document G when the document G passes through the nip position between the pressing member 22 and the second transparent glass 4b. The support shaft 31 is composed of one or more shaft members 31a, which will be described later. The support shaft 31 engages with a bearing portion 22c, which will be described later. The bearing portion 22 c is provided on the pressing member 22 . Since the support shaft 31 rotatably supports the pressing member 22, a clearance is provided between the support shaft 31 and the bearing portion 22c. By providing the clearance, the pressing member 22 can be displaced along the X-axis and the Z-axis. The displacement of the pressing member 22 includes rotation about the support shaft 31, sliding movement in the -X direction along the X axis, sliding movement in the +Z direction along the Z axis, and the like. The support shaft 31 corresponds to an example of a support portion.

The support shaft 31 is arranged upstream in the direction in which the document G is conveyed with respect to the scan area RA. The support shaft 31 is arranged in the +X direction and the +Z direction with respect to the scan area RA. By arranging the support shaft 31 upstream in the transport direction, the pressing member 22 rotates upward when the document G is transported to the nip position between the pressing member 22 and the second transparent glass 4b. By rotating the pressing member 22 upward, it is possible to prevent the pressing member 22 from applying an excessive pressing force to the document G. As shown in FIG.

The pressing member 22 has an inclined surface 22b at a position in the -X direction of the scan area RA, which is inclined in a direction away from the glass upper surface 4s of the second transparent glass 4b. The -X direction of the scan area RA corresponds to the downstream side of the document G transport direction. When the document G is nipped by the discharge roller pair 25 , tension is applied to the document G between the pressing member 22 and the discharge roller pair 25 . Since the discharge roller pair 25 is positioned above the pressing member 22, the document G under tension causes the pressing member 22 to move upward. By providing the pressing member 22 with the inclined surface 22 b , it is possible to reduce the upward movement of the pressing member 22 by the document G nipped by the discharge roller pair 25 . The inclined surface 22b corresponds to an example of an inclined portion.

The contact surface 22a that contacts the glass upper surface 4s has an inclined surface 22b that is inclined away from the glass upper surface 4s downstream of the scanning area RA.
The upward movement of the pressing member 22 due to the tension applied when the document G is nipped by the discharge roller pair 25 can be reduced.

The pressing member 35 presses the pressing member 22 toward the second transparent glass 4b. The pressing member 22 presses the second transparent glass 4 b by the pressing force of the pressing member 35 . The pressing force of the pressing member 35 is adjusted in advance within a range in which the pressing member 22 can be rotated. The pressure member 35 is composed of an elastic member such as a spring or rubber.

The paper guide member 23 is spaced apart from the pressing member 22 in the direction parallel to the X-axis. When the document G is not conveyed, the pressing member 22 and the paper guide member 23 are arranged in a non-contact state. The pressing member 22 is rotatable by arranging the pressing member 22 and the paper guide member 23 in a non-contact state.

A protrusion 41 is provided between the pressing member 22 and the paper guide member 23 . The protrusion 41 is arranged downstream of the scan area RA. The protrusion 41 is provided on the pressing member 22 or the paper guide member 23 . The protrusion 41 is provided on the surface of the pressing member 22 facing the paper guide member 23 or on the surface of the paper guiding member 23 facing the pressing member 22 . The protrusion 41 does not come into contact with the pressing member 22 or the paper guide member 23 when the document G is not conveyed. The protrusion 41 contacts the pressing member 22 or the paper guide member 23 when the pressing member 22 is displaced. The protrusion 41 reduces displacement of the pressing member 22 . The projecting portion 41 corresponds to an example of a restricting portion.

A scanner unit 1 for reading a document G transported in the transport direction includes a second transparent glass 4b having a glass upper surface 4s that contacts the document G, a reading unit 7 for reading the document G through the second transparent glass 4b, a glass A holding member 22 that faces the upper surface 4s and presses the upper surface 4s of the glass, and a holding member 22 are arranged upstream in the transport direction with respect to the scanning area RA where the upper surface 4s of the glass and the holding member 22 are in contact with each other, and the holding member 22 can be rotated. a support shaft 31 that supports the support shaft 31, a paper guide member 23 that is arranged downstream in the transport direction with respect to the scan area RA and guides the document G, and a pressing member 22 that is arranged downstream in the transport direction with respect to the scan area RA. and a protrusion 41 that regulates the displacement of the .
By providing the support shaft 31 upstream in the transport direction of the document G, when the document G is transported to the nip position between the pressing member 22 and the second transparent glass 4b, the scanner unit 1 supports the pressing member against the document G. An increase in the load due to the rotation of 22 can be suppressed. Further, when the document G is transported to the nip position between the pressing member 22 and the second transparent glass 4b, the scanner unit 1 suppresses the vibration and noise caused by the displacement of the pressing member 22 by means of the protrusion 41. can be done. The pressing member 22 vibrates due to variations in the frictional force between the document G and the contact surface 22 a of the pressing member 22 . The amount of vibration of the pressing member 22 is reduced by providing the protrusion 41 . Since the protrusion 41 reduces the vibration amount, the vibration of the pressing member 22 is reduced, and the generation of abnormal noise due to the vibration is suppressed.

A printer 100 that reads a document G transported in the transport direction and records an image on a recording sheet has a second transparent glass 4b having a glass upper surface 4s that contacts the document G, and the document G is passed through the second transparent glass 4b. A reading unit 7 for reading, a pressing member 22 that faces the glass top surface 4s and presses the glass top surface 4s, and a scanning area RA where the glass top surface 4s and the pressing member 22 are in contact with each other are arranged upstream in the conveying direction and hold down. a support shaft 31 that rotatably supports the member 22; a paper guide member 23 that is arranged downstream in the transport direction with respect to the scan area RA and guides the document G; A protrusion 41 arranged to restrict the displacement of the pressing member 22 and a recording head 108 recording an image on a recording sheet based on read data read by the reading unit 7 are provided.
By providing the support shaft 31 upstream in the transport direction of the document G, when the document G is transported to the nip position between the pressing member 22 and the second transparent glass 4b, the printer 100 can press the pressing member 22 onto the document G. It is possible to suppress the increase in load due to In addition, when the document G is conveyed to the nip position between the pressing member 22 and the second transparent glass 4b, the printer 100 suppresses the vibration and noise caused by the displacement of the pressing member 22 by the protrusion 41. can be done.

The protrusion 41 may be provided on the pressing member 22 or may be provided on the paper guide member 23 . The protrusion 41 is preferably provided on the paper guide member 23 . The paper guide member 23 is fixedly arranged on the ADF 3 . By providing the protrusion 41 on the paper guide member 23, the gap between the protrusion 41 and the pressing member 22 can be accurately manufactured when the scanner unit 1 is manufactured. The projecting portion 41 is provided as a projecting member 41 a at a portion of the paper guide member 23 facing the pressing member 22 . The convex member 41a corresponds to an example of a convex portion. Further, it is preferable that the convex member 41a is configured integrally with the paper guide member 23. As shown in FIG.

The protrusion 41 is preferably a protrusion 41 a provided on the paper guide member 23 .
By using the projecting member 41a provided on the paper guide member 23 as the projecting portion 41, variations in the distance between the projecting member 41a and the pressing member 22 can be suppressed.

The protrusion 41 is preferably formed integrally with the paper guide member 23 .
The number of parts of the scanner unit 1 at the time of manufacturing the scanner unit 1 is reduced.

The material of the protrusion 41 provided on the paper guide member 23 may be the same material as the paper guide member 23, or may be a different material. The material of the protrusion 41 is preferably different from that of the paper guide member 23 . The pressing member 22 is made of ABS resin, for example. The paper guide member 23 is made of, for example, polystyrene resin. As an example, the protrusion 41 is preferably an elastic member. A member having elasticity can press the pressing member 22 . Materials having elasticity include natural rubber, butadiene rubber, silicone rubber, urethane rubber, and fluororubber. A member having elasticity corresponds to an example of an elastic member. Vibration of the pressing member 22 is suppressed by forming the projecting portion 41 from an elastic member. Moreover, it is preferable to form the projecting portion 41 from a material having high slidability. A material with high slidability is, for example, polyacetal resin. Since the protrusion 41 is made of a highly slidable material, abrasion when the protrusion 41 comes into contact with the pressing member 22 is suppressed.

The protrusion 41 provided on the paper guide member 23 may be configured by a spring member. A spring member is an example of a member having elasticity. A spring member corresponds to an example of an elastic member. The spring member presses the pressing member 22 . The projecting portion 41 can absorb the impact when the projecting portion 41 comes into contact with the pressing member 22 by being composed of a spring member.

The projecting portion 41 is provided on the paper guide member 23 and is a member having elasticity capable of pressing the pressing member 22 .
Vibration of the pressing member 22 is suppressed by forming the projecting portion 41 from a member having elasticity.

FIG. 4 shows the configuration of the pressing member 22 and the paper guide member 23 viewed from the +Z direction. FIG. 4 omits members arranged above the pressing member 22 and the paper guide member 23 . FIG. 4 shows the support structure of the pressing member 22 by the support shaft 31 and the relationship between the pressing member 22 and the paper guide member 23. As shown in FIG.

As shown in FIG. 4, the support shaft 31 is composed of a plurality of shaft members 31a. The shaft member 31 a supports the pressing member 22 . The shaft member 31a is supported by the frame of the ADF 3 (not shown) or the like. Although FIG. 4 shows six shaft members 31a, it is not limited to this. The support shaft 31 is composed of one or more shaft members 31a.

The support shaft 31 engages with the bearing portion 22c. The bearing portion 22c has an engagement hole (not shown) that engages with the shaft member 31a. The bearing portion 22c engages with the shaft member 31a through an engagement hole. The inner diameter of the engaging hole is larger than the outer shape of the shaft member 31a. A clearance is provided between the engagement hole and the shaft member 31a. The bearing portion 22c is rotatably engaged with the shaft member 31a. The pressing member 22 rotates around the rotation axis RS. The rotation axis RS is a virtual axis passing through the center of the support shaft 31 . The rotation axis RS intersects the conveying direction of the document G in the scanning area RA. The rotation axis RS corresponds to an example of a virtual support axis. FIG. 4 shows a plurality of bearings 22c. The bearing portion 22c is provided corresponding to the shaft member 31a. The bearing portion 22 c is configured in the pressing member 22 .

As shown in FIG. 4, two bearing portions 22c are engaged with one shaft member 31a. A region between the engagement positions of the two bearing portions 22c when the two bearing portions 22c are engaged with one shaft member 31a is referred to as an engagement region SA. The engagement area SA is a partial area of the rotation axis RS along the rotation axis RS. The support shaft 31 supports the pressing member 22 in an engagement area SA that is part of the rotation shaft RS. The engagement area SA corresponds to an example of a support area.

A first area PA and a second area PB shown in FIG. 4 indicate positions where the protrusions 41 are formed. The first area PA is located on the +Y direction side of the pressing member 22 and the paper guide member 23 . The second area PB is located on the −Y direction side of the pressing member 22 and the paper guide member 23 . The protrusions 41 are provided in the first area PA and the second area PB. The first area PA and the second area PB are positioned so as not to overlap the engagement area SA when viewed in the direction along the X axis. The direction along the X-axis corresponds to the transport direction of the document G in the scanning area RA. The protrusion 41 arranged in the first area PA is configured at a position not overlapping the engagement area SA when viewed in the direction along the X axis. The protrusion 41 arranged in the second area PB is configured at a position that does not overlap with the engagement area SA when viewed in the direction along the X axis.

When the pressing member 22 is supported by the shaft member 31a in a partial region of the rotation shaft RS, the end of the pressing member 22 is displaced in the +X direction or the -X direction about the shaft member 31a. A position that does not overlap with the engagement area SA is more likely to be displaced in the +X direction or the -X direction than a position that overlaps with the engagement area SA. Therefore, the pressing member 22 may be tilted with respect to the Y-axis. The protrusion 41 is provided at a position that does not overlap with the engagement area SA in the direction along the X axis, so that the protrusion 41 can suppress the inclination of the pressing member 22 .

The support shaft 31 supports the pressing member 22 in a partial engagement region SA of the rotation shaft RS that intersects the conveying direction, and the protrusion 41 overlaps the engaging region SA when viewed from the conveying direction. not.
The projecting portion 41 can suppress the inclination of the pressing member 22 .

FIG. 5 shows the configuration of the first area PA. FIG. 6 shows the configuration of the second region PB. FIG. 5 shows an enlarged view of the first area PA shown in FIG. FIG. 6 shows an enlarged view of the second region PB shown in FIG. Projecting members 41a, which are projections 41, are provided in the first area PA and the second area PB.

FIG. 5 shows the projecting member 41a provided in the first area PA. The convex member 41 a is provided on the paper guide member 23 . FIG. 5 shows the configuration when the document G is not conveyed. The projecting member 41 a does not contact the pressing member 22 . When the document G passes through the scanning area RA, the pressing member 22 is displaced. When the pressing member 22 is displaced, the convex member 41a comes into contact with the pressing member 22. As shown in FIG. The projecting member 41 a can suppress vibration of the pressing member 22 by contacting the pressing member 22 . The convex member 41a corresponds to an example of a contact member.

FIG. 6 shows the convex member 41a provided in the second region PB. The convex member 41 a is provided on the paper guide member 23 . FIG. 6 shows the configuration when the document G is not conveyed. The projecting member 41 a does not contact the pressing member 22 . When the document G passes through the scanning area RA, the pressing member 22 is displaced. When the pressing member 22 is displaced, the convex member 41a comes into contact with the pressing member 22. As shown in FIG. The projecting member 41 a can suppress vibration of the pressing member 22 by contacting the pressing member 22 .

The first area PA and the second area PB each have a convex member 41a. The paper guide member 23 shown in FIG. 4 includes two convex members 41a. The projecting portion 41 is composed of two projecting members 41a. The number of projecting members 41a is not limited to two. Two or more convex members 41a may be provided. The paper guide member 23 may be provided with a plurality of convex members 41a. A plurality of projecting members 41a are provided along the Y-axis. The Y-axis is an example of a direction intersecting the transport direction. By providing the plurality of projecting members 41a, it is possible to prevent the pressing member 22 from tilting with respect to the Y-axis. At this time, since the first area PA and the second area PB are separated from each other, it is possible to more effectively suppress the inclination of the pressing member 22 with respect to the Y axis.

The projecting portion 41 is provided on the paper guide member 23 and is composed of a plurality of projecting members 41a that can come into contact with the pressing member 22. The plurality of projecting members 41a are provided along the direction intersecting the conveying direction.
By providing the plurality of projecting members 41a along the Y-axis, the inclination of the pressing member 22 can be suppressed.

REFERENCE SIGNS LIST 1 scanner unit 2 main body 3 ADF 4 manuscript table 4a first transparent glass 4b second transparent glass 4s upper surface of glass 6 ADF cover 7 reading unit 7a Reading sensor 10 Feeding tray 10a First feeding member 10b Second feeding member 12 Guide section 12a First edge guide 12b Second edge guide 13 Discharge tray 15 Feed roller 16 Separation section 16a Separation roller 16b Separation member 17 Roller support member 19 First conveying roller pair 19a First driving roller 19b First driven roller 20 Support rollers 21 Second conveying roller pair 21a Second driving roller 21b Second driven roller 22 Pressing member 22a Contact surface 22b Inclined surface 22c Bearing 23 Paper guide member , 24 Flap 24a Flap rocking shaft 25 Discharge roller pair 25a First discharge roller 25b Second discharge roller 27 Support member 27a Support member swing shaft 31 Support shaft 31a...Shaft member 35...Pressure member 41...Protrusion 41a...Convex member 100...Printer 101...Recording unit 102...Paper feed unit 102a...First paper feed cassette 102b...Second paper feed Cassette 103 Ejection port 104 Operation unit 105 Paper ejection unit 106 Rear cover 107 Carriage 108 Recording head G Document F1 First document transport path F2 Second document transport Path, PA... first area, PB... second area, RA... scanning area, RS... rotating shaft, SA... engaging area.

Claims (8)

An image reading device for reading a document conveyed in a conveying direction,
a document support member having a reading surface that contacts the document;
a reading unit that reads the document via the document support member;
a pressing portion that faces the reading surface and presses the reading surface;
a support portion arranged upstream in the conveying direction with respect to a reading area where the reading surface and the pressing portion are in contact with each other, and rotatably supporting the pressing portion;
a path member arranged downstream in the transport direction with respect to the reading area and guiding the document;
a regulating portion arranged downstream in the transport direction with respect to the reading area and regulating displacement of the pressing portion;
an image reader. The restricting portion is a convex portion provided on the path member,
The image reading device according to claim 1. The restricting portion is formed integrally with the path member,
3. The image reading device according to claim 2. The restricting portion is provided in the path member and is an elastic member capable of pressing the pressing portion.
The image reading device according to claim 1. The support portion supports the pressing portion in a partial support area of a virtual support shaft that intersects the conveying direction,
the restricting portion does not overlap the support area when viewed from the transport direction;
The image reading device according to any one of claims 1 to 4. The regulating portion is provided on the path member and is composed of a plurality of contact members capable of contacting the pressing portion, and the plurality of contact members are provided along a direction intersecting the conveying direction.
The image reading device according to any one of claims 1 to 5. the pressing surface in contact with the reading surface has an inclined portion downstream of the reading area and inclined in a direction away from the reading surface;
The image reading device according to any one of claims 1 to 6. A recording device that reads a document transported in a transport direction and records an image on a medium,
a document support member having a reading surface that contacts the document;
a reading unit that reads the document via the document support member;
a pressing portion that faces the reading surface and presses the reading surface;
a support portion arranged upstream in the conveying direction with respect to a reading area where the reading surface and the pressing portion are in contact with each other, and rotatably supporting the pressing portion;
a path member arranged downstream in the transport direction with respect to the reading area and guiding the document;
a regulating portion arranged downstream in the transport direction with respect to the reading area and regulating displacement of the pressing portion;
a recording unit that records the image on the medium based on the read data read by the reading unit;
recording device.

Images