JP7185553B2 - Image reader - Google Patents

Description

The technology of the present disclosure relates to an image reading device.

2. Description of the Related Art There is known an image reading apparatus provided with a switching unit that switches a conveying path according to the detection result of the thickness of a medium (Patent Document 1). 2. Description of the Related Art A sheet tray provided with a plurality of sheet guide portions for positioning sheets of different sizes at predetermined placement positions is known (Patent Document 2).

JP 2013-52929 A JP 2004-345787 A

In the image reading apparatus of Patent Document 1, since the thickness of the medium is detected after the medium is conveyed, the medium may pass through the switching section before the switching section switches the conveying path, causing a problem. .

The disclosed technology has been made in view of the above points, and aims to provide an image reading apparatus that appropriately transports a medium to a switched transport path.

An image reading device according to one aspect of an embodiment includes a chute having a depression, an imaging unit that captures an image of a medium fed from the chute, and guides the medium to a first transport path or a second transport path. a switching unit, a mechanism for changing the magnitude of the force with which the imaging unit presses the medium, a sensor for detecting whether or not the first medium is placed in the depression, and the first medium in the depression. The mechanism controls the switching unit so that the first medium is guided to the first transport path when it is detected to be placed , and the mechanism reduces the magnitude of the force. and a control unit for controlling the

The disclosed image reading device can appropriately transport the medium to the switched transport path.

FIG. 1 is a perspective view showing an image reading apparatus of Example 1. FIG. FIG. 2 is a perspective view showing the image reading device when the switching unit is arranged at the discharge opening open position. FIG. 3 is a perspective view showing the image reading device when the stacker is arranged at the stacker storage position. FIG. 4 is a perspective view showing the image reading device when the shooter is arranged at the shooter retracted position. FIG. 5 is a perspective view showing a shooter. FIG. 6 is a plan view showing the shooter. FIG. 7 is a side view showing the shooter. 8 is a cross-sectional view taken along the line BB of FIG. 6. FIG. 9 is a cross-sectional view taken along the line AA of FIG. 6. FIG. FIG. 10 is a front view showing an imaging unit and a pressing force switching mechanism. FIG. 11 is a front view showing the imaging section when the frame 53 is arranged at the weak pressing force position. FIG. 12 is a block diagram showing an image reading device. FIG. 13 is a flow chart showing the operation of the image reading device. FIG. 14 is a flow chart showing another operation of the image reading apparatus. FIG. 15 is a flow chart showing still another operation of the image reading apparatus. FIG. 16 is a perspective view showing the shooter of the image reading apparatus of the modification. FIG. 17 is a side view of the shooter of the image reading apparatus according to the second embodiment; FIG. 18 is a side view of the shooter of the image reading apparatus according to the second embodiment when the shooter main body is arranged at the shooter deployment position. FIG. 19 is a side view showing the shooter of the image reading apparatus of the second embodiment when the recessed portion is arranged at the recessed portion unfolded position.

An image reading apparatus according to embodiments disclosed in the present application will be described below with reference to the drawings. In addition, the present invention is not limited by the following description. Also, in the following description, the same constituent elements are given the same reference numerals, and overlapping descriptions are omitted.

FIG. 1 is a perspective view showing an image reading apparatus 1 of Example 1. FIG. The image reading apparatus 1 includes an image reading apparatus main body 2, a shooter 3, a stacker 5, and a switching section 6, as shown in FIG. The image reading device main body 2 is formed in a box shape and placed on an installation surface on which the image reading device 1 is installed. The image reading apparatus main body 2 is formed with a discharge port 7 and a transport path (not shown). The transport path is formed inside the image reading apparatus main body 2 .

The shooter 3 is formed in a plate shape and has a shooter mounting surface 11 formed thereon. The shooter 3 is supported by the image reading apparatus main body 2 so as to be rotatable about a rotation shaft 12 so as to be arranged at the shooter deployment position or the shooter retracted position. The shooter 3 is fixed to the image reading apparatus main body 2 so that the shooter mounting surface 11 faces obliquely upward when the shooter is arranged at the unfolded position. One end of the transport path that is closer to the shooter 3 is connected to the shooter mounting surface 11 when the shooter 3 is arranged at the shooter deployment position.

The stacker 5 is formed in a plate shape and has a stacker mounting surface 14 formed thereon. The stacker 5 is supported by the image reading apparatus main body 2 so as to be rotatable about a rotary shaft 15 so as to be arranged at the stacker deployment position or the stacker storage position. The stacker 5 is fixed to the image reading apparatus main body 2 so that the stacker placement surface 14 faces obliquely upward when the stacker 5 is placed at the stacker deployment position.

The switching unit 6 is arranged near the discharge port 7 and is movably supported by the image reading apparatus main body 2 so as to be arranged at the discharge port closed position or the discharge port open position. The switching unit 6 switches the conveying path to the U-turn path when the outlet is closed. One end of the U-turn path is connected to the shooter mounting surface 11, the other end is connected to the stacker mounting surface 14, and the other end and the discharge port 7 are blocked. In other words, the switching unit 6 closes the ejection port 7 and guides the medium fed from the chute 3 to the U-turn path when it is in the ejection port closed position.

FIG. 2 is a perspective view showing the image reading device 1 when the switching unit 6 is arranged at the discharge opening open position. The switching unit 6 switches the conveying path to the straight path when it is in the discharge port open position. One end of the straight path is connected to the shooter mounting surface 11, the other end is connected to the discharge port 7, and the other end and the stacker mounting surface 14 are blocked. In other words, the switching unit 6 opens the discharge port 7 and guides the medium fed from the chute 3 to the straight path when it is in the discharge port open position.

FIG. 3 is a perspective view showing the image reading device 1 when the stacker 5 is arranged at the stacker storage position. The stacker 5 runs along the upper surface of the image reading apparatus main body 2 when arranged at the stacker storage position. When the stacker 5 is placed at the stacker retracted position, the stacker 5 retreats from the area through which the shooter 3 passes when moving from the shooter unfolding position to the shooter retracted position. By retreating from this area, the stacker 5 is prevented from interfering with the shooter 3 when the shooter 3 moves from the shooter deployment position to the shooter retracted position.

FIG. 4 is a perspective view showing the image reading device 1 when the shooter 3 is arranged at the shooter storage position. The shooter 3 can be placed at the shooter storage position when the stacker 5 is placed at the stacker storage position. The shooter placement surface 11 of the shooter 3 faces obliquely downward and faces the stacker placement surface 14 when the shooter 3 is arranged at the shooter storage position. The image reading device 1, when the shooter 3 is arranged at the shooter storing position, is made more compact than the image reading device 1 when the shooter 3 is arranged at the shooter unfolding position, and is stored in a smaller space. can be done.

FIG. 5 is a perspective view showing the shooter 3. FIG. The shooter 3 has a recess 21 formed in the shooter mounting surface 11 . The shooter 3 is formed with a small medium mounting surface 22 by forming a recess 21 . The small medium mounting surface 22 is generally flat and forms the bottom of the recess 21 . FIG. 6 is a plan view showing the shooter 3. FIG. FIG. 7 is a side view showing the shooter 3. FIG. The small media placement surface 22 includes a common portion 23 , a right portion 24 , a left portion 25 and an upstream portion 26 . The common portion 23 is formed so as to connect to the center of the end 27 of the shooter 3 that is closer to one end of the transport path. The right portion 24 and the left portion 25 are arranged so that the common portion 23 is arranged between the right portion 24 and the left portion 25 and are formed to be connected to the end 27 . The upstream portion 26 is positioned farther from the end 27 than the common portion 23 such that the common portion 23 is positioned between the upstream portion 26 and the end 27 .

The shooter 3 further has a side wall surface formed by forming a recess 21 . The side wall surfaces include an upper alignment surface 31 for vertical media, an upper right alignment surface 32 for horizontal media, an upper left alignment surface 33 for horizontal media, a right alignment surface 34 for horizontal media, and a left alignment surface 35 for horizontal media. and a right aligning surface 36 for longitudinal media and a left aligning surface 37 for longitudinal media. The vertically placed medium upper alignment surface 31 is formed substantially flat along a plane substantially perpendicular to the plane along the shooter mounting surface 11 . The upper tandem media alignment surface 31 further faces the edge 27 and connects to the upstream portion 26 such that the plane along the upper tandem media alignment surface 31 is parallel to the straight line along the edge 27 and the upstream portion 26 . are arranged so that

The laterally placed medium upper right alignment surface 32 is formed substantially flat along a plane substantially perpendicular to the plane along the shooter mounting surface 11 . The lateral media upper right alignment surface 32 is further opposed to the edge 27 such that a plane along the lateral media upper right alignment surface 32 is parallel to a straight line along the edge 27 and the right side portion 24 are arranged so that they are connected to The laterally placed medium upper left alignment surface 33 is formed substantially flat along a plane along the laterally placed medium upper right alignment surface 32 . An upper left side alignment surface 33 for transverse media is further arranged to face the end 27 and connect to the left side portion 25 .

The laterally placed medium right alignment surface 34 is formed substantially flat along a plane that is substantially perpendicular to the plane along the shooter mounting surface 11 . Right lateral media alignment surface 34 is further positioned such that a plane along right lateral media alignment surface 34 is generally perpendicular to a line along edge 27 and joins right portion 24 . ing. The laterally placed medium left alignment surface 35 is formed substantially flat along a plane substantially perpendicular to the plane along the shooter mounting surface 11 . The left lateral media alignment surface 35 is further positioned such that a plane along the left lateral media alignment surface 35 is generally perpendicular to a straight line along the edge 27 and joins the left portion 25 . ing. The left horizontal alignment surface 35 further faces the right horizontal alignment surface 34 , and the right horizontal alignment surface 34 faces the left horizontal alignment surface 35 .

The vertically placed medium right alignment surface 36 is formed substantially flat along a plane that is substantially perpendicular to the plane along the shooter mounting surface 11 . Right transverse media alignment surface 36 is further positioned such that a plane along right transverse media alignment surface 36 is generally perpendicular to a straight line along edge 27 and joins upstream portion 26 . ing. The vertically placed medium left alignment surface 37 is formed substantially flat along a plane substantially perpendicular to the plane along the shooter mounting surface 11 . Left longitudinal media alignment surface 37 is further positioned such that a plane along left longitudinal media alignment surface 37 is generally perpendicular to a line along edge 27 and joins upstream portion 26 . ing. The left portrait media alignment surface 37 further faces the right portrait media alignment face 36 , and the right portrait media alignment face 36 faces the left portrait media alignment face 37 .

A small medium 38 such as a business card, credit card, or cash card is placed vertically or horizontally in the recess 21 . When the small media 38 is placed vertically in the recess 21, one edge of the small media 38 is aligned with the upper vertical media alignment surface 31, the right vertical media alignment surface 36, and the left vertical media alignment surface 36. It is sandwiched between the alignment surface 37 and the alignment surface 37 . The small media 38 are formed into a common portion by one edge of the small media 38 along the upper vertical media alignment surface 31 and sandwiched between the right vertical media alignment surface 36 and the left vertical media alignment surface 37 . 23 and upstream portion 26 are suitably mounted. When the small medium 38 is placed horizontally in the recess 21, one edge of the small medium 38 is aligned with the upper right side alignment surface 32 and the upper left side alignment surface 33 for the sideways medium. It is sandwiched between the right media alignment surface 34 and the left lateral media alignment surface 35 . The small media 38 has one edge along the right landscape media alignment surface 32 and the top left landscape media alignment surface 33 and has a right landscape media alignment surface 34 and a left landscape media alignment surface 35 . It is properly placed on the common portion 23, the right portion 24 and the left portion 25 by being sandwiched between them. In other words, the recess 21 is formed so that the small medium 38 is placed vertically or so that the small medium 38 is placed horizontally. Also, the small medium 38 is placed on the common portion 23 regardless of whether it is placed vertically or horizontally.

The image reader 1 further comprises a first small medium detection sensor 41, as shown in FIG. 8 is a cross-sectional view taken along the line BB of FIG. 6. FIG. The first small medium detection sensor 41 is formed of a reflective sensor and includes a sensor body 42 and a reflective member 43 . The sensor body 42 is arranged on the upper vertical media alignment surface 31 . The sensor body 42 emits light that travels from the vertically placed medium upper alignment surface 31 toward the common portion 23 , and when the light is being emitted, the light travels from the common portion 23 to the vertically placed medium upper alignment surface 31 . Detects the presence or absence of light traveling toward it. The reflecting member 43 is arranged in the common portion 23 so as to reflect the light emitted by the sensor body 42 so that the reflected light travels toward the upper alignment surface 31 for longitudinally placed media. The first small medium detection sensor 41 determines that no medium is placed in the depression 21 when the sensor body 42 detects light traveling from the common portion 23 toward the upper alignment surface 31 for vertically placed medium. The first small medium detection sensor 41 determines that a medium is placed in the recess 21 when the sensor body 42 does not detect light traveling from the common portion 23 toward the upper alignment surface 31 for vertically placed medium.

The image reader 1 further comprises a second small medium detection sensor 45, as shown in FIG. 9 is a cross-sectional view taken along the line AA of FIG. 6. FIG. The second small medium detection sensor 45 is formed from a reflective sensor and includes a sensor body 46 and a reflective member 47 . The sensor body 46 is positioned on the right lateral media alignment surface 34 . The sensor body 46 emits light that travels from the right laterally placed medium alignment surface 34 toward the common portion 23 and, when the light is being emitted, travels from the common portion 23 to the right laterally placed medium alignment surface 34 . Detects the presence or absence of light traveling toward it. The reflecting member 47 is arranged in the common portion 23 so as to reflect the light emitted by the sensor body 46 so that the reflected light travels toward the laterally placed medium right alignment surface 34 . The second small medium detection sensor 45 determines that no medium is placed in the depression 21 when the sensor body 46 detects light traveling from the common portion 23 toward the right alignment surface 34 for laterally placed media. The second small medium detection sensor 45 determines that a medium is placed in the depression 21 when the sensor body 46 does not detect light traveling from the common portion 23 toward the right alignment surface 34 for laterally placed media.

The image reading device 1 further includes an imaging unit 51 and a pressing force switching mechanism 52, as shown in FIG. FIG. 10 is a front view showing the imaging unit 51 and the pressing force switching mechanism 52. As shown in FIG. The imaging unit 51 is formed from a CIS (Contact Image Sensor) type image sensor. The imaging unit 51 is arranged near the transport path inside the image reading apparatus main body 2 so as to come into contact with one surface of the medium transported along the transport path, and is perpendicular to the plane along the transport path. It is supported by the image reading device main body 2 so as to be able to translate in a pressing direction 56 . The imaging unit 51 captures an image of a medium conveyed on the conveying path.

The pressing force switching mechanism 52 includes a frame 53 , a compression coil spring 54 and a pressing force switching actuator 55 . The frame 53 is arranged between a reading unit support portion 57, which is a part of the image reading apparatus main body 2, and the imaging unit 51, and is arranged in the pressing direction so as to be arranged at the strong pressing force position or the weak pressing force position. 56 is supported by a reading section support portion 57 so as to be able to translate. The compression coil spring 54 is made of an elastic material and arranged between the frame 53 and the imaging section 51 . One end of the compression coil spring 54 is fixed to the frame 53 and the other end of the compression coil spring 54 is fixed to the imaging section 51 . The compression coil spring 54 applies elastic force to the imaging section 51 so that the imaging section 51 is pressed against the medium conveyed along the conveyance path. The pressing force switching actuator 55 is arranged between the frame 53 and the reading section support portion 57 . The pressing force switching actuator 55 translates the frame 53 in the pressing direction 56 to place the frame 53 at the strong pressing force position or the weak pressing force position.

FIG. 11 is a front view showing the imaging section 51 when the frame 53 is arranged at the weak pressing force position. The distance between the frame 53 and the transport path when the frame 53 is placed at the weak pressing force position is longer than the distance between the frame 53 and the transport path when the frame 53 is placed at the strong pressing force position. . Therefore, when the frame 53 is placed at the weak pressing force position, the compression coil spring 54 exerts an elastic force on the imaging unit 51, and when the frame 53 is placed at the strong pressing force position, the elastic force applied to the imaging unit 51 is the same as that of the compression coil spring 54 applied to the imaging unit. It is weaker than the elastic force given to 51.

FIG. 12 is a block diagram showing the image reading device 1. As shown in FIG. The image reading apparatus 1 further includes a medium set detection sensor 61 , a switching unit switching actuator 62 , a conveying unit 63 , a scan button 64 and a controller 65 . The medium set detection sensor 61 is provided in the shooter 3 and detects whether or not a medium is placed in an area adjacent to the depression 21 of the shooter placement surface 11 of the shooter 3 , and sends the detection result to the controller 65 . Output. The switching portion switching actuator 62 is controlled by the controller 65 to move the switching portion 6 to place the switching portion 6 at the discharge port closed position or the discharge port open position.

The transport unit 63 is controlled by the controller 65 to feed one medium onto the transport path when one medium is placed on the shooter 3 . Under the control of the controller 65 , the transport unit 63 transports one of the plurality of media placed farther from the shooter 3 into the transport path when a plurality of media are placed on the shooter 3 . send out to Under the control of the controller 65, the transport unit 63 transports the fed medium along the U-turn path when the switching unit 6 is arranged at the discharge port closed position, and transports the transported medium. It is placed on the stacker 5 . Under the control of the controller 65, the transport unit 63 transports the fed medium along a straight path when the switching unit 6 is arranged at the discharge port open position, and transports the transported medium. It is discharged from the discharge port 7. At this time, the degree of deformation of the medium conveyed through the U-turn path is greater than the degree of deformation of the medium conveyed through the straight path.

The scan button 64 is provided in the image reading apparatus main body 2 , detects whether or not it has been pressed by the user, and outputs the detection result to the controller 65 .

The controller 65 is a computer and includes a CPU (Central Processing Unit) 66 and a storage device 67 . The CPU 66 processes information and controls the storage device 67 by executing a computer program installed in the controller 65 . The CPU 66 further includes the first small medium detection sensor 41 , the second small medium detection sensor 45 , the pressing force switching actuator 55 , the medium set detection sensor 61 , the switching unit switching actuator 62 , the transport unit 63 , and the scan button 64 . Control. Examples of the storage device 67 include memories such as RAM and ROM, fixed disk devices such as hard disks, and SSDs (Solid State Drives). The storage device 67 records computer programs installed in the controller 65 and records information used by the CPU 66 .

For example, the controller 65 controls the first small medium detection sensor 41 and the second small medium detection sensor 45 so as to detect whether or not a medium is placed in the recess 21 of the shooter 3 . The controller 65 controls the medium set detection sensor 61 so as to detect whether or not a medium is placed in an area adjacent to the recess 21 of the shooter placement surface 11 of the shooter 3 . The controller 65 controls the pressing force switching actuator 55 so that the frame 53 is arranged at the strong pressing force position or the weak pressing force position. The controller 65 controls the switching portion switching actuator 62 so that the switching portion 6 is arranged at the discharge port closed position or the discharge port open position. The controller 65 controls the transport section 63 so that the medium placed on the shooter 3 is fed to the transport path, and the medium fed to the transport path is transported along the U-turn path or the straight path. The controller 65 further controls the transport section 63 so that the medium transported along the U-turn path is placed on the stacker 5 and the medium transported along the straight path is discharged from the discharge port 7 . Control.

[Operation of image reading device 1]
FIG. 13 is a flow chart showing the operation of the image reading apparatus 1. As shown in FIG. When the user wants to read an image on a medium using the image reading apparatus 1, the user places the shooter 3 at the shooter unfolding position and the stacker 5 at the stacker unfolding position. The switching unit 6 is initially placed at the discharge port closed position before the image reading apparatus 1 operates, the transport path is switched to the U-turn path, and the frame 53 is placed at the strong pressing position. Further, the storage device 67 records that, before the image reading apparatus 1 operates, it is initially arranged at the discharge port closed position and the transport path is switched to the U-turn path. When the user wants to read an image of one small medium using the image reading apparatus 1, the user places one small medium on the small medium placement surface 22 of the recess 21 of the shooter 3 and presses the scan button 64. (step S1). When a user wants to read an image of one large-sized medium using the image reading device 1, the user places one large-sized medium on an area adjacent to the recess 21 of the shooter mounting surface 11 of the shooter 3, and scans the medium. button 64 is pressed; A4 size copy paper is exemplified as a large medium.

After detecting that the scan button 64 has been pressed, the controller 65 controls the medium set detection sensor 61 so that the large medium is placed in the area of the shooter placement surface 11 adjacent to the recess 21 . is detected (step S2). The controller 65 controls the first small medium detection sensor 41 and the second small medium detection sensor 45 when no large medium is placed (step S2, No), so that the small medium placement surface 22 (step S3). When it is detected that no small medium is placed on the small medium placement surface 22 (step S3, No), the controller 65 determines that no medium is placed on the shooter 3 (step S4). ).

When it is detected that a small medium is placed on the small medium placement surface 22 (step S3, Yes), the controller 65 controls the switching unit switching actuator 62 to switch the switching unit 6. Place the outlet in the open position. The conveying path is switched to a straight path by arranging the switching unit 6 at the discharge opening open position (step S5). Further, the controller 65 arranges the frame 53 at the weak pressing force position by controlling the pressing force switching actuator 55 . Further, the controller 65 erases from the storage device 67 that the transport path has been switched to the U-turn path, and records in the storage device 67 that the transport path has been switched to the straight path.

The controller 65 starts scanning (step S6) when it detects that a large medium is placed (step S2, Yes) or after the transport path is switched to the straight path (step S5). ). When scanning is started, the controller 65 feeds the medium placed on the shooter 3 onto the transport path by controlling the transport unit 63, and transports the medium fed onto the transport path along the transport path. . The controller 65 captures an image of the medium being transported along the transport path by controlling the imaging unit 51 while the medium is being transported along the transport path. The imaged medium is transported along the straight path and placed on the stacker 5 when the transport path is switched to the U-turn path. The medium on which the image has been captured is conveyed along the straight path when the conveying path is switched to the straight path, and discharged from the discharge port 7 (step S7).

The controller 65 determines whether or not it is recorded in the storage device 67 that the transport path has been switched to the straight path after the medium is placed on the stacker 5 or after the medium is ejected from the ejection port 7. is determined (step S8). When the storage device 67 records that the straight path has been switched (step S8, No), the controller 65 controls the switching portion switching actuator 62 to move the switching portion 6 to the discharge port closed position. to be placed. The transport path is switched to a U-turn path by arranging the switching unit 6 at the discharge port closed position (step S9). The controller 65 also controls the pressing force switching actuator 55 to place the frame 53 at the strong pressing force position. Further, the controller 65 erases from the storage device 67 that the transport path has been switched to the straight path, and records in the storage device 67 that the transport path has been switched to the U-turn path.

According to such operations, the image reading apparatus 1 can automatically move the switching unit 6 to convey a large-sized medium along a U-turn path and convey a small-sized medium along a straight path. can. Therefore, the image reading apparatus 1 can prevent the small medium from being guided to the U-turn path, thereby preventing the small medium from being bent or jamming the U-turn path. can do.

Before the small-sized medium placed in the depression 21 of the shooter 3 is delivered to the conveying path, the image reading apparatus 1 sets the switching unit 6 to the discharge port open position so that the small-sized medium is guided to the straight path. can be placed. Therefore, the image reading apparatus 1 can place the switching unit 6 at the ejection port open position before the small medium passes through the switching unit 6, and can appropriately convey the small medium along the straight path. can.

FIG. 14 is a flow chart showing another operation of the image reading apparatus 1. FIG. When a user wants to read images of a plurality of small-sized media and images of a plurality of large-sized media using the image reading apparatus 1, the user first places the plurality of small-sized media on the mounting surface 22 of the recess 21 of the shooter 3. be placed on. After a plurality of small-sized media are placed on the small-sized medium placement surface 22 of the recess 21, the user places a plurality of large-sized media on an area of the shooter placement surface 11 of the shooter 3 adjacent to the recess 21. (step S11). After placing a plurality of small media and a plurality of large media on the shooter 3, the user presses the scan button 64 (step S12).

After detecting that the scan button 64 has been pressed, the controller 65 detects whether or not a large medium is placed on the shooter placement surface 11 by controlling the medium set detection sensor 61 (step S13). The controller 65 controls the first small medium detection sensor 41 and the second small medium detection sensor 45 when no large medium is placed (step S13, No), so that the small medium placement surface 22 (step S14). When the controller 65 detects that a small medium is placed on the small medium placement surface 22 (step S14, Yes), the controller 65 controls the switching unit switching actuator 62 to switch the switching unit 6. Place the outlet in the open position. The conveying path is switched to a straight path by arranging the switching unit 6 at the discharge opening open position (step S15). Further, the controller 65 arranges the frame 53 at the weak pressing force position by controlling the pressing force switching actuator 55 .

The controller 65 starts scanning (step S16) when it detects that a large medium is placed (step S13, Yes) or after the transport path is switched to the straight path (step S15). ). When scanning is started, the controller 65 controls the transport unit 63 to feed one medium farther from the shooter 3 out of the plurality of media placed on the shooter 3 onto the transport path, and transport the medium. The medium fed out to the path is transported along the transport path. The controller 65 captures an image of the medium being transported along the transport path by controlling the imaging unit 51 while the medium is being transported along the transport path. The imaged medium is transported along the straight path and placed on the stacker 5 when the transport path is switched to the U-turn path. The medium on which the image has been captured is conveyed along the straight path when the conveying path is switched to the straight path, and discharged from the discharge port 7 (step S17). The controller 65 repeats the operations from step S13 to step S17 until all the media placed on the shooter 3 are used up.

When it is detected that no small medium is placed on the small medium placement surface 22 (step S14, No), the controller 65 determines that no medium is placed on the shooter 3 (step S18). ). After determining that no medium is placed on the shooter 3, the controller 65 determines whether the transport path is switched to the U-turn path or the straight path (step S19). When the transport path is switched to the straight path (step S19, No), the controller 65 controls the switching section switching actuator 62 to place the switching section 6 at the outlet closed position. The transport path is switched to a U-turn path by arranging the switching unit 6 at the discharge port closing position (step S20). The controller 65 also controls the pressing force switching actuator 55 to place the frame 53 at the strong pressing force position.

According to such an operation, the image reading apparatus 1 can arrange the switching unit 6 at the discharge opening open position before the small medium passes through the switching unit 6, similar to the operation of FIG. Media can be properly transported along a straight path. Further, the image reading apparatus 1 successively transports a plurality of media placed on the chute 3 and reads the images, thereby reading the images of the plurality of media at a higher speed than the operation of FIG. can.

[Effects of the image reading device 1 of the first embodiment]
The image reading apparatus 1 of the first embodiment includes a shooter 3 , an imaging unit 51 , a switching unit 6 , a first small medium detection sensor 41 , a second small medium detection sensor 45 and a controller 65 . A recess 21 is formed in the shooter 3 . The imaging unit 51 captures an image of the medium fed out from the shooter 3 . A switching unit 6 guides the medium to a U-turn path or a straight path. The first small medium detection sensor 41 and the second small medium detection sensor 45 detect whether or not a medium is placed in the recess 21 . The controller 65 ejects the switching section 6 by controlling the switching section switching actuator 62 so that the medium is guided to the straight path when it is detected that the medium is placed in the recess 21 . Place it in the exit open position.

The extent to which media transported on a U-turn path deforms is greater than the extent to which media transported on a straight path deforms. At this time, the image reading apparatus 1 can prevent the small medium from being guided to the U-turn path, thereby preventing the small medium from being bent or jamming the U-turn path. can do. The image reading apparatus 1 arranges the switching unit 6 at the ejection opening open position so that the small medium placed in the recess 21 of the shooter 3 is guided to the straight path before the small medium is fed to the conveying path. be able to. Therefore, the image reading apparatus 1 can move the switching unit 6 before the small medium passes through the switching unit 6, and can appropriately transport the medium to the switched transport path.

Further, the image reading apparatus 1 of the first embodiment further includes a medium set detection sensor 61 for detecting whether or not a large medium is placed in an area adjacent to the depression 21 of the shooter placement surface 11 of the shooter 3. I have. When it is detected that a large medium is placed, the controller 65 controls the switching section switching actuator 62 so that the large medium is guided to the U-turn path, thereby switching the switching section 6 to the discharge port. Place in closed position. At this time, the image reading apparatus 1 can prevent the large medium from being guided to the straight path.

Further, the image reading apparatus 1 of the first embodiment further includes a scan button 64 that detects user's operation. After the depression of the scan button 64 is detected, the controller 65 controls the switching section switching actuator 62 so that the medium is guided to the U-turn path or the straight path, thereby moving the switching section 6 to the discharge opening open position. move. At this time, the image reading apparatus 1 can prevent unnecessary switching of the transport path to the U-turn path or the straight path before the scan button 64 is pressed.

By the way, in the image reading apparatus 1 of the above-described first embodiment, scanning is started after the scan button 64 is pressed. good too. The reading instruction is exemplified by outputting a predetermined signal to the image reading device 1 from a personal computer connected to the image reading device 1 so as to be able to transmit information. Also in this case, the image reading apparatus 1 can appropriately transport the medium to the switched transport path. Further, the image reading apparatus 1 may start scanning after an event other than the reading instruction is detected.

FIG. 15 is a flow chart showing still another operation of the image reading apparatus 1. As shown in FIG. When the user wants to read an image of one small medium using the image reading apparatus 1 , the user places one small medium on the small medium placement surface 22 of the recess 21 of the shooter 3 . Alternatively, when the user wants to read an image of one large-sized medium using the image reading device 1, the user places one large-sized medium on an area of the shooter mounting surface 11 of the shooter 3 adjacent to the depression 21. (Step S31).

The controller 65 intermittently controls the medium set detection sensor 61, the first small medium detection sensor 41, and the second small medium detection sensor 45 to detect the medium on the shooter mounting surface 11 of the shooter 3 or the recess 21. It is detected whether or not it is placed (step S32). When it is detected that no medium is placed on the shooter placement surface 11 or the recess 21 (step S32, No), the controller 65 determines that neither the large-sized medium nor the small-sized medium is placed on the shooter 3. (step S33). The controller 65 repeats the process of step S<b>32 until it is determined that the medium is placed on the shooter placement surface 11 or the recess 21 , and waits until the medium is placed on the shooter 3 .

When it is detected that a medium is placed on the shooter 3 (step S32, Yes), the controller 65 controls the medium set detection sensor 61 so that the large medium is placed on the shooter placement surface 11. It is detected whether or not it is set (step S34). When it is detected that a large medium is placed on the shooter placement surface 11 (step S34, Yes), the controller 65 controls the switching portion switching actuator 62 to switch the switching portion 6 to the discharge port. Place in closed position. The transport path is switched to the U-turn path by arranging the switching unit 6 at the discharge port closing position (step S35). The controller 65 also controls the pressing force switching actuator 55 to place the frame 53 at the strong pressing force position.

When it is detected that no large medium is placed on the shooter placement surface 11 (step S34, No), the controller 65 controls the switching part switching actuator 62 to switch the switching part 6 to the discharge port. Place in open position. The conveying path is switched to a straight path by arranging the switching unit 6 at the discharge opening open position (step S36). Further, the controller 65 arranges the frame 53 at the weak pressing force position by controlling the pressing force switching actuator 55 .

After the transport path is switched to the U-turn path (step S35) or after the transport path is switched to the straight path (step S36), the controller 65 starts scanning (step S37). When scanning is started, the controller 65 feeds the medium placed on the shooter 3 onto the transport path by controlling the transport unit 63, and transports the medium fed onto the transport path along the transport path. . The controller 65 captures an image of the medium being transported along the transport path by controlling the imaging unit 51 while the medium is being transported along the transport path. The imaged medium is transported along the straight path and placed on the stacker 5 when the transport path is switched to the U-turn path. The medium on which the image has been captured is conveyed along the straight path when the conveying path is switched to the straight path, and discharged from the discharge port 7 (step S38). After the scanning is completed (step S38), the controller 65 waits for a predetermined period of time (step S39), and executes the processes after step S32 again.

13 or 14, the image reading apparatus 1 places the switching section 6 at the ejection opening open position before the small medium passes through the switching section 6. and small media can be properly transported along a straight path. Further, the image reading apparatus 1 can arrange the switching section 6 at the ejection port closing position before the large medium passes through the switching section 6, and can appropriately convey the large medium along the U-turn path. . The image reading apparatus 1 automatically starts scanning after detecting that the medium has been placed on the shooter 3, thereby eliminating the need for the user to press the scan button 64, and performing the operations in FIG. 13 and in FIG. User operations can be simplified compared to operations.

The image reading apparatus 1 according to the first embodiment further includes a pressing force switching mechanism 52 that changes the magnitude of the pressing force with which the imaging unit 51 is pressed against the medium. The controller 65 controls the pressing force switching mechanism 52 so that the magnitude of the pressing force is reduced when it is detected that the medium is placed in the recess 21 . At this time, the image reading apparatus 1 can reduce the load applied to the small medium when the small medium is conveyed in the vicinity of the imaging unit 51 in the conveying path. Media can be properly transported.

By the way, although the image reading apparatus 1 of the above-described first embodiment is provided with the pressing force switching mechanism 52, the pressing force switching mechanism 52 may be omitted. Even if the pressing force switching mechanism 52 is omitted, the image reading apparatus 1 can move the switching unit 6 before the medium placed on the chute 3 is fed to the transport path. media can be properly transported to the

[Modified image reading device]
In the modified image reading apparatus, the shooter 3 of the image reading apparatus 1 of the first embodiment is replaced with another shooter 71 as shown in FIG. FIG. 16 is a perspective view showing the shooter 71 of the image reading apparatus of the modification. The shooter 71 is formed with a shooter mounting surface 11 in the same manner as the shooter 3 described above. The shooter 71 has a depression 73 formed in the shooter mounting surface 11 . The shooter 71 is formed with a small medium mounting surface 74 by forming a recess 73 . The small medium mounting surface 74 is generally flat and forms the bottom of the recess 73 . The small medium mounting surface 74 includes a common portion 23, a right portion 24, a left portion 25, and an upstream portion 26, similar to the small medium mounting surface 22 described above.

Shooter 71 has a side wall surface formed by forming depression 73 . The side wall surface includes an upper vertical medium alignment surface 31, a right horizontal medium alignment surface 34, and a left horizontal medium alignment surface 35, similarly to the shooter 3 described above. The sidewall surface further includes a right angled surface 76 and a left angled surface 77 . The right slanted surface 76 is generally flat and arranged so as to be connected to the small medium placement surface 74 , the vertical medium upper alignment surface 31 and the horizontal medium right alignment surface 34 . The left slanted surface 77 is generally flat and arranged so as to be connected to the small medium loading surface 74 , the vertical medium upper alignment surface 31 and the horizontal medium left alignment surface 35 .

In the depression 73 of the shooter 71 , the small medium 38 is placed vertically or horizontally in the same manner as the depression 21 of the shooter 3 . That is, when the small media 38 is longitudinally placed in the recess 73 , one edge of the small media 38 lies along the upper longitudinal media alignment surface 31 and properly rests on the common portion 23 and the upstream portion 26 . placed. When the small medium 38 is placed horizontally in the depression 73, the small medium 38 is sandwiched between the right laterally placed medium alignment surface 34 and the left laterally placed medium alignment surface 35, and is sandwiched between the common portion 23, the right portion 24, and the left portion 25. properly placed. Even when the shooter 3 is replaced with the shooter 71, the image reading apparatus 1 of the above-described first embodiment similarly moves the switching unit 6 before the medium placed on the shooter 71 is delivered to the transport path. It is possible to properly transport the medium to the switched transport path. The shooter 71 has a right inclined surface 76 and a left inclined surface 77 so that the small medium 38 can be easily inserted into the recess 73, and is superior in design compared to the shooter 3.

In the image reading apparatus of the second embodiment, the shooter 3 of the image reading apparatus 1 of the first embodiment is replaced with another shooter 81 as shown in FIG. FIG. 17 is a side view of the shooter 81 of the image reading apparatus according to the second embodiment. The shooter 81 has a shooter body 82 and a recessed portion 83 . The shooter main body 82 is formed in a plate shape and has a shooter mounting surface 84 formed thereon. The shooter main body 82 is supported by the image reading apparatus main body 2 so as to be rotatable about the rotary shaft 12 so as to be arranged at the shooter deployment position or the shooter retracted position. The shooter body 82 is further formed with a hole. The side wall surface of the hole is formed in the same manner as the side wall surface formed by forming the aforementioned recess 21 in the shooter 3 .

The recessed portion 83 is formed in a plate-like shape whose edge generally follows the side wall surface of the hole formed in the shooter body 82, and a generally flat small medium mounting surface 85 is formed. The recessed portion 83 is disposed in the bore of the shooter body 82 and is rotatably supported by the shooter body 82 about a rotation axis 86 so as to be disposed in the recessed portion retracted position or the recessed portion deployed position. The rotating shaft 86 is parallel to the rotating shaft 12 and arranged near the rotating shaft 12 . A guide groove 87 is further formed in the shooter main body 82 . A pin 88 is formed in the recessed portion 83 . The pin 88 fits into the guide groove 87 and limits the range in which the recessed portion 83 rotates with respect to the shooter body 82 .

The shooter mounting surface 84 faces downward as shown in FIG. 17 when the shooter body 82 is arranged at the shooter retracted position. The recessed portion 83 is placed in the recessed portion retracted position by its own weight when the shooter body 82 is placed in the shooter retracted position. The recessed portion 83 is configured to be disposed entirely within the bore of the shooter body 82 when placed in the recessed portion storage position. Further, the recessed portion 83 is formed such that the small medium loading surface 85 is generally aligned with a plane along the shooter loading surface 84 when the recessed portion is placed at the recessed portion storage position.

The shooter main body 82 is arranged at the shooter deployment position by rotating about the rotation shaft 12 from the shooter deployment position. FIG. 18 is a side view showing the shooter 81 of the image reading apparatus according to the second embodiment when the shooter main body 82 is arranged at the shooter deployment position. The shooter placement surface 84 faces obliquely upward when the shooter main body 82 is arranged at the shooter deployment position.

FIG. 19 is a side view showing the shooter 81 of the image reading apparatus of the second embodiment when the recessed portion 83 is arranged at the recessed portion unfolding position. The recessed portion 83 rotates around the rotation axis 86 due to its own weight when the shooter main body 82 is arranged at the shooter deployment position. The recessed portion 83 is arranged at the recessed portion deployed position by rotating about the rotary shaft 86 by a predetermined angle θ from the state arranged at the recessed portion retracted position. In the shooter 81, when the recessed portion 83 is arranged in the recessed portion developed position, a recess is formed with the small medium mounting surface 85 as the bottom. The recess to be formed is formed in the same manner as the recess 21 described above. The shooter 81 has the recessed portion 83 protruding from the surface of the shooter body 82 opposite to the shooter mounting surface 84 when the recessed portion 83 is arranged at the recessed portion deployed position. Therefore, the thickness of shooter 81 when recessed portion 83 is placed in the recessed portion retracted position is smaller than the thickness of shooter 81 when recessed portion 83 is placed in the recessed portion deployed position.

The shooter 81 is further provided with a first small medium detection sensor 41, a second small medium detection sensor 45, and a medium set detection sensor 61, like the shooter 3 described above. The image reading apparatus according to the second embodiment is similar to the image reading apparatus 1 according to the first embodiment, because the shooter 81 is formed in the same manner as the shooter 3 when the shooter main body 82 is arranged at the shooter unfolded position. can be used for By using the image reading apparatus of the second embodiment in the same manner as the image reading apparatus 1 of the first embodiment, the switching section 6 can be moved before the small medium passes through the switching section 6. , the medium can be appropriately transported to the switched transport path.

Further, in the image reading apparatus of the second embodiment, the thickness of the shooter 81 is reduced when the hollow portion 83 is arranged at the hollow portion storing position, so that when the shooter body 82 is arranged at the shooter storing position, the thickness of the shooter 81 is reduced. , can be formed more compactly. The image reading apparatus of the second embodiment can be stored in a smaller space by being compact when the shooter main body 82 is arranged at the shooter storage position.

By the way, the above-mentioned first small medium detection sensor 41 is provided with the sensor main body 42 and the reflecting member 43, but these may be replaced with a light emitting section and a light receiving section, respectively. At this time, when the light emitted from the light emitting portion is not received by the light receiving portion, the first small medium detection sensor 41 determines that the small medium is placed in the recess 21, and detects the light emitted from the light emitting portion. is received by the light receiving portion, it is determined that the small medium is not placed in the depression 21 . The first small medium detection sensor 41 detects whether or not a small medium is placed in the depression 21 in a non-contact manner. may be replaced with a sensor that detects Similarly to the first small medium detection sensor 41, the second small medium detection sensor 45 may be replaced with another sensor that detects whether or not a small medium is placed in the recess 21 by another method. . Even when such a sensor is provided, the image reading apparatus can appropriately detect whether or not a small medium is placed in the depression 21, and before the small medium passes through the switching unit 6, The switching unit 6 can be moved, and the medium can be appropriately transported to the transport path.

It should be noted that although the image reading apparatus of the above-described embodiment is provided with the first small medium detection sensor 41 and the second small medium detection sensor 45, the first small medium detection sensor 41 and the second small medium detection sensor 45 may be omitted. The image reading device can detect that the small medium is placed in the recess even if one is omitted, and the switching section 6 can be moved before the small medium passes through the switching section 6. The medium can be appropriately transported to the switched transport path.

Although the embodiments have been described above, the embodiments are not limited by the contents described above. In addition, the components described above include those that can be easily assumed by those skilled in the art, those that are substantially the same, and those within the so-called equivalent range. Furthermore, the components described above can be combined as appropriate. Furthermore, at least one of various omissions, replacements, and modifications of components can be made without departing from the gist of the embodiments.

1: Image reading device 2: Image reading device main body 3: Chuter 5: Stacker 6: Switching unit 7: Ejection port 11: Shooter mounting surface 21: Recess 22: Small medium mounting surface 38: Small medium 41: First Small Medium Detection Sensor 45 : Second Small Medium Detection Sensor 51 : Imaging Section 52 : Pressure Switching Mechanism 61 : Medium Set Detection Sensor 62 : Switching Section Switching Actuator 63 : Conveying Section 64 : Scan Button 65 : Controller 71 : Shooter 73 : recess 74: mounting surface for small medium 81: shooter 82: shooter main body 83: recess portion

Claims (6)

a shooter having a recess formed therein;
an imaging unit that captures an image of the medium fed out from the shooter;
a switching unit that guides the medium to a first transport path or a second transport path;
a mechanism for changing the magnitude of the force with which the imaging unit presses the medium;
a sensor that detects whether or not the first medium is placed in the recess;
controlling the switching unit so that the first medium is guided to the first transport path when it is detected that the first medium is placed in the depression , and a magnitude of the force; and a controller that controls the mechanism so that the a shooter having a recess formed therein;
an imaging unit that captures an image of the medium fed out from the shooter;
a switching unit that guides the medium to a first transport path or a second transport path;
a sensor that detects whether or not the first medium is placed in the recess;
a control unit that controls the switching unit so that the first medium is guided to the first transport path when it is detected that the first medium is placed in the recess;
The shooter
a shooter body formed with a region adjacent to the recess and movable;
and a recessed portion that is movably supported with respect to the shooter body and in which the recess is formed in the shooter by moving relative to the shooter body.
Image reader. Further comprising a mechanism for changing the magnitude of the force with which the imaging unit presses the medium,
The control unit controls the mechanism such that the magnitude of the force is reduced when it is detected that the first medium is placed in the depression.
3. The image reading device according to claim 2. further comprising another sensor for detecting whether or not a second medium is placed in an area of the shooter adjacent to the recess,
The control unit controls the switching unit so that the second medium is guided to the second transport path when it is detected that the second medium is placed in the area. The image reading device according to any one of claims 1 to 3 . The image reading apparatus according to any one of claims 1 to 4 , wherein the degree of deformation of the medium conveyed on the second conveying path is greater than the degree of deformation of the medium conveyed on the first conveying path. . further comprising a reading instruction detection unit that detects the reading instruction,
The control unit controls the switching unit so that the medium is guided to the first transport path or the second transport path after the reading instruction is detected. 2. The image reading device according to item 1 .

Images