JP7368077B2 - Sheet discharge device and image reading device - Google Patents

Description

The present invention relates to a sheet discharging device that discharges sheets, and an image reading device equipped with such a sheet discharging device.

2. Description of the Related Art A sheet discharge device that discharges sheets has a configuration that improves sheet stacking performance by discharging sheets in a corrugated shape. For example, a configuration has been proposed in which waisted rollers each having a larger outer diameter than the pair of discharge rollers are provided on the outside of the pair of discharge rollers provided on the drive shaft and on the inside of the pair of discharge rollers (Patent Document 1).

Japanese Patent Application Publication No. 2015-37998

In the case of the configuration described in Patent Document 1, when a small-sized sheet such as a business card is discharged, the sheet does not contact the outer waist roller of a pair of ejection rollers, but hits the inner waist roller. It may be discharged if it comes in contact with the product. Since the outer diameter of the waisted roller is larger than the pair of discharge rollers, when a small size sheet is discharged by the pair of discharge rollers, the inner waisted roller accelerates the sheet discharge speed, and the discharged sheet is reversed. There is a risk that the sheet ejection performance may be deteriorated.

In view of the above, the sheet discharging device according to the present invention includes a first shaft, a pair of first discharging rollers provided on the first shaft, a second shaft, and a pair of first discharging rollers provided on the second shaft. a pair of second discharge rollers that form nip portions that contact the first discharge rollers to sandwich the sheet, and rotate together with the pair of first discharge rollers to discharge the sheet sandwiched by the nip portion; , a pair of first protrusions provided on the first shaft outside the pair of first discharge rollers in the axial direction of the first shaft and protruding toward the second shaft side with respect to the nip portion; The pair of first protrusions are provided to be rotatable relative to the first shaft, and are a pair of rollers having a larger outer diameter than the pair of first discharge rollers. .
Further , the sheet discharging device of the present invention includes a first shaft, a pair of first discharging rollers provided on the first shaft, a second shaft, and a pair of first discharging rollers disposed on the second shaft. a pair of second ejection rollers forming nip portions that contact the ejection rollers to nip the sheet, and rotating together with the pair of first ejection rollers to eject the sheet sandwiched by the nip portion; a pair of first protrusions provided on the first shaft outside the pair of first discharge rollers in the axial direction of the first shaft and protruding toward the second shaft side with respect to the nip portion; provided on the shaft side, protrudes toward the first shaft side relative to the pair of second discharge rollers when viewed from the axial direction of the second shaft, and extends at least directly at the nip portion with respect to the discharge direction in which the sheet is discharged. A pair of third protrusions that can come into contact with the sheet upstream.

According to the present invention, sheet discharge performance can be improved.

FIG. 1 is a schematic cross-sectional view of an image reading device according to an embodiment. FIG. 1 is a schematic diagram showing main parts of an image reading device according to an embodiment. FIG. 1 is a perspective view of a sheet discharging device according to an embodiment. FIG. 1 is a front view of a sheet discharging device according to an embodiment. FIG. 3 is a cross-sectional view of a sheet discharging device and a sheet discharging and stacking section of the image reading device according to the embodiment. FIG. 7 is a perspective view of a sheet discharging device according to another example of the embodiment. FIG. 1 is a schematic cross-sectional view of a sheet discharging device according to an embodiment. (a) A front view and (b) a side view of a discharge driven roller according to an embodiment. FIG. 3 is a plan view of the discharge drive roller and the lever according to the embodiment, viewed from above. 3 is a cross-sectional view showing how thin paper is discharged by the sheet discharging device according to the embodiment, (a) a state in which the thin paper is in front of the nip section, (b) a state in which the thin paper is nipped in the nip section, and (c) a state in which the thin paper is nipped in the nip section. ) Diagrams each showing a state in which the thin paper is discharged from the nip section. FIG. 3 is a front view of the sheet discharging device according to the embodiment, showing a state in which thin paper is nipped at a nip portion in the sheet discharging device. FIG. 12 is a diagram schematically showing an enlarged central portion of FIG. 11; 3 is a cross-sectional view showing how cardboard is discharged by the sheet discharging device according to the embodiment, (a) a state where the cardboard is in front of the nip section, (b) a state where the cardboard is nipped at the nip section, and (c) a state where the cardboard is nipped in the nip section. ) Diagrams each showing the state in which the cardboard is discharged from the nip section. FIG. 3 is a front view of the sheet discharging device according to the embodiment, showing a state in which cardboard is nipped at a nip portion in the sheet discharging device. FIG. 7 is a cross-sectional view of a sheet discharging device and a sheet discharging and stacking section of an image reading device according to another first example of the embodiment. FIG. 7 is a sectional view of a sheet discharging device and a sheet discharging and stacking section of an image reading device according to another second example of the embodiment.

An embodiment will be described using FIGS. 1 to 14. First, the schematic configuration of the image reading device of this embodiment will be described using FIGS. 1 and 2.

[Image reading device]
The image reading device 200 conveys a sheet S as a document and reads images on both sides or one side of the sheet S. For this purpose, the image reading device 200 includes a sheet importing device 101. The sheet importing device 101 has a sheet stacking table (original loading table) 1, and a plurality of sheets S can be stacked on the sheet stacking table 1. This sheet stacking table 1 is configured to be able to move up and down. The sheet stacking table drive motor 2 moves the sheet stacking table 1 up and down. The sheet detection sensor 3 detects that the sheets S stacked on the sheet stacking table 1 are at the sheet take-in position. The sheet stacking detection sensor 12 detects that sheets S are stacked on the sheet stacking surface 1a of the sheet stacking table 1. The sheet stacking table 1 has regulating plates 1b that come into contact with both widthwise ends of the sheet S that intersect (orthogonal to, in this embodiment) the conveyance direction of the sheet S to regulate the widthwise position of the sheet S.

A pickup roller 4 (taking unit), which is an example of a document pickup unit, sends out the sheet S on the sheet stacking table 1 from the sheet stacking table 1 . The pickup roller drive motor 5 rotates the pickup roller 4. In FIG. 2, the upper surface of the sheet S is at the sheet take-in position, and when the pickup roller 4 is rotated, the sheet S starts being taken in. Further, the pickup roller 4 can be moved between a sheet take-in position and a retracted position above the sheet take-in position by a driving means (not shown). The pickup roller 4 is moved to the take-in position when taking in the sheet S, and is moved to the retracted position when the take-in is finished.

The feeding roller 6 is driven by a feeding motor 8 to rotate in a direction that feeds the sheet S downstream in the conveying direction. The separation roller 7 constantly receives rotational force from the separation motor 9 via a torque limiter (slip clutch), not shown, to rotate in a direction that pushes the sheet S back toward the upstream side in the conveyance direction. When there is one sheet S between the feeding roller 6 and the separation roller 7, the separation roller 7, which is transmitted by the torque limiter, will feed more than the upper limit of the rotational force in the direction of pushing the sheet S back to the upstream side. The frictional force between the sheet S sent downstream by the roller 6 and the separation roller 7 exceeds the rotational force in the direction in which the sheet S is fed downstream, and the separation roller 7 follows the feeding roller 6. Rotate (accompanied).

On the other hand, when a plurality of sheets exist between the feeding roller 6 and the separation roller 7, the separation roller 7 receives rotation from the roller shaft in the direction of pushing the sheets S back upstream, and all but the uppermost sheet S are Prevent it from being transported downstream.

In this way, due to the action of the feeding roller 6 to feed the sheet S to the downstream side and the action of the separation roller 7 to prevent the sheet S from being transported downstream, the sheets S overlap and are separated from the feeding roller 6. When fed into the nip with the roller 7, only the uppermost sheet S is fed downstream, and other sheets S are prevented from being conveyed downstream, so that overlapping sheets S are separated and fed. sent. Therefore, the feeding roller 6 and the separation roller 7 constitute a pair of separation rollers 42 (original separation section). Note that in this embodiment, a pair of separation rollers 42 is used, but instead of the pair of separation rollers 42, a pair of separation belt rollers in which either the separation roller or the feeding roller is a belt may be used. . Further, the separation roller may be replaced with a separation pad which comes into contact with the sheets S to prevent a plurality of sheets S from being conveyed to the downstream side.

The sheets S stacked on the sheet stacking table 1 are separated one by one by the document pickup unit composed of the pickup roller 4, the feeding roller 6, the separation roller 7, etc. configured in this way, and the sheets S are separated into sheets inside the image reading device 200. be taken in.

Further, by providing the double feed detection sensor 30 at a position where the separated sheets S pass, it is possible to detect whether the sheets S have been separated one by one by the document separation unit. In this embodiment, a detection device using an ultrasonic transmitter/receiver is used as the double feed detection sensor 30, and double feed can be detected based on the amount of attenuation of ultrasonic waves between the transmitter/receiver across the conveyance path.

The conveyance motor 10 conveys the separated sheet S to the image reading position where the image on the sheet S is read by the reading units 14 and 15, and further conveys it to the ejection position. ) to drive. Further, the conveyance motor 10 drives each roller so that the conveyance speed of the sheet S can be changed according to settings such as the optimal speed for reading the sheet S and the resolution of the sheet.

The nip gap adjustment motor 11 adjusts the gap between the feeding roller 6 and the separation roller 7 or the pressure force with which the feeding roller 6 presses against the separation roller 7 via the sheet S. Thereby, the gap or the pressure contact force is adjusted to suit the thickness of the sheet S, and the sheet S can be separated.

The registration clutch 19 transmits the rotational driving force of the conveyance motor 10 to the registration rollers 18 serving as a conveyance unit that conveys the sheet S, or blocks the transmission. By stopping the rotation of the registration roller pair made up of the registration rollers 17 and 18, the leading edge of the fed sheet S abuts against the nip portion of the registration roller pair, thereby correcting the skew of the sheet.

The roller pairs including a pair of conveying rollers constituted by conveying rollers 20 and 21, a pair of conveying rollers consisting of conveying rollers 22 and 23, and a pair of rollers of a sheet discharging device 100 further downstream shown in FIG. The sheet is conveyed to the sheet discharge stacking section 44. Two guide plates, the upper guide plate 40 and the lower guide plate 41, guide the sheet S conveyed by the separation roller pair, the registration roller pair, and each conveyance roller pair. That is, the upper guide plate 40 and the lower guide plate 41 form a conveyance path 400 for conveying the sheet.

Further, the sheet whose image has been read by reading units 14 and 15, which will be described later, is conveyed through a discharge conveyance path 401, and is discharged to a sheet discharge and stacking section 44 by a sheet discharge device 100. The discharge conveyance path 401 is formed by a first guide section 402 and a second guide section 403 that are arranged to face each other. The first guide part 402 and the second guide part 403 are each formed to be curved. For this reason, the discharge conveyance path 401 is a path that folds back the sheet conveyed by the conveyance path 400, and the sheet is delivered to the sheet discharge stacking section 44 disposed above the conveyance path 400, the separation roller pair 42, etc. It is possible to transport it. Note that the first guide portion 402 and the upper guide plate 40, and the second guide portion 403 and the lower guide plate 41, may be configured integrally with each other, or may be separate bodies.

The pre-registration sensor 32 is disposed upstream of the pair of registration rollers 17 and 18, and detects the sheet S being conveyed. The post-registration sensor 33 is disposed downstream of the pair of registration rollers 17 and 18, and detects the sheet S being conveyed.

When the sheet S is detected by the post-registration sensor 33, a control device 45 serving as a control unit issues an image reading instruction to the reading units 14 and 15, and the image of the sheet S being conveyed is read. The reading units 14 and 15, which serve as reading sections, are arranged to face each other across the conveyance path 400 along which the sheet S is conveyed, as described above, and read images on both sides or one side of the sheet.

That is, each of the reading units 14 and 15 includes, for example, a housing, a line image sensor disposed within the housing, and a contact glass disposed on the transport path 400 side of the line image sensor. Such reading units 14 and 15 are capable of reading an image of a sheet (original) S conveyed by registration rollers 17 and 18 as conveyance sections with a line image sensor through a contact glass.

The control device 45 controls the entire image reading device 200. Such a control device 45 has a CPU (Central Processing Unit), a ROM (Read Only Memory), and a RAM (Random Access Memory). The CPU controls each part while reading a program corresponding to a control procedure stored in the ROM. Further, the RAM stores work data and input data, and the CPU performs control by referring to the data stored in the RAM based on the aforementioned program and the like. The image of the sheet read by the reading units 14 and 15 is transmitted to an external device such as an information processing device via an interface section (not shown).

[Sheet discharge device]
Next, the sheet discharging device 100 will be explained. As shown in FIG. 1, the sheet discharging device 100 is disposed at the most downstream of the discharging conveyance path 401 of the image reading device 200, and transfers sheets whose images have been read by the reading units 14 and 15 to the sheet discharging and stacking section 44. Discharge.

As shown in FIGS. 3 and 4, the sheet discharge device 100 includes a drive shaft 54, a driven shaft 55, a pair of discharge drive rollers 50, a pair of discharge driven rollers 51, a pair of belted rollers 52, and a waisted lever 53. have The pair of discharge drive rollers 50 and the pair of discharge driven rollers 51 constitute a discharge roller pair 60.

A drive shaft 54 serving as a first shaft is rotationally driven by a discharge drive motor 56, as shown in FIG. A driven shaft 55 as a second shaft is disposed at a position substantially parallel to the drive shaft 54 and facing the drive shaft 54 via the discharge conveyance path 401 . In this embodiment, the drive shaft 54 is arranged above the driven shaft 55 in the direction of gravity. Note that the drive shaft may be arranged below the driven shaft in the direction of gravity.

A pair of discharge drive rollers 50 serving as a pair of first discharge rollers are provided on the drive shaft 54 at intervals from each other in the axial direction. The pair of discharge drive rollers 50 are fixed to the drive shaft 54 so as not to rotate relative to each other, and rotate together with the drive shaft 54 when the drive shaft 54 is rotationally driven by the discharge drive motor 56 . Further, the pair of discharge drive rollers 50 are arranged at a distance that allows them to pinch and convey even a small sheet, such as the size of a business card, for example.

A pair of discharge driven rollers 51 serving as a pair of second discharge rollers are provided on a driven shaft 55 with an interval between them in the axial direction. The pair of discharge driven rollers 51 respectively contact the pair of discharge drive rollers 50 to form a nip portion N for sandwiching the sheet, and rotate together with (in this embodiment, driven by) the pair of discharge drive rollers 50. By doing so, the sheets held in the nip portion N are discharged to the sheet discharge and stacking section 44. The pair of discharge driven rollers 51 are fixed to the driven shaft 55, and rotate together with the driven shaft 55 by being driven by the pair of discharge drive rollers 50. Note that the driven shaft 55 may be fixed, and the pair of discharge driven rollers 51 may be rotated relative to the driven shaft 55.

[Roller with waist]
A pair of buckled rollers 52 as a pair of first protrusions are provided on the outside of the pair of discharge drive rollers 50 (on both shaft end sides of the drive shaft 54) with respect to the axial direction of the drive shaft 54, respectively. It is provided to be relatively rotatable. Further, as shown in FIG. 4, the pair of waisted rollers 52 pass through a nip portion N when viewed from the discharge direction in which the sheet is discharged (the direction of arrow A in FIG. 7, which will be described later), and the sheet is discharged. It protrudes toward the driven shaft 55 side (second shaft side) from an imaginary line (nip line) L1 parallel to the discharge direction. That is, the pair of buckled rollers 52 are provided on the drive shaft 54 and protrude from the nip portion N toward the driven shaft 55 side. Note that the virtual line L1 is shown as a line passing through the pair of nip portions N when viewed from the discharge direction.

Specifically, the pair of waisted rollers 52 are provided to be rotatable relative to the drive shaft 54, and have a larger outer diameter than the pair of discharge drive rollers 50. Further, the pair of stiffening rollers 52 and the pair of discharge drive rollers 50 are arranged concentrically. Therefore, as shown in FIG. 5, the outer circumferential surfaces of the pair of stiffened rollers 52 protrude more toward the driven shaft 55 than the outer circumferential surfaces of the pair of discharge drive rollers 50. Therefore, as is clear from FIG. 4, the outer circumferential surfaces of the pair of stiffened rollers 52 protrude further toward the driven shaft 55 than the imaginary line L1 passing through the nip N.

Since such a pair of waisted rollers 52 is arranged outside the pair of ejection drive rollers 50, when a small-sized sheet such as a business card size is conveyed by the pair of ejection drive rollers 50, , does not touch this small size sheet. In other words, the waisted rollers are arranged at positions outside (on both ends) of the discharge drive roller 50, where they do not come into contact with small-sized sheets such as business card size (for example, 55 mm x 91 mm). On the other hand, when the sheet to be discharged is larger than a predetermined size (larger than a small size such as a business card size, for example, larger than a postcard size), the pair of waisted rollers 52 are arranged at least in the nip portion N in the sheet discharge direction. It comes into contact with a sheet larger than this predetermined size immediately upstream.

As described above, the pair of buckled rollers 52 are rollers provided on the drive shaft 54, so they are kept in contact with the sheet from just upstream to just downstream of the nip portion N in the sheet discharging direction. There is. That is, the pair of stiffening rollers 52 continue to contact the sheet from just before the sheet enters the nip portion N, while the sheet passes through the nip portion N, and further until immediately after the sheet leaves the nip portion N. These "directly upstream" and "directly downstream" will be described later.

As described above, since the pair of waisted rollers 52 have a larger outer diameter than the discharge drive roller 50, the pair of discharge drive rollers 50 cover the surface of the sheet of a predetermined size or larger that is nipped and conveyed in the nip portion N. Press the outer position. As a result, the pair of waist rollers 52 waveforms on both ends of the sheet in the width direction (in the direction of the imaginary line L1 intersecting (in this embodiment, orthogonal to) the discharge direction) from the position where the sheet is nipped at the nip portion N. It has the role of letting the player hit the ball and ejecting the ball while resting on this sheet. As a result, the leading edge of the sheet to be discharged is discharged without curling up or down.

Further, the pair of elastic rollers 52 are entirely made of an elastic member. Specifically, as shown in FIG. 3, the pair of waisted rollers 52 are rollers in which a plurality of holes are provided in a cylindrical rubber member that penetrates in the axial direction. Note that, as in a sheet discharging device 100A as another example of the present embodiment shown in FIG. 6, a soft and elastic material such as a sponge material may be used as the pair of elastic rollers 52A. The elastic roller 52A of FIG. 6 is made of a sponge material in a cylindrical shape, and does not have a plurality of holes penetrating in the axial direction like the elastic roller 52 of FIG. 3.

By configuring the pair of stiffening rollers 52 (52A) with an elastic member in this way, when a sheet (for example, a thick sheet) that is difficult to stiffen (high rigidity) is held and conveyed at the nip N, the stiffening rollers 52 The outer circumferential surface of is elastically deformed. As a result, the load on the sheet can be reduced and conveyed. On the other hand, when conveying a sheet (for example, a thin sheet) that tends to curl and buckle (low rigidity) during discharge, the outer peripheral surface of the buckle roller 52 does not undergo almost any elastic deformation, and the sheet is not stiffened. can be discharged.

Furthermore, if the belted roller 52 is rotationally driven together with the drive shaft 54, the peripheral speed of the belted roller 52 will be faster than that of the discharge drive roller 50 because the outer diameter of the belted roller 52 is larger than the discharge drive roller 50. turn into. As a result, the stiffening roller 52 slips on the surface of the sheet being conveyed, causing wear of the stiffening roller 52 and the sheet. For this reason, the buckled roller 52 is supported so as to be rotatable relative to the drive shaft 54. As a result, the stiffening roller 52 is driven to rotate in accordance with the conveyance speed of the sheet, so that the sheet can be transported without wearing out the stiffening roller 52 and the sheet. In this embodiment, as an example, a buckled roller 52 is attached to a drive shaft 54 via a bearing.

[Lever with waist]
With respect to the axial direction of the drive shaft 54, which is one of the first and second shafts, the lever 53 with a waist as the second protruding portion functions as one of the pair of ejection rollers provided on the drive shaft 54. It protrudes from the drive shaft 54 toward the driven shaft 55 inside the pair of discharge drive rollers 50 . Further, the lever 53 with a waist is fixed at a position different from the drive shaft 54 so that the amount of protrusion toward the driven shaft 55 can be changed. Such a waist lever 53 is provided to a fixed part other than the drive shaft 54 (a swing shaft 53b to be described later) so as not to rotate about the drive shaft 54. That is, the buckled lever 53 is arranged between the pair of discharge drive rollers 50, in the case of this embodiment, at the center in the axial direction of the portion between the pair of discharge drive rollers 50. Furthermore, when viewed from the axial direction of the drive shaft 54, the lever 53 is driven as the other shaft of the first shaft and the second shaft from a virtual line L1 (FIG. 4) passing through the nip portion N. It protrudes toward the shaft 55 side (the other shaft side), and the amount of protrusion can be changed. That is, the lever 53 with a waist protrudes further toward the driven shaft 55 side (second shaft side) than the pair of discharge drive rollers 50, and the amount of protrusion from the virtual line L1 toward the driven shaft 55 can be changed. The waist lever 53 contacts the sheet at least immediately upstream of the nip portion N in the discharge direction in which the sheet is discharged.

Further, the waist lever 53 also comes into contact with the sheet immediately downstream of the nip portion N in the sheet ejection direction. In this embodiment, the waist lever 53 is configured to continue contacting the sheet from just upstream to just downstream of the nip portion N. That is, the waist lever 53 continues to contact the sheet from just before the sheet enters the nip N, while it passes through the nip N, and even until immediately after it leaves the nip N. These "directly upstream" and "directly downstream" will be described later.

In the case of this embodiment, as shown in FIG. 7, the lever 53 has a contact portion 53a that contacts the seat, and a biasing member that urges the contact portion 53a toward the driven shaft 55 as the other shaft. It has a tension spring 53c as a force means. The contact portion 53a is provided so as to be swingable about a swing shaft 53b that is arranged substantially parallel to the drive shaft 54 as one axis. In this embodiment, the entire waist lever 53 is provided to be swingable.

That is, the lever 53 with a waist has a lever part 530 that is swingably supported by a swing shaft 53b, and a part of this lever part 530 is used as a contact part 53a. Specifically, the lever portion 530 includes a support portion 531 supported by the swing shaft 53b, a distal end portion 532 extending from the support portion 531 toward the nip portion N, and a tip end portion 532 extending from the support portion 531 to the side opposite to the nip portion N. The proximal end portion 533 extending from the base end portion 533 is integrally constructed. The side surface (lower surface) of the distal end portion 532 on the discharge conveyance path 401 side is a contact portion 53a. The distal end portion 532 is curved so that its distal end portion is bent substantially upward.

On the other hand, a hook portion 534 for hooking one end of the tension spring 53c is provided at the base end portion of the base end portion 533. The other end of the tension spring 53c is hooked onto a fixed portion (not shown) of the main body of the device. As a result, the base end portion 533 is pulled in a direction away from the discharge conveyance path 401 by the tension spring 53c (substantially upward in FIG. 7), and the distal end portion 532 is pulled in a direction toward the discharge conveyance path 401 around the swing shaft 53b. (in the direction of arrow C).

Note that when the lever portion 530 is not in contact with the sheet, a portion of the tip end portion 532 enters the discharge conveyance path 401, and the tip portion is located closer to the driven shaft 55 than the nip portion N. It is installed like this. Further, the swinging is restricted by a regulating member (not shown) so that it does not swing any further towards the driven shaft 55 side. The position of the waist lever 53 in this state is defined as the initial position.

In the case of the present embodiment, the swing shaft 53b is located upstream of the drive shaft 54 with respect to the sheet discharge direction (direction of arrow A), and closer to the drive shaft 54 than the discharge conveyance path 401 (first shaft side, i.e. , upper side). Note that the swing shaft 53b may be provided downstream of the drive shaft 54 in the sheet discharge direction, and closer to the drive shaft 54 than the imaginary line L2 passing through the nip N and parallel to the discharge direction. Note that the virtual line L2 is shown as a line passing through the nip portion N when viewed from the axial direction of the drive shaft 54.

The lever 53 configured in this way is swingably supported by the swing shaft 53b and does not rotate about the drive shaft 54. Further, the contact portion 53a of the waisted lever 53 contacts the sheet conveyed from the discharge conveyance path 401 toward the nip portion N by the urging force of the tension spring 53c. By pressing the contact portion 53a against the seat in this manner, it is possible to make the seat more stable.

Further, depending on the rigidity of the sheet to be conveyed, the waist lever 53 swings about the swing shaft 53b and moves so that the tip end portion 532 retreats toward the drive shaft 54 (in the direction of arrow B). That is, the amount by which the contact portion 53a projects toward the driven shaft 55 side relative to the discharge drive roller 50 changes.

Specifically, the waist lever 53 is more likely to come into contact with a sheet having a second basis weight that is larger than the first basis weight than when it comes into contact with a sheet whose basis weight is the first basis weight. The amount of protrusion is smaller when they are in contact. That is, in the case of a sheet with a large basis weight such as cardboard, the sheet has high rigidity and is difficult to stiffen, so when it comes into contact with the abutting portion 53a, the abutting portion 53a is lifted up against the biasing force of the tension spring 53c.

On the other hand, in the case of a sheet with a small basis weight such as thin paper, the rigidity is low and it tends to stiffen, so even if it makes contact with the abutting part 53a, the abutting part 53a may not lift up against the biasing force of the tension spring 53c. , only slightly lifted. In addition, in the case of a sheet such as plain paper, which has lower rigidity than thick paper and lower rigidity than thin paper, when it comes into contact with the abutting portion 53a, the abutting portion 53a is lifted up more than when it is thin paper, and more than when it is made from thick paper. Also, the contact portion 53a does not lift up. Therefore, when conveying a sheet such as thin paper or plain paper through the nip portion N, the stiffening lever 53 applies stiffness to the sheet and discharges the sheet.

Note that thin paper has, for example, a basis weight of less than 52 g/m ² , plain paper has a basis weight of, for example, greater than 52 g/m ² and less than 128 g/m ² , and thick paper has, for example, a basis weight of 128 g/m 2 . It is ² or more.

The lever 53 with a waist configured in this way is arranged inside the pair of ejection drive rollers 50, so the length of the business card, etc. in the width direction is short, and the lever 53 with a waist that does not hit the pair of belt rollers 52 when ejecting is small. Even when conveying a large size sheet, it comes into contact with this small size sheet. Therefore, even if the seat is of such a small size, the waist adjustment lever 53 can be used to perform the waist adjustment. Of course, even if the seat is larger than a small size seat, the waist adjustment lever 53 comes into contact and the waist adjustment is performed.

[Timing when the waist roller and waist lever contact the seat]
Here, the timing at which the tension roller 52 and the tension lever 53 come into contact with the sheet will be explained. First, the "immediately upstream" portion of the nip portion N where the sheet starts contacting the buckling roller 52 and the buckling lever 53 will be described with reference to FIG. As shown in FIG. 7, the nip portion N is a portion where the discharge drive roller 50 and the discharge driven roller 51 come into contact to sandwich the sheet, and has a predetermined length in the sheet discharge direction (direction of arrow A). . Immediately upstream of the nip portion N is the position immediately before the sheet conveyed through the discharge conveyance path 401 enters the nip portion N, and in this embodiment, it is defined as follows.

As shown in FIG. 7, in a cross section perpendicular to the rotational axis direction of the discharge drive roller 50 and the discharge driven roller 51, common tangents between the outer circumferential surface of the discharge drive roller 50 and the outer circumferential surface of the discharge driven roller 51 are T1 and T2. do. The tangents T1 and T2 are tangents that do not intersect with each other, and the tangent T1 is a line that touches the outer peripheral surfaces of the discharge drive roller 50 and the discharge driven roller 51 on the upstream side of the nip portion N in the discharge direction. The tangent T2 is a line that touches the outer peripheral surfaces of the discharge drive roller 50 and the discharge driven roller 51 on the downstream side of the nip portion N in the discharge direction.

Furthermore, the intersection between the imaginary line L2 and the tangent T1 that is parallel to the sheet ejection direction and passes through the nip portion N is P1, and the intersection between the imaginary line L2 and the tangent T2 is P2. In this case, "immediately upstream" with respect to the sheet discharge direction of the nip portion N is defined as the area from the upstream end of the nip portion N (not including the upstream end) to the intersection P1. That is, the pair of stiffening rollers 52 and the stiffening lever 53 come into contact with the sheet in the range from the upstream end of the nip portion N to the intersection P1 and not including the upstream end of the nip portion N. The position where the pair of waist rollers 52 and the waist lever 53 start contacting the sheet may be within this range, for example, from the center in the discharge direction between the upstream end of the nip N and the intersection P1 to the center of the nip N. The range may be up to the upstream end and not include the upstream end of the nip portion N.

On the other hand, the pair of waist rollers 52 and the waist lever 53 may be separated from the sheet between the upstream end of the nip portion N and the intersection P1, but at least the pair of waist rollers 52 and the waist lever 53 are It is preferable that the sheet be in contact with the sheet until it reaches the upstream end of the nip portion N.

Further, regarding the sheet discharge direction of the nip portion N, “directly downstream” is defined as the period from the downstream end (not including the downstream end) of the nip portion N to the intersection P2. That is, the pair of stiffening rollers 52 and the stiffening lever 53 come into contact with the sheet in the range from the downstream end of the nip portion N to the intersection P2 and not including the downstream end of the nip portion N. The position at which the pair of waist rollers 52 and the waist lever 53 start contacting the sheet may be within this range, for example, from the center in the discharge direction between the downstream end of the nip N and the intersection P2 to the nip N The range may be up to the downstream end of the nip portion N and not include the downstream end of the nip portion N.

Note that the position where the pair of tension rollers 52 and the tension lever 53 are separated from the sheet may be any position between the downstream end of the nip portion N and the intersection point P2. For example, the pair of stiffening rollers 52 and the stiffening lever 53 may be separated from the sheet from the center in the discharge direction between the downstream end of the nip portion N and the intersection P2 to the intersection P2.

Further, the pair of stiffening rollers 52 and the stiffening lever 53 only need to contact the sheet at least immediately upstream of the nip portion N, and do not need to contact the nip portion N and immediately downstream of the nip portion N. In this case, the pair of stiffening rollers 52 may have the same configuration as the stiffening lever 53. Further, when contacting the sheet only immediately upstream, the contact may be continued until the upstream end of the nip portion N is reached.

However, it is preferable that the pair of waist rollers 52 and the waist lever 53 also contact the sheet immediately downstream of the nip portion N. This is because the sheet can be ejected more reliably in a state where the seat is seated. In this embodiment, as described above, the pair of stiffening rollers 52 and the stiffening lever 53 continue to contact the sheet from just upstream to just downstream of the nip portion N.

Note that in a state where the sheet is held in the nip portion N, the pair of waist rollers 52 and the waist lever 53 do not need to be in contact with the sheet. In this case, the pair of waist rollers 52 and the waist lever 53 are shaped so that they contact the sheet only immediately upstream and downstream of the nip portion N, for example, with protrusions that protrude toward the sheet at these two locations. It is also possible to have a shape that has the following shape.

Furthermore, the pair of tension rollers 52 and tension lever 53 may start contacting the sheet at the same time or whichever comes first. That is, even if the tension lever 53 hits the sheet first, the pair of tension rollers 52 may contact the sheet first. Similarly, the pair of stiffening rollers 52 and the stiffening lever 53 may be separated from the sheet (released from contact) at the same time or whichever comes first. That is, the stiffening lever 53 may be separated from the sheet later, or the pair of stiffening rollers 52 may be separated from the sheet later.

[Kicking protrusion]
As shown in FIG. 4, kick-out protrusions 51a as third protrusions are formed on the outer peripheral surfaces of the pair of discharge driven rollers 51, respectively. That is, the kick-out protrusion 51a is provided at a position on the outer circumferential surface of the pair of discharge driven rollers 51 that is away from the nip portion N in the axial direction of the driven shaft 55 so as to protrude from the outer circumferential surface of the pair of discharge driven rollers 51. It is being In the case of this embodiment, the kick-out protrusion 51a is provided at the outer end of the outer circumferential surface of the pair of discharge driven rollers 51 with respect to the axial direction of the driven shaft 55.

The pair of kick-out protrusions 51a are provided on the driven shaft 55 side (second shaft side), and are closer to the drive shaft 54 than the pair of discharge driven rollers 51 when viewed from the axial direction of the driven shaft 55. stand out. The pair of kick-out protrusions 51a can contact the sheet at least immediately upstream of the nip portion N in the sheet discharge direction.

In addition, the kick-out protrusion 51a includes a plurality of protrusions 510 provided intermittently over the entire outer circumferential surface of the pair of discharge driven rollers 51, as shown in FIGS. 8(a) and 8(b). have The diameter of the circumscribed circle of the plurality of protrusions 510 is made larger than the outer diameter of the discharge driven roller 51.

The kicking protrusion 51a has the role of ejecting the thin sheet that has passed through the nip N with force so as to kick it out of the ejection port of the device. Thereby, the sheet can be discharged to the sheet discharging and stacking section 44 without the rear end of the sheet to which a load is applied by the buckled lever 53 and the buckled roller 52 remaining in the discharge port.

Further, the kick-out protrusion 51a also has the effect of making contact with the sheet and giving the sheet a stiffness when the sheet is ejected. Since the kicking protrusion 51a has a plurality of protrusions 510 over the entire circumference of the outer peripheral surface of the discharge driven roller 51, the kick-out protrusion 51a has a plurality of protrusions 510 extending over the entire circumference of the outer peripheral surface of the discharge driven roller 51. Continues contact with the sheet up to just downstream.

Note that the kick-out protrusion 51a may also be made of an elastic member similarly to the pair of waisted rollers 52. By being composed of an elastic member, when a sheet (for example, a thick sheet) that is difficult to stiffen (high rigidity) is held and conveyed in the nip portion N, the kicking protrusion 51a is elastically deformed to reduce the load on the sheet. be able to.

Further, the timing at which the kicking protrusion 51a starts contacting the sheet may be at the same time as the pair of waist rollers 52 and the waist lever 53, or may be different. For example, it may be made to abut before the lever 53 with a waist. For example, the sheet may come into contact with the pair of waist rollers 52, the kick-out protrusion 51a, and the waist lever 53 in this order. In this embodiment, the seat is brought into contact with the lever 53, the kick-out protrusion 51a, and the pair of rollers 52, in this order. This is because when the sheet is caught in the nip N, it is difficult to bend even if the sheet comes into contact with the waist lever 53 on the inside. This is because the effect of tightening by the lever 53 can be obtained more reliably. Furthermore, if the sheet comes into contact with the kick-out protrusion 51a and the waist roller 52 in this order from the waist lever 53 outward, the sheet tends to wave, and the effect of the waist can be more reliably obtained. preferable. The timing at which the contact is released is the opposite of this. Furthermore, the timing at which the contact is released may be simultaneous or different.

Further, in FIG. 8B, the kick-out protrusion 51a has a plurality of protrusions 510 arranged on the outer circumferential surface of the discharge driven roller 51, divided into six equal parts, but this number can be set as appropriate. Moreover, the kick-out protrusion 51a does not need to be divided into a plurality of protrusions like this, and the protrusion may be continuous on the outer peripheral surface.

[Function of the waist lever]
Here, as described in Patent Document 1, if a belted roller is disposed between the pair of discharge drive rollers 50 instead of the belted lever 53, when a small-sized sheet is conveyed, the trailing edge of the sheet may be in the nip. When the sheet leaves part N, the sheet is accelerated and discharged due to the urging force acting on the sheet from the waist roller. Therefore, there is a possibility that the leading edge of the sheet may be turned upside down.

On the other hand, in the present embodiment, a lever 53 is provided between the pair of discharge drive rollers 50 so as not to rotate about the drive shaft 54 . Therefore, even when a small-sized sheet is conveyed, friction is generated by the contact between the waist lever 53 and the sheet, and a brake is applied to the sheet, so that the sheet can be ejected without being reversed.

FIG. 9 is a diagram of the sheet discharging device 100 viewed from above. In this embodiment, the contact portion 53a (FIG. 7) of the lever 53 slides on the sheet conveyed from immediately upstream to immediately downstream in the discharge direction. Therefore, the brake lever 53 can apply a brake to the sheet being ejected, and the sheet can be prevented from being ejected forcefully and turned over, thereby improving the sheet ejection performance.

In particular, the contact portion 53a of the waist lever 53 is located within the nip portion N (FIG. 7) (in particular, in the nip portion N downstream of the center in the ejection direction) with respect to the sheet ejection direction (arrow A direction). Even in the moving position 53d), it slides on the sheet conveyed in the nip portion N. Therefore, the brake can be applied more reliably to the discharged sheet. Further, since the contact portion 53a of the waist lever 53 also contacts directly downstream of the nip portion N, it is possible to further apply a brake to the sheet after passing through the nip portion N. The flow of sheet discharge according to the sheet type will be described below with reference to FIGS. 10 to 14.

[Thin paper]
First, a case where the sheet is thin paper with a small basis weight (hereinafter referred to as sheet S1) will be described using FIGS. 10 to 12. First, as shown in FIG. 10A, a sheet S1 is conveyed toward the sheet discharge device 100 through the discharge conveyance path 401. Since the discharge conveyance path 401 is formed in a curved manner as described above, the sheet S1 is guided by the second guide section 403 located on the upper side and moves in the direction of the arrow toward the nip section N (see FIG. 11 etc.). transported. At this time, since the waist lever 53 is not in contact with the seat S1, it is located at the above-mentioned initial position.

Next, when the sheet S1 is further conveyed toward the nip portion N, the sheet S1 is first moved immediately upstream of the nip portion N by a pair of waist rollers 52, a kicking protrusion 51a, and a waist lever. 53. For this reason, the sheet S1 enters the nip portion N in a state in which it is stiffened by the pair of stiffening rollers 52, the kick-out protrusion 51a, and the stiffening lever 53. Then, as shown in FIG. 10(b), the sheet S1 is conveyed through the nip portion N in the direction of the arrow with the waist still attached.

At this time, as shown in FIGS. 11 and 12, the sheet S1 is moved downward in FIGS. 11 and 12 by 51a, and further pushed downward in FIGS. 11 and 12 by the waisted roller 52 on the outside thereof. As a result, the sheet S1 is discharged from the nip portion N in a wavy shape, that is, in a bent state.

The pair of waist rollers 52, the kick-out protrusion 51a, and the waist lever 53 continue to contact each other until the sheet S1 is immediately downstream of the nip portion N. Therefore, the sheet S1 passes through the nip N in a state in which the sheet S1 is stiffened by these, and the stiffness is maintained even after being ejected from the nip N, as shown in FIG. 10(c). Then, the sheet S1 is discharged substantially linearly in the direction of arrow D, falls gently in the direction of arrow E (downward), and is discharged to the sheet discharge and stacking section 44.

[Thick paper]
Next, a case where the sheet is cardboard with a large basis weight (hereinafter referred to as sheet S2) will be described using FIGS. 13 and 14. First, as shown in FIG. 13A, the sheet S2 is conveyed toward the sheet discharge device 100 through the discharge conveyance path 401, similarly to the sheet S1 described above. At this time, the waist lever 53 is not in contact with the seat S2, so it is located at the above-mentioned initial position.

Next, when the sheet S2 is further conveyed toward the nip portion N, the sheet S2 is first moved immediately upstream of the nip portion N by a pair of waist rollers 52, a kicking protrusion 51a, and a waist lever. 53. However, since the sheet S2 has high rigidity, the pair of buckled rollers 52 are elastically deformed, and the contact portion 53a of the buckled lever 53 (see FIG. 7) moves to retreat from the discharge conveyance path 401. For this reason, the sheet S2 enters the nip portion N in a state in which the seat is hardly stiffened by these factors. Then, as shown in FIG. 13(b), the sheet S2 is conveyed through the nip N in the direction of the arrow in a state in which the waist is hardly attached. In this case, the amount of protrusion of the lever 53 from the discharge drive roller 50 is approximately zero, for example.

At this time, the sheet S2 is in a state in which there is almost no undulation in the width direction, as shown in FIG. Therefore, the sheet S2 passes through the nip N in a substantially linear shape in the width direction, and after being ejected from the nip N, as shown in FIG. 13(c), the sheet S2 is gently ejected in the direction of the arrow. Ru.

As described above, in this embodiment, the fixed lever 53 is provided between the pair of discharge drive rollers 50 so as not to rotate about the drive shaft 54. Therefore, even when a small-sized sheet is conveyed, friction is generated when the seat lever 53 and the sheet come into contact, and a brake is applied to the sheet. You can eject the sheet while holding it down.

Further, since the waist lever 53 contacts the sheet immediately upstream of the nip portion N, the sheet can be fed into the nip portion N with the waist attached, even if it is a small sheet, for example. Therefore, even if the sheet is of small size, the sheet discharge performance can be improved. Furthermore, in the present embodiment, the buckle lever 53 is in contact with the sheet even immediately downstream of the nip portion N, so that the sheet can be ejected more reliably with the seat buckled. Furthermore, since the buckle lever 53 continues to contact from just upstream to just downstream of the nip portion N, it is possible to more stably buckle the seat.

In addition, since the member that comes into contact with the sheet to give the seat a seat is the seat lever 53 that does not rotate around the drive shaft 54, the seat lever 53 comes into contact with the sheet discharged from the nip portion N, and the seat is You can apply the brakes against it. In this manner, in this embodiment, it is possible to adjust the seat to the seat, apply a brake to the seat, and discharge the seat, so that the sheet discharge performance can be improved.

[Another first example of embodiment]
FIG. 15 shows, as another first example of the embodiment, a configuration in which a waist lever 53A is provided downstream of the configuration described above. The waist lever 53A has the same configuration as the waist lever 53 described above, except for the position in the sheet ejection direction. In the case of another first example, the waist lever 53A contacts the sheet at least immediately downstream of the nip portion N (see FIG. 7) in the sheet discharging direction, but does not contact the sheet immediately upstream. In addition, in the example of FIG. 15, the lever 53A with a waist contacts only immediately downstream of the nip part N, but it may be made to contact|abut also in the nip part N. Even with such a configuration, when the sheet is ejected from the nip portion N, it is possible to give the seat a stiffness using the stiffening lever 53A. In particular, since the sheet is stiffened after passing through the nip portion N, the sheet can be stiffened without applying any load to the sheet or the rollers.

[Another second example of the embodiment]
FIG. 16 shows, as another second example of the embodiment, a configuration in which a waist lever 53B is provided upstream of the configuration described above. The waist lever 53B has the same configuration as the waist lever 53 described above, except for the position in the sheet ejection direction. In the case of another second example, the waist lever 53B contacts the sheet at least immediately upstream of the nip portion N (see FIG. 7) in the sheet ejection direction, but does not contact the sheet immediately downstream. In addition, in the example of FIG. 16, the lever 53B with a waist contacts only immediately upstream of the nip part N, but it may be made to contact|abut also in the nip part N. Even with such a configuration, when the sheet is ejected from the nip portion N, it is possible to give the seat a stiffness using the stiffening lever 53B.

[Other embodiments]
In the above description, the second protrusions are the waisted levers 53, 53A, and 53B, but the second protrusions may have other configurations. For example, the second protrusion may be an elastic member such as a leaf spring. For example, one end of the leaf spring may be fixed, the other end may be a free end, and this free end side may be made to protrude toward the driven shaft 55 side beyond an imaginary line passing through the nip portion and parallel to the discharge direction.

Further, the levers 53, 53A, and 53B may be provided on the driven shaft 55 side and protrude toward the drive shaft 54 side. In this case, one of the shafts becomes the driven shaft 55, and the levers 53, 53A, and 53B are provided so as not to rotate around the driven shaft 55. The levers 53, 53A, and 53B are provided inside the pair of discharge driven rollers 51 provided on the driven shaft 55, and are closer to the drive shaft 54 than the imaginary line L1 passing through the nip N and parallel to the discharge direction. The amount of protrusion can be changed. The contact position with the seat is the same as when the waist levers 53, 53A, 53B are provided on the drive shaft 54 side.

Furthermore, the pair of stiffened rollers 52 may be located on the driven shaft 55 side. In this case, the kick-out protrusion 51a is preferably provided on the discharge drive roller 50.

The tangent line defining the range immediately upstream and downstream of the nip portion N may be the tangent line between the stiffening roller 52 and the discharge driven roller 51. That is, the tangent T1 is a line that touches the outer circumferential surfaces of the buckled roller 52 and the discharge driven roller 51 on the upstream side of the nip portion N in the discharge direction, and the tangent T2 is the line that touches the outer circumferential surfaces of the stiffened roller 52 and the discharge driven roller 51 at the nip. It may also be a line that touches part N on the downstream side in the discharge direction.

In addition to the image reading device, the sheet discharging device of the present invention can also be used with an image forming device such as a copying machine, a printer, a facsimile machine, or a multifunctional device having multiple functions thereof, or with a sheet discharging device that performs processes such as bookbinding and stapling on sheets. It can also be applied to the sheet discharging section of a sheet processing device.

14, 15...Reading unit (reading section)/17, 18...Registration roller (conveyance section)/50...Ejection drive roller (first ejection roller)/51...Ejection driven roller (second Discharge roller)/51a... Kick-out protrusion (third protrusion)/52, 52A... Roller with waist (first protrusion)/53, 53A, 53B... Lever with waist (second protrusion) part)/53a... Contact part/53b... Swing shaft/53c... Tension spring (biasing means)/54... Drive shaft (first shaft)/55... Driven shaft ( 2nd axis)/100...Sheet discharge device/200...Image reading device/510...Protrusion

Claims (15)

The first axis,
a pair of first discharge rollers provided on the first shaft;
a second axis;
A sheet is provided on the second shaft to form a nip portion that comes into contact with each of the pair of first ejection rollers to nip the sheet, and rotates together with the pair of first ejection rollers so that the sheet is nipped by the nip portion. a pair of second ejection rollers that eject the sheet;
a pair of first protrusions provided on the first shaft outside the pair of first discharge rollers with respect to the axial direction of the first shaft and protruding toward the second shaft side with respect to the nip portion; ,
The pair of first protrusions are a pair of rollers that are provided to be rotatable relative to the first shaft and have a larger outer diameter than the pair of first discharge rollers.
A discharge device characterized by: Projecting from the one shaft toward the other shaft inside the pair of discharge rollers in the axial direction of one shaft on which one of the first discharge roller and the second discharge roller is provided. , comprising a second protrusion fixed at a position different from the one shaft such that the amount of protrusion toward the other shaft can be changed;
The sheet discharging device according to claim 1, characterized in that: When viewed from the axial direction of the first shaft, the first protrusion protrudes toward the second shaft side beyond an imaginary line that passes through the nip and is parallel to a discharge direction in which the sheet is discharged. abutting against the sheet of the predetermined size or larger at least immediately upstream of the nip portion with respect to the discharge direction in which the sheet is discharged, when the sheet is of a predetermined size or larger;
The second protrusion protrudes toward the other of the first and second shafts with respect to the imaginary line when viewed from the axial direction of the one shaft, and the second protrusion protrudes toward the other one of the first and second shafts when viewed from the axial direction of the one shaft, and at least extends toward the nip in the discharge direction. contact the sheet immediately upstream of the
The sheet discharging device according to claim 2, characterized in that: The first shaft is a drive shaft that is rotationally driven.
The sheet discharging device according to any one of claims 1 to 3, characterized in that: The second protruding portion also contacts the sheet immediately downstream of the nip portion with respect to the discharge direction in which the sheet is discharged.
The sheet discharging device according to claim 2 or 3, characterized in that: The second protrusion continues to contact the sheet from just upstream to just downstream of the nip in the discharge direction.
The sheet discharging device according to claim 5, characterized in that: The second protruding portion has a contact portion that contacts the seat, and a biasing means that biases the contact portion toward the other shaft side.
The sheet discharging device according to any one of claims 2, 3, and 5, characterized in that: The contact portion is provided to be swingable about an axis substantially parallel to the one axis.
The sheet discharging device according to claim 7, characterized in that: The first axis,
a pair of first discharge rollers provided on the first shaft;
a second axis;
A sheet is provided on the second shaft to form a nip portion that comes into contact with each of the pair of first ejection rollers to nip the sheet, and rotates together with the pair of first ejection rollers so that the sheet is nipped by the nip portion. a pair of second ejection rollers that eject the sheet;
a pair of first protrusions provided on the first shaft outside the pair of first discharge rollers in the axial direction of the first shaft and protruding toward the second shaft side with respect to the nip portion;
The nip is provided on the second shaft side, protrudes toward the first shaft side relative to the pair of second discharge rollers when viewed from the axial direction of the second shaft, and at least the nip with respect to the discharge direction in which the sheet is discharged. a pair of third protrusions that can come into contact with the sheet immediately upstream of the part;
A sheet discharging device characterized by: The third protruding portion is provided on the outer circumferential surface of the pair of second discharge rollers at a position away from the nip portion in the axial direction of the second shaft so as to protrude from the outer circumferential surface.
The sheet discharging device according to claim 9, characterized in that: The third protrusion includes a plurality of protrusions provided intermittently over the entire outer peripheral surface of the pair of second ejection rollers.
The sheet discharging device according to claim 10, characterized in that: The third protrusion is provided at an outer end of the outer circumferential surface of the pair of second discharge rollers with respect to the axial direction of the second shaft.
The sheet discharging device according to claim 10 or 11, characterized in that: The first axis is arranged above the second axis in the direction of gravity,
The sheet discharging device according to any one of claims 1 to 12, characterized in that: When viewed from the axial direction of the first shaft, the first protrusion protrudes toward the second shaft side beyond an imaginary line that passes through the nip and is parallel to a discharge direction in which the sheet is discharged. abutting against the sheet of the predetermined size or larger at least immediately downstream of the nip portion in the discharge direction when the sheet is larger than a predetermined size;
The second protrusion protrudes toward the other of the first and second shafts with respect to the imaginary line when viewed from the axial direction of the one shaft, and the second protrusion protrudes toward the other one of the first and second shafts when viewed from the axial direction of the one shaft, and at least extends toward the nip in the discharge direction. contacting the sheet immediately downstream of the
The sheet discharging device according to claim 2, characterized in that: a conveyance unit that conveys the sheet;
a reading unit capable of reading an image of a sheet conveyed by the conveyance unit;
The sheet ejection device according to any one of claims 1 to 14 , which ejects the sheet whose image has been read by the reading section.
An image reading device characterized by:

Images