KR20220164856A - medium supplier with deviation prevention structure for side guide - Google Patents

Abstract

A paper feeder is disclosed. The paper feeder comprises first and second loading units arranged in a paper feeding direction, a side guide capable of switching between a first position for blocking the leading end of a printing medium loaded on the second loading unit and a second position retracted from the leading end of the printing medium, and a deviation prevention member for selectively allowing the side guide to be switched to the second position.

Description

Paper feed device having a structure for preventing deviation of the side guide {medium supplier with deviation prevention structure for side guide}

An image forming apparatus prints an image on a print medium by various printing methods. A print medium is accommodated in a paper feed device. Print media is taken out sheet by sheet from the paper feed device and supplied to the main body of the image forming apparatus. The paper feed device may have various structures. The paper feed device may include a paper feed tray protruding from the side of the main body of the image forming device, a paper feed cassette positioned under the main body of the image forming device, a side feed device positioned on the side of the main body of the image forming device to supply print media to the main body, and the like. can A paper feed device positioned below the main body of the image forming apparatus is called a 'paper feed cassette'. A plurality of print media within the paper feed unit needs to be kept aligned with the stacking unit.

1 is a schematic plan view of an example of a sheet feeding device.
2 is a perspective view of an example of a separation prevention structure.
3 is an exploded perspective view of an example of the separation preventing structure shown in FIG. 2 .
4 is a plan view showing a state in which the side guide is positioned in the first position and the departure prevention member is positioned in the locking position.
5 is a plan view showing a state in which an impact is applied to the side guide.
6 is a plan view showing a state in which the side guide is positioned in the second position and the separation preventing member is positioned in the release position.
7 is a schematic plan view of an example of a separation prevention structure.
8 is a schematic side view of an example of a sheet feeding device.
9 is a schematic plan view of an example of a sheet feeding device showing a state in which a side guide is positioned in a first position.
FIG. 10 shows a state in which a side guide is positioned in a second position in an example of the paper feeding device shown in FIG. 9 .

A paper feed device is connected to the main body of the image forming apparatus to supply print media to the image forming apparatus. The paper feed device can be moved in and out of the main body of the image forming apparatus. For example, in order to replenish print media in the paper feed device, the paper feed device may be withdrawn from the main body so that the loading portion of the paper feed device is exposed. After the print medium is loaded on the stacking unit, it can be inserted into the main body of the image forming apparatus by sliding the paper feed device. In order to increase the loading capacity of the paper feeding device, the paper feeding device may be provided with two stacking units. The two loading parts are positioned aligned in the feeding direction of the printing medium. Print media from the stacking unit (first stacking unit) located at the front is supplied to the main body of the image forming apparatus. When all of the print media in the first loading unit is used up, the print media loaded in the rear loading unit (second loading unit) is moved to the first loading unit, loaded, and supplied to the main body of the image forming apparatus. It is necessary to keep the print media loaded in the second loading unit in an aligned state. An impact may be applied to the paper feed device when it is inserted into the main body of the image forming apparatus and reaches a mounting position. Due to this impact, alignment of the print media loaded in the second loading unit may be disturbed.

The paper feed device of this example adopts a structure capable of maintaining alignment of the print media loaded in the second stacking unit. The paper feed device of this example maintains the alignment of the print media loaded in the second stacker by preventing the side guides blocking the front end of the print media stacked in the second stacker from leaving. As an example, the paper feed device may include a side guide switchable between a first position blocking the front end of the print medium loaded in the second loading unit and a second position escaping from the front end of the print medium, and switching the side guide to the second position. It may be provided with a separation prevention member that selectively allows. Since the shifting of the side guide to the second position is selectively allowed by the separation preventing member, even if a force applied to the side guide to the second position is applied due to an impact applied when the paper feed device is inserted into the main body of the image forming apparatus, the side guide is moved to the second position. Conversion of the guide to the second position can be prevented by the separation prevention member. Therefore, the print media loaded in the second loading unit can be maintained in the second loading unit in an aligned state with its front end blocked by the side guide located in the first position.

The departure prevention member may be moved to a blocking position preventing the side guide from switching from the first position to the second position and a releasing position allowing the side guide to switch from the first position to the second position. The separation preventing member can be moved to a locked position and a release position along a straight path or a rotational path. A slip prevention structure may be employed to support the separation preventing member positioned at the locking position so as not to be pushed by the side guide that is switched to the second position by impact. The side guide and the separation prevention member may be driven by a common actuator. The side guide may be rotated and switched to the first and second positions. The actuator may be a linear actuator, for example a solenoid. The actuator may be a rotary motor, and the separation preventing member may be implemented by a combination of a worm gear and a pinion rotated by the rotary motor. Hereinafter, examples of the sheet feeding device will be described with reference to the drawings.

1 is a schematic plan view of an example of a sheet feeding apparatus 1 . Referring to FIG. 1 , an example of a sheet feeding device 1 is stacked in a first stacking unit 11, a second stacking unit 12, and a second stacking unit 12 arranged in the paper feeding direction SD. A side guide 20 switchable between a first position blocking the front end of the print medium P2 (position shown by a solid line) and a second position escaped from the front end of the print medium P2 (position shown by a dotted line), and It may include a separation prevention member 30 that selectively allows the conversion of the side guide 20 to the second position. The feeding direction (SD) is the direction in which print media is drawn from the paper feeding device 1 .

Based on the paper feeding direction (SD), the first stacking unit 11 is located in front of the second stacking unit 12 . Print media P1 and P2 are loaded on the first loading unit 11 and the second loading unit 12, respectively. When the paper feed device 1 is installed in the image forming device (not shown), the printed media P1 stacked in the first stacking unit 11 are removed from the first stacking unit 11 one by one by a pull-out mechanism (not shown). are withdrawn When the print media P1 loaded in the first loading unit 11 is exhausted, the printing media P2 loaded in the second loading unit 12 is transported to the first loading unit 11 . For example, the end guide 13 pushes the upstream edge of the print medium P2 while being moved in the feeding direction SD by a driving mechanism (not shown). The print medium P2 is conveyed from the second loading unit 12 to the first loading unit 11 . The image forming apparatus may take out the print media P2 from the first loading unit 11 one by one.

The side guide 20 blocks the front end of the print medium P2 loaded on the second loading unit 12 . The side guide 20 blocks the front end of the print medium P2 and the first position that blocks the print medium P2 from moving in the feeding direction SD, and escapes from the front end of the print medium P2 to prevent the print medium P2 from moving in the feeding direction SD. P2) can be switched to the second position allowing it to be moved in the paper feeding direction SD. As an example, the side guide 20 may be rotated to a first position and a second position. In this example, the side guide 20 is located on one side of the print medium P2 in the width direction. The side guide 20 may include a body 21 and a blocking portion 22 . The body 21 may be rotatably supported on the sidewall 14 of the paper feeding device 1 in the width direction about the rotation shaft 23 . The body 21 extends from the rotation shaft 23 in the feeding direction SD. The blocking portion 22 extends from the end of the body 21 in the width direction. When the side guide 20 is located in the first position, the blocking portion 22 blocks the front end of the print medium P2. The front end of the print medium P2 is maintained in an aligned state by contacting the blocking portion 22 . When the side guide 20 is positioned at the second position, the blocking portion 22 escapes from the front end of the print medium P2, and movement of the print medium P2 in the feeding direction SD is permitted.

In order to load the print media P1 (P2) in the first loading unit 11 and the second loading unit 12, the paper feed device 1 can be taken out from the image forming apparatus. For example, the paper feed apparatus 1 can be slid in the removal direction A1 and taken out from the image forming apparatus. When the print media P1 or P2 are loaded on the first loading unit 11 and the second loading unit 12, the paper feed device 1 can be slid in the mounting direction A2 and inserted into the image forming apparatus. . When the paper feeder 1 reaches the mounting position, it is caught, for example, by a stopper (not shown) and stops. At this time, a shock may be applied to the sheet feeding device 1 . The faster the sliding speed of the sheet feeding device 1 is, the greater the impact can be. A force in a direction that is switched from the first position to the second position may be applied to the side guide 20 by this impact. When the side guide 20 is switched to the second position, alignment of the print media P2 loaded in the second loading unit 12 may be disturbed. For example, when the print medium P2 advances in the feeding direction SD, the side guide 20 may not be able to return to the first position from the second position, and the print medium P2 may not return to the first loading unit 11. can pass to In addition, the side edge of the print medium P2 may be folded or stamped by the side guide 20 . Such disorder of the print medium P2 may cause poor drawing or meandering. In addition, as the side guide 20 is switched to the second position by the impact, a structure for driving the side guide 20, for example, a connection structure between an actuator and the side guide 20 described below is damaged or inoperable. It can be.

The sheet feeding device 1 of this example has a separation prevention structure that prevents the side guide 20 from being separated from the first position to the second position due to an impact. As an example, the paper feeding device 1 may include a separation prevention member 30 that selectively allows the side guide 20 to be switched from the first position to the second position. The separation preventing member 30 may have a structure that prevents the side guide 20 from being rotated to the second position by being caught by the separation preventing member 30 when the side guide 20 is rotated from the first position to the second position by impact. As an example, the departure prevention member 30 is a blocking position for blocking the conversion from the first position to the second position of the side guide 20, and the conversion from the first position to the second position of the side guide 20 can be moved to a release position that allows According to this configuration, the side guide 20 can be switched from the first position to the second position only when the separation preventing member 30 is located at the release position, and the side guide 20 is separated due to impact. this can be prevented.

2 is a perspective view of an example of a separation prevention structure. 3 is an exploded perspective view of an example of the separation preventing structure shown in FIG. 2 . Referring to FIGS. 2 and 3 , the paper feeding device 1 may include an actuator that drives the side guide 20 . The actuator may include a linear actuator such as solenoid 40 for example. The solenoid 40 is connected to the side guide 20 and the detachment prevention member 30 to move them to the second position and the release position, respectively.

The solenoid 40 may include a driving unit 41 and a plunger 42 . When a voltage is applied to the driver 41, the plunger 42 moves linearly. The side guide 20 may be connected to the plunger 42 . For example, the side guide 20 may have a hooking piece 25 provided with a hooking groove 24 . An insertion groove 43 into which the locking piece 25 is inserted may be provided in the plunger 42 . The connecting pin 50 may pass through the plunger 42 and be inserted into the locking groove 24 . The elastic member 60 may apply an elastic force in a direction positioned at the first position to the side guide 20 . For example, the elastic member 60 may be implemented by a tension coil spring having one end and the other end connected to the side guide 20 and the side wall 14, respectively. When voltage is applied to the solenoid 40, the plunger 42 is moved in the opposite direction to the elastic force of the elastic member 60 by the electromagnetic force. The connection pin 50 moves together with the plunger 42 and pulls the locking groove 24 to switch the side guide 20 to the second position. When the voltage applied to the solenoid 40 is released, the electromagnetic force is removed and the side guide 20 may be returned to the first position by the elastic force of the elastic member 60.

For example, the separation preventing member 30 may be supported on the side wall 14 so as to be linearly movable into a locking position and a release position. When the side guide 20 starts to rotate from the first position to the second position while the separation preventing member 30 is positioned at the locking position, the side guide 20 comes into contact with the separation preventing member 30 . Therefore, rotation of the side guide 20 is blocked so that the side guide 20 cannot be switched to the second position and can be maintained in the first position. The side guide 20 may be provided with an interference portion 26 so as to be in contact with the separation preventing member 30 located in the locking position.

When the side guide 20 is switched to the second position, a slip prevention structure supporting the separation prevention member 30 located at the locking position so as not to be pushed by the side guide 20 may be employed. As an example, the pushing prevention structure may include an insertion protrusion 32 provided on the separation preventing member and a guide slot 15 into which the insertion protrusion is inserted. The insertion protrusion 32 may protrude from the lower surface of the separation preventing member 30 . The guide slot 15 may be provided on the side wall 14 . The guide slot 15 may extend linearly to guide the separation preventing member 30 to a locking position and an unlocking position. The extending direction of the guide slot 15 may be a direction crossing the direction in which the side guide 20 is converted from the first position to the second position.

The separation preventing member 30 may be driven by an actuator that drives the side guide 20 . As an example, the separation preventing member 30 may be connected to the plunger 42 and moved from a locking position to a release position by the solenoid 40 . A pin groove 31 may be provided in the separation preventing member 30 . The connecting pin 50 passing through the plunger 42 protrudes downward from the plunger 42 and may be inserted into the pin groove 31 . When voltage is applied to the solenoid 40, the plunger 42 is moved in the opposite direction to the elastic force of the elastic member 60 by the electromagnetic force. At this time, the connecting pin 50 moves together with the plunger 42 and pulls the pin groove 31 to move the separation preventing member 30 from the locking position to the release position. As the separation preventing member 30 is moved to the releasing position, the side guide 20 may be switched to the second position. When the voltage applied to the solenoid 40 is released, the electromagnetic force is canceled and the side guide 20 is returned to the first position by the elastic force of the elastic member 60. As the plunger 42 is returned to its original position by the elastic force of the elastic member 60, the separation preventing member 30 may also be returned from the releasing position to the locking position.

4 is a plan view showing a state in which the side guide 20 is positioned in the first position and the separation preventing member 30 is positioned in the locking position. 5 is a plan view showing a state in which an impact is applied to the side guide 20. 6 is a plan view showing a state in which the side guide 20 is positioned in the second position and the separation preventing member 30 is positioned in the release position. 4 to 6, the elastic member 60 is omitted. The operation of the sheet feeding device 1 will be described below with reference to FIGS. 4 to 6 .

First, referring to Figure 4, the side guide 20 is located in the first position, the separation prevention member 30 is located in the locking position. The front end of the print medium P2 is in contact with the blocking portion 22 of the side guide 20. Therefore, the print medium P2 does not move in the feeding direction SD and can be maintained in the second stacking unit 12 in an aligned state. As described above, in order to load the print media P1 or P2 in the first loading unit 11 and the second loading unit 12, the paper feed device 1 can be taken out from the image forming apparatus. At this time, the side guide 20 is maintained in the first position, and the separation prevention member 30 is maintained in the locking position. When the print media P1 and P2 are loaded on the first loading unit 11 and the second loading unit 12, the printing media P2 are aligned by the side guide 20 located in the first position. It can be maintained in the second loading part 12 as. In this state, the paper feed device 1 can be mounted on the image forming device.

An impact may be applied to the paper feed apparatus 1 when it reaches the mounting position and stops. By this impact, a force in a direction shifting from the first position to the second position is applied to the side guide 20, and as shown in FIG. 5, the side guide 20 may be slightly rotated toward the second position. At this time, the interference portion 26 comes into contact with the separation preventing member 30 located in the locking position. The side guide 20 is blocked by the separation prevention member 30 and no longer rotates toward the second position. Even if the side guide 20 is slightly rotated, the blocking portion 22 does not deviate from the front end of the print medium P2. Thus, the print medium P2 can be maintained in a state aligned with the second mounting unit 12 . When the impact is released, as shown in FIG. 4 , the side guide 20 may be returned to the first position by the elastic force of the elastic member 60 .

Even if the interference portion 26 of the side guide 20 pushes the separation preventing member 30, since the separation preventing member 30 is supported by the pushing preventing structure, the separation preventing member 30 can be maintained in the locking position. . For example, when a pushing force is applied to the separation preventing member 30 by the side guide 20, the insertion protrusion 32 collides with the wall of the guide slot 15. Since the wall of the guide slot 15 extends in a direction crossing the direction of rotation of the side guide 20 from the first position to the second position, the separation preventing member 30 is not pushed to the release position and is maintained in the locking position It can be.

When the print media P1 loaded in the first loading unit 11 is exhausted, the printing media P2 loaded in the second loading unit 12 needs to be transported to the first loading unit 11 . To this end, a voltage is applied to the solenoid 40 . Then, the plunger 42 is moved in a direction opposite to the feeding direction SD, for example, by the electromagnetic force. The connecting pin 50 pulls the pin groove 31 while moving together with the plunger 42 to pull the separation preventing member 30 from the locking position to the releasing position. At the same time, the connecting pin 50 pulls the locking groove 24 in the opposite direction to the elastic force of the elastic member 60 to rotate the side guide 20 from the first position to the second position. Since the separation preventing member 30 is moved to the release position, the interference portion 26 of the side guide 20 does not collide with the separation preventing member 30, and rotation of the side guide 20 to the second position is permitted. ,

As shown in Figure 5, the side guide 20 may be located in the second position. The blocking portion 22 of the side guide 20 is separated from the front end of the print medium P2. In this state, as described above, the print medium P2 may be transported to the first loading unit 11 by moving the end guide 13 in the feeding direction SD. When the print medium P2 is completely transported to the first loading unit 11, the voltage applied to the solenoid 40 is released. The electromagnetic force is canceled and the side guide 20 is returned to the first position by the elastic force of the elastic member 60. At this time, since the connecting pin 50 is pulled in the feeding direction SD by the catching groove 24, the plunger 42 returns to its original position, and the separation preventing member 30 can also return to the locking position. Accordingly, as shown in FIG. 4 , the side guide 20 may be positioned at the first position and the separation preventing member 30 at the locking position.

Referring back to FIG. 4 , a gap G may exist between the interference portion 26 of the side guide 20 and the separation preventing member 30 . That is, when the side guide 20 is in the first position, the interference part 26 is opposed to the separation preventing member 30 located in the locking position at a distance (G). The gap (G) is such that when the side guide 20 is rotated toward the second position by an impact and the interference portion 26 contacts the separation preventing member 30 located in the locking position, the blocking portion 22 blocks the printing medium ( It can be determined not to deviate from the tip of P). In addition, the gap G is the separation preventing member ( 30) can be set to move to the release position.

7 is a schematic plan view of an example of a separation prevention structure. Referring to FIG. 7, the linear movement path of the separation preventing member 30 is the interference portion 26 when the interference portion 26 of the side guide 20 contacts the separation prevention member 30 located in the locking position. It may be a direction orthogonal to the direction of the force (F) applied by For example, the guide slot 15 in which the insertion protrusion 32 of the separation preventing member 30 is inserted to provide a linear movement path of the separation preventing member 30 extends in a direction perpendicular to the direction of the force F. It can be. The solenoid 40 may be disposed in the extension direction of the guide slot 15 . According to this configuration, the force applied to the separation preventing member 30 by the side guide 20 when the interference portion 26 of the side guide 20 contacts the separation preventing member 30 located in the locking position. The direction of (F) is orthogonal to the guide slot 15. Accordingly, a push preventing structure capable of effectively preventing the release preventing member 30 from being pushed by the side guide 20 may be implemented.

8 is a schematic side view of an example of the paper feed apparatus 1. The paper feed apparatus 1 of this example differs from the above-described embodiments of the paper feed apparatus 1 in that the separation preventing member 30 is rotated and moved to the locking position and the releasing position. The differences are mainly explained below. Referring to FIG. 8 , the separation preventing member 30 is supported on the side wall 14 so as to be rotatable about the rotation shaft 16 . For example, the rotation axis 16 of the departure prevention member 30 may be perpendicular to the rotation axis 23 of the side guide 20 . The connection pin 50 protruding downward through the plunger 42 of the solenoid 40 is inserted into the pin groove 31 of the separation preventing member 30 . When voltage is applied to the solenoid 40 , the detachment prevention member 30 is rotated around the rotational shaft 16 and can be moved from a locking position to a releasing position. In addition, when the voltage applied to the solenoid 40 is released, the separation preventing member 30 may return from the releasing position to the locking position by the elastic force of the elastic member 60 . The slip prevention structure of the separation preventing member 30 may be the same as that described in FIG. 3 . For example, an insertion protrusion 32 may be provided under the separation preventing member 30 . A guide slot 15 into which the insertion protrusion 32 is inserted may be provided on the side wall 14 of the paper feed device 1 . The guide slot 15 may extend linearly so that the separation preventing member 30 can be rotated and moved to a locking position and a releasing position.

In the above embodiments, a linear actuator, for example, a solenoid 40 is employed as an actuator. A rotary motor may be employed as an actuator. 9 is a schematic plan view of an example of the sheet feeding device 1, showing a state in which the side guide 120 is located in the first position. FIG. 10 shows a state in which the side guide 120 is located in the second position in an example of the paper feeding device 1 shown in FIG. 9 . The paper feed apparatus 1 of this example differs from the above-described examples in that a rotary motor 70 is employed as an actuator. The differences are mainly explained below. Referring first to FIG. 9 , a rotary motor 70 is shown. The side guide 120 is switched to the first position and the second position by the rotary motor 70, for example, is rotated. Side guide 120 is provided with a partial gear portion 124 connected to the rotary motor (70). The side guide 120 is rotated to the first position and the second position with the rotation center of the partial gear unit 124 as an axis. As an example, the partial gear unit 124 may have a partial arc shape centered on the rotation axis 123 of the side guide 120 .

Conversion from the first position to the second position of the side guide 120 due to impact, for example, the separation prevention member for preventing rotation is implemented by the self-locking action of the worm gear 80 and the pinion 90 can The pinion 90 is connected with the partial gear part 124. The worm gear 80 is connected to the rotation motor 70 and is rotated by the rotation motor 70 . For example, the worm gear 80 may be coupled to a rotation shaft of the rotation motor 70 . The worm gear 80 meshes with the pinion 90. For example, the pinion 90 may be a second gear having a first gear portion 91 meshed with the worm gear 80 and a second gear portion 92 meshed with the partial gear portion 124 . Of course, the pinion 90 may be a first gear having a first gear unit 91, in which case the first gear unit 91 may be connected to the partial gear unit 124 directly or via one or more intermediate gears. can

The combination of the worm gear 80 and the pinion 90 enables transmission of rotational force from the worm gear 80 to the pinion 90, but transmission of rotational force in the reverse direction is impossible. In other words, the pinion 90 can be rotated by rotating the worm gear 80, but the worm gear 80 cannot be rotated by rotating the pinion 90. Therefore, as shown in FIG. 9, even if an impact in the direction of rotation to the second position is applied to the side guide 120 in a state where the side guide 120 is located in the first position, the worm gear 80 and the pinion 90 ) The rotation of the side guide 120 can be prevented by the magnetic locking structure. Thus, the side guide 120 can be maintained in the first position without being separated from the first position.

In order to transport the print medium P2 of the second loading unit 12 to the first loading unit 11, it is necessary to switch the side guide 120 to the second position. To this end, the rotary motor 70 is rotated in the forward direction in the state shown in FIG. 9 . Then, the rotational force of the rotary motor 70 is transmitted to the partial gear part 124 via the worm gear 80 and the pinion 90, and the side guide 120 can be rotated. The side guide 120 reaches the second position as shown in FIG. 10 . In this state, the print medium P2 may be transported to the first loading unit 11 by moving the end guide 13 in the feeding direction SD.

When the print medium P2 is completely transported to the first loading unit 11, the rotary motor 70 is rotated in the reverse direction in the state shown in FIG. 10. Then, the rotational force of the rotary motor 70 is transmitted to the partial gear part 124 via the worm gear 80 and the pinion 90, and the side guide 120 can be returned from the second position to the first position . When the side guide 120 reaches the first position, the side guide 120 may be maintained at the first position by the magnetic locking action of the worm gear 80 and the pinion 90 .

The present invention has been described with reference to the embodiments shown in the drawings, but this is only exemplary, and those skilled in the art can make various modifications and equivalent other embodiments. will understand Therefore, the true technical protection scope of the present invention should be determined by the claims below.

Claims (15)

a first stacking unit and a second stacking unit arranged in the paper feeding direction;
a side guide switchable between a first position blocking the front end of the printing medium loaded in the second loading unit and a second position escaping from the front end of the printing medium;
and a detachment prevention member selectively allowing the side guide to be switched to the second position. According to claim 1,
The detachment prevention member is configured to a blocking position for preventing the transition of the side guide from the first position to the second position, and a releasing position for allowing the transition of the side guide from the first position to the second position. Removable paper feed unit. According to claim 2,
An actuator for driving the side guide; includes,
The separation prevention member is driven by the actuator. According to claim 2,
An elastic member for applying an elastic force in a direction positioned at the first position to the side guide; includes,
The actuator includes a solenoid connected to the side guide and the separation prevention member to move the side guide and the solenoid to the second position and the release position, respectively. According to claim 2,
The side guide is rotated to the first position and the second position,
The separation preventing member is linearly moved to the locking position and the unlocking position. According to claim 5,
The side guide has an interference portion capable of interfering with the separation preventing member located in the locking position,
A linear movement path of the separation preventing member is orthogonal to a direction of force applied to the separation preventing member by the interference portion. According to claim 2,
The side guide is rotated to the first position and the second position,
The separation preventing member is rotationally moved to the locking position and the unlocking position. According to claim 2,
and a slip prevention structure supporting the separation preventing member positioned at the locking position so as not to be pushed by the side guide. According to claim 8,
The anti-skimming structure,
an insertion protrusion provided on the separation preventing member;
A guide slot in which the insertion protrusion is inserted and extends in a direction crossing a direction in which the side guide is switched from the first position to the second position and guides the separation preventing member to the locking position and the release position. Including paper feeder. According to claim 2,
The actuator includes a rotary motor,
The separation prevention member includes a pinion, a worm gear rotated by the rotation motor, and a pinion meshed with the worm gear,
The side guide has a paper feed device having a partial gear connected to the pinion. a first stacking unit and a second stacking unit arranged in the paper feeding direction;
a side guide rotatable between a first position blocking the front end of the paper loaded in the second loading unit and a second position escaping from the front end of the paper;
an elastic member for applying an elastic force to the side guide in a direction positioned at the first position;
a solenoid for rotating the side guide to the second position;
a separation prevention member movable to a blocking position preventing the side guide from switching from the first position to the second position and a releasing position allowing the side guide to switch from the first position to the second position; Paper feed device comprising a. According to claim 11,
The separation preventing member is connected to the solenoid to move from the blocking position to the release position, and is returned to the locking position by the elastic force of the elastic member. According to claim 11,
The side guide includes an interference portion opposed to the separation preventing member located in the locking position at a distance from the first position,
The gap is set so that the separation preventing member is moved to the release position before the interference portion comes into contact with the separation preventing member when the side guide is switched from the first position to the second position by the solenoid. . According to claim 11,
and a slip prevention structure supporting the separation preventing member positioned at the locking position so as not to be pushed by the side guide. a first stacking unit and a second stacking unit arranged in the paper feeding direction;
a side guide rotatable between a first position blocking the front end of the printing medium loaded in the second loading unit and a second position escaping from the front end of the printing medium, and having a partial gear unit;
a pinion connected to the partial gear;
a worm gear engaged with the pinion;
Paper feeding device comprising a; rotation motor for rotating the worm gear.

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