JP2011105405A - Stack device and image forming device having the same - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a stack device which stores only the recording media that must be unloaded to a post-processing device and does not feed unnecessary media to the post-processing device, and also provide an image recording device having the stack device. <P>SOLUTION: This stack device includes a loading part 3 for loading recording media, a storage part 2 for storing a plurality of sheets of recording media desired to store among the recording media loaded from the loading part 3, an unloading part 4 for unloading the plurality of sheets of recording media stored in the storage part 2, a disposal part 5 for discharging the undesired recording media not desired to store among the recording media loaded from the loading part 4, a sheet abutting part 27 for sorting the recording media into the storage part 2 and the disposal part 5, and a control unit which controls the sheet abutting part 27 according to external signals including signals indicating whether the recording media are desired or not to be stored in the storage part 2 or feed the recording media to the discard part 5. The image recording device having the stack device is also provided. <P>COPYRIGHT: (C)2011,JPO&INPIT

Description

  The present invention relates to a stack apparatus that stores recording media on which images are formed, stacks the stored recording media, and delivers them to a post-processing apparatus, and an image forming apparatus equipped with the stack apparatus.

  A plurality of image-formed recording media are accommodated, and delivered to a post-processing device that performs post-processing (for example, shift processing, punching processing, binding processing, folding processing, gluing processing, etc.) in a state where these recording media are overlapped. Stack devices are known.

  Such a stack apparatus is disclosed in Patent Document 1, for example. The stack device (paper aligning device) stores a plurality of recording media conveyed from the image forming apparatus in a standing state in a paper storage unit, aligns the stored recording media, and then stores these recording media with a carry-out roller. It is sandwiched and delivered to the post-processing device.

JP 2007-137536 A

  In the stack apparatus described in Patent Document 1 described above, since there is no mechanism for identifying or separating a recording medium (unnecessary medium) that does not need to be transported to the post-processing apparatus, the unnecessary medium is carried into the stack apparatus. Even in such a case, the unnecessary medium is surely carried out to the post-processing apparatus. Therefore, it is necessary to perform an operation of removing unnecessary media from those processed by the post-processing device, which requires time and effort, and delays in processing due to the work time.

  SUMMARY OF THE INVENTION An object of the present invention is to provide a stack apparatus that stores only necessary recording media to be carried out to the post-processing apparatus and does not send unnecessary media to the post-processing apparatus, and an image recording apparatus equipped with the stack apparatus. And

  Embodiments according to the present invention include a carry-in unit that carries a plurality of recording media, a storage unit that stores a desired recording medium among the plurality of recording media carried from the carry-in unit, and a storage unit that stores the storage medium. An unloading unit for unloading the recording medium; a discarding unit for discharging an undesired recording medium among the plurality of recording media loaded from the loading unit; and a storage unit and the discarding unit for loading the recording medium And a control unit that controls whether the plurality of recording media are stored in the storage unit or sent to the disposal unit. And a control unit.

  An embodiment according to the present invention includes a feeding unit that supplies a continuous continuous recording medium, an image forming unit that forms an image on the continuous recording medium, and a continuous recording medium recorded by the image forming unit. A cutter unit that cuts the recording medium into a recording medium of a predetermined size, a medium transport unit that transports the continuous recording medium from the feeding unit to the cutter unit, and the recording medium that is disposed below the cutter unit and cut A stacking device that delivers the image to a downstream device, and a control device that controls at least the feeding unit, the image forming unit, the cutter unit, the medium conveying unit, and the stacking device. An image forming apparatus characterized by the above.

  According to the present invention, it is possible to provide a stack device that stores only necessary recording media to be carried out to the post-processing device and does not send unnecessary media to the post-processing device, and an image recording device equipped with the stack device. .

FIG. 1A is a front view of a stack device according to the first embodiment of the present invention. FIG. 1B is a top view of the stacking device along the dotted line BB in FIG. 1A. 1C is a side view of the stacking device taken along the dotted line CC in FIG. 1A. 1D is a side view of the stacking device along the dotted line DD in FIG. 1A. FIG. 1E is a side view of the stacking device along the dotted line EE of FIG. 1A. FIG. 2 is a diagram illustrating a state in which the lifting platform is raised and the stacked recording media are pushed up to the recording medium unloading unit. FIG. 3A is a diagram illustrating a state when the stack device is activated or stopped. FIG. 3B shows a state in which the unnecessary medium is discarded in the stacking apparatus, and the movement of the sheet abutting portion to the first position is started at the timing when the leading edge of the last unnecessary medium is nipped by the discharge roller pair. FIG. FIG. 3C is a diagram showing a state in which the sheet abutting portion is located at the first position, which is an unnecessary medium discarding process in the stacking apparatus. FIG. 3D is a diagram illustrating a state in which unnecessary media is discarded in the stacking apparatus, and the unnecessary media is discharged to a disposal tray. FIG. 4A is a side view showing a state in which the stack apparatus accommodates one recording medium and further one recording medium is conveyed. FIG. 4B is a top view showing a state in which the stack apparatus accommodates one recording medium. FIG. 5A is a side view showing a state in which the stack apparatus accommodates two recording media and one recording medium is being conveyed. FIG. 5B is a top view illustrating a state in which the stack apparatus stores two recording media. FIG. 6 is a diagram illustrating a state where the impeller rotates and presses the storage medium. FIG. 7A is a top view showing a state in which the stack apparatus carries out two recording media and discharges one recording medium. FIG. 7B is a side view showing a state where the stack apparatus carries out two recording media, ejects one recording medium, and further conveys one recording medium. FIG. 8 is a flowchart showing stack processing by the stack device. FIG. 9 is a flowchart showing a discard process of unnecessary media in the stack process. FIG. 10 is a diagram showing a configuration example in which the stack apparatus of the present invention is mounted on an image forming apparatus that forms an image on a continuous recording medium. FIG. 11 is a side view of a stack device according to a modification of the first embodiment of the present invention. FIG. 12 is a schematic view of a stack device according to the second embodiment of the present invention. FIG. 13 is a diagram illustrating a switching operation of the switching gate when the first sheet is an unnecessary medium and the second sheet is a storage medium. FIG. 14 is a diagram illustrating a switching operation of the switching gate when the first sheet is a storage medium and the second sheet is an unnecessary medium.

Hereinafter, embodiments of the present invention will be described with reference to the drawings.
First, the configuration of the stack device according to the first embodiment of the present invention will be described with reference to FIGS. 1A to 1E.
The stack apparatus 1 that performs stack processing is configured to hold a sheet-like recording medium sequentially discharged from a discharge port of an upstream image forming apparatus or the like in a direction (Y direction) orthogonal to the transport direction (Z direction) so as to be stretched. It is stored in a stacked state in a state where it is bent and bent. When the number of stored recording media reaches a preset number, the recording media that have been aligned are delivered to the carry-in port of the downstream post-processing device while the new recording medium is still accepted. For example, when a rectangular recording medium including a long side and a short side is transported along the long side direction, the short side that is orthogonal to the transport direction is set in the Z direction. When viewed from above, both ends are curved to the extent that they are round or have no corners (see FIG. 4B described later).

  The image forming apparatus is a printer such as an ink jet printer, a copier, or the like. Further, the recording medium may be carried into the stack apparatus directly from the image forming apparatus or from a sorter mechanism attached to the image forming apparatus. The post-processing device is a device that performs, for example, shift processing, punching processing, binding processing, folding processing, and gluing processing.

  As shown in FIG. 1A and FIG. 1C, the stack apparatus 1 is roughly divided into an apparatus main body unit 2 as a storage unit, a recording medium carry-in unit 3, a recording medium carry-out unit 4, and a recording medium disposal as a discard unit. It is comprised by the part 5 and the control part 6 which controls these.

  The recording medium carry-in unit 3 includes an entrance guide 7, a medium detection unit 8, and an entrance roller pair 9. The entrance guide 7 guides the loading of the recording medium 10. The medium detection unit 8 detects the recording medium 10 that passes through the entrance guide 7. Further, the entrance roller pair 9 carries the recording medium 10 into the apparatus main body 2.

  As shown in FIG. 1C, an opening is provided in the intermediate portion of the entrance guide 7, and the light emitting portion and the light receiving portion of the medium detecting portion 8 are arranged so as to face each other with the opening interposed therebetween. When the recording medium 10 passes through the medium detection unit 8, the recording medium 10 blocks the light from the light emitting unit, thereby detecting the front end portion to the rear end portion of the recording medium 10.

  The rotational speed of the inlet roller pair 9 is set so that the interval is longer at the time of taking than the interval of the recording medium 10 when it is being conveyed. That is, the speed of the recording medium taken in by the entrance roller pair 9 is set to be higher than the speed of the recording medium carried into the entrance roller pair 9.

  The recording medium carry-out unit 4 includes a pickup roller pair 11, a carry-out guide 12, and a carry-out roller pair 13. The pick-up roller pair 11 nips and removes a desired recording medium, that is, a necessary recording medium (storage medium) 10, which is stacked and stored in the apparatus main body 2. The carry-out guide 12 and the carry-out roller pair 13 are a guide and roller pair for carrying the recording medium to the downstream post-processing device. The pickup roller pair 11 and the carry-out roller pair 13 appropriately include a one-way clutch.

  The recording medium discarding unit 5 includes a discharge roller pair 14, a discard guide 15, and a discard roller pair 16. The discharge roller pair 14 pulls out an unnecessary recording medium (unnecessary medium) that is unnecessary from the apparatus main body 2. The discard guide 15 and the discard roller pair 16 are a guide and roller pair for discharging the recording medium 10 to the discard tray 17 (see FIG. 3D).

  The apparatus main body 2 temporarily stores the recording medium to be transferred to the post-processing apparatus, and transports the recording medium to the recording medium unloading section 4 in a stacked state (stacked state), while discharging unnecessary media to the recording medium discarding section 5. To do. In the description herein, a recording medium on which desired image information is recorded is referred to as a necessary recording medium or a desired recording medium. Further, a recording medium in which image information is not recorded at a leading end portion or a trailing end portion of a recording medium such as roll paper, or a recording medium in which a recording error has occurred is referred to as an unnecessary medium or an undesired recording medium.

  The apparatus main body 2 is broadly divided into a base material 18, carry-in guides 19 and 20, a stiffness guide 21 for giving tension (waist) to the recording medium, impellers 22 and 23, a fan 24, and a paddle. The rollers 25, 26, the sheet abutting part 27, and the elevating part 28 are configured.

As shown in FIG. 1A, the base material portion 18 has a rectangular shape made of a hard material such as a metal, and as shown in FIG. Thin convex shape. Impellers 22 and 23 extending in the Z direction are arranged at positions facing the XZ planes at both ends of the convex shape. In addition, the base material part 18 makes the surface side in which the impellers 22 and 23 are arrange | positioned the surface, and makes the surface (non-arrangement surface) side in which the impellers 22 and 23 are not arranged a back surface. Further, a back plate (not shown) is provided at a position facing the base material portion 18 with the impellers 22 and 23 interposed therebetween. The back plate is provided so as to be openable and closable so that the recording medium 10 can be taken out when a jam occurs. As shown in FIG. 1C and FIG. 1D, a storage space 29 for storing the recording medium 10 is formed by the base material portion 18, the impellers 22 and 23, and the back plate.
The back plate is provided with carry-in guides 19 and 20, a stiffness guide 21, a fan 24, and paddle rollers 25 and 26.

  The carry-in guides 19 and 20 are arranged below the inlet roller pair 9 with respect to the Z direction as shown in FIG. 1A and between the impellers 22 and 23 with respect to the X direction as shown in FIG. 1B. Has been. Here, as shown in FIG. 1E, the carry-in guide 19 is adjusted in angle so that the leading end of the loaded recording medium 10 enters between the blades that are partition members of the impeller 22. . The same applies to the carry-in guide 20.

  The carry-in guides 19 and 20 are carried in after the upper end (rear end in the transport direction) of the recording medium 10 previously stored in the storage space 29 when the recording medium 10 is continuously stored. It is provided so as not to collide with the front end (front end in the transport direction) of the recording medium 10. These carry-in guides 19 and 20 are formed with a curved surface (collision surface) by using a metal or a hard resin with good slipperiness of the recording medium 10. When the leading end of the recording medium 10 collides with the carry-in guides 19 and 20, the recording medium 10 may be supported by an elastic member such as a spring from the back surface (non-collision surface) so as to buffer the bounce of the leading end. .

  As shown in FIG. 1D, the stiffness guide 21 has a shape in which the lower end (discharge side) is widened in the Y direction with respect to the upper end (loading side). With this shape, the stiffness guide 21 bends at least both ends of the recording medium 10 toward the back plate. In other words, the stiffness guide 21 bends the leading end of the recording medium 10 so that the normal of the surface of the sheet abutting portion 27 on which the recording medium 10 abuts is the center of curvature. In this way, the recording medium 10 is curved and deformed into a standing shape, so that the recording medium 10 is stretched and is not easily bent in the Z direction. When the recording medium 10 is carried in, the recording medium 10 is accommodated in this state with the leading end in contact with the sheet abutting portion 27.

  The impellers 22 and 23 as the medium moving parts are configured such that a plurality of blades as partition members are evenly attached to a cylindrical shaft extending in the Z direction, and a plurality of spaces are provided between the blades. Each is formed. These blades are formed using a flexible member, for example, metal, resin, or hard rubber. Thereby, when the impellers 22 and 23 rotate, even if the tip portion of the blade comes into contact with the surface of the base material portion 18, the blade can pass in a slightly flexible state. And a blade | wing returns to the original shape, after passing. In the present embodiment, an impeller having six blades is shown as an example, but the number of blades is not limited to six.

  As shown in FIG. 1B and FIG. 1C, the fan 24 as a blower is provided in the vicinity of the carry-in guides 19 and 20. These fans 24 blow air to the stored recording medium 10 in the Y direction to press the recording medium 10 toward the base member 18 side. That is, the fan 24 forms a gap between the stored recording medium 10 and the carry-in guides 19 and 20, and the recording medium in which the leading end of the recording medium 10 carried from the carry-in guides 19 and 20 is already stored. It plays an auxiliary role so as not to come into contact with the rear end of 10. Therefore, the fan 24 may be provided as necessary.

  Paddle rollers 25 and 26 serving as a conveyance assist mechanism are provided on both sides of the stiffness guide 21. The paddle rollers 25 and 26 have soft blade portions, and are formed of, for example, rubber or resin. When the recording medium 10 is stored, the paddle rollers 25 and 26 are not subjected to the conveying force of the inlet roller pair 9 (that is, the rear end of the recording medium 10 is moved into the apparatus main body 2 from the inlet roller pair 9. This is an auxiliary transport mechanism that transports the recording medium 10 to the downstream side when transported). The paddle rollers 25 and 26 rotate at the same rotational speed as the entrance roller pair 9.

  The sheet abutting portion 27 has a plate shape extending in the Y direction, and is disposed below the stiffness guide 21 with respect to the Z direction. The sheet abutting portion 27 aligns the recording medium 10 by bringing the tip of the recording medium 10 sent to the sheet abutting portion 27 by the paddle rollers 25 and 26 into contact with the plate surface of the sheet abutting portion 27. . At this time, as described above, the recording medium 10 is in a state of being bent due to the bending guide 21.

  The sheet abutting portion 27 is located between a position closest to the base material portion 18 (first position) and a position further away from the base material portion 18 than the first position (second position). It can move in the Y direction. The first position is a contact position that contacts the recording medium 10, and the recording medium 10 that is carried in with the sheet abutting portion 27 being in the first position contacts the sheet abutting portion 27 and is stored. It is stored in the space 29. Note that a position where the recording medium 10 abuts against and contacts the sheet abutting portion 31 is defined as a storage position. The second position is a non-contact position that does not contact the recording medium 10, and the recording medium 10 carried in with the sheet abutting portion 27 being in the second position contacts the sheet abutting portion 27. Without being guided to the discharge roller pair 14.

  The sheet abutting portion 27 may have an elastic force in a direction toward the first position. This elastic force acts to such an extent that when the sheet abutting portion 27 comes into contact with an unnecessary recording medium to be discharged (hereinafter referred to as an unnecessary medium), the sheet abutting portion 27 is pushed back so as not to disturb the discharging operation of the unnecessary medium. In addition, the shape of the sheet abutting portion 27 may be a convex shape in which a portion where an elevator platform 31, 32 described later is disposed is recessed.

Next, the structure of the raising / lowering part 28 is demonstrated.
The elevating unit 28 includes elevating platforms 31, 32, fixed support members 33 (33a, 33b), 34 (34a, 34b), two guide shafts 35 (35a, 35b), support members 36, 37, And a connecting member 38.

  The fixed support members 33 and 34 fix the guide shafts 35 a and 35 b to the back surface of the base material portion 18 (non-arrangement surfaces of the impellers 22 and 23). These guide shafts 35 a and 35 b are extended in the Z direction on the back surface side of the base material portion 18. The elevators 31 and 32 are attached to the guide shafts 35a and 35b via the connecting member 38 and the support members 36 and 37, respectively. The support members 36 and 37 support the lifting platforms 31 and 32 so as to be movable along the guide shafts 35a and 35b, respectively. In addition, the base material portion 18 is provided with a notch 39 for raising and lowering the lifting platforms 31 and 32.

  The elevators 31 and 32 are movable in the Z direction between the lowered position shown in FIG. 1C and the raised position shown in FIG. For raising and lowering between the lowered and raised positions of the elevators 31 and 32, a driving mechanism using a ball screw, a cylinder mechanism using oil or air, a driving mechanism using a pulley and a wire, or a magnet (such as a linear motor) is used. A known drive mechanism such as a drive mechanism is appropriately employed.

  When the elevators 31 and 32 are in the lowered position, the elevators 31 and 32 are set lower than the sheet abutting portion 27 in the Z direction, and the lower surface of the sheet abutting portion 27 and the elevator 31 , 32 is formed with a gap 30 through which the recording medium can pass. Further, the positions of the lifting platforms 31 and 32 are also positions that do not interfere with the sheet abutting portion 27 when the lifting platforms 31 and 32 are pushed up.

  For example, the control unit 6 determines whether the recording medium carried into the stack apparatus 1 is a desired recording medium or an undesired recording medium, that is, information notified by an external signal including an instruction on whether or not the recording medium is desired. Is remembered. The control unit 6 also includes a roller drive unit 40, a butting drive unit 41, and a lift platform drive based on information related to the passage of the recording medium 10 detected by the medium detection unit 8 and information notified by the external signal. Signals are sent to the unit 42 to drive the paddle rollers 25 and 26, the sheet abutting unit 27, and the lifting platforms 31 and 32, respectively. The sheet abutting unit 27 and the abutting driving unit 41 constitute a sorting unit that sorts the loading destination of the recording medium 10 into a storage unit and a discarding unit.

  Next, stack processing by the stack apparatus 1 will be described with reference to the flowchart shown in FIG.

  First, the stack apparatus 1 is activated and initialized by turning on the main power (step S1). At this time, the image forming apparatus and the post-processing apparatus are also activated. Instead of starting each device individually, the stack device and the post-processing device may be started when the image forming apparatus is started. In the initialization, it is confirmed whether or not the sheet abutting portion 27 is located at the second position and whether the lifting platforms 31 and 32 are located at the lowered position. When each is not located in the discharge position and the lowered position, it is moved to the second position and the lowered position. And the drive of each component is started.

  Next, an unnecessary medium is discarded (step S2). For example, as will be described later, in the case of a stack apparatus that forms an image on a continuous recording medium such as roll paper and stacks cut sheets obtained by cutting the continuous recording medium, the path from the recording unit to the cutter unit of the image forming apparatus Therefore, an unnecessary medium is always generated at the start of image formation. For this reason, it is effective to perform the disposal process at this stage. This discarding process will be described with reference to the flowchart shown in FIG. 9 and FIGS. 3A to 3D.

  FIG. 3A shows a state when the stack device 1 is started or stopped. At this time, the sheet abutting portion 27 is disposed at a second position farther from the base material portion 18 than the first position. In this state, it is confirmed whether or not an unnecessary recording medium that is unnecessary (hereinafter, referred to as an unnecessary medium 10a) is sent to the stack apparatus 1 (step S11). This confirmation can be recognized by notification from the control unit of the image forming apparatus to the control unit 6 of the stack apparatus 1 from the apparatus connected to the stack apparatus 1. That is, the control unit of the image forming apparatus notifies information such as whether or not there is an unnecessary medium 10a, and if so, how many unnecessary media 10a are sent to the stack apparatus 1.

  If it is determined in step S11 that there is an unnecessary medium 10a (YES), it is monitored whether or not all of the unnecessary medium 10a has passed through the medium detection unit 8 (step S12). The medium detection unit 8 detects the leading end and the trailing end of the unnecessary medium 10a and counts the number of unnecessary media that have passed. When all unnecessary media 10a have not passed through in step S12 (NO), monitoring is continued until the passing is completed.

  On the other hand, if it is determined in step S11 that there is no unnecessary medium 10a (NO), and if the medium detection unit 8 detects the front end and / or the rear end in the transport direction of the last unnecessary medium 10a in step S12 (YES). After a predetermined time has passed, the sheet abutting portion 27 is moved to the first position closest to the base material portion 18 (step S13). Specifically, as shown in FIG. 3B, at the timing when the leading end in the transport direction of the last unnecessary medium 10a is nipped by the discharge roller pair 14, the butting drive unit 41 moves the sheet butting portion 27 in the Y direction. Move. Then, as shown in FIG. 3C, the sheet abutting portion 27 is stopped at the first position.

  Here, during the movement of the sheet abutting portion 27 to the first position, the leading end abuts against the unnecessary medium 10a. However, since the sheet abutting portion 27 and the lifting platforms 31 and 32 are provided with a gap 30 in the vertical direction at the overlapping portion as described above, the unnecessary medium 10a remains as it is due to the conveying force of the discharge roller pair 14. It is conveyed and passes through the gap 30. Then, as shown in FIG. 3D, the unnecessary medium 10 a is discharged to the disposal tray 17 through the disposal guide 15 and the disposal roller pair 16.

Thus, before the last unnecessary medium 10a is accommodated in the waste tray 17, the sheet abutting portion 27 starts to move to the first position. Thereby, for example, as shown in FIG. 3B, even if a recording medium to be stored immediately after the last unnecessary medium 10a (hereinafter, the recording medium to be stored is referred to as a storage medium 10b) has been conveyed. The leading end of the storage medium 10 b can be brought into contact with the sheet abutting portion 27 and stored in the storage space 29.
Thus, the discarding process is terminated and the process returns (step S14).

  Next, the storage medium 10b carried in for the stacking process is sequentially abutted against the sheet abutting portion 27 and stored in the storage space 29 (step S3). Then, the medium detection unit 8 determines whether or not the set number of storage media has been stored (step S4). The number of storage media 10b stored in the stack apparatus 1 is included in the information notified from the control unit of the image forming apparatus to the control unit 6 of the stack apparatus 1 at the time of the discarding process. In this embodiment, two storage media 10b (10b1, 10b2) are stored.

  The first storage medium 10b1 carried in from the inlet guide 7 reaches the inlet roller pair 9 after passing through the medium detector 8. The medium detection unit 8 detects the front end and the rear end of the storage medium 10b1 and counts the number of storage media that have passed. The storage medium 10b1 is carried between the blades of the impellers 22 and 23 through the carry-in guides 19 and 20 by the rotation of the inlet roller pair 9. At this time, the rear end of the storage medium 10b1 is detached from the inlet roller pair 9, but the storage medium 10b1 is pulled down by the paddle rollers 25 and 26 and is brought into contact with the sheet abutting portion 27 and stored. At that time, the storage medium 10 b 1 is conveyed while being guided by the stiffness guide 21.

  The storage state of the storage medium 10b1 is shown in FIGS. 4A and 4B. As shown in FIG. 4B, the storage medium 10b1 is curved by the stiffness guide 21 and has a waist. Specifically, the stiffness guide 21 bends the tip of the storage medium 10b1 so that the normal of the surface of the sheet abutting portion 27 on which the storage medium 10b1 abuts is the center of curvature. As a result, as shown in FIG. 4A, the storage medium 10 b 1 takes a form in which the storage medium 10 b 1 rises straight and is not easily bent in the Z direction.

  Further, since air is blown to the storage medium 10b1 by the fan 24, a gap is generated between the rear end of the storage medium 10b1 and the carry-in guides 19 and 20. In this state, the subsequent second storage medium 10 b 2 is carried between the blades of the impellers 22 and 23 via the carry-in guides 19 and 20. At this time, the leading edge of the storage medium 10b2 contacts the surface portion of the storage medium 10b1, so that no jamming occurs. Then, as shown in FIG. 5B, a set number of storage media are stored.

  In step S4, if the number of storage reaches the set number as described above (YES), the impellers 22 and 23 are rotated with the storage media 10b1 and 10b2 being aligned. Then, both side ends of the storage media 10b1 and 10b2 are moved from the sheet abutting portion 27 to the lifting platforms 31 and 32 (step S5). On the other hand, if the storage number does not reach the set number (NO), the storage medium is continuously stored.

  In step S5, the timing of rotating the impellers 22 and 23 is after a predetermined time has elapsed since the medium detection unit 8 detected the rear end of the storage medium 10b2. That is, the impellers 22 and 23 rotate at the timing when the storage media 10b1 and 10b2 are placed on the sheet abutting portion 27. FIG. 6 shows a state where the impellers 22 and 23 are rotating.

  The impellers 22 and 23 shown in FIG. 6 are rotated from the state shown in FIG. 5B by an integral multiple of the same angle as the pitch of the blades. In this embodiment, the angle for two blades is rotated in the direction of the arrow in each. By this rotation, both side ends of the storage media 10b1 and 10b2 are pressed against the base material portion 18 side. That is, by rotating the impellers 22 and 23, at least a part of both side ends of the storage media 10b1 and 10b2 is moved from the storage position in contact with the sheet abutting portion 27 to the pushed-up position in which the contact is released. . Thereby, at least a part of the both side ends of the storage media 10b1 and 10b2 moves to the lifting platforms 31 and 32 side. At this time, the elevators 31 and 32 are disposed at a position lower than the sheet abutting portion 27 as described above. For this reason, the both side ends of the storage media 10b1 and 10b2 can be smoothly moved to the lifting platforms 31 and 32 side. As described above, the rotation of the impellers 22 and 23 causes both ends of the storage media 10 b 1 and 10 b 2 to bend in a direction opposite to the state of being bent by the stiffness guide 21.

  Then, it is determined whether there are storage media 10c1 and 10c2 to be stored next (step S6). Information indicating whether there is a storage medium to be stored next is also included in the information notified from the control unit of the image forming apparatus to the control unit 6 of the stack apparatus 1.

  In step S6, when there are storage media 10c1 and 10c2 to be stored next (YES), as shown in FIG. 7A, the storage medium 10c1 is transported immediately after the storage medium 10b2, and the process proceeds to step S7. At this time, as shown in FIG. 6, the impellers 22 and 23 are rotated to form a new space in which the storage medium 10c1 is stored. That is, as shown in FIG. 7A, the storage medium 10c1 is stored between the blades different from the blades of the impellers 22 and 23 in which the storage media 10b1 and 10b2 are stored.

  At the same time that the storage medium 10c1 is stored, the elevating platforms 31 and 32 are raised along the guide shafts 35a and 35b (step S7), and the storage media 10b1 and 10b2 in an aligned state are pushed up. At this time, since the tip of the newly stored storage medium 10c1 is not in contact with the lifting platforms 31, 32, only the storage medium 10b1, 10b2 can be pushed up as shown in FIG. 7B. Then, after step S7, the process returns to step S3 to store the set number of storage media again.

  In this manner, by rotating the impellers 22 and 23, the operation of carrying out the storage media 10b1 and 10b2 to the recording medium carrying-out unit 4 and the operation of carrying in the storage media 10c1 and 10c2 into the main body unit 2 are simultaneously performed. And high-speed processing is possible. The lifting platforms 31 and 32 are returned to the lowered position by the lifting platform driving unit 42 before the storage medium 10b1 and 10b2 are unloaded and before the next storage medium 10c1 and 10c2 is unloaded.

  If there is no storage medium to be stored next in step S6 (NO), the process proceeds to step S8. The operation of raising the elevators 31 and 32 in step S7 and step S8 and pushing up the aligned recording medium to the recording medium unloading section 4 will be described.

  FIG. 2 is a diagram showing a state in which the elevators 31 and 32 are pushed up in order to deliver the stacked recording media 10 b 1 and 10 b 2 to the recording medium carry-out unit 4. The elevators 31 and 32 are simultaneously raised by the elevator driver 42 along the guide shafts 35a and 35b to reach the raised position. Then, the pushed-up recording media 10b1 and 10b2 come into contact with the rotating pickup roller. These recording media 10 b 1 and 10 b 2 are nipped by the pickup roller pair, taken out by the carry-out guide 15, and conveyed to the carry-out roller pair 16. As described above, the recording media 10 b 1 and 10 b 2 are pushed up by the elevators 31 and 32 in a state where they are aligned and delivered to the recording medium unloading unit 4.

After step S8, the series of sequences ends.
As described above, the stack device according to the present invention has a tension applied by abutting the leading end curved by the stiffness guide 21 to the sheet abutting portion 27 when the recording medium is accommodated in the accommodating space 29. By storing in a standing state, the recording medium can be prevented from wobbling (bending or twisting) due to abutting against a recording medium that is weak, and a jam error can be prevented.

  In addition, by holding the recording medium parallel to the direction of gravity, the installation area of the stack device can be reduced, and even if the stack device is mounted on an image forming device or sorter device, the device area increases. Can be reduced.

  In addition to a path for transferring the recording medium to the downstream post-processing apparatus, that is, a stacking apparatus 1 in addition to a carry-out path for transporting the recording medium from the apparatus main body 2 as a storage section to the recording medium carry-out section 4, 2 has a discard path for conveying the recording medium from the recording medium discarding section 5 to the recording medium discarding section 5. When this stack device is installed in a printer or a copier, unnecessary media can be further divided into stacks for trial printing and the like and output to the waste tray 17. Therefore, unnecessary media are not stored, delivery to the downstream post-processing apparatus can be prevented, and manual removal work can be eliminated.

  In addition, the stack apparatus of the present invention has a control unit 6. The control unit 6 stores information such as whether there is an unnecessary medium, how many unnecessary media are present, and how many recording media are unnecessary media. Then, the medium detection unit 8 counts the number of recording media that have passed through the recording medium carry-in unit 3, and based on the counted information, the control unit 6 performs the paddle roller driving unit 40, the butting driving unit 41, and the lifting / lowering unit. A signal is sent to the table drive unit 42 to drive the paddle rollers 25 and 26, the butting drive unit 27, and the lift tables 30 and 31, respectively. That is, the control unit 6 controls whether the recording medium is stored in the apparatus main body unit 2 that is a storage unit or sent to the recording medium discarding unit 5. Accordingly, switching between the carry-out route and the discard route can be selected by moving the sheet abutting portion 27 provided at the bottom of the storage space 29 in parallel with the installation surface like a shutter. In addition, the recording medium once stored in the storage space 29 is removed by retracting the sheet abutting portion 27, rotating the paddle rollers 25, 26, and niping them to the discharge roller pair 14. It can be reliably discharged to the disposal route side.

  The sheet abutting portion 27 and the elevators 31 and 32 that push up the recording medium are arranged with a step and a gap as described above. The timing of the movement of the sheet abutting portion 27 from the second position to the first position is started when the final unnecessary medium is nipped by the discharge roller pair 14. Therefore, the sheet abutting portion 27 abuts against the unnecessary medium, but since the gap is formed, the unnecessary medium is discharged by the discharge roller pair 14. At the same time, since the sheet abutting portion 27 is positioned at the first position while the unnecessary medium is being discharged, the unnecessary medium and the recording medium to be stacked are stacked even if they are brought in close proximity. The recording medium can be securely stored.

  In addition, by simply rotating the impellers 22 and 23 that hold both side edges of the recording medium that are aligned in the set number, the both side edges of the recording medium are moved from the storage position on the sheet abutting portion 27 to the lifting platforms 31 and 32. The recording medium can be moved up to the push-up position, and the recording medium is pushed up while being guided by the blades, and can be conveyed to the carry-out roller without being disturbed.

  FIG. 10 is a diagram showing a configuration example in which the stack apparatus of the present invention is mounted on an image forming apparatus that forms an image on a continuous recording medium. Note that the configuration and reference numerals of the stack apparatus 1 in FIG. 10 are not described here with reference to FIGS. 1A to 1E.

  The stack apparatus 1 is disposed below the cutter unit 190 in the image forming apparatus 100. The recording medium cut into a predetermined size by the cutter unit 190 is carried into the stack apparatus 1, and the stack apparatus 1 delivers the aligned recording medium to the post-processing apparatus.

The image forming apparatus 100 will be described below.
The image forming apparatus 100 includes an unwinder unit 101 and a printer unit 102.

First, the unwinder unit 101 will be described.
The unwinder unit 101 includes, for example, a paper tube fixing shaft 104 on which a continuous recording medium 103 that is a wound roll paper is mounted, a stand 105, and a brake 106. The unwinder unit 101 is a recording medium supply unit that holds the continuous recording medium 103 rotatably by the paper tube fixing shaft 104 and supplies the continuous recording medium 103 to the printer unit 102.

  The stand 105 supports the paper tube fixing shaft 104 in a rotatable manner. In the paper tube fixing shaft 104, a plurality of claw portions that chuck the inner diameter of the paper tube protrude in the radial direction by injecting air from an air inlet (not shown). As a result, the claw portion of the paper tube fixing shaft 104 bites into the inner diameter of the paper tube of the continuous recording medium 103 and firmly holds the continuous recording medium 103.

  A brake 106 is connected to the paper tube fixing shaft 104 via a pulley and a belt. The braking force of the brake 106 is transmitted to the paper tube fixing shaft 104. As a result, the brake 106 has a function of applying tension in the direction opposite to the conveyance direction of the continuous recording medium 103.

Next, the printer unit 102 will be described.
The printer unit 102 includes a plurality of rollers 107 to 120, an introduction guide 121, a main body frame 122, a first drum 130 and a second drum 140, a conveying unit for the continuous recording medium 103, a first recording unit 150, and a second recording unit. The recording unit 160, the first cleaning unit 170, the second cleaning unit 180, the cutter unit 190, the stack device 1, the control device 200, and the waste tray 17.

  The printer unit 102 introduces a continuous recording medium 103 that is fed from the unwinder unit 101 in the direction indicated by the arrow A.

  The control device 200 includes at least an unwinder unit 101 that is a recording medium supply unit, a conveyance unit that conveys the continuous recording medium 103, a first recording unit 150 and a second recording unit 160 that are image forming units, and a cleaning unit. The operations of the first cleaning unit 170, the second cleaning unit 180, the cutter unit 190, and the stack apparatus 1 are controlled.

  The continuous recording medium 103 introduced into the printer unit 102 is transported to the first drum 130 via a transport system including free rollers 107 and 108, a swing roller 109, and free rollers 110 and 111.

  The swing roller 109 is attached to the tip of an arm 109b that is rotatably held on the main body frame 122 by a rotation center 109a so as to be rotatable in both forward and reverse directions. The swing roller 109 constitutes a tension generating unit that applies tension to the continuous recording medium 103 conveyed along the lower peripheral surface of the swing roller 109 by the own weight of the swing roller 109 and the arm 109b. .

  The tension generating unit also has a function of eliminating the slack when the continuous recording medium 103 is loosened due to a tension variation caused by eccentricity of the continuous recording medium 103 held by the unwinder unit 101. Yes.

  In addition, a potentiometer 109c that detects a rotation position when the swing roller 109 moves in the vertical direction is provided at the rotation center 109a. The brake 106 connected to the paper tube fixing shaft 104 of the unwinder unit 101 is operated by the output signal of the potentiometer 109c. Thereby, the tension of the continuous recording medium 103 is controlled. The free rollers 107, 108, 110, and 111 are rotatably supported by the main body frame 122, respectively.

  The continuous recording medium 103 conveyed to the first drum 130 via the conveyance system is wound around the first drum 130 by the free rollers 111 and 112 at a winding angle of about 330 degrees, for example. The first drum 130 is a hollow cylinder made of, for example, aluminum, and the rotation shaft 120 a is rotatably supported by the main body frame 122. Then, the continuous recording medium 103 held on the first drum 130 is transported directly below the first recording unit 150 disposed facing the first drum 130, and is continuously recorded by the first recording unit 150. Recording is performed on the surface of the medium 103.

  Note that, by ensuring a wide winding angle of the continuous recording medium 103 on the first drum 130, for example, about 330 degrees, there is no slip between the first drum 130 and the continuous recording medium 103, and the continuous recording medium. 103 can be held in close contact with the first drum 130. As a result, accurate paper conveyance and drum rotation speed control are possible.

  After the end of winding of the first drum 130, the continuous recording medium 103 on which an image is recorded on the surface by the first recording unit 150 passes through the conveying system of the free rollers 112 to 114 to the second drum 140. Be transported.

  Similarly to the first drum 130, the continuous recording medium 103 conveyed to the second drum 140 is also wound around the second drum 118 by a free winding roller 114 and 115 at a winding angle of 330 degrees. The second drum 140 is also a hollow cylinder made of aluminum, for example, and the rotation shaft 130a is rotatably supported by the main body frame 122. The free rollers 112 to 115 are also rotatably supported by the main body frame 122.

  As described above, the continuous recording medium 103 wound around the second drum 140 at a winding angle of about 330 degrees, for example, is caused by the tension at the start of winding and the tension at the end of winding of the second drum 140. A normal force is applied to the outer peripheral surface 140. As a result, the frictional force between the second drum 140 and the continuous recording medium 103 increases, so that there is no slip between the second drum 140 and the continuous recording medium 103, and the continuous recording medium 103 is the second recording medium 103. The drum 140 is held in close contact with the drum 140.

  The second drum 140 rotates in the counterclockwise direction in the figure by the driving force of the driving motor 141 connected to the rotating shaft 130a via a pulley and a belt. As described above, the second drum 140 functions as a driving drum, and the first drum 130 is a driven drum that is rotated clockwise by the second drum 140 via the continuous recording medium 103.

  Then, by the rotation of the second drum 140, the continuous recording medium 103 held on the second drum 140 is conveyed directly below the second recording unit 160 disposed facing the second drum 140. .

  In the continuous recording medium 103 wound and held around the second drum 140, the image recording surface recorded by the first recording unit 150 on the first drum 130 faces downward (the peripheral surface side of the second drum 140). The back side that has not yet been recorded is facing upward (the direction facing the second recording unit 160).

  The second recording unit 160 forms an image on the back surface of the continuous recording medium 103 that is wound and held around the second drum 140 and conveyed directly below the second recording unit 160. Thereby, double-sided recording on the continuous recording medium 103 is completed.

  In addition, an encoder in the position detection unit is connected to the rotation shaft 140 a of the second drum 140. The encoder rotates with the rotation of the second drum 140 and outputs a detection pulse corresponding to the rotation position of the second drum 140. Then, the detection pulse output from the encoder is input via a control device 200 to a driving substrate (not shown) that drives the recording heads of the first recording unit 150 and the second recording unit 160. In synchronization with this detection pulse, the recording head ejects ink by drive control from the drive substrate. That is, since the continuous recording medium 103 is conveyed at the same speed without slipping on the first drum 130 and the second drum 140, the continuous recording medium 103 is based on the detection pulse output with the rotation of the second drum 140. The ejection drive of the first recording unit 150 and the second recording unit 160 can be controlled.

  Next, the first recording unit 150 and the second recording unit 160 will be described. Since the configuration of the first recording unit 150 is the same as that of the second recording unit 160, the first recording unit 150 will be described as a representative.

  The first recording unit 150 of the present embodiment includes recording head units 151a, 151b, 151c, and 151d for a total of four colors of cyan (C), black (K), magenta (M), and yellow (Y). ing. In the present embodiment, the recording heads 151a to 151d are configured by a plurality of recording heads. A plurality of recording heads are fixed on the head holding plate 152 so as to be equal to or more than the recording area of the continuous recording medium 104. The nozzle surface formed on the recording head is disposed opposite to the image recording surface of the continuous recording medium 103 held on the outer peripheral surface of the first drum 130. The relative position between the head holding plate 152 and the first drum 130 is determined by a member (not shown).

  Next, the first cleaning unit 170 and the second cleaning unit 180 will be described. Since the configuration of the first cleaning unit 170 is the same as that of the second cleaning unit 180, the first cleaning unit 170 will be described as a representative. The first cleaning unit 170 is provided for cleaning the recording heads 151a, 151b, 151c, and 151d of the first recording unit 150, and has a function of performing a known cleaning operation such as wiping and nozzle suction. Have.

  When the first recording unit 150 is cleaned by the first cleaning unit 170, first, the head holding plate 152 is retracted in a direction away from the peripheral surface of the first drum 130 by a retracting mechanism (not shown). As a result, the recording heads 151a to 151d are also moved away from the circumferential surface of the first drum 130, and a predetermined gap is formed between the lower surface of the recording heads 151a to 151d and the circumferential surface of the first drum 130. It is formed.

  Thereafter, the first cleaning unit 170 is moved directly below the recording head portions 151a to 151d to clean the recording head portions 151a to 151d. After completion of the cleaning operation, the first cleaning unit 170 returns to the standby position shown in FIG. 10, and the first recording unit 150 returns to the image recording position.

  As described above, the continuous recording medium 103 which has been recorded on the front surface by the first recording unit 150 and recorded on the back surface by the second recording unit 160 to complete the double-sided recording is recorded from the winding end portion of the second drum 140. Then, it is transported by a transport system after the free roller 115.

  After the end of winding of the second drum 140, the continuous recording medium 103 is conveyed to the first nip roller pair 116. Note that the first nip roller pair 116 is rotatably supported by the main body frame 122.

  The first nip roller pair 116 includes a pair of rollers, and a torque limiter, a reduction gear, and a drive motor (not shown) are connected to one of the rollers, and continuous recording on the first drum 130 and the second drum 140 is performed. The continuous recording medium 103 is transported at the same speed as the transport speed of the medium 103. As a result, the first nip roller pair 116 constitutes a tension generating unit for applying tension to the continuous recording medium 103 in the same direction as the transport direction.

  After the first nip roller pair 116, the continuous recording medium 103 is conveyed to the second nip roller pair 120 via free rollers 117 to 119. The free rollers 117 to 119 and the second nip roller pair 120 are also rotatably supported by the main body frame 122.

  The second nip roller pair 120 includes a pair of rollers. Although not particularly shown, a torque limiter, a reduction gear, and a drive motor are connected to one of the rollers, and the first nip roller pair 116 conveys the continuous recording medium 103. The continuous recording medium 103 is transported toward the introduction guide 121 disposed immediately after at the same speed as the speed.

  The introduction guide 121 has a function of suppressing the fluctuation in the thickness direction of the continuous recording medium 103 in the conveyance path and introducing the continuous recording medium 103 into the cutter unit 190. The introduction guide 121 extends in the width direction of the continuous recording medium 103, covers the front and back of the continuous recording medium 103, and restricts the conveyance path. The introduction guide 121 is a component made of, for example, sheet metal or resin molding. Alternatively, it may be constituted by a pair of elongated rollers.

  The continuous recording medium 103 is introduced into the cutter unit 190 from the second nip roller pair 120 via the introduction guide 121. The conveyance path between the second nip roller pair 120 and the cutter unit 190 is configured to be as short as possible.

  The cutter unit 190 includes an anvil roller 191, a cutter roller 192 disposed to face the anvil roller 191, and a brush roller 193 provided downstream of the anvil roller 191 and the cutter roller 192 in the transport direction. Yes.

  The cutter roller 192 is provided with a cutter blade 192a. Here, two cutter blades 192a are provided on the outer peripheral surface of the cutter roller 192 at equal intervals. Then, the cutter roller 192 and the anvil roller 191 are continuously conveyed by the conveying speed of the continuous recording medium 103 on the first drum 130 and the second drum 140, and continuously by the first nip roller pair 116 and the second nip roller pair 120. The recording medium 103 is rotated at the same speed as the conveyance speed. Thereby, the continuous recording medium 103 can be continuously cut into a sheet-like recording medium 10 having a predetermined size.

  Rubber, sponge, and other friction members are formed on the outer peripheral surface of the brush roller 193. In the present embodiment, a large number of linear members extending in the radial direction of the roller are implanted as the friction member. The brush roller 193 prevents the leading end of the continuous recording medium 103 cut by the cutter roller 192 from being wound along the cut roller 192 or the anvil roller 191. Therefore, the linear velocity of the outermost roller circumference of the brush roller 193 is set faster than the linear velocity of the tip of the cutter blade 192a in the cutter roller 192. Accordingly, the continuous recording medium 103 can be transported without being slackened. The cutter unit 190 can be replaced. In addition, by changing the roller diameter and appropriately replacing the cutter unit that cuts to a desired size, recording media of a plurality of sizes can be output.

  The sheet-like recording medium 10 cut by the cutter unit 190 is carried into the stack apparatus 1. The stack device 1 is disposed vertically below the cutter unit 190, and as described above, the recording media 10 are stacked and delivered to the post-processing device. A detailed description of the configuration and operation of the stack apparatus 1 is omitted here. The image forming apparatus 100 stops conveying the continuous recording medium 103 when the continuous recording medium 103 on which the image is recorded by the image recording unit is delivered from the stack apparatus 1 to the post-processing apparatus.

  Here, in an image forming apparatus that forms an image using a continuous recording medium such as a rolled paper roll, when the previous image formation is completed, what is on the conveyance path from the image recording unit to the cutter unit? However, a continuous recording medium on which no image is formed remains. Therefore, when the next image formation is performed, the continuous recording medium remaining from the image recording unit to the cutter unit must be discarded as an unnecessary medium. Further, when a blank sheet or the like is inserted between jobs during image recording, this blank sheet portion becomes an unnecessary medium. For this reason, unnecessary media generated between jobs must be discarded. However, by disposing the stack device 1, unnecessary media are discarded in the disposal tray 17, and only the recording medium (storage medium) to be stored can be stored and transported to the post-processing device. In other words, as described above, the stack apparatus 1 can perform the unnecessary medium discarding process and the storage medium storage process continuously without stopping the image formation by the image forming apparatus.

  Note that when the stack apparatus of the present embodiment is used to bind a booklet with a stacked recording medium, the image forming apparatus sequentially prints the image for one booklet on the continuous recording medium from the first page to the last page. It can be realized by forming, cutting and carrying it into the stack device.

  As described above, the image forming apparatus that forms an image on the continuous recording medium 103 remains at least on the conveyance path from the first recording unit 150 to the cutter unit 190 of the first drum 130 at the start of image formation. The continuous recording medium 103 is discarded. The continuous recording medium 103 to be discarded is cut and discharged by the cutter unit 190. However, the cutter blade 192a can be moved from the cutting position, and can be discarded by passing through the roller while maintaining its long length.

  The stack apparatus according to the present embodiment can pass the cut recording medium to the recording medium discarding unit 6 through the sheet abutting unit 27 in which unnecessary recording media have been evacuated, and can be automatically discarded to the disposal tray 17. . Accordingly, it is not necessary for the operator to take out an unnecessary recording medium stored in the storage space.

  Further, by disposing the stack device below the cutter unit 190, an increase in the installation area of the image forming apparatus including the stack device can be suppressed to a minimum, and downsizing can be realized.

Next, a modification of the stack device according to the first embodiment of the present invention will be described with reference to FIG.
In the first embodiment, as the medium detection unit 8, the light emitting unit and the light receiving unit are disposed to face each other, and only the passage of the recording medium 10 is detected and counted. However, in the modification, the medium detection unit 8, a line sensor is used. As a result, the image formed on the recording medium is recognized, whether the recording medium is an unnecessary medium or a storage medium is determined on the spot, and a signal is sent to each driving unit by the control unit 6, and the sheet The butting portion 27 and the like can be controlled. In this modification, it is possible to sort the recording media even when it is not known in advance how many unnecessary media are present.

Next, a stack device according to a second embodiment of the present invention will be described with reference to FIGS.
In the second embodiment, between the medium detection unit 8 and the entrance roller pair 9 in the recording medium carrying-in unit 3, a path (carrying out the carrying medium to the apparatus main body unit 2 and carrying it out to the recording medium carrying-out unit 4. A switching gate 43 that switches between a path) and a path for transporting unnecessary media to the disposal tray 17 (discard path). That is, the carry-out route and the discard route are switched on the upstream side of the apparatus main body 2 including the storage space 29.

  As shown in FIG. 12, the switching gate 43 is driven by the rotary plunger 44 connected to the base of the switching gate 43 based on the information read by the medium detection unit 8 to switch between the carry-out route and the disposal route. The unnecessary medium is transported through the disposal guide 45 by the roller pairs 46 a and 46 b and discharged to the disposal tray 17. A drive motor is connected to one roller of the roller pair 46a. Similarly, a drive motor is connected to one roller of the roller pair 46b. Since the switching gate 43 is provided on the upstream side of the apparatus main body 2, the waste tray 17 can also be provided above the apparatus main body 2, and the operator can easily access the waste tray 17. In addition, it is possible to secure a space for adding a plurality of routes to be switched for each job.

  Next, the switching operation of the switching gate 43 will be described with reference to FIGS. 13 and 14.

  FIG. 13 is a diagram illustrating a switching operation of the switching gate 43 when the first sheet is the unnecessary medium 10a and the second sheet is the storage medium 10b. It is assumed that information such as how many sheets are unnecessary media or contained media and how many unnecessary media are present is known in advance as in the first embodiment.

  When the first sheet is the unnecessary medium 10a, as shown in FIG. 13A, the switching gate 43 is preset by the rotary plunger 44 so as to convey the recording medium to the disposal path. Then, as shown in FIG. 13B, the conveyed first unnecessary medium 10a is conveyed to the disposal path. Subsequently, when the second storage medium 10b is carried into the entrance guide 8, as shown in FIG. 13C, the switching gate 43 moves in the direction of the arrow so as to convey the recording medium to the carry-out path. And the path is switched. This path switching timing is switched at the timing when the unnecessary medium 10a is nipped by the roller pair 46a. At this time, since a gap is formed between the switching gate 43 and the discard guide 45, the unnecessary medium 10a is sent to the discard path through this gap without being affected by the switching operation. Then, the roller pair 46 guides the waste tray 17. On the other hand, the storage medium 10b is sent to the carry-out path as shown in FIG. Thus, the unnecessary medium 10a and the storage medium 10b are separated.

  FIG. 14 is a diagram illustrating a switching operation of the switching gate 43 when the first sheet is the storage medium 10b and the second sheet is the unnecessary medium 10a. Also in this case, the same switching operation as in FIG. 13 is performed. That is, the switching gate 43 is switched at the timing when the storage medium 10a is nipped between the inlet roller pair.

  Note that the stack apparatus 1 of the second embodiment can also be mounted on the image forming apparatus 100 as in the first embodiment.

The following are the additional claims of the present invention.
[1] A carry-out unit for storing a plurality of sheet-like recording media carried in from the carry-in unit in a storage space formed along the vertical direction and delivering the plurality of stored recording media to a downstream apparatus. A stacking device comprising:
An abutting portion that stops the recording medium at the storage position by abutting the leading end of the recording medium carried into the storage space.
A recording medium that has a plurality of partition members, forms a plurality of spaces in which a plurality of recording media can be stored between the partition members, and stops at any one of the plurality of spaces at the storage position. A medium moving unit that houses and moves the partition member to move at least a part of the tip of the recording medium to a push-up position different from the storage position;
An elevating unit that pushes up the recording medium moved to the push-up position by the medium moving unit to the unloading unit;
And a switching mechanism that switches between two or more paths by moving the abutting portion in accordance with a signal from a host controller that controls a recording medium conveyance operation and image formation.
[2] The medium conveyance path can be switched so that the sheet-like recording medium, which is disposed upstream of the storage space and guided from the carry-in section, is guided to the storage space or a path different from the storage space. The stacking device according to [1], further comprising: a switching member disposed on the surface.

  DESCRIPTION OF SYMBOLS 1 ... Stack apparatus, 2 ... Apparatus main body part, 3 ... Recording medium carrying-in part, 4 ... Recording medium carrying-out part, 5 ... Recording medium discarding part, 6 ... Control part, 7 ... Entrance guide, 8 ... Medium detection part, 9 ... Inlet roller pair, 10 ... Recording medium, 11 ... Inlet roller pair, 12 ... Pickup roller pair, 13 ... Outlet guide, 14 ... Outlet roller pair, 15 ... Discard guide, 16 ... Discard roller pair, 17 ... Discard tray DESCRIPTION OF SYMBOLS 18 ... Base-material part, 19, 20 ... Carry-in guide, 21 ... Stiffening guide, 22, 23 ... Impeller, 24 ... Fan, 25, 26 ... Paddle roller, 27 ... Sheet abutting part, 28 ... Lifting part, 29 ... Storage space, 30 ... Gap, 31, 32 ... Elevator, 33, 34 ... Fixed support member, 35 ... Guide shaft, 36, 37 ... Support member, 38 ... Connection member, 39 ... Notch, 40 ... Roller drive part 41 ... Abutting drive unit, 42 ... Descending drive unit, 43 ... switching gate, 44 ... rotating plunger, 45 ... disposal guide, 46 ... roller pair, 100 ... image forming apparatus, 101 ... unwinder unit, 102 ... printer unit, 103 ... continuous recording medium, 104 ... Paper tube fixing shaft, 105 ... Stand, 106 ... Brake, 107, 108 ... Free roller, 109 ... Swing roller, 109a ... Center of rotation, 109b ... Arm, 109c ... Potentiometer, 110-115 ... Free roller, 116 Nip roller pair, 117 to 119 ... free roller, 120 ... nip roller pair, 121 ... introduction guide, 122 ... main body frame, 130 ... first drum, 130a ... rotating shaft, 140 ... second drum, 140a ... rotating Shaft 141 drive motor 150 first recording unit 151a to 151d recording head 52 ... Plate, 160 ... Second recording unit, 170 ... First cleaning unit, 180 ... Second cleaning unit, 190 ... Cutter unit, 191 ... Anvil roller, 192 ... Cutter roller, 192a ... Cutter blade, 193 ... Brush roller, 200... Control device.

Claims (7)

A carry-in section for carrying a plurality of recording media;
Among the plurality of recording media carried from the carry-in unit, a storage unit that stores a desired recording medium;
An unloading section for unloading the recording medium stored in the storage section;
Among the plurality of recording media carried in from the carry-in unit, a discarding unit that discharges an undesired recording medium;
A sorting unit for sorting the recording medium into the storage unit and the discarding unit;
A control unit that controls the sorting unit according to an external signal including an instruction of the desired presence / absence, and controls whether the plurality of recording media are stored in the storage unit or sent to the discard unit;
A stack apparatus comprising: The sorting section is
An abutting portion that comes into contact with and stops the plurality of loaded recording media;
In accordance with an external signal sent from the control unit, the abutting unit is moved to switch between a first position for storing the recording medium in the storage unit and a second position for discarding the recording medium in the discarding unit. The butting drive,
The stack apparatus according to claim 1, comprising:   The storage unit forms a space in which the plurality of recording media can be stored between the plurality of partition members, and stores the plurality of recording media in any one of the plurality of spaces, and the partition member A medium moving unit that moves at least a part of the front end portions of the plurality of recording media from a storage position in contact with the abutting unit to a push-up position that is not in contact with the abutting unit. The stack device according to claim 2, wherein   The stacking device according to claim 2, wherein the discard unit is disposed vertically below the storage unit.   Arranged so that the medium transport path can be switched so as to guide the plurality of recording media loaded from the carry-in section to the path different from the storage section or the storage section, arranged upstream from the storage section. The stacking device according to claim 1, further comprising a switching member that is provided.   The stacking device according to claim 5, wherein the discard unit is disposed vertically above the storage unit. A feeding unit for supplying a long continuous recording medium;
An image forming unit that forms an image on the continuous recording medium;
A cutter unit for cutting the continuous recording medium recorded by the image forming unit into a recording medium of a predetermined size;
A medium transport unit that transports the continuous recording medium from the feeding unit to the cutter unit;
The stack device according to any one of claims 1 to 6, wherein the stack is disposed below the cutter unit and the cut recording medium is subjected to stack processing and delivered to a downstream device;
A control device that controls at least the feeding unit, the image forming unit, the cutter unit, the medium transport unit, and the stack device;
An image forming apparatus comprising:

Images