JP2007277002A - Stacker position changer, recording apparatus and liquid ejecting apparatus - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a stacker position changer capable of easily setting a CD-R tray on an ejection stacker with a good posture. <P>SOLUTION: This ejection stacker lifting device 200 has a first ejection stacker 500 moving to a first position for placing a first medium recorded in a recording apparatus 100 recording on the first medium P and a second medium Q and a second position for receiving the recorded first medium and second medium by guiding the first medium P and the second medium to a recording part 110. The first ejection stacker moves to the downstream side in the carrying direction in recording when moving to the second position from the first position, and afterwards, moves in the direction orthogonal to the main scanning direction X and the carrying direction Y. An attitude of a medium guiding surface 523 arranged in the first ejection stacker and guiding the first medium and the second medium, is constituted so as to become parallel to the main scanning direction X and the carrying direction Y. <P>COPYRIGHT: (C)2008,JPO&INPIT

Description

  The present invention provides a first position for placing a first medium recorded in a recording apparatus that ejects ink from a recording head provided in a recording unit to record on a first medium and a second medium; and A discharge stacker including a first discharge stacker that guides the first medium and the second medium to the recording unit and moves to a second position for receiving the recorded first medium and second medium. The present invention relates to a lifting device, a recording device including the discharge stacker lifting device, and a liquid ejecting apparatus including the discharge stacker lifting device.

Here, the liquid ejecting apparatus refers to an ink jet recording apparatus, a copying machine, a facsimile, or the like that performs recording on a recording material by ejecting ink from a recording head as a liquid ejecting head to a recording material such as recording paper. In addition to the recording apparatus, instead of ink, a liquid corresponding to a specific application is ejected from the liquid ejecting head corresponding to the recording head to the ejected material corresponding to the recording material, and the liquid is ejected to the ejected material. Used to include the device to be attached. In addition to the recording head described above, the liquid ejecting head includes a color material ejecting head used for manufacturing a color filter such as a liquid crystal display, an electrode material used for forming an electrode such as an organic EL display and a surface emitting display (FED) ( Examples thereof include a conductive paste) ejection head, a bio-organic matter ejection head used for biochip manufacturing, and a sample ejection head that ejects a sample as a precision pipette.
The recording apparatus includes types such as an ink jet printer, a wire dot printer, a laser printer, a line printer, a copying machine, and a facsimile.

In the present specification, “first medium” refers to “non-rigid medium” as an example, and “second medium” refers to “rigid medium” as an example.
Here, the “non-rigid medium” refers to a flexible medium such as paper or an OHP sheet. The “rigid medium” refers to a medium having little flexibility such as a dedicated CD-R tray with a CD-R attached.

Conventionally, an ink jet recording apparatus that records a sheet as an example of a non-rigid medium performs recording on a label surface of an information recording medium such as a CD-R as an example of a rigid medium (for example, Patent Document 1 and Patent Document 2). The sheets are stacked on a hopper provided on the upstream side of the transport path, and only the uppermost sheet among the stacked sheets by the swing of the hopper is picked up by a side-view D-type feeding roller. Yes.
Then, the sheet is fed from the feed roller to the pair of transport rollers on the downstream side in the transport direction, and is transported to the recording unit while being sandwiched between the pair of transport rollers. Further, the sheet is recorded by the recording unit and discharged to the discharge stacker by the discharge roller pair on the downstream side in the transport direction.
Usually, in order to place the recorded paper on the discharge stacker, the discharge stacker is disposed below the pair of discharge rollers.

  On the other hand, when recording the CD-R label surface, the CD-R is attached to a dedicated CD-R tray and recorded in order to convey the disc-shaped CD-R with good posture. At this time, in the non-rigid paper conveyance path, the feeding roller and the conveyance roller are not provided in a straight line for the purpose of separating the paper that is likely to be fed in an overlapping manner. Therefore, the rigid CD-R and CD-R tray cannot be set in the hopper like the paper.

  Therefore, the conveyance path downstream in the conveyance direction from the conveyance roller pair is provided in a straight line, the CD-R tray is inserted from the discharge roller pair provided downstream in the sheet conveyance direction, and the discharge roller pair is driven in reverse. The CD-R tray was moved to a position where the upstream recording head could record on the CD-R label surface. Then, recording is performed on the label surface of the CD-R while moving from the recording start position to the downstream side.

At this time, it is necessary to set the CD-R tray on the discharge roller pair. In the prior art, the discharge stacker provided below the discharge roller pair is moved upward to guide the CD-R tray to the discharge roller pair. In other words, when recording the label surface of the CD-R, the discharge stacker is moved to the height of the linear conveyance path so that the discharge stacker guides the CD-R tray to the discharge roller pair, and after recording. The CD-R tray is configured to serve also as a CD-R tray discharge stacker that receives the discharged CD-R tray.
JP 2005-14494 A JP 2005-212906 A

However, since the movement direction of the discharge stacker is only the vertical direction in the prior art, there is a possibility that the CD-R tray cannot be easily set when the discharge stacker is recessed upstream in the transport direction. . Also, when recording on the label surface of the CD-R, if the CD-R tray holding the CD-R is set in the discharge stacker, the downstream side in the transport direction during recording of the CD-R tray (transport before recording) There is a risk that the posture will be unstable due to the downward (upstream) direction.
The present invention has been made in view of such a situation, and a problem thereof is that it includes a discharge stacker lifting device capable of easily setting a CD-R tray on a discharge stacker with a good posture, and the discharge stacker lifting device. And a liquid ejecting apparatus including the discharge stacker lifting device.

  In order to achieve the above object, according to a first aspect of the present invention, a first recording is performed in a recording apparatus that records ink on a first medium and a second medium by ejecting ink from a recording head provided in a recording unit. And a second position for guiding the first medium and the second medium to the recording unit and receiving the recorded first medium and second medium. A discharge stacker lifting device having a first discharge stacker that moves to the first stacker, wherein the first discharge stacker moves downstream in the transport direction during recording when moving from the first position to the second position. Thereafter, the first medium and the second medium are moved in a direction perpendicular to the width direction and the conveyance direction of the first medium and the second medium to be recorded, and are provided in the first discharge stacker. The first medium on which the attitude of the medium guide surface for guiding Preliminary the width direction and the conveying direction of the second medium, characterized in that it is configured to be parallel.

According to the first aspect of the present invention, the first discharge stacker moves downstream in the transport direction during recording when the first discharge stacker moves from the first position to the second position. Thereafter, the first medium and the second medium are moved in a direction perpendicular to the width direction and the conveyance direction of the first medium and the second medium to be recorded, and are provided in the first discharge stacker. The posture of the medium guide surface that guides the recording medium is parallel to the width direction and the transport direction of the first medium and the second medium to be recorded. That is, the second position is on the downstream side in the transport direction as compared with the first position. In addition, when the user sets the first medium and the second medium in the first discharge stacker, the normal user usually has a downstream side in the transport direction of the first medium after recording and the second medium (before recording). It is at the position in front of the discharge stacker lifting device which is the upstream side in the transport direction of the second medium. Therefore, since the first stacker moves toward the user, the user can easily set the first medium and the second medium in the first discharge stacker.
In addition, the first discharge stacker can support the set first medium and second medium closer to the center of gravity.

  According to a second aspect of the present invention, in the first aspect, a first medium is placed together with the first discharge stacker on the downstream side in the transport direction of the first discharge stacker at the first position. A discharge stacker is provided, and when the first discharge stacker moves from the first position to the second position, first, a position downstream of the first discharge stacker in the transport direction is set to the second discharge stacker. Raising the stacker to a position higher than the upstream side in the transport direction, tilting the posture of the first discharge stacker, and then moving the tilted first discharge stacker to the downstream side in the transport direction. The upstream side in the transport direction of the first discharge stacker is configured to rise so that the posture of the medium guide surface of the first discharge stacker is parallel to the parallel direction.

  According to the second aspect of the present invention, in addition to the same effects as those of the first aspect, first, the position of the first discharge stacker on the downstream side in the transport direction is set from the upstream side in the transport direction of the second discharge stacker. The first discharge stacker is raised to a high position, and the posture of the first discharge stacker is tilted. Next, the first discharge stacker whose posture is inclined is moved downstream in the transfer direction, and then the transfer direction of the first discharge stacker The upstream side is configured to be raised so that the posture of the medium guide surface of the first discharge stacker becomes parallel. That is, the first discharge stacker utilizes the space on which the first medium on the upper surface side of the first discharge stacker and the second discharge stacker at the first position is placed, It is configured to move from a position to the second position. Therefore, it is effective when the space is limited, such as when the upstream side of the first discharge stacker cannot be raised at the first position.

Further, when the first discharge stacker moves to the downstream side in the transport direction, the transport direction downstream end of the first discharge stacker is within the range from the upstream end to the downstream end in the transport direction of the second discharge stacker in the transport direction. It is possible to move. In this case, since the first discharge stacker is not in contact with or restricted by another place even in a place limited in the transport direction, for example, in a room, the first discharge stacker can be surely connected to the first position. To the second position.
Furthermore, since only the first discharge stacker is moved instead of the entire discharge stacker, the weight of the moved member is lighter than when the entire discharge stacker is moved. Therefore, when the first discharge stacker is configured to move by a power source such as a motor, the power source can be reduced in size.

  According to a third aspect of the present invention, in the first or second aspect, a discharge driving roller for moving the first medium and the second medium in the transport direction is provided on the base unit side of the discharge stacker lifting device. And a discharge frame portion having a first discharge driven roller that sandwiches the first medium in cooperation with the discharge drive roller is connected to the first discharge stacker, and the first discharge stacker is connected to the first discharge stacker. The first discharge driven roller moves in a direction away from the discharge drive roller as it moves from the first position to the second position.

  According to the third aspect of the present invention, in addition to the same function and effect as the first or second aspect, the first discharge driven roller that clamps the first medium in cooperation with the discharge drive roller is provided. The discharge frame portion provided is connected to the first discharge stacker, and the first discharge driven roller is moved as the first discharge stacker moves from the first position to the second position. It is configured to move in a direction away from the discharge drive roller. For example, when recording a rigid medium, the first discharge driven roller for the first medium that is not required can be retreated with the movement of the first discharge stacker.

  According to a fourth aspect of the present invention, in any one of the first to third aspects, the first discharge stacker includes a second discharge driven roller from the first position to the second position. When moving, the ejection drive after moving in the direction perpendicular to the width direction and transport direction of the first medium and the second medium to be recorded and the attitude of the medium guide surface becomes parallel In order to make the roller and the second driven roller for discharge cooperate, it is configured to move to the upstream side in the transport direction.

  According to the fourth aspect of the present invention, in addition to the same function and effect as any one of the first to third aspects, the first recorded when moving from the first position to the second position. After the medium guide surface moves in the direction perpendicular to the width direction and the conveyance direction of the first medium and the second medium and the posture of the medium guide surface becomes parallel, the discharge drive roller and the second discharge follower In order to cooperate with the roller, it is configured to move upstream in the transport direction. For example, when recording the second medium, the second discharge driven roller for the second medium is moved to a position that cooperates with the discharge drive roller as the first discharge stacker moves. be able to. When recording the second medium, the second discharge driven roller can move the second medium upstream and downstream in the transport direction in cooperation with the discharge drive roller.

According to a fifth aspect of the present invention, in the fourth aspect, the apparatus includes a position restricting means for restricting a position and a posture of the first discharge stacker at the second position.
According to the fifth aspect of the present invention, in addition to the same function and effect as the fourth aspect, the discharge stacker lifting device includes the position restricting means. Therefore, the position and posture of the first discharge stacker at the second position can be regulated.
For example, when the first discharge stacker moves to the second position, the first discharge stacker is configured so that the member on the base portion side and the member on the first discharge stacker side are engaged with each other. It is possible to regulate the position and posture of the stacker.

  According to a sixth aspect of the present invention, in the fifth aspect, the position regulating means is provided in a bifurcated shape, and the first discharge stacker moves from the first position to the second position. The position restricting means is configured to sandwich the shaft of the discharge driving roller when moving upstream in the transport direction.

  According to the sixth aspect of the present invention, in addition to the same function and effect as the fifth aspect, the position restricting means is provided in a bifurcated shape, and the first discharge stacker is moved from the first position to the second position. The position restricting means is configured to sandwich the shaft of the discharge driving roller when moving to the upstream position in the transport direction. Therefore, the position restricting means can be easily provided. In addition, since the position and posture of the first discharge stacker are regulated based on the shaft of the discharge drive roller, the first medium and the second medium can be reliably transported and discharged.

According to a seventh aspect of the present invention, in the sixth aspect, of the bifurcated shape of the position restricting means, only the first position side portion is provided so as to be swingable, and the bifurcated is closed by the biasing means. It is characterized by being energized.
According to the seventh aspect of the present invention, in addition to the same effects as the sixth aspect, only the first position side portion of the bifurcated shape of the position restricting means is provided to be swingable. The bifurcation is biased by the biasing means. That is, when the position is other than the second position, the bifurcated state is closed. Further, the first position side part capable of swinging is in a state of moving so as to retreat to the second position side part of the bifurcated part that does not swing. Therefore, when the discharge stacker is in the first position, the space near the bifurcated portion can be effectively used.
In addition, since the other side does not swing, it can be regulated with higher accuracy than the configuration in which both swing.

According to an eighth aspect of the present invention, in the seventh aspect, when the first discharge stacker moves from the first position to the second position, the first of the two forked positions of the position restricting means. The position side portion is configured to be in contact with the shaft of the discharging drive roller first.
According to the eighth aspect of the present invention, in addition to the same effects as the seventh aspect, when the first discharge stacker moves from the first position to the second position, Of the bifurcated shape, the first position side portion is configured to contact the shaft of the discharge driving roller first. Therefore, when the first discharge stacker moves from the first position to the second position, so-called overshoot at the second position can be prevented.

  According to a ninth aspect of the present invention, in any one of the fourth to eighth aspects, the first discharge stacker has a width direction and a conveyance direction of the first medium and the second medium to be recorded. After moving in the orthogonal direction and the posture of the medium guiding surface becomes parallel, the distance moved upstream in the transport direction is the first medium and the second medium on which the first discharge stacker is recorded. Before moving in the direction perpendicular to the width direction and the transport direction, the distance travels downstream in the transport direction.

  According to the ninth aspect of the present invention, in addition to the same functions and effects as in any one of the fourth to eighth aspects, the first discharge stacker includes the first medium and the second medium to be recorded. The distance traveled to the upstream side in the transport direction after the medium guide surface is moved in the direction perpendicular to the width direction and the transport direction and then moved to the upstream side in the transport direction is recorded by the first discharge stacker. The first medium and the second medium are configured to be shorter than the distance moved downstream in the transport direction before moving in the direction orthogonal to the width direction and the transport direction. In other words, in the transport direction, the second position is configured to maintain a relationship downstream of the first position. Therefore, when the first discharge stacker moves from the first position to the second position, even if the first discharge stacker moves to the upstream side in the transport direction, the same effect as the first aspect is achieved. Can be obtained.

According to a tenth aspect of the present invention, in any one of the fourth to ninth aspects, the second medium is a disk tray that holds an information storage medium disk that is a rigid medium. The discharge driven roller is provided so as to sandwich only the disk tray in cooperation with the discharge drive roller.
According to the tenth aspect of the present invention, in addition to the same function and effect as any one of the fourth to ninth aspects, the second medium is in a state of holding an information storage medium disc that is a rigid medium. The second discharge driven roller is a disk tray, and is provided so as to sandwich only the disk tray in cooperation with the discharge drive roller. Therefore, there is no possibility that the second discharge driven roller directly contacts the information storage medium disk and damages the information stored in the information storage medium disk.

  According to an eleventh aspect of the present invention, in any one of the first to tenth aspects, a rack provided on the first discharge stacker side and a base portion side of the discharge stacker elevating device are provided to the rack. The first discharge stacker is orthogonal to the width direction and the conveyance direction of the first medium and the second medium recorded along the rack by the rack and the pinion. It is comprised so that it may move to the direction to carry out, and a conveyance direction.

  According to the eleventh aspect of the present invention, in addition to the same functions and effects as any one of the first to tenth aspects, the rack provided on the first discharge stacker side and the base portion of the discharge stacker lifting device The first discharge stacker is provided on a side and includes a pinion that transmits power to the rack, and the first discharge stacker has a width of a first medium and a second medium recorded along the rack by the rack and the pinion. It is comprised so that it may move to the direction orthogonal to a conveyance direction and a conveyance direction, and a conveyance direction. Therefore, along the direction in which the rack is provided, the first discharge stacker not only in one direction but also in the width direction of the first medium and the second medium to be recorded and the direction orthogonal to the transport direction, Further, it can be moved with high accuracy in the transport direction.

According to a twelfth aspect of the present invention, in any one of the third to eleventh aspects, the movement of the first discharge stacker between the first position and the second position is the discharge drive. It is comprised so that it may carry out using the drive force of the 1st motor which drives a roller, It is characterized by the above-mentioned.
According to the twelfth aspect of the present invention, in addition to the same function and effect as any one of the third to eleventh aspects, between the first position and the second position of the first discharge stacker. The movement is performed using the driving force of the first motor that drives the discharge driving roller. Therefore, it is not necessary to provide a new power source.
Further, the position of the first discharge stacker can be determined with high accuracy by controlling the first motor.

  According to a thirteenth aspect of the present invention, in the twelfth aspect, the first discharge stacker moves from the second position to the first position by the forward rotation of the first motor, and the first discharge The discharge drive roller is configured to rotate forward when the stacker moves from the second position to the first position.

According to the thirteenth aspect of the present invention, in addition to the same effects as the twelfth aspect, when the first discharge stacker moves from the second position to the first position, the discharge drive roller Is configured to rotate forward. For example, after the recording of the second medium is finished, when the first discharge stacker returns from the second position to the first position, the discharge driving roller and the second discharge driven roller However, even when the second medium is still sandwiched, the ejection drive roller can move the second medium downstream in the transport direction. That is, the second medium can be released from being held by the discharge driving roller and the second discharge driven roller. Then, the second medium moves to the first position together with the first discharge stacker. Furthermore, in other words, even if the second medium stops at an abnormal position due to an abnormal discharge, the second medium can be discharged to a normal discharge position. At this time, there is no possibility that the second medium is damaged by the movement of the first discharge stacker.
Further, even when the user forgets to take the second medium, the discharging drive roller is driven to rotate in the forward direction, so that a so-called wrapping operation that moves the second medium to the recording head side may occur. Absent.

  According to a fourteenth aspect of the present invention, in the twelfth or thirteenth aspect, the recording apparatus has a gap between the first medium and the second medium and the recording unit during recording by the driving force of the second motor. A recording unit gap adjusting device that automatically switches and adjusts the recording unit gap adjusting device by switching power transmission from the first motor to the first discharge stacker when switching and adjusting the gap. The discharge stacker is configured to move.

  According to the fourteenth aspect of the present invention, in addition to the same function and effect as the twelfth or thirteenth aspect, the recording unit gap adjusting device may change the gap from the first motor to the first. The power transmission to the discharge stacker is switched to move the first discharge stacker. Therefore, it is not necessary to provide a new power source in order to switch the power transmission from the first motor to the first discharge stacker.

According to a fifteenth aspect of the present invention, in any one of the eleventh to fourteenth aspects, the rack and the pinion are provided as a pair on both sides in the width direction with respect to the transport direction. A power transmission unit that transmits the driving force of the pinion to the other pinion is provided.
According to the fifteenth aspect of the present invention, in addition to the same function and effect as any one of the eleventh to fourteenth aspects, the rack and the pinion are provided on both sides in the width direction with respect to the transport direction, A power transmission unit that transmits the driving force of one pinion to the other pinion is provided on the base body side. Accordingly, the operations of the rack and the pinion can be synchronized in the left-right width direction, and the posture of the first discharge stacker can be stabilized.

According to a sixteenth aspect of the present invention, in any one of the second to fifteenth aspects, the second discharge stacker opens and closes the first medium and the mounting opening through which the second medium is discharged. It is provided in.
According to the sixteenth aspect of the present invention, in addition to the same functions and effects as any one of the second to fifteenth aspects, the second discharge stacker discharges the first medium and the second medium. It is provided so as to open and close the mounting opening. That is, the second discharge stacker is provided not only as a discharge stacker for placing the first medium but also as a cover lid.

A seventeenth aspect of the present invention is a recording apparatus comprising: a recording unit that performs recording on a recording medium by a recording head; and a discharging unit that discharges the recording medium from the recording unit to the downstream side in the transport direction. The discharge unit includes the discharge stacker lifting device according to any one of the first to sixteenth aspects.
According to the seventeenth aspect of the present invention, the discharge section includes the discharge stacker lifting / lowering device according to any one of the first to sixteenth aspects. Therefore, in the recording apparatus, the first to sixteenth aspects are provided. The effect similar to the effect of either aspect can be acquired.

  According to an eighteenth aspect of the present invention, the first medium on which the liquid is ejected is placed in the liquid ejecting apparatus that ejects the liquid from the liquid ejecting head provided in the liquid ejecting unit to the first medium and the second medium. And the first medium and the second medium guided to the liquid ejecting unit and moved to the second position for receiving the first medium and the second medium ejected with the liquid. A liquid ejecting apparatus including a discharge stacker lifting device including a first discharge stacker, wherein the first discharge stacker is transported when liquid is ejected when moving from the first position to the second position. The first medium is moved to the downstream side in the direction, and then moved in the direction perpendicular to the width direction and the conveying direction of the first medium and the second medium to be recorded. The posture of the medium guide surface for guiding the second medium and the second medium is For the first medium and the width direction and the conveying direction of the second medium to be recorded, I characterized in that it is configured to be parallel.

  Hereinafter, a discharge stacker lifting apparatus according to the present invention and a recording apparatus which is an example of a liquid ejecting apparatus to which the discharge stacker lifting apparatus is applied will be described. First, an ink jet printer 100 is taken up as the best mode for carrying out a liquid ejecting apparatus of the present invention and a recording apparatus as an example thereof, and an outline of the entire configuration will be described with reference to the drawings.

  FIG. 1 is a perspective view showing the appearance of an ink jet printer, and FIG. 2 is a perspective view showing the internal structure of the ink jet printer with the housing removed. FIG. 3 is a side sectional view showing an outline of the internal structure of the ink jet printer.

  As shown in FIG. 1, the ink jet printer 100 described here includes a liquid ejecting apparatus main body and a scanner device 4 above a printer main body 3 which is an example of a recording apparatus main body. A liquid crystal monitor screen 7 is provided at the center of the front panel 6 of the printer body 3, and operation buttons 8 are provided on the left and right sides thereof. A memory card insertion portion 9 for inserting a memory card or the like on which photograph data taken with a digital camera is recorded is provided at the lower center portion of the front panel 6. The ink jet printer 100 of this type is a relatively compact ink jet printer having a composite function that can directly perform recording without using a personal computer and can also be used as a copier.

  In addition, a feeding cassette 30 is provided at the lower front portion of the printer body 3 so as to be detachable in the front-rear direction. A discharge stacker 50 that also functions as a part of the front cover of the printer main body 3 when not in use is provided at the upper portion of the feeding cassette 30 as shown by a solid line in FIG. In addition, the stacker 50 for discharge is used in a posture in which the stacking surface 51 faces upward as shown in a virtual line in FIG. Further, the liquid crystal monitor screen 7, a part of the operation buttons 8 and the memory card insertion portion 9 are parts used when recording is performed directly without being connected to a personal computer. That is, by inserting a memory card (not shown) into the memory card insertion portion 9 and operating the operation button 8 while looking at the liquid crystal monitor screen 7, it is possible to easily print any number of desired photos with high quality while at home. Can be done.

  Further, an automatic feeding device capable of automatically feeding a recording material P (hereinafter also simply referred to as a sheet P), which is an example of a liquid ejecting material, to the upper portion on the back side of the printer body 3 automatically. 2 is provided. The automatic feeding device 2 includes a feeding tray 5 on which a plurality of sheets P can be stacked, a hopper 16 that pushes the sheets P on the feeding tray 5 toward the feeding roller 14, The feeding roller 14 that picks up the upper sheet P on the feeding tray 5 by the nipping pressure feeding action, and the succeeding sheet P that has been double fed so that only the uppermost sheet P is fed A non-illustrated retard roller or separation pad, which is an example of a separation action unit that separates the upper paper P, and a return lever (not shown) for returning the separated subsequent paper P onto the feeding tray 5 are provided. .

  Next, an outline of the internal structure of the inkjet printer 100 will be described according to the conveyance path of the paper P. The feeding tray 5 is provided on the most upstream side in the transport direction, and is an example of a liquid injection material stacking unit that stacks a plurality of sheets P. The feeding tray 5 is provided with an edge guide 15 that abuts on the side edge (edge) of the paper P and guides smooth conveyance in the sub-scanning direction Y that is the conveyance direction of the paper P. With the rotation of the rotating shaft 17 of the feeding roller 14, the hopper 16 rises at a predetermined timing and is pushed up toward the feeding roller 14 on the paper P on the feeding tray 5. Then, the sheet P receives a separating force from a retard roller (not shown) that is a separating action portion provided in the vicinity of the feeding roller 14 in order from the sheet P positioned on the uppermost surface as the feeding roller 14 rotates. Are picked up in units and fed downstream in the transport direction.

  Downstream of the feeding roller 14, a recording material detection unit (not shown) (hereinafter simply referred to as a detection lever) that is an example of a liquid ejection material detection unit that detects the passage of the paper P is provided. A transport roller 19 including a transport drive roller 19a and a transport driven roller 19b is provided downstream of the detection lever. Of these, the driven roller 19b for conveyance is pivotally supported at the downstream end of the roller holder 18, and the roller holder 18 is in a nip state in which the driven roller 19b for conveyance is always in pressure contact with the driving roller 19a for conveyance by a torsion coil spring (not shown). It is urged to turn.

  Then, the sheet P conveyed while being pinched by the conveying roller 19 is guided to the recording position 26, and the recording execution unit is an example of a liquid jet execution unit that performs recording on the sheet P at the recording position 26. A carriage 10 is provided as a main component. The carriage 10 is supported by a carriage guide shaft 12 so as to be reciprocally movable in a main scanning direction X that is the width direction of the paper P to be recorded and the CD-R tray Q, and is reciprocated by an endless belt 11. ing. A recording head 13, which is an example of a liquid ejecting head that performs recording by ejecting (ejecting) ink, which is an example of liquid, onto the paper P or the like is mounted on the lower surface of the carriage 10. An ink cartridge C, which is an example of a liquid cartridge, is inserted into the carriage 10.

  A platen 28 that defines the gap PG between the head surface of the recording head 13 and the paper P or the like is provided below the recording head 13 so as to face the recording head 13. Then, between the recording head 13 and the platen 28, the sheet P or the like is transported by a predetermined transport amount in the sub-scanning direction Y orthogonal to the main scanning direction X, and the recording head 13 is reciprocated once in the main scanning direction X. By repeating the operation of ejecting ink from the recording head 13 onto the paper P or the like during the operation, desired recording is performed over almost the entire recording surface of the paper P or the like. Note that the gap PG is an extremely important element in executing high-precision recording, and is appropriately adjusted according to a change in the thickness of the paper P or the like.

  Disposed downstream of the recording head 13 is a discharge roller 20 that is an example of a liquid ejecting material discharge unit including a discharge drive roller 20a and a plurality of first discharge driven rollers 20b, 20b,. ing. Further, a plurality of discharge auxiliary driven rollers 22, 22,... Are provided upstream of the first discharge driven rollers 20 b, 20 b,. Then, the paper P discharged by the discharge roller 20 is discharged onto the placement surface 51 on the discharge stacker 50, which is an example of the liquid injection material receiving portion positioned further downstream in the transport direction. ing.

  The first discharge driven rollers 20b, 20b,... And the discharge auxiliary driven rollers 22, 22,... Are toothed rollers having a plurality of teeth on the outer periphery thereof, and can be freely rotated by a roller holder that holds each of them. Is pivotally supported. The transport driven roller 19b is disposed such that its axial center is located somewhat downstream in the transport direction with respect to the transport drive roller 19a, and the first discharge driven rollers 20b, 20b,. Are arranged so that the axial center position is located somewhat upstream in the conveying direction from the discharge driving roller 20a. By adopting such an arrangement, the sheet P is formed in a curved state called “reverse sled” that slightly protrudes downward between the transport roller 19 and the discharge roller 20. . As a result, the sheet P located at the position facing the recording head 13 is pressed against the platen 28, and the sheet P is prevented from being lifted, so that the recording is executed normally.

[Example]
Next, the discharge stacker lifting / lowering device of the present invention provided for such an ink jet printer 100 will be specifically described with reference to the drawings.
4 to 6 are front perspective views showing the discharge stacker lifting device of the present invention. 4 shows a state where the first discharge stacker in the paper recording mode is at the first position, and FIG. 5 shows a state where the first discharge stacker in the CD-R recording mode is at the second position. FIG. 6 shows a state in which the CD-R tray is set in FIG.

As shown in FIGS. 4 to 6, the discharge unit 120 that discharges the paper and the like of the recording apparatus 100 is provided with a discharge stacker elevating device 200, and the discharge stacker elevating device 200 is a paper recording mode for recording the paper P. And a CD-R recording mode for recording a CD-R label. The recording mode is switched so that the user can switch the recording mode by operating the operation button 8. When the recording mode is switched, the first discharge stacker 500 provided in the discharge stacker elevating device 200 is moved to the first position and the second position by the motor of the power source of the discharge drive roller 20a. Has been. The movement of the first discharge stacker 500 will be described in detail later. First, the first position and the second position will be described.
The recording mode may be switched so that the control unit determines and switches the recording mode when the recording information data is sent to a control unit (not shown).
4 to 6, the right side in the X direction in the drawings is the one digit side, and the left side is the 80 digit side.

  As shown in FIG. 4, the discharge stacker 50 includes a first discharge stacker 500 on the upstream side in the transport direction that is the sub-scanning direction Y, and a second discharge stacker 600 on the downstream side. The second discharge stacker 600 is configured to open and close a placement opening 260 provided on the front surface of the recording apparatus 100, and the state shown in FIG. 4 is an open state. When the recorded paper P is discharged by the discharge roller 20 in the paper recording mode, the paper P is discharged from the first loading unit 510 of the first discharge stacker 500 and the second discharge stacker 600 as the mounting surface 51. It is placed on the upper surface of the second placement unit 610. At this time, the downstream end in the transport direction of the first discharge stacker 500 is configured to be higher than the upstream end of the second discharge stacker 600. Therefore, there is no possibility that the leading end of the paper P, that is, the downstream end in the transport direction, is caught in the gap between the first discharge stacker 500 and the second discharge stacker 600, that is, so-called paper jam.

  As shown in FIG. 5, in the CD-R recording mode, the first discharge stacker 500 moves to above the second discharge stacker 600 on the downstream side in the transport direction. This position is the second position of the first discharge stacker 500. The first discharge stacker 500 has a CD-R tray guide opening 522 on the downstream side in the transport direction of the first loading unit 510, and a lower surface in the CD-R tray guide opening and a CD-R tray Q (see FIG. 6). ) In the transport direction (Y). In the second position, the CD-R tray guide surface 523 is parallel to the transport direction (Y) and the main scanning direction X, and has the same height as the upper positions of the ejection drive roller 20a and the platen 28. It is provided to become.

  As shown in FIG. 6, when switched to the CD-R recording mode, the first discharge stacker 500 moves to the second position. Then, the user attaches the CD-R to be recorded on the label to the dedicated CD-R tray Q, inserts the CD-R tray Q into the CD-R tray guide opening 522 of the first discharge stacker 500, and sets it. When set, the CD-R tray Q is sandwiched between the discharge drive roller 20a and second discharge driven rollers 503 and 503 (see FIGS. 10 to 22) described later. Thereafter, the paper is sent upstream in the transport direction by the reverse drive of the discharge driving roller 20a. Then, the downstream end in the transport direction of the CD-R attached to the CD-R tray Q stops at a position facing the recording head 13, that is, a so-called recording start position. At this time, on the upstream side of the CD-R tray Q, the conveyance roller 19a is in contact with the label surface of the CD-R to prevent the data stored in the CD-R from being damaged. 19 so as not to be sandwiched between the two.

  The ejection drive roller 20a and the second ejection driven rollers 503 and 503 do not directly sandwich the CD-R, but 2 so as to sandwich the vicinity of both sides in the main scanning direction of the CD-R tray main body (Q). One is provided. Therefore, there is no possibility of damaging the data information stored on the CD-R. Further, in order to improve the conveyance accuracy of the CD-R tray, not only the ejection drive roller 20a and the second ejection driven rollers 503 and 503 but also the conveyance roller 19 carries the CD-R tray while sandwiching it. Of course, you may comprise.

  Thereafter, the ejection drive roller 20a is driven to rotate in the forward direction, and the recording head 13 is scanned in the main scanning direction X while the CD-R tray Q is moved downstream in the transport direction, and recording is performed on the CD-R label. To do. When the recording is completed, the discharge driving roller 20a and the second discharge driven rollers 503 and 503 cooperate to discharge the CD-R tray Q to the downstream side in the transport direction. At this time, the upstream end in the transport direction of the CD-R tray Q is disengaged from the nip between the ejection drive roller 20a and the second ejection driven rollers 503 and 503, so that the CD-R tray Q is again in the CD as shown in FIG. -Stops at a position where the CD-R tray Q protrudes further than a position where a part of the CD-R tray Q protrudes from the R tray guide opening 522.

In the CD-R recording mode, the first discharge stacker 500 provided with the CD-R tray guide opening 522 moves to the downstream side in the transport direction, so that the user can easily set the CD-R tray Q. . Further, after recording, the user can easily take out the CD-R tray Q. At this time, since a part of the CD-R tray Q protrudes from the CD-R tray guide opening 522, the CD-R tray Q can be taken out more easily.
Further, since the first discharge stacker 500 moves downstream in the transport direction, it is possible to support the center of gravity of the CD-R tray Q. Therefore, the posture of the CD-R tray Q can be stabilized.

[About PG switching and recording mode switching]
FIG. 7 to FIG. 9 are schematic side views showing power transmission to the discharge stacker lifting device according to the present invention. Of these, FIG. 7 shows a state in which the power is cut off. FIG. 8 shows a state in which power is transmitted in the reverse rotation state of the discharge drive roller, and FIG. 9 shows a state in which power is transmitted in the forward rotation state of the discharge drive roller.

  As shown in FIG. 7, the recording apparatus 100 includes a recording unit gap adjusting device 300 that can adjust the distance between the recording head 13 provided in the recording unit 110 and the platen 28 according to the thickness of the paper and the like. In order to guide and receive the CD-R tray Q when recording a label, the power of the discharge stacker elevating device 200 that moves the first discharge stacker 500 and the power of the discharge drive roller 20a is transmitted to the discharge stacker elevating device 200. A power transmission switching device 400 that switches between the two is provided.

Among these, the recording unit gap adjusting device 300 includes a cam shaft 302 that is rotated by a PG adjusting motor that is a second motor (not shown), and a carriage guide that is provided so as to be eccentric with respect to the rotation fulcrum of the cam shaft 302. The shaft 12 includes a PG adjustment cam portion 301 provided on the cam shaft 302, and a lever member 304 that constantly biases the PG adjustment cam portion 301 by a torsion coil spring (not shown).
Further, the discharge stacker lifting / lowering device 200 includes a base portion 220, power transmission means 210 for transmitting power transmitted from the power transmission switching device 400 to the first discharge stacker 500, and a first position and a second position. And a first discharge stacker 500 that moves between them.

Furthermore, the power transmission switching device 400 is provided coaxially with the discharge drive roller 20a rotated by the first motor, and rotates integrally with the sun gear 426, the first planetary gear 423 circumscribing the sun gear 426, and A second planetary gear 424, a planetary gear holder 420 that holds the first planetary gear 423 and the second planetary gear 424, and swings freely around the pivot fulcrum shaft 425 of the sun gear 426; A first gear 211 that receives power from the gear 423 and the second planetary gear 424 and a lock lever 410 that regulates the attitude of the planetary gear holder portion 420 are provided.
Here, the first motor is configured to also rotate the transport driving roller 19a and the feeding roller 14.

  The recording head 13 is provided on the carriage 10 that moves in the main scanning direction X by the carriage guide shaft 12. If there is a change in the thickness of the paper P or a change from the paper recording mode for recording the paper P to the CD-R recording mode for recording the CD-R label surface, the cam is driven by a PG adjustment motor (second motor) (not shown). The shaft 302 rotates. At this time, the carriage guide shaft 12 is eccentric with respect to the cam shaft 302. Accordingly, the recording unit gap adjusting device 300 can adjust a so-called platen gap or paper gap (hereinafter referred to as PG), which is the interval between the recording head 13 and the platen 28, by the rotation of the cam shaft 302. .

  Further, the cam shaft 302 is provided with a PG adjustment cam portion 301. A lever abutting portion 303 of a lever member 304 urged clockwise with a lever shaft 305 as a fulcrum by a torsion coil spring (not shown) is provided so as to abut and press against the PG adjustment cam portion 301. ing. At this time, the PG adjustment is performed by rotating the cam shaft 302 within a range in which the arc portion 301 a of the PG adjustment cam portion 301 contacts the lever contact portion 303. Then, when switching between the paper recording mode and the CD-R recording mode, the cam shaft 302 is rotated so that the chord portion 301b of the PG adjustment cam portion 301 faces the lever contact portion 303, which will be described later. The power transmission switching device 400 is configured to be switched.

  The side of the lever member 304 opposite to the side on which the lever contact portion 303 is provided is rotatably connected to one end of a slide bar 430 that reciprocates in the horizontal direction by a bar guide 431 provided on the base portion 220. ing. On the other hand, the other end of the slide bar 430 is rotatably connected to one end of the lock lever 410.

  As described above, the sun gear 426 is provided to rotate by the rotation of the discharge drive roller 20a. The planetary gear holder 420 holding the first planetary gear 423 and the second planetary gear 424 by the rotation of the sun gear 426 tries to rotate in the same direction as the rotation direction of the sun gear 426, but the lock lever The posture is regulated by 410. Then, both the first planetary gear 423 and the second planetary gear 424 are separated from the first gear 211. Therefore, the power of the sun gear 426 is not transmitted to the first gear 211.

  Here, the planetary gear holder unit 420 may be configured to rotate in the same direction as the sun gear 426 by a frictional resistance generated between the planetary gear holder unit 420 and the rotation fulcrum shaft 425. Further, it may be configured to rotate in the same direction as the sun gear 426 by a frictional resistance generated between the first planetary gear 423 and the second planetary gear 424 and the planetary gear holder portion 420.

[Switching from paper recording mode to CD-R recording mode]
As shown in FIG. 8, when the camshaft 302 is rotated clockwise and the string portion 301b is opposed to the lever contact portion 303, the lever member 304 is rotated clockwise. Then, the slide bar 430 moves to the left side in the figure. Further, as the slide bar 430 moves to the left side, the lock lever 410 moves, so that the planetary gear holder portion 420 is released from the restriction of the lock lever 410. Therefore, the planetary gear holder 420 generates a force that rotates in the rotating direction of the sun gear 426. At this time, the discharge drive roller 20a is rotated in the counterclockwise direction in the figure, which is the reverse direction in which the paper P can be moved upstream. The sun gear 426 is provided so as to rotate in the same direction as the discharge drive roller 20a. Accordingly, the planetary gear holder portion 420 rotates counterclockwise about the rotation fulcrum shaft 425 of the sun gear 426 so that the second planetary gear 424 contacts the first gear 211. That is, the power of the sun gear 426 is transmitted to the first gear 211 via the second planetary gear 424. At this time, since the second planetary gear 424 contacts the first gear 211 while rotating clockwise, the first gear 211 rotates counterclockwise.

  The power transmission means 210 of the discharge stacker lifting / lowering device 200 is provided integrally with a first gear 211, a second gear 212 circumscribing the first gear 211, a third gear 213 circumscribing the second gear 212, and a third gear 213. The fourth gear 214, the fifth gear 215 circumscribing the fourth gear 214, the sixth gear 216 circumscribing the fifth gear 215, the seventh gear 217 and the seventh gear 217 provided integrally with the sixth gear 216; A circumscribed eighth gear 218, a pinion 219 provided integrally with the eighth gear 218, and a rack 227 that receives power from the pinion 219 are provided.

  A pair of fifth gear 215, sixth gear 216, seventh gear 217, eighth gear 218, pinion 219, and rack 227 is provided in the width direction with respect to the transport direction (Y), that is, on both the left and right sides in the main scanning direction. It has been. The pair of left and right fifth gears 215 are provided to rotate synchronously by the power transmission shaft 270. Accordingly, the sixth gear 216, the seventh gear 217, the eighth gear 218, the pinion 219, and the rack 227 that are provided in a pair can rotate synchronously. Since synchronous rotation is performed on both the left and right sides, in the following description, only one side will be described, and the other description will be omitted.

  When the first gear 211 rotates counterclockwise, power is transmitted to the second gear 212 and the second gear 212 rotates clockwise. The power of the second gear 212 is transmitted to the third gear 213, and the third gear 213 rotates counterclockwise. Since the fourth gear 214 is provided integrally with the third gear 213, it rotates counterclockwise together with the third gear 213. The power of the fourth gear 214 is transmitted to the fifth gear 215, and the fifth gear 215 rotates clockwise. The power of the fifth gear 215 is transmitted to the sixth gear 216, and the sixth gear 216 rotates counterclockwise. Since the seventh gear 217 is provided integrally with the sixth gear 216, the seventh gear 217 rotates counterclockwise integrally with the sixth gear 216. The power of the seventh gear 217 is transmitted to the eighth gear 218, and the eighth gear 218 rotates clockwise. Since the pinion 219 is provided integrally with the eighth gear 218, the pinion 219 rotates clockwise together with the eighth gear 218.

  When the pinion 219 rotates in the clockwise direction, the pinion 219 is provided to move the first discharge stacker 500 from the first position to the second position via the rack 227 provided on the first discharge stacker side. It has been. When the first discharge stacker 500 finishes moving to the second position, the cam shaft 302 rotates counterclockwise until the arc portion 301a and the lever contact portion 303 come into contact with each other, and the lever member 304 is rotated. Is rotated counterclockwise until the state shown in FIG. At this time, the cam shaft 302 rotates so that the PG is in the CD-R recording mode.

[Switching from CD-R recording mode to paper recording mode]
On the other hand, when switching from the CD-R recording mode to the paper recording mode, the cam shaft 302 rotates clockwise from the state shown in FIG. 7, and the lever member 304 rotates clockwise to the position shown in FIG. Then, as described above, the planetary gear holder portion 420 is released from the restriction of the lock lever 410.
At this time, as shown in FIG. 9, the discharge drive roller 20a is rotated in the clockwise direction in the figure, which is the normal rotation direction in which the paper P can be moved downstream. Therefore, as described above, the sun gear 426 also rotates in the clockwise direction, which is the same direction as the discharge drive roller 20a. As described above, the sun gear 426 rotates the planetary gear holder 420 in the clockwise direction.

  The planetary gear holder 420 rotates clockwise, and the first planetary gear 423 circumscribes the first gear 211. Accordingly, the power of the sun gear 426 is transmitted to the first gear 211 via the first planetary gear 423. At this time, since the sun gear 426 rotates clockwise, the first planetary gear 423 rotates counterclockwise, and the first gear 211 rotates clockwise. As the first gear 211 rotates, from the upstream side to the downstream side in the power transmission direction, the second gear 212 is counterclockwise, the third gear 213 and the fourth gear 214 are clockwise, and the fifth gear 215 is In the counterclockwise direction, the sixth gear 216 and the seventh gear 217 rotate in the clockwise direction, and the eighth gear 218 and the pinion 219 rotate in the counterclockwise direction.

  When the pinion 219 rotates counterclockwise, the pinion 219 moves the first discharge stacker 500 from the second position described later to the first position via the rack 227 provided on the first discharge stacker side. It is provided as follows. When the first discharge stacker 500 finishes moving to the first position, the cam shaft 302 rotates counterclockwise until the arc portion 301a and the lever contact portion 303 come into contact with each other, and the lever member 304 is rotated. Is rotated counterclockwise until the state shown in FIG. At this time, the cam shaft 302 rotates so that the PG enters the paper recording mode.

[Movement of first discharge stacker from first position to second position]
Next, the movement of the first discharge stacker 500 from the first position to the second position will be described.
Here, the first position is a position at which the sheet P recorded and discharged by the discharge drive roller 20a can be received in the sheet recording mode, and the discharge drive for placing the sheet P is performed. The position below the roller 20a is said.
On the other hand, in the CD-R recording mode, the second position is for discharging the CD-R tray Q holding the CD-R before recording, including the discharge driving roller 20a and the second discharge driven rollers 503 and 503. Guide to the pair of rollers and receive the CD-R tray Q holding the recorded CD-R ejected by the pair of ejection rollers comprising the ejection drive roller 20a and the second ejection driven rollers 503 and 503. This is a position where the CD-R tray guide surface 523 of the first discharge stacker 500 is substantially the same height as the upper end of the discharge drive roller 20a.

10 to 22 are side views showing the movement of the first discharge stacker of the discharge stacker lifting device according to the present invention. Among these, FIG. 10 is the first position of the first discharge stacker, FIGS. 11 to 21 are moving from the first position to the second position, and FIG. 22 is the second position.
As shown in FIG. 10, the discharge stacker elevating device 200 is disposed on the downstream side in the transport direction of the first discharge stacker 500 and the first discharge stacker 500 that move between the first position and the second position. 2 discharge stacker 600, discharge drive roller 20a provided on the base portion side, first discharge driven rollers 20b, 20b,... For discharging paper P in the discharge direction in cooperation with discharge drive roller 20a. The discharge frame portion 800, the connecting arm portion 700 for connecting the discharge frame portion 800 and the first discharge stacker 500, and the power transmission means 210 for transmitting the power of the discharge drive roller 20a to the first discharge stacker 500 are provided. .

  A first groove 221 that guides the movement of the first discharge stacker 500 is provided on the right side in the transport direction of the base body 220, that is, on the 80th digit side in the main scanning direction. Further, a second groove portion 222 that guides the movement of the first discharge stacker 500 is provided on the digit side of the base portion 220 in the main scanning direction. Furthermore, a pair of fourth groove portions 224 and 224 and fifth groove portions 225 and 225 for guiding the movement of the discharge frame portion 800 are provided on both sides of the base body portion 220 in the main scanning direction. Further, a posture regulating unit 228 for regulating the posture of the moving first discharge stacker 500 is provided above the base unit 220 on the first digit side in the main scanning direction.

The first discharge stacker 500 includes a first placement unit 510 on which the paper P discharged on the upper surface at the first position is placed, and a CD inside the first placement unit and before recording at the second position. A CD-R tray guide opening 522 for guiding the R-tray Q to a pair of discharging rollers composed of a driving roller 20a for discharging and second driven rollers for discharging 503 and 503, and receiving the CD-R tray Q after recording; From the first protrusion 501 engaged / guided with the first groove 221 of the portion 220, the second protrusion 504 engaged / guided with the second groove 222 of the base portion 220, and the first mounting portion 510. Provided on the upstream side in the transport direction, swings around the swing shaft 502 while being urged by a spring (not shown), and moves the CD-R tray Q in the transport direction (Y) in cooperation with the ejection drive roller 20a. Second discharge driven roller 503 And 503, a and posture regulating portions 228 of the base portion 220 and the abutment surface 520 and the abutment projection 521 abuts.
The first discharge stacker 500 includes a pair of sixth grooves 226 and 226 provided on both sides in the main scanning direction, and a pair of third grooves 223 and 223 that engage with the connecting arm 700 on both sides in the main scanning direction. ing. Racks 227 and 227 are provided on one surface of the pair of sixth groove portions 226 and 226, and are configured to mesh with the pair of pinions 219 and 219 described above.

  The second discharge stacker 600 includes a second placement portion 610 that rotates around the cover shaft 601 and places the discharged paper P in cooperation with the first discharge stacker 500 at the first position. Yes. The second discharge stacker 600 is provided so as to rotate around the cover shaft 601 and close the mounting opening 260 in a state where recording is not executed. In other words, the second discharge stacker 600 is provided so as to also serve as a cover case. When the second discharge stacker 600 is opened, the posture of the second discharge stacker 600 is restricted by the cover restricting portion 250 provided on the base portion 220.

The discharge frame portion 800 is engaged with a pair of fourth protrusions 801 and 801 engaged and guided by the pair of fourth groove portions 224 and 224 of the base portion 220 and the pair of fifth groove portions 225 and 225 of the base portion 220. A pair of fifth protrusions 802, 802 to be joined and guided, and first discharge driven rollers 20b, 20b,... That circumscribe the discharge drive roller 20a on the base portion side while being urged by a spring (not shown). I have. The discharge frame portion 800 is always urged upstream in the transport direction by a torsion coil spring (not shown).
The connecting arm portion 700 includes a pair of third protrusions 701 and 701 that are engaged and guided by the pair of third groove portions 223 and 223 of the first discharge stacker 500 at one end, and the other end is a first portion of the discharge frame portion 800. The four protrusions 801 are provided so as to be rotatably connected to the downstream side in the transport direction.

  In the first position, the position of the downstream end of the first discharge stacker 500 in the transport direction is set higher than the position of the upstream end of the second discharge stacker 600 in the transport direction. Therefore, in the paper recording mode, the leading edge of the paper P discharged from the discharge roller is at the level difference between the first placement portion 510 of the first discharge stacker 500 and the second placement portion 610 of the second discharge stacker 600. There is no risk of getting caught.

The first position is the so-called home position of the first discharge stacker 500, and the home position detector 230 provided on the base 220 is configured to be in contact with the first discharge stacker 500 for detection. Yes. The driving amount of the first motor when the first discharge stacker 500 moves from the first position to the second position is a predetermined number of steps after the first discharge stacker 500 is separated from the home position detector 230. It is controlled to stop at. On the other hand, the driving amount of the first motor when the first discharge stacker 500 moves from the second position to the first position is controlled so that the first discharge stacker 500 stops in contact with the home position detector 230. Has been.
In the following description, the third protrusion, the fourth protrusion, the fifth protrusion, the third groove part, the fourth groove part, and the fifth groove part provided in pairs in the main scanning direction have the same shape on the left and right and are synchronized. Therefore, only one side will be described, and the other side will not be described.

As shown in FIG. 11, when the pinion 219 rotates clockwise from the state shown in FIG. 10, power is transmitted to the rack 227 of the first discharge stacker 500. At this time, since the position of the pinion 219 is fixed to the base portion side, the pinion 219 moves downward through the sixth groove portion 226 provided with the rack 227 to move the first discharge stacker 500 upward. To do. That is, a force to move upward acts on the first discharge stacker 500. Then, the first discharge stacker 500 is inclined so that the downstream end in the transport direction rises with the first protrusion 501 on the upstream side in the transport direction as a fulcrum. At this time, the second protrusion 504 of the first discharge stacker 500 moves slightly upward in the second groove of the base body 220.
Further, when the downstream end of the first discharge stacker 500 rises, the first discharge stacker 500 moves away from the home position detector 230, so that the count of the number of steps of the motor is started.

  As shown in FIG. 12, when the pinion 219 further rotates clockwise from the state shown in FIG. 11, the pinion 219 attempts to move the first discharge stacker 500 further upward via the rack 227. Accordingly, the first discharge stacker 500 is inclined so that the downstream end in the transport direction further rises with the first protrusion 501 as a fulcrum. The lower end of the downstream end of the first discharge stacker 500 in the transport direction is higher than the upper end of the upstream end of the second discharge stacker 600 in the transport direction.

  As shown in FIG. 13, when the pinion 219 further rotates clockwise from the state shown in FIG. 12, the pinion 219 tends to move along the sixth groove 226 upstream in the transport direction. That is, the pinion 219 attempts to move the first discharge stacker 500 to the downstream side in the transport direction via the rack 227. Therefore, the first discharge stacker 500 is guided by the engagement between the first protrusion 501 and the first groove 221 and is guided by the engagement between the second protrusion 504 and the second groove 222 while being guided in the transport direction. Move downstream. At this time, the inclination, that is, the posture of the first discharge stacker 500 is regulated by the engagement between the first protrusion 501 and the first groove 221 and the engagement between the second protrusion 504 and the second groove 222. Therefore, the downstream end remains in the raised posture. Accordingly, the first discharge stacker 500 can move downstream in the transport direction so that the position of the downstream end of the first discharge stacker 500 in the transport direction is above the upstream end of the second discharge stacker 600.

  As shown in FIG. 14, when the pinion 219 further rotates clockwise from the state shown in FIG. 13, the pinion 219 tries to move the first discharge stacker 500 further downstream in the transport direction via the rack 227. . Accordingly, the first discharge stacker 500 is guided by the engagement between the first protrusion 501 and the first groove 221 and further conveyed while being guided by the engagement between the second protrusion 504 and the second groove 222. Move downstream in the direction. At this time, the third projecting portion 701 of the connecting arm portion 700 moves the third groove portion 223 of the first discharge stacker 500 to the upstream side in the transport direction and hits the upstream end of the third groove portion 223.

As shown in FIG. 15, when the pinion 219 further rotates clockwise from the state shown in FIG. 14, the first discharge stacker 500 further moves downstream in the transport direction. At this time, since the third protrusion 701 of the connecting arm portion 700 is in contact with the upstream end in the transport direction of the third groove portion 223 of the first discharge stacker 500, the first discharge stacker 500 is interposed via the connecting arm portion 700. Thus, the discharge frame portion 800 is moved downstream in the conveyance direction against the biasing force of the torsion coil spring described above.
At this time, the discharge frame portion 800 is guided by the engagement of the fourth protrusion 801 and the fourth groove portion 224 and the engagement of the fifth protrusion 802 and the fifth groove portion 225, and on the downstream side in the transport direction and above Move to. As the discharge frame portion 800 moves, the first discharge driven rollers 20b, 20b,... Provided in the discharge frame portion 800 are separated from the discharge drive roller 20a.
The discharge auxiliary driven rollers 22, 22,... (See FIG. 3) move in the same direction as the first discharge driven rollers 20b, 20b,. Has been.

  Further, due to the biasing force of the torsion coil spring described above, a force acts so that the third protrusion 701 of the connecting arm 700 pulls the upstream end of the third groove 223 of the first discharge stacker 500 upstream. Accordingly, a force is generated in the first discharge stacker 500 to rotate counterclockwise around a position where the rack 227 meshes with the pinion 219. The first protrusion 501 and the second protrusion 504 that are located on the opposite side of the third protrusion 701 with respect to the fulcrum by the force to rotate in the counterclockwise direction are the first groove 221 and It is pressed against the lower surface of the second groove 222. Accordingly, the posture of the first discharge stacker 500 can be further stabilized during movement.

  As shown in FIG. 16, when the pinion 219 further rotates clockwise from the state shown in FIG. 15, the first discharge stacker 500 further moves downstream in the transport direction. Then, the first discharge stacker 500 moves downstream in the transport direction, and the first discharge stacker 500 moves the discharge frame portion 800 through the connecting arm portion 700 against the biasing force of the torsion coil spring described above. Further, it is moved downstream in the transport direction.

  As shown in FIG. 17, when the pinion 219 further rotates clockwise from the state shown in FIG. 16, the pinion 219 attempts to move downward along the sixth groove portion 226. That is, the pinion 219 tries to move the first discharge stacker 500 upward via the rack 227. At this time, due to the biasing force of the torsion coil spring described above, a force is generated in the first discharge stacker 500 so as to rotate counterclockwise around a position engaging with the pinion 219 in the rack 227. Accordingly, when the pinion 219 rotates in the clockwise direction, the first discharge stacker 500 tilts so that the downstream end of the first discharge stacker 500 further rises with the first protrusion 501 as a fulcrum. Then, the contact surface 520 provided above the downstream side in the transport direction of the first discharge stacker 500 contacts the attitude regulating unit 228 of the base body 220.

  In a state where the contact surface 520 is in contact with the attitude regulating portion 228, the place where the third protrusion 701 and the third groove 223, which are the places where the biasing force of the torsion coil spring acts, is in the rack 227. It is located between a portion meshing with the pinion 219 and a portion in contact with the attitude regulating portion 228 on the contact surface 520. Therefore, the posture restricting portion 228 causes the contact surface to rotate in the counterclockwise direction with the urging force of the torsion coil spring as described above rotating about the position where the first discharge stacker 500 is engaged with the pinion 219 in the rack 227. It can be regulated by contacting with 520.

Further, when the pinion 219 is rotated in the clockwise direction, the movement of the first discharge stacker 500 on the downstream side in the conveyance direction is restricted by the attitude restriction unit 228, so that the first discharge stacker 500 has the downstream in the conveyance direction as a fulcrum. Move to lift the upstream side upward. At this time, the contact surface 520 contacts the posture restricting portion 228, and at the same time, the first discharge stacker 500 is restricted from rotating counterclockwise around the position where the rack 227 is engaged with the pinion 219. The first protrusion 501 and the second protrusion 504 are released from being pressed against the lower surfaces of the first groove 221 and the second groove 222, respectively. Accordingly, the pinion 219 rotates in the clockwise direction, and the first protrusion 501 and the second protrusion 504 move upward along the first groove 221 and the second groove 222, respectively.
Further, as the first discharge stacker 500 moves, the discharge frame portion 800 moves downstream in the transport direction.

As shown in FIG. 18, when the pinion 219 further rotates clockwise from the state shown in FIG. 17, the pinion 219 attempts to move the first discharge stacker 500 further upward via the rack 227. Accordingly, the first discharge stacker 500 moves so that the upstream end in the transport direction further rises with the downstream side in the transport direction as a fulcrum. That is, the inclination of the CD-R tray guide surface 523 of the first discharge stacker 500 with respect to the transport direction (Y) is decreased. At this time, the second projecting portion 504 and the second groove portion 222 are biased by the torsion coil spring described above in order to prevent the rack 227 from being separated from the pinion 219 by the biasing force of the torsion coil spring described above. Is provided so that the second protrusion 504 is always located on the opposite side of the rack 227 with respect to the pinion 219 while acting on the first discharge stacker 500.
Further, as the first discharge stacker 500 moves, the discharge frame portion 800 moves downstream in the transport direction.

As shown in FIG. 19, when the pinion 219 further rotates clockwise from the state shown in FIG. 18, the first discharge stacker 500 moves so that the upstream end in the transport direction further rises with the downstream side in the transport direction as a fulcrum. . At this time, the attitude regulating portion 228 of the base body portion 220 comes into contact with the contact protrusion 521 provided on the contact surface 520 of the first discharge stacker 500. The contact protrusion 521 always moves the first discharge stacker 500 to make the posture of the CD-R tray guide surface 523 of the first discharge stacker 500 parallel to the transport direction (Y). 228 and the first discharge stacker 500 are provided so as to be in contact with each other.
Further, as the first discharge stacker 500 moves, the discharge frame portion 800 moves downstream in the transport direction.

As shown in FIG. 20, when the pinion 219 further rotates clockwise from the state shown in FIG. 19, the first discharge stacker 500 moves so that the upstream end in the transport direction further rises with the downstream side in the transport direction as a fulcrum. . At this time, the second discharge driven rollers 503 and 503 provided on the upstream side in the transport direction of the first discharge stacker 500 move to a position near the downstream side in the transport direction of the discharge drive roller 20a on the base unit side.
Further, as the first discharge stacker 500 moves, the discharge frame portion 800 moves downstream in the transport direction.

  As shown in FIG. 21, when the pinion 219 further rotates clockwise from the state shown in FIG. 20, the first discharge stacker 500 moves so that the upstream end in the transport direction further rises with the downstream side in the transport direction as a fulcrum. . At this time, the second discharge driven rollers 503 and 503 provided on the upstream side in the transport direction of the first discharge stacker 500 are higher than the discharge drive roller 20a on the base portion side, and the second discharge driven roller The lower part of 503 and 503 moves to a position where it is substantially the same height as the upper part of the discharge drive roller 20a. At this time, the inclination, that is, the posture of the first discharge stacker 500 is such that the CD-R tray guide surface 523 of the first discharge stacker 500 is parallel to the transport direction (Y).

Here, “parallel” means that the CD-R tray Q can be guided to the recording unit 110 and the recorded CD-R tray Q can be received in the main scanning direction X and the conveyance direction (Y). On the other hand, it means being substantially parallel.
As the first discharge stacker 500 moves, the discharge frame portion 800 receives the biasing force of the torsion coil spring and moves upstream in the transport direction.

As shown in FIG. 22, when the pinion 219 further rotates clockwise from the state shown in FIG. 21, the pinion 219 tends to move along the sixth groove 226 downstream in the transport direction. That is, the pinion 219 tries to move the first discharge stacker 500 to the upstream side in the transport direction through the rack 227 in cooperation with the biasing force of the torsion coil spring described above. Therefore, the first discharge stacker 500 is guided by the engagement between the first protrusion 501 and the first groove 221 and is guided by the engagement between the second protrusion 504 and the second groove 222 while being guided in the transport direction. Move upstream. That is, the posture of the first discharge stacker 500 is regulated by the engagement between the first protrusion 501 and the first groove 221 and the engagement between the second protrusion 504 and the second groove 222. Accordingly, the CD-R tray guide surface 523 is translated in the upstream direction in the transport direction while maintaining a posture that is parallel to the transport direction (Y).
As the first discharge stacker 500 moves, the discharge frame portion 800 receives the biasing force of the torsion coil spring and moves upstream in the transport direction.

  Here, since the posture of the first discharge stacker 500 has already obtained the desired posture, the contact protrusion 521 of the first discharge stacker 500 is separated from the posture regulating portion 228 of the base body 220. In other words, when the first discharge stacker 500 moves in parallel, the posture regulating unit 228 is provided so as not to act on the first discharge stacker 500 at all. Accordingly, there is no possibility that the posture of the first discharge stacker 500 becomes unstable due to the frictional resistance generated between the posture restricting unit 228 and the first discharge stacker 500.

  In addition, due to the urging force of the torsion coil spring described above, a force that rotates the first discharge stacker 500 counterclockwise acts on a position where the first discharge stacker 500 meshes with the pinion 219 in the rack 227. Since the first protrusion 501 of the first discharge stacker 500 is pressed against the lower portion of the first groove portion 221 of the base body 220, the first discharge stacker 500 can hold the posture with high accuracy.

  The first discharge stacker 500 is stopped when the pinion 219 is stopped at a position where the lower portions of the second discharge driven rollers 503 and 503 of the first discharge stacker 500 are in contact with the upper portion of the discharge drive roller 20a on the base portion side. Stops. The stop position of the first discharge stacker 500 shown in FIG. 22 is the second position that the first discharge stacker 500 takes in the CD-R recording mode. At this time, the second discharge driven rollers 503 and 503 are biased so as to swing toward the discharge drive roller by a biasing force of a spring (not shown). Accordingly, in the CD-R recording mode, the second discharge driven rollers 503 and 503 cooperate with the discharge drive roller 20a to sandwich the CD-R tray Q, and to the upstream and downstream in the transport direction. Can be moved.

  The timing at which the pinion 219 stops is the direction in which the first driving stacker 500 is separated from the home position detector 230 as described above and the first motor is rotated by a predetermined number of steps and the discharging drive roller 20a is reversely rotated. It is provided to stop after being driven to. Therefore, the second position of the first discharge stacker 500 can be determined with high accuracy.

  As described above, the discharge stacker lifting / lowering device 200 moves so as to first draw the downstream side of the first discharge stacker 500 to the upper side and the downstream side of the discharge stacker lifting / lowering device 200 without coming into contact with the second discharge stacker 600. Next, the upstream side of the first discharge stacker 500 can be moved to be pulled up above the discharge stacker lifting device 200. That is, when the discharge stacker lifting / lowering device 200 moves from the first position to the second position, the discharge stacker lifting / lowering device 200 is located above the first placement portion 510 of the first discharge stacker 500 and the second placement portion 610 of the second discharge stacker 600. Even if the space is restricted by, for example, the bar guide 431, the first discharge stacker 500 can be moved.

[Movement of first discharge stacker from second position to first position]
When the CD-R recording mode is switched to the paper recording mode, the power transmission shown in FIG. 9 is connected from the state where the power transmission is cut by the power transmission switching device 400 shown in FIG. 7 as described above. At this time, the discharge drive roller 20a is driven forward, that is, the sun gear 426 rotates clockwise. Then, the power of the sun gear 426 is transmitted to the pinion 219 by the power transmission means 210. Accordingly, the pinion 219 rotates counterclockwise.

When the pinion 219 rotates counterclockwise from the state shown in FIG. 22, the pinion 219 tends to move along the sixth groove 226 upstream in the transport direction. In other words, the pinion 219 attempts to move the first discharge stacker 500 to the downstream side in the transport direction through the rack 227 against the biasing force of the torsion coil spring described above. Therefore, the first discharge stacker 500 is guided by the engagement between the first protrusion 501 and the first groove 221 and is guided by the engagement between the second protrusion 504 and the second groove 222 while being guided in the transport direction. Move downstream. At this time, the first discharge stacker 500 moves parallel to the downstream side in the transport direction while maintaining the posture in which the CD-R tray guide surface 523 is parallel to the transport direction (Y).
Further, as the first discharge stacker 500 moves, the discharge frame portion 800 moves downstream in the transport direction.

  As shown in FIG. 21, when the pinion 219 rotates counterclockwise from the state shown in FIG. 22, the first discharge stacker 500 moves downstream in the transport direction against the biasing force of the torsion coil spring. . At this time, the second discharge driven rollers 503 and 503 of the first discharge stacker 500 are separated from the discharge driving roller 20a on the base portion side. Further, the abutting protrusion 521 of the first discharge stacker 500 abuts on the attitude regulating portion 228 of the base portion 220 that has been separated. Then, the first protrusion 501 of the first discharge stacker 500 is separated from the lower surface of the first groove 221 by the shape of the first groove 221. Therefore, due to the urging force of the torsion coil spring described above, a force that causes the first discharge stacker 500 to rotate counterclockwise acts at a position where the first discharge stacker 500 meshes with the pinion 219 in the rack 227. At this time, the posture of the first discharge stacker 500 is regulated by the posture regulating unit 228 coming into contact with the contact projection 521.

As shown in FIG. 20, when the pinion 219 further rotates counterclockwise from the state shown in FIG. 21, the first discharge stacker 500 moves with the downstream side in the transport direction as a fulcrum so that the upstream end in the transport direction is lowered. . At this time, the second discharge driven rollers 503 and 503 provided on the upstream side in the transport direction of the first discharge stacker 500 move to a position near the downstream side in the transport direction of the discharge drive roller 20a on the base unit side.
As the first discharge stacker 500 moves, the discharge frame unit 800 moves upstream in the transport direction.

As shown in FIG. 19, when the pinion 219 further rotates counterclockwise from the state shown in FIG. 20, the first discharge stacker 500 moves so that the upstream end in the transport direction is further lowered with the downstream side in the transport direction as a fulcrum. To do. At this time, the positions of the second discharge driven rollers 503 and 503 of the first discharge stacker 500 are lower than the position of the discharge drive roller 20a on the base portion side.
As the first discharge stacker 500 moves, the discharge frame unit 800 moves upstream in the transport direction.

As shown in FIG. 18, when the pinion 219 further rotates counterclockwise from the state shown in FIG. 19, the first discharge stacker 500 moves so that the upstream end in the transport direction further descends with the downstream side in the transport direction as a fulcrum. To do. At this time, the posture regulating unit 228 of the base body 220 regulates the posture of the first discharge stacker 500 by being separated from the contact protrusion 521 of the first discharge stacker 500 and contacting the contact surface 520.
As the first discharge stacker 500 moves, the discharge frame unit 800 moves upstream in the transport direction.

  As shown in FIG. 17, when the pinion 219 further rotates counterclockwise from the state shown in FIG. 18, the first discharge stacker 500 moves so that the upstream end in the transport direction further descends with the downstream side in the transport direction as a fulcrum. To do. As the first discharge stacker 500 moves, the discharge frame unit 800 moves upstream in the transport direction.

As shown in FIG. 16, when the pinion 219 further rotates counterclockwise from the state shown in FIG. 17, the first discharge stacker 500 moves so that the upstream end in the transport direction further descends with the downstream side in the transport direction as a fulcrum. To do. At this time, the first protrusion 501 on the upstream side in the transport direction of the first discharge stacker 500 contacts the lower surface of the first groove 221 of the base body 220. As the pinion 219 rotates, the first discharge stacker 500 resists the force that the first discharge stacker 500 rotates counterclockwise due to the biasing force of the torsion coil spring described above. With the portion where 501 and the first groove 221 are in contact with each other as a fulcrum, it moves clockwise so that the downstream side in the transport direction of the first discharge stacker 500 is lowered. Accordingly, the contact surface 520 of the first discharge stacker 500 is separated from the attitude regulating portion 228 of the base body portion 220. At this time, the posture of the first discharge stacker 500 is such that the first protrusion 501 is brought into contact with the lower surface of the first groove 221 of the base body 220 by the force that the first discharge stacker 500 tries to rotate counterclockwise. It is regulated by hitting.
As the first discharge stacker 500 moves, the discharge frame unit 800 moves upstream in the transport direction.

As shown in FIG. 15, when the pinion 219 further rotates counterclockwise from the state shown in FIG. 16, the pinion 219 attempts to move along the sixth groove 226 downstream in the transport direction. That is, the pinion 219 tries to move the first discharge stacker 500 to the upstream side in the transport direction through the rack 227 in cooperation with the biasing force of the torsion coil spring described above. Therefore, the first discharge stacker 500 is guided by the engagement between the first protrusion 501 and the first groove 221 and is guided by the engagement between the second protrusion 504 and the second groove 222 while being guided in the transport direction. Move upstream. At this time, the posture of the first discharge stacker 500 is regulated by the engagement between the first protrusion 501 and the first groove 221 and the engagement between the second protrusion 504 and the second groove 222. That is, the first discharge stacker 500 moves parallel to the upstream side while maintaining the posture in which the upstream side in the transport direction is lowered and the downstream side is raised.
Further, as the first discharge stacker 500 moves, the discharge frame portion 800 is engaged by the engagement between the fourth protrusion 801 and the fourth groove 224 and the engagement between the fifth protrusion 802 and the fifth groove 225. It is guided and moves downward in the conveying direction and downward.

As shown in FIG. 14, when the pinion 219 further rotates counterclockwise from the state shown in FIG. 15, the first discharge stacker 500 engages with the first protrusion 501 and the first groove 221 and the second protrusion. While being guided by the engagement between the portion 504 and the second groove 222, the upstream side in the transport direction is lowered and the downstream side is raised, and the translation is performed in the upstream direction. Further, the discharge frame portion 800 moves with the movement of the first discharge stacker 500, and the lower portions of the first discharge driven rollers 20b, 20b,. It contacts the upper part of 20a. At this time, the fourth projecting portion 801 and the fifth projecting portion 802 of the discharge frame portion 800 hit the upstream ends of the fourth groove portion 224 and the fifth groove portion 225 of the base portion 220 in the conveying direction, respectively, and the discharge frame portion 800 stops To do.
Further, the fourth projecting portion 801 and the fifth projecting portion 802 hit the upstream ends in the conveying direction of the fourth groove portion 224 and the fifth groove portion 225 of the base body portion 220, respectively. It does not reach the first discharge stacker 500.

As shown in FIG. 13, when the pinion 219 further rotates counterclockwise from the state shown in FIG. 14, the first discharge stacker 500 moves parallel to the upstream side in the transport direction. At this time, the discharge frame portion 800 is held in a stopped state by the biasing force of the torsion coil spring described above. Accordingly, the third protrusion 701 of the connecting arm 700 moves away from the upstream end in the transport direction of the third groove 223 of the first discharge stacker 500 and moves downstream.
Here, the first discharge stacker 500 is provided to move in parallel to the upstream side in the transport direction until the downstream end in the transport direction of the first discharge stacker 500 is located upstream from the upstream end of the second discharge stacker 600. It has been.

  As shown in FIG. 12, when the pinion 219 further rotates counterclockwise from the state shown in FIG. 13, the pinion 219 attempts to move upward along the sixth groove portion 226. That is, the pinion 219 tries to move the first discharge stacker 500 downward through the rack 227. Accordingly, the first discharge stacker 500 rotates clockwise with the first protrusion 501 as a fulcrum so that the downstream end in the transport direction is lowered and the height difference between the upstream end and the downstream end is reduced.

As shown in FIG. 11, when the pinion 219 further rotates counterclockwise from the state shown in FIG. 12, the first discharge stacker 500 descends at the downstream end in the transport direction with the first protrusion 501 as a fulcrum. And turn clockwise so that the difference in height between the downstream end and the downstream end is further reduced.
As shown in FIG. 10, when the pinion 219 further rotates counterclockwise from the state shown in FIG. 11, the first discharge stacker 500 descends with the first protrusion 501 as a fulcrum and the downstream end in the transport direction descends to the upstream end. And turn clockwise so that the difference in height between the downstream end and the downstream end is further reduced. At this time, the first discharge stacker 500 contacts the home position detector 230. Then, the home position detector 230 detects the first discharge stacker 500, stops the driving of the first motor, and stops the rotation of the pinion 219. Accordingly, the first discharge stacker 500 is accurately positioned at the first position.

  As described above, the discharge stacker lifting / lowering device 200 moves so as to push the upstream side of the first discharge stacker 500 into the lower side and upstream of the discharge stacker lifting / lowering device 200 without coming into contact with the second discharge stacker 600. Then, the downstream side of the first discharge stacker 500 can be moved so as to be pushed below the discharge stacker lifting device 200. That is, when the discharge stacker lifting / lowering device 200 moves from the second position to the first position, the first stacker 510 of the first discharge stacker 500 and the second stacker 610 of the second discharge stacker 600 are located above. Even if the space is restricted by, for example, the bar guide 431, the first discharge stacker 500 can be moved.

  Further, when the first discharge stacker 500 moves from the second position to the first position, the discharge drive roller 20a is driven to rotate forward. The forward rotation means a clockwise rotation in FIGS. Accordingly, even when the CD-R tray Q is sandwiched between the discharge drive roller 20a and the second discharge driven rollers 503 and 503, that is, when the CD-R tray Q is not normally discharged after recording, the discharge drive roller 20a. The second discharge driven rollers 503 and 503 can cooperate to move the CD-R tray Q to the downstream side in the transport direction. Then, the CD-R tray Q is not nipped by the discharge drive roller 20a and the second discharge driven rollers 503 and 503. As a result, the CD-R tray Q is moved to the first position while the CD-R tray Q is nipped between the discharge driving roller 20a and the second discharge driven rollers 503 and 503, whereby the CD-R tray Q is moved to the first position. There is no risk of the tray Q being damaged. Further, when the first discharge stacker 500 moves from the second position to the first position, the discharge drive roller 20a and the second discharge driven rollers 503 and 503 do not have the possibility of involving the CD-R tray Q. This is effective when the user leaves the CD-R tray Q in the CD-R tray guide opening of the first discharge stacker 500.

  Further, since only the first discharge stacker 500 is moved instead of the entire discharge stacker 50, the weight of the moved member is lighter than when the entire discharge stacker 50 is moved. Therefore, the power source can be reduced in size accordingly.

[Opening and closing the second discharge stacker]
23 to 25 are side views showing opening and closing of the second discharge stacker according to the present invention. 23 shows a state in which the second discharge stacker is closed, FIG. 24 shows a state in the middle of opening, and FIG. 25 shows an open state.

  As shown in FIG. 23, when the power is turned off, the first discharge stacker 500 is provided so as to be located at the first position, and the second discharge stacker 600 is in a state where the placement opening 260 is closed. The second discharge stacker 600 is configured to be kept closed by a lock lever (not shown) with a spring force. When the power source is switched on and the CD-R recording mode is selected, the first discharge stacker 500 moves from the first position to the second position as described above.

  As shown in FIG. 24, when the first discharge stacker 500 moves from the first position to the second position, the first discharge stacker 500 moves upward and then moves downstream in the transport direction. At this time, the downstream end in the transport direction of the first discharge stacker 500 abuts and presses against the second placement portion 610 on the front end side from the cover shaft 601 of the second discharge stacker 600. Accordingly, the second discharge stacker 600 rotates in the clockwise direction in the drawing with the cover shaft 601 as a fulcrum.

As shown in FIG. 25, when the second discharge stacker 600 is pushed by the first discharge stacker 500 and pivots clockwise to some extent, the second discharge stacker 600 is slowly rotated by its own weight and a damper (not shown) that resists its own weight. Keep doing. Then, the second discharge stacker 600 comes into contact with the cover restricting portion 250 of the base portion 220 and stops. That is, when the CD-R recording mode is selected, the second discharge stacker 600 is automatically opened even when it is closed.
As described above, when the CD-R recording mode is selected, the user sets the CD-R tray Q in the closed state in order to set the CD-R tray Q in the CD-R tray guide opening 522 of the first discharge stacker 500. There is no need to manually open the stacker 600.
Of course, the user can manually open and close the second discharge stacker.

[CD-R recording mode]
FIG. 26 is a schematic side view showing a second position of the first discharge stacker according to the present invention. FIG. 26 is also a schematic side view of the state shown in FIG.
As shown in FIG. 26, when the first discharge stacker 500 is in the second position, the CD-R tray Q is inserted from the CD-R tray guide opening 522 along the CD-R tray guide surface 523. When set in the set position shown in FIG. 6, the upstream end in the transport direction of the CD-R tray Q is sandwiched between the discharge driving roller 20a and the second discharge driven rollers 503 and 503 as shown in FIG. It becomes a state.

Thereafter, the paper is sent upstream in the transport direction by the reverse drive of the discharge driving roller 20a. Then, the downstream end in the transport direction of the CD-R attached to the CD-R tray Q stops at a position facing the recording head 13, that is, a so-called recording start position. Thereafter, the ejection drive roller 20a is driven to rotate in the forward direction, and the recording head 13 is scanned in the main scanning direction X while the CD-R tray Q is moved downstream in the transport direction, and recording is performed on the CD-R label. To do. When the recording is completed, the discharge driving roller 20a and the second discharge driven rollers 503 and 503 cooperate to discharge the CD-R tray Q to the downstream side in the transport direction. At this time, the upstream end in the transport direction of the CD-R tray Q is disengaged from the nip between the discharge driving roller 20a and the second discharge driven rollers 503 and 503, so that the CD-R tray Q is CD- The CD-R tray Q stops at a position protruding further than the position where a part of the CD-R tray Q protrudes from the R tray guide opening 522.
Of course, instead of the CD-R tray, the sheet may be manually set in the CD-R tray guide opening of the first discharge stacker.

  The discharge stacker lifting / lowering device 200 of the present embodiment ejects ink from the recording head 13 provided in the recording unit 110 which is an example of a liquid ejecting unit, and the sheet P and the second medium P which are non-rigid media as a first medium. The recording apparatus 100 for recording on a CD-R tray Q to which a CD-R which is a rigid medium as a medium is mounted, a first position on which the recorded paper P is placed, and the paper P and the CD-R tray Q. And a discharge stacker lifting device 200 including a first discharge stacker 500 that moves to a second position for receiving the recorded paper P and the CD-R tray Q. When the first discharge stacker 500 moves from the first position to the second position, the first discharge stacker 500 moves to the downstream side in the transport direction during recording, and then the width of the paper P and the CD-R tray Q to be recorded. CD that is a medium guide surface that moves in a direction perpendicular to the main scanning direction X and the conveyance direction (Y) and that is provided in the first discharge stacker 500 and guides the paper P and the CD-R tray Q. The posture of the −R tray guide surface 523 is configured to be parallel to the main scanning direction X and the conveyance direction (Y).

  Further, in the discharge stacker lifting / lowering device 200 of the present embodiment, the second discharge stacker 600 for placing the paper P together with the first discharge stacker 500 is located downstream in the transport direction of the first discharge stacker 500 at the first position. When the first discharge stacker 500 is moved from the first position to the second position, first, the position of the first discharge stacker 500 on the downstream side in the transfer direction is transferred to the second discharge stacker 600. The first discharge stacker 500 is raised to a position higher than the upstream side in the direction to tilt the posture of the first discharge stacker 500. Next, the first discharge stacker 500 with the tilted posture is moved to the downstream side in the transport direction. The upstream side in the conveyance direction of 500 is configured to be raised so that the posture of the CD-R tray guide surface 523 of the first discharge stacker 500 is parallel to the above.

  Further, in the present embodiment, a discharge drive roller 20a for moving the paper P and the CD-R tray Q in the transport direction (Y) is provided on the base side of the discharge stacker lifting device 200, and the discharge drive roller The discharge frame portion 800 including the first discharge driven rollers 20b, 20b,... That sandwich the paper P in cooperation with the 20a is connected to the first discharge stacker 500, and the first discharge stacker 500 is connected to the first discharge stacker 500. The first discharge driven rollers 20b, 20b,... Are moved in a direction away from the discharge drive roller 20a in accordance with the movement from the first position to the second position. And

  The first discharge stacker 500 of the present embodiment includes second discharge driven rollers 503 and 503, and moves in the main scanning direction X and the transport direction (Y) when moving from the first position to the second position. To move the discharge drive roller 20a and the second discharge driven rollers 503 and 503 in cooperation after the CD-R tray guide surface 523 is moved in the direction perpendicular to the CD-R tray and the posture of the CD-R tray guide surface 523 becomes parallel. In addition, it is configured to move to the upstream side in the transport direction.

  In the present embodiment, the first discharge stacker 500 moves upward, which is a direction orthogonal to the main scanning direction X and the transport direction (Y), and the posture of the CD-R tray guide surface 523 is parallel to the above. The first discharge stacker 500 moves downstream in the transport direction before the first discharge stacker 500 moves upward, which is a direction orthogonal to the main scanning direction X and the transport direction (Y). It is characterized by being configured to be shorter than the distance to move to.

In the present embodiment, the second medium is a CD-R tray Q as a disk tray in a state where an information storage medium disk that is a rigid medium is held, and the second discharge driven rollers 503 and 503 are for discharge. Further, in the present embodiment, a rack 227 is provided on the first discharge stacker side, and the discharge stacker is provided so as to sandwich only the CD-R tray Q in cooperation with the drive roller 20a. A pinion 219 that transmits power to the rack 227 is provided on the base unit side of the lifting device 200. The first discharge stacker 500 is moved along the rack 227 in the main scanning direction X and the transport direction (by the rack 227 and the pinion 219). It is configured to move in the vertical direction, which is a direction orthogonal to Y), and in the transport direction (Y).
The first discharge stacker 500 is moved between the first position and the second position by using a driving force of a first motor that drives the discharge driving roller 20a. It is characterized by being.

In the discharge stacker lifting / lowering device 200 of the present embodiment, the first discharge stacker 500 is moved from the second position to the first position by the forward rotation of the first motor, and the first discharge stacker 500 is moved to the first position. When moving from the position 2 to the first position, the discharging drive roller 20a is configured to rotate forward.
Furthermore, in the present embodiment, the recording apparatus 100 automatically switches and adjusts the sheet P and the PG that is the gap between the CD-R tray Q and the recording unit 110 during recording by the driving force of the second motor. An adjustment device 300 is provided, and the recording unit gap adjustment device 300 is configured to move the first discharge stacker 500 by switching power transmission from the first motor to the first discharge stacker 500 when switching and adjusting PG. It is characterized by being.

In this embodiment, a pair of racks 227 and pinions 219 are provided on both sides in the main scanning direction X, which is the width direction with respect to the transport direction (Y), and the driving force of one pinion 219 is applied to the other pinion on the base portion side. The power transmission shaft 270 which is the power transmission means 210 which transmits to 219 is provided.
Further, the second discharge stacker 600 of the present embodiment is provided so as to open and close the placement opening 260 where the paper P and the CD-R tray Q are discharged by the discharge drive roller 20a. .

  In the present embodiment, a rack is provided on one surface (the upper surface in FIGS. 10 to 22) of the sixth groove portion, and the first discharge stacker is moved by the forward / reverse drive of the first motor. Racks may be provided on the upper surface and the lower surface of the first motor, and the first motor may be normally driven to move the first discharge stacker to the first position and the second position. That is, the pinion is engaged with the rack on the lower surface side, the first discharge stacker is moved from the first position to the second position, the pinion is engaged with the rack on the upper surface side, and the first discharge stacker is moved to the second position. You may comprise so that it may move to a 1st position from a position. In such a case, it is possible to always prevent the CD-R tray from being caught.

In the present embodiment, the relationship between the first position and the second position is such that the first position is upstream in the transport direction and downward in the vertical direction, and the second position is downstream in the transport direction and upward in the vertical direction. However, the positional relationship is not limited thereto.
Furthermore, in this embodiment, the rack and the pinion are synchronized in the same shape on the left and right, but the left and right shapes and positions may be different. In such a case, the posture of the first discharge stacker can always be regulated.
The present invention is not limited to the above-described embodiments, and various modifications are possible within the scope of the invention described in the claims, and it goes without saying that these are also included in the scope of the present invention. Yes.

[Other Embodiments]
[About position control means]
FIG. 27 to FIG. 30 show position restricting means according to another embodiment. 27 is an enlarged perspective view of the restricted state viewed from the upstream side in the transport direction, FIG. 28 is an enlarged side view of the state before the restriction, and FIG. 29 is an enlarged side view of the restricted state. FIG. 30 is a plan view.
As shown in FIGS. 27 to 29, a first discharge stacker 1500 according to another embodiment includes a position restricting means 560 that restricts the position and posture of the first discharge stacker 1500 at the second position.

The position restricting means 560 includes a position restricting base 562 that is integrally formed on the base side of the first discharge stacker 1500, and a position restricting lever 561 that rotates around a lever rotation shaft 563. That is, the position restricting means 560 is provided in a bifurcated shape in which one is rotated. One end of the lever biasing spring 566 is engaged with the lever side spring engaging portion 564 of the position regulating lever 561, and the other end is engaged with the discharge stacker side spring engaging portion 570 on the base side of the first discharge stacker 1500. Are combined. Therefore, the position restricting lever 561 is always urged toward the position restricting base, that is, the direction in which the fork is closed, and is closed when no other force is applied.
The discharge stacker elevating device 1200 and the first discharge stacker 1500 of the other embodiments are the same as those of the above-described embodiment except for the position regulating means 560. Further, since the other members are the same as those in the above-described embodiment, the same reference numerals are used and the description thereof is omitted.

Next, the operation will be described.
When the first discharge stacker 1500 is moved from the first position to the second position as shown in FIGS. 21 to 22 as in the above-described embodiment, first, as shown in FIG. The lever inclined portion 565 provided on the shaft abuts on the shaft 20c of the discharging drive roller 20a. As the first discharge stacker 1500 moves, the shaft 20c of the discharge drive roller 20a rotates the position regulating lever 561 so that the fork is opened against the biasing force of the lever biasing spring 566.

  When the movement to the second position is completed, as shown in FIG. 29, the shaft 20c of the ejection drive roller 20a contacts the position restriction lever 561 and the position restriction base 562. That is, the position restricting means 560 sandwiches the shaft 20c of the discharge drive roller 20a by the position restricting base 562 and the position restricting lever 561 while being biased by the biasing force of the lever biasing spring 566, and the position restricting base 562 and the discharge. The position and posture of the first discharge stacker 1500 are regulated based on the position of the contact portion with the shaft 20c of the driving roller 20a.

Therefore, the second discharge driven rollers 503 and 503 provided on the first discharge stacker side can be accurately positioned with respect to the discharge drive roller 20a. In particular, positioning can be performed with high accuracy in a direction orthogonal to the main scanning direction X and the transport direction (Y). As a result, the CD-R tray Q can be securely held and moved in the transport direction.
When the position is restricted, first, the position restriction lever 561 on the lower side of the bifurcated position restriction means 560, that is, the first position side is provided so as to contact the shaft 20c of the discharge drive roller 20a. It has been. Therefore, when the movement of the first discharge stacker 1500 from the first position to the second position is completed, it is possible to prevent so-called overshooting in which the upstream side in the transport direction of the first discharge stacker 1500 rises excessively.
Furthermore, in the second position, the parallelism of the CD-R tray guide surface 523 with respect to the width direction and the conveyance direction of the paper P and the CD-R tray Q to be recorded can be further improved.

When the first discharge stacker 1500 moves from the second position to the first position, the state shown in FIG. 29 (FIG. 22) to FIG. 28 (FIG. 21) is obtained. That is, with the movement of the first discharge stacker 1500, the shaft 20c of the discharge drive roller 20a is released from the clamping of the bifurcated position restricting means 560. Therefore, the position restricting lever 561 is turned to the position restricting base side by the biasing force of the lever biasing spring 566 and the bifurcated state is closed. And the position control means 560 moves to a 1st position with the closed state. Therefore, there is no possibility of colliding with other members during movement, and there is no possibility of disturbing the arrangement of the feeding cassette 30 (see FIGS. 1 to 9) provided below. That is, the limited space can be used effectively by moving the position restricting means 560 in the closed state.
Of course, if there is enough space, the position restricting means 560 may be provided in a bifurcated shape that does not close, that is, a U-shape.

In addition, as shown in FIG. 30, the position restricting means 560 is in the vicinity of the second discharge driven rollers 503 and 503 in the main scanning direction X of the first discharge stacker 1500, and is in the CD-R tray Q conveyance path ( It is provided outside the CD-R tray guide surface 523). Therefore, the second discharge driven rollers 503 and 503 can be positioned more accurately with respect to the shaft 20c of the discharge drive roller 20a.
Note that it is desirable to provide the position restricting means 560 at two locations on both sides outside the CD-R tray Q conveyance path (CD-R tray guide surface 523).

The discharge stacker lifting / lowering device 1200 according to another embodiment includes a position restricting unit 560 that restricts the position and posture of the first discharge stacker 1500 at the second position.
Further, the position regulating means 560 of another embodiment is provided in a bifurcated shape, and is moved when the first discharge stacker 1500 moves from the first position to the second position and moves upstream in the transport direction. In this case, the position restricting means 560 is configured to sandwich the shaft 20c of the discharge driving roller 20a.

In the discharge stacker lifting / lowering device 1200 of another embodiment, only the position restriction lever 561 which is the first position side portion of the bifurcated shape of the position restriction means 560 is provided so as to be swingable, and serves as an urging means. A biasing force of a lever biasing spring 566 biases the fork to close.
In the discharge stacker lifting / lowering device 1200 according to another embodiment, when the first discharge stacker 1500 moves from the first position to the second position, the position restriction lever 561 among the bifurcated shapes of the position restriction means 560. Is configured to contact the shaft 20c of the discharge driving roller 20a first.

FIG. 2 is a perspective view showing the appearance of an inkjet printer. The perspective view which removes a casing and shows the internal structure of an inkjet printer. FIG. 3 is a side sectional view showing an outline of the internal structure of the ink jet printer. The perspective view (1st position) which shows the paper recording mode of the discharge | emission stacker raising / lowering apparatus which concerns on this invention. The perspective view (2nd position) which shows CD-R recording mode of the discharge | emission stacker raising / lowering apparatus which concerns on this invention. The perspective view which shows the state which set the CD-R tray in CD-R recording mode (2nd position). The schematic side view (cutting) which shows the power transmission to the discharge | emission stacker raising / lowering apparatus which concerns on this invention. The schematic side view (reverse rotation) which shows the power transmission to the discharge | emission stacker raising / lowering apparatus which concerns on this invention. The schematic side view (forward rotation) which shows the power transmission to the discharge | emission stacker raising / lowering apparatus which concerns on this invention. The side view (1st position) which shows the movement of the 1st discharge | emission stacker of the discharge | emission stacker raising / lowering apparatus which concerns on this invention. The side view which shows the movement of the 1st discharge stacker concerning the present invention (downstream end rise). The side view which shows the movement of the 1st discharge stacker concerning the present invention (downstream end rise). The side view which shows the movement of the 1st discharge stacker concerning the present invention (moving downstream). The side view which shows the movement of the 1st discharge stacker concerning the present invention (moving downstream). The side view which shows the movement of the 1st discharge stacker concerning the present invention (moving downstream). The side view which shows the movement of the 1st discharge stacker concerning the present invention (moving downstream). The side view which shows the movement of the 1st discharge stacker concerning the present invention (upstream end rise). The side view which shows the movement of the 1st discharge stacker concerning the present invention (upstream end rise). The side view which shows the movement of the 1st discharge stacker concerning the present invention (upstream end rise). The side view which shows the movement of the 1st discharge stacker concerning the present invention (upstream end rise). The side view which shows the movement of the 1st discharge stacker concerning the present invention (moving to the upstream side). The side view (2nd position) which shows the movement of the 1st discharge stacker concerning the present invention. The side view (closed state) which shows opening and closing of the 2nd discharge stacker concerning the present invention. The side view which shows opening and closing of the 2nd discharge stacker which concerns on this invention. The side view (open state) which shows opening and closing of the 2nd discharge stacker concerning the present invention. The side view which shows the 2nd position of the 1st discharge stacker concerning the present invention. The expansion perspective view which shows the position control means which concerns on other embodiment. The enlarged side view (before regulation) showing the position regulation means concerning other embodiments. The expansion perspective view (regulation state) which shows the position control means concerning other embodiments. The top view which shows the position control means which concerns on other embodiment.

Explanation of symbols

2 Automatic feeding device, 3 Printer body (recording device body), 4 Scanner device,
5 Feed tray, 6 Front panel, 7 LCD monitor screen, 8 Operation buttons,
9 Memory card insertion part, 10 Carriage, 11 Endless belt,
12 Carriage guide shaft, 13 Recording head, 14 Feeding roller,
15 edge guide, 16 hopper, 17 rotating shaft (for feeding roller),
18 roller holder (for driven roller for conveyance), 19 roller for conveyance,
19a Carrying drive roller, 19b Carrying driven roller, 20 Ejecting roller,
20a discharge driving roller, 20b first discharge driven roller,
20c (discharge drive roller) shaft, 22 discharge auxiliary driven roller,
26 recording positions, 28 platens, 30 feeding cassettes,
50 discharge stacker, 51 mounting surface, 100 inkjet printer (recording device),
110 recording unit, 120 discharge unit, 200 discharge stacker lifting device,
210 power transmission means, 211 first gear, 212 second gear, 213 third gear,
214 4th gear, 215 5th gear, 216 6th gear, 217 7th gear,
218, eighth gear, 219 pinion, 220 base, 221 first groove,
222 2nd groove, 223 3rd groove, 224 4th groove, 225 5th groove,
226 6th groove part, 227 rack, 228 posture regulation part,
230 home position detector, 250 cover restricting section, 260 mounting opening,
270 power transmission shaft, 300 recording unit gap adjusting device,
301 PG adjustment cam part, 301a arc part, 301b string part, 302 camshaft,
303 lever contact portion, 304 lever member, 305 lever shaft,
400 power transmission switching device, 410 lock lever, 420 planetary gear holder,
423 first planetary gear, 424 second planetary gear, 425 rotation fulcrum shaft (sun gear),
426 sun gear, 430 slide bar, 431 bar guide,
500 first discharge stacker, 501 first protrusion, 502 swing shaft,
503 second discharge driven roller, 504 second protrusion, 510 first mounting portion,
520 contact surface, 521 contact protrusion, 522 CD-R tray guide opening,
523 CD-R tray guide surface, 560 position restriction means, 561 position restriction lever,
562 position restriction base, 563 lever rotation shaft, 564 lever side spring engagement portion,
565 Lever inclined portion, 566 lever biasing spring, 570 discharge stacker side spring engaging portion,
600 second discharge stacker, 601 cover shaft, 610 second mounting portion,
700 connecting arm portion, 701 third protrusion, 800 discharge frame portion,
801 4th projection, 802 5th projection,
1200 discharge stacker lifting device (of other embodiments),
1500 (of other embodiments) first discharge stacker, C ink cartridge,
P paper (recording material), Q CD-R tray, X main scanning direction, Y sub-scanning direction,
PG gap

Claims (18)

A first position on which a first medium recorded in a recording apparatus for recording ink on a first medium and a second medium by discharging ink from a recording head provided in the recording unit, and the first medium And a second medium are guided to a recording unit, and the discharge stacker lifting device includes a first discharge stacker that moves to a second position for receiving the recorded first medium and second medium. And
When the first discharge stacker moves from the first position to the second position,
Move downstream in the transport direction during recording,
Thereafter, the recording medium moves in a direction perpendicular to the width direction and the transport direction of the first medium and the second medium to be recorded, and is provided in the first discharge stacker, and the first medium and the second medium are A discharge stacker lifting apparatus characterized in that a posture of a medium guiding surface to be guided is configured to be parallel to a width direction and a conveying direction of a first medium and a second medium to be recorded. 2. The discharge stacker lifting device according to claim 1, wherein a second discharge stacker for placing a first medium together with the first discharge stacker is disposed downstream of the first discharge stacker in the transport direction at the first position. Arranged,
When the first discharge stacker moves from the first position to the second position,
First, the position of the first discharge stacker on the downstream side in the transport direction is raised to a position higher than the upstream side of the second discharge stacker in the transport direction, and the posture of the first discharge stacker is tilted.
Next, the first discharge stacker whose posture is inclined is moved downstream in the transport direction,
Thereafter, the discharge stacker lifting device is configured to raise the upstream side in the transport direction of the first discharge stacker so that the posture of the medium guide surface of the first discharge stacker is parallel to the parallel direction. . The discharge stacker lifting apparatus according to claim 1 or 2, wherein a discharge driving roller for moving the first medium and the second medium in the transport direction is provided on the base portion side of the discharge stacker lifting apparatus.
A discharge frame portion including a first discharge driven roller that holds the first medium in cooperation with the discharge drive roller is connected to the first discharge stacker, and the first discharge stacker is connected to the first discharge stacker. A discharge stacker elevating device, wherein the first discharge driven roller is moved in a direction away from the discharge drive roller as it moves from a position to the second position. . 4. The discharge stacker lifting device according to claim 1, wherein the first discharge stacker includes a second discharge driven roller. 5.
When moving from the first position to the second position, the medium guide surface is moved in a direction perpendicular to the width direction and the transport direction of the first medium and the second medium to be recorded. The discharge stacker is moved up and down in the conveying direction so that the discharge driving roller and the second discharge driven roller cooperate with each other after the parallel movement of the discharge drive roller and the second discharge driven roller. apparatus.   5. The discharge stacker lifting apparatus according to claim 4, further comprising position restricting means for restricting a position and a posture of the first discharge stacker at the second position. The discharge stacker lifting device according to claim 5, wherein the position restricting means is bifurcated.
When the first discharge stacker moves from the first position to the second position and moves upstream in the transport direction, the position restricting means holds the shaft of the discharge drive roller. A discharge stacker lifting apparatus characterized by being configured as described above.   The discharge stacker lifting / lowering device according to claim 6, wherein, of the bifurcated shape of the position regulating means, only the first position side portion is provided so as to be swingable, and is urged so that the bifurcated is closed by the urging means. A discharge stacker elevating device characterized by being provided.   8. The discharge stacker lifting device according to claim 7, wherein when the first discharge stacker moves from the first position to the second position, the first position side of the bifurcated shape of the position restricting means. The discharge stacker lifting device is characterized in that the portion is configured to contact the shaft of the discharge drive roller first. The discharge stacker lifting apparatus according to any one of claims 4 to 8, wherein the first discharge stacker is orthogonal to the width direction and the conveyance direction of the first medium and the second medium to be recorded. After moving to and the posture of the medium guide surface becomes parallel, the distance to move upstream in the transport direction is
The first discharge stacker is shorter than the distance traveled downstream in the transport direction before moving in the direction perpendicular to the width direction and transport direction of the first medium and the second medium to be recorded. A discharge stacker lifting device characterized by being configured. The discharge stacker lifting apparatus according to any one of claims 4 to 9, wherein the second medium is a disk tray that holds an information storage medium disk that is a rigid medium.
The discharge stacker elevating device, wherein the second discharge driven roller is provided so as to sandwich only the disk tray in cooperation with the discharge drive roller. In the discharge stacker raising / lowering device according to any one of claims 1 to 10, a rack provided on the first discharge stacker side;
Provided on the base portion side of the discharge stacker lifting device, and includes a pinion for transmitting power to the rack,
The first discharge stacker is moved by the rack and the pinion in a direction perpendicular to the width direction and the conveyance direction of the first medium and the second medium recorded along the rack, and in the conveyance direction. A discharge stacker lifting apparatus characterized by being configured as described above.   12. The discharge stacker lifting / lowering device according to claim 3, wherein the movement of the first discharge stacker between the first position and the second position drives the discharge drive roller. A discharge stacker elevating device characterized in that it is configured to use the driving force of the first motor. The discharge stacker lifting device according to claim 12, wherein the first discharge stacker moves from the second position to the first position by forward rotation of the first motor,
The discharge stacker elevating apparatus, wherein the discharge drive roller is configured to rotate forward when the first discharge stacker moves from the second position to the first position. 14. The discharge stacker lifting / lowering device according to claim 12 or 13, wherein the recording device automatically switches and adjusts a gap between the first medium and the second medium and the recording unit during recording by a driving force of a second motor. Including a recording unit gap adjusting device,
The recording unit gap adjusting device is configured to switch power transmission from the first motor to the first discharge stacker to move the first discharge stacker when switching and adjusting the gap. A discharge stacker lifting device. The discharge stacker lifting device according to any one of claims 11 to 14, wherein the rack and the pinion are provided in a pair on both sides in the width direction with respect to the transport direction,
A discharge stacker lifting device characterized in that a power transmission portion for transmitting the driving force of one pinion to the other pinion is provided on the base portion side.   16. The discharge stacker lifting / lowering apparatus according to claim 2, wherein the second discharge stacker is provided to open and close a mounting opening through which the first medium and the second medium are discharged. A discharge stacker lifting device characterized by that. A recording unit that performs recording on a recording medium by the recording head; and
A recording apparatus comprising: a discharge unit that discharges the recording medium from the recording unit to the downstream side in the transport direction;
A recording apparatus comprising the discharge stacker lifting device according to any one of claims 1 to 16. A first position on which a first medium on which a liquid is ejected is placed in a liquid ejecting apparatus that ejects liquid onto a first medium and a second medium from a liquid ejecting head provided in the liquid ejecting section; A first discharge stacker that guides the medium and the second medium to the liquid ejecting unit and moves to a second position for receiving the first medium and the second medium ejected with the liquid. A liquid ejecting apparatus including a stacker lifting device,
When the first discharge stacker moves from the first position to the second position,
Move to the downstream side in the transport direction during liquid injection,
Thereafter, the recording medium moves in a direction perpendicular to the width direction and the transport direction of the first medium and the second medium to be recorded, and is provided in the first discharge stacker, and the first medium and the second medium are A liquid ejecting apparatus, characterized in that a posture of a medium guiding surface to be guided is configured to be parallel to a width direction and a conveying direction of a first medium and a second medium to be recorded.

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