The present application is based on, and claims priority from JP Application Serial Number 2018-197311, filed Oct. 19, 2018, the disclosure of which is hereby incorporated by reference herein in its entirety.
The present disclosure relates to a media folding device that folds media and a control method for the media folding device.
Some media processing devices that perform predetermined processing on media are, after performing saddle-stitch processing to bind the width-direction center of a plurality of stacked media, configured to be able to form a booklet by performing fold processing to fold the media at binding positions.
Further, such media processing devices may be incorporated into a recording system that is capable of continuously performing processing from recording on media by a recording device represented by an ink jet printer to saddle stitch processing and fold processing of the media after recording has been performed thereon.
Some such media processing devices are configured to include, for example, a folding roller pair and a blade for pushing media between the folding roller pair as a media folding device that performs folding processing, as illustrated in JP-A-2012-082075.
The media folding device described in JP-A-2012-082075, after the media have been pushed between the folding roller pair by the blade, pulls out only the blade from between the folding roller pair and performs fold processing in which the media are pressed and folded by rotation of the folding roller pair.
At this time, when the blade that has been pushed into the folding roller pair along with the media is pulled out, marks of the blade may be left as scratches on the media.
In addition, because the blade is sandwiched between the folding roller pair, the blade is formed in a comb-tooth shape that avoids the binding positions of the media; however, when the media are pushed in with such a comb-shaped blade, wrinkles may occur in the media.
According to an aspect of the present disclosure, a media folding device includes a stacking portion on which media transported from an introduction path are placed; a folding roller pair that folds the media at a folding position after the media have been stacked in the stacking portion; and a bend forming mechanism that includes a first abutting portion configured to abut against a front end of the media, which are stacked in the stacking portion, in a transport direction, and a second abutting portion that is configured to abut against a rear end of the media, which are stacked in the stacking portion, in the transport direction, and that causes the folding position of the media to be nipped by the folding roller pair by shortening the relative distance between the first abutting portion and the second abutting portion to bend the media toward the folding roller pair.
Hereinafter, the present disclosure will be schematically described.
A media folding device according to a first aspect includes a stacking portion on which media transported from an introduction path are placed; a folding roller pair that folds the media at a folding position after the media have been stacked in the stacking portion; and a bend forming mechanism that includes a first abutting portion configured to abut against a front end of the media, which are stacked in the stacking portion, in a transport direction, and a second abutting portion that is configured to abut against a rear end of the media, which are stacked in the stacking portion, in the transport direction, and that causes the folding position of the media to be nipped by the folding roller pair by shortening the relative distance between the first abutting portion and the second abutting portion to bend the media toward the folding roller pair.
According to this aspect, because the bend forming mechanism causes the folding position of the media to be nipped by the folding roller pair by shortening the relative distance between the first abutting portion and the second abutting portion to bend the media, it is possible to reduce the possibility of the surface of the media being scratched or wrinkled when the folding position of the media is folded by the folding roller pair.
In a second aspect according to the first aspect, the stacking portion is configured to allow bending of the media such that the folding position approaches the folding roller pair, and not allow bending of the media such that the folding position moves away from the folding roller pair.
According to this aspect, because the stacking portion is configured to allow bending of the media such that the folding position approaches the folding roller pair, and not allow bending of the media such that the folding position moves away from the folding roller pair, the media can be more reliably nipped by the folding roller pair through the bend forming mechanism.
In a third aspect according to the first aspect or the second aspect, the stacking portion includes a projecting portion that protrudes toward the folding roller pair at a position corresponding to the folding position when the media are bent.
According to this aspect, because the stacking portion includes a projecting portion that protrudes toward the folding roller pair at a position corresponding to the folding position when the media are bent, when the relative distance between the first abutting portion and the second abutting portion is shortened, the folding position can be easily bent toward the folding roller pair.
In a fourth aspect according to the first aspect to the third aspect, the stacking portion is formed by connecting an upstream member formed upstream in the transport direction and a downstream member formed downstream of the upstream member, and a connection portion between the upstream member and the downstream member is provided at a position corresponding to the folding position when the medium is bent and is configured to switch between a linear state in which the upstream member and the downstream member are flush and a bent state in which the upstream member and the downstream member are connected in a projecting shape toward the folding roller pair side.
According to this aspect, when the media are bent by the bend forming mechanism, the folding position can be easily bent so as to be directed to the folding roller pair side by putting the upstream member and the downstream member in the bent state. When the media are stacked in the stacking portion, the upstream member and the downstream member may be in the linear state to enable the media to be appropriately stacked.
In a fifth aspect according to the first aspect to the fourth aspect, the media folding device further includes an abutting member that is provided at a position on the opposite side to the folding roller pair with respect to the stacking portion, and that is configured to switch between a retracted state of being retracted from the stacking portion, and an advanced state of being advanced to the folding position of the media stacked in the stacking portion, in which the abutting member in the advanced state does not overlap the folding roller pair in an advancing direction.
According to this aspect, because the media folding device further includes an abutting member that is provided at a position on the opposite side to the folding roller pair with respect to the stacking portion, and that is configured to switch between a retracted state of being retracted from the stacking portion, and an advanced state of being advanced to the folding position of the media stacked in the stacking portion, in which the abutting member in the advanced state does not overlap the folding roller pair in an advancing direction, when shortening the relative distance between the first abutting portion and the second abutting portion, the folding position can be easily bent so as to be directed to the folding roller pair side by setting the abutting member in the advanced state.
In addition, because the abutting member in the advanced state does not overlap the folding roller pair in the advancing direction, when the abutting member is moved from the advanced state to the retracted state, it is possible to reduce the possibility of the abutting member scratching the medium.
In a sixth aspect according to the fifth aspect, the abutting member is configured to adjust an amount of advancement in the advancing state in accordance with the number of the media stacked in the stacking portion.
According to this aspect, the amount of advancement of the abutting member in the advanced state can be adjusted according to the number of the media stacked in the stacking portion.
For example, when the number of media stacked in the stacking portion is large, because the stiffness of the media bundle increases, it is possible to facilitate bending of the media by increasing the amount of advancement of the abutting member.
In a seventh aspect according to the first aspect to the sixth aspect, the folding roller pair transports and discharges the media folded by the folding roller pair.
According to this aspect, after the media have been folded at the folding position, a discharging configuration can be easily realized.
In an eighth aspect according to the first aspect to the seventh aspect, the media folding device further includes a binding unit for binding the media stacked in the stacking portion at a predetermined position in the transport direction, wherein a position at which binding is performed by the binding unit is set as the folding position.
According to this aspect, after the media stacked in the stacking portion are bound at a predetermined position in the transport direction, the media can be folded with the position at which binding is performed by the binding unit as the folding position.
In a ninth aspect according to the first aspect to the eighth aspect, the media folding device further includes a crease forming mechanism provided in the introduction path to form a crease in the media at the folding position.
According to this aspect, because a crease forming mechanism is provided in the introduction path to form a crease in the media at the folding position, the medium can be easily folded at the folding position.
In a tenth aspect according to the ninth aspect, the crease forming mechanism includes a crease forming portion that abuts against the media and that moves in a width direction intersecting the transport direction.
According to this aspect, a crease can be easily formed by the crease forming mechanism provided with the crease forming portion that abuts against the media and that moves in the width direction intersecting the transport direction.
A control method for a media folding device according to an eleventh aspect is a control method for a media folding device that includes a stacking portion on which media transported from an introduction path are placed; and a folding roller pair that folds the media at a folding position after the media have been stacked in the stacking portion, including: bending the media with a folding position at the top toward the folding roller pair by shortening a relative distance between a first abutting portion configured to abut against a front end of the media, which are stacked in the stacking portion, in a transport direction, and a second abutting portion that is configured to abut against a rear end of the media, which are stacked in the stacking portion, in the transport direction; nipping with the folding roller pair the folding position of the media that have been bent; and transporting the media by the folding roller pair.
According to this aspect, because the folding position of the media can be nipped by the folding roller pair by bending the media, it is possible to reduce the possibility of scratching the surface of the media when the folding position of the media is folded by the folding roller pair.
Hereinafter, a first embodiment will be described with reference to the drawings. In the XYZ coordinate system illustrated in each drawing, the X-axis direction is the width direction of the medium and indicates the apparatus depth direction, the Y-axis direction indicates the apparatus width direction, and the Z-axis direction indicates the apparatus height direction.
Overview of Recording System
A recording system 1 illustrated in
The recording unit 2 includes a line head 10 as a “recorder” that performs recording on a medium P. The intermediate unit 3 receives the medium P after recording has been performed from the recording unit 2 and delivers it to the processing unit 4. The processing unit 4 includes a first processing portion 30 and a second processing portion 40, which will be described later, as processing devices for performing predetermined processing on the medium P after recording has been performed in the recording unit 2.
In the recording system 1, the recording unit 2, the intermediate unit 3, and the processing unit 4 are connected to one another so that the medium P can be transported from the recording unit 2 to the processing unit 4.
The recording system 1 is configured to enable input of, for example, an operation for recording on the medium P in the recording unit 2, the intermediate unit 3 and the processing unit 4 from an operation panel (not illustrated). The operation panel can, for example, be provided in the recording unit 2.
The schematic configurations of the recording unit 2, the intermediate unit 3 and the processing unit 4 will be described below in order.
Recording Unit
The recording unit 2 illustrated in
At a lower portion of the recording unit 2, a plurality of medium housing cassettes 7 are provided. A medium housed in the medium housing cassettes 7 is fed to a recording region of the line head 10 through a feeding path 11 illustrated by a solid line in the recording unit 2 of
In addition, the recording unit 2 includes an inverting path 14 indicated by a two-dot chain line in the recording unit 2 of
In each of the feeding path 11, the first discharge path 12, the second discharge path 13, and the inverting path 14, a pair of transport roller pairs (not illustrated) is disposed as an example of a unit for transporting the medium.
The recording unit 2 is provided with a control unit 15 that controls operations related to the transport and recording of the medium in the recording unit 2.
Intermediate Unit
The intermediate unit 3 illustrated in
In the intermediate unit 3, there are two transport paths along which the medium is transported. The first transport path is a path through which the medium is transported from the receiving path 20 to a merged path 23 via a first switchback path 21. The second path is a path through which the medium is transported from the receiving path 20 to the merged path 23 via a second switchback path 22.
The first switchback path 21 is a path that switches back the medium in the arrow A2 direction after receiving the medium in the arrow A1 direction. The second switchback path 22 is a path for switching back the medium in the arrow B2 direction after receiving the medium in the arrow B1 direction.
The receiving path 20 branches into the first switchback path 21 and the second switchback path 22 at a first branching portion 24. In addition, the first switchback path 21 and the second switchback path 22 merge at a merging portion 25. Therefore, regardless of which switchback path the medium is sent to from the receiving path 20, the medium can be transferred from the merged path 23, which is a common path, to the processing unit 4.
In the present embodiment, the merged path 23 branches into a first path 27 and a second path 28 at a second branching portion 26. The first path 27 is a path that sends the medium to the first processing portion 30 of the processing unit 4, and the second path 28 is a path that sends the medium to the second processing portion 40 of the processing unit 4. One or more transport roller pairs (not illustrated) are disposed in each of the receiving path 20, the first switchback path 21, the second switchback path 22, the merged path 23, the first path 27, and the second path 28.
In the case where recording is continuously performed on a plurality of media in the recording unit 2, the media having entered the intermediate unit 3 are alternately sent to the transport path passing through the first switchback path 21 and the transport path passing through the second switchback path 22. By this, it is possible to increase the medium transport throughput in the intermediate unit 3.
Further, in the recording system 1, the intermediate unit 3 can be omitted. That is, the recording unit 2 and the processing unit 4 can be connected to each other, and the medium, after recording has been performed thereon in the recording unit 2, can be directly sent to the processing unit 4 without passing through the intermediate unit 3.
As in the present embodiment, when the medium, after recording has been performed thereon in the recording unit 2, is sent to the processing unit 4 via the intermediate unit 3, because the transport time is longer than when the medium is directly sent from the recording unit 2 to the processing unit 4, it is possible to make the ink of the medium drier before being transported to the processing unit 4.
Processing Unit
As described above, the processing unit 4 illustrated in
In
In addition, in the second processing portion 40, as processing to be performed on the media, it is possible to perform saddle-stitch processing in which a center portion of the media is bound and then the bound portion is folded to form a booklet. The second processing portion 40 is provided with a media folding device 50 that folds the media.
In
The processing unit 4 includes a control unit 45 that controls various operations of the first processing portion 30 and the second processing portion 40, which includes the media folding device 50.
The media folding device 50 will be described in detail below.
Media Folding Device
The media folding device 50 illustrated in
As illustrated in
Details of the operation of nipping the media P with the folding roller pair 53 by the bend forming mechanism 60 will be described later.
The first abutting portion 61 and the second abutting portion 62 are configured to move in both the transport direction +R of the media P in the stacking portion 52 illustrated in
The first abutting portion 61 and the second abutting portion 62 can be moved in the transport direction +R and the reverse direction −R, for example, using a rack and pinion mechanism, a belt moving mechanism, or the like operated by the power of a drive source (not illustrated).
The media folding device 50 illustrated in
The binding units 54 are configured to bind at the center portion of the media bundle M, that is, at the folding position C in the transport direction +R. In other words, the binding positions for the binding units 54 correspond to the folding position C for the folding roller pair 53.
Therefore, after the media bundle M stacked in the stacking portion 52 is bound at the center portion in the transport direction +R, the booklet M can be formed with the binding positions for the binding unit 54 as the folding position C.
In addition, in the introduction path 51, an upstream roller pair 55 and a downstream roller pair 56 are provided, and a crease forming mechanism 70 that forms a crease at the folding position C of the medium P is provided between the upstream roller pair 55 and the downstream roller pair 56. By providing the crease forming mechanism 70 in the introduction path 51, it is possible to make creases at the folding positions C of the individual media P by the crease forming mechanism 70 before the folding process by the folding roller pair 53; therefore, the media bundle M can be easily folded at the folding position C.
As illustrated in
The belt mechanism 74 includes the endless belt 75, a drive pulley 76 around which the endless belt 75 is wound, and a driven pulley 77. The drive pulley 76 is rotationally driven by a drive source (not illustrated). The drive pulley 76 is rotatable clockwise and counterclockwise in a plan view of
Next, with reference to
First, as illustrated in the left diagram of
A medium detection unit 57 is provided upstream of the upstream roller pair 55. Using the detection of the front end E1 of the medium P by the medium detection unit 57 as a reference, by controlling the transport of the upstream roller pair 55 and the downstream roller pair 56, the folding position C of the medium P can be aligned with the position corresponding to the crease forming portion 71.
In the left view of
A plurality of media P are stacked in the stacking portion 52 by repeating this operation. Subsequent media P are stacked on the previously stacked media P.
The second abutting portion 62 is located in the −R direction relative to the joining position G while the medium P is transported from the introduction path 51.
Subsequently, the left view of
As illustrated in the right view of
The media bundle M is stapled at the folding position C by the binding units 54 in a state where the front end E1 and the rear end E2 of the media bundle M are aligned.
After the media bundle M has been bound by the binding units 54, as illustrated in the left diagram of
Furthermore, the media bundle M may be moved in the +R direction by moving only the first abutting portion 61 in the +R direction while keeping the media bundle M in contact with the first abutting portion 61 by its own weight.
Subsequently, when the folding position C of the media bundle M is disposed at a position facing the nip position N of the folding roller pair 53, as illustrated in the right view of
The first abutting portion 61 and the second abutting portion 62 may both move to shorten the relative distance between the first abutting portion 61 and the second abutting portion 62 or, for example, the second abutting portion 62 may be brought close to the first abutting portion 61 while the first abutting portion 61 is fixed. Of course, the first abutting portion 61 can be moved while the second abutting portion 62 is fixed.
The stacking portion 52 is open between the folding position C illustrated in the left diagram of
As illustrated in the left view of
When the folding position is nipped by the folding roller pair 53, the folding roller pair 53 rotate and transport the media bundle M. That is, a third step S3 in the flowchart illustrated in
In addition, after the folding position C is nipped by the folding roller pair 53, the first abutting portion 61 and the second abutting portion 62 move in directions away from each other, and return to the state of the left diagram in
As described above, the control method of the media folding device 50 includes, the first step S1 of bending the media bundle M toward the folding roller pair 53 with the folding position C at the top by shortening the relative distance between the first abutting portion 61 and the second abutting portion 62, the second step S2 of nipping the folded position C of the bent media bundle M by the folding roller pair 53, and the third step S3 of transporting the media bundle M by the folding roller pair 53.
In the present embodiment, since the relative distance is shortened between the first abutting portion 61 and the second abutting portion 62 as the bend forming mechanism 60, the medium P is bent toward the folding roller pair 53, and the folding position C of the medium P is nipped by the folding roller pair 53, it is possible to reduce the possibility of the surface of the medium P being scratched or wrinkled when folding the folding position C of the media bundle M by the folding roller pair 53.
In the stacking portion 52 illustrated in each of
That is, the stacking portion 52 is configured to allow the media bundle M (medium P) to bend in such a manner that the folding position C approaches the folding roller pair 53 and not allow the media to bend in such a manner that the folding position C moves away from the folding roller pair 53. Therefore, when the relative distance between the first abutting portion 61 and the second abutting portion 62 is shortened, the media bundle M can be bent in a direction in which the folding position C approaches the folding roller pair 53, and the folding position C can be nipped by the folding roller pair 53 more reliably.
In addition, because the stacking portion includes the projecting portion 64, when the first abutting portion 61 and the second abutting portion 62 are brought close to each other, the folding position C of the media bundle M can be easily bent so as to be directed toward the folding roller pair 53 side.
In a second embodiment, another example of the medium folding apparatus will be described with reference to
Further, in the second and subsequent embodiments, the same components as those in the first embodiment are denoted by the same reference signs as in the first embodiment, and description thereof will be omitted.
A media folding device 80 illustrated in the second embodiment includes an abutting member 81 that is provided at a position on the opposite side to the folding roller pair 53 with respect to the stacking portion 52 and that is capable of switching between, as illustrated in the left diagram of
In the left and right diagrams of
In the left view of
The abutting member 81 is entirely provided outside the stacking portion 52 in the retracted state illustrated in the left diagram of
When the media bundle M is bent by shortening the relative distance between the first abutting portion 61 and the second abutting portion 62, by providing the abutting member 81 that advances and retracts with respect to the stacking portion 52, it is possible to assist in bending the folding position C toward the folding roller pair 53 side with the abutting member 81 in the advanced state.
Here, the abutting member 81 in the advanced state illustrated in the right view of
When the abutting member 81 advances to a position overlapping the folding roller pair 53 in the advancing direction +S and approaches the nip position N, after the folding position C of the media bundle M is nipped by the folding roller pair 53, the abutting member 81 can easily contact the inner surface of the folded media bundle M, and when the abutting member 81 is returned from the advanced state to the retracted state, the inner side surface of the media bundle M may be scratched.
In this embodiment, since the abutting member 81 in the advanced state does not overlap the folding roller pair 53 in the advancing direction +S, the likelihood of the inner side surface of the media bundle M being scratched when the abutting member 81 returns from the advanced state to the retracted state can be reduced.
Further, it is desirable that the abutting member 81 in the advanced state not overlap the folding roller pair 53 in the advancing direction +S; however, the abutting member 81 in the advanced state may be configured to overlap the folding roller pair 53 in front of the nip position N at a position where it is not nipped by the folding roller pair 53.
In addition, the abutting member 81 may be configured to adjust the amount of advancement in the advanced state. Thus, the amount of advancement of the abutting member 81 in the advanced state can be adjusted in accordance with the number of media P stacked in the stacking portion 52. For example, when the number of media P stacked in the stacking portion 52 is large, the rigidity of the entire media bundle M may be high, and it may be difficult to form a bend by the bend forming mechanism 60. Therefore, when the number of stacked media P is large, by increasing the amount of advancement of the abutting member 81 in the advanced state, it is possible to facilitate the formation of the bend by the bend forming mechanism 60.
In addition, when the rigidity of the medium P itself is high, the amount of advancement of the abutting member 81 can be increased even if the number of media stacked is small.
In a third embodiment, another example of the medium folding apparatus will be described with reference to
In a medium folding apparatus 90 illustrated in the third embodiment, the stacking portion 52 is formed by connecting an upstream member 91 formed upstream in the transport direction +R and a downstream member 92 formed downstream of the upstream member 91. The upstream member 91 and the downstream member 92 are connected by a connection portion 93.
As illustrated in the left diagram of
Because the upstream member 91 and the downstream member 92 constituting the stacking portion 52 can be switched between the linear state illustrated in the left diagram of
The processing unit 4 in the first embodiment can be regarded as a “media folding device” including the stacking portion 52, the folding roller pair 53, and the bend forming mechanism 60. In addition, the apparatus from which the recording function is omitted from the recording system 1 can be regarded as a “media folding device” including the stacking portion 52, the folding roller pair 53, and the bend forming mechanism 60.
In addition, it is needless to say that various modifications are possible within the scope of the disclosure described in the claims without being limited to the above embodiment, and they are also included in the scope of the present disclosure.
Number | Date | Country | Kind |
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JP2018-197311 | Oct 2018 | JP | national |
Number | Name | Date | Kind |
---|---|---|---|
5382011 | Tani | Jan 1995 | A |
7121993 | Matsumoto | Oct 2006 | B2 |
7954797 | Sasahara | Jun 2011 | B2 |
8162306 | Suzuki | Apr 2012 | B2 |
20060153612 | Saitsu | Jul 2006 | A1 |
20080001338 | Kotani | Jan 2008 | A1 |
20080185763 | Iguchi | Aug 2008 | A1 |
20120046154 | Takeuchi | Feb 2012 | A1 |
Number | Date | Country |
---|---|---|
4108218 | Jun 2008 | JP |
2012-041113 | Mar 2012 | JP |
2012-082075 | Apr 2012 | JP |
2012-140215 | Jul 2012 | JP |
Number | Date | Country | |
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20200122954 A1 | Apr 2020 | US |