The entire disclosure of Japanese Patent Application No. 2018-051074, filed Mar. 19, 2018 is expressly incorporated by reference herein.
The present disclosure relates to a processing apparatus for processing a medium.
There are processing apparatuses that are provided with recording apparatuses having a recording section for ejecting ink, which is an example liquid, onto paper, which is an example medium, to record images, or the like and discharge the recorded paper to a discharge tray. These recording apparatuses are called ink jet printers. In such printers, in some cases, the ink ejected from the recording section and adhered to the paper causes the paper to curl (corrugate) and the curling paper is discharged to the discharge tray, resulting in the decrease in the stacking properties.
JP-A-2016-166094 discloses a recording apparatus that includes a discharge section for discharging a medium. The recording apparatus includes a first acting section that acts so that first portions of paper outside both sides of the discharge section are located on a lower side of a nipping position of a discharge driving roller and a discharge driven roller in a recording surface intersecting direction that intersects a recording surface and a second acting section that acts so that second portions of the paper outside both sides of the first portions in a width direction of the discharged paper are located on an upper side of the first portions. Specifically, paper is corrugated in the width direction by the first portions and the second portions to reduce the curling of the paper.
The recording apparatus disclosed in JP-A-2016-166094, however, applies a pressing force to the paper by the first portions and the second portions, and depending on the paper condition, the recording apparatus may cause damage such as scratches on the paper surface by the first portions or the second portions that strongly press the paper surface at the positions where the first portions or the second portions come into contact with the paper, and there is a room for improvement in this respect.
An advantage of some aspects of the disclosure is that there is provided a processing apparatus capable of achieving good medium stacking properties and reducing the occurrence of damage to a medium.
According to an aspect of the disclosure, a processing apparatus includes a processing section configured to perform processing to a medium, a discharge section configured to discharge the medium that has been transported from the processing section along a medium transport path, and a first contact section configured to come into contact with the medium that has passed through the processing section and being transported toward the discharge section in the medium transport path to press the medium from one side toward the other side, in which the first contact section is switched between a first position for pressing the medium and a second position that is closer to the one side than the first position.
According to this aspect, a processing apparatus includes a first contact section configured to come into contact with the medium from one side, which is one surface side of the medium, toward the other side, which is the other surface side of the medium. The processing apparatus can switch the first contact section between a first position for pressing the medium to increase the stiffness of the medium and a second position that is closer to the one side than the first position. Accordingly, by switching the first contact section to the first position, the medium can be corrugated in a medium width direction that is a direction intersecting a medium transport direction, and good medium stacking properties can be achieved. The first contact section is switched to the second position at a timing in discharging the medium. With this operation, the pressing force of the first contact section for pressing the surface of the medium can be released and the occurrence of damage to the medium can be reduced.
It is preferable that the processing apparatus further include a second contact section disposed away from the first contact section in a medium width direction that is a direction intersecting the medium transport direction, the second contact section being configured to come into contact with the medium being transported toward the discharge section to press the medium from the other side toward the one side.
In this structure, the processing apparatus includes a second contact section disposed away from the first contact section in a medium width direction that is a direction intersecting the medium transport direction, the second contact section being configured to come into contact with the medium being transported toward the discharge section to press the medium from the other side toward the one side. Accordingly, the medium can be more reliably corrugated in the medium width direction.
It is preferable that the discharge section be disposed in a central area in the medium width direction, the first contact section be disposed outside the discharge section in the medium width direction, and the second contact section be disposed outside the first contact section in the medium width direction.
With the structure in which the discharge section is disposed in a central area in the medium width direction, the first contact section is disposed outside the discharge section in the medium width direction, and the second contact section is disposed outside the first contact section in the medium width direction, a functional effect similar to the above-described functional effect can be achieved.
It is preferable that the position at which the first contact section in the first position come into contact with the medium be closer to the other side than the position at which the second contact section come into contact with the medium.
In this structure, the position at which the first contact section in the first position comes into contact with the medium is closer to the other side than the position at which the second contact section comes into contact with the medium. Accordingly, the medium can be reliably corrugated in the medium width direction by the first contact section and the second contact section.
It is preferable that the second contact section be on an upstream side of the first contact section in the medium transport path. With the structure in which the second contact section is on an upstream side of the first contact section in the medium transport path, some of the above-described operational effects can be achieved.
It is preferable that the first contact section be disposed at a higher position with respect to the medium transport path and the second contact section be disposed at a lower position with respect to the medium transport path.
With the structure in which the first contact section is disposed at a higher position with respect to the medium transport path and the second contact section is disposed at a lower position with respect to the medium transport path, some of the above-described operational effects can be achieved.
It is preferable that the position at which the second contact section comes into contact with the medium be higher than the position at which the first contact section in the first position comes into contact with the medium and be lower than the position at which the discharge section comes into contact with the medium.
With this structure, the position at which the second contact section comes into contact with the medium is higher than the position at which the first contact section in the first position comes into contact with the medium and is lower than the position at which the discharge section comes into contact with the medium. Accordingly, the medium can be more reliably corrugated in the medium width direction.
It is preferable that the position at which the first contact section in the second position comes into contact with the medium be a substantially the same height as the position at which the second contact section comes into contact with the medium or be lower than the position at which the second contact section comes into contact with the medium.
With this structure, the position at which the first contact section in the second position comes into contact with the medium is a substantially the same height as the position at which the second contact section comes into contact with the medium or is lower than the position at which the second contact section comes into contact with the medium. Accordingly, even if the first contact section is switched to the second position, it can be expected that the corrugated shapes will remain to some extent in the medium and the curl reducing effect can be continuously achieved.
It is preferable that the position at which the first contact section in the second position comes into contact with the medium be higher than the position at which the second contact section comes into contact with the medium.
With this structure, the position at which the first contact section in the second position comes into contact with the medium is higher than the position at which the second contact section comes into contact with the medium. Accordingly, the pressing force of the first contact section for pressing the surface of the medium can be more reliably released and the occurrence of damage to the medium can be more reliably reduced.
It is preferable that a plurality of the first contact sections, or a plurality of the second contact sections, or a plurality of first contact sections and the second contact sections be disposed in the medium width direction.
With this structure, a plurality of the first contact sections, or a plurality of the second contact sections, or a plurality of first contact sections and the second contact sections are disposed in the medium width direction, and the medium can be more reliably corrugated in the medium width direction.
It is preferable that when a leading edge of the medium reaches the first contact section, the first contact section be in the first position and by the time a trailing edge of the medium passes through the first contact section, the first contact section be switched from the first position to the second position.
With this structure, when a leading edge of the medium reaches the first contact section, the first contact section is in the first position and by the time a trailing edge of the medium passes through the first contact section, the first contact section is switched from the first position to the second position. Accordingly, the effect of reducing the occurrence of damage to the medium by the first contact section can be achieved in a predetermined area in the medium.
It is preferable that the first contact section be switched from the first position to the second position when a central position of the medium in the discharge direction reaches the discharge section.
When a central position of the medium in the discharge direction reaches the discharge section, the position of the center of gravity in the medium becomes on the downstream side of the discharge section, and the portion of the medium on the downstream side will automatically fall with the discharge section as a fulcrum. Accordingly, the portion of the medium on the upstream side comes into contact with the first contact section with a strong force the medium is more likely to be damaged by the first contact section. With this structure, in such a case, the first contact section is switched from the first position to the second position and thereby the occurrence of damage to the medium by the first contact section can be effectively reduced.
It is preferable that the first contact section be switched from the first position to the second position step by step. Since the first contact section is switched from the first position to the second position step by step, sudden change in the orientation of the medium in discharging the medium can be reduced and good stacking properties can be achieved.
It is preferable that depending on the type of medium, a discharging operation to be performed in a state in which the first contact section is in the first position and a discharging operation to be performed in a state in which the first contact section is in the second position be switched.
For example, if the medium is paper that has high stiffness such as thick paper, since the medium does not easily curl, it is substantially not necessary to press the medium to corrugate with the pressing force by the first contact section to reduce curling to achieve good stacking properties. Moreover, in the case of the medium that has high stiffness, the pressure from the first contact section would damage the medium surface. Consequently, in such a case, the medium is discharged in the state in which the first contact section is in the second position. On the other hand, if the medium is paper that has low stiffness such as thin paper, since the medium easily curl, it is necessary to press the medium by the first contact section to corrugate the medium to reduce curling to achieve good stacking properties. Accordingly, in such a case, the medium is discharged in a state in which the first contact section is in the first position. For example, as described above, depending on the type of medium, a discharging operation to be performed in a state in which the first contact section is in the first position and a discharging operation to be performed in a state in which the first contact section is in the second position are switched, and thereby a discharging operation appropriate for the medium type can be performed.
It is preferable that the processing section include a recording unit configured to perform recording onto the medium. With this structure in which the processing section includes a recording unit configured to perform recording onto the medium, some of the above-described functional effects can be achieved.
The disclosure will be described with reference to the accompanying drawings, wherein like numbers reference like elements.
Hereinafter, a processing apparatus according to an embodiment of the disclosure will be described with reference to the drawings. In the following description, an ink jet printer (hereinafter, simply referred to as a “printer”) 1 will be described as an example processing apparatus according to the embodiment of the disclosure. The method of performing recording onto a sheet, which is an example medium, is not limited to the ink jet system, and various systems such as an electrophotographic system or a dot impact system may be employed. The ink jet systems include various systems such as a system having an ink cartridge that is attached to a carriage, a system that has an ink accommodating section provided outside a carriage and the ink accommodating section and the carriage are connected by an ink tube, and the like. Embodiments of the disclosure can be applied to any of the systems. The printer 1 according to the embodiment has an ink accommodating section that is provided outside a carriage and the ink accommodating section and the carriage are connected by an ink tube. Recording heads for discharging ink includes recording heads that move in a sheet width direction and recording heads that are immovable and have a size enough to cover a sheet width direction. The printer 1 according to the embodiment is the latter type.
In an x-y-z coordinate system in the drawings, an x direction denotes an apparatus depth direction and a sheet width direction, and a y direction denotes an apparatus width direction, and a z direction denotes an apparatus height direction and a gravity direction. A direction toward which a sheet is transported is referred to as “downstream” and the opposite direction is referred to as “upstream”.
With reference to
An operation section 5 is used to perform various operations to the printer 1. A tray 4 receives a discharged recorded sheet, specifically, a face-down discharge tray that receives a sheet that is discharged with a surface placed face down onto which recording has been performed most recently. A feeding unit 35 rotates about a pivot point (not illustrated) to be opened or closed with respect to the apparatus body 2A.
The feeding unit 35 includes an access cover 6. The access cover 6 can swing open about a pivot shaft 6a (
A side of the printer 1 on which the operation section 5 is disposed is an apparatus front side, and a side on which the access cover 6 is disposed is an apparatus right side. Specifically, feeding, transporting, and discharging of a sheet in the printer 1 is performed along the apparatus right-left direction.
Sheet transport paths in the printer 1 will be described with reference to
The printer 1 has two sheet discharging methods: a face-up discharging (see a face-up discharge trajectory T1) for discharging a sheet with a surface placed face up onto which recording has been performed most recently and a face-down discharging (see a face-down discharge trajectory T2) for discharging a sheet with a surface placed face down onto which recording has been performed most recently.
A face-up discharge tray 7 in
The printer 1 includes five sheet transport paths: a recording transport path R1, a switchback path R2, a reversing path R3, a face-down discharge path R4, and a face-up discharge path R5.
In
When the flap 33 is in the state indicated by the solid line in
In
The paper cassette 10A that is detachably attached to the apparatus body 2A includes a hopper 11. The hopper 11 swings about a shaft 11a so that a sheet stored in the paper cassette 10A comes into contact with or separates from a feeding roller 12, which is driven by a motor (not illustrated) to rotate.
A sheet that is fed from the paper cassette 10A by the feeding roller 12 passes through a nip position of a separation roller pair 13 and is separated (multi-sheet feeding is prevented), is subjected to a feeding force from a transport roller pair 14, and reaches the registration roller pair 17. Similarly, each of the expansion units 2B and 2C (
Hereinafter, the sheet transport paths on the downstream side of the registration roller pair 17 will be described with reference to
First, rollers that are disposed in each sheet transport path will be described.
The rollers F are driving rollers that are driven by motors (not illustrated), and for example, rubber rollers that are disposed at appropriate intervals in the sheet width direction. The rollers G are driven rollers that are driven to rotate while coming into contact with a sheet and can nip the sheet with the rollers F by urging members (not illustrated). The rollers G are provided together with the rollers F as pairs and are disposed at appropriate intervals in the sheet width direction. The roller G is a serrated roller that has a plurality of teeth on its outer circumference. The roller G comes into contact with a recording surface at a point to reduce the occurrence of white patches of ink and transferring of ink onto the recording surface. Each of the driven rollers G comprises each transport roller pair and is disposed at an appropriate position in the sheet transport paths, particularly, provided on the side the driven roller G comes into contact with a surface on which recording has been made most recently. Driven rollers in the discharge mechanism section 36 have a structure similar to that of the driven rollers G as will be described below.
On the other hand, the registration roller pair 17 and the transport roller pair 29 have structures different from that of the above-described roller pairs. Specifically, the transport roller pair 29 has a driving roller 29a that is driven to rotate and a driven roller 29b that is pressed against the driving roller 29a and can be driven to rotate. The driven roller 29b is a resin roller that has a smooth outer circumferential surface.
The registration roller pair 17 has a driving roller 17a that is driven to rotate and a driven roller 17b that is pressed against the driving roller 17a by an urging member (not illustrated) and can be driven to rotate. The driving roller 17a has a fine uneven outer circumferential surface. The driven roller 17b is a resin roller that has a smooth outer circumferential surface. A plurality of driving rollers 17a are disposed at appropriate intervals along an axis direction with respect to a rotation shaft 17c. Similarly, a plurality of driven rollers 17b are disposed at appropriate intervals along an axis direction with respect to a rotation shaft 17d.
Between the above-described rollers, a sheet is guided by upper and lower guiding members. Although no reference numerals are given to the guiding members in
The recording transport path R1, which serves as a first transport path, extends under the recording head 8, which serves as a recording section for performing recording onto a sheet, to its upstream side and downstream side. In this embodiment, the recording transport path R1 is between around a position M1 and a position M2 in
In this embodiment, the recording head 8, which serves as a recording unit, is a recording head (so-called line head) that is provided such that nozzles for ejecting ink covers the entire area in the sheet width direction to enable recording onto the entire sheet width without moving in the sheet width direction. The recording head 8 is an example processing section that performs processing to a sheet, which is an example medium.
The switchback path R2, which serves as a second transport path, is connected to the recording transport path R1. The switchback path R2 feeds a sheet that has passed under the recording head 8 (left direction in
The reversing path R3, which serves as a third transport path, is connected to the switchback path R2. The reversing path R3 reverses a sheet that has been fed in the opposite direction (right direction in
The face-down discharge path R4, which serves as a fourth transport path, is connected to the recording transport path R1. The face-down discharge path R4 curves a sheet that has passed under the recording head 8 such that the surface that has faced the recording head 8 faces inward to reverse and discharge the sheet. In this embodiment, the face-down discharge path R4 is on the left side of around the position M2 in
At connection sections in the transport paths, a first flap 31 and a second flap 32 that serve as path switching sections for switching the transport paths are disposed. The first flap 31 receives a driving force from a driving unit (not illustrated) to swing about a pivot 31a. The second flap 32 can engage with the first flap 31 via an engaging portion (not illustrated) and swings about a pivot 32a in response to a swing of the first flap 31. With these flaps, a path for a sheet is set.
The overall structure of the printer 1 has been described above, and hereinafter, the discharge mechanism section 36 that is disposed most downstream of the face-down discharge path R4 to discharge a sheet obliquely upward will be described with reference to
In this embodiment, a plurality of discharge roller pairs 25 are disposed at predetermined intervals in a central area in the sheet width direction (x direction). In the sheet width direction (x direction), a driven roller 48, which serves as a “first contact section”, is disposed outside the discharge roller pairs 25, and a driven roller 47, which serves as a “second contact section”, is disposed outside the driven roller 48. A plurality of driven rollers 47 are disposed at predetermined intervals in the sheet width direction (x direction). Specifically, the discharge roller pairs 25, which serves as the discharge section, are disposed in the central area in the sheet width direction (x direction), the driven roller 48, which serves as the first contact section, is disposed outside the discharge roller pairs 25 in the sheet width direction (x direction), and the driven rollers 47, which serve as the second contact section, are disposed outside the driven roller 48 in the sheet width direction (x direction). In the sheet transport direction, the driven roller 47 is disposed on the upstream side of the driven roller 48 (see
Specifically, in this embodiment, two spurs constitute one driven roller 48, and one driven roller 48 is disposed on one side (one side from the center) in the sheet width direction (x direction), and one spur constitutes the driven roller 47 and two driven rollers 47 are disposed on the one side (the one side from the center) in the sheet width direction (x direction). In this embodiment, at least a plurality of driven rollers 47 or a plurality of driven rollers 48 is disposed on one side (one side from the center) in the sheet width direction (x direction). With this structure, a sheet can be more reliably corrugated. Instead of the above example, on one side (one side from the center) in the sheet width direction (x direction), two pairs of driven rollers 48 may be disposed, one driven roller 47 may be disposed, or two or more pairs of driven rollers 47 and 48 may be disposed respectively, that is, a plurality of driven rollers 47 and driven rollers 48 may be disposed. In this embodiment, four spurs constitute one driven roller 64 that is a part of the discharge roller pair 25, and four driven rollers 64 are disposed in the sheet width direction (x direction). Similarly to the driven roller 48, two spurs constitute one driven roller 49 and the driven roller 49 is disposed.
In
Among the plurality of driven rollers 44, 45, 46, 47, 48, and 49, which are disposed between the transport roller pair 24 and the discharge roller pair 25, the driven rollers 44, 45, 46, and 47 come into contact with a recording surface (lower surface) of a sheet on which recording has been made most recently, and the driven rollers 48 and 49 come into contact with a surface (upper surface) opposite to the most-recently-recorded surface of the sheet.
The driven rollers 48 and 49 are disposed in a roller supporting member 51. The roller supporting member 51 can be rotated about a rotation shaft 52 in the clockwise direction or in the counterclockwise direction in
As also illustrated in
A first cam member 57 is fixed to an end of the rotation shaft 54 as illustrated in
The rotation of the rotation shaft 54 rotates the roller supporting member 51 and thereby the driven rollers 48 and 49 that are supported by the roller supporting member 51 can move toward or away from the sheet transport path. With this structure, from the viewpoint of the driven roller 48, which serves as the first contact section, the driven roller 48 comes into contact with a sheet that is transported in the sheet transport path (face-down discharge path R4) toward the discharge roller pair 25 from one side, which is one surface side of the sheet, toward the other side, which is the other surface side of the sheet. In this embodiment, an upper surface of the sheet in
The operation of the driven roller 48 will be further described with reference to
In
The driven rollers 48 can be switched from the pressing position as in
In this embodiment, as illustrated in
Instead of the above, the position where the driven roller 48 that is in the retracted position comes into contact with the sheet P may be set to a position higher than the position where the driven roller 47 comes into contact with the sheet P. With this structure, the pressing force of the driven rollers 48 and the driven rollers 47 for pressing the surface of the sheet P can be more reliably released and the occurrence of damage to the sheet P can be more reliably reduced.
A specific example of the switching of the driven rollers 48 between the pressing position and the retracted position will be described with reference to
The controller 9 monitors whether a central position Y1 (
Specifically, when the central position Y1 in the discharge direction in the sheet P has reached the discharge roller pair 25, the position of the center of gravity in the sheet P is on the downstream side of the discharge roller pair 25, and the portion of the sheet P on the downstream side (portion on the right side of the central position Y1 in
In such a case, the controller 9 switches the driven rollers 48 from the pressing position to the retracted position. This operation effectively reduces the occurrence of the damage to the sheet P by the driven rollers 48. The timing of switching the driven rollers 48 from the pressing position to the retracted position is not limited to the above-described timing; alternatively, other timings during the discharge of the sheet P by the discharge roller pair 25 may be employed. Such a timing may be appropriately set by a person skilled in the art based on the necessity of pressing a sheet by the driven rollers 48 to reduce curling and the necessity of retracting the driven rollers 48 to reduce damage.
The switching of the driven rollers 48 from the pressing position to the retracted position may be performed step by step. For example, at least one intermediate position may be provided between the pressing position and the retracted position and the driven rollers 48 may be temporarily stopped at the intermediate position. This structure can reduce sudden change in the orientation of the sheet P in discharging the sheet P and good stacking properties can be achieved. In addition to the step-by-step switching of the driven rollers 48 from the pressing position to the retracted position, power of a motor or the like may be used instead of the solenoid 60 (
The switching of the driven rollers 48 from the pressing position to the retracted position may be performed depending on the paper type. Specifically, depending on the paper type, the control process in step S102 in
On the other hand, if paper that has low stiffness such as thin paper is used, since the paper easily curl, it is necessary to set the driven rollers 48 to the pressing position to corrugate the paper to reduce curling to achieve good stacking properties. Accordingly, in such a case, the processing in step S102 in
The retracted position of the driven rollers 48 is not limited to one, and a plurality of positions may be set. Furthermore, in such a case, the retracted positions may be set for each paper type. For example, for paper (hereinafter, referred to as “first paper”) that tends to easily curl due to ink absorption, the driven rollers 48 may be set to a pressing position (hereinafter, referred to as a “first pressing position”) at which the driven rollers 48 can press the paper with a strongest force. For paper (hereinafter, referred to as “second paper”) that needs the pressure from the driven rollers 48 to reduce curling but is relatively hard to curl as compared to the first paper, the driven rollers 48 may be set to a second pressing position at which a pressing force weaker than that at the first pressing position is provided. With such a structure, appropriate discharging suitable for individual paper type can be performed.
It is to be understood that the disclosure is not limited to the above-described embodiments, various modifications can be made within the scope of the following claims, and these modifications are included within the scope of the disclosure. For example, in the above-described embodiments, the recording section including the recording head has been described as the processing section. Alternatively, the processing section may be a reading section that includes an image reading sensor in the scanner section 3. In such a case, the discharge section is a discharge section for discharging a document from the reading section that reads the document while transporting the document. Furthermore, in the above-described embodiments, for example, a sheet is discharged face down and in single-sided recording, at least a recording surface of the sheet is not damaged by the first contact section. Consequently, in the case of the single-sided recording, since the sheet is to be corrugated first to increase the stiffness in the single-sided recording, the first contact section may not be switched to the second position.
Number | Date | Country | Kind |
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JP2018-051074 | Mar 2018 | JP | national |
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Number | Date | Country | |
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20190283465 A1 | Sep 2019 | US |