The present disclosure relates to a recording head recovery system having an ink ejection surface in which an ink ejection ports are formed so as to eject ink to a recording medium such as a paper sheet, a head cleaning mechanism, and an inkjet recording apparatus including the same.
As a recording apparatus such as a facsimile, a copier, or a printer, an inkjet recording apparatus that forms images by ejecting ink is widely used because it can form a high definition images.
In this inkjet recording apparatus, micro ink droplets (hereinafter referred to as mist) ejected together with ink droplets for recording images and rebound mist generated when the ink droplets are adhered to the recording medium may be adhered and fixed to the ink ejection surface of the recording head. As the mist on the ink ejection surface is gradually increased and overlaps the ink ejection ports, deterioration of ink ejection straightness (bending flying), non-ejection, or the like may occur, so that printing performance of the recording head is deteriorated.
Therefore, in order to clean the ink ejection surface of the recording head, there is known an inkjet recording apparatus in which a plurality of cleaning liquid supply ports are disposed in a part outside the ink ejection region in which a plurality of ink ejection ports are formed (a part on an upstream side in a wiping direction of a wiper) in the ink ejection surface. In this inkjet recording apparatus, after supplying cleaning liquid from the cleaning liquid supply ports, the wiper is moved along the ink ejection surface from outside of the cleaning liquid supply port, so that the wiper can wipe the ink ejection surface while holding the cleaning liquid. In this way, a recording head recovery process can be performed.
A recording head recovery system of a first aspect of the present disclosure includes a recording head, a wiper, a wipe unit, and a control unit. The recording head includes an ink ejection surface provided with an ink ejection region in which a plurality of ink ejection ports are formed for ejecting ink onto a recording medium. The wiper wipes the ink ejection surface in a predetermined direction. The wipe unit holds the wiper and moves the wiper in an up and down direction while moving the same along the ink ejection surface. The control unit controls the wipe unit. The recording head includes a cleaning liquid supply region disposed on an upstream side in a wiping direction of the ink ejection region, the wiping direction in which the wiper wipes the ink ejection surface, the cleaning liquid supply region in which a plurality of cleaning liquid supply ports for supplying cleaning liquid are formed. The control unit is capable of performing a recovery operation of the recording head including a cleaning liquid supply operation for supplying the cleaning liquid from the cleaning liquid supply port, and a wipe operation for wiping the ink ejection surface with the wiper in a state holding the cleaning liquid, by moving the wiper from a position on the wiping direction upstream side of the cleaning liquid supply region to a position on the wiping direction downstream side of the ink ejection region. In the wipe operation, a height position of a lower end part of the wiper when passing the cleaning liquid supply region is lower than a height position of the lower end part of the wiper when wiping the ink ejection region.
A recording head recovery system of a second aspect of the present disclosure includes recording a head, a wiper, a wiper holding member, a rotation mechanism, and a control unit. The recording head includes an ink ejection surface provided with an ink ejection region in which a plurality of ink ejection ports are formed for ejecting ink onto a recording medium. The wiper wipes the ink ejection surface in a predetermined direction. The wiper holding member holds the wiper, moves the same along the ink ejection surface, and is capable of rotating about a rotation shaft extending in a head width direction perpendicular to a wiping direction in which the wiper wipes the ink ejection surface. The rotation mechanism rotates the wiper holding member about the rotation shaft. The control unit controls the rotation mechanism. The recording head includes a cleaning liquid supply region disposed on an upstream side in the wiping direction of the ink ejection region, the cleaning liquid supply region in which a plurality of cleaning liquid supply ports for supplying cleaning liquid are formed. The control unit is capable of performing a recovery operation of the recording head including a cleaning liquid supply operation for supplying the cleaning liquid from the cleaning liquid supply port, and a wipe operation for wiping the ink ejection surface with the wiper in a state holding the cleaning liquid by moving the wiper from a position on the wiping direction upstream side of the cleaning liquid supply region to a position on the wiping direction downstream side of the ink ejection region. In the wipe operation, the control unit rotates the wiper holding member so that a pressure contact angle of a tip of the wiper to the ink ejection surface is decreased after the wiper passes the cleaning liquid supply region before reaching the ink ejection region.
A head cleaning mechanism of a third aspect of the present disclosure includes recording a head, and a wiper. The recording head includes an ink ejection surface in which a plurality of ink ejection ports are formed for ejecting ink onto a recording medium, and a cleaning liquid supply surface in which a plurality of cleaning liquid supply ports for supplying cleaning liquid are formed. The wiper wipes the ink ejection surface in a predetermined direction. The recording head are constituted of an ink ejection head portion including the ink ejection surface, and a cleaning liquid supplying head portion disposed on an upstream side in a wiping direction of the ink ejection head portion, the wiping direction in which the wiper wipes the ink ejection surface, the cleaning liquid supplying head portion including the cleaning liquid supply surface. The cleaning liquid supply surface includes a lower surface disposed in parallel to the ink ejection surface on the wiping direction upstream side of the ink ejection surface adjacent to the same. A length of the lower surface in the head width direction perpendicular to the wiping direction is larger than a length of the ink ejection surface in the head width direction.
Other objects of the present disclosure and specific advantages obtained by the present disclosure will become more apparent from the description of embodiments given below.
Hereinafter, embodiments of the present disclosure are described with reference to the drawings.
As shown in
On a downstream side (the right side in
The recording portion 9 includes a head housing 10, and line heads 11C, 11M, 11Y, and 11K held by the head housing 10. These line heads 11C to 11K are supported at a height such that a predetermined space (e.g. 1 mm) is formed between a conveying surface of the first conveyor belt 8 and the heads. As shown in
As shown in
The recording heads 17a to 17c constituting the line heads 11C to 11K are supplied with four color (cyan, magenta, yellow, and black) ink stored in ink tanks (not shown) for each color of the line heads 11C to 11K, respectively.
Each of the recording heads 17a to 17c ejects ink from the ink ejection port 18a to the paper sheet S sucked and held to be conveyed by the conveying surface of the first conveyor belt 8 according to image data received from an external computer based on a control signal from the control unit 110 (see
In addition, the recording heads 17a to 17c are provided with a cleaning liquid supply member (cleaning liquid supplying head portion) 60, which supplies cleaning liquid. The cleaning liquid supply member 60 is disposed adjacent to the head portion 18 on an upstream side (the right side in
As shown in
As shown in
As shown in
The supply path 70 is constituted of a single path at the upstream end and branches repeatedly toward the downstream side so as to be branched into 12 paths. The 12 paths are connected to the cleaning liquid supply members 60 of the recording heads 17a to 17c, respectively.
In this inkjet recording apparatus 100, in order to clean the ink ejection surfaces F1 of the recording heads 17a to 17c, when starting to print after a long halt and between printing operations, ink is forcibly ejected from all the ink ejection ports 18a of the recording heads 17a to 17c, while the cleaning liquid is supplied to the cleaning liquid supply surface F2 from all the cleaning liquid supply ports 60a of the recording heads 17a to 17c (see
With reference to
The paper sheet S with the ink image recorded by the recording portion 9 is sent to the second conveying unit 12, and the ink ejected to the surface of the paper sheet S is dried while passing through the second conveying unit 12. In addition, a wipe unit 19 and a cap unit 90 are disposed below the second conveying unit 12. The wipe unit 19 moves to below the recording portion 9 when performing the above-mentioned wipe operation using the wipers 35a to 35c, so as to wipe off the ink ejected forcibly from the ink ejection ports 18a of the recording heads 17a to 17c and the cleaning liquid supplied from the cleaning liquid supply ports 60a, and to collect the wiped ink and cleaning liquid. In addition, the wipe unit 19 is configured to be capable of moving in the up and down direction with a drive mechanism (not shown) including a drive source such as a stepping motor. When the wipe unit 19 moves up or down, the wipers 35a to 35c are also moved up or down. When capping the ink ejection surfaces F1 (see
In addition, the downstream side of the second conveying unit 12 in the paper sheet conveying direction is provided with a discharge roller pair 16 that discharges the paper sheet S with the recorded image to the outside of the apparatus main body, and a discharge tray (not shown) on which the paper sheet S is placed after being discharged to the outside of the apparatus is provided on the downstream side of the discharge roller pair 16.
Next, a detailed structure of the wipe unit 19 is described. As shown in
Rail portions 41a and 41b are formed on opposed edges of an upper surface of the support frame 40, and rollers 36 disposed at four corners of the wiper carriage 31 abut the rail portions 41a and 41b so that the wiper carriage 31 is supported by the support frame 40 in a slidable manner in an arrow AA′ direction.
A wiper carriage moving motor 45 for moving the wiper carriage 31 in the horizontal direction (arrow AA′ direction), and a gear train (not shown) that engages with the wiper carriage moving motor 45 and rack teeth (not shown) of the wiper carriage 31 are attached to the outside of the support frame 40. When the wiper carriage moving motor 45 rotates forward and backward, the gear train rotates forward and backward so that the wiper carriage 31 moves in the horizontal direction (arrow AA′ direction) in a reciprocating manner.
The wipers 35a to 35c are elastic members (e.g. rubber members made of EPDM) for wiping off the cleaning liquid supplied from the cleaning liquid supply ports 60a of the recording heads 17a to 17c (see
The four wipers 35a are disposed with substantially equal spaces. Similarly, four wipers 35b as well as four wipers 35c are disposed with substantially equal spaces. The wipers 35a and 35c are respectively disposed at positions corresponding to the left and right recording heads 17a and 17c (see
The upper surface of the support frame 40 is provided with a collection tray 44 for collecting waste ink and cleaning liquid wiped off the ink ejection surface F1 by the wipers 35a to 35c. A substantially middle part of the collection tray 44 is provided with an exit hole (not shown), and tray surfaces 44a and 44b on both sides of the exit hole have down slopes toward the exit hole. The waste ink and cleaning liquid wiped off the ink ejection surface F1 by the wipers 35a to 35c drop to the tray surfaces 44a and 44b and flow to the exit hole (not shown). After that, the waste ink and cleaning liquid passes through an ink collection path (not shown) connected to the exit hole and are collected to a collection tank (not shown).
Next, a recovery operation of the recording heads 17a to 17c using the wipe unit 19 in the inkjet recording apparatus 100 of this embodiment is described. Note that the recovery operation of the recording heads 17a to 17c described below are performed by controlling operations of the recording heads 17a to 17c, the wipe unit 19, and the like, based on the control signal from the control unit 110 (see
When the recovery operation of the recording heads 17a to 17c is performed, first as shown in
(Cleaning Liquid Supply Operation)
Prior to a wiping operation (wipe operation described later), as shown in
(Ink Extrusion Operation)
In addition, prior to the wiping operation (wipe operation described later), as shown in
(Wipe Operation)
As shown in
From the state of
Then, the wipers 35a to 35c further moves in the left direction (in the arrow A direction), and when it passes the step at the boundary part between the cleaning liquid supply surface F2 and the ink ejection surface F1, the control unit 110 upwardly moves the wipers 35a to 35c by approximately 1.1 mm as shown in
After that, as shown in
(Separation Operation)
After performing the wipe operation, as shown in
Finally, the control unit 110 horizontally moves the wipe unit 19 positioned between the recording portion 9 and the first conveying unit 5 so that it is positioned below the second conveying unit 12, and the control unit 110 moves the first conveying unit 5 upward to a predetermined position. In this way, the recovery operation of the recording heads 17a to 17c is finished.
In this embodiment, as described above, the control unit 110 moves the wipers 35a to 35c from the position P1 on the wiping direction upstream side of the cleaning liquid supply region R2 to the position P2 on the wiping direction downstream side of the ink ejection region R1, and hence the wipers 35a to 35c can perform the wipe operation of wiping the ink ejection surface F1 in the state holding the cleaning liquid 23. In this way, the ink ejection surface F1 can be cleaned.
In addition, in the wipe operation, the height position H11 of the lower end parts of the wipers 35a to 35c when wiping the cleaning liquid supply region R2 is lower than the height position H12 of the lower end parts of the wipers 35a to 35c when wiping the ink ejection region R1. In this way, the contact pressing force of the wipers 35a to 35c to the cleaning liquid supply surface F2 when wiping the cleaning liquid supply region R2 can be reduced, and hence tips of the wipers 35a to 35c can be prevented from being damaged by an edge of the cleaning liquid supply port 60a.
In addition, as described above, if the opening diameter of the cleaning liquid supply port 60a is larger than the opening diameter of the ink ejection port 18a, an entering amount of the tips of the wipers 35a to 35c into the cleaning liquid supply port 60a becomes more than an entering amount of the same into the ink ejection port 18a, and hence the tips of the wipers 35a to 35c are apt to be damaged. Therefore, it is particularly effective to apply the present disclosure in the case where the opening diameter of the cleaning liquid supply port 60a is larger than the opening diameter of the ink ejection port 18a.
In addition, as described above, if the height position H2 of the cleaning liquid supply surface F2 is lower than the height position H1 of the ink ejection surface F1, the contact pressing force of the wipers 35a to 35c to the cleaning liquid supply surface F2 is apt to be larger than the contact pressing force of the wipers 35a to 35c to the ink ejection surface F1, and hence the tips of the wipers 35a to 35c are apt to be damaged. Therefore, it is particularly effective to apply the present disclosure in the case where the height position H2 of the cleaning liquid supply surface F2 is lower than the height position H1 of the ink ejection surface F1.
In addition, as described above, the overlap amount of the wipers 35a to 35c with the cleaning liquid supply surface F2 when wiping the cleaning liquid supply region R2 is smaller than the overlap amount of the wipers 35a to 35c with the ink ejection surface F1 when wiping the ink ejection region R1. In this way, the contact pressing force of the wipers 35a to 35c to the cleaning liquid supply surface F2 can be smaller than the contact pressing force of the wipers 35a to 35c to the ink ejection surface F1, and hence the tips of the wipers 35a to 35c can be prevented more from being damaged.
In addition, as described above, the part on the wiping direction downstream side of the cleaning liquid supply member 60 is provided with the thin plate portion 65 having a thin plate-like shape, and the thin plate portion 65 is disposed to overlap under an end of the ink ejection surface F1. In this way, the cleaning liquid 23 can be prevented from entering a gap between the head portion 18 and the cleaning liquid supply member 60.
In addition, as described above, the overlap amount of the wipers 35a to 35c with the cleaning liquid supply surface F2 when wiping the cleaning liquid supply region R2 is less than or equal to a half of the overlap amount of the wipers 35a to 35c with the ink ejection surface F1 when wiping the ink ejection region R1. In this way, the contact pressing force of the wipers 35a to 35c to the cleaning liquid supply surface F2 when wiping the cleaning liquid supply region R2 can be sufficiently small, and hence the tips of the wipers 35a to 35c can be sufficiently prevented from being damaged by the edge of the cleaning liquid supply port 60a.
In the inkjet recording apparatus 100 of a second embodiment of the present disclosure, the thin plate portion 65 of the cleaning liquid supply member 60 has a thickness of 0.05 mm to 0.1 mm, for example. Therefore, the height position H2 of the cleaning liquid supply surface F2 (see
As shown in
Each end of the wiper holder stay 32 in the head width direction is provided with a rotation shaft 32a extending in the head width direction. Note that the wiper holder stay 32 may be fixed to one rotation shaft 32a that is longer than the wiper holder stay 32. The rotation shafts 32a are pivotally supported by bearings (not shown) of the wiper carriage 31, and the wiper holder stay 32 can rotate about the rotation shaft 32a. When the wiper carriage 31 moves in the arrow AA′ direction, the wiper holder stay 32 moves in the arrow AA′ direction in a state holding the wipers 35a to 35c.
One of the rotation shafts 32a is connected to a rotation mechanism 37 for rotating the wiper holder stay 32 about the rotation shaft 32a. The rotation mechanism 37 is constituted of an angle adjusting motor 38 constituted of a stepping motor, a gear 39a fixed to the rotation shaft 32a, and a gear train constituted of a plurality of gears 39b for linking between a motor gear 38a of the angle adjusting motor 38 and the gear 39a. When the angle adjusting motor 38 rotates forward and backward, the wiper holder stay 32 rotates forward and backward by a predetermined angle in the state holding the wipers 35a to 35c.
Other structures of the second embodiment are the same as those of the first embodiment described above.
Next, the recovery operation of the recording heads 17a to 17c using the wipe unit 19 in the inkjet recording apparatus 100 of this embodiment is described. The recovery operation of the recording heads 17a to 17c described below is performed by controlling operations of the recording heads 17a to 17c, the wipe unit 19, the rotation mechanism 37, and the like, based on the control signal from the control unit 110 (see
When the recovery operation of the recording heads 17a to 17c is performed, first as shown in
(Cleaning Liquid Supply Operation)
As shown in
(Ink Extrusion Operation)
In addition, as shown in
(Wipe Operation)
As shown in
From the state of
Further, when the wipers 35a to 35c further moves in the left direction (in the arrow A direction) so as to pass the boundary part between the cleaning liquid supply surface F2 and the ink ejection surface F1, the control unit 110 rotates the wiper holder stay 32 in a counterclockwise direction by a predetermined angle in
After that, as shown in
(Separation Operation)
After the wipe operation is performed, as shown in
Finally, the control unit 110 horizontally moves the wipe unit 19 disposed between the recording portion 9 and the first conveying unit 5 so that it is positioned below the second conveying unit 12, and the control unit 110 upwardly moves the first conveying unit 5 to a predetermined position. In this way, the recovery operation of the recording heads 17a to 17c is finished.
Other operations in the second embodiment are the same as those in the first embodiment described above.
In this embodiment, as described above, in the wipe operation, after the wipers 35a to 35c pass the cleaning liquid supply region R2, before they reach the ink ejection region R1, the control unit 110 rotates the wiper holder stay 32 so that the pressure contact angle of the tips of the wipers 35a to 35c to the ink ejection surface F1 is decreased. In other words, the pressure contact angle of the tips of the wipers 35a to 35c to the recording heads 17a to 17c is larger when the wipers 35a to 35c pass the cleaning liquid supply region R2 than when the wipers 35a to 35c wipe the ink ejection region R1. In this way, the contact pressing force of the wipers 35a to 35c to the cleaning liquid supply surface F2 when passing the cleaning liquid supply region R2 can be reduced, and hence the tips of the wipers 35a to 35c can be prevented from being damaged by the edge of the cleaning liquid supply port 60a.
In addition, as described above, the wiper mounting surface 32b of the wiper holder stay 32 is disposed to be inclined upward toward the wiping direction upstream side when the wipers 35a to 35c pass the cleaning liquid supply region R2, while it is disposed to be perpendicular to the ink ejection surface F1 when the wipers 35a to 35c pass the ink ejection region R1. In this way, the contact pressing force of the wipers 35a to 35c to the cleaning liquid supply surface F2 when passing the cleaning liquid supply region R2 can be easily reduced, and hence the tips of the wipers 35a to 35c can be easily prevented from being damaged by the edge of the cleaning liquid supply port 60a.
In addition, as described above, when the height position H2 of the cleaning liquid supply surface F2 is lower than the height position H1 of the ink ejection surface F1, the step is formed at the boundary part between the cleaning liquid supply surface F2 and the ink ejection surface F1, and hence the tips of the wipers 35a to 35c are apt to be damaged by the step more easily when the wipers 35a to 35c pass the step. Therefore, it is particularly effective to apply the present disclosure in the case where the height position H2 of the cleaning liquid supply surface F2 is lower than the height position H1 of the ink ejection surface F1.
In addition, as described above, the pressure contact angle β1 of the tips of the wipers 35a to 35c to the cleaning liquid supply surface F2 when wiping the cleaning liquid supply region R2 is larger than the pressure contact angle β2 of the tips of the wipers 35a to 35c to the ink ejection surface F1 when wiping the ink ejection region R1 by 10 to 20 degrees. In this way, the contact pressing force of the wipers 35a to 35c to the cleaning liquid supply surface F2 when wiping the cleaning liquid supply region R2 can be sufficiently decreased, and hence the tips of the wipers 35a to 35c can be sufficiently prevented from being damaged by the edge of the cleaning liquid supply port 60a.
Other effects of the second embodiment are the same as those in the first embodiment described above.
In the inkjet recording apparatus 100 of a third embodiment of the present disclosure, as shown in
As shown in
In addition, the length L60 in the head width direction of the lower surface F2 is smaller than the length L35 in the head width direction of the wipers 35a to 35c by approximately 1 mm. Therefore, the wipers 35a to 35c protrudes from the lower surface F2 in the head width direction on each side by approximately 0.5 mm.
An end of the lower surface F2 on the wiping direction downstream side (the left side in
In this embodiment, the recording heads 17a to 17c, the wipers 35a to 35c, the supply path 70, the cleaning liquid supply mechanism, and the like constitute the head cleaning mechanism.
Other structures of the third embodiment are the same as those in the first embodiment described above.
Next, the recovery operation of the recording heads 17a to 17c using the wipe unit 19 in the inkjet recording apparatus 100 of this embodiment is described. Note that in this embodiment, unlike the first embodiment described above, the wipers 35a to 35c are not moved upward when the wipers 35a to 35c pass the step U. In addition, in this embodiment, unlike the second embodiment described above, the wiper holder stay 32 is not rotated when the wipers 35a to 35c pass the step U.
When performing the recovery operation of the recording heads 17a to 17c, first as shown in
(Cleaning Liquid Supply Operation)
Prior to the wiping operation (wipe operation described later), as shown in
(Ink Extrusion Operation)
In addition, prior to the wiping operation (wipe operation described later), as shown in
(Wipe Operation)
As shown in
From the state of
After that, as shown in
(Separation Operation)
After the wipe operation is performed, as shown in
Finally, the control unit 110 horizontally moves the wipe unit 19 disposed between the recording portion 9 and the first conveying unit 5 so that it is positioned below the second conveying unit 12, and the control unit 110 upwardly moves the first conveying unit 5 to a predetermined position. In this way, the recovery operation of the recording heads 17a to 17c is finished.
Other operations in the third embodiment are the same as those in the first embodiment described above.
In this embodiment, as described above, the recording heads 17a to 17c are constituted of the head portion 18 that ejects the ink 22, and the cleaning liquid supply member 60 that supplies the cleaning liquid 23. In this way, an ink passing path and a cleaning liquid passing path in the recording heads 17a to 17c can be formed in different members (the head portion 18 and the cleaning liquid supply member 60), and hence structures of the recording heads 17a to 17c can be prevented from being complicated.
In addition, the length L60 in the head width direction of the lower surface F2 of the cleaning liquid supply member 60 is larger than the length L18 in the head width direction of the ink ejection surface F1. In this way, even if the head portion 18 and the cleaning liquid supply member 60 are disposed to be shifted from each other in the head width direction, one end of the ink ejection surface F1 in the head width direction can be prevented from protruding from the lower surface F2 of the cleaning liquid supply member 60 in the head width direction. For this reason, the cleaning liquid 23 of the lower surface F2 can be supplied to the entire region in the head width direction of the ink ejection surface F1, and hence the ink ejection surface F1 can be cleaned over the entire region in the head width direction.
In addition, as described above, the length L35 in the head width direction of the wipers 35a to 35c is larger than the length L60 in the head width direction of the lower surface F2, and the two corner portions 65a of the end of the lower surface F2 on the wiping direction downstream side are formed to have a round shape in a plan view. In this way, when the wipers 35a to 35c move from the lower surface F2 to the ink ejection surface F1, the wipers 35a to 35c can be prevented from being damaged by the corner portion 65a of the lower surface F2. Note that when the corner portion 65a is formed in a right angle in a plan view, the corner portion 65a may damage the wipers 35a to 35c so that ends of the wipers 35a to 35c in the head width direction may be cut along the wiping direction.
In addition, when the thin plate portion 65 of the cleaning liquid supply member 60 is disposed to overlap under an end of the ink ejection surface F1, i.e., when the lower surface F2 is disposed under the ink ejection surface F1, the contact pressing force of the wipers 35a to 35c to the lower surface F2 becomes larger than the contact pressing force of the wipers 35a to 35c to the ink ejection surface F1. For this reason, when the wipers 35a to 35c move from the lower surface F2 to the ink ejection surface F1, the wipers 35a to 35c are apt to be damaged by the corner portion 65a of the lower surface F2. Therefore, it is particularly effective to form the end of the lower surface F2 in the wiping direction downstream side to have a round shape in the structure in which the lower surface F2 is disposed under the ink ejection surface F1.
In addition, as described above, a radius of curvature of the corner portion 65a is larger than or equal to the protrusion amount W65a of the lower surface F2 from the ink ejection surface F1 in the head width direction. In this way, the round shape of the corner portion 65a can be large, and hence the wipers 35a to 35c can be prevented from being damaged by the corner portion 65a.
Other effects of the third embodiment are the same as those in the first embodiment described above.
Note that the embodiments disclosed in this specification are merely examples in every aspect and should not be interpreted as limitations. The scope of the present disclosure is defined not by the above description of the embodiments but by the claims and should be understood to include all modifications within meanings and scopes equivalent to the claims.
For example, in the first and second embodiments described above, the cleaning liquid supply member 60 including the cleaning liquid supply region R2 in which the cleaning liquid supply ports 60a are formed is disposed separately from the head portion 18 as an example, but the present disclosure is not limited to this. It is possible to adopt a structure in which the cleaning liquid supply member 60 is not disposed, and the cleaning liquid supply region R2 in which the cleaning liquid supply ports 60a are formed is disposed in the head portion 18.
In addition, in the embodiments described above, the cleaning liquid supply operation is performed before the wipe operation as an example, but it may be performed simultaneously with the wipe operation as long as before the wipers 35a to 35c enter the cleaning liquid supply region R2. In addition, the ink extrusion operation is performed before the wipe operation in the example, but it may be performed simultaneously with the wipe operation as long as before the wipers 35a to 35c enter the ink ejection region R1.
In addition, in the embodiments described above, the cleaning liquid 23 and the ink (purged ink) 22 are used for performing the recovery operation of the recording heads 17a to 17c, but only the cleaning liquid 23 may be used for performing the recovery operation of the recording heads 17a to 17c. In other words, the ink extrusion operation may not be performed.
In addition, in the embodiments described above, the step is formed between the cleaning liquid supply surface F2 and the ink ejection surface F1 as an example, but the present disclosure is not limited to this. In other words, the cleaning liquid supply surface F2 and the ink ejection surface F1 may be flush with each other.
In addition, in the third embodiment described above, the cleaning liquid supply region R2 in which the cleaning liquid supply ports 60a are formed is disposed in the lower surface F2 as an example, but it may be disposed in the inclined surface 62. In this case, the cleaning liquid 23 supplied to the inclined surface 62 flows along the inclined surface 62 to the lower surface F2, and hence the wipers 35a to 35c can wipe off the cleaning liquid 23. Note that the cleaning liquid supply surface is constituted of the inclined surface 62 and the lower surface F2.
In addition, in the third embodiment described above, the two corner portions 65a of the end of the lower surface F2 in the wiping direction downstream side are formed to have a round shape in a plan view as an example, but the present disclosure is not limited to this. For example, like the recording heads 17a to 17c shown in
Number | Date | Country | Kind |
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JP2017-011347 | Jan 2017 | JP | national |
JP2017-027920 | Feb 2017 | JP | national |
JP2017-031740 | Feb 2017 | JP | national |
This application is a divisional of U.S. application Ser. No. 16/926,592, filed Jul. 10, 2020, which is a divisional of U.S. application Ser. No. 15/868,162, filed Jan. 11, 2018, now U.S. Pat. No. 10,744,773, issued on Aug. 18, 2020 in the U.S. Patent and Trademark Office, which claims the benefit of priority from the corresponding Japanese Patent Applications No. 2017-011347 filed Jan. 25, 2017, No. 2017-027920 filed Feb. 17, 2017, and No. 2017-031740 filed Feb. 23, 2017, the entire contents of which are hereby incorporated by reference.
Number | Name | Date | Kind |
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7478897 | Takagi | Jan 2009 | B2 |
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20070165063 | Horie | Jul 2007 | A1 |
20090046122 | Inoue | Feb 2009 | A1 |
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Number | Date | Country |
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2006-88617 | Apr 2006 | JP |
2007-83496 | Apr 2007 | JP |
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2008-201102 | Sep 2008 | JP |
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Entry |
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Extended European Search Report dated Jun. 26, 2018, issued to European Application No. 18151633.7. |
Japanese Office Action dated Oct. 8, 2019, issued to Japanese Application No. 2017-011347. |
Japanese Office Action dated Oct. 8, 2019, issued to Japanese Application No. 2017-031740. |
Japanese Office Action dated Oct. 23, 2019, issued by the Japanese Patent Office in corresponding application JP 2017-027920. |
Number | Date | Country | |
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20210101388 A1 | Apr 2021 | US |
Number | Date | Country | |
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Parent | 16926592 | Jul 2020 | US |
Child | 17124748 | US | |
Parent | 15868162 | Jan 2018 | US |
Child | 16926592 | US |