Field of the Invention
The present invention relates to a carriage assembly for use in (applied for), for example, a printing apparatus that prints images, while moving a carriage on which a head is mounted.
Description of the Related Art
A serial scan type printing apparatus prints images on sheets, while reciprocally moving a carriage on which a print head is mounted. The carriage is guided along a guide member to be capable of reciprocating in the main scanning direction. In order to improve the quality of an image printed by the printing apparatus, it is important that the print head should be appropriately positioned with respect to the sheet. For example, in a case wherein sheets having a different thickness are employed to print images, the position of the print head opposite a print face of the sheet should be adjusted in accordance with the thickness of the sheet, and an appropriate distance should be set between the print head and the sheet that faces the print head. In the present invention, this distance will be called a “gap”.
In order to adjust the gap, an arrangement described in Japanese Patent Laid-Open No. 2004-268340 employs a carriage provided by assembling two structures. One of the two structures includes a bearing that can be reciprocally guided along a guide member arranged in the main body of a printing apparatus, while the other structure is provided to mount a print head on, and is attached to the previously mentioned structure through a position adjustment mechanism in a manner such that position adjustment can be performed. The position adjustment mechanism adjusts the position of the latter structure, with respect to the former structure, and sets a gap between the print head and a sheet.
According to the arrangement described in Japanese Patent Laid-Open No. 2004-268340, the print head is positioned, with respect to the guide member, by the structure guided by the guide member, the position adjustment mechanism, and the other structure. In the above described case wherein the print head is positioned, with respect to the guide member, by the two structures and the position adjustment mechanism, there is a possibility that the accuracy of positioning the print head will be degraded, and accordingly, the quality of a printed image will deteriorate.
The present invention provides a carriage assembly having a configuration that can improve the accuracy of positioning a head with respect to a carriage, and in which the position of the head can be easily adjusted.
In the first aspect of the present invention, there is provided a carriage assembly comprising:
a guide member; and
a carriage configured to be moved along the guide member, with a head being mounted on the carriage, the carriage including (a) a first structure, which has a first sliding face that contacts the guide member, and on which the head is to be mounted, and (b) a second structure, which includes a second sliding face that contacts the guide member, and which holds the first structure to allow positional adjustment of the first structure,
wherein a portion of the first sliding face that contacts the guide member is changed by performing the positional adjustment.
In the second aspect of the present invention, there is provided an apparatus comprising:
a carriage assembly in the first aspect of the present invention; and
a conveying unit configured to convey a sheet, for which the head performs printing or scanning, in a direction crossing a direction in which the carriage assembly moves.
A carriage assembly according to the present invention includes a first structure and a second structure, wherein the position of the first structure, with respect to the second structure, can be adjusted. When the first structure on which a head is mounted is positioned directly relative to a guide member, the accuracy of positioning the head can be increased, and the position of the head (e.g., a gap between the head and the sheet) can be easily adjusted.
Further features of the present invention will become apparent from the following description of exemplary embodiments (with reference to the attached drawings).
A printing apparatus in an embodiment of the present invention is a serial scan type ink jet printing apparatus wherein an ink jet print head, that can eject ink, is mounted on a carriage that is to be moved in a main scanning direction. Images are printed in a serial scanning manner by moving the carriage in the main scanning direction.
(General Configuration of the Printing Apparatus)
The configuration of the printing apparatus is roughly divided into a feeding unit (ASF unit) 20, a conveying unit (sheet conveying unit) 30, a discharging unit 40, a print head recovery section (recovery unit) 50 and a carriage 100 that moves with a print head 200 being mounted on it.
The carriage 100 is provided as a carriage assembly that includes a first carriage structure and a second carriage structure that will be described later. Hereinafter, the carriage assembly is also called a carriage unit 100.
As will be described later, an ejection portion that can eject ink is provided for the print head 200. The printing apparatus stores, in a controller (not shown) on a control board 5, print data, for example, transmitted from a host apparatus (not shown), and starts a printing operation based on a printing start command issued by the controller.
In the printing operation, first, a print sheet P is supplied by the feeding unit 20 as a medium on which an image is to be printed. Based on information associated with the print sheet P that has been transmitted from the host apparatus, a lift driver 80 adjusts a distance (hereinafter also called a “gap”) between the ejection portion of the print head 200 and the print sheet P in a manner that will be described later.
Thereafter, when the carriage unit 100 is moved, one time, in the main scanning direction indicated by an arrow X, the ejection portion of the print head 200 ejects ink based on the print data for one line. The carriage unit 100 is guided by a guide shaft (guide member) 11, which is fixed to a chassis 10 that is a constituent of the main body of the printing apparatus, and a support rail 12 that is fixed to the upper portion of the chassis 10, so that the carriage unit 100 can reciprocate in the main scanning direction of the arrow X. The main scanning direction of the arrow X intersects (is perpendicular to, in this case) a direction indicated by an arrow Y, in which the print sheet P is to be conveyed. The carriage unit 100 receives a drive force of a carriage motor 14 through a carriage belt 16 extended between the carriage motor 14 and an idler pulley 15, and reciprocally moves along the guide shaft 11 in the main scanning direction.
When an image for one line has been printed, the print sheet P is conveyed (fed) along a platen 31, at a required distance, by the conveying unit (sheet conveying unit) 30. Printing of the image for one line and conveying of the print sheet Pare repetitiously performed in this manner, and an image is printed in the entire print area of the print sheet P.
As shown in
A pressure contact connector (not shown) that can be electrically connected to the print head 200 is provided for the first carriage structure 110, on which the print head 200 can be mounted on. The pressure contact connector is pressed against a conductor exposing portion of a head board of the print head 200 by using elastic deformation of a plated metal, and is electrically connected to the print head 200. Further, the pressure contact connector is soldered to a carriage board (not shown) that is mounted on the first carriage structure 110. This carriage board is electrically connected through a flexible flat cable (FFC) 17 to the control board (control circuit) 5 in the main body of the printing apparatus.
When a signal is received from a head driver (not shown) through the FFC 17, the print head 200 can eject ink based on print data. Further, a CR encoder (not shown) on the carriage board reads markings on an encoder strip 18 extended along the chassis 10, and detects the movement position of the carriage unit 100. Based on the obtained detection results, the print head 200 ejects ink to the print sheet P at an appropriate timing.
A print head board (not shown) that can be electrically connected to the pressure contact connector of the first carriage structure 110 is provided on a side (the rear face) of the print head 200 upstream in the direction in which the print sheet P is to be conveyed. A conductor exposing portion (hereinafter also called a “contact face”) for which resist deposition is not performed is formed on the print head board. Further, sixty contacts, for example, that can be electrically connected to the pressure contact connector of the first carriage structure 110 are arranged on the contact face. A plurality of ejection ports through which ink can be ejected are formed on the ejection portion 201 of the print head 200, and when ejection energy generating elements that correspond respectively to the ejection ports are selectively driven based on a print signal, ink can be ejected selectively from multiple ejection ports. Electrothermal transducing elements (heaters) or piezoelectric elements, for example, may be employed as ejection energy generating elements.
Two engagement portions 203 for print head positioning are arranged on the lower portion of the print head 200, as shown in
(Arrangement of the Carriage Unit)
As described above, the carriage unit 100 includes the first carriage structure 110 that serves as the primary structure and the second carriage structure 120 that serves as the secondary structure coupled with the rear side of the first carriage structure 110. As shown in
Moreover, a print head setting lever 145 is arranged for the first carriage structure 110, and serves as a manipulation portion used by the user of the printing apparatus to pivot the head fixing portion 140. The print head setting lever 145 is rotatable in a direction indicated by an arrow A1 or A2 at a lever rotation shaft 146 (see
More specifically, the Z abutting faces of the engagement portions 203 for print head positioning are pressed against the Z-directional positioning faces of the positioning protrusions 113 of the first carriage structure 110. Further, the Y abutting faces of the engagement portions 203 for print head positioning are brought in contact with the Y-directional positioning faces prepared near the Z-directional positioning faces of the positioning protrusions 113 of the first carriage structure 110. Moreover, the X abutting faces of the engagement portions 203 for print head positioning are pressed against the X-directional positioning faces of the positioning protrusions 113 of the first carriage structure 110. Also, the Y-directional sub abutting face (not shown) prepared in the upper portion of the print head 200 is pressed against the Y-directional sub positioning face at the distal end of a protrusion that is formed near the center of the first carriage structure 110. When these faces are pressed against each other, the print head 200 can be appropriately and accurately mounted on and positioned at a predetermined mounting location of the print head receiving portion 111 of the first carriage structure 110.
As shown in
(Structure of the Bearing)
The first sliding faces 115 provided for the first carriage structure 110 and the second sliding faces 125 provided for the second carriage structure 120 constitute the bearings 105 of the carriage unit 100 that are located with respect to the guide shaft 11. When the first unit holding faces 118 of the first carriage structure 110 and the second unit holding faces 128 of the second carriage structure 120 always contact with each other, the stable posture of the carriage 100 is maintained. While maintaining the contact of the first and second unit holding faces 118 and 128, the first carriage structure 110 and the second carriage structure 120 are displaced relative to each other in the direction of the arrow Z (Z1 or Z2). Because of this displacement, the relative positions of the first and second sliding faces 115 and 125 that constitute the bearings 105 are changed. The first and second sliding faces 115 and 125 form a so-called inverted V-shape bearing face. As a result, the bearings 105 wherein the first and second sliding faces 115 and 125 contact the guide shaft 11 are provided at the lower portion of the carriage unit 100 to clamp the guide shaft 11. In other words, the individual bearings 105 are provided by employing the first sliding faces 115 of the first carriage structure 110 and the second sliding faces 125 of the second carriage structure 120.
The bearings 105 contact the guide shaft 11 from above by simply receiving the weight of the carriage unit 100. The first sliding faces 115 of the first carriage structure 110 and the second sliding faces 125 of the second carriage structure 120 contact the outer peripheral surface of the guide shaft 11 to clamp the guide shaft 11 between these sliding faces 115 and 125. The first sliding faces 115 are extended in the gravitational direction (vertical direction) of the arrow Z, as shown in
When the bearings 105 are brought in contact with the guide shaft 11 by simply applying the weight of the carriage unit 100, the carriage unit 100 can be moved in the main scanning direction, while being stably and accurately held in position. Therefore, a special impelling mechanism employing, for example, an impelling spring is not required to bring the bearings 105 in contact with the guide shaft 11. Furthermore, a sliding load imposed between the bearings 105 and the guide shaft 11 can be reduced to minimize abrasions at the locations (line contact points) where these components contact, and the durability of the components can be improved.
The first carriage structure 110 directly positions the print head 200 by engaging the positioning protrusions 113 and the engagement portions 203 used for positioning the print head 200. Further, when the first sliding faces 115 of the first carriage structure 110 are brought in contact with the guide shaft 11, the first carriage structure 110 can be immediately positioned with respect to the guide shaft 11, and can slide in the main scanning direction. The first carriage structure 110 that is one of the parts provides the portions (positioning protrusions 113) that hold the print head 200 in position and the portions (first sliding faces 115) that contact the guide shaft 11 to hold the first carriage unit 110 in position. Therefore, compared with a case wherein these portions are provided by using two different parts, a tolerance of the two parts can be excluded, therefore the positioning accuracy for the print head 200 with respect to the guide shaft 11 can be increased, and the quality of the image printed on the print sheet P can be improved.
(Structure of the Guide Shaft)
The guide shaft 11 is fixed to the chassis 10 at the two ends in order to reciprocally guide the carriage unit 100 in the main scanning direction of the arrow X. The ends of the guide shaft 11 are fixed to a shaft fixing stay 13 that is made of a sheet metal, and the shaft fixing stay 13 is attached to the chassis 10 to provide the fixed center location of the guide shaft 11. The guide shaft 11 and the shaft fixing stay 13 are fastened by five screws (not shown) at almost equal intervals, while the shaft fixing stay 13 fastened to the guide shaft 11 and the chassis 10 are fastened by five screws (not shown) at almost equal intervals.
(Structure of a Carriage Lift Mechanism)
A carriage lift mechanism (gap changing mechanism) is driven by the lift driver 80 to move the first carriage structure 110 in the vertical directions of the arrow Z. In accordance with this movement, a distance (gap) between the ejection portions 201 of the print head 200 and the print sheet P is changed.
As shown in
For performing printing on, for example, a thick print sheet P, the lift cam unit 130 increases the gap to protect the print head 200 from contact the print sheet P. An explanation will be given for the arrangement wherein a first gap position used to change the gap to a comparatively small gap G1 and a second gap position used to change the gap to a comparatively large gap are set.
(Operation of the Carriage Lift Mechanism)
At the first gap position shown in
In a case wherein the first gap position is to be changed to the second gap position, the lift cam unit 130 serving as a carriage lift mechanism is rotated by the lift driver 80 prepared for the chassis 10, as shown in
The lift driver 80 is provided for the chassis 10, so that the lift driver 80 is located opposite the carriage lift mechanism when the carriage unit 100 has reached a predetermined scanning position. During the operation of the carriage lift mechanism, the sun gear 81A rotates in a direction of an arrow D1, as shown in
For operating the lift cam unit 130, the carriage unit 100 is halted at the predetermined scanning position opposite the lift driver 80, and as shown in
When the lift cam unit 130 is pivoted, as shown in
After the first gap position is changed to the second gap position in this manner, the lift motor 83 is rotated in a direction of an arrow B2. Sequentially, the sun gear 81A is rotated through the lift idler gear 82 in the direction of the arrow D2, while the planetary gear 81B revolves in the direction of the arrow D2, and is retracted outside the scanning area of the carriage unit 100. Thereafter, the carriage unit 100 is moved in the main scanning direction to print an image on the print sheet P.
In a case wherein the position of the first carriage structure 110 is to be changed from the second gap position to the first gap position, the carriage unit 100 is halted at the predetermined scanning position opposite the lift driver 80. Then, the lift motor 83 is rotated in the direction of the arrow B1, as shown in
Switching between the first and second gap positions can be automatically performed, without manipulation by the user being required, based on information associated with the print sheet P, such as information associated with the thickness of the print sheet P, that is transmitted from the host apparatus to the printing apparatus. Further, the most appropriate gap for the thickness or the type of the print sheet P can be set in accordance with the shapes and the rotational angles of the eccentric cams 132.
(Positional Relationship of the First and Second Sliding Faces)
As shown in
In a case wherein the first carriage structure 110 is located at the first gap position as shown in
When the location of the first carriage structure 110 is adjusted, by switching the gap position, in the predetermined direction of the arrow Z1 or Z2, with respect to the second carriage structure 120, the first sliding faces 115 still contact the guide shaft 11 at the contact positions in the same plane. Therefore, even when the gap position has been changed, relative positions of the first carriage structure 110 and the second carriage structure 120 in the conveying direction (Y direction) are always fixed. Therefore, as described above, the angle β formed by the first and second sliding faces 115 and 125 is fixed and unchanged. As a result, the bearings 105 are formed constantly in a so-called inverted V shape, regardless of the gap position.
In this embodiment, the print head 200 and the guide shaft 11 directly contact the first carriage structure 110 employed in common, and are positioned in the conveying direction (Y direction). When the first sliding faces 115 contact the guide shaft 11, the first carriage structure 110 moves upward or downward (in the Z1 or Z2 direction) in accordance with the gap position, while maintaining the same posture, and also moves in the main scanning direction (in the X direction) while maintaining the same posture. Therefore, high positioning accuracy for the print head 200 and the guide shaft 11 can be maintained, regardless of the gap position, and a high quality image can be printed on the print sheet P. Furthermore, the number of gap positions to be set is not limited to only two, and an arbitrary number of gap positions may be set.
(Modifications)
When the first carriage structure 110 is located at the first gap position, the upper sliding faces 115a contact the guide shaft 11 at a contact point S1, and the slides along the guide shaft 11, as shown in
As described above, so long as the first sliding faces 115 are located on the same plane of the first carriage structure 110 that serves as the primary structure, the first sliding faces 115 may be provided in an arbitrary manner, and may be divided into a plurality of segments as in the modification. The number of segments of the first sliding faces 115 is not limited to two as in this modification, and the number of segments that corresponds to the number of gap positions to be set may be employed.
The arrangement for the first and second sliding faces 115 and 125 is not limited to that shown in the embodiment, and the arrangement shown in
The direction in which the distance (gap) between the print head 200 and the print sheet P is to be adjusted is not limited to the vertical direction, and an arbitrary direction can be set. Further, the direction in which the first carriage structure 110 moves with respect to the second carriage structure 120 is not limited to the direction for adjusting the gap, but may be another direction. For example, when the first and second sliding faces 115 and 125 are formed in the manner as shown in
The number of gap positions to be set is not limited to only two, and may be three or more, and further, the gap positions may be set in a stepless manner. Further, the shape of the guide shaft 11 in cross section is not limited to only a circular shape, and an arbitrary shape may be employed, so long as the movement of the first carriage structure 110 is allowed.
In the above embodiment, the carriage lift mechanism that is driven by the lift motor 83 has been described as an example. However, a carriage lift mechanism that is manually operated by manipulation of, for example, a lever by a user may be employed, and in this case, the same effects can also be obtained. The arrangement of the carriage lift mechanism is not limited to the arrangement wherein the lift cam unit 130 moves the first carriage structure 110, and another arrangement may be employed. As an example arrangement, a slide member that can slide in the main scanning direction may be provided between the first carriage structure 110 and the second carriage structure 120, and the slide member may include a portion, for which the vertical thickness is changed, step by step, or steplessly, in the main scanning direction. For this carriage lift mechanism, the first carriage structure 110 can be moved in the vertical direction, with respect to the second carriage structure 120, in a multistep manner, or in a stepless manner. Further, a rack extended vertically may be prepared for one of the first carriage structure 110 and the second carriage structure 120, and a pinion that engages the rack may be prepared for the other carriage structure. Such a carriage lift mechanism can vertically move the first carriage structure 110, with respect to the second carriage structure 120, in accordance with the rotation of the pinion.
The print head 200 mounted on the first carriage structure 110 may be provided as a separate unit from the ink tank 300, or may constitute an ink jet cartridge integrated with the ink tank 300. Further, the present invention is not limited to an ink jet printing apparatus, and can be widely applied to printing apparatuses of various printing types. Furthermore, the present invention can constitute a position adjustment mechanism that adjusts the position of the print head.
Moreover, the present invention is not limited to a printing apparatus, but can be applied to a scanning device that reads an image or information printed on a sheet, while scanning the sheet by employing a scanning head (an image sensor unit) mounted on a carriage. That is, the feature of the present invention is the construction of the carriage assembly that moves while holding the head (a print head or a scanning head), and may employ a mode in which printing of an image is performed by a print head, while the carriage is moved relative to the sheet, or a mode in which scanning of an image is performed by a scanning head, while the carriage is moved relative to the sheet.
An embodiment of the present invention provides a mechanism that improves accuracy for positioning a head relative to a carriage, and easily performs positional adjustment for the head. A carriage unit (100) includes a first carriage structure (110) and a second carriage structure (120). The first carriage structure (110) includes a first sliding face (115) that can slide along a guide shaft (11), and a head (100) can be mounted on the first carriage structure (110). The second carriage structure (120) includes a second sliding face (125) that can slide along the guide shaft (11), and can hold the first carriage structure (110) to allow positional adjustment for the first carriage structure (110) in a predetermined direction in which a position where the first sliding face (115) contacts the guide shaft (11) is to be shifted.
While the present invention has been described with reference to exemplary embodiments, it is to be understood that the invention is not limited to the disclosed exemplary embodiments. The scope of the following claims is to be accorded the broadest interpretation so as to encompass all such modifications and equivalent structures and functions.
This application claims the benefit of Japanese Patent Application No. 2014-119640, filed Jun. 10, 2014, which is hereby incorporated by reference herein in its entirety.
Number | Date | Country | Kind |
---|---|---|---|
2014-119640 | Jun 2014 | JP | national |
This application is a continuation of U.S. application Ser. No. 14/731,482, filed Jun. 5, 2015 (pending), the contents of which are incorporated herein by reference.
Number | Name | Date | Kind |
---|---|---|---|
4595931 | Toganoh et al. | Jun 1986 | A |
4642654 | Toganoh et al. | Feb 1987 | A |
4733247 | Arai et al. | Mar 1988 | A |
5984466 | Nagashima et al. | Nov 1999 | A |
6789966 | Tanaka et al. | Sep 2004 | B2 |
6974203 | Ikeda et al. | Dec 2005 | B2 |
7537312 | Sekino et al. | May 2009 | B2 |
7566108 | Nojima et al. | Jul 2009 | B2 |
7753480 | Ueda et al. | Jul 2010 | B2 |
8146529 | Hakamata et al. | Apr 2012 | B2 |
8220411 | Yoshino et al. | Jul 2012 | B2 |
8348401 | Sekino et al. | Jan 2013 | B2 |
8465124 | Hanaoka et al. | Jun 2013 | B2 |
8789491 | Nagahara et al. | Jul 2014 | B2 |
8939527 | Shinohara et al. | Jan 2015 | B2 |
8960859 | Sekino | Feb 2015 | B2 |
9573398 | Sekino | Feb 2017 | B2 |
20070229590 | Kadota et al. | Oct 2007 | A1 |
20080007593 | Buonerba et al. | Jan 2008 | A1 |
20090309922 | Iwakura | Dec 2009 | A1 |
20130113862 | Kemma | May 2013 | A1 |
20140009518 | Kumagai et al. | Jan 2014 | A1 |
Number | Date | Country |
---|---|---|
2 591 918 | May 2013 | EP |
2004-268340 | Sep 2004 | JP |
2008-238785 | Oct 2008 | JP |
2009-096029 | May 2009 | JP |
Entry |
---|
Chinese Office Action dated Jun. 2, 2016 in Chinese Application No. 201510313106.1. |
Number | Date | Country | |
---|---|---|---|
20170129264 A1 | May 2017 | US |
Number | Date | Country | |
---|---|---|---|
Parent | 14731482 | Jun 2015 | US |
Child | 15413292 | US |