The exemplary embodiment relates generally to sheet transport systems and finds particular application in connection with a gravity-assisted registration system for sheet media which is suited to use in a printing system.
Transport systems are widely used for transporting sheet media between and within modules of a printing system, such as between a sheet feeder and a marking module, or on a return path through the marking module to enable duplex (double sided) printing. The transport system may include a combination of rollers, conveyor belts, vacuum-assisted transport units, and the like. In order to ensure that each sheet arrives at a printer component with an acceptable level of skew and lateral errors, registration subsystems are used to steer the sheets to achieve correct alignment.
There are demands for new printer designs that are able to increase the size of the sheet (e.g., to about 66 cm, or higher, in process-direction length) or to increase the printer speed from what is conventionally achievable. For the registration subsystem, steering long sheets and steering sheets at high speeds are challenging. In high speed printers, the amount of time available to perform the registration correction is reduced, which can increase stresses on the sheets. This means that sheets may not be correctly registered if their input error is too large. Registration correction algorithms are used to attempt to steer these sheets to the machine registration targets. However, the large corrections may result in sheet trailing edges being driven into the sidewalls of the transport (resulting in sheet damage or jams) or cause sheets to slip, breaking free of the drive nips, resulting in poor registration.
In one type of registration subsystem, skew and lateral errors are corrected in one motion. This correction induces more skew to move the sheet laterally, creating a ‘tail-wag’ motion of the sheet. This motion of the sheet is stressful, and the tangential forces on the sheet may exceed the threshold of slip with larger sheets. Another type of registration subsystem uses independent drive rolls for correcting skew while lateral correction is effected by a translating (cross-process) carriage. This has an advantage of decoupling the lateral and skew correction. However, the use of the translating carriage limits the maximum speed of the printer system due to the limit on the carriage return time that can be achieved, given the mass of the carriage (including motors, rollers and other drive elements).
One method used to enable registering large sheets is to manually adjust the positions of preceding modules to try to keep the input error low. For example, the sheet feeder may undergo an alignment procedure to reduce the errors in the sheet entering the marking module, or a duplex path alignment procedure may be performed. However, such module alignment procedures impact only the mean input error and are unable to address sheet-to-sheet variations. Thus, even though average input error may be within acceptable bounds, sheet-to-sheet variations can result in misregistration of some of the sheets.
There remains a need for systems and methods for media registration which address these deficiencies and enable improvements in the capability of a printing system to handle faster sheet speeds, larger sheet sizes, and/or larger weight sheets.
The following references, the disclosures of which are incorporated in their entireties by reference, are mentioned:
U.S. Pub. No. 20150284203, published Oct. 8, 2015, entitled FINISHER REGISTRATION SYSTEM USING OMNIDIRECTIONAL SCUFFER WHEELS, by Terrero, et al., describes a sheet registration system for use in a finisher of a digital printing system. Omnidirectional scuffer wheels with a plurality of overlapping rollers provide uninterrupted traction to move media sheets against a registration wall for process direction registration.
U.S. Pub. No. 20150217958, published Aug. 6, 2015, entitled SYSTEMS AND METHODS FOR IMPLEMENTING UNIQUE OFFSETTING STACKER REGISTRATION USING OMNI-DIRECTIONAL WHEELS FOR SET COMPILING IN IMAGE FORMING DEVICES, by Dunham, et al., describes a system for improving stack integrity for a set of image receiving media substrates at an output of a compiler in an image forming device. A substrate handling device downstream of the output of the compiler includes a plurality of omni-directional wheeled devices that provide drive (traction) normal to a motor axis under control of one of a respective plurality of independent motors while allowing sliding in the motor axis direction. When using three or more omni-directional wheeled devices, translational movement can be combined with rotation to deliver sheets of image receiving media exiting the compiler at a correct angle and lateral position for further processing.
U.S. Pat. No. 4,775,142, issued Oct. 4, 1988, entitled ROLLER APPARATUS FOR SIDE REGISTRATION OF DOCUMENTS, by Silverberg, describes an apparatus for urging documents against a registration fence while simultaneously driving the documents along a conveying path determined by the fence.
U.S. Pat. No. 5,065,998, issued Nov. 19, 1991, entitled LATERAL SHEET REGISTRATION SYSTEM, by Salomon, describes a sheet registration and feeding system for laterally registering a sheet without frictional drive slippage against the sheet.
U.S. Pat. No. 4,179,117, issued Dec. 18, 1979, entitled PAPER ALIGNMENT ROLLERS, by Rhodes, Jr., describes paper aligning rolls in which the drive roll is skewed to the direction of travel move paper toward a referencing edge while the backup roll is oppositely skewed to urge the paper away from the referencing edge.
In accordance with one aspect of the exemplary embodiment, a gravity-assisted wall registration system includes a transport member including a surface on which an associated sheet is translated in a process direction. The surface defines an angle with respect to horizontal in a cross-process direction of at least one degree. A registration wall adjacent a lower end of the surface defines a registration edge for registering the sheet. The system further includes a drive mechanism and at least one rotation mechanism, driven by the drive mechanism, for translating sheet in the process direction. Each rotation mechanism includes at least one drive member with an axis of rotation parallel to the surface in the cross-process direction. Each drive member includes a sliding mechanism, at a periphery of the drive member, which enables the sheet to slide, under gravity, on the surface, toward the registration wall into an alignment position, in contact with the registration wall.
In accordance with another aspect of the exemplary embodiment, a printing system includes a marking device, which applies a marking material to associated sheets of print media, and a sheet transport system, which transports the sheets in a process direction to the marking device. The sheet transport system includes a gravity-assisted registration system. The gravity-assisted registration system includes a transport member including a surface on which the sheets are translated in the process direction. The surface defines an angle with respect to horizontal in a cross-process direction of at least 1 degree. A registration wall adjacent a lower end of the surface defines a registration edge for registering the sheet. The gravity-assisted registration system further includes a drive mechanism and at least one rotation mechanism, driven by the drive mechanism. Each rotation mechanism includes at least one drive member with an axis of rotation parallel to the surface in the cross-process direction, which translates the sheets in the process direction. Each drive member includes a sliding mechanism, at a periphery of the drive member, enabling the sheets to slide, under gravity, on the surface, toward the registration wall into an alignment position, in contact with the registration wall.
In accordance with another aspect of the exemplary embodiment, a method of printing includes transporting a sheet of print media in a process direction on a print media path. The sheet of print media is registered with a gravity-assisted registration system to reduce at least one of skew and lateral shift. A marking material is applied to the sheet with a marking device positioned on the paper path, upstream or downstream of the gravity-assisted registration system. The gravity-assisted registration system includes a transport member including a surface on which the sheet is translated in the process direction, the surface defining an angle with respect to horizontal in a cross-process direction, of at least 1 degree. A registration wall, adjacent a lower end of the surface, defines a registration edge for registering the sheet. The gravity-assisted registration system further includes a drive mechanism and at least one rotation mechanism, driven by the drive mechanism. Each rotation mechanism includes at least one drive member with an axis of rotation parallel to the surface in the cross-process direction, which translates the sheet in the process direction, each drive member including a sliding mechanism, at a periphery of the drive member, enabling the sheet to slide, under gravity, on the surface, toward the registration wall into an alignment position, in contact with the registration wall.
Aspects of the exemplary embodiment relate to a gravity-assisted wall registration system suited to use in a printer for correcting or reducing registration errors in sheets of print media as they are conveyed along a paper path. The wall registration system allows each sheet to be registered independently and quickly and is particularly suited to use in high speed printers and/or those which are designed to handle large sheets of print media. In particularly, rotatable members are used to apply a driving force to a sheet in the process direction, while a sliding mechanism allows the sheet to slide, under gravity, towards a registration wall.
As used herein, a “printer,” or a “printing system” refers to one or more devices used to generate printed media by forming images on print media, using a marking material, such as one or more colored inks or toner particles. The printer may be a digital copier, bookmaking machine, facsimile machine, multi-function machine, or the like, which performs a print outputting function. The print media may be sheets of paper, card, transparencies, parchment, film, fabric, plastic, photo-finishing papers, or other coated or non-coated flexible substrates suitable for printing.
The printer includes a marking module which may incorporate one or more xerographic marking devices in which toner particles are transferred from an electrically charged surface to the print media and then fused to the sheet. Alternatively, the printer may be inkjet printer which incorporates an inkjet marking device including inkjet heads which jet droplets of ink onto the print media, which are then cured, e.g., with ultraviolet radiation. Other marking devices are also contemplated. The printer may be configured for monochrome (single color) and/or color (more than one color) printing.
The “leading edge” of a sheet of print media refers to an edge of the sheet that is furthest downstream in the process direction. The “process direction” refers to the direction in which a sheet travels along a paper path during the printing process.
While some components of the printer are described herein as modules, this is not intended to imply that they are separately housed from each other and in some embodiments, may be otherwise separated into different housings or contained in a single printer housing.
Independent of the type of marking module 20, skew and/or lateral shift in the sheet as it passes through the print module can result in incorrect positioning of the image on the sheet.
From the marking module 20, the sheet transport system 14 conveys the printed sheets to a fixing module 40, where the marking material is more permanently affixed to the sheet. In a xerographic printer, fixing module 40 may include a fuser 42, which applies heat and pressure to the marked sheet. In the case of an inkjet printer the inks may be cured with heat and/or UV radiation.
From the fixing module 40, the sheet transport system 14 conveys the printed sheets to a sheet output 50, such as an output tray, where the marked sheets are output. The printer may include other components, such as a finisher 52 and/or stacker 54 in the paper path, intermediate the fixing module 40 and the output 50. The finisher performs post-processing operations, such as stapling, collating, binding, and the like, while the stacker assembles the sheets into a stack. In the illustrated printer, the paper path 18 includes a return loop 56, which returns the sheets to the marking device 22, e.g., via an inverter 58, to allow printing on the other side of the sheet. A diverter 60 may be used to divert the sheets into the return loop 56, when needed.
The transport system 14 may include various mechanisms for conveying the sheets, such as rollers, drive nips, belts, air/vacuum assisted transport mechanisms, and the like. In particular, a sheet feeder 62 draws sheets singly from a stack 64 in the supply unit 16 and sends them in single file along the paper path 18. The transport system 14 also includes one or more registration components for registering the sheets intermediate the sheet feeder 62 and the printed media output 50. At least one of the registration components is in the form of a gravity-assisted wall registration system 70, which repositions each sheet, as needed, to reduce skew and/or lateral shift (in the cross-process direction). In the illustrated printer 10, the registration system 70 is positioned in the return loop 56, to register the sheets before they return to the marking device 22. As will be appreciated, one or more registration systems 70 may be alternatively or additionally positioned elsewhere along the paper path 18, such as between the sheet feeder 62 and the marking device 22, and/or between the marking device and the fixing module 40. The wall registration system 70 may feed the sheets to a further registration system 72, upstream of the marking device.
The printer may include a feedback system 74 which includes one or more sensors 76, positioned in the paper path 18, e.g., upstream of one or more of the registration systems 70, 72. Suitable sensors include charge-coupled devices (CCD), contact image sensors (CIS), and similar sensor arrays. Each sensor is configured to acquire sensor data 78, relating to the skew and/or lateral shift of each sheet passing along that part of the paper path 18. The sensor data 78 is used to determine adjustments to the respective registration system 70, 72 if needed, for the particular sheet being registered. For example, the sensor data 78 is acquired from the sensor(s) by a control system 80. The control system includes an input device 82, which receives the sensor data into memory 84. Memory 84, or a separate memory, stores instructions, which are executed by an associated processor device 86, for generating control signals 88, which are output from the control system 80 via a data output device 90. Hardware components 82, 84, 86, 90 of the control system may be communicatively connected by a data/control bus 92. The control signals 88 are received by the respective registration system 70, 72. The respective registration system 70, 72 makes registration adjustments, based on the control signals 88, with the aim of reducing detected lateral shift and/or skew.
In one embodiment, the wall registration system 70 operates without sensor-derived feedback 88.
The control system may also control other components of the printer, such as the marking module 20, finishing module 40, finisher 52 and stacker 54. In one embodiment, the control system receives input image data 94 representing an image to be rendered, and includes instructions for converting the image data 94 into output image data 96 in a form which can be interpreted by the marking module 20.
The illustrated wall registration system 70 includes one or more rotation mechanisms 100, 102, 106, 108 (see also
The gravity-assisted wall registration system 70 may be used for pre-registration to eliminate any large misalignment in the print media position prior to a finer scale registration by the second registration system 72. By eliminating any gross misalignment this makes it possible to utilize larger, heavier media that would traditionally be too difficult to align using conventional registration systems. The wall registration system 70 is able utilize the weight of heavier media to its advantage in aligning the media.
A transport member 110, such as a plate or continuous belt, has an upper surface 112, on which the sheet media 12 is transported by the rotation mechanisms. The member 110 may be formed of sheet metal or plastic. At least a portion of the upper surface 112, is angled to the horizontal, in the cross-process direction B, by an angle θ, as illustrated in
A lower end of the transport member 110 terminates in a registration wall 116, which extends upward and may be angled generally perpendicular to the transport member 110. The wall 116 provides a registration edge for the sheets. The registration wall 116 may be rigidly connected to the member 110, or spaced therefrom. The registration wall 116 provides a barrier to lateral movement of the sheet 12 in the cross-process direction when the sheet 12 makes contact with the registration wall 116. The sheet moves towards the registration wall at least partially under the influence of gravity.
In a first embodiment, illustrated in
The exemplary drive mechanism 124, 126 remains in a fixed position, relative to the process and cross-process directions, during advancement of the sheet, i.e., there is no need to translate the rotation mechanism 100, 102, 106, 108 laterally, towards the wall 116, in order for registration to occur.
The drive members 118, 120, 122 each incorporate a sliding mechanism 138, which allows the sheet 12 to slide, under the force of gravity, towards the registration wall. In one embodiment, the drive members 118, 120, 122, etc., may be formed from rubber or other suitable material. As illustrated in
The drive members 118, 120, 122 are rotated for applying a force to the sheets to translate the sheets in the process direction, thereby moving the print media 12 along the paper path, while the flexible tips 142 of the wheels allow the print media to slide under gravity towards the registration wall 116. Other, similarly configured, rotatable members, such as rotatable members 143, 144, positioned beneath the paper path (
The portion of the paper path 18, in the region of the wall registration system, may gradually increase in angle from horizontal to achieve the angle θ, and then decrease in angle back to horizontal to allow takeaway by the transport downstream. For example, as illustrated in
In a second embodiment, illustrated in
The omni-directional wheels provide drive (traction) normal to the rotation axis 128 while allowing sliding in the motor axis direction. Thus, they provide drive in the same way as regular wheel, but are able to slide freely side to side by positioning of the small rollers 186, 188 around the periphery of the wheel. Having a pair of wheel sections 176, 178, with the peripheral rollers 186, 188 staggered helps to ensure that a part of the wheel is always in contact with the sheet.
As illustrated in
In the illustrated embodiment, each core member has four spokes 192, 194 and carries four rollers 186, 188, although fewer or more rollers and spokes are contemplated, such as from two to six. Additionally, while two wheel sections 176, 178 are shown on each wheel 118, fewer or more than two wheel sections 176, 178 in each wheel are contemplated, such as from one to four wheel sections.
With reference to
In the embodiment of
In the embodiment of
In the embodiment of
As will be appreciated, combinations of the registration assist mechanisms 210, 220, 230 illustrated in
The wall registration system 70 described in
For the embodiment of
The angle θ may be tailored for the expected weight of the sheets. For a lower weight (gsm) paper (which is more difficult to slide down the transport) the angle could be greater than for a higher weight paper. Where the registration system 70 includes a registration assist mechanism 210, 220, 230, as illustrated in
The wall registration system 70 may be used as the sole registration system or may be used in combination with one or more other registration system(s) 72, positioned downstream and/or upstream of the registration system 70. A combination of the gravity-assisted pre-registration system 70 with a second registration system 72 which is generally only suited to use with smaller/lower weight sheets allows registration capabilities of an existing printer to be extended to larger and heavier sheets and/or when operating at faster speeds.
The wall registration system 70 does not need to employ complex steering algorithms which rely on feedback to correct misregistration. Rather, each sheet 12 is registered automatically, and often to different extents, as it passes through the registration system 70.
The gravity-assisted wall registration system 70 substantially reduces or eliminates the gross misalignment from the paper path that can occur with large, heavy media. This eliminates the need for large fishtailing maneuvers.
The registration system 70 is able to utilize the weight of heavier media to assist with the registration process.
The registration system 70 can be incorporated into the paper path of an existing printer design.
With reference to
At S104, a sheet 12 of print media is transported in the process direction A, towards a marking device 22, on a print media path 18, by a sheet transport system 14.
At S106, the sheet of print media is registered with the gravity-assisted wall registration system 70, as described herein, to reduce at least one of skew and lateral shift.
Optionally, at S108, the sheet of print media is registered with second registration system 72, as described herein, to reduce at least one of skew and lateral shift.
At S110, a marking material is applied to the sheet, which has been registered with registration system 70 and optionally registration system 72, with the marking device 22.
At S112, the marked sheet is output. As will be appreciated, the marked sheet may undergo further marking, registering with a wall registration system 70, and/or other processing prior to being output from the printer.
The method ends at S114.
It will be appreciated that variants of the above-disclosed and other features and functions, or alternatives thereof, may be combined into many other different systems or applications. Various presently unforeseen or unanticipated alternatives, modifications, variations or improvements therein may be subsequently made by those skilled in the art which are also intended to be encompassed by the following claims.
Number | Name | Date | Kind |
---|---|---|---|
4179117 | Rhodes, Jr. | Dec 1979 | A |
4775142 | Silverberg | Oct 1988 | A |
5031894 | Bedzyk | Jul 1991 | A |
5065998 | Salomon | Nov 1991 | A |
7735818 | Fournier | Jun 2010 | B2 |
7828286 | Dekoning | Nov 2010 | B2 |
20080179826 | Gregoire | Jul 2008 | A1 |
20150217958 | Dunham et al. | Aug 2015 | A1 |
20150284203 | Terrero et al. | Oct 2015 | A1 |
20180218557 | Cao | Aug 2018 | A1 |
Number | Date | Country |
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56122747 | Sep 1981 | JP |
Number | Date | Country | |
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20190300314 A1 | Oct 2019 | US |