Patent Grant
9108811
Devices and methods herein generally relate to sheet feeding systems, and more particularly to sheet feeding systems that feed sheets to a printing engine.
Special purpose machines, such as printing devices, that feed individual sheets, such as cut sheets of print media (paper, transparencies, plastic sheets, card stock, etc.) commonly utilize closely spaced opposing rollers (one or more of which may be powered) that form a nip to move the individual cut sheets along a media path. One or more specialized circuits (such as a speed control circuit or other form of special-purpose controller) control the speed at which the nips feed sheets along the media path. Some nips are spaced a distance from each other that is less than the length of the sheets of media being fed along the media path. In such situations, if the sheet feeding speeds of the adjacent closely-spaced nips are not properly controlled, undesirable consequences can occur, such as sheet stretching, sheet buckling, etc., which can result in printing errors, print jams, damage to the nips, etc.
In one example, the speeds of the registration and transfer nips within a printing device should be correctly matched, or image defects can occur. Matching the sheet feeding speeds of the nips and the mechanical design can alleviate such problems; although, this may result in a system that is very hard to control precisely. If the sheet feeding speeds are not well matched, such devices cannot guarantee that they will always meet image quality targets. More specifically, such systems are very sensitive to hardware variation, and if tolerances such as roll diameters and media path lengths are not properly controlled, errors can occur.
Various methods herein feed sheets of media along a sheet path to a printing engine. The printing engine comprises a first nip (e.g., registration nip) at a first location of the sheet path, and a second nip (e.g., transfer nip) at a second location of the sheet path. For example, the registration nip removes skew to properly align the sheet edges parallel to the sheet path, and the transfer nip transfers marking material to the sheets of media. The distance between the registration nip and the transfer nip is less than the length(s) of sheets the sheet path is designed to accommodate, which results in the sheets of media being simultaneously driven by the registration nip and the transfer nip at certain times when the sheets are traveling along sheet path.
These methods control the sheet feeding speeds of the registration nip and the transfer nip, using a speed control circuit. More specifically, these methods feed a sheet of media from the registration nip to the transfer nip along the sheet path and maintain the registration nip and the transfer nip at a first sheet feeding speed when the leading edge of the sheet of media is between the registration nip and the transfer nip (using the speed control circuit).
However, these methods create (and maintain) a specific amount of buckle in the sheet of media by first increasing the sheet feeding speed of the registration nip to a second sheet feeding speed while maintaining the transfer nip at the first sheet feeding speed during a first portion of when the sheet of media is simultaneously within the registration nip and the transfer nip, using the speed control circuit. Then, after creating the desired amount of buckle in the sheet of media, these methods decrease the sheet feeding speed of the registration nip back to the first sheet feeding speed, using the speed control circuit. Further, these methods maintain both the registration nip and the transfer nip at the first sheet feeding speed during the remaining portion of when the sheet of media is simultaneously within the registration nip and the transfer nip so as to maintain that specific amount of buckle in the sheet of media during the full amount of the remaining portion of when the sheet of media is simultaneously within the registration nip and the transfer nip, again using the speed control circuit.
Thus, methods herein increase the sheet feeding speed of only the registration nip for only a portion of the time when the sheet is simultaneously held by both nips to first create and then maintain a previously established optimum amount of buckle in the sheet. This optimum amount of buckle, is determined by the methods herein empirically or through modeling so that the amount of buckle that will minimize registration drive frequency effects caused by excess tension in the sheet, while at the same time minimizing image defects that result from vibrations in the sheet caused by excess buckle in the sheet.
Printing devices (apparatuses) herein can include, among other components, a printing engine and a sheet path feeding sheets of media to the printing engine. The sheet path can include, for example, various driven nips (closely spaced opposing rollers (one or more of which may be driven by a motor or actuator)) such as a registration nip at a first location of the sheet path, and a transfer nip at a second location of the sheet path. For example, the registration nip removes skew to properly align the sheet edges to be parallel to the sheet path, and the transfer nip transfers marking material (e.g., toners, inks, etc.) to the sheets of media.
The printing devices herein also include at least one speed control circuit that controls the sheet feeding speeds of the registration nip and the transfer nip. In operation, the registration nip feeds a sheet of media to the transfer nip along the sheet path. The speed control circuit maintains the registration nip and the transfer nip at approximately the same speed (e.g., a first sheet feeding speed) when the leading edge of the sheet of media is between the registration nip and the transfer nip (when the sheet of media is being driven only by the registration nip).
The distance between the registration nip and the transfer nip is less than the length(s) of sheets the sheet path is designed to accommodate, which results in the sheets of media sometimes being simultaneously driven by the registration nip and the transfer nip. With methods herein, the speed control circuit creates a specific amount of buckle in the sheet of media by increasing the sheet feeding speed of the registration nip to a second sheet feeding speed while maintaining the transfer nip at the first sheet feeding speed when the sheet of media is simultaneously within the registration nip and the transfer nip. This “second” sheet feeding speed is greater than the “first” sheet feeding speed, which creates the buckle or bend in the sheet as the sheet is fed faster out of the registration nip than it is taken in by the transfer nip.
Then, after creating this specific amount of buckle in the sheet of media, the speed control circuit decreases the sheet feeding speed of the registration nip back to the first sheet feeding speed so that both the registration nip and transfer nip are again at the same approximate speed. Thus, the speed control circuit maintains the registration nip and the transfer nip at the first sheet feeding speed during the remaining portion of when the sheet of media is simultaneously within the registration nip and the transfer nip to maintain the specific amount of buckle present in the sheet of media during the remaining portion of when the sheet of media is simultaneously within the registration nip and the transfer nip. This “remaining” portion of when the sheet of media is simultaneously within the registration nip and the transfer nip occurs from when the process of creating the specific amount of buckle in the sheet of media is complete, until a trailing edge of the sheet of media exits the registration nip.
The speed difference between the relatively slower first sheet feeding speed of the transfer nip and the relatively faster second sheet feeding speed causes the sheet to buckle between the registration nip and the transfer nip when the sheet of media is simultaneously within the registration nip and the transfer nip. For purposes herein, a “buckle” or “bend” within a sheet occurs when at least a portion of the edges of the sheet that are parallel to the direction in which this sheet is being moved along the sheet path become curved (are no longer completely straight). Such a buckle generally occurs in the location of the sheet away from the leading edge and the trailing edge of the sheet.
This intentionally created buckle prevents the sheet from being stretched between the registration nip and the transfer nip, which prevents the transfer nip from spinning against the print media and reduces printing errors. However, excess buckle can undesirably result in vibrations being delivered to the transfer nip, which can also result in printing errors, or excess buckle can cause the sheet to undesirably contact other components of the printing device. Thus, these devices utilize a previously established optimum amount of buckle in the sheet that balances the competing benefits of minimizing tension while avoiding excesses buckling. This “previously established” amount of buckle in the sheet has been previously established (e.g. empirically, or through modeling, etc.) to minimize registration drive frequency effects caused by excess tension in the sheet, while at the same time minimizing image defects resulting from vibrations in the sheet caused by excess buckle in the sheet. Thus, the speed control circuit first speeds up the registration nip to create a specific amount of buckle, and then keeps both the registration nip and transfer nip at the same speed to maintain that amount of buckle in the sheet during the all the remaining time when the sheet of media is simultaneously within the registration nip and the transfer nip.
These and other features are described in, or are apparent from, the following detailed description.
Various exemplary devices and methods are described in detail below, with reference to the attached drawing figures, in which:
As mentioned above, if the sheet feeding speeds of the adjacent closely-spaced nips are not properly controlled, undesirable consequences can occur, such as sheet stretching, sheet buckling, etc., which can result in printing errors, print jams, damage to the nips, etc.
Therefore, the devices and methods herein maintain a specific amount of buckle in sheets that are held simultaneously by the registration nip than the transfer nip. With the devices herein, sheets are transferred from the registration rolls to the transfer tip using a nip roller and a drive roller driven by a stepper motor. The transfer nip, photoreceptor, and bias transfer roller (BTR) can be controlled by a constant velocity brushless DC motor, for example. To avoid image defects, the registration nip can be driven faster than the photoreceptor nip so that a buckle is formed in the sheet between the registration and transfer nips, thereby preventing the sheet from being pulled tight (which causes image defects).
Constraints in the media path may only allow for a certain amount of buckle to be formed, and any amount of buckle greater than this may cause image defects at the trail edge of the print media. Image defects may occur if the registration nip speed is too slow or too fast, and such visual defects are exacerbated on long medias. The devices and methods herein actively control the speed of the registration nip stepper motor to maintain the optimum sheet buckle over the period of time that the sheet is being driven simultaneously by the registration nip and the transfer nip.
Therefore, with methods and devices herein, the transfer nip runs at constant velocity as controlled by a brushless DC motor, for example. With devices herein, a hybrid stepper can control the registration nip, allowing the nip speed to be altered as the sheet passes through registration. To achieve an image transferred to the required media a sheet is delivered from the registration nip to the transfer nip. While the image is being transferred from the transfer belt or photoreceptor to the media, the media will be in both the registration nip and the transfer nip until the trailing edge of the print media sheet leaves the registration nip.
As noted above, the media should not be tight between the registration nip and the transfer nip, nor should too much buckle be generated. More specifically, if the media is tight, then registration drive frequency effects can be transferred to the image. Conversely, if the media buckle is too large, then image defects will occur when the media trailing edge leaves the registration nip. To achieve the optimum media buckle between the registration nip and the transfer nip, the sheet feeding speed of only the registration nip is increased for only a portion of the time when the sheet is simultaneously held by both nips, to first create, and then maintain, a previously established optimum amount of buckle in the sheet.
For example, the registration nip 110 is formed between opposing rollers 112, 114, at least one of which is powered by a motor, such as a stepper motor that has the ability to change the rotational speed of one of the rollers 112, 114, thereby changing the sheet forwarding speed of the registration nip 110. As is understood by those ordinarily skilled in the art, the registration nip 110 removes skew to properly align the sheet edges to be parallel to the sheet path 236.
The transfer nip 120 is formed between pressure roller 122 and a transfer device 124 that contains marking material that is to be transferred to the sheet of media 102. For example, the transfer device 124 can comprise a photoreceptor (PR), an intermediate transfer belt (ITB), or any other surface that contains patterned marking material (e.g., toners, inks, etc.) that is to be transferred to the sheet of media 102. The pressure roller 122 or the transfer device 124 can be powered by a motor to provide a sheet feeding speed for the transfer nip 120.
While nips 110 and 120 are referred to herein as transfer and registration nips, respectively, those ordinarily skilled in the art would understand that these nips are only used as examples, and that the methods and devices herein are equally applicable to any closely spaced nips that would benefit from a fed cut sheets maintaining a consistent buckle between such nips. Further, the methods and devices herein are greatly distinguished from systems that feed uncut webs of print media from rolls, because cut sheets have unique issues associated with vibrations and other physical repercussions resulting from rolls contacting the leading and trailing edges of the sheets and continuously fed webs of material do not experience such issues because they do not have leading or trailing edges. Therefore, experiences from the art of continuously fed webs of material are not germane to the art of feeding cut sheets within media paths.
The printing devices herein also include at least one speed control circuit 224 (shown in
As shown in
With methods herein, the speed control circuit 224 creates a specific amount of buckle in the sheet of media 102 by increasing the sheet feeding speed of the registration nip 110 to a second sheet feeding speed while maintaining the transfer nip 120 at the first sheet feeding speed when the sheet of media 102 is simultaneously within the registration nip 110 and the transfer nip 120. This “second” sheet feeding speed is greater than the “first” sheet feeding speed, which creates the buckle or bend in the sheet as the sheet is fed faster out of the registration nip 110 than it is taken in by the transfer nip 120.
More specifically, as shown in
Then, after creating this specific amount of buckle (consistently having length Y and height X) in the sheet of media 102, as shown in
Thus, in the schematic illustration shown in
The “first” portion is when the sheet of media is simultaneously within the registration nip 110 and the transfer nip 120, and when the registration nip 110 is at a relative higher sheet forwarding speed and the buckle is being formed, as shown in
The speed difference between the relatively slower first sheet feeding speed of the transfer nip 120 and the relatively faster second sheet feeding speed shown in
As noted above, the buckle is formed to specifically have length Y and height X (
More specifically, this intentionally created amount of buckle (or buckle shape) prevents the sheet from being stretched between the registration nip 110 and the transfer nip 120, which prevents the transfer nip 120 from spinning against the print media 102 and reduces printing errors. However, excess buckle can undesirably result in vibrations being delivered to the transfer nip 120, which can also result in printing errors, or excess buckle can cause the sheet to undesirably contact other components of the printing device.
Simply maintaining the registration nip 110 always at a higher relative speed to the transfer nip 120 would cause the buckle to constantly grow until the trailing edge 104 of the sheet of media 102 exited the registration nip 110, which could result in a buckle that was too small at certain times and too large at other times. By increasing the speed of the registration nip 110 only a portion of the time that the sheet of media 102 is maintained between the nips 110, 120, the size and shape of the buckle can be maintained consistently for most of the time while the sheet of media 102 is simultaneously within both nips 110, 120.
Thus, these devices and methods create a previously established optimum amount of buckle in the sheet that balances the competing benefits of minimizing tension while avoiding excesses buckling. This “previously established” amount of buckle in the sheet has been previously established (e.g. empirically, through modeling, etc.) to minimize registration drive frequency effects caused by excess tension in the sheet, while at the same time minimizing image defects resulting from vibrations in the sheet caused by excess buckle in the sheet for a given printing device. Thus, the speed control circuit 224 first speeds up the registration nip 110 to create a specific amount of buckle, and then keeps both the registration nip 110 and transfer nip 120 at the same speed to maintain that amount of buckle in the sheet during all the remaining time when the sheet of media 102 is simultaneously within the registration nip 110 and the transfer nip 120.
The transfer buckle time 158 is the period beginning at point 152 and continuing until the buckle is fully formed in the sheet of media 102. Beginning when the leading edge 106 of the sheet of media 102 enters the transfer nip 120 at item 160 (Media LE @ Transfer Nip) during the last part of the transfer buckle time 158, the speed of the registration roller 112 is increased to a second speed 162 (e.g., RegBuckleSpeed) that is greater than the first speed (greater than the registration approach speed 156). Note that during the last part of the transfer buckle time 158, the rollers of the transfer nip are rotating at the registration approach speed 156, to allow the buckle to be formed in the sheet of media. Once the buckle is fully formed at the end of item 158, the speed of the registration roller 112 is decreased back down to the registration approach speed 156. Note that the transfer buckle time 158 begins at the same time the transfer approach time 154 begins for convenience of timing; however, the transfer buckle time 158 could begin at time 160 and only measure the actual time that the buckle is formed. Additionally, the registration process speed 164 (RegProcessSpeed) can be the same or different from speed 154 (RegApproachSpeed) if required to cope with system variations, but is set to maintain the buckle once formed. Speed 164 is maintained by the registration roller 112 until the trailing edge 104 of the sheet of media exits the registration nip 110.
In item 182, these methods feed the sheets of media along the sheet path to the printing engine. For example, the registration nip removes skew to properly align the sheet edges parallel to the sheet path, and the transfer nip transfers marking material to the sheets of media. The distance between the registration nip and the transfer nip is less than the length(s) of sheets the sheet path is designed to accommodate, which results in the sheets of media being simultaneously driven by the registration nip and the transfer nip at certain times when the sheets are traveling along sheet path.
These methods control the sheet feeding speeds of the registration nip and the transfer nip, using a speed control circuit. More specifically, these methods feed a sheet of media from the registration nip to the transfer nip along the sheet path and, in item 184, maintain the registration nip and the transfer nip at a first sheet feeding speed when the leading edge of the sheet of media is between the registration nip and the transfer nip (using the speed control circuit).
However, in item 186, these methods create (and maintain) a specific amount of buckle in the sheet of media by first increasing the sheet feeding speed of the registration nip to a second sheet feeding speed, while maintaining the transfer nip at the first sheet feeding speed, during a first portion of when the sheet of media is simultaneously within the registration nip and the transfer nip, using the speed control circuit. Then, in item 188, after creating the desired amount of buckle in the sheet of media, these methods decrease the sheet feeding speed of the registration nip back to the first sheet feeding speed, using the speed control circuit. Further, as shown in item 190, these methods maintain both the registration nip and the transfer nip at the first sheet feeding speed during the remaining portion of when the sheet of media is simultaneously within the registration nip and the transfer nip (e.g., until the trailing edge of the sheet of media exits the registration nip) so as to maintain that specific amount of buckle in the sheet of media during the full amount of the remaining portion of when the sheet of media is simultaneously within the registration nip and the transfer nip, again using the speed control circuit.
The input/output device 214 is used for communications to and from the printing device 204 and comprises a wired device or wireless device (of any form, whether currently known or developed in the future). A specialized image processor 224 (that is different from a general purpose computer because it is specialized for processing image data and controlling internal components of a printing device, such as the speed of nips, etc.) controls the various actions of the computerized device. A non-transitory, tangible, computer storage medium device 210 (which can be optical, magnetic, capacitor based, etc., and is different from a transitory signal) is readable by the tangible processor 224 and stores instructions that the tangible processor 224 executes to allow the computerized device to perform its various functions, such as those described herein. Thus, as shown in
The printing device 204 includes at least one marking device (printing engine(s)) 240 operatively connected to the specialized image processor 224, a media path 236 positioned to supply sheets of media from a sheet supply 230 to the marking device(s) 240, etc. After receiving various markings from the printing engine(s) 240, the sheets of media can optionally pass to a finisher 234 which can fold, staple, sort, etc., the various printed sheets. Also, the printing device 204 can include at least one accessory functional component (such as a scanner/document handler 232 (automatic document feeder (ADF)), etc.) that also operate on the power supplied from the external power source 220 (through the power supply 218).
The one or more printing engines 240 are intended to illustrate any marking device that applies a marking material (toner, inks, etc.) to sheets of media, whether currently known or developed in the future and can include, for example, devices that use a photoreceptor belt 248 (as shown in
More specifically,
The photoreceptor belt 248 is driven (using, for example, driven rollers 252) to move the photoreceptor in the direction indicated by the arrows past the development stations 242, and a transfer station 238. Note that devices herein can include a single development station 242, or can include multiple development stations 242, each of which provides marking material (e.g., charged toner) that is attracted by the patterned charge on the photoreceptor belt 248. The same location on the photoreceptor belt 248 is rotated past the imaging station 246 multiple times to allow different charge patterns to be presented to different development stations 242, and thereby successively apply different patterns of different colors to the same location on the photoreceptor belt 248 to form a multi-color image of marking material (e.g., toner) which is then transferred to print media at the transfer station 238.
As is understood by those ordinarily skilled in the art, the transfer station 238 generally includes rollers and other transfer devices. Further, item 222 represents a fuser device that is generally known by those ordinarily skilled in the art to include heating devices and/or rollers that fuse or dry the marking material to permanently bond the marking material to the print media.
Thus, in the example shown in
Alternatively, printing engine(s) 240 shown in
One exemplary individual electrostatic marking station 250 is shown in
While
Thus, in printing devices herein a latent image can be developed with developing material to form a toner image corresponding to the latent image. Then, a sheet is fed from a selected paper tray supply to a sheet transport for travel to a transfer station. There, the image is transferred to a print media material, to which it may be permanently fixed by a fusing device. The print media is then transported by the sheet output transport 236 to output trays or a multi-function finishing station 234 performing different desired actions, such as stapling, hole-punching and C or Z-folding, a modular booklet maker, etc., although those ordinarily skilled in the art would understand that the finisher/output tray 234 could comprise any functional unit.
As would be understood by those ordinarily skilled in the art, the printing device 204 shown in
While some exemplary structures are illustrated in the attached drawings, where like numbers identify the same or similar items, those ordinarily skilled in the art would understand that the drawings are simplified schematic illustrations and that the claims presented below encompass many more features that are not illustrated (or potentially many less) but that are commonly utilized with such devices and systems. Therefore, Applicants do not intend for the claims presented below to be limited by the attached drawings, but instead the attached drawings are merely provided to illustrate a few ways in which the claimed features can be implemented.
Many computerized devices are discussed above. Computerized devices that include chip-based central processing units (CPU's), input/output devices (including graphic user interfaces (GUI), memories, comparators, tangible processors, etc.) are well-known and readily available devices produced by manufacturers such as Dell Computers, Round Rock Tex., USA and Apple Computer Co., Cupertino Calif., USA. Such computerized devices commonly include input/output devices, power supplies, tangible processors, electronic storage memories, wiring, etc., the details of which are omitted herefrom to allow the reader to focus on the salient aspects of the devices and methods described herein. Similarly, printers, copiers, scanners and other similar peripheral equipment are available from Xerox Corporation, Norwalk, Conn., USA and the details of such devices are not discussed herein for purposes of brevity and reader focus.
The terms printer or printing device as used herein encompasses any apparatus, such as a digital copier, bookmaking machine, facsimile machine, multi-function machine, etc., which performs a print outputting function for any purpose. The details of printers, printing engines, etc., are well-known and are not described in detail herein to keep this disclosure focused on the salient features presented. The devices and methods herein can encompass devices and methods that print in color, monochrome, or handle color or monochrome image data. All foregoing devices and methods are specifically applicable to electrostatographic and/or xerographic machines and/or processes.
In addition, terms such as “right”, “left”, “vertical”, “horizontal”, “top”, “bottom”, “upper”, “lower”, “under”, “below”, “underlying”, “over”, “overlying”, “parallel”, “perpendicular”, etc., used herein are understood to be relative locations as they are oriented and illustrated in the drawings (unless otherwise indicated). Terms such as “touching”, “on”, “in direct contact”, “abutting”, “directly adjacent to”, etc., mean that at least one element physically contacts another element (without other elements separating the described elements). Further, the terms automated or automatically mean that once a process is started (by a machine or a user), one or more machines perform the process without further input from any user.
It will be appreciated that the above-disclosed and other features and functions, or alternatives thereof, may be desirably 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. Unless specifically defined in a specific claim itself, steps or components of the devices and methods herein cannot be implied or imported from any above example as limitations to any particular order, number, position, size, shape, angle, color, or material.
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