Patent Grant
9250594
1. Field of Disclosed Subject Matter
This disclosure relates to systems and methods for implementing an asynchronous buffering module and/or scheme employing an integrated registration function, particularly for in-line printing in an image forming system.
2. Related Art
Most modern, sometimes complex, image forming systems include one or more techniques for image forming on both sides of an image receiving media substrate. These two-sided or duplex printing functions typically include the input of a sheet of image receiving media from an input tray and translation of the sheet of image receiving media, via a first transport path, through a media marking engine that is configured to deposit a marking material on a first surface of the sheet of image receiving media. The image may then be fused, or otherwise fixed, on the first surface of the sheet of image receiving media. With a duplex mode selected in the image forming system, the sheet of image receiving media is not output to an output tray. Rather, the sheet of image receiving media is translated, via a second (duplex) transport path, to a beginning of the first transport path, the second (duplex) transport path including a sheet inversion function or unit that results in the sheet of image receiving media being reintroduced, via the first transport path, through the media marking engine again such that the marking material is deposited on a second surface of the sheet of image receiving media. The sheet of image receiving media may then be passed to, or through, an image fusing/fixing unit to finally finish the images on the first and second surfaces of the sheet of image receiving media, prior to passing the sheet of image receiving media to a post-processing device, or to an output tray.
Regardless of the simplicity or complexity of the two-sided or duplex printing operations, duplexing operations typically significantly reduce the page-per-minute (ppm) throughput of the image forming system. The manipulations of the sheets of image receiving media to cause them to appropriately pass through the single media marking engine twice before ultimately being passed downstream in the process direction account for a significant percentage of the reductions in throughput.
Image forming system designers and manufacturers, driven by the competitive nature of the business and in an effort to meet ever increasing production requirements levied by their customers, have sought solutions to limit the reductions in image receiving media throughput in their devices, particularly in a duplex printing mode. One solution to increase the throughput in duplex image forming operations in an image forming system that is to place two marking engines, each operating in a single-side printing or simplex mode, in series.
In duplex image forming configurations including serial simplex media marking engines, as described above and as generally depicted in
Separately, printing systems, media marking engines, and other, including third party, media handling systems require that input registration characteristics of the sheets of image receiving media meet specific criteria. Generally, an output of one media marking engine does not necessarily provide the registration performance to allow a downstream media marking engine to re-register the sheet of image receiving media substrate to proper specifications.
Further compounding the registration dilemma is that the downstream media marking engine, if not identical, i.e., a third party system, may have different registration standards. For example, a first media marking engine may be edge registered while a second media marking engine may be center registered, or vice versa.
Media marking engines, as those devices may be referenced throughout this disclosure, are not intended to be devices that are restricted to employment of any particular media marking materials, e.g., inks, toners and the like, or to any particular delivery mechanisms for those media marking materials, including but not limited to, xerographic image forming, inkjet delivery, laser marking, lithographic ink delivery or the like. Further, the media marking engines described in this disclosure may include initial image finishing components, e.g., fuser modules for fusing and/or fixing the delivered media marking materials on the surfaces of the image receiving media by heat, pressure, or a combination of the two. It should be recognized, however, that the initial image finishing components may be separate, stand-alone devices or may be incorporated as portions of other media post-processing devices.
It would be advantageous in view of the above-noted circumstances arising from image forming and fixing operations in image forming systems employing multiple in-line simplex media marking engines arranged in series to implement a mechanism or scheme that may include an asynchronous buffering module with the capacity to modify the timing of individual sheets of image receiving media as they pass between the in-line simplex media marking devices. It may be further advantageous to augment such a buffering module with an integrated registration function for the in-line duplex printing. Such a combined mechanism or scheme may provide a capacity between the multiple media marking engines to effect timing synchronization and re-registration for the sheets of image receiving media exiting the first serial media marking engine allowing them to be properly timed and registered, as appropriate, for feeding to the second serial media marking engine.
Exemplary embodiments of the systems and methods according to this disclosure may implement a separate module that is configured of a plurality of separate buffering trays that may provide a capacity for handling the sheets of image receiving media output by a first media marking device and buffering those sheets of image receiving media in a manner that times the outputs of the first media marking device to meet the required input timing for the second media marking device. Such a buffering module may allow each of the individual media marking devices to conduct image forming operations at simplex speeds, thereby resulting in increased coordinated and unimpeded duplex image forming operation throughput.
Exemplary embodiments may divert individual sheets of image receiving media to one of a plurality of buffering slots and then time their release from the buffering slots to match an optimal timing for input of the individual sheets of image receiving media to the downstream media marking device. In this manner, timing discrepancies between the two in-line media marking devices may be reduced, or otherwise substantially eliminated.
Exemplary embodiments may take an asynchronous combination of media marking devices and synchronize the feed of sheets of image receiving media between the media marking devices.
Exemplary embodiments may include a selectable mode in a buffering module whereby, when the image forming system is operated in a simplex mode, sheets of image receiving media may pass straight through the buffering module without being diverted into one of a plurality of buffering slots.
Exemplary embodiments may augment the buffering and/or timing modification capacity of the disclosed buffering module by combining a registration unit with buffering bins to provide appropriate registration of sheets of image receiving media passing therethrough to make the registration of the sheets compatible with the input requirements of the downstream media marking device.
In embodiments, an integral or connected registration unit may take the form of a translating electronic registration or TELER system. The TELER registration system may include a moveable top edge registration sensor or CCD, and be capable of, for example, taking a center registered sheet and re-registering the sheet to the edge as an edge registered sheet, or vice versa, to make compatible both an input and output to the specific requirements of the individual media marking devices with regard to being either edge or center registered systems.
These and other features, and advantages, of the disclosed systems and methods are described in, or apparent from, the following detailed description of various exemplary embodiments.
Various exemplary embodiments of the disclosed systems and methods for implementing an asynchronous buffering module and/or scheme employing an integrated registration function, particularly for in-line duplex printing in an image forming system, will be described, in detail, with reference to the following drawings, in which:
The systems and methods for implementing an asynchronous buffering module and/or scheme employing an integrated registration function, particularly for in-line printing in an image forming system according to this disclosure will generally refer to this specific utility or function for those systems and methods. Exemplary embodiments described and depicted in this disclosure should not be interpreted as being specifically limited to any particular configuration of the described elements, or as being specifically directed to any particular intended use, including any particular functioning or operation of a plurality of in-line single-side or simplex media marking devices in an image forming system. Any advantageous combination of features, schemes, techniques and/or processes that may employ a particularly-configured structure of a module for modifying a timing of individual sheets of image receiving media passing between the plurality of in-line single-side simplex media marking devices, including implementing a re-registration function to render compatible an output registration from the first media marking device to an input registration for the second media marking device is contemplated as being encompassed by this disclosure.
Specific reference to, for example, various configurations of image forming systems, individual media marking devices, and other component devices within those systems, including sheet inverters, post-processors and the like, as those concepts and related terms are captured and used throughout this disclosure, should not be considered as limiting those concepts or terms to any particular configuration of the respective devices, the overall system or the individually-described elements. The subject matter of this disclosure is intended to broadly encompass systems, devices, schemes and elements that may involve image forming and finishing operations as those operations would be familiar to those of skill in the art. The disclosed concepts are particularly adapted to implementing timing adjustment for the feeding of sheets of image receiving media from a first simplex media marking device to a second downstream in-line simplex media marking device, and for supplementing the timing adjustment with appropriate re-registration of the sheets of image forming media as necessary to facilitate ease of operations for second-side printing on the sheets of image receiving media in the second downstream in-line simplex media marking device.
A plurality of similarly-configured buffering or timing control passages (referred to alternatively as bins, slots, portals or trays) 320,330,340,350 may be provided. Each of the plurality of timing control passages 320,330,340,350 may include a media transport nip 322 and timing control passage entrance gate or diverter 324 that is movable between two positions. The two positions for the timing control passage entrance gate(s) or diverter(s) 324 may include a first position that diverts the sheet of image receiving media into a respective one of the timing control passages 320,330,340,350, and a second position that allows the sheet of image receiving media to bypass respective ones of the timing control passages 320,330,340,350.
In instances where, for example, the image forming system with which the exemplary device 300 is associated recognizes that a commanded image forming operation is a single-side simplex image forming operation, each of the entrance gates or diverters may be commanded to the second position. By positioning each of the entrance gates or diverters to the second position, the sheets of image receiving media substrates having been marked on a first surface by the upstream single-side simplex media marking device, may be passed along to a simplex transport path 360. The simplex path 360 may include a series of simplex transport path nips 365 for transporting the sheets of image receiving media to a first (simplex) outlet portal 370. In this manner, the sheets of image receiving media may be transported downstream in a process direction via a transport path that bypasses a second downstream single-side simplex media marking device (see
In instances where the image forming system with which the exemplary device 300 is associated recognizes that a commanded image forming operation is a two-sided duplex image forming operation, one of the entrance gates or diverters associated with a currently unoccupied one of the timing control passages 320,330,340,350 may be commanded to the first position thereby diverting the sheet of image receiving media into the one of the timing control passages 320,330,340,350. The sheet of image receiving media may be transported downward into the one of the timing control passages 320,330,340,350 through a series of timing control passage nips 326. A presence of a sheet in the one of the timing control passages 320,330,340,350 may be sensed by one or more timing control passage media sensors 328. A signal may be generated by the timing control passage media sensor 328 to communicate to the second downstream single-side simplex media marking device that a sheet of image receiving media is held in the one of the timing control passages 320,330,340,350 awaiting release. In this manner, the sheets of image receiving media may be buffered in a manner that controls their timing before being passed via a timing control output roller 329 into a timing control exit path 380 for further transport. The timing control exit path 380 may include a series of timing control exit path nips 382 for transporting the sheets of image receiving media in a downstream direction.
The timing control exit path 380 may, for example, direct the sheets of image receiving media downstream in a process direction past one or more sensors, including a registration process sensor 384 in a vicinity of registration nip 386 leading to an entrance to a media re-registration device 390. More detail of an exemplary media re-registration device will be provided below with reference to
Ultimately, a properly timed and properly registered sheet of image receiving media substrate may be directed to a second (duplex) outlet portal 392. In this manner, the sheets of image receiving media may be transported downstream in a process direction via, for example, one or more additional transport nips 395 to the second downstream single-side simplex media marking device (see
As described, the exemplary device 300 is provided as a separate module that is configured to include of a plurality of buffering trays capable of handling an output of the first upstream single-side simplex media marking device, and buffering that output such that it is then timed to meet the timing requirements/constraints of the second downstream single-side simplex media marking device. This allows each of the separate media marking devices to operate efficiently at simplex speeds, thereby resulting in increased throughput for the image forming system with which the exemplary device 300 is associated when conducting duplex image forming operations.
By diverting the sheets of image receiving media individually to one of the plurality of timing control passages 320,330,340,350 for duplex image forming operations, their release to match the second downstream single-side simplex media marking device input, timing discrepancies between the two single-side simplex media marking devices can be substantially eliminated. This takes the asynchronous nature of the combination of the two single-side simplex media marking devices and synchronizes the sheet of image receiving media feed between them.
The registration component 450 may be comprised of any commonly-known device for facilitating registration of individual documents. One such common device known in the art is typically referred to as a TELER system. A TELER system typically provides a method of registering copy paper or documents. The TELER system generally includes three optical sensors, a pair of coaxial independently driven drive rolls, a carriage with a linear drive on which paper drive rolls are mounted, and a microprocessor controller. A sheet of image receiving media is driven into the nip rolls and moved through the paper path for placement and fusing of an image thereon. The speed of both nip rolls may be controlled to effect skew alignment and longitudinal registration. The nip rollers may generally be mounted on a carriage movable transversely with respect to the feed path. A sensor system may control positioning of the carriage to achieve the desired top edge or a lateral positioning of the sheet. Independent control of nip roll drive and carriage translation provides simultaneous alignment in lateral and longitudinal directions. A TELER system of this type is disclosed in U.S. Pat. No. 5,094,442 to Kamprath et al., issued Mar. 10, 1992, and discussed at some length in U.S. Pat. No. 5,794,176 to William D. Milillo, issued Aug. 11, 1998, and U.S. Pat. No. 6,910,689 to Kevin M. Carolan, issued Jun. 28, 2005. These patents are co-owned by the Assignee of this application, and the contents of their disclosures are hereby incorporated by reference herein in their entireties.
By incorporating a TELER system with a moveable top edge registration sensor, for example, as the media re-registration device 400, the TELER system can take a center registered sheet and register it to the edge, or an edge registered sheet and register it to the center making both the input and output compatible with edge and center registered systems. The time controlled and registered sheet of image receiving media may then be passed out of the media re-registration device via an internal output port 454, an outlet drive nip 460, one or more sensors 470 for confirming registration of the sheet of image receiving media and then out of the media re-registration device 400 via an outlet port 480 for transport to the second downstream single-side simplex media marking device.
Inclusion of a buffering and registration module, generally configured as described above, responds to a need in in-line print systems by providing an ability to match the print timing and, in some cases, registration of the first simplex media marking device to that of the second simplex media marking device facilitating selection for the media marking devices to work either independently or coupled. The disclosed buffering and registration module thus constitutes a device that, in essence, performs as another stacker to the first media marking device, while performing like a feeder module to the second media marking device. The internal buffering capability of the disclosed buffering and registration module may actively orchestrate media flow between both media marking devices and eliminate device to device synchronization in a coupled mode. The included registration function may ensure that any output registration issues from the upstream media marking device are corrected prior to feeding the downstream media marking device.
Typically, the disclosed buffering and registration module may be required to host from three to five sheets of image receiving media to enable the system to function, but the system may be expanded to larger numbers of bins to accommodate larger buffering capacity. The disclosed buffering and registration module functions as a sheet delaying and registration station and not a module where sheet re-acquisition is required. Because the sheets of image receiving media are never compiled, they do not require singulation to feed to the downstream media marking device. By not requiring any sheet re-acquisition, the overall module will have a high degree of reliability. The added function of registration corrects for any accumulated registration error from the upstream media marking device. This function may be particularly relevant when dealing with larger media lengths, where incoming skew to the downstream media marking device may be limited and must be controlled to a tight specification.
The exemplary control system 500 may include an operating interface 510 by which a user may communicate with the exemplary control system 500 for directing at least a mode of operation of a media buffering and/or registration device in the image forming system. Control inputs received in the exemplary control system 500 via the operating interface 510 may be processed and communicated to the image forming system via one or more of a buffering and timing control unit 570 or a registration/re-registration unit 580. The operating interface 510 may be a locally accessible user interface associated with the image forming system, which may be configured as one or more conventional mechanisms common to control devices and/or computing devices that may permit a user to input information to the exemplary control system 500. The operating interface 510 may be a part of a function of a graphical user interface (GUI) mounted on, integral to, or associated with, the image forming system with which the exemplary control system 500 is associated to direct processing or post-processing image receiving media transport in the associated image forming system.
The exemplary control system 500 may include one or more local processors 520 for individually operating the exemplary control system 500. The processor 520 may reference image forming operation and/or individual media marking device characteristics that may stored, for example, in one or more data storage devices 530. Processor(s) 520 may include at least one conventional processor or microprocessor that interprets and executes instructions to direct specific functioning of the exemplary control system 500 and an associated image forming system for processing and/or post-processing of image formed documents.
The exemplary control system 500 may include one or more data storage devices 530. Such data storage device(s) 530 may be used to store data or operating programs to be used by the exemplary control system 500, and specifically the processor(s) 520 in carrying into operation the disclosed functions. Data storage device(s) 530 may be used to store information regarding the image forming operation carried out by the image forming system as well as specific timing and/or registration requirements for each of the multiple image marking devices in the image forming system. Stored schemes and operating parameters may be referenced to control aspects of the image forming functions as well as determining optimum timing and/or registration conditions to be effected by the media buffering and/or registration device controlled by the exemplary control system 500.
The data storage device(s) 530 may include a random access memory (RAM) or another type of dynamic storage device that is capable of storing updatable database information, and for separately storing instructions for execution of system operations by, for example, processor(s) 520. Data storage device(s) 530 may also include a read-only memory (ROM), which may include a conventional ROM device or another type of static storage device that stores static information and instructions for processor(s) 520. Further, the data storage device(s) 530 may be integral to the exemplary control system 500, or may be provided external to, and in wired or wireless communication with, the exemplary control system 500.
The exemplary control system 500 may include at least one data output/display device 540, which may be configured as one or more conventional mechanisms that output information to a user, including, but not limited to, a display screen on a GUI of the image forming system with which the exemplary control system 500 may be associated. The data output/display device 540 may be used to indicate operating conditions or modes of the media buffering and/or registration device.
Where appropriate, the exemplary control system 500 may include at least one external data communication interface 550 by which the exemplary control system 500 may communicate with the image forming system for effecting image forming operations and post-processing operations including control of the media buffering and/or registration device.
An image receiving media sensor analyzing unit 560 may be provided as a standalone device or as a portion, and/or as a function, of the processor 520 in communication with the at least one data storage device 530. The image receiving media sensor analyzing unit 560 may collect and process information from one or more sensors positioned throughout the media buffering and/or registration device to establish parameters for operating control functions to carry into effect by the media buffering and/or registration device generally as described above.
The exemplary control system 500 may include a buffering and timing control unit 570 by which signals are generated to operate the media buffering and/or registration device, in the manner described above, to execute timing control of the sheets of image receiving media passing therethrough for facilitating precise duplex image forming operations in an image forming system. Signals generated by the buffering and timing control unit 570 may be based on a detection and isolation of a position of individual sheets of image receiving media passing through the media buffering and/or registration device. Signals generated by the buffering and timing control unit 570 may also be sent to the second downstream single-side simplex media marking device to identify that a sheet of image receiving media is available for release to the downstream single-side simplex media marking device. Return signals may be received by the buffering and timing control unit 570 from the second downstream single-side simplex media marking device to cause an available sheet of image receiving media to be released for processing in the downstream single-side simplex media marking device according to timing controlled by the media marking device.
The exemplary control system 500 may include a registration/re-registration control unit 580 by which signals are generated to operate the media buffering and/or registration device in the manner described above to direct registration of a sheet of image receiving media passing therethrough in order to make the physical registration of the sheet of image receiving media comport with requirements of the second downstream single-side simplex media marking device by reference to parameters of that media marking device that may be recovered from the media marking device itself, or that may be stored, for example, in one or more data storage devices 530.
All of the various components of the exemplary control system 500, as depicted in
It should be appreciated that, although depicted in
The disclosed embodiments may include an exemplary method for implementing image forming operations including selectable in-line media processing, which may include media buffering and/or re-registration, in an image forming system.
In Step S6050, two single-side simplex media marking modules may be arranged in series in a process direction for duplex image forming in an image forming system. Operation of the method proceeds to Step S6100.
In Step S6100, a duplex coupling module for at least one of (1) media buffering and/or timing modification, and (2) media re-registration may be provided between the two single-side simplex media marking modules in the image forming system. Operation of the method proceeds to Step S6150.
In Step S6150, a print command may be received by the image forming system for execution of an image forming operation in the image forming system. Operation of the method proceeds to Step S6200.
In Step S6200, a sheet of image receiving media may be transported from an input media source to a first of the two single-side simplex media marking modules in the image forming system. Operation of the method proceeds to Step S6250.
In Step S6250, an image may be formed on a first side of the sheet of image receiving media with the first of the two single-side simplex media marking modules in the image forming system. Operation of the method proceeds to Step S6300.
Step S6300 is a determination step. In Step S6300, a determination is made regarding whether the image forming operation undertaken in the image forming system according to the print command is a duplex image forming operation.
If in Step S6300, it is determined that the image forming operation undertaken in the image forming system according to the print command is not a duplex image forming operation, operation of the method proceeds to Step S6350.
In Step S6350, the sheet of image receiving media may be transported in a bypass mode through the duplex coupling module exiting the duplex coupling module via a first output portal that in turn may direct the sheet of image receiving media to bypass a second of the two single-side simplex media marking modules in the image forming system. Operation of the method proceeds to Step S6550.
If in Step S6300, it is determined that the image forming operation undertaken in the image forming system according to the print command is a duplex image forming operation, operation of the method proceeds to Step S6400.
In Step S6400, the sheet of image receiving media may be transported through the duplex coupling module in a processing mode, which will be described in further detail below with reference to the method depicted in
In Step S6450, the sheet of image receiving media substrate may be transported from the duplex coupling module to the second of the two single-side simplex media marking modules. Operation method proceeds to Step S6500.
In Step S6500, an image may be formed on a second side of the sheet of image receiving media in the second of the two single-side simplex media marking modules. Operation of the method proceeds to Step S6550.
In Step S6550, an image product of the image forming operation on the sheet of image receiving media may be output from the image forming system. Operation of the method proceeds to Step S6600, where operation of the method ceases.
The disclosed embodiments may include an exemplary method for media buffering and/or re-registration between multiple in-line media marking devices in an image forming system.
In Step S7050, a first sheet of image receiving media may be transported from a first single-side simplex marking device by which an image has been formed on a first surface of the first sheet of image receiving media to a duplex coupling module. Operation of the method proceeds to Step S7100.
In Step S7100, for single-side simplex image forming operations, the first sheet of image receiving media may be transported via a bypass path through the duplex coupling module directly to a first output portal. The first output portal may provide a transport mechanism by which a second downstream single-side simplex marking device may be bypassed. Operation of the method proceeds to Step S7150.
In Step S7150, for double-side duplex image forming operations, a leading edge and trailing edge of the first sheet of image receiving media may be sensed with an entrance sensor in the duplex coupling module. The sensing may facilitate analysis undertaken for timing control of the first sheet of image receiving media substrate in the duplex coupling module prior to being passed downstream to the second single-side simplex media marking device. Operation of the method proceeds to Step S7200.
In Step S7200, the first sheet of image receiving media may be diverted into an unoccupied one of a plurality of buffering bins in the duplex coupling module. Operation of the method proceeds to Step S7250.
In Step S7250, a leading edge and trailing edge of a second and subsequent sheet of image receiving media may be sensed with the entrance sensor in the duplex coupling module. This sensing may facilitate analysis undertaken for timing control of the second and subsequent sheet of image receiving media substrate in the duplex coupling module prior to being passed downstream to the second single-side simplex media marking device. Operation of the method proceeds to Step S7300.
In Step S7300, the second and subsequent sheet of image receiving media substrate may be diverted into other unoccupied ones of the plurality of buffering bins in the duplex coupling module. Operation of the method proceeds to Step S7350.
In Step S7350, a signal may be sent to the second downstream single-side simplex media marking device that the first sheet of image receiving media is ready to be fed to the second downstream single-side simplex media marking device. Operation of the method proceeds to Step S7400.
In Step S7400, based on signals exchanged between the duplex marking module and the second downstream single-side simplex media marking device, the first sheet of image receiving media may be released from the one of the plurality of buffering bins for further transport downstream in the duplex coupling module including to a registration/re-registration unit in the duplex coupling module. Operation of the method proceeds to Step S7450.
In Step S7450, registration/re-registration of the first sheet of image receiving media substrate may be executed in the registration/re-registration unit to register the first sheet of image receiving media appropriately as may be required by the second downstream single-side simplex media marking device. Operation of the method proceeds to Step S7500.
In Step S7500, the properly-timed and appropriately registered/re-registered first sheet of image receiving media may be passed downstream to the second single-side simplex media marking device. Operation method proceeds to Step S7550.
In Step S7550, a second surface of the first sheet of image receiving media may be marked in the second downstream single-side simplex media marking device. Operation of the method proceeds to Step S7600.
In Step S7600, the duplex marked first sheet of image receiving media may be output from the second downstream single-side simplex media marking device. Operation of the method proceeds to Step S7650.
In Step S7650, the signaling of the second downstream single-side simplex media marking module, the transporting of the first sheet of image receiving media to the registration/re-registration unit, the executing of the registration/re-registration, the passing of the properly timed and registered/reregistered first sheet of image receiving media to the second downstream single-side simplex media marking device, the marking of the second surface of the first sheet of image receiving media, and the outputting of the duplex marked first sheet of image receiving media may be repeated on the second and subsequent sheet of image receiving media until the image forming operation in the image forming system is completed. Operation of the method proceeds to Step S7700, where operation of the method ceases.
The above-described exemplary systems and methods reference certain conventional components to provide a brief, general description of suitable document processing and post-processing means by which to carry out the disclosed buffering and re-registration scheme between in-line simplex media marking devices for clarity and ease of understanding. Those skilled in the art will appreciate that other embodiments of the disclosed subject matter may be practiced with many types and configurations of individual devices and combinations of devices particularly common to image forming and post processing of image formed products in image forming devices of varying complexity. No limitation to the variety or configuration of individual component devices included in image forming systems of varying complexity is to be inferred from the above description.
The exemplary depicted sequences of executable instructions represent only examples of corresponding sequences of acts for implementing the functions described in the steps. The exemplary depicted steps in either or both of the above-described methods may be executed in any reasonable order to carry into effect the objectives of the disclosed embodiments. No particular order to the disclosed steps of the methods is necessarily implied by the depictions in
Although the above description may contain specific details, they should not be construed as limiting the claims in any way. Other configurations of the described embodiments of the disclosed systems and methods are part of the scope of this disclosure. For example, the above-described sensing and processing functions may be carried out by any form of sensor typically adapted for use in image forming systems and under the control of associated hardware circuits, software instructions, or firmware, as well as combinations thereof.
It will be appreciated that a variety of 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.
| Number | Name | Date | Kind |
|---|---|---|---|
| 3815897 | Hoehl et al. | Jun 1974 | A |
| 6124561 | Luckhurst et al. | Sep 2000 | A |
| 6910689 | Carolan | Jun 2005 | B2 |
| 8493589 | Nakamura | Jul 2013 | B2 |
| 20100247194 | Suh | Sep 2010 | A1 |
| Number | Date | Country | |
|---|---|---|---|
| 20150241830 A1 | Aug 2015 | US |
