This application is a national stage application under 35 U.S.C. §371 of PCT/US2008/082479, filed Nov. 5, 2008.
Creating a print job offset conventionally involves offsetting one or more entire print jobs or utilizing sheets to act as separators between each print job. This often results in repeated and continual stress on one or more motors in having to repeatedly perform the motions of shifting and adjusting speeds and/or positions for each print job. As a result, a printing apparatus may fail more frequently or the printing apparatus life may be reduced. Furthermore, resources, such as sheets, replacement parts, and technical support, may be wasted and/or increased.
Various features and advantages of the invention will be apparent from the detailed description which follows, taken in conjunction with the accompanying drawings, which together illustrate, by way of example, features of the invention and wherein:
The present invention differs from previous approaches by creating one or more print job offsets with a first sheet job offset for each print job without repeatedly and continually stressing one or more outputting mechanisms for a printing apparatus and without wasting additional resources. A common practice for conventional print job offsetting is to offset the entire print job and/or use extra sheets as bookmarks between each print job. As a result, a user may find that he/she may have to frequently perform maintenance on the machine since the motors and outputting means are being worn out at a continual and an accelerated rate. In addition, extra time, sheets, and/or other additional resources are wasted. The present invention alleviates much of the stress on the printing apparatus and burden on the user by not offsetting an entire print job and/or wasting resources, yet continues to perform print job offsetting that can separate each print job efficiently and effectively using a first sheet of each print job.
As noted above, the printing apparatus 100 may comprise a printer controller 160, which may be used to control the printing apparatus 100 and comprise a PROCESSOR, RAM, Storage/Computer Readable Medium, and print controller software 170. The print controller software 170 may manage the operations of the printing apparatus 100, in conjunction with the print controller 160, by sending instructions to one or more components and/or devices comprising the printing apparatus 100 and/or connected to the printing apparatus 100. The print controller software 170 may be firmware that is embedded onto the print controller 160 or the printing apparatus 100. Additionally, the print controller software 170 may be a software application stored on the printer apparatus 100 through a storage medium readable and accessible by the printing apparatus 100 or the print controller software 170 may be stored on a computer readable medium readable and accessible by the printing apparatus 100 from a different location. Further, the print controller software 170 may be stored and/or accessed through a server connected through a local area network or a wide area network. The print controller software 170 may communicate with the print controller 160 and/or other additional devices and/or components connected to the printing apparatus 100 physically or wirelessly through one or more communication channels included in or attached to the printing apparatus 100.
The print controller software 170 may poll a printing spool 110 to determine whether at least one print job 120 is queued in the printing spool 110. A printing spool 110 may include data of multiple print jobs, including at least one print job 120, that has been queued for printing. Further the print controller software 170 may access each print job and the data inside each print job when they are ready to be printed. As illustrated in
After accessing the data from at least one print job 120, the print controller software 170 may send instructions to the print controller 160 and sheet advancement system according to the data from at least one print job 120. Additionally, the print controller software 170 may determine, based on whether at least one print job 120 specifies to be printed single sided or double sided, when a first sheet will be ready to be outputted from the printing apparatus 100.
In printing each page of each print job in the printing spool 110, the print software controller 170 may initially send instructions to the sheet advancement system to acquire sheets from one or more input bins. The print controller software 170 may then send an instruction for the sheet advancement system to transfer one or more sheets to the image printing system, where the print controller software 170 may utilize the data from each print job to determine what images, text, and/or patterns are to be printed on each page of the corresponding print job, as well as the number of pages to be printed on each side of a sheet. A sheet is the physical media that the one or more pages of each print job may be printed on. Each side of the sheet may be printed on with one or more pages from the corresponding print job. In one embodiment, if the data from at least one print job 120 has indicated that each sheet of at least one print job 120 is to be printed double sided, the print controller software 170 may next send an instruction for each sheet of at least one print job 120 to be sent to the duplexer where it will be flipped and returned to the image printing system where the next page, or set of pages, of at least one print job 120 will be printed on the other side of each sheet. The general method disclosed above may be used for the printing of each sheet of each print job in the printing spool 110. Additional methods and/or additional device or components may be utilized in the printing of each sheet of at least one print job 120 and any additional print jobs queued in the printing spool 110 in addition to and/or in lieu of those depicted above.
In outputting each sheet of each print job, the print controller software 170 will initially determine when a first sheet of the corresponding print job is ready to be outputted from the printing apparatus 100. In one embodiment, a first sheet of at least one print job 120 is ready to be outputted when all of the images, text, and/or patterns designated to be printed on a single side or both sides of the sheet have been imprinted onto one or both designated sides by the image printing system. The print software controller 170 may then send one or more instructions to one or more outputting mechanisms 140, at least one friction bias arm 180, and/or at least one rat tail 130 to accelerate the first sheet of at least one print job 120 out of the printing apparatus 100 by increasing an output force, accelerating a rotation, and/or raising at least one friction bias arm 180 and/or at least one rat tail 130. As a result, the distance traveled by the first sheet of at least one print job 120 outputted from the printing apparatus 100 will be increased and at least one first sheet job offset will be created for at least one print job 120. A first sheet job offset is a print job that has been outputted from the printing apparatus 100 where the first sheet of the corresponding print job is offset from each remaining sheet of the corresponding print job. The first sheet of the corresponding print job will be offset a distance greater than each remaining sheet in the corresponding print job. Each remaining sheet of the corresponding print job will not be offset and will be evenly stacked one on top of another at a distance less than the first sheet of the corresponding print job.
After the first sheet of the corresponding print job has been outputted from the printing apparatus 100, the print controller software 170 may then send another instruction to one or more outputting mechanisms 140, at least one friction bias arm 180, and/or at least one rat tail 130 to decrease output force, decelerate a rotation, and/or lower at least one friction bias arm 180 and/or at least one rat tail 130 to decrease the travel distance traveled for each remaining sheet of a corresponding print job, when outputted from the printing apparatus 100. The method disclosed above may be utilized for the outputting of at least one print job 120 and any additional print jobs queued in the printing spool 110. Additional methods and/or additional device or components may be utilized in the outputting of each sheet of at least one print job 120 and any additional print jobs queued in the printing spool 110 in addition to and/or in lieu of those depicted above.
As illustrated in
In one embodiment, the print controller software may instruct the motor to rotate one or more rollers 200 at an accelerated speed for a first sheet of at least one print job when the first sheet of at least one print job is detected to be ready for output from the printing apparatus. The first sheet of at least one print job will thus be accelerated out of the printing apparatus. After the first sheet has been outputted from the printing apparatus, the print controller software may send a second instruction for the motor to rotate one or more rollers 200 at a normal or decelerated speed for each remaining sheet of at least one print job. Each remaining sheet of at least one print job will then be decelerated out of the printing apparatus. As a result, when the first sheet of at least one print job is outputted from the printing apparatus, the first sheet will travel a greater distance than each remaining sheet of at least one print job and thereby create a first sheet job offset. When processing a subsequent print job, the print controller may again send instructions to the motor to rotate one or more rollers 200 at an accelerated speed for a first sheet of the corresponding print job and then rotate at a normal or decelerated speed for each remaining sheet of the corresponding print job.
Further, as illustrated in
Even when sharing a common source of air flow, the output of each air nozzle 210 or an array or matrix of air nozzles 210 may be controlled by one or more doors 240 opening and/or closing or one or more levers 220, 230 extending or retracting over each air nozzle 210 independently or over an array or matrix of air nozzles 210 upon instruction by the print controller software. As noted above and illustrated in
In one embodiment, lever 220 may be moved vertically, up or down, over one or more air nozzles 210 to block or unblock one or more air nozzles to control the amount of air flow exiting one or more air nozzles 210. Further, lever 230 may be moved horizontally, left or right, over one or more air nozzles 210 to block or unblock one or more air nozzles to control the amount of air flow exiting one or more air nozzles 210. In another embodiment, lever 220 may be automatically extendable in a vertical movement, up or down, from the bottom and/or top of a matrix of air nozzles 210 to block or unblock one or more air nozzles. Further lever, 230 may automatically be extendable in a horizontal movement, left or right, from the left and/or right of a matrix of air nozzles 210 to block or unblock one or more air nozzles 210.
Further, as noted above and illustrated in
In one embodiment, the print controller software may detect that a first sheet of at least one print job is ready to be outputted from the printing apparatus. The print controller software may then send an instruction to one or more doors 240 to open and/or one or more levers 220, 230 to retract to insure that each air nozzle 210 is open to increase air flow and accelerate the first sheet of at least one print job out of the printing apparatus. Additionally and/or alternatively, the print controller software may send an instruction for the motorized fan to rotate at an accelerated rate in order to increase air flow for one or more air nozzles 210 to accelerate the first sheet of at least one print job out of the printing apparatus. After the first sheet of at least one print job has been outputted from the printing apparatus, the print controller software may next send an instruction to close one or more doors 240 and/or extend one or more levers 220, 230 for one or more air nozzles 210 to decrease air flow for each remaining sheet of at least one print job so that each remaining sheet will be decelerated out of the printing apparatus. As a result, the amount of open air nozzles 210, as well as the amount of air flow provided to output each remaining sheet in at least one print job is decreased.
Additionally and/or alternatively, the print controller software may instruct the motorized fan to rotate at a normal or decelerated speed to decrease the air flow to one or more air nozzles 210. As a result, the remaining sheets of at least one print job will be decelerated out of the printing apparatus and will travel a distance shorter than the first sheet of at least one print job when outputted from the printing apparatus. Additional methods and/or a combination of the above actions may be utilized to increase and/or decrease the amount of air flow flowing out of one or more air nozzles 210 in addition to and/or in lieu of those depicted in
As illustrated in
At least one rat tail 320 may be fixed in stationary position or at least one rat tail 320 may be moved manually by a user or automatically with a spring or motor by the printing apparatus. In one embodiment, where at least one rat tail 320 is stationary, an outputting mechanism may be accelerated in order to accelerate a first sheet of each print job out of the printing apparatus. The outputting mechanism may then decelerate each remaining sheet of the print job at a force less than the force used for the first sheet. As a result, at least one rat tail 320 will make contact and create friction for each page of the print job. Because the first sheet of the corresponding print job was accelerated out of the printing apparatus, the first sheet of the corresponding print job will travel a greater distance than the remaining sheets of the corresponding print job, thereby creating at least one first sheet job offset for the corresponding print job.
In another embodiment, where the rat tail 320 is automatically movable through a spring or a motor, the print controller software may send an instruction for the spring to expand or the motor to rotate so that the rat tail 320 is raised to an elevated position. As a result, the first sheet of the corresponding print job will indirectly be accelerated out of the printing apparatus by the rat tail will not make contact with the first sheet of the corresponding print job and create friction with the first sheet of the corresponding print job. Additionally, the outputting mechanism may be accelerated in order to increase the force and travel distance of the first sheet of the corresponding print job. After the first sheet of the print job has been outputted, the print controller software may send an instruction for the spring to contract or the motor to rotate so that the rat tail 320 is lowered to a declined position. As a result, the rat tail 320 will make contact with each remaining sheet of the corresponding print job and decelerate each remaining sheet of the corresponding print job by creating friction for each remaining sheet of the corresponding print job. The first sheet of the corresponding print job will thus be offset because the first sheet of the corresponding print job will have been indirectly accelerated out of the printing apparatus by traveling a greater distance than each remaining sheet in the corresponding print job due to at least one rat tail 320 not making contact and creating friction with the first sheet, as it does for each remaining sheet of the corresponding print job. At least one rat tail 320 may be fixed or moved into additional positions manually or automatically using additional means in addition to and/or in lieu of those depicted in
Further,
In one embodiment, where at least one friction bias arm 300 is stationary, an outputting mechanism may be accelerated in order to increase the force used to output a first sheet of each corresponding print job. The outputting mechanism may then output each remaining sheet of the corresponding print job at a force less than the force used for the first sheet of the corresponding print job. As a result, the friction bias arm 300 will create friction for each sheet of the corresponding print job. However, the first sheet of the corresponding print job will still travel a greater distance than the remaining sheets of the corresponding print job since the outputting mechanism was accelerated for the first sheet. As a result, at least one first sheet job offset of the corresponding print job is created.
In another embodiment, where at least one friction bias arm 300 is movable, the print controller software may send an instruction for the friction bias arm 300 to raise to an elevated position so that the friction bias arm 300 will not make contact with the first sheet of the corresponding print job and no friction will be created with the first sheet of the corresponding print job by at least one friction bias arm 300. Additionally, the outputting mechanism may be accelerated in order to increase the force and travel distance of the first sheet of the corresponding print job. After the first sheet of the corresponding print job has been outputted, the print controller software may send an instruction for at least one friction bias arm 300 to lower to a declined position so that the friction bias arm 300 will make contact with each remaining sheet of the corresponding print job and create friction with each remaining sheet of the corresponding print job. As a result, the first sheet of the corresponding print job will be offset and travel a greater distance than each remaining sheet in the corresponding print job since the friction bias arm 300 will not create friction for the first sheet of the corresponding print job, as it does each remaining sheet of the corresponding print job. At least one friction bias arms 300 may be fixed or moved into additional positions manually or automatically using additional means in addition to and/or in lieu of those depicted in
As noted above, one or more output bin trays 400 as illustrated in
The dimensions of one or more output bin trays 400, both horizontal dimensions and vertical dimensions, may be adjusted with an extendable and/or retractable device to support various sheet and media types and/or media types of different dimensions. Additionally, an extender device may be attached and/or removed from one or more output bin trays 400 to support various sheet and media types and/or sheets and media types of different dimensions. Further, one or more output bin trays 400 may include or be attached to a motor that may move in various directions to hold and store multiple print jobs and various print jobs of different sizes.
Additionally, as illustrated in
Further, as illustrated in
As illustrated in
Further, as noted above, the printer controller software 600 may be firmware that may be imbedded into one or more components of the printing apparatus 610. Additionally, the printer controller software 600 may be a software application which may be stored and accessed from a hard drive, a compact disc, a flash disk, a network drive or any other form of computer readable medium that is connected to the printing apparatus. In one embodiment, the printer controller software 600 may be stored on a server or another device that may or may not be connected to the printing apparatus 610. The printing apparatus 610 may utilize a local area network or a wide area network to store and access the printer controller software 600. The printer controller 600 may be stored and accessed from additional devices in addition to and/or in lieu of those depicted in
Reference will now be made to exemplary embodiments illustrated in the drawings, and specific language will be used herein to describe the same. It will nevertheless be understood that no limitation of the scope of the invention is thereby intended. Alterations and further modifications of the inventive features illustrated herein, and additional applications of the principles of the invention as illustrated herein, which would occur to one of ordinary skill within the relevant art and having possession of this disclosure, are to be considered within the scope of the invention.
As illustrated in
If one or more print jobs are found to be queued in the printing spool, the print controller software will then determine whether a first sheet of the print job queued in the printing spool is ready to be outputted to an output bin tray 720. If a first sheet of the print job is not ready to be outputted to an output bin tray, the print controller will continue to determine whether a first sheet of the print job is ready to be outputted to an output bin tray 720.
If a first sheet of a print job is ready to be outputted to an output bin tray, the print control software will proceed to send an instruction to adjust an outputting mechanism when outputting each sheet of a corresponding print job so that a first sheet of the corresponding print job is offset from each remaining sheet from the corresponding print job 730. As noted above, an outputting mechanism may be one or more rollers, one or more air pressure nozzles, and/or other additional devices which may transition media out of the printing apparatus and into one or more output bin trays.
In adjusting an outputting mechanism when outputting each sheet of a corresponding print job so that a first sheet of the corresponding print job is offset from each remaining sheet from the corresponding print job, in one embodiment, the print controller software may send an instruction to raise at least one friction bias arm and/or at least one rat tail on the printing apparatus so that at least one friction bias arm and/or at least one rat tail does not make contact and create friction with the first sheet of the corresponding print job 740 when outputted from the printing apparatus. Alternatively and/or additionally, the print controller software may also send an instruction to an outputting mechanism to accelerate the first sheet of the corresponding print job out of the printing apparatus by accelerating one or more rollers and/or increasing air flow output from one or more air nozzles when outputting the first sheet of the corresponding print job 750.
In some circumstances, a user may wish to decrease the distance traveled by the first sheet to insure that it does not sail off the output print bin. An output tray stopper and/or ridges on the output bin tray may be utilized to decrease the distance traveled by the first sheet of the corresponding print job 760.
After the first sheet of the corresponding print job has been printed, the print controller software may send an instruction to decelerate one or more rollers and/or decrease air flow from one or more air nozzles when outputting each remaining sheet in the corresponding print job 770 so that each remaining sheet of the corresponding print job is decelerated out of the printing apparatus. If one or more air nozzles are used as an outputting mechanism, the print controller software may further send one or more instructions to close one or more doors and/or extend one or more levers for one or more air nozzles 780.
Alternatively, the print controller software may send an instruction to lower at least one friction bias arm and/or at least one rat tail on the printing apparatus to make contact and create friction with each remaining sheet of the corresponding print job 790. By lowering at least one friction bias arm, at least one rat tail, and/or decelerating an outputting mechanism, each remaining sheet of a corresponding print job will travel a shorter distance than the first sheet of the corresponding print job and will be stacked uniformly as illustrated in
After each remaining sheet of the corresponding print job has been printed, at least one first sheet job offset will be created for the corresponding print job. The print controller software may then determine whether any more print jobs are queued in the printing spool 710. If no more print jobs are queued in the printing spool, the print controller software may continue to monitor and check whether a print job is queued in the printing spool 710 or the method will end. If one or more print jobs remain queued in the printing spool, the print controller software may continue to utilize the above disclosed method repeatedly to create one or more additional first sheet job offsets for each subsequent print job queued in the printing spool until no more print jobs remain in the queue.
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/US2008/082479 | 11/5/2008 | WO | 00 | 4/11/2011 |
Publishing Document | Publishing Date | Country | Kind |
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WO2010/053477 | 5/14/2010 | WO | A |
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Number | Date | Country | |
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20110261409 A1 | Oct 2011 | US |