The present exemplary embodiments relate to media (e.g., documents, paper or the like) handling systems and systems for printing thereon and is especially applicable for printing systems comprising a plurality of associated image output terminals (“IOTs”).
The subject application is related to the following co-pending applications: U.S. Ser. No. 10/924,113, for “Printing System with Inverter Disposed For Media Velocity Buffering and Registration”;
Printing systems including a plurality of IOTs are known and are generally referred to as tandem engine printers. See U.S. Pat. No. 5,568,246. Such systems facilitate expeditious duplex printing (both sides of a document are printed) with the first side of a document being printed by one of the IOTs and the other side of the document being printed by another so that parallel printing of sequential documents can occur. The document receives a single pass through the first IOT or marking engine, is inverted and then a single pass through the second IOT for printing on the second side, so effectively the document receives a single pass through the system but is duplex printed. Single pass duplex printing using two printers can be twice as fast as duplex printing in a single IOT. Such tandem printing systems may simply consist of a feed source capable of delivering sheets to the first IOT, the first IOT, a transport communicating sheets from the first to the second IOT, the second IOT, and a finishing module. It should be appreciated that the described printing system offers no advantage over a single IOT for simplex printing productivity.
One approach for constructing tandem printing systems having increased simplex productivity is to provide each IOT with a separate and dedicated feed source for the paper or print media being processed. Consequently, for a two IOT system, this means that operators must access two different places to load media, and then those feed trays will only deliver media directly to their respective marking engine. From an operability standpoint, having all the media located in a single place would be an advantageous feature, at least for the operator. In addition, with separate and dedicated feed sources it is difficult to provide a media path allowing all the media to be delivered to any marking engine, or to selected output devices. Although some known parallel printing systems provide variable route media paths, there is a need for a printing system which can provide essentially a single media feed source to a plurality of marking engines while also providing a variable route media path so media sheets can be directed from the single source to any marking engine or a by-pass path, within the overall system.
Especially for multi-engine, parallel printing systems, architectural innovations which effectively provide maximum media path variability can enhance document process path reliability and increase system efficiency.
According to aspects illustrated herein, there is provided a printing system comprising a paper path architecture for parallel printing using multiple marking engines. The media path configuration enables all the media feed trays or sources to be located in one general location, relative to the marking engines. A simple media path to and from each marking engine, and a by-pass path enables the feeder modules to be used as an interposer, i.e., without requiring the media within the interposing feeder module to pass through a marking engine. Also, a cross-over module is located between marking engines. Additionally, the cross-over module can interleave printed media sheets that are being transported away from a first marking engine with the blank sheets being transported to the second marking engine. The cross-over module also includes a straight through path that enables media sheets to be transported directly to a finishing device without going through either marking engine. A merge module selectively merges media which can then be further processed in a finishing transition module prior to communication to a finishing device.
In accordance with other aspects illustrated herein, a printing system is provided comprising a media path architecture for facilitating selectively variable printing in a printing system including a plurality of marking engines. The architecture comprises a selectively variable route media path through the printing system, the path having a start and an end. The marking engines each include an internal simplex path and an internal duplex path. Since the marking engines each include an internal duplex path, the system can print duplex jobs by delivering sheets to each marking engine in groups. For example, if each marking engine can handle six letter size sheets in its internal duplex loop, the system can deliver six sheets to the first marking engine and then six sheets to the second marking engine, and then repeat that process. This simplifies the overall delivery and merging of the sheets to and from the marking engines. A diverter module is disposed adjacent the start of the paper path for receiving sheets from the media supply source and for selectively directing the sheets to the variable route paper path. A substantially horizontal media path spans the top of the plurality of marking engines for selective by-passing of the marking engines. A cross-over module is disposed between two of the marking engines and includes a first transport path for receiving media from a first marking engine and transporting the media to the horizontal media path, and a second transport path for receiving media from the horizontal media path and transporting the media to a second marking engine. A finishing device finishes the processing of the sheets and may be associated with a merge module for selective merging of the sheets and a parallel finishing transition module for selective orientation of the sheets.
a and 3b compriseshowings of an exemplary system duplex operation;
a and 5b are showings of an exemplary system simplex operation.
With reference to the drawings, the showings are for purposes of illustrating alternative embodiments and not for limiting same.
Sheets exit the first marking engine 12 from either the first marking engine by-pass path 32 or from marking path exit 44 and are communicated to cross-over module 50. Cross-over module 50 may be essentially common in structural assembly with entrance module 26 to include an upper by-pass path 54, a cross-over path 56 and a lower by-pass path 58. An operational advantage of the cross-over module 50 is that it facilitates interleaving of sheets from sheets communicated from the first marking engine 12 with other sheets destined for the second marking engine 14. More particularly, blank sheets may be transported to the second marking engine 14 over the top of the first marking engine via horizontal by-pass path 32. The timing and disposition of the sheets for the interleaving process is controlled to maximize throughput efficiencies so that a marked sheet from the first marking engine 12 is disposed within the cross-over module to allow the blank sheet to be directed to the entrance path 60 of the second marking engine so it can be marked therein before the sheet already marked by the first engine is communicated to the entrance path 60. Alternatively, sheets marked by the first engine 12 can be transported through the cross-over module for communication over the top of the second marking engine via the second marking engine by-pass path 64. The cross-over module 50 facilitates a variety of selectively available media paths. The sheets may be directly communicated from the feeder module 22 to the second marking engine horizontal by-pass path 64 without having to go through the first marking engine entrance 38 or the cross-over path 56 of cross-over module 50. Alternatively, marked sheets from the first marking engine 12 exiting via path 44 can be directly communicated along path 58 to the entrance 60 of the second marking engine, as where a single pass duplex mode through the system 10 is being employed.
Sheets exit the second marking engine 14 via bypass path 64 or engine exit path 68. The end of the media path is generally designated 70 and comprises a finishing device 72 associated with a finishing merge module 74 which similarly facilitates sheets communication to the device 72 from either by-pass path 64 or marking engine exit 68 and may include structural and operational commonness with modules 26 and 50.
The subject printing system 10 provides significant operational advantages for tightly integrated parallel printing and throughput efficiency. More particularly, a duplex mode printing operation could be effected in the first marking engine 12 wherein duplex printing is effected along a duplex path 42 and then the marked output comprising a plurality of sheets, could be merged together via cross-over module 50 with the second group of sheets. In other words, a group of sheets could be delivered to the first marking engine 12, and then a second group of sheets could be delivered to the second marking engine 14, alternating back and forth. Each marking engine executes a duplex mode printing for the group of sheets in a conventional manner. The group of sheets could then be interleaved via cross-over modules 50 or 74. The result is a job stream having no interruptions while really running parallel jobs within sequentially operating marking engines. In other words, a group of sheets comprising a job portion can be marked in a duplex mode within a single marking engine, another group of sheets can be marked within the second marking engine, but both groups can then be merged, one group after the other, to achieve the desired job stream result.
With particular reference to
With reference to
While a first group of media sheets are being printed in the first IOT in this manner, the group can be sized in number to fit within the internal duplex path of the first IOT to comprise a first portion of a job as a first collective group of sheets of the job.
With reference to
Again, a sequential collection of sheets enter 112 from the feeder supply source 20 and are diverted 113 in cross-over module 26 to the first IOT bypass path for bypassing 114 the first IOT 12. These sheets are then diverted 115 to the second IOT 14 where a side one of a sheet can be printed 116. The sheet is then inverted 117 and is recirculated so that the second side of the sheet can be printed. The sheet then exits 119 the second IOT and is routed 120 to the lower path 98 so that it can be exited 122 to the finisher.
Again, it is envisioned that the duplex operation in the second IOT comprises a group of sheets being sequentially processed within the internal duplex group path of the second IOT 14. The groups of sheets can then be bundled or interleaved either within the cross-over module 74, or within the finisher as may be desired.
With reference to
In accordance with this embodiment it can be seen that sheets are sequentially processed through the printing system for duplex printing thereon.
With reference to
The second IOT printing processing steps are shown in
It will be appreciated that various of the above-disclosed and other features and functions, or alternatives thereof, may be desirably combined into many other different systems or applications. Also that 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.
The claims can encompass embodiments in hardware, software, or combination thereof.
The phrase “marking engine” as used herein encompasses any apparatus, such as a printer, digital copier, bookmaking machine, facsimile machine, multi-function machine, etc. which performs a printing/outputting function for any purpose using Xerographic, ink-jet or any other marking means. The claims encompass embodiments that print in monochrome or in color or handle color image data.
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