The present disclosure relates to printing systems which include two or more integrated printing apparatuses and/or image marking engines (“IME”).
One example of an integrated printing system is disclosed in U.S. patent application number US 2006/0221159 which provides two or more IMEs which are integrated by means of a media highway. The media highway integrates the IMEs to provide transportation of a marking substrate to each IME for image marking. Notably, IMEs may be integrated horizontally, vertically, or horizontally and vertically.
Conventionally, the number of marking engines integrated within a specific printing system is chosen to satisfy a desired print rate. For example, a printing system designed to produce a maximum page rate of 100 ppm could include 4 IMEs, each capable of 25 ppm. Alternatively, the printing system could include 5 IMEs, each capable of 20 ppm.
One disadvantage associated with these conventional integrated printing systems is they only provide partial productivity when one or more of the IMEs is unable to operate for technical or service related issues.
For example, for a 4 IME system with an advertised productivity of 100 ppm (i.e. each IME producing 25 ppm), a maximum productivity of 75 ppm is attainable with 1 IME out of service. This variance in productivity from the advertised or specified throughput of the printing system may contribute to user dissatisfaction.
This disclosure provides a method and system to maintain a specified or advertised printing system throughput, while providing for the removal/disablement of one or more IMEs from the system.
U.S. patent publication No. 2006/0221159 by Moore et al., published on Oct. 5, 2006, entitled “PARALLEL PRINTING ARCHITECTURE WITH PARALLEL HORIZONTAL PRINTING MODULES,” is totally incorporated herein by reference.
In one aspect of this disclosure, a method of operating a printing system is disclosed. The printing system comprises two or more integrated image marking engines and the method comprises operating the printing system with less than the total number of image marking engines (IMEs) to generate the maximum specified prints per minute (ppm) associated with the printing system, each image marking engine being controlled to be active and inactive for a predetermined duty cycle, where the duty cycle associated with each of the said two or more integrated image marking engines is substantially equal.
In another aspect of this disclosure, a printing system is disclosed. The printing system comprises two or more integrated image marking engines; and a controller, wherein the controller is configured to execute a method comprising operating the printing system with less than the total number of image marking engines (IMEs) to generate the maximum specified prints per minute (ppm) associated with the printing system, each image marking engine being controlled to be active and inactive for a predetermined duty cycle, where the duty cycle associated with each of the said two or more integrated image marking engines is substantially equal.
In another aspect of this disclosure, a xerographic imaging system is disclosed. The xerographic imaging system comprises two or more image marking engines; a media sheet feeder module; a media sheet stacker module; one or more media path highways operatively connected to the two or more image marking engines, the media sheet feeder module and the media sheet stacker module; and a controller, wherein the controller is configured to execute a method comprising operating the printing system with less than the total number of image marking engines (IMEs) to generate the maximum specified prints per minute (ppm) associated with the printing system, each image marking engine being controlled to be active and inactive for a predetermined duty cycle, where the duty cycle associated with each of the said two or more integrated image marking engines is substantially equal.
As briefly discussed in the Background section, this disclosure provides a method and system to maintain an advertised or specified throughput associated with an integrated printing system in the event one or more of the integrated IMEs is removed from the system or off-line for any reason. The disclosed integrated printing method and system utilizes one or more extra IMEs which can operate to maintain the overall printing system throughput requirements.
For example, in a 4 engine printing system, assume each IME is capable of operating at 33.3 ppm and the printing system is specified to have a maximum throughput of 100 ppm (i.e. the printing system is advertised to the user/customer as having a throughput of 100 ppm). To provide 100 ppm, 3 IMEs are active and operated at 33.3 ppm, and 1 IME is off-line and inactive. In the event an active IME fails or is removed from the printing system, the inactive IME is brought on-line and enables the printing system to maintain 100 ppm.
Notably, the example provided above is only one method, according to this disclosure, of operating a printing system with excess IMEs integrated within the printing system to maintain a required printing throughput. Another method of operating the “spare” or “excess” IME includes operation of the IMEs in a round-robin fashion, where the printing system runs three IMEs at 33.3 ppm and cyclically inactivates each of the four IMEs for a predetermined period of time. Alternatively, the printing system may inactivate each of the four IMEs after the printing system marks a predetermined number of sheets. The round-robin method provides more consistent aging of the IMEs which provides more consistent image marking quality between the IMEs.
With reference to
To facilitate the routing of media sheets from the sheet feeder module 2 to IMEs 6, 10, 12, and 16, fuser modules 8, 18, 14 and 20, and image sensor 23, transport module 22 includes an upper horizontal transport 26 which operates in the forward direction, a middle horizontal transport 27 which operates in the reverse direction, a lower horizontal transport 28 which operates in the forward direction, a first intersection transport 24 and a second intersection transport 25. In addition, transport module 22 provides routing of media sheets between any of the IMEs and fusing modules illustrated.
As will become apparent from the detailed description which follows, the method and system for operating a printing system according to this disclosure, and claims which follow, are not limited to the printing system illustrated in
With reference to
Substantially, the method of sequencing the IMEs illustrated in
For example, with continuing reference to
After the predetermined cycle time, the controller sequences the printing system illustrated in
After the predetermined cycle time has elapsed, the controller sequences the printing system illustrated in
During the third sequential state 34, the controller 3 activates IMEs 1, 3 and 4 associated with IMEs 6, 12 and 16 illustrated in
After the predetermined cycle time has elapsed, the controller sequences the printing system illustrated in
After the predetermined cycle time has elapsed, the controller sequences the printing system illustrated in
This sequencing of printing system states may be continued for an indefinite time or may continue for a specific predetermined time specified by the user. Alternatively, the controller may determine a particular IME is in need of service and/or is producing a low quality print as measured by the image sensor 23 which necessitates the IME being inactivated until the condition is corrected.
In the event the controller inactivates an IME for an indefinite time for service, etc., the controller will terminate sequencing the printing system until the inactive IME is placed in service. For example, the controller can indefinitely execute state 2 (32) if IME 3 (12) is down.
With reference to
The executed algorithm operates as follows:
Initially a printing system controller receives a print job 40.
Next, the controller determines if an IME is out of service 42.
If an IME is out of service, the controller executes a printing system state where the respective IME is inactive 50.
Otherwise, if all IMEs are in service, the controller cycles to the next state assignment associated with the active IMEs 44.
At this point the controller schedules 46 media sheets to the active IMEs to initiate the received print job.
Next, the controller starts executing 48 the printing job based on the schedule generated in step 46.
Next, the controller determines 52 if the number of printed sheets has exceeded a predetermined number N. If the number of printed sheets has exceeded a predetermined number N, the controller cycles 56 the printing system to the next sequential state of active IMEs, provided out of service IMEs do not prevent additional states from being executed.
In the event the printing system has not exceeded the predetermined number of printed sheets N, the printing job continues 54 to be executed without changing states until the number of printed sheets does exceed N.
After completion of the printing job, the controller starts the process again by receiving a print job 40.
Described hereto is a printing system and method of operation which includes two or more integrated IMEs, where the printing system operates with less than the total number of IMEs available to generate a specific throughput normally specified as prints per minute (ppm). By operating a printing system in this manner, the specified throughput of the system can be more reliably maintained where the throughput is specified as the throughput of the printing system operating less than all available IMEs.
For example, a 4 IME system as illustrated in
In addition to an improvement in overall printing system reliability, the round-robin approach to the sequencing of IMEs contributes to more consistent image quality among the IMEs by maintaining an approximately equivalent number of performed printings associated with the IMEs.
It is to be understood that a round-robin approach to sequencing the printing system is only one example of a sequencing methodology.
Another exemplary embodiment of the disclosed method and system for sequencing a printing system includes an image sensor. The image sensor can be integrated in-line with the printing system as illustrated in
As a means for sequencing the printing system, the output of the image sensor is used by the printing system controller to associate a relative quality level with each IME.
As previously discussed, the relative quality of an IME is partly due to the number of printing cycles completed by the IME. Accordingly, a printing system can be selectively operated in a particular state which inactivates an IME producing relatively low quality prints as measured by the image sensor.
Notably, other variations of the printing system described hereto are within the scope of this disclosure. These variations include, but are not limited to, a variable cycle associated with the state cycle, a state sequencing cycle based on elapsed time which may or may not be associated with a component of the printing system, a printing system including two or more horizontally integrated IMEs, a printing system including two or more vertically integrated IMEs, a printing system including a combination of vertically and horizontally integrated IMEs, and a printing system including IMEs of different individual throughputs.
With reference to
In operation, the high productivity mode is selected 60 by a user while the printing system is operating in one of the sequential states 1, 2, 3, or 4.
After operator selection of the high productivity mode, the controller overrides 62 current system state execution and makes all available IMEs active and prints using the high productivity state 68.
As the printing system prints in the high productivity state, the controller monitors 64 the progress of the print job until completion.
After completion of the print job, the controller resumes 66 the system state being executed prior to the execution of the high productivity state.
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.
Number | Name | Date | Kind |
---|---|---|---|
5859711 | Barry et al. | Jan 1999 | A |
5963770 | Eakin | Oct 1999 | A |
20060221159 | Moore et al. | Oct 2006 | A1 |
20060291018 | Lang et al. | Dec 2006 | A1 |
Number | Date | Country | |
---|---|---|---|
20090153884 A1 | Jun 2009 | US |