JP2017109392A - Printer, control method and program thereof - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a printer which can efficiently perform double-side printing processing.SOLUTION: A printer can execute the first double-side printing for performing double-side printing in the order of the first surface and second surface of the following sheet after printing on the first surface and printing on the second surface of the preceding sheet when performing double-side printing on the plural sheets and the second double-side printing for performing printing on the first surface of at least one following sheet during a period to printing on the second surface after printing on the first surface of the preceding sheet, determines whether the image data to be printed on the top sheet of the following job has been generated at the prescribed timing subsequent to at least transfer start of the final sheet of the preceding job when the final sheet of the preceding job is double-side printing when executing the consecutive jobs in the second double-side printing, continues the second double-side printing when it is determined that the image data to be printed on the top sheet of the following job has been generated, and performs switching from the second double-side printing to the first double-side printing when it is determined that the image data to be printed on the top sheet of the following job has not been generated.SELECTED DRAWING: Figure 7

Description

  The present invention relates to a printing apparatus, a control method therefor, and a program.

  When receiving print data composed of a plurality of pages and performing double-sided printing on a plurality of sheets by the image forming apparatus, the image forming apparatus sequentially acquires print data corresponding to each page from the first page. Then, the obtained print data of each page is subjected to image processing, and the processed image data of each page is sequentially printed on the front and back surfaces of the paper. In such double-sided printing, for example, two pages are printed on the front surface of the first paper, and one page is printed on the back surface of the first paper, followed by 4 on the front surface of the subsequent second paper. Double-sided printing (usually double-sided printing) that prints 3 pages on the page and the back side is known. In order to shorten the printing waiting time due to the conveyance of each sheet, there is a method of printing the print data corresponding to each page regardless of the acquisition order. For example, when 6-page image data is printed on both sides of 3 sheets of paper, 2 pages are printed on the surface of the first sheet, then 4 pages are printed on the surface of the second sheet, and then the first sheet. One page is printed on the back side. Then, 6 pages are printed on the front side of the third sheet, then 3 pages are printed on the back side of the second sheet, and finally 5 pages are printed on the back side of the third sheet. Thus, it is known to perform double-sided printing (high-speed double-sided printing) with reduced printing waiting time due to paper conveyance (see, for example, Patent Document 1).

  By the way, when printing on each sheet, printing is started after image data to be printed on the sheet is generated. However, in high-speed double-sided printing, priority is given to efficiency in consideration of the conveyance time of each sheet, and therefore sheet conveyance control is performed regardless of the print data acquisition order. For this reason, there may occur a case where image data corresponding to the paper is not generated before the printing of the paper is started. In this case, a printing process error occurs, and, for example, a sheet in the middle of printing remains in the image forming apparatus. That is, in high-speed double-sided printing, when printing on each sheet is started, there is a possibility that image data corresponding to the sheet is not generated, and in this case, the printing process is in a standby state ( For example, see Patent Document 2).

JP 2002-337417 A JP 2010-173186 A

  As a countermeasure against the latter problem, it is confirmed at a predetermined timing (hereinafter referred to as “availability determination timing”) whether image data of the subsequent sheet has been generated. At that time, if the image data has not been generated, there is a technique for switching high-speed duplex printing to normal duplex printing. In addition, in the case of the final sheet of the job, this availability determination timing is the printable timing of the first side of the final sheet, and in the case of other sheets, the printable timing of the first side of the sheet, and This is the timing for completing the printing of the first side of the paper.

  However, in the above prior art, in the case of the last paper of the preceding job of the continuous job, the start of image data generation of the paper of the succeeding job is delayed because there is a job separation, and the image on the succeeding paper is delayed at the above-described availability determination timing. There is a high possibility that data is not generated. For this reason, it becomes easy to switch from high-speed duplex printing to normal duplex printing between the preceding job and the succeeding job. For this reason, for example, in the case where a job for executing double-sided printing for each sheet is continuously executed, switching to normal double-sided printing frequently occurs for each job, resulting in a problem that productivity is lowered. is there.

  An object of the present invention is to solve the above-described problems of the prior art.

  The objective of this invention is providing the technique which can perform a double-sided printing process efficiently.

In order to achieve the above object, a printing apparatus according to an aspect of the present invention has the following configuration. That is,
A printing device,
When performing double-sided printing on a plurality of sheets, after printing on the first side of the preceding sheet, printing on the second side of the sheet, double-sided printing in the order of the first side and the second side of the subsequent sheet After the first double-sided printing to be performed and the printing of the first side of the preceding paper until the second side of the paper is printed, the printing is performed on the first side of at least one subsequent paper. A printing means capable of executing two-sided printing;
When a continuous job is executed in the second double-sided printing, when the last sheet of the preceding job is double-sided printing, the succeeding job is at least at a predetermined timing after the start of the transfer of the last sheet of the preceding job. Determining means for determining whether image data to be printed on the first sheet of paper has been generated;
If the determination unit determines that the image data to be printed on the first sheet of the subsequent job has been generated, the second double-sided printing is continued, and the determination unit has not generated the image data to be printed on the first sheet of the subsequent job. Control means for controlling to switch from the second double-sided printing to the first double-sided printing.

  According to the present invention, it is possible to efficiently perform a double-sided printing process. Further, when the second double-sided printing is continued between a plurality of jobs, the second double-sided printing across the jobs is easily continued, and the productivity is improved.

  Other features and advantages of the present invention will become apparent from the following description with reference to the accompanying drawings. In the accompanying drawings, the same or similar components are denoted by the same reference numerals.

The accompanying drawings are included in the specification, constitute a part thereof, show an embodiment of the present invention, and are used together with the description to explain the principle of the present invention.
1 is a block diagram illustrating a configuration of an image forming apparatus according to an embodiment. FIG. 2 is a diagram schematically illustrating a hardware configuration of a printer unit of the image forming apparatus according to the embodiment. 5A is a timing chart for explaining the flow of double-sided printing on one sheet in the image forming apparatus according to the embodiment, and FIG. FIG. 4 is an explanatory diagram of a job and a page for explaining double-sided printing processing across jobs executed in the image forming apparatus according to the embodiment. 6 is a sequence diagram when high-speed double-sided printing is possible between jobs and high-speed double-sided printing is executed across jobs in the image forming apparatus according to the embodiment. FIG. 4 is a sequence diagram when high-speed double-sided printing cannot be performed between jobs and high-speed double-sided printing cannot be executed across jobs in the image forming apparatus according to the embodiment. FIG. 6 is a flowchart for explaining processing of a control unit of the image forming apparatus according to the embodiment.

  Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings. The following embodiments do not limit the present invention according to the claims, and all combinations of features described in the embodiments are not necessarily essential to the solution means of the present invention. . In the embodiment, an example of the printing apparatus of the present invention will be described by taking an image forming apparatus including a finisher as an example, but an image forming apparatus having only a printing function may be used.

  FIG. 1 is a block diagram illustrating a configuration of an image forming apparatus 1000 according to the embodiment.

  In FIG. 1, an image forming apparatus 1000 includes a control unit 100 and a printer unit 110, and is connected to an information processing apparatus 1001 that creates a print job and inputs it to the image forming apparatus 1000 via a communication unit 107. The control unit 100 and the printer unit 110 are connected via a printer I / F 104 and a printer I / F 114. The control unit 100 includes a CPU 101, a RAM 102, a ROM 103, a printer I / F 104, an HDD 105, and a communication unit 107, which are connected to each other via a bus 106. The printer unit 110 includes a CPU 111, a RAM 112, a ROM 113, a printer I / F 114, an HDD 115, a marking unit 116, a paper feed unit 1107, and a paper discharge unit 118, which are connected to each other via a bus 119.

  In the control unit 100, the CPU 101 controls the control unit 100 in an integrated manner. The RAM 102 is used as a work memory for the CPU 101. A ROM 103 is a boot ROM and stores a boot program of the control unit 100. The printer I / F 104 performs data communication with the printer unit 110. An HDD (Hard Disk Drive) 105 holds various information. The communication unit 107 communicates with the information processing apparatus 1001, for example, receives print data transmitted from the information processing apparatus 1001, and transmits the state of the image forming apparatus 1000 to the information processing apparatus 1001.

  Next, the configuration of the printer unit 110 will be described. The CPU 111 controls the printer unit 110 in an integrated manner. The RAM 112 is used as a system work memory for the CPU 111. A ROM 113 is a boot ROM, and stores a boot program for the printer unit 110. The printer I / F 114 performs data communication with the control unit 100. The HDD 115 holds various information. The marking unit 116 draws an image on the transfer belt (hereinafter referred to as image formation) using toner based on the image data, and transfers and fixes the image onto a sheet. The paper feed unit 117 includes a paper feed cassette for storing paper and a manual feed tray. The paper discharge unit 118 receives the paper printed and discharged by the marking unit 116, and further has a finishing function such as a sort process or a staple process.

  FIG. 2 is a diagram schematically illustrating a hardware configuration of the printer unit 110 of the image forming apparatus 1000 according to the embodiment. Here, in order to facilitate understanding, the internal components are illustrated so as to be seen through. Yes.

  The printer unit 110 includes a paper feed unit 117, a paper discharge unit 118, paper feed cassettes 201 to 202, a paper feed conveyance path 203, a conveyance path 204, a transfer unit 205, a transfer belt 206, toner cartridges 207 to 210, a fixing roller 211, An intermediate tray 212 is provided. Further, a discharge conveyance path 213, a double-side conveyance path 214, a double-sided paper feed conveyance path 215, a paper discharge flapper 216, a reverse flapper 217, a double-sided roller 218, and a double-sided paper feed roller 219 are provided. The above-described marking unit 116 includes a transfer unit 205, a transfer belt 206, toner cartridges 207 to 210, a fixing roller 211, and the like.

  The printing process by the printer unit 110 shown in FIG. 2 will be described with reference to the timing chart of FIG. FIG. 3A is a timing chart for explaining the flow of double-sided printing on one sheet.

  In FIG. 2, in the printer unit 110, a plurality of sheets are stored in each of the sheet feeding cassettes 201 to 202. Here, when the printer unit 110 receives a control signal serving as an instruction to start printing from the control unit 100 in S301, the image forming process on one side (first side) of the first sheet is started. That is, toner images of four colors based on image data formed on the first surface of the first sheet are transferred to the transfer belt 206 from toner cartridges 207 to 210 that respectively contain yellow, magenta, cyan, and black toner. Superimpose and transfer. The start of image formation on the first side of the first sheet is referred to as first side image formation start. In FIG. 3A, reference numeral 301 denotes an image forming period of the first surface. In response to the control signal received in S301, in S302, the sheet is conveyed from one of the sheet cassettes 201 to 202 to the sheet feeding path 203 (hereinafter, the first side sheet feeding is started). The first sheet thus transported to the paper feed transport path 203 is transported to the transport path 204 in S303 (first side paper feed completed). Then, after the image formation period 301 on the first surface, the image formed on the transfer belt 206 is transferred by the transfer unit 205 to the first surface of the first sheet conveyed to the conveyance path 204 (S304) ( First surface transfer is started). After S304, the first sheet whose transfer has been completed by the transfer unit 205 (first surface transfer completed) is conveyed to the fixing roller 211 and fixed in S305.

  Here, in the case of single-sided printing, the first sheet on which the image is fixed by the fixing roller 211 is conveyed to the discharge conveyance path 213 by the discharge flapper 216 and is discharged after being subjected to a predetermined finishing process by the discharge unit 118. Is done.

  On the other hand, in the case of duplex printing, the first sheet with the image fixed on the first surface by the fixing roller 211 is transported to the intermediate tray 212 by the reverse flapper 217 and then switched back in S306, and in S307. Then, it is conveyed to the double-sided conveyance path 214.

  Here, when performing normal duplex printing, the first sheet is conveyed to the duplex feeding path 215 by the duplex roller 218 in S309 in the duplex conveyance path 214 without waiting in S308. Reference numerals 303 and 304 denote the double-sided conveyance sections of the first sheet in this case. At this time, in S310, image formation on the second side of the first sheet is started (second side image formation is started). After S310, the conveyance of the first sheet is started by the double-sided sheet feeding roller 219 in S312 (second-side sheet feeding is started), and in S313, the first sheet is conveyed to the print conveyance path 204 (first sheet). 2 side feeding completed). Thereafter, similarly to the image formation on the first surface of the first sheet, the image formed on the transfer belt 206 is transferred to the second surface of the first sheet conveyed to the print conveyance path 204 in S314. Transfer starts (second surface transfer starts). In step S <b> 315, the first sheet whose transfer is completed by the transfer unit 205 (second surface transfer is completed) is fixed by the fixing roller 211. The first sheet having the image fixed on both sides is conveyed to the discharge conveyance path 213 by the discharge flapper 216 and subjected to a predetermined finishing process by the discharge unit 208, and then discharged (printing completed) in S316. .

  In this case, after the image formation on the first surface of the first sheet is performed by the transfer unit 205 and the fixing roller 211, the first sheet is again transferred to the print conveyance path 204 via the duplex conveyance path 214 and the like. There is a waiting time during which the transfer unit 205 and the fixing roller 211 do not operate until they are conveyed. This corresponds to the period from S304 to S310 in FIG.

  Next, a case where high-speed double-side printing is performed will be described with reference to a timing chart showing the flow of high-speed double-side printing in FIG. 3B. In FIG. The timing is shown.

  In the case of performing high-speed duplex printing, the second sheet is fed between the time when the first sheet having an image formed on the first side is conveyed to the intermediate tray 212 by the reverse flapper 217 and then conveyed to the printing conveyance path 204. The first surface image formation 331 is started. That is, in S331, the toner cartridges 207 to 210 transfer the toner image on the first surface of the second sheet to the transfer belt 206, and start image formation on the first surface of the second sheet. Thereafter, in S332, the second sheet is fed from one of the cassettes 201 to 202, and in S333, the second sheet is conveyed to the print conveyance path 204. In S334, the transfer of the second sheet is performed. Be started. Thus, with high-speed duplex printing, the waiting time in duplex printing is shortened. The image is transferred by the transfer unit 205 to the first surface of the second sheet conveyed to the printing conveyance path 204 in this way, and further the second sheet is conveyed to the fixing roller 211 and the image is formed on the first surface of the second sheet. It is fixed. The second sheet having the image fixed on the first side in this manner is conveyed to the intermediate tray 212 by the reverse flapper 217 in S336. At this time, the first sheet is conveyed to the print conveying path 204, and image formation is performed on the second surface of the first sheet by the transfer unit 205 and the fixing roller 211.

  Specifically, the transfer unit 205 transfers the image to the second side of the first sheet, that is, the second side where the image is not transferred, and the fixing roller 211 is transferred to the second side of the first sheet. Fix the image. Thereafter, the first sheet on which images are formed on both sides in this way is conveyed to a discharge conveyance path 213 by a discharge flapper 216, and is discharged after a predetermined finishing process is performed by a discharge unit 208. Note that the processing after S336 on the second paper is the same as the processing after S307 on the first paper, and therefore the description thereof is omitted.

  Next, the double-sided printing process according to the embodiment of the present invention will be described.

  FIG. 4 is an explanatory diagram of jobs and pages for explaining double-sided printing processing across jobs executed in the image forming apparatus 1000 according to the embodiment.

  In the present embodiment, a case will be described in which a plurality of jobs each including double-sided printing of a small amount of pages are continuously executed. In this case, print data corresponding to the job / page exists in order. For example, in the example of FIG. 4A, the print data for the second page of the third job in the job order from the print data of the first job / first page (hereinafter referred to as [job number-page number]) [ 3-2] are transmitted from the information processing apparatus 1001.

  Here, in normal double-sided printing, for example, as shown in FIG. 4B, according to the conveyance order of each sheet, print data [1-2] → print data [1-1] → print data [2-2]. Printing is performed in the order of print data [2-1], print data [3-2], and print data [3-1]. That is, the second page image of the first job is printed on the first side of the first sheet 401, and then the first job 1 is printed on the second side (the back side of the first side) of the first sheet 401. Print the image of the page. Next, the second page image of the second job is printed on the first side of the second sheet 402, and the first page image of the second job is printed on the second side of the second sheet 402. Finally, the second page image of the third job is printed on the first side of the third sheet 403, and the first page image of the third job is printed on the second side of the third sheet 403. To do. As a result, the first paper sheet is discharged to the paper discharge unit 118 with the side on which the image of the first page of the first job is printed facing down. Similarly, the second and third sheets are each discharged with the side on which the image of the first page is printed facing down.

  On the other hand, in high-speed double-sided printing, as shown in FIG. 4C, for example, as shown in FIG. 4C, the print data [1-2] → print data [2-2] → print data [1-1] is not followed. ], Print data [3-2], print data [2-1], and print data [3-1]. That is, the second page image of the first job is printed on the first side of the first sheet 411, and the second page image of the second job is printed on the first side of the second sheet 412. Next, the first page image of the first job is printed on the second side of the first sheet 411, and then the second page image of the third job is printed on the first side of the third sheet 413. To do. The first page image of the second job is printed on the second side of the second sheet 412, and finally the first page image of the third job is printed on the second side of the third sheet 413. .

  In the above example, the case where duplex printing is performed on one sheet in one job has been described. Next, a case where duplex printing is performed on a plurality of sheets in a single job will be described.

  FIG. 4D illustrates an example in which the print data from the first page to the sixth page in the page order transmitted by the information processing apparatus 1001 is transmitted in one job. FIG. 4E shows the printing order in high-speed duplex printing. Here, print data [1-2] → print data [1-4] → print data [1-1] → print data [1-6] → print data [1-3] → print data [1-5] Printed in order. That is, first, the second page image is printed on the first side of the first sheet 421, and then the fourth page image is printed on the first side of the second sheet 422. Then, the first page image is printed on the second side of the first sheet 421, the sixth page image is printed on the first side of the third sheet 423, and the second side of the second sheet 422 is printed. Print the third page image. Finally, the fifth page image is printed on the second side of the third sheet 423.

  5 and 6 are sequence diagrams illustrating an example of switching between high-speed duplex printing and normal duplex printing between jobs. FIG. 5 is a sequence diagram when high-speed duplex printing is possible between jobs and high-speed duplex printing is executed across jobs. FIG. 6 is a sequence when high-speed duplex printing is not possible between jobs. FIG.

  In steps S501 to S504 in FIG. 5, the information processing apparatus 1001 prints the first and second side print data printed on the last sheet of the preceding job and the first and second side prints printed on the first sheet of the subsequent job. The print data is sequentially transmitted to the control unit 100. Upon receiving these print data, the control unit 100 determines whether or not double-sided printing is performed in S505. If it is determined that double-sided printing is performed, the image data to be printed on the first and second surfaces of the final sheet of the preceding job is determined in S506. Generate. In S507 to S508, image data to be printed on the first and second surfaces of the first sheet of the subsequent job is generated in the same manner. Note that the processing of S501 to S508 is performed asynchronously with the communication between the control unit 100 and the printer unit 110.

  In step S <b> 509, the control unit 100 determines, on the basis of the image data to be printed on the first sheet of the last sheet of the preceding job, the printer unit 110 that has the sheet for printing the image data of the last sheet of the preceding job. Instruct to start feeding. Here, the start of paper feed for printing on the first side of the paper is instructed. As a result, the printer unit 110 first starts an image forming process on the first surface of the sheet that is the final sheet of the preceding job. Then, after the image formation on the transfer belt 206 is completed, the printer unit 110 starts feeding the paper at a timing at which transfer is possible. Upon completion of feeding, the printer unit 110 sends the preceding job to the control unit 100 in step S510. Is notified of the completion of feeding of the first side of the first sheet.

Thereafter, the printer unit 110 determines whether or not high-speed duplex printing is possible with respect to the control unit 100 in S511, which is a specific timing from the completion of the transfer to the first surface of the sheet that is the final sheet of the preceding job to the completion of printing. Is notified of whether or not to determine whether or not. This availability determination timing is determined based on various times and timings required for printing. For example, the minimum time required from the start of sheet feeding to the start of transfer (time A), after the control unit 100 receives this availability determination timing, the printer unit 110 is notified of the next sheet feeding start and the printer Assume that the printer unit 200 knows the time until the unit 110 receives (hereinafter, time B) and the time from a certain point to the start of the fastest transfer (time C). In that case,
Time A + Time B <Time C ... Formula (1)
At this timing, an availability determination timing notification for determining whether high-speed duplex printing is possible is issued. Note that when the above formula (1) is satisfied, for example, even if the start of image creation to be printed on the next side is instructed after waiting for the determination timing of S511, the productivity per double-sided printing does not deteriorate.

  When the control unit 100 receives this availability determination timing, in step S512, it is determined whether image data of the first and second surfaces of the sheet that is the first sheet of the subsequent job has been generated. Here, if image data has been generated, it is determined that high-speed duplex printing is possible, and in step S513, the printer unit 110 is instructed to start image formation on the first surface of the sheet serving as the first sheet of the subsequent job.

  In this case, high-speed duplex printing can be executed across jobs.

  FIG. 6 shows a case where the image data to be printed on the first surface of the sheet that is the first sheet of the subsequent job is not generated at the time of S511. In FIG. 6, parts common to FIG. 5 are denoted by the same reference numerals.

  In this case, in step S601, the control unit 100 determines that high-speed duplex printing is not possible. In step S <b> 602, the control unit 100 notifies the printer unit 110 of the start of the image to be printed on the second side of the sheet that is the last sheet of the preceding job, not the first sheet of the subsequent job, and executes normal duplex printing. To do. 5 and 6, the same processing as in S501 to S514 is performed for the final sheet of the subsequent job, and the high-speed double-sided printing and the normal double-sided printing are switched every time it is determined whether high-speed double-sided printing is possible. can do.

  As described above, the print data of each page is received by the image forming apparatus 1000 in job order and page order. For example, as shown in FIG. 4A, this is acquired in correspondence with the sheet conveyance order. In the high-speed duplex printing process, as shown in FIG. 4C, printing is performed without following the sheet acquisition order. At that time, depending on the job contents and environment, there is a possibility that a state (hereinafter referred to as an image data non-generation state) may not occur in time for generation of image data to be printed on the subsequent sheet at the timing for determining whether high-speed duplex printing is possible. . In particular, regarding the print data [2-2] on the second page of the second job, the second sheet on which the print data [2-2] is printed is applied to the first side of the first sheet. Conveyed after printing. That is, the print data for the second page of the second job is printed on the second transported sheet (see FIG. 4C).

  On the other hand, the print data [2-2] is obtained after obtaining the print data [1-1] to the print data [2-1], that is, obtained as the fourth print data (FIG. 4A )), It is most likely that an image data non-generated state will occur. As described above, the timing for determining whether high-speed double-sided printing is possible is the time when the feeding of the first surface of the paper on which printing is to be completed in the case of printing the final sheet of the job. If the final sheet of the job is not printed, it is the time when the first side of the paper on which it is printed is fed and the time when the first side is printed.

  In the example of FIG. 4C, the first sheet is the last sheet of the first job. Therefore, in order to continue high-speed double-sided printing between jobs, print data [2 -2] needs to be generated when the feeding of the first side of the first sheet is completed. The timing for completing the feeding of the first side of the first sheet does not have much time delay from the reception of the print data [2-2] printed on the second sheet. For this reason, the generation of the image data to be printed on the second sheet is not in time, and there is a high possibility of switching to the normal double-sided printing at a job break, and the productivity of the double-sided printing process is reduced.

  On the other hand, in the high-speed double-sided printing according to the embodiment, the determination as to whether high-speed double-sided printing on the final sheet of the job is possible is performed at the timing notified from the printer unit 110 to the control unit 100 in S511 described above. As a result, there is a certain margin from the start of the generation of the image data of the succeeding paper to the determination of whether high-speed double-sided printing is possible, and there is an effect that high-speed double-sided printing can be easily continued.

  FIG. 7 is a flowchart illustrating processing of the control unit 100 of the image forming apparatus 1000 according to the embodiment. A program for executing this processing is stored in the HDD 105, and is expanded in the RAM 102 at the time of execution, and is achieved by the CPU 101 executing the expanded program.

  In steps S <b> 701 to S <b> 703, the CPU 101 waits for one of a notification of completion of feeding the first side of the preceding paper, a notification of timing for determining whether high-speed duplex printing is possible, and a notification of completion of printing of the first side. Here, when the completion of feeding of the first side of the preceding paper is notified, the process advances from S701 to S704, and the CPU 101 determines whether image data to be printed on the first side of the succeeding paper has been generated at that time. If the CPU 101 determines in step S704 that image data to be printed on the first side of the subsequent sheet has been generated, the process advances to step S708, and the CPU 101 executes printing on the first side of the subsequent sheet based on the image data. This process is terminated. In step S704, the process returns to step S701 in which it is determined that image data to be printed on the subsequent sheet has not been generated.

  Next, when the above-described high-speed double-sided printability determination timing is notified, the process advances from S702 to S705, and the CPU 101 determines whether image data to be printed on the first side of the succeeding paper has been generated at that time. If the CPU 101 determines in step S705 that image data to be printed on the first side of the subsequent sheet has been generated, the process advances to step S708, and the CPU 101 performs printing on the first side of the subsequent sheet based on the image data. Run. On the other hand, if the CPU 101 determines in step S705 that image data to be printed on the first side of the subsequent sheet has not been generated, the process advances to step S706 to determine whether the preceding sheet is the last sheet of the job. If the CPU 101 determines in step S706 that the sheet is the final sheet of the job, the process advances to step S709 to execute printing on the second side of the preceding sheet, and the process ends. If the CPU 101 determines in step S706 that the sheet is not the final sheet, the process advances to step S701. That is, here, when image data to be printed on the first side of the succeeding sheet is not generated and the preceding sheet is the last sheet of the preceding job, the normal double-sided printing is started from the high-speed duplex printing. Switch to.

  If the completion of printing on the first surface of the preceding paper is notified in S703, the process proceeds to S707, and the CPU 101 determines whether image data to be printed on the succeeding paper has been generated at that time. If the CPU 101 determines in step S707 that image data to be printed on the succeeding sheet has been generated, the process advances to step S708 to execute printing on the first surface of the succeeding sheet, and the process ends. On the other hand, if the CPU 101 determines in step S707 that image data to be printed on the succeeding sheet has not been generated, the process advances to step S709, and the CPU 101 performs printing on the second surface of the preceding sheet, and ends this process.

  As described above, according to the embodiment, it is easy to continue high-speed double-sided printing even at job breaks, and double-sided printing across multiple jobs can be efficiently performed. As a result, the productivity of double-sided printing increases.

  In addition, when the generation of the print data of the succeeding sheet is not in time for the determination timing of whether or not the high-speed double-sided printing is possible, the normal printing is switched to the double-sided printing. Productivity does not decrease.

(Other embodiments)
The present invention supplies a program that realizes one or more functions of the above-described embodiments to a system or apparatus via a network or a storage medium, and one or more processors in a computer of the system or apparatus read and execute the program This process can be realized. It can also be realized by a circuit (for example, ASIC) that realizes one or more functions.

  The present invention is not limited to the above-described embodiment, and various changes and modifications can be made without departing from the spirit and scope of the present invention. Therefore, in order to make the scope of the present invention public, the following claims are attached.

  DESCRIPTION OF SYMBOLS 100 ... Control part, 101 ... CPU, 110 ... Printer part, 117 ... Paper feed unit, 118 ... Paper discharge unit, 1000 ... Image forming apparatus, 1001 ... Information processing apparatus

Claims (6)

A printing device,
When performing double-sided printing on a plurality of sheets, after printing on the first side of the preceding sheet, printing on the second side of the sheet, double-sided printing in the order of the first side and the second side of the subsequent sheet After the first double-sided printing to be performed and the printing of the first side of the preceding paper until the second side of the paper is printed, the printing is performed on the first side of at least one subsequent paper. A printing means capable of executing two-sided printing;
When a continuous job is executed in the second double-sided printing, when the last sheet of the preceding job is double-sided printing, the succeeding job is at least at a predetermined timing after the start of the transfer of the last sheet of the preceding job. Determining means for determining whether image data to be printed on the first sheet of paper has been generated;
If the determination unit determines that the image data to be printed on the first sheet of the subsequent job has been generated, the second double-sided printing is continued, and the determination unit has not generated the image data to be printed on the first sheet of the subsequent job. Control means for controlling to switch from the second duplex printing to the first duplex printing;
A printing apparatus comprising:   2. The printing according to claim 1, wherein the predetermined timing is a timing that is in time for starting the fastest transfer onto the paper when feeding of the paper that is the first paper of the subsequent job is started at the timing. apparatus.   The printing apparatus according to claim 1, wherein the second surface of the sheet is a back side of the first surface of the sheet.   4. The printing apparatus according to claim 1, wherein the second double-sided printing performs double-sided printing on a plurality of sheets at a higher speed than the first double-sided printing. 5. A control method for controlling a printing apparatus,
When performing double-sided printing on a plurality of sheets, after printing on the first side of the preceding sheet, printing on the second side of the sheet, double-sided printing in the order of the first side and the second side of the subsequent sheet A first double-sided printing step to be performed;
A second double-sided printing step of printing on the first side of at least one subsequent sheet after printing the first side of the preceding sheet and before printing the second side of the sheet;
When a continuous job is executed in the second double-sided printing process, if the last paper of the preceding job is double-sided printing, the succeeding job is at least at a predetermined timing after the start of the transfer of the last paper of the preceding job. A determination step of determining whether image data to be printed on the first sheet of the job has been generated;
If the determination process determines that the image data to be printed on the first sheet of the subsequent job has been generated, the second double-sided printing process is continued, and the determination process has generated the image data to be printed on the first sheet of the subsequent job. A control process for controlling to switch from the second double-sided printing process to the first double-sided printing process,
A control method for a printing apparatus, comprising:   The program for functioning a computer as each means of the printing apparatus of any one of Claims 1 thru | or 4.

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