JP2019194003A - Image forming device and image forming method - Google Patents

Abstract

To provide an image forming device capable of executing two-sided printing even when a sheet is not supported for two-sided printing at the time of two-sided printing.SOLUTION: A printer 1 includes an image forming part 3 for forming an image on a sheet P and a media sensor 240 for detecting characteristics of the sheet P. When the characteristics of the sheet P are not supported for automatic two-sided printing, the printer 1 forms an image on a first surface of the sheet P and discharges it to an FD paper discharge part 5 or an FU paper discharge part 7. The printer 1 instructs a user to place the discharged sheet P on a cassette 100 or a manual insertion tray 200. When the sheet P in which an image is formed on the first surface is placed on the cassette 100 or the manual insertion tray 200, the printer 1 forms an image on a second surface of the sheet P.SELECTED DRAWING: Figure 1

Description

  The present invention relates to an image forming apparatus such as a copying machine, a printer, and a facsimile.

  The image forming apparatus can form images on various types of recording materials. In the following description, the recording material is simply referred to as “paper”. An image forming apparatus may incorporate a sensor (hereinafter referred to as “media sensor”) to determine the type of paper. The image forming apparatus performs an optimal image forming process according to the type of paper determined using the media sensor. The image forming process includes fixing control for fixing an image on a sheet and conveyance control for conveying the sheet inside the image forming apparatus.

  For transport control according to the detection result of the media sensor, when double-sided printing is set to print on the front and back sides of one sheet of paper, it is determined whether the paper is compatible with automatic double-sided printing. In this case, there is a process for continuing the conveyance of the sheet. For example, in Patent Document 1, when it is determined from the detection result of the media sensor that the paper does not support automatic double-sided printing, an image to be formed on the front side and an image to be formed on the back side are arranged on one side in the order of two images. An invention of a printing apparatus that performs printing is disclosed.

JP 2009-154540 A

  In the printing apparatus of Patent Document 1, the user obtains two sheets of single-sided printed paper as a product, although the user desires double-sided printing. Therefore, the user cannot obtain the desired deliverable. Further, since the number of sheets to be printed increases, resources are consumed.

  SUMMARY OF THE INVENTION In view of the above problems, the present invention mainly provides an image forming apparatus that performs double-sided printing while suppressing paper consumption even when the paper does not support double-sided printing during double-sided printing. And

  The image forming apparatus of the present invention, based on the input print job, double-sided printing that performs printing on the second surface of the recording material by reversing the front and back of the recording material printed on the first surface on the conveyance path, or In an image forming apparatus that performs printing on a first surface of a recording material and performs single-sided printing that discharges the recording material, a sheet feeding unit that feeds the recording material, and an image corresponding to image data on the recording material An image forming unit for forming; a paper discharge unit for discharging the recording material on which the image is formed; a detection unit for detecting characteristics of the recording material fed by the paper feed unit; and the paper feed unit Control means for determining whether or not the recording material is compatible with the double-sided printing based on the detection result of the detection means for the recording material fed by the control means, the control means, Double-sided printing is specified in the print job When it is determined that the recording material does not support the double-sided printing based on the detection result of the detection unit, the image of the even page of the print job is displayed on the first surface of the recording material to the image forming unit. The recording materials formed in the order of the page numbers, the recording material on which the image is formed on the first surface are discharged to the paper discharge means, and the discharged recording material is supplied to the user for the printing of the second surface The image forming unit on the second surface of the recording material on which the image is formed on the first surface fed from the paper feeding unit for printing on the second surface. Thus, an odd-numbered page image is formed.

  According to the present invention, even when the paper does not support double-sided printing at the time of double-sided printing, it is possible to execute double-sided printing while suppressing paper consumption.

FIG. The block diagram of a controller. Explanatory drawing of a print job. 6 is a flowchart showing image forming processing. 6 is a flowchart illustrating normal printing processing. (A), (b) is an illustration figure of a message. (A)-(c) is explanatory drawing of imposition. (A)-(c) is explanatory drawing of imposition. 6 is a flowchart showing image forming processing. (A)-(d) is explanatory drawing of imposition. (A)-(d) is explanatory drawing of imposition. The flowchart showing the display process of an operation message. (A), (b) is an illustration figure of an operation message.

  The image forming apparatus of the present invention will be described with reference to the drawings.

(Hardware configuration)
FIG. 1 is a configuration diagram of a laser printer (hereinafter simply referred to as “printer”) which is an example of an image forming apparatus of the present embodiment. The printer 1 includes an image forming unit 3, a fixing device 4, a paper feeding unit that feeds paper P as a recording material, and a paper discharge unit (paper discharge tray) from which the paper P after image formation is discharged.

The image forming unit 3 includes an image carrier 31 made of, for example, a photoconductor and a developing device 32. The developing device 32 develops, for example, an electrostatic latent image formed on the image carrier 31 by charging and exposure processing with toner. As a result, a toner image is formed on the image carrier 31. A transfer roller 33 is provided at a position facing the image carrier 31 with a conveyance path through which the paper P is conveyed. Between the image carrier 31 and the transfer roller 33, a transfer unit T is configured to transfer the toner image from the image carrier 31 to the paper P. The image carrier 31 rotates, and conveys the formed toner image to the transfer unit T by rotating.
The fixing device 4 fixes the toner image on the paper P on which the toner image is transferred by the transfer unit T. The fixing device 4 heats and melts the toner, for example, and pressurizes the toner image on the paper P by pressurizing.

  The paper feed unit of the present embodiment includes a cassette 100 and a manual feed tray 200 as a plurality of paper feed ports. The cassette 100 is provided on the lower side of the casing of the printer 1. The manual feed tray 200 is provided on the side of the housing of the printer 1. In the present embodiment, the paper discharge unit includes an FD (Face Down) paper discharge unit 5 and a FU (Face Up) paper discharge unit 7 as a plurality of paper discharge ports. The FD paper discharge unit 5 is a paper discharge unit that discharges an image surface of a single-side printed paper or a front surface (first surface) of a double-side printed paper facing downward. The FU paper discharge unit 7 is a discharge unit that discharges an image surface of a single-side printed paper or a front surface (first surface) of a double-side printed paper facing upward. A transport path for transporting the paper P from the paper feed unit to the paper discharge unit is provided. Various rollers for transporting the paper P are provided in the transport path. The image forming unit 3 and the fixing device 4 are provided along the conveyance path.

  The cassette 100 has a function of detecting the size of the paper P to be stored. The cassette 100 includes a cassette sheet presence / absence sensor 103 that detects the presence / absence of the sheet P to be stored. The cassette 100 includes a cassette paper feed roller 101 on the conveyance path side. The paper P stored in the cassette 100 is separated and fed one by one to the transport path by a cassette paper feed roller 101 and a separation roller (not shown). The paper P fed from the cassette 100 is transported to the registration roller unit 20 by the cassette transport roller 102 and the transport roller 10 provided in the transport path.

  The manual feed tray 200 does not have a function of detecting the size of the loaded paper P. The manual feed tray 200 includes a manual feed tray paper presence / absence sensor 203 that detects the presence / absence of the paper P to be placed. In the present embodiment, the number of sheets that can be set in the manual feed tray 200 is 100 sheets. The manual feed tray 200 includes a manual feed tray roller 201 on the conveyance path side. The paper P placed on the manual feed tray 200 is separated and fed one by one to the transport path by the manual feed tray paper feed roller 201 and a separation roller (not shown). The paper P fed from the manual feed tray 200 is conveyed to the registration roller unit 20 by a manual feed tray conveyance roller 202 provided in the conveyance path.

  A media sensor 240 is provided on the upstream side of the registration roller unit 20 in the conveyance direction of the paper P after the conveyance path from the cassette 100 and the conveyance path from the manual feed tray 200 merge. The media sensor 240 detects characteristics such as the type and thickness (basis weight) of the paper P transported along the transport path. Based on the detection result of the media sensor 240, it is determined whether or not the paper P being conveyed is compatible with double-sided printing.

  The registration roller unit 20 stops rotating when the paper P is conveyed. The registration roller unit 20 corrects the skew of the sheet P, and conveys the sheet P to the transfer unit T in synchronization with the timing at which the toner image formed on the image carrier 31 is conveyed to the transfer unit T. On the paper P, the toner image is transferred by the transfer portion T, and the toner image is fixed by the fixing device 4, whereby an image is formed. The paper P on which the image is formed is conveyed from the fixing device 4 to the downstream side in the conveying direction by a fixing conveying roller 41 included in the fixing device 4.

A branch flapper 51 is provided on the downstream side of the fixing device 4 in the conveying direction. The branch flapper 51 sorts the paper P into either a discharge path for discharging the paper P to the outside of the apparatus, or a double-sided conveyance unit 6 for inverting the front and back surfaces of the paper P during double-sided printing.
A branch flapper 71 is provided in the discharge path. The branch flapper 71 distributes the paper P to either the FD paper discharge unit 5 or the FU paper discharge unit 7. When the paper P is sorted to the FD paper discharge unit 5 side by the branch flapper 71, the paper P is discharged and stacked on the FD paper discharge unit 5 by the paper discharge roller 52 in the order of printing. When the paper P is sorted to the FU paper discharge unit 7 by the branch flapper 71, the paper P is discharged and stacked on the FU paper discharge unit 7 in the order of printing.

The double-sided conveyance unit 6 includes a double-sided conveyance roller 61, a reverse roller 62, and a refeed roller 64. When duplex printing is set, the duplex conveying unit 6 reverses the front and back of the sheet on which the image is printed on the first side on the conveyance path, and feeds it for the second side printing. Specifically, the paper P on which an image is formed on the first surface is conveyed to the double-sided conveyance unit 6 by the branch flapper 51 and transferred to the double-sided conveyance roller 61. The duplex conveying roller 61 conveys the paper P to the reverse roller 62. When the rear end of the paper P in the transport direction passes through the double-sided transport roller 61 and reaches a predetermined paper reversal position R, the reversing roller 62 stops rotating. Thereafter, the reverse roller 62 reversely rotates to reverse the paper P and convey it to the refeed roller 64. The refeed roller 64 conveys the paper P. When the leading edge of the paper P reaches the refeed standby position S, the refeed roller 64 stops rotating. The double-sided conveyance unit 6 has a configuration in which it is difficult to convey a sheet having a predetermined basis weight or more because of the curvature of the bent portion of the conveyance path. Accordingly, a sheet having a predetermined basis weight or more is a sheet that does not support automatic duplex printing.
At the timing when printing on the second surface becomes possible, the refeed roller 64 resumes rotation and conveys the paper P to the registration roller unit 20. The paper P conveyed to the registration roller unit 20 is image-formed in the same manner as the first surface. The paper P on which image formation on the second side has been completed is distributed to the discharge path by the branch flapper 51 and discharged to one of the FD paper discharge unit 5 and the FU paper discharge unit 7.

(controller)
FIG. 2 is a configuration diagram of a controller that controls the operation of the printer 1. The controller 11 includes a CPU (Central Processing Unit) 1000, a ROM (Read Only Memory) 1001, and a RAM (Random Access Memory) 1002. The CPU 1000 controls the operation of the printer 1 by executing a computer program stored in the ROM 1001 using the RAM 1002 as a work area. The controller 11 includes a print control unit 1010, an A / D converter 1003, a duplex conveyance control unit 1004, and an interface (I / F) 260.

  The I / F 260 performs communication control with an external device 1100 such as a personal computer. The I / F 260 includes, for example, a USB (Universal Serial Bus), a LAN (Local Area Network), a modem, and the like. The I / F 260 acquires a print job including image data representing an image to be formed from the external device 1100. The I / F 260 transmits the acquired print job to the CPU 1000. The CPU 1000 expands image data included in the print job into bit data used for printing (image formation) by the printer 1, and the operation of the printer 1 is controlled by the print control unit 1010 according to the print job. The image data of the present embodiment represents a plurality of pages of images.

  FIG. 3 is an explanatory diagram of a print job. The print job includes an ID number 401, paper size data 402, paper feed port data 403, paper discharge port data 404, print mode data 405, single-sided / double-sided print data 406, and image data 410. The print job is one packet that includes various information when printing an image according to the image data 410. The CPU 1000 that has acquired the print job by the I / F 260 stores the print job in the RAM 1002.

  The ID number 401 is information for identifying image data. The paper size data 402 includes information that specifies the size of the paper to be printed in millimeters. The paper feed port data 403 includes information for designating a paper feed port (cassette 100, manual feed tray 200) for feeding paper for forming an image. The paper discharge port data 404 includes information for designating a discharge destination (FD paper discharge unit 5 and FU paper discharge unit 7) to discharge the image-formed paper. The print mode data 405 is information for designating control according to the basis weight of the paper or the paper type. The print mode data 405 includes a thin paper mode, a plain paper mode, a thick paper mode, an auto mode, and the like corresponding to the characteristics of the paper. Single-sided / double-sided printing data 406 is information for designating whether single-sided printing or double-sided printing is performed on a sheet.

  A print control unit 1010 controls the operation of the printer 1 under the control of the CPU 1000. A print control unit 1010 performs a series of high-pressure control such as conveyance control of paper P, charging processing, development processing, and transfer processing, scanner motor control, optical system control such as a laser beam, and fixing control. The print control unit 1010 detects the operating state of these loads. The CPU 1000 can detect a failure of each load according to a predetermined condition from the operation state of each load detected by the print control unit 1010.

The duplex conveyance control unit 1004 performs conveyance control of the sheet P performed by the duplex conveyance unit 6 when performing duplex printing on the sheet P under the control of the CPU 1000.
The A / D converter 1003 performs analog / digital conversion of the detection result output from the media sensor 240 and transmits the converted digital signal to the CPU 1000. As described above, the media sensor 240 detects the type and thickness (basis weight) of the paper P. The digital signal represents the type and thickness (basis weight) of the paper P detected by the media sensor 240. The CPU 1000 uses the acquired detection result digital signal for fixing control and conveyance control by the print control unit 1010.

  The operation unit 250 has a function as a user interface and includes an input device and an output device. The input device is, for example, an input key, a numeric keypad, a touch panel, or the like. The output device is a display, a speaker, or the like. The operation unit 250 can perform various settings of the printer 1 using an input device. The operation unit 250 can also input various information when printing an image included in the above-described print job by an input device. The operation unit 250 displays a print job input screen, a screen indicating the progress of printing, various setting screens, and the like by the output device.

(Example 1 of image forming process)
FIG. 4 is a flowchart showing image forming processing (printing processing) by the printer 1 having such a configuration. This process is started when the CPU 1000 acquires a print job from the operation unit 250 or the external device 1100. The CPU 1000 stores the acquired print job in the RAM 1002 and performs processing according to the stored print job. In this process, the CPU 1000 determines the type of the paper P from the detection result of the media sensor 240. When the paper P does not support double-sided printing, the CPU 1000 displays an operation message on the output device of the operation unit 250. The printer 1 outputs a product in response to a user response to the operation message.

  For this purpose, the CPU 1000 first determines whether or not the manual double-side mode is set (S101). In the manual duplex mode, the user manually moves the sheet from the paper discharge port to the manual feed tray 200 after printing on one side (first side), and then the other side (second side) according to the user's instruction. This is a print mode in which double-sided printing is performed by printing. When double-sided printing is instructed in the print job and the paper does not support double-sided printing, the CPU 1000 sets the manual double-sided mode according to the user's instruction.

  When the manual duplex mode is not set (S101: N), the CPU 1000 determines whether to perform single-sided printing or printing of the first side of double-sided printing by the image forming process (printing process) performed this time (S102). . The CPU 1000 makes this determination based on the simplex / duplex print data 406 of the print job stored in the RAM 1002.

  When printing on the second side of duplex printing (S102: N), the CPU 1000 starts normal printing processing (S200). FIG. 5 is a flowchart showing the printing process executed in the process of S200.

  The CPU 1000 determines whether single-sided printing or double-sided printing is designated based on the single-sided / double-sided printing data 406 of the print job stored in the RAM 1002 (S201). When single-sided printing is designated (S201: N), the CPU 1000 causes the print control unit 1010 to perform single-sided printing processing based on image data included in the print job (S210). The CPU 1000 causes the print control unit 1010 to discharge the printed paper P to the discharge port specified by the discharge port data 404 of the print job (S211).

When double-sided printing is designated (S201: Y), the CPU 1000 determines whether or not the current printing is printing on the first side of the paper P (S202). When it is the first surface (S202: Y), the CPU 1000 causes the print control unit 1010 to perform printing processing on the first surface based on the image data included in the print job (S203). The CPU 1000 causes the print control unit 1010 to convey the paper P after printing on the first surface to the duplex conveying unit 6 (S204).
When it is the second side (S202: N), the CPU 1000 causes the print control unit 1010 to perform printing processing on the second side based on the image data included in the print job (S205). The CPU 1000 causes the print control unit 1010 to discharge the printed paper P to the discharge port specified by the discharge port data 404 of the print job (S206). As described above, the printing process of S200 is performed.

  When the printing process is completed, the CPU 1000 determines whether the printing of the last page is completed by the print job (S150). When the printing of the last page is not completed (S150: N), the CPU 1000 repeatedly performs the processing from S101. When printing of the final page is completed (S150: Y), the CPU 1000 ends the process.

  When printing on the first side of single-sided printing or double-sided printing (S102: Y), the CPU 1000 feeds paper from either the cassette 100 or the manual feed tray 200 based on the paper feed port data 403 of the print job stored in the RAM 1002. Confirm whether to do. Here, a case where the cassette 100 is set in the paper feed port data 403 will be described. The CPU 1000 feeds paper from the cassette 100 specified by the paper feed port data 403 by the print control unit 1010 (S103). As a result, the printer 1 starts feeding.

The CPU 1000 acquires the detection result of the media sensor 240 and detects the type and basis weight of the fed paper P (S104). The CPU 1000 stores the detected type and basis weight of the paper P in the RAM 1002. The CPU 1000 determines whether or not the sheet P being conveyed is a support target corresponding to printing on the first side of single-sided printing or double-sided printing according to the detected basis weight of the paper P (S105). The basis weight supported by printing on the first side of single-sided printing or double-sided printing is stored in the ROM 1001 in advance. The CPU 1000 uses the basis weight detected by the media sensor 240 and the basis weight supported by the printing on the first side of single-sided printing or double-sided printing stored in the ROM 1001 to perform single-sided printing or double-sided printing on the paper P being conveyed. It is determined whether or not it is an object to be supported for printing the first side. In this embodiment, the basis weight upper limit supported by the printing on the first side of single-sided printing or double-sided printing is 199 [g / m ² ].

  If the paper P being transported is not supported for printing on the first side of single-sided printing or double-sided printing (S105: Y), the CPU 1000 determines that it is a misprint (S141). The CPU 1000 that has determined that the print has been misprinted cancels printing and issues a warning indicating that printing has been stopped by the operation unit 250. Thereafter, the CPU 1000 ends the process.

  When the paper P being transported is a support target for printing on the first side of single-sided printing or double-sided printing (S105: N), the CPU 1000 determines whether or not the auto mode is designated in the print mode data 405 of the print job. Judgment is made (S106). In the auto mode, the CPU 1000 automatically controls the fixing according to the detection result of the media sensor 240 without setting the print mode (thin paper mode, plain paper mode, thick paper mode, etc.) corresponding to the paper type by the user. This is a printing mode in which conveyance control is executed.

  When the auto mode is not designated (S106: N), the CPU 1000 operates in the print mode designated by the user. The CPU 1000 determines whether a sheet usable in the designated print mode is being conveyed based on the print mode designated in the print job and the detection result of the media sensor 240 (S140). If it cannot be used (S140: N), the CPU 1000 determines that a misprint has occurred (S141). The CPU 1000 that has determined that the print has been misprinted cancels printing and issues a warning indicating that printing has been stopped by the operation unit 250. Thereafter, the CPU 1000 ends the process. If it is usable (S140: Y), the CPU 1000 executes printing on the first side of single-sided printing or double-sided printing (S200).

When the auto mode is designated (S106: Y), the CPU 1000 determines whether or not it is the first side of double-sided printing based on the single-sided / double-sided printing data 406 of the print job (S107). If it is not the first side of duplex printing (S107: N), the CPU 1000 executes single-sided printing (S200).
When it is the first side of duplex printing (S107: Y), the CPU 1000 reads the basis weight of the paper P detected by the media sensor 240 from the RAM 1002. The CPU 1000 compares the basis weight supported by the double-sided printing recorded in the ROM 1001 with the basis weight detected by the media sensor 240 and determines whether or not the paper P being conveyed is supported by the double-sided printing ( S108). In the present embodiment, the basis weight of paper supported by double-sided printing is up to an upper limit of 120 [g / m ² ]. When the paper P being conveyed is supported by double-sided printing (S108: N), the CPU 1000 executes printing on the first side of double-sided printing (S200).

The point of this embodiment is that even if the paper exceeds the upper limit (120 [g / m ² ]) of the basis weight supported by automatic double-sided printing, the product of double-sided printing can be obtained by operating in the manual double-sided mode. Is to be. For example, even if the paper has a basis weight of 150 [g / m ² ] outside the automatic duplex printing support, a duplex printing product can be obtained by the procedure after S109 described below.

  If the paper P being conveyed is not supported by double-sided printing (S108: Y), the CPU 1000 displays a confirmation message on the operation unit 250 (S109). FIG. 6 is an exemplary view of a message displayed on the operation unit 250. In the process of S109, the message of FIG. 6A is displayed. FIG. 6A is a confirmation message for notifying the user that the paper P does not support double-sided printing and processing for performing double-sided printing. In the present embodiment, the confirmation message notifies the user that “the paper is not supported by the double-sided printing” and “a product of double-sided printing can be obtained in the manual duplex mode”. The user instructs the CPU 1000 whether or not to change the print mode to the manual duplex mode by selecting “Yes” or “No” in the confirmation message.

  If “No” is selected and no change to the manual duplex mode is instructed (S110: N), the CPU 1000 clears the confirmation message displayed on the operation unit 250 (S120). The CPU 1000 determines that a misprint has occurred after clearing the confirmation message (S141). The CPU 1000 that has determined that the print has been misprinted cancels printing and issues a warning indicating that printing has been stopped by the operation unit 250. Thereafter, the CPU 1000 ends the process.

  When “Yes” is selected and a change to the manual duplex mode is instructed (S110: Y), the CPU 1000 clears the confirmation message displayed on the operation unit 250 (S111). The CPU 1000 changes the print mode to the manual duplex mode after clearing the confirmation message (S112). The CPU 1000 stores information indicating that the manual duplex mode has been changed in the RAM 1002.

  The CPU 1000 determines the imposition of the printing order (imposition) of each page of the image data included in the print job according to the discharge destination of the printed paper P (S113). The CPU 1000 stores the determined imposition information in the RAM 1002. In the manual duplex mode, the printer 1 of the present embodiment prints an odd page after printing an even page of image data. In normal duplex printing (automatic duplex printing), imposition is performed so that even-numbered pages and odd-numbered pages are printed alternately.

  7 and 8 are explanatory views with impositions. FIGS. 7A and 8A show the number of sheets necessary for printing, which are impositioned during normal duplex printing. N represents the last page number of the image data. FIGS. 7B and 7C and FIGS. 8B and 8C illustrate impositioning during manual duplex printing according to the present embodiment. The imposition shown in FIG. 7 differs from the imposition shown in FIG.

  FIG. 7 shows imposition when the paper P after double-sided printing is discharged to the FD paper discharge unit 5. FIG. 7A illustrates impositioning when automatic duplex printing is performed on a sheet to be supported for duplex printing. The image data is assigned in the order of the even page and the odd page from the smallest page number. FIGS. 7B and 7C illustrate impositioning during manual duplex printing according to the present embodiment. In FIG. 7B, the image data in the first side printing is rearranged into even pages from the page with the larger page number. In the configuration in which the exposure of the first image is started before the media sensor 240 determines the type of the paper P, if it is determined that the paper P is out of the double-sided support, the toner already formed on the image carrier 31 The image is erased and printing is performed according to the modified imposition. In FIG. 7C, the image data in the second side printing is rearranged into odd-numbered pages from the smaller page number.

  FIG. 8 shows imposition when the paper P after double-sided printing is discharged to the FU paper discharge unit 7. FIG. 8A shows imposition when automatic duplex printing is performed on a sheet to be supported for duplex printing. The image data is assigned in the order of even pages and odd pages starting from the largest page number. 8B and 8C illustrate impositioning during manual duplex printing according to the present embodiment. In FIG. 8B, the image data in the first side printing is rearranged into even pages from the page number having the larger page number. In the configuration in which the exposure of the first image is started before the media sensor 240 determines the type of the paper P, if it is determined that the paper P is out of the double-sided support, the 1 already formed on the image carrier 31 is used. The first toner image can be used as it is. In FIG. 8C, the image data in the second side printing is rearranged into odd-numbered pages from the page with the larger page number.

  After determining the imposition, the CPU 1000 determines again whether or not the manual duplex mode is set (S101). Here, the printing mode is changed to the manual duplex mode in the process of S112. Since the manual duplex mode is set (S101: Y), the CPU 1000 determines whether printing of even-numbered pages of image data is completed according to the print job (S301). The CPU 1000 selects the paper discharge unit (the output destination of the result (paper P after double-sided printing)) specified by the print job discharge port data 404 in the order of FIG. 7B or FIG. 8B. Print even pages. The CPU 1000 makes this determination based on whether or not the last image data of the even page has been printed.

  When printing of even-numbered pages is not completed (S301: N), the CPU 1000 feeds paper from the cassette 100 designated by the paper feed port data 403 of the print job by the print control unit 1010 (S310). The CPU 1000 causes the print control unit 1010 to print an even page of image data on the first surface of the paper P (S311). The CPU 1000 causes the print control unit 1010 to discharge the paper P on which the first surface is printed to the paper discharge unit specified by the paper discharge port data 404 of the print job (S312). When the FD paper discharge unit 5 is designated, even-numbered pages are printed in the order shown in FIG. When the FU paper discharge unit 7 is designated, even pages are printed in the order shown in FIG. 8B. The CPU 1000 repeats the processes of S101, S301, S310 to S312 until the printing of even pages is completed.

  When printing of even pages is completed (S301: Y), the CPU 1000 determines whether printing of odd pages of image data is started (S302). When the odd-numbered page printing has not started (S302: N), the CPU 1000 displays an operation message for executing the printing of the second side in the manual double-sided printing illustrated in FIG. (S303). The operation message of the present embodiment instructs the user to set the paper P on which the even pages are printed on the first side to the manual feed tray 200. The CPU 1000 waits until the paper P is set on the manual feed tray 200 (S304: N).

  The CPU 1000 detects that the paper P is set on the manual tray 200 based on the detection result of the manual tray paper presence / absence sensor 203. When the paper P is set on the manual feed tray 200 (S304: Y), the CPU 1000 waits until the “execute” key 601 of the operation message is pressed (S305: N). When the “execute” key 601 of the operation message is pressed (S305: Y), the CPU 1000 clears the operation message displayed on the operation unit 250 (S306). The CPU 1000 starts printing odd pages of image data on the second surface of the paper P set on the manual feed tray 200 by the print control unit 1010 (S307). The CPU 1000 is shown in FIG. 7C or FIG. 8C according to the paper discharge unit (the output destination of the product (paper P after double-sided printing)) specified by the paper discharge port data 404 of the print job. Print odd pages in the order of imposition. The CPU 1000 causes the print control unit 1010 to discharge the paper P on which the second surface is printed to the paper discharge unit specified by the paper discharge port data 404 of the print job (S312).

  After discharging the first double-side printed paper P, the CPU 1000 performs the processes of S101, S301, and S302. Here, since printing of odd-numbered pages of image data has started (S302: Y), the CPU 1000 determines whether or not printing of odd-numbered pages of image data included in the print job has been completed (S320). When printing of odd pages is not completed (S320: N), the CPU 1000 feeds the paper P on which even pages set on the manual feed tray 200 are printed by the print control unit 1010. The CPU 1000 causes the print control unit 1010 to print the odd pages of the image data on the paper P on which the even pages are printed on the first surface (S322). The CPU 1000 causes the print control unit 1010 to discharge the paper P on which the second surface is printed to the paper discharge unit specified by the paper discharge port data 404 of the print job (S312). The CPU 1000 repeats the processes of S101, S301, S302, S320, S322, and S312 until the odd-numbered page is printed. When printing of odd pages is completed (S320: Y), the CPU 1000 ends the process.

  In the present embodiment, as shown in FIGS. 7A and 8A, the description has been given of the single-sheet circulation in which double-sided printing is performed in the order of even pages and odd pages. However, the present invention is not limited to this. Even page (first page 1), even page (second page 1), odd page (first page 2), even page (third page 1), odd page (second page) The present embodiment can be applied to other double-sided printing such as well-known two-sheet circulation in which double-sided printing is performed in the order of the second surface).

  In the present embodiment, the printer 1 prints even-numbered pages on the paper P fed from the cassette 100 in the first-side printing in the manual duplex mode. The user sets the paper P on which even-numbered pages are printed on the manual feed tray 200. Thereafter, the printer 1 prints odd-numbered pages on the paper P set on the manual feed tray 200 as the second side printing.

(Example 2 of image forming process)
FIG. 9 is another flowchart showing the image forming process (printing process) by the printer 1. In FIG. 9, the same processing steps as those in FIG. 4 are given the same step numbers. For the sake of brevity, the difference from the processing of FIG. 4 will be described. This process is started when the CPU 1000 acquires a print job from the operation unit 250 or the external device 1100. The CPU 1000 stores the acquired print job in the RAM 1002 and performs processing according to the stored print job. In this process, the CPU 1000 determines the type of the paper P from the detection result of the media sensor 240. When the paper P does not support double-sided printing, the CPU 1000 displays an operation message on the output device of the operation unit 250. The printer 1 outputs a product in response to a user response to the operation message.

  The CPU 1000 determines whether or not the manual duplex mode is set (S101). In the manual duplex mode of the present embodiment, the user manually moves the sheet from the paper discharge port to the cassette 100 or the manual feed tray 200 after printing the first side, and then prints the second side according to the user's instruction. This is a print mode for performing double-sided printing. When the paper is placed on the cassette 100, the surface on which the image is formed is placed face up. When the paper is placed on the manual feed tray 200, the surface on which the image is formed is placed face down. When double-sided printing is instructed in the print job and the paper does not support double-sided printing, the CPU 1000 sets the manual double-sided mode according to the user's instruction.

  The processes of S101 to S113, S200, S150, S140, S141, S120, S301, S302, S310 to S312 and S320 to S322 are the same as the processes shown in FIG. However, the imposition changing process performed in S113 is different.

10 and 11 are explanatory views with impositions. FIG. 10A and FIG. 11A show the number of sheets necessary for printing, with imposition on normal duplex printing. N represents the last page number of the image data. 10 (b), 10 (c), 10 (d) and FIGS. 11 (b), 11 (c), and 11 (d) show impositioning during manual duplex printing according to the present embodiment. 10A and 10B and the imposition shown in FIGS. 11A and 11B differ in the discharge destination of the paper P. The chamfers shown in FIGS. 10C and 10D and the chamfers shown in FIGS. 11C and 11D correspond to the paper feed port on which the paper P is placed after printing the first surface. Represents imposition.
Detailed description will be given below.

  FIG. 10 shows imposition when the paper P after double-sided printing is discharged to the FD paper discharge unit 5. FIG. 10A shows imposition when automatic duplex printing is performed on a sheet to be supported for duplex printing. The image data is assigned in the order of the even page and the odd page from the smallest page number.

  10 (b), 10 (c), and 10 (d) represent impositions during manual duplex printing according to this embodiment. In FIG. 10B, the image data in the first surface printing is rearranged into even pages from the page number having the smallest page number. In the configuration in which the exposure of the first image is started before the media sensor 240 determines the type of the paper P, if it is determined that the paper P is out of the double-sided support, the 1 already formed on the image carrier 31 is used. The first toner image can be used as it is.

  FIG. 10C shows the imposition when the paper P is placed on the cassette 100 after printing the first surface. The image data in the second side printing is rearranged into odd-numbered pages from the page with the smallest page number. FIG. 10D shows imposition when the paper P is placed on the manual feed tray 200 after printing the first surface. The image data in the second side printing is rearranged into odd-numbered pages from the page with the larger page number.

  FIG. 11 shows imposition when the paper P after double-sided printing is discharged to the FU paper discharge unit 7. FIG. 11A shows imposition when automatic duplex printing is performed on a sheet to be supported for duplex printing. The image data is assigned in the order of even pages and odd pages starting from the largest page number.

  11 (b), 11 (c), and 11 (d) illustrate impositioning during manual duplex printing according to the present embodiment. In FIG. 11B, the image data in the first side printing is rearranged into even pages from the page number having the larger page number. In the configuration in which the exposure of the first image is started before the media sensor 240 determines the type of the paper P, if it is determined that the paper P is out of the double-sided support, the 1 already formed on the image carrier 31 is used. The first toner image can be used as it is.

FIG. 11C shows imposition when the paper P is placed on the manual feed tray 200 after printing the first surface. The image data in the second side printing is rearranged into odd-numbered pages from the page with the larger page number. FIG. 11D shows the imposition when the paper P is placed on the cassette 100 after printing the first surface. The image data in the second side printing is rearranged into odd-numbered pages from the page with the smallest page number.
As described above, the imposition process of S113 is performed.

  When printing of even pages has been completed and printing of odd pages has not started (S302: N), the CPU 1000 displays an operation message for executing printing of the second surface in manual duplex printing on the operation unit 250. (S400). FIG. 12 is a flowchart showing the operation message display process executed in S400. FIG. 13 is an exemplary diagram of an operation message.

  When displaying the operation message, the CPU 1000 determines whether or not the even-numbered page is 100 pages or less by the print job (S331). In the case of 100 pages or less (S331: Y), the CPU 1000 displays an operation message for executing the printing of the second side in the manual duplex printing illustrated in FIG. 13A on the operation unit 250 (S332). Here, an operation message 611 for setting paper in the manual feed tray 200 and an operation message 612 for setting paper in the cassette 100 are displayed.

  When the number of printed pages exceeds 100 pages (S331: N), the CPU 1000 displays an operation message for executing the printing of the second side in the manual duplex printing illustrated in FIG. S333). Here, in consideration of the number of sheets that can be set in the manual feed tray 200, only an operation message 612 for setting sheets in the cassette 100 is displayed.

  As described above, the operation message display process of S400 is performed. The operation message of the present embodiment instructs the user that the paper P on which the even pages are printed on the first side can be set in the cassette 100 or the manual feed tray 200. The CPU 1000 waits until the paper P is set in the cassette 100 or the manual feed tray 200 (S401: N).

  The CPU 1000 detects that the paper P is set in the cassette 100 based on the detection result of the cassette paper presence / absence sensor 103. Further, the CPU 1000 detects that the paper P has been set on the manual tray 200 based on the detection result of the manual tray paper presence / absence sensor 203. When the paper P is set in the cassette 100 or the manual feed tray 200 (S401: Y), the CPU 1000 waits until the “execute” key 613 of the operation message is pressed (S402: N). When the “execute” key 613 of the operation message is pressed (S402: Y), the CPU 1000 stores the paper feed port on which the paper is set in the RAM 1002 (S403). The CPU 1000 clears the operation message displayed on the operation unit 250 (S404).

  The CPU 1000 starts printing an odd page of image data by the print control unit 1010 on the second surface of the paper P set in the cassette 100 or the manual feed tray 200 (S405). The CPU 1000 prints odd pages in the order of imposition shown in FIGS. 10C and 10D or FIGS. 11C and 11D in accordance with the paper feed port on which the paper P is set.

  The CPU 1000 determines the paper feed port on which the paper P is set based on the paper feed port on which the paper P stored in the RAM 1002 is set (S406). When the paper P is set in the cassette 100 (S406: Y), the CPU 1000 discharges the paper P on which the second surface is printed to the FD paper discharge unit 5 (S407). When the paper P is set on the manual feed tray 200 (S406: N), the CPU 1000 discharges the paper P on which the second surface is printed to the FU paper discharge unit 7 (S408).

  After discharging the first double-side printed paper P, the CPU 1000 performs the processes of S101, S301, and S302. Thereafter, odd pages are printed by the same processing as S320 to S322 in FIG.

  In the present embodiment, as shown in FIGS. 10A and 11A, the description has been given of the single-sheet circulation in which double-sided printing is performed in the order of even pages and odd pages, but the present invention is limited to this. is not. Even page (first page 1), even page (second page 1), odd page (first page 2), even page (third page 1), odd page (second page) The present embodiment can also be applied to other double-sided printing such as the well-known two-sheet circulation that performs double-sided printing in the order of the second side).

  In the present embodiment, the printer 1 prints even-numbered pages on the paper P fed from the cassette 100 in the first-side printing in the manual duplex mode. The user sets the paper P on which even pages are printed in the cassette 100 or the manual feed tray 200. Thereafter, the printer 1 prints odd-numbered pages on the paper P set in the cassette 100 or the manual feed tray 200 as the second side printing.

  The printer 1 of the present embodiment as described above determines whether the paper is supported by duplex printing according to the detection result of the media sensor 240. If the paper is not supported by double-sided printing, the printer 1 operates in the manual double-sided mode in which the user sets a paper with an image formed on one side in the printer, and the order of the pages of image data to be double-sided printed. To change. Thereby, double-sided printing can be executed while suppressing the consumption of the paper P.

  Since double-sided printing is performed by changing the page order of image data, the user can obtain a desired double-sided printing product. Further, in the configuration in which the exposure of the first image is started before the media sensor 240 determines the type of the paper P, if it is determined that the paper P is out of the double-sided support, it has already been formed on the image carrier 31. The first toner image can be used as it is. As a result, since it is not necessary to erase the formed toner image, both sides can be printed quickly and at the same time, waste of toner consumption can be eliminated.

  In the manual duplex mode, it is not necessary to transport the sheet by the duplex transport unit 6. Therefore, it is not necessary to mechanically change the conveyance path of the double-sided conveyance unit 6 and it is possible to perform double-sided printing on a type of paper that is not supported by automatic double-sided printing without increasing the cost. Further, even in a downsized printer that does not include the double-sided conveyance unit 6, double-sided printing can be performed by switching to manual double-sided. As described above, the printer 1 according to the present embodiment executes double-sided printing while suppressing paper consumption by switching to manual double-sided printing even when the paper does not support automatic double-sided printing during double-sided printing. It is possible.

Claims (10)

Double-sided printing that prints on the second surface of the recording material by inverting the front and back of the recording material printed on the first surface on the conveyance path based on the input print job, or printing on the first surface of the recording material In an image forming apparatus that performs single-sided printing for discharging the recording material,
Paper feeding means for feeding the recording material;
Image forming means for forming an image according to image data on the recording material;
A paper discharge means for discharging the recording material on which the image is formed;
Detecting means for detecting characteristics of the recording material fed by the paper feeding means;
Control means for determining whether or not the recording material is compatible with the double-sided printing based on a detection result of the detection means for the recording material fed by the paper feeding means,
When the control unit determines that double-sided printing is specified in the print job and the recording material does not support the double-sided printing based on the detection result of the detecting unit, the control unit sends the image forming unit to the image forming unit. An image of the even pages of the print job is formed on the first surface of the recording material in the order of page numbers, and the recording material on which the image is formed on the first surface is discharged to a paper discharge unit. An instruction is given to place the discharged recording material on a paper feeding means for printing on the second surface, and an image is fed on the first surface fed from the paper feeding means for printing on the second surface. An image of odd pages is formed on the second surface of the formed recording material by the image forming means,
Image forming apparatus. The paper discharge means is configured to discharge a first paper discharge tray on which the odd-numbered page image surface of the recording material is discharged downward, and an upper surface of the recording material on which the odd-numbered page image is formed. And a second paper discharge tray,
When the control unit determines that the recording material does not support the double-sided printing based on the detection result of the detection unit, the control unit selects an odd page and an even number according to the paper discharge unit specified in the print job. Determining the printing order of pages,
The image forming apparatus according to claim 1. When the control unit determines that the recording material does not support the double-sided printing, the control unit determines that the recording material does not support the double-sided printing and an image on the first surface. The recording material formed and discharged to the paper discharge means is notified to urge the user to place the recording material on the paper supply means for printing on the second surface.
The image forming apparatus according to claim 1. The notification that prompts the user to place the sheet on the sheet feeding unit includes a first notification that is notified when a print page of the print job is a predetermined page or less, and a second notification that is notified when the print page exceeds the predetermined page. Having a notification,
The image forming apparatus according to claim 3. The sheet feeding means includes a first sheet feeding unit on which the recording material is placed with a surface on which an even page image is formed facing down, and the recording on which a surface on which an even page image is formed is facing upward. A second paper feeding unit on which the material is placed,
The control means determines the printing order of odd pages according to the paper feeding means on which the recording material on which images of even pages are formed is placed.
The image forming apparatus according to claim 1. The control means switches the paper discharge means as the discharge destination of the recording material on which the odd-numbered page image is formed, according to the paper feeding means on which the recording material on which the even-numbered page image is formed is placed. Characterized by the
The image forming apparatus according to claim 1. The control means terminates the print job without forming an image when the user does not instruct execution of processing in response to the notification.
The image forming apparatus according to claim 3. The print job includes print mode data indicating a print mode for performing printing according to the characteristics of the recording material,
The control unit causes the image forming unit to form an image when the characteristic of the recording material corresponds to a print mode represented by the print mode data, and when the characteristic of the recording material does not correspond to the print mode. The process is terminated without forming an image.
The image forming apparatus according to claim 1. The control unit causes the image forming unit to form an image on the first surface of the recording material when the double-sided printing is specified in the print job and the recording material does not support the double-sided printing. Characterized by starting,
The image forming apparatus according to claim 8. A paper feeding means for feeding the recording material;
Image forming means for forming an image according to predetermined image data on the recording material;
A paper discharge means for discharging the recording material on which the image is formed;
Detecting means for detecting the characteristics of the recording material fed by the paper feeding means, and reverses the front and back of the recording material printed on the first surface on the conveyance path based on the input print job. A method executed by an image forming apparatus for performing double-sided printing for printing on the second surface of the recording material or single-sided printing for performing printing on the first surface of the recording material and discharging the recording material,
Based on the detection result of the detection means for the recording material fed by the paper feeding means, determine whether the recording material is compatible with the double-sided printing,
When double-sided printing is specified in the print job and it is determined that the recording material does not support the double-sided printing, the image forming unit applies even-numbered pages of the print job to the first surface of the recording material. Are formed in the order of page numbers, and the recording material on which the image is formed on the first surface is discharged to a paper discharge means,
Instructing the user to place the discharged recording material on a paper feeding means for printing on the second side,
Forming an image of odd pages by the image forming unit on the second side of the recording material on which the image is formed on the first side fed from the paper feeding unit for printing on the second side; Characterized by the
Image forming method.

Images