Patent Application
20200236237
Japanese Patent Application No. 2019-005611 filed on Jan. 17, 2019, including description, claims, drawings, and abstract, the entire disclosure of which is incorporated herein by reference in its entirety.
The present invention is directed to image forming apparatuses, methods for controlling sheet insertion, and non-transitory computer-readable recording media each storing a program for controlling sheet insertion. In particular, the present invention is directed to image forming apparatuses equipped with a sheet inserter for inserting insertion sheets between media sheets, methods for controlling sheet insertion in the image forming apparatus, and non-transitory computer-readable recording media each storing a program for controlling sheet insertion to be executed in the image forming apparatus.
Image forming apparatuses like MFPs (multi-functional peripherals) provide various kinds of capability. For example, on the market, there are image forming apparatuses capable of checking an image formed on each printed media sheet and of inserting insertion sheets between printed media sheets by using a sheet inserter.
As an example of techniques relating to such image forming apparatuses equipped with a sheet inserter, Japanese Unexamined Patent Publication (JP-A) No. 2008-094570 discloses the following image forming system. The image forming system includes an image forming apparatus, an insertion-sheet feeder, a post-processor, a sensor and a mode selector. The image forming apparatus is configured to form images on media sheets. The insertion-sheet feeder is configured to feed insertion sheets into a sheet path downstream of the image forming apparatus. The post-processor is configured to receive the media sheets processed by the image forming apparatus and insertion sheets fed by the insertion-sheet feeder, and finish the received sheets. The sensor is configured to detect the presence of an abnormality in conveyance of each insertion sheet that is being fed from the insertion-sheet feeder to the post-processor. The mode selector is configured to change a sheet-conveyance mode to one of: a productive mode in which, without waiting for a completion of the detection of the presence of an abnormality in conveyance of an insertion sheet with the sensor, the image forming system starts conveyance of the next media sheet fed from the image forming apparatus, succeeding to the insertion sheet; and a quality-first mode in which, after the completion of the detection of the presence of an abnormality in conveyance of an insertion sheet with the sensor, the image forming system starts conveyance of the next media sheet.
When a problem or defect has been detected in a printed image on a media sheet downstream of an insertion sheet after the insertion sheet had been put into the sheet path, the insertion sheet in the sheet path needs to be ejected to be disposed together with the printed media sheet with a defective image, as spoilage, even if the insertion sheet is usable, because the feeding of the upstream insertion sheet is earlier than the detection of a defective image on the downstream media sheet. It causes not only a problem that a usable insertion sheet or sheets are spoiled and a number of sheets are wastefully used in a process to make print products in total, but also a problem that, in a case that ordered insertion sheets (insertion sheets to be put between printed media sheets in predetermined order, like insertion sheets with page numbers) are used in this process, the pages of a resulting print product becomes out of order.
The present invention is directed to image forming apparatuses, methods of controlling sheet insertion, and non-transitory computer-readable recording media each storing a program for controlling sheet insertion, which can reduce wasteful use of insertion sheets and maintain the correct page order of print products, in operations of the image forming apparats to create one or more print products according to a job, with putting insertion sheets between printed media sheets.
The present invention is further directed to image forming apparatuses, methods of controlling sheet insertion, and non-transitory computer-readable recording media each storing a program for controlling sheet insertion, which can minimize a fall of the productivity of the image forming apparatus even if spoilage of sheets occurs in the operations of the image forming apparatus.
An image forming apparatus reflecting one aspect of the present invention is an image forming apparatus that processes a job to create one or more print products. The image forming apparatus comprises a print engine that forms images on respective media sheets; an image checker; a sheet inserter; a sheet ejector; and one or more controllers. The image checker comprises a sensor that, in response to the image checker receiving a media sheet output from the print engine, reads an image formed on the media sheet to obtain a measured image for use in a check whether the image is defective or not. The sheet inserter puts insertion sheets into a sheet path between the print engine and the image checker. The sheet ejector ejects media sheets subjected to the check and insertion sheets put into the sheet path by the sheet inserter, and comprises a first ejection path for ejecting media sheets with images determined to be non-defective together with insertion sheets put between the media sheets, and a second ejection path, which is different from the first ejection path, for ejecting media sheets with images determined to be defective. On the image checker receiving a media sheet output from the print engine, the one or more controllers perform, by using the measured image obtained by the sensor, a check whether an image formed on the media sheet is defective or not. The one or more controllers further cause the sheet inserter to start putting an insertion sheet into the sheet path, after a determination that an image of one of media sheets output from the print engine is non-defective is made, as a result of the check.
A method reflecting one aspect of the present invention is a method of controlling sheet insertion in an image forming apparatus that processes a job to create one or more print products. The image forming apparatus comprises: a print engine that forms images on respective media sheets; an image checker; sheet inserter; sheet ejector; and one or more controllers. The image checker comprises a sensor that, in response to the image checker receiving a media sheet output from the print engine, reads an image formed on the media sheet to obtain a measured image for use in a check whether the image is defective or not. The sheet inserter puts insertion sheets into a sheet path between the print engine and the image checker. The sheet ejector ejects media sheets subjected to the check and insertion sheets put into the sheet path by the sheet inserter, and comprises a first ejection path for ejecting media sheets with images determined to be non-defective together with insertion sheets put between the media sheets, and a second ejection path, which is different from the first ejection path, for ejecting media sheets with images determined to be defective. The method comprises: on the image checker receiving a media sheet output from the print engine, performing, by the one or more controllers, a check whether an image formed on the media sheet is defective or not, by using the measured image obtained by the sensor; and causing the sheet inserter to start putting an insertion sheet into the sheet path, by the one or more controllers, after a determination that an image of one of media sheets output from the print engine is non-defective is made, as a result of the check.
A non-transitory computer-readable recording medium reflecting one aspect of the present invention stores a program for controlling sheet insertion in an image forming apparatus that processes a job to create one or more print products. The image forming apparatus comprises: a print engine that forms images on respective media sheets; an image checker; a sheet inserter; a sheet ejector; and one or more controllers. The image checker comprises a sensor that, in response to the image checker receiving a media sheet output from the print engine, reads an image formed on the media sheet to obtain a measured image for use in a check whether the image is defective or not. The sheet inserter puts insertion sheets into a sheet path between the print engine and the image checker. The sheet ejector ejects media sheets subjected to the check and insertion sheets put into the sheet path by the sheet inserter, and comprises a first ejection path for ejecting media sheets with images determined to be non-defective together with insertion sheets put between the media sheets, and a second ejection path, which is different from the first ejection path, for ejecting media sheets with images determined to be defective. The program comprises instructions which, when being executed by the one or more controllers, cause the one or more controllers to perform the following operations. The operations comprise: on the image checker receiving a media sheet output from the print engine, performing, by using the measured image obtained by the sensor, a check whether an image formed on the media sheet is defective or not; and causing the sheet inserter to start putting an insertion sheet into the sheet path, after a determination that an image of one of media sheets output from the print engine is non-defective is made, as a result of the check.
The advantages and features provided by one or more embodiments of the invention will become more fully understood from the detailed description given hereinbelow and the appended drawings which are given by way of illustration only, and thus are not intended as a definition of the limits of the present invention, wherein:
Hereinafter, one or more embodiments of the present invention will be described with reference to the drawings. However, the scope of the invention is not limited to the illustrated embodiments.
As indicated in BACKGROUND, in operations to put an insertion sheet in a sheet path in an image forming apparatus capable of checking an image formed on each media sheet and inserting insertion sheets between printed media sheets by using a sheet inserter, the following problem can arise. When a problem or defect has been detected in a printed image on a media sheet downstream of an insertion sheet after the insertion sheet had been put into the sheet path, the insertion sheet in the sheet path needs to be ejected to be disposed together with the printed media sheet with a defective image, as spoilage, even if the insertion sheet is usable. It causes not only a problem that a usable insertion sheet or sheets are spoiled and a number of sheets are wastefully used in a process to make print products in total, but also a problem that, in a case that ordered insertion sheets are used for this process, the pages of a resulting print product becomes out of order.
In view of that, the following image forming apparatus that processes a job to create one or more print products is given as one embodiment according to the present invention. The image forming apparatus is configured to suspend feeding of an insertion sheet into a sheet path during a detection of the presence of a defective image formed on one of printed media sheets (a check whether an image formed on the media sheet is defective or not), and cause a sheet inserter to start putting an insertion sheet into the sheet path after a determination that an image of the media sheet is non-defective is made. In concrete terms, the image forming apparatus includes a print engine that forms images on respective media sheets, an image checker, a sheet inserter, a sheet ejector and one or more controllers. The image checker is equipped with a sensor that, in response to the image checker receiving a media sheet output from the print engine, reads an image formed on the media sheet to obtain a measured image for use in a check whether the image is defective or not. The sheet inserter is disposed so as to put insertion sheets into a sheet path between the print engine and the image checker. The sheet ejector ejects, through the first ejection path, media sheets with images determined to be non-defective together with insertion sheets put between the media sheets, and further ejects media sheets with images determined to be defective through the second ejection path which is different from the first ejection path. The one or more controllers perform the following operations. That is, when the image checker receives a media sheet output from the print engine, the one or more controllers perform, by using the measured image obtained by the sensor, a check whether an image formed on the media sheet is defective or not. The one or more controllers then cause the sheet inserter to start putting an insertion sheet into the sheet path, after a determination that an image of one of media sheets output from the print engine (for example, a media sheet to be followed by the insertion sheet in the sheet path) is non-defective is made, as a result of the check.
In another case that unordered insertion sheets (insertion sheets that can be put between media sheets output from the print engine, regardless of order of the insertion sheets) are used for a process to create one or more print products according to a job, the sheet-ejection operations such that the sheet ejector ejects a printed media sheet on which a defective image has been detected and an insertion sheet following the media sheet to the same ejection tray, do not make a large problem. In other words, even if the image forming apparatus performs recovery printing in response to the detection of a defective image on a printed media sheet, the above-described operations do not cause disorder of pages of a resulting print product because all the insertion sheets are unordered insertion sheets that can be used regardless of the order. However, the image forming apparatus is configured to cause the sheet inserter to start putting an insertion sheet into the sheet path after the determination of an image formed on one of printed media sheets. It may cause a fall of the productivity of the image forming apparatus.
In view of that, in one embodiment of the present invention, the image forming apparatus is configured to define the timing of putting insertion sheets into the sheet path in accordance with a result of an estimation whether insertion sheets in the sheet inserter are unordered insertion sheets (insertion sheets that can be put between media sheets output from the print engine, regardless of order of the insertion sheets) or ordered insertion sheets (insertion sheets to be put between media sheets output from the print engine, in predetermined order). In concrete terms, the sensor of the image checker is configured to, in response to the image checker receiving an insertion sheet put into the sheet path, read a face of the insertion sheet and obtain measured image, and the one or more controllers are configured to perform an insertion-sheet check by using the measured images of a pair of insertion sheets put into the sheet path. In the insertion-sheet check, the one or more controllers estimate whether the pair of insertion sheets are unordered insertion sheets or ordered insertion sheets, and according to a result of the estimation, further estimate whether insertion sheets in the sheet inserter are unordered insertion sheets or ordered insertion sheets. The one or more controllers then define the timing of putting insertion sheets into the sheet path in accordance with a result of the estimation whether insertion sheets in the sheet inserter are unordered insertion sheets or ordered insertion sheets.
As described above, the image forming apparatus is configured to cause the sheet inserter to start putting an insertion sheet into the sheet path, after a completion of a determination that an image of one of media sheets output from the print engine is non-defective. It reduces wasteful use of insertion sheets and maintains the correct page order of print products. Further, with the apparatus's operations to define the timing of putting insertion sheets into the sheet path according to a result of an estimation whether insertion sheets in the sheet inserter are unordered insertion sheets or ordered insertion sheets, a fall of the productivity of the image forming apparatus can be minimized even if spoilage of sheets occurs in a process to make print products.
In order to describe an embodiment of the present invention in more in detail, a description is given of an image forming apparatus, a method of controlling sheet insertion, and a non-transitory computer-readable recording medium storing a program for controlling sheet insertion, with reference to
Image forming apparatus 10 according to the present embodiment is an apparatus for processing print jobs and forming images on media sheets to create one or more print products, like a MFP. As illustrated in
Built-in controller 11 includes CPU (Central Processing Unit) 11a, which is a hardware processor, and memories including ROM (Read Only Memory) 13 and RAM (Random Access Memory) 14. CPU 12 is configured to read out control programs (including a program for controlling sheet insertion which will be described later) stored in ROM 13 or storage unit 15, load the control programs onto RAM 14, and execute the control programs, thereby controlling operations of image forming apparatus 10.
Storage unit 15 is a non-transitory computer-readable recording medium including a HDD (hard disk drive) and/or a SSD (solid-state drive). Storage unit 15 stores programs which, when being executed, causes CPU 12 to control the components of image forming apparatus 10, information about processing and functions of image forming apparatus 10, a print job, image data created by image processor 18 and other data.
Network interface (I/F) 16 includes a NIC (Network Interface Card) and/or a modem, and communicably connects image forming apparatus 10 to a communication network so that image forming apparatus 10 can receive print jobs from a client terminal.
Display and operation unit 17 is a device configured to display various kinds of screens (like a screen for setting a sheet-insertion mode, which will be described later) and allow an operator to perform in the screens various kinds of operations (like an operation to choose the sheet-insertion mode in the screen). Examples of display and operation unit 17 include a touch screen in which an operation unit that works as an input device (a resistive touch sensor composed of lattice-shaped transparent electrodes or a capacitive touch sensor) is arranged on a display unit like a LCD (liquid-crystal display) or an OEL (organic electroluminescence) display. In the present embodiment, a touch screen, in which a display unit and an operation unit are housed in one body, is employed as an instance of display and operation unit 17, but alternatively, a display unit and an operation unit as separated bodies may be employed as an instance of display and operation unit 17.
Image processor 18 serves as a RIP (raster-image processor), and is configured to translate a print job into intermediate data (an intermediate format called the display list or DL), and then rasterize pages of a document provided by the print job to create bitmap image data. Image processor 18 is further configured to perform image processing, such as screening, tone correction, density-balance adjustment, thinning, halftoning and other processing, on image data as needed; and output the resulting image data to print processor 20.
Sheet feeder 19 includes one or more feed trays (in
Print processor 20 is a print engine that is configured to use image data on which image processing was performed by image processor 18, to form images on respective media sheets. Print processor 20 includes components necessary for forming images on respective media sheets by using electrographic processes or electrostatic recording process, in other words, includes, for example, a charging unit, a photoreceptor drum, an exposure unit, a developing unit, transfer rollers, a transfer belt and a fixing unit. In concrete terms, print processor 20 is configured to perform print processing as follows. The charging unit charges the photoreceptor drum, and the exposure unit irradiates the photoreceptor drum with light in accordance with image data, to create a latent image. The developing unit adheres charged toner onto the photoreceptor drum, to develop the toner image. The toner image is transferred onto a media sheet by using the transfer rollers (for the first transfer process) and the transfer belt (for the second transfer process). The fixing unit then fixes the toner image onto a media sheet.
Sheet inserter 21 includes one or more insertion trays for loading insertion sheets thereon (in
Image checker 22 includes a sensor capable of, in response to image checker 22 receiving a media sheet output from print processor 20, reading one face of a sheet or both faces of a sheet and obtaining measured image or images, at image-check position 22a in
Image checker 22 is further configured work as an insertion-sheet checker by using measured images of insertion sheets in the sheet path, obtained by the inline sensor. In concrete terms, in response to image checker 22 receiving an insertion sheet put into the sheet path, the inline sensor reads a face of the insertion sheet and obtains a measured image. Using the measured images of a pair of insertion sheets put into the sheet path, image checker 22 performs an insertion-sheet check. In the insertion-sheet check, image checker 22 estimates whether the pair of insertion sheets are unordered insertion sheets (insertion sheets that can be put between media sheets, regardless of order of the insertion sheets) or ordered insertion sheets (insertion sheets to be put between media sheets in predetermined order), and according to a result of the estimation, further estimate whether insertion sheets in sheet inserter 21 are unordered insertion sheets or ordered insertion sheets. Image checker 22 may perform the insertion-sheet check each time when image checker 22 (the inline sensor) receives an insertion sheet put into the sheet path by sheet inserter 21. As an example of such insertion-sheet check, the inline sensor may be configured to read both faces of an insertion sheet and obtain measured images, and image checker 22 may perform, in response to receiving an insertion sheet put into the sheet path, an estimation whether a pair of insertion sheets in the sheet path are unordered insertion sheets or ordered insertion sheets based on the measured images of first faces of the pair of insertion sheets and another estimation based on the measured images of second faces of the pair of insertion sheets. On finding that one or both of the estimations resulted in that the pair of insertion sheets are ordered insertion sheets, image checker 22 may estimate that the pair of insertion sheets are ordered insertion sheets as a result of the first estimation in the insertion-sheet check. As another example of the insertion-sheet check, after the first estimation in the insertion-sheet check (estimating whether a pair of insertion sheets in the sheet path are unordered insertion sheets or ordered insertion sheets) came to the same result for a predetermined number of times in succession, image checker 22 may omit the first estimation for the remaining insertion sheets till the end of processing of a current print job. As another example of the insertion-sheet check, after the first estimation in the insertion-sheet check came to the same result for a predetermined number of times in succession during creation of one of print products according to a print job, image checker 22 may omit the first estimation for the remaining insertion sheets during creation of remaining print products according the print job. As another example of the insertion-sheet check, on finding that the first estimation in the insertion-sheet check resulted in that a pair of the insertion sheets in the sheet path are unordered insertion sheets for a predetermined number of times in succession, image checker 22 may estimate that insertion sheets in sheet inserter 21 are unordered insertion sheets as a result of the second estimation in the insertion-sheet check. Image checker 22 may perform the above-described estimations by using various estimation bases (in other words, may choose one of bases to be used for the estimations). For example, the first estimation in the insertion-sheet check may be performed on the basis of measured images of predetermined areas of a pair of insertion sheets in the sheet path, obtained by the inline sensor. For another example, the first estimation in the insertion-sheet check may be performed on the basis of one or both of surface profiles of a pair of insertion sheets in the sheet path and colors of a pair of insertion sheets in the sheet path.
Sheet ejector 23 includes multiple output trays (in
As illustrated in
Sheet-insertion-mode determiner 11a is configured to prompt an operator to define timing of putting insertion sheets into the sheet path by sheet insertor 21, by using a display like display and operation unit 17. Sheet-insertion-mode determiner 11a may be configured to present multiple modes of putting insertion sheets into the sheet path (sheet-insertion modes) on a display, to prompt an operator to choose one of the sheet-insertion modes. Examples of the sheet-insertion modes include an automatic mode, a productive mode and a quality-first mode. In the automatic mode, sheet inserter 21 starts putting each insertion sheet into the sheet path in accordance with a result of the insertion-sheet check performed by the insertion-sheet checker. In the productive mode, sheet inserter 21 disregards a result of the insertion-sheet check with the insertion-sheet checker and starts putting each insertion sheet into the sheet path without waiting for a completion of the check of an image formed on a media sheet to be followed by the each insertion sheet. In the quality-first mode, sheet inserter 21 disregards a result of the insertion-sheet check performed by the insertion-sheet checker and starts putting each insertion sheet after a completion of the check of an image formed on a media sheet to be followed by the each insertion sheet.
It should be noted that
For example, sheet inserter 21 in the above description is configured to control feeding of insertion sheets according to a result of the check performed by image checker 22 (or the insertion-sheet checker). Alternatively, built-in controller 11 may be configured to determine the timing of putting insertion sheets into the sheet path according to a result of the check performed by image checker 22 (or the insertion-sheet checker), and cause sheet inserter 21 to start putting insertion sheets into the sheet path. For another example, image checker 22 in the above description is configured to perform the check whether an image formed on a received media sheet is defective or not by using measured image obtained by the inline sensor, and is configured to work as the insertion-sheet checker so as to perform the insertion-sheet check (estimating whether a pair of insertion sheets in the sheet path are unordered insertion sheets or ordered insertion sheets, and estimating whether insertion sheets in sheet inserter 21 are unordered insertion sheets or ordered insertion sheets) by using measured images of a pair of insertion sheets in the sheet path, obtained by the inline sensor. Alternatively, built-in controller 11 may be configured to receive the measured image of a media sheet from the inline sensor and perform the check of an image formed on the media sheet, and may be configured to receive the measured images of a pair of insertion sheets in the sheet path from the inline sensor and work as the insertion-sheet checker so as to perform the insertion-sheet check. For another example, sheet ejector 23 in the above description is configured to control sheet ejection. Alternatively, built-in controller 11 may be configured to eject media sheets with non-defective images, into the first ejection path, together with insertion sheets put between the media sheets, and to eject media sheets with defective images into the second ejection path. Built-in controller 11 may also be configured to, on image checker 22 making a determination that an image of one of media sheets output from print processor 20 is defective, confirm the presence of one or more insertion sheets having been put into the sheet path following the media sheet with a defective image, and put the one or more insertion sheets confirmed, into the second ejection path together with the media sheet with the defective. In other words, control sheet inserter 21, image checker 22 and sheet ejector 23 may include respective controllers configured to perform the above-described operations, or alternatively, built-in controller 11 may be configured to control sheet inserter 21, image checker 22 and sheet ejector 23, so as to perform the operations relating to the control of sheet conveyance in image forming apparatus 10, when built-in controller 11 (CPU 12) executes the program for controlling sheet insertion.
Hereinafter, a description is given of operations to control sheet conveyance in image forming apparatus 10 according to the present embodiment in details, with reference to
A description is given of operations to start putting an insertion sheet into the sheet path, after a completion of a determination whether an image formed on one of printed media sheets is defective or not. As illustrated in
Next, a description is given of operations to control the timing of putting insertion sheets into the sheet path in accordance with a result of the insertion-sheet check. As illustrated in
When estimating that insertion sheets 31-1 and 31-2 that passed through image-check position 22a in the sheet path are unordered insertion sheets, image checker 22 (or built-in controller 11) estimates that insertion sheets in insertion tray 21a (in
Next, a description is given of the insertion-sheet check (estimation of the kinds of insertion sheets), with reference to
In an example of
In another example that image checker 22 is configured to read both faces of each insertion sheet 31 (for example, by using inline sensors disposed at both sides of the sheet path), image checker 22 (or built-in controller 11) compares measured images of one face (for example, the bottom face) of insertion sheet 31-1 and one face at the same side (the bottom face) of insertion sheet 31-2 obtained by the inline sensor and further compares measured images of the other face (the upper face) of insertion sheet 31-1 and the other face (the upper face) of insertion sheet 31-2 obtained by the inline sensor, as illustrated in
Image forming apparatus 10 can surely reduce wasteful use of insertion sheets by performing the above-described operations to compare measured images of insertion sheets in the sheet path to perform the estimation of the kinds of insertion sheets (insertion-sheet check) each time when image checker 22 receives an insertion sheet as illustrated in
In an example of
In another example of
In another example, when a comparison of measured images of insertion sheets 31-1 and 31-2 results in the estimation that the compared insertion sheets are unordered insertion sheets, as illustrated in
Image checker 22 (or built-in controller 11) may use various bases for the estimation of the kind insertion sheets. For example, image checker 22 (or built-in controller 11) may perform the estimation on the basis of the whole part of the insertion sheets, or the same and predetermined areas of the insertion sheets. As illustrated in
For another example, image checker 22 (or built-in controller 11) may perform the estimation on the basis of surface profiles of insertion sheets. In the example of
For another example, image checker 22 (or built-in controller 11) may perform the estimation on the basis of colors of insertion sheets. In the example of
As described above, image checker 22 (or built-in controller 11) is configured to define the timing of putting insertion sheets 31 into the sheet path according to a result of the estimation whether insertion sheets in sheet inserter 21 are ordered insertion sheets or unordered insertion sheets. It reduces wasteful use of insertion sheets even if spoilage of printed media sheets occurs in print processing of image forming apparatus 10. However, some operators may hope to avoid a fall of the productivity of image forming apparatus 10 which comes from the operations to perform the estimation of the kind of insertion sheets before causing insertion sheet 31 to start putting an insertion sheet into the sheet path. In view of that, image forming apparatus 10 according to the present embodiment is configured to work in one of operation modes (sheet-insertion modes) by using sheet-insertion-mode determiner 11a (built-in controller 11) so as to prompt an operator to define timing of putting insertion sheets into the sheet path by sheet insertor 21. For example, as illustrated in
Under the condition that the automatic mode is chosen, sheet inserter 21 (or built-in controller 11) refers to a result of the estimation whether insertion sheets in sheet inserter 21 are ordered insertion sheets or unordered insertion sheets, made by the insertion-sheet checker (or built-in controller 11), and starts putting each insertion sheet 31 into the sheet path in accordance with the estimation result, as described above. When finding that insertion sheets in sheet inserter 21 are estimated to be ordered insertion sheets, sheet inserter 21 starts putting each insertion sheet into the sheet path after a completion of the check of an image formed on the media sheet to be followed by the each insertion sheet (the media sheet downstream of the each insertion sheet). When finding that insertion sheets in sheet inserter 21 are estimated to be unordered insertion sheets, sheet inserter 21 starts putting each insertion sheet into the sheet path without waiting for a completion of the check of an image formed on the media sheet to be followed by the each insertion sheet (the media sheet downstream of the each insertion sheet).
Under the condition that the productive mode is chosen, sheet inserter 21 (or built-in controller 11) disregards a result of the estimation whether insertion sheets in sheet inserter 21 are ordered insertion sheets or unordered insertion sheets, made by the insertion-sheet checker (or built-in controller 11), and starts putting each insertion sheet 31 into the sheet path without waiting for a completion of the check of an image formed on the media sheet to be followed by the each insertion sheet (the media sheet downstream of the each insertion sheet).
Under the condition that the quality-first mode is chosen, sheet inserter 21 (or built-in controller 11) disregards a result of the estimation whether insertion sheets in sheet inserter 21 are ordered insertion sheets or unordered insertion sheets, made by the insertion-sheet checker (or built-in controller 11), and starts putting each insertion sheet 31 into the sheet path after a completion of the check of an image formed on the media sheet to be followed by the each insertion sheet (the media sheet downstream of the each insertion sheet).
Next, a description is given of operations to eject printed media sheets 30 and insertion sheets 31, with reference to
When image checker 22 (or built-in controller 11) made a determination that an image formed on media sheet 30-1 is defective in the example of
Hereinafter, a description is given of operations of image forming apparatus 10 according to the present embodiment in details. CPU 32 reads out the program for controlling sheet insertion stored in ROM 33 or storage unit 35, loads the program onto RAM 34, and executes the program, thereby executing the steps of the flowchart illustrated in
In response to receiving an insertion sheet put into the sheet path, image checker 22 or the insertion-sheet checker (or built-in controller 11) uses measured images of a pair of insertion sheets put into the sheet path and performs the insertion-sheet check (estimates whether the pair of insertion sheets are unordered insertion sheets or ordered insertion sheets, and further estimates whether insertion sheets in the sheet inserter are unordered insertion sheets or ordered insertion sheets in accordance with a result of the first estimating) (Step S101). Before putting an insertion sheet into the sheet path, image checker 22 (or built-in controller 11) checks whether the preceding sheet (the sheet positioned downstream of the insertion sheet to be fed into the sheet path) is a printed media sheet or not (Step S102). When insertion sheets in sheet inserter 21 are estimated to be unordered insertion sheets (YES in Step S101), or the preceding sheet is not determined to be a printed media sheet (is determined to be an insertion sheet) (NO in Step S102), the operations jump to Step S105 because there is no need to wait for a completion of the check of an image formed on the preceding sheet with image checker 22. When insertion sheets in sheet inserter 21 are estimated to be ordered insertion sheets (NO in Step S101) and the preceding sheet is determined to be a printed media sheet (YES in Step S102), sheet inserter 21 suspends putting the insertion sheet till the end of the check of the image formed on the media sheet with image checker 22 (or built-in controller 11) (Step S103).
When the check has been completed (YES in Step S103), sheet inserter 21 (or built-in controller 11) refers to the result of the check and confirms whether the check came to the result that the image formed on the preceding media sheet is non-defective (Step S104). When the image of the media sheet was determined to be defective (NO in Step S104), sheet inserter 21 suspends putting the insertion sheet into the sheet path and sheet ejector 23 puts the checked media sheet with defective image into the second ejection path to eject the sheet into the ejection tray for defective sheets (Step S107), and the operations end.
When the image of the media sheet was determined to be non-defective (YES in Step S104), sheet inserter 21 starts putting the insertion sheet into the sheet path (Step S105). Sheet ejector 23 (or built-in controller 11) then refers to the result of the check and confirms whether the check came to the result that the image formed on the preceding media sheet is non-defective. When finding that the check resulted in that the image is non-defective (YES in Step S106), sheet ejector 23 puts the insertion sheet that had been put into the first sheet path, into the ejection path to eject the insertion sheet into the ejection tray for non-defective sheets (Step S108). When finding that the check resulted in that the image is defective (NO in Step S106), sheet ejector 23 puts the insertion sheet that had been put into the sheet path, into the second ejection path to eject the insertion sheet into the ejection tray for defective sheets (Step S109), and the operations end.
As described above, image forming apparatus 10 is configured to cause sheet inserter 21 to start putting an insertion sheet into the sheet path, after a determination that an image of one of printed media sheets (the preceding media sheet). It reduces wasteful use of insertion sheets and maintains the correct page order of print products. Further, image forming apparatus 10 is configured to define the timing of putting insertion sheets into the sheet path by sheet inserter 21 in accordance with a result of the estimation whether insertion sheets in sheet inserter 21 are unordered insertion sheets or ordered insertion sheets. It minimizes a fall of the productivity of image forming apparatus 10 even if spoilage of sheets occurs in operations of the apparatus.
It should be noted that the present invention should not be limited to the above-described embodiments, and the constitution and operations of the image forming apparatus can be modified appropriately, unless the modification deviates from the intention of the present invention.
For example, the above-described embodiments gave image forming apparatus 10 includes print processor 20, sheet inserter 21, image checker 22 and sheet ejector 23. But alternatively, an image check apparatus including sheet inserter 21 and image checker 22 may be prepared separately from the image forming apparatus 10, so that the image check apparatus can receive printed media sheets and execute the above-described method of controlling sheet insertion in the same manner.
The present invention is applicable to image forming apparatuses equipped with a sheet inserter for inserting insertion sheets between media sheets, methods of controlling sheet insertion in the image forming apparatus, programs for controlling sheet insertion to be executed in the image forming apparatus, and non-transitory computer-readable recording media each storing the program for controlling sheet insertion.
Although embodiments of the present invention have been described and illustrated in detail, it is clearly understood that the same is by way of illustration and example only and not limitation, the scope of the present invention should be interpreted by terms of the appended claims.
| Number | Date | Country | Kind |
|---|---|---|---|
| 2019-005611 | Jan 2019 | JP | national |
