JP2019101270A - Image forming apparatus, control method of image forming apparatus, and program - Google Patents

Abstract

To reduce the occurrence of an error caused by a difference between the information of a sheet attribute registered in an image forming apparatus and an actual sheet attribute.SOLUTION: The image forming apparatus has a first mode for executing a display operation for performing screen display urging the input of sheet information, when it is detected that a sheet is placed on a sheet holding part in a state before a job is started. In the first mode, when it is detected that the sheet is placed on the sheet holding part, after it is detected that the sheet does not exist on the sheet holding part during the execution of the job and the job is interrupted, a paper feeding operation is executed without executing the display operation, to restart the job. In the first mode, when the error relating to the conveyance of the sheet is detected, after the paper feeding operation is executed without executing the display operation and the job is restarted, the display operation is executed (1504).SELECTED DRAWING: Figure 15

Description

  The present invention relates to an image forming apparatus for forming an image on a sheet, a control method of the image forming apparatus, and a program for causing a computer to execute the control method.

  2. Description of the Related Art An image forming apparatus such as a printer, a copying machine, and a multifunction machine feeds sheets held in a sheet holding unit such as a cassette one by one to form an image on the sheet. In the image forming apparatus, information such as the size and type of the sheet held in the sheet holding unit is registered, and the image forming operation is executed based on the information on the registered sheet.

  In Patent Document 1, every time a sheet is set in the manual feed tray, a setting mode for displaying sheet information (size and type) is displayed on the display unit, and even if the sheet is set in the manual feed tray, the setting is made in the display unit. An image forming apparatus is described in which a second mode in which the screen is not displayed is implemented. In this image forming apparatus, even when the first mode is selected, if the manual tray is replenished with paper after the manual tray is exhausted and the job is interrupted during job execution, The sheet information setting screen is not displayed. In this case, sheet information used in the interrupted job is displayed on the display unit, and the user can resume the job only by performing an operation of confirming the display content.

JP, 2015-3476, A

  However, when sheets are depleted during job execution and the sheets are replenished after the job is interrupted, the user may be replenishing sheets having attributes different from those of sheets used before the interruption. In such a case, in the process of forming an image on a supplied sheet, errors such as sheet jamming may occur due to differences in attributes such as the sheet size and type. Then, as in the configuration described in Patent Document 1, in the configuration in which the sheet information setting screen is not always displayed when sheets are supplied during execution of a job, the setting of the sheet information is updated after the error is eliminated. If there is no job, the job may be resumed and errors may occur repeatedly.

  Therefore, the present invention provides an image forming apparatus capable of reducing the occurrence of an error caused by the difference between sheet attribute information registered in the image forming apparatus and an actual sheet attribute, and a control method and program of the image forming apparatus. The purpose is

  An image forming apparatus according to an aspect of the present invention includes a sheet holding unit that holds a sheet, an image forming unit that forms an image on a sheet fed from the sheet holding unit, and a sheet held by the sheet holding unit. Input means capable of inputting information on the attributes of the sheet, display means capable of displaying the information, detection means for detecting the presence or absence of the sheet held in the sheet holding unit, and the sheet held in the sheet holding unit A display operation for causing the display unit to display a screen prompting the user to input information related to the attribute through the input unit, and a job for requesting image formation on a sheet are input to the image forming unit. And a control unit capable of performing a feeding operation of feeding a sheet from the sheet holding unit to form the sheet, and the control unit performs the detection in a state before starting the job. When it is detected by the step that the sheet is placed on the sheet holding unit, a first mode for executing the display operation is implemented, and in the first mode, the sheet holding unit holds the sheet by the detection unit while the job is being executed. After detecting that there is no sheet in the unit and interrupting the job, when the detecting unit detects that the sheet is placed on the sheet holding unit, the feeding operation is performed without executing the display operation. It is possible to resume the job by executing it, and in the first mode, after performing the feeding operation and restarting the job without executing the display operation, the display is performed when an error related to sheet conveyance is detected. Execute the operation.

  In the control method of an image forming apparatus according to another aspect of the present invention, the control unit may input, to the image forming apparatus, information regarding an attribute of a sheet held by a sheet holding unit of the image forming apparatus. A step of displaying a prompting screen on a display means, and the control means feeding the sheet from the sheet holding unit to form an image on the sheet when a job requesting image formation on the sheet is input And a feeding step, and when it is detected that the sheet is placed on the sheet holding unit before the job is started, the display step is executed, and the sheet holding unit is executed while the job is being executed. After detecting that there is no sheet and interrupting the job, when it is detected that the sheet is placed on the sheet holding unit, the feeding step is performed without executing the display step to re-execute the job. It is possible, after resuming the job running the feed process without executing the display process, when detecting an error related to the transport of the sheet, and executes the display process, and wherein the.

  According to the present invention, it is possible to reduce the occurrence of an error caused by the difference between the sheet attribute information registered in the image forming apparatus and the actual sheet attribute.

FIG. 1 is a conceptual view showing a network configuration of an image forming system. FIG. 1 is a block diagram showing a schematic configuration of an information processing apparatus. FIG. 1 is a block diagram showing the configuration of a multifunction peripheral according to the present disclosure. FIG. 2 is a schematic view showing an internal configuration of a multifunction machine. FIG. 2 is a schematic view showing an operation unit of the multifunction machine. The upper view (a) of a manual feed tray and the graph (b) showing the output of a volume sensor, and the relationship between sheet width. FIG. 6 is an image view showing a default setting screen (a), a sheet size setting screen (b) and a sheet type setting screen (c) displayed on an operation unit. FIG. 8 is an image view showing a sheet selection screen (a) displayed on the operation unit, a sheet size setting screen (b) when using the temporary change function, and a sheet type setting screen (c). FIG. 5 is a sequence diagram showing the procedure of print processing. 3 is a flowchart showing a print job processing procedure. FIG. 8 is an image view showing a sheet-free screen displayed on the operation unit. 5 is a flowchart showing the contents of sheet information registration processing. 5 is a flowchart showing the contents of feed determination processing. FIG. 10 is an image view showing a guide width error screen displayed on the operation unit. 5 is a flowchart showing the contents of sheet information registration processing at the time of jam release. FIG. 8 is an image view showing a jam error screen displayed on the operation unit.

  Hereinafter, an image forming apparatus according to the present disclosure will be described with reference to the drawings. The image forming apparatus includes a printer, a copier, a facsimile machine, and a multifunction machine, and forms an image on a sheet used as a recording medium based on image data input from an external device and image data read from an original. Sheets used as recording media include paper such as paper and envelopes, plastic films such as overhead projector sheets (OHTs), and cloth.

  FIG. 1 is a diagram showing a network configuration of an image forming system according to the present embodiment. A multifunction peripheral 103, which is an example of an image forming apparatus, is connected to a personal computer 102, which is an external device, via a network 101 that supports, for example, the TCP / IP protocol. When receiving the image data from the personal computer 102, the multifunction peripheral 103 can print out the sheet placed on the multifunction peripheral 103 or hold the image data for later output. The illustrated configuration is a conceptual view of a general configuration. For example, a plurality of personal computers 102 and multifunction peripherals 103 may be provided.

(Information processing device)
FIG. 2 shows an example of the internal configuration of a general information processing apparatus, and shows the personal computer 102 in FIG. A central processing unit (CPU) 202 performs information processing for overall control of the personal computer 102. A random access memory (RAM) 203 provides a work area for the CPU 202. A read only memory (ROM) 204 stores firmware and the like, and is used as a main storage device of the CPU 202. The auxiliary storage device 205 is a hard disk or the like that stores a control program. The input device 206 is a device such as a mouse or a keyboard that allows the user to perform input operation on the personal computer 102. The image display device 207 is a device such as a liquid crystal display used for the purpose of presenting a message or information to the user. The network I / F 208 can exchange data with other network devices via the network. The main bus 201 connects these respective devices.

(MFP)
FIG. 3 is a block diagram showing a schematic configuration of the multifunction peripheral 103 according to the present embodiment. The controller 325 including the CPU 301 functions as a control unit that controls the operation of the multifunction peripheral 103. The CPU 301 generally controls various devices connected to the system bus 307 in accordance with a control program stored in the ROM 303 or the HDD 304, and also centrally controls various processes performed in the controller 325. A RAM 302 is a system work memory for the CPU 301 to operate, and is also a memory for temporarily storing image data. The ROM 303 stores a boot program of the apparatus. An HDD 304 is a hard disk drive and stores system software and image data. The RAM 302, the ROM 303, and the HDD 304 all correspond to storage units capable of temporarily or permanently storing information used by the image forming apparatus.

  The operation unit I / F 305 is an interface unit for connecting the system bus 307 and the operation unit 321. The operation unit I / F 305 outputs image data to be displayed on the operation unit 321 from the system bus 307 to the reception operation unit 321, and outputs information input from the operation unit 321 to the system bus 307. A network I / F 306 connects the LAN or WAN 324 to the system bus 307, and exchanges data bidirectionally between the controller 325 and other devices.

  An image bus 320 is a transmission path for exchanging image data, and is configured by a PCI bus or IEEE 1394. The scanner image processing unit 312 corrects, processes, and edits image data received from the scanner unit 322 via the scanner I / F 311. The embedded information extraction unit 310 performs processing of detection of a pattern embedded in a background image from image data and extraction of additional information. The compression unit 313 receives image data and compresses the data.

  After decompressing the image data acquired from the image bus 320, the decompressing unit 315 rasterizes it and sends it to the printer image processing unit 317. The printer image processing unit 317 receives the image data sent from the decompression unit 315, and performs image processing on the image data while referring to the attribute data attached to the image data. In addition, the code image data generated by the code image generation unit 316 is combined with the image data as necessary. The code image generation unit 316 generates code image data such as a two-dimensional code image, a barcode image, and an image generated by the information embedding technology. Note that the generation of the code image is performed by executing a program stored in the RAM 302. The image data after image processing is output to the printer unit 323 via the printer I / F 318. The image conversion unit 314 performs predetermined conversion processing such as rotation, color space conversion, binary multi-value conversion, image combination, and thinning on image data. The RIP unit 308 receives intermediate data generated based on PDL code data, and generates bitmap data (multi-value). The generated bitmap data is compressed by the compression unit 309 and sent to the image bus 320.

  Here, “PDL” is an abbreviation of a page description language (Page Description Language) used when an external device issues a print command to an image forming apparatus. The PDL code data includes data of an image to be printed, attributes of a sheet used for printing, and information specifying a feeding stage as a sheet supply source, described in accordance with a PDL format. Sheet attributes refer to sheet characteristics including sheet size and type. With sheet type, classification by the optional feature other than the size of the sheet such as material of sheet (basis weight, presence or absence of surface treatment, material etc), shape (index paper, loose leaf etc) and special purpose (envelope etc) It shall be pointed. Also, RIP is an abbreviation of raster image processor, and converts image data included in intermediate data into raster format.

  The authentication processing unit 319 performs job authentication in addition to user and work group authentication using the user information input from the operation unit 321. It also manages information on authenticated users and workgroups. The finisher unit 326 assembles a plurality of sheets into a bundle of sheets, and performs various processes such as stapling, punching, and sorting on the sheets discharged from the printer unit 323.

  The print job (image forming job) refers to a command input to the controller 325 to cause the multifunction peripheral 103 to execute image formation on a sheet. The print job includes a copy job for forming an image on a sheet based on the image data read by the scanner unit 322 by the user operating a copy button of the operation unit 321 or the like. The print job includes a PDL job that the multifunction peripheral 103 receives in the form of PDL code data from an external device connected via the network 101.

(Printer unit and scanner unit)
FIG. 4 is a longitudinal sectional view showing an internal structure of the multifunction peripheral 103 shown in FIG. As shown in FIG. 4, the multifunction peripheral 103 includes a scanner unit 322, a printer unit 323, a finisher unit 326, and an operation unit 321. The scanner unit 322 and the printer unit 323 are integrally configured, and the finisher unit 326 is configured to be attachable to and detachable from the printer unit 323.

  A document feeder (Auto Document Feeder, ADF) 401 is mounted on the scanner unit 322. The ADF 401 feeds sheets (original sheets) serving as originals placed upward on the original tray one sheet at a time in order from the first page to the left, and moves to a predetermined position on the platen glass 402 through a curved path. Transport The document conveyed to a predetermined position on the platen glass 402 is scanned by the scanner unit 403 moving from the left to the right in the drawing, and the image data is read. When the scanner unit 403 scans a document, the reading surface of the document sheet is irradiated with the light of the lamp of the scanner unit 403, and the reflected light from the document sheet is guided to the lens through the mirror. The light passing through the lens is imaged as an optical image on the imaging surface of the image sensor 404, converted into image data by the image sensor 404, and output. The image data output from the image sensor 404 is subjected to predetermined processing in the scanner image processing unit 312, and then input to the exposure control unit 405 of the printer unit 323 via the printer image processing unit 317 (see FIG. 3). ).

  Next, the operation of the printer unit 323 in the case of forming an image on a sheet will be described. The printer unit 323 includes an electrophotographic image forming unit 400 as an example of an image forming unit that forms an image on a sheet. The exposure control unit 405 of the printer unit 323 modulates and outputs laser light based on a signal (video signal) that is input from the printer image processing unit 317 and that specifies the exposure amount for each pixel. The laser beam is irradiated onto the photosensitive drum 406 by scanning with a polygon mirror (not shown) or the like. As a result, the surface of the photosensitive drum 406, which has been charged in advance, is neutralized, and an electrostatic latent image corresponding to the image data is formed. The electrostatic latent image carried on the photosensitive drum 406 is visualized as a developer image by the developer supplied from the developing device 407.

  At the same time, a sheet as a recording medium is fed from any of the cassettes 408 and 409 or the manual feeding tray 410 which are the feeding stages provided in the printer unit 323. The cassettes 408 and 409 and the manual feed tray 410 are all examples of a sheet holding unit that holds sheets. The leading end (downstream end in the sheet conveying direction) of the sheet fed from any of the feeding stages abuts against the registration roller 411 and is temporarily stopped to correct the skew of the sheet. Thereafter, the sheet is conveyed by the registration roller 411 to the transfer portion between the photosensitive drum 406 and the transfer device 412 at a timing synchronized with the start of the laser light irradiation.

  Next, the developer image borne on the photosensitive drum 406 is transferred onto the sheet by the transfer device 412. The sheet on which the developer image has been transferred is conveyed to the fixing unit 413. The fixing unit 413 includes a pair of rollers (fixing rollers) that nip and convey the sheet, and fixes the developer image on the sheet by applying heat and pressure to the sheet. The sheet having passed through the fixing unit 413 is conveyed toward the flap 415 by the conveyance roller 414, and is guided toward the discharge roller 416 by the flap 415 which is a guide member. Then, the sheet is discharged from the printer unit 323 to the finisher unit 326 through the discharge roller 416. At this time, the sheet is discharged in a posture (face-up state) in which the surface on which the image is formed is directed upward.

  The printer unit 323 can also discharge the sheet to the finisher unit 326 face down. When performing face-down discharge, the posture of the flap 415 is switched so as to guide the sheet having passed through the fixing unit 413 to the reverse conveyance path 417, and the sheet passes through the flap 415 and is reversed by the conveyance rollers 418 and 419. It is transported into 417. The sheet conveyed to the reverse conveyance path 417 is switched back, whereby the front and back of the sheet is reversed. Then, the sheet whose front and back sides are reversed is discharged from the printer unit 323 to the finisher unit 326 through the discharge roller 416.

  Further, in the case of double-sided printing, the sheet on which the image is formed on the first side is guided to the reverse conveyance path 417 by the flap 415 and switched back, and the registration roller 411 is once again switched with the first side and the second side changed. Transported to Then, the developer image is transferred to the second surface of the sheet by the transfer device 412, and after the fixing unit 413 fixes the developer image, the developer image is discharged to the finisher unit 326 through the discharge roller 416.

  In the case of using the fixing unit 413 of the heat fixing method, for example, when the print job for designating thick paper runs out of sheets and the user subsequently refills the thin paper, excessive heat is applied to the thin paper and curling is larger than usual. And may wrap around the fixing roller. When a sheet is wound around the fixing roller, the controller 325 uses a sensor such as a discharge sensor 452 provided near the discharge roller 416 to detect the occurrence of an error related to sheet conveyance such as sheet jamming. For example, when the discharge sensor 452 does not detect a sheet within a predetermined time from the start of sheet feeding, the controller 325 determines that sheet jamming due to winding in the fixing unit 413 has occurred. Further, the multifunction peripheral 103 is provided with a door which can be opened and closed with respect to a housing (apparatus main body) of the printer unit 323, and a door sensor 451 which detects the opening and closing of the door. The discharge sensor corresponds to a sheet detection unit, and the door sensor 451 corresponds to an open / close detection unit capable of detecting an opening / closing operation of a door which is an opening / closing member. When the controller 325 detects a sheet jam error, for example, when the door sensor 451 detects that the door is opened and then closed, the controller 325 determines that the sheet jam is eliminated.

(Finisher department)
The finisher unit 326 has a first punch unit 420 and a staple stacker unit 421, and uses these to perform various processes such as stapling, punching, and sorting on a sheet bundle in which a plurality of sheets are bundled. I do. The first punch unit 420 is a unit for performing a multi-hole punching process. The first punch unit 420 has an inlet conveyance roller 422 for receiving the sheet discharged from the printer unit 323 into the first punch unit 420. The sheet conveyed into the first punch unit 420 is conveyed toward the discharge roller 424 or the conveyance roller 425 by the switching operation of the flap 423. When the sheet is conveyed toward the discharge roller 424 by the flap 423, the sheet passes through the first punch unit 420 and is directly conveyed to the staple stacker unit 421. When the sheet is conveyed toward the conveyance roller 425 by the flap 423, the following multi-hole punching process is performed on the sheet.

  On the downstream side of the conveyance roller 425, a conveyance roller 426, a sensor 427, a punch portion 428 and an abutment plate 429 are provided. The sensor 427 is a sensor for detecting the front end of the sheet. Normally, the abutment plate 429 is located at the position where the sheet conveyance path is opened, is rotated by π / 2 (rad) angle at a predetermined timing, and protrudes into the sheet conveyance path so that the leading end of the sheet abuts. The sheet is positioned at a predetermined position with respect to the punch portion 428 by abutting the front end of the sheet against the abutting plate 429. The punching section 428 performs a multi-hole punching process in which a large number of holes (for example, 30 holes) are formed at the leading end of the sheet positioned by the abutment plate 429. On the downstream side of the abutment plate 429, a plurality of transport rollers 430 to 433 are provided. The sheet subjected to the multi-hole punching process is guided to the discharge roller 424 through the conveyance path constituted by the conveyance rollers 430 to 433.

  The staple stacker unit 421 has an inlet roller 434 for receiving the sheet discharged from the first punch unit 420 into the unit. The sheet conveyed into the staple stacker unit 421 via the inlet roller 434 is guided to the second punching unit 435. The second punching unit 435 is a small number of holes for forming a small number of holes (for example, 2 to 4 holes) in the vicinity of the sheet rear end (upstream end in the sheet conveying direction) when the small number of holes punching process is set. Perform punch processing. Further, the second punching unit 435 passes the sheet and conveys the sheet to the downstream side when the small hole punching process is not set.

  In the second punch unit 435, a sensor 436 for detecting the rear end of the sheet and an abutment plate 437 with which the rear end of the sheet is abutted are provided. When the second punching unit 435 performs the small hole punching process, the transport roller in the second punching unit 435 is reversely rotated at a predetermined timing after the sensor 436 detects the rear end of the sheet. Further, the abutment plate 437 is rotated by π / 2 (rad) and protrudes onto the conveyance path. The sheet is switched back toward the abutment plate 437, and is stopped in a state where the rear end of the sheet abuts on the abutment plate 437. In this manner, with the sheet positioned with respect to the rear end, a small number of holes are made in the rear end of the sheet.

  Thereafter, the sheet is conveyed toward the flap 438 by the conveyance roller. The flap 438 performs a switching operation to direct the sheet to the non-sorting path 439 or the transport roller 440. Here, when the post-processing such as sorting, punching, and stapling is not set, and the sheet is discharged as it is, the sheet is guided to the non-sorting path 439 by the flap 438. The sheet guided to the non-sorting path 439 is discharged to the stack tray 442 by the conveyance roller 441.

  When post-processing such as sorting or stapling is set for the sheet, the sheet is discharged from the printer unit 323 to the finisher unit 326 face down. Then, the sheet carried into the finisher unit 326 is conveyed to the staple stacker unit 421 through the first punch unit 420 and is then guided by the flap 438 to the conveyance roller 440, and is conveyed by the conveyance roller 440 onto the bundle discharge belt 443. Discharged into At this time, a low-friction intermediate processing tray (not shown) is provided parallel to the bundle discharge belt 443 at a position several millimeters higher than the upper surface of the belt, and the sheet is actually discharged onto the intermediate processing tray. Ru. The discharged sheet falls in the lower right direction in the figure with its own weight along the intermediate processing tray. Further, the fan-shaped return roller 444 rotates in the counterclockwise direction in the drawing, and the friction member provided at the outer edge thereof abuts on the sheet. Due to the contact of the friction member, a force that causes the sheet to drop in the lower right direction acts on the sheet, and the end of the sheet is abutted against the stopper plate 445. As a result, alignment in the longitudinal direction (feed direction) is performed on the sheet.

  Further, on the intermediate processing tray, alignment plates 446 positioned on the front side and the rear side in the drawing are provided. Each alignment plate 446 is driven each time a sheet is discharged onto the intermediate processing tray. Thus, the alignment on the sheet on the intermediate processing tray is performed in the lateral direction (the direction orthogonal to the sheet conveyance direction, the sheet width direction). Then, when a predetermined number of sheets are discharged onto the intermediate processing tray and stacked, the bundle discharge belt 443 is driven, and the sheets are discharged to the stack tray 442 or 447.

  When the staple mode is set, a bundle of sheets to be stapled is discharged onto the intermediate processing tray, and the alignment plate 446 aligns the sheets in the lateral direction. Thereafter, the staple unit 448 is driven to staple the sheet bundle, and the stapled sheet bundle is discharged onto the stack tray 442 or 447 by the bundle discharge belt 443.

  Here, the stack trays 442 and 447 are configured to be able to move up and down. Each stack tray 442, 447 is provided with a sensor 449, 450 for detecting the presence or absence of a sheet. Further, the staple unit 448 can select various binding positions such as “corner binding” for binding the back side position of the rear end of the sheet and “double binding” for binding the rear end of the sheet at two positions. The binding position for the sheet is set by the user.

(Operation part)
Subsequently, an operation unit 321 which is a user interface of the multifunction peripheral 103 will be described using the configuration example shown in FIG. In FIG. 5, a start key 501 is a key for receiving a scan start instruction from the scanner unit 322. The clear / stop key 502 has a function of accepting an instruction to delete the job when there is a pending or interrupted job of the apparatus, and an instruction to suspend the job when there is a job being executed. The ten key 503 is configured to be able to input numbers. A user mode key 513 receives an instruction to transition to a user mode screen for setting functions of the multifunction peripheral 103.

  In addition to these keys, the operation unit 321 is provided with a liquid crystal panel 500 for displaying a screen and a touch panel for receiving a touch operation of the user integrally formed. The display panel 500 corresponds to display means capable of displaying a message or the state of the apparatus to the user by screen display. In addition, various physical keys (501, 502, 503, 513) and the touch panel function of the display panel 500 correspond to an input unit that allows the user to input information to the multifunction peripheral 103.

  A function screen area 504 of the display panel 500 displays a screen for performing various settings when using individual functions provided to the multifunction peripheral 103, such as copying and fax transmission. Here, a copy function screen used when executing copy work will be described as an example. The sheet selection key 505 selects a sheet holding unit of the multifunction peripheral 103 or automatically causes the multifunction peripheral 103 to select a sheet holding unit (automatic sheet selection). Set the paper).

  The same magnification key 506 is a key that is designated when printing out (at the same magnification) at the same scale as an original, and when the zoom key 507 is selected, it is possible to designate an arbitrary magnification. The color mode selection key 508 can set a color mode (for example, full color / monochrome selection) at the time of print output. The shortcut keys 509 to 512 are keys that can set various functions of the multifunction peripheral 103. For example, to perform the copy operation with the finishing setting for setting the presence / absence of processing by the finisher unit 326, the two-sided setting for setting double-sided printing / single-sided printing, the density setting for setting the density of the output image, and the optimum setting according to the document type. Document type settings etc. can be performed. The various settings selected in the function screen area 504 are stored in the RAM 302 for each job.

(Manual feed tray)
Subsequently, the manual feed tray 410 provided in the multifunction peripheral 103 will be described. FIG. 6A is a top view of the manual feed tray 410, and the printer unit 323 is located on the left side of the figure. The manual feed tray 410 is different from the cassettes 408 and 409 which can load a large number of frequently used sheets, and can be used as a multipurpose tray which allows a user to manually set various sheets according to the purpose. When execution of a job is started with one or more sheets placed on the manual feed tray 410, the pickup roller 601 separates sheets from the sheet (sheet bundle) one by one and feeds the sheets. Ru.

  In the manual feed tray 410, a sheet presence sensor 604 is provided as a detection unit that detects the presence or absence of a sheet. As the sheet presence sensor 604, for example, it is possible to use a transmission type photoelectric sensor that detects a flag that is swung by being pressed by the sheet and a position of the flag. When a sheet is placed on the manual feed tray 410, the sheet presence sensor 604 is turned on, and an ON signal from the sheet presence sensor 604 is transmitted from the printer unit 323 to the controller 325. In this case, the controller 325 determines that the manual feed tray 410 has a sheet. When no sheet is placed on the manual feed tray 410, the sheet presence sensor 604 is turned off, and the controller 325 determines that there is no sheet on the manual feed tray 410.

  Further, the sheet placed on the manual feed tray 410 is held by the side regulating guides 602 and 603 as regulating plates at both ends of the sheet in the width direction D2. Thus, the sheet position in the width direction is adjusted, and skewing of the sheet when fed by the pickup roller 601 is restricted. Further, the side restriction guides 602 and 603 can correspond to a sheet having an arbitrary width that can be placed on the manual feed tray 410 by sliding in the width direction D2. The sheet width is the sheet length in the width direction D2, which is a direction orthogonal to the sheet feeding direction D1.

  The side regulation guides 602 and 603 are connected to a volume sensor 607 as a size detection unit capable of acquiring information on the sheet size via a link member (not shown). The volume sensor 607 outputs a signal (AD value) corresponding to the position of the side regulating guides 602 and 603 to the controller 325 in conjunction with the operation of the side regulating guides 602 and 603. The controller 325 determines the width of the sheet based on the signal (AD value) input from the volume sensor 607.

  A method of determining the width of the sheet placed on the manual feed tray 410 will be described with reference to FIG. FIG. 6B shows the relationship between the signal (AD value) output from the volume sensor 607 provided on the manual feed tray 410 and the actual guide width. Specifically, the AD value on the horizontal axis is that the volume sensor 607 outputs the change in the electrical resistance according to the position of the side regulating guides 602 and 603 as a 10-bit digital value. The volume sensor 607 is configured to output an AD value which linearly changes with respect to the position of the side restriction guides 602 and 603 in the range of 0x000 to 0x400 in hexadecimal notation. As shown in the graph, AD value “0x320” corresponds to A4R width 210 mm, AD value “0x384” corresponds to B4R width 257 mm, AD value “0x3D4” to A4 width 297 mm It corresponds. Such a relationship is registered in advance in the ROM 303 or the like, and the controller 325 can determine the sheet width based on the AD value output from the volume sensor 607 by referring to it as necessary.

  Although the size detection means capable of detecting the width of the sheet has been described above, the size detection means capable of detecting the sheet length in the feeding direction D1 may be disposed. Further, the detection method is not limited to the volume sensor (variable resistor), and for example, a flag type photoelectric sensor that detects the presence or absence of a sheet at a predetermined position on the tray may be used.

(How to register sheet information)
Next, a method of registering information (hereinafter referred to as “sheet information”) related to the attribute of the sheet placed on the manual feeding tray will be described with reference to FIGS. 7A to 7C. In the present embodiment, the “fixed mode” and the “every-time designation mode” are implemented as two modes in which the registration method of the sheet information for the manual feed tray is different. The user can call and set the default setting screen 700 of FIG. 7A to select which of the fixed mode and the designated mode each time. In the present embodiment, it is assumed that the fixed mode and the designated mode can be selected each time only for the manual feed tray among the feed stages provided in the multifunction peripheral 103.

  In the fixed mode, when a sheet is placed on the manual feed tray, the size and type of the sheet currently placed are registered using the sheet information registered by the user in advance and stored in the RAM 302 or the like. Be done. In the designation mode every time, in principle, the sheet information setting screen is displayed each time a sheet is placed on the manual feed tray, and the size and type of the sheet currently placed are registered based on the user's operation. . The controller 325 determines whether or not the sheet can be fed from the manual feed tray at the time of execution of the print job based on the registered sheet size and type (a feed determination process described later).

  Hereinafter, the sheet information registered in the fixed mode is set as the “default value”, and is registered when the sheet is placed on the feeding stage of the multifunction machine 103, and the sheet information used in the feeding determination process is registered. We distinguish as "value". The default value of sheet information in the fixed mode is stored in a storage area (for example, the RAM 302 of the controller 325) different from the registered value of the sheet information. The registration value of the sheet information for each feeding stage is held in the MFP 103 by a method such as storing in a storage device provided in the RAM 302, for example, and updated appropriately when the sheet is placed on each feeding stage. Be done. Although the “default value” and the “registered value” have been described as being stored in the RAM 302, they may be stored in the HDD 304 or the ROM 303. If the “default value” and the “registration value” are distinguished and stored, the storage location is not limited.

  The default setting screen 700 is displayed when “default setting of the manual feed tray” is selected on the user mode screen displayed when the user mode key 513 of the operation unit 321 is pressed. A plurality of items for performing various settings of the MFP 103 exist in the user mode screen, and the user mode screen is configured to transition to a setting screen corresponding to the selected item. The user mode screen may be displayed grouped and hierarchized for each related item.

  When the fixed mode button 701 is selected on the default setting screen 700 for the manual feeding tray, the controller 325 operates as the fixed mode. By pressing the registration button 705 in the default setting screen 700, the user can change the default value of sheet information in the fixed mode. Even if the user has never operated the registration button 705, it is assumed that the default value of the sheet information is registered as the initial setting. When the registration button 705 is pressed, the operation unit 321 displays a sheet size setting screen 710 shown in FIG. 7B. The user selects one of the paper size setting buttons 711 and presses the next button 712. Then, a sheet type setting screen 720 shown in FIG. 7C is displayed. The user selects one of the sheet type setting button group 721 and presses the OK button 722. As a result, the selected sheet size and type are registered as default settings for the manual feed tray in the fixed mode.

  On the other hand, when the designation mode button 702 is selected each time on the default setting screen 700 (FIG. 7A) of the manual feeding tray, the controller 325 operates in the designation mode every time. When the OK button 722 is pressed with the designation mode button 702 selected each time, the setting screens 710 and 720 in FIGS. 7B and 7C are not displayed, and the default setting screen 700 is closed. Instead, the controller 325 causes the operation unit 321 to display setting screens 710 and 720, which are screens prompting setting of sheet information, every time a sheet is placed on the manual feed tray. Then, when the user selects the sheet size and type in the same procedure as the operation of the setting screen 710 and 720 in the fixed mode, the controller 325 registers the selected size and type as the sheet information of the manual feed tray. In addition, as a screen prompting setting of sheet information, “Please check the size and type of sheet” may be displayed.

  That is, in principle, the controller 325 according to the present embodiment is provided with the designation mode, which corresponds to the first mode in which the setting screen of the sheet information is displayed each time a sheet is placed on the manual feed tray. In addition, the controller 325 does not display the sheet information setting screen even if a sheet is placed on the manual feed tray, and is fixed to a second mode in which a print job can be executed using sheet information registered in advance. Mode is implemented.

  By enabling selection of such a plurality of registration methods, the user can customize the multifunction peripheral 103 according to the main usage method. For example, when it is determined that one sheet is fed using the manual feed tray, the sheet information setting operation at the time of executing each print job is omitted by selecting the fixed mode. It is possible to On the other hand, when feeding a different sheet each time using the manual feed tray, by selecting the designation mode each time, the user who submits the print job the appropriate sheet information corresponding to the loaded sheet be registered. For this reason, compared to the case where sheet information is automatically registered in the fixed mode, a situation in which the registered value of the sheet information does not match the attribute of the actual sheet is less likely to occur.

  Note that it is not necessary to present all the sizes and all types of options supported by the MFP 103 on the sheet information setting screen displayed each time in the designation mode, and some frequently used sizes and types are displayed preferentially You may Further, even in the fixed mode, it is possible to register a value different from the default value as the registered value of the sheet information by using the temporary change function described later.

(Temporary change of sheet information in fixed mode)
In the fixed mode, there may be a case where it is desired to temporarily change the registered value of the sheet information. In such a case, for example, by selecting the paper selection key 505 on the copy function screen (see FIG. 5) and calling up the paper selection screen 800 shown in FIG. It becomes possible to register information.

  When one of the manual feed tray selection button 801 and the cassette selection buttons 802 and 803 is selected on the sheet selection screen 800, it is possible to specify a sheet feeding stage to be used as a sheet supply source. When temporarily changing the sheet information of the manual feed tray, the user operates the temporary change button 806. The temporary change button 806 can be pressed only when the sheet is placed on the manual feed tray.

  When the temporary change button 806 is pressed, the operation unit 321 displays a sheet size setting screen 810 shown in FIG. 8B. The user selects one of the paper size setting buttons 811 and presses the next button 812. Then, a sheet type setting screen 820 shown in FIG. 8C is displayed. The user selects one of the sheet type setting button group 821 and presses the OK button 822. Thus, information on the sheet size and type in the fixed mode is set. The controller 325 registers the set information as the sheet information of the sheet currently placed on the manual feed tray.

(Communication sequence in printing process)
Next, a process (print process) for causing the printer unit 323 to form an image on a sheet when the controller 325 executes a print job will be described. FIG. 9 is a sequence diagram showing the contents of communication between the controller 325 and the printer unit 323 when the controller 325 performs printing processing. The controller 325 issues a print preparation request 901 to the printer unit 323 before starting print processing for the first page. The printer unit 323 having received the print preparation request performs preparation operations (pre-print processing) necessary for image formation, such as temperature control of the fixing unit 413 and pre-rotation (processing for rotating the photosensitive drum to adjust the surface condition). Start.

  After the pre-printing process is completed, the printer unit 323 issues a print preparation status 902 to the controller 325. The controller 325 that has received the print preparation status 902 issues a feeding execution request 903 requesting the sheet feeding to the printer unit 323. At this time, the controller 325 notifies the printer unit 323 of information specifying which one of the feeding stages (the cassettes 408 and 409 and the manual feeding tray 410) the printer unit 323 has to feed a sheet. .

  The printer unit 323 having received the feed execution request 903 starts sheet feeding, and a sensor provided in the sheet feeding path detects the trailing end of the sheet fed from the designated feeding stage. , Issues a feed result status 904 to the controller 325. Note that if there is no sheet in the designated feeding stage, the printer unit 323 notifies the controller 325 of an error (a sheet absence error) in the feeding result status 904. The printer unit 323 also notifies the controller 325 of an error when an error such as a sheet jam (jam) is detected in the process of feeding a sheet from the designated feeding stage.

  After the sheet feeding starts, when the sheet reaches a predetermined position, the printer unit 323 issues a print start permission (print start preparation completion 905) to the controller 325. The controller 325 that has received the print start permission from the printer unit 323 issues a print execution request 906 to the printer unit 323 when the image formation is actually possible, and requests the formation and fixing of the image on the sheet. Do. In addition, hardware signal synchronization of image data (IMAGE) is performed between the controller 325 and the printer unit 323. That is, the video signal is transmitted from the printer image processing unit 317 to the exposure control unit 405 in synchronization with the clock signal transmitted from the printer unit 323 to the controller 325. Further, the sheet conveyance operation by the printer unit 323 is controlled such that the sheet is fed to the transfer portion in accordance with the timing when the developer image formed on the photosensitive drum 1 reaches the facing position of the transfer device 412. Thereby, the image is transferred to the sheet, and the fixing unit 413 further performs fixing.

  When image formation is performed on the sheet, the printer unit 323 issues a print result status 907 to the controller 325. In detail, in the case of single-sided printing, the print result status 907 is issued at the timing when the sheets are stacked on the stack tray 442, 447, and in the case of double-sided printing, the image formation on each side is completed. When an abnormality such as a sheet jam occurs, the printer unit 323 notifies the controller 325 of an error in the printing result status 907. If image formation is completed for all pages designated by the print job and the sheets are stacked on the stack trays 442 and 447 and there is no subsequent output image, the controller 325 sends a print end notification 908 to the printer unit 323. Issue Thus, the communication sequence of the printing process ends.

(Display control of sheet information setting screen)
Here, the case where the sheet information setting screen (FIGS. 7B and 7C) is displayed in the designation mode every time will be described. The following three are conceivable as a state of transition from a state in which a sheet is not placed on the manual feeding tray to a state in which a sheet is newly placed.
Case (1) When a sheet is placed in a state in which the MFP 103 is waiting for a print job to be input Case (2) A print job is input to the MFP 103 in a state where no sheet is placed, 1 When a no-sheet error occurs and the sheet is loaded before the second sheet is fed Case (3) The no-sheet error occurs and the job is interrupted after the MFP 103 starts printing , When the sheet is placed (supplemented)

  In the present embodiment, in Case (1), a setting screen of sheet information is displayed on the operation unit 321, and the sheet information is registered based on the user's operation. In case (2), no sheet is fed and there is no information for estimating the attribute of the sheet to be stacked thereafter, and the sheet information setting screen is displayed on the operation unit 321 as in case (1). Needs to be displayed. In case (3), the print job execution is interrupted after at least one sheet is fed, and it is highly probable that the user sets a sheet having the same attribute as the sheet used before the interruption. . Therefore, in the case (3), it is possible to omit the display of the sheet information setting screen. By enabling resumption of the print job without displaying the sheet information setting screen, usability can be improved by reducing the burden of requiring an operation of setting sheet information each time a sheet absence error occurs. It is.

  However, even in the case (3), it is conceivable to place a sheet having an attribute different from that of the sheet used by the user before the interruption of the job on the manual feed tray. For example, there may be a case where the user sets a sheet without noticing that the sheet has a different basis weight from that before the interruption. It is also conceivable that the user intentionally places a sheet having an attribute different from that before the interruption. For example, after the user recognizes that the number of sheets of a desired size is insufficient, a part of the number of copies may be printed using a sheet of a desired size, and the rest of the number of copies may be printed using a sheet of another size. . In addition, there is also a case where it is desired to print on different types of sheets, such as printing on a low quality sheet as a test print, and printing the rest on a high quality sheet.

  In such a case, the sheet jammed due to the difference between the registered value of the sheet information recognized as the attribute of the sheet placed on the manual feed tray by the MFP 103 and the attribute of the sheet actually placed. (Jam error) may occur. For example, if the basis weight of the newly replenished sheet is different from the sheet used before the interruption, the above-mentioned sticking to the fixing roller may occur. In addition, when the size of the newly supplied sheet is different from the sheet used before the interruption, the sheets collide with each other during the conveyance, or the sheet is conveyed compared to the time expected from the registered value of the sheet information. The time required may become long and it may be determined that the sheet is jammed. Then, even if the user performs an operation to eliminate a jam error, the user prints without recognizing that a jam error has occurred because a sheet having an attribute different from that before the interruption of the job is placed. If you continue, the same kind of error will occur repeatedly.

  From such knowledge, in the present embodiment, if a jam error occurs after sheets are supplied in the case (3) and the print job is resumed, the sheet information setting screen is displayed even while the print job is suspended. I decided to display it. As a result, the user is presented with the possibility that the sheet having an attribute different from that before the interruption is the cause of the jam error, and the user is required to reset the sheet information, so that the error occurs repeatedly. You can prevent.

  In the case where the display of the sheet information setting screens 710 and 720 is omitted in case (3), in the present embodiment, the guide width of the side regulation guide and the sheet size required by the interrupted job are matched. According to the conditions, the print job is automatically resumed. If there is consistency between the guide width and the sheet size, there is a high possibility that the sheet with the same attributes as the one before the interruption is placed, so the print job is automatically resumed without asking for the confirmation operation by the user. Can improve usability. On the other hand, when the guide width and the sheet size requested by the interrupted job do not match, the sheet information setting screens 710 and 720 are displayed on the operation unit 321, and the user is prompted to reset the sheet information.

In summary, in the present embodiment, the display of the sheet information setting screens 710 and 720 (FIGS. 7B and 7C) in the designation mode each time is controlled as follows.
Case (1) When a sheet is placed in a state in which the multifunction machine 103 is waiting for a print job to be input ... Displayed (2) A print job in the multifunction machine 103 with no sheet placed Is inserted, and a sheet absence error occurs before the first sheet is fed, and the sheet is placed... Display Case (3) Sheet after the MFP 103 starts printing None When an error occurs and the job is interrupted and the sheet is placed (supplemented) (3-1) When the guide width and the sheet size required by the job are consistent ... Not displayed (3-2) Guide When the width and the sheet size requested by the job do not match ... displayed Case (4) When a jam error occurs after starting feeding of the sheet supplied in case (3-1) ... displayed

(Processing of print job)
Hereinafter, a configuration example of a control method for realizing such control will be specifically described. First, the flow of processing the print job by the controller 325 will be described along the flowchart of FIG. Each step of this flowchart and flowcharts to be described later (FIG. 12, FIG. 13, FIG. 15) is realized by the CPU 301 of the MFP 103 reading out and executing a program stored in the ROM 303 or the HDD 304.

  First, in step 1001, the controller 325 determines whether a print execution instruction has been received, and if not received, the controller 325 stands by. The print execution instruction is a signal instructing execution of a print job. In the case of a copy job, in response to a copy start instruction received from the operation unit 321, the scanner unit 322 reads an original, and when a video signal is received by the controller 325 as image data, the controller 325 determines that a print execution instruction is received. Do. In the case of a PDL job, for example, when a signal for instructing printing hold (retention) is included, when the hold is released by the operation of the operation unit 321, and when such a signal is not included, the PDL When a job is received, it is determined that a print execution instruction has been issued.

  If it is determined that a print execution instruction has been issued, the controller 325 sets OFF as an initial value of the automatic registration flag in step 1002. The automatic registration flag is a flag indicating that the sheet information of the sheet placed on the manual feed tray is automatically registered without the user's hand. The automatic registration flag is information individually held for each print job, and is stored, for example, in the RAM 302. Also, in the manual feed sheet information registration process (FIG. 12) described later, the sheet information of the manual feed tray is automatically turned on without being input by the user (step 1224).

  At step 1003 (feed process), the controller 325 issues a feed execution request 903 to the printer unit 323. At this time, the controller 325 notifies the printer unit 323 from which feed stage the sheet is to be fed. When the print job is first executed from the standby state, the controller 325 issues the print preparation request 901 before the feed execution request 903 and receives the print preparation status from the printer unit 323 as needed. It is assumed that At step 1004, the controller 325 receives the feeding result status 904 from the printer unit 323. In step 1005, the controller 325 determines whether the received feeding result status 904 is a no-sheet error.

  If it is determined in step 1005 that the error is not a sheet absence error, the controller 325 executes printing processing in step 1006. That is, the controller 325 issues a print execution request 906 to the printer unit 323 and transmits a video signal to the printer unit 323 to form an image on a sheet. Thereafter, the controller waits for the notification of the printing result status 907 from the printer unit 323, and determines whether the printing process has ended normally. When a jam error is notified by the printing result status 907, the below-described process (steps 1020 to 1026) including the jam release sheet information registration process is executed. If it is determined in step 1017 that the printing process has ended normally, the controller 325 confirms in step 1018 whether the next page exists in the print job. If the next page exists, the process returns to step 1003 and the job is performed. To continue. If it is determined in step 1018 that the next page does not exist, the controller 325 ends the print job processing.

  If it is determined in step 1005 that there is no sheet error, the controller 325 causes the operation unit 321 to display a sheet out screen in step 1007, and waits for an event in step 1008. The event to wait at step 1008 is an operation event for the no-sheet screen and a sheet replenishment detection event indicating that the sheet has been replenished to the sheet feeding stage designated as the sheet supply source.

  As shown in FIG. 11, the no-sheet screen 1100 is a screen for notifying the user that there is no sheet at the designated feeding stage and urging the user to supply sheets. In the sheet absence screen 1100, by selecting one of the manual feeding trays 410 or feeding stage selection buttons 1101, 1102 and 1103 representing the cassettes 408 and 409 and pressing the OK button 1004, from the designated feeding stage The sheet can be forcibly fed. Further, by pressing the cancel button 1105 on the no-sheet screen 1100, it is possible to cancel the job interrupted due to the no-sheet error.

  When the controller 325 receives an event, the controller 325 determines in step 1009 of FIG. 10 whether the received event is an operation unit event. In the case of an operation unit event, in step 1010, the controller 325 determines whether the received operation unit event is a forced feed request (OK button 1104) or a cancellation request (cancel button 1105). In the case of a forcible feed request, the controller 325 issues a feed execution request 903 of the interrupted job due to a sheet absence error to the printer unit 323 in step 1011, and returns to the process of step 1003. At this time, the controller 325 notifies the printer unit 323 of which feed stage to feed the sheet in accordance with the selection result of the feed stage selection buttons 1101 to 1103 in the sheet absence screen. If it is determined in step 1010 that a job cancellation request has been made, in step 1012, the controller 325 requests the printer unit 323 to cancel the interrupted job due to a no-sheet error, and the process ends.

  If it is determined in step 1009 that the operation unit event is not detected, the controller 325 determines whether the received event is sheet supply detection, and if it is determined that sheet supply detection is not detected, the process returns to step 1008 and waits for the event again. Do. If it is determined in step 1013 that sheet supply detection has been performed, then in step 1014, the controller 325 performs manual feed sheet information registration processing (FIG. 12) described later. In the manual feed sheet information registration process, the registration value of the sheet information of the manual feed sheet is updated according to the mode (the designation mode or the fixed mode) set for the manual feed tray.

  At step 1015, the controller 325 carries out a later-described feed determination process (FIG. 13). In the feeding determination process, the controller 325 starts feeding a sheet from any feeding stage, or notifies the user via the operation unit 321 that feeding of the sheet is impossible. In step 1016, the controller 325 determines whether sheet feeding has been resumed, and if it is determined that the sheet feeding has not been resumed, the process returns to step 1008 and waits for an event again. If it is determined in step 1016 that the no-sheet interruption job has been resumed, the process advances to step 1006 to execute printing processing.

  The processing in the case where it is determined in step 1017 that a jam error has occurred will be described below. At step 1019, the controller 325 causes the operation unit 321 to display a jam error screen. As shown in FIG. 16, the jam error screen 1600 is used to notify the user that a sheet jam has occurred and to present information such as a sheet jam release procedure. The user can cancel the print job by operating the cancel button 1601 as well as removing the jammed sheet in accordance with the displayed information.

  After displaying the jam error screen, the controller 325 waits for an event at step 1020. The event to wait here is an operation of the stop button 1601 on the jam error screen or a detection signal of the door sensor 451 indicating that the jam error release operation has been performed. When the controller 325 receives an event, in step 1021 the controller 325 determines whether the received event is a job cancellation of the operation unit event. In the case of job cancellation, in step 1012, the controller 325 sends a job cancellation request to the printer unit 323, and ends the processing.

  If it is determined in step 1021 that the received event is not job cancellation, in step 1022 the controller 325 determines whether the received event is a jam release event. If not, the controller 325 returns to step 1020 to wait for an event. At the jam clearing event, the controller 325 determines in step 1023 whether the automatic registration flag is ON. When the automatic registration flag is ON, it means that the registration value of the sheet information of the manual feed tray is automatically registered without the user's hand. In this case, in step 1024, the controller 325 performs sheet information registration processing (FIG. 15) at the time of jam release described later. In the sheet information registration process at the time of jam release, the sheet information setting screen (FIGS. 7B and 7C) is displayed on the operation unit 321, and the sheet information of the manual feed tray is registered based on the user's input operation. The value is updated.

  When the sheet information registration process at the time of jam release is completed, the controller 325 changes the automatic registration flag to OFF in step 1025. Then, in step 1026, the controller 325 performs a later-described feed determination process (FIG. 13), and repeats the process from step 1003 onward according to the result of the feed determination process. When the automatic registration flag is OFF in step 1023, it means that the registered value of the sheet information of the manual feed tray is registered by the user's hand. In this case, the controller 325 executes the feed determination process 1026 without executing the sheet information registration process at the time of jam release.

(Manual feed sheet information registration process)
Next, manual sheet information registration processing, which is processing for registering sheet information of the manual feed tray, will be described. In the manual feed sheet information registration process, when a sheet is supplied to the manual feed tray in a state where a no-sheet error occurs (step 1014 in FIG. 10), and in the standby state in which the print job is on standby, It is executed when the sheet is replenished.

  First, in step 1201, the controller 325 confirms whether there is a sheet in the manual feed tray, and if it does not exist, the processing is ended. If there is a sheet in the manual feed tray, the controller 325 determines in step 1202 which of the fixed mode and the designation mode is set for the manual feed tray.

1. Every Time Designation Mode If it is determined that the specification mode is every time in step 1202, the controller 325 checks in step 1203 whether there is a interrupted job (a no-sheet interrupted job) because there is no sheet in the manual feed tray.

  If it is determined in step 1203 that a no-sheet interrupted job exists (case (2) or (3) above), the controller 325 acquires sheet information designated by the no-sheet interrupted job in step 1204. In step 1205, the controller 325 determines whether the sheet size of the acquired sheet information matches the sheet size information detected by the size detection unit. That is, the guide widths of the side regulating guides 602 and 603 are acquired based on the detection result (AD value) of the volume sensor 607 (see FIGS. 6A and 6B), and the sheet size width acquired in step 1204 is obtained. Determine if they match.

  When the guide width and the sheet size designated by the job are aligned (case (3-1)), the controller 325 determines that the same sheet as the sheet before interruption is set. In this case, in step 1206, the controller 325 registers the sheet size and type designated by the job as sheet information of the manual feed tray. Then, in step 1224, the controller 325 sets the automatic registration flag of the sheet information to ON, and ends the processing. As a result, it is stored in the storage unit such as the RAM 302 that the registration value of the sheet information of the current manual feed tray is automatically registered without the user's hand.

  If it is determined in step 1203 that the no sheet interruption job does not exist (case (1)), the controller 325 causes the operation unit 321 to display a sheet information setting screen in step 1207 (display step). Also, if it is determined in step 1205 that the guide width and the sheet size designated by the job do not match (case (3-2)), the controller 325 causes the operation unit 321 to display a sheet information setting screen. In these cases, the controller 325 performs a display operation for displaying the setting screen 710 and the setting screen 720 of FIGS. 7B and 7C on the operation unit 321, and is in a state of accepting the user's screen operation. At step 1208, controller 325 waits for user input. When the operation unit 321 detects an input from the user in step 1209, the controller 325 receives a signal from the operation unit 321 that notifies the input sheet size and sheet type. If it is determined in step 1209 that the controller 325 has not received an input signal of sheet information, the controller 325 returns to step 1208 and waits for the user's input operation.

  In step 1210, the controller 325 determines whether the sheet size information input by the user matches the sheet size information detected by the size detection unit. If the alignment between the guide width and the sheet size can be confirmed in step 1210, the controller 325 registers the size and type of the sheet received from the operation unit 321 as sheet information of the manual feed tray in step 1212, and ends the process. . If it is determined in step 1210 that the guide width and the sheet size do not match, the operation unit 321 displays the guide width error screen (FIG. 14) in step 1211, and then returns to the process of step 1208 and the sheet size and type by the user Wait for the re-input of.

  As shown in FIG. 14, the guide width error screen 1400 notifies the user that the attribute of the sheet designated by the print job may be different from the attribute of the sheet actually placed on the manual feed tray. Warning screen. The guide width error screen 1400 notifies that the width of the sheet size designated by the print job and the guide widths of the side restriction guides 602 and 603 do not match, and includes a message 1401 prompting resetting of the sheet information.

2. Fixing Mode If it is determined in step 1202 that the fixing mode is selected, then in step 1213, the controller 325 checks whether there is a no-sheet interruption job for the manual feed tray 410.

  If it is determined in step 1213 that there is no sheetless interruption job, in step 1214, the controller 325 acquires a default value of sheet information in the fixed mode. In step 1215, the controller 325 determines whether the sheet width of the default value of the sheet information acquired in step 1214 matches the guide widths of the side restriction guides 602 and 603 acquired based on the detection result of the volume sensor 607. If they match, in step 1216, the controller 325 registers the sheet information of the manual feed tray based on the sheet information acquired in step 1214. On the other hand, if it is determined in step 1215 that the guide width does not match the sheet width of the default value of the sheet information, the controller 325 causes the operation unit 321 to display a guide width error screen (FIG. 14) in step 1217 and ends the processing. .

  If it is determined in step 1213 that a no-sheet interrupted job exists, the controller 325 acquires the size and type of sheets requested by the no-sheet interrupted job stored in the RAM 302 in step 1218. In step 1219, the controller 325 determines whether the width of the sheet size acquired in step 1218 matches the guide width of the side restriction guides 602 and 603 acquired based on the detection result of the volume sensor 607. If they match, in step 1220, the controller 325 determines that the same sheet as the sheet before interruption is set, and registers the size and type of the sheet acquired in step 1218 as the sheet information of the manual feed tray.

  On the other hand, if it is determined in step 1219 that the guide width does not match the sheet size width requested by the no-sheet interruption job, the controller 325 determines that a sheet having an attribute different from that of the sheet before interruption may have been set. Do. In this case, the controller 325 determines in step 1221 whether or not the no-sheet interruption job can be rotated. Whether or not the sheetless interrupted job can be rotated is whether printing can be performed with the print image rotated 90 degrees in the sheet conveyance direction in the printer unit 323 (long side feed and short side feed Point to whether it can convert For example, when a large sheet size is specified such that the sheet can not be conveyed when it is rotated, it is determined that the rotation is not possible. The rotation determination is performed by the printer image processing unit 317 with reference to the received image data and attribute data attached to the image data.

  When the guide width of the side regulation guides 602 and 603 matches the sheet size after rotation, it may be considered that the user has placed the same sheet as the sheet used before the interruption in a direction different from that before the interruption by 90 degrees. it can. Therefore, in order to minimize the setting operation of the sheet information as much as possible, the no-sheet interrupt job can be rotated, and when the guide width matches the sheet size after rotation, the print image is rotated by 90 degrees. I will let you continue printing. Specifically, in step 1222, the guide width acquired based on the detection result of the volume sensor 607 matches the sheet size width obtained by rotating the sheet size designated by the interrupted job acquired in step 1218 by 90 degrees. Determine if If they match, in step 1223 the controller 325 registers the sheet size obtained by rotating the sheet size designated by the interrupted job by 90 degrees and the sheet type designated by the interrupted job as the sheet information of the manual feed tray. , End the process.

  If it is determined in step 1221 that rotation of the image data is not possible, or if the guide width does not match the sheet size after rotation in step 1222, the controller 325 proceeds to step 1214. In this case, as described above, it is determined whether the guide widths of the side restriction guides 602 and 603 match the sheet size as the default value of the sheet information (step 1215). Then, the sheet information is registered using the default value in the case of matching (step 1216), and the guide width error screen (FIG. 14) is displayed in the case of not matching, and the processing is ended.

(Feeding judgment processing)
Next, a feeding determination process of determining whether to feed a sheet from a feeding stage designated by a print job will be described with reference to the flowchart of FIG. This feed determination process is executed when the controller 325 detects the release of an error after the occurrence of a no-sheet error or a jam error (steps 1015 and 1026 in FIG. 10).

  First, in step S1301, the controller 325 determines whether a sheet is supplied to a feeding stage (hereinafter referred to as feeding stage A) designated in the interrupted print job. When the sheet is supplied to the feeding stage A, the controller 325 stores the sheet size and type designated by the interrupted job and the sheet information about the feeding stage A in steps 1302 and 1303. Judge whether the registered value of matches. If both the sheet size and the type match, in step 1304 (feeding step), the controller 325 issues a feeding execution request 903 to feed the sheet from the feeding stage A to the printer unit 323, thereby printing Resume job execution. Thus, the feeding operation for feeding the sheet from the feeding stage A is performed, and the printing process (image forming operation) on the fed sheet is performed (step 1005 in FIG. 10).

  On the other hand, if any one of the sheet size and the sheet type does not match in steps 1302 and 1303, the controller 325 ends the process without feeding the sheet from the feeding stage A. In this case, the controller 325 causes the operation unit 321 to display an error screen notifying that, for example, a sheet of a size or type different from the sheet attribute designated by the print job has been replenished. Then, the process waits for an event such as a sheet exchange or job cancel instruction (step 1008 in FIG. 10), and continues processing of the print job according to the contents of the event.

  If it is determined in step 1301 that the sheet has not been supplied to the feeding stage A, the controller 325 determines in step 1305 whether or not the feeding stage A is a target of automatic cassette selection (set to ACC (Auto Cassette Change)). The feed stage to be subjected to the ACC function can be set in advance from the user mode screen, and when processing a print job for which the ACC function is valid, the controller 325 selects the sheet feed source from among the feed stages set as the target. Automatically selects. If it is determined in step 1305 that the feed stage A is not the target of the ACC function, the controller 325 ends the process.

  If it is determined in step 1305 that the feed stage A is the target of the ACC function, then in step 1306 the controller 325 searches for a feed stage having the highest priority among unsearched feed stages (hereinafter referred to as feed Select as stage B). Here, the order of priority defines what is preferentially used as a sheet supply source between the feed stages provided in the multifunction peripheral 103. As an example of the priority order, in order to improve the productivity, it can be considered that the shorter the conveyance route from the feeding stage to the transfer device 412, the higher the priority order. In addition, the cassette is usually prioritized over the manual feed tray because of the occurrence of sheet skewing and the storage capacity. That is, the order of the feeding stages in the printer unit 323 shown in FIG. 4 is the order of the cassette 408, the cassette 409, and the manual feeding tray 410. In the processing of steps 1306 to 1311, it is determined whether the sheet can be fed from the feeding stage in descending order of priority from the feeding stage. If the sheet can not be fed, it is excluded from the search target and the next priority is determined. The process of selecting a high feed stage as a search target is repeated. As a result, among the feeding stages set as the target of the ACC function, a feeding stage capable of feeding a sheet is searched.

  Specifically, at step 1307, the controller 325 checks whether there is an unsearched feed stage (whether the feed stage could be selected at step 1306). If it is determined that there is no unsearched feed stage remaining, the controller 325 ends the processing on the assumption that there is no feed stage that can be fed. If it is determined in step 1307 that a feed stage not searched yet remains, it is determined whether the feed stage B selected in step 1306 is set as the target of the ACC function. When the feed stage B is the target of the ACC function, the controller 325 checks in step 1309 whether a sheet is present at the feed stage B. Further, in steps 1310 and 1311, the controller 325 determines whether the size and type of the sheet designated by the print job and the registered value of the sheet information of the feed stage B match, which are stored in the RAM 302. If all the determinations in these steps 1308 to 1311 are successful, the current feed stage B to be searched is determined as the sheet supply source. In this case, the controller 325 issues a feeding execution request 903 for feeding the sheet from the feeding stage B to the printer unit 323 in step 1312. On the other hand, if any one of the determinations in steps 1308 to 1311 fails, the controller 325 returns to step 1306 to select the next feed stage to be searched.

(Sheet information registration process at the time of jam release)
Next, sheet information registration processing at the time of jam release will be described along the flowchart of FIG. This process is executed when the designation mode is selected each time and the jam error is eliminated with the automatic registration flag ON (step 1024 in FIG. 10).

  First, in step 1501, the controller 325 determines whether a sheet is present in the manual feed tray. If there is a sheet, the controller 325 determines in step 1502 which of the fixed mode and the designation mode is set each time as a method of registering sheet information of the manual feed tray. If it is determined in step 1501 that the sheet does not exist, or if it is determined in step 1502 that the fixing mode is set, the controller 325 ends the process because there is no need to update the sheet information of the manual feed tray.

  If it is determined in step 1502 that the designated mode is selected each time, the controller 325 checks in step 1503 whether there is a job interrupted by a jam error of a sheet fed from the manual feed tray 410 (jam interrupted job). Ends the process. When there is a jam interruption job, the controller 325 performs a display operation to display the sheet information setting screen 710 and the setting screen 720 of FIGS. 7B and 7C on the operation unit 321 in step 1504 (display step). , And the screen operation of the user is accepted. At step 1505, controller 325 waits for user input. When the operation unit 321 detects an input from the user in step 1506, the controller 325 receives a signal from the operation unit 321 that notifies the input sheet size and sheet type. If it is determined in step 1506 that the controller 325 has not received an input signal of sheet information, the controller 325 returns to step 1505 and waits for the user's input operation.

  In step 1507, the controller 325 determines whether the sheet size information input by the user matches the sheet size information detected by the size detection unit. If the alignment between the guide width and the sheet size can be confirmed in step 1507, the controller 325 registers the sheet size and type received from the operation unit 321 as sheet information of the manual feed tray in step 1509, and ends the process. . If it is determined in step 1507 that the guide width and the sheet size do not match, the operation unit 321 displays the guide width error screen (FIG. 14) in step 1508, and then returns to the process of step 1505 to control the sheet size and type by the user. Wait for the re-input of.

(Effect of this embodiment)
As described above, the MFP 103 according to the present exemplary embodiment displays the sheet information setting screen 710 and 720 each time the sheet is placed in a state where the print job is not executed (step 1207 in FIG. 12). The specification mode (first mode) is implemented. Also, in the designation mode every time, when the sheet absence error occurs and the sheet is replenished after the first sheet is fed, the display of the sheet information setting screens 710 and 720 is omitted and the job is resumed. It is possible (step 1505 of FIG. 15). As a result, it is possible to improve usability by reducing the burden of setting the sheet information each time a sheet absence error occurs.

  In such a configuration, when the specification mode is selected each time and the jam error is resolved in a state where the automatic registration flag is ON, the sheet information setting screen on the operation unit 321 (FIGS. 7B and 7C). Is displayed (step 1504 in FIG. 15). In other words, when the sheet information setting screen 710 or 720 is not displayed at the time of elimination of the no-sheet error and the job restarts and a jam error occurs after that (case (4) above), the sheet information is displayed to the user. It is configured to prompt for input. In addition, as a screen prompting the user to set the sheet information, as a display prompting the user to confirm like "Please check the sheet size and type" instead of the setting screen (Fig. 7 (b) and (c)). Also good.

  As a result, even if a jam error has occurred due to the user placing a sheet having a different attribute from that before the interruption, the job resumes with proper sheet information being input, so the jam error Is prevented from occurring repeatedly. On the other hand, the sheet information setting screens 710 and 720 are not displayed except in the case (4) even when the jam error is eliminated by managing the automatic registration flag, so the sheet information is generated each time the jam error occurs. You will not be required to In the present embodiment, after the error screen (FIG. 16) for notifying the jam error is displayed, the sheet information setting screens 710 and 720 are displayed when the jam error is eliminated. Information for which setting is requested may be displayed on the same screen.

  In the present embodiment, when the sheet is placed after the job is interrupted due to a sheet absence error, the sheet information setting screen is displayed in the case (3-2) in which the guide width and the sheet size requested by the job do not match. Was displayed. As a result, when the user places a sheet having a size different from that before the interruption, a sheet information setting screen is displayed, and the print result as desired by the user can be obtained. On the other hand, in the case (3-1) in which the guide width and the sheet size requested by the job match, the job is automatically resumed, and the usability is improved. As a modification, in the case of (3-1), a screen for notifying that the job can be resumed and asking for confirmation of the user is displayed on the operation unit 321, and the sheet information is displayed only when the user explicitly operates. The setting screen may be displayed.

(Other embodiments)
In the above embodiment, it has been described that the MFP 103 has both the designated mode corresponding to the first mode and the fixed mode corresponding to the second mode implemented. However, the present technology is also applicable to an image forming apparatus in which only the first mode is implemented. Further, in addition to the first mode and the second mode, the present invention is also applicable to an image forming apparatus having another mode in which the operation when a sheet is placed on the feeding stage is different.

  The present invention supplies a program that implements one or more functions of the above-described embodiments to a system or apparatus via a network or storage medium, and one or more processors in a computer of the system or apparatus read and execute the program. Can also be realized. It can also be implemented by a circuit (eg, an ASIC) that implements one or more functions.

103 Image forming apparatus (MFP) / 302, 303, 304 Storage unit (ROM, RAM, HDD) / 325 Control means (controller) / 400 Image forming means (image forming unit) / 408, 409, 410 ... sheet holding unit (cassette, manual feed tray) / 451 ... open / close detection means (door sensor) / 452 ... sheet detection means (discharge sensor) / 500 ... display means (display panel) / 501, 502, 503, 513, 500 ... input Means (physical key and touch panel) / 604 ... detection means (sheet presence / absence sensor) / 607 ... size detection means (volume sensor) / 1003 ... feeding process / 1207, 1504 ... display process

Claims (9)

A sheet holding unit that holds a sheet;
An image forming unit configured to form an image on a sheet fed from the sheet holding unit;
An input unit capable of inputting information on the attributes of the sheet held in the sheet holding unit;
Display means capable of displaying information;
A detection unit that detects the presence or absence of a sheet held by the sheet holding unit;
A display operation for causing the display unit to display a screen prompting the user to input information related to the attribute of the sheet held in the sheet holding unit via the input unit, and a job for requesting image formation on the sheet have been input. A control unit capable of executing a feeding operation of feeding a sheet from the sheet holding unit in order to cause the image forming unit to form an image;
The control means
When the detection unit detects that a sheet is placed on the sheet holding unit before the job is started, a first mode for executing the display operation is implemented.
In the first mode, the sheet detecting unit detects that there is no sheet in the sheet holding unit during job execution and interrupts the job, and then the sheet is placed on the sheet holding unit by the detecting unit. When it is detected, it is possible to restart the job by executing the feeding operation without executing the display operation,
In the first mode, after the sheet feeding operation is performed and the job is resumed without executing the display operation, the display operation is performed when an error related to sheet conveyance is detected.
An image forming apparatus characterized by The control means
In the first mode, after the sheet feeding operation is started and the job is resumed without executing the display operation, a screen notifying of the occurrence of an error is displayed on the display means when an error related to sheet conveyance is detected. Thereafter, when it is detected that the error has been eliminated, the display operation is performed in a state where the feeding operation is not performed,
The image forming apparatus according to claim 1, characterized in that: A size detection unit capable of detecting information on the size of the sheet held by the sheet holding unit;
The control means
In the first mode, the sheet detecting unit detects that there is no sheet in the sheet holding unit during job execution and interrupts the job, and then the sheet is placed on the sheet holding unit by the detecting unit. If you detect
When the detection result of the size detection unit does not match the size of a sheet designated by a job, the display operation is performed in a state in which the feeding operation is not performed.
When the detection result of the size detection unit matches the size of a sheet specified by a job, the feeding operation is performed without performing the display operation.
An image forming apparatus according to claim 1 or 2, characterized in that: A storage unit for storing information on attributes of the sheet held by the sheet holding unit;
The control means
When the detection unit detects that a sheet is placed on the sheet holding unit before the job is started, the display operation is not performed and the job is performed using the information stored in the storage unit. A second mode is implemented that allows you to
The image forming apparatus according to any one of claims 1 to 3, characterized in that: A sheet detection unit provided in a conveyance path of a sheet fed from the sheet holding unit and detecting the sheet;
And an opening / closing detection means capable of detecting the opening / closing operation of the opening / closing member provided openably / closably with respect to the apparatus main body,
The control means
Detecting an error related to sheet conveyance based on a detection result of the sheet detection unit;
After the occurrence of an error relating to the conveyance of the sheet, when the open / close detection unit detects that the open / close member is opened and then closed, the cancellation of the error is detected.
The image forming apparatus according to any one of claims 1 to 4, characterized in that: The sheet holding unit is a manual feed tray capable of manually setting sheets.
The image forming apparatus according to any one of claims 1 to 5, characterized in that: The screen, which is displayed in the display operation and prompts the user to input information on the attribute of the sheet held in the sheet holding unit via the input unit, is a sheet information setting screen.
The image forming apparatus according to any one of claims 1 to 6, characterized in that: A control method of the image forming apparatus,
A display step of causing the display unit to display a screen for prompting the image forming apparatus to input information related to the attribute of the sheet held by the sheet holding unit of the image forming apparatus;
The control unit includes a feeding step of feeding the sheet from the sheet holding unit to form an image on a sheet when a job requesting image formation on the sheet is input;
When it is detected that the sheet is placed on the sheet holding unit before the job is started, the display process is performed,
After interrupting the job after detecting that there is no sheet in the sheet holding unit while the job is being executed, if it is detected that a sheet has been placed on the sheet holding unit, the display step is not performed. The job can be resumed by executing the feeding process.
The printing process is performed when an error related to sheet conveyance is detected after the feeding process is performed to restart the job without executing the displaying process.
And controlling the image forming apparatus. The program for making a computer perform each process of the control method of the image forming apparatus of Claim 8.

Images