JP2019206089A - Image formation apparatus - Google Patents

Abstract

To shorten the time of operating an image formation apparatus in a first feeding mode.SOLUTION: An image formation apparatus 101 can be operated in a first feeding mode of causing a recording medium feeding part 208 to start feeding of a recording medium after it is determined that a slip sheet is in a slip sheet feeding part 213 on the basis of the detection result of slip sheet detection means 221 when the slip sheet is loaded immediately before the recording medium to be fed by the recording medium feeding part, and a second feeding mode of causing the recording medium feeding part to start feeding of the recording medium regardless of the detection result of the slip sheet detection means. A control part 201 stores information indicating that there is the jam of the slip sheet in a storage part when the jam of the slip sheet occurs during a slip sheet insertion job. The control part operates the image formation apparatus in the second feeding mode and determines whether or not to operate the image formation apparatus in the first feeding mode on the basis of the information indicating that there is the jam of the slip sheet stored in the storage part.SELECTED DRAWING: Figure 7

Description

  The present invention relates to an image forming apparatus having an insert function.

  2. Description of the Related Art Conventionally, a printer (hereinafter referred to as an image forming apparatus main body) corresponding to a finisher (hereinafter referred to as a post-processing apparatus) that performs finishing (hereinafter referred to as post-processing) such as stapling or punching is known. A sheet on which an image is formed by the image forming apparatus main body (hereinafter referred to as transfer paper) is conveyed to a post-processing apparatus and subjected to post-processing. In addition to transfer paper, a feeding device (hereinafter referred to as an inserter) that feeds a sheet (hereinafter referred to as a slip sheet) to the inside of a post-processing device is known. The inserter may be provided in the post-processing apparatus, or may be connected between the image forming apparatus main body and the post-processing apparatus. The interleaving paper fed from the inserter is stacked together with transfer paper on which an image is formed by the image forming apparatus main body, and post-processing is performed by the post-processing device.

  The inserter is downstream of the image forming apparatus main body in the transfer sheet conveyance direction. The transfer paper discharged from the image forming apparatus main body is transported to a transport path inside the inserter. The slip sheet fed from the feeding section of the inserter is transported to the same transport path inside the inserter. The distance from the feeding section of the image forming apparatus main body or the feeding section of the feeding apparatus connected upstream of the image forming apparatus main body to the conveying path inside the inserter is the conveying path inside the inserter from the feeding section of the inserter. Longer than the distance. Therefore, even if the transfer paper is loaded after the interleaving paper, it is necessary to start feeding the transfer paper several sheets ahead of the interleaving paper. In order to maintain productivity, it is necessary to feed the transfer paper from the feeding unit one after another before the interleaving paper. Therefore, when it is detected that there is no interleaving paper to be fed next after the last interleaving paper placed on the feeding unit of the inserter is fed, the transfer paper that should follow the interleaving paper May already be fed from the feeding section. In this case, in order to secure the page order of the stacked transfer paper and the interleaving paper, the image forming apparatus main body is temporarily stopped, the transfer paper remaining on the image forming apparatus main body is removed, and the image of the removed transfer paper is removed. Image formation must be resumed.

  Therefore, after it is determined that the slip sheet is in the feeding unit of the inserter, an image forming operation is performed to start feeding the transfer sheet to be stacked immediately after the slip sheet (hereinafter referred to as slip sheet presence confirmation mode). There is a device. The image forming apparatus operates in the interleaving paper confirmation mode, so that when the absence of interleaving paper is detected in the feeding unit of the inserter, the image forming apparatus main body is not left in the image forming apparatus main body. Can be stopped.

  However, in the interleaving paper confirmation mode, it is necessary to wait for the start of feeding the transfer paper to be stacked immediately after the interleaving paper until it is determined that the interleaving paper is present in the feeding unit of the inserter. Accordingly, the gap between the preceding transfer sheet and the succeeding transfer sheet is expanded, and the productivity is lowered. Therefore, in order to solve this problem, Patent Document 1 discloses a slip sheet remaining amount sensor for detecting the remaining amount of slip sheet in the inserter feeding unit, and whether or not there is slip sheet in the inserter feeding unit. An image forming apparatus including a slip sheet sensor for detection is disclosed. If the remaining amount of the slip sheet is greater than the predetermined amount based on the detection result of the slip sheet remaining sensor, the gap between the transfer sheets is determined without determining whether there is a slip sheet based on the detection result of the slip sheet sensor. Transfer paper is fed from the feeding unit of the image forming apparatus main body so as to be as small as possible (hereinafter referred to as a parting mode). Thereby, productivity is improved. On the other hand, when the remaining amount of the slip sheet is less than or equal to the predetermined amount based on the detection result of the slip sheet remaining sensor, the feeding timing is changed after it is confirmed that the slip sheet is present based on the detection result of the slip sheet sensor. Then, the image forming apparatus main body operates in the slip sheet presence confirmation mode for feeding the transfer sheet. Thereby, even if the main body of the image forming apparatus is stopped when it is detected that there is no slip sheet in the feeding portion of the inserter, it is possible to prevent transfer paper from remaining in the main body of the image forming apparatus.

JP 2003-104576 A

  However, even when the user sets more than the required number of slip sheets in the feeding section of the inserter, if the remaining amount of slip sheets becomes a predetermined amount or less, the main body of the image forming apparatus operates in the slip sheet presence confirmation mode (first There is a problem that the productivity is lowered by operating in the feeding mode). Further, even when the user sets more than the required number of slip sheets in the feeding section of the inserter, if the number of set slip sheets is not more than a predetermined amount from the beginning, the image forming apparatus main body is in the parting mode. There is a problem that the productivity is lowered by operating in the slip sheet presence confirmation mode from the beginning without operating.

  Therefore, the present invention provides an image forming apparatus capable of shortening the time for operating in the first feeding mode.

According to one embodiment of the present invention, an image forming apparatus includes:
A recording medium feeding unit for feeding the recording medium;
An image forming unit that forms an image on the recording medium fed from the recording medium feeding unit;
A slip sheet feeding section for feeding slip sheets;
A slip sheet detecting means for detecting the presence or absence of the slip sheet in the slip sheet feeding unit;
The recording medium feeding unit and the slip sheet so as to execute a slip sheet insertion job that joins and discharges the recording medium on which the image is formed and the slip sheet fed by the slip sheet feeding unit. A control unit for controlling the feeding unit;
A storage unit;
With
In the image forming apparatus, when the slip sheet is stacked immediately before the recording medium to be fed by the recording medium feeding unit, the slip sheet is fed based on the detection result of the slip sheet detecting unit. A first feeding mode for causing the recording medium feeding unit to start feeding the recording medium after being determined to be in the feeding unit, and the recording medium feeding unit regardless of a detection result of the slip sheet detecting unit In the second feeding mode for starting feeding of the recording medium,
When the slip sheet jam occurs during execution of the slip sheet insertion job, the control unit stores information indicating that the slip sheet jam has occurred in the storage unit,
The control unit operates the image forming apparatus in the second feeding mode, and controls the image forming apparatus based on the information indicating that the slip sheet jam is stored in the storage unit. It is determined whether or not to operate in the first feeding mode.

  According to the present invention, the time for operating the image forming apparatus in the first feeding mode can be shortened.

1 is a diagram illustrating a network of image forming apparatuses. 1 is a cross-sectional view of an image forming apparatus. FIG. 3 is a block diagram of a control unit that controls the image forming apparatus. Explanatory drawing which shows the image formation order of the page in double-sided printing. Explanatory drawing which shows the image formation order of a page in interleaf presence determination mode, and the insertion timing of a slip. Explanatory drawing which shows the image formation order of a page in the parting mode, and the insertion timing of a slip sheet. 6 is a flowchart showing transfer sheet feeding determination operation executed by a CPU. The flowchart which shows the setting operation | movement of the jam flag performed by CPU. The flowchart which shows the display judgment operation | movement of the inserter productivity setting screen performed by CPU. The figure which shows the inserter productivity setting screen displayed on the touch panel. The figure which shows the switching timing of a parting mode and a slip sheet determination mode. 9 is a flowchart showing a transfer paper feeding determination operation of the second embodiment executed by a CPU.

  Hereinafter, embodiments for carrying out the present invention will be described with reference to the drawings.

  FIG. 1 is a diagram illustrating a network 103 of the image forming apparatus 101. The image forming apparatus 101 is electrically connected to the host computer 102 via the network 103. The host computer 102 transmits image data to the image forming apparatus 101 via the network 103. In addition to the function of transmitting image data, the host computer 102 also has a function of running an image processing application to perform image editing processing. The image forming apparatus 101 communicates with the host computer 102 via the network 103. The image forming apparatus 101 forms an image on a recording medium (hereinafter referred to as transfer paper) according to the image data received from the host computer 102. Note that the image forming apparatus 101 may include an image reading device (not shown), and may form an image on a transfer sheet according to image data of a document read by the image reading device.

(Image forming device)
FIG. 2 is a cross-sectional view of the image forming apparatus 101. The image forming apparatus 101 includes an image forming apparatus main body 200 as a printer and an insert apparatus (hereinafter referred to as an inserter) 213 having an insert function of inserting a slip sheet between transfer sheets on which images are formed by the image forming apparatus main body 200. Have. In this embodiment, the image forming apparatus main body 200 forms an image on a transfer sheet by an electrophotographic method. The transfer paper is, for example, paper, an OHP sheet, cloth, or the like. The interleaving paper is preprinted paper or the like. An inserter 213 serving as a slip sheet feeding unit feeds slip sheets. The inserter 213 is controlled so that the fed slip sheet is stacked together with the transfer sheet on which the image is formed by the image forming apparatus main body 200 to form a part. The inserter 213 is arranged downstream of the image forming apparatus main body 200 in the transfer paper conveyance direction so as to receive the transfer paper on which the image is formed by the image forming apparatus main body 200, and is connected to the image forming apparatus main body 200.

  The image forming apparatus main body 200 includes a controller (hereinafter referred to as a control unit) 201, an operation unit 202, a toner supply unit 203, an image forming unit 204, an intermediate transfer belt 205, a fixing device 206, a surplus toner collecting unit 207, and transfer paper feeding. An apparatus 208 and a transfer paper feeding path 241 are included. The control unit 201 operates software for performing various controls of the image forming apparatus 101. The operation unit 202 is an interface for a user to give an operation instruction to the image forming apparatus 101. The operation unit 202 includes a touch panel 232 and hard keys 233. The operation unit 202 displays information related to the image forming apparatus 101 on a touch panel 232 serving as a display unit. The user can input settings to the image forming apparatus 101 using the touch panel 232 or the hard key 233 of the operation unit 202. A toner supply unit 203 supplies toner as a developer to the image forming unit 204. The toner supply unit 203 is provided with an open / close door (not shown). The user can supply toner to the toner supply unit 203 by opening an open / close door (not shown).

  The image forming unit 204 uses the toner supplied from the toner supply unit 203 to form a toner image on the photosensitive drum 234 according to the image data. The image forming unit 204 transfers the toner image on the photosensitive drum 234 to the intermediate transfer belt 205. The image forming unit 204 transfers the toner image on the intermediate transfer belt 205 onto a transfer sheet by a secondary transfer roller (secondary transfer unit) 235. The fixing device 206 fixes the toner image onto the transfer paper by applying heat and pressure to the transfer paper on which the toner image has been transferred, and forms an image. The belt cleaner 236 collects the toner remaining on the intermediate transfer belt 205 after the toner image is transferred to the transfer paper. The toner collected by the belt cleaner 236 is accumulated in the surplus toner collecting unit 207.

  A transfer paper feeding device (recording medium feeding unit) 208 stores transfer paper. The feeding roller 402 feeds the transfer paper from the transfer paper feeding device 208 to the transfer paper feeding path 241. The transfer paper is conveyed to the transfer paper conveyance path 242 by the conveyance roller 420 and the conveyance roller 403. The image forming apparatus main body 200 is provided with a transfer paper input port 211 for inputting transfer paper from an external transfer paper supply device (recording medium supply unit) (not shown). The transfer paper loaded into the transfer paper slot 211 is conveyed to the transfer paper conveyance path 242 by the feeding roller 401 and the conveyance roller 403. The transfer paper is conveyed by the registration roller 404 at the timing when the toner image on the intermediate transfer belt 205 reaches the secondary transfer roller 235. The transfer sheet on which the toner image is transferred is conveyed to the fixing device 206 by the conveyance roller 405. The transfer paper on which the toner image is fixed by the fixing device 206 is conveyed to the transfer paper discharge path 243 by the conveyance roller 406. The transfer paper is transported along the transfer paper discharge path 243 by the transport roller 407, and is discharged to the transfer paper discharge unit 212 by the discharge roller 421. The transfer paper discharge unit 212 transfers the transfer paper on which the image is formed by the image forming apparatus main body 200 to the inserter 213. When forming images on both sides of the transfer paper, the transport roller 406 transports the transfer paper to the reverse path 244. The transfer paper is transported to the switchback unit 210 by transport rollers 408, 409, 410 and 411. The switchback unit 210 reverses the front and back surfaces of the transfer paper.

  The inserter 213 includes a slip sheet feeding tray 217, a near empty sensor (hereinafter referred to as a slip sheet remaining amount sensor) 222, a slip sheet sensor 221, a slip sheet transport path 216, a transport path 218, a switchback unit (reverse path) 215, and A discharge tray 220 is provided. The inserter 213 is provided with a slot 214 for receiving transfer paper from the image forming apparatus main body 200. The transfer paper loaded from the insertion port 214 is conveyed to the conveyance path 218 by the entrance roller 422, the conveyance roller 423 and the conveyance roller 428. A slip sheet remaining amount sensor 222 serving as a remaining amount detection unit detects the remaining amount of slip sheets to determine whether or not the remaining amount of slip sheets stacked on the slip sheet feeding tray 217 is larger than a predetermined amount. To do. The interleaf sheet remaining amount sensor 222 may be an optical sensor such as a light transmission type sensor that detects the height of the interleaf sheets loaded on the interleaf sheet feeding tray 217. In this embodiment, the interleaf sheet remaining amount sensor 222 is used to detect the interleaf sheet remaining amount. However, other methods may be used to detect the interleaf sheet remaining amount. For example, if the configuration is such that the interleaf feed tray 217 is raised to a position where the feed roller 430 can feed, the amount of rise of the interleaf feed tray 217 (the number of drive pulses and the drive time of the motor) is measured. Thus, the remaining amount of the slip sheet may be detected. A slip sheet sensor 221 serving as a slip sheet detecting unit detects slip sheets in order to determine whether or not slip sheets are present on the slip sheet feeding tray 217. The interleaf sensor 221 may be an optical sensor such as a light reflection sensor. The slip sheet placed on the slip sheet feed tray 217 is fed to the slip sheet transport path 216 by the feed roller 430. The interleaving paper is conveyed to the conveyance path 218 by the conveyance roller 429 and the conveyance roller 428. The slip sheet fed from the slip sheet feeding tray 217 is transported to the transport path 218 via the slip sheet transport path 216 and merges with the transfer sheet transported from the image forming apparatus main body 200 through the transport path 218. The interleaving paper and the transfer paper are conveyed on the conveying path 218 by the conveying roller 431 and the conveying roller 432 in the order set in the interleaving paper insertion job, discharged from the discharging unit 219 by the discharging roller 433, and stacked on the discharging tray 220. Is done. The switchback unit 215 reverses the front and back surfaces of the transfer paper in the inserter 213.

(Control part)
FIG. 3 is a block diagram of the control unit 201 that controls the image forming apparatus 101. The control unit 201 includes a central processing unit (hereinafter referred to as CPU) 305, a RAM 306, an operation unit interface (hereinafter referred to as operation unit I / F) 307, and a network interface (hereinafter referred to as network I / F) 308. The control unit 201 also includes a modem (hereinafter referred to as MODEM) 309, a ROM 310, a hard disk (hereinafter referred to as HDD) 311, a CPU bus 312, and an image bus interface (hereinafter referred to as Image Bus I / F) 313. Further, the control unit 201 includes a raster image processor interface (hereinafter referred to as RIP I / F) 314, a data compression device 315, a device interface (hereinafter referred to as device I / F) 316, an image processing device 317, and an image bus 324. .

  The control unit 201 is electrically connected to the operation unit 202 through the operation unit I / F 307. The control unit 201 is connected to a network 103 connected to an external device such as the host computer 102 via a network cable 303 by a network I / F 308. The control unit 201 is connected to an external device by a MODEM 309 via a telephone line (line cable) 304. The control unit 201 is electrically connected to a raster image processor (hereinafter referred to as RIP) 321 through a RIP I / F 314. The control unit 201 is electrically connected to the inserter 213 via the data bus 319 by the device I / F 316. The control unit 201 is electrically connected to the image forming apparatus main body 200 via the data bus 320 by the device I / F 316.

  The CPU bus 312 electrically connects the CPU 305, RAM 306, operation unit I / F 307, network I / F 308, MODEM 309, ROM 310, and HDD 311. The image bus 324 electrically connects hardware groups for performing image processing, such as the RIP I / F 314, the data compression device 315, the device I / F 316, and the image processing device 317. The Image Bus I / F 313 electrically connects the CPU bus 312 and the image bus 324.

  The CPU 305 operates a program for controlling the entire control unit 201. The RAM 306 is managed by a program that runs on the CPU 305. The RAM 306 is used as a reception buffer that temporarily stores data received from an external device. The RAM 306 is used as an image data buffer that temporarily stores image data rasterized by the RIP 321. The ROM 310 is a storage unit that stores programs, data, and the like that operate on the CPU 305. The HDD 311 is a non-volatile storage device that can store various data for a long time.

  The RIP 321 has a function of converting image description data input from an external device into bitmap image data. The RIP I / F 314 connects the RIP 321 and the image bus 324 via an image transfer bus 318. The data compression device 315 compresses data. The image processing device 317 performs various types of image processing on the bitmap image data generated by the RIP 321. The image processing device 317 has a function of digitally processing bitmap image data, such as a function of combining bitmap image data of two pages with bitmap image data of one page. The CPU 305 outputs a command for image formation to the inserter 213 and the image forming apparatus main body 200 via the data buses 319 and 320 in accordance with an instruction signal input from the operation unit 202 or an external device to the network cable 303. Form.

(Transfer paper transport path in the image forming apparatus main body)
Next, with reference to FIG. 2, the transfer paper conveyance path 400 in the image forming apparatus main body 200 will be described. The transfer paper transport path 400 includes a transfer paper feed path 240, a transfer paper feed path 241, a transfer paper transport path 242, a transfer paper discharge path 243, a reverse path 244, a re-transport path 245 and a reverse discharge path 246. In the transfer paper conveyance path 400, a feed roller 401, a feed roller 402, a registration roller 404, and a discharge roller 421 are provided. The transfer paper conveyance path 400 further includes conveyance rollers 403, 405, 406, 407, 408, 409, 410, 411, 412, 413, 414, 415, 416, 417, 418, 419, 420. . The transport roller 406 is provided with a switching mechanism for switching the transport path for transporting the transfer paper between the transfer paper discharge path 243 and the reverse path 244. The transport roller 411 is provided with a switching mechanism for switching the transport path for transporting the transfer paper between the re-transport path 245 and the reverse discharge path 246. These rollers are controlled by the control unit 201.

  The transfer paper fed into the transfer paper slot 211 from an external feeding device (not shown) is fed by the feed roller 401 to the transfer paper transport path 242 through the transfer paper feed path 240. The transfer paper in the transfer paper feeding device 208 is fed by the feed roller 402 through the transfer paper feed path 241 to the transfer paper transport path 242. The conveyance roller 403 conveys the transfer paper to the registration roller 404 through the transfer paper conveyance path 242. The registration roller 404 conveys the transfer paper to the secondary transfer roller 235 so that the front end of the transfer paper coincides with the front end of the toner image on the intermediate transfer belt 205. The conveyance roller 405 conveys the transfer paper on which the toner image is transferred to the fixing device 206.

  When the transfer paper on which the image is formed in the single-sided printing for forming an image on one side of the transfer paper or the double-sided printing for forming an image on both sides of the transfer paper is conveyed to the transfer paper discharge unit 212, the transfer paper is It is conveyed to the transfer paper discharge path 243. The transfer paper is discharged to the transfer paper discharge unit 212 by the transport roller 407 and the discharge roller 421. When the front and back surfaces of the transfer paper are reversed and transported to the transfer paper discharge unit 212 in the image forming apparatus main body 200 in single-sided printing, the transfer paper is transported to the reverse path 244 by the transport roller 406. The transfer paper is transported to the switchback unit 210 by transport rollers 408, 409, 410, 411 and 412. When the transfer paper is transported to the switchback unit 210, the control unit 201 reverses the transport rollers 411 and 412 and transports the transfer paper to the reverse discharge path 246. The transfer paper is conveyed to the discharge roller 421 by the conveyance rollers 413 and 414 through the reverse discharge path 246. As a result, the transfer paper is discharged to the transfer paper discharge unit 212 by the discharge roller 421 with the front and back sides reversed.

  In the case of duplex printing in which an image is formed on both sides of a transfer sheet, the transfer sheet on which an image is formed on one side is conveyed to a reverse path 244 by a conveyance roller 406 and switched back by conveyance rollers 408, 409, 410, 411 and 412. To the unit 210. When the transfer paper is transported to the switchback unit 210, the control unit 201 reverses the transport rollers 411 and 412 and transports the transfer paper to the re-transport path 245. The transfer paper transported to the re-transport path 245 is transported to the transfer paper feed path 241 by transport rollers 415, 416, 417, 418 and 419. As a result, the transfer sheet is conveyed to the secondary transfer roller 235 by the conveyance roller 420, the conveyance roller 403, and the registration roller 404 with the front and back surfaces reversed. The toner image is transferred to the back surface of the transfer paper by the secondary transfer roller 235. In this way, images are formed on both sides of the transfer paper.

(Transfer paper transport path in the inserter)
Next, the transfer paper conveyance path 450 in the inserter 213 will be described. The transfer paper conveyance path 450 includes a switchback unit 215 and a conveyance path 218. In the transfer paper conveyance path 450, an entrance roller 422, conveyance rollers 423, 424, 425, 426, 427, 428, 431, and 432, and a discharge roller 433 are provided. The entrance roller 422 is provided with a switching mechanism for switching the transport path for transporting the transfer paper between the switchback unit 215 and the transport path 218. These rollers are controlled by a control unit 201 provided in the image forming apparatus main body 200.

  The transfer paper loaded from the image forming apparatus main body 200 to the loading port 214 is conveyed to the switchback unit 215 or the conveyance path 218 by the inlet roller 422. When the transfer paper is discharged to the discharge tray 220 without inverting the front and back surfaces of the transfer paper in the inserter 213, the entrance roller 422 transports the transfer paper to the transport path 218. The transfer paper is conveyed on the conveyance path 218 by the conveyance rollers 423, 428, 431, and 432, and is discharged to the discharge tray 220 by the discharge roller 433. When the front and back surfaces of the transfer paper are reversed in the inserter 213 and the transfer paper is discharged to the discharge tray 220, the entrance roller 422 conveys the transfer paper to the switchback unit 215. The transfer paper is transported by transport rollers 424, 425, and 426 at the switchback unit 215 and is temporarily stopped. The control unit 201 reversely rotates the conveyance rollers 425 and 426 to convey the transfer paper toward the conveyance path 218, and conveys the transfer paper to the conveyance path 218 by the conveyance rollers 427 and 428. The transfer paper is conveyed on the conveyance path 218 by the conveyance rollers 431 and 432, and is discharged to the discharge tray 220 by the discharge roller 433. As a result, the transfer paper is discharged to the discharge tray 220 with the front and back surfaces of the transfer paper reversed in the inserter 213.

(Transfer paper transfer in single-sided printing)
When the transfer paper is discharged to the discharge tray 220 with the image-formed side facing up in single-sided printing, the transfer paper on which the image is formed on one side by the image forming apparatus main body 200 is transferred by the transfer roller 406 to the transfer paper discharge path. It is conveyed to 243. The transfer paper is conveyed to the transfer paper discharge unit 212 by the conveyance roller 407 and the discharge roller 421. The transfer paper is transferred from the transfer paper discharge unit 212 of the image forming apparatus main body 200 to the insertion port 214 of the inserter 213. The entrance roller 422 conveys the transfer paper to the conveyance path 218. The transfer paper is transported on the transport path 218 by transport rollers 423, 428, 431, and 432, and is discharged to the discharge tray 220 with the surface on which the image is formed by the discharge roller 433. When an image is formed on a plurality of transfer sheets in the order of the pages, and the plurality of transfer sheets are stacked on the discharge tray 220 with the surface on which the image is formed facing up, the image on the previous page is discharged with the face up. The succeeding transfer sheet is overlaid on the preceding transfer sheet with the image of the subsequent page facing upward. Accordingly, the page order of the output items stacked on the discharge tray 220 is reversed. For this reason, in one-sided printing, the transfer paper is discharged to the discharge tray 220 with the surface on which the image is formed facing upward mainly when forming an image on only one transfer paper.

  There are two methods for discharging the transfer paper to the discharge tray 220 with the image-formed side down in single-sided printing. One is a method of inverting the transfer paper in the image forming apparatus main body 200. The transfer paper on which an image is formed on one side in the image forming apparatus main body 200 is transported to the reverse path 244 by the transport roller 406 and transported to the switchback unit 210 by the transport rollers 408, 409, 410, 411 and 412. When the transfer paper is transported to the switchback unit 210, the control unit 201 reverses the transport rollers 411 and 412 and transports the transfer paper to the reverse discharge path 246. The transfer paper is conveyed to the discharge roller 421 by the conveyance rollers 413 and 414 through the reverse discharge path 246. As a result, the transfer paper is discharged to the transfer paper discharge unit 212 by the discharge roller 421 with the front and back sides reversed. The transfer paper is input from the transfer paper discharge unit 212 of the image forming apparatus main body 200 to the input port 214 of the inserter 213. The transfer paper is conveyed to the conveyance path 218 by the entrance roller 422, conveyed on the conveyance path 218 by the conveyance rollers 423, 428, 431, and 432, and discharged to the discharge tray 220 by the discharge roller 433.

  The other is a method of inverting the transfer paper in the inserter 213. The transfer paper on which an image is formed on one side in the image forming apparatus main body 200 is transported to the transfer paper discharge path 243 by the transport roller 406. The transfer paper is discharged to the transfer paper discharge unit 212 by the transport roller 407 and the discharge roller 421. The transfer paper is input from the transfer paper discharge unit 212 of the image forming apparatus main body 200 to the input port 214 of the inserter 213. The transfer paper is conveyed to the switchback unit 215 by the entrance roller 422. The transfer paper is transported by transport rollers 424, 425, and 426 at the switchback unit 215 and is temporarily stopped. The control unit 201 reversely rotates the conveyance rollers 425 and 426 to convey the transfer paper toward the conveyance path 218, and conveys the transfer paper to the conveyance path 218 by the conveyance rollers 427 and 428. The transfer paper is conveyed on the conveyance path 218 by the conveyance rollers 431 and 432, and is discharged to the discharge tray 220 by the discharge roller 433. As a result, the transfer paper is discharged to the discharge tray 220 with the front and back surfaces of the transfer paper reversed in the inserter 213.

  The control unit 201 may determine whether to reverse the front and back surfaces of the transfer paper in the image forming apparatus main body 200 or to reverse the front and back surfaces of the transfer paper in the inserter 213 as follows. The control unit 201 determines whether or not the inserter 213 provided with the switchback unit 215 is connected to the image forming apparatus main body 200. When the inserter 213 provided with the switchback unit 215 is connected to the image forming apparatus main body 200, the control unit 201 reverses the front surface and the back surface of the transfer paper by the switchback unit 215 of the inserter 213. When the inserter 213 provided with the switchback unit 215 is not connected to the image forming apparatus main body 200, the control unit 201 reverses the front and back surfaces of the transfer paper by the switchback unit 210 in the image forming apparatus main body 200. .

(Transfer paper transfer for duplex printing)
In double-sided printing in which images are continuously formed on both sides of a plurality of transfer papers, the transfer papers D1, D2, D3, D4, and D5 on which the images are formed have re-conveying paths 245, The switchback unit 210 and the reverse path 244 are made to wait. This is conveyed from transfer paper D6, D7,... Fed by a feed roller 402 (or 401) to form an image on the front surface, and a re-conveying path 245 to form an image on the back surface. This is because the transfer sheets D1-D5 are alternately conveyed to the secondary transfer roller 235. By alternately transferring the transfer paper from the feed roller 402 (or 401) and the re-transport path 245 to the secondary transfer roller 235, productivity can be improved.

  FIG. 4 is an explanatory diagram showing the image formation order of pages in duplex printing. FIG. 4A is a diagram showing seven transfer sheets D1-D7 on which images of 14 pages of pages P01-P14 are formed on both sides. The page P01 is the first page, the page P02 is the second page, and so on. Further, pages P01, P03, P05, P07, P09, P11, and P13 on the upper side of the transfer paper D1-D7 represent page numbers on the surface of the transfer paper D1-D7. The lower pages P02, P04, P06, P08, P10, P12, and P14 of the transfer paper D1-D7 represent page numbers on the back surface of the transfer paper D1-D7.

  FIG. 4B is a diagram showing the image formation order and image formation timing for obtaining the output result shown in FIG. In this embodiment, as shown in FIG. 2, transfer paper D1-D5 having an image formed on one side at a standby position on a double-sided conveyance path (re-conveyance path 245, switchback unit 210, and reverse path 244) in double-sided printing. Can be made to stand by. Note that the number of standby transfer sheets is not limited to five, and may be set to a different number according to the image forming apparatus main body 200. First, images of pages P01, P03, P05, P07, and P09 are formed on the surface of five transfer papers D1-D5, respectively, and the transfer papers D1-D5 are put on standby at a standby position. At this time, the transfer sheets D1-D5 to be fed are separated by one transfer sheet so that the transfer sheets D6 and D7 can be inserted between the transfer sheets D1-D5. This is because transfer papers D6 and D7 fed by a feed roller 402 (or 401) to form an image on the front surface and transfer paper D1 fed from a re-conveying path 245 to form an image on the back surface. This is because -D5 is alternately conveyed to the secondary transfer roller 235 at the same conveyance speed.

  Next, the transfer paper D1 on which the image of the page P01 is formed is re-fed to form the image of the page P02 on the back surface of the page P01. Next, the transfer paper D6 is fed by the feed roller 402 (or 401), and an image of the page P11 is formed on the surface of the transfer paper D6. Next, the transfer paper D2 on which the image of page P03 is formed is fed again, and the image of page P04 is formed on the back surface of page 03. Next, the transfer paper D7 is fed by the feed roller 402 (or 401), and an image of the page P13 is formed on the surface of the transfer paper D7. Next, the transfer paper D3 on which the image of page P05 is formed is fed again, and the image of page P06 is formed on the back surface of page 05. In this way, image formation on the back surfaces of the transfer papers D1, D2, and D3 and image formation on the front surfaces of the transfer papers D6 and D7 are performed alternately. The image formation on the surface of the transfer paper is completed by the image formation on page P13. Thereafter, images of pages P08, P10, P12, and P14 are formed on the back surfaces of the transfer papers D4, D5, D6, and D7, respectively. By forming an image on both sides of the transfer paper in this image formation order, an image having a smaller page number on the transfer paper on which the image is formed on both sides is transferred without using the switchback unit (reversing path) 210 or 215. Thus, the transfer paper can be discharged to the discharge tray 220. When there is a mixture of transfer paper on which images are formed on both sides and transfer paper on which images are formed only on one side, an image is first formed on the back side in double-sided printing, an image is formed on the front side by refeeding, and then the inserter 213. The transfer paper may be reversed and discharged to the discharge tray 220.

(Interleaf paper confirmation mode and parting mode)
In the present exemplary embodiment, the image forming apparatus 101 performs the interleaving paper confirmation mode (the first paper interleaving mode) as the transfer paper feeding control for executing the interleaving paper insertion job including interleaving papers I1 and I2 and the transfer papers D1 to D7. It is possible to operate in a (feed mode) and a parting mode (second feed mode). In the interleaving paper confirmation mode, for example, the feeding of the transfer paper D1 is started after it is determined that the interleaving paper I1 to be fed immediately before the transfer paper D1 is in the interleaf feeding tray 217. Control. In the parting mode, for example, feeding of the transfer paper D1 is started before it is determined whether or not the interleaving paper I1 to be discharged immediately before the transfer paper D1 is in the interleaf feeding tray 217. Control.

(Transfer paper and interleaf transport in interleaving paper confirmation mode)
Hereinafter, with reference to FIG. 5, the image forming order on the transfer sheets D1 to D7 and the insertion timing of the slip sheets I1 and I2 in the slip sheet presence / absence mode will be described. FIG. 5 is an explanatory diagram showing the image forming order of pages and the insertion timing of the slip sheets I1 and I2 in the slip sheet presence confirmation mode. FIG. 5A shows seven transfer sheets D1-D7 on which images of 14 pages of pages P01-P14 are formed on both sides, and slip sheets I1 and I2 inserted in front of transfer sheets D1 and D3, respectively. FIG. The transfer paper D1-D7 and the interleaf papers I1 and I2 constitute a part. FIG. 5 shows a plurality of parts formed continuously.

  FIG. 5B is a diagram showing the image formation order, the image formation timing, and the insertion timings of the slip sheets I1 and I2 in the slip sheet presence confirmation mode for obtaining the output result shown in FIG. In the slip sheet presence confirmation mode, the transfer sheet feeding is started after the presence of the slip sheet to be inserted immediately before the transfer sheet is confirmed. As a result, even if the image forming apparatus 101 is stopped due to the detection of no interleaving paper, the transfer paper does not remain in the image forming apparatus 101, and the order of the pages of the deliverables does not change. Therefore, the operation of the image forming apparatus 101 can be resumed smoothly after the interleaving paper is supplied.

  First, before starting the feeding of the transfer paper D1 on which the image of the page P01 is formed, it is determined whether or not there is a slip sheet I1 inserted immediately before the transfer paper D1. When it is determined that there is a slip sheet on the slip sheet feeding tray 217 of the inserter 213 based on the detection result of the slip sheet sensor 221, feeding of the transfer sheet D1 is started. Next, the transfer paper D2 on which the image of the page P03 is formed on the front surface is not inserted with a slip sheet immediately before, and is fed from the same transfer paper feeding device 208 as the transfer paper D1. Accordingly, the image forming apparatus 101 is not stopped even if no slip sheet is detected, and the order of pages in the product is not changed, so that there is no gap between the transfer sheet D1 and one transfer sheet. Feeding of the transfer paper D2 is started after emptying.

  Next, the transfer paper D3 on which the image of the page P05 is formed is discharged after the slip sheet I2. If it is not determined that the slip sheet I2 is present on the slip sheet feeding tray 217, feeding of the transfer sheet D3 cannot be started. Therefore, the presence or absence of the slip sheet I2 is determined before the transfer sheet D3 is fed. However, the slip sheet sensor 221 cannot detect the presence or absence of the slip sheet I2 unless the slip sheet I1 is fed from the slip sheet feeding tray 217. Accordingly, it is not possible to start feeding the transfer sheet D3 at a normal timing with a gap between the transfer sheet D2 and one transfer sheet. Since the transfer paper D3 on which the image of the page P05 is formed cannot be fed, the transfer papers D4 and D5 on which the images of the pages P07 and P09 are formed cannot be fed. On the other hand, the transfer paper D1 having the image of the page P01 formed on the front surface is re-fed from the reconveying path 245 to form the image of the page P02 on the back surface and conveyed to the inserter 213. The inserter 213 starts feeding the slip sheet I1 from the slip sheet feed tray 217 so that the slip sheet I1 can be merged in the transport path 218 of the inserter 213 immediately before the transfer sheet D1. When the slip sheet I1 is fed, the presence or absence of the slip sheet I2 can be detected based on the detection result of the slip sheet sensor 221. When it is determined that the slip sheet I2 is present on the slip sheet feeding tray 217, feeding of the transfer sheet D3 on which the image of the page P05 is formed is started.

  From here, the remaining transfer sheets D4, D5, D6 and D7 of the first part B1 can all be fed. Pages P07, P09, P11 and P13 are formed on the surfaces of the transfer papers D4, D5, D6 and D7 of the first part B1, respectively. When the image of the page P13 is formed, the image formation on the surface of the first part B1 is completed. Next, images of pages P06, P08, P10, P12 and P14 are formed on the back surfaces of the transfer papers D3, D4, D5, D6 and D7 of the first part B1, respectively. Here, in order to increase the image forming efficiency, the formation of the image on the front surface of the second part B2 is started alternately with the image on the back surface of the first part B1. Since the slip sheet I2 of the first part B1 has already been fed, it is possible to determine whether or not the slip sheet I1 of the second part B2 is on the slip sheet feeding tray 217. When it is determined that the second part B2 slip sheet I1 is present on the slip sheet feeding tray 217, the second part B2 page P01 image is formed after the first part B1 page P06 image. Next, an image of page P08 of the first part B1 is formed, and then an image of page P03 of the second part B2 is formed. Similarly to the first part B1, the feeding of the transfer sheet D3 on which the image of the page P05 of the second part B2 is formed cannot be started unless it is determined that the slip sheet I2 of the second part B2 is present. Therefore, the timing at which the image of page P05 is formed on the front surface of transfer paper D3 is immediately after the image of page P02 is formed on the back surface of transfer paper D1. Thereafter, as with the first part B1, image formation of the second part B2 and the third part B3 is performed.

(Conveyance of transfer paper and interleaving paper in the parting mode)
Hereinafter, with reference to FIG. 6, the image forming order on the transfer sheets D1 to D7 and the insertion timing of the slip sheets I1 and I2 in the parting mode will be described. FIG. 6 is an explanatory diagram showing the image forming order of pages and the insertion timings of the slip sheets I1 and I2 in the parting mode. FIG. 6A shows an output result similar to that shown in FIG.

  FIG. 6B is a diagram showing the image formation order, the image formation timing, and the insertion timings of the slip sheets I1 and I2 in the parting mode for obtaining the output result of FIG. In the parting mode, feeding of the transfer paper is started without determining whether or not there is a slip sheet to be inserted immediately before the transfer paper. Thereby, productivity can be improved from the slip sheet presence / absence determination mode. However, when it is detected that there is no slip sheet to be inserted immediately before the transfer sheet on the slip sheet feeding tray 217, the image forming apparatus 101 is stopped. When the image forming apparatus 101 is stopped, the transfer paper may have already been fed from the transfer paper feeding apparatus 208, so that the transfer paper remains in the image forming apparatus 101 or the order of pages in the product. May be replaced.

  First, the transfer paper D1 on which the image of the page P01 is formed is fed from the transfer paper feeding device 208 without determining the presence or absence of the interleaf I1 inserted immediately before the transfer paper D1. Similarly, the transfer papers D2, D3, D4, and D5 on which the images of pages P03, P05, P07, and P09 are formed on the front surface are separated by one transfer sheet without determining whether or not there is a slip sheet. Are sent. The transfer paper D1 having the image of the page P01 formed on the front surface is re-fed from the re-conveying path 245, the image of the page P02 is formed on the back surface, and is conveyed to the inserter 213. The inserter 213 starts feeding the slip sheet I1 from the slip sheet feed tray 217 so that the slip sheet I1 can be merged in the transport path 218 of the inserter 213 immediately before the transfer sheet D1. On the other hand, the transfer paper D6 on which the image of the page P11 is formed is fed from the transfer paper feeding device 208 so as to be conveyed to the secondary transfer roller 235 immediately after the transfer paper D1. Next, the transfer paper D2 on which the image of the page P03 is formed on the front surface is re-fed from the reconveying path 245 to form the image of the page P04 on the back surface, and is conveyed to the inserter 213. On the other hand, the inserter 213 starts feeding the slip sheet I2 from the slip sheet feed tray 217 so that the slip sheet I2 can be merged in the transport path 218 of the inserter 213 immediately after the transfer sheet D2. Next, the transfer paper D7 on which the image of the page P13 is formed is fed from the transfer paper feeding device 208 so as to be conveyed to the secondary transfer roller 235 immediately after the transfer paper D2. Thereafter, the transfer paper is fed with a paper interval as short as possible so that image formation on the back surface of the first part B1 and image formation on the front surface of the second part B2 are alternately performed. Thereby, the productivity in the parting mode is improved as compared with the productivity in the slip sheet determination mode shown in FIG.

  Although the example of the duplex printing job has been described with reference to FIGS. 5 and 6 as the operation example of the slip sheet presence confirmation mode and the parting-off mode, the present invention is not limited to the duplex printing job but also to the simplex printing job. Applicable. The present invention is also effective for single-sided printing jobs when there are many slip sheets to be inserted or when the transport path from the transfer sheet feeding section to the junction of the slip sheets and the transfer sheets is long.

(Transfer paper feeding mode for slip sheet insertion jobs)
In the interleaving paper confirmation mode, the feeding of the transfer paper immediately after the interleaving paper is started after it is determined that the interleaving paper is present. Therefore, even if it is detected that there is no interleaving paper and the image forming apparatus 101 is stopped, the image No transfer paper remains in the forming apparatus 101, and the page order of the deliverables is not changed. However, since it is confirmed that there is a slip sheet before the transfer paper is fed, productivity is lowered. On the other hand, the parting mode is higher in productivity than the slip sheet determination mode. However, when it is detected that there is no slip sheet and the image forming apparatus 101 is stopped, transfer paper remains in the image forming apparatus 101. The page order of the deliverables may be changed. In this embodiment, in order to improve the productivity of the slip sheet insertion job by taking advantage of the slip sheet presence confirmation mode and the parting mode, the transfer sheet feeding mode is set to the slip sheet presence mode during the slip sheet insertion job. And switch to the parting mode. The user usually sets a sufficient number of necessary slip sheets on the inserter 213. Therefore, as long as no jamming of the slip sheet is detected in the inserter 213, the slip sheet is rarely lost on the slip sheet feeding tray 217 of the inserter 213. In this embodiment, therefore, productivity is improved by operating in the parting mode while the slip sheet is not jammed during the slip sheet insertion job, and operating in the slip sheet presence confirmation mode after the slip sheet is jammed. Plan.

(Paper jam)
The inserter 213 is provided with sheet sensors 501 and 502. The sheet sensors 501 and 502 are turned on when a sheet such as a slip sheet or a transfer sheet is detected, and turned off when a sheet is not detected. The sheet sensor 501 is provided in the slip sheet conveyance path 216 and detects the slip sheet conveyed on the slip sheet conveyance path 216. If the sheet sensor 501 is not turned on even after a predetermined time has elapsed since the feeding roller 430 started feeding the slip sheet on the slip sheet feed tray 217, the CPU 305 causes a slip of the slip sheet. Judge that If the sheet sensor 501 is not turned off after a predetermined time has elapsed after the sheet sensor 501 is turned on, the CPU 305 determines that a slip sheet jam has occurred. A sheet sensor 502 is provided in the conveyance path 218 and detects a slip sheet or a transfer sheet conveyed on the conveyance path 218. The CPU 305 determines whether a jam of the slip sheet or a jam of the transfer sheet has occurred based on the conveyance timing of the slip sheet and the transfer sheet based on the slip sheet insertion job and the detection result of the sheet sensor 502. If the CPU 305 determines that there is no slip sheet on the slip sheet feeding tray 217 based on the detection result of the slip sheet sensor 221, it determines that a slip sheet jam has occurred. When a slip sheet jam occurs, the CPU 305 turns on the jam flag and stops the operation of the image forming apparatus 101 including the inserter 213. The jam flag is stored in a RAM (storage unit) 306. After the image forming apparatus 101 is stopped, the user removes the jammed slip sheet or transfer sheet from the image forming apparatus 101 or supplies the slip sheet to the slip sheet feeding tray 217. Thereafter, upon receiving an instruction to resume printing by the user, the CPU 305 resumes the image forming operation of the image forming apparatus 101.

(Transfer paper feeding judgment operation)
Hereinafter, with reference to FIG. 7, the operation of determining whether or not to start feeding the transfer sheet in the slip sheet insertion job will be described. FIG. 7 is a flowchart showing transfer sheet feeding determination operation executed by the CPU 305. The CPU 305 executes a transfer sheet feeding determination operation in accordance with a program stored in the ROM 310. When the transfer sheet feeding determination operation is started in the slip sheet insertion job, the CPU 305 is a slip sheet in which the sheet immediately before the transfer sheet to be fed is fed from the slip sheet feeding tray 217 of the inserter 213. It is determined whether or not there is (S901). If the immediately preceding sheet is not a slip sheet (NO in S901), the CPU 305 advances the process to S904. When the immediately preceding sheet is a slip sheet (YES in S901), the CPU 305 determines whether or not the jam flag is ON (S902). The setting of the jam flag will be described later with reference to FIG. If the jam flag is OFF (NO in S902), the CPU 305 advances the process to S904. If the jam flag is ON (YES in S902), the CPU 305 determines whether or not it is determined that the slip sheet, which is the immediately preceding sheet, is present in the slip sheet feeding tray 217 (S903). When it is determined that there is a slip sheet (YES in S903), the CPU 305 determines to start the transfer sheet feeding (S904), and ends the transfer sheet feeding determination operation. If it is not determined that there is a slip sheet (NO in step S903), the CPU 305 determines whether it is determined that there is no slip sheet in the slip sheet feed tray 217 based on the detection result of the slip sheet sensor 221. Judgment is made (S905). If it is not determined that there is no slip sheet (NO in S905), the CPU 305 returns the process to S903. The case where it is not determined that there is a slip sheet and the case where it is not determined that there is no slip sheet are, for example, because the feeding of the slip sheet immediately before the slip sheet whose presence or absence should be determined has not been completed. This is a case where the CPU 305 cannot determine the presence or absence of a slip sheet based on the detection result of the slip sheet sensor 221. If it is determined that there is no slip sheet (YES in step S905), the CPU 305 ends the transfer sheet feeding determination operation.

(Jam flag setting operation)
Hereinafter, the jam flag setting operation during execution of the slip sheet insertion job will be described with reference to FIG. FIG. 8 is a flowchart showing the jam flag setting operation executed by the CPU 305. The CPU 305 executes a jam flag setting operation in accordance with a program stored in the ROM 310. When a jam occurs in the slip sheet insertion job, the CPU 305 starts a jam flag setting operation. The CPU 305 determines whether the jammed sheet includes the slip sheet fed from the slip sheet feeding tray 217 of the inserter 213 (S1001). The determination as to whether or not a slip sheet is included in the jam sheet is made based on, for example, whether or not a slip sheet jam has occurred based on the detection results of the slip sheet sensor 221 and the sheet sensors 501 and 502. The If no slip sheet is included in the jam sheet (NO in step S1001), the CPU 305 ends the jam flag setting operation. When a slip sheet is included in the jam sheet (YES in step S1001), the CPU 305 causes a jam flag indicating that the slip sheet is included in the slip sheet insertion job (there is a slip sheet jam). It is determined whether or not (information indicating this) is ON (S1002). The jam flag is stored in a RAM (storage unit) 306. If the jam flag is ON (YES in S1002), the CPU 305 ends the jam flag setting operation. If the jam flag is OFF (NO in S1002), the CPU 305 sets the jam flag to ON (S1003), and ends the jam flag setting operation. In this embodiment, the jam flag is set to OFF when it is detected that a slip sheet is present in the slip sheet feeding tray 217 of the inserter 213 based on the detection result of the slip sheet sensor 221 at the start of a print job. Further, the jam flag is set to OFF when it is detected that there is no slip sheet once based on the detection result of the slip sheet sensor 221 after the start of the print job, and it is detected that there is slip sheet again. This is because it is determined that the slip sheet has been set in the slip sheet feeding tray 217 by the user after the slip sheet has been exhausted.

(Insert productivity setting screen display judgment operation)
In this embodiment, if the jammed sheet includes the slip sheet fed from the slip sheet feeding tray 217 of the inserter 213 during the slip sheet insertion job, the image forming apparatus 101 operates in the slip sheet presence confirmation mode. . However, when the image forming apparatus 101 operates in the slip sheet presence confirmation mode, the productivity decreases. Therefore, even after the jam of the slip sheet occurs, if the slip sheet is sufficiently set in the slip sheet feeding tray 217 of the inserter 213, the inserter productivity setting screen is displayed on the touch panel 232 of the operation unit 202. Then, the user may be able to select the parting mode.

  Hereinafter, the display determination operation of the inserter productivity setting screen will be described with reference to FIG. FIG. 9 is a flowchart showing the display determination operation of the inserter productivity setting screen executed by the CPU 305. The CPU 305 executes display judgment operation for the inserter productivity setting screen according to the program stored in the ROM 310. When a jam occurs during the slip sheet insertion job, the CPU 305 starts a display determination operation. When the user removes all the jam sheets (S1101), the CPU 305 determines whether or not the jam flag is ON (S1102). If the jam flag is OFF (NO in S1102), the CPU 305 ends the display determination operation. This is because it is determined that no slip sheet is included in the jam sheet. When the jam flag is ON (YES in S1102), the CPU 305 displays an inserter productivity setting screen (selection screen) 1200 on the touch panel 232 of the operation unit 202 (S1103). FIG. 10 is a diagram showing an inserter productivity setting screen 1200 displayed on the touch panel 232. The user touches the check box 1201 to set the close-off mode or the slip sheet presence / absence determination mode (S1104). In this embodiment, the check box 1201 performs a toggle operation. When the check box 1201 is checked, the parting mode is selected. When the check box 1201 is unchecked, the slip sheet determination mode is selected. FIG. 10 shows a state where the check box 1201 is checked. The CPU 305 determines whether printing has been resumed (S1105). Whether or not printing has been resumed is determined by determining whether the user has touched the print resume key 1202 or the job cancel key 1203 on the inserter productivity setting screen 1200. When the print restart key 1202 is touched by the user (YES in S1105), the CPU 305 restarts the operation in the part-off mode or the slip sheet presence mode according to the user selection result, and ends the display determination operation. . When the job cancel key 1203 is touched by the user (NO in S1105), the CPU 305 cancels the currently executed slip sheet insertion job (S1106) and ends the display determination operation.

  According to the first embodiment, the transfer sheet feeding is operated in the parting-out mode, and when the interleaf jam occurs, the operation is performed in the interleaf presence determination mode, so that the number of interleaf sheets set in the inserter 213 is increased. Regardless, the productivity of the image forming apparatus 101 can be improved. On the other hand, when the user selects the parting mode with the touch panel 232 even when the jam flag is ON, the image forming apparatus is operated in the parting mode. According to the first exemplary embodiment, it is possible to shorten the time during which the image forming apparatus is operated in the interleaf presence determination mode (first feeding mode).

  Hereinafter, Example 2 will be described with reference to FIGS. 11 and 12. In the second embodiment, the same structures as those in the first embodiment are denoted by the same reference numerals, and the description thereof is omitted. Since the image forming apparatus 101 and the control unit 201 according to the second embodiment are the same as those according to the first embodiment, description thereof is omitted. In the first exemplary embodiment, when a jam occurs during a slip sheet insertion job and the jam sheet includes the slip sheet, the transfer sheet feeding mode is changed to the slip sheet presence confirmation mode, and the slip sheet has the slip sheet. If it is not included, the parting mode is maintained. However, an interleaving paper jam may occur during the interleaving paper insertion job, and a sufficient number of interleaving papers may still be set on the interleaving paper feed tray 217 even after the jammed interleaving paper is removed. In addition, when a slip sheet jam occurs immediately after the start of the slip sheet insertion job, a sufficient number of slip sheets may still be set on the slip sheet feeding tray 217. If the image forming apparatus 101 operates in the slip sheet presence confirmation mode even though a sufficient number of slip sheets are set on the slip sheet feeding tray 217, productivity is unnecessarily lowered.

  Therefore, in the second embodiment, the productivity is further improved by using the interleaf sheet remaining amount sensor 222. Even if a jam of the slip sheet occurs, the slip sheet feeding is performed until the remaining amount of the slip sheet on the slip sheet feeding tray 217 becomes a predetermined amount or less based on the detection result of the slip sheet remaining amount sensor 222. There is no possibility that the slip sheet on the tray 217 will run out. In such a case, the image forming apparatus 101 is operated in the parting mode. If the remaining amount of interleaving paper on the interleaving paper feed tray 217 is equal to or less than a predetermined amount based on the detection result of the interleaving paper remaining amount sensor 222 when the interleaving paper jam occurs, the image forming apparatus 101 has the interleaving paper present. Operate in fixed mode. As a result, even when an interleaf jam occurs, the image forming apparatus 101 can be operated in the part-off mode to improve productivity.

  FIG. 11 is a diagram illustrating switching timing between the parting mode and the slip sheet determination mode. FIG. 11A shows the relationship between the remaining amount of slip sheets on the slip sheet feed tray 217 of the inserter 213 and time. In this embodiment, the interleaf feed tray 217 of the inserter 213 can stack 500 interleaf sheets. If the predetermined amount is 20, the timing 1301 indicates that the remaining amount of the slip sheet is equal to or less than the predetermined amount based on the detection result of the slip sheet remaining amount sensor 222. When obtaining the output results shown in FIGS. 5A and 6A, two slip sheets are fed per part. If the slip sheet insertion job is completed without the slip sheet being included in the jam sheet even if a jam occurs, the transfer sheet is fed in the parting mode to the end as shown in FIG. FIG. 11C is a diagram illustrating an operation when a jam including slip sheets occurs at a timing 1302 before the remaining amount of slip sheets becomes equal to or less than a predetermined amount. At timing 1302, since the remaining amount of the slip sheet has not yet reached the predetermined amount, the image forming apparatus 101 operates in the parting mode. After that, based on the detection result of the interleaving sheet remaining amount sensor 222, at a timing 1301 when the interleaving sheet remaining amount becomes equal to or less than a predetermined amount, the transfer sheet feeding mode is changed to the interleaving sheet presence mode. FIG. 11D is a diagram illustrating an operation when a jam including slip sheets occurs at a timing 1303 after the remaining amount of slip sheets is equal to or less than a predetermined amount. Based on the detection result of the interleaving paper remaining amount sensor 222, no jamming including interleaving paper has occurred until the timing 1301 when the remaining amount of interleaving paper becomes a predetermined amount or less. Works with. When a jam including slip sheets occurs at a timing 1303 after the remaining amount of slip sheets is equal to or less than a predetermined amount, the transfer sheet feeding mode is changed from the complete mode to the slip sheet presence mode. According to the second embodiment, it is possible to shorten the time for operating in the slip sheet presence confirmation mode, and it is possible to improve productivity.

(Transfer paper feeding judgment operation)
Hereinafter, with reference to FIG. 12, an operation for determining whether or not to start feeding the transfer sheet in the slip sheet insertion job based on the detection result of the slip sheet remaining amount sensor 222 will be described. FIG. 12 is a flowchart illustrating the transfer sheet feeding determination operation according to the second embodiment, which is executed by the CPU 305. The CPU 305 executes a transfer sheet feeding determination operation in accordance with a program stored in the ROM 310. When the transfer sheet feeding judgment operation is started in the slip sheet insertion job, the CPU 305 is a slip sheet in which the sheet immediately before the transfer sheet to be fed is fed from the slip sheet feeding tray 217 of the inserter 213. It is determined whether or not there is (S1401). If the immediately preceding sheet is not a slip sheet (NO in S1401), the CPU 305 advances the process to S1405. If the immediately preceding sheet is a slip sheet (YES in S1401), the CPU 305 determines whether the remaining amount of slip sheet is equal to or less than a predetermined amount based on the detection result of the slip sheet remaining amount sensor 222 (S1402). . If the remaining amount of the slip sheet is not less than or equal to the predetermined amount (NO in S1402), the CPU 305 advances the process to S1405. If the remaining amount of the slip sheet is equal to or less than the predetermined amount (YES in S1402), the CPU 305 determines whether or not the jam flag is ON (S1403). If the jam flag is OFF (NO in S1403), the CPU 305 advances the process to S1405. When the jam flag is ON (YES in S1403), the CPU 305 determines whether or not it is determined that the slip sheet as the immediately preceding sheet is present in the slip sheet feeding tray 217 (S1404). If it is determined that there is a slip sheet (YES in S1405), the CPU 305 determines to start feeding the transfer sheet (S1405) and ends the transfer sheet feeding determination operation. If it is not determined that there is a slip sheet (NO in S1404), the CPU 305 determines whether or not it is determined that there is no slip sheet in the slip sheet feed tray 217 based on the detection result of the slip sheet sensor 221. Judgment is made (S1406). If it is not determined that there is no slip sheet (NO in S1406), the CPU 305 returns the process to S1404. If it is determined that there is no slip sheet (YES in step S1406), the CPU 305 ends the transfer sheet feeding determination operation.

  According to the second exemplary embodiment, when the transfer paper feeding is operated in the parting-off mode, and the remaining amount of the slip sheet is larger than the predetermined amount when the slip sheet jam occurs, the mode is not changed to the slip sheet presence confirmation mode. By operating in the parting mode, the productivity of the image forming apparatus 101 can be improved. According to the second exemplary embodiment, it is possible to shorten the time during which the image forming apparatus is operated in the slip sheet presence determination mode (first feeding mode).

DESCRIPTION OF SYMBOLS 101 ... Image forming apparatus 201 ... Control part 204 ... Image forming part 208 ... Transfer paper feeding apparatus (recording medium feeding part)
213: Inserter (interleaf feed section)
221 ... Interleaf sensor (interleaf detection means)

Claims (5)

An image forming apparatus,
A recording medium feeding unit for feeding the recording medium;
An image forming unit that forms an image on the recording medium fed from the recording medium feeding unit;
A slip sheet feeding section for feeding slip sheets;
A slip sheet detecting means for detecting the presence or absence of the slip sheet in the slip sheet feeding unit;
The recording medium feeding unit and the slip sheet so as to execute a slip sheet insertion job that joins and discharges the recording medium on which the image is formed and the slip sheet fed by the slip sheet feeding unit. A control unit for controlling the feeding unit;
A storage unit;
With
In the image forming apparatus, when the slip sheet is stacked immediately before the recording medium to be fed by the recording medium feeding unit, the slip sheet is fed based on the detection result of the slip sheet detecting unit. A first feeding mode for causing the recording medium feeding unit to start feeding the recording medium after being determined to be in the feeding unit, and the recording medium feeding unit regardless of a detection result of the slip sheet detecting unit In the second feeding mode for starting feeding of the recording medium,
When the slip sheet jam occurs during execution of the slip sheet insertion job, the control unit stores information indicating that the slip sheet jam has occurred in the storage unit,
The control unit operates the image forming apparatus in the second feeding mode, and controls the image forming apparatus based on the information indicating that the slip sheet jam is stored in the storage unit. An image forming apparatus that determines whether or not to operate in a first feeding mode.   The control unit causes the image forming apparatus to operate in the first feeding mode when the information indicating that the slip sheet jam has occurred is stored in the storage unit. Item 2. The image forming apparatus according to Item 1. Further comprising a remaining amount detecting means for detecting a remaining amount of the slip sheet in the slip sheet feeding unit,
The control unit is a case where the remaining amount of the slip sheet is equal to or less than a predetermined amount based on a detection result of the remaining amount detection unit, and the storage unit has a jam of the slip sheet. The image forming apparatus according to claim 1, wherein when the information to be displayed is stored, the image forming apparatus is operated in the first feeding mode.   The control unit is configured to operate the image forming apparatus in the second feeding mode when the information indicating that the slip jam has occurred is not stored in the storage unit. Item 4. The image forming apparatus according to any one of Items 1 to 3. A display unit for displaying information on the image forming apparatus;
The control unit is a screen that allows the user to select the first feeding mode and the second feeding mode when the information indicating that the slip sheet jam has occurred is stored in the storage unit. Is displayed on the display unit,
The image forming apparatus according to claim 1, wherein the control unit causes the image forming apparatus to operate in the first feeding mode or the second feeding mode according to a selection result of the user.

Images