JP2019133096A - Image forming apparatus - Google Patents

Abstract

To provide an image forming apparatus that can reliably eject a sheet even when detecting mismatch between sheet sizes in inverting and ejecting the sheet.SOLUTION: In an inversion and ejection job, when a sheet size error occurs in which a preset sheet size stored in storage means and a sheet size detected on the basis of a detection signal from detection means are different from each other, an image forming apparatus does not interchange a leading end and a rear end of the sheet and ejects the sheet while maintaining a relationship between the leading end and the rear end of the sheet during image formation.SELECTED DRAWING: Figure 5

Description

  The present invention relates to an image forming apparatus.

  2. Description of the Related Art Conventionally, image forming apparatuses such as copying machines, printers, facsimile machines, and the like have a paper feeding unit for stacking paper, and images formed by the image forming unit are transferred to the paper conveyed one by one from the paper feeding unit. And discharged as a product. Some sheet feeding units are provided with a guide plate and automatically detect the length direction and width direction of the sheet by detecting the position where the guide plate is set. However, if the guide plate is not set correctly with the paper, the paper size may be erroneously detected. In the case of a paper feed unit that does not have automatic detection means, the paper size is set by the user specifying the paper size as a job condition. However, the user may mistakenly specify a different paper size.

  On the other hand, the image forming unit of the image forming apparatus forms an image based on the set size. Therefore, as described above, if the size detected by the paper feed unit is false detection, or if the user specifies the paper size incorrectly, the formed image size does not match the paper size, and the user It may not be the desired deliverable. In that case, the job is generally interrupted as a paper size difference jam.

  As a method of determining a paper size difference jam, for example, a sensor is provided on a paper conveyance path, and a paper size calculated based on a time when the front end of the paper passes the sensor and a time when the rear end of the paper passes the sensor is used. There is. In this method, a paper size difference jam is determined by comparing the detected size with the set size.

  However, if jamming is stopped when it is determined that the paper size is different, a work load is imposed on the user because it is necessary to remove the paper. On the other hand, since the paper does not cause a paper jam, it is considered that the paper is not damaged and can be conveyed. Therefore, conventionally, when it is determined that the paper size is different, it is proposed that the job is interrupted after the paper is automatically discharged (see Patent Document 1).

JP 2008-221543 A

  When it is determined that the paper size is different as described above, if the job is interrupted after the paper is automatically discharged, the work load related to the jam processing by the user can be reduced.

  However, when automatically ejecting a sheet that has been determined to be different in size, there is a gap between the detected size and the set size, so if you attempt to eject the sheet based on incorrect sheet size information, the sheet There is a risk of jamming. In particular, when performing reverse discharge that discharges after reversing the conveyance direction of the sheet, for example, if the drawing amount of the sheet drawn into the reverse conveyance path is insufficient, the sheet cannot be reversed and the sheet jams. There is a fear.

  SUMMARY An advantage of some aspects of the invention is that it provides an image forming apparatus that can reliably discharge a sheet even when a sheet size mismatch occurs during a reversal discharge job for reversing and discharging a sheet. To do.

  An image forming apparatus according to the present invention includes an image forming unit that forms an image on a sheet, a detection unit that is provided on the sheet conveyance path and detects the size of the sheet being conveyed, and downstream of the image forming unit in the sheet conveyance direction. A reversing and conveying means that reverses and conveys the image-formed sheet by reversing the leading and trailing edges of the sheet; a storage means that stores sheet size information; and a leading and trailing edge of the sheet during image formation A control unit capable of executing a straight discharge job that discharges a sheet in a state where the relationship is maintained, and a reverse discharge job that discharges a sheet by switching the leading end and the trailing end of the sheet by the reverse conveying unit; The control unit is detected based on a set size of the sheet stored in the storage unit and a detection signal from the detection unit in the reverse discharge job. If Tosaizu and different sheet size error occurs, without interchanging the front end and the rear end of the sheet, to discharge the sheet while maintaining the relationship between the sheet leading and trailing ends at the time of image formation.

  According to the present invention, even when a sheet size error occurs during a reverse discharge job, it is possible to reliably discharge the sheet, and to reduce the work load related to the jam processing of the user.

1 is a schematic diagram of a printer according to an embodiment of the present invention. FIG. 2 is a schematic diagram of a reverse conveyance mechanism of the printer of FIG. 1. FIG. 2 is a block diagram of a control unit of the printer in FIG. 1. The flowchart figure which showed the sheet size error detection flow. The flowchart figure which showed the automatic discharge flow at the time of sheet size error detection. The flowchart figure which showed the drawing amount determination flow at the time of inversion. The flowchart figure which showed the drawing amount determination flow at the time of inversion in other embodiment. The flowchart figure which showed the detection size determination flow. The flowchart figure which showed the detection size determination flow in another Example.

<Overall configuration of image forming apparatus>
Embodiments according to the present invention will be described below with reference to the drawings. FIG. 1 is a diagram illustrating a configuration of a printer 1 as an image forming apparatus according to the present embodiment. The printer 1 includes a printer main body 10, a document reading device 30 provided on the upper portion of the printer main body 10, and a sheet processing device 50 that performs various processes such as a binding process on a sheet on which an image is formed. It is configured with. The printer main body 10 includes an image forming unit (image forming unit) 10A that forms an image on a sheet. The image forming unit 10A includes photosensitive drums 102y to 102k, exposure units 103y to 103k, which will be described later, and an intermediate unit. The transfer body 104 is provided.

  The printer 1 forms a sheet on the basis of an image signal generated by the scanner unit 100 of the document reading device 30 reading a document or instructing a job to be executed from the operation display device 20 or an external PC (not shown). Form an image. When the image signal is input to the exposure units 103y to 103k of the image forming unit 10A from the document reader 30 or an external PC, the exposure units 103y to 103k emit laser light based on the image signal. Then, the laser light is reflected by the rotary polygon mirrors 101 y to 101 k and irradiated to the photosensitive drum 102. As a result, electrostatic latent images are formed on the respective photosensitive drums 102y to 102k.

  The electrostatic latent images on the photosensitive drums 102y to 102k are developed by a developing device. The photosensitive drums 102y to 102k on which toner images of yellow (Y), magenta (M), cyan (C), and black (K) are formed are arranged along the intermediate transfer member 104 at a predetermined interval. The toner images formed on the photosensitive drums 102y to 102k are primarily transferred onto the intermediate transfer member 104 at predetermined timings by the primary transfer units 105y to 105k, respectively, and each color component is overlapped, so that a desired color image is formed. It is formed.

  On the other hand, the sheet fed from the feeding unit 110 or the manual feed tray 40 is conveyed to the registration roller 111. When the leading edge of the sheet reaches the registration roller 111, the registration roller 111 is driven in synchronization with the laser light irradiation process and the development process, and the secondary transfer nip between the intermediate transfer member 104 and the secondary transfer roller 106 is reached. The sheet is conveyed to T2. At the secondary transfer nip T2, the toner image primarily transferred onto the intermediate transfer member 104 is secondarily transferred onto the sheet. The toner image transferred on the sheet is heated and pressurized in the fixing unit 107 and fixed on the sheet. The sheet after fixing is discharged to a sheet processing apparatus (post-processing apparatus) 50, and then conveyed on a sheet conveyance path in the sheet processing apparatus 50 and stacked on the stacking tray 120.

<Reverse discharge mechanism>
Next, the sheet reversing and discharging mechanism 210 will be described with reference to FIG. FIG. 2 is a diagram showing in detail a portion downstream of the fixing unit 107 of the printer main body unit 10 of FIG. The inner discharge sensor 201, the outer discharge sensor 202, and the reverse sensor 203 are sensors for detecting the presence / absence of a sheet. The leading edge of the sheet has reached each sensor position, and the trailing edge of the sheet has passed through each sensor position. Can be detected.

  The conveyance rollers 211 to 216 are driven to convey the sheet in a predetermined direction. The conveyance roller 211 is driven to convey a sheet conveyed from the fixing unit 107 in the D2 direction and passed to the reversing roller 213, and directly conveyed in the D1 direction from the fixing unit 107 without passing through the reversing roller 213. May be driven to convey the sheet to be conveyed.

  The reversing roller 213 is driven to convey the sheet received from the conveying roller 211 toward the reversing roller 214, and is driven in the reverse rotation to convey the sheet reversed by the reversing roller 214 in the direction D3. There is. The reverse roller 214 pulls the sheet conveyed from the reverse roller 213 and then reversely rotates and conveys it in the D4 direction toward the double-sided conveyance path 234, and conveys the sheet to the reverse roller 213 in the D3 direction. There is a case. In the present embodiment, the reversing conveyance unit provided by the reversing rollers 213 and 214 downstream in the sheet conveying direction of the image forming unit, reverses the image-formed sheet and exchanges the leading and trailing ends of the sheet. Is configured.

  A conveyance roller 212 is a roller for conveying the sheet from the discharge unit 200 to the outside of the printer main body unit 10. The conveyance rollers 215 and 216 are rollers for conveying the sheet reversed by the reversing roller 214 during duplex printing on the sheet on the duplex conveyance path 234. The positions of the flappers 221 and 222 as switching means for switching the sheet conveyance path are controlled in order to switch the sheet conveyance direction. The flapper 221 is switched between a case where the sheet passing through the fixing unit 107 is conveyed in the reverse conveyance path direction D2 and a case where the sheet is conveyed in the straight discharge direction D1. That is, the flapper 221 serves as a switching unit that switches the sheet conveyance path to a reversal conveyance path (reverse discharge path) 236 that is pulled in when reversing the sheet. For this reason, the flapper 221 can move between a first position for guiding the sheet to the reverse conveyance path 236 and a second position for guiding the sheet to the straight discharge path 237 without guiding to the reverse conveyance path 236. It has become. The straight discharge path 237 is a conveyance path that is connected to the discharge port 10 </ b> B (see FIG. 1) of the printer body 10 at the shortest distance without passing through the reverse conveyance path 236. Further, the flapper 222 is switched between a case where the sheet drawn into the reverse roller 214 is conveyed to the double-sided conveyance path 234 and a case where the sheet is conveyed in the reverse discharge direction D3.

  Since the reverse discharge mechanism 210 is configured as described above, the printer 1 can execute a straight discharge job and a reverse discharge job. A straight discharge job is a job for discharging a sheet by a straight discharge operation (hereinafter also simply referred to as straight discharge) in which the sheet is discharged while maintaining the relationship between the leading edge and the trailing edge of the sheet during image formation. is there. The reverse discharge job is a job for discharging a sheet by a reverse discharge operation (hereinafter also simply referred to as reverse discharge) in which the front and rear ends of the sheet are switched by a reverse conveyance unit. For this reason, when the sheet is discharged from the printer body 10 with the surface on which the image is formed facing up, the sheet is discharged by straight discharge. That is, in this case, the flapper 221 is switched to the second position, the sheet passes through the fixing unit 107, and is conveyed in the straight discharge path direction D1. Thereafter, the sheet is discharged from the discharge unit 200 to the sheet processing apparatus 50 outside the printer main body 10 via the conveyance roller 212. Note that the sheet conveyance speed when the sheet is discharged straight is the same as the image forming speed.

  Next, when the sheet is discharged from the printer main body 10 with the image-formed side down, the sheet is discharged by reverse discharge. That is, in this case, after the flapper 221 is switched to the first position and the sheet passes through the fixing unit 107, the sheet is conveyed in the reverse conveyance path direction D2. Thereafter, the sheet is switched back at the reverse position P2 via the reverse rollers 213 and 214. When the sheet is reversed and discharged, when the inner discharge sensor 201 detects the trailing edge of the sheet, the sheet conveyance speed is increased to a speed higher than the speed at which image formation is performed. At the time of switchback, after the reverse sensor 203 detects the leading edge of the sheet, the reverse rollers 213 and 214 are driven for a predetermined time and the sheet is drawn into the reverse conveyance path. The pull-in amount at this time is determined in advance according to the size of the sheet in the sub-scanning direction. Thereafter, after the reversing rollers 213 and 214 are temporarily stopped, the reversing rollers 213 and 214 are reversely rotated to convey the sheet in the reverse direction. The switched back sheet is conveyed in the reverse discharge direction D3 by switching the flapper 222, and is discharged from the discharge unit 200 to the sheet processing apparatus 50 connected to the printer main body unit 10 via the conveyance roller 212.

  Next, a case where image formation is performed on both sides of a sheet will be described. Even in the case of duplex printing, the same control as in the case of reverse discharge is performed until the reverse roller 214 is drawn. Thereafter, the switched-back sheet is conveyed in the double-side direction D4 by switching the flapper 222, and is conveyed to the double-sided conveyance path 234 via the conveyance rollers 215 and 216. In the case of duplex printing, the sheet conveyed to the duplex conveyance path 234 is conveyed toward the secondary transfer nip T2 and the toner image is transferred and fixed again as in the case of printing on the first surface of the sheet. . Since the sheet printed on both sides is discharged from the printer main body 10 with the last image-formed side facing up, the sheet passes through the same path as the straight discharge described above, and is discharged from the discharge unit 200 to the sheet processing apparatus 50. Discharged.

<Printer control>
Next, control of the printer 1 will be described with reference to FIG. FIG. 3 is a block diagram illustrating a configuration of the control unit 300 of the printer 1. The control unit 300 comprehensively controls the printer main body unit 10. The control unit 300 includes a CPU circuit unit 302. The CPU circuit unit 302 includes a CPU 311, a ROM 312, and a RAM 313. The control program stored in the ROM 312 controls the print job control unit 321, the operation display device control unit 322, the accessory communication unit 323, and the printer control unit 324 for each block. The CPU circuit unit 302 temporarily stores control data in the RAM 313 and uses the RAM 313 as a work area for arithmetic processing associated with control. The ROM 312 and RAM 313 form a storage unit of the printer 1, and the storage unit stores sheet size information stored in the feeding unit (feed cassette) 110. As the sheet size information, a sheet size detected by a sensor provided in the feeding unit 110 and a size designated by the user are stored as set size information.

  Next, the basic operation of the control unit 300 during the printing operation will be described. When a print instruction is input via the operation display device 20 or a PC (not shown), the CPU circuit unit 302 determines a print job to be executed and instructs the print job control unit 321 of corresponding print job information. To do. The CPU circuit unit 302 stores the print job information and further instructs the operation display device control unit 322 to display the corresponding information on the operation display device 20. Further, the CPU circuit unit 302 instructs the accessory communication unit 323 to transmit print job information to the control unit of the sheet processing apparatus 50. Further, the CPU circuit unit 302 instructs the printer control unit 324 to comprehensively control the motor control unit 331, the high voltage control unit 332, the I / O control unit 333, and the fixing control unit 334 of each block inside the printer. .

<Sheet size error detection control>
Next, detection control of the sheet size error, which is different from the set size of the sheet and the sheet size detected on the basis of the detection signal provided on the sheet conveyance path and detecting the size of the sheet being conveyed, will be described. To do. FIG. 4 is a flowchart showing detection control of a sheet size error. When starting the job, the user stacks sheets used for the job on the feeding unit 110 or the manual feed tray 40 and sets the sheet size. The set sheet size becomes the set size of the sheet, and based on this, the CPU 311 as the control unit determines the set size Lset in the sheet sub-scanning direction in S501. Next, if it is determined in S502 that the job has been started, sheet feeding is started from the feeding unit 110 or the manual feed tray 40 in S503. On the other hand, the CPU 311 starts a detection size determination flow in S504. In the present embodiment, the sheet size error detection flow and the detection size determination flow are executed in parallel.

  FIG. 8 is a flowchart showing a detection size determination flow. First, in S410, the CPU 311 determines whether or not the registration sensor 113 has detected the leading edge of the sheet. If it is determined that the sheet has been detected, length measurement in the sub-scanning direction of the sheet is started in S411. If it is determined in S412 that the registration sensor 113 has detected the trailing edge of the sheet, the detection size Ldetect in the sub-scanning direction of the sheet is determined (S413). More specifically, the CPU 311 determines the detection size Ldetect according to the equation Ldetect = T × V from the time T from when the registration sensor 113 detects the leading edge of the sheet until the trailing edge of the sheet is detected and the sheet conveyance speed V. .

  On the other hand, as shown in FIG. 4, the CPU 311 determines whether or not the detection size Ldetect has been determined in S <b> 505 of the sheet size error detection flow. If it is determined that it has been determined, in S506, the difference between the set size Lset and the detected size Ldetect is compared with the predetermined value Lthresh1. The predetermined value Lthresh1 is a predetermined threshold value, and when it is determined that the difference between the set size Lset and the detected size Ldetect is smaller than Lthresh1, it is determined that the sheet sizes match. That is, if Lset-Ldetect <Lthresh1, the sheet is discharged as it is according to the discharge job in S507. Thereafter, if it is determined in S508 that the job has been completed, the sheet size error detection flow is ended. If it is determined that the job has not ended, the process returns to S504 and the flow is repeated.

  On the other hand, if it is determined in S506 that the difference between the set size Lset and the detected size Ldetect is larger than Lthresh1, it is determined that a sheet size error has occurred. That is, if Lset−Ldetect ≧ Lthresh1, the conveyance of the sheet and the subsequent sheet is stopped in S509, and then the automatic discharge flow at the time of detecting the sheet size error is executed in S510.

  FIG. 5 is a flowchart showing an automatic discharge flow when a sheet size error is detected. First, in step S <b> 601, the CPU 311 determines whether the sheet has been discharged by a straight discharge job. If the CPU 311 determines that the job is a straight discharge job, the CPU 311 automatically discharges the sheet via the straight discharge path 237 in step S <b> 602. If the CPU 311 determines that the job is not a straight discharge job, in S603, the CPU 311 determines whether or not the leading edge of the sheet has reached the predetermined position P1. In the present embodiment, the predetermined position P1 is a position (hereinafter referred to as a switching position) for determining which of the straight discharge path 237 and the reverse conveyance path 236 is to be conveyed. Is the position.

  In the present embodiment, the inner discharge sensor 201 is a switching position detecting unit that detects a sheet at a position upstream of the flapper 221 serving as a switching unit and upstream of the sheet conveying direction and closest to the flapper 221. More specifically, the inner discharge sensor 201 conveys the sheet more than the distance at which the sheet is conveyed during the time required for the flapper 221 to switch from the first position to the second position, more than the branch point to the reverse conveyance path 236. It is located at a position upstream in the direction. The switching position is not limited to the position of the inner discharge sensor 201, and may be a switching point between the straight discharge path 237 and the reverse conveyance path 236 according to the configuration.

  If the leading edge of the sheet has not reached the predetermined position P1, the CPU 311 determines whether there is a preceding sheet in S604. If it is determined that there is no preceding sheet, the sheet is automatically discharged through the straight discharge path 237 in S602. If it is determined that there is a preceding sheet, the CPU 311 determines in S605 that the distance between the sheets Leverval with the trailing end of the preceding sheet when the outer discharge sensor 202 detects the leading end of the sheet when the sheet is discharged straight. Is calculated.

  For example, the inter-sheet distance Linterval is a time Tdiff from when the trailing edge of the preceding sheet passes the outside discharge sensor 202 until the leading edge of the sheet reaches the outside discharging sensor, and the trailing edge of the preceding sheet is the outside discharging sensor. 2 is obtained based on Vpre. When the time when the trailing edge of the preceding sheet r passes the outer discharge sensor 202 is Tpre and the time when the leading edge of the preceding sheet passes the outer discharge sensor 202 is Tcon, the time Tdiff is Tdiff = Tcon−Tpre. Further, if the speed at which the trailing edge of the preceding sheet passes the outer discharge sensor 202 is Vpre, the distance Linterval from the trailing edge of the preceding sheet at the time when the outer discharging sensor 202 detects the leading edge of the sheet is Linterval = Tdiff. * Calculated by Vpre.

  Next, in S606, Linterval is compared with a predetermined value Lthresh2. Lthresh2 is a predetermined threshold, and is, for example, the minimum distance between sheets necessary for conveying a sheet. Alternatively, when the sheet processing apparatus 50 is connected to the downstream side of the printer main body 10 in the conveyance direction, the sheet processing apparatus 50 receives the preceding sheet and then receives the sheet during the preparation time for receiving the sheet at the straight discharge speed. This is the distance that the sheet travels at the straight discharge speed.

  In this embodiment, as described above, in the case of reverse discharge, when the inner discharge sensor 201 detects the trailing edge of the sheet, the sheet conveyance speed is increased to a speed higher than the speed at which image formation is performed. The On the other hand, in the case of straight discharge, the sheet conveyance speed is the same as the speed at which image formation is performed. However, in the case of reverse discharge, it takes time to discharge because the sheet is drawn into the reverse conveyance path 236. For this reason, when the preceding sheet is reversed and discharged, if the sheet is to be discharged straight, the leading edge of the sheet may collide with the trailing edge of the preceding sheet. Alternatively, there is a possibility that the sheet processing apparatus 50 cannot receive the straight discharged sheet.

  If the CPU 311 determines that Linterval is greater than Lthresh2, the CPU 311 determines that the sheet can be discharged straight without the leading edge of the preceding sheet colliding with the trailing edge of the preceding sheet. Alternatively, it is determined that the sheet processing apparatus 50 can receive a straight discharged sheet. That is, if Linterval> Lthresh2, the process proceeds to S602, and the sheet is automatically discharged via the straight discharge path 237.

  On the other hand, if the CPU 311 determines that Linterval is equal to or lower than Lthresh2, the CPU 311 determines that the leading edge of the preceding sheet collides with the trailing edge of the preceding sheet, which may cause a jam. Alternatively, it is determined that the sheet processing apparatus 50 cannot receive a straight discharged sheet. That is, if Linterval ≦ Lthresh2, straight discharge is not performed, and the process proceeds to the reverse discharge control step in S607. In step S <b> 607, the CPU 311 executes a reverse pull-in amount determination flow.

  FIG. 6 is a flowchart showing a reversal pull-in amount determination flow. First, the CPU 311 compares the detection size Ldetect and the set size Lset in S701. In the case of reverse discharge, it is necessary to calculate the reverse position P2 in advance based on the sheet size. When the detection size Ldetect and the set size Lset are different, the reversal position P2 is calculated based on the larger one of the detection size Ldetect and the set size Lset. That is, if Ldetect <Lset, in S702, the inversion amount Lrev is determined based on the set size Lset. In the present embodiment, the amount of pulling the sheet into the reverse conveyance path by driving the reverse rollers 213 and 214 after the reversing sensor 203 detects the leading edge of the sheet is referred to as a retraction amount Lrev. That is, when the inversion margin is Lmargin, Lrev = Lset + Lmargin.

  On the other hand, if Ldetect ≧ Lset in S701, the reverse pull-in amount Lrev is determined in S703 based on the detected size Ldetect. That is, when the inversion margin is Lmargin, Lrev = Ldetect + Lmargin.

  Next, as shown in FIG. 5, the CPU 311 calculates a distance Lref from the reversing roller 214 to the reversing position P2 based on the reversing pull-in amount Lrev in the automatic discharge flow S608 at the time of detecting the sheet size error. In the present embodiment, the front end position of the sheet when the sheet is pulled into the reverse conveyance path 236 by the pull-in amount Lrev at the time of reverse is set as the reverse position P2. That is, if the distance from the reverse sensor 203 to the reverse roller 214 is L distance, Lref = Lrev−L distance.

  Next, in step S609, the CPU 311 compares Lref with the detection size Ldetect. When the distance Lref from the reversing roller 214 to the reversing position P2 is larger than the detection size Ldetect, the rear end of the sheet may pass through the reversing roller 214 and be unable to be conveyed. That is, when Lref> Ldetect, the sheet is not automatically discharged, and the automatic discharge flow at the time of detecting a sheet size error is terminated.

  On the other hand, when the distance Lref from the reversing roller 214 to the reversing position P2 is equal to or smaller than the detection size Ldetect, the sheet can be reversed without the leading end of the sheet passing through the reversing roller 214. That is, if Lref ≦ Ldetect, the sheet is automatically discharged via the reverse conveyance path 236 in S610.

  In the present embodiment, the detection size Ldetect in the sub-scanning direction of the sheet is determined using the registration sensor 113, but another sensor on the sheet conveyance path may be used. That is, the registration sensor 113 is one of a plurality of sheet sensors provided on the sheet conveyance path as detection means for detecting the size of the sheet being conveyed. The sheet size during conveyance may be detected by the other sheet sensor, or may be detected by a plurality of sheet sensors.

  As described above, after performing the automatic discharge flow at the time of detecting the sheet size error, the CPU 311 notifies the operation display device 20 or the PC (not shown) of the detection of the sheet size error in S511 of the sheet size error detection flow.

  As described above, in this embodiment, by executing automatic sheet discharge control when a sheet size error occurs, the sheet in which the sheet size error is detected can be automatically discharged, and the jam processing load on the user Can be reduced. In particular, when a sheet size error occurs in the reverse discharge job, the sheet is discharged by the straight discharge operation without performing the reverse discharge operation. For this reason, it is possible to prevent the sheet from jamming when the automatic sheet discharge control is executed.

  If a sheet size error occurs during the reverse discharge job, and the leading edge of the sheet has already reached the switching position when the sheet size error is detected, reverse discharge is performed without straight discharge. Automatic discharge control is being executed. For this reason, the sheet is prevented from jamming by uniformly changing to straight discharge.

  Further, when the sheet is automatically discharged by the reverse discharge, the sheet is reversed based on the larger one of the set size of the sheet and the detected size. For this reason, even if the size information of either the set size or the detected size is incorrect, it is possible to prevent the sheet from jamming due to a shortage of the drawing amount of the sheet.

  Further, when the sheet pull-in amount is calculated, if the sheet is pulled into the reverse conveyance path 236 by the calculated pull-in amount, whether or not the rear end of the sheet is downstream of the reverse roller 214 in the sheet conveyance direction. Is calculated. When the trailing edge of the sheet is downstream of the reverse roller 214 in the sheet conveyance direction, the automatic sheet discharge is stopped to prevent the sheet from being disabled.

  Further, when a sheet size error is detected in the reverse discharge job, even if the leading edge of the sheet does not reach the switching position at the time when the sheet size error is detected, the gap between the sheet and the preceding sheet is not detected. The distance is calculated. When the distance between the sheets is smaller than a predetermined threshold, the sheet is discharged by the reverse discharge operation, thereby preventing the sheet from catching up with the preceding sheet by straight discharge.

<Other embodiments>
Next, another example of sheet size error detection will be described. Note that this embodiment is different from the above-described embodiment in that the detection size of the sheet is detected using a plurality of detection sensors, and the drawing amount of the sheet is determined based on the plurality of detection sizes. . For this reason, in the following description, only a different point from the above-mentioned embodiment is demonstrated, and it abbreviate | omits about other description.

  As shown in FIG. 9, the CPU 311 detects the sheet size not only by the registration sensor 113 to detect the detection size Ldetect but also by the inner discharge sensor 201 on the downstream side of the registration sensor 113 in the sheet conveyance direction. Specifically, the CPU 311 determines whether or not the inner discharge sensor 201 has detected the leading edge of the sheet in S420. If it is determined that it has been detected, in step S421, length measurement in the sub-scanning direction of the sheet is started. If it is determined in S422 that the inner discharge sensor 201 has detected the trailing edge of the sheet, the detection size L2detect in the sheet sub-scanning direction is obtained as follows (S423). That is, the CPU 311 determines the detection size L2detect in the sheet sub-scanning direction as L2detect = T2 × V2 from the time T2 from when the inner discharge sensor 201 detects the leading edge of the sheet until the trailing edge of the sheet is detected and the sheet conveyance speed V2. It is determined by the following formula.

  Next, a flow for determining the reversal pull-in amount Lrev in the present embodiment will be described with reference to FIG. As shown in FIG. 7, the CPU 311 first determines whether or not the detection size L2detect has been determined in S711. If it is determined that the sheet has not been determined, the sheet is conveyed to the reverse conveyance path 236 in S712. If the detection size L2detect is determined, the conveyance of the sheet is stopped in S713. Next, the CPU 311 compares the detection sizes Ldetect and L2detect (S714). If the detected sizes Ldetect and L2detect match (Yes in S714), it is determined that the sheet size is correctly detected, and inversion control is performed based on the detected size. That is, if Ldetect = L2detect, in S715, the reverse pull-in amount Lrev is determined based on the detected size Ldetect. That is, when the inversion margin is Lmargin, Lrev = Ldetect + Lmargin.

  On the other hand, if Ldetect ≠ L2detect in S714, the CPU 311 compares the set size Lset with the detected sizes Ldetect and L2detect in S716. If the detection sizes Ldetect and L2detect do not match, it is determined that at least one detection size is a false detection. In this case, the sheet can be normally reversed by calculating the reversal position based on the largest size compared to the set size Lset. That is, if Lset> Ldetect and Lset> L2detect, in S717, the reverse pull-in amount Lrev is determined based on the set size Lset. That is, when the inversion margin is Lmargin, Lrev = Lset + Lmargin.

  On the other hand, if Lset ≦ Ldetect or Lset ≦ L2detect in S716, Ldetect and L2detect are compared in S718. That is, if Ldetect> L2detect, in S719, the reverse pull-in amount Lrev is determined based on the detected size Ldetect. That is, when the inversion margin is Lmargin, Lrev = Ldetect + Lmargin.

  On the other hand, if Ldetect ≦ L2detect in S718, the inversion amount Lrev is determined based on the detected size L2detect in S720. That is, when the inversion margin is Lmargin, Lrev = L2detect + Lmargin.

  As described above, in the present embodiment, when the sheet sizes detected based on the detection signals of at least two or more detection units match, the sheet is reversed by the reverse conveyance unit based on the detection size. Yes. By detecting the detection size of the sheet by a plurality of sheet sensors, the reverse pull-in amount Lrev of the sheet can be determined more accurately.

  In this embodiment, the detection size Ldetect in the sub-scanning direction of the sheet is determined by using the registration sensor 113 and the detection size L2detect is determined by using the inner discharge sensor 201. However, other sensors on the sheet conveyance path may be used. . Further, the number of sensors used may be further increased. In this embodiment, the branch point to the reverse conveyance path 236 is provided upstream of the sheet discharge port. However, the present invention is not limited to this. For example, the branch point is downstream of the sheet discharge port. It may be provided. In this case, the switching position is set upstream of the branch point to the sheet discharge port.

  Further, the above-described distance between sheets and the amount of sheet pull-in are not necessarily obtained as an actual distance unit, and can be obtained, for example, as a unit of time. Further, in the above-described embodiment, the configuration including the document reading device 30 and the sheet processing device 50 has been described. For example, a printer that does not include at least one of the document reading device 30 and the sheet processing device 50 is described. It can also be applied. Furthermore, the present invention can be applied not only to a full color laser printer but also to a monochrome color laser printer, and also to an ink jet printer.

1: Image forming apparatus (printer), 10A: Image forming means (image forming part), 113, 201: Detection means (registration sensor, internal discharge sensor), 213, 214: Reverse conveying means (reverse roller), 300: Control part , 312, 313: Storage means (ROM, RAM)

Claims (8)

Image forming means for forming an image on a sheet;
A detecting means provided on the sheet conveying path for detecting the size of the sheet being conveyed;
A reversing conveying unit that is provided downstream of the image forming unit in the sheet conveying direction, reverses the image formed sheet, and conveys the leading and trailing ends of the sheet;
Storage means for storing sheet size information;
A straight discharge job that discharges the sheet while maintaining the relationship between the leading edge and the trailing edge of the sheet during image formation, and a reverse discharging that discharges the sheet by switching the leading edge and the trailing edge of the sheet by the reverse conveying unit. A control unit capable of executing jobs,
When the control unit generates a sheet size error in the reverse discharge job, the set size of the sheet stored in the storage unit is different from the sheet size detected based on the detection signal from the detection unit The sheet is discharged while maintaining the relationship between the leading edge and the trailing edge of the sheet during image formation without replacing the leading edge and the trailing edge of the sheet.
An image forming apparatus. A reversing conveyance path for drawing the sheet when reversing the sheet by the reversing conveyance means;
When the control unit detects a sheet size error in the reverse discharge job, at the time of detecting the sheet size error, the leading edge of the sheet is switched upstream of the branch point to the reverse transport path on the sheet transport path. If the position has already been reached, replace the leading and trailing edges of the sheet and discharge the sheet.
The image forming apparatus according to claim 1. Switching means for switching the sheet conveyance path to the reverse conveyance path;
A switching position detecting means for detecting a sheet at a position upstream of the switching means in the sheet conveying direction and closest to the switching means,
The controller determines whether or not the sheet has reached the switching position based on whether or not the switching position detection means detects the leading edge of the sheet;
The image forming apparatus according to claim 2. Switching means capable of moving between a first position for guiding the sheet to the reverse conveyance path and a second position for not guiding the sheet to the reverse conveyance path;
The switching position is equal to or more than a distance in which the sheet is conveyed during the time required for the switching unit to switch from the first position to the second position, and upstream of the branching point to the reverse conveyance path. The position of
The image forming apparatus according to claim 2. The controller, when detecting a sheet size error in the reverse discharge job, when discharging the sheet by switching the leading edge and the trailing edge of the sheet, based on the set size of the sheet and a detection signal from the detection unit Reversing the sheet by the reversing conveyance means based on the larger one of the detected sheet sizes,
The image forming apparatus according to claim 2, wherein the image forming apparatus is an image forming apparatus. The detection means is one of a plurality of detection means provided on the sheet conveyance path,
When the control unit detects a sheet size error in the reverse discharge job and discharges the sheet by exchanging the leading edge and the trailing edge of the sheet, at least two or more detection means among the plurality of detection means When the sheet sizes detected based on the detection signal match, the sheet is reversed by the reversing conveyance unit based on the sheet size detected based on the detection signal of the detection unit,
The image forming apparatus according to claim 2, wherein the image forming apparatus is an image forming apparatus. When the sheet size error in the reverse discharge job is detected, the control unit detects the sheet even if the leading edge of the sheet has not reached the switching position at the time of detecting the sheet size error. When the inter-sheet distance between the rear end of the preceding sheet and the front end of the sheet when the front end and the rear end of the sheet are discharged without replacement is calculated, and the inter-sheet distance is smaller than a predetermined threshold Replaces the leading and trailing edges of the sheet and discharges the sheet.
The image forming apparatus according to claim 2, wherein the image forming apparatus is an image forming apparatus. When the control unit detects a sheet size error in the reverse discharge job, the control unit sets a pull-in amount for pulling the sheet into the reverse conveyance path even when the leading edge of the sheet has already reached the switching position. When the sheet is drawn into the reverse conveyance path by the calculated pull-in amount, the discharge of the sheet is stopped when the rear end of the sheet is downstream of the reverse conveyance unit in the sheet conveyance direction. ,
The image forming apparatus according to claim 2, wherein the image forming apparatus is an image forming apparatus.

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