The present invention relates to an image forming apparatus configured to form an image by an electrophotographic process, and more particularly, to an image forming apparatus configured to perform jam handling of a sheet.
With a related-art image forming apparatus, before giving a print instruction, a user can input a sheet length (length of a sheet in a conveyance direction) of a sheet to be printed through an operation unit of the image forming apparatus. Further, in another image forming apparatus, there is provided a trailing edge regulation member configured to regulate a trailing edge (edge on an upstream side in a sheet feeding direction) of a sheet stacked on a sheet feeding tray. The trailing edge regulation member can be moved in accordance with the sheet stacked on the sheet feeding tray, and the image forming apparatus can detect a sheet length of the sheet stacked on the sheet feeding tray in accordance with a position of the trailing edge regulation member. When a user inputs a sheet length which is different from that of a sheet actually stacked on the sheet feeding tray, or when a user does not move a position of the trailing edge regulation member in accordance with the sheet actually stacked on the sheet feeding tray, an incorrect sheet length is set to the image forming apparatus.
In an image forming apparatus described in Japanese Patent Application Laid-Open No. H10-194529, after a sheet is fed from a sheet feeding tray, an actual sheet length of the sheet being conveyed is detected by a sensor provided on a conveyance path. Then, the actual sheet length detected by the sensor and a preset sheet length are compared. When a difference in sheet length is beyond a predetermined range (sheet length irregularity margin), the image forming apparatus determines that sheet length irregularity is present. When the image forming apparatus determines that the sheet length irregularity is present, the image forming apparatus stops the print action and allows the sheet being conveyed to be discharged to an outside of the image forming apparatus. Then, the image forming apparatus displays information of the sheet length irregularity on a display screen of the operation unit to notify a user of the presence of the sheet length irregularity.
In recent years, for improvement in productivity of an image forming apparatus, there has been a strong demand for shortening a distance between a trailing edge of a preceding sheet and a leading edge of a following sheet (hereinafter also referred to as “distance between sheets”, “sheet-to-sheet distance”, or “sheet interval”) during conveyance as much as possible.
A top sensor 100 includes a lever as illustrated in
As described above, when the actual sheet length of the preceding sheet S1 is larger than the preset sheet length, and the trailing edge is positioned in the region L3 being a sheet length irregularity region, control to be performed later differs depending on the sheet-to-sheet distance. That is, under a state in which the sheet-to-sheet distance is long, it is determined that the sheet length irregularity is present, and hence the preceding sheet S1 is automatically discharged to the outside of the image forming apparatus. Meanwhile, even when the sheet lengths are equal, under the state in which the sheet-to-sheet distance is small, it is determined that the jam (paper jam) has occurred, with the result that jam handling by a user is required.
According to one aspect of the present invention, there is provided an image forming apparatus, in which regardless of the magnitude of a sheet interval, when an actual sheet length is longer than a set sheet length, a sheet being conveyed is discharged to an outside of the image forming apparatus without handling by a user.
According to another aspect of the present invention, there is provided an image forming apparatus including a first detection unit provided on a conveyance path for introducing a sheet from a stacking unit on which the sheet is stacked to an image forming portion for performing image formation on the sheet, and is configured to detect the sheet, a second detection unit provided downstream in a conveyance direction of the sheet with respect to the first detection unit, and is configured to detect the sheet, a first conveyance unit provided upstream in the conveyance direction with respect to the first detection unit, and is configured to convey the sheet, a second conveyance unit provided downstream in the conveyance direction with respect to the first detection unit, and is configured to convey the sheet, and a control unit configured to start drive of the first conveyance unit and the second conveyance unit in a case where a first sheet and a second sheet subsequent to the first sheet are fed from the stacking unit, the control unit being configured to stop the drive of the first conveyance unit and continue drive of the second conveyance unit in a case where the first detection unit does not detect a trailing edge of the first sheet before a first timing, and the control unit being configured to re-drive the first conveyance unit or stop the drive of the second conveyance unit in accordance with a sheet length of the first sheet in the conveyance direction in a case where the second detection unit detects the trailing edge of the first sheet before a second timing later than the first timing.
Further features of the present invention will become apparent from the following description of exemplary embodiments with reference to the attached drawings.
Now, embodiments of the present invention are described in detail with reference to the drawings.
[Detection of Sheet Length when Sheet-to-Sheet Distance is Long]
First, for comparison with the embodiments described later, description is made of a detection method for a sheet length, which is performed by a conveyance sensor configured to detect a sheet being conveyed, with reference to the drawings.
In
The region L3 is a region which leads to determination that the irregularity is present between the actual sheet length calculated by detection of the trailing edge of the preceding sheet S1 and the preset sheet length. When a length of the region (L1+L2+L3) is expressed by L(L1+L2+L3), the sheet length L(S1) of the preceding sheet S1 which leads to the determination that the sheet length irregularity is present is expressed by the size relationship of L(L1+L2)<L(S1)≤L(L1+L2+L3). As a result of detection of the actual sheet length, when the sheet trailing edge of the preceding sheet S1 is positioned in the region L3 being the sheet length irregularity region, the image forming apparatus stops the print action, and all the sheets being conveyed in the image forming apparatus are discharged to the outside of the image forming apparatus.
The region L4 is a region which leads to determination that a stay jam of the preceding sheet S1 has occurred based on the actual sheet length calculated through detection of the trailing edge of the preceding sheet S1. The sheet length L(S1) of the preceding sheet S1 which leads to the determination that the stay jam has occurred is expressed by the size relationship of L(L1+L2+L3)<L(S1). As a result of detection of the actual sheet length, when the sheet trailing edge of the preceding sheet S1 is positioned in the stay jam region L4, the image forming apparatus determines that the preceding sheet S1 stays at the top sensor 100, and stops the print action.
The regions L1 to L4 described above are regions given when the leading edge and the trailing edge of the preceding sheet S1 are detected by the top sensor 100 and the actual sheet length is calculated, and include regions which do not lead to the determination that the sheet length irregularity is present, a region which leads to the determination that the sheet length irregularity is present, and a region which leads to the determination that the stay jam has occurred. Meanwhile, the region L8 illustrated in
The top sensor 100 detects passage of the leading edge of the preceding sheet S1 when the lever is shifted from the state illustrated with the solid lines to the state illustrated with the broken lines as illustrated in
Meanwhile, the region L6 is a region in which the interval between sheets being continuously conveyed can be detected. When the sheet trailing edge of the preceding sheet S1 is positioned within the region L6, the top sensor 100 can detect the trailing edge of the preceding sheet S1 and the leading edge of the following sheet S2. Therefore, the image forming apparatus calculates the sheet length of the preceding sheet S1 based on the timing of passage of the leading edge and the trailing edge of the preceding sheet S1, which is detected by the top sensor 100, and performs the above-mentioned operation in accordance with the calculated sheet length. Further, the region L7 is a region in which the sheet length irregularity of the preceding sheet S1 with respect to the preset sheet length can be detected. As illustrated in
The table shown in
[Detection of Sheet Length when Sheet-to-Sheet Distance is Short]
Further, the table shown in
As described above, in the case in which the actual sheet length of the preceding sheet S1 is larger than the preset sheet length, and the trailing edge is positioned within the sheet length irregularity region L3, when the sheet-to-sheet distance is long, it is determined that the sheet length irregularity is present, and the preceding sheet S1 is discharged to an outside of the image forming apparatus. Meanwhile, even in the case in which the sheet lengths are equal, when the sheet-to-sheet distance (L8) is short, it is determined that the jam has occurred, with the result that jam handling by a user is required.
[Configuration of Image Forming Apparatus]
When a user inputs a print instruction through the operation unit 4 (
The image forming apparatus 1 feeds a sheet S from the sheet feeding tray of the sheet feeding cassette 2 or the manual feeding tray 3 in accordance with an instruction from a user. The sheet S fed from the sheet feeding cassette is conveyed to a registration roller pair 10 by a conveyance roller which rotates in the arrow direction in the sheet feeding portion 5. Meanwhile, the sheet S fed from the manual feeding tray 3 is conveyed to the registration roller pair 10 by a conveyance roller which rotates in the arrow direction and an intermediate conveyance roller pair 27 in the sheet feeding portion 6. At a timing at which the top sensor 100 detects the sheet S having passed through the registration roller pair 10, the image forming apparatus 1 calculates a time difference with respect to a timing at which the toner images having been transferred onto the intermediate transfer belt 23 arrive at the transfer roller 20. Then, based on the time difference having been calculated, the image forming apparatus 1 controls conveyance of the sheet S so that the toner images on the intermediate transfer belt 23 and the sheet S arrive at the transfer roller 20 at the same timing. Then, the toner images on the intermediate transfer belt 23 are transferred to the sheet S having arrived at the transfer roller 20. The exposure device 21, the process cartridges 22, the intermediate transfer belt 23, and the transfer roller 20, which are mentioned above, construct an image forming portion configured to perform image formation on the sheet S. The configuration of the top sensor 100 and the mechanism of detecting the sheet S are described above, and hence description thereof is now omitted.
The sheet S having the toner images transferred thereon is heated and pressurized in a fixing unit 30, and the toner images on the sheet S are fixed to the sheet S. The sheet S having the toner images fixed thereto passes through a fixing outlet roller 29 and a fixing outlet sensor 101 and is conveyed to the discharge roller 40. The discharge roller 40 discharges the sheet S onto a discharge tray 50 provided in an upper portion of the image forming apparatus 1 under a state in which a surface having the toner images transferred thereto (surface subjected to image formation) faces downward. The fixing outlet sensor 101 being a second detection unit has the same configuration as the top sensor 100, and is configured to detect the sheet S being conveyed.
Further, the image forming apparatus 1 includes motors 25 and 26 which are drive sources configured to drive conveyance rollers provided on the conveyance path through which the sheet S is conveyed. The motor 25 being a first drive unit drives the following conveyance rollers being a first conveyance unit provided on the conveyance path extending from the sheet feeding cassette 2 and the manual feeding tray 3 to the registration roller pair 10. That is, the motor 25 drives the conveyance roller of the sheet feeding portion 5, the conveyance roller of the sheet feeding portion 6, the intermediate conveyance roller pair 27, and the registration roller pair 10. The sheet S is fed from either one of the sheet feeding cassette 2 and the manual feeding tray 3. Therefore, clutch mechanisms (not shown) configured to transmit and cut the drive of the motor 25 are provided between the motor 25 and the conveyance roller of the sheet feeding portion 5, between the motor 25 and the conveyance roller of the sheet feeding portion 6, and between the motor 25 and the intermediate conveyance roller pair 27, respectively. Further, the motor 26 being a second drive unit drives the following conveyance rollers being a second conveyance unit provided downstream in the conveyance path with respect to the registration roller pair 10. That is, the motor 26 drives the transfer roller 20, the pressurizing roller which rotates in the arrow direction of the fixing unit 30, the fixing outlet roller 29, and the discharge roller 40. Herein, the motors 25 and 26 are each configured to drive a plurality of conveyance rollers. In the first embodiment, it is only necessary that the conveyance rollers including the registration roller pair 10 disposed upstream in the conveyance path and the conveyance rollers disposed downstream in the conveyance path with respect to the registration roller pair 10 are not driven by the same motor. Thus, the conveyance rollers may be driven by different motors, respectively.
[Detection of Sheet Length when Sheet-to-Sheet Distance is Long]
Next, detection of the sheet length of the actual sheet S being fed in the conveyance path is described. Now, with reference to
From
L(S1) [mm]=L1 [mm]+V [mm/sec]×t1 [sec]=L1 [mm]+R1 [mm] (1)
L1 represents a sheet length of the preceding sheet S1 which is preset to the image forming apparatus, and V is a conveyance speed (unit: ram/sec) of the preceding sheet S1. Further, the time period t1 is elapsed time (unit: sec), with the timing T1 at which it is estimated that the trailing edge (locus 33) of the preceding sheet S1 having the sheet length L1 passes through the top sensor 100 as a reference, to a timing at which the trailing edge (locus 32) of the preceding sheet S1 actually passes through the top sensor 100.
[Jam Detection of Preceding Sheet and Following Sheet]
Next, jam detection of the preceding sheet S1 and the following sheet S2 at the top sensor 100 is described with reference to
The time T2 (also referred to as “timing T2”) represents a theoretical timing being an estimated timing at which the leading edge of the following sheet S2 passes through the top sensor 100. In the first embodiment, the following sheet S2 is fed, after feeding of the preceding sheet S1, based on the preset sheet length L1, the margin length L2 of the sheet length, and the predetermined sheet-to-sheet distance. Further, the time T2′ (also referred to as “timing T2′”) represents a timing at which the leading edge of the following sheet S2 passes through the top sensor 100 when a delay that is determined as the delay jam occurs. When the delay amount of the following sheet S2 is less than a threshold value, the normal print action is continued. Meanwhile, when the delay amount is equal to or more than the threshold value, the locus of the leading edge of the following sheet S2 is shifted to the delay jam region side on the right side in
As mentioned above, the image forming apparatus 1 includes the fixing outlet sensor 101 configured to detect the sheet S. The fixing outlet sensor 101 is provided downstream in the conveyance path of the sheet S with respect to the fixing unit 30, and has the same configuration as the top sensor 100.
The time T3 (also referred to as “timing T3”) represents a theoretical timing (timing which can be obtained by calculation) which is an estimated timing at which the trailing edge of the preceding sheet S1 having the sheet length L1 passes through the fixing outlet sensor 101. Further, the time T3′ (also referred to as “timing T3′”) being a second timing represents a timing at which the trailing edge of the preceding sheet S1 having the sheet length of (L1+L2+L3) passes through the fixing outlet sensor 101. Also at the fixing outlet sensor 101, similarly to the top sensor 100, when the sheet length of the preceding sheet S1 is larger than (L1+L2) and equal to or smaller than (L1+L2+L3), the image forming apparatus 1 determines that the sheet length irregularity of the preceding sheet S1 is present. Meanwhile, when the sheet length of the preceding sheet S1 is larger than (L1+L2+L3), the locus of the trailing edge of the preceding sheet S1 is shifted to the jam region side on the right side in
[Control Sequence of Jam Detection]
In Step S10, the controller 60 determines whether or not the printing instructed by a user involves continuous feeding for image formation on two or more sheets S. When the controller 60 determines that the print instruction does not involve continuous feeding, the processing is terminated. When the controller 60 determines that the print instruction involves continuous feeding, the processing proceeds to Step S11.
In Step S11, the controller 60 determines whether or not the trailing edge of the preceding sheet S1 has been detected by the top sensor 100 before the timing T1′ being the above-mentioned detection timing of the jam caused by stay of the trailing edge of the preceding sheet S1. When the controller 60 determines that the trailing edge of the preceding sheet S1 has been detected by the top sensor 100 before the timing T1′, the processing is terminated. When the controller 60 determines that the trailing edge of the preceding sheet S1 has not been detected, the processing proceeds to Step S13.
The order of the timing T1′ and the timing T2′ of detecting the jam at the top sensor 100 may be set depending on the conveyance control specification of the image forming apparatus 1. The flowchart of
In Step S13, in order to stop the conveyance of the preceding sheet S1 or the following sheet S2, the controller 60 stops drive of the motor 25 to stop the registration roller pair 10 and conveyance rollers which are provided upstream in the conveyance path with respect to the registration roller pair 10. At this time, when the trailing edge of the preceding sheet S1 passes through the registration roller pair 10, the preceding sheet S1 is conveyed on the conveyance path as it is by the conveyance rollers that are provided downstream in the conveyance path with respect to the registration roller pair 10 and driven by the motor 26.
In Step S14, the controller 60 determines whether or not the fixing outlet sensor 101 has detected the trailing edge of the preceding sheet S1 before the timing T3′ being the above-mentioned detection timing for the jam caused by stay of the trailing edge of the preceding sheet S1. When it is determined that the fixing outlet sensor 101 has detected the trailing edge of the preceding sheet S1 before the timing T3′, the controller 60 allows the processing to proceed to Step S17. When the fixing outlet sensor 101 has not detected the trailing edge of the preceding sheet S1 before the timing T3′, the controller 60 allows the processing to proceed to Step S15. In Step S15, the controller 60 determines that preceding sheet S1 stays at the top sensor 100 or downstream in the conveyance path with respect to the top sensor 100, and stops drive of the motor 26. With this action, in addition to the above-mentioned processing in Step S13, the conveyance rollers provided downstream in the conveyance path with respect to the registration roller pair 10 are also stopped, thereby stopping all of the conveyance rollers on the conveyance path. In Step S16, the controller 60 displays jam information on a display screen of the operation unit 4 to notify a user of the occurrence of the jam, and terminates the processing.
In Step S17, the controller 60 calculates an actual sheet length of the preceding sheet S1 based on the timings at which the fixing outlet sensor 101 has detected the leading edge and the trailing edge of the preceding sheet S1. Now, description is made of a method of calculating the actual sheet length of the preceding sheet S1 based on the detection result of the preceding sheet S1 by the fixing outlet sensor 101.
In
Further, the time T3 (also referred to as “timing T3”) represents a timing at which the trailing edge of the preceding sheet S1 passes through the fixing outlet sensor 101 when the sheet length of the preceding sheet S1 is L1. The time T3 is a theoretical timing, and the controller 60 can determine the time T3, for example, by the following method. The controller 60 adds, to the time at which the fixing outlet sensor 101 detects the leading edge of the preceding sheet S1, the time obtained by dividing the length L1 of the preceding sheet S1 by the conveyance speed of the transfer roller 20. In such a manner, the controller 60 can calculate the above-mentioned time T3.
Further, the time period t3 represents a time difference between the time T3 and the time at which the trailing edge of the actual preceding sheet S1 passes through the fixing outlet sensor 101. In
L(S1) [mm]=L1 [mm]+V [mm/sec]×t3 [sec]=L1 [mm]+R3 [mm] Expression (2)
In Step S18, the controller 60 determines whether or not the actual sheet length L(S1) of the preceding sheet S1 calculated in Step S17 is within a predetermined length being equal to or smaller than the length (L1+L2) obtained by adding the margin length L2 to the preset sheet length L1 (or within a range of the predetermined sheet length). When the controller 60 determines that the actual sheet length L(S1) is equal to or smaller than (L1+L2), the controller 60 determines that the sheet interval could not be detected by the top sensor 100 because the following sheet S2 has reached the top sensor 100 too early, and allows the processing to proceed to Step S19. Meanwhile, when the controller 60 determines that the actual sheet length L(S1) is larger than the length (L1+L2), the controller 60 determines that the sheet interval could not be detected by the top sensor 100 because the actual sheet length of the preceding sheet S1 is excessively large (sheet length irregularity), and allows the processing to proceed to Step S21.
In Step S19, in order to stop conveyance of the preceding sheet S1, the controller 60 stops drive of the motor 26 to stop the conveyance rollers provided downstream in the conveyance path with respect to the registration roller pair 10. With this action, the drive of the motors 25 and 26 is stopped, thereby stopping all of the conveyance rollers on the conveyance path. In Step S20, the controller 60 displays jam information on the display screen of the operation unit 4 to notify a user of the occurrence of the jam, and terminates the processing.
In Step S21, the controller 60 determines that the sheet length of the preceding sheet S1 is irregular with respect to the preset sheet length but no jam has occurred. Then, the controller 60 drives again (re-drives) the motor 25 and discharges the following sheet S2 to the discharge tray 50. In Step S22, the controller 60 displays sheet length irregularity information on the display screen of the operation unit 4 to notify a user, and terminates the processing.
As mentioned above, when the sheet-to-sheet distance becomes smaller due to a large actual sheet length, and thus the top sensor 100 cannot detect the sheet interval, only the conveyance of the following sheet S2 is stopped, and the sheet interval is increased. With this action, the actual sheet length of the preceding sheet S1 can be detected at the fixing outlet sensor 101. As a result, even when the sheet interval cannot be detected by the top sensor 100 due to the actual sheet length which is excessively larger than the preset sheet length, the image forming apparatus can discharge the preceding sheet S1 and the following sheet S2 to an outside of the image forming apparatus. With this action, in the case of the sheet length irregularity, a user is not required to perform jam handling of the sheet staying in the image forming apparatus, thereby being capable of improving the usability.
As described above, according to the first embodiment of the present invention, regardless of the magnitude of the sheet interval, when the actual sheet length is larger than the set sheet length, the sheets being conveyed can be discharged to the outside of the image forming apparatus without handling by a user.
In the first embodiment, the actual sheet length is calculated based on elapsed time from detection of the leading edge of the sheet to detection of the trailing edge of the sheet by the top sensor 100 or the fixing outlet sensor 101. In a second embodiment of the present invention, description is made of a method of calculating the sheet length based on the rotation number of the motor configured to drive the conveyance rollers for conveying the sheet S.
[Detection of Sheet Length]
In the second embodiment, a pulse motor (also referred to as “stepping motor”) driven in accordance with pulse signals is used as the motor 25 configured to drive the conveyance rollers including the registration roller pair 10 disposed upstream in the conveyance path. The distance by which the preceding sheet S1 is conveyed per pulse signal by rotation of the motor 25 in accordance with the pulse signal is Ls. Further, with the above-mentioned timing T1 as a reference, the number of steps of the motor 25 until the top sensor 100 actually detects the trailing edge of the preceding sheet S1 (the number of pulse signals input to the motor 25) is S. The sheet length L(S1) of the preceding sheet S1 described with Expression (1) in the first embodiment can be calculated by Expression (3) described below with use of the conveyance distance Ls and the number of steps S of the motor 25.
L(S1) [mm]=L1 [mm]+Ls [mm/step]×S[step] (3)
As mentioned above, in the second embodiment, through the use of the number of steps of the motor 25, the actual sheet length can be calculated regardless of the conveyance speed of the sheet S. In the above, description is made of the case in which the motor 25 is the pulse motor. However, it may also be applied to the case in which the motor 26 is the pulse motor. In the second embodiment, description is made of the example in which the pulse motor is used for the motor 25. However, for example, the actual sheet length can be calculated also by providing an encoder configured to measure the rotation number of the motor to the motors 25 and 26. For example, the distance by which the sheet S is conveyed per second can be calculated by measuring the rotation number of the motor 25 per second, and multiplying the measured rotation number by the distance by which the preceding sheet S1 is conveyed per rotation. Then, the calculated conveyance distance per unit time (1 second) is multiplied by the time difference between the time at which the trailing edge of the preceding sheet S1 having the preset sheet length passes through the top sensor 100 and the time at which the trailing edge of the actual preceding sheet S1 passes through the top sensor 100. A preset sheet length is added to the calculated difference between the preset sheet length and the actual sheet length, thereby being capable of calculating the actual sheet length of the sheet S.
As described above, according to the second embodiment, regardless of the magnitude of the sheet interval, when the actual sheet length is larger than the set sheet length, the sheets being conveyed can be discharged to an outside of the image forming apparatus without handling by a user.
While the present invention has been described with reference to exemplary embodiments, it is to be understood that the invention is not limited to the disclosed exemplary embodiments. The scope of the following claims is to be accorded the broadest interpretation so as to encompass all such modifications and equivalent structures and functions.
This application claims the benefit of Japanese Patent Application No. 2017-084430, filed Apr. 21, 2017, which is hereby incorporated by reference herein in its entirety.
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