The present invention relates to image forming apparatuses, such as a copying machine, a printer, and a facsimile machine.
In recent years, some image forming apparatuses, such as a copying machine, a printer, and a facsimile machine, discharge and stack printed sheets heated by a fixing device in a high temperature state due to miniaturization of an apparatus, improvement of productivity, etc. In the meantime, a melting point of toner is lowering for saving power. Particularly in a case of double-sided printing, toners of printed sheets stacked up-and-down may printed matter may fuse to each other, so that the printed sheets are adhered. Such a phenomenon is referred to as discharged sheet adhesion (blocking). Separation of adhered sheets may peel off toner.
In order to prevent the discharged sheet adhesion beforehand, a conventional image forming apparatus takes countermeasures, such as reduction of productivity and lowering of a discharge temperature of a printed sheet. For example, Japanese Laid-Open Patent Publication (Kokai) No. 2003-302875 (JP 2003-302875A) discloses a technique that aborts printing or changes print sequence, such as a discharge interval or a process speed, on the basis of a temperature of printed sheets discharged and stacked on a discharge tray that is detected by a temperature sensor provided in the discharge tray.
However, the technique disclosed in the above-mentioned publication is able to prevent the discharged sheet adhesion but causes a new problem that the productivity is lowered.
The present invention provides an image forming apparatus that is capable of preventing the discharged sheet adhesion while reducing degradation of the productivity.
Accordingly, an aspect of the present invention provides an image forming apparatus comprising a print unit configured to print an image on a sheet based on a print job, a fixing unit configured to fix the image printed on the sheet to the sheet, a discharge tray to which the sheet to which the image is fixed is discharged, a counter configured to count discharged sheet number that is the number of sheets discharged to the discharge tray during a continuous print operation, a controller configured to control the print unit so as to lower productivity that is discharging sheet number per unit time in response to increase in the discharged sheet number counted by the counter and so as to recover the productivity in a case where the sheets discharged to the discharge tray are removed in a state where the productivity is lowered.
According to the present invention, the discharged sheet adhesion is prevented while reducing degradation of the productivity.
Further features of the present invention will become apparent from the following description of exemplary embodiments with reference to the attached drawings.
Hereafter, embodiments according to the present invention will be described in detail with reference to the drawings.
A cassette 70 that is a sheet feeding port for feeding the sheet P is arranged in a lower part of the printer 100. The cassette 70 is constituted so as to be freely opened and closed in order to set the sheet P to the cassette 70 concerned. An opening/closing state of the cassette 70 is detected by a cassette opening/closing sensor 74.
The sheet P stored in the cassette 70 is separated and fed one by one by a cassette feed roller 71 and a separation means (not shown). The sheet P fed from the cassette 70 is conveyed by a cassette conveying roller pair 72 and a conveying roller pair 10, and is sent to the registration roller unit 20.
The sheet P sent to a registration roller unit 20 is conveyed to the primary transfer portion T at a timing that synchronizes with the toner image formed on the image bearing member 31 by the registration roller unit 20 and the toner image is transferred to the sheet P concerned at the transfer unit T.
The sheet P to which the toner image was transferred is conveyed to the fixing device 4, and the image is fixed to the sheet P by heating and pressurizing. The sheet P to which the image was fixed is conveyed to a discharge roller pair 52 by a fixing conveying roller pair 41 when a branch flapper 51 is switched to a direction toward a discharge unit 5. The sheet P is discharged by the discharge roller pair 52, and is stacked on the discharge unit 5 in a page order. The sheet P that is discharged and stacked on the discharge unit 5 is detected by a discharged sheet sensor 53.
In a case of double-sided printing, the sheet P to which an image was formed on a first surface thereof is conveyed by the fixing conveying roller pair 41 and is transferred to a double-sided conveying roller pair 61 when a conveyance path is switched to a direction toward a double-sided unit 6 by the branch flapper 51. The sheet P transferred to the double-sided conveying roller pair 61 is conveyed by to a reversing roller pair 62 by the double-sided conveying roller pair 61.
The sheet P conveyed to the reversing roller pair 62 is further conveyed. When the rear end of the sheet P passes over the double-sided conveying roller pair 61 and arrives at a predetermined sheet reversing position R, the reversing roller pair 62 stops. After that, the reversing roller pair 62 is reversed to reverse and convey the sheet P to a re-feeding roller pair 64.
The sheet P conveyed by to the re-feeding roller pair 64 is further conveyed by the re-feeding roller pair 64. When the front end of the sheet P arrives at a paper-re-feeding standby position S, the re-feeding roller pair 64 stops. After that, the re-feeding roller pair 64 restarts at a predetermined timing when the printing to the second surface of the sheet P is enabled. The sheet P is conveyed to the registration roller unit 20 and an image is formed on the second surface in the same manner as the image formation to the first surface.
The sheet P to which the images were formed on the both surfaces thereof is conveyed to the discharge roller pair 52 by rotating the fixing conveying roller pair 41 when the branch flapper 51 is switched to the direction toward the discharge unit 5. After that, the sheet P is discharged to the discharge unit 5 by the discharge roller pair 52.
Next, a control system of the printer 100 will be described.
As shown in
The I/F 260 consists of USB and LAN. The CPU 1000 receives image data sent from the external apparatus 1100 like a PC through the I/F 260, develops the image data to bit data needed to print, obtains print information (print job), and controls the printer 100.
An ID number 401 is information for identifying image data for every page. A sheet size 402 designates length and width of a sheet that is subjected to printing in millimeters. Sheet-feeding-port information 403 designates a sheet feeding port from which a sheet is fed. Discharge-port information 404 designates a discharge port to which a printed sheet is discharged.
A print mode 405 is prepared for designating control corresponding to a basis weight (g/m2) of a sheet or a type of a sheet. The print mode is selected from among a thin paper mode, normal paper mode, thick paper mode, coat paper mode, etc. A print job using thick paper or coat paper tends to cause discharged sheet adhesion in comparison with a print job using normal paper. A user sets up the type of a sheet through the operation unit 250, for example. It should be noted that a mode may be selected according to a determination result of a sensor (sheet determination unit) that is provided to determine a type of a sheet.
Referring back to
The heater drive unit 240, heater 241, main thermistor 242, and sub-thermistor 243 are components of the fixing device 4. The heater drive unit 240 controls electricity of the heater 241 according to instructions from the CPU 1000. The main thermistor 242 and the sub-thermistor 243 detect temperature of the fixing device 4. The detection results of the main thermistor 242 and the sub-thermistor 243 are used for fixing control of the printer unit 1010. The discharged sheet sensor 53 detects whether the sheet P is loaded on the discharge unit 5. The operation unit 250 is used to display the print information and a progress state, and to set up various conditions of the printer.
Next, a print process executed by the printer 100 in
As shown in
The CPU 1000 determines whether the print mode in the print job concerned is a double-sided printing mode (the step S104). As a result of the determination in the step S104, when the print mode is not the double-sided printing mode but a single-sided printing mode (“NO” in the step S104), the CPU 1000 executes single-sided printing (step S106), and returns the process to the step S103 after that.
In the meantime, as a result of the determination in the step S104, when the print mode is the double-sided printing mode (“YES” in the step S104), the CPU 1000 executes double-sided printing (step S105). After executing the double-sided printing (the step S105), the CPU 1000 proceeds with the process to step S110 and increments the discharged sheet number N by one.
Next, the CPU 1000 determines whether the discharged sheet number N exceeds “40” (step S111).
It should be noted that the discharging sheet number per unit time (it is called productivity) is lowered when the discharged sheet number N exceeds a first predetermined value “50” that is a threshold, for example, in order to prevent discharged sheet adhesion. Accordingly, when the discharged sheet number N exceeds “40” that is fewer than the first predetermined value “50”, a message is displayed. However, the value “40” and the first predetermined value “50” may be changed according to the toner use amount that the CPU 1000 calculates and the type of the printing sheet. It should be noted that the first predetermined value “50” is smaller than the maximum number of sheets that are allowed to be stacked on a discharge tray. As a result of the determination in the step S111, when the discharged sheet number N exceeds “40” (“YES” in the step S111), the CPU 1000 proceeds with the process to step S112. That is, the CPU 1000 displays a message showing that removal of sheets stacked on the discharge tray (the discharge unit 5) avoids lowering the discharging sheet number per unit time (productivity) on the display screen of the operation unit 250 (step S112).
As a result of the determination in the step S113, when the “YES” button is pressed (“YES” in the step S113), the CPU 1000 suspends print operation (step S114). Suspension of the print operation facilitates the removal of the sheets discharged and stacked on the discharge tray by the user. When the “YES” button in
After suspending the print operation (the step S114), the CPU 1000 displays a message for checking whether the sheets on the discharge tray have been removed on the display screen of the operation unit 250 (step S115).
Next, the CPU 1000 determines whether the “Confirmation” button in
After that, when the sheets P are removed and the “Confirmation” button is pressed (“YES” in the step S116), the CPU 1000 clears the discharged sheet number N stored in the RAM 1002 to “0” (step S117). Next, the CPU 1000 restarts printing (step S118) and erases the message displayed on the display screen (step S119).
After eliminating the message displayed on the display screen (the step S119), the CPU 1000 proceeds with the process to step S130 and determines whether the discharged sheet number N exceeds “50” (the step S130). At this time, since the sheets P on the discharge tray are removed in the step S116 and the discharged sheet number N is cleared to “0” in the step S117, the discharged sheet number N becomes “50” or less (“NO” in the step S130). Accordingly, the CPU 1000 proceeds with the process to step S131, continues the print job without lowering the productivity (step S131), and returns the process to the step S103 after that.
In the meantime, as a result of the determination in the step S111, when the discharged sheet number N is not more than “40” (“NO” in the step S111), the CPU 1000 proceeds with the process to step S130. That is, the CPU 1000 determines whether the discharged sheet number N exceeds “50” (step S130). At this time, since the discharged sheet number N is not more than “40”, the determination in the step S130 is “NO”. Accordingly, the CPU 1000 proceeds with the process to the step S131, continues the printing without lowering the productivity, and returns the process to the step S103.
Moreover, as a result of the determination in the step S113, the “YES” button is not pressed (“NO” in the step S113), the CPU 1000 proceeds with the process to the step S130 and determines whether the discharged sheet number N exceeds “50” (step S130). Hereinafter, the steps S130, S131, S103 through S105, S110 through S113, and S130 are repeated, and the discharged sheet number N increases one by one in the step S110.
When the discharged sheet number N exceeds “50”, the determination in the step S130 becomes “YES”. Then, the CPU 1000 proceeds with the process to step S132 and determines whether the discharged sheet number N is less than “120” (the step S132). As a result of the determination in the step S132, when the discharged sheet number N is less than “120” (“YES” in the step S132), the CPU 1000 lowers the productivity to a first productivity down level (step S133), and then, returns the process to the step S103 to continue the print job.
In the meantime, as a result of the determination in the step S132, when the discharged sheet number N becomes “120” or more (“NO” in the step S132), the CPU 1000 proceeds with the process to step S134 and lowers the productivity to a second productivity down level. The second productivity down level (second level) is lower in the productivity (smaller in the discharging sheet number per unit time) than the first productivity down level (first level). When the number of stacked sheets P increases because the sheets are not removed from the discharge tray, the productivity should be lowered more in order to prevent from causing the discharged sheet adhesion.
As shown in
Referring back to
According to the process in
Moreover, according to the first embodiment, since it is not necessary to provide an incidental facility like a sheet cooling fan in the discharge tray (discharge unit 5), there is no special cost increase for preventing the discharged sheet adhesion, which prevent the size of the apparatus from increasing.
In the first embodiment, when a user does not remove the sheets P at the time point when the discharged sheet number N exceeds the first predetermined value, the productivity is lowered once when the discharged sheet number N exceeds “50” (the first predetermined value), for example. Moreover, when the discharged sheet number N became more than “120” (the second predetermined value) that is a threshold, for example, the productivity is further lowered. If the user removes the sheets P, the productivity will be recovered after that. This minimizes the degradation of productivity while preventing the discharged sheet adhesion.
In the first embodiment, a print job is a print job in the double-sided printing mode, for example. Although the double-sided printing mode tends to cause the discharged sheet adhesion because the toner of the sheets discharged to the discharge tray directly contact, the first embodiment is effective even for such a case.
Next, a second embodiment of the present invention will be described.
A hardware configuration of an image forming apparatus according to the second embodiment is identical to the hardware configuration of the image forming apparatus according to the first embodiment.
As shown in
The CPU 1000 determines whether the print mode in the print job concerned is the double-sided printing mode (the step S204). As a result of the determination in the step S204, when the print mode is not the double-sided printing mode but the single-sided printing mode (“NO” in the step S204), the CPU 1000 executes the single-sided printing (step S206), and returns the process to the step S203 after that.
In the meantime, as a result of the determination in the step S204, when the print mode is the double-sided printing mode (“YES” in the step S204), the CPU 1000 executes the double-sided printing (step S205). After executing the double-sided printing (the step S205), the CPU 1000 increments the discharged sheet number N by one (step S207).
Next, the CPU 1000 determines whether the discharged sheet number N exceeds “50” (step S208). It should be noted that the first predetermined value “50” may be changed according to the toner use amount that is calculated by the CPU 1000.
As a result of the determination in the step S208, when the discharged sheet number N does not exceed “50” (“NO” in the step S208), the CPU 1000 prints without lowering the productivity (step S209) and returns the process to the step S203 after that.
In the meantime, as a result of the determination in the step S208, when the discharged sheet number N exceeds “50” (“YES” in the step S208), the CPU 1000 proceeds with the process to step S210 and determines whether the discharged sheet number N is less than “120” (step S210). As a result of the determination in the step S210, when the discharged sheet number N is less than “120” (“YES” in the step S211), the CPU 1000 lowers the productivity to the first productivity down level (step S211), and then, returns the process to the step S220.
Moreover, as a result of the determination in the step S210, when the discharged sheet number N is “120” or more (“NO” in the step S210), the CPU 1000 lowers the productivity to the second productivity down level (step S212) and proceeds with the process to the step S220 after that. It should be noted that the second productivity down level is set to lower the productivity rather than the first productivity down level.
In the step S220, the CPU 1000 displays a message showing that “removal of sheets stacked on the discharge tray raises the productivity” so as to call user's attention on the display screen of the operation unit 250.
After displaying the message, the CPU 1000 determines whether the “YES” button is pressed in the display screen in
In the meantime, as a result of the determination in the step S221, when the “YES” button is not pressed (“NO” in the step S221), the CPU 1000 returns the process to the step S203 and determines whether there is a print job.
As a result of the determination in the step S203, when there is no print job (“NO” in the step S203), the CPU 1000 erases the message displayed on the display screen (the step S230) and finishes the print operation (step S231). The message erased in the step S230 is displayed in the step S220.
According to the process in
In the meantime, when the sheets P on the discharge tray are removed according to the message that calls for attention after lowering the productivity (“YES” in the step S221), the discharged sheet number N is cleared to “0”, and then, the lowered productivity is recovered to the state earlier than lowering (the step S208 to S209).
As mentioned above, according to the second embodiment, the removal of the sheets P stacked on the discharge tray recovers the productivity to the initial productivity 30 ipm even when the productivity is once lowered at the time point when the discharged sheet number N exceeds “50” to prevent the discharged sheet adhesion. This prevents the discharged sheet adhesion while minimizing degradation of the productivity. Moreover, there is a merit that user's stress resulting from the lowered productivity is reduced.
It should be noted that a user cannot know that the productivity is lowered for countermeasure against the discharged sheet adhesion in a conventional apparatus. Moreover, since a user did not know a solution for the discharged sheet adhesion, a print operation continues in a state where the productivity is lowered. The second embodiment improves the productivity by avoiding such inconvenience.
Moreover, although the process (the steps S113 and S114 in
Next, a third embodiment of the present invention will be described.
The image forming apparatus according to the third embodiment uses the discharged sheet sensor 53 provided in the discharge unit 5 for controlling the productivity.
As with the second embodiment, the CPU 1000 receives a print job from the external device 1100 through the I/F 260. Next, the CPU 1000 starts the received print job.
A procedure in
As a result of the determination in the step S208, when the level of the productivity is not lowered (the step S209), the CPU 1000 proceeds with the process to the step S320. Moreover, when the productivity is lowered to the first productivity down level (the step S211) or the second productivity down level (the step S212) through the determinations in the steps S208 and S210, the CPU 1000 proceeds with the process to the step S320.
Then, the CPU 1000 determines whether there is no sheet P on the discharge tray on the basis of the detection result of the discharged sheet sensor 53 provided in the discharge tray in the step S320. As a result of the determination in the step S320, when there is no sheet P on the discharge tray (“YES” in the step S320), the CPU 1000 clears the discharged sheet number N to “0” (step S321) and returns the process to the S203 after that.
In the meantime, as a result of the determination in the step S320, when there are the sheets P on the discharge tray (“NO” in the step S320), the CPU 1000 returns the process to the step S203 as-is without clearing the discharged sheet number N to “0”.
When the detection result of the discharged sheet sensor 53 provided in the discharge tray shows that there is no sheet (“YES” in the step S320), the discharged sheet number N is cleared to “0” in the step S321 according to the process in
In the meantime, when the user does not remove the sheets P from the discharge tray, the productivity is lowered (the steps S211 and S212) in order to prevent the discharged sheet adhesion.
As mentioned above, the discharged sheet sensor 53 detects whether the sheets P are removed from the discharge tray, and the productivity is controlled on the basis of the detection result in the third embodiment. This facilitates the determination of whether the sheets P are removed from the discharge tray and enables to control the productivity appropriately, which prevents the discharged sheet adhesion beforehand while minimizing the degradation of the productivity.
It should be noted that removal of sheets stacked on the discharge tray by a user is a part of a series of actions in the print operation Accordingly, the third embodiment reduces the degradation of the productivity accompanying the countermeasure against the discharged sheet adhesion because a user removes the sheets on the discharge tray without any special consciousness. Moreover, both the keeping of the productivity and the prevention of the discharged sheet adhesion are achieved without increasing cost by the simple method of removing the sheets on the discharge tray by a user.
Moreover, since the discharged sheet sensor 53 provided in the discharge tray is not used for checking the removal of sheets in the first and second embodiments, the control methods described in the first and second embodiments are executable even if the discharged sheet sensor 53 is not provided.
Moreover, the discharged sheet sensor 53 that detects the removal of sheets may be used in place of the confirmation button for checking the removal of sheets in the first embodiment. Moreover, the process of the first embodiment may be changed so that the process proceeds to the step S117 when the discharged sheet sensor 53 detects that there is no sheet and when the user presses the confirmation button.
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. 2017-201952, filed Oct. 18, 2017, which is hereby incorporated by reference herein in its entirety.
Number | Date | Country | Kind |
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2017-201952 | Oct 2017 | JP | national |