JP4979311B2 - Image forming apparatus - Google Patents

Description

  The present invention relates to an image forming apparatus having a normal operation mode in which an image forming operation can be performed by an image forming unit and a power saving operation mode with lower power consumption than the normal operation mode, and in particular, in the power saving operation mode, The present invention relates to an image forming apparatus in which input of a clock signal to an engine control unit that controls the image forming unit is stopped.

The operation modes of image forming apparatuses such as copiers, facsimile machines, printers, and multi-function machines include the normal operation mode in which normal image forming operations are performed, and the supply of power to fixing heaters and various sensors is shut off. Therefore, there is a power saving operation mode for reducing power consumption.
These operation modes are switched and controlled based on preset mode switching conditions by a main control unit that performs overall control of the image forming apparatus. For example, when there is no document image data or print data input in the normal operation mode for a predetermined time or longer, the mode is switched to the power saving operation mode, and the user performs a copy operation (opening / closing operation of the document cover) in the power saving operation mode. Or a copy start pressing operation, etc.), the normal operation mode is switched.

On the other hand, the image forming apparatus includes an engine control unit that controls an image forming unit that performs image formation, separately from the main control unit. Here, the main control unit can operate in the power saving operation mode, but the engine control unit may be completely stopped for the purpose of reducing power consumption in the power saving operation mode as much as possible. (For example, see paragraphs [0125] to [0136] of Patent Document 1).
For example, as described in Patent Document 1, when the input of the clock signal to the engine control unit is stopped, the operation of the engine control unit is stopped. In this case, since the engine control unit is not operating, even if a control signal is input to the engine control unit, the engine control unit cannot execute processing based on the control signal.
Therefore, at the time of switching from the power saving operation mode to the normal operation mode, the main control unit resets the engine control unit (instant power supply switching operation). As a result, the engine controller reproduces the state when the image forming apparatus is turned on in a pseudo manner. Then, the engine control unit restarted by the reset executes various return (wake-up) processes such as memory initialization, calibration process, and aging process, similar to when the image forming apparatus is powered on. Is done.
As described above, in the configuration in which the engine control unit is reset at the time of switching to the normal mode, the same return processing is executed both when the image forming apparatus is powered on and at the time of switching to the normal operation mode. This is because the engine control unit cannot determine whether the cause of the restart of the engine control unit is the power-on of the image forming apparatus or the reset when switching to the normal operation mode. is there.
JP 2004-42639 A

By the way, the restoration process executed in the engine control unit when the image forming apparatus is powered on may include a procedure that does not need to be executed when switching from the power saving operation mode to the normal operation mode. . For example, calibration processing and aging processing executed when the image forming apparatus is turned on can be omitted when switching to the normal operation mode.
However, conventionally, only the same restoration processing can be executed when the image forming apparatus is turned on and when switching to the normal operation mode, and more than necessary processing is executed when switching to the normal operation mode. Therefore, there is a problem that the time required for the return processing is unnecessarily long.
Accordingly, the present invention has been made in view of the above circumstances, and the object of the present invention is to stop the input of a clock signal to the engine control unit during the power saving operation mode and to control the engine when switching to the normal operation mode. An object of the present invention is to provide an image forming apparatus in which the reset process executed when switching to the normal operation mode can be simplified compared to when the power of the image forming apparatus is turned on.

To achieve the above object, the present invention provides an image forming unit that performs an image forming operation based on input image data, an image forming control unit that controls the image forming unit in accordance with an input clock signal, and a preset value. A mode for switching the operation mode of the image forming apparatus between a normal operation mode in which an image forming operation by the image forming unit can be performed and a power saving operation mode in which power consumption is lower than that of the normal operation mode in accordance with the set mode switching condition The clock signal is input to the image forming control means in the normal operation mode and the switching means, and the clock signal is input to the image forming control means in the power saving operation mode and when the image forming apparatus is turned off. a clock signal control means for stopping, electricity to the image forming control means from the power saving operation mode upon switch-over to the normal operation mode It is one that is applied to an image forming device including a reset means for setting a reset flag to a state indicating that it is reset and executes a reset to instantaneous interruption of the supply, the power supply of the image forming apparatus When a predetermined preparation completion signal is input from the image formation control means after being turned on, if the reset flag is not reset, a first return processing signal is sent to the image formation control signal. After the image forming control unit is reset by the reset unit and when a predetermined preparation completion signal is input from the image forming control unit, the reset flag is reset. In some cases, a second return processing signal different from the first return processing signal is input to the image forming control means.
The image formation control unit executes the first return process when the first return process signal is input, and the first return process when the second return process signal is input. It is comprised so that the 2nd return process simplified rather than may be performed.
Specifically, the second return process is simplified more than the first return process by omitting the calibration process and the aging process included in the first return process.
In the image forming apparatus configured as described above, different return processing signals (first return processing signal and second return processing signal) when the image forming apparatus is turned on and when the image forming apparatus is switched to the normal operation mode. Is input to the image formation control unit (corresponding to the engine control unit). As a result, the image formation control unit can determine the difference between when the image forming apparatus is turned on and when the image forming apparatus is switched to the normal operation mode. The second return process simplified than the return process can be executed, and the time required for the return process can be shortened.

  In addition to timing the stop time of the clock signal separately from the image forming control means, and providing a time notifying means for notifying the image forming control means of the stop time, the image forming control means The contents of the first return process and the second return process can be changed based on the stop time notified by the time measuring means. Thereby, for example, the execution time of the aging process can be appropriately changed according to the stop time of the clock signal.

According to the present invention, a different return processing signal (first return processing signal, second return processing signal) is generated when the image forming apparatus is powered on and switched to the normal operation mode. Input to (corresponding to the engine control unit), the image formation control unit can determine the difference between when the image forming apparatus is turned on and when it is switched to the normal operation mode. At the time of switching to the normal operation mode, the second return process simplified than the first return process can be executed, and the time required for the return process can be shortened.
In addition to timing the stop time of the clock signal separately from the image forming control means, and providing a time notifying means for notifying the image forming control means of the stop time, the image forming control means The contents of the first return process and the second return process can be changed based on the stop time notified by the time notification means. For example, the execution time of the aging process is set to the stop time of the clock signal. It can be changed appropriately according to the situation.

Hereinafter, embodiments of the present invention will be described with reference to the accompanying drawings so that the present invention can be understood. The following embodiment is an example embodying the present invention, and does not limit the technical scope of the present invention.
FIG. 1 is a block diagram showing a schematic configuration of an image forming apparatus X according to an embodiment of the present invention. FIG. 2 is a diagram for explaining an example of a procedure of mode switching processing executed in the image forming apparatus X. A flowchart and FIG. 3 are flowcharts for explaining an example of a return switching process executed in the image forming apparatus X.
First, the schematic configuration of the image forming apparatus X according to the embodiment of the present invention will be described with reference to FIG. The image forming apparatus X is, for example, a copying machine, a facsimile machine, a printer device, a multifunction machine, or the like.

  As shown in FIG. 1, an image forming apparatus X according to an embodiment of the present invention includes a CPU, peripheral devices such as a ROM and a RAM, and executes processing according to a predetermined program stored in the ROM. A main control unit 1 for comprehensively controlling the image forming apparatus X, a display / operation unit 2 having a liquid crystal display, a touch panel and the like for performing various displays and operations, and an image reading device (scanner device, etc.) not shown. And an image processing unit 3 that performs predetermined image processing on image data input from the outside, an image forming unit 4 that performs an image forming operation based on the image data input from the image processing unit 3, and the main control unit 1 generates a clock signal having an arbitrary frequency in accordance with an instruction from 1 (an example of the clock signal control means) and inputs from the clock signal control unit 5 Is schematically configured to include an engine control unit 41 for controlling (in synchronization with) the image forming unit 4 (an example of an image forming control unit), the according to the clock signal.

The image forming unit 4 includes an exposure device such as a laser scanning unit, a photosensitive drum exposed by the exposure device, and an electrostatic latent image formed on the surface of the photosensitive drum by toner supplied from a toner cartridge. The image forming apparatus includes a developing device for developing, a transfer device for transferring a toner image formed on the surface of the photosensitive drum by the developing device to a sheet, a fixing device for fixing the toner to the sheet, and the like.
The engine control unit 41 controls each component of the image forming unit 4 by executing processing in accordance with a predetermined program stored in the ROM, which includes a CPU, a peripheral device such as a ROM and a RAM. An image forming operation is executed.

Similar to the conventional apparatus, the image forming apparatus X includes a normal operation mode in which an image forming operation by the image forming unit 4 can be performed, and a sleep mode (an example of a power saving operation mode, which consumes less power than the normal operation mode. These operation modes are switched by the main control unit 1 based on preset mode switching conditions. The sleep mode is an operation mode in which power consumption is reduced by cutting off power supply to the image forming unit 4 and various sensors (not shown), for example. Here, the main control unit 1 performs a mode switching process (see the flowchart of FIG. 2) to be described later for switching the operation mode of the image forming apparatus X between the normal operation mode and the sleep mode. This corresponds to the switching means.
For example, when there is no input of document image data or print data in the normal operation mode for a predetermined time or longer, the mode is switched to the sleep mode. In the sleep mode, the user performs a copy operation (open / close operation of the document cover or copy start). When a pressing operation or the like is performed, the operation mode is switched to the normal operation mode.
In the image forming apparatus X, whether or not the clock signal is input to the engine control unit 41 by the clock signal control unit 5 is switched when the operation mode is switched. For example, when switching from the normal operation mode to the sleep mode, the clock signal input to the engine control unit 41 by the clock signal control unit 5 is completely stopped. Thereby, power consumption in the sleep mode can be further reduced.

The clock signal controller 5 has an RC oscillator that can generate a clock signal at an arbitrary frequency by arbitrarily changing an RC time constant. It should be noted that the clock signal control unit 5 may include a crystal resonator or the like as another embodiment.
The clock signal generated by the clock signal control unit 5 is input to the engine control unit 41. However, when the main power switch of the image forming apparatus X is turned off, the drive power supply path to other than the main control unit 1 is cut off, so that the clock signal control unit 5 supplies the engine control unit 41 to the engine control unit 41. The clock signal input is completely stopped.
As described above, the clock signal control unit 5 inputs a clock signal to the engine control unit 41 in accordance with an instruction from the main control unit 1 in a mode switching process (see the flowchart of FIG. 2) described later. The presence or absence of is switched. Specifically, the main control unit 1 controls the engine control unit 41 to input the clock signal to the engine control unit 41 in the normal operation mode and to stop the input of the clock signal to the engine control unit 41 in the sleep mode. Is done.

By the way, in the image forming apparatus X, when the power of the image forming apparatus X main body is turned on, various return (wake-up) processes for shifting the image forming unit 4 to a state in which an image forming operation is possible are performed by the engine control. This is executed by the unit 41. For example, the return processing includes initialization of memory in the engine control unit 41, calibration processing, aging processing, and the like.
Further, in the image forming apparatus X, the engine control unit 41 performs various restoration processes for shifting the image forming unit 4 to a state in which the image forming operation can be performed even when shifting from the sleep mode to the normal operation mode. Executed. However, as described above, in the sleep mode, the engine control unit 41 is in a completely stopped state, and therefore processing cannot be executed based on an externally received signal. Therefore, the return processing at the time of switching to the normal operation mode is started when the engine control unit 41 is reset by the main control unit 1 at the time of switching from the sleep mode to the normal operation mode. The main control unit 1 when executing the reset process of the engine control unit 41 corresponds to a reset means.

As described above, in the configuration in which the clock signal input to the engine control unit 41 is stopped in the sleep mode and the engine control unit 41 is reset in the transition to the normal operation mode, the engine control unit 41 performs the image control. It cannot be determined whether the forming apparatus X is turned on or reset when the sleep mode is switched to the normal operation mode. Therefore, conventionally, the engine control unit 41 has executed the same return processing when the image forming apparatus X is turned on and when the sleep mode is shifted to the normal operation mode.
However, in the image forming apparatus X according to the embodiment of the present invention, the main control unit 1 executes a mode switching process (see the flowchart of FIG. 2), which will be described later, and the main control unit 1 and the engine control unit 41. Since a return switching process described later (see the flowchart of FIG. 3) is executed during this period, a different return process occurs when the image forming apparatus X body is turned on and when the sleep mode is shifted to the normal operation mode. Executed.

First, an example of the procedure of mode switching processing executed by the main control unit 1 will be described with reference to the flowchart of FIG. Here, it is assumed that the mode switching process is started when the image forming apparatus X is in the normal operation mode. In the figure, S1, S2,... Represent processing procedure (step) numbers.
[Steps S1, S2]
In step S1, the main control unit 1 determines whether or not it is necessary to shift to the sleep mode in accordance with a preset mode switching condition. For example, as described above, when there is no input of document image data or print data for a predetermined time or more, it is determined that the transition to the sleep mode is necessary.
Here, while it is determined that the transition to the sleep mode is not necessary, the determination in step S1 is repeatedly executed (No side of S1), and the normal operation mode is continued, but the transition to the sleep mode is not performed. If it is determined that it is necessary (Yes in S1), the process proceeds to step S2.
In step S2, the clock signal control unit 5 is controlled by the main control unit 1, whereby the clock signal input from the clock signal control unit 5 to the engine control unit 41 is stopped. As a result, the engine control unit 41 stops the operation of the engine control unit 41 because no clock signal is received. At this time, the main control unit 1 executes other processes for shifting the entire image forming apparatus X to the sleep mode, but the description thereof is omitted here.

[Steps S3 to S5]
Thereafter, in step S3, the main control unit 1 determines whether or not it is necessary to shift to the normal operation mode in accordance with a preset mode switching condition. For example, when the user performs a copy operation (opening / closing operation of the document cover, pressing operation of copy start, etc.) in the sleep mode, it is determined that the transition to the normal operation mode is necessary.
Here, while it is determined that the transition to the normal operation mode is not necessary, the determination in step S3 is repeatedly executed (No side of S3), and the sleep mode is continued, but the transition to the normal operation mode is performed. Is determined to be necessary (Yes side of S3), the process proceeds to step S4.
In step S4, the main control unit 1 resets the engine control unit 41. For example, by turning off / on a switch (not shown) provided in the middle of the power supply path following the engine control unit 41 to cut off the power supply to the engine control unit 41, the engine control unit 41 Is reset. As a result, the engine control unit 41 starts a return process (see the flowchart of FIG. 3), which will be described later.
In step S5 executed substantially in parallel with step S4, the clock signal control unit 5 is controlled by the main control unit 1 so that the clock signal control unit 5 sends the engine control unit 41 to the engine control unit 41. Input of the clock signal is started. As a result, the engine control unit 41 receives the clock signal, so that the operation of the engine control unit 41 is started. At this time, the main control unit 1 executes other processing for shifting the entire image forming apparatus X from the sleep mode to the normal operation mode, but the description thereof is omitted here.

[Step S6]
Thereafter, in step S6, the main control unit 1 updates the reset flag indicating that the engine control unit 41 has been reset from “0” to “1”, and the process returns to step S1. Here, the reset flag is stored in, for example, the RAM of the main control unit 1. When the engine control unit 41 is reset by “1”, the engine control unit 41 is reset by “0”. Indicates that it has not been reset. The initial value of the reset flag is “0”. That is, in the image forming apparatus X, the reset flag is “0” when the image forming apparatus X is turned on. However, when the sleep mode is switched to the normal operation mode, the reset flag is set in step S6. Becomes “1”. Whether the reset flag is a power-on (reset flag = 0) of the image forming apparatus X or a switch from the sleep mode to the normal operation mode (reset flag = 1) in a return switching process to be described later. It is used as a judgment index.

Next, an example of a return switching process executed between the main control unit 1 and the engine control unit 41 will be described with reference to the flowchart of FIG. In FIG. 3A, S11, S12,... Are processing procedure (step) numbers on the main control unit 1 side, and S21, S22,. Represents a procedure (step) number.
Here, the return switching process on the main control unit 1 side is appropriately executed during the operation of the main control unit 1. On the other hand, the return switching process on the engine control unit 41 side is performed when the image forming apparatus X is turned on or when the main control unit 1 resets the engine control unit 41 (step S4). To begin.

First, the processing on the main control unit 1 side will be described.
[Steps S11 and S12]
In step S11, the main control unit 1 determines whether or not a preparation completion signal is received from the engine control unit 41. Here, while it is determined that the preparation completion signal is not received (No side of S11), step S11 is repeatedly executed. On the other hand, if it is determined that the preparation completion signal has been received (Yes in S11), the process proceeds to step S12.
In step S12, the main control unit 1 determines whether or not the reset flag is “1”. Here, the preparation completion signal is input from the engine control unit 41 after the image forming apparatus X is turned on based on whether the reset flag is “0” or “1”. It is determined whether the input is from the engine control unit 41 after switching from the sleep mode to the normal operation mode.
If it is determined that the reset flag is “1” (Yes in S12), the process proceeds to step S13, and if it is determined that the reset flag is “0” (S12). The process proceeds to step S15.

[Steps S13 and S14]
If it is determined in step S12 that the reset flag is “1”, that is, the preparation completion signal input from the engine control unit 41 is the engine at the time of switching from the sleep mode to the normal operation mode. If it is generated due to the reset of the control unit 41, a sleep return processing signal (an example of a second return processing signal) indicating that is sent to the engine control unit 41 by the main control unit 1. Is output (S13). Thereby, the engine control unit 41 receives the sleep return processing signal.
In step S14, the main controller 1 updates the reset flag from “1” to “0” (reset), and the process returns to step S11.

[Step S15]
On the other hand, if it is determined in step S12 that the reset flag is “0”, that is, the preparation completion signal input from the engine control unit 41 is caused by power-on of the image forming apparatus X. If this occurs, a power-on recovery processing signal (an example of a first recovery processing signal) indicating that is output to the engine control unit 41 by the main control unit 1 (S15). Thereby, the engine control unit 41 receives the power-on return processing signal. Thereafter, the process returns to step S11.
Thus, in the image forming apparatus X, when the main control unit 1 turns on the power of the image forming apparatus X and then receives a preparation completion signal from the engine control unit 41, the power supply An input / return processing signal (an example of a first return processing signal) is input to the engine control unit 41, and after the engine control unit 41 is reset by the main control unit 1, a preparation completion signal is sent from the engine control unit 41. Is input to the engine control unit 41, the sleep recovery processing signal (an example of a second recovery processing signal) different from the power-on recovery processing signal. Here, the main control unit 1 when executing such processing corresponds to a return processing control means.

Next, processing on the engine control unit 41 side will be described.
In the engine control unit 41, when the power of the image forming apparatus X is turned on or when the operation mode of the image forming apparatus X is switched from the sleep mode to the normal operation mode, the main control unit 1 When the engine control unit 41 is reset (see the flowchart of FIG. 2, S4), the return process is started.

[Steps S21 and S22]
First, in step S21, various initialization processes such as initialization of memory of the engine control unit 41, parameter setting, communication setting with the main control unit 1 are executed by the engine control unit 41.
When the initialization process is completed, the engine control unit 41 outputs a preparation completion signal to the main control unit 1 in the subsequent step S22. Accordingly, the main control unit 1 receives the preparation completion signal (S11).

[Steps S23 and S24]
Thereafter, the engine control unit 41 waits for reception of the sleep return processing signal or the power-on return processing signal from the main control unit 1 (S23 to S24).
Here, if it is determined that the sleep recovery process signal is input from the main control unit 1 (Yes in S23), the process proceeds to step S26, and the power-on recovery process signal is transmitted from the main control unit 1. If it is determined that the input has been made (Yes in S24), the process proceeds to step S25.

[Steps S25 and S26]
In step S25, the engine control unit 41 performs a restoration process (an example of a first restoration process) including a calibration process for adjusting the color of the image forming unit 4 and an aging process for performing a preliminary operation. It is executed as a return process when the forming apparatus X is turned on.
On the other hand, in step 26, the engine control unit 41 performs a return process (an example of the second return process) simplified by omitting the calibration process included in the return process in step S25. It is executed as a return process when returning to the mode. That is, in the image forming apparatus X, when returning from the sleep mode, a recovery process simplified than the recovery process (S25) when the image forming apparatus X is turned on is executed. Is shortened.

As described above, in the image forming apparatus X, different signals (power-on return processing signal, sleep return processing signal) are generated when the image forming apparatus X is turned on and when the sleep mode is switched to the normal operation mode. Since the main control unit 1 inputs the input to the engine control unit 41 (S13, S15), the engine control unit 41 causes the image forming apparatus X to turn on and to switch from the sleep mode to the normal operation mode. Can be discriminated. Accordingly, in the return process (S26) at the time of switching from the sleep mode to the normal operation mode, the process is simplified to the normal operation mode than the return process (S25) when the image forming apparatus X is turned on. It is possible to reduce the time required for the return process at the time of switching.
In step S26, the case where the return process in which the calibration process is omitted is performed is described as an example, but the present invention is not limited to this. For example, the aging process and other processes may be omitted, and a plurality of processes such as the calibration process and the aging process may be omitted. Further, shortening the time for executing the aging process corresponds to simplification of the process.

  By the way, in the image forming apparatus X, it is desirable to appropriately change the restoration process of the image forming unit 4 according to the non-operation time of the image forming apparatus X. For example, when the image forming apparatus X has not been operated for a long time, the aging process is executed for a sufficiently long time before the start of image formation, and when the non-operation time is short, the aging process is performed. It is conceivable to reduce the execution time. Hereinafter, an embodiment for realizing such a configuration will be described.

The main control unit 1 stops the clock signal input to the engine control unit 41 by the clock signal control unit 5, that is, from when the image forming apparatus X is turned off until the next power is turned on. And a process for measuring the time between the transition to the sleep mode and the transition to the normal operation mode.
The main control unit 1 outputs the power-on return processing signal when outputting the sleep return processing signal in step S13 (see the flowchart in FIG. 3) or in step S15 (see the flowchart in FIG. 3). In doing so, a process for simultaneously notifying the counted stop time is executed. Here, the main control unit 1 when executing such processing corresponds to a time measuring means.

As a result, when the engine control unit 41 executes the return process in steps S25 and S26 (see the flowchart of FIG. 3), the return process is performed according to the stop time notified from the main control unit 1. The contents of are changed. For example, if the stop time is less than 1 hour, the execution time of the aging process is set to 5 seconds, and if the stop time is 1 hour or more, the execution time of the aging process is set to 10 seconds. It is possible.
Here, the case where the execution time of the aging process is changed has been described as an example. However, the present invention is not limited to this, and the contents of the calibration process and other processes may be changed.
In another embodiment, the engine control unit 41 may switch between executing the power-on return process or the sleep return process according to the timed stop time. For example, even if it is determined in step S23 that the sleep recovery processing signal has been received, if the stop time notified at that time is equal to or longer than a predetermined time, the image formation It can be considered that it is necessary to execute a return process similar to that at the time of power-on of the device X, and the process proceeds to step S25.

1 is a block diagram showing a schematic configuration of an image forming apparatus according to an embodiment of the present invention. 6 is a flowchart for explaining an example of a procedure of mode switching processing executed in the image forming apparatus according to the embodiment of the present invention. 6 is a flowchart for explaining an example of a procedure of return switching processing executed in the image forming apparatus according to the embodiment of the present invention.

DESCRIPTION OF SYMBOLS 1 ... Main control part 2 ... Display and operation part 3 ... Image processing part 4 ... Image formation part 41 ... Engine control part 5 ... Clock signal control part S1, S2, ..., Process procedure (step) number S11, S12, ... , ... Processing procedure (step) number S21, S22, ..., processing procedure (step) number

Claims (3)

An image forming unit that performs an image forming operation based on input image data;
Image formation control means for controlling the image forming unit in accordance with an input clock signal;
According to preset mode switching conditions, the operation mode of the image forming apparatus is changed between a normal operation mode in which an image forming operation can be performed by the image forming unit and a power saving operation mode with lower power consumption than the normal operation mode. Mode switching means for switching,
A clock signal that inputs the clock signal to the image formation control means during the normal operation mode and stops the input of the clock signal to the image formation control means during the power saving operation mode and when the image forming apparatus is powered off Control means;
A reset means for executing a reset for instantaneously interrupting the power supply to the image forming control means at the time of switching from the power saving operation mode to the normal operation mode and setting a reset flag in a state indicating the reset;
An image forming apparatus comprising:
When a predetermined preparation completion signal is input from the image forming control means after the image forming apparatus is turned on, the first return is made when the reset flag is not reset. After the processing signal is input to the image formation control unit and the image formation control unit is reset by the reset unit, the reset flag is reset when a predetermined preparation completion signal is input from the image formation control unit. A return processing control means for inputting a second return processing signal different from the first return processing signal to the image forming control means when the state is a
The image forming control unit executes a first return process when the first return process signal is input by the return process control unit, and the second return process signal is input by the return process control unit. In this case, the image forming apparatus is configured to execute a second return process simplified more than the first return process.   2. The second return process is simplified from the first return process by omitting the calibration process and / or the aging process included in the first return process. The image forming apparatus described. Provided separately from the image formation control means, further comprising a time notifying means for timing the stop time of the clock signal and notifying the image formation control means of the stop time;
The image forming control means changes the contents of the first return processing and / or the second return processing based on the stop time notified by the time notification means. The image forming apparatus according to any one of the above.

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