JP2010282504A - Electronics - Google Patents

Abstract

PROBLEM TO BE SOLVED: To cancel a shutdown process with a simple operation after a controller starts an end process (shutdown process) in response to an operation of turning off a power switch, so that a job can be immediately returned to a state where it can be processed.
A predetermined time (shutdown adjustment period) after a controller 2 receives power supply from a power supply line on the switch means 42 side and starts a shutdown process in accordance with an operation of turning off a main switch 41 after startup. If the main switch 41 is turned on, the scheduled shutdown process is canceled and the job is immediately returned to a standby state where the job can be processed.
[Selection] Figure 1

Description

  The present invention relates to an electronic device that controls the operation of a device by a controller that operates by receiving power supply, and more specifically, shuts down a controller (control system) even if a main switch provided in a power feeding path is unexpectedly turned off. The present invention relates to an electronic device having a function that enables processing.

  Electronic devices that consume power and operate, such as digital MFPs (MFPs) and servers / PCs (personal computers) that combine functions such as copying, facsimile, printers, and scanners, can be controlled even when they are not used directly by users. Various software driven by the system (controller) operates in the background. Therefore, if the power switch is turned off unexpectedly when there is software in operation, necessary data cannot be saved in the nonvolatile memory, and it may not be able to start up normally at the next power-on.

Patent documents 1 and 2 can be illustrated as prior art which made it possible to avoid the trouble which arises by such unexpected power-off.
In Patent Document 1, when a power-off is instructed by the sub-power switch, it is determined whether or not a job is being executed or a registered reserved job is being waited. If it is determined that the operation is in progress, the display section displays a three-choice display for selecting one of the three operation items of “forced termination”, “save and save the current state”, and “stop the termination operation”. An image forming apparatus is shown that controls an operation according to an operation item selected and operated when a screen is displayed and any operation item is selected and operated by a touch panel.
Further, Patent Document 2 includes a switch state detection unit that detects on / off of a main switch, and receives a signal that the controller has detected that the main switch has been turned off, and is connected to the power supply in parallel with the main switch. There is shown an image forming apparatus that outputs a control signal for turning on a controllable switch, maintains output of a power supply until necessary data is saved in a nonvolatile memory, and then controls to turn off the power.

In the above-described prior art, when there is software in operation, such as during job execution, the operation can be restored when the power supply to the control unit (main controller) is turned off by the operation of the power switch. The power supply is maintained until the process is completed or the normal termination process is completed, but it is possible to perform an operation of completely turning off the power thereafter.
However, if the control unit (main controller) starts the termination process according to the power switch off operation and then notices that the operation has been mistakenly performed, I want to proceed with the process to immediately restore the job to a processable state. However, a means for responding to such a request, canceling the end process with a simple operation, and performing the recovery process is not shown in the above-described prior art. In Patent Document 1, an operation of “stopping the end operation” is enabled. However, after the power switch is turned off, the operation must be performed by a selection operation on the three-option display screen. For those who did not, the number of operation procedures will increase, which is not sufficient in terms of operability and usability.

  The present invention has a function of maintaining power until a normal termination process (such as a process that terminates in a state where the operation can be restored) is completed when the power supply to the control unit (controller) is turned off by the operation of the power switch. In view of the above-described problems of the related art in electronic devices, the purpose of the controller is to cancel the end process with a simple operation immediately after the controller starts the end process according to the power switch off operation. It is to be able to return to a state where the job can be processed.

  The present invention is an electronic device that controls the operation of a device by a controller that operates upon receiving power supply, and is a main switch that can be turned on and off at any time provided in a power supply path from the power source to the controller. 1 switch, switch state detecting means for detecting the on / off state of the first switch, and a first switch connected in parallel with the first switch and turned on / off according to a control signal from the controller. And the controller turns on the second switch and means for sending a control signal to turn on the second switch on the condition that the off state is detected by the switch state detecting means. Before scheduled when the ON state of the first switch is not detected by the switch state detecting means within a predetermined time from the time A means for executing a controller shutdown process; and a controller shutdown process scheduled when an on-state is detected by the switch state detection means within the predetermined time from when the second switch is turned on. A means for canceling is provided.

  After the controller starts the end process according to the power switch turning off the power switch, the end process can be canceled by a simple and natural operation of turning on the power switch so that the job can be processed immediately. Thus, operability and convenience can be improved.

1 is a block diagram illustrating a schematic configuration of an image forming apparatus according to an embodiment of the present invention. FIG. 6 is a timing chart showing transition of the operation state of the image forming apparatus (FIG. 1) when the main switch is turned off during standby. FIG. 6 is a timing diagram illustrating transition of an operation state of the image forming apparatus (FIG. 1) when a main switch is turned off during job execution. FIG. 6 is a timing diagram illustrating a transition (first embodiment) of an operation state of the image forming apparatus (FIG. 1) when the main switch is turned off during standby and then the main switch is turned on again to cancel the shutdown process. FIG. 6 is a timing diagram illustrating a transition (first embodiment) of the operation state of the image forming apparatus (FIG. 1) when the main switch is turned off during job execution and then the main switch is turned on again to cancel the shutdown process. FIG. 5 is a diagram illustrating a control flow (first embodiment) of a shutdown process according to an off operation of a main switch and a cancel process of a shutdown according to an on operation. Timing chart showing the transition of the operation state (second embodiment) of the image forming apparatus (FIG. 1) when the main switch is turned off during standby and then the main switch is turned on again to cancel the shutdown process. It is. FIG. 10 is a diagram illustrating a control flow (second embodiment) of a shutdown process according to an off operation of a main switch and a cancel process of a shutdown according to an on operation. It is a block diagram which shows schematic structure of the image forming apparatus which concerns on other embodiment of this invention. FIG. 10 is a diagram illustrating a control flow (third embodiment) of a shutdown process according to an off operation of a main switch and a cancel process of a shutdown according to an on operation. FIG. 10 is a diagram illustrating a control flow (seventh embodiment) of a shutdown process according to an off operation of a main switch and a cancel process of a shutdown according to an on operation. FIG. 16 is a diagram illustrating a control flow (seventh embodiment) of a shutdown process in accordance with an off operation of a main switch and a cancel process of shutdown in accordance with an on operation. FIG. 15 is a diagram illustrating a control flow (sixth embodiment) of a shutdown process according to an off operation of a main switch and a cancel process of a shutdown according to an on operation.

Hereinafter, embodiments in which the present invention is applied to an image forming apparatus (for example, a copying machine, a facsimile machine, a printer, a multifunction machine, etc.) will be described with reference to the accompanying drawings.
“Embodiment 1”
FIG. 1 is a block diagram illustrating a schematic configuration of an image forming apparatus according to an embodiment of the present invention.
As shown in FIG. 1, the image forming apparatus 1 includes a controller 2 having an input port (input interface) 21 and an output port (output interface) 22, an engine 3, and a DC power supply / AC control plate 4.
The controller 2 controls the entire image forming apparatus. The controller 2 can be implemented by constructing a control system having a software configuration that includes a computer and software (program) for causing the computer to function as the controller.
The engine 3 is a printer engine that prints an image on a sheet, a scanner engine that reads an image of a document, or the like.

The DC power source / AC control board 4 is a board (board) on which circuits for converting power supplied from the AC power source into DC power source and supplying the power to each part (here, the controller 2 and the engine 3) in the device are mounted. It is.
The DC power / AC control board 4 of this embodiment is equipped with a switch means 42 including a main switch 41, a relay driver 42a and a relay 42b, a power circuit 43 and a breaker 44.
One end of the breaker 44 is connected to a power line from an AC power source, and the other end is connected to one end (input side) of the main switch 41 and one end (input side) of the relay 42b. The breaker 44 can be manually opened and closed (on / off) by the user. When the breaker 44 is closed, the AC power supply and the input side of each of the main switch 41 and the relay 42b are connected to the power supply line.

  The main switch 41 can be turned on / off at any time by the user, and includes two open / close contacts that open and close (on / off) in conjunction with the turning on / off operation by the user. One of the two switching contacts, that is, the fixed contact (AC power supply contact) x2 corresponding to the switching contact (AC switching contact) to which AC power is input through the breaker 44 is connected to the input side of the power circuit 43 by the power line. The other switching contact, that is, the fixed contact (low voltage DC contact) x1 corresponding to the switching contact (DC switching contact) connected to the ground (GND) is connected to the input port 21 of the controller 2 by a signal line.

  Therefore, when the main switch 41 is turned on (contacts are closed) when the breaker 44 is on (closed), power from the AC power supply is supplied to the power supply circuit 43 through the main switch 41. The state of the low voltage DC contact x1 (ground potential = 0) is input to the input port 21 of the controller 2. On the other hand, when the main switch 41 is turned off (contacts are opened), power from the AC power supply is not supplied to the power supply circuit 43. Further, the state of the low voltage DC contact x1 (relatively high potential) is input to the input port 21 of the controller 2. That is, the detection signal 101 of the on / off state of the main switch 41 is input to the input port 21. That is, as a means for detecting the switch state of the main switch 41, “Low” is given to the input port 21 if the main switch 41 is on (closed), and “High” is given to the input port 21 if it is off (open).

The other end (output side) of the relay 42 b of the switch means 42 is connected to the input side of the power supply circuit 43. Therefore, when the breaker 44 is on (closed) and the relay 42b is turned on (closed), power from the AC power supply is supplied to the power circuit 43 through the relay 42b.
On the other hand, when the relay 42b is turned off (opened), the power supply circuit 43 is not supplied with power from the AC power supply. The relay 42b is turned on / off depending on whether the relay driver 42a in the switch means 42 receives the control signal 102 transmitted from the output port 22 of the controller 2 and the level is "High" or "Low". To control the drive of the control relay.

By controlling the relay 42b of the switch means 42, the power supply to the power supply circuit 43 can be maintained so that the controller 2 or the like maintains the operating state even when the power supply line on the main switch 41 side is turned off. Therefore, it is possible to prevent an abnormal operation that may occur due to the main switch 41 being turned off unexpectedly.
That is, when power is supplied only through the main switch line, the main switch 41 is unexpectedly turned off. When power supply is stopped, if the control system of the controller 2 is operating at this time, the necessary data is transferred to the nonvolatile memory. May not be able to be saved, and even if an attempt is made to interrupt the process by turning on the power again, there may be a problem that it cannot be started up normally.
In order to avoid such a problem, a shutdown process is performed by the control system, and after this process is performed so that no abnormal operation occurs, a procedure for terminating the process is performed. In the embodiment to be described later, since the shutdown process is performed after the job being executed is processed, the job processing is not interrupted. The device information is subject to shutdown processing as data that needs to be saved.
In order to execute such a procedure, it is necessary to supply power to the controller 2 until the shutdown process is performed. In this power supply control, the controller 2 determines the power supply maintenance based on the detection signal 102 obtained by the means for detecting the on / off state of the main switch 41, and controls the driving of the relay driver 42a of the switch means 42. The power is supplied through the power supply line on the switch means 42 side for a necessary period by turning on / off the relay 42b.

In the image forming apparatus (FIG. 1), the operation when the main switch 41 is closed by the user's ON operation and the image forming operation is started is described first.
When the main switch 41 is turned on and the contact is closed, AC power is supplied to the power circuit 43. The power supply circuit 43 converts the AC power into a DC power having a predetermined level necessary for the operations of the engine 3 and the controller 2 and supplies them to each. The engine 3 and the controller 2 that are activated by power supply are ready for job processing after initialization, and when a job such as copying is submitted, the operating conditions set by the initialization and processing specified by the user are processed. The image forming apparatus 1 is operated according to the conditions.
At this time, the detection signal 101 for outputting the on / off state of the main switch 41 to the controller 2 outputs to the controller 2 that the main switch 41 is on (closed). The controller 2 does not output the control signal 102 to the switch means 42 when the DC power is supplied through the power supply circuit 43 based on the power from the power supply line on the main switch 41 side. The relay 42b is kept off (open). For this reason, the power supply line on the switch means 42 side is cut off, and energy loss due to the switch means 42 during this time is suppressed.

The operation when the main switch 41 is opened by the user's off operation and the image forming operation is stopped will be described.
When the main switch 41 is turned off and the contact is opened, the supply of AC power to the power circuit 43 is interrupted. Since the supply of AC power is cut off, the DC output voltage of the power supply circuit 43 disappears after a holding time due to the input / output capacitor capacity. The detection signal 101 for outputting the on / off operation state of the main switch 41 to the controller 2 immediately outputs to the controller 2 that the main switch 41 is opened. At this time, the controller 2 receives the detection signal 101 during the DC power supply holding time of the power supply circuit 43.
The controller 2 that has received the main switch-off detection signal 101 performs a normal shutdown process without outputting the control signal 102 to the switch means 42 if the image forming apparatus 1 is in a standby state waiting for job input. power off.

On the other hand, if the image forming apparatus 1 is executing a job when the main switch-off detection signal 101 is received, the controller 2 outputs a control signal 102 to the switch means 42 to turn on the contact of the relay 42b ( The AC power is supplied to the power supply circuit 43.
For this reason, the power supply circuit 43 receives power from the power supply line on the switch means 42 side after the power supply from the power supply line on the main switch 41 side is cut off, and starts conversion from AC power to DC power. Before the DC power holding time 43 elapses, the DC power supply to the engine 3 and the controller 2 is started. For this reason, the operation of the image forming apparatus 1 is not interrupted, and the job being executed can be completed.
Further, the controller 2 performs a shutdown process at the time of completing the job being executed, and sends a signal for switching the instruction to the relay 42b from on to off as the control signal 102 to the switch means 42. The supply of AC power to the power supply circuit 43 from the power supply line on the 42 side is cut off, and after the DC power supply holding time of the power supply circuit 43 has elapsed, the DC output of the power supply circuit 43 disappears.

Next, the operation of the image forming apparatus 1 (FIG. 1) according to the present embodiment performed according to the operation of the main switch 41 will be described in more detail with reference to FIGS.
<Operation to be terminated by shutdown processing in response to main switch OFF operation>
In the following, the operation from when the image forming apparatus 1 is activated in a state where the job can be processed according to the on operation of the main switch, after which the shutdown processing is performed according to the off operation of the main switch and the power is turned off. A description will be given with reference to FIGS. 2 and 3 showing the transition of the operation state of each part in the image forming apparatus 1. FIG.
It should be noted that since the operation is different between when the main switch 41 is turned off during standby and when the job is being executed, each will be described separately below.

“When the main switch is turned off during standby”
FIG. 2 is a timing chart showing the transition of the operation state of the image forming apparatus 1 when the main switch is turned off during standby.
In FIG. 2, each element representing the operation state of the image forming apparatus 1 is given as A to F, and the operation state is shown for each of the elements A to F by taking the time elapsed toward the right in the drawing. Here, the elements A to F representing the operation state of the image forming apparatus 1 mean the following.
A: The main switch 41 is turned on / off.
B: In the on / off detection signal 101 of the main switch 41, “Low” indicates on and “High” indicates off.
C: The power supply state of the AC power supply to the power supply circuit 43 is shown.
D: In the control signal 102 for turning on / off the relay 42b of the switch means 42, “High” indicates ON and “Low” indicates OFF.
E: Indicates the output state of the DC power supply from the power supply circuit 43.
F: Indicates the processing contents executed by the software (control system).
Note that t1 to t5 on the time axis in FIG. 2 indicate timings at which specific state changes (described in detail later) occur.

With reference to FIG. 2, a change in the operation state from the state where the main switch 41 is off, that is, the controller 2 (control system) is stopped when the power is turned off will be described.
When the user turns on the main switch 41 at timing t1 from the power-off state (A in FIG. 2 is turned off to on), AC power is supplied to the power supply circuit 43 (in FIG. 2, C is 0V → 100V). ). The power supply circuit 43 receives supply of AC power, starts conversion to DC power, and outputs the converted DC power to the controller 2 and the engine 3 (E in FIG. 2 from OFF to ON).
At the timing t2 when the DC power supplied from the power supply circuit 43 rises to a predetermined voltage, the controller 2 that receives the supply of the DC power starts up the software, starts the operation constituting the control system, The startup process is performed in a state where the process is possible (period of startup process F in FIG. 2), and at a timing t3 when the startup process is finished, a standby state is entered in which a job or other instruction is given. In the activation process, the engine 3 is also activated in the case of the image forming apparatus.
The control system (software processing) that has started up at timing t3 after the start processing ends checks the state of the on / off detection signal 101 of the main switch 41 (processing at the end of F in FIG. 2).
As a result of this check, since the detection signal 101 is “Low”, the control signal 102 output from the controller 2 is “Low”, and power supply from the power supply line on the switch means 42 side to the power supply circuit 43 is not performed. It remains shut off (state B in timing t3 in FIG. 2).

Next, a change in the operation state when the main switch 41 is turned off while waiting for an instruction such as a job to be given will be described.
When the user turns off the main switch 41 at time t4 from the power-on state (A in FIG. 2 from on to off), the AC power from the power supply line on the main switch 41 side to the power circuit 43 is cut off ( In FIG. 2, C 100V → 0V).
In addition, since the detection signal 101 of the main switch 41 becomes “High (off)” in synchronization with the timing t4 when the main switch 41 is turned off, the control signal 102 output from the controller 2 is “High (on)”. 2 (states B and D at timing t4 in FIG. 2), power is supplied to the power supply circuit 43 from the power supply line on the switch means 42 side.

At this time, the power supply from the power supply line on the main switch 41 side is cut off, and the AC power supply to the power supply circuit 43 is momentarily reduced. However, before the DC output holding time of the power supply circuit 43 ends, the power supply line on the switch means 42 side Is supplied again to the power supply circuit 43, so that the DC output of the power supply circuit 43 to the controller 2, the engine 3, etc. is continuously supplied without dropping (the main switch at timing t4 in FIG. 2). C and E states due to actions related to 41 off).
Further, the controller 2 confirms the operation state of the image forming apparatus 1 in order to execute the process according to the procedure according to the current operation state at the timing t4 when the main switch 41 is turned off. In the operation example of FIG. 2, since it is in the standby state, it can be immediately shifted to the shutdown adjustment period. Therefore, after waiting for the start of the shutdown process, the shutdown adjustment period is entered, and the shutdown process is started after the lapse of this period. Note that the shutdown adjustment period is a period related to a canceling operation of a shutdown process described later (not performed in the operation example of FIG. 2), and will be described in detail later.
When the shutdown process is completed, the controller 2 sets the control signal 102 to “Low (off)” to cut off the AC power from the power supply line on the switch means 42 side to the power circuit 43, and the controller 2, engine 3, etc. The DC output of the power supply circuit 43 is also turned off, and the power is turned off (states B, C, D, and E at timing t5 in FIG. 2).

“When the main switch is turned off during job execution”
FIG. 3 is a timing chart showing the transition of the operation state of the image forming apparatus 1 when the main switch is turned off during job execution. In addition, A to F (elements representing the operation state of each part) and t1 to t5 (timing) shown in the figure are synonymous with those in FIG. Further, since the operation from the power-off state to the start-up of the device and the standby state is not different from the operation of FIG. 2, the above-described operation description is referred to and the description is omitted here.
Next, an operation when an instruction for a job or the like is received during standby and the main switch 41 is turned off during execution of the job will be described.
When the user turns off the main switch 41 at timing t4 during execution of the job (A in FIG. 3 from ON to OFF), the controller 2 executes the process according to the procedure according to the operation state at this time. Then, the operating state of the image forming apparatus 1 is confirmed.
In the operation example of FIG. 3, since the job is being executed, the job being executed is continuously processed. After the job is completed, the shutdown process is performed and the process is terminated when the power is turned off.

The control operation for maintaining the DC output from the power supply circuit 43 when continuously executing the job being executed in response to the OFF operation of the main switch 41 is performed at each of the timings A to E in FIG. Since the operation is the same, the above description is referred to.
Since the DC output from the power supply circuit 43 is maintained by the operation at the timing t4, the job being executed can be continuously processed, and the processing instructed by the user can be completed.
The controller 2 performs the shutdown process after completing the processing of the job being executed. In this embodiment, since the shutdown adjustment period is provided, the controller 2 shifts to this period.
The shutdown adjustment period is entered, and the shutdown process is started after this period. Note that the shutdown adjustment period is a period related to a canceling operation of a shutdown process described later (not performed in the operation example of FIG. 3), and will be described in detail later.
When the shutdown process is completed, the controller 2 sets the control signal 102 to “Low (off)” to cut off the AC power from the power supply line on the switch means 42 side to the power circuit 43, and the controller 2, engine 3, etc. The DC output of the power supply circuit 43 is also turned off and the power supply is turned off (states B, C, D, and E at timing t5 in FIG. 3).

<Operation when the shutdown process according to the main switch OFF operation is canceled>
In the above, when the power is turned off by turning off the main switch 41 that can be operated at any time, the power is maintained on the power supply line on the switch means 42 side, and the shutdown process is performed to restore the operation. The configuration for performing the operation of turning off the power or the operation of turning off the power after completing the job being processed and performing the shutdown process is shown.
However, if the user notices that the user has mistakenly performed the off operation after the main controller 2 starts the operation of shifting to the termination process such as the shutdown process according to the off operation of the main switch 41, the job can be processed immediately. It appears as a request to restore the state (standby state). In this embodiment, there is provided means for responding to such a request, canceling the end process with a simple operation, and performing a process for recovering to the standby state.

In this embodiment, as a means for performing this process, the controller 2 receives a power supply from the power supply line on the switch means 42 side in accordance with the turning-off operation of the main switch 41 and starts an operation for shifting to the end process. When the main switch 41 is turned on within a predetermined time, a unit is provided that cancels the scheduled shutdown process and can immediately return to a standby state in which a job can be processed.
The predetermined time is a timing at which the main switch 41 can be returned to the standby state after the main switch 41 is turned off, that is, a timing at which the shutdown process is started (can be returned to the standby state). In this case, a period determined by this time is referred to as “shutdown adjustment period”. In this embodiment, the shutdown adjustment period is a predetermined time from the time when the relay 42b is turned on by the control signal 102 for switching to the power supply of the power supply line on the switch means 42 side according to the turning-off operation of the main switch 41. This period.

In the following, the image forming apparatus 1 is activated in a state where the job can be processed in response to the ON operation of the main switch 41, and then the shutdown process scheduled to be performed in response to the OFF operation of the main switch 41 is canceled. The operation until returning to the standby state will be described with reference to FIGS. 4 and 5 showing the transition of the operation state of each part in the image forming apparatus 1.
Note that the canceling operation of the shutdown process differs between when the main switch 41 is turned off during standby and when the job is being executed, and will be described separately below.

“Cancellation of shutdown processing when the main switch is turned off during standby”
FIG. 4 is a timing chart showing the transition of the operation state of the image forming apparatus (FIG. 1) when the main switch 41 is turned off during standby and then the main switch 41 is turned on again to cancel the shutdown process. In addition, A to F (elements representing the operation state of each part) and t1 to t4 (timing) shown in the figure are synonymous with those in FIG. As will be described later, t5 is the ON operation timing of the main switch 41 during the shutdown adjustment period, and t6 is the return timing to the standby state. In addition, since the apparatus is started up from the power-off state, enters the standby state, and the operation until the main switch 41 is turned off and the shutdown adjustment period is reached during the standby state is the same as the operation of FIG. The description of the operation is referred to and the description is omitted here.

Next, operations after the main switch 41 is turned on during the shutdown adjustment period (timing t5) will be described.
It is determined that the ON operation of the main switch 41 during the shutdown adjustment period is a request to cancel the scheduled shutdown process and return to the standby state. In this embodiment, the controller 2 checks the on operation of the main switch 41 based on the detection signal 101 during the shutdown adjustment period. That is, the on operation of the main switch 41 is detected by “Low” of the detection signal 101, and the timing t5 at which this detection is performed is within the shutdown adjustment period (A, B and F at the timing t5 in FIG. 4). The operation of returning to the standby state is performed without shifting to the shutdown process.
In the operation to return to the standby state, after the main switch 41 is turned on, the power from the power supply line on the main switch 41 side is supplied to the power circuit 43, and the output of the DC power of the power circuit 43 can be maintained without dropping. By setting the control signal 102 to the switch means 42 to “Low (off)”, the power supply to the power supply line on the switch means 42 side is cut off. In addition, an operation for shifting to a standby state is performed at timing t6 after the shutdown adjustment period has elapsed.

“Cancellation of shutdown processing when the main switch is turned off during job execution”
FIG. 5 is a timing chart showing the transition of the operation state of the image forming apparatus 1 (FIG. 1) when the main switch 41 is turned off during job execution and then the main switch 41 is turned on again to cancel the shutdown process. . In addition, A to F (elements representing the operation state of each part) and t1 to t4 (timing) shown in the figure are synonymous with those in FIG. As will be described later, t5 is the ON operation timing of the main switch 41 during the shutdown adjustment period, and t6 is the return timing to the standby state. In addition, after starting up the device from the power-off state and passing through the standby state, the processing of the accepted job is started, and the operation until the main switch 41 is turned off during the job execution and the shutdown adjustment period is reached. Since the operation is not different from the operation of FIG. 3, the description of the operation is referred to and the description is omitted here.

Next, operations after the main switch 41 is turned on during the shutdown adjustment period (timing t5) will be described.
It is determined that the ON operation of the main switch 41 during the shutdown adjustment period is a request to cancel the scheduled shutdown process and return to the standby state. In this embodiment, the controller 2 checks the on operation of the main switch 41 based on the detection signal 101 during the shutdown adjustment period. That is, the on operation of the main switch 41 is detected by “Low” of the detection signal 101, and the timing t5 at which this detection is performed is within the shutdown adjustment period (A, B, and F at the timing t5 in FIG. 5). The operation of returning to the standby state is performed without shifting to the shutdown process.
In the operation to return to the standby state, after the main switch 41 is turned on, the power from the power supply line on the main switch 41 side is supplied to the power circuit 43, and the output of the DC power of the power circuit 43 can be maintained without dropping. By setting the control signal 102 to the switch means 42 to “Low (off)”, the power supply to the power supply line on the switch means 42 side is cut off. In addition, an operation for shifting to a standby state is performed at timing t6 after the shutdown adjustment period has elapsed.

<Control flow executed by the controller according to the operation of the main switch>
Next, a control operation executed by the image forming apparatus 1 (FIG. 1) according to the present embodiment in response to an on / off operation of the main switch 41 will be described based on a control flow shown in FIG.
The controller 2 of the image forming apparatus 1 executes an operation according to the control flow shown in FIG. 6 and performs the operations shown in FIGS. 2 to 5 performed according to different conditions by this control operation. enable.
In this control flow, when the user turns on the main switch 41 and AC power is supplied, the DC power is output from the power supply circuit 43 to the controller 2 in response to the supply of the power.
When this control flow is activated, first, activation processing is performed (step S101). The start-up process is a process for starting up the control system so that a job can be processed, and includes a process called initialization.

When the activation process is completed, the standby state is entered, and the state of the on / off detection signal 101 of the main switch 41 is checked (step S102). In this control flow, the transition to the next step S103 is not performed until the user turns off the main switch 41 and the detection signal 101 becomes “High” (switch off). The operation of the image forming apparatus 1 is to execute job processing if there is a job processing request while the detection signal 101 is “Low” (switch-on).
Here, when the user turns off the main switch 41, the detection signal 101 “High” is generated (step S102—YES).
In response to the generation of the detection signal 101 “High”, the control signal 102 “High” is immediately transmitted to the switch means 42, and power is supplied by the power supply line on the switch means 42 side (step S 103).
If there is a job being executed when the control signal 102 is set to “High” (step S104-YES), the process of the job being executed is not performed without proceeding to the next shutdown adjustment period (step S105). Wait until is finished.
When the processing of the job being executed is completed (step S104-NO), the process proceeds to the shutdown adjustment period (step S105).

In the shutdown adjustment period, the cancellation of the shutdown process is accepted. That is, when the user notices that the off operation performed by the user in step S102 is incorrect, the user can operate the main switch 41 again (on operation) to cancel the shutdown process and return to the standby state. become. Therefore, in the shutdown adjustment period, whether or not the main switch 41 is turned on and cancellation of the shutdown process is instructed is checked based on whether or not the detection signal 101 is “Low” (switch on) (step S1). S106).
Here, if the detection signal 101 is “Low” (switch-on) (YES in step S106), it is a case where cancellation of the shutdown process is instructed. Therefore, as a measure for returning to the standby state, first, in step S103. Then, the control signal 102 set to “High” is set to “Low” to cut off the power supply to the power supply line on the switch means 42 side (step S111). This is because the power supply line on the main switch 41 side has already been supplied by turning on the main switch 41 (step S106).
Next, the end of the shutdown adjustment period is confirmed (step S112-NO), and the process returns to the standby state, that is, step S102.

On the other hand, if the main switch 41 is not turned on in step S106 (step S106-NO) and the shutdown adjustment period has elapsed (step S107-NO), the shutdown process is executed (step S108).
When the shutdown process ends, the control signal 102 set to “High” in step S103 is set to “Low (off)” (step S109).
When the control signal 102 is set to “Low”, the AC power supply from the power supply line on the switch means 42 side to the power supply circuit 43 is cut off, and the DC output of the power supply circuit 43 to the controller 2, the engine 3, etc. is also turned off. The power is turned off (step S110).
The power flow is turned off, and this control flow ends.
As described above, according to this embodiment, when the main switch 41 is erroneously turned off and the power is turned off, or when the power is turned off by a third party, the main switch 41 is simply turned on. In addition, the shutdown process can be canceled by a natural operation, and the operation state intended by the user can be quickly restored. Further, it is possible to prevent a decrease in the defect reproduction rate due to the execution of the shutdown process, such as when performing a defect analysis.

“Embodiment 2”
This embodiment shows an example in which an operation adapted to the case where the instruction to cancel the shutdown process in the first embodiment is performed after a predetermined time has elapsed is added.
In the first embodiment, a predetermined time (shutdown adjustment period) after the controller 2 starts the operation of shifting to the end process upon receiving power supply from the power supply line on the switch means 42 side according to the turning-off operation of the main switch 41. When the main switch 41 is turned on, the scheduled shutdown process is canceled so that the job can be immediately returned to a standby state where the job can be processed.
However, if the user's instruction is not in time within the shutdown adjustment period, the power is turned off as scheduled, and the user's request that the requested job should be processed quickly cannot be met. Therefore, even if the shutdown adjustment period has elapsed, as long as the termination process (including the shutdown process) is not completed, an operation that meets this requirement is performed.
In this embodiment, the restart process of the control system is promptly performed according to the ON operation of the main switch 41 performed by the user after the shutdown adjustment period has elapsed. Specifically, when the end process (including the shutdown process) is finished, the process is immediately restarted to start up to a standby state.

In the operation shown in FIGS. 4 and 5 in the first embodiment, when the instruction for canceling the shutdown process to be performed within the shutdown adjustment period is not in time, immediately after the end process being executed is completed, the operation is immediately restarted. With reference to FIG. 7 showing the transition of the operation state of each part in the image forming apparatus 1, the operation from activation to startup in the standby state will be described.
Note that the operation added in this embodiment is an operation performed in accordance with a user operation performed in the shutdown process (end process) period, that is, an operation after the shutdown process, so that the main switch 41 that causes the shutdown process is turned off. It has nothing to do with whether the operation was performed during standby or during job execution. Accordingly, only an example in which the main switch 41 is turned off during standby will be described below.

  FIG. 7 is a timing chart showing the transition of the operation state of the image forming apparatus 1 (FIG. 1) when the cancel operation of the shutdown process performed by turning off the main switch 41 during standby is not in time and restarting is performed. is there. In addition, A to F (elements representing the operation state of each part) and t1 to t4 (timing) shown in the figure are synonymous with those in FIG. As will be described later, t5 is an ON operation timing of the main switch 41 after the shutdown adjustment period has elapsed, and t6 indicates a timing of starting the restart process. In addition, since the apparatus is started up from the power-off state, enters the standby state, and the operation until the main switch 41 is turned off and the shutdown adjustment period is reached during the standby state is the same as the operation of FIG. The description of the operation is referred to and the description is omitted here.

Next, an operation after the main switch 41 is turned on after the shutdown adjustment period has elapsed (timing t5) will be described.
In the operation of FIG. 7, there is no user operation during the shutdown adjustment period, the shutdown process is started, and the main switch 41 is turned on at timing t5 during the shutdown process. The ON operation at this timing is determined to be a request to immediately restart at the end of the shutdown process being processed. In this embodiment, the controller 2 checks the on operation of the main switch 41 based on the detection signal 101 during the shutdown processing period. In other words, the on operation of the main switch 41 is detected by “Low” of the detection signal 101, and the timing t5 at which this detection is performed is the shutdown processing period (in FIG. 7, A, B, and F at timing t5). Based on the determination of (status), an operation to immediately restart is performed at the end of the shutdown process.
The restart process is performed at timing t6 when the shutdown process ends. At the time of restart, the main switch 41 is already turned on, the power from the power supply line on the main switch 41 side is supplied to the power supply circuit 43, and the output of the DC power supply of the power supply circuit 43 is in a normal state. However, since the control signal 102 to the switch means 42 is “High (on)”, the power supply to the power supply line on the switch means 42 side is cut off by setting it to “Low (off)”. The restart process is a process for starting up to a state that can process the job, such as a process to set again various setting data saved by the shutdown process, as an operation condition necessary for proper operation of the device. .

Next, a control operation executed by the image forming apparatus 1 according to the present embodiment in response to an on / off operation of the main switch 41 will be described based on a control flow shown in FIG.
The controller 2 of the image forming apparatus 1 executes an operation in accordance with the control flow shown in FIG. 8, and enables the operations shown in FIGS. 2 to 5 and 7 to be performed by this control operation. This control flow is the same as that of the first embodiment added to the first embodiment (that is, an operation that is applied when an instruction operation for canceling the shutdown process is performed after a predetermined time has elapsed). As in the control flow described above with reference to FIG. 6, steps S201 to S211 in FIG. 8 and steps S101 to S110 in FIG. 6 are common (however, step S209 in FIG. 8 is excluded). Therefore, description of this common part will be omitted here with reference to the description of FIG.

In the shutdown adjustment period transitioning to step S205 in the control flow of FIG. 8, the cancellation of the shutdown process is accepted. That is, when the user notices that the off operation performed in step S202 in the control flow of FIG. 8 is incorrect, the user operates the main switch 41 again (on operation), thereby canceling the shutdown process and waiting. It becomes possible to return to the state. Therefore, in the shutdown adjustment period, whether or not the main switch 41 is turned on and cancellation of the shutdown process is instructed is checked based on whether or not the detection signal 101 is “Low” (switch on) (step S1). S206).
Here, if the detection signal 101 is “Low” (switch-on) (YES in step S206), it is a case where cancellation of the shutdown process is instructed. Therefore, as a measure for returning to the standby state, first, in step S203. Then, the control signal 102 set to “High” is set to “Low” to cut off the power supply to the power supply line on the switch means 42 side (step S212). This is because the power supply line on the main switch 41 side has already been supplied by the ON operation of the main switch 41 (step S206).
Next, the end of the shutdown adjustment period is confirmed (step S213-NO), and the process returns to the standby state, that is, step S202.

On the other hand, if the main switch 41 is not turned on in step S206 (step S206-NO) and the shutdown adjustment period has elapsed (step S207-NO), the shutdown process is executed (step S208).
In this control flow, when an instruction for canceling the shutdown process is performed in time for the shutdown adjustment period, when the shutdown process is completed, the process is immediately restarted and the process for starting the standby process is performed. To. The instruction for this process is determined by an ON operation of the main switch 41 performed during the execution of the shutdown process. Therefore, after the shutdown process in step S208 is started, it is confirmed that the shutdown process has not been completed (step S209-NO), and it is checked whether or not the main switch 41 is turned on (step S214). .
Here, if the main switch 41 is not turned on (step S214-NO), the main switch 41 is checked repeatedly until the shutdown process is completed (step S209-YES).

On the other hand, if it is confirmed in step S214 that the main switch 41 is turned on (step S214-YES), the end of the shutdown process is confirmed (step S215-YES), and the control signal 102 set to “High” in step S203 is sent. “Low” is set to cut off the power supply to the power supply line on the switch means 42 side (step S216).
Further, a restart process is performed immediately after the shutdown process is completed (step S217). In the restart process, a process for resetting various setting data saved by the shutdown process as an operation condition necessary for proper operation of the device is performed, and a job process is started.
After the restart process, the process returns to the standby state, that is, step S202.
As described above, according to this embodiment, even when the timing for turning on the main switch 41 performed as an instruction operation for canceling the shutdown process is late and the cancellation process is not in time, the control system of the controller 2 immediately after the shutdown process is completed. Is restarted, the operation of the system is guaranteed and the processing can be performed quickly.

“Embodiment 3”
This embodiment shows an example of a form in which a means for notifying the user of the execution of the cancellation is added to the above-described embodiment 1 that enables cancellation of the shutdown process.
In the first embodiment, a predetermined time (shutdown adjustment period) after the controller 2 starts the operation of shifting to the end process upon receiving power supply from the power supply line on the switch means 42 side according to the turning-off operation of the main switch 41. When the main switch 41 is turned on, the scheduled shutdown process is canceled so that the job can be immediately returned to a standby state where the job can be processed.
However, in order to cancel the shutdown process, the main switch 41 is turned off once, the power off is instructed, and then the main switch 41 is turned off within a limited period of time, which is the shutdown adjustment period. Therefore, the user is confused without knowing which instruction operation performed twice is effective. Therefore, in this embodiment, when cancellation of the shutdown process is executed, this is notified through an operation panel (notification / operation means) that functions as a user interface.

FIG. 9 is a block diagram illustrating a schematic configuration of the image forming apparatus according to the present embodiment.
The image forming apparatus 1 of FIG. 9 is basically the same as the image forming apparatus 1 of FIG. 1 except that the operation panel (notification / operation means) 5 as an additional configuration in this embodiment is incorporated in the image forming apparatus 1 (FIG. 1). There is no difference. The same components in FIG. 9 and FIG. 1 are given common reference numerals, and the device configuration is as described above with reference to FIG. Therefore, description is abbreviate | omitted here with reference to description of FIG.
The operation panel 5 of the image forming apparatus 1 shown in FIG. 9 includes display means (screen, lamp, sound, etc.) for notifying the user of various device information such as the operation state of the image forming apparatus 1, and the user The unit has an operation unit for performing an instruction (input) operation such as an operation condition to be performed, and provides a function as a user interface, and operates under the control of the controller 2.

Next, a control operation executed by the image forming apparatus 1 according to the present embodiment in response to an on / off operation of the main switch 41 will be described based on a control flow shown in FIG.
The control flow shown in FIG. 10 is based on the assumption that the operation based on the control flow of FIG. 8 shown in the second embodiment is performed, and when the shutdown process is canceled, the operation panel 5 indicates that the shutdown process has been canceled. A procedure for informing the user is added. The control flow of FIG. 8 (including the control flow of FIG. 6 shown in the first embodiment) is a procedure that enables the operations shown in FIGS. 2 to 5 and 7 to be performed as described above. Have. That is, the control flow shown in FIG. 10 differs from the control flow shown in FIG. 8 only in that a procedure (step S319) for displaying on the operation panel 5 for notifying the user of cancellation of the shutdown process is added. Therefore, the description of the procedure of the control flow other than the procedure for performing this display (step S319) is omitted here with reference to the description of FIG.

In the shutdown adjustment period transitioning to step S305 in the control flow of FIG. 10, the cancellation of the shutdown process is accepted. That is, when the user notices that the off operation performed in step S302 in the control flow of FIG. 10 is incorrect, the user operates the main switch 41 again (on operation) to cancel the shutdown process and wait. It becomes possible to return to the state. Therefore, in the shutdown adjustment period, whether or not the main switch 41 is turned on and cancellation of the shutdown process is instructed is checked based on whether or not the detection signal 101 is “Low” (switch on) (step S1). S306).
Here, if the detection signal 101 is “Low” (switch on) (YES in step S306), it is a case where cancellation of the shutdown process is instructed. Therefore, as a measure for returning to the standby state, first, in step S303. Then, the control signal 102 set to “High” is set to “Low” to cut off the power supply to the power supply line on the switch means 42 side (step S312).

At the same time, in order to notify the user that the ON operation of the main switch 41 has been accepted as an instruction for canceling the shutdown process, a display notifying that the shutdown process has been canceled is displayed on the screen of the display means of the operation panel 5 (step S319).
Next, the end of the shutdown adjustment period is confirmed (step S313-NO), and the process returns to the standby state, that is, step S302.
As described above, according to this embodiment, it is possible to cancel the shutdown process by clearly indicating that the shutdown process has been canceled on the screen of the display means provided on the operation panel 5 without checking the state of the control system. It is possible to determine whether or not it has been done, and it is possible to determine the next action to be taken without confusing the user, thereby enhancing convenience.

“Embodiment 4”
This embodiment shows another example of the embodiment in which means for notifying the user that the shutdown process performed in accordance with the instruction for canceling the shutdown process in the first embodiment is canceled.
This embodiment includes means for notifying a user for the same purpose as that of the third embodiment, and the notification method is different from that of the third embodiment, but there is no difference other than this.
In this embodiment, in addition to the display on the screen of the display means provided on the operation panel 5 used as a means for notifying the user that the shutdown process has been canceled in the third embodiment, the other provided on the operation panel 5 The buzzer which is the notification means is used.

FIG. 11 is a diagram illustrating a control flow of processing executed by the image forming apparatus 1 according to the present embodiment in response to an on / off operation of the main switch 41.
The control flow shown in FIG. 11 is different from the control flow of FIG. 10 only in the operation content in the procedure (step S319) for notifying the user of cancellation of the shutdown process in the control flow of FIG. 10 shown in the third embodiment. Therefore, the description of the procedure of the control flow other than the procedure of performing notification to the user (step S419) is omitted here with reference to the description of FIG.

If the detection signal 101 is “Low” (switch-on) in step S406 in the control flow of FIG. 11 (step S406-YES), it is a case where the cancellation of the shutdown process is instructed, so that the process returns to the standby state. As a measure, first, the control signal 102 set to “High” in Step S403 is set to “Low” to cut off the power supply of the power supply line on the switch means 42 side (Step S412).
At the same time, in order to notify the user that the ON operation of the main switch 41 has been accepted as an instruction for canceling the shutdown process, a display notifying that the shutdown process has been canceled is displayed on the screen of the display means of the operation panel 5, A buzzer provided as notification means on the operation panel 5 is sounded (step S419).
Next, the end of the shutdown adjustment period is confirmed (step S413—NO), and the process returns to the standby state, that is, step S402.
As described above, according to this embodiment, in addition to displaying on the operation panel 5 that the shutdown process has been canceled, a buzzer is sounded to notify the user that the shutdown process has been canceled. Even if only the display is overlooked, the situation can be surely notified.

“Embodiment 5”
In each of the above-described embodiments, a predetermined time (shutdown adjustment period) after the controller 2 receives power supply from the power supply line on the switch means 42 side and starts an end process in accordance with the turning-off operation of the main switch 41. When the main switch 41 is turned on, the scheduled shutdown process is canceled so that the job can be immediately returned to a standby state where the job can be processed.
However, if the shutdown adjustment period is fixed, there may be cases where it does not necessarily match the timing of the cancel operation that the user thinks is desirable depending on the usage situation. Therefore, in this embodiment, an optimal operation can be obtained by providing an input unit that can change the length of the set shutdown adjustment period by a user operation.
Since an operation panel is used as the input unit, the present embodiment can be implemented by the image forming apparatus 1 having the configuration shown in FIG. 9 having the operation panel (notification / operation unit) 5.

Here, a control operation executed by the image forming apparatus 1 according to the present embodiment in response to an on / off operation of the main switch 41 will be described based on a control flow shown in FIG.
The control flow shown in FIG. 12 adds step S520 as a procedure for setting the shutdown adjustment period on the assumption that the operation based on the control flow of FIG. 11 shown in the fourth embodiment is performed. This is different from the control flow of FIG. Therefore, for the other procedures except the procedure for setting the shutdown adjustment period (step S520) in the control flow, refer to the description of FIG. 11 (including the descriptions of FIGS. 8 and 6 related to FIG. 11). The description is omitted here.
In this embodiment, the control flow shown in FIG. 11 of the fourth embodiment is used. However, the control flow of the first to third embodiments may of course be applied.

In the control flow of FIG. 12, when the image forming apparatus 1 starts up in a state where the activation process is completed in step S501 and the job can be processed, the user can request processing through the operation panel 5. The user instructs various operating conditions from the initial screen to be displayed, and opens an input screen for setting.
A screen for setting the shutdown adjustment period is prepared as one of the setting input screens, and the length required by the user is set by an input operation to the setting screen (step S520). As the input means used for this setting, for example, it is possible to adopt a method that allows an arbitrary value within the setting range to be input.
The shutdown adjustment period set in step S520 is used in step S507 for managing the subsequent shutdown adjustment period. During this period, whether or not the main switch 41 is turned on and cancellation of the shutdown process is instructed. Is checked based on whether or not the detection signal 101 is “Low” (switch-on) (step S506).
As described above, according to this embodiment, the shutdown adjustment period can be set to a length required by the user, so that cancellation of the shutdown process can be instructed under an optimum operating condition for the user, and the shutdown adjustment period is unnecessarily extended. Without the performance can be improved.

“Embodiment 6”
In each of the above-described embodiments, a predetermined time (shutdown adjustment period) after the controller 2 receives power supply from the power supply line on the switch means 42 side and starts an end process in accordance with the turning-off operation of the main switch 41. When the main switch 41 is turned on, the scheduled shutdown process is canceled so that the job can be immediately returned to a standby state where the job can be processed.
However, regardless of whether or not to cancel the shutdown process, the process will not proceed unless the above shutdown adjustment period has passed, so depending on the usage situation, it may be better not to perform the operation to cancel the shutdown process. May be better. Therefore, in this embodiment, it is possible to instruct whether or not to operate the means for canceling the shutdown process, that is, by providing an input means that can set on / off of the cancellation process of the shutdown by a user operation. , So that the optimum operation can be obtained.
Since an operation panel is used as the input unit, the present embodiment can be implemented by the image forming apparatus 1 having the configuration shown in FIG. 9 having the operation panel (notification / operation unit) 5.

Here, the control operation executed by the image forming apparatus 1 according to the present embodiment in response to the on / off operation of the main switch 41 will be described based on the control flow shown in FIG.
The control flow shown in FIG. 13 is based on the assumption that the operation based on the control flow shown in FIG. 12 shown in the fifth embodiment is performed, and steps S602, S603, and S608 is added, and only this procedure is different from the control flow of FIG. Accordingly, with respect to other procedures except for the procedure (steps S602, S603, and S608) relating to the setting of the shutdown cancel process in the control flow (steps S602, S603, and S608), FIG. The description is omitted here with reference to (including the description of FIG. 11).
Although this embodiment is based on the control flow of FIG. 12 of the fifth embodiment, it may be applied to the control flows of the first to fourth embodiments.

In the control flow of FIG. 13, when the image forming apparatus 1 starts up in a state where the activation process is completed in step S601 and the job can be processed, the user can request processing through the operation panel 5. The user instructs various operating conditions from the initial screen to be displayed, and opens an input screen for setting.
In this embodiment, as an input screen for the setting, a screen for setting on / off of a shutdown process for a shutdown and a screen for setting a shutdown adjustment period are prepared. First, for setting on / off of a cancellation process for a shutdown On / off of the cancel processing input on the screen is acquired as a setting condition (step S602).
Next, it is confirmed whether or not the setting of the cancel processing for shutdown performed in step S602 is on or off (step S603). If not canceled (step S603-NO), the shutdown adjustment period setting screen is displayed. The input shutdown adjustment period is acquired as a condition used for period management in step S611 for managing the subsequent shutdown adjustment period (step S604).
On the other hand, if it is confirmed in step S603 that the setting is to be canceled (step S603—YES), the process immediately proceeds to the next step S605.

When Steps S601 to S604 are finished, a standby state is entered, and the state of the on / off detection signal 101 of the main switch 41 is checked (Step S605). In this control flow, the transition to the next step S606 is not performed until the user turns off the main switch 41 and the detection signal 101 becomes “High” (switch off).
Here, if the main switch 41 is turned off by the user, the detection signal 101 “High” is generated (YES in step S605).
In response to the generation of the detection signal 101 “High”, the control signal 102 “High” is immediately transmitted to the switch means 42, and power is supplied by the power supply line on the switch means 42 side (step S 606).
If there is a job being executed when the control signal 102 is set to “High” (step S607—YES), the processing of the job being executed is completed without proceeding to step S608 for checking whether the next cancel processing is on. Wait until you do.

When the processing of the job being executed is completed (step S607-NO), it is checked whether or not the setting condition of the shutdown cancel processing acquired in step S602 is on (step S608).
Here, if the setting condition of the cancel process for shutdown is on (step S608-YES), the process proceeds to the shutdown adjustment period (step S609).
In the shutdown adjustment period, the cancellation of the shutdown process is accepted. That is, when the user notices that the off operation performed by the user in step S605 is incorrect, the shutdown process can be canceled and returned to the standby state by operating the main switch 41 again (on operation). become. Therefore, in the shutdown adjustment period, whether or not the main switch 41 is turned on and cancellation of the shutdown process is instructed is checked based on whether or not the detection signal 101 is “Low” (switch on) (step S1). S610).
Here, if the detection signal 101 is “Low” (switch-on) (step S610—YES), it is a case where cancellation of the shutdown process is instructed, so the shutdown process is canceled and the process returns to the standby state. The processing at this time is the same as the processing of steps S412, S419, and S413 in the control flow of FIG. 11, and is as described in the fourth embodiment.

On the other hand, if the setting condition of the cancel process for shutdown is OFF (step S608-NO), the process of steps S609 to S611 performed during the shutdown adjustment period is skipped and the shutdown process is immediately executed (step S612).
One of the processes after the shutdown process of step S612 is the process of steps S613, S619, S614, and S615 that ends when the power is turned off, and the other is the process of steps S613, S619, S620, S621, and S622 that returns from the restart to the standby state. It is. These processes are the same as the processes in steps S209, S214, S210, and S211 and the processes in steps S209, S214, S215, S216, and S217 in the control flow of FIG. 8, respectively, as described in the second embodiment.
As described above, according to this embodiment, whether or not the function for canceling the shutdown process is activated can be instructed by the user's operation. It can be faster and improve performance.

  DESCRIPTION OF SYMBOLS 1 .... Image forming apparatus 2. Controller 3. Engine 4. DC power supply / AC control board 5. Operation panel 41. Main switch 42. Switch means 42b Relay 43. Power supply circuit.

JP 2008-65242 A JP 2002-312075 A

Claims (6)

An electronic device that controls the operation of the device by a controller that operates upon receiving power supply,
A first switch as a main switch that can be turned on and off at any time provided in a power supply path from a power source to the controller;
Switch state detecting means for detecting an on / off state of the first switch;
A second switch connected in parallel with the first switch and turned on / off in response to a control signal from the controller;
The controller includes a means for sending a control signal for turning on the second switch on the condition that an off state is detected by the switch state detecting means, and a predetermined time from the time when the second switch is turned on. Means for executing a shutdown process of the controller scheduled when the switch state detecting means does not detect the on state of the first switch, and the predetermined time from the time when the second switch is turned on. An electronic apparatus comprising: means for canceling a scheduled shutdown process of the controller when an ON state is detected by the switch state detecting means. The electronic device according to claim 1,
When the controller detects the ON state by the switch state detecting means during execution of the controller shutdown process after the predetermined time has elapsed from the time when the second switch is turned ON, An electronic apparatus comprising: means for restarting the controller after completion of a shutdown process. The electronic device according to claim 1,
As a user interface under the control of the controller, it has a notification / operation means for notifying the state of the device and inputting instructions to the device by operation,
The electronic device is characterized in that the notification / operation unit is a unit that notifies cancellation of a shutdown process. The electronic device according to claim 3,
The electronic device is characterized in that the notification / operation unit is a unit that notifies the cancellation of the shutdown process by at least one of a screen display and a buzzer. The electronic device according to any one of claims 1 to 4,
The notification / operation means includes means for performing an input for adjusting a predetermined time from when the second switch is turned on, which determines whether to execute or cancel the shutdown process. Electronic equipment. The electronic device according to any one of claims 1 to 5,
The electronic device according to claim 1, wherein the notification / operation unit includes a unit for performing an input to instruct whether or not to operate the unit for canceling the shutdown process.

Images