JP2019040697A - Electronic equipment and charging program - Google Patents

Abstract

To provide electronic equipment and a charging program for obtaining an accurate system time.SOLUTION: In a MFP100, a CPU121 corrects a discharge curve becoming the base of power supply from a secondary battery 112 to a RTC113, by using the voltage of the secondary battery 112 acquired at the moment in time of start processing and the acquired time, and the voltage of the secondary battery 112 acquired at the moment in time of end processing and the acquired time, and obtains a prediction time when the voltage of the secondary battery 112 reaches a threshold level from the corrected discharge curve, before setting the obtained prediction time in the RTC113. When confirming that the prediction time has been reached, the RTC113 sends an alarm signal for notifying of charging start to a power supply control section 111. Since charging of the secondary battery 112 can be started at an appropriate time, even if the discharge characteristics of the secondary battery 112 are changed by secular change, and use environment, malfunction of the RTC113 can be prevented.SELECTED DRAWING: Figure 1

Description

  The present invention relates to an electronic device and a charging program suitable for using a secondary battery.

  For example, in an image forming apparatus such as an MFP (Multifunction Peripheral) which is one of electronic devices, execution of print job reservation, creation of file or folder creation date or update date (time stamp), access information recording ( Time information called system time is used for logs and events. By the way, since the system time is managed in the memory, it is deleted when the image forming apparatus is in the power OFF mode. Therefore, when the image forming apparatus shifts from the power OFF mode to the power ON mode, the image forming apparatus acquires the current time from a hardware clock, for example, RTC (Real Time Clock), and reflects it in the system time. Note that the RTC operates with the power of the commercial power supply (AC 100 V power supply) when the image forming apparatus is in the power ON mode, but operates with the power of the provided secondary battery when the image forming apparatus is in the power OFF mode.

  In addition, although the operating voltage of RTC changes with products, the operation | movement in the range of 5.1-2.0V is stabilized, for example. Further, the minimum voltage at which the RTC can operate varies depending on the product, but is, for example, less than 2.0V to about 1.1V.

  For this reason, when the capacity of the secondary battery becomes less than a certain value (for example, less than 1.1 V) while the image forming apparatus is in the power OFF mode, the operation of the RTC is stopped. As described above, if the operation of the RTC is stopped while the image forming apparatus is in the power-off mode, the current time cannot be obtained from the RTC when the image forming apparatus shifts to the power-on mode. The system time cannot be obtained.

  In order to solve such a problem, in Patent Document 1, when the output voltage of the secondary battery reaches a voltage equal to or lower than a specified voltage by the sub-control circuit, the power supply unit is changed from the non-output state to the output state to the secondary battery. A first predetermined time, which is a time from when the power supply unit changes from the output state to the non-output state until a specified time (for example, every 24 hours), is measured based on the clock from the RTC. When the second predetermined time from when the battery is changed from the output state to the non-output state until the output voltage of the secondary battery reaches the specified voltage or lower is shorter than the first predetermined time, the measurement of the first predetermined time is stopped. An image forming apparatus is proposed.

JP 2013-049144 A

  In the image forming apparatus disclosed in Patent Document 1 described above, when the second predetermined time is shorter than the first predetermined time, the power consumed by the measurement of the first predetermined time can be suppressed by stopping the measurement of the first predetermined time. The use time of the secondary battery can be prolonged.

  By the way, in the image forming apparatus of Patent Document 1, although the secondary battery can be charged when the remaining amount of the secondary battery decreases, the second predetermined time until the output voltage of the secondary battery reaches a threshold value or less. Time is decided uniquely. Here, in the secondary battery, the rate of decrease in capacity changes according to aging and usage environment. That is, the secondary battery has a long service life and tends to have a faster capacity reduction rate in a high temperature and high humidity environment. For this reason, if the second predetermined time is uniquely determined, depending on the secular change and the use environment, it is predicted that the capacity of the secondary battery will reach the threshold value or less earlier than the second predetermined time. . In this case, when the RTC is operating with the power of the secondary battery, the remaining amount of the secondary battery reaches the specified voltage or less earlier than the second predetermined time, and the RTC stops operating. Become.

  As described above, when the RTC stops operating due to the remaining amount of the secondary battery reaching the threshold value or less, the current time is acquired from the RTC when the image forming apparatus shifts to the power ON mode. There is a problem that the system time cannot be obtained because the system time cannot be obtained.

  This invention is made | formed in view of such a condition, and it aims at providing the electronic device and charging program which can eliminate the said problem.

The electronic device of the present invention is charged by the power supply control unit when the voltage reaches a threshold value with the power supply control unit that controls power supply, the RTC that measures the current time, and the power supply to the RTC. A CPU that starts a startup process or an end process based on a notification of a mode transition relating to a power supply from the power supply control unit, acquires a current time from the RTC during the startup process, and reflects it in a system time; The power supply control unit detects a voltage of the secondary battery at the time of mode transition and notifies the CPU of the first battery of the secondary battery acquired at the time of the startup process. Power to the RTC of the secondary battery using the voltage and the acquired first time, the second voltage of the secondary battery acquired at the time of the end process, and the acquired second time As a base with supply The discharge curve was corrected, the voltage of the secondary battery from corrected the discharge curve was determined predicted time which reaches a threshold value, and sets the predicted time obtained in the RTC,
When the RTC confirms that the predicted time has been reached, the RTC sends an alarm signal notifying the start of charging to the power supply control unit.
The power control unit shifts to any one of a power ON mode, a power OFF mode, and a charge mode, and the CPU shifts the first voltage and the first voltage with a shift from the power OFF mode to the power ON mode. 1 is acquired, the second voltage and the second time are acquired in accordance with the transition from the power ON mode to the power OFF mode, the process is terminated after the predicted time is set in the RTC. It is characterized by doing.
The CPU acquires the first voltage and the first time as the charging mode is shifted from the power-off mode, and the second time is determined as the power-off mode is shifted from the charging mode. And the second time is acquired, and after the predicted time is set in the RTC, the process is terminated.
The charging program of the present invention is a charging program that is executed by a computer that controls an electronic device, the step of controlling power supply by a power supply control unit, the step of measuring the current time by an RTC, and the voltage as a threshold value. When the power reaches the RTC by the secondary battery charged by the power supply control unit, the CPU starts the startup process or the termination process based on the mode change notification from the power supply control unit by the CPU. And acquiring the current time from the RTC during the startup process and reflecting it in the system time, and the power supply control unit detects the voltage of the secondary battery at the time of mode transition and The CPU notifies the first voltage of the secondary battery acquired at the time of the startup process, the acquired first time, and the time of the end process. Using the acquired second voltage of the secondary battery and the acquired second time, the discharge curve serving as a base accompanying the power supply of the secondary battery to the RTC is corrected, and the corrected discharge curve To determine the predicted time when the voltage of the secondary battery reaches a threshold value, set the calculated predicted time to the RTC, and confirm that the RTC has reached the predicted time, An alarm signal notifying the start of charging is transmitted.
In the electronic device and the charging program of the present invention, power supply is controlled by the power controller, the current time is measured by the RTC, power is supplied to the RTC by the secondary battery, and the mode transition relating to the power from the power controller is performed by the CPU. On the basis of this notification, start processing or end processing is started, and the current time from the RTC is acquired during the start processing, and reflected in the system time. In addition, when the power supply control unit detects the voltage of the secondary battery at the time of mode transition and notifies the CPU, the CPU acquires the first voltage of the secondary battery acquired at the time of the startup process and the acquired first voltage. , The second voltage of the secondary battery acquired at the time of the termination process, and the acquired second time are used to correct the base discharge curve associated with the power supply to the RTC of the secondary battery. The predicted time when the voltage of the secondary battery reaches the threshold value is obtained from the corrected discharge curve, and the calculated predicted time is set in the RTC. When the RTC confirms that the predicted time has been reached, the RTC sends an alarm signal notifying the start of charging to the power supply control unit.
In this way, since the CPU can obtain the predicted time when the voltage of the secondary battery reaches the threshold value from the discharge curve corresponding to the discharge characteristics of the secondary battery, the voltage at which the remaining capacity of the secondary battery makes the RTC inoperable Before reaching the value, charging of the secondary battery can be started.

  According to the electronic device and the charging program of the present invention, even if the discharge characteristics of the secondary battery change due to aging or usage environment, the CPU determines the voltage of the secondary battery from the discharge curve corresponding to the discharge characteristics of the secondary battery. Is obtained, and charging of the secondary battery is started at an appropriate time, so that the inability to operate the RTC can be reliably prevented and an accurate system time can be obtained.

FIG. 6 is a diagram for explaining an embodiment when an electronic apparatus of the present invention is applied to an MFP. FIG. 2A is a diagram for explaining the power-on mode of the MFP, and FIG. 2B is a diagram for explaining the power-off mode of the MFP. FIG. FIG. 2 is a diagram for explaining a charging mode of the MFP of FIG. 1. FIG. 4A illustrates an example of calculation of a predicted charging start time by the CPU of FIG. 1, and FIG. 4A illustrates an example of calculation of a predicted charging start time at the time of transition from the power ON mode to the power OFF mode. FIG. 4B is a diagram illustrating an example of calculation of an estimated charging start time at the time of transition from the charging mode to the power OFF mode. 3 is a flowchart for explaining a transition from a power ON mode to a power OFF mode in the MFP of FIG. 3 is a flowchart for explaining a transition from a power-off mode to a charging mode in the MFP of FIG. 1. 3 is a flowchart for explaining a transition from a charging mode to a power-off mode in the MFP of FIG. 1. 3 is a flowchart for explaining a transition from a power-off mode to a power-on mode in the MFP of FIG.

  Hereinafter, an electronic device according to an embodiment of the present invention will be described with reference to FIGS. An example of an electronic device in the following description is an MFP (Multifunction Peripheral) that is a complex peripheral device equipped with a print function, a copy function, a FAX function, a data transmission / reception function via a network, and the like. And

  First, FIG. 1 shows an outline of the MFP 100. The MFP 100 includes a power switch 110, a power supply control unit 111, a secondary battery 112, an RTC (Real Time Clock) 113, and a control unit 120. Reference numeral 200 indicates a commercial power source (AC 100 V power source). Symbols b1 and b2 indicate buses, symbols r1 to r3 indicate lead wires for supplying power, and symbols s1 to s3 indicate signal lines for transmitting signals.

  The power switch 110 is operated when the power mode of the power control unit 111 is switched to the power ON mode or the power OFF mode. The power control unit 111 shifts to the power ON mode or the power OFF mode according to the operation of the power switch 110. That is, when the power switch 110 is operated while the power control unit 111 is in the power ON mode, the power control unit 111 shifts to the power OFF mode. On the other hand, when the power switch 110 is operated while the power control unit 111 is in the power OFF mode, the power control unit 111 shifts to the power ON mode.

The power supply control unit 111 detects the voltage of the secondary battery 112 at the time of the following (1) to (4) mode transition.
(1) When shifting from the power OFF mode to the power ON mode.
(2) When shifting from power ON mode to power OFF mode.
(3) When shifting from the power-off mode to the charging mode.
(4) When shifting from the charging mode to the power OFF mode.

Moreover, the power supply control part 111 changes the supply destination of the electric power of the commercial power supply (AC100V power supply) 200 according to the following power supply modes (5) to (7).
(5) In the power ON mode, power is supplied to the control unit 120 and the RTC 113 via the lead wires r1 and r2 (see FIG. 2A described later).
(6) No power is supplied in the power OFF mode (see FIG. 2B described later).
(7) In the charging mode, power is supplied to the system control unit 121A, the secondary battery 112, and the RTC 113 via the lead wires r1 to r3 (see FIG. 3 described later).
Further, although the details will be described later, when the power supply control unit 111 receives an alarm signal via the signal line s3 in the power supply OFF mode, the power supply control unit 111 shifts to the charging mode (see FIG. 3 described later).

  The details of the secondary battery 112 will be described later. As shown in FIG. 3 to be described later, when the power supply control unit 111 is in the charging mode, the secondary battery 112 is charged by the power of the commercial power supply (AC100V power supply) 200 from the power supply control unit 111. Do. Further, the secondary battery 112 supplies power to the RTC 113 when the power control unit 111 is in the power OFF mode. As shown in FIG. 2A or FIG. 3 described later, the RTC 113 uses the power of the commercial power supply (AC100V power supply) 200 from the power supply control unit 111 when the power supply control unit 111 is in the power ON mode or the charging mode. Operates and keeps the current time. Further, as shown in FIG. 2B described later, the RTC 113 operates with the power from the secondary battery 112 when the power control unit 111 is in the power OFF mode, and measures the current time. The RTC 113 will be described later in detail, but when it reaches the estimated charging start time Ts or Ts1 (see FIGS. 4A and 4B described later) set by the CPU 121, the RTC 113 supplies power via the signal line s3. An alarm signal is sent to the control unit 111. The operating voltage of the RTC 113 varies depending on the product, but is assumed to be in the range of 5.1 to 2.0 V, for example. Further, the minimum voltage at which the RTC 113 can operate varies depending on the product, but is assumed to be, for example, less than 2V to about 1.1V.

  The control unit 120 includes a system control unit 121A, a scanner control unit 124, a printer control unit 125, a FAX (Facsimile) control unit 126, a communication control unit 127, an image processing unit 128, and a panel operation control unit 129. The scanner control unit 124 controls the reading operation of a scanner unit (not shown). The printer control unit 125 controls a printer unit printing operation (not shown). The FAX control unit 126 controls data transmission / reception operations by a FAX unit (not shown). The communication control unit 127 controls transmission / reception of data and the like via a network via an I / F (interface) (not shown). The image processing unit 128 performs image processing (rasterization) on image data read by a scanner unit (not shown). Panel operation control unit 129 controls the display operation of a panel unit (not shown).

  The system control unit 121A controls the operation of each unit, and includes a CPU (Central Processing Unit) 121, a RAM (Random Access Memory) 122, and a ROM (Read-Only Memory) 123. Although details will be described later, the CPU 121 obtains a predicted start time Ts or Ts1 (see FIGS. 4A and 4B described later) for charging the secondary battery 112, and sets it in the RTC 113. The RAM 122 is a work memory for executing a program. The RAM 122 also stores print data that has been subjected to image processing by the image processing unit 128. The ROM 123 stores a control program for performing an operation check of each unit.

  Next, an outline of operations of the power supply control unit 111 and the CPU 121 will be described with reference to FIGS. 2 and 3, the lead wires r1 to r3, the frame line of the control unit 120, and the frame line of the system control unit 121A are indicated by solid lines or dotted lines. A solid line indicates that power from the power supply control unit 111 is supplied, and a dotted line indicates that power from the power supply control unit 111 is not supplied.

  First, FIG. 2A shows a case where the power control unit 111 is in the power ON mode. When the power supply control unit 111 is in the power supply ON mode, power from the commercial power supply (AC100V power supply) 200 is supplied to the control unit 120 and the RTC 113 via lead wires r1 and r2 indicated by solid lines. In this case, power is not supplied from the commercial power supply (AC100V power supply) 200 to the secondary battery 112 as in the lead wire r3 indicated by the dotted line.

  Next, FIG. 2B shows a case where the power control unit 111 is in the power OFF mode. When the power control unit 111 is in the power OFF mode, the operation of the power control unit 111 stops, so that the power from the commercial power source (AC100V power source) 200 via the lead wires r1 to r3 is shown as indicated by dotted lines. There is no supply.

  Next, FIG. 3 shows a case where the power control unit 111 is in the charging mode. When the power supply control unit 111 is in the charging mode, the power from the commercial power supply (AC100V power supply) 200 is supplied to the system control unit 121A, the secondary battery 112, and the RTC 113 via the lead wires r1 to r3 indicated by solid lines. . In this case, power is not supplied from the commercial power source (AC 100V power source) 200 to the control unit 120. The charging mode is started when the RTC 113 sends an alarm signal to the power supply control unit 111 via the signal line s3.

  Next, an example of the calculation of the predicted time Ts for starting charging the secondary battery 112 by the CPU 121 will be described with reference to FIG. Note that the CPU 121 is charged during the mode transition when the power control unit 111 transitions from the power ON mode to the power OFF mode and during the mode transition when the power control unit 111 transitions from the charging mode to the power OFF mode. The predicted start time Ts is calculated, and the calculated charge start predicted times Ts and Ts1 are set in the RTC 113 via the signal line s2.

  First, with reference to FIG. 4A, calculation of the estimated charging start time Ts at the time of mode transition when the power control unit 111 transitions from the power ON mode to the power OFF mode will be described. When shifting from the power OFF mode to the power ON mode, the power controller 111 supplies power to the controller 120 and the RTC 113 via the lead wires r1 and r2, as shown in FIG. Further, the power supply control unit 111 notifies the CPU 121 of the mode shift via the signal line s1. At this time, the CPU 121 executes a startup process. In addition, the power control unit 111 detects the voltage of the secondary battery 112 and notifies the CPU 121 via the signal line s1. The CPU 121 obtains the current time from the RTC 113 via the signal line s2 and reflects it in the system time during the start-up process. Here, the voltage of the secondary battery 112 received from the power supply control unit 111 during the startup process of the CPU 121 is set to V1. The time when the CPU 121 receives the voltage V1 of the secondary battery 112 from the power supply control unit 111 is defined as T1. The CPU 121 stores the voltage V <b> 1 and time T <b> 1 at the start-up process in the RAM 122.

  Next, when shifting from the power ON mode to the power OFF mode, the power controller 111 notifies the CPU 121 of the mode shift via the signal line s1. At this time, the CPU 121 executes an end process. In addition, the power control unit 111 detects the voltage of the secondary battery 112 and notifies the CPU 121 via the signal line s1. The CPU 121 acquires the current time from the system time during execution of the termination process. Here, the voltage of the secondary battery 112 received from the power supply control unit 111 during the termination process of the CPU 121 is set to V2. The time when the CPU 121 receives the voltage V2 of the secondary battery 112 from the power supply control unit 111 is T2. Then, the CPU 121 obtains the discharge curve d shown in FIG. 4A by using the voltage V1 and time T1 at the start-up process and the voltage V2 and time T2 at the end process stored in the RAM 122. The discharge curve d is a discharge curve (not shown) that is a base for supplying power to the RTC 113 of the secondary battery 112, and includes the voltage V1 at the start process and the time T1, and the voltage V2 at the end process and the time T2. It can be obtained by using and correcting. That is, the discharge curve d has a discharge characteristic that accompanies power consumption that is different from that of natural discharge by using a discharge curve that is a base associated with power supply to the RTC 113 of the secondary battery 112. Further, since the discharge curve d uses the voltage V1 and time T1 at the start-up process and the voltage V2 and time T2 at the end process, the secular change of the secondary battery 112 and the change of the discharge characteristics due to the use environment. It will be tailored to. Further, the time T3 when the voltage V2 of the secondary battery 112 indicated by the discharge curve d becomes 0 V corresponds to the secular change of the secondary battery 112 and the change of the discharge characteristics depending on the use environment.

  Further, the CPU 121 obtains a predicted time when the voltage V2 of the secondary battery 112 reaches, for example, the minimum operable voltage V3 of the RTC 113 from the obtained discharge curve d. The obtained predicted time is set as a predicted start time Ts for charging the secondary battery 112. Then, the CPU 121 sets the calculated estimated charging start time Ts to the RTC 113 via the signal line s2, and ends the process. Note that the predicted time may be obtained based on a voltage higher than the lowest operable voltage V3 of the RTC 113.

  Here, as described above, the discharge curve d obtained by the CPU 121 is adapted to the secular change of the secondary battery 112 and the change of the discharge characteristics depending on the use environment. In other words, the secondary battery 112 has a long service life and tends to have a faster capacity reduction rate in a high temperature and high humidity environment. For this reason, even if, for example, the time T3 when the voltage of the secondary battery 112 becomes 0V changes depending on the years of use and the use environment, the estimated start time Ts of charging that matches the change in the discharge characteristics of the secondary battery 112 is set. It can be determined accurately.

  Next, referring to FIG. 4B, when the power control unit 111 shifts from the power OFF mode to the charge mode and further shifts from the charge mode to the power OFF mode, the CPU 121 obtains the estimated start time Ts for charging start. The case will be described.

  First, when the power supply control unit 111 receives an alarm signal indicating that the estimated charging start time Ts has been reached from the RTC 113 via the signal line s3 in the power supply OFF mode shown in FIG. The mode shifts from the mode to the charging mode shown in FIG. At this time, the power supply control unit 111 supplies power to the system control unit 121A and the RTC 113 via the lead wires r1 and r2, as shown in FIG. Further, the power control unit 111 stops the power supply from the secondary battery 112 to the RTC 113. Further, the power supply control unit 111 notifies the CPU 121 of the mode shift via the signal line s1. At this time, the CPU 121 starts activation processing. In addition, the power control unit 111 detects the voltage of the secondary battery 112 and notifies the CPU 121 via the signal line s1. The voltage of the secondary battery 112 at this time is assumed to be the lowest operable voltage V3. The CPU 121 obtains the current time from the RTC 113 via the signal line s2 and reflects it in the system time during the start-up process.

  Further, when the charging of the secondary battery 112 is completed, the power control unit 111 detects the voltage of the secondary battery 112 and notifies the CPU 121 via the signal line s1. The voltage of the secondary battery 112 at this time is assumed to be a constant voltage (for example, a fully charged voltage) voltage V4. The time when the CPU 121 receives the voltage V4 of the secondary battery 112 from the power supply control unit 111 is set to T4. Further, when the power control unit 111 shifts from the charging mode to the power OFF mode, the power control unit 111 notifies the CPU 121 of the mode shift via the signal line s1. In addition, the power control unit 111 shifts to the power OFF mode illustrated in FIG. At this time, the power supply control unit 111 stops the power supply to the secondary battery 112, the RTC 113, and the system control unit 121A, and switches to the power supply from the secondary battery 112 to the RTC 113. In addition, the CPU 121 executes a termination process. Further, the CPU 121 obtains a discharge curve d1 shown in FIG. 4B by using the voltage V3 and time Ts during the start-up process and the time T4 when the fully charged voltage V4 and voltage V4 are received. Note that the discharge curve d1 is a discharge curve (not shown), which is a base for supplying power to the RTC 113 of the secondary battery 112, as in the above, with the voltage V3 and time Ts at the start-up process, and the fully charged voltage V4 and voltage. It can be obtained by correcting using time T4 when V4 is received. In other words, the discharge curve d1 has a discharge characteristic that accompanies power consumption different from that of natural discharge by using a discharge curve that is a base associated with power supply to the RTC 113 of the secondary battery 112. In addition, since the discharge curve d1 uses the voltage V3 and time Ts during the start-up process and the time T4 when the fully charged voltage V4 and voltage V4 are received, it depends on the secular change of the secondary battery 112 and the usage environment. It will be adapted to the change in discharge characteristics. Further, the time T5 when the voltage V4 of the secondary battery 112 indicated by the discharge curve d1 becomes 0 V is in accordance with the secular change of the secondary battery 112 and the change of the discharge characteristics depending on the use environment.

  Further, the CPU 121 obtains a predicted time when the voltage V4 of the secondary battery 112 reaches, for example, the minimum operable voltage V3 of the RTC 113 from the obtained discharge curve d1. The calculated predicted time is set as a predicted start time Ts1 for charging the secondary battery 112. Then, the CPU 121 sets the calculated estimated charging start time Ts1 to the RTC 113 via the signal line s2, and ends the process. Note that the predicted time may be obtained based on a voltage higher than the lowest operable voltage V3 of the RTC 113.

  Here, similarly to the above, the discharge curve d1 obtained by the CPU 121 is adapted to the secular change of the secondary battery 112 and the change of the discharge characteristics depending on the use environment. In other words, the secondary battery 112 has a long service life and tends to have a faster capacity reduction rate in a high temperature and high humidity environment. For this reason, even if the time T5 when the voltage of the secondary battery 112 becomes 0V changes according to the years of use and the usage environment, the estimated charging start time Ts1 that matches the change in the discharge characteristics of the secondary battery 112 is accurately determined. Can be requested.

  Next, charging control for the secondary battery 112 will be described with reference to FIGS. First, referring to FIG. 5, a description will be given of a transition process from the power ON mode shown in FIG. 2A to the power OFF mode shown in FIG.

(Step S101)
The power supply control unit 111 determines whether power-off is instructed.
In this case, the power control unit 111 determines that the power OFF is not instructed unless the power switch 110 is operated (step S101: No).
On the other hand, when the power switch 110 is operated, the power control unit 111 determines that the power OFF is instructed (step S101: Yes), and proceeds to step S102.

(Step S102)
The power control unit 111 detects the voltage of the secondary battery 112.

(Step S103)
The power supply control unit 111 notifies the CPU 121 of the detected voltage of the secondary battery 112 and the mode shift.
Note that the voltage of the secondary battery 112 detected by the power control unit 111 when the power OFF is instructed is set to V2 as shown in FIG. Further, it is assumed that the power supply control unit 111 detects the voltage of the secondary battery 112 and notifies the CPU 121 when the power supply OFF mode shifts to the current power supply ON mode. The voltage in this case is V1 as shown in FIG.

(Step S104)
The CPU 121 starts an end process.

(Step S105)
CPU121 calculates | requires prediction time Ts when the secondary battery 112 becomes below a threshold value.
In this case, as described in FIG. 4A, the CPU 121 stores the voltage of the secondary battery 112 received from the power control unit 111 during the startup process as V1, and stores the time when the voltage V1 is received as T1 in the RAM 122. ing. When executing the termination process, the CPU 121 supplies the RTC 113 of the secondary battery 112 to the RTC 113 based on the voltage V1 and time T1 during the startup process and the voltage V2 and time T2 during the termination process stored in the RAM 122. A discharge curve d shown in FIG. 4A is obtained by correcting a discharge curve (not shown) which is a base associated with power supply. Further, the CPU 121 obtains a predicted time when the voltage V2 of the secondary battery 112 reaches, for example, the minimum operable voltage V3 of the RTC 113 from the obtained discharge curve d. The obtained predicted time is set as a predicted start time Ts for charging the secondary battery 112.

(Step S106)
The CPU 121 transmits the estimated charging start time Ts obtained from the discharge curve d to the RTC 113 via the signal line s2, and sets the alarm function of the RTC 113.

(Step S107)
The CPU 121 notifies the power supply control unit 111 of the completion of setting and ends the processing.

(Step S108)
When the power supply control unit 111 receives a notification of setting completion from the CPU 121, the power supply control unit 111 shifts to the power supply OFF mode.

  Next, with reference to FIG. 6, the transition process from the power OFF mode shown in FIG. 2B of the power control unit 111 to the charging mode shown in FIG. 3 will be described.

(Step S201)
The RTC 113 checks whether or not the estimated charging start time Ts has been reached.
If the predicted start time Ts for charging start has not been reached (step S201: No), the RTC 113 continues to check whether the predicted start time Ts for charging has been reached.
On the other hand, when the RTC 113 confirms that the estimated charging start time Ts has been reached (step S201: Yes), the process proceeds to step S202.

(Step S202)
The RTC 113 sends an alarm signal to the power control unit 111 via the signal line s3.

(Step S203)
As shown in FIG. 3, the power supply control unit 111 supplies power from the commercial power supply (AC100V power supply) 200 to the secondary battery 112, the RTC 113, and the system control unit 121A. In this case, the power supply control unit 111 does not supply power to the control unit 120.

(Step S204)
The power supply control unit 111 notifies the CPU 121 of the voltage of the secondary battery 112 and the transition to the charging mode via the signal line s1.
At this time, the CPU 121 starts activation processing.

(Step S205)
As shown in FIG. 3, the power supply control unit 111 stops the power supply from the secondary battery 112 to the RTC 113.

  Next, a transition process from the charging mode shown in FIG. 3 to the power OFF mode shown in FIG. 2B by the power supply control unit 111 will be described with reference to FIG.

(Step S301)
The power supply control unit 111 determines whether charging of the secondary battery 112 is completed.
In this case, the power supply control unit 111 detects the voltage of the secondary battery 112, and when the voltage of the secondary battery 112 is not a constant voltage (for example, a fully charged voltage), the charging of the secondary battery 112 is completed. It is determined that it is not present (step S301: No).
On the other hand, the power supply control unit 111 detects the voltage of the secondary battery 112, and when the voltage of the secondary battery 112 is a constant voltage (for example, a fully charged voltage), the charging of the secondary battery 112 is completed. (Step S301: Yes), the process proceeds to Step S302.
At this time, the power supply control unit 111 holds a value of a constant voltage (for example, a fully charged voltage) of the secondary battery 112.

(Step S302)
The power supply control unit 111 stops the power supply from the commercial power supply (AC100V power supply) 200 to the secondary battery 112 as shown in FIG.

(Step S303)
The power supply control unit 111 restarts the power supply from the commercial power supply (AC100V power supply) 200 from the secondary battery 112 to the RTC 113 as shown in FIG.

(Step S304)
The power supply control unit 111 stops the power supply from the commercial power supply (AC100V power supply) 200 to the RTC 113 as shown in FIG.

(Step S305)
The power supply control unit 111 notifies the CPU 121 of the voltage of the secondary battery 112 when charging is completed and the mode transition.

(Step S306)
CPU121 calculates | requires the prediction time of the charge start when the secondary battery 112 becomes below a threshold value.
In this case, as described with reference to FIG. 4B, the CPU 121 receives the voltage V3 and the time Ts during the start-up process, and the time T4 when the voltage V4 and the voltage V4 that are constant voltages (for example, a fully charged voltage) are received. Originally, the discharge curve d1 shown in FIG. 4B is obtained by correcting a discharge curve (not shown) which becomes a base associated with power supply to the RTC 113 of the secondary battery 112. Further, the CPU 121 obtains a predicted time when the voltage V4 of the secondary battery 112 reaches, for example, the minimum operable voltage V3 of the RTC 113 from the obtained discharge curve d1. The calculated predicted time is set as a predicted start time Ts1 for charging the secondary battery 112.

(Step S307)
The CPU 121 transmits the estimated charging start time Ts1 obtained from the discharge curve d1 to the RTC 113 via the signal line s2, and sets the alarm function of the RTC 113.

(Step S308)
The CPU 121 notifies the power supply control unit 111 of the completion of setting and ends the processing.

(Step S309)
Upon receiving the notification of setting completion from the CPU 121, the power supply control unit 111 stops the power supply from the commercial power supply (AC100V power supply) 200 to the system control unit 121A and shifts to the power supply OFF mode.

  Next, the transition process from the power OFF mode shown in FIG. 2B to the power ON mode shown in FIG. 2A by the power control unit 111 will be described with reference to FIG.

(Step S401)
The power control unit 111 determines whether the power ONF is instructed.
In this case, the power control unit 111 determines that the power ON is not instructed unless the power switch 110 is operated (step S401: No).
On the other hand, when the power switch 110 is operated, the power supply control unit 111 determines that the power supply is instructed (step S401: Yes), and proceeds to step S402.

(Step S402)
The power supply control unit 111 supplies power from the commercial power supply (AC100V power supply) 200 to the RTC 113 and the control unit 120 as shown in FIG.

(Step S403)
The power supply control unit 111 stops the power supply from the secondary battery 112 to the RTC 113 as shown in FIG.

(Step S404)
The power control unit 111 detects the voltage of the secondary battery 112.

(Step S405)
The power supply control unit 111 notifies the CPU 121 of the detected voltage of the secondary battery 112 and the mode shift.
Note that when the power ON is instructed, the voltage of the secondary battery 112 detected by the power control unit 111 is V1 as shown in FIG.

(Step S406)
The CPU 121 acquires the current time from the RTC 113.

(Step S407)
The CPU 121 reflects the current time acquired from the RTC 113 in the system time.

  As described above, in this embodiment, the power supply control unit 111 controls power supply, the RTC 113 measures the current time, the secondary battery 112 supplies power to the RTC, and the CPU 121 relates to the power supply from the power supply control unit 111. Based on the mode change notification, start processing or end processing is started, the current time from the RTC is acquired during the start processing, and is reflected in the system time. In addition, when the power supply control unit 111 detects the voltage of the secondary battery 112 at the time of mode transition and notifies the CPU 121 of the voltage, the CPU 121 detects the voltage V1 or V3 (first voltage of the secondary battery 112 acquired at the time of the startup process). Voltage), the acquired time T1 or Ts (first time), the voltage V2 or V4 (second voltage) of the secondary battery 112 acquired at the time of the termination process, and the acquired time T2 or T4 ( 2), the discharge curve that is the base accompanying the power supply of the secondary battery 112 to the RTC 113 is corrected, and the predicted time when the voltage of the secondary battery 112 reaches the threshold value from the corrected discharge curve d or d1 Ts or Ts1 is obtained, and the obtained predicted time Ts or Ts1 is set in the RTC 113. When the RTC 113 confirms that the predicted time Ts or Ts1 has been reached, the RTC 113 sends an alarm signal notifying the power supply control unit 111 of the start of charging.

  Thus, the CPU 121 obtains the predicted time Ts or Ts1 when the voltage of the secondary battery 112 reaches, for example, the lowest operable voltage V3 (threshold value) of the RTC 113 from the discharge curve d or d1 that matches the discharge characteristics of the secondary battery 112. Therefore, charging of the secondary battery 112 can be started before the remaining amount of the secondary battery 112 reaches a voltage value at which the RTC 113 becomes inoperable. In other words, even if the discharge characteristics of the secondary battery 112 change due to aging or usage environment, charging of the secondary battery 112 is started at an appropriate time. System time can be obtained.

  In the present embodiment, the MFP 100 is exemplified as the electronic device. However, the present invention may be applied to other electronic devices such as a multifunction printer and a PC (Personal Computer).

100 MFP
110 Power switch 111 Power supply control unit 112 Secondary battery 113 RTC
120 controller 121A system controller 121 CPU
122 RAM
123 ROM
124 Scanner control unit 125 Printer control unit 126 FAX control unit 127 Communication control unit 128 Image processing unit 129 Panel operation control unit 200 Commercial power supply (AC100V power supply)
b1, b2 buses r1-r3 lead wires s1-s3 signal lines

Claims (4)

A power control unit for controlling power supply;
RTC that keeps the current time,
With the supply of power to the RTC, a secondary battery charged by the power supply control unit when the voltage reaches a threshold value;
A CPU that starts a startup process or an end process based on a notification of mode transition related to the power supply from the power supply control unit, acquires a current time from the RTC during the startup process, and reflects it in a system time;
The power control unit detects the voltage of the secondary battery at the time of mode transition and notifies the CPU,
The CPU acquires the first voltage of the secondary battery acquired at the time of the startup process, the acquired first time, the second voltage of the secondary battery acquired at the time of the end process, and The obtained second time is used to correct a discharge curve that is a base associated with the power supply of the secondary battery to the RTC, and the predicted time when the voltage of the secondary battery reaches a threshold value from the corrected discharge curve And setting the predicted time obtained in the RTC,
When the RTC confirms that the predicted time has been reached, the RTC sends an alarm signal notifying the start of charging to the power supply control unit. The power control unit shifts to one of a power ON mode, a power OFF mode, and a charging mode,
The CPU
Accompanying the transition from the power OFF mode to the power ON mode, the first voltage and the first time are acquired,
Accompanying the transition from the power ON mode to the power OFF mode, the second voltage and the second time are acquired,
The electronic device according to claim 1, wherein the processing is terminated after the predicted time is set in the RTC. The CPU
Accompanying the transition from the power OFF mode to the charging mode, the first voltage and the first time are acquired,
Accompanying the transition from the charging mode to the power OFF mode, the second voltage and the second time are acquired,
The electronic device according to claim 2, wherein the processing is terminated after the predicted time is set in the RTC. A charging program that is executed by a computer that controls an electronic device,
A step of controlling power supply by the power supply control unit;
A process of measuring the current time by RTC;
Supplying power to the RTC by a secondary battery charged by the power supply controller when the voltage reaches a threshold;
A step of starting a startup process or an end process based on a notification of mode transition relating to power from the power control unit by the CPU, acquiring a current time from the RTC during the startup process, and reflecting the current time in a system time; Let it run
The power control unit detects the voltage of the secondary battery at the time of mode transition and notifies the CPU,
The CPU acquires the first voltage of the secondary battery acquired at the time of the startup process, the acquired first time, the second voltage of the secondary battery acquired at the time of the end process, and The obtained second time is used to correct a discharge curve that is a base associated with the power supply of the secondary battery to the RTC, and the predicted time when the voltage of the secondary battery reaches a threshold value from the corrected discharge curve And setting the predicted time obtained in the RTC,
When the RTC confirms that the predicted time has been reached, the RTC sends an alarm signal notifying the start of charging to the power supply control unit.

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