JP2014116905A - Image processing system, apparatus control method, and apparatus control program - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an image processing system, apparatus control method, and apparatus control program, capable of preventing failure due to apparatus movement during power supply from another power supply than a commercial power supply.SOLUTION: The image processing system includes: detection means for detecting a state change of power supply from a commercial power supply; state control means for controlling shifting from a current operation mode to an operation mode corresponding to a power supply state on the basis of a detection result of the state change; and job control means for controlling job processing corresponding to the power supply state on the basis of the detection result of the state change.

Description

  The present invention relates to a technique for controlling a device.

  In recent years, there has been proposed an image processing apparatus that realizes energy saving by receiving power supply from a power source other than a commercial power source such as a storage battery (power storage device). Such an image processing apparatus has an operation mode in which power is supplied from the storage battery and no job request is accepted during that time. This operation mode is a mode in which it is assumed that the user removes the plug from the commercial power source and moves the image processing apparatus. For example, Patent Document 1 discloses a technique for shifting to the operation mode by a user operation (pressing an outlet-off mode button).

  However, in the conventional device control, the user must instruct the transition of the operation mode. Therefore, when the user forgets the operation, the image processing apparatus is moved in a state where the operation mode is not shifted. As a result, in the image processing apparatus, a problem such as failure of the device occurs due to an impact when the device moves.

  As described above, in the conventional device control, the image processing apparatus is not controlled to automatically shift to the optimum operation mode when the device is moved.

  The present invention has been made in view of the above, and it is an object of the present invention to provide an image processing apparatus, a device control method, and a device control program capable of preventing a failure due to device movement when power is supplied from other than a commercial power source. .

  In order to solve the above-described problems and achieve the object, an image processing apparatus according to the present invention is based on a detection unit that detects a change in the state of power supply from a commercial power supply and a detection result of the change in state. A state control unit that controls the transition from the operation mode to the operation mode corresponding to the power supply state; and a job control unit that controls job processing corresponding to the power supply state based on the detection result of the state change. .

  According to the present invention, it is possible to prevent a failure due to equipment movement when power is supplied from other than a commercial power source.

FIG. 1 is a diagram illustrating a hardware configuration example of the image processing apparatus according to the first embodiment. FIG. 2 is a diagram illustrating a hardware configuration example of the controller according to the first embodiment. FIG. 3 is a diagram illustrating a configuration example of the device control function according to the first embodiment. FIG. 4 is a flowchart illustrating an example of a processing procedure during device control according to the first embodiment. FIG. 5 is a flowchart illustrating an example of a processing procedure during job control according to the first embodiment.

  Exemplary embodiments of an image processing apparatus, an apparatus control method, and an apparatus control program (hereinafter referred to as “embodiments”) will be described in detail below with reference to the accompanying drawings.

[First Embodiment]
<Hardware configuration>
<Image processing device>
FIG. 1 is a diagram illustrating a hardware configuration example of an image processing apparatus 100 according to the present embodiment. As illustrated in FIG. 1, the image processing apparatus 100 includes a controller 101, an HDD (Hard Disk Drive) 102, a FAX 103 (fax), a switch 104, an operation unit 105, an external I / F (Interface) 106, and a communication I / F. (Communication interface) 107 and the like.

  The controller 101 is a base (board) that controls the entire image processing apparatus 100. The hardware configuration of the controller 101 will be described later with reference to FIG. An HDD (Hard Disk Drive) 102 is a non-volatile storage device that holds programs and data. The HDD 102 manages programs and data by a predetermined file system and / or DB (Data Base). The FAX 103 is a device that processes facsimile data. The switch 104 is a component that turns the power of the image processing apparatus 100 on and off.

  The operation unit 105 includes a UI (User Interface) component and a display device, and is a device that accepts a processing request from a user and notifies the user of various information (for example, “apparatus status” and “processing status”). The external I / F 106 is an interface with an external device. Examples of the external device include a recording medium 106a. Thereby, the image processing apparatus 100 can read and / or write to the recording medium 106a. The recording medium 106a includes a memory card. The communication I / F 107 is an interface that connects the image processing apparatus 100 to a predetermined data transmission path (for example, “network”). As a result, the image processing apparatus 100 can perform data communication with other devices. The controller 101 is connected to the above devices and components.

  The image processing apparatus 100 includes a plug 111 and a PSU (Power Supply Unit) 112. The plug 111 is a component that receives power supply from the commercial power source P. The PSU 112 is connected to the controller 101, the charge / discharge unit 121, the image writing unit 131, the image reading unit 132, and the like, and is a control device that controls power supply to these devices. For example, when power is supplied to the controller 101, the PSU 112 steps down the supplied power voltage to the drive voltage. In addition, the PSU 112 switches power supply to the image writing unit 131 or the image reading unit 132.

  The image processing apparatus 100 includes a charge / discharge unit 121, a storage battery 122, a solar unit 123, and the like. The charging / discharging unit 121 is a control device that controls charging / discharging of the storage battery 122. The storage battery 122 is a power storage device that stores commercial power and / or supplied power from other than commercial power. The storage battery 122 includes a terminal that receives supply power, and is detachable from the image processing apparatus 100. The solar unit 123 is a power supply device other than commercial power that generates power by receiving light with a light receiving element and supplies power. The solar unit 123 is an example of a power supply device other than commercial power, and is not limited to this. A solar unit 123 is connected to the storage battery 122, and a storage battery 122 is connected to the charge / discharge unit 121.

  The image processing apparatus 100 also includes an image writing unit 131 and an image reading unit 132. The image writing unit 131 is a printer device that prints an image on a medium such as paper. Note that the image writing unit 131 includes components for performing exposure, latent image, development, transfer, and the like corresponding to each processing step when printing is performed according to the electrophotographic process. The image reading unit 132 is a scanner device that scans a medium such as paper and acquires a scanned image.

"controller"
FIG. 2 is a diagram illustrating a hardware configuration example of the controller 101 according to the present embodiment. As shown in FIG. 2, the controller 101 includes a CPU (Central Processing Unit) 11 and a memory 12. The controller 101 includes an ASIC (Application Specific Integrated Circuit) 13, a power supply control microcomputer 14, and an I / F 15.

  The CPU 11 is an arithmetic device that implements control and mounting functions (image processing functions) of the entire image processing apparatus 100 by reading out programs and data onto the memory 12 and executing the processing. The memory 12 is a volatile semiconductor memory that temporarily stores programs and data. The CPU 11 is connected to a memory 12 and an ASIC 13.

  The ASIC 13 is an integrated circuit in which circuits having a plurality of functions are collected for a specific application. The specific application mentioned here includes image processing. The ASIC 13 is connected to the HDD 102, and controls the HDD 102 including reading / writing of image data.

  The power supply control microcomputer 14 is an integrated circuit that controls the power supply. In the present embodiment, the configuration example in which the controller 101 includes the power supply control microcomputer 14 has been described. For example, the structure with which the charging / discharging unit 121 is provided may be sufficient. The I / F 15 is an interface for connecting the ASIC 13, the image writing unit 131, and the PSU 112. The interface here includes a connector, a cable, and the like.

  As described above, the image processing apparatus 100 according to the present embodiment can provide each function of image processing and device control with the above hardware configuration.

<Device control function>
A device control function according to the present embodiment will be described.

  The image processing apparatus 100 according to the present embodiment detects that power supply from the commercial power source P has been cut off. The image processing apparatus 100 determines the current operation mode of the device based on the detection result. Further, the image processing apparatus 100 determines whether or not the operation mode shift control is necessary when power other than the commercial power supply P is supplied. As a result, when control is necessary, the image processing apparatus 100 shifts from the determined operation mode to an operation mode suitable for power supply other than the commercial power supply P. In addition, the image processing apparatus 100 performs a predetermined operation restriction on job processing in the shifted operation mode. The image processing apparatus 100 according to the present embodiment has such a device control function.

  In the conventional device control, the user must instruct the image processing apparatus 100 to shift to an operation mode suitable for moving the apparatus, and the image processing apparatus is automatically shifted to the optimal operation mode when moving the apparatus. 100 control was not performed.

  For this reason, if the user forgets to perform an operation, the image processing apparatus 100 is moved without shifting to an appropriate operation mode, and the device may be damaged due to an impact when the device is moved. Further, while the device was moving, the power of the storage battery 122 was consumed more than necessary (discharged), and the device could not be driven for a long time.

  Specifically, it is as follows. For example, if the image processing apparatus 100 moves while the HDD 102 is reading or writing, the HDD 102 may fail or the data may be damaged. The HDD 102 includes a disk for recording data and a head for reading and writing data, and the head moves on the rotating disk when reading or writing data. For this reason, when the head is present on the disk, if it receives external vibration or impact, the head contacts the disk and damages the disk. Since the HDD 102 in recent years has a high data storage area, a large amount of data cannot be read or written even with a slight scratch.

  In addition, when the image processing apparatus 100 receives a request for a job with high power consumption using the image writing unit 131, the image reading unit 132, or the like while the device is moving, it is considered that the power of the storage battery 122 is significantly consumed. . For example, the current consumption value (reference value) of the controller alone is 1.6 [A] in the job operation, and 0.1 [A] in the energy saving mode. Thus, during job operation, about 10 times as much power as that in the energy saving mode is consumed. Therefore, when a job request using the image writing unit 131, the image reading unit 132, or the like is received, more power is consumed than when the controller operates alone.

  Therefore, in the device control function according to the present embodiment, in response to the switch from the commercial power supply P to the power supply other than the commercial power supply P, the apparatus control function automatically shifts to an operation mode suitable for power supply other than the commercial power supply P to perform job processing. The mechanism that restricts the operation of

  As a result, the device control function according to the present embodiment does not require a user operation for shifting to the optimum operation mode, and provides an environment that restricts job processing that causes device failure or job processing that consumes a lot of power. To do. As a result, the device control function according to the present embodiment can prevent a failure due to device movement when power is supplied from other than the commercial power source P. Further, the device control function according to the present embodiment can be driven for a long time when power is supplied from other than the commercial power source P.

  The configuration and operation of the device control function according to this embodiment will be described below.

  FIG. 3 is a diagram illustrating a configuration example of the device control function according to the present embodiment. As shown in FIG. 3, the device control function according to the present embodiment includes a detection unit 21, a state control unit 22, a job control unit 23, and the like.

  The detection unit 21 is a functional unit that detects a change in the state of power supply from the commercial power source P. The detector 21 detects a change in the state of power supply by the following method.

  For example, a signal line is provided between the PSU 112 and the controller 101 such that the signal is H when a current from the commercial power source P is input and the signal is L when no current is input. An output signal from the PSU 112 is input to the power control microcomputer 14 via the I / F 15. The detection unit 21 functions by the following processing performed by the power supply control microcomputer 14 of the controller 101.

  The detection unit 21 determines whether or not electric power is supplied from the commercial power source P based on the input signal, and detects a state change. When the input signal is L, the detection unit 21 determines that power is not supplied from the commercial power source P, and detects that the power supply from the commercial power source P is cut off. The state in which the power supply from the commercial power supply P is cut off includes not only the case where the plug 111 is removed from the commercial power supply P but also the power interruption or power failure due to the malfunction of the commercial power supply P or the plug 111.

  The signal line may be provided between the PSU 112 and the charge / discharge unit 121. The detection unit 21 functions when the above processing is performed by a power supply control microcomputer (not shown) of the charge / discharge unit 121.

  The state control unit 22 is a functional unit that controls the device state of the image processing apparatus 100 to shift to a device state suitable for power supply other than the commercial power supply P. When the power supply from the commercial power supply P is cut off, the state control unit 22 shifts the operation mode of the device to an operation mode suitable for power supply other than the commercial power supply P (an operation mode corresponding to the power supply state). . The state control unit 22 is a function realized by the ASIC 13 of the controller 101 or the power supply control microcomputer 14.

  Here, main operation modes of the image processing apparatus 100 will be described. The image processing apparatus 100 has a standby mode, an energy saving mode, and a shutdown mode. The standby mode is an operation mode in which a requested job can be executed. In the energy saving mode, for example, an unused (unused) electronic component (for example, “display device of the operation unit 105”) is turned off (powered off) while waiting for a job request, and the standby mode is set when a job request is received. This is a transferable operation mode. The shutdown mode is an operation mode in which almost all electronic components are powered off and no job request is accepted.

  Therefore, in the image processing apparatus 100 according to the present embodiment, the energy saving mode is divided into an operation mode during commercial power supply (hereinafter referred to as “normal energy saving mode”) and an operation mode during battery driving (hereinafter referred to as “battery driven energy saving mode”). ") And control the device status. That is, when the power supply from the commercial power source P is cut off, the state control unit 22 changes the operation mode of the device from the standby mode or the normal energy saving mode to the battery-powered energy saving mode (suitable for power supply other than the commercial power source P). Shift to the operation mode). For this reason, the state control unit 22 includes a mode determination unit 221.

  When the power supply from the commercial power source P is cut off, the mode determination unit 221 determines the current operation mode. The mode determination unit 221 determines which operation mode is the current operation mode among the standby mode, the normal energy saving mode, the battery-powered energy saving mode, or the shutdown mode.

  Based on the determination result of the operation mode, the state control unit 22 shifts the operation mode when the power supply from the commercial power source P is cut to an operation mode suitable for power supply other than the commercial power source P. When the power supply from the commercial power source P is cut off, the state control unit 22 shifts from each operation mode to the battery-driven energy saving mode when the operation mode of the device is the standby mode or the normal energy saving mode. The state control unit 22 shifts the operation mode by changing the control value of the current operation mode to the control value of the battery-powered energy saving mode.

  For example, when the operation mode of the image processing apparatus 100 is already in the battery-powered energy saving mode or the shutdown mode when the power supply from the commercial power source P is cut off, it is not necessary to shift the operation mode. Therefore, the state control unit 22 includes a control necessity determination unit 222.

  When the power supply from the commercial power supply P is cut off, the control necessity determination unit 222 determines whether or not it is necessary to shift from the current operation mode to an operation mode suitable for power supply other than the commercial power supply P. To do. Based on the determination result of the operation mode, the control necessity determination unit 222 determines that it is not necessary to shift the operation mode when the current operation mode is the battery-powered energy saving mode or the shutdown mode.

  The job control unit 23 is a functional unit that controls to perform job processing suitable for power supply other than the commercial power supply P. When the operation mode of the device shifts to the battery-powered energy-saving mode, the job control unit 23 restricts (prohibits use) job processing that causes device failure and / or job processing that consumes a large amount of power after the operation mode shifts. . The job control unit 23 is a function realized by the CPU 11, the ASIC 13, or the power supply control microcomputer 14 of the controller 101.

  Here, main job processing corresponding to the above-described restriction target will be described.

  In the present embodiment, the processing of the HDD 102, the processing of the image writing unit 131 and the image reading unit 132, the processing of the FAX 103, the processing of the communication I / F 107, and the like are set as job processing corresponding to the restriction target. The processing of the HDD 102 and the processing of the image writing unit 131 and the image reading unit 132 correspond to job processing that causes a device failure. The processing of the image writing unit 131 and the image reading unit 132, the processing of the FAX 103, and the processing of the communication I / F 107 correspond to job processing that consumes a lot of power.

  The job control unit 23 performs restriction processing on the job processing determined in advance based on the cause of equipment failure or the high power consumption.

  The job process restriction control method will be described below.

<< Restriction Control of HDD102 >>
The restriction control of the HDD 102 includes control for prohibiting reading and / or writing of data, control for turning off the power of the HDD 102, and the like.

  In response to the shift to the battery-driven operation mode, the job control unit 23 prohibits data reading and / or writing processing to the HDD 102. In addition, the job control unit 23 turns off the power of the HDD 102. In addition, the job control unit 23 retracts the head from the disk of the HDD 102.

  The controller 101 receives a control signal notifying that the supply of power from the commercial power source P is cut off and the operation mode is switched to the battery drive mode. The CPU 11, the ASIC 13, or the power supply control microcomputer 14 receives the input of the control signal and changes the specified register value when the GIO terminal changes. The job control unit 23 performs restriction control of the HDD 102 by detecting a change in the register value.

  As a result, when the power supply from the commercial power source P is cut off, the image processing apparatus 100 does not accept a job request for reading and / or writing to the HDD 102. As a result, the image processing apparatus 100 can prevent a failure of the HDD 102 or data corruption. Further, the image processing apparatus 100 can reduce the power consumption due to the operation of the HDD 102 while the power supply from the commercial power source P is cut off.

  Note that the image processing apparatus 100 may include an SSD (Solid State Drive: not shown) that is resistant to vibration and impact and operates with low power consumption. In this case, it is not necessary to perform the above control. Therefore, the job control unit 23 needs to determine whether the storage device of the image processing apparatus 100 is the HDD 102 or the SSD. For discriminating between the HDD 102 and the SSD, there is a method using a command of the storage interface standard “ATA8-ACS”. In the method using the command, the determination is made based on the value indicating the rotational speed of the disk. For example, in the case of the HDD 102 of 7200 [prm], the value indicating the rotational speed of the disk is “1C20h”, whereas in the case of the SSD, the value indicating the rotational speed of the disk is “0001h”. . As described above, the job control unit 23 determines whether the installed storage device is the HDD 102 or the SSD from the difference in the rotational speed value of the disk. As a result, based on the determination result, the job control unit 23 performs the above control when the storage device included in the image processing apparatus 100 is the HDD 102.

<< Restriction Control of Image Writing Unit 131 and Image Reading Unit 132 >>
The restriction control of the image writing unit 131 and the image reading unit 132 includes a control for turning off the power of a mechanical drive unit such as the image writing unit 131 or the image reading unit 132.

  In response to the shift to the battery-driven operation mode, the job control unit 23 turns off the power of the image writing unit 131 and / or the image reading unit 132. Note that, when the power of the mechanical drive unit such as the image writing unit 131 or the image reading unit 132 is turned off, a predetermined time is required until the power-off is completed. Therefore, the job control unit 23 does not accept a job request using the image writing unit 131 and / or the image reading unit 132 until the power-off is completed. Note that the job control unit 23 controls the image writing unit 131 and / or the image reading unit 132 by detecting a change in the register value, similarly to the control of the HDD 102.

  As a result, when the power supply from the commercial power source P is cut off, the image processing apparatus 100 does not accept a job request that uses the image writing unit 131 and / or the image reading unit 132. As a result, in the image processing apparatus 100, it is possible to prevent a failure of the device due to a machine operation when the device is moved. Further, the image processing apparatus 100 can reduce power consumption due to mechanical operation while power supply from the commercial power supply P is cut off.

<< Limit control of FAX103 >>
The FAX 103 restriction control includes a control to turn off the power of the FAX 103 or a control to put the FAX 103 in a sleep state.

  In response to the shift to the battery-driven operation mode, the job control unit 23 turns off the power of the FAX 103. Further, the job control unit 23 continues to supply power only to a predetermined electronic component of the FAX 103 and stops the power supply to other electronic components, thereby setting the sleep state. Note that the job control unit 23 performs limit control of the FAX 103 by detecting a change in the register value, similarly to the control of the HDD 102, the image writing unit 131, and the image reading unit 132.

  As a result, when the power supply from the commercial power source P is cut off, the image processing apparatus 100 does not accept a job request using the FAX 103. As a result, in the image processing apparatus 100, it is possible to prevent a failure of the device due to a machine operation when the device is moved. Further, the image processing apparatus 100 can reduce power consumption due to mechanical operation while power supply from the commercial power supply P is cut off.

<< Limiting control of communication I / F 107 >>
The restriction control of the communication I / F 107 includes a control for lowering the communication speed than usual.

  In response to the shift to the battery-driven operation mode, the job control unit 23 changes the communication speed value set in the communication I / F 107 to a value smaller than the normal setting value, and makes the communication speed slower than normal. For example, when the normal communication speed setting value is “100” [Gbps], the setting value is changed to “100” [Mbps]. Note that the job control unit 23 performs restriction control of the communication I / F 107 by detecting a change in the register value, similarly to the control of the HDD 102, the image writing unit 131, the image reading unit 132, and the FAX 103.

  Thereby, in the image processing apparatus 100, when the power supply from the commercial power source P is cut off, the data communication speed performed between the image processing apparatus 100 and another device is decreased. As a result, the image processing apparatus 100 can reduce power consumption due to communication processing while power supply from the commercial power supply P is cut off.

  Note that the job control unit 23 may control each of the job processes according to a predetermined priority order. The priority order may be determined, for example, from the viewpoint of giving priority to job processing that causes equipment failure over job processing that consumes a large amount of power. In this case, the job control unit 23 controls the processing of the HDD 102 that causes the most concerned device failure with priority over other job processing.

  As described above, the device control function according to the present embodiment is realized by executing the device control program in the image processing apparatus 100 and performing the above-described functional units in cooperation with each other.

  The device control program is provided by being incorporated in advance in a memory 12 such as a ROM provided in the image processing apparatus 100 as an execution environment. The device control program has a module configuration including the above-described functional units, and the functional units are generated on the RAM when the CPU 11 of the controller 101 reads and executes the program from the ROM. Note that the method for providing the device control program is not limited to this. For example, a device control program may be stored in a device connected to the Internet and downloaded via a network. Alternatively, a method of recording and providing a file in an installable or executable format on the recording medium 106a readable by the image processing apparatus 100 may be used.

  Hereinafter, processing (cooperation operation of each functional unit) at the time of executing the device control program will be described using a flowchart.

<Processing during device control>
FIG. 4 is a flowchart illustrating an example of a processing procedure during device control according to the present embodiment. Note that the process shown in FIG. 4 is repeatedly executed (routine process) at predetermined time intervals.

  As shown in FIG. 4, the detection unit 21 determines whether or not power is supplied from the commercial power source P, and detects a change in the state of power supply from the commercial power source P (step S101).

  When the state control unit 22 detects that the power supply from the commercial power source P is cut off (step S101: NO), the mode determination unit 221 determines the current operation mode.

  Specifically, the mode determination unit 221 first determines whether or not the battery driving energy saving mode is set (step S102).

  When the current operation mode is not the battery-powered energy saving mode (step S102: NO), the mode determination unit 221 determines whether or not the shutdown mode is set (step S103).

  When the current operation mode is not the shutdown mode (step S103: NO), the mode determination unit 221 determines whether or not the standby mode is set (step S104).

  As a result, when the current operation mode is the standby mode (step S104: YES), the state control unit 22 shifts the operation mode of the device from the standby mode to the battery-powered energy saving mode (step S105).

  Next, the job control unit 23 performs control so as to perform job processing suitable for the battery-powered energy saving mode (step S106). The job control unit 23 limits job processing that causes a device failure and / or job processing that consumes a large amount of power after the operation mode of the device shifts to the battery-powered energy saving mode. A specific control process will be described later with reference to FIG.

  Further, when the current operation mode is not the standby mode (step S104: NO), the mode determination unit 221 determines whether or not the normal energy saving mode is set (step S107).

  As a result, when it is determined that the current operation mode is the normal energy saving mode (step S107: YES), the state control unit 22 shifts the device operation mode from the normal energy saving mode to the battery-driven energy saving mode. (Step S108).

  Next, the job control unit 23 performs control so as to perform job processing suitable for the battery-powered energy saving mode (step S109). The job control unit 23 limits job processing that causes a device failure and / or job processing that consumes a large amount of power after the operation mode of the device shifts to the battery-powered energy saving mode. A specific control process will be described later with reference to FIG.

  In addition, when the current operation mode is not the normal energy saving mode (step S107: NO), the mode determination unit 221 determines that the current operation mode is not the operation mode assumed for the device, and performs predetermined error processing. (Step S110). Error processing includes error screen display on the operation unit 105 and error notification to other devices.

  When the current operation mode is the battery-powered energy saving mode or the shutdown mode (steps S102 and S103: YES), the state control unit 22 causes the control necessity determination unit 222 to change the operation mode and restrict job processing. It is determined that there is no need to perform such as. Therefore, the image processing apparatus 100 does not perform operation mode transition by the state control unit 22 and job processing restriction by the job control unit 23.

  In addition, when power supply from the commercial power source P is detected (step S101: YES), the state control unit 22 determines whether or not the current operation mode is a battery-driven energy saving mode by the mode determination unit 221. (Step S111).

  As a result, when the current operation mode is the battery-powered energy saving mode (step S111: YES), the state control unit 22 shifts the device operation mode to the operation mode before the battery-driven energy saving mode transition (step S112). ). At this time, the state control unit 22 returns the control value of the operation mode to the control value before shifting to the battery-driven energy saving mode. For example, the state control unit 22 may record and hold the control value before shifting to the battery-powered energy saving mode in a predetermined storage area such as the memory 12 when the operation is shifted.

  When the current operation mode is not the battery-powered energy saving mode (step S111: NO), the state control unit 22 determines that the control mode necessity determination unit 222 does not need to perform the operation mode return or the like. Therefore, the image processing apparatus 100 does not perform the operation mode transition by the state control unit 22.

  Details of the control process (steps S106 and S109) will be described below.

《Job control processing》
FIG. 5 is a flowchart showing an example of a processing procedure during job control according to the present embodiment. FIG. 5 shows an example in which the processing of the HDD 102, the processing of the image writing unit 131 and the image reading unit 132, the processing of the FAX 103, and the processing of the communication I / F 107 are set as job processing to be controlled. ing.

  As shown in FIG. 5, when there is a job process corresponding to the control target (step S201: YES), the job control unit 23 controls each corresponding job process. Note that the job control unit 23 does not perform any particular processing when there is no job processing corresponding to the control target (step S201: NO).

Specifically, when the corresponding job process is the process of the HDD 102, the job control unit 23 performs a process of prohibiting reading and / or writing of data to the HDD 102, or a power-off process of the HDD 102 (step S202 ₁ ). . Processing in step S202 ₁ is executed when the image processing apparatus 100 is provided with a HDD 102. Note that the job control unit 23 may perform a head withdrawal process from the disk of the HDD 102 in addition to the restriction process.

Further, when the corresponding job processing is processing of the image writing unit 131 or the image reading unit 132, the job control unit 23 performs power-off processing of the image writing unit 131 or the image reading unit 132 (step S202 ₂ ). Specifically, when the image processing apparatus 100 includes the image writing unit 131, a power-off process is performed on the image writing unit 131. When the image processing apparatus 100 includes the image reading unit 132, the job control unit 23 performs a power-off process on the image reading unit 132. At this time, the job control unit 23 does not accept a job request using the image writing unit 131 and / or the image reading unit 132 until the power-off is completed because a predetermined time is required until the power-off is completed. (Job reception prohibition processing).

In addition, when the corresponding job processing is FAX 103 processing, the job control unit 23 performs power-off processing of the FAX 103 or sleep processing of the FAX 103 (Step S202 ₃ ). The process of step S202 ₃ is executed when the image processing apparatus 100 is provided with a FAX103.

In addition, when the corresponding job processing is the communication I / F 107, the job control unit 23 performs a communication speed setting change process of the communication I / F 107 (step S202 ₄ ). The process of step S202 _4, the image processing apparatus 100 is executed if a communication I / F107.

  Note that the job control unit 23 performs limit control of job processing for each control target by detecting a change in the register value due to the input of the control signal.

The processing of step S202 ₁ from S202 ₄ instead of performing a sequential processing for each control object, parallel processing possible, it is desirable to process in parallel a plurality of control target. As a result, the image processing apparatus 100 can quickly shift to a device state suitable for power supply other than the commercial power supply P.

  As described above, the device control function according to the present embodiment does not require a user operation for shifting to the optimum operation mode even when the power supply from the commercial power source P is cut off. In addition, the device control function according to the present embodiment can limit job processing that causes a failure due to device movement while the power supply from the commercial power supply P is cut off or job processing that consumes a lot of power. .

<Summary>
As described above, according to the image processing apparatus 100 according to the present embodiment, the detection unit 21 detects that power supply from the commercial power source P has been cut off. Based on the detection result, the state control unit 22 uses the mode determination unit 221 to determine the current operation mode of the device. Further, the state control unit 22 uses the control necessity determination unit 222 to determine whether it is necessary to control the operation mode transition when supplying power other than the commercial power source P. As a result, when control is necessary, the state control unit 22 shifts from the determined operation mode to an operation mode suitable for power supply other than the commercial power supply P. Further, the job control unit 23 performs a predetermined operation restriction on job processing in the shifted operation mode.

  As a result, the image processing apparatus 100 according to the present embodiment does not require a user operation for shifting to the optimum operation mode, and an environment that restricts job processing that causes a device failure or job processing that consumes a large amount of power. provide. As a result, the image processing apparatus 100 according to the present embodiment can prevent a failure due to equipment movement when power is supplied from other than the commercial power source P. Further, the image processing apparatus 100 according to the present embodiment can be driven for a long time when power is supplied from other than the commercial power source P.

  In the above-described embodiment, the job processing to be controlled has been described using the HDD 102, the image writing unit 131, the image reading unit 132, the FAX 103, the communication I / F 107, and the like as examples. However, the present invention is not limited to this. The job process to be controlled may be a job process that causes a device failure and / or a job process that consumes a large amount of power when the power supply from the commercial power source P is cut off.

  In the above embodiment, the example of the restriction process of the HDD 102 that performs either the data reading and / or writing prohibition process or the power-off process has been described, but the present invention is not limited to this. For example, in the restriction process of the HDD 102, a prohibition process and a power-off process may be combined. Specifically, the power-off process is performed after the data read and / or write prohibition process is performed.

  In the above-described embodiment, the example of the limiting process of the FAX 103 that performs either the power-off process or the sleep process has been described. For example, in the FAX 103 restriction process, a power-off process and a sleep process may be combined. Specifically, the power-off process is performed after the sleep process.

  Finally, the present invention is not limited to the requirements shown here, such as combinations of other elements with the shapes and configurations described in the above embodiments. With respect to these points, the present invention can be changed within a range that does not detract from the gist of the present invention, and can be appropriately determined according to the application form.

21 detection unit 22 state control unit (221: mode determination unit, 222: control necessity determination unit)
23 Job control unit 100 Image processing apparatus 101 Controller 102 HDD
103 FAX
107 Communication I / F
122 Storage Battery 131 Image Writing Unit 132 Image Reading Unit

JP 2011-194838 A

Claims (12)

Detection means for detecting a change in the state of power supply from a commercial power source;
State control means for controlling the transition from the current operation mode to the operation mode corresponding to the power supply state based on the detection result of the state change;
An image processing apparatus comprising: job control means for controlling job processing corresponding to a power supply state based on a detection result of the state change. Power storage means for storing power,
The state control means includes
When power supply is cut off from the commercial power source,
The image processing apparatus according to claim 1, wherein the current operation mode is shifted to an operation mode when power is supplied from the power storage unit. The state control means includes
Determine the operation mode when the power supply is cut off from the commercial power supply,
From the determined operation mode, determine whether to shift to the operation mode at the time of power supply from the power storage means,
The image processing apparatus according to claim 2, wherein transition to the operation mode is controlled based on a determination result. The state control means includes
When the operation mode when the power supply is cut off from the commercial power supply is a standby mode in which a request job can be executed or an energy saving mode in which the power of unused electronic components is in an off state,
The image processing apparatus according to claim 3, wherein the image processing apparatus shifts to an operation mode when power is supplied from the power storage unit. The job control means includes
When power supply is cut off from the commercial power source,
The image processing apparatus according to claim 2, wherein job processing when power is supplied from the power storage unit is limited. The job control means includes
The image processing apparatus according to claim 5, wherein at least one of the job processing that causes a device failure and the job processing that consumes a large amount of power is restricted. The job control means includes
The image processing apparatus according to claim 6, wherein at least one of a read / write prohibition process of data to the hard disk drive and a power-off process of the hard disk drive is performed. The job control means includes
The image processing apparatus according to claim 6, wherein a power-off process of a mechanical drive unit for image writing and image reading is performed. The job control means includes
The image processing apparatus according to claim 6, wherein at least one of a fax power-off process and a fax sleep process is performed. The job control means includes
The image processing apparatus according to claim 6, wherein a setting change process of a communication speed of the communication interface is performed. A detection procedure for detecting a change in the state of power supply from a commercial power source,
A state control procedure for controlling the transition from the current operation mode to the operation mode corresponding to the power supply state based on the detection result of the state change;
A device control method for controlling job processing corresponding to a power supply state based on a detection result of the state change. The image processing device
Detection means for detecting a change in the state of power supply from a commercial power source;
State control means for controlling the transition from the current operation mode to the operation mode corresponding to the power supply state based on the detection result of the state change;
A device control program that functions as job control means for controlling job processing corresponding to a power supply state based on a detection result of the state change.

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