JP2009237985A - Image processor, control circuit and program - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To reduce power consumption even in modes other than, for example, image processing operation in consideration of a power conversion efficiency of a power output means provided in an image processor. <P>SOLUTION: When a main power supply switch is turned on (S101), whether or not power is supplied from a USB cable is determined (S102). When the power is supplied, whether or not supplied power is sufficient is determined (S103). When it is not sufficient, the process proceeds to S105, and when it is sufficient, the switch is turned off (S104). When no power is supplied, the process proceeds to S105. In S105, whether or not there power is supplied from other cable is determined. When power is supplied, whether or not the supplied power is sufficient is determined (S106). When not sufficient, the process proceeds to S109, and when it is sufficient, an internal switch is turned off (S107) to detect a change in maximum power consumption (S108). In 109, whether or not power is supplied from AC power supply part is determined. When power is not supplied, the internal switch is turned on (S110) to detect a shift to a power saving mode (S111). <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention relates to an image processing apparatus, a control circuit, and a program.

  For example, Patent Document 1 discloses a printing apparatus that suppresses power-related costs, eliminates power operation, and suppresses power consumption during standby in the energy saving mode. That is, this printing apparatus has a power control unit that turns on a PSU (main power supply) by connecting a USB interface cable connected to an energized personal computer to a connector provided in the printing apparatus. When the printing process has not been performed for a predetermined time, the power control unit turns off the PSU and shifts to a printer language reception standby state by the power supplied from the personal computer. When the printer language is received, the PSU is turned on to execute printing.

JP 2003-118204 A

  Here, the power supply included in the image processing apparatus is generally set so that the power conversion efficiency is optimized during the image processing operation. Therefore, the power conversion efficiency of the power supply is generally lowered in a power saving mode other than the image processing operation, for example, or in another mode in which power consumption is lower than that during the image processing operation and higher than the power saving mode.

  The present invention provides an image processing apparatus, a control circuit, and a program that can reduce power consumption even in modes other than the image processing operation, for example, in consideration of the power conversion efficiency of the power output means provided therein. For the purpose.

The invention described in claim 1 includes a power output means for receiving DC power from a commercial power source and outputting DC power, and a first external device connected by a cable having a communication function and a power supply function. A first power receiving means for receiving power supply via a cable; and a second power receiving means for receiving power supply via a cable from a second external device connected by a cable having a communication function and a power supply function. The acquisition means for acquiring power information, and the power to be used based on the power information acquired by the acquisition means, the power output from the power output means and the first power reception means receive power supply. And a selecting unit that selects any one or a combination of the power received by the second power receiving unit and the power supplied by the second power receiving unit.
The invention according to claim 2 further includes on / off means for turning on and off the power output means, and the on / off means is configured to switch the power output means when the power output from the power output means is not selected by the selection means. The image processing apparatus according to claim 1, wherein the image processing apparatus is cut.
The invention according to claim 3 is the image processing apparatus according to claim 1, wherein the first power receiving unit and the second power receiving unit are configured according to different standards. .
According to a fourth aspect of the present invention, the maximum power at which the second power receiving means receives power supply is larger than the maximum power at which the first power receiving means receives power supply, and the selection means is configured to receive the second power receiving power. If the power consumption by the acquired power information exceeds the maximum power in the second power receiving means, the power in the first power receiving means and the second power receiving means is selected. 4. The image processing apparatus according to claim 1, wherein the image processing apparatus is selected.
The invention according to claim 5 is characterized in that the first external device connected by a cable having a communication function and a power supply function is a hub. It is an image processing apparatus of description.

According to a sixth aspect of the present invention, there is provided a power output means for outputting DC power upon receiving power supply from a commercial power supply, and a first external device connected by a cable having a communication function and a power supply function. A first power receiving means for receiving power supply via a cable; and a second power receiving means for receiving power supply via a cable from a second external device connected by a cable having a communication function and a power supply function. , An image processing apparatus including: an acquisition unit that acquires power information; and power to be used is output from the power output unit based on the power information acquired by the acquisition unit A selection circuit that selects one or a combination of electric power, electric power received by the first power receiving means, and electric power received by the second power receiving means. A.
The invention according to claim 7 further includes on / off means for turning on and off the power output means, and the on / off means is configured to switch the power output means when the power output from the power output means is not selected by the selection means. The control circuit according to claim 6, wherein the control circuit is cut.

According to an eighth aspect of the present invention, there is provided a power output means for outputting DC power upon receiving power supply from a commercial power source, and a first external device connected by a cable having a communication function and a power supply function. A first power receiving means for receiving power supply via a cable; and a second power receiving means for receiving power supply via a cable from a second external device connected by a cable having a communication function and a power supply function. , A computer equipped with an image processing apparatus including: an acquisition function for acquiring power information; and a power to be used based on the power information acquired by the acquisition function, the power output from the power output means, and the A selection function for selecting any one or a combination of the power received by the first power receiving means and the power received by the second power receiving means. It is a lamb.
The invention according to claim 9 further realizes an on / off function for turning on and off the power output means, and the on / off function is configured to output the power output means when the power output from the power output means is not selected by the selection function. 9. The program according to claim 8, wherein the program is cut.

According to the first aspect, compared to the case where the present invention is not applied, for example, it is possible to reduce power consumption even in a mode other than the image processing operation.
According to the second aspect, it is possible to reduce power consumption as compared with the case where the present invention is not applied.
According to claim 3, by using power receiving means of different standards, it is possible to improve versatility compared to the case where the present invention is not applied.
According to the fourth aspect, it is possible to receive power supply corresponding to the required amount of electric power as compared with the case where the present invention is not applied.
According to claim 5, it is possible to use power more efficiently than in the case where the present invention is not applied.
According to the sixth aspect, compared to the case where the present invention is not applied, for example, it is possible to reduce power consumption even in other modes other than the image processing operation.
According to the seventh aspect, it is possible to reduce power consumption as compared with the case where the present invention is not applied.
According to the eighth aspect, compared to the case where the present invention is not applied, for example, it is possible to reduce power consumption even in other modes other than the image processing operation.
According to the ninth aspect, it is possible to reduce power consumption as compared with the case where the present invention is not applied.

Embodiments of the present invention will be described below in detail with reference to the accompanying drawings.
FIG. 1 is a schematic configuration diagram showing a power feeding system PS according to the present embodiment.
As shown in the figure, the power supply system PS receives an image processing instruction as an example of an image processing apparatus that receives and prints, and information processing as a host apparatus connected to the image processing apparatus 1 via a cable C2. The apparatus 2 includes a hub 3 as a switching hub that is connected to the image processing apparatus 1 via a cable C3 and is network-connected and can be supplied with power via the cable C3. Each of the cables C2 and C3 has a communication function and a power supply function as will be described later.

The image processing apparatus 1 has a power cord 1a with a power plug that is connected to a power line outlet (not shown). The information processing apparatus 2 includes a power cord 2a with a power plug that is connected to a power line outlet (not shown). The hub 3 has a power cord 3a with a power plug connected to an outlet of a power line (not shown).
More specifically, the image processing apparatus 1 receives power supply from the information processing apparatus 2 via the cable C2 and receives power supply from the hub 3 via the cable C3.

  This power supply system PS is a system that prints out the information processing apparatus 2 to the image processing apparatus 1 through the cable C2, and also prints out from the network NW and the hub 3 to the image processing apparatus 1 through the cable C3. It is. Such a power supply system PS can be installed in an office, for example.

  Here, the cable C2 is a USB (Universal Serial Bus) cable, and can transfer data and supply power. That is, a maximum power supply of 2.5 W is possible with the cable C2. The image processing apparatus 1 has a USB interface (not shown) as an external interface.

In addition, the cable C3 is formed by integrating a data communication line and a power supply line, but it is also conceivable to use a cable configured by a pair of a data communication line and a power supply line.
More specifically, the power supply line of the cable C3 can supply a maximum of 12.95 W with an input voltage of 36 to 57 V, for example. For this reason, if it is a low power apparatus, it can operate | move, without preparing a power supply itself. As such power supply, power supply and data transmission / reception from the hub 3 to the image processing apparatus 1 through a power supply network connection such as a Power-over-Ethernet (registered trademark) connection. It is conceivable to adopt a standard called IEEE802.3af that performs the above.

  The hub 3 corresponds to Power over Ethernet (registered trademark) that supplies power to the network device, and can supply power to the image processing apparatus 1 through the cable C3 by supplying power to a predetermined port. It is configured.

  Here, in addition to the case where the power supply to the image processing apparatus 1 is performed from the information processing apparatus 2 via the cable C2 and from the hub 3 via the cable C3, the power supply from the information processing apparatus 2 via the cable C2 is performed. And the case where the operation is performed from the hub 3 via the cable C3. In addition, since the hub 3 is normally used in a state where the power is on, it is preferable as a stationary power source rather than the information processing apparatus 2.

  As described above, the power supply amount supplied to the image processing apparatus 1 through the cable C2 is the smallest, and the power supply amount supplied through the cable C3 and the power supply amount supplied through the power cord 1a increase in this order. For this reason, it can be considered that the power supply side is selected in accordance with the power consumption state of the image processing apparatus 1. In other words, depending on the amount of power required by the image processing apparatus 1, a configuration in which unnecessary ones of the power feeding means through the cables C2 and C3 and the power cord 1a are turned off is also conceivable.

  In addition, the image processing apparatus 1 can transmit / receive predetermined data to / from the information processing apparatus 2 via the cable C2, and the apparatus (not shown) connected to the hub 3 via the cable C3 and the predetermined data. Data can be sent and received. Before the data transfer between the image processing device 1 and the information processing device 2 or the data transfer between the image processing device 1 and a device connected to the hub 3 (not shown), Negotiation for establishing data communication with the transmission destination is performed via the cables C2 and C3. The term “negotiation” can also be said to mean that hardware devices exchange information regarding communication (communication conditions).

FIG. 2 is a block diagram illustrating a functional configuration example of the hub 3.
As shown in the figure, the hub 3 includes a plurality of input ports 31A and 31B (hereinafter also referred to as “input ports 31”), a switching unit 32, a hub control unit 33, a plurality of output ports 34A and 34B, 34C, 34D, 34E (hereinafter also referred to as “output port 34” as a representative), an address management table storage unit 35, a buffer memory 36, and an internal power source 37. In the figure, signal lines for transmitting signals such as data signals and control signals are indicated by broken lines, and power lines for supplying power to each functional unit are indicated by solid lines.
The input ports 31A and 31B are connected to the network NW through a signal cable (communication line) such as a LAN cable. Then, print data from a terminal device (not shown) is received, and the received print data is transmitted to the hub control unit 33 via the switching unit 32.
The switching unit 32 transmits the print data received at the input port 31 to the hub control unit 33. Further, under the control of the hub control unit 33, the print data is transmitted to the output port 34 to which the image processing apparatus 1 designated in the print data is connected.
Further, the internal power supply 37 converts 100V supplied from the commercial power supply into 5V, for example, and supplies it to the output ports 34A to 34E. In addition, driving power is supplied to each functional unit in the hub 3 through a power line (not shown).

  The hub control unit 33 acquires the print data received at the input port 31 via the switching unit 32. Then, the print data is stored in the buffer memory 36. Further, the hub control unit 33 analyzes the acquired print data and determines an output port 34 that is a distribution destination of the print data. Then, the switching unit 32 is instructed to set the output port 34, and the switching unit 32 sets the output port 34 that is the distribution destination. Then, the hub control unit 33 transmits the print data stored in the buffer memory 36 to the set output port 34 via the switching unit 32.

  Here, the hub controller 33 distributes the output ports 34 based on, for example, the MAC address of Ethernet (registered trademark). That is, the address management table storage unit 35 stores an address management table indicating a correspondence relationship between the MAC address and the output port 34, and which MAC address of the image processing apparatus 1 is connected to which output port 34. It is managed. Then, the hub control unit 33 refers to the address management table in the address management table storage unit 35 and determines an output port 34 that is a distribution destination based on the MAC address at the head of the received print data. When the print data is received, the address management table is based on the input port 31 that has received the print data and the MAC address of the information processing apparatus 2 (see FIG. 1) that is the transmission source included in the print data. Automatically created. Further, the administrator of the image processing apparatus 1 may add the correspondence between the specific output port 34 and the specific MAC address to the address management table. If the correct entry is not yet registered in the address management table, the received print data is transmitted to all the output ports 34 (34A to 34E). However, when the print data is received even once, the MAC address is automatically set. Learn and update the address management table.

  Further, the hub control unit 33 determines whether each of the output ports 34A to 34E is connected to the image processing apparatus 1 having a power receiving function compliant with a specific standard (for example, IEEE802.3af). That is, a network interface (hereinafter referred to as “network I / F”) that simultaneously receives a data signal and power provided in the image processing apparatus 1 connected to the output ports 34A to 34E is specified by a specific standard (for example, IEEE 802. It is determined whether or not it conforms to 3af). When it is determined that the image processing apparatus 1 has a network I / F that conforms to a specific standard, the power from the internal power supply 37 is supplied to the image processing apparatus 1 via the output port 34. To control.

Here, the hub control unit 33 determines whether or not it is connected to the image processing apparatus 1 having a network I / F compliant with a specific standard as follows. That is, for example, a predetermined value of voltage is supplied to the image processing apparatus 1 from the output port 34 to which the image processing apparatus 1 is connected, and the current value flowing at that time is detected. Then, based on the supplied voltage value and the detected current value, it is checked whether or not the network I / F of the image processing apparatus 1 has a predetermined resistance value (for example, 25 kΩ). As a result, when the network I / F of the image processing apparatus 1 has a resistance value of a predetermined magnitude, the hub control unit 33 has a network I / F whose output port 34 conforms to a specific standard. It is determined that it is connected to the image processing apparatus 1 provided with.
The hub control unit 33 receives power from the internal power source 37 from the output port 34 connected to the image processing apparatus 1 having a network I / F compliant with a specific standard. Control to supply.

The output ports 34A to 34E are connected to the image processing apparatus 1 via a signal cable (communication line) such as a LAN cable. Then, the print data received at the input port 31 is transmitted to the image processing apparatus 1 under the control of the hub control unit 33 described above.
Further, when it is determined by the hub control unit 33 that the output ports 34A to 34E are connected to the image processing apparatus 1 having a network I / F conforming to a specific standard, for example, 5 V from the internal power supply 37 is output. Is supplied to the image processing apparatus 1 via the output port 34.

FIG. 3 is a block diagram illustrating a configuration example of the image processing apparatus 1.
As shown in FIG. 1, the image processing apparatus 1 is an example of a power output unit that converts a AC power supplied from a power cord 1 a into a DC power source, and a controller 4 that performs predetermined control. AC power supply unit (commercial power supply) 51. The configuration of the controller 4 will be described later.
In addition, the image processing apparatus 1 is provided in the power supply path of the AC power supply unit 51, and the DC power supply converted by the AC power supply unit 51 is supplied to the controller 4 through the power supply path and the DC power supply path is cut off. An internal switch 52 is provided as an example of an on / off means for switching between a state in which no power is supplied. The image processing apparatus 1 also includes a main power switch SW for turning on / off the power supply from the power cord 1 a to the AC power source 51. In addition, when the main power switch SW is off, the internal switch 52 of the AC power supply unit 51 is off.

  The controller 4 is connected to the power supply line of the cable C2, and includes a power supply acquisition unit 41 that acquires power via the cable C2, a switch 42 that switches power on and off to the power supply acquisition unit 41, and a power supply line of the cable C3. , And a switch 44 for turning on / off the power supply to the power acquisition unit 43. On / off of the switches 42 and 44 and the internal switch 52 is controlled by a power supply control circuit 61 described later. The main power switch SW is manually operated by the user. The power acquisition unit 41 and the switch 42 constitute a first power reception unit, and the power acquisition unit 43 and the switch 44 constitute a second power reception unit. Note that the maximum power of the power source acquired via the cable C3 is larger than the maximum power of the power source acquired via the cable C2.

  The controller 4 includes a power supply switching unit 45 to which the power from the power acquisition unit 41 and the power from the power acquisition unit 43 are supplied in addition to the power from the AC power supply unit 51. The power supply switching unit 45 supplies the power from the AC power supply unit 51, the power supply acquisition unit 41, and the power supply acquisition unit 43 to the load system 46 and the load system 47 (power distribution).

  More specifically, the power supply switching unit 45 always supplies power to the load system 46 from at least one of the power supply line of the cable C2, the power supply line of the cable C3, and the power supply path from the AC power supply unit 51. Has been. Also, in the load system 47, the power supply switching unit 45 is connected to the power supply line of the cable C 2, the power supply line of the cable C 3, and the power supply path from the AC power supply unit 51 based on an instruction from the power control circuit 61 described later. Power is supplied from one or more. In addition, the AC power supply unit 51 directly supplies power to the load system 48. The load system 48 has higher power consumption than the load systems 46 and 47.

In the present embodiment, the load system 46 has a power control circuit 61 connected to each of the data communication line of the cable C2 and the data communication line of the cable C3, and a plurality of application functions for controlling each device and the like. And a mounted IO ASIC (Application Specific Integrated Circuit) 62. The power supply control circuit 61 and the power supply switching unit 45 can constitute acquisition means and selection means. Furthermore, it is conceivable to include the IO ASIC 62 in the configuration of the acquisition unit and the selection unit.
Further, the power supply control circuit 61 and the power supply switching unit 45 can constitute a control circuit included in the image processing apparatus 1.

  In addition, the load system 47 functions as a CPU (Central Processing Unit) 71 as an example of an arithmetic unit that executes digital arithmetic processing according to a predetermined operation control program (firmware), a work memory of the CPU 71, and the like. And a memory 72 that stores processing programs executed by the CPU 71 and data such as setting values used in the processing programs. Note that the memory 72 can be configured by, for example, a flash memory, an EEPROM (Electronically Erasable and Programmable Read Only Memory), or the like. The CPU 71, the memory 72, and the IO ASIC 62 are connected by a bus.

  In addition, the load system 48 includes an HDD (Hard Disk Drive) 81 in which predetermined program data and the like are stored, and a panel for displaying information and the like that the user operates and the information processing apparatus 2 notifies the user. 82 and an IC card reader 83 for performing user authentication. The load system 48 includes a video ASIC 84 having a plurality of application functions for controlling video and the like, a scanner 85 for reading an image, an engine 86 for forming an image on a sheet, and a hole in the sheet. And a finisher 87 that performs post-processing such as opening. Note that the IC card reader 83 and the finisher 87 are externally connected to the image processing apparatus 1.

FIG. 4 is a block diagram illustrating a configuration example of the power supply control circuit 61.
As shown in the figure, the power supply control circuit 61 includes an information acquisition unit 91 that acquires power information, and a storage unit 92 that stores various types of information including the power information acquired by the information acquisition unit 91. . The power supply control circuit 61 uses the cable C2 as power to be supplied to the load system 47 (see FIG. 3) based on the power information acquired by the information acquisition unit 91 and / or the information stored in the storage unit 92. A determination unit 93 that determines one or more of the power from the cable C3, the power from the cable C3, and the power from the AC power supply unit 51, and a transmission unit 94 that transmits the determination result by the determination unit 93 to the power supply switching unit 45. And.
The determination unit 93 determines whether the switches 42 and 44 and the internal switch 52 are turned on and off, and notifies the switch control unit 95 of the determination result. The switch control unit 95 instructs the switches 42 and 44 and the internal switch 52 to turn on and off.

5A and 5B are tables showing an example of power information acquired by the information acquisition unit 91 of the power supply control circuit 61. FIG.
As shown in the figure, the power information acquired by the information acquisition unit 91 includes information about supplied power and information about power consumption. Information on the supplied power includes information on the amount of power by the AC power source 51 and information on the amount of power by the cables C2 and C3. In the cable C2, there are two stages of supply power states, and the respective power amounts are acquired. Further, the cable C3 has three levels of supply power states, and the respective power amounts are acquired. Specifically, the AC power supply unit 51 supplies 1500 W at the maximum. The cable C2 has a minimum guarantee of 0.5W and a maximum of 2.5W. In cable C3, class 1 is 4W, class 2 is 7W, and class 3 is 15.4W. That is, the maximum power that can be supplied by the cable C2 and the cable C3 is 2.5W + 15.4W = 17.9W. Therefore, the image processing apparatus 1 can be supplied with power of 0.5 W to 17.9 W through the cable C2 and the cable C3.

Further, as information on power consumption, there is information on each power amount of the controller 4, HDD 81, IC card reader 83, scanner 85, engine 86 and finisher 87. Furthermore, the controller 4 has different amounts of power in the power saving mode and in the normal mode, and acquires information on the amount of power for each. More specifically, the power consumption of the controller 4 is 2 W in the power saving mode and 10 W in the normal mode. The power consumption of the HDD 81 is 10 W, and the power consumption of the IC card reader 83 is 5 W. The panel 82 consumes 40 W, the scanner 85 consumes 200 W, the engine 86 consumes 1000 W, and the finisher 87 consumes 200 W. Thus, the overall power consumption of the image processing apparatus 1 is highest when the engine 86 is used and lowest in the power consumption mode.
More specifically, in the power saving mode, the power consumption of the controller 4 can be handled only by the power supplied from the cable C2. Further, in the normal mode, the power supplied by the cable C2 cannot cope with the power consumption of the controller 4, but can be handled only by the power supplied by the cable C3. Further, the power consumption of the IC card reader 83 can be handled only by the power supplied from the cable C3.

  And as shown to (a) and (b) of FIG. 5, the information acquisition part 91 acquires the relationship between the information regarding power supply, and the information regarding power consumption. In addition to the case where the information is input by the user, a case where the information is stored in advance in the memory 72 (see FIG. 3) can be considered. The power information acquired in this way is temporarily stored in the storage unit 92 and is read out as necessary, or transferred to the determination unit 93 after being acquired. In the table shown in the figure, the case where the power supplied from any one of the AC power supply unit 51, the cable C2, and the cable C3 is shown, but the AC power supply unit 51, the cable C2, and the cable C3 It may be possible to cope with power supplied from a plurality of combinations. For example, a combination of the cable C2 and the cable C3.

FIG. 6 is a flowchart illustrating an example of a processing procedure performed by the determination unit 93 of the power supply control circuit 61.
In the flowchart shown in FIG. 6, when the main power switch SW is turned on by the user (step 101), the determination unit 93 obtains whether or not there is power supply from the cable C <b> 2 through the data communication line of the cable C <b> 2. (Step 102). If the determination unit 93 determines that there is power feeding from the cable C2, it is next determined from the power information (see FIG. 5) whether or not the maximum power consumption is equal to or greater than the power supplied from the cable C2. That is, the determination unit 93 determines whether or not the power supplied from the cable C2 is sufficient (step 103). In step 103, if it is determined that the power supplied from the cable C2 is insufficient, the process proceeds to step 105. If it is determined that the power supplied from the cable C2 is sufficient, it is confirmed that the power supply from the cable C3 is off. If the power supply from the cable C3 is not off, the determination unit 93 turns off the switch 44 via the switch control unit 95 (step 104), and proceeds to step 107.
When the determination unit 93 determines that there is no power supply from the cable C2 in step 102, the process proceeds to step 105. That is, the process proceeds to step 105 when the determination unit 93 determines that there is no power supply from the cable C2 or that the maximum power consumption is not sufficient even if power is supplied from the cable C2.

  In step 105, the determination unit 93 determines whether there is power feeding from the cable C3 from the information acquired via the data communication line of the cable C3. When the determination unit 93 determines that there is power feeding from the cable C3, the relationship between the maximum power consumption and the power supplied from the cables C2 and C3 is determined. In other words, it is determined from the power information (see FIG. 5) whether or not the maximum power consumption is greater than or equal to the power supplied from the cables C2 and C3. That is, the determination unit 93 determines whether or not the power supplied from the cables C2 and C3 is sufficient (step 106). If it is determined that the power supplied from the cables C2 and C3 is insufficient, the process proceeds to step 109. If it is determined that the power supplied from the cables C2 and C3 is sufficient, it is confirmed that the internal switch 52 of the AC power supply unit 51 is off. . If not, the determination unit 93 turns off the internal switch 52 via the switch control unit 95 (step 107). As described above, when the power consumption of the image processing apparatus 1 is sufficient by the power supplied from the cables C2 and C3, only the power supplied from the cables C2 and C3 is used, and the internal switch 52 of the AC power supply unit 51 is turned off. As a result, the use of the AC power supply unit 51 in a state where the power conversion efficiency of the AC power supply unit 51 is reduced and the energy loss during power conversion is increased is avoided, thereby reducing power consumption.

  Thereafter, the determination unit 93 determines whether or not the maximum power consumption has been changed using, for example, the table shown in FIG. 5 (step 108). For example, the power saving mode is canceled and the normal mode is set, for example. If there is a change in the maximum power consumption, the process returns to step 102. That is, until now, the AC power supply unit 51 was not used but the power supplied from the cables C2 and C3 was used. When the maximum power consumption was changed, the determination unit 93 uses the AC power supply unit 51. Return to step 102 to determine if it is necessary.

  If it is determined in step 105 that no power is supplied from the cable C3, the process proceeds to step 109. That is, in the case of proceeding to Step 109, the determination unit determines that there is no power supply from the cable C2 and power supply from the cable C3, or even if there is power supply from the cable C2 and / or cable C3, the maximum power consumption is not sufficient. This is the time when 93 is judged.

  In step 109, the determination unit 93 determines whether or not the internal switch 52 of the AC power supply unit 51 is on. When determining that the internal switch 52 is not on, the determination unit 93 turns on the internal switch 52 via the switch control unit 95 (step 110), and starts using the AC power supply unit 51.

Thereafter, the determination unit 93 determines whether or not the mode has shifted to the power saving mode (step 111), and returns to step 102 when determining that the mode has shifted from the normal mode to the power saving mode, for example.
If it is determined in step 109 that the internal switch 52 is on, the process proceeds to step 111.

  As described above, when the main power switch SW is turned on, the power supply from the cable C2, the power supply from the cable C3, the power supply from the cable C2 and the cable C3, and the AC power supply unit 51 according to the maximum power consumption. It becomes various forms of power feeding such as power feeding.

It is a schematic block diagram which shows the electric power feeding system which concerns on this Embodiment. It is the block diagram which showed the functional structural example of the hub. It is a block diagram which shows the structural example of an image processing apparatus. It is a block diagram which shows the structural example of a power supply control circuit. (A) And (b) is a table | surface which shows an example of the electric power information which the information acquisition part of a power supply control circuit acquires. It is a flowchart which shows an example of the process sequence by the judgment part of a power supply control circuit.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 ... Image processing apparatus, 3 ... Hub, 4 ... Controller, 41, 43 ... Power supply acquisition part, 42, 44 ... Switch, 45 ... Power supply switching part, 46, 47, 48 ... Load system, 51 ... AC power supply part, 52 ... Internal switch, 61 ... Power supply control circuit, 91 ... Information acquisition unit, 92 ... Storage unit, 93 ... Judgment unit, 94 ... Transmission unit, 95 ... Switch control unit, C2, C3 ... Cable

Claims (9)

Power output means for receiving DC power from a commercial power source and outputting DC power;
First power receiving means for receiving power supply via a cable from a first external device connected by a cable having a communication function and a power supply function;
A second power receiving means for receiving power supply via a cable from a second external device connected by a cable having a communication function and a power supply function;
Obtaining means for obtaining power information;
Based on the power information acquired by the acquisition means, the power to be used is the power output from the power output means, the power received by the first power receiving means, and the second power receiving means. Selection means for selecting any one or a plurality of combinations with the supplied electric power;
An image processing apparatus. Further comprising on / off means for turning on / off the power output means,
The image processing apparatus according to claim 1, wherein the on / off unit turns off the power output unit when the power output from the power output unit is not selected by the selection unit.   The image processing apparatus according to claim 1, wherein the first power receiving unit and the second power receiving unit are configured according to different standards. The maximum power at which the second power receiving means receives power supply is greater than the maximum power at which the first power receiving means receives power supply,
The selection means selects power in the second power receiving means, and when the power consumption amount by the acquired power information exceeds the maximum power in the second power receiving means, the first power receiving means and 4. The image processing apparatus according to claim 1, wherein the second power receiving unit selects electric power. 5.   The image processing apparatus according to claim 1, wherein the first external device connected by a cable having a communication function and a power supply function is a hub. A power output means for receiving DC power from a commercial power source and outputting DC power, and a first external device connected by a cable having a communication function and a power supply function. Control provided in the image processing apparatus, including: a first power receiving unit; and a second power receiving unit that receives power from the second external device connected by a cable having a communication function and a power supply function. A circuit,
Obtaining means for obtaining power information;
Based on the power information acquired by the acquisition means, the power to be used is the power output from the power output means, the power received by the first power receiving means, and the power received by the second power receiving means. Selecting means for selecting any one or a combination of
Including control circuit. Further comprising on / off means for turning on / off the power output means,
The control circuit according to claim 6, wherein the on / off means turns off the power output means when the power output from the power output means is not selected by the selection means. A power output means for receiving DC power from a commercial power source and outputting DC power, and a first external device connected by a cable having a communication function and a power supply function. A computer having an image processing apparatus including: a first power receiving unit; and a second power receiving unit that receives power from the second external device connected by a cable having a communication function and a power supply function. In addition,
An acquisition function to acquire power information;
Based on the power information acquired by the acquisition function, the power used is the power output from the power output means, the power received by the first power receiving means, and the power received by the second power receiving means. A selection function for selecting any one or a combination of
A program that realizes Further realizing an on / off function for turning on / off the power output means,
9. The program according to claim 8, wherein the on / off function turns off the power output means when the power output from the power output means is not selected by the selection function.

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