JP2007150411A - Image forming system - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an image forming system which is downsized, attaining operation stability, and suppressing consumed power. <P>SOLUTION: The image forming system includes: a first apparatus 300 including a power supply section 310 for generating drive voltages and an image forming section 340; and a second apparatus 200 for controlling the image forming section 340. The power supply section 310 generates a first drive voltage and a second drive voltage higher than the first drive voltage as the drive voltages, and the second apparatus 200 includes a voltage application control section 214 for controlling whether the second drive voltage is applied to the second apparatus 200. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

  The present invention relates to an image forming system.

  A conventional input / output device is disclosed in Japanese Patent Laid-Open No. 6-233016 (Patent Document 1). The conventional input / output device has a scanner unit and a printer unit. The scanner unit and the printer unit are supplied with driving power from different power supply circuits, and further supplied with control power from other power supply circuits. .

However, in the above conventional input / output device, since the power supply circuit must be provided in each of the scanner unit and the printer unit, there has been a problem that the apparatus becomes large and expensive. In an input / output device having a scanner unit and a printer unit, it is important to suppress power consumption.
JP-A-6-233016

  An object of the present invention is to provide an image forming system capable of reducing the size and stabilizing the operation and suppressing the power consumption.

(1) An image forming system according to the present invention includes:
A first device having a power supply unit for generating a drive voltage and an image forming unit;
A second device for controlling the image forming unit;
Including
The power supply unit generates a first drive voltage and a second drive voltage higher than the first drive voltage as the drive voltage,
The second device includes a voltage supply control unit that controls whether or not the second drive voltage is supplied to the second device.

  According to the above configuration, since the power supply unit supplied to the first and second devices is provided in the first device, the power supply unit is smaller than the power supply unit provided in each of the first and second devices. An inexpensive image forming system can be provided.

  Further, according to the above configuration, since the second device independently controls the second drive voltage supplied to the second device, the load on the first device is reduced and the entire image forming system is consumed. Electric power can be greatly reduced.

(2) In this image forming system,
The first apparatus may further include a voltage supply control unit that controls whether or not the second drive voltage is supplied to the image forming unit.

  According to the above configuration, since the first device independently controls the second drive voltage supplied to the first device, the load on the second device is reduced and the power consumption of the entire image forming system is reduced. Significant reduction can be achieved.

(3) In this image forming system,
The supply of the second drive voltage to the second device may be performed after the second drive voltage is supplied to the image forming unit.

  According to the above configuration, the timing at which the first device is driven and the timing at which the second device is driven can be shifted, so that the image forming system can be operated stably.

(4) In this image forming system,
The supply of the second drive voltage to the second device may be performed after the first drive voltage is supplied to the second device.

  According to the above configuration, for example, a low voltage for control is supplied first, and then a high voltage for driving is supplied. Therefore, the image forming system can be restored more stably.

(5) In this image forming system,
The supply of the second drive voltage to the second device may be performed after confirming the operating state of the second device.

  According to the above configuration, for example, when the second device is not operating or malfunctioning, the supply of the second drive voltage can be stopped. Therefore, a more stable image forming system can be operated.

(6) In this image forming system,
The second device may further include an image input unit.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings.

1. Overview of Image Forming System FIG. 1 is a block diagram showing an embodiment of an image forming system of the present invention. The image forming system includes a host computer 100 that is an external device, an image forming device 300 that is an example of a first device, an image input device (or image reading device) 200 that is an example of a second device, and power supply. And a cable 400 which is an example of a unit. In the image forming system of the present embodiment, an image forming apparatus 300 that performs printing processing on a medium is connected to a host computer 100 operated by a user via an image input apparatus 200 and a cable 400.

  Based on the instruction received from the user, the host computer 100 instructs the image input apparatus 200 to cause the image forming apparatus 300 and / or the image input apparatus 200 to perform predetermined processing.

  The image forming apparatus 300 is, for example, a printer, and includes a power supply unit 310, a first control unit 320, an engine unit 340, and a relay unit 330. The engine unit 340 is an example of an image forming unit.

  The image input device 200 is a scanner, for example, and includes a second control unit 210 and an image input unit 220. The second control unit 210 controls the operations of the image input apparatus 200 and the image forming apparatus 300 based on instructions received from the host computer 100. The image input unit 220 recognizes an image drawn on a medium or the like set in the image input unit 220, converts the recognized image into data, and supplies the data to the host computer 100 and / or the image forming apparatus 300.

  The power supply unit 310 receives an AC voltage from a commercial power supply and generates a drive voltage for driving the image input apparatus 200 and the image forming apparatus 300. The drive voltage generated by the power supply unit 310 is supplied to the image input apparatus 200 via the cable 400 which is an example of a power supply member.

  The first control unit 320 controls each component included in the engine unit 340 based on an instruction from the second control unit 210 of the image input device 200. The engine unit 340 is configured to have a configuration necessary for forming an image on a medium set in the image forming apparatus 300. Examples of the configuration include a photoconductor drive motor unit and an overall drive motor unit. Secondary transfer roller separation clutch, intermediate transfer belt cleaner separation clutch, development drive motor unit, rotary drive motor unit, eraser lamp unit, ozone fan unit, toner fan unit, cooling fan, paper feed related clutch, scanner motor, etc. Is included.

  The relay unit 330 relays the power supply unit 310 and the first control unit 320 and the cable 400. Specifically, the relay unit 330 supplies the drive voltage generated by the power supply unit 310 to the cable 400 and supplies various signals generated by the second control unit 210 to the first control unit 320 and the like.

  A cable 400 connects the image input apparatus 200 and the image forming apparatus 300. The cable 400 is detachably attached to the image input apparatus 200 and the image forming apparatus 300. The cable 400 includes a plurality of signal lines, and each signal line supplies the drive voltage generated by the power supply unit 310 to the image input apparatus 200, and the image input apparatus 200 to the image forming apparatus 300 or the image formation. Various signals are supplied from the apparatus 300 to the image input apparatus 200.

  In the image forming system of this embodiment, when the cable 400 is disconnected from at least one of the image input apparatus 200 and the image forming apparatus 300 (for example, when disconnected), the drive voltage is not supplied to the image input apparatus 200. The image input apparatus 200 stops its operation. Accordingly, an instruction or the like is not supplied from the second control unit 210 to the image forming apparatus 300.

2. Next, a circuit configuration of the image forming system according to the present embodiment will be described. FIG. 2 is a diagram showing a part of the circuit configuration of the image forming system of the present embodiment.

  The power supply unit 310 receives an AC voltage from a commercial power supply, and based on a control signal (not shown), as a drive voltage for driving the image input apparatus 200 and the image forming apparatus 300, a first drive voltage (+5 V in this example) and A second driving voltage higher than that (+24 V in this example) is generated. The first and second drive voltages are supplied to the first control unit 320 on the one hand and to the second control unit 210 via the relay unit 330 on the other hand.

  Specifically, out of the drive voltages generated by the power supply unit 310, the second drive voltage (+24 V) is based on the first voltage supply control unit 322 of the image forming apparatus 300, and the first control unit 320 (final). Is controlled whether it is supplied to the engine unit 340). Specifically, an FET 324 is provided between the power supply unit 310 and the first control unit 320. The FET 324 has a source connected to the power supply unit 310 and a drain connected to the second drive voltage. The gate is connected to the first voltage supply controller 322 and the gate is connected to the first controller 320. The FET 324 is controlled based on the voltage supplied from the first voltage supply controller 322 to determine whether the gate is turned on / off and whether the second drive voltage is supplied to the first controller 320. The The first voltage supply control unit 322 may be provided as a part of the first control unit 320 as shown in FIG. 2 or may be provided separately from the first control unit 320. May be. The FET 324 may be provided separately from the first control unit 320 as shown in FIG. 2 or may be provided as a part of the first control unit 320. The FET 324 is a p-channel MOS transistor in the example shown in FIG.

  The relay unit 330 includes FETs 332, 334, a plurality of signal lines 336, fuses 337, 338, 339, a signal buffer 360, and a connector 380. The FETs 332 and 334 are p-channel MOS transistors in the example shown in FIG.

  The second control unit 210 of the image input apparatus 200 includes a connector 212 to which the cable 400 can be attached and detached. Via the cable 400 and the connector 212, the relay unit 330 and various signals and drive voltages are provided. Deliver.

  Whether or not the first drive voltage (+5 V) generated by the power supply unit 310 is supplied to the second control unit 210 is controlled based on the attachment / detachment state of the cable 400. Specifically, an FET 334 is provided between the power supply unit 310 and the second control unit 210. The FET 334 has a source connected to the power supply unit 310 and a drain connected to the first drive voltage. The gate is connected to the connector 380 and the gate is connected to the signal line PSS1. The signal line PSS1 is pulled up to +5 V and connected to the connector 380, and is grounded in the image input apparatus 200 via the cable 400 and the connector 212. That is, the signal line PSS1 is grounded when the cable 400 is connected to both of the connectors 380 and 212, and the voltage becomes 0 V, and the cable 400 is disconnected from at least one of the connectors 380 and 212. In that case, the voltage becomes + 5V. Therefore, the FET 334 is turned on when the cable 400 is connected to both the connectors 380 and 212, and the gate voltage becomes 0 V (L logic), and as a result, the first drive voltage causes the relay unit 330 and the cable 400 to be turned on. Via the second control unit 210 (image input device 200). On the other hand, when the cable 400 is disconnected from at least one of the connectors 380 and 212, the gate voltage becomes + 5V (H logic) and is turned off. As a result, the connector 380, the cable 400, and the second control unit 210 (image input) The drive voltage is no longer supplied to the device 200).

  In the example shown in FIG. 2, the drain of the FET 334 is connected to the second control unit 210 so that the first drive voltage can be supplied via the fuse 339 on the one hand, and the voltage is stepped down via the step-down unit 370 and the fuse 338 on the other hand. It is connected to the second control unit 210 so as to supply a later drive voltage (+3.3 V in this example). The + 3.3V is supplied to the second control unit 210 (image input device 200) via the cable 400 when the cable 400 is connected to both the connectors 380 and 212. In the example shown in FIG. 2, the step-down unit 370 is provided on the relay unit 330 (image forming apparatus 300) side. However, as a modification, the step-down unit 370 is provided on the second control unit 210 (image input apparatus 200) side. May be.

  The second drive voltage (+24 V) generated by the power supply unit 310 is supplied to the second control unit 210 based on the attachment / detachment state of the cable 400 and the second voltage supply control unit 214 provided in the image input device 200. Whether or not to be performed is controlled. Specifically, an FET 332 is provided between the power supply unit 310 and the second control unit 210. The FET 332 has a source connected to the power supply unit 310 and a drain connected to the second drive voltage. The fuse 337 is connected to the connector 380, and the gate is connected to the second voltage supply control unit 214 via the cable 400. The signal line PSS2 is pulled up to + 5V and connected to the connector 380, and is connected to the second control unit 210 via the cable 400 and the connector 212. When the cable 400 is connected to both the connectors 380 and 212, the FET 332 has its gate turned on / off based on the voltage supplied from the second voltage supply control unit 214, and the second drive voltage Whether or not is supplied to the second control unit 210 is controlled. On the other hand, when the cable 400 is disconnected from at least one of the connectors 380 and 212, the gate voltage becomes + 24V (H logic) and is turned off. As a result, the connector 380, the cable 400, and the second control unit 210 (image input) The drive voltage is no longer supplied to the device 200). Note that the second voltage supply control unit 214 may be provided as a part of the second control unit 210 as shown in FIG. 2 or provided separately from the second control unit 210. May be.

  The signal buffer 360 includes a plurality of signal lines 336 and a plurality of switches SW. The switch SW is a switch such that the wiring connected to the switch SW becomes high impedance when the switch SW is off. The plurality of switches SW are controlled according to the voltage of the signal line PSS. Specifically, the plurality of switches SW are configured to be turned off when the voltage of the signal line PSS is +5 V (H logic) and to be turned on when the voltage is 0 V (L logic). That is, the plurality of signal lines 336 are high impedance when the cable 400 is disconnected from at least one of the connectors 380 and 212, while the cable 400 is connected to both the connectors 380 and 212. Is connected to the second control unit 210 via

  In the example illustrated in FIG. 2, a dedicated line 372 is provided between the first and second voltage supply control units 322 and 214. Thereby, control of the 1st and 2nd voltage supply control parts 322 and 214 can be synchronized mutually. For example, after the first voltage supply control unit 322 turns on the FET 324, a signal indicating the ON state is sent from the first voltage supply control unit 322 to the second voltage supply control unit 214 via the dedicated line 372, After confirming the signal, the second voltage supply control unit 214 can turn on the FET 332. Therefore, for example, the timing at which the second drive voltage is supplied to the engine unit 340 and the timing at which the second drive voltage is supplied to the image input device 200 can be intentionally shifted. Therefore, it is possible to avoid the start timings of both the image forming apparatus 300 and the image input apparatus 200 being coincident, and the image forming system can be operated stably.

  In the image forming system of this embodiment, the second driving voltage (+ 24V) is mainly used as a driving power source for driving a mechanism constituting the image forming system, and the first driving voltage (+ 5V). The other driving voltage (+3.3 V) is mainly used as a control power source for driving the structure for controlling the mechanism.

  In the above-described configuration, the FETs 324, 332, and 334 are p-channel MOS transistors. However, n-channel MOS transistors can also be applied. In that case, what is necessary is just to control so that H logic and L logic become reverse in ON / OFF of FET. Further, the FETs 324, 332, and 334 are examples of switch elements, and are not limited to FETs as long as the on / off operation can be switched.

3. Operation of Image Forming System Next, an example of the operation of the image forming system of this embodiment will be described. FIG. 3 is a flowchart for explaining the operation of the image forming system when the cable is disconnected, and FIG. 4 is a flowchart for explaining the operation of the image forming system when the cable is connected.

  (3-1) As shown in FIGS. 2 and 3, when the cable 400 is connected to both the connectors 380 and 212 (S102, NO), that is, the image input apparatus 200 and the image forming apparatus 300 are connected to each other. In such a case, the image forming apparatus 300 is in a state where power can be supplied to the image input apparatus 200, and they are in a state where they can communicate with each other.

  Specifically, in this case, since the signal line PSS1 is grounded in the image input device 200 via the cable 400, and the FET 334 is turned on by this, the first drive voltage (+ 5V) generated by the power supply unit 310 is The image is supplied to the image input apparatus 200 via the cable 400. In addition, +3.3 V that has been stepped down by the step-down unit 370 is also supplied to the image input device 200 via the cable 400. Further, when the signal line PSS 1 is grounded, the switch SW is turned on, and the plurality of signal lines 336 are connected to the second control unit 210. As a result, the image input device 200 and the image forming device 300 can perform communication such as instructions and delivery of various data. Further, when the second voltage supply control unit 214 turns on the FET 332 (that is, inputs L logic to the gate), the second drive voltage (+ 24V) generated by the power supply unit 310 is also transmitted via the cable 400. It is supplied to the image input device 200.

  As shown in FIGS. 2 and 3, when the cable 400 is disconnected from at least one of the connectors 380 and 212 (S102, YES), that is, when the image input apparatus 200 and the image forming apparatus 300 are disconnected from each other. The image forming apparatus 300 stops supplying power to the image input apparatus 200, and the mutual communication is cut off.

  Specifically, in this case, the signal line PSS1 is pulled up to +5 V when the cable 400 is disconnected from the state of being grounded via the cable 400. When the voltage of the signal line PSS1 becomes +5 V, the gate voltage of the FET 334 becomes +5 V (H logic) and is turned off (S104). As a result, the first drive voltage (+5 V) and the voltage after step-down (+3.3 V) are not supplied to the connector 380. Similarly, the signal line PSS2 is pulled up to + 5V when the cable 400 is disconnected, the FET 332 is turned off with a gate voltage of + 5V (H logic) (S104), and the connector 380 has a second drive voltage (+ 24V). ) Will not be supplied. Therefore, it is possible to prevent the components of the image forming apparatus 300 from being destroyed due to a short circuit or the like.

  When the voltage of the signal line PSS1 becomes + 5V (H logic), the switch SW of the signal buffer 360 is turned off (S106), and the communication between the image input apparatus 200 and the image forming apparatus 300 by the plurality of signal lines 336 is disconnected. Is done.

  When the cable 400 is disconnected from at least one of the connectors 380 and 212, the first voltage supply control unit 322 turns off the FET 324, and the first control unit 320 (or engine unit) of the second drive voltage (+ 24V). 340) is stopped (S108). On / off of the FET 324 may be controlled based on, for example, the mutual connection state of the first and second voltage supply control units 322 and 214 (for example, the connection state of the dedicated line 372). When the supply of the second drive voltage (+ 24V) is stopped, the first control unit 320 stops its operation (S110), and the operation of the engine unit 340 is also stopped. Alternatively, the first controller 320 may shift to the energy saving mode by stopping the supply of the second drive voltage (+ 24V) (S110). Even when the first control unit 320 enters the energy saving mode, the operation of the engine unit 340 stops.

  From the above, when the cable 400 is disconnected from at least one of the connectors 380 and 212, the power supply unit 310 stops supplying the second drive voltage (+ 24V) and supplies the first drive voltage (+ 5V). The first control unit 320 is supplied. As a result, it is possible to prevent the image forming system from being damaged due to a short circuit.

  (3-2) Next, with reference to FIG. 4, the operation of returning the image forming system when the cable 400 is connected to both the connectors 380 and 212 will be described. Here, the case where the image forming system operates in the normal mode in both the image input apparatus 200 and the image forming apparatus 300 will be described.

  Here, the normal mode refers to the case where both the mechanism constituting the image forming system and the control circuit that controls the mechanism are operated, while the energy saving mode refers to the mechanism constituting the image forming system. This is a case where only the control circuit to be controlled is operated.

  First, when the cable 400 is connected to both the connectors 380 and 212 (S122, YES), the signal line PSS1 is grounded via the cable 400, and its voltage becomes 0V. When the voltage of the signal line PSS1 becomes 0V, the FET 334 is turned on with the gate voltage being 0V (L logic), and the first drive voltage (+ 5V) is supplied to the second controller 210 via the cable 400 (S124). ). At the same time, the voltage (+3.3 V) after being stepped down by the step-down unit 370 is also supplied to the second control unit 210 via the cable 400.

  When the signal line PSS1 becomes 0V, the switch SW of the signal buffer 360 is turned on (S126). As a result, the plurality of signal lines 336 connect the first and second control units 320 and 210, and communication such as instructions and various data can be communicated between the image input apparatus 200 and the image forming apparatus 300. .

  On the other hand, the first voltage supply control unit 322 turns on the FET 324, and the second drive voltage (+ 24V) is supplied to the first control unit 320 (or the engine unit 340) (S128). The supply of the second drive voltage to the first control unit 320 may be performed substantially simultaneously with the supply of the first drive voltage to the second control unit 210 described above, or performed before or after that. Also good.

  Then, the second voltage supply control unit 214 sets the voltage of the signal line PSS2 to 0V (L logic), turns on the FET 332, and supplies the second drive voltage (+ 24V) via the cable 400 to the second control unit 210. (S130).

  In the example illustrated in FIG. 4, the second drive voltage (+ 24V) is supplied to the second control unit 210 after the second drive voltage is supplied to the first control unit 320. For example, the time from when the cable 400 is connected to both the connectors 380 and 212 until the second drive voltage (+ 24V) is supplied is determined in each of the first and second voltage supply control units 322 and 214. You may set beforehand so that it may differ. Or you may control intentionally so that the timing of a voltage supply may be shifted by the exclusive line 372 which can communicate between the 1st and 2nd voltage supply control parts 322 and 214. FIG. According to this, since the timing at which the image forming apparatus 300 is driven and the timing at which the image input apparatus 200 is driven can be shifted, the image forming system can be operated stably.

  Further, in the example shown in FIG. 4, the second drive voltage (+ 24V) is supplied to the second control unit 210 after the first drive voltage (+ 5V) is supplied to the second control unit 210. Is called. For example, in the second voltage supply control unit 214, the FET 400 is connected to the FET 332 after a certain time from when the cable 400 is connected to both the connectors 380 and 212 and the first drive voltage (+ 5V) is supplied to the second control unit 210. May be turned on. According to this, the low voltage for control is supplied to the second controller 210 first, and then the high voltage for driving is supplied. Therefore, the image forming system can be restored more stably.

  Note that the second drive voltage (+ 24V) is supplied to the second control unit 210 after confirming the operation state of the image input apparatus 200 (for example, the second control unit 210) (for example, confirming normal operation). You may go. According to this, the supply of the second drive voltage (+ 24V) can be stopped when the image input apparatus 200 is not operating or malfunctioning.

  From the above, when the cable 400 is connected to both the connectors 380 and 212, the first and second drive voltages can be stably supplied to the image forming apparatus 300 and the image input apparatus 200.

  (3-3) Next, operations of the image input apparatus 200 and the image forming apparatus 300 in a state where the cable 400 is connected to both the connectors 380 and 212 will be described.

  When the image input apparatus 200 and the image forming apparatus 300 are in the energy saving mode, the first drive voltage (+5 V) is supplied to the first control unit 320 on the one hand, and the second drive voltage via the FET 334 and the cable 400 on the other hand. It is supplied to the control unit 210. The signal line PSS1 is grounded by the connection of the cable 400 and the switch SW is turned on, and the image input apparatus 200 and the image forming apparatus 300 can communicate with each other by the plurality of signal lines 336.

  First, when the image forming apparatus 300 returns from the energy saving mode to the normal mode, the first voltage supply control unit 322 turns on the FET 324 and supplies the second drive voltage (+24 V) to the first control unit 320. To do. In this case, if necessary, the first voltage supply control unit 322 may communicate with the second voltage supply control unit 214 via the dedicated line 372. For example, the first voltage supply control unit 322 may turn on the FET 324 after confirming that the second voltage supply control unit 214 turns off the FET 332.

  When the image input apparatus 200 returns from the energy saving mode to the normal mode, the second voltage supply control unit 214 turns on the FET 334 and supplies the second drive voltage (+24 V) to the second control unit 210. To do. In this case, if necessary, the second voltage supply control unit 214 may communicate with the first voltage supply control unit 322 via the dedicated line 372. For example, when the image forming apparatus 300 also returns to the normal mode at the same time, the first voltage supply control unit 322 turns on the FET, and after a predetermined time has elapsed, the second voltage supply control unit 214 turns on the FET 332. May be.

  The second voltage supply control unit 214 confirms the operation state of the image input apparatus 200 (for example, the second control unit 210) (for example, confirms normal operation), and then the second voltage supply control unit 214 performs the second drive voltage (+ 24V). Supply may be performed. According to this, the supply of the second drive voltage (+ 24V) can be stopped when the image input apparatus 200 is not operating or malfunctioning.

  Further, when the image forming apparatus 300 shifts from the normal mode to the energy saving mode, the first voltage supply control unit 322 turns off the FET 324. As a result, the supply of the second drive voltage (+ 24V) to the first controller 320 is stopped. Therefore, only the first drive voltage (+ 5V) is supplied from the power supply unit 310 to the first control unit 320, and only the control circuit that controls the mechanism is stopped while stopping the operation of the mechanism including the engine unit 340. It can be operated.

  Further, when the image input apparatus 200 shifts from the normal mode to the energy saving mode, the second voltage supply control unit 214 turns off the FET 334. As a result, the supply of the second drive voltage (+ 24V) to the second controller 210 is stopped. Therefore, only the first drive voltage (+ 5V) is supplied from the power supply unit 310 to the second control unit 320, and the operation of the mechanism (for example, a mechanism related to FAX transmission, network scanning, etc.) is stopped while the second control unit 320 is stopped. Only the control circuit that controls the mechanism can be operated.

  According to the above configuration, whether or not the second drive voltage (+ 24V) is supplied to the image input device 200 is controlled by the image input device 200 itself. Can be determined based on the condition. That is, when the image input device 200 is not operating or malfunctioning, for example, the second drive voltage (+24 V) can be prevented from being supplied. Therefore, supply of a high voltage in an uncontrolled state can be avoided, and destruction due to a short circuit or the like can be reduced. Furthermore, since the second drive voltage (+ 24V) supplied to the image input apparatus 200 is independently controlled by the image input apparatus 200 itself, the load on the image forming apparatus 300 is reduced and the entire image forming system is consumed. Electric power can be greatly reduced.

  The present invention is not limited to the above-described embodiments, and various modifications can be made. For example, the present invention includes configurations that are substantially the same as the configurations described in the embodiments (for example, configurations that have the same functions, methods, and results, or configurations that have the same purposes and results). In addition, the invention includes a configuration in which a non-essential part of the configuration described in the embodiment is replaced. In addition, the present invention includes a configuration that exhibits the same operational effects as the configuration described in the embodiment or a configuration that can achieve the same object. Further, the invention includes a configuration in which a known technique is added to the configuration described in the embodiment.

1 is a block diagram showing an embodiment of an image forming system of the present invention. 1 is a diagram illustrating a part of a circuit configuration of an image forming system according to an embodiment of the present invention. 6 is a flowchart illustrating an example of an operation of the image forming system according to the embodiment of the present invention. 6 is a flowchart illustrating an example of an operation of the image forming system according to the embodiment of the present invention.

Explanation of symbols

DESCRIPTION OF SYMBOLS 200 ... Image input device 210 ... 2nd control part 212 ... Connector 214 ... 2nd voltage supply control part 220 ... Image input part 300 ... Image forming apparatus 310 ... Power supply part 320 ... 1st control part 322 ... 1st Voltage supply control unit 330 ... relay unit 340 ... engine unit 400 ... cable

Claims (6)

A first device having a power supply unit for generating a drive voltage and an image forming unit;
A second device for controlling the image forming unit;
Including
The power supply unit generates a first drive voltage and a second drive voltage higher than the first drive voltage as the drive voltage,
The second apparatus is an image forming system including a voltage supply control unit that controls whether or not the second drive voltage is supplied to the second apparatus. The image forming system according to claim 1.
The image forming system further includes a voltage supply control unit that controls whether the second driving voltage is supplied to the image forming unit. The image forming system according to claim 1 or 2,
Supplying the second drive voltage to the second device is an image forming system performed after the second drive voltage is supplied to the image forming unit. The image forming system according to any one of claims 1 to 3,
The image forming system in which the second drive voltage is supplied to the second device after the first drive voltage is supplied to the second device. The image forming system according to any one of claims 1 to 4,
The image forming system in which the supply of the second drive voltage to the second device is performed after confirming the operating state of the second device. The image forming system according to any one of claims 1 to 5,
The second apparatus is an image forming system further including an image input unit.

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