JP7339595B2 - processing equipment - Google Patents

Description

The present invention relates to a processing device including an image processing device such as a printer.

Conventionally, the power supply device provided in the processing device includes an AC-DC converter that converts the AC voltage supplied from the commercial power supply to a DC voltage, and the DC voltage output by the AC-DC converter that further converts to a predetermined DC voltage. and a plurality of DC-DC converters. For example, in the power supply device described in Patent Document 1, an AC-DC converter generates a DC voltage to be supplied to a load such as a motor driver from an AC voltage, and the DC-DC converter converts the DC voltage to 3.3 V or higher. It is converted to a DC voltage of 1.5V.

On the other hand, devices equipped with an interface for connecting to external devices have not only the conventional USB (Universal Serial Bus) 2.0 and USB 3.1 standards, but also the USB-PD (Universal Serial Bus - Power Delivery) standard. There is something that satisfies In this device, it is necessary to supply various powers ranging from 5 mW to 100 W according to the power supply requirements of the power supply destination connected to the device.

JP 2013-34365 A

In order to meet this need, a configuration is conceivable in which a DC-DC converter dedicated to USB power supply is newly provided in the power supply device, and power is supplied to the power supply destination from the DC-DC converter dedicated to USB power supply. However, the DC-DC converter dedicated to USB power supply consumes a large amount of power, and if the DC-DC converter dedicated to USB power supply is frequently driven, the power consumption increases.

SUMMARY OF THE INVENTION An object of the present invention is to provide a processing apparatus capable of suppressing an increase in power consumption due to power supply to an external device.

In order to achieve the above object, a processing apparatus according to the present invention provides an external device connector which can be connected to an external device and has a power supply terminal for supplying power to the external device and a communication terminal for communicating with the external device. , a control unit that detects the connection between an external device and an external device connector and receives a power supply request from the external device via a communication terminal, and a fixed output voltage DC-DC that converts DC voltage and outputs a fixed voltage. The power supply terminal is the output terminal of the converter, the output voltage variable DC-DC converter that converts the DC voltage into a variable voltage set based on the instruction from the control unit and outputs the variable voltage, and the output voltage fixed DC-DC converter. and a second switching state in which the output terminal of the variable output voltage DC-DC converter is connected to the power supply terminal, wherein the control section is configured to externally When the connection between the device and the external device connector is detected, the changeover switch section is controlled to switch to the first switching state, the output voltage fixed DC-DC converter is controlled to output a fixed voltage, and the output voltage fixed DC-DC converter is controlled to output a fixed voltage. When a power supply request is received, if the voltage of the power supply request is equal to the fixed voltage, the output voltage fixed DC-DC converter is controlled to output the voltage of the power supply request, and when a power supply request from an external device is received, power is supplied When the requested voltage is not equal to the fixed voltage, the changeover switch unit is controlled to switch from the first switching state to the second switching state, and the output voltage variable DC-DC is controlled to output the voltage of the power supply request. .

According to this configuration, when detecting connection between the external device and the external device connector, the control unit causes the fixed output voltage DC-DC converter to output the fixed voltage to the power supply terminal. At this time, the control unit stops the output voltage variable DC-DC converter. After that, when receiving a power supply request from an external device, if the voltage value of the power supply request is equal to the fixed voltage, the control unit causes the output voltage fixed DC-DC converter to output the fixed voltage to the power supply terminal. On the other hand, when the voltage value of the power supply request is not equal to the fixed voltage, the control unit causes the output voltage variable DC-DC converter to output a voltage corresponding to the power supply request to the power supply terminal. As a result, the variable output voltage DC-DC converter does not operate wastefully, and an increase in power consumption due to frequent driving of the variable output voltage DC-DC converter can be suppressed.

According to the present invention, it is possible to suppress an increase in power consumption due to power supply to an external device.

It is a figure which shows the electrical structure of the processing apparatus which concerns on one Embodiment of this invention. 4 is a flowchart showing a main flow of first power supply control; FIG. 11 is a flowchart (part 1) showing the flow of a first request response process; FIG. FIG. 12 is a flowchart (part 2) showing the flow of the first request response process; FIG. It is a figure which shows the electrical structure of the processing apparatus which concerns on other embodiment of this invention. It is a flowchart which shows the main flow of 2nd electric power feeding control. FIG. 11 is a flowchart (part 1) showing the flow of second request response processing; FIG. FIG. 11 is a flowchart (part 2) showing the flow of second request response processing; FIG.

BEST MODE FOR CARRYING OUT THE INVENTION Below, embodiments of the present invention will be described in detail with reference to the accompanying drawings.

<Configuration of processing device>
A processing device 1 shown in FIG. 1 is a device that operates on alternating current power supplied from an external commercial power supply via a power cord 2 . The processing device 1 includes a plurality of motors M and a motor driver 11 that controls power supply to each motor M. FIG. The processing device 1 is, for example, an MFP (Multi-Function Peripheral), and a plurality of motors M serve as a reading unit for reading an original, a conveying unit for conveying paper, and an image forming unit for forming an image on the conveyed paper. drive each.

The processing device 1 includes a CPU (Central Processing Unit) 12 , a RAM 13 (Random Access Memory), a ROM (Read Only Memory) 14 and various logic circuits 15 and 16 . The RAM 13 is a volatile memory such as a DRAM (Dynamic Random Access Memory), and is used as a work area when the CPU 12 executes programs. The ROM 14 is a rewritable non-volatile memory such as flash memory. The ROM 14 stores programs executed by the CPU 12 and various data. The logic circuits 15 and 16 are electronic circuits that perform logic operations.

The processing device 1 also includes an AC-DC converter 21, a variable output voltage DC-DC converter 22, a fixed output voltage DC-DC converter 23, and DC-DC converters 24, 25, and 26 for logic. In the processing device 1, an AC voltage supplied from an external commercial power source is converted into a DC voltage by an AC-DC converter 21, and the DC voltage is supplied to a variable output voltage DC-DC converter 22 and a fixed output voltage DC-DC converter 22 as necessary. The voltage is stepped down by the DC converter 23 and the logic DC-DC converters 24, 25 and 26 and supplied to each part.

The AC-DC converter 21 includes a rectifying/smoothing circuit and the like. An AC voltage supplied from an external commercial power source through the power cord 2 is input to the input terminal 31 of the AC-DC converter 21 . AC-DC converter 21 converts an AC voltage input to input terminal 31 into a constant DC voltage (for example, 24 V DC) and outputs the converted DC voltage from output terminal 32 . A DC voltage output from an output terminal 32 of an AC-DC converter 21 is supplied to the motor driver 11 .

The variable output voltage DC-DC converter 22 includes a linear regulator and the like. A wiring 34 is connected to an input terminal 33 of the output voltage variable DC-DC converter 22 , and the DC voltage output from the output terminal 32 of the AC-DC converter 21 is input via the wiring 34 . The output voltage variable DC-DC converter 22 converts the DC voltage input to the input terminal 33 into any one of DC 9V, DC 15V and DC 20V according to instructions from the CPU 12, and outputs the converted DC voltage. Output from terminal 35 .

The fixed output voltage DC-DC converter 23 includes a linear regulator and the like. A wiring 37 is connected to an input terminal 36 of the fixed output voltage DC-DC converter 23 , and the DC voltage output from the output terminal 32 of the AC-DC converter 21 is input via the wiring 37 . The fixed output voltage DC-DC converter 23 converts the DC voltage input to the input terminal 36 into a constant DC voltage (5V DC) and outputs the converted DC voltage from the output terminal 38 .

The logic DC-DC converter 24 includes a linear regulator and the like. A line 42 is connected to the input terminal 41 of the DC-DC converter 24 for logic, and the DC voltage output from the output terminal 38 of the fixed output voltage DC-DC converter 23 is input through the line 42 . The logic DC-DC converter 24 converts the DC voltage input to the input terminal 41 into a constant DC voltage, and outputs the converted DC voltage from the output terminal 43 . The DC voltage output from the output terminal 43 is, for example, 3.3V DC, and is supplied to the logic circuit 15 or the like that operates at the voltage of 3.3V DC.

The logic DC-DC converter 25 includes a linear regulator and the like. A wiring 45 is connected to an input terminal 44 of the DC-DC converter 25 for logic, and the DC voltage output from the output terminal 38 of the fixed output voltage DC-DC converter 23 is input via the wiring 45 . The logic DC-DC converter 25 converts the DC voltage input to the input terminal 44 into a constant DC voltage and outputs the converted DC voltage from the output terminal 46 . The DC voltage output from the output terminal 46 is, for example, DC 1.5V and is supplied to the RAM 13 or the like that operates at DC 1.5V.

The logic DC-DC converter 26 includes a linear regulator and the like. A wiring 48 is connected to an input terminal 47 of the DC-DC converter 26 for logic, and the DC voltage output from the output terminal 38 of the fixed output voltage DC-DC converter 23 is input via the wiring 48 . The logic DC-DC converter 25 converts the DC voltage input to the input terminal 47 into a constant DC voltage and outputs the converted DC voltage from the output terminal 49 . The DC voltage output from the output terminal 49 is, for example, DC 1.0V, and is supplied to the CPU 12 or the like that operates at DC 1.0V.

The processing device 1 also includes a USB interface 50 for USB connection with an external device. The USB interface 50 is provided with a USB connector 51 (an example of an external device connector) and a USB controller 52 (an example of a control section). The USB connector 51 and USB controller 52 comply with the USB 3.1 standard and the USB-PD standard.

The USB connector 51 is a Type-C connector receptacle (female side), and a receiving port for receiving a Type-C connector plug (male side) is arranged so as to be exposed to the outside from the housing of the processing apparatus 1. . The USB connector 51 has CC1 terminal, CC2 terminal, Dp (D+) 1 terminal, Dp2 terminal, Dn (D-) 1 terminal, Dn2 terminal, TX1 terminal pair (TXp1 terminal and TXn1 terminal), TX2 terminal pair (TXp2 terminal and TXn2 terminal), RX1 terminal pair (RXp1 terminal and RXn1 terminal), RX2 terminal pair (RXp2 terminal and RXn2 terminal), GND terminal, VBUS terminal, and SBU1 terminal and SBU2 terminal (not shown). It is configured so that the plug can be received in two directions, up and down.

The USB controller 52 includes a power setting communication/power supply control unit 53 , a cable plug power supply unit 54 , a power supply capability presentation unit 55 , a USB communication control unit 56 and a multiplexer (MUX) 57 .

The power setting communication/power supply control unit 53 has a function of detecting the connection (cable connection) when a plug provided at one end of the USB cable is connected to the USB connector 51 . The other end of the USB cable is connected to an external device. When the power setting communication/power supply control unit 53 detects the cable connection, the power setting communication/power supply control unit 53 configures the USB connection with the external device via the CC1 terminal and the CC2 terminal. .

Depending on the configuration of the USB connection, the power setting communication/power supply control unit 53 determines whether the VBUS terminal operates as a source of USB power supply, the direction of the plug (male side) of the accepted Type-C connector, and data communication by USB. determine the direction of In addition, when the VBUS terminal operates as a USB power supply source, the power setting communication/power supply control unit 53 controls the variable current sources 63 and 64 and the switches 65 and 66 provided in the power supply capability presentation unit 55. , to notify the external device of the initial power supply capability from VBUS.

The power setting communication/power supply control unit 53 selects an appropriate one of the CC1 terminal and CC2 terminal as the configuration communication (CC communication) terminal based on the detected Type-C connector plug direction. decide. In CC communication, in accordance with the USB-PD standard, communication for controlling the power supply of the VBUS terminal and executing an alternate mode for exchanging data other than the USB standard using a USB cable is performed by an external device. between In addition, the switches 61 and 62 provided in the cable plug power supply unit 54 are controlled, and the terminals not assigned for CC communication are transferred to the EMCA (Electrical Marked Cable Assembly) built into the USB cable for the cable plug power (VCONN). ) is supplied.

A multiplexer 57 is connected to the USB communication control unit 56, and the USB communication control unit 56 controls the multiplexer 57 and Data communication is performed with an external device via the TX1 terminal pair, the TX2 terminal pair, the RX1 terminal pair, or the RX2 terminal pair.

The USB-PD standard stipulates a power rule. According to this power rule, voltages of DC5V, DC9V, DC15V, and DC20V can be supplied to external devices according to the power that can be supplied by the device, and DC5V, DC9V, and DC15V. The maximum current at 20V DC is specified at 3A and the maximum current at 20V DC is specified at 5A. The USB-PD standard also stipulates that an external device can request any voltage from DC 3.3V to 21V other than the voltage specified in the power rule. Then, when the power setting communication/power supply control unit 53 determines that the power supply request based on the combination of the voltage value and the current value can be supplied, it notifies the external device of the power supply availability by CC communication.

A variable output voltage DC-DC converter 22 and a fixed output voltage DC-DC converter 23 are connected to the VBUS terminal of the USB connector 51 via a selector switch section 71 . The switch section 71 includes a first switching element 72 , a first backflow prevention element 73 , a second switching element 74 and a second backflow prevention element 75 .

The first switching element 72, the first backflow prevention element 73, the second switching element 74, and the second backflow prevention element 75 are all N-channel MOSFETs (NMOS).

The first switching element 72 and the first backflow prevention element 73 are connected in reverse series (back-to-back). That is, the source of the first switching element 72 and the source of the first backflow prevention element 73 are connected. The drain of the first switching element 72 is connected to the output terminal 38 of the fixed output voltage DC-DC converter 23 via the wiring 76 . A drain of the first backflow prevention element 73 is connected to the VBUS terminal of the USB connector 51 via a wiring 77 .

Also, the second switching element 74 and the second backflow prevention element 75 are connected in anti-series. That is, the source of the second switching element 74 and the source of the second backflow prevention element 75 are connected. A drain of the second switching element 74 is connected to the output terminal 35 of the variable output voltage DC-DC converter 22 via a wiring 78 . The drain of the second backflow prevention element 75 is connected to the VBUS terminal of the USB connector 51 via the wiring 79 .

The power setting communication/power supply control unit 53 of the USB controller 52 (hereinafter simply referred to as the “USB controller 52”) controls power supply to the external device connected to the USB connector 51, so that the first switching element 72, It controls switching between conduction (ON) and non-conduction (OFF) of the first backflow prevention element 73, the second switching element 74, and the second backflow prevention element 75. FIG.

By controlling the switching by the USB controller 52, the output terminal 38 of the fixed output voltage DC-DC converter 23 is connected to the VBUS terminal of the USB connector 51, and the DC voltage output from the output terminal 38 can be supplied to the VBUS terminal. 1 switching state and a second switching state in which the output terminal 35 of the output voltage variable DC-DC converter 22 is connected to the VBUS terminal of the USB connector 51 and the DC voltage output from the output terminal 35 can be supplied to the VBUS terminal. can be switched.

That is, the USB controller 52 turns on the first switching element 72 and the first backflow prevention element 73 to enable conduction between the wirings 76 and 77, so that the output terminal 38 of the fixed output voltage DC-DC converter 23 A first switching state is entered in which the output DC voltage can be supplied to the VBUS terminal of the USB connector 51 . In the first switching state, the second switching element 74 and the second backflow prevention element 75 are turned off.

On the other hand, the USB controller 52 turns on the second switching element 74 and the second backflow prevention element 75 to enable conduction between the wirings 78 and 79, so that the output terminal 35 of the variable output voltage DC-DC converter 22 A second switching state is entered in which the output DC voltage can be supplied to the VBUS terminal of the USB connector 51 . In the second switching state, the first switching element 72 and the first backflow prevention element are turned off.

<First power supply control>
In order to supply power to the external device connected to the USB connector 51, the main flow of the first power supply control shown in FIG. 2 is executed by the USB controller 52 (power setting communication/power supply control unit 53).

In the initial state before an external device is connected to the USB connector 51 , the USB controller 52 stops the output voltage variable DC-DC converter 22 (S11). Also, the USB controller 52 turns off both the first switching element 72 and the second switching element 74 (S12).

While the USB cable is not connected to the USB connector 51, the USB controller 52 determines whether the USB cable is connected to the USB connector 51 (S13). When the USB controller 52 detects that the USB cable is connected to the USB connector 51 (S13: YES), it turns on the first switching element 72 (S14). The second switching element 74 is left off.

Then, the USB controller 52 starts configuring the external device and power supply. First, the USB controller 52 transmits a power supply capability signal (Source Capabilities) indicating the power supply capability to the external device (S15). Next, the USB controller 52 determines whether or not a request signal (Request) indicating a request for power supply has been received from the external device in response to the transmission of the power supply capability signal. When the USB controller 52 receives the request signal (S16: YES), it executes the first request response process (S17). By executing the first request response process, power is supplied from the variable output voltage DC-DC converter 22 or the fixed output voltage DC-DC converter 23 to the external device via the VBUS terminal of the USB connector 51 . Details of the first request response process will be described later.

When the USB cable is disconnected from the USB connector 51, the USB controller 52 detects the cable disconnection. When detecting the disconnection of the cable (S18: YES), the USB controller 52 turns off both the first switching element 72 and the second switching element 74 (S19). Then, when the output voltage variable DC-DC converter 22 is operating, the USB controller 52 stops the output voltage variable DC-DC converter 22 (S20), and determines whether the USB cable is connected to the USB connector 51. Whether or not is determined again (S13).

<First request response process>
The flow of the first request response process executed in step S17 of FIG. 2 is shown in FIGS. 3A and 3B.

In the first request response process, the USB controller 52 determines whether or not the power supply request from the external device is equal to or less than the power supply capacity, that is, whether or not power can be supplied in response to the power supply request from the external device. (S1701 in FIG. 3A). If the power supply request exceeds the power supply capacity, the USB controller 52 determines that the power supply request is not equal to or below the power supply capacity (S1701: NO), and outputs a rejection signal (Reject) indicating that the power cannot be supplied. The data is sent to the external device (S1702), and the first request response process ends. Upon completion of the first request response process, the USB controller 52 returns to the main flow of power supply control shown in FIG. 2 to determine whether or not disconnection of the USB cable from the USB connector 51 has been detected (see S18).

When the USB controller 52 determines that the power supply request is equal to or less than the power supply capacity (S1701: YES), the USB controller 52 transmits a permission signal (Accept) indicating that power can be supplied to the external device (S1703). After that, the USB controller 52 determines whether or not the voltage related to the power supply request from the external device (this voltage is hereinafter referred to as the “requested voltage”) is DC5V (S1704).

When the USB controller 52 determines that the required voltage from the external device is DC5V (S1704: YES), it turns on the first switching element 72 and turns off the second switching element 74 (S1705). Also, when the output voltage variable DC-DC converter 22 is operating, the USB controller 52 stops the output voltage variable DC-DC converter 22 (S1706). After that, the USB controller 52 checks whether the voltage of the VBUS terminal of the USB connector 51 matches the voltage requested by the external device (S1707 in FIG. 3B). Then, when the USB controller 52 confirms that the voltage of the VBUS terminal matches the voltage requested by the external device (S1707: YES), the USB controller 52 outputs a power supply preparation signal (PS_RDY) indicating that power supply preparation is completed. The data is transmitted to the external device (S1708), and the first request response process ends. When the external device that has received the power supply preparation signal becomes ready to receive power, the fixed output voltage DC-DC converter 23 starts supplying power to the external device through the VBUS terminal in accordance with the power supply request.

On the other hand, when the USB controller 52 determines that the required voltage from the external device is not DC 5V (S1704 in FIG. 3A: NO), the output terminal 38 of the fixed output voltage DC-DC converter 23 is currently connected to the USB connector 51. It is determined whether or not it is in the first switching state in which it is connected to the VBUS terminal (S1709). When determining that the USB controller 52 is in the first switching state (S1709: YES), the USB controller 52 turns on both the first switching element 72 and the second switching element 74 (S1710). The USB controller 52 then sets the output voltage of the variable output voltage DC-DC converter 22 to the voltage requested by the external device (S1711). Since both the first switching element 72 and the second switching element 74 are turned on, the output voltage of the variable output voltage DC-DC converter 22 and the output voltage of the fixed output voltage DC-DC converter 23 are connected to the VBUS terminal. The higher output voltage is supplied.

After that, the USB controller 52 determines whether or not the output voltage of the variable output voltage DC-DC converter 22 exceeds the output voltage of the fixed output voltage DC-DC converter 23 (S1712). When the USB controller 52 determines that the output voltage of the variable output voltage DC-DC converter 22 has exceeded the output voltage of the fixed output voltage DC-DC converter 23 (S1712: YES), the USB controller 52 turns off the first switching element 72, and turns off the second switching element 72. The switching element 74 is turned on (S1713). Then, when the USB controller 52 confirms that the voltage of the VBUS terminal matches the voltage requested by the external device (S1707: YES), the USB controller 52 outputs a power supply preparation signal (PS_RDY) indicating that power supply preparation is completed. The data is transmitted to the external device (S1708), and the first request response process ends.

When the USB controller 52 determines that the required voltage from the external device is not DC5V (S1704 in FIG. 3A: NO) and determines that it is not in the first switching state (S1709: NO), the output voltage variable The output voltage of the DC-DC converter 22 is changed to the voltage requested by the external device (S1714). After that, the USB controller 52 checks whether the voltage of the VBUS terminal matches the voltage requested by the external device (S1707 in FIG. 3B). Then, when the USB controller 52 confirms that the voltage of the VBUS terminal matches the voltage requested by the external device (S1707: YES), the USB controller 52 outputs a power supply preparation signal (PS_RDY) indicating that power supply preparation is completed. The data is transmitted to the external device (S1708), and the first request response process ends.

<Effect>
As described above, the USB controller 52 causes the output voltage fixed DC-DC converter 23 to output a fixed voltage to the VBUS terminal of the USB connector 51 when detecting the connection between the external device and the USB connector 51 . At this time, the USB controller 52 stops the output voltage variable DC-DC converter 22 . After that, when the USB controller 52 receives a power supply request from an external device and the requested voltage is equal to the fixed voltage, the USB controller 52 causes the output voltage fixed DC-DC converter 23 to output the fixed voltage to the VBUS terminal. On the other hand, when the requested voltage is not equal to the fixed voltage, the USB controller 52 causes the output voltage variable DC-DC converter 22 to output the requested voltage to the VBUS terminal. As a result, the variable output voltage DC-DC converter 22 does not operate wastefully, and an increase in power consumption due to frequent driving of the variable output voltage DC-DC converter 22 can be suppressed. As a result, it is possible to suppress an increase in power consumption due to power feeding to the external device.

Further, when receiving a power supply request from an external device, in the first switching state in which the output terminal 38 of the fixed output voltage DC-DC converter is connected to the VBUS terminal of the USB connector 51, the requested voltage is higher than the fixed voltage. In this case, the output voltage of the output voltage variable DC-DC converter 22 is set to the required voltage. After the output voltage of the output voltage variable DC-DC converter 22 exceeds the output voltage of the output voltage fixed DC-DC converter 23, the output voltage variable DC-DC converter 22 is switched from the first switching state by the changeover switch unit 71. The terminal 35 is switched to the second switching state in which it is connected to the VBUS terminal. Therefore, power corresponding to the required voltage can be stably supplied from the output voltage variable DC-DC converter 22 to the external device via the VBUS terminal.

On the other hand, when a power supply request is received from an external device, in the second switching state in which the output terminal 35 of the output voltage variable DC-DC converter 22 is connected to the VBUS terminal, if the requested voltage is higher than the fixed voltage, the output The output voltage of the voltage variable DC-DC converter 22 is changed to the required voltage. As a result, without switching between the first switching state and the second switching state, it is possible to stably supply electric power according to the required voltage from the output voltage variable DC-DC converter 22 to the external device via the VBUS terminal. .

Further, when a power supply request is received from an external device, in the second switching state in which the output terminal 35 of the output voltage variable DC-DC converter 22 is connected to the VBUS terminal, if the requested voltage is equal to the fixed voltage, , is first switched from the second switching state. As a result, a fixed voltage equal to the required voltage can be supplied from the fixed output voltage DC-DC converter 23 to the external device via the VBUS terminal.

Before the external device is connected to the USB connector 51, it is an initial state in which neither the fixed output voltage DC-DC converter 23 nor the variable output voltage DC-DC converter 22 is connected to the VBUS terminal of the USB connector 51. In this initial state, , the output voltage variable DC-DC converter 22 is stopped. As a result, it is possible to prevent the variable output voltage DC-DC converter 22 from being driven unnecessarily, thereby suppressing an increase in power consumption due to the unnecessary driving.

When the external device and the USB connector 51 are connected, the switching unit 71 switches from the initial state to the first switching state. Therefore, even if there is no voltage switching request from the external device, the fixed voltage can be immediately supplied to the external device.

<Other embodiments>
In the configuration shown in FIG. 1, the output voltage variable DC-DC converter 22 converts the DC voltage input to the input terminal 33 to any one of DC 9V, DC 15V and DC 20V, and converts the DC voltage is output from the output terminal 35. Not limited to this configuration, as shown in FIG. 4, the output voltage variable DC-DC converter 22 follows the instruction from the CPU 12 to set the DC voltage input to the input terminal 33 within the range of DC 3.3 to 21V. A configuration in which the DC voltage is converted into a DC voltage and the converted DC voltage is output from the output terminal 35 may be employed.

In FIG. 4, parts corresponding to the parts shown in FIG. 1 are denoted by the same reference numerals as those parts. In addition, in the "Modes for Carrying Out the Invention", the description of the configuration of the portions to which the same reference numerals are attached is omitted.

<Second power supply control>
In the processing device 1 having the configuration shown in FIG. 4, in order to supply power to the external device connected to the USB connector 51, the USB controller 52 (power setting communication/power supply control unit 53) controls the second power supply shown in FIG. 2 The main flow of power supply control is executed.

In FIG. 5, steps corresponding to the steps shown in FIG. 2 are given the same step numbers as those steps. In the following, the second power supply control, the main flow of which is shown in FIG. 5, will be described by taking up only differences from the second power supply control, the main flow of which is shown in FIG.

In the second power supply control, the USB controller 52 transmits a power supply capability signal indicating power supply capability to the external device (S15), and then receives a power supply request signal (Request) from the external device (S16). : YES), the second request response process is executed (S31).

<Second request response processing>
The flow of the second request response process executed in step S31 of FIG. 5 is shown in FIGS. 6A and 6B.

In the second request response process, the USB controller 52 determines whether or not the power supply request from the external device is equal to or less than the power supply capacity, that is, whether or not power can be supplied in response to the power supply request from the external device. (S3101 in FIG. 6A). When the power supply request exceeds the power supply capacity, the USB controller 52 determines that the power supply request is not equal to or below the power supply capacity (S3101: NO), and outputs a rejection signal (Reject) indicating that the power cannot be supplied. The data is transmitted to the external device (S3102), and the second request response process ends. Upon completion of the second request response process, the USB controller 52 returns to the main flow of power supply control shown in FIG. 5 to determine whether or not disconnection of the USB cable from the USB connector 51 has been detected ( S18).

When the USB controller 52 determines that the power supply request is equal to or less than the power supply capacity (S3101: YES), the USB controller 52 transmits a permission signal (Accept) indicating that power can be supplied to the external device (S3103). After that, the USB controller 52 determines whether or not the voltage related to the power supply request from the external device (hereinafter referred to as "requested voltage") is DC 5V (S3104).

When the USB controller 52 determines that the required voltage from the external device is 5V DC (S3104: YES), it turns on the first switching element 72 and turns off the second switching element 74 (S3105). Also, when the output voltage variable DC-DC converter 22 is operating, the USB controller 52 stops the output voltage variable DC-DC converter 22 (S3106). After that, the USB controller 52 checks whether the voltage of the VBUS terminal of the USB connector 51 matches the voltage requested by the external device (S3107 in FIG. 6B). Then, when the USB controller 52 confirms that the voltage of the VBUS terminal matches the voltage requested by the external device (S3107: YES), the USB controller 52 outputs a power supply preparation signal (PS_RDY) indicating that power supply preparation is completed. The data is transmitted to the external device (S3108), and the second request response process ends. When the external device that has received the power supply preparation signal becomes ready to receive power, the fixed output voltage DC-DC converter 23 starts supplying power to the external device through the VBUS terminal in accordance with the power supply request.

On the other hand, when the USB controller 52 determines that the required voltage from the external device is not DC 5V (S3104 in FIG. 6A: NO), the output terminal 38 of the fixed output voltage DC-DC converter 23 is currently connected to the USB connector 51. It is determined whether or not it is in the first switching state in which it is connected to the VBUS terminal (S3109). When determining that the USB controller 52 is in the first switching state (S3109: YES), the USB controller 52 determines whether or not the voltage requested by the external device is higher than DC 5V (S3110).

When the USB controller 52 determines that the required voltage is higher than DC5V (S3110: YES), it turns on both the first switching element 72 and the second switching element 74 (S3111). The USB controller 52 then sets the output voltage of the variable output voltage DC-DC converter 22 to the voltage requested by the external device (S3112). Since both the first switching element 72 and the second switching element 74 are turned on, the output voltage of the variable output voltage DC-DC converter 22 and the output voltage of the fixed output voltage DC-DC converter 23 are connected to the VBUS terminal. The higher output voltage is supplied.

After that, the USB controller 52 determines whether or not the output voltage of the variable output voltage DC-DC converter 22 exceeds the output voltage of the fixed output voltage DC-DC converter 23 (S3113 in FIG. 6B). When the USB controller 52 determines that the output voltage of the variable output voltage DC-DC converter 22 has exceeded the output voltage of the fixed output voltage DC-DC converter 23 (S3113: YES), the USB controller 52 turns off the first switching element 72, and turns off the second switching element 72. The switching element 74 is turned on (S3114). Then, when the USB controller 52 confirms that the voltage of the VBUS terminal matches the voltage requested by the external device (S3107: YES), the USB controller 52 outputs a power supply preparation signal (PS_RDY) indicating that power supply preparation is completed. The data is transmitted to the external device (S3108), and the second request response process ends.

When the USB controller 52 determines that the required voltage is not greater than DC5V, that is, the required voltage is less than DC5V (S3110 in FIG. 6A: NO), the output voltage of the output voltage variable DC-DC converter 22 is set externally. Set to the required voltage from the device (S3115). After that, the USB controller 52 confirms that the output voltage of the output voltage variable DC-DC converter 22 has reached the required voltage (S3116 in FIG. 6B: YES), turns off the first switching element 72, and turns off the second switching element. 74 is turned on (S3117). Then, a power supply preparation signal (PS_RDY) indicating completion of power supply preparation is transmitted to the external device (S3108), and the second request response process ends.

Further, when the USB controller 52 determines that the requested voltage from the external device is not 5 VDC (S3104 in FIG. 6A: NO) and determines that it is not in the first switching state (S3109: NO), the output The output voltage of the voltage variable DC-DC converter 22 is changed to the required voltage from the external device (S3118). After that, the USB controller 52 checks whether the voltage of the VBUS terminal matches the voltage requested by the external device (S3107 in FIG. 6B). Then, when the USB controller 52 confirms that the voltage of the VBUS terminal matches the voltage requested by the external device (S3107: YES), the USB controller 52 outputs a power supply preparation signal (PS_RDY) indicating that power supply preparation is completed. The data is transmitted to the external device (S3108), and the second request response process ends.

<Effect>
The configuration according to this embodiment can also achieve the same effects as the configuration according to the above-described embodiment.

<Modification>
Although two embodiments of the present invention have been described above, the present invention can also be implemented in other forms.

For example, in each of the above-described embodiments, the first power supply control (including the first request response process) and the second power supply control (including the second request response process) are performed by the USB controller 52. The first power supply control and the second power supply control may be executed by the CPU 12 as an example of the control unit. Also, the CPU 12 and the USB controller 52 may cooperate to execute the first power supply control and the second power supply control. In this case, both the CPU 12 and the USB controller 52 are examples of control units. For example, the output voltage variable DC-DC converter 22 may be controlled by the CPU 12, and the USB controller 52 may control other units. .

Also, each of the above-described embodiments does not necessarily conform to the USB standard, and may be implemented in a device that supplies DC power to an external device.

In addition, various design changes can be made to the above configuration within the scope of the matters described in the claims.

1: processing device 12: CPU
22: Output voltage variable DC-DC converter 23: Output voltage fixed DC-DC converter 35, 38: Output terminal 50: USB interface 51: USB connector 52: USB controller 71: Switch unit 72: First switching element 73: Second 1 backflow prevention element 74: second switching element 75: second backflow prevention element

Claims (7)

an external device connector connectable to an external device and having a power supply terminal for supplying power to the external device and a communication terminal for communicating with the external device;
a control unit that detects connection between the external device and the external device connector and receives a power supply request from the external device via the communication terminal;
a fixed output voltage DC-DC converter that converts a DC voltage and outputs a fixed voltage;
an output voltage variable DC-DC converter that converts the DC voltage into a variable voltage set based on an instruction from the control unit and outputs the variable voltage;
A first switching state in which the output terminal of the fixed output voltage DC-DC converter is connected to the power supply terminal, and a second switching state in which the output terminal of the variable output voltage DC-DC converter is connected to the power supply terminal. a switch section for switching,
with
The control unit
Controlling the output voltage variable DC-DC converter and the changeover switch unit to perform power supply control,
In the power supply control,
stopping the output voltage variable DC-DC converter without detecting connection between the external device and the external device connector;
when the connection between the external device and the external device connector is detected, controlling the changeover switch unit to set the first switching state ;
When the voltage of the power supply request is equal to the fixed voltage when the power supply request is received from the external device, the output voltage fixed DC-DC converter outputs the fixed voltage to the power supply terminal. controlling the changeover switch unit to set the first switching state, and stopping the output voltage variable DC-DC converter when the output voltage variable DC-DC converter is operating;
When the power supply request from the external device is received and the voltage of the power supply request is not equal to the fixed voltage, the output voltage variable DC-DC converter is controlled so that the output voltage variable DC-DC converter is supplied to the The changeover switch unit is controlled so that the voltage of the power supply request is output, and the voltage of the power supply request is output from the output voltage variable DC-DC converter to the power supply terminal, and the switching state is changed from the first switching state to the second switching state. 2 switch to the switching state ,
A processing device characterized by: The processing apparatus according to claim 1,
The control unit
When receiving the power supply request from the external device , if the voltage of the power supply request does not match the fixed voltage, and if the first switching state, the output of the output voltage variable DC-DC converter After the output voltage of the variable output voltage DC-DC converter exceeds the output voltage of the fixed output voltage DC-DC converter, the selector switch unit is controlled to switching from one switching state to the second switching state;
A processing device characterized by: The processing apparatus according to claim 1 or 2,
The control unit
When receiving the power supply request from the external device , if the voltage of the power supply request does not match the fixed voltage and the second switching state is reached, the output is maintained in the second switching state. causing the voltage variable DC-DC converter to output the voltage of the power supply request;
A processing device characterized by: The processing apparatus according to claim 1,
The variable output voltage DC-DC converter is capable of outputting a voltage ranging from a first voltage value lower than the fixed voltage to a second voltage value higher than the fixed voltage,
The control unit
When the power supply request from the external device is received and the voltage of the power supply request does not match the fixed voltage , in the first switching state, the voltage of the power supply request is lower than the fixed voltage. If it is smaller, after setting the output voltage of the variable output voltage DC-DC converter to the voltage of the power supply request, controlling the switch unit to switch from the first switching state to the second switching state;
A processing device characterized by: The processing apparatus according to any one of claims 1 to 4 ,
Before the connection between the external device and the external device connector is an initial state in which neither the output voltage fixed DC-DC converter nor the output voltage variable DC-DC converter is connected to the power supply terminal,
When the control unit detects connection between the external device and the external device connector, the control unit controls the changeover switch unit to switch from the initial state to the first switching state.
A processing device characterized by: The processing apparatus according to any one of claims 1 to 5 ,
The changeover switch section
a first switching element arranged after the fixed output voltage DC-DC converter for switching between conduction and non-conduction;
a first backflow prevention element disposed between the first switching element and the power supply terminal to prevent current from flowing from the power supply terminal to the first switching element;
a second switching element arranged after the variable output voltage DC-DC converter for switching between conduction and non-conduction;
a second backflow prevention element disposed between the second switching element and the power supply terminal to prevent current from flowing from the power supply terminal to the second switching element;
with
The control unit
By energizing the first switching element and the second switching element, the higher output voltage of the fixed output voltage DC-DC converter and the variable output voltage DC-DC converter is output to the power supply terminal. is switchable to a third switching state in which
A processing device characterized by: A processing apparatus according to any one of claims 1 to 6 ,
The external device connector is provided on a USB interface,
The USB interface is provided with a controller for controlling power supply to the external device connected to the external device connector,
The control unit is the controller,
A processing device characterized by:

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