JP2021141733A - Control device, information processing device and program - Google Patents

Abstract

To appropriately distribute power to the multiple terminal devices to charge them.SOLUTION: A control device for controlling the power supply to multiple terminal devices includes: a charge control unit that supplies power to each of the multiple terminal devices via a cable according to a power profile indicating a combination of voltage and current; a remaining amount acquisition unit that acquires the remaining amount of the battery and the maximum power consumption according to the remaining amount, for each of the multiple terminal devices connected to the charge control unit; a priority terminal determination unit that determines one or more priority devices, on the basis of the remaining amount of each of the multiple terminal devices; and a priority setting instruction unit that gives the charge control unit a priority power setting instruction that the maximum power input via the cable is set to a first power amount according to the maximum power consumption for one or each of the multiple priority devices and the maximum profile setting instruction that sets a power profile to the maximum power profile for one or each of the multiple priority devices.SELECTED DRAWING: Figure 12

Description

The present invention relates to control devices, information processing devices and programs.

In recent years, the use of tablet computers (hereinafter referred to as tablets) for education has been studied in schools and the like. In such a case, the tablet is stored and managed in a dedicated rack installed in the classroom, for example. Before the start of class, students remove the tablet from the rack, activate the removed tablet, and start using it at their own seat. At the end of the lesson, the student shuts down the tablet he was using, stores the shut down tablet in the rack, and connects it to the control device in the rack via a cable.

Then, the control device in the rack charges the stored tablet via the cable. In addition, the information processing device in the rack accepts remote control and the like via the network, updates software to the stored tablet, and performs maintenance on the tablet.

International Publication No. 2018/096798

By the way, the charging characteristics of a battery differ depending on the remaining amount of charging power. In general, a battery is not rapidly charged unless a voltage equal to or higher than a predetermined value is applied when the remaining amount is less than a certain value (for example, when the remaining amount is 80% or less). However, when the remaining amount exceeds a certain value (for example, when it is larger than 80%), the battery is not rapidly charged even if a voltage exceeding a certain value is applied.

In addition, a large number of tablets are stored in the rack. However, if the rack charges a large number of tablets at the same time with the maximum power that can be supplied, the total power supply may exceed the maximum allowable power. Also, when installed in a classroom, the rack must keep the battery level above a certain level for all of the many tablets it houses by the start of the next lesson. Therefore, the rack must properly distribute and charge power instead of charging all of a large number of tablets uniformly.

The disclosed technology has been made in view of the above, and an object of the present invention is to provide a control device, an information processing device, and a program that appropriately distributes electric power to a plurality of terminal devices and efficiently charges them. ..

The control device according to the first aspect of the present invention is a control device that controls power supply to a plurality of terminal devices, and can be connected to each of the plurality of terminal devices via a cable, and the plurality of terminal devices can be connected to each other via a cable. A charge control unit that performs information communication with each of the above cables via the cable and supplies power to each of the plurality of terminal devices via the cable according to a power profile indicating a combination of voltage and current, and the charge control unit. The remaining amount of the battery for each of the plurality of connected terminal devices, the remaining amount acquisition unit for acquiring the maximum power consumption according to the remaining amount, and the remaining amount of each of the plurality of terminal devices. Based on this, the cable for each of the priority terminal determination unit for determining one or a plurality of priority devices, which is one or a plurality of terminal devices to be preferentially charged among the plurality of terminal devices, and the one or a plurality of priority devices. A priority power setting instruction for setting the maximum electric energy input via From the priority setting instruction unit that gives the maximum profile setting instruction, which is the profile setting instruction to be set to the maximum power profile indicating power, to the charge control unit and the total electric energy that can be supplied from the charge control unit, the one or more. The surplus electric energy calculation unit that calculates the surplus electric energy obtained by subtracting the total of the first electric energy set for the priority device, and one or a plurality of terminal devices excluding the one or the plurality of priority devices among the plurality of terminal devices. The charge control unit gives a profile setting instruction for setting the power profile for each of the one or more normal devices so that the amount of power supplied to the one or more normal devices does not exceed the surplus electric energy. It is provided with an input setting instruction unit for giving to.

The information processing device according to the second aspect of the present invention is an information processing device that controls a charge control unit that supplies electric energy to a plurality of terminal devices, and the charge control unit is each of the plurality of terminal devices. And can be connected via a cable, information communication is performed with each of the plurality of terminal devices via the cable, and the cable indicates each of the plurality of terminal devices according to a power profile indicating a combination of voltage and current. The information processing device supplies power to the battery, and the information processing device acquires the remaining amount of the battery and the maximum electric energy according to the remaining amount for each of the plurality of terminal devices connected to the charge control unit. A priority terminal that determines one or a plurality of priority devices, which are one or a plurality of terminal devices to be preferentially charged among the plurality of terminal devices, based on the amount acquisition unit and the remaining amount of each of the plurality of terminal devices. For each of the determination unit and the one or more priority devices, a priority power setting instruction for setting the maximum electric energy input via the cable to the first electric energy according to the maximum power consumption, and the above 1 Alternatively, the priority setting instruction unit that gives the maximum profile setting instruction, which is a profile setting instruction for setting the maximum power profile indicating the maximum power that can supply the power profile for each of the plurality of priority devices, to the charge control unit, and the above-mentioned The surplus electric energy calculation unit that calculates the surplus electric energy obtained by subtracting the total of the first electric energy set for the one or more priority devices from the total electric energy that can be supplied from the charge control unit, and the plurality of terminal devices. Of the one or more normal devices, the one or more normal devices excluding the one or more priority devices so that the amount of power supplied to the one or more normal devices does not exceed the surplus electric energy. It includes an input setting instruction unit that gives a profile setting instruction for setting the power profile for each to the charge control unit.

The program according to the third aspect of the present invention is a program for operating a computer as an information processing device that controls a charge control unit that supplies electric energy to a plurality of terminal devices, and the charge control unit is the above-mentioned. It is possible to connect to each of the plurality of terminal devices via a cable, perform information communication with each of the plurality of terminal devices via the cable, and use a power profile indicating a combination of voltage and current to obtain the plurality of terminal devices. Power is supplied to each of them via the cable, and the computer is connected to the remaining amount of the battery for each of the plurality of terminal devices connected to the charge control unit, and the maximum electric energy according to the remaining amount. Based on the remaining amount of the remaining amount acquisition unit and the remaining amount of each of the plurality of terminal devices, one or a plurality of priority devices which are one or a plurality of terminal devices to be preferentially charged among the plurality of terminal devices. A priority power setting instruction for setting the maximum electric energy input via the cable to the first electric energy according to the maximum electric energy for each of the priority terminal determination unit to be determined and the one or a plurality of priority devices. A priority setting instruction for giving a maximum profile setting instruction, which is a profile setting instruction for setting the power profile to the maximum power profile indicating the maximum power that can be supplied for each of the one or a plurality of priority devices, to the charge control unit. The surplus electric energy calculation unit that calculates the surplus electric energy obtained by subtracting the total of the first electric energy set for the one or more priority devices from the total electric energy that can be supplied from the charge control unit, and the plurality of units. The one or more so that the amount of power supplied to one or more normal devices, which is one or more terminal devices excluding the one or more priority devices, does not exceed the surplus electric energy. It functions as an input setting instruction unit that gives a profile setting instruction for setting the power profile for each of the normal devices of the above to the charge control unit.

According to the control device according to the first aspect of the present invention, electric power can be appropriately distributed to a plurality of terminal devices to efficiently charge them.

According to the information processing device according to the second aspect of the present invention, electric power can be appropriately distributed to a plurality of terminal devices to efficiently charge them.

According to the program according to the third aspect of the present invention, electric power can be appropriately distributed to a plurality of terminal devices to efficiently charge them.

FIG. 1 is a diagram showing an information processing system. FIG. 2 is a diagram showing the appearance of the charging cabinet. FIG. 3 is an enlarged view of the peripheral portion of the terminal device housed in the charging cabinet. FIG. 4 is a block diagram showing a configuration of a charging cabinet in which a terminal device is housed, together with a school server and a wireless communication device. FIG. 5 is a diagram showing a configuration when the charging cabinet includes a plurality of charging control devices. FIG. 6 is a diagram showing the hardware configuration of the charge control device together with the plurality of terminal devices. FIG. 7 is a diagram showing the hardware configuration of the terminal device and the hardware configuration of the terminal control unit in the charge control device. FIG. 8 is a diagram showing a functional configuration of the information processing apparatus according to the first embodiment. FIG. 9 is a diagram showing a processing flow of the information processing system according to the first embodiment. FIG. 10 is a flowchart showing a processing flow of the information processing apparatus according to the first embodiment. FIG. 11 is a diagram showing a processing flow when an input power setting instruction and a profile setting instruction are given in the information processing system according to the first embodiment. FIG. 12 is a diagram showing a functional configuration of the information processing apparatus according to the second embodiment. FIG. 13 is a diagram showing a processing flow of the information processing system according to the second embodiment. FIG. 14 is a flowchart showing a processing flow of the information processing apparatus according to the second embodiment. FIG. 15 is a diagram showing a processing flow when a priority power setting instruction and an input power setting instruction are given in the information processing system according to the second embodiment. FIG. 16 is a diagram showing a functional configuration of the information processing apparatus according to the third embodiment. FIG. 17 is a diagram showing a processing flow of the information processing system according to the third embodiment. FIG. 18 is a diagram showing a processing flow of the information processing system following FIG. FIG. 19 is a diagram showing a processing flow of the information processing system following FIG.

The information processing system 10 according to the embodiment will be described below. The disclosed technology is not limited depending on the embodiment. Further, configurations having substantially the same function in a plurality of embodiments are designated by the same reference numerals, and duplicate description will be omitted.

(First Embodiment)
First, the information processing system 10 according to the first embodiment will be described.

FIG. 1 is a diagram showing an information processing system 10 according to the first embodiment. In the present embodiment, the information processing system 10 is a system for supporting lessons in a school. The information processing system 10 is not limited to supporting lessons at school, and may be applied to other environments. The information processing system 10 may be applied to any environment as long as it is an environment in which a large number of participants work or learn while operating a computer, such as in a company, a seminar, or a conference. ..

The information processing system 10 includes a plurality of terminal devices 20, a school server 22, a wireless communication device 24, and a charging cabinet 26 (control device).

Each of the plurality of terminal devices 20 is a tablet-type or notebook-type computer. The terminal device 20 has an information input function, an output function, and an information processing function. The terminal device 20 has a secondary battery and can be operated by the electric power charged in the secondary battery. Therefore, the terminal device 20 can be carried by the user. Further, the terminal device 20 has a wireless communication function, and can perform information communication with another device without using a communication cable.

The school server 22 is a server-type computer, and is accessed from a plurality of terminal devices 20 via an internal network. Further, the school server 22 restricts access from a device on the external network to a device on the internal network, or restricts access from a device on the internal network to a device on the external network, for example.

The wireless communication device 24 is provided outside the charging cabinet 26. The wireless communication device 24 is connected to the internal network by wire. The wireless communication device 24 connects to each of the plurality of terminal devices 20 by wireless communication. The wireless communication device 24 allows the terminal device 20 connected by wireless communication to access another device on the internal network.

The charging cabinet 26 has a charging control device 30 and an information processing device 32. The charging cabinet 26 houses a plurality of terminal devices 20 inside. The terminal device 20 housed inside the charging cabinet 26 can be taken out by the user.

The charging cabinet 26 charges the terminal device 20 housed inside. Further, the charging cabinet 26 can start or shut down the power supply of the terminal device 20 housed inside. The charging cabinet 26 can communicate with the terminal device 20 housed inside by wire. Further, the charging cabinet 26 can wirelessly communicate with the terminal device 20 in a state where the terminal device 20 housed therein is activated.

Further, the charging cabinet 26 is connected to the internal network. The charging cabinet 26 can operate and communicate with the terminal device 20 housed inside in response to an instruction from an external device.

In such an information processing system 10, each of the plurality of terminal devices 20 is taken out from the charging cabinet 26 by the student before the start of the lesson. During class, the terminal device 20 is used by the student. During class, the terminal device 20 accesses the school server 22 via the wireless communication device 24. As a result, during the lesson, the terminal device 20 can download the material data from the school server 22 and make the student refer to it. Further, during the lesson, the terminal device 20 can upload the information input by the student (for example, the answer to the problem) to the server 22 in the school.

Further, each of the plurality of terminal devices 20 is housed in the charging cabinet 26 after the lesson is completed. The charging cabinet 26 charges the stored terminal device 20 by the start of the next lesson. As a result, the charging cabinet 26 can prevent the terminal device 20 from becoming inoperable due to running out of charge during the lesson.

Further, the charging cabinet 26 operates the stored terminal device 20 in response to a remote control from an external device or the like. Then, the charging cabinet 26 causes the stored terminal device 20 to update the program or install the program in response to remote control from an external device or the like. As a result, the charging cabinet 26 allows a maintenance worker at a remote location to maintain the terminal device 20.

FIG. 2 is a diagram showing the appearance of the charging cabinet 26. The charging cabinet 26 has a storage unit 28 for accommodating the charging control device 30 and the information processing device 32. The plurality of terminal devices 20 are stored in predetermined positions of the storage unit 28.

The charge control device 30 executes charge control and communication control for the stored terminal device 20. Further, the information processing device 32 communicates with another device via the internal network. In addition, the information processing device 32 controls the charge control device 30 and wirelessly communicates with the stored terminal device 20.

FIG. 3 is an enlarged view of a peripheral portion of the terminal device 20 housed in the charging cabinet 26. The terminal device 20 housed in the charging cabinet 26 is connected to the charging control device 30 via a cable 34.

The cable 34 can be attached to the terminal device 20. During the storage operation, the terminal device 20 is manually attached to the cable 34 by the user. Further, during the removal work, the terminal device 20 is manually removed from the cable 34 by the user.

The cable 34 complies with a standard that defines specifications for power supply and information communication between two devices. In the present embodiment, the cable 34 is a USB Type-C cable compliant with the USB (Universal Serial Bus) -C standard. According to this standard, power can be supplied as well as information is communicated between the two devices.

FIG. 4 is a block diagram showing the configuration of the charging cabinet 26 in which the terminal device 20 is housed together with the school server 22 and the wireless communication device 24. The charging cabinet 26 includes a charging control device 30, an information processing device 32, a plurality of cables 34, a power strip 36, and a plurality of AC adapters 38 (power converters).

The charge control device 30 is connected to one or more terminal devices 20 via a cable 34. One terminal of each of the one or a plurality of cables 34 is connected to the charge control device 30, and the other terminal can be connected to the terminal device 20.

The charge control device 30 executes charge control and communication control for each of the one or a plurality of terminal devices 20. The configuration of the charge control device 30 will be described in more detail in FIGS. 6 and 6 and later.

The information processing device 32 is a computer having a communication function and an information processing function. The information processing device 32 includes a CPU (Central Processing Unit), a ROM (Read Only Memory), a RAM (Random Access Memory), and the like, and executes information processing according to an installed program. Further, the information processing device 32 is connected to the internal network and performs information communication with other devices on the internal network. In addition, the information processing device 32 communicates information with other devices on the external network via the school server 22.

Further, the information processing device 32 is connected to the charge control device 30 via the internal communication cable 40. As a result, the information processing device 32 can control the charge control device 30.

The internal communication cable 40 connects the information processing device 32 and the charge control device 30. The internal communication cable 40 is a USB Type-A to C cable conforming to the USB-C standard. The internal communication cable 40 is not limited to this, and may be a cable conforming to other standards.

The power strip 36 is connected to a commercial AC power outlet provided in the classroom via an AC cable. Further, the power tap 36 has a plurality of sub power outlets. An AC adapter 38 for supplying DC power to the information processing device 32 is connected to the sub power outlet of the power tap 36. The AC adapter 38 converts the AC power supplied from the power strip 36 into DC power and supplies the power to the information processing device 32. As a result, the information processing device 32 can operate using AC power as a power source.

Further, an AC adapter 38 for supplying DC power to the charge control device 30 is connected to the sub power outlet of the power tap 36. The AC adapter 38 converts the AC power supplied from the power strip 36 into DC power and supplies the power to the charge control device 30. As a result, the charge control device 30 can operate using AC power as a power source.

FIG. 5 is a diagram showing a configuration when the charging cabinet 26 includes a plurality of charging control devices 30. The charging cabinet 26 may have a plurality of charging control devices 30. In the present embodiment, the plurality of charge control devices 30 are cascade-connected by the internal communication cable 40. The information processing device 32 may be individually (parallel) connected to each of the plurality of charge control devices 30.

FIG. 6 is a diagram showing the hardware configuration of the charge control device 30 together with the plurality of terminal devices 20. The charge control device 30 includes an upper conversion unit 42, a device control unit 44, and a plurality of terminal control units 46.

The upper conversion unit 42 is connected to the information processing device 32 via the internal communication cable 40. The upper conversion unit 42 converts the signal format between the signal line of the internal communication cable 40 and the signal line input / output by the device control unit 44 and the plurality of terminal control units 46.

In the present embodiment, the device control unit 44 and the plurality of terminal control units 46 input / output signals in the RS485 format. Therefore, in the present embodiment, the upper conversion unit 42 converts the signal format between USB-C and RS485.

When the device control unit 44 and the plurality of terminal control units 46 input / output USB-C signals, the charge control device 30 does not have to have the upper conversion unit 42. Further, the upper conversion unit 42 may convert not only RS485 but also other formats.

The device control unit 44 has a processor circuit or the like inside. The device control unit 44 controls the entire charge control device 30.

Each of the plurality of terminal control units 46 can be connected to the terminal device 20 via the cable 34. Each of the plurality of terminal control units 46 executes charge control and communication control for the terminal device 20 connected via the corresponding cable 34. Each of the plurality of terminal control units 46 may be connected to a plurality of terminal devices 20 via a plurality of cables 34.

Further, each of the plurality of terminal control units 46 receives a command from the information processing device 32 via the upper conversion unit 42. Each of the plurality of terminal control units 46 can also execute charge control and communication control in response to a command received from the information processing device 32. Further, each of the plurality of terminal control units 46 notifies the information processing device 32 via the upper conversion unit 42 of the status of the terminal device 20 connected via the corresponding cable 34 and the like.

FIG. 7 is a diagram showing a hardware configuration of the terminal device 20 and a hardware configuration of the terminal control unit 46 in the charge control device 30.

Each of the plurality of terminal control units 46 included in the charge control device 30 includes a charge side PD controller 52 (power supply controller, charge control unit), a charge side communication processor 54, a lower conversion unit 56, and a charge side power supply unit 58. And have.

The charging side PD controller 52 can be connected to the terminal device 20 via the cable 34. The charging-side PD controller 52 performs power supply and information communication in accordance with a standard that defines specifications for power supply and information communication using the cable 34.

In the present embodiment, the charging side PD controller 52 performs power supply and information communication with the terminal device 20 in a manner compliant with the USB-C standard. In the present embodiment, the charging side PD controller 52 transmits and receives a VDM (Vendor Defined Messaging) signal to and from the terminal device 20 via a CC (Configuration Cannel) signal line in the cable 34 conforming to the USB-C standard.

When the charging side PD controller 52 is connected to the terminal device 20 via the cable 34, the charging side PD controller 52 executes a sequence (power delivery sequence) predetermined in the standard with the terminal device 20 to execute the terminal device 20. Set the combination of voltage and current to be supplied to. In the present embodiment, the charging side PD controller 52 sets a power profile indicating a combination of voltage and current supplied to the terminal device 20 by executing the power delivery sequence defined by the USB-C standard. Then, the charging side PD controller 52 gives an instruction to the charging side power supply unit 58 to supply power to the terminal device 20 by the combination of the voltage and the current shown in the set power profile.

The charging-side communication processor 54 includes a CPU, ROM, RAM, and the like, and controls the charging-side PD controller 52. The charging-side communication processor 54 expands, for example, a program stored in advance in the ROM into the RAM, and controls according to the program. Further, the charging side communication processor 54 receives a command from the information processing device 32 via the lower conversion unit 56 and the upper conversion unit 42 according to the program. Further, the charging side communication processor 54 notifies the information processing device 32 of the information via the lower conversion unit 56 and the upper conversion unit 42 according to the program.

The lower conversion unit 56 is connected to the upper conversion unit 42 via a bus. The lower conversion unit 56 converts the signal format between the signal line of the bus connected to the upper conversion unit 42 and the signal line input / output by the charging side communication processor 54.

In the present embodiment, the charging side communication processor 54 inputs / outputs a signal in a UART (Universal Asynchronous Receiver / Transmitter) format. Therefore, in the present embodiment, the lower conversion unit 56 converts the signal format between RS485 and UART.

When the charging side communication processor 54 inputs / outputs the RS485 signal, the terminal control unit 46 does not have to have the lower conversion unit 56. Further, the lower conversion unit 56 may convert not only RS485 but also other formats.

The charging side power supply unit 58 receives power from the AC adapter 38 that converts the AC voltage into direct current. The charging-side power supply unit 58 supplies power to the terminal device 20 via the cable 34 in accordance with the instruction from the charging-side PD controller 52 by the combination of voltage and current indicated in the designated power profile.

The terminal device 20 includes a terminal-side PD controller 62 (power supply controller), a terminal-side communication processor 64, a processing circuit 66, a wireless communication unit 68, a battery 70, a terminal-side power supply unit 72, and a power switch 74. Has.

The terminal-side PD controller 62 can be connected to the charge control device 30 via the cable 34. The terminal-side PD controller 62 receives power supply and performs information communication in accordance with a standard that defines specifications for power supply and information communication using the cable 34.

In the present embodiment, the terminal-side PD controller 62 receives power supply from the charge control device 30 in a manner compliant with the USB-C standard, and also performs information communication. In the present embodiment, the terminal-side PD controller 62 transmits and receives a VDM signal to and from the charge control device 30 via the CC signal line in the cable 34 conforming to the USB-C standard.

When the terminal-side PD controller 62 is connected to the charge control device 30 via the cable 34, the terminal-side PD controller 62 is charged by executing a sequence (power delivery sequence) predetermined in the standard with the charge control device 30. The combination of voltage and current received from the control device 30 is set. In the present embodiment, the terminal-side PD controller 62 sets a power profile indicating a combination of voltage and current received from the charge control device 30 by executing a power delivery sequence defined by the USB-C standard. Then, the terminal-side PD controller 62 gives an instruction to the terminal-side power supply unit 72 to receive the electric power of the combination of the voltage and the current shown in the set power profile from the charge control device 30.

The terminal-side communication processor 64 includes a CPU, ROM, RAM, and the like, and controls the terminal-side PD controller 62. The terminal-side communication processor 64 expands, for example, a program stored in advance in the ROM into the RAM, and controls according to the program. For example, the terminal-side communication processor 64 gives the processing circuit 66 information about the charge control device 30 connected via the cable 34 and the like. Further, the terminal-side communication processor 64 controls the power supply state based on the information received from the charge control device 30 via the cable 34, the signal from the internal circuit of the terminal device 20, and the operation of the power switch 74.

The processing circuit 66 includes a CPU, ROM, RAM, and the like, and executes overall control of the terminal device 20. The processing circuit 66 expands, for example, a program stored in advance in the ROM into the RAM, and controls according to the program. The processing circuit 66 gives a command to the terminal-side communication processor 64 or acquires information from the terminal-side communication processor 64 according to the execution of the program. Further, the processing circuit 66 controls the wireless communication unit 68 according to the execution of the program.

The wireless communication unit 68 performs wireless communication according to the control by the processing circuit 66. In the present embodiment, the wireless communication unit 68 wirelessly communicates with the wireless communication device 24. Then, the wireless communication unit 68 relays information communication between the processing circuit 66 and another device.

The battery 70 is a secondary battery. The battery 70 supplies electric power to each circuit included in the terminal device 20.

The terminal-side power supply unit 72 receives electric power from the battery 70, and supplies the electric power received from the battery 70 to each circuit such as the processing circuit 66 and the wireless communication unit 68. The terminal-side PD controller 62, the terminal-side communication processor 64, and the terminal-side power supply unit 72 are constantly supplied with electric power regardless of the power supply state of the terminal device 20.

Further, the terminal-side power supply unit 72 can also receive electric power from the charge control device 30 via the cable 34 in accordance with the instruction from the terminal-side PD controller 62. In this case, the terminal-side power supply unit 72 supplies the electric power received from the charge control device 30 to each circuit such as the processing circuit 66 and the wireless communication unit 68 via the power switch 74. Further, the terminal-side power supply unit 72 charges the battery 70 by supplying the electric power received from the charge control device 30 to the battery 70 via the cable 34.

The power switch 74 is a push switch provided in the housing and performing an alternate operation. The power switch 74 is operated by the user.

When the power switch 74 is pressed by the user, the terminal-side communication processor 64 switches the power state. For example, the terminal-side communication processor 64 switches to the on state when the power switch 74 is pressed in the off state. Further, the terminal-side communication processor 64 switches to the off state when the power switch 74 is pressed in the on state. Further, the terminal-side communication processor 64 switches the power supply state (on state or off state) according to the information (wake-up command, sleep command, etc.) received from the charge control device 30 via the cable 34. Further, the terminal-side communication processor 64 also switches the power supply state by a signal from the internal circuit of the terminal device 20.

The terminal-side power supply unit 72 supplies electric power to each circuit such as the processing circuit 66 and the wireless communication unit 68 in the on state. The terminal-side power supply unit 72 cuts off the power supply to each circuit such as the processing circuit 66 and the wireless communication unit 68 in the off state.

FIG. 8 is a diagram showing a functional configuration of the information processing apparatus 32 according to the first embodiment. The information processing device 32 according to the first embodiment includes a connection detection unit 114, an average power calculation unit 116, and an input setting instruction unit 118.

The information processing apparatus 32 according to the first embodiment executes a predetermined program including a connection detection module, an average power calculation module, and an input setting designation module to execute a connection detection unit 114, an average power calculation unit 116, and an input setting instruction. Functions as part 118. In the information processing device 32, a part or all of the connection detection unit 114, the average power calculation unit 116, and the input setting instruction unit 118 may be configured by hardware.

The connection detection unit 114 acquires connection information from the charge control device 30. The charge control device 30 transmits connection information to the information processing device 32 when the terminal device 20 is connected via the cable 34 and when the terminal device 20 connected via the cable 34 is removed. .. The connection information includes, for example, identification information of the connected or disconnected terminal device 20 and a port number of the charge control device 30. Then, the connection detection unit 114 registers the identification information and the port number of the terminal device 20 connected to the charge control device 30 in the memory or the like.

The average power calculation unit 116 detects the number of terminal devices 20 connected to the charge control device 30 based on the information registered by the connection detection unit 114. The average power calculation unit 116 acquires the detected number of units and the total amount of power that can be supplied for charging.

The total electric energy is set in advance by the user or the like based on, for example, the electric energy that can be input from the power tap 36. For example, the total electric energy is an amount obtained by subtracting the required electric energy from the electric energy that can be input from the power strip 36. The required power amount is, for example, the amount of power consumed by the charging cabinet 26, the amount of power consumed when all the ports of the charging control device 30 are supplied with the default power profile, and the amount of margin power added. It is the value that was set. The information processing device 32 may acquire the total electric energy from the school server 22 or the like in advance via the internal network.

The average power calculation unit 116 calculates the average power amount obtained by dividing the total power amount by the number of units. In the present embodiment, the average electric energy represents the amount of electric power that can be supplied per unit when the electric power is supplied to all the terminal devices 20 currently connected to the charge control device 30 on average.

The input setting instruction unit 118 gives an input power setting instruction to the charge control device 30. In the present embodiment, the input power setting instruction is an instruction to set the maximum power input to each of the plurality of terminal devices 20 connected to the charge control device 30 via the cable 34 to the average power amount. ..

When the input power setting instruction is received from the information processing device 32, the charge control device 30 averages the maximum power input to each of the connected one or a plurality of terminal devices 20 via the cable 34. Sends a maximum input power setting command to set the amount. The terminal device 20 that receives the maximum input power setting command for setting the maximum input power to the average power amount from the charge control device 30 does not receive power larger than the average power amount via the cable 34. , Control power consumption.

Further, the input setting instruction unit 118 gives the charge control device 30 a maximum profile setting instruction for each of the plurality of terminal devices 20 connected to the charge control device 30. In the present embodiment, the maximum profile setting instruction is a profile setting instruction for setting the power profile for the terminal device 20 to the maximum power profile indicating the maximum power that can be supplied.

Upon receiving the maximum profile setting instruction from the information processing device 32, the charge control device 30 performs a power delivery sequence with each of the plurality of connected terminal devices 20 so that the voltage and current are supplied by the maximum power profile. Run.

FIG. 9 is a diagram showing a processing flow of the information processing system 10 according to the first embodiment. The information processing system 10 according to the first embodiment executes processing in the flow as shown in FIG.

First, the terminal device 20 is physically connected to the charge control device 30 via a cable 34 (S111-1, S111-2). Subsequently, the charge control device 30 and the terminal device 20 execute the power delivery sequence and set the power profile (S112-1, S112-2). As a result, the charge control device 30 can supply the power of the voltage and the current indicated in the set power profile to the terminal device 20.

Here, the charge control device 30 and the terminal device 20 execute the following procedure as a power delivery sequence. First, each of the charge control device 30 and the terminal device 20 is preset with power delivery object information in which one or more power profiles that can be supplied or input are described. The charge control device 30 transmits power delivery object information including one or a plurality of preset power profiles to the terminal device 20. Subsequently, the terminal device 20 determines one power profile for which supply is requested from the power delivery object information sent from the charge control device 30, and provides response information indicating the determined power profile to the charge control device 30. Send to. Then, the charge control device 30 starts supplying power to the terminal device 20 according to the power profile shown in the response information. By executing such a procedure, the charge control device 30 and the terminal device 20 can supply power to the terminal device 20 by the combination of the voltage and the current shown in the power profile.

In the USB-C standard, "5V / 0.9A", "5V / 3A", "9V / 3A", "12V / 3A", "15V / 3A" and "20V / 3A" are defined as power profiles. ing. Further, in the USB-C standard, the minimum voltage and the minimum current "5V / 0.9A" are defined as the default power profile. It is stipulated that devices conforming to the USB-C standard must be able to supply and receive power with the default power profile.

In the present embodiment, the charge control device 30 and the terminal device 20 perform a power delivery sequence immediately after the terminal device 20 is physically connected via the cable 34, thereby performing a default power profile (5V / 0. 9A) is set. For example, the charge control device 30 transmits power delivery object information in which only the default power profile is described to the terminal device 20 in the power delivery sequence immediately after the terminal device 20 is connected via the cable 34. As a result, the charge control device 30 supplies power to the terminal device 20 by the voltage and current shown in the default power profile (5V / 0.9A) immediately after the terminal device 20 is connected via the cable 34. can do.

The charge control device 30 can supply very small power to the terminal device 20 set to the default power profile (5V / 0.9A) as compared with other power profiles. Therefore, the charge control device 30 cannot substantially charge the terminal device 20 set to the default power profile (5V / 0.9A).

The charge control device 30 is connected when the terminal device 20 is physically connected (S111-1, S111-2) and the power delivery sequence is executed (S112-1, S112-2). The connection information of 20 is transmitted to the information processing device 32 (S113-1, S113-2). The charge control device 30 transmits connection information each time a new terminal device 20 is physically connected. Further, when the terminal device 20 that is already physically connected is removed, the charge control device 30 transmits connection information indicating that the terminal device 20 has been removed to the information processing device 32.

Each time the information processing device 32 receives connection information from the charge control device 30, the information processing device 32 registers the terminal device 20 connected to the charge control device 30 (S114). For example, the information processing device 32 registers the identification information, the port number, and the like of the terminal device 20 newly connected to the charge control device 30 in the memory. Further, for example, the information processing device 32 deletes the identification information, the port number, and the like of the terminal device 20 removed from the charge control device 30 from the memory.

FIG. 10 is a flowchart showing a processing flow of the information processing apparatus 32 according to the first embodiment. The information processing device 32 repeats the processes from S122 to S126 every predetermined period (for example, every 5 minutes or 10 minutes) (loop processing between S121 and S127).

In S122, the information processing device 32 determines whether or not the new terminal device 20 is connected to the charge control device 30 after the predetermined period immediately before. When the new terminal device 20 is not connected to the charge control device 30 (No in S122), the information processing device 32 advances the process to S127 without performing any process.

When the new terminal device 20 is connected to the charge control device 30 (Yes in S122), the information processing device 32 advances the process to S123. In S123, the information processing device 32 detects the number of terminal devices 20 connected to the charge control device 30 by referring to the memory in which the terminal device 20 connected to the charge control device 30 is registered.

Subsequently, in S124, the information processing apparatus 32 calculates the average electric energy amount by dividing the total electric energy amount that can be supplied for charging by the detected number of units. Subsequently, in S125, the information processing device 32 gives an input power setting instruction for each of the one or a plurality of terminal devices 20 connected to the charge control device 30 to the charge control device 30. Subsequently, in S126, the information processing device 32 gives the charge control device 30 a maximum profile setting instruction for each of the one or a plurality of terminal devices 20 connected to the charge control device 30.

When the information processing device 32 finishes the process of S126, the information processing device 32 advances the process to S127. Then, in S127, the information processing apparatus 32 returns the processing to S121, waits for the processing for a predetermined time (for example, 5 minutes or 10 minutes), and advances the processing to S122.

In the process shown in FIG. 10, the information processing device 32 does not execute any process when the new terminal device 20 is not connected (No in S122). That is, the information processing device 32 does not execute any processing even when the terminal device 20 is removed. Instead of this, the information processing device 32 may execute the processes of S123 to S127 even when any of the terminal devices 20 is removed after the predetermined period immediately before. As a result, the information processing device 32 can supply more power to one or more terminal devices 20 connected to the charge control device 30.

Further, in the processing of S125, the information processing device 32 gives an input power setting instruction to the terminal device 20 in which the average power amount before the change and the average power amount after the change match among the plurality of terminal devices 20. It does not have to be. As a result, the information processing device 32 can reduce the processing for the terminal device 20 that does not change the maximum input power amount.

Further, in the process of S126, the information processing device 32 does not give a maximum profile setting instruction to the terminal device 20 in which the power profile before the change and the power profile after the change match among the plurality of terminal devices 20. May be good. As a result, the information processing device 32 can eliminate the processing of the power delivery sequence with the terminal device 20 that does not change the power profile.

FIG. 11 is a diagram showing a processing flow when an input power setting instruction and a maximum profile setting instruction are given in the information processing system 10 according to the first embodiment.

When the information processing device 32 gives an input power setting instruction and a maximum profile setting instruction to the charge control device 30 (S125, S126), the information processing system 10 executes the process in the flow as shown in FIG.

First, the charge control device 30 issues a maximum input power setting command to each of one or a plurality of connected terminal devices 20 to set the maximum power to be input to the average power amount by the VDM signal. Transmit (S131-1, S131-2).

Subsequently, each of the one or a plurality of terminal devices 20 sets the maximum power to be input to the average electric energy (S132-1, S132-2). As a result, each of the one or the plurality of terminal devices 20 controls the power consumption so that the power consumption larger than the set average power amount is not received via the cable 34 thereafter. Subsequently, each of the one or a plurality of terminal devices 20 transmits information indicating completion to the charge control device 30 by a VDM signal (S133-1, S133-2).

Upon receiving the completion information, the charge control device 30 executes a power delivery sequence with the terminal device 20 for which the average electric energy setting has been completed so that the voltage and current are supplied according to the maximum power profile. (S134-1, S134-2).

The maximum power profile is a profile indicating the maximum power among the power profiles that can be set between the charge control device 30 and the terminal device 20. For example, the charge control device 30 can supply power at 5V / 0.9A "," 5V / 3A "," 9V / 3A "," 12V / 3A "," 15V / 3A "and" 20V / 3A ". , It is assumed that the terminal device 20 can receive power at 5V / 0.9A ”,“ 5V / 3A ”and“ 20V / 3A ”. In this case, the maximum power profile is "20V / 3A", which is the maximum power of the power profiles common to each other.

The charge control device 30 and the terminal device 20 may not be able to change the power profile in the state of being connected via the cable 34 after once executing the power delivery sequence. In this case, the charge control device 30 may be reconnected after disconnecting the power supply and information communication via the cable 34 with the corresponding terminal device 20. For example, the charge control device 30 may open the ground line or power supply line in the cable 34 to temporarily disconnect the power supply and information communication, and then connect the ground line or power supply line. As a result, the charge control device 30 and the terminal device 20 can execute the power delivery sequence again.

The charging cabinet 26 (control device) according to the first embodiment as described above has the following effects.

The charging cabinet 26 according to the first embodiment includes an input power setting instruction for setting the maximum power input to each of the plurality of terminal devices 20 via the cable 34 to the average power amount, and the plurality of terminal devices 20. The charge control device 30 is given a maximum profile setting instruction for setting the power profile for each of the above to the maximum power profile. As a result, the charging cabinet 26 according to the first embodiment can supply an average amount of electric power to the plurality of terminal devices 20.

As described above, the charging cabinet 26 according to the first embodiment charges a large number of terminal devices 20 at the same time by setting the maximum power input to each of the plurality of terminal devices 20 to the average electric energy. Can be done. As a result, the charging cabinet 26 according to the first embodiment can charge the plurality of terminal devices 20 in a short time.

Further, the charging cabinet 26 according to the first embodiment determines at each predetermined period whether or not a new terminal device 20 is connected to the charging control device 30 after the immediately preceding predetermined period, and the new terminal device 20 is used. When connected to the charge control device 30, an input power setting instruction and a maximum profile setting instruction are given to the charge control device 30. As a result, according to the charging cabinet 26, it is possible to make each of the plurality of terminal devices 20 set the maximum input power at an appropriate timing.

Further, when setting the power profile, the charging cabinet 26 according to the first embodiment executes a power delivery sequence for determining a combination of the supplied voltage and the current with each of the plurality of terminal devices 20. As a result, according to the charging cabinet 26, the power profile for each of the plurality of terminal devices 20 can be set by the processing conforming to the USB-C standard.

Further, the charging cabinet 26 according to the first embodiment inputs a VDM signal to each of the plurality of terminal devices 20 via the cable 34 by exchanging a VDM signal with each of the plurality of terminal devices 20 via the cable 34. Set the maximum power to be set to the average power amount. As a result, according to the charging cabinet 26, the maximum power input via the cable 34 can be set to the average power amount in each of the plurality of terminal devices 20 by the processing conforming to the USB-C standard.

Further, the charging cabinet 26 according to the first embodiment further includes a storage unit 28 that stores a plurality of terminal devices 20 so that they can be taken out by a user. As a result, according to the charging cabinet 26, it is possible to charge while storing the plurality of terminal devices 20.

(Second Embodiment)
Next, the information processing system 10 according to the second embodiment will be described. The information processing system 10 according to the second embodiment has the same hardware configuration as that of the first embodiment.

FIG. 12 is a diagram showing a functional configuration of the information processing apparatus 32 according to the second embodiment. The information processing device 32 according to the second embodiment includes a connection detection unit 114, a remaining amount acquisition unit 212, a priority terminal determination unit 214, a priority setting instruction unit 216, a surplus power calculation unit 218, and an average power calculation unit. It includes 116 and an input setting instruction unit 118.

The information processing apparatus 32 according to the second embodiment includes a predetermined program including a connection detection module, a remaining amount acquisition module, a priority determination module, a priority setting instruction module, a surplus power calculation module, an average power calculation module, and an input setting instruction module. By executing the module, it functions as a connection detection unit 114, a remaining amount acquisition unit 212, a priority terminal determination unit 214, a priority setting instruction unit 216, a surplus power calculation unit 218, an average power calculation unit 116, and an input setting instruction unit 118. The information processing device 32 is one of a connection detection unit 114, a remaining amount acquisition unit 212, a priority terminal determination unit 214, a priority setting instruction unit 216, a surplus power calculation unit 218, an average power calculation unit 116, and an input setting instruction unit 118. Part or all may consist of hardware.

The connection detection unit 114 acquires connection information from the charge control device 30. Then, the connection detection unit 114 registers the terminal device 20 connected to the charge control device 30 in the memory or the like.

The remaining amount acquisition unit 212 acquires the remaining amount of the battery 70 and the maximum power consumption according to the remaining amount for each of the plurality of terminal devices 20 connected to the charge control device 30. The remaining amount of the battery 70 is expressed as a percentage, for example.

When a new terminal device 20 is connected to the charge control device 30, the remaining amount acquisition unit 212 acquires the remaining amount of the newly connected terminal device 20 and the maximum power consumption according to the remaining amount. Further, the remaining amount acquisition unit 212 periodically acquires the remaining amount and the maximum power consumption according to the remaining amount for each of the one or a plurality of terminal devices 20 connected to the charge control device 30.

The maximum power consumption is the maximum power consumption that can be consumed by the terminal device 20. Generally, the maximum power consumption correlates with the remaining amount of the battery 70. The terminal device 20 stores information representing the maximum power consumption for each remaining amount of the battery 70. For example, the terminal device 20 generates and stores information representing the maximum power consumption for each remaining amount by detecting the relationship between the past remaining amount and the power consumption. Further, for example, the terminal device 20 may store information representing the maximum power consumption for each remaining amount calculated by the designer or the like at the time of manufacture. The terminal device 20 transmits the remaining amount and the maximum power consumption amount corresponding to the remaining amount to the charge control device 30 by a VDM signal in response to a request from the charge control device 30 or periodically. The remaining amount acquisition unit 212 acquires the remaining amount transmitted from the terminal device 20 to the charge control device 30 and the maximum power consumption amount corresponding to the remaining amount from the charge control device 30.

The priority terminal determination unit 214 determines one or a plurality of priority devices based on the remaining amount of each of the plurality of terminal devices 20 connected to the charge control device 30. The one or more priority devices are one or more terminal devices 20 that preferentially charge among the plurality of terminal devices 20.

In the present embodiment, the priority terminal determination unit 214 has a predetermined number of terminals from the plurality of terminal devices 20 whose remaining amount is equal to or less than a preset threshold value and whose remaining amount is the smallest. Device 20 is determined as one or more priority devices. As a result, the priority terminal determination unit 214 can preferentially charge the terminal device 20 having a small remaining amount.

The threshold value may be determined, for example, based on a curve representing the maximum charging current flowing through the battery 70 with respect to the remaining amount of the battery 70. The curve representing the maximum charging current with respect to the remaining amount is generally constant from 0% to the first value (about 80%) of the remaining amount. Further, the curve representing the maximum charging current with respect to the remaining amount becomes smaller as the remaining amount increases while the remaining amount is between the first value and 100%. The threshold value may be, for example, a first value or a vicinity of the first value. Further, the threshold value may be, for example, the minimum remaining amount that must be charged in order to use the terminal device 20.

The priority setting instruction unit 216 acquires information for identifying one or more priority devices determined by the priority terminal determination unit 214. Further, the priority setting instruction unit 216 acquires the maximum power consumption acquired by the remaining amount acquisition unit 212 for each of the one or a plurality of priority devices.

The priority setting instruction unit 216 gives a priority power setting instruction to the charge control device 30. The priority power setting instruction is an instruction to set the maximum power input to each of the one or a plurality of priority devices via the cable 34 to the first power amount according to the maximum power consumption amount. The first electric energy may be the maximum electric energy, the electric energy obtained by adding a predetermined margin amount to the maximum electric energy, or the maximum electric energy that can be supplied to the priority device. There may be.

When the priority power setting instruction is received from the information processing device 32, the charge control device 30 determines the maximum power input to each of the one or a plurality of priority devices via the cable 34 according to the maximum power consumption. A command to set the maximum input power for setting the first electric energy is transmitted. The priority device that receives such a setting command from the charge control device 30 controls the power consumption so that the power consumption larger than the first power amount corresponding to the maximum power consumption amount is not received via the cable 34.

Further, the priority setting instruction unit 216 gives the charge control device 30 a maximum profile setting instruction for each of the one or a plurality of priority devices. Upon receiving the maximum profile setting instruction from the information processing device 32, the charge control device 30 executes a power delivery sequence with each of the one or more priority devices so that the voltage and current are supplied by the maximum power profile.

The surplus power calculation unit 218 acquires the total power amount. In addition, the surplus power calculation unit 218 acquires the first power amount to be set for each of the one or a plurality of priority devices. Then, the surplus power calculation unit 218 calculates the surplus power amount obtained by subtracting the total of the one or a plurality of first power amounts set for the one or a plurality of priority devices from the total power amount.

The average power calculation unit 116 calculates the number of one or a plurality of normal devices. The one or more conventional devices are one or more terminal devices 20 excluding one or more priority devices among the plurality of terminal devices 20. Further, the average power calculation unit 116 acquires the surplus power amount calculated by the surplus power calculation unit 218. Then, the average power calculation unit 116 calculates the average power amount obtained by dividing the surplus power amount by the number of one or a plurality of normal devices. In the present embodiment, the average electric energy represents the amount of electric power that can be supplied per unit when the electric power is supplied to one or a plurality of ordinary devices on an average basis.

The input setting instruction unit 118 gives an input power setting instruction to the charge control device 30. In the present embodiment, the input power setting instruction is an instruction to set the maximum electric power input to each of one or a plurality of normal devices via the cable 34 to the average electric energy.

When the input power setting instruction is received from the information processing device 32, the charge control device 30 causes each of the one or a plurality of normal devices to set the maximum power input via the cable 34 to the average power amount. Sends a command to set the maximum input power of. The terminal device 20 that receives such a setting command from the charge control device 30 controls the power consumption so that the power larger than the average power amount is not received via the cable 34.

Further, the input setting instruction unit 118 gives the charge control device 30 a maximum profile setting instruction for each of the one or a plurality of normal devices. Upon receiving the maximum profile setting instruction from the information processing device 32, the charge control device 30 executes a power delivery sequence with each of the one or more conventional devices so that the voltage and current are supplied by the maximum power profile. ..

In the second embodiment, the input setting instruction unit 118 has a power profile for each of the one or more normal devices so that the amount of power supplied to the one or more normal devices does not exceed the surplus electric energy. If the configuration is such that the charge control device 30 is given a profile setting instruction for setting the above, another process may be executed.

For example, the input setting instruction unit 118 may give a profile setting instruction for one or more normal devices to the charge control device 30 so that one or more normal devices are charged in rotation.

In the case of rotating charging, the input setting indicator 118 sets the power profile for a part of one or more normal devices to the maximum power profile, and for the other part of one or more normal devices. Set the power profile of to the default power profile. Then, in the case of rotating charging, the input setting instruction unit 118 sequentially changes some of the normal devices to be set in the maximum power profile of one or a plurality of normal devices at predetermined time intervals. As a result, the input setting indicator 118 sets the profile setting for each of the one or more normal devices so that the amount of power supplied to the one or more normal devices does not exceed the surplus electric energy. Instructions can be given to the charge control device 30.

FIG. 13 is a diagram showing a processing flow of the information processing system 10 according to the second embodiment. The information processing system 10 according to the second embodiment executes processing in the flow as shown in FIG.

First, the terminal device 20 is physically connected to the charge control device 30 via the cable 34 (S211). Subsequently, the charge control device 30 and the terminal device 20 execute the power delivery sequence and set the power profile (S212). In the present embodiment, the charge control device 30 and the terminal device 20 perform a power delivery sequence immediately after the terminal device 20 is physically connected via the cable 34, thereby performing a default power profile (5V / 0. 9A) is set. As a result, the charge control device 30 supplies power to the terminal device 20 by the voltage and current shown in the default power profile (5V / 0.9A) immediately after the terminal device 20 is connected via the cable 34. can do.

When the terminal device 20 is physically connected (S211) and the power delivery sequence is executed (S212), the charge control device 30 transmits connection information about the connected terminal device 20 to the information processing device 32. (S213). The charge control device 30 transmits connection information each time a new terminal device 20 is physically connected. Further, when the terminal device 20 already physically connected is removed, the charge control device 30 transmits the connection information about the removed terminal device 20 to the information processing device 32.

Subsequently, the information processing device 32 transmits a request for acquiring the remaining amount of the battery 70 to the charge control device 30 for the newly connected terminal device 20 (S214). Subsequently, the charge control device 30 transmits the remaining amount transmission command to the corresponding terminal device 20 by the VDM signal (S215).

Subsequently, the terminal device 20 that has received the remaining amount transmission command acquires the remaining amount of the battery 70 (S216). Further, the terminal device 20 that has received the remaining amount transmission command acquires the maximum power consumption with respect to the current remaining amount of the battery 70 (S217). Subsequently, the terminal device 20 that has received the remaining amount transmission command transmits the remaining amount and the maximum power consumption amount to the charge control device 30 by the VDM signal (S218). Subsequently, the charge control device 30 transmits the remaining amount and the maximum power consumption received from the terminal device 20 to the information processing device 32 (S219). When the information processing device 32 receives the remaining amount and the maximum power consumption, the information processing device 32 registers the information processing device 32 in the memory in association with the identification information of the terminal device 20.

The information processing device 32 periodically transmits a remaining amount acquisition request to the charge control device 30 for each of the one or a plurality of terminal devices 20 connected to the charge control device 30. Then, the information processing device 32 periodically updates the remaining amount and the maximum power consumption registered in the memory for each of the one or a plurality of terminal devices 20 connected to the charge control device 30.

FIG. 14 is a flowchart showing a processing flow of the information processing apparatus 32 according to the second embodiment. The information processing device 32 repeats the processes from S222 to S231 every predetermined period (for example, every 5 minutes or 10 minutes) (loop processing between S221 and S232).

In S222, the information processing device 32 determines whether or not the new terminal device 20 is connected to the charge control device 30 after the predetermined period immediately before. When the new terminal device 20 is not connected to the charge control device 30 (No in S222), the information processing device 32 advances the process to S223.

In S223, the information processing device 32 determines whether or not the remaining amount of the battery 70 of any one or the plurality of priority devices is larger than the threshold value. When the remaining amount of any of the priority devices is not larger than the threshold value (No in S223), the information processing device 32 advances the processing to S232 without performing any processing.

When the new terminal device 20 is connected to the charge control device 30 (Yes in S222) or when the remaining amount of any of the priority devices becomes larger than the threshold value (Yes in S223), the information processing device 32 The process proceeds to S224.

In S224, the information processing device 32 determines one or a plurality of priority devices to be preferentially charged among the plurality of terminal devices 20 connected to the charge control device 30. In the present embodiment, the information processing device 32 uses 1 of a plurality of terminal devices 20 to have a predetermined number of terminal devices 20 having a remaining amount equal to or less than a threshold value and having the smallest remaining amount. Or it is determined as a plurality of priority devices.

Subsequently, in S225, the information processing device 32 gives a priority power setting instruction for one or more priority devices to the charge control device 30.

Subsequently, in S226, the information processing device 32 gives the charge control device 30 a maximum profile setting instruction for one or more priority devices. Subsequently, in S227, the information processing device 32 uses one or a plurality of ordinary terminal devices 20 excluding one or a plurality of priority devices among the plurality of terminal devices 20 connected to the charge control device 30. Identify as a device.

Subsequently, in S228, the information processing apparatus 32 calculates the surplus electric energy by subtracting the total of the first electric energy set for one or a plurality of priority devices from the total electric energy.

Subsequently, in S229, the information processing device 32 calculates the average power amount by dividing the surplus power amount by the number of one or a plurality of normal devices.

Subsequently, in S230, the information processing device 32 gives an input power setting instruction to the charge control device 30. Subsequently, in S231, the information processing device 32 gives the charge control device 30 a maximum profile setting instruction for one or a plurality of normal devices.

When the information processing device 32 finishes the process of S231, the information processing device 32 advances the process to S232. Then, in S232, the information processing apparatus 32 returns the process to S221, waits for the process for a predetermined time (for example, 5 minutes or 10 minutes), and advances the process to S222.

In the processing of S225, the information processing device 32 gives a priority power setting instruction to the priority device in which the maximum input power amount before the change and the maximum input power amount after the change match among one or more priority devices. Does not have to be given. As a result, the information processing device 32 can reduce the processing for the priority device that does not change the maximum input power amount.

Further, in the process of S226, the information processing device 32 does not give the maximum profile setting instruction to the priority device in which the power profile before the change and the power profile after the change match among one or more priority devices. May be good. As a result, the information processing device 32 can eliminate the processing of the power delivery sequence with the priority device that does not change the power profile.

Further, in the processing of S230, the information processing device 32 gives an input power setting instruction to one or a plurality of normal devices in which the average power amount before the change and the average power amount after the change match. It does not have to be. As a result, the information processing device 32 can reduce the processing for the normal device that does not change the maximum input power amount.

Further, in the process of S231, the information processing apparatus 32 does not give the maximum profile setting instruction to the ordinary apparatus in which the power profile before the change and the electric power profile after the change match among one or a plurality of ordinary devices. May be good. As a result, the information processing device 32 can eliminate the processing of the power delivery sequence with the normal device that does not change the power profile.

FIG. 15 is a diagram showing a processing flow when a priority power setting instruction and an input power setting instruction are given in the information processing system 10 according to the second embodiment.

When the information processing device 32 gives a priority power setting instruction and a maximum profile setting instruction to the charge control device 30 (S225, S226), the information processing system 10 executes the processes of S241 to S244.

First, the charge control device 30 transmits a maximum input power setting command for setting the maximum power to be input to the first power amount according to the maximum power consumption by using the VDM signal (VDM signal). S241).

Subsequently, the priority device sets the maximum power input via the cable 34 to the first power amount according to the maximum power consumption (S242). As a result, the priority device controls the power consumption so that the power consumption larger than the set first power amount is not received via the cable 34 thereafter. The priority device transmits information indicating completion to the charge control device 30 by means of a VDM signal (S243).

Upon receiving the completion information, the charge control device 30 executes a power delivery sequence with the priority device so that the voltage and current are supplied according to the maximum power profile (S244).

Further, when the information processing device 32 gives an input power setting instruction and a maximum profile setting instruction to the charge control device 30 (S230, S231), the information processing system 10 executes the processes of S245 to S248.

First, the charge control device 30 transmits a maximum input power setting command for setting the maximum input power to the average power amount by the VDM signal to each of the one or a plurality of normal devices (S245). ..

Subsequently, the normal device sets the maximum electric power input via the cable 34 to the average electric energy (S246). As a result, the normal device controls the power consumption so as not to receive power larger than the set average power amount via the cable 34 thereafter. Subsequently, the normal device transmits information indicating completion to the charge control device 30 by means of a VDM signal (S247).

Upon receiving the completion information, the charge control device 30 executes a power delivery sequence with the normal device having completed the setting of the average electric energy so that the voltage and the current are supplied according to the maximum power profile ( S248).

The charging cabinet 26 (control device) according to the second embodiment as described above has the following effects.

The charging cabinet 26 according to the second embodiment determines one or a plurality of priority devices based on the remaining amount of each of the plurality of terminal devices 20. Further, the charging cabinet 26 charges and controls a priority power setting instruction for setting the maximum power input via the cable 34 to the first power amount according to the maximum power consumption for each of the one or a plurality of priority devices. Give to device 30. Further, the charging cabinet 26 gives the charging control device 30 a maximum profile setting instruction, which is a profile setting instruction for setting a power profile for each of the one or a plurality of priority devices to the maximum power profile. Further, the charging cabinet 26 charges a profile setting instruction for setting a power profile for each of the one or more normal devices so that the amount of power supplied to the one or more normal devices does not exceed the excess power. It is given to the control device 30. As a result, according to the charging cabinet 26, electric power can be appropriately distributed to the plurality of terminal devices 20 to efficiently charge the terminals.

The charging cabinet 26 according to the second embodiment calculates the average electric energy divided by the number of one or a plurality of normal devices, and averages the maximum power input to each of the plurality of normal devices via the cable 34. The charge control device 30 is given an input power setting instruction for setting the electric energy and a maximum profile setting instruction for setting the power profile for each of the plurality of normal devices to the maximum power profile. As a result, according to the charging cabinet 26, electric power can be supplied to one or a plurality of ordinary devices so as not to exceed the amount of surplus electric power.

Further, the charging cabinet 26 according to the second embodiment sets the power profile for a part of one or a plurality of normal devices to the maximum power profile, and sets the power profile for the other part of the one or a plurality of normal devices. Set the power profile of to the default power profile. Then, the charging cabinet 26 sequentially changes some of the normal devices set in the maximum power profile of the one or a plurality of normal devices at predetermined time intervals. As a result, according to the charging cabinet 26, electric power can be supplied to one or a plurality of ordinary devices so as not to exceed the amount of surplus electric power.

Further, the charging cabinet 26 according to the second embodiment has a plurality of terminals 20 having a remaining amount equal to or less than a preset threshold value and a predetermined number of terminals starting from the one with the smallest remaining amount. Device 20 is determined as one or more priority devices. As a result, according to the charging cabinet 26, the terminal device 20 having a small remaining amount can be preferentially charged.

Further, in the charging cabinet 26 according to the second embodiment, when the remaining amount of the priority device of any one of the one or a plurality of priority devices becomes larger than the preset threshold value, a new one or a plurality of the charging cabinet 26 is used. Determine the priority device for. Further, the charging cabinet 26 gives the charging control device 30 a priority power setting instruction and a maximum profile setting instruction for each of the one or more priority devices when one or more priority devices are changed, and one or more of them. A profile setting instruction for each of one or a plurality of normal devices is given to the charge control device 30 so that the amount of power supplied to the normal device does not exceed the surplus power amount. Thereby, according to the charging cabinet 26 according to the second embodiment, a new one or a plurality of priority devices can be determined at an appropriate timing.

Further, when setting the power profile, the charging cabinet 26 according to the second embodiment sets the power delivery sequence for determining the combination of the supplied voltage and the current with the designated terminal device 20 among the plurality of terminal devices 20. Run. As a result, according to the charging cabinet 26, the power profile for each of the plurality of terminal devices 20 can be set by the processing conforming to the USB-C standard.

Further, the charging cabinet 26 according to the second embodiment exchanges VDM signals with each of the plurality of terminal devices 20 via the cable 34 to obtain the remaining amount and the maximum power consumption of each of the plurality of terminal devices 20. get. As a result, according to the charging cabinet 26, the remaining amount and the maximum power consumption can be obtained from each of the plurality of terminal devices 20 by the processing conforming to the USB-C standard.

Further, the charging cabinet 26 according to the second embodiment further includes a storage unit 28 that stores a plurality of terminal devices 20 so that they can be taken out by a user. As a result, the charging cabinet 26 can be charged while storing the plurality of terminal devices 20.

(Third Embodiment)
Next, the information processing system 10 according to the third embodiment will be described. The information processing system 10 according to the third embodiment has the same hardware configuration as the first embodiment and the second embodiment.

FIG. 16 is a diagram showing a functional configuration of the information processing apparatus 32 according to the third embodiment. The information processing device 32 according to the third embodiment includes a connection detection unit 114, a remaining amount acquisition unit 212, a power-on acquisition unit 312, a start setting instruction unit 314, a surplus power calculation unit 218, and an average power calculation unit. It includes an 116, an input setting instruction unit 118, and a wakeup instruction unit 316.

The information processing device 32 according to the third embodiment includes a connection detection module, a remaining amount acquisition module, a power-on acquisition module, a start setting instruction module, a surplus power calculation module, an average power calculation module, an input setting instruction module, and a wakeup instruction module. By executing a predetermined program including, connection detection unit 114, remaining amount acquisition unit 212, power-on acquisition unit 312, start setting instruction unit 314, surplus power calculation unit 218, average power calculation unit 116, input setting instruction unit It functions as 118 and a wake-up indicator 316. The information processing device 32 includes a connection detection unit 114, a remaining amount acquisition unit 212, a power-on acquisition unit 312, a start setting instruction unit 314, a surplus power calculation unit 218, an average power calculation unit 116, an input setting instruction unit 118, and a wake. A part or all of the up instruction unit 316 may be configured by hardware.

The connection detection unit 114 acquires connection information from the charge control device 30. Then, the connection detection unit 114 registers the terminal device 20 connected to the charge control device 30 in the memory or the like.

The remaining amount acquisition unit 212 acquires the remaining amount of the battery 70 for each of the plurality of terminal devices 20 connected to the charge control device 30. For example, the remaining amount acquisition unit 212 periodically acquires the remaining amount for each of the plurality of terminal devices 20. The remaining amount of the battery 70 is expressed as a percentage, for example.

The power-on acquisition unit 312 acquires power-on information for turning on the target device, which is any one of the plurality of terminal devices 20.

In the present embodiment, the terminal device 20 maintains the off state when the power switch 74 is operated by the user in the off state, that is, indicates that the operation of turning on the power switch 74 without turning it on is performed. The power-on information is transmitted to the charge control device 30 via the cable 34. When the charge control device 30 receives the power-on information from any of the plurality of terminal devices 20 connected via the cable 34, the charge control device 30 together with the identification information of the terminal device 20 that has transmitted the power-on information. The power-on information is transmitted to the information processing device 32. As a result, the power-on acquisition unit 312 can acquire the power-on information for turning on the target device.

Further, the information processing device 32 provides power-on information for turning on any of the plurality of terminal devices 20 connected to the charge control device 30 by remote operation from another computer, server, or the like. You may get it. Even in such a case, the power-on acquisition unit 312 can acquire the power-on information for turning on the target device.

The activation setting instruction unit 314 gives an activation profile setting instruction to the charge control device 30 when the power-on acquisition unit 312 acquires the power-on information. The start-up profile setting instruction is a profile setting instruction for setting the power profile for the target device to the start-up power profile indicating a combination of voltage and current in which the target device in the started state can operate. For example, the activation profile setting instruction may be a profile setting instruction for setting the power profile for the target device to the maximum power profile indicating the maximum power that can be supplied. When the start profile setting instruction is received from the information processing device 32, the charge control device 30 executes a power delivery sequence with the target device so that the voltage and current are supplied by the start power profile.

The activation setting instruction unit 314 acquires the remaining amount of the battery 70 of the target device from the remaining amount acquisition unit 212, and compares the acquired remaining amount of the battery 70 with a predetermined threshold value. Then, the activation setting instruction unit 314 may give an activation profile setting instruction to the charge control device 30 when the remaining amount is smaller than a predetermined threshold value. That is, when the remaining amount is equal to or higher than a predetermined threshold value, the activation setting instruction unit 314 does not give the activation profile setting instruction to the charge control device 30 even when the power-on information is acquired. Here, the threshold value is the remaining amount that allows the terminal device 20 to operate in the ON state without extracting power from the cable 34.

The surplus power calculation unit 218 acquires the total power amount. Further, the surplus power calculation unit 218 acquires the amount of power indicated in the start power profile when the power profile for the target device is set in the start power profile by the start setting instruction unit 314. Then, the surplus power calculation unit 218 calculates the surplus power amount obtained by subtracting the power amount shown in the starting power profile from the total power amount.

The average power calculation unit 116 calculates the number of one or more non-target devices. One or a plurality of non-target devices is one or a plurality of terminal devices 20 excluding the target device among the plurality of terminal devices 20. Further, the average power calculation unit 116 acquires the surplus power amount calculated by the surplus power calculation unit 218. Then, the average power calculation unit 116 calculates the average power amount obtained by dividing the surplus power amount by the number of one or a plurality of non-target devices. In the present embodiment, the average electric energy represents the amount of electric power that can be supplied per unit when the electric power is supplied to one or a plurality of non-target devices on an average basis.

The input setting instruction unit 118 gives an input power setting instruction to the charge control device 30. In the present embodiment, the input power setting instruction is an instruction to set the maximum power input to each of one or a plurality of non-target devices via the cable 34 to the average power amount.

When the input power setting instruction is received from the information processing device 32, the charge control device 30 causes one or a plurality of non-target devices to set the maximum power input via the cable 34 to the average power amount. Sends a command to set the maximum input power for. The terminal device 20 that receives such a setting command from the charge control device 30 controls the power consumption so that the power larger than the average power amount is not received via the cable 34.

Further, the input setting instruction unit 118 gives the charge control device 30 a maximum profile setting instruction for each of the one or a plurality of non-target devices. Upon receiving the maximum profile setting instruction from the information processing device 32, the charge control device 30 executes a power delivery sequence with each of the one or more non-target devices so that the voltage and current are supplied by the maximum power profile. ..

The wake-up instruction unit 316 gives a wake-up instruction to start the target device to the charge control device 30 after the power profile for the target device is set in the start power profile by the start setting instruction unit 314.

When the charge control device 30 receives the wake-up instruction, the charge control device 30 transmits the wake-up instruction to the target device via the cable 34. When the wake-up command is received, the target device switches the power state from the off state to the on state. In this case, the target device can receive the power indicated in the starting power profile from the charge control device 30 via the cable 34. Therefore, the target device can continue to operate without shutting down even when the remaining amount of the battery 70 is low.

In the third embodiment, the input setting instruction unit 118 is provided for each of the one or more non-target devices so that the amount of power supplied to the one or more non-target devices does not exceed the surplus power amount. Other processing may be executed as long as the charge control device 30 is configured to give a profile setting instruction for setting the power profile.

For example, the input setting instruction unit 118 may give a profile setting instruction for one or a plurality of non-target devices to the charge control device 30 so that one or a plurality of non-target devices are charged in rotation.

When rotating charging, the input setting indicator 118 sets the power profile for a part of one or more non-target devices to the maximum power profile, and sets the power profile for one or more other non-target devices. Set the power profile for the unit to the default power profile. Then, in the case of rotating charging, the input setting instruction unit 118 sequentially changes some of the non-target devices set in the maximum power profile of one or a plurality of non-target devices at predetermined time intervals. As a result, the input setting indicator 118 sets the power profile for each of the one or more non-target devices so that the amount of power supplied to the one or more non-target devices does not exceed the surplus power amount. A profile setting instruction can be given to the charge control device 30.

FIG. 17 is a diagram showing a processing flow of the information processing system 10 according to the third embodiment. The information processing system 10 according to the third embodiment executes processing in the flow as shown in FIG.

First, the user operates the power switch 74 of any of the terminal devices 20 (target device) in the off state among the plurality of terminal devices 20 connected to the charge control device 30 via the cable 34 (S311). ). When the power switch 74 is operated, the target device maintains the off state and transmits the power-on information to the charge control device 30 by the VDM signal (S312).

When the charge control device 30 receives the power-on information from the target device, the charge control device 30 transmits the power-on information to the information processing device 32 together with the identification information of the target device that has transmitted the power-on information (S313).

The information processing device 32 that has received the power-on information acquires the remaining amount of the battery 70 of the target device (S314). For example, the information processing device 32 periodically collects the remaining amount of the plurality of terminal devices 20 and stores them in the memory. In this case, the information processing device 32 reads the remaining amount of the battery 70 of the target device from the memory. For example, the information processing device 32 may give an instruction to transmit the remaining amount to the charge control device 30 to cause the target device to transmit the remaining amount of the battery 70. In addition, the target device may also transmit the remaining amount of the battery 70 when transmitting the power-on information.

Subsequently, the information processing device 32 compares the remaining amount with a predetermined threshold value (S315). When the remaining amount of the battery 70 of the target device is not smaller than the threshold value (No in S315), the information processing device 32 advances the process to S332 in FIG.

When the remaining amount of the battery 70 of the target device is smaller than the threshold value (Yes in S315), the information processing device 32 gives an activation profile setting instruction to the charge control device 30 (S316).

Subsequently, the charge control device 30 executes a power delivery sequence with the target device so that the voltage and current are supplied according to the starting power profile (S317).

As in the first embodiment or the second embodiment, the target device may set the maximum amount of electric power that can be input via the cable 34. In this case, the target device cannot receive power via the cable 34 in excess of the set amount of power. Therefore, in this case, the charge control device 30 transmits the release command of the maximum input power to the target device by the VDM signal (S318). When receiving the maximum input power release command, the target device cancels the setting of the maximum input power (S319). As a result, the target device can receive power via the cable 34 up to the voltage and current indicated by the starting power profile.

FIG. 18 is a diagram showing a processing flow of the information processing system 10 following FIG. The information processing system 10 according to the third embodiment executes the processing in the flow as shown in FIG. 18 following the processing shown in FIG.

After giving the start-up profile setting instruction, the information processing apparatus 32 calculates the surplus power amount obtained by subtracting the power amount shown in the start-up power profile from the total power amount (S321). Subsequently, the information processing device 32 calculates the average power amount obtained by dividing the surplus power amount by the number of one or a plurality of non-target devices (S322).

Subsequently, the information processing device 32 gives an input power setting instruction for one or a plurality of non-target devices to the charge control device 30 (S323). Subsequently, the information processing device 32 gives a maximum profile setting instruction for one or a plurality of non-target devices to the charge control device 30 (S324).

Subsequently, the charge control device 30 transmits a maximum input power setting command for setting the maximum input power to the average power amount by the VDM signal to each of the one or a plurality of non-target devices ((). S325).

Subsequently, the non-target device sets the maximum input power to the average electric energy (S326). As a result, the non-target device controls the power consumption so as not to receive power larger than the set average power amount via the cable 34 thereafter. Subsequently, the non-target device transmits information indicating completion to the charge control device 30 by the VDM signal (S327).

Upon receiving the completion information, the charge control device 30 executes a power delivery sequence so that the voltage and current are supplied according to the maximum power profile with the non-target device for which the average electric energy setting has been completed. (S328).

FIG. 19 is a diagram showing a processing flow of the information processing system 10 following FIG. The information processing system 10 according to the third embodiment executes the processing in the flow as shown in FIG. 19 following the processing shown in FIG.

When the charge control device 30 completes the setting of the maximum power to be input and the power delivery sequence with all of the one or a plurality of non-target devices, the charge control device 30 transmits information indicating the completion to the information processing device 32 (S331). ..

When the information processing device 32 receives the information indicating the completion, the information processing device 32 gives a wake-up instruction to activate the target device to the charge control device 30 (S332). Further, even when the power-on information is received from the target device and the remaining amount of the battery 70 of the target device is not smaller than the threshold value (No in S315), the information processing device 32 charges the wake-up instruction. It is given to the control device 30.

When the wake-up instruction is received, the charge control device 30 transmits the wake-up instruction to the target device by the VDM signal (S333). When the wake-up command is received, the target device switches the power supply state from the off state to the on state (S334). As a result, the target device can receive the power indicated in the starting power profile from the charge control device 30 via the cable 34. Therefore, the target device can continue to operate without shutting down even when the remaining amount of the battery 70 is low.

The charging cabinet 26 (control device) according to the third embodiment as described above has the following effects.

The charging cabinet 26 according to the third embodiment acquires power-on information for turning on the target device, which is the terminal device 20 of any one of the plurality of terminal devices 20. Further, when the charging cabinet 26 acquires the power-on information, the charging cabinet 26 gives a start-up profile setting instruction to set the power profile for the target device to the start-up power profile indicating the combination of voltage and current in which the target device in the start-up state can operate. It is given to the charge control device 30. Further, the charging cabinet 26 gives a wake-up instruction to activate the target device to the charging control device 30 after the power profile for the target device is set in the starting power profile. As a result, according to the charging cabinet 26, even when any of the terminal devices 20 (target device) of the plurality of terminal devices 20 is turned on, the terminal device 20 (target device) turned on is turned on. The device) can be reliably supplied with power.

Further, the charging cabinet 26 according to the third embodiment gives an activation profile setting instruction to the charging control device 30 when the remaining amount of the battery 70 of the target device is smaller than a predetermined threshold value. As a result, according to the charging cabinet 26, if the target device can be operated by the battery 70, the power supply to the other terminal device 20 can be increased.

Further, in the charging cabinet 26 according to the third embodiment, when the power profile for the target device is set to the starting power profile, the power indicated in the starting power profile is obtained from the total amount of power that can be supplied from the charge control device 30. Calculate the amount of surplus power after subtracting the amount. The amount of power supplied to the charging cabinet 26 to one or a plurality of non-target devices, which is one or a plurality of terminal devices 20 excluding the target device among the plurality of terminal devices 20, does not exceed the surplus power amount. As described above, the charge control device 30 is given a profile setting instruction for setting a power profile for each of the one or a plurality of non-target devices. As a result, according to the charging cabinet 26, electric power can be appropriately distributed to the plurality of terminal devices 20 to efficiently charge the terminals.

The charging cabinet 26 according to the third embodiment calculates the average electric energy obtained by dividing the surplus electric energy by the number of one or a plurality of non-target devices. Then, the charging cabinet 26 receives an input power setting instruction for setting the maximum power input to each of the plurality of non-target devices via the cable 34 to the average power amount, and each of the plurality of non-target devices. The charge control device 30 is given a maximum profile setting instruction for setting the power profile to the maximum power profile. Thereby, according to the charging cabinet 26, power can be supplied to one or more non-target devices so as not to exceed the surplus electric energy.

Further, the charging cabinet 26 according to the third embodiment sets the power profile for a part of one or a plurality of non-target devices to the maximum power profile, and sets the power profile to the maximum power profile, and sets the power profile to the other one of the one or a plurality of non-target devices. Set the power profile for the unit to the default power profile. Then, the charging cabinet 26 sequentially changes some of the non-target devices set in the maximum power profile of the one or a plurality of non-target devices at predetermined time intervals. Thereby, according to the charging cabinet 26, power can be supplied to one or more non-target devices so as not to exceed the surplus electric energy.

Further, when setting the power profile, the charging cabinet 26 according to the third embodiment sets the power delivery sequence for determining the combination of the supplied voltage and the current with the designated terminal device 20 among the plurality of terminal devices 20. Run. As a result, according to the charging cabinet 26, the power profile for each of the plurality of terminal devices 20 can be set by the processing conforming to the USB-C standard.

Further, the charging cabinet 26 according to the third embodiment further includes a storage unit 28 that stores a plurality of terminal devices 20 so that they can be taken out by a user. As a result, the charging cabinet 26 can be charged while storing the plurality of terminal devices 20.

(Programs, etc.)
The program executed by the charge control device 30 or the terminal device 20 of each of the above-described embodiments is a file in an installable format or an executable format, and is a CD-ROM, a flexible disk (FD), a CD-R, or a DVD (Digital). It is recorded and provided on a computer-readable recording medium such as Versatile Disk).

Further, the program executed by the charge control device 30 or the terminal device 20 of each of the above-described embodiments is stored on a computer connected to a network such as the Internet, and is provided by being downloaded via the network. You may. Further, the program executed by the charge control device 30 or the terminal device 20 of each of the above-described embodiments may be configured to be provided or distributed via a network such as the Internet. Further, the program executed by the charge control device 30 or the terminal device 20 of each of the above-described embodiments may be configured to be provided by incorporating it into a ROM or the like in advance.

Although some embodiments of the present invention have been described, these embodiments are presented as examples and are not intended to limit the scope of the invention. These novel embodiments can be implemented in various other embodiments, and various omissions, replacements, and changes can be made without departing from the gist of the invention. These embodiments and modifications thereof are included in the scope and gist of the invention, and are also included in the scope of the invention described in the claims and the equivalent scope thereof.

10 Information processing system 20 Terminal device 22 School server 24 Wireless communication device 26 Charging cabinet 28 Storage unit 30 Charging control device 32 Information processing device 34 Cable 36 Power tap 38 AC adapter 40 Internal communication cable 42 Upper conversion unit 44 Device control unit 46 Terminal control unit 52 Charging side PD controller 54 Charging side communication processor 56 Lower conversion unit 58 Charging side power supply unit 62 Terminal side PD controller 64 Terminal side communication processor 66 Processing circuit 68 Wireless communication unit 70 Battery 72 Terminal side power supply unit 74 Power switch 114 Connection detection unit 116 Average power calculation unit 118 Input setting instruction unit 212 Remaining amount acquisition unit 214 Priority terminal determination unit 216 Priority setting instruction unit 218 Surplus power calculation unit 312 Power on acquisition unit 314 Start setting instruction unit 316 Wake-up instruction unit

The control device according to the first aspect of the present invention is a control device that controls power supply to a plurality of terminal devices, and can be connected to each of the plurality of terminal devices via a cable, and the plurality of terminal devices can be connected to each other via a cable. A charge control unit that performs information communication with each of the above cables via the cable and supplies power to each of the plurality of terminal devices via the cable according to a power profile indicating a combination of voltage and current, and the charge control unit. For each of the plurality of connected terminal devices, a remaining amount acquisition unit that acquires the remaining amount of the battery and the maximum power consumption corresponding to the remaining amount, and the remaining amount of each of the plurality of terminal devices. Based on the above, the priority terminal determination unit for determining one or a plurality of priority devices, which is one or a plurality of terminal devices to be preferentially charged among the plurality of terminal devices, and the one or a plurality of priority devices, respectively. A priority power setting instruction is given to the charge control unit to set the maximum electric energy input via the cable to the maximum electric energy or the first electric energy which is the electric energy obtained by adding a predetermined margin to the maximum electric energy. Thereby, the corresponding priority device is made to control the electric energy consumption so as not to receive the electric energy larger than the first electric energy through the cable , and the electric energy for each of the one or a plurality of priority devices. From the priority setting instruction unit that gives the maximum profile setting instruction, which is the profile setting instruction to set the maximum power profile indicating the maximum power that can be supplied, to the charge control unit, and the total electric energy that can be supplied from the charge control unit. , Excluding the surplus electric energy calculation unit for calculating the surplus electric energy obtained by subtracting the total of the first electric energy set for the one or the plurality of priority devices, and the one or the plurality of priority devices among the plurality of terminal devices. Alternatively, profile setting for setting the power profile for each of the one or more normal devices so that the amount of power supplied to one or more normal devices, which are a plurality of terminal devices, does not exceed the surplus electric energy. It includes an input setting instruction unit that gives an instruction to the charge control unit.

The information processing device according to the second aspect of the present invention is an information processing device that controls a charge control unit that supplies electric energy to a plurality of terminal devices, and the charge control unit is each of the plurality of terminal devices. And can be connected via a cable, information communication is performed with each of the plurality of terminal devices via the cable, and the cable indicates each of the plurality of terminal devices according to a power profile indicating a combination of voltage and current. The information processing device acquires the remaining amount of the battery and the maximum electric energy according to the remaining amount for each of the plurality of terminal devices connected to the charge control unit. Priority for determining one or a plurality of priority devices which are one or a plurality of terminal devices to be preferentially charged among the plurality of terminal devices based on the remaining amount acquisition unit and the remaining amount of each of the plurality of terminal devices. The maximum electric energy input via the cable for each of the terminal determination unit and the one or the plurality of priority devices is the maximum electric energy or the electric energy obtained by adding a predetermined margin to the maximum power consumption . By giving a priority electric energy setting instruction to be set to one electric energy to the charge control unit, the electric energy consumption is controlled so that the corresponding priority device does not receive electric energy larger than the first electric energy through the cable. it is allowed, and the priority to give maximum profile setting instructing a profile setting instruction for setting the maximum power profile indicating the maximum power capable of supplying the power profile for each of the one or more priority device to the charge control unit A setting instruction unit, a surplus power calculation unit that calculates a surplus electric energy obtained by subtracting the total of the first electric energy set for the one or a plurality of priority devices from the total electric energy that can be supplied from the charge control unit. The above 1 so that the amount of power supplied to one or a plurality of normal devices which are one or a plurality of terminal devices excluding the one or a plurality of priority devices among the plurality of terminal devices does not exceed the surplus electric energy. Alternatively, it includes an input setting instruction unit that gives a profile setting instruction for setting the power profile for each of the plurality of normal devices to the charge control unit.

The program according to the third aspect of the present invention is a program for operating a computer as an information processing device that controls a charge control unit that supplies electric energy to a plurality of terminal devices, and the charge control unit is the above-mentioned. It is possible to connect to each of the plurality of terminal devices via a cable, perform information communication with each of the plurality of terminal devices via the cable, and use a power profile indicating a combination of voltage and current to obtain the plurality of terminal devices. Power is supplied to each via the cable, and the computer is connected to the charge control unit for each of the plurality of terminal devices, the remaining amount of the battery and the maximum power consumption according to the remaining amount. One or a plurality of priority devices which are one or a plurality of terminal devices to be preferentially charged among the plurality of terminal devices based on the remaining amount acquisition unit for acquiring the amount and the remaining amount of each of the plurality of terminal devices. For each of the priority terminal determination unit and the one or more priority devices, the maximum power input via the cable is the maximum power consumption or the maximum power consumption plus a predetermined margin. By giving a priority power setting instruction to set the first electric energy, which is an amount, to the charge control unit, the electric energy of the corresponding priority device is prevented from receiving electric energy larger than the first electric energy through the cable. is controlled consumption, and the one or the said charge control the maximum profile setting instruction is a profile setting instruction for setting the maximum power profile indicating the maximum power capable of supplying power profile for each of the plurality of priority devices Surplus electric energy calculated by subtracting the total of the first electric energy set for the one or more priority devices from the total electric energy that can be supplied from the priority setting instruction unit given to the unit and the charge control unit. The amount of power supplied to the calculation unit and one or more normal devices, which are one or more terminal devices excluding the one or more priority devices among the plurality of terminal devices, does not exceed the surplus electric energy. To function as an input setting instruction unit that gives a profile setting instruction for setting the power profile for each of the one or a plurality of normal devices to the charge control unit.

Claims (10)

A control device that controls the power supply to multiple terminal devices.
The plurality of terminal devices can be connected to each of the plurality of terminal devices via a cable, information communication is performed with each of the plurality of terminal devices via the cable, and the plurality of terminal devices are described by a power profile indicating a combination of voltage and current. A charge control unit that supplies power to each of the above cables via the cable,
The remaining amount of the battery for each of the plurality of terminal devices connected to the charge control unit, and the remaining amount acquisition unit for acquiring the maximum power consumption according to the remaining amount.
A priority terminal determination unit that determines one or a plurality of priority devices, which are one or a plurality of terminal devices to be preferentially charged among the plurality of terminal devices, based on the remaining amount of each of the plurality of terminal devices.
For each of the one or more priority devices, a priority power setting instruction for setting the maximum power input via the cable to the first power amount corresponding to the maximum power consumption, and the one or more priority devices. A priority setting instruction unit that gives a maximum profile setting instruction, which is a profile setting instruction for setting the maximum power profile indicating the maximum power that can supply the power profile for each of the devices, to the charge control unit.
A surplus power calculation unit that calculates a surplus power amount obtained by subtracting the total of the first power amounts set for the one or a plurality of priority devices from the total power amount that can be supplied from the charge control unit.
The 1 Alternatively, an input setting instruction unit that gives a profile setting instruction for setting the power profile for each of the plurality of normal devices to the charge control unit, and an input setting instruction unit.
A control device comprising. Further provided with an average power calculation unit for calculating the average power amount obtained by dividing the surplus power amount by the number of the one or a plurality of normal devices.
The input setting instruction unit sets an input power setting instruction for setting the maximum power input to each of the one or a plurality of normal devices via the cable to the average power amount, and the one or a plurality of normal devices. The control device according to claim 1, wherein the maximum profile setting instruction is given to the charge control unit for each of the devices. The input setting indicator is
The power profile for a part of the one or more conventional devices is set to the maximum power profile, and the power profile for the other part of the one or more normal devices is set to the minimum voltage. Set to a default power profile that shows the combination of and minimum current
The control device according to claim 1, wherein some of the normal devices set in the maximum power profile among the one or a plurality of normal devices are sequentially changed at predetermined time intervals. The priority terminal determination unit selects a predetermined number of terminal devices from the plurality of terminal devices whose remaining amount is equal to or less than a preset threshold value and whose remaining amount is the smallest. The control device according to any one of claims 1 to 3, which is determined as one or a plurality of priority devices. When the remaining amount of the priority device of any one of the one or a plurality of priority devices becomes larger than a preset threshold value, the priority terminal determination unit is a new priority device. Decide,
When the one or more priority devices are changed
The priority setting instruction unit gives the priority power setting instruction and the maximum profile setting instruction for each of the one or a plurality of priority devices to the charge control unit.
The input setting instruction unit charges the profile setting instruction for each of the one or more normal devices so that the amount of power supplied to the one or more normal devices does not exceed the surplus electric energy. The control device according to any one of claims 1 to 4, which is given to the control unit. The cable complies with the USB-C (Universal Serial Bus) standard.
When setting the power profile, the charge control unit executes a power delivery sequence for determining a combination of voltage and current to be supplied with a designated terminal device among the plurality of terminal devices, claims 1 to 5. The control device according to any one of the above items. The charge control unit exchanges a VDM (Vendor Define Messaging) signal with each of the plurality of terminal devices via the cable, thereby causing the remaining amount and the maximum power consumption of each of the plurality of terminal devices. The control device according to claim 6. The control device according to any one of claims 1 to 7, further comprising a storage unit for storing the plurality of terminal devices so that they can be taken out by a user. An information processing device that controls a charge control unit that supplies power to multiple terminal devices.
The charge control unit can be connected to each of the plurality of terminal devices via a cable, performs information communication with each of the plurality of terminal devices via the cable, and has a power profile showing a combination of voltage and current. Power is supplied to each of the plurality of terminal devices via the cable.
The information processing device
The remaining amount of the battery for each of the plurality of terminal devices connected to the charge control unit, and the remaining amount acquisition unit for acquiring the maximum power consumption according to the remaining amount.
A priority terminal determination unit that determines one or a plurality of priority devices, which are one or a plurality of terminal devices to be preferentially charged among the plurality of terminal devices, based on the remaining amount of each of the plurality of terminal devices.
For each of the one or more priority devices, a priority power setting instruction for setting the maximum power input via the cable to the first power amount corresponding to the maximum power consumption, and the one or more priority devices. A priority setting instruction unit that gives a maximum profile setting instruction, which is a profile setting instruction for setting the maximum power profile indicating the maximum power that can supply the power profile for each of the devices, to the charge control unit.
A surplus power calculation unit that calculates a surplus power amount obtained by subtracting the total of the first power amounts set for the one or a plurality of priority devices from the total power amount that can be supplied from the charge control unit.
The 1 Alternatively, an input setting instruction unit that gives a profile setting instruction for setting the power profile for each of the plurality of normal devices to the charge control unit, and an input setting instruction unit.
Information processing device equipped with. A program for operating a computer as an information processing device that controls a charge control unit that supplies power to a plurality of terminal devices.
The charge control unit can be connected to each of the plurality of terminal devices via a cable, performs information communication with each of the plurality of terminal devices via the cable, and has a power profile showing a combination of voltage and current. Power is supplied to each of the plurality of terminal devices via the cable.
The computer
The remaining amount of the battery for each of the plurality of terminal devices connected to the charge control unit, and the remaining amount acquisition unit for acquiring the maximum power consumption according to the remaining amount.
A priority terminal determination unit that determines one or a plurality of priority devices, which are one or a plurality of terminal devices to be preferentially charged among the plurality of terminal devices, based on the remaining amount of each of the plurality of terminal devices.
For each of the one or more priority devices, a priority power setting instruction for setting the maximum power input via the cable to the first power amount corresponding to the maximum power consumption, and the one or more priority devices. A priority setting instruction unit that gives a maximum profile setting instruction, which is a profile setting instruction for setting the maximum power profile indicating the maximum power that can supply the power profile for each of the devices, to the charge control unit.
A surplus power calculation unit that calculates a surplus power amount obtained by subtracting the total of the first power amounts set for the one or a plurality of priority devices from the total power amount that can be supplied from the charge control unit.
The 1 Alternatively, a program that functions as an input setting instruction unit that gives a profile setting instruction for setting the power profile for each of a plurality of normal devices to the charge control unit.

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