JP2021065006A - Virtual grid hub port unit, virtual grid control device, virtual grid system, and program - Google Patents

Abstract

To provide a virtual grid hub port unit by which dynamic zoning in a power supply network can be performed according to power receiving/supplying authorities.SOLUTION: Virtual grid hub port units are coupled together to form a virtual grid. Each virtual grid hub port unit includes: a plurality of power bus terminals that transmit power by being connected to another virtual grid hub port unit; a device connection terminal that transmits power by being connected to a load device or a power source device; a power control section that controls and outputs inputted power in accordance with a control command from another device; and a switch that connects or disconnects the power bus terminals, connects or disconnects the power bus terminals and the power control section, and connects or disconnects the device connection terminal and the power control section, in accordance with a control command from the other device.SELECTED DRAWING: Figure 4

Description

The present invention relates to a virtual grid hub port unit, a virtual grid control device, a virtual grid system, and a program.

Today, USB (Universal Serial Bus) is widely used as a power supply means for battery-powered devices such as smartphones, as well as interfaces for information devices such as personal computers. In recent years, a new standard for supplying power to USB interfaces called USB PD (USB Power Delivery) has been established.

The USB PD can supply up to 100W of power, and a roll swap function has been introduced that reverses the relationship between the power supply and load without changing the cable connection status. With this function, it is possible to connect a power supply and load (hereinafter, also referred to as a power supply device and a load device, or collectively referred to as a device) with a hub, and to control the relationship between the power supply and the load and the amount of power supply by a computer. became. However, it is assumed that a single power supply and multiple loads are connected, and multiple power supplies (power supply group) and multiple loads (load group) are connected to the hub, and the total power supply capacity of the power supply group is adjusted to the load group. There is no function to allocate and provide to.

When the power or electric energy required by one load exceeds the capacity of individual power sources, the load requirements cannot be satisfied even if the power supply group has a power supply capacity exceeding the load requirements. For example, the output power of a storage battery for a smartphone is often smaller than the power required by a personal computer, and even if a plurality of such batteries are prepared, it is not possible to supply appropriate power to the personal computer. In order to utilize storage batteries with various capacities for battery-powered equipment, which is expected to increase in the future, as a large-scale storage capacity for the entire power grid, the function of intelligently connecting the power supply group and the load group is indispensable. Is.

In order to solve the above problems, a power supply control system (Patent Document 1) that interconnects a power supply group and a load group and provides the load group with the total power supply capacity (output power and electric energy) of the power supply group is disclosed. Has been done.

The power supply control system of Patent Document 1 controls a hub that receives DC power from a plurality of power supply devices and distributes the power to a plurality of load devices, and controls the connection state of the plurality of power supply devices and the plurality of load devices to the hub. It is provided with a controller that issues an instruction to be issued.

JP-A-2019-88109

According to the power supply control system of Patent Document 1, it is possible to realize a power supply network that receives DC power from a plurality of power supply devices and distributes the power to a plurality of load devices. Could not be dynamically zoned to correspond to the authority of. Even if multiple power supply devices are collected, the power output and capacity are often insufficient for the load, or the owners of the power supply devices and load devices may be different, so the device owners are in their own device group. It is also assumed that you want to close and manage power transfer. In addition, even if there is a surplus in the capacity of a certain power device, it is assumed that the surplus should be saved for a specific load group. That is, the power supply device group and the load device group are divided into groups, the power receiving control is made independent in each group, the power distribution control of each group is stabilized, and the surplus power of the group is supplied to other devices. It is assumed that control is desirable.

It is conceivable to network the VG hub by the power supply control system of Patent Document 1, form a zone in the unit of the VG hub, and assign the above group to solve the above problem. In this case, the number of ports of the VG hub is large. There are problems that the zone configuration is fixed and the degree of freedom of zone configuration is low, and that the VG hub and the device must be star-connected, which requires a large amount of cables.

Therefore, in the present invention, the power supply network is dynamically zoned so as to correspond to the authority of power supply / reception, that is, the zone corresponding to the power supply / demand authority is dynamically set, and the power supply / reception within the zone is performed. The purpose is to provide a virtual grid hub port unit that can divide the authority of power supply and reception between zones.

The virtual grid hub port unit of the present invention is a virtual grid hub port unit that is connected to each other to form a virtual grid, and includes a plurality of power bus terminals, a device connection terminal, a power control unit, and a switch.

The plurality of power bus terminals are connected to other virtual grid hub port units to transmit electric power. The device connection terminal is connected to a load device or a power supply device to transmit power. The power control unit controls and outputs the input power according to control commands from other devices. The switch connects or disconnects the power bus terminals to each other, connects or disconnects the power bus terminal and the power control unit, and connects or disconnects the device connection terminal and the power control unit according to a control command from another device. To do.

According to the virtual grid hub port unit of the present invention, the power supply network can be dynamically zoned to correspond to the power receiving and supplying authority.

A block diagram showing an overview of the virtual grid system. The block diagram which shows the structure of the virtual grid control unit. The block diagram which shows the structure of the virtual grid hub controller. A block diagram showing the configuration of a virtual grid hub port unit. The conceptual diagram which shows the virtual grid hub formation example 1 by four units. The conceptual diagram which shows the network of the virtual grid hub equivalent to the state of FIG. The conceptual diagram which shows the virtual grid hub formation example 2 by four units. The conceptual diagram which shows the network of the virtual grid hub equivalent to the state of FIG. The figure which shows the example of the state change in a unit by a switch change. The figure explaining the switch of the unit which has 3 terminals and 3 power control units. The figure which shows the example 1 of the zone setting and the cooperative power supply in the case of a frequency 4. The figure which shows the example 2 of the zone setting and the cooperative power supply in the case of a frequency 4. The figure which shows the functional structure example of a computer.

Hereinafter, embodiments of the present invention will be described in detail. The components having the same function are given the same number, and duplicate explanations will be omitted.

<Virtual Grid System 1>
Hereinafter, the virtual grid system 1 of the first embodiment will be described with reference to FIG. The virtual grid system 1 of the first embodiment has a virtual grid control device 13 that controls the entire virtual grid 6 and a plurality of virtual grid hub control devices 12 that control a virtual grid hub 5 formed by dividing a part of the virtual grid 6. And a plurality of virtual grid hub port units 11 (hereinafter, also referred to as VG-hub port units 11) which are devices constituting the virtual grid 6.

<Virtual grid control device 13>
The virtual grid control device 13 is a device that gives control commands to each of a plurality of VG-hub port units 11-1, 11-2, ... That are connected to a load device or a power supply device and can transmit electric power. FIG. As shown in the above, a virtual grid forming unit 131, a virtual grid hub forming unit 132, and a determination unit 133 are included.

The virtual grid forming unit 131 controls the connection or disconnection between the VG-hub port units to form the virtual grid. For example, in the example of FIG. 1, the virtual grid forming unit 131 connects the VG-hub port unit 11-1 and the VG-hub port unit 11-2, and connects the VG-hub port unit 11-2 and the VG-hub port unit 11. -3 is connected, VG-hub port unit 11-3 and VG-hub port units 11-4 and 11-6 are connected, and VG-hub port unit 11-4 and VG-hub port unit 11-5 are connected. Then, a tree-shaped power supply network formed by connecting the VG-hub port unit 11-6 and the VG-hub port units 11-7 and 11-8, that is, the virtual grid 6 is formed. As the power supply path connecting the VG-hub port units 11 to each other, for example, a USB Type-C cable can be used when the present invention is realized within the power supply capacity of the USB PD. In addition, it is self-evident that the present invention can be applied by using a cable conforming to the standard even if a standard that has further power supply capacity by 48V DC power supply or the like and can be handled safely comes out in the future. is there.

The virtual grid hub forming unit 132 divides the virtual grid by limiting the power supply between some VG-hub port units, and forms the virtual grid hub which is the result of each division. For example, in the example of FIG. 1, the virtual grid hub forming unit 132 divides the virtual grid 6 by limiting the power supply with the VG-hub port unit 11-3 as a boundary, and divides the virtual grid 6 into a virtual grid hub 5-1 (VG). -Consists of hub port units 11-1 and 11-2), virtual grid hub 5-2 (consisting of VG-hub port units 11-4, 11-5, 11-6, 11-7, 11-8) To be).

The determination unit 133 determines whether or not power can be supplied from any virtual grid hub to any other virtual grid hub, and the amount of power supplied. For example, in the example of FIG. 1, the determination unit 133 determines whether or not the power can be supplied from the virtual grid hub 5-1 to the virtual grid hub 5-2 and the amount of power supplied, depending on the amount of surplus power in the virtual grid hub 5-1. Judgment is made according to the power shortage situation in the virtual grid hub 5-2. Similarly, the determination unit 133 determines whether or not the power can be supplied from the virtual grid hub 5-2 to the virtual grid hub 5-1 and the amount of power supplied, the amount of surplus power in the virtual grid hub 5-2, and the virtual grid hub 5. Judgment is made according to the power shortage situation in -1.

<Virtual grid hub controller 12>
The virtual grid hub control device 12 is a device provided corresponding to each virtual grid hub. For example, in the example of FIG. 1, the virtual grid hub control device 12-1 is provided corresponding to the virtual grid hub 5-1 and the virtual grid hub control device 12-2 is provided corresponding to the virtual grid hub 5-2. .. As shown in FIG. 3, the virtual grid hub control device 12 includes a unit control unit 121. The unit control unit 121 gives a control command to each VG-hub port unit in the corresponding virtual grid hub.

The unit control unit 121 executes control to provide the total power supply capacity (output power and electric energy) of the power supply device in the corresponding virtual grid hub to the load device in the corresponding virtual grid hub in a well-balanced manner. For example, in the example of FIG. 1, the unit control unit 121 of the virtual grid hub control device 12-1 balances the total power supply capacity of the power supply devices in the corresponding virtual grid hub 5-1 so that the virtual grid hub 5-1 Performs the controls it provides to the load devices in it. This operation is the same as the operation of the power supply control system of Patent Document 1.

Further, the unit control unit 121 receives the determination of the determination unit 133, and controls the VG-hub port unit located at the boundary of the corresponding virtual grid hub according to the determination. For example, in the example of FIG. 1, the unit control unit 121 of the virtual grid hub control device 12-1 determines whether or not power can be supplied and the amount of power supplied between the virtual grid hub 5-1 and the virtual grid hub 5-2. It executes control of the VG-hub port unit 11-3 located at the boundary between the two hubs.

<VG-hub port unit 11>
The VG-hub port unit 11 is a device that is connected to each other to form a virtual grid. Hereinafter, a configuration example of the VG-hub port unit 11 will be described with reference to FIG. As shown in the figure, the VG-hub port unit 11 of this embodiment includes a plurality of power bus terminals 115, a device connection terminal 111, a power control unit 113, and switches 112 and 114. The power control unit 113 can be realized by, for example, a DC / DC converter or the like.

The plurality of power bus terminals 115 are connected to other VG-hub port units 11 to transmit electric power. The device connection terminal 111 is connected to a load device or a power supply device to transmit electric power. The power control unit 113 controls and outputs the input power according to a control command from another corresponding device (virtual grid hub control device 12). The switches 112 and 114 connect or disconnect the power bus terminals 115 to each other according to control commands from other devices (virtual grid hub control device 12, virtual grid control device 13), and connect or disconnect the power bus terminals 115 from each other, and connect the power bus terminals 115 to the power control unit 113. Is connected or disconnected, and the device connection terminal 111 and the power control unit 113 are connected or disconnected.

Although the VG-hub port unit 11 including three power bus terminals 115 and three power control units 113 is disclosed in the figure, the present invention is not limited to this, and for example, the power bus terminal 115 is set to two terminals. It may be 4 terminals or more. Further, the number of power control units 113 may be one or two, or four or more.

Although the VG-hub port unit 11 having one device connection terminal 111 is disclosed in the figure, the present invention is not limited to this, and the VG-hub port unit 11 omitting the device connection terminal 111 is a virtual grid. It may be contained in a certain ratio. The VG-hub port unit 11 omitting the device connection terminal 111 cannot be used for connecting a load device or a power supply device, but can be used for connecting to another VG-hub port unit 11 and can be used as a virtual grid hub. It can also be used as a boundary.

The device connection terminal 111 described above is also referred to as a virtual grid hub port when it is inside the virtual grid hub. This is because when the virtual grid hub is regarded as one hub, all the device connection terminals 111 in the virtual grid hub are treated as ports in the virtual grid hub. Since the device shown in FIG. 4 is a unit for providing a port of a virtual grid hub, it is referred to as a virtual grid hub port unit 11 (VG-hub port unit 11).

<Formation example 1 of virtual grid hub>
An example 1 of forming a virtual grid hub using four VG-hub port units 11 disclosed in FIG. 4 will be described with reference to FIG. In the figure, VG-hub port units 11-9, 11-10, 11-11, and 11-12 are connected, and the VG is via the power control unit 113 at the right end of the VG-hub port unit 11-10. -Hub port units 11-11 are connected. Therefore, the power control unit 113 at the right end of the VG-hub port unit 11-10 serves as a boundary, and the virtual grid hub 5-3 including the VG-hub port units 11-9, 11-10, and 11-12 and the VG-hub A virtual grid hub 5-4 including port units 11-11 is formed. FIG. 6 shows a network of virtual grid hubs equivalent to the state of FIG.

In the virtual grid hub 5-3, the power bus terminal 115 of the VG-hub port unit 11-9 and the power bus terminal 115 of the VG-hub port unit 11-10 are connected, and the VG-hub port unit 11-10 is connected. By connecting the power bus terminal 115 of the above and the power bus terminal 115 of the VG-hub port unit 11-12, a power transmission path between the three units is secured, and a device connection connected to the load device or the power supply device is secured. The terminal 111 is connected to the power transmission line via the power control unit 113. As a result, each power control unit 113 can control the power supply amount to the load device and the power supply amount from the power supply device according to the control of the other device (virtual grid hub control device 12).

<Formation example 2 of virtual grid hub>
A second example of forming a virtual grid hub using four VG-hub port units 11 disclosed in FIG. 4 will be described with reference to FIG. 7. In the figure, VG-hub port units 11-9, 11-10, 11-11, and 11-12 are connected, and the VG-hub port unit 11-10 is connected to the VG-hub port unit 11-10 via each power control unit 113. Hub port units 11-9, 11-11, 11-12 are connected. Therefore, each power control unit 113 of the VG-hub port unit 11-10 serves as a boundary, and the virtual grid hub 5-5 including the VG-hub port unit 11-9 and the virtual grid including the VG-hub port unit 11-11 are included. A hub 5-6 and a virtual grid hub 5-7 including a VG-hub port unit 11-12 are formed. FIG. 8 shows a network of virtual grid hubs equivalent to the state of FIG. 7. In this formation example, since each virtual grid hub has one device connection terminal, it does not function as a hub. However, by connecting a plurality of VG-hub port units to each virtual grid hub, a plurality of VG-hub port units can be connected. It is possible to extend it to provide a hub function with a device connection terminal.

<Example of state change in the unit due to switch switching>
FIG. 9 shows an example of a state change in the unit due to switch switching. The figure is a configuration example including two power control units 113 and three power bus terminals 115. For example, [01] to [03] in the figure function as terminations in the virtual grid hub because there is a connection between the power bus terminal 115-the left power control unit 113-the device connection terminal 111 and no other connection. ing.

For example, [04] to [06] in the figure function as power transmission lines in a virtual grid hub to which two power bus terminals 115 are connected, and the power control unit 113 is used for this transmission line. The device connection terminal 111 is connected. The load device or power supply device connected to the device connection terminal 111 receives power from the power transmission line described above, or supplies power to the power transmission line described above.

For example, [07] to [09] in the figure are connected to the power bus terminal 115-the left power control unit 113-the device connection terminal 111, are located at the end in a virtual grid hub, and the remaining two. By connecting the power bus terminal 115, it also functions as a power transmission line in another virtual grid hub.

For example, [10] to [12] in the figure function as a boundary between one virtual grid hub and another virtual grid hub by connecting the two power bus terminals 115 via the power control unit 113. The remaining power bus terminal 115 is connected to the power bus terminal 115-power control unit 113-device connection terminal 111, and also functions as a terminal in a virtual grid hub.

For example, [13] to [15] in the figure are virtual because one power bus terminal 115 is not connected anywhere and the remaining two power bus terminals 115 are connected via the power control unit 113. It serves only as a boundary between the grid hub and other virtual grid hubs. The VG-hub port unit 11 that functions in this way does not necessarily need the device connection terminal 111. Therefore, by limiting the usage to [13] to [15], the device connection terminal 111 may be omitted as a simplified version (low-priced version) of the VG-hub port unit 11.

For example, in [16] of the figure, three power bus terminals 115 are connected and function as a power transmission line (branch point) in a virtual grid hub, and the power control unit 113 is used for this transmission line. The device connection terminal 111 is connected to the device and functions as a power transmission line.

<Switch 112, 114>
FIG. 10 is a diagram illustrating switches 112 and 114 of a VG-hub port unit 11 having three terminals and three power control units 113. In the example of FIG. 10, the switches 112 and 114 are realized as an integrated switch. The number of branches in the case of the VG-hub port unit 11 including the power control unit 113 having _{n terminals and two n} Cs is shown in parentheses in the figure.

<Power zone setting example 1 when the frequency is 4>
FIG. 11 discloses a setting example 1 of a power zone (virtual grid hub) when the frequency is 4 (the power bus terminals 115 are 4 terminals).

<Power zone setting example 2 when the frequency is 4>
In setting example 1 of FIG. 11, when the power supply device (UPS, uninterruptible power supply) in the center of the figure is defective, the power zone (virtual grid hub) is dynamically set as shown in FIG. 12, for example. It can be fixed.

Further, when it is desired to perform cooperative power supply of three power supply devices (UPS), the entire virtual grid shown in FIGS. 11 and 12 can be set as one power zone (virtual grid hub) (not shown). ..

<Supplement>
The device of the present invention is, for example, an input unit to which a keyboard or the like can be connected, an output unit to which a liquid crystal display or the like can be connected, and a communication device (for example, a communication cable) capable of communicating outside the hardware entity as a single hardware entity. Communication unit to which can be connected, CPU (Central Processing Unit, cache memory, registers, etc.), RAM and ROM which are memories, external storage device which is a hard disk, and input units, output units, and communication units of these. , CPU, RAM, ROM, has a connecting bus so that data can be exchanged between external storage devices. Further, if necessary, a device (drive) or the like capable of reading and writing a recording medium such as a CD-ROM may be provided in the hardware entity. A physical entity equipped with such hardware resources includes a general-purpose computer and the like.

The external storage device of the hardware entity stores the program required to realize the above-mentioned functions and the data required for processing this program (not limited to the external storage device, for example, reading a program). It may be stored in a ROM, which is a dedicated storage device). Further, the data obtained by the processing of these programs is appropriately stored in a RAM, an external storage device, or the like.

In the hardware entity, each program stored in the external storage device (or ROM, etc.) and the data necessary for processing each program are read into the memory as needed, and are appropriately interpreted, executed, and processed by the CPU. .. As a result, the CPU realizes a predetermined function (each configuration requirement represented by the above, ... Department, ... means, etc.).

The present invention is not limited to the above-described embodiment, and can be appropriately modified without departing from the spirit of the present invention. Further, the processes described in the above-described embodiment are not only executed in chronological order according to the order described, but may also be executed in parallel or individually as required by the processing capacity of the device that executes the processes. ..

As described above, when the processing function in the hardware entity (device of the present invention) described in the above embodiment is realized by a computer, the processing content of the function that the hardware entity should have is described by a program. Then, by executing this program on the computer, the processing function in the above hardware entity is realized on the computer.

The various processes described above can be performed by causing the recording unit 10020 of the computer shown in FIG. 13 to read a program for executing each step of the above method and operating the control unit 10010, the input unit 10030, the output unit 10040, and the like. ..

The program describing the processing content can be recorded on a computer-readable recording medium. The computer-readable recording medium may be, for example, a magnetic recording device, an optical disk, a semiconductor memory, or the like. Specifically, for example, as a magnetic recording device, a hard disk device, a magnetic tape, etc., and as an optical disk, a DVD (Digital Versatile Disc), a DVD-RAM (Random Access Memory), a CD-ROM (Compact Disc Read Only Memory), A flash memory or the like can be used as a semiconductor memory such as a CD-R (Recordable) / RW (ReWritable).

Further, the distribution of this program is performed, for example, by selling, transferring, renting, or the like a portable recording medium such as a DVD or CD-ROM on which the program is recorded. Further, the program may be stored in the storage device of the server computer, and the program may be distributed by transferring the program from the server computer to another computer via a network.

A computer that executes such a program first, for example, first stores a program recorded on a portable recording medium or a program transferred from a server computer in its own storage device. Then, when the process is executed, the computer reads the program stored in its own recording medium and executes the process according to the read program. Further, as another execution form of this program, a computer may read the program directly from a portable recording medium and execute processing according to the program, and further, the program is transferred from the server computer to this computer. Each time, the processing according to the received program may be executed sequentially. In addition, cloud computing that provides computer resources in the form of services via a computer network in order to realize processing functions only by instructing execution and acquiring results without transferring programs from the server computer to this computer. By using the ing, the above-mentioned processing may be executed. The program in this embodiment includes information to be used for processing by a computer and equivalent to the program (data that is not a direct command to the computer but has a property of defining the processing of the computer, etc.).

Further, in this form, the hardware entity is configured by executing a predetermined program on the computer, but at least a part of these processing contents may be realized in terms of hardware.

Claims (7)

A virtual grid hub port unit that is connected to each other to form a virtual grid.
Multiple power bus terminals that are connected to the other virtual grid hub port units to transmit power,
A device connection terminal that is connected to a load device or power device to transmit power,
A power control unit that controls and outputs the input power according to control commands from other devices,
According to a control command from another device, the power bus terminals are connected or disconnected from each other, the power bus terminal and the power control unit are connected or disconnected, and the device connection terminal and the power control unit are connected or disconnected. A virtual grid hub port unit that contains the switches to be connected. A virtual grid hub port unit that is connected to each other to form a virtual grid.
Multiple power bus terminals that are connected to the other virtual grid hub port units to transmit power,
A power control unit that controls and outputs the input power according to control commands from other devices,
A virtual grid hub port unit including a switch that connects or disconnects the power bus terminals to each other and connects or disconnects the power bus terminals and the power control unit according to a control command from another device. A virtual grid controller that gives control commands to each of a plurality of virtual grid hub port units that are connected to a load device or power device and can transmit power.
A virtual grid forming unit that controls connection or disconnection between the virtual grid hub port units to form a virtual grid,
A virtual grid control device including a virtual grid hub forming unit that divides the virtual grid by limiting power supply between some of the virtual grid hub port units to form a virtual grid hub that is the result of each division. A virtual grid system that includes a virtual grid controller and a virtual grid hub controller.
The virtual grid control device is a device that gives control commands to each of a plurality of virtual grid hub port units that are connected to a load device or a power supply device and can transmit electric power.
A virtual grid forming unit that controls connection or disconnection between the virtual grid hub port units to form a virtual grid,
Includes a virtual grid hub forming portion that divides the virtual grid by limiting power supply between some of the virtual grid hub port units to form a virtual grid hub that is the result of each division.
The virtual grid hub control device is
A virtual grid system that includes a unit control unit that gives control commands to each virtual grid hub port unit in the corresponding virtual grid hub. The virtual grid system according to claim 4.
The virtual grid control device is
Including a determination unit for determining whether or not power can be supplied from any said virtual grid hub to any other said virtual grid hub and the amount of power supplied.
The unit control unit of the virtual grid hub control device is
A virtual grid system that controls the virtual grid hub port unit located at the boundary of the corresponding virtual grid hub according to the above determination. A program that causes a computer to function as the virtual grid hub port unit according to claim 1 or 2. A program that causes a computer to function as the virtual grid control device according to claim 3.

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