JP2019126198A - Power supply management server and power supply system - Google Patents

Abstract

To wirelessly transmit power to a device to which power supply is permitted.SOLUTION: A power supply management server 10 includes: a communication device 13 that receives power reception apparatus identification information to uniquely identify a power reception apparatus 30; and a control device 11 that instructs a power supply apparatus 20 to radiate a beam to the power reception apparatus 30 if the power reception apparatus identification information received by the communication device 13 is the power reception apparatus identification information to identify the power reception apparatus 30 to which power supply is permitted.SELECTED DRAWING: Figure 3

Description

  The present invention relates to the art of wireless power transfer using beams.

  Recently, techniques have been developed to transfer power to devices by wireless power transfer. Patent Document 1 discloses a technology for wirelessly transmitting power when a receiver receives radio waves generated by a transmitter.

JP, 2014-168374, A

By the way, since the conventional wireless power transmission method transmits power by wireless electromagnetic field coupling via a power receiving antenna, when a plurality of receivers are arranged in a region where radio waves are radiated, power is received by all the receivers. It will be done. Therefore, power could not be transmitted only to a specific receiver among the plurality of receivers. For example, in the case where power transmission is performed on the condition of joining a power feeding service, there is a problem that even a receiver not subscribed to the power feeding service can receive power.
The present invention has been made in view of the above-described circumstances, and one of the problems to be solved is to transmit power wirelessly to a device to which power feeding is permitted.

  In order to solve the above problems, the power supply management server according to a preferred aspect of the present invention specifies the direction toward the power receiver located in the irradiation range of the beam, and irradiates the beam in the specified direction to perform the above A power feeding management server connected to a power feeding device capable of feeding power to a power receiving device, the communication device receiving power receiving device identification information for identifying the power receiving device, and the power receiving device identification information received by the communication device And a control device configured to instruct the power feeding device to irradiate a beam toward the power receiving device when the power receiving device identification information identifies a power receiving device permitted to be fed.

  A power feeding system according to a preferred aspect of the present invention is a power feeding system including a power feeder feeding power to a power receiver, and a power feeding management server connected to the power feeder, wherein the power feeder emits a beam. A beam irradiation apparatus, a beam direction specifying apparatus for specifying a direction from the beam irradiation apparatus toward a power receiver located in an irradiation range of the beam, a processing apparatus for irradiating the beam in the direction specified by the beam direction specifying apparatus; The power supply management server includes a communication device that receives power receiver identification information that identifies the power receiver, and a power receiver that identifies a power receiver whose power receiver identification information received by the communication device is permitted to be supplied And a control device that instructs the power feeding device to irradiate a beam toward the power receiving device if the identification information is the identification information.

  According to the present invention, in the case where the power receiving device whose power feeding is permitted is located in the irradiation range of the beam of the power feeding device and the power receiving device whose power feeding is not permitted, power is supplied only to the power receiving device whose power feeding is permitted. be able to.

It is a block diagram showing composition of an electric supply system concerning an embodiment of the present invention. It is an explanatory view showing an example of a feeding place. It is a block diagram which shows the structure of a electric power feeding management server. It is explanatory drawing which shows an example of the content of a management table. It is explanatory drawing which shows an example of the content of a feeder table. It is a block diagram which shows the structure of a feeder. It is explanatory drawing which shows an example of the content of a receiver table. It is explanatory drawing for demonstrating a beam direction. It is a block diagram showing composition of a receiving set. It is a sequence chart which shows operation of a feed system at the time of usual. It is explanatory drawing for demonstrating the relationship between the 1st irradiation range of a 1st electric power feeder, the 2nd irradiation range of a 2nd electric power feeder, and a power receiver. It is a sequence chart which shows operation of a feed system at the time of competition. It is an explanatory view for explaining specification of a beam direction using a beacon signal concerning a modification. It is an explanatory view for explaining an example of transmission of call receiver identification information concerning a modification.

Embodiment
<1. Configuration of feed system>
FIG. 1 is a block diagram showing a configuration of a power supply system 1 according to an embodiment of the present invention. The power feeding system 1 includes a plurality of power feeding management servers 10, a communication network NET such as the Internet or LAN, and a plurality of first power feeders 20A and second power feeders 20B connected to the power feeding management server 10 through the communication networks NET. And 30b1, 30b2... The feeding system 1 includes a plurality of feeders such as the first feeder 20A and the second feeder 20B, but the number of feeders may be one. Further, when it is not necessary to distinguish the individual feeders, one feeder among the plurality of feeders is referred to as a feeder 20. Although the power supply system 1 of this example includes a plurality of power receivers such as the power receiver 30a1, the power receiver 30a2, and so on, the number of power receivers may be one. Moreover, when it is not necessary to distinguish an individual power receiver, one power receiver among the plurality of power receivers is referred to as a power receiver 30.

  The feed system 1 is used for a feed service that transmits power wirelessly. In this feed service, the receiver 30 that has joined the feed service can receive power from the feeders 20 disposed at various feed places. FIG. 2 is an explanatory view showing an example of a feeding place. In this example, power is supplied to a plurality of power receivers 30 in a cafe in which two power feeders 20 are disposed on the ceiling.

<1-1: Power supply management server>
The power supply management server 10 illustrated in FIG. 1 manages power supply to the power receiver 30 that has subscribed to the power supply service.
The power feeding device 20 feeds power to the power receiving device 30 by irradiating the power receiving device 30 located in the predetermined range with a beam. The beam irradiated by the feeder 20 may be any beam as long as it can transmit energy and has directivity. Such beams include electromagnetic and ultrasonic beams. Further, the electromagnetic wave beam includes a laser beam, an infrared beam, a microwave beam, and a weak radio wave beam. The weak radio wave beam is a GHz band radio wave having directivity. Hereinafter, an infrared beam is illustrated and demonstrated as a beam which the feeder 20 irradiates.
The power receiver 30 is, for example, a portable device such as a mobile phone, a smartphone or a tablet terminal, and includes a power receiving module that converts an infrared beam into electric power. In the following description, it is assumed that the power receiver 30 is a smartphone.

  FIG. 3 is a block diagram showing the configuration of the power supply management server 10. As shown in FIG. The power supply management server 10 includes a control device 11, a storage device 12, a communication device 13, and a display device 14. The elements of the power supply management server 10 are mutually connected by one or more buses. In addition, the term "device" in the present application may be read as another term such as a circuit, a device or a unit. In addition, each element of the power supply management server 10 may be configured by one or more devices, and some elements of the power supply management server 10 may be omitted.

  The control device 11 is a processor that controls the entire power supply management server 10, and includes, for example, one or more chips. The control device 11 is configured by, for example, a central processing unit (CPU) including an interface with a peripheral device, an arithmetic device, a register, and the like. Note that some or all of the functions of the control device 11 are realized by hardware such as a digital signal processor (DSP), an application specific integrated circuit (ASIC), a programmable logic device (PLD), or a field programmable gate array (FPGA). May be The controller 11 executes various processes in parallel or sequentially.

  The storage device 12 is a recording medium readable by the control device 11, and stores a plurality of programs executed by the control device 11, various data used by the control device 11, a management table TBLa, and a power feeder table TBLb. The storage device 12 is configured of, for example, one or more types of storage circuits such as a ROM (Read Only Memory), an EPROM (Erasable Programmable ROM), an EEPROM (Electrically Erasable Programmable ROM), and a RAM (Random Access Memory).

In the management table TBLa, power receiver identification information, power feeder identification information, power feeding start conditions, power feeding end conditions, and power feeding state information are stored in association with one another. FIG. 4 shows an example of the storage contents of the management table TBLa.
The receiver identification information is information uniquely identifying the receiver 30, and, for example, corresponds to a power receiving module number uniquely assigned to the power receiving module. However, the power receiver identification information stored in the management table TBLa is power receiver identification information assigned to the power receiver 30 for which power feeding is permitted by joining the power feeding service. Therefore, by referring to the management table TBLa, it is possible to know the power receiver identification information of the power receiver 30 to be supplied with power. In other words, the power receiver 30 to which the power receiver identification information not stored in the management table TBLa is assigned is not supplied with power.

The feeder identification information is information uniquely identifying the feeder 20. By storing the receiver identification information and the feeder identification information in the management table TBLa in association with each other, it is possible to know which feeder 20 supplies power to the receiver 30.
The first power feeder 20A shown in FIG. 1 supplies power to the power receiver 30a1 and the power receiver 30a2. Here, it is assumed that the power feeder identification information of the first power feeder 20A is “PS0701”, the power receiver identification information of the power receiver 30a1 is “AH 9600”, and the power receiver identification information of the power receiver 30a2 is “AS5963”. In this case, in the management table TBLa, as shown in FIG. 4, the receiver identification information “AH 9600” and the power feeder identification information “PS 0 70 1” are stored in association with each other, and the receiver identification information “AH 5963” and the power feeder identification Information “PS0701” is stored in association with one another.
Further, when there is no power feeder identification information corresponding to the power receiver identification information in the management table TBLa, although power reception is permitted for the power receiver 30 corresponding to the power receiver identification information, the irradiation range of any power feeder 20 It means that the power receiver 30 is not located inside. For example, since the power receiver identification information is not associated with the power receiver identification information “AS 0101” illustrated in FIG. 4, the power receiver 30 corresponding to the power receiver identification information “AS 0101” may not be in a state capable of power feeding. I understand.

  The power feeding start condition is a condition under which the power feeder 20 automatically starts power feeding. Further, the power feeding end condition is a condition under which the power feeder 20 automatically stops power feeding. Power feeding may be started by the user manually operating the power receiver 30. Similarly, when the user operates the power receiver 30 manually, power feeding may be terminated. In the example illustrated in FIG. 4, the power feeding start condition is “less than 30% of charge rate” and the power feed stop condition is “charge rate of 95% or more” corresponding to the receiver identification information “AS0005”. . Therefore, for the power receiver 30 to which the power receiver identification information "AS0005" is assigned, the power feeder 20 starts power feeding when the charging rate is less than 30%, and ends power feeding when the charging rate is 95% or more.

The feeding state information indicates the feeding state of the power receiver 30. In the power feeding state, “power feeding” in which a beam is irradiated from the power feeder 20 toward the power receiver 30 to feed power, the power receiver 30 receives a power feed start request, but waits for power feed to the power receiver 30 There are “standby”, “standby” that is not in standby, and the power receiver 30 does not irradiate a beam to the power receiver 30 and is not powered.
The feeding state information includes a feeding flag indicating "feeding", a stopping flag indicating "stop", and a waiting flag indicating "waiting". Each flag is valid at "1" and invalid at "0". The stoppage flag is “1” when the power receiver 30 is not located within the irradiation range of the power feeder 20 or when the power receiver 30 is located within the irradiation range of the power feeder 20 but there is no demand for power supply. is there.
Further, the power feeding standby state is when the state of the power feeding device 20 simultaneously reaches the upper limit of the power receiving device 30 capable of power feeding, and power feeding can not be started immediately.

  The feeder table TBLb is associated with feeder identification information, store name information indicating the store name where the feeder is installed, store position information indicating the position of the store, and link information for displaying a map of the store It is memorized. FIG. 5 shows an example of stored contents of the power feeder table TBLb.

<1-2: Power feeder>
FIG. 6 is a block diagram showing the configuration of the power feeder. The feeder 20 includes a processing unit 21, a beam irradiation unit 22, a beam direction specifying unit 23, a communication unit 24, a near field radio unit 25, and a storage unit 26. Each element of the feeder 20 is mutually connected by one or more buses. Each element of the power supply device 20 may be configured of one or more devices, and some elements of the power supply device 20 may be omitted.

  The processing device 21 is a processor that controls the entire power feeder 20, and is configured of, for example, one or more chips. The processing unit 21 is constituted by, for example, a central processing unit including an interface with peripheral devices, an arithmetic unit, and a register. Note that part or all of the functions of the processing device 21 may be realized by hardware in the same manner as the control device 11 of the power supply management server 10.

  The storage device 26 is a recording medium readable by the processing device 21 and stores a plurality of programs executed by the processing device 21, various data used by the processing device 21, and a power receiver table TBLc. The storage device 26 is configured of, for example, one or more types of storage circuits such as a ROM, an EPROM, an EEPROM, and a RAM.

  The beam irradiation device 22 emits an infrared beam. The beam irradiation device 22 can change the direction in which the infrared beam is irradiated. The range in which the infrared beam can be irradiated is referred to as an irradiation range by changing the irradiation direction by the beam irradiation device 22. The beam irradiation unit 22 controls the direction of the infrared beam based on control data supplied from the processing unit 21.

  The number of infrared beams that can be emitted simultaneously by the beam irradiation device 22 may be two or more, or one. It is assumed that the beam irradiation device 22 irradiates one infrared beam, and the power receiver 30a1 and the power receiver 30a2 are located within the irradiation range and the power is supplied to them. When the direction from the beam irradiation device 22 to the power receiver 30a1 is a first direction, and the direction from the beam irradiation device 22 to the power receiver 30a2 is a second direction, the processing device 21 applies a first direction to the beam irradiation device 22. And control data for specifying the second direction are supplied in a time division manner. When power is supplied to a plurality of power receivers 30 located in the irradiation range, the number of infrared beams that can be simultaneously irradiated by the beam irradiation device 22 is one by irradiating the infrared beams toward each power receiver 30 in time division. Even with one power supply, power can be supplied to a plurality of power receivers 30.

  The beam direction specification device 23 specifies the direction of the infrared beam to be emitted from the beam irradiation device 22 to the power receiver 30 located within the irradiation range, and generates beam direction information indicating the specified direction. The beam direction specifying device 23 may be anything as long as the direction of the infrared beam can be specified. For example, the direction of the infrared beam is controlled from the beam irradiation device 22 to irradiate the infrared beam scanning the irradiation range, the reflected light is detected in the beam direction specifying device 23, and the direction of the infrared beam is specified based on the detection result. May be

  In addition, the beam direction identification device 23 may include an imaging element, and analyze the data of the image imaged by the imaging element to identify the direction of the infrared beam. More specifically, the power receiver 30 includes a photoelectric conversion panel 32A (see FIG. 9) such as a solar panel that converts an infrared beam into electric energy, and provides a specific mark around the photoelectric conversion panel 32A. The beam direction specifying device 23 may detect a specific mark by image analysis, and specify the direction of the infrared beam based on the coordinates of the mark on the image.

  The communication device 24 is a device that communicates with other devices via the communication network NET. The communication device 24 is also described as, for example, a network device, a network controller, a network card or a communication module. Specifically, the communication device 24 communicates with the power supply management server 10 via the communication network NET. The short distance wireless device 25 performs wireless communication with the power receiver 30. For example, Bluetooth (registered trademark) is applicable as a short-distance wireless communication method.

FIG. 7 shows an example of the storage content of the power receiver table TBLc stored in the storage device 26. As shown in FIG. The power receiver identification information of the power receiver 30 located within the irradiation range and the beam direction information are stored in association with each other in the power receiver table TBLc. The beam direction information indicates the argument θ and the argument φ.
The argument θ and the argument φ will be described with reference to FIG. The beam irradiation device 22 is located at an origin O shown in FIG. Also, the power receiver 30 is located at point Q. In this case, the beam direction indicated by the arrow is given by an angle of deviation φ on the XY plane with respect to the X axis and an angle of deviation θ on a plane including the beam direction and the Z axis with respect to the Z axis.

<1-3: power receiver>
FIG. 9 is a block diagram showing the configuration of a power receiver. The power receiver 30 includes a processing device 31, a power reception module 32, a storage device 33, a communication device 34, a display device 35, an operation device 36, a secondary battery 37, and a GPS device 38. The elements of the power receiver 30 are mutually connected by one or more buses. Each element of the power receiver 30 may be configured of one or more devices, and some elements of the power receiver 30 may be omitted.

  The processing device 31 is a processor that controls the entire power receiving device 30, and is configured of, for example, one or more chips. The processing unit 31 is constituted by, for example, a central processing unit including an interface with a peripheral device, an arithmetic unit, and a register. Note that part or all of the functions of the processing device 31 may be realized by other hardware in the same manner as the control device 11 of the power supply management server 10.

The storage device 33 is a recording medium readable by the processing device 31 and stores a plurality of programs including a power supply application executed by the processing device 31 and various data used by the processing device 31. The storage device 26 is configured of, for example, one or more types of storage circuits such as a ROM, an EPROM, an EEPROM, and a RAM.
In order for the power receiver 30 to be supplied with power using the power supply system 1, it is necessary to join the power supply service. The feed application is used to guide, join and operate feed services. Also, the power supply application is installed in the power receiver 30 by downloading from a predetermined site.

  The power receiving module 32 includes a photoelectric conversion panel 32A that outputs a signal obtained by converting an infrared beam emitted from the power feeder 20 into electrical energy, and a short distance wireless device 32B that performs short distance wireless communication with the power feeder 20 and non-volatile And the memory 32C of Although the power receiving module 32 of this example is incorporated in the power receiving device 30, the power receiving module 32 may be configured to be detachable from the power receiving device 30. When the power receiver 30 is a smart phone, the power receiving module 32 may be provided with a terminal connectable to a charging terminal such as micro USB. The memory 32C stores receiver identification information for uniquely identifying the receiver 30.

  The communication device 34 is a device that communicates with other devices via a communication network NET such as a mobile communication network or the Internet. The communication device 34 is also described as, for example, a network device, a network controller, a network card or a communication module. For example, the application received by the communication device 34 from the power supply management server 10 via the communication network NET is stored in the storage device 33. The downloaded application includes a power supply application.

  The display device 35 can display various images under the control of the processing device 31. For example, various display panels such as a liquid crystal display panel and an organic EL display panel are suitably used as the display device 35.

  The operating device 36 is a device for inputting a user's instruction. The operating device 36 accepts an operation by the user. Specifically, operation device 36 accepts an operation for inputting a code such as a number and a character, and an operation for selecting an image to be displayed by display device 35. For example, a touch panel that detects a touch on the display surface of the display device 35 is suitable as the operation device 36. The operating device 36 may include a plurality of operators which can be operated by the user.

  The secondary battery 37 is charged by the power supplied from the charging terminal or the power supplied from the power receiving module 32. Further, the secondary battery 37 functions as a power supply for supplying power to each element of the power receiver 30.

  The GPS device 38 receives radio waves from a plurality of satellites, and generates position information from the received radio waves. The position information may be in any form as long as the position can be identified. The position information indicates, for example, the latitude and the longitude of the power receiver 30. In this example, it is illustrated that the position information is obtained from the GPS device 38, but the receiver 30 may obtain the position information by any method. For example, the location information may be acquired using the cell ID assigned to the base station that is the communication destination of the power receiver 30. Furthermore, when the power receiving device 30 communicates with an access point of a wireless LAN, it refers to a database in which the identification address (MAC address) on the network assigned to the access point is associated with the actual address (position). You may acquire position information.

  In the power receiver 30, when the power supply application is started, the display device 35 displays a guidance of the power supply service. The guidance includes the installation place of the power feeder 20 and a charge plan. In addition, the guidance screen is provided with a button for proceeding to joining, and when the user depresses this button, a screen for joining is displayed. Then, when the user selects subscription of the power feeding service, the processing device 31 reads the power receiver identification information from the memory 32C, and transmits the read power receiver identification information to the power feeding management server 10 by the communication device 34. The power supply management server 10 stores the power receiver identification information in the management table TBLa as information for specifying the power receiver 30 whose power supply is permitted. Furthermore, it is possible to transmit the feed start condition and the feed end condition inputted by the user using the operation device 36 to the feed management server 10. The feed management server 10 stores the feed start condition and the feed end condition in the management table TBLa in association with the receiver identification information. The input of the feed start condition and the feed end condition is optional. Therefore, even if the receiver identification information is stored in the management table TBLa, there are cases where the corresponding power supply start condition and power supply end condition are not stored.

<2. Power supply system operation>
Next, the operation of the power supply system 1 will be described by dividing it into an operation at normal time, an operation at communication failure, an operation at competition, and an operation at guidance.

<2-1: Normal time>
FIG. 10 is a sequence chart for explaining the normal operation of the power supply system 1.
The feeder 20 controls the direction of the infrared beam emitted from the beam irradiation device 22 to scan the inside of the irradiation range. The beam direction identification device 23 generates beam direction information indicating the direction of the infrared beam directed to the power receiver 30 by detecting the light amount of the reflected light of the infrared beam in synchronization with the above-described scan and analyzing the detection result. (S1). By this, it is possible to specify the direction of the beam directed to the power receiver 30. The above process is executed at a predetermined cycle. Therefore, when the power receiver 30 is newly moved from the outside of the irradiation range to the inside of the irradiation range, it is possible to specify the direction of the infrared beam to be irradiated for power supply to the moved power receiver 30.

  Thereafter, near field communication is established between the power feeder 20 and the power receiver 30. Next, the power feeder 20 transmits a power receiver information request to the power receiver 30 using near field wireless communication. The receiver information request is for requesting the receiver 30 of the communication destination to return receiver identification information.

  When the near field communication device 32B of the power receiver 30 receives the power receiver information request, the processing device 31 reads the power receiver identification information from the memory 32C of the power reception module 32, and generates a power receiver information response including the power receiver identification information. Thereafter, the processing device 31 transmits a receiver information response to the power feeder 20.

  When the power receiving device 20 receives the power receiving device information response, the processing device 21 associates the received power receiving device identification information with the beam direction information generated in step S1 and writes the received data in the power receiving device table TBLc. The stored contents are updated (S2). Thereafter, the processing device 21 generates a registration request including the power receiver identification information used for updating and the power feeder identification information read from the storage device 26, and uses the communication device 24 to register the registration request to the power supply management server 10. Send.

  When the communication device 13 of the power supply management server 10 receives the registration request, the control device 11 causes the power receiver identification information included in the registration request to be included in the power receiver identification information for which power supply is permitted stored in the management table TBLa. It is determined whether or not (S3). If the determination result is affirmative, the control device 11 stores the power feeder identification information in the management table TBLa in association with the power receiver identification information (S4). By this, with reference to the management table TBLa, it can be known from which feeder 20 the power-receiving unit 30 to which power feeding is permitted can be fed.

Thereafter, the control device 11 determines whether or not the start condition for starting the power supply is satisfied (S5), and when the start condition is satisfied, the control device 11 transmits a power supply start request to the power feeder 20.
The start conditions include a feed start condition and a forced start condition. In the determination of step S5, the control device 11 determines which of the power supply start condition and the forced start condition is satisfied. The feed start condition is, as described above, a condition under which feed is automatically started by the user registering in advance. On the other hand, the forced start condition is a condition under which power feeding is started by the user's request even if the power feeding start condition is not satisfied.

  The feed start condition is, for example, “less than 30% charging rate” as shown in FIG. In order to determine this, it is necessary to grasp the charging rate of the power receiver 30 by the power supply management server 10. For this reason, the power receiver 30 notifies the power supply management server 10 of the charging rate at predetermined time intervals. In this case, the notification of the charging rate is performed using a power supply application. However, although the power feeding application is installed, the power receiving device 30 that has not subscribed to the power feeding service does not notify the power feeding management server 10 of the charging rate. Also, for the reason that the power receiver 30 that has subscribed to the power supply service notifies the power supply management server 10 of the charging rate, the power receiver 30 receives the above-described power receiver information request from the power feeder 20, and the power receiver 30 is power feeder It is started after being confirmed to be within the irradiation range of 20 infrared beams. That is, it is a condition of notification that the power receiver 30 is in a state capable of performing power supply by the infrared beam. Under such conditions, the power receiver 30 notifies the power supply management server 10 of the state relating to charging of the power receiver 30 via the communication network NET, so that the processing load of the power supply management server 10 can be reduced.

  Specifically, when the forced start condition is satisfied, the user operates the power receiver 30, which is a smartphone, to start the power supply application and manually input the power supply start. When the power supply start is manually input, a power supply request including power feeder identification information and power receiver identification information is transmitted from the power receiver 30 to the power feeding management server 10 via the communication network NET. When the communication device 13 of the power supply management server 10 receives the power supply request, the control device 11 determines whether the received power receiver identification information is stored in the management table TBLa, and if it is stored, the forced start condition is Determined to be satisfied.

  If the determination result in step S5 is affirmative, the power supply management server 10 transmits a power supply start request including the power receiver identification information to the power feeder 20 corresponding to the received power feeder identification information.

  When the feeder 20 receives the feed start request, the feeder 20 starts irradiation of the infrared beam (S6). Specifically, the processing device 21 of the power feeder 20 refers to the power receiver table TBLc to read beam direction information corresponding to the power feeder identification information included in the power feeding start request, and applies the beam direction information to the beam irradiation. The device 22 is supplied. The beam irradiation device 22 emits an infrared beam in the direction indicated by the beam direction information. As a result, the power receiving module 32 of the power receiver 30 outputs a voltage and starts charging the secondary battery 37 (S7).

The feeder 20 transmits to the feed management server 10 a feed start response indicating that the feed has been started. The feed start response includes the receiver identification information of the receiver 30 that has started feeding and the feeder identification information of the feeder 20. In addition, when the state of the power feeder 20 reaches the upper limit of the power receiver 30 which can simultaneously feed power when the power feeder 20 receives the power feeding start request, the power feeder 20 feeds power instead of the power feeding start response. The power supply management server 10 is sent a standby notification indicating that it is in standby.
The standby notification includes receiver identification information of the power receiver 30 waiting for power feeding and power feeder identification information of the power feeder 20.

  When the power supply management server 10 receives the power supply start response or the standby notification, the control device 11 updates the power supply state information stored in the management table TBLa based on the received power supply start response or the standby notification (S8). ). When the power supply start response is received, the control device 11 updates the in-stop flag corresponding to the received receiver identification information from "1" to "0" and updates the in-feed flag from "0" to "1". . On the other hand, when the standby notification is received, the control device 11 updates the stoppage flag corresponding to the received receiver identification information from "1" to "0", and the standby flag from "0" to "1". Update.

  The power feeder 20 determines whether the power receiver 30 is located within the irradiation range (S9). Specifically, the beam direction identification device 23 of the power feeder 20 constantly monitors the position of the power receiver 30, and outputs beam direction information when the position of the power receiver 30 changes, and the beam stored in the power receiver table TBLc Update direction information. If the beam direction information stored in the power receiver table TBLc is out of the irradiation range, the processing device 21 determines that the power receiver 30 is not located within the irradiation range. In this case, the power feeder 20 transmits, to the power supply management server 10, a power supply end notification indicating that the power supply is ended. The feed end notification includes receiver identification information and feeder identification information.

Next, the control device 11 determines whether the end condition is satisfied (S10). The termination conditions include a power feeding termination condition, a first forced termination condition, and a second forced termination condition. In the determination of step S10, the control device 11 determines whether any one of the power supply termination condition, the first forcible termination condition, and the second forcible termination condition is satisfied. As described above, the power feeding end condition is a condition under which power feeding is automatically ended when the user registers in advance. On the other hand, the first forced termination condition is a condition under which power feeding is terminated by the user's request even if the power feeding termination condition is not satisfied. The second forcible termination condition is a condition under which the feeding is terminated due to the feeding failure even if the feeding termination condition is not satisfied.
The feed end condition is, for example, "charge rate of 95% or more" as shown in FIG. In order to determine this, it is necessary to grasp the charging rate of the power receiver 30 by the power supply management server 10. The fact that there are two modes for grasping the charge rate is similar to the feed start condition.

  Specifically, when the first forced start condition is satisfied, the user operates the power receiver 30, which is a smartphone, to start the power supply application and manually input the power supply stop. When the power supply stop is manually input, a power supply stop request including the power feeder identification information and the power receiver identification information is transmitted from the power receiver 30 to the power feeding management server 10 via the communication network NET. When the communication device 13 of the power supply management server 10 receives the power supply stop request, the control device 11 determines whether the received receiver identification information is stored in the management table TBLa, and if it is stored, the first forced It is determined that the start condition is satisfied.

  The case where the second forced start condition is satisfied is a case where the power receiving device 30 being fed moves from within the irradiation range of the infrared beam to outside the irradiation range. In this case, since the power feeding management server 10 receives the power feeding end notification, the control device 11 determines whether the second forced termination condition is satisfied depending on whether or not the power feeding end notification is received.

If the termination condition is satisfied, the power supply management server 10 transmits, to the power supply unit 20, a power supply termination request instructing to terminate the power supply. The feed end request includes receiver identification information. However, when the second forced termination condition is satisfied, the power feeding management server 10 does not transmit the power feeding end request to the power feeding unit 20 because the power feeding unit 20 has already finished the power feeding.
Next, the control device 11 updates the storage content of the management table TBLa (S11). Specifically, the control device 11 updates the power supply state information associated with the power receiver identification information corresponding to the power receiver 30 whose power supply has ended. That is, the in-stop flag is set to “1”, and the in-feed flag and the on-wait flag are set to “0”.

In the power feeding device 20, when the power feeding end request is received, or when the determination result in step S10 is negative, the processing device 21 determines the power receiving device identification information of the power receiving device 30 from which the power feeding is to be finished. The beam direction information is deleted, and the stored contents of the power receiver table TBLc are updated (S12).
Thereafter, the processing device 21 controls the beam irradiation device 22 so as to end the irradiation of the infrared beam to the power receiver 30 corresponding to the deleted power receiver identification information. The beam irradiation device 22 ends the irradiation of the infrared beam to the power receiver 30 which ends the power feeding (S13).
When the irradiation of the infrared beam ends, the power receiving device 30 ends the charging of the secondary battery 37 (S14).

<2-2: At the time of communication failure>
The normal operation described above is premised on that the communication between the power supply management server 10 and the power feeder 20 and the communication between the power feeder 20 and the power receiver 30 are normal. However, communication failure may occur. In this case, although the power supply state information of the power supply management server 10 indicates that power is being supplied, it is possible that the infrared beam is not irradiated from the power feeder 20 to the power receiver 30.

  As described above, when it is determined that the power supply management server 10 satisfies the power supply start condition, the power supply management server 10 automatically starts the power supply, and the user operates the power receiver 30 to request the power supply management server There is an aspect which notifies 10. In particular, in the latter case, it is a problem that the power feeding is not started although the power feeding start request is transmitted from the power receiver 30.

Therefore, in the present embodiment, the power feeding state is monitored by the power receiver 30, and if the power feeding start request and the actual power feeding state do not match, the power feeding start request is transmitted to the power feeding management server again.
That is, the power receiving device 30 monitors the power feeding by the beam after requesting the power feeding management server 10 to start power feeding, and requests the power feeding management server 10 to start the power feeding again if power feeding is not performed.

  The monitoring of the power supply by the beam is performed by the processing device 31 monitoring the output voltage of the photoelectric conversion panel 32A. When the output voltage is equal to or lower than the predetermined voltage, the processing device 31 determines that power feeding is not performed, and transmits a power feeding start request to the power feeding management server 10 using the communication device 34. The request for starting power feeding includes receiver identification information assigned to the receiver 30.

  When the communication device 13 receives a request for starting power supply including the power receiver identification information from the power receiver 30, the control device 11 of the power supply management server 10 assigns power feeder identification information associated with the power receiver identification information. The power supply unit 20 is instructed to irradiate the beam toward the power reception unit 30. The control device 11 first refers to the management table TBLa to specify power feeder identification information corresponding to the power receiver identification information included in the request for starting power feeding. Next, the control device 11 controls the communication device 13 so as to transmit a power supply start request including the power receiver identification information to the power feeder 20 corresponding to the power feeder identification information. The request for starting power feeding may be transmitted from the power receiver 30 to the power feeder 20 using near field communication, and the power feeder 20 may transmit a request for power feeding start to the power feeding management server 10.

  As described above, after the power receiving device 30 requests the power supply management server 10 to start supplying power, it monitors power supply by the beam, and when power is not supplied, requests the power supply management server 10 to start power supply again. When the communication device 13 receives a request for power supply start including the receiver identification information from the power receiver 30, the controller 11 of the power supply management server 10 determines the feeder identification information associated with the receiver identification information. Instructs the assigned power feeder 20 to irradiate a beam toward the power receiver 30. This makes it possible to avoid power failure due to communication failure. Further, the power supply management server 10 does not have to inquire the power receiver 30 or the power feeder 20 about the power supply state in consideration of the communication failure, so that the processing load of the power supply management server 10 can be reduced.

<2-3: At the time of competition>
In the case of introducing the power supply system 1 in a store such as a public facility or a cafe, it is preferable to arrange two or more power feeders 20 to enable power supply over a wide area. When arranging a plurality of feeders 20, the irradiation ranges may overlap.

  In the following description, as shown in FIG. 11, a first feeder 20A capable of emitting an infrared beam to the first irradiation range W1 and a second feeder 20B capable of emitting an infrared beam to the second irradiation range W2; It is assumed that the power receiver 30 is located in the overlapping range Z where the first irradiation range W1 and the second irradiation range W2 overlap.

FIG. 12 shows a sequence chart until the power feeder 20 to be fed is determined when the power receiver 30 is located in the overlapping range Z.
The power supply management server 10 manages which power supply unit 20 can supply power from the power receiver 30 using the management table TBLa. The control device 11 of the power supply management server 10 detects a conflict when receiving a registration request from both of the first power feeder 20A and the second power feeder 20B (S20).

  When detecting the conflict, the control device 11 transmits a power supply start request to the first power feeder 20A. The feed start request includes receiver identification information of the receiver 30 located in the overlapping range Z.

When the first power feeder 20A receives the power feeding start request, the first power feeder 20A irradiates the power receiver 30 with an infrared beam to start power feeding (S21). The first feeder 20A transmits a feed start response indicating that feed has been started to the feed management server 10.
When the power supply management server 10 receives the power supply start response, the power supply management server 10 receives a detection strength request requesting to report first strength information indicating the strength of the infrared beam irradiated from the first power feeder 20A detected in the power receiver 30. It transmits to the electric machine 30.

  When the power receiving device 30 receives the detected intensity request, the processing device 21 detects the output voltage of the photoelectric conversion panel 32A as the first intensity information (S22), and the detected intensity response including the detected first intensity information is supplied to the power management server 10 Send to The detected intensity response includes receiver identification information in addition to the first intensity information.

  When the power supply management server 10 receives the detected strength response, the control device 11 stores the first strength information in the storage device 12 in association with the power feeder identification information of the first power feeder 20A.

  Thereafter, the power supply management server 10 transmits a power supply stop request including the power receiver identification information to the first power feeder 20A. When the first feeder 20A receives the feed stop request, the first feeder 20A stops the feed to the power receiver 30 corresponding to the feeder identification information included in the feed stop request (S23).

  The first power feeder 20A transmits a power feed stop response including the power receiver identification information to the power feed management server 10. When the power supply management server 10 receives the power supply stop response, the power supply management server 10 transmits a power supply start request including the power feeder identification information to the second power feeder 20B.

  When the second feeder 20B receives the feed start request, the second feeder 20B starts feeding power to the power receiver 30 (S24), and transmits a feed start response to the feed management server 10. When the power supply management server 10 receives the power supply start response, the power supply management server 10 receives a detection strength request requesting to report second strength information indicating the strength of the infrared beam irradiated from the second power feeder 20B detected in the power receiver 30. It transmits to the electric machine 30.

  When the power receiving device 30 receives the detected intensity request, the processing device 21 detects the output voltage of the photoelectric conversion panel 32A as the second intensity information (S25), and the detected intensity response including the detected second intensity information is supplied to the power management server 10 Send to The detected intensity response includes receiver identification information in addition to the second intensity information.

  When the power supply management server 10 receives the detected intensity response, the control device 11 compares the second intensity information with the first intensity information stored in the storage device 12 and feeds the larger intensity to the power receiver 30. It is determined as the power feeder 20.

  The communication device 13 of the power supply management server 10 is irradiated from the first intensity information indicating the intensity of the beam irradiated from the first power feeder 20A detected in the power receiver 30, and from the second power feeder 20B detected in the power receiver 30. And second intensity information indicative of the intensity of the beam. Then, when the intensity indicated by the first intensity information is larger than the intensity indicated by the second intensity information, the control device 11 instructs the first power feeder 20A to irradiate a beam toward the power receiver 30, and It instructs the power receiver 20B not to irradiate a beam toward the power receiver 30.

  As described above, the intensity of the beam is detected in the power receiver 30, and the power feeder 20 to which the beam should be irradiated is determined based on the detection result, so that the power can be efficiently transmitted. In addition, since the beam irradiation from the first feeder 20A and the beam irradiation from the second feeder 20B are controlled to be exclusive in detecting the beam intensity, the beam intensity can be accurately determined. It can be detected.

<2-4: At the time of guidance>
When the battery remaining amount of the power receiving device 30 decreases outside the home, the power receiving system 30 may be used to charge the power receiving device 30. However, it is not easy for the user to grasp the installation place of the power feeder 20 in advance.

Therefore, in the present embodiment, by executing the power feeding application, the user is notified of the installation location of the nearest power feeder 20, and the user who is not subscribed to the power feeding service is urged to join.
The power receiver 30, which is an information processing apparatus such as a smartphone, can acquire position information by the GPS device 38 as described above. When the power supply application is activated and display of the power supply location is selected, the processing device 31 of the power receiver 30 transmits a guidance request including position information and power receiver identification information output from the GPS device 38 to the power supply management server 10 .

  When the communication device 13 of the power supply management server 10 receives the guidance request, the control device 11 refers to the power feeder table TBLb and extracts installation information on one or more power receivers 30 in order of proximity to position information included in the guidance request. Do. The installation information is information on the installation of the power feeder 20, and may include shop name information, shop position information, or link information shown in FIG. The control device 11 transmits a guidance response including the installation information to the power receiver 30 using the communication device 13.

  When receiving the guidance response, the power receiver 30 causes the display device 35 to display a power supply location near the power receiver 30 based on the installation information. This allows the user to know where to use the power supply service.

  By the way, even in the case of the power receiving device 30 in which the power feeding application is installed, the power feeding service can not be used unless the user operates the operation device 36 and joins the power feeding service. If an unsubscribed user wishes to provide guidance on the feeding location, it is highly likely that they want to subscribe to the feeding service.

  Therefore, when the guidance request is received, the control device 11 of the power supply management server 10 determines whether the receiver identification information included in the guidance request is included in the receiver identification information stored in the management table TBLa. If it is included, the guidance response is transmitted to the power receiver 30 by including subscription guidance information prompting the user to join the power supply service.

  When the receiver 30 receives the guidance response, it causes the display device 35 to display an image prompting the user to join the power feeding service based on the subscription guidance information. This enables the user to deepen the understanding of the power supply service, and makes it easy to consider the merits of joining.

  As described above, the control device 11 of the power supply management server 10 manages the installation information indicating the installation place of the power feeder 20, and when the communication device 13 receives a request including the position information of the power receiver 30, the communication device 13. The installation information of the power feeder 20 according to the position information is transmitted to the power receiver 30 using the information 13. Therefore, the user of the power receiver 30 can know the installation place of the power feeder 20, and the convenience improves.

  Further, the request includes the power receiver identification information of the power receiver 30, and when the power receiver identification information included in the request is not the power receiver identification information of the power receiver to which the power supply is permitted, the control device 11 The receiver 30 transmits subscription guidance information for prompting subscription to the receiver 30. By this, it is possible to urge the power feeding service to join the power feeding service not subscribed to the power feeding service 30, and since the subscription guidance information is not transmitted to the power receiving machine that has been subscribed to the power feeding service, the processing of the power feeding management server The load can be reduced.

  In the embodiment described above, the power feeder 20 specifies the direction toward the power receiver 30 located in the irradiation range of the beam, irradiates the beam in the specified direction, and can supply power to the power receiver 30. The power supply management server 10 is connected to the power feeder 20, and the communication device 13 of the power supply management server 10 receives power receiver identification information that uniquely identifies the power receiver 30, and the control device 11 is a communication device. If the receiver identification information received by the receiver 13 is receiver identification information for identifying a receiver permitted to be supplied with power, the power supply unit 20 is instructed to irradiate a beam toward the receiver 30. According to the power supply management server 10, when the power receiver 30 whose power supply is permitted and the power receiver 30 whose power supply is not permitted are located in the irradiation range of the beam of the power feeder 20, the power receiver whose power supply is permitted Power can be supplied only for thirty. Moreover, since the beam irradiated from the feeder 20 has directivity, power transmission efficiency can be improved as compared to wireless power transmission using nondirectional electromagnetic waves. In addition, when an omnidirectional electromagnetic wave is used, power can be received if the electromagnetic wave is received by the power receiver 30 which does not permit power feeding. By using the beam as in the present embodiment, it is possible to prevent the power theft of the power receiver 30 for which the power supply is not permitted.

  The communication device 13 of the power supply management server 10 receives, from the plurality of power feeders 20, the power feeder identification information assigned to the power feeder 20 that specifies the direction of the power receiver, and the control device 11 is received by the communication device 13. When the power receiver identification information is power receiver identification information of the power receiver 30 permitted to be fed, the power receiver 20 corresponding to the power receiver identification information corresponds to the power receiver identification information received by the communication device 13. Direct 30 to direct the beam. According to the power supply management server 10, the power receiver 30 permitted to be supplied power can receive power from any of the plurality of power receivers 30.

  The communication device 13 receives a power feeding start condition which is a condition for automatically starting power feeding to the power receiver 30, and the control device 11 directs the power feeder 20 to the power receiver 30 when the power feeding start condition is satisfied. Direct the irradiation of Since the power supply management server 10 manages the power supply start condition, the power receiver 30 can receive power supply according to the power supply start condition set in advance, without requesting the power supply start.

  The communication device 13 receives a power supply termination condition which is a condition for automatically terminating the power supply to the power receiver 30, and the control device 11 irradiates the beam to the power receiver 30 when the power supply termination condition is satisfied. The power supply unit 20 is instructed to end the irradiation of the beam directed to the power reception unit 30. Since the power supply management server 10 manages the power supply end condition, the power receiver 30 can receive power supply according to a preset power supply start condition without requiring the end of the power supply.

  The control device 11 associates and manages the power reception identification information of the power receiver 30 for which power feeding is permitted and the power feeding state information indicating the power feeding state of the power receiver 30, and feeds power based on the request of the power receiver 30 for which power feeding is permitted. When the power supply is terminated based on the request of the power receiver 30 for which the power supply has been permitted, the power supply state information is updated. That is, since the power supply management server 10 manages the power supply state information indicating the power supply state of the power receiver to which the power supply is permitted, the power supply management server can grasp the power supply state of the power receiver 30 without inquiring the power receiver. it can. As a result, in the power receiver 30, in response to an inquiry from the power supply management server 10, the signal processing for detecting the power supply state can be reduced to reduce the processing load.

<Modification>
The present invention is not limited to the embodiments exemplified above. The aspect of a specific deformation | transformation is illustrated below. Two or more aspects arbitrarily selected from the following examples may be merged.

(1) In the embodiment described above, the beam direction specifying device 23 of the power feeder 20 detects the reflected light of the infrared beam and specifies the direction of the beam based on the detection result, but the present invention is not limited to this.
For example, the position information acquired by the power receiver 30 may be transmitted to the power receiver 30 using the short-distance wireless device 32B, and the beam direction identification device 23 of the power receiver 30 may calculate the beam direction based on the position information. . The position information of the power receiver 30 is stored in advance in the storage device 26.

  Alternatively, as shown in FIG. 13, the power receiver 30 may transmit the beacon signal BS and the power feeder 20 may receive the beacon signal BS to specify the direction of the beam BE to be irradiated to the power receiver 30. In this case, the beam direction identification device 23 described above receives the beacon signal BS and identifies the direction of the beacon signal BS. In the example shown in FIG. 13, even if the obstacle 50 is located between the power feeder 20 and the power receiver 30, the beacon signal BS is reflected by the wall 60 and transmitted to the power feeder 20. Similarly, the beam BE emitted from the power feeder 20 is also reflected by the wall 60 and transmitted to the power receiver 30. As described above, it is also possible to use the reflection to supply power to the power receiver 30 located in a place that can not be seen directly.

(2) In the embodiment described above, the power receiver 30 communicates with the power supply management server 10 to join the power supply service, but the present invention is not limited to this. For example, as shown in FIG. 14, the receiver identification information of the receiver 30X may be transmitted to the power supply management server 10 using the information processing apparatus 100. The power receiver 30X does not include the communication device 34 shown in FIG. The information processing apparatus 100 is, for example, a smartphone.

There are the following modes for the information processing apparatus 100 to acquire the receiver identification information of the receiver 30X.
In the first mode, a QR code (registered trademark) indicating receiver identification information is displayed on the power receiver 30X, and the information processing apparatus 100 acquires the receiver identification information by reading the QR code (registered trademark). Do.
In the second mode, the information processing apparatus 100 reads receiver identification information of the receiver 30X using near-field wireless communication.
In the third mode, the user manually inputs, to the information processing apparatus 100, the receiver identification information displayed on the receiver 30X.

  By using the information processing apparatus 100 in this manner, even if the power receiver 30X does not have the function of communicating with the power supply management server 10, the power supply service can be used.

(3) In the embodiment described above, as described with reference to FIG. 10, the receiver identification information is transmitted to the power supply management server 10 via the power feeder 20, but the present invention is limited thereto It may be transmitted from the power receiver 30 to the power supply management server 10 instead.
Moreover, although receiver identification information is information which identifies the receiver 30 uniquely, this invention is not limited to this, Information which identifies the receiver 30 may be sufficient. For example, receiver identification information common to a plurality of power receivers 30 may be assigned. When one user uses the power supply service to a plurality of devices, it is possible to centrally manage power supply to a plurality of devices by allocating common power receiver identification information. Alternatively, common receiver identification information may be assigned to a family, and a power supply service may be used in each person's device.

(4) In the embodiment described above, the storage device 12 of the power supply management server 10 stores the management table TBLa and the power feeder table TBLb, but the present invention is not limited to this. These tables may be stored in another server connected to the power supply management server 10 via the communication network NET.

(5) In the embodiment described above, the storage device 12 is a recording medium readable by the control device 11 and exemplified the ROM and the RAM, but the flexible disk, the magneto-optical disk (for example, compact disk, digital versatile) Disk, Blu-ray (registered trademark) disk, smart card, flash memory device (eg, card, stick, key drive), CD-ROM (Compact Disc-ROM), register, removable disk, hard disk, floppy (registered trademark) ) Disks, magnetic strips, databases, servers and other suitable storage media. Also, the program may be transmitted from the network via a telecommunication link. Also, the program may be transmitted from the communication network via a telecommunication line.

(6) The embodiment described above is LTE (Long Term Evolution), LTE-A (LTE-Advanced), SUPER 3G, IMT-Advanced, 4G, 5G, FRA (Future Radio Access), W-CDMA (registered trademark) , GSM (registered trademark), CDMA2000, UMB (Ultra Mobile Broadband), IEEE 802.11 (Wi-Fi), IEEE 802.16 (WiMAX), IEEE 802.20, UWB (Ultra-WideBand), Bluetooth (registered trademark) And / or systems based on other suitable systems and / or expanded next generation systems based on these.

(7) In the embodiment described above, the information, signals, etc. described may be represented using any of a variety of different techniques. For example, data, instructions, commands, information, signals, bits, symbols, chips etc that may be mentioned throughout the above description may be voltage, current, electromagnetic waves, magnetic fields or particles, light fields or photons, or any of these May be represented by a combination of

(8) In the embodiment described above, input and output information may be stored in a specific place (for example, a memory) or may be managed by a management table. Information to be input or output may be overwritten, updated or added. The output information etc. may be deleted. The input information or the like may be transmitted to another device.

(9) In the embodiment described above, the determination may be performed by the value (0 or 1) represented by one bit, or may be performed by the true / false value (Boolean: true or false). It may be performed by comparison of numerical values (for example, comparison with a predetermined value).

(10) In the flowchart exemplified in the above-described embodiment, the order of the steps may be changed. That is, the order of each process in the preferred embodiment of the present invention is not limited to a specific order.

(11) The program exemplified in the above-described embodiment is referred to as an instruction, an instruction set, a code, a code segment, a program regardless of whether it is called software, firmware, middleware, microcode or hardware description language or other names. It should be interpreted broadly to mean code, subprograms, software modules, applications, software applications, software packages, routines, subroutines, objects, executables, threads of execution, procedures or functions, etc.
Also, software, instructions, etc. may be sent and received via a transmission medium. For example, software may use a wired technology such as coaxial cable, fiber optic cable, twisted pair and digital subscriber line (DSL) and / or a website, server, or other using wireless technology such as infrared, radio and microwave When transmitted from a remote source, these wired and / or wireless technologies are included within the definition of transmission medium.

(12) Any reference to an element using the designation "first," "second," etc. as used herein does not generally limit the quantity or order of those elements. These designations may be used herein as a convenient way of distinguishing between two or more elements. Thus, reference to the first and second elements does not mean that only two elements can be taken there, or that in any way the first element must precede the second element.

(13) In the embodiment described above, the case where the power receiver 30 and the information processing apparatus 100 are mobile stations is included. The mobile station may be a subscriber station, a mobile unit, a subscriber unit, a wireless unit, a remote unit, a mobile device, a wireless device, a wireless communication device, a remote device, a mobile subscriber station, an access terminal, a mobile terminal, a wireless terminal, by those skilled in the art. It may also be called a terminal, a remote terminal, a handset, a user agent, a mobile client, a client, or some other suitable term.

(14) In the form described above, the term "connected" or any variation thereof means any direct or indirect connection or coupling between two or more elements, It may include the presence of one or more intermediate elements between the two elements connected. The connection between elements may be physical, logical or a combination thereof. As used herein, the two elements are by using one or more electrical wires, cables and / or printed electrical connections, and radio frequency as some non-limiting and non-inclusive examples. It can be considered "connected" to one another by using electromagnetic energy such as electromagnetic energy having wavelengths in the region, microwave region and light (both visible and invisible) regions.

(15) In the above-mentioned form, the description "based on" does not mean "based only on" unless otherwise specified. In other words, the phrase "based on" means both "based only on" and "based at least on."

(16) As long as "including", "comprising", and variations thereof are used in the present specification or claims, these terms as well as the term "comprising" Is intended to be comprehensive. Further, it is intended that the term "or" as used in the present specification or in the claims is not an exclusive OR.

(17) Throughout the present application, when articles are added by translation, such as a, an and the in English, for example, these articles are not clearly indicated from the context, Including multiple.

(18) It will be apparent to those skilled in the art that the present invention is not limited to the embodiments described herein. The present invention can be implemented as modifications and changes without departing from the spirit and scope of the present invention defined based on the description of the claims. Accordingly, the description herein is for illustrative purposes and does not have any limiting meaning on the present invention. In addition, a plurality of aspects selected from the aspects illustrated in the present specification may be combined.

DESCRIPTION OF SYMBOLS 1 ... Power supply system, 10 ... Power supply management server, 11 ... Control apparatus, 12 ... Storage apparatus, 13 ... Communication apparatus, 20 ... Power supply machine, 21 ... Processing apparatus, 22 ... Beam irradiation apparatus, 23 ... Beam direction specific apparatus, 30 ... power receiver, 32 ... power reception module, 32A ... photoelectric conversion panel.

Claims (10)

A power supply management server connected to a power supply that specifies a direction toward a power receiver located in a beam irradiation range and irradiates the beam in the specified direction to enable power to the power receiver,
A communication device that receives receiver identification information that identifies the receiver;
A control device that instructs the power supply device to irradiate a beam to the power receiving device when the power receiving device identification information received by the communication device is power receiving device identification information identifying a power receiving device permitted to be fed When,
Power supply management server equipped with. Connected to a plurality of feeders including the feeder;
The communication device receives, from the plurality of power feeders, power feeder identification information assigned to a power feeder that specifies the direction of the power receiver.
When the power receiver identification information received by the communication device is the power receiver identification information of a power receiver to which power feeding is permitted, the control device is configured to transmit power to the power feeder corresponding to the power feeder identification information received by the communication device. Instructing to irradiate a beam to a power receiver corresponding to the power receiver identification information;
The power supply management server according to claim 1. The communication device receives a power supply start condition, which is a condition for automatically starting power supply to the power receiver,
The controller instructs the power supply to irradiate the beam to the power receiver if the power supply start condition is satisfied.
The power supply management server according to claim 1. The communication device receives a power supply termination condition which is a condition for automatically terminating power supply to the power receiver,
The controller is
In the case where the feed end condition is satisfied, an instruction is given to the feed device which is irradiating the beam to the power receiver, to finish the irradiation of the beam directed to the power receiver.
The power supply management server according to claim 1. The control device associates and manages power reception identification information of a power receiver to which power feeding is permitted and power feeding state information indicating a power feeding state of the power receiver, and power feeding is started based on a request of the power receiver to which power feeding is permitted. If the power supply is terminated based on the request of the power receiving device to which the power supply has been permitted, the power supply state information is updated.
The power supply management server according to claim 1. The power receiving device monitors the power supply by the beam after requesting the power supply management server to start power supply, and requests the power supply management server to start power supply again if power is not supplied.
When the communication device receives a request to start power feeding including the power receiver identification information from the power receiver, the control device is connected to the power feeder to which power feeder identification information associated with the power receiver identification information is assigned. Instructing the power receiver to emit a beam;
The power supply management server according to claim 5. The feeder is a first feeder,
Connected to the first feeder and the second feeder,
In the case where the power receiver is located in an overlapping range where the irradiation range of the first power feeder and the irradiation range of the second power feeder overlap,
The communication device is configured to receive first intensity information indicating the intensity of a beam emitted from the first power feeder detected in the power receiver, and the intensity of the beam emitted from the second power feeder detected in the power receiver. Receive second intensity information to indicate
The control device compares the first intensity information with the second intensity information, and when the first intensity information is larger than the second intensity information, a beam is directed to the first power feeder toward the power receiver. Instructing to irradiate, and instructing the second power feeder not to irradiate a beam towards the power receiver;
The power supply management server according to claim 1. The power receiver is an information processing apparatus,
The controller is
It manages the installation information that indicates the installation location of the feeder.
When the communication device receives a request including position information of the information processing device, the communication device is used to transmit installation information of a feeder according to the position information to the information processing device.
The power supply management server according to claim 1. The request includes receiver identification information of the receiver, and
If the receiver identification information included in the request is not the receiver identification information of the receiver to which the power supply has been permitted, the control device transmits, to the information processing device, subscription guidance information for prompting subscription to a power feeding service.
The power supply management server according to claim 8. A power feeding system comprising: a power feeding device for feeding power to a power receiving device; and a power feeding management server connected to the power feeding device,
The feeder is
A beam irradiation device for irradiating a beam;
A beam direction specifying device for specifying a direction from the beam irradiation device toward a power receiver located in the irradiation range of the beam;
And a processing device for irradiating the beam in the direction specified by the beam direction specifying device,
The power supply management server is
A communication device that receives receiver identification information that identifies the receiver;
A control device that instructs the power supply device to irradiate a beam to the power receiving device when the power receiving device identification information received by the communication device is power receiving device identification information identifying a power receiving device permitted to be fed With
Power supply system.

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