JP6646840B2 - Wireless power transmission system - Google Patents

Description

  The present disclosure relates to a wireless power transmission system that wirelessly transmits power.

  In recent years, wireless (non-contact) power transmission technology for wirelessly (non-contact) power transmission to mobile devices such as mobile phones and electric vehicles has been developed. For example, Patent Document 1 discloses a wireless power transmission system that performs power transmission using magnetic resonance. This system transmits magnetic power to another power receiving device by using magnetic resonance, even if only one power receiving device is in a power reach range for one power transmitting device. Thereby, power is supplied to the plurality of loads.

  A configuration for supplying power to a plurality of loads is also disclosed in Patent Document 2. Patent Literature 2 discloses that power is supplied from a power supply unit to a plurality of storages by wire instead of wirelessly. It is disclosed that when the storage unit is activated by the power supply unit, power is sequentially supplied from the power supply unit to each storage unit with a predetermined time difference via a non-simultaneous activation circuit.

JP 2010-154592 A JP 06-100031 A

  In the related art, in a wireless power transmission system in which one or more relay devices are arranged between a power transmitting device and a power receiving device to drive a plurality of loads, there is room for improvement in operation stability at startup. .

In order to solve the above problems, a wireless power transmission system according to an aspect of the present disclosure,
A wireless power transmission system including a power transmission device, a power reception device, and a relay device disposed between the power transmission device and the power reception device,
The power transmission device,
A transmission-side inverter circuit that converts transmission-side DC power supplied from an external power supply into transmission-side AC power,
A power transmission side power transmission antenna for wirelessly transmitting the power transmission side AC power,
The relay device,
A relay-side receiving antenna that receives the power-transmitting-side AC power,
A relay-side rectifier that converts the transmission-side AC power into relay-side DC power,
A relay-side inverter circuit that converts the relay-side DC power into relay-side AC power,
Relay side load,
A relay-side switch circuit that is disposed between the relay-side rectifier and the relay-side load and that switches connection / disconnection between the relay-side rectifier and the relay-side load;
A relay-side power transmitting antenna that wirelessly transmits the relay-side AC power,
The power receiving device,
A power receiving side power receiving antenna for receiving the relay side AC power,
A power receiving side rectifier that converts the relay side AC power into power receiving side DC power,
Receiving side load,
A power-receiving-side switch circuit that is disposed between the power-receiving-side rectifier and the power-receiving-side load and that switches connection / disconnection of the power-receiving-side rectifier and the power-receiving-side load;
In the wireless power transmission system,
First, in a state where the relay side switch circuit disconnects the relay side rectifier and the relay side load and the power receiving side switch circuit disconnects the power receiving side rectifier and the power receiving side load, the power transmission side The power transmitting side AC power is transmitted from the power transmitting antenna to the relay side power receiving antenna, and the relay side AC power is transmitted from the relay side power transmitting antenna to the power receiving side power receiving antenna,
Next, after the voltage of the power receiving side DC power reaches the required voltage of the power receiving device,
The power receiving side switch circuit connects the power receiving side rectifier and the power receiving side load at a timing T2 different from the timing T1 at which the relay side switching circuit connects the relay side rectifier and the relay side load.

  The above general or specific aspects may be implemented by a system, a method, an integrated circuit, a computer program, or a recording medium. Alternatively, the present invention may be realized by any combination of a system, an apparatus, a method, an integrated circuit, a computer program, and a recording medium.

  According to an embodiment of the present disclosure, it is possible to arrange one or more relay devices between a power transmission device and a power reception device to more stably operate a start-up operation in a wireless power transmission system that drives a plurality of loads. it can.

FIG. 2 is a diagram illustrating an example of a wireless power transmission system including a plurality of loads. FIG. 1 is a diagram illustrating an example of a system that supplies power from a power supply to each load via a number of cables. FIG. 9 is a diagram schematically illustrating a configuration of a wireless power transmission system according to a comparative example of the present disclosure. FIG. 9 is a diagram for describing a problem in a configuration of a comparative example. FIG. 5 is a diagram illustrating an example of a temporal change of a DC voltage and a load voltage in the configuration of the embodiment of the present disclosure. 1 is a block diagram schematically illustrating an example of a wireless power transmission system according to the present disclosure. 1 is a diagram illustrating an example of a wireless power transmission system in which one relay device 200 is disposed between a power transmitting device 100 and a power receiving device 300. FIG. 1 is a block diagram illustrating a configuration of a wireless power transmission system according to a first embodiment of the present disclosure. FIG. 4 is a diagram illustrating an example of an equivalent circuit of an antenna having a configuration of a series resonance circuit. FIG. 3 is a diagram illustrating a configuration example of a relay-side inverter circuit 230. FIG. 9 is a diagram illustrating another configuration example of the relay-side inverter circuit 230. FIG. 4 is a diagram illustrating a configuration example of a load modulation circuit 275. FIG. 14 is a diagram illustrating another configuration example of the load modulation circuit 275. FIG. 2 is a diagram schematically illustrating a configuration when the wireless power transmission system according to the first embodiment is applied to a robot arm. FIG. 4 is a sequence diagram illustrating an example of an operation at the time of startup according to the first embodiment. 1 is a diagram illustrating an example of a wireless power transmission system including a plurality of relay devices 200. FIG. FIG. 13 is a diagram schematically illustrating a configuration when the wireless power transmission system in FIG. 12 is applied to a robot arm. FIG. 9 is a sequence diagram illustrating an example of an operation at the time of startup in a wireless power transmission system including a plurality of relay devices 200. FIG. 3 is a diagram illustrating a phenomenon in which a DC voltage decreases after a load is connected, and a phenomenon (current draw) in which a DC current increases when a load is connected. It is a sequence diagram showing an example of an operation at the time of an abnormality. FIG. 13 is a sequence diagram illustrating an example of an operation at the time of startup according to the second embodiment. FIG. 13 is a sequence diagram illustrating an example of an operation at the time of startup when the number of relay devices is plural in the second embodiment. FIG. 14 is a sequence diagram illustrating an example of an operation according to the third embodiment. FIG. 14 is a sequence diagram illustrating an example of an operation at the time of startup when the number of relay devices is plural in the third embodiment.

(Knowledge underlying the present disclosure)
Before describing the embodiments of the present disclosure, the knowledge that became the basis of the present disclosure will be described.

  The present inventors dispose one or more relay devices between a power transmitting device and a power receiving device to drive a plurality of loads, and wireless power of a multi-stage connection (hereinafter, also referred to as “cascade connection”). We are considering a transmission system. Such a wireless power transmission system can be suitably used for a device such as a robot arm having a plurality of loads (for example, motors) as shown in FIG. In the robot arm shown in FIG. 1, a plurality of portions are rotated or moved by a motor. For this reason, it is necessary to supply power to each motor individually for control.

  In such a device having a plurality of movable parts, conventionally, power has been supplied from a power supply to each load through a large number of cables. FIG. 2 is a diagram schematically showing such a conventional configuration. In the configuration shown in FIG. 2, power is supplied from a power supply to a plurality of loads through a wired bus connection. However, in such a configuration, there is a problem that an accident due to the catching of the cable is likely to occur, a movable range is limited, and parts cannot be easily replaced. Therefore, the present inventors are studying to supply power to each load from a power supply using wireless power transmission and to eliminate a cable from the power supply.

  FIG. 3 is a diagram schematically illustrating a configuration of a wireless power transmission system according to a comparative example of the present disclosure. This wireless power transmission system has a cascade connection configuration in which a plurality of relay devices are connected between a power transmitting device and a power receiving device. Each relay device and power receiving device are connected to a load. In this example, there are a plurality of relay devices, but there may be one relay device.

  In a wired system using a bus connection, generally, when the power is turned on, all the loads are energized almost simultaneously. On the other hand, in the cascade-connected wireless power transmission system, power is supplied in order from the load connected to the relay device close to the power supply.

  However, according to studies by the present inventors, it has been found that the configuration of the comparative example shown in FIG. 3 has the following problems.

  (1) When starting power transmission, the power is immediately supplied to the load after various control circuits in the wireless power transmission system (for example, a microcontroller or the like that controls an inverter circuit in each relay device) are activated, so that a voltage drop occurs. May stop the control circuit. For this reason, power cannot be supplied stably to each load.

  (2) Since power is supplied to the load all at once after the various control circuits in the wireless power transmission system are activated, excessive current flows to the load due to transient response. As a result, the load cannot operate as desired.

  FIG. 4A is a diagram for describing the above-described problem in the configuration of the comparative example in more detail. FIG. 4A shows an example of a time change of a direct current (DC) voltage output from a rectifier in each relay device to an inverter circuit and a voltage (load voltage) applied to a load. When the wireless power transmission system performs connection and power supply to the load upon startup, each relay device is connected to the load immediately after receiving power. As a result, each relay device is connected to the load in a state where the DC voltage has not reached a predetermined value (for example, a voltage value required by the power receiving device). Then, as shown in FIG. 4A, there is a possibility that the voltage required for driving the control circuit (referred to as a control system driving voltage) is temporarily lowered due to a voltage drop. In such a situation, the inverter circuit in the relay device cannot be driven, and an uncontrollable state occurs.

  The present inventors have found the above problem in a wireless power transmission system that supplies power to a plurality of loads via a relay device, and have studied a configuration for solving the problem. As a result, the inventors have conceived that the above-mentioned problem can be solved by connecting the load to the load at a shifted timing after the transmission power is established. Here, “establishment of transmission power” refers to a state in which a predetermined voltage required by the power receiving device and required for stable operation (referred to as “required voltage of power receiving device” in this specification) is satisfied. Means that

  FIG. 4B is a diagram illustrating an example of a temporal change of the DC voltage and the load voltage in the configuration of the embodiment of the present disclosure in which the load is connected after the transmission power is established. In this example, connection to the load is performed in a state where the DC voltage output by the rectifier circuit in the relay device satisfies the required voltage of the power receiving device. Here, the required voltage of the power receiving device is set to a sufficiently high voltage that the DC voltage does not fall below the drive voltage of the control system even if a voltage drop occurs due to the connection of the load. Therefore, according to the embodiment of the present disclosure, control can be continued without the DC voltage falling below the drive voltage. Further, in the embodiment of the present disclosure, after the transmission power is established, the connection to the load is performed at a shifted timing. Thus, stable start-up is possible without falling into an uncontrollable state.

(Overview of Embodiment of the Present Disclosure)
A wireless power transmission system according to an aspect of the present disclosure,
A wireless power transmission system including a power transmission device, a power reception device, and a relay device disposed between the power transmission device and the power reception device,
The power transmission device,
A transmission-side inverter circuit that converts transmission-side DC power supplied from an external power supply into transmission-side AC power,
A power transmission side power transmission antenna for wirelessly transmitting the power transmission side AC power,
The relay device,
A relay-side receiving antenna that receives the power-transmitting-side AC power,
A relay-side rectifier that converts the transmission-side AC power into relay-side DC power,
A relay-side inverter circuit that converts the relay-side DC power into relay-side AC power,
Relay side load,
A relay-side switch circuit that is disposed between the relay-side rectifier and the relay-side load and that switches connection / disconnection between the relay-side rectifier and the relay-side load;
A relay-side power transmitting antenna that wirelessly transmits the relay-side AC power,
The power receiving device,
A power receiving side power receiving antenna for receiving the relay side AC power,
A power receiving side rectifier that converts the relay side AC power into power receiving side DC power,
Receiving side load,
A power-receiving-side switch circuit that is disposed between the power-receiving-side rectifier and the power-receiving-side load and that switches connection / disconnection of the power-receiving-side rectifier and the power-receiving-side load;
In the wireless power transmission system,
First, in a state where the relay side switch circuit disconnects the relay side rectifier and the relay side load and the power receiving side switch circuit disconnects the power receiving side rectifier and the power receiving side load, the power transmission side The power transmitting side AC power is transmitted from the power transmitting antenna to the relay side power receiving antenna, and the relay side AC power is transmitted from the relay side power transmitting antenna to the power receiving side power receiving antenna,
Next, after the voltage of the power receiving side DC power reaches the required voltage of the power receiving device,
The power receiving side switch circuit connects the power receiving side rectifier and the power receiving side load at a timing T2 different from the timing T1 at which the relay side switching circuit connects the relay side rectifier and the relay side load.

According to the above aspect,
After the voltage of the power receiving-side DC power reaches the required voltage of the power receiving device, the connection between the relay rectifier and the relay load and the connection between the power receiving rectifier and the power receiving load are performed. Further, the former connection and the latter connection are performed at different timings.

For this reason, the above problem in the comparative example, that is,
(1) When starting power transmission, the power is immediately supplied to the load after various control circuits in the wireless power transmission system (for example, a microcontroller or the like that controls an inverter circuit in each relay device) are activated, so that a voltage drop occurs. May stop the control circuit. For this reason, power cannot be supplied stably to each load.
(2) Since power is supplied to the load all at once after the various control circuits in the wireless power transmission system are activated, excessive current flows to the load due to transient response. As a result, the load cannot operate as desired.
Can be solved.

A wireless power transmission system according to another aspect of the present disclosure,
A wireless power transmission system comprising: a power transmission device; a power reception device; and N (N is an integer of 2 or more) relay devices disposed between the power transmission device and the power reception device,
The power transmission device,
A transmission-side inverter circuit that converts transmission-side DC power supplied from an external power supply into transmission-side AC power,
A power transmission side power transmission antenna for wirelessly transmitting the power transmission side AC power,
The first relay device among the N relay devices is:
A first relay-side power receiving antenna for receiving the power transmission-side AC power,
A first relay-side rectifier for converting the transmission-side AC power into a first relay-side DC power,
A first relay-side inverter circuit that converts the first relay-side DC power into a first relay-side AC power;
A first relay load;
A first relay disposed between the first relay-side rectifier and the first relay-side load for switching connection / disconnection between the first relay-side rectifier and the first relay-side load; A relay-side switch circuit,
A first relay-side power transmitting antenna that wirelessly transmits the first relay-side AC power,
The i-th (i = 2 to N) relay devices of the N devices are:
An i-th relay-side receiving antenna that receives the (i-1) -th relay-side AC power,
An i-th relay rectifier for converting the (i-1) -th relay AC power into an i-th relay DC power,
An i-th relay-side inverter circuit that converts the i-th relay-side DC power into an i-th relay-side AC power,
an i-th relay load,
An i-th relay-side rectifier disposed between the i-th relay-side rectifier and the i-th relay-side load, for switching connection / disconnection between the i-th relay-side rectifier and the i-th relay-side load; A relay-side switch circuit,
An i-th relay-side power transmitting antenna that wirelessly transmits the i-th relay-side AC power,
The power receiving device,
A power receiving side power receiving antenna for receiving the Nth relay side AC power,
A receiving-side rectifier that converts the N-th relay-side AC power into receiving-side DC power;
Receiving side load,
A power receiving side switch circuit that is disposed between the power receiving side rectifier and the power receiving side load and that switches connection / disconnection of the power receiving side rectifier and the power receiving side load;
In the wireless power transmission system,
First, the i-th (i = 1 to N) switch circuit disconnects the i-th (i = 1 to N) relay-side rectifier and the i-th (i = 1 to N) relay-side load. And, in the state where the power receiving side switch circuit disconnects the power receiving side rectifier and the power receiving side load, the power transmitting side AC power transmitted from the power transmitting side power transmitting antenna is the i-th (i = 1 to i) N), sequentially transmitted through the relay device to the power receiving side power receiving antenna as the Nth AC power,
Next, the i-th (i = 1 to N) switch circuit is connected to the i-th (i = 1 to N) relay-side rectifier at the timing Ti (i = 1 to N) by the i-th (i = 1 to N). N), and the power-receiving-side switch circuit connects the power-receiving-side rectifier and the power-receiving-side load at timing Tr, and at least one of the timing Ti (i = 1 to N) and the timing Tr. Some are different.

According to the above aspect,
First, the i-th (i = 1 to N) switch circuit disconnects the i-th (i = 1 to N) relay-side rectifier and the i-th (i = 1 to N) relay-side load. And, in a state where the power receiving side switch circuit disconnects the power receiving side rectifier and the power receiving side load, the power transmitting side AC power transmitted from the power transmitting side power transmitting antenna is the i-th (i = 1 to i) The power is sequentially transmitted to the power receiving side power receiving antenna as the Nth AC power via the relay device N). Next, the i-th (i = 1 to N) switch circuit is connected to the i-th (i = 1 to N) relay-side rectifier at the timing Ti (i = 1 to N) by the i-th (i = 1 to N). N), and the power receiving side switch circuit connects the power receiving side rectifier and the power receiving side load at timing Tr. Here, at least a part of the timing Ti (i = 1 to N) and the timing Tr are different. That is, the timing Ti (i to 1 to N) and the timing Tr are not all the same timing.

  Thus, power supply to each load is started after power is transmitted to all of the N relay devices and the power receiving devices. The timing of starting power supply to the load in the i-th (i = 1 to N) relay device and the timing of starting power supply to the load in the power receiving device are shifted (at least in part).

Therefore, also in the present embodiment, the above-described problem in the comparative example,
(1) When starting power transmission, since various control circuits (for example, a microcomputer) in the wireless power transmission system are started and immediately connected to a load, the control circuit may be stopped due to a voltage drop. As a result, power cannot be supplied stably to each load.
(2) Since various control circuits in the wireless power transmission are simultaneously connected to the load after being activated, excessive current flows due to a transient response when the load is connected. As a result, the load cannot operate as desired.
Can be solved.

  Here, a basic configuration in the embodiment of the present disclosure will be described.

  FIG. 5A is a block diagram schematically illustrating an example of the wireless power transmission system of the present disclosure. In this system, power is wirelessly transmitted from the power transmitting device 100 connected to the external power supply 50 to the power receiving device 300 via the plurality of relay devices 200. Each of the plurality of relay apparatuses 200 and the power receiving apparatuses 300 is connected to the load 400 and supplies a part of the received power to the load 400. Each relay device 200 supplies power to the connected load 400 and transmits power to a subsequent device (another relay device 200 or power receiving device 300 in proximity) in a non-contact manner. Note that, in this specification, the side closer to the power transmitting device is referred to as “front stage” and the side closer to the power receiving device is referred to as “back stage” with respect to the relay device of interest.

  Power transmission between the devices is performed by a power transmitting antenna and a power receiving antenna. The power transmitting device 100 includes a power transmitting antenna, and the power receiving device 300 includes a power receiving antenna. Each relay device 200 includes both a power receiving antenna and a power transmitting antenna. Each antenna can be realized by, for example, a resonant circuit including a coil and a capacitor, or a circuit including a pair of electrodes. The former is used for power transmission by magnetic field coupling, and the latter is used for power transmission by electric field coupling.

  The load 400 is not limited to a motor, and may be any load such as a camera or a lighting device. The load 400 is driven by power from the connected relay device 200 or power receiving device 300.

  Although the system illustrated in FIG. 5A includes a plurality of relay devices 200, the number of relay devices 200 may be one. FIG. 5B illustrates an example of a wireless power transmission system in which one relay device 200 is disposed between the power transmitting device 100 and the power receiving device 300.

  With the above configuration, power is wirelessly transmitted from the power transmitting device 100 to the power receiving device 300 via at least one relay device 200. Power can be individually supplied to each load 400 without using a cable connecting the power supply 50 and the loads 400. Furthermore, since the control circuits in each device cooperate to appropriately adjust the timing of connection to each load 400, the operation at startup can be stabilized.

  5A and 5B, the load 400 is shown as a component independent of the relay device 200 or the power receiving device 300. However, the load 400 may be handled as included in the relay device 200 or the power receiving device 300. Good.

  Hereinafter, more specific embodiments of the present disclosure will be described. However, an unnecessary detailed description may be omitted. For example, a detailed description of a well-known item or a redundant description of substantially the same configuration may be omitted. This is to prevent the following description from being unnecessarily redundant and to facilitate understanding by those skilled in the art. The inventors provide the accompanying drawings and the following description so that those skilled in the art can fully understand the present disclosure, and they are intended to limit the subject matter described in the claims. is not. In the following description, the same or similar components are denoted by the same reference numerals.

  In this specification, for the sake of simplicity, the terms relating to the power transmitting device are referred to as “power transmitting side”, the term relating to the relay device is referred to as “relay side”, and the term relating to the power receiving device is referred to as “power receiving side”. May be used. Terms such as “power transmission side”, “relay side”, and “power reception side” may be omitted for simplicity.

(Embodiment 1)
FIG. 6 is a block diagram illustrating a configuration of the wireless power transmission system according to the first embodiment of the present disclosure. This wireless power transmission system includes a power transmitting device 100, a relay device 200, and a power receiving device 300. This system corresponds to the configuration shown in FIG. 5B and includes one relay device 200 between the power transmitting device 100 and the power receiving device 300. In the present embodiment, power is sequentially supplied to the loads 395 and 295 in order from the power receiving device 300 to the relay device 200.

  The power transmission device 100 includes a power transmission side inverter circuit 130 that converts DC power (power transmission side DC power) supplied from an external power supply (DC power supply) 50 into AC power (power transmission side AC power) and outputs the power, and a power transmission side inverter circuit. And a power transmitting side power transmitting antenna 140 for transmitting the AC power output from 130. The power transmission device 100 further demodulates data transmitted from the power transmission side pulse output circuit 160 that drives the power transmission side inverter circuit 130, the power transmission side control circuit 150 that controls the power transmission side pulse output circuit 160, and the relay device 200. And a power transmission side demodulator 180. Demodulator 180 demodulates the data transmitted from relay device 200 by detecting a change in the amplitude of the AC voltage output from power transmission side inverter circuit 130. Note that a receiver 190 and a transmitter 192 that perform communication of another method may be provided in place of communication using such amplitude modulation.

  The relay device 200 is electromagnetically coupled to the power transmission side transmission antenna 140 and receives the transmitted AC power (power transmission side AC power). The relay side power reception antenna 210, and converts the received power transmission side AC power into DC power (relay power). Relay-side rectifier 220 for converting the relay-side DC power to AC power (relay-side AC power), and a relay-side for wirelessly transmitting the converted relay-side AC power. A power transmission antenna 240. Further, the relay device 200 includes a relay-side pulse output circuit 260 that drives the inverter circuit 230, and a relay-side control circuit 250 that controls the relay-side pulse output circuit 260. The control circuit 250 converts DC power to AC power by controlling the inverter circuit 230 via the pulse output circuit 260.

  The relay device 200 further includes a relay load 295, a relay switch circuit 255 disposed between the relay rectifier 220 and the relay load 295, and a relay for detecting a DC voltage output from the relay rectifier 220. And a side detector 225. The relay-side switch circuit 255 includes one or more switching elements, and switches on / off of the switching elements in response to a control signal from the control circuit 250. Thereby, connection / disconnection of the relay side rectifier 220 and the relay side load 295 is switched. The relay-side control circuit 250 generates the above-described control signal based on a comparison result between the value of the DC voltage detected by the relay-side detector 225 and a predetermined value of the required voltage of the power receiving device 300, It is sent to the relay side switch circuit 255.

  The relay device 200 includes a load modulation circuit 275 and a relay-side amplitude modulator 270 as components for transmitting data to the power transmission device 100. Further, a relay-side demodulator 280 is provided as a component for receiving data from the power receiving device 200. The load modulation circuit 275 is connected between the power receiving antenna 210 and the rectifier 220, and changes the size of the load of the load modulation circuit 275 according to the value of data to be transmitted. Relay-side demodulator 280 detects a change in the amplitude of the AC voltage applied to power transmitting antenna 240 and demodulates data transmitted from power receiving device 300 at the subsequent stage. Instead of these components, a transmitter 292 and a receiver 290 that perform communication by another method may be used.

  The power receiving apparatus 300 receives the relay-side AC power transmitted from the relay-side power transmitting antenna 240, and converts the AC power received by the power receiving antenna 310 into DC power (power-receiving DC power) and outputs the DC power. It includes a power receiving side rectifier 320, a power receiving side load 395, and a power receiving side switch circuit 355 disposed between the power receiving side rectifier 320 and the power receiving side load 395. The power receiving side switch circuit 355 includes one or more switching elements. By switching on / off of the switching element in response to a control signal from the power receiving side control circuit 350, connection / disconnection between the power receiving side rectifier 320 and the power receiving side load 395 is switched. The control signal is generated based on a comparison result between the magnitude of the power receiving side DC power detected by the power receiving side detector 325 and the required voltage of the power receiving device 300.

  The power receiving device 300 further includes a load modulation circuit 375 connected between the power receiving antenna 310 and the rectifier 320, and a power receiving side amplitude that controls the load modulation circuit 375 to modulate the amplitude of the AC power received by the power receiving antenna 310. And a modulator 370. A transmitter 392 and a receiver 390 that perform communication using a method different from the amplitude modulation method may be separately provided.

  Each of the power transmitting side power transmitting antenna 140, the relay side power receiving antenna 210, the relay side power transmitting antenna 240, and the power receiving side power receiving antenna 310 can be realized by a resonance circuit including a coil and a capacitor, for example. FIG. 7 shows an example of an equivalent circuit of the antennas 140, 240, 210, 310 having a configuration of a series resonance circuit. Not limited to the illustrated example, each antenna may have a configuration of a parallel resonance circuit. In this specification, the coil of the power transmitting antenna may be referred to as a power transmitting coil, and the coil of the power receiving antenna may be referred to as a power receiving coil. According to such an antenna, power is transmitted wirelessly by inductive coupling (that is, magnetic field coupling) between the power transmitting coil and the power receiving coil. Each antenna may have a configuration for wirelessly transmitting power using electric field coupling instead of magnetic field coupling. In that case, each antenna may include two electrodes for transmitting or receiving power and a resonant circuit including an inductor and a capacitor. A power transmitting antenna and a power receiving antenna using electric field coupling can be suitably used when wirelessly transmitting power to a moving device such as a transfer robot in a factory.

  The power receiving device 300 may be, for example, a tip of a robot arm or a rotating unit of a monitoring camera. The power transmission device 100 is a device that wirelessly supplies power to the relay device 200, and may be mounted on, for example, a root-side portion of a robot arm or a fixed portion of a monitoring camera. The relay device 200 may be, for example, a portion that connects the root-side portion of the robot arm and the tip portion, or a portion that connects the fixed portion and the rotating portion of the monitoring camera.

  Each load may be, for example, a device including a motor such as an actuator mounted on a tip of a robot arm, or an imaging device such as a CCD camera or a lighting device mounted on a rotating unit of a monitoring camera. Each load is connected to the relay rectifier 220 or the power receiving rectifier 320 via the switch circuit 255 or 355, and is driven by DC power.

  Each rectifier can be a known rectifier circuit such as, for example, a single-phase full-wave rectifier circuit or a single-phase half-wave rectifier circuit. Each inverter circuit may be, for example, a known full-bridge or half-bridge inverter circuit. Each pulse output circuit can be, for example, a known gate driver circuit. Each control circuit can be an integrated circuit including a processor and a memory, such as a microcontroller (microcomputer). When the processor executes the control program stored in the memory, an operation described later is executed. Each of the control circuits 150, 250, 350 may be part of a circuit integrated with other components.

  FIG. 8 is a diagram illustrating a configuration example of the relay-side inverter circuit 230. The inverter circuit 230 includes a plurality of switching elements S1 to S4 that change the conduction / non-conduction state according to the pulse signal supplied from the pulse output circuit 260. By changing the conduction / non-conduction state of each switching element, the input DC power can be converted to AC power. In the example shown in FIG. 8, a full-bridge type inverter circuit including four switching elements S1 to S4 is used. In this example, each switching element is an IGBT (Insulated-Gate Bipolar Transistor), but other types of switching elements such as a MOSFET (Metal Oxide Semiconductor Field-Effect Transistor) may be used.

  In the example shown in FIG. 8, among the four switching elements S1 to S4, the switching elements S1 and S4 (referred to as a first switching element pair) output a voltage having the same polarity as the supplied DC voltage at the time of conduction. On the other hand, switching elements S2 and S3 (referred to as a second switching element pair) output a voltage having a polarity opposite to the supplied DC voltage when conducting. The pulse output circuit 260 supplies a pulse signal to the gates of the four switching elements S1 to S4 according to an instruction from the control circuit 250. At this time, by adjusting the phase difference between the two pulse signals supplied to the first switching element pair (S1 and S4) and the phase difference between the two pulse signals supplied to the second switching element pair (S2 and S3). , Amplitude control can be performed.

  FIG. 9 is a diagram illustrating another configuration example of the relay-side inverter circuit 230. The inverter circuit 230 in this example is a half-bridge type inverter circuit. When a half-bridge type inverter circuit is used, the above-described phase control cannot be applied. In this case, the amplitude of the voltage can be controlled by controlling the duty ratio of the pulse signal input to each switching element.

  The inverter circuit 230 shown in FIG. 9 is a half-bridge type inverter circuit including two switching elements S1 and S2 and two capacitors. The two switching elements S1, S2 and the two capacitors C1, C2 are connected in parallel. One end of the power transmission antenna 240 is connected to a point between the two switching elements S1 and S2, and the other end is connected to a point between the two capacitors C1 and C2.

  The control circuit 250 and the pulse output circuit 260 supply a pulse signal to each switching element so that the switching elements S1 and S2 are turned on alternately. Thereby, DC power is converted into AC power.

  In this example, by adjusting the duty ratio of the pulse signal (that is, the ratio of the ON period in one cycle), the output time ratio of the output voltage V (that is, a non-zero value in one cycle is changed). Percentage of time taken). Thus, the amplitude of the voltage of the AC power input to power transmission antenna 240 can be adjusted. Such a duty control can be similarly applied when a full-bridge type inverter circuit as shown in FIG. 8 is used.

  In the above example, the configuration and the control method of the relay-side inverter circuit 230 are illustrated, but the same configuration and control can be similarly applied to the power transmission-side inverter circuit 130.

  FIG. 10A is a diagram illustrating a configuration example of the load modulation circuit 275. The illustrated load modulation circuit 275 is connected between the power receiving antenna 210 and the rectifier 220. Load modulation circuit 275 includes two switches and two capacitors connected in parallel to power receiving antenna 210, and a resistor connected between a point between the two capacitors and ground. The load modulation circuit 275 performs load modulation by switching the open / close state of two switches based on a control signal from the amplitude modulator 270. More specifically, the magnitude of the load of the entire circuit is changed by switching on and off states of two switches to open or close a path through which a current flows separately from a path toward the load 400. . Thereby, information can be transmitted to power transmission device 100.

  In the configuration example shown in FIG. 6, the load modulation circuit 275 is arranged before the rectifier 220, but may be arranged after the rectifier 220. FIG. 10B is a diagram illustrating an example of the load modulation circuit 275 arranged as such. This load modulation circuit 275 is connected between the rectifier 220 and the load 400. Load modulation circuit 275 includes a resistor and a switch connected in parallel to rectifier 220. By switching the ON / OFF state of the switch based on a control signal from the amplitude modulator 270, the load of the entire power receiving device can be changed.

  10A and 10B show a configuration example of the relay-side amplitude modulator 270 and the relay-side load modulation circuit 275, but the power-receiving-side amplitude modulator 370 and the power-receiving-side load modulation circuit 375 have the same configuration.

  With such a configuration, the wireless power transmission system of the present embodiment can communicate data between adjacent devices while wirelessly transmitting power. The type of data to be transmitted may be information such as a stability notification, arrival information, and a notification of completion of leading end energization described later. Alternatively, it may be information indicating a power value or a voltage value in the circuit, a control signal from a connected load or a signal indicating an abnormality, or a response signal to a command or image (video) data.

  Next, the operation of the wireless power transmission system according to the present embodiment will be described.

  In the wireless power transmission system of the present embodiment, the relay switch circuit 255 disconnects the relay rectifier 220 and the relay load 295, and the power switch circuit 355 connects the power rectifier 330 and the power load 395 to each other. The power transmission starts from a state in which is disconnected. In this state, power transmission-side AC power is transmitted from power transmission-side power transmission antenna 140 to relay-side power reception antenna 210, and further, relay-side AC power is transmitted from relay-side power transmission antenna 240 to power reception-side power reception antenna 310.

  That is, power is transmitted first when both the relay side switch circuit 255 and the power receiving side switch circuit 355 are non-conductive (OFF). Then, the voltage of the power receiving side DC power eventually reaches the required voltage of power receiving device 300. Here, the required voltage of the power receiving device 300 means a value of a predetermined voltage preset in the power receiving device. This required voltage is set to a sufficiently high value that does not fall below the drive voltage of a power reception control circuit (for example, a microcomputer) in the power receiving device even when power is supplied to the power receiving side load connected to the power receiving device.

  Next, after the voltage of the power receiving side DC power reaches the required voltage of the power receiving device, the relay side switch circuit 255 connects the relay side rectifier 220 and the relay side load 295 at the timing T1, and the timing T2 different from the timing T1. , The power receiving side switch circuit 355 connects the power receiving side rectifier 330 and the power receiving side load 395.

In the present embodiment, the timing T1 is later than the timing T2. That is, power is supplied to the load sequentially from the rear (front end side). To summarize the above, the flow of operation in the present embodiment is as follows (1) to (5).
(1) The relay switch circuit 255 disconnects the relay rectifier 220 and the relay load 295, and the power switch circuit 355 disconnects the power rectifier and the load.
(2) The power transmitting side AC power is transmitted from the power transmitting side power transmitting antenna 140 to the relay side power receiving antenna 210, and the relay side AC power is transmitted from the relay side power transmitting antenna 240 to the power receiving side power receiving antenna 310.
(3) The voltage of the power receiving side DC power reaches the required voltage of the power receiving device 300.
(4) The power receiving side switch circuit 355 connects the power receiving side rectifier 330 and the power receiving side load 395.
(5) The relay switch circuit 255 connects the relay rectifier 230 and the relay load 295.

  After the above (4), after the power receiving-side DC power is stabilized, that is, after the time change of the power receiving-side DC power falls within a predetermined range, the power receiving apparatus 300 receives information indicating that (in the present specification, A “stability notification” may be transmitted to the relay device 200. The relay-side control circuit 250 can switch the relay-side switch circuit 255 from off to on, triggered by the reception of the stability notification. Transmission and reception of such a stability notification can be performed by the power receiving side amplitude modulator 370 and the power receiving side load modulation circuit 375, and the relay side demodulator 280. Instead, the transmission may be performed using the transmitter 392 in the power receiving device 300 and the receiver 290 in the relay device 200.

  Next, a more specific example of the operation in the present embodiment will be described. In the following description, the configuration shown in FIG. 11A is assumed as an example.

  FIG. 11A is a diagram schematically illustrating a configuration when the wireless power transmission system according to the present embodiment is applied to a robot arm. This robot arm includes a power transmission device 100 at the base, a power receiving device 300 at the distal end, and a relay device 200 therebetween. Here, in each device, a group of circuit elements related to power transmission is called a power transmission circuit, and a group of circuit elements related to power reception is called a power reception circuit. That is, the power transmission circuit includes components related to power transmission, such as an inverter circuit and a power transmission antenna. On the other hand, the power receiving circuit includes components related to power receiving, such as a power receiving antenna and a rectifier. The power transmission device 100 illustrated in FIG. 11A includes a power transmission side power transmission circuit 145. The relay device 200 includes a relay-side power receiving circuit 205, a relay-side load 295, and a relay-side power transmission circuit 245. The power receiving device 300 includes a power receiving side power receiving circuit 305 and a power receiving side load 395.

  FIG. 11B is a sequence diagram illustrating an example of an operation at the time of startup in the present embodiment. FIG. 11B shows the order of supplying (starting up) the power to each unit and the timing of the stability notification after the power is supplied to the load. After the power is turned on, when the voltage supplied to each control circuit exceeds a predetermined voltage (the drive voltage of the control system described above), the control circuit is activated, the inverter circuit is driven, and power transmission is started. The control circuits 250 and 350 are connected to the rectifier circuits 275 and 375, respectively, and are driven by the DC power output from the rectifier circuits 275 and 375. The power transmission side control circuit 150 is driven by DC power output from the power supply 50. The power is transmitted in the order of the power transmission circuit 145, the relay power reception circuit 205, the relay power transmission circuit 245, and the power reception circuit 305. During this time, the relay-side switch circuit 255 and the power-receiving-side switch circuit 355 are kept in a non-connected (off) state. After the power receiving side power receiving circuit 305 receives the power, the power receiving side control circuit 350 determines that the voltage value of the power receiving side DC power detected by the power receiving side detector 325 is equal to a predetermined threshold (the required voltage of the power receiving device 300 described above). To determine if it exceeds. When determining that the voltage value of the power receiving-side DC power has exceeded a predetermined threshold, the power receiving side control circuit 350 sends a control signal to the power receiving side switch circuit 355 to switch on. As a result, power is supplied to the power receiving load 395. After that, when detecting that the temporal variation of the voltage of the power receiving side DC power falls within a predetermined range, the power receiving side control circuit 350 transmits a stability notification to the relay device 200. This stability notification is transmitted when the power receiving side control circuit 350 instructs the power receiving side amplitude modulator 370 to transmit data indicating the stability notification. Relay-side control circuit 250 reads (receives) the transmitted stability notification based on the fluctuation in the amplitude of the voltage detected by relay-side demodulator 280. After receiving the stability notification, the relay-side control circuit 250 sends a control signal to the relay-side switch circuit 255 to switch on. As a result, power is supplied to the relay load 295.

  As described above, in the present embodiment, after the voltage of the power receiving-side DC power reaches the required voltage of the power receiving device 300, power is supplied to the power receiving load 395 and the relay load 295 in this order. Therefore, a sudden voltage drop that occurs when power is simultaneously supplied to the relay load 295 and the power receiving load 395 can be suppressed. As a result, it is possible to avoid a stop of the operation of the control system (such as the relay-side control circuit 250 and the power-receiving-side control circuit 350) due to the rapid voltage drop.

  In the present embodiment, the number of relay devices 200 is one, but a plurality of relay devices 200 may be arranged between the power transmitting device 100 and the power receiving device 300. Hereinafter, an example of such a wireless power transmission system will be described.

  FIG. 12 is a diagram illustrating an example of a wireless power transmission system including a plurality of relay devices 200. The wireless power transmission system is disposed between the power transmitting device 100 (not shown), the power receiving device 300 (not shown), and the power transmitting device 100 and the power receiving device 300, and is arranged in the order from the first to the Nth power transmitting device 100. And N (N is an integer equal to or greater than 2) relay devices 200 arranged in order. FIG. 12 illustrates only the (i-1) -th (i = 2 to N) and i-th relay devices of the N (N is an integer equal to or greater than 2) relay devices. The configuration of each relay device 200 is the same as the configuration of the relay device 200 shown in FIG. The configurations of the power transmitting device 100 and the power receiving device 300 not shown in FIG. 12 are the same as the configurations of the power transmitting device 100 and the power receiving device 300 shown in FIG. 6, respectively.

In the wireless power transmission system shown in FIG. 12, first, the i-th (i = 1 to N) relay switch circuit 255 is connected to the i-th (i = 1 to N) relay rectifier 220 and the i-th (i = 1 to N). N) with the relay-side load 295 disconnected, and the power-receiving-side switch circuit 355 disconnecting the power-receiving-side rectifier 320 and the power-receiving-side load 395 in a disconnected state. The power is sequentially transmitted to the power receiving antenna 310 as the Nth AC power via the i-th (i = 1 to N) relay devices. Next, the i-th (i = 1 to N) switch circuit is connected to the i-th (i = 1 to N) relay-side rectifier 220 at the timing Ti (i = 1 to N) and the i-th (i = 1 to N). And the power receiving side switch circuit connects the power receiving side rectifier 320 and the power receiving side load 395 at timing Tr. Here, at least part of the timing Ti (i = 1 to N) and the timing Tr are different. In the present embodiment, particularly, an example in which power is supplied to a load with a timing shifted sequentially from the rear (toward the power receiving device 300) will be described. That is, an example in the case of Tr < _TN < _TN-1 <... <T1 will be described.

The wireless power transmission system shown in FIG. 12 performs, for example, the following operation.
(1) The power transmission is started with the relay rectifier 220 and the relay load 295 in each relay device 200 disconnected (off), and the power receiving rectifier 320 and the power receiving load 395 disconnected (off).
(2) After the voltage of the power receiving side DC power reaches the required voltage of the power receiving device 300, the power receiving device 300 supplies the power receiving side load 395 with the power receiving side DC power.
(3) After the power receiving-side DC power of the power receiving device 300 is stabilized, a “stability notification” is transmitted from the power receiving device 300 to the N-th relay device, and power is supplied to the N-th relay load.
(4) After the N-th relay-side DC power is stabilized, a “stability notification” is transmitted from the N-th relay device to the (N−1) -th relay device, and power is supplied to the (N−1) -th relay-side load. .
(5) Thereafter, the same operation as (4) is repeated while decreasing the number of the relay device, until power is supplied to the first relay-side load.

  Next, a more specific example of the operation in the present embodiment will be described. Here, the configuration of the robot arm shown in FIG. 13A is assumed. This robot arm has the same configuration as that shown in FIG. 11A except that a plurality of relay devices 200 are provided.

  FIG. 13B is a sequence diagram illustrating an example of an operation at the time of startup in this example. FIG. 13B shows the order of supplying (starting) power to each unit and the timing of the stability notification after power is supplied to the load. After the power is turned on, when the voltage supplied to each control circuit exceeds a predetermined voltage (the drive voltage of the control system described above), the control circuit is activated, the inverter circuit is driven, and power transmission is started. The power is transmitted in the order of the power transmitting device 100, the first relay device,..., The N-th relay device, and the power receiving device 300. During this time, the relay-side switch circuit 255 and the power-receiving-side switch circuit 355 in each relay device 200 are kept in a non-connected (off) state. After the power receiving side power receiving circuit 305 receives the power, the power receiving side control circuit 350 determines that the voltage value of the power receiving side DC power detected by the power receiving side detector 325 is equal to a predetermined threshold (the required voltage of the power receiving device 300 described above). To determine if it exceeds. When determining that the voltage value of the power receiving-side DC power has exceeded a predetermined threshold, the power receiving side control circuit 350 sends a control signal to the power receiving side switch circuit 355 to switch on. As a result, power is supplied to the power receiving load 395. Thereafter, upon detecting that the temporal variation of the voltage of the DC power of the power receiving side falls within a predetermined range, the power receiving side control circuit 350 transmits a stability notification to the Nth relay apparatus 200. This stability notification is transmitted when the power receiving side control circuit 350 instructs the power receiving side amplitude modulator 370 to transmit data indicating the stability notification. The N-th relay-side control circuit 250 reads (receives) the transmitted stability notification based on the fluctuation in the amplitude of the voltage detected by the N-th relay-side demodulator 280. After receiving the stability notification, the N-th relay-side control circuit 250 sends a control signal to the N-th relay-side switch circuit 255 to switch on. As a result, power is supplied to the N-th relay-side load 295. Thereafter, when detecting that the temporal variation of the voltage of the relay-side DC power falls within a predetermined range, the N-th relay-side control circuit 250 transmits a stability notification to the (N−1) -th relay device 200. . Thereafter, the same operation is sequentially repeated from the (N-1) th relay device 200 to the first relay device 200.

Thus, the wireless power transmission system of the present embodiment performs the following operations in summary.
(1) Only the part of the wireless power transmission system excluding the load is activated first. Upon receiving the power, each relay device 200 immediately transmits the power to the power receiving device 300 (front end side).
(2) When the control system is started up to the tip (power receiving device 300), loads are sequentially connected from the tip side.
(3) After being connected to the load 295, each relay device 200 waits until the voltage is stabilized, and notifies the preceding stage when the voltage is stabilized. Note that the standby time may be a preset fixed time.
(4) The operation of (3) is repeated until the load of the root (the first relay device) is connected.

  The operation of this embodiment has an advantage that it can be realized by one-way communication from the power receiving side 300 to the power transmitting side 100 (for example, the above-described load modulation communication).

  As described above, the wireless power transmission system is vulnerable to a sudden current draw due to a heavy load or the like. However, as in the present embodiment, the transient response at the time of startup can be suppressed by limiting the number of simultaneously connected loads. . For this reason, starting can be stabilized.

  FIG. 14 illustrates a phenomenon in which the DC voltage decreases after the load is connected, and a phenomenon (current draw) in which the DC current increases when the load is connected. Making the connection to the load results in a drop in voltage and an increase in current as shown. Therefore, each of the relay-side control circuits 250 and the power-receiving-side control circuits 350 in this embodiment determines that power supply has stabilized when the DC voltage has returned to a predetermined value after dropping, and transmits a stability notification. Instead of the DC voltage, a DC current may be detected, and when the DC current increases and then returns to a predetermined value, it may be determined that the power supply has been stabilized.

  According to the present embodiment, the power supply to the load such as the motor is started after the power is supplied to the end, so that when there is an abnormality in any part of the power transmission part (referred to as a power supply system) excluding the load, the load is Without powering the power supply.

  FIG. 15 is a sequence diagram showing an example of the operation at the time of such an abnormality. Here, it is assumed that there are a plurality of relay devices, but the same operation can be applied to the case where there is only one relay device.

  For example, when an abnormality occurs in the activation of the relay-side control circuit 250 in the N-th relay device, a notification indicating the abnormality (referred to as an abnormality notification) may be transmitted to the preceding relay device. Each relay device sequentially transmits the abnormality notification to the power transmission device 100, and the power transmission device 100 can stop the startup sequence in response to the notification.

  Even when the startup sequence has progressed to the power receiving device 300 and the connection to the load has been reached, even when the voltage is not stable after the load is connected, a similar abnormality notification may be performed and the power transmission may be stopped.

(Embodiment 2)
Next, a second embodiment of the present disclosure will be described.

  The present embodiment is different from the first embodiment in that power is supplied to the load in order from the side closer to the power transmission device 100. The physical configuration of the present embodiment is the same as the configuration of the first embodiment (FIGS. 6, 12 and the like).

  First, the operation when there is one relay device 200 will be described. Here, too, the configurations shown in FIGS. 6 and 11A are assumed.

The wireless power transmission system according to the present embodiment performs the following operation.
(1) Power transmission is started with the relay rectifier 220 and the relay load 295 disconnected (off) and the power receiving rectifier 330 and the power receiving load 395 disconnected (off).
(2) After the voltage of the power receiving-side DC power reaches the required voltage of the power receiving device 300, the first information (arrival information) is transmitted from the power receiving device 300 to the relay device 200.
(3) The relay side control circuit 250 controls the relay side switch circuit 255 to supply the relay side load 295 with the relay side DC power.
(4) After the voltage of the relay-side DC power of the relay device 200 is stabilized, information (stability notification) indicating that the voltage is stabilized is transmitted from the relay device 200 to the power receiving device 300.
(5) The power receiving side control circuit 350 controls the power receiving side switch circuit 355 to supply power receiving side DC power to the power receiving side load 395.

  In the present embodiment, since bidirectional communication is required, both the relay device 200 and the power receiving device 300 need to have transmission and reception functions. For this communication, for example, the transmitters 292 and 392 and the receivers 290 and 390 shown in FIG. 6 can be used. The method of information communication is not limited to a specific method, but may be any method. Not limited to the amplitude modulation method, for example, a frequency modulation method or a wireless method such as a wireless LAN or Zigbee (registered trademark) may be used.

  FIG. 16 is a sequence diagram illustrating an example of an operation at the time of startup in the present embodiment. FIG. 16 shows the order of supplying (starting) power to each unit and the timing of arrival information and stability notification after power is supplied to the load. After the power is turned on, when the voltage supplied to each control circuit exceeds a predetermined voltage (the drive voltage of the control system described above), the control circuit is activated, the inverter circuit is driven, and power transmission is started. The power is transmitted in the order of the power transmission circuit 145, the relay power reception circuit 205, the relay power transmission circuit 245, and the power reception circuit 305. During this time, the relay-side switch circuit 255 and the power-receiving-side switch circuit 355 are kept in a non-connected (off) state. After the power receiving side power receiving circuit 305 receives the power, the power receiving side control circuit 350 determines that the voltage value of the power receiving side DC power detected by the power receiving side detector 325 is equal to a predetermined threshold (the required voltage of the power receiving device 300 described above). To determine if it exceeds. When determining that the voltage value of the receiving-side DC power has exceeded a predetermined threshold, the receiving-side control circuit 350 transmits the arrival information to the relay device 200. The arrival information is transmitted by the power receiving side control circuit 350 instructing the power receiving side amplitude modulator 370 to transmit the arrival information. Relay-side control circuit 250 reads the transmitted arrival information based on the fluctuation in the amplitude of the voltage detected by relay-side demodulator 280. After receiving the arrival information, the relay-side control circuit 250 sends a control signal to the relay-side switch circuit 255 to switch on. As a result, power is supplied to the relay load 295. After that, when detecting that the temporal variation of the voltage of the relay DC power falls within a predetermined range, the relay control circuit 250 transmits a stability notification to the power receiving device 300. This stability notification can be transmitted, for example, by the relay control circuit 250 instructing the relay transmitter 292 to transmit data indicating the stability notification. When the power receiving side receiver 390 receives the stability notification from the relay device 200, the power receiving side control circuit 350 sends a control signal to the power receiving side switch circuit 355 to switch on. As a result, power is supplied to the power receiving load 395.

  The above operation can be similarly applied even when the number of relay devices 200 is plural. Hereinafter, an example of the operation when the number of relay devices 200 is plural will be described. Here, as in the first embodiment, the configuration shown in FIGS. 12 and 13A is assumed.

  FIG. 17 is a sequence diagram showing an example of an operation at the time of startup in this example. In this example, first, power is transmitted from the power transmitting device 100 to the power receiving device 300 via the N relay devices 200 in a state where all the switch circuits are turned off. The power receiving side control circuit 350 determines whether or not the voltage value of the power receiving side DC power detected by the power receiving side detector 325 exceeds a predetermined threshold (the required voltage of the power receiving device 300 described above). When determining that the voltage value of the power receiving side DC power has exceeded a predetermined threshold value, the power receiving side control circuit 350 transmits the first information (this is referred to as a front end energization completion notification) indicating this to the first relay device. . The leading end energization completion notification can be transmitted, for example, by the power receiving side control circuit 350 instructing the power receiving side transmitter 392 to transmit a tip energizing completion notification to the relay side receiver 290 in the first relay device. Alternatively, information may be sequentially transmitted using the power receiving side amplitude modulator 370 and the relay side amplitude modulator 270 in each relay device 200. When the first relay device receives the notification of the completion of the front-end energization, the first relay-side control circuit 250 sends a control signal to the first relay-side switch circuit 255 to switch on. As a result, power is supplied to the first relay load 295. Thereafter, when detecting that the temporal variation of the voltage of the first relay-side DC power falls within a predetermined range, the first relay-side control circuit 250 transmits a stability notification to the second relay device. . Upon receiving the stability notification, the second relay-side control circuit 250 switches on the second relay-side switch circuit 255. When it is determined that the voltage of the second relay-side DC power is stable, a stability notification is transmitted to the third relay device. After that, similarly, the ON of the switch circuit (that is, connection to the load) and the transmission of the stability notification are sequentially performed up to the N-th relay device, and finally the power of the power receiving device 300 is supplied to the load.

  Also in the present embodiment, the power supply to the load is performed in order after the power supply to the power receiving device 300 is completed, so that the transient response at the time of starting can be suppressed, and the starting can be stabilized.

(Embodiment 3)
Next, a third embodiment of the present disclosure will be described.

  The present embodiment is different from the first and second embodiments in that the power transmitting device 100 controls the relay device 200 and the power receiving device 300. Such an operation is suitable for a mode in which the operation state of each load is integrally managed by the power transmission side control circuit 150. Power transmission device 100 may be a part of a power control device including DC power supply 50. Such a power supply control device can centrally manage the states of a plurality of loads and control them individually.

  As shown in FIG. 6, the operation of the present embodiment in a configuration having one relay device 200 will be described.

In summary, the wireless power transmission system according to the present embodiment performs the following operations.
(1) The power-receiving-side control circuit 350 transmits to the power-transmitting-side control circuit 150 a notification that the voltage of the power-receiving-side DC power has reached the required voltage of the power receiving device 200 (a front-end energization completion notification).
(2) What is the timing T1 at which the power transmission side control circuit 150 connects the relay side rectifier 220 and the relay side load 295 to the relay side control circuit 250 after receiving the end energization completion notification from the power receiving side control circuit 350 At a different timing T2, the power receiving side control circuit 350 connects the power receiving side rectifier 320 and the power receiving side load 395.

  FIG. 18 is a sequence diagram illustrating an example of the operation according to the present embodiment. As shown in FIG. 18, power is transmitted to the power receiving device 300 in a state where all the switch circuits are off. When the received power is stabilized, the power receiving side control circuit 350 transmits a tip power supply completion notification to the power transmitting device 100. After receiving the notification of the completion of the leading end energization, the power transmission side control circuit 150 transmits information (connection instruction) for instructing the relay device 200 to connect. The relay-side control circuit 250 receives this connection command, turns on the relay-side switch circuit 255, and starts power supply to the relay-side load 295. After that, the relay-side control circuit 250 waits until the relay-side DC power is stabilized, and sends a stability notification to the power transmission device 100 after the power is stabilized. Upon receiving the stability notification, the power transmission side control circuit 150 sends a connection command to the power receiving device 200. The power receiving side control circuit 350 receives the connection command, turns on the power receiving side switch circuit 355, and starts power supply to the power receiving side load 395. The power receiving-side control circuit 350 waits until the power receiving-side DC power is stabilized, and transmits a stability notification to the power transmitting device 100 after the power receiving side DC power is stabilized. In the above operation, transmission and reception of various information can be performed by an arbitrary method.

  In FIG. 18, power is supplied to the load 295 of the relay device 200 first, but power may be supplied to the load 395 of the power receiving device 300 first. The power supply timing may be arbitrarily determined by the control circuit 150 in the power transmission device 100.

  FIG. 19 is a diagram illustrating an example of a startup sequence in a plurality of configurations (FIG. 12) of the relay device 200. Similarly, in this example, when the power supply to the power receiving apparatus 300 is completed, the power receiving side control circuit 350 transmits a leading end power supply completion notification to the power transmitting side control circuit 150. When the power transmission side control circuit 150 receives the leading end energization completion notification, it issues a connection command to any of the relay devices 200 or the power receiving devices 300 that have not yet been connected to the load. The relay device 200 or the power receiving device 300 that has received the connection instruction turns on the switch circuit and connects to the load. After the output is stabilized, the relay device 200 or the power receiving device 300 that has connected to the load transmits a stability notification to the power transmitting device 100. Upon receiving the stability notification, the power transmitting device 100 issues a connection command to the relay device 200 or the power receiving device 300 that is not yet connected to the load. Thereafter, the same operation is repeated until the power supply to the loads of all the relay devices 200 and the power receiving devices 300 is completed.

  According to the present embodiment, the power transmitting device 100 can centrally control power supply to the loads of the relay devices 200 and the power receiving devices 300. Therefore, in addition to the effect of stabilizing the operation at the time of startup described in the first and second embodiments, there is an advantage that each load can be driven more flexibly. In the above example, power is supplied one by one to a plurality of loads. However, control such as supplying power to each group of a plurality of loads is also possible. The timing of connection of a plurality of loads is not limited to the above example, and may be any timing as long as the timing of connection of all loads is not simultaneous.

  As described above, the present disclosure includes the wireless power transmission system and the power transmission device described in the following items.

[Item 1]
A wireless power transmission system including a power transmission device, a power reception device, and a relay device disposed between the power transmission device and the power reception device,
The power transmission device,
A transmission-side inverter circuit that converts transmission-side DC power supplied from an external power supply into transmission-side AC power,
A power transmission side power transmission antenna for wirelessly transmitting the power transmission side AC power,
The relay device,
A relay-side receiving antenna that receives the power-transmitting-side AC power,
A relay-side rectifier that converts the transmission-side AC power into relay-side DC power,
A relay-side inverter circuit that converts the relay-side DC power into relay-side AC power,
Relay side load,
A relay-side switch circuit that is disposed between the relay-side rectifier and the relay-side load and that switches connection / disconnection between the relay-side rectifier and the relay-side load;
A relay-side power transmitting antenna that wirelessly transmits the relay-side AC power,
The power receiving device,
A power receiving side power receiving antenna for receiving the relay side AC power,
A power receiving side rectifier that converts the relay side AC power into power receiving side DC power,
Receiving side load,
A power-receiving-side switch circuit that is disposed between the power-receiving-side rectifier and the power-receiving-side load and that switches connection / disconnection of the power-receiving-side rectifier and the power-receiving-side load;
In the wireless power transmission system,
First, in a state where the relay side switch circuit disconnects the relay side rectifier and the relay side load and the power receiving side switch circuit disconnects the power receiving side rectifier and the power receiving side load, the power transmission side The power transmitting side AC power is transmitted from the power transmitting antenna to the relay side power receiving antenna, and the relay side AC power is transmitted from the relay side power transmitting antenna to the power receiving side power receiving antenna,
Next, after the voltage of the power receiving side DC power reaches the required voltage of the power receiving device,
The power receiving side switch circuit connects the power receiving side rectifier and the power receiving side load at a timing T2 different from the timing T1 at which the relay side switching circuit connects the relay side rectifier and the relay side load,
Wireless power transmission system.

According to the above aspect,
After the voltage of the power receiving-side DC power reaches the required voltage of the power receiving device, the connection between the relay rectifier and the relay load and the connection between the power receiving rectifier and the power receiving load are performed. Further, the former connection and the latter connection are performed at different timings.
For this reason, the operation at the time of startup can be made more stable.

[Item 2]
The relay device further includes a relay-side control circuit that controls the relay-side switch circuit,
The power receiving device further includes a power receiving side control circuit that controls the power receiving side switch circuit,
The power transmission device further includes a power transmission side control circuit that controls the relay side control circuit and the power reception side control circuit,
The power receiving side control circuit transmits a completion notification that the voltage of the power receiving side DC power has reached a required voltage of the power receiving device to the power transmission side control circuit,
The power transmission side control circuit,
After receiving the completion notification from the power receiving control circuit,
The power receiving side rectifier and the power receiving side load are connected using the power receiving side control circuit at a timing T2 different from the timing T1 for connecting the relay side rectifier and the relay side load using the relay side control circuit. ,
Item 2. The wireless power transmission system according to item 1.

According to the above aspect,
The power transmission side control circuit,
After receiving the completion notification from the power receiving control circuit,
The power receiving side rectifier and the power receiving side load are connected using the power receiving side control circuit at a timing T2 different from the timing T1 for connecting the relay side rectifier and the relay side load using the relay side control circuit. .

  Thereby, the operation at the time of startup in the configuration in which the power transmitting device controls the relay device and the power receiving device can be stabilized.

[Item 3]
The timing T1 is earlier than the timing T2,
3. The wireless power transmission system according to any one of items 1 and 2.

  According to the above aspect, power is sequentially supplied to the load from the power transmission device side (front side), so that there is an advantage that control is simple.

[Item 4]
The timing T1 is later than the timing T,
3. The wireless power transmission system according to any one of items 1 and 2.

  According to the above aspect, since power is sequentially supplied to the load from the power receiving device side (rear side), for example, there is an advantage that the power can be realized without mounting a bidirectional communication function.

[Item 5]
The relay device further includes a relay-side control circuit that controls the relay-side switch circuit,
The power receiving device further includes a power receiving side control circuit that controls the power receiving side switch circuit,
The power receiving side control circuit transmits a completion notification that the voltage of the power receiving side DC power has reached a required voltage of the power receiving device to the relay side control circuit,
The relay-side control circuit,
After receiving the completion notification,
Connecting the power receiving side rectifier and the power receiving side load by using the power receiving side control circuit at a timing T2 later than the timing T1 for connecting the relay side rectifier and the relay side load;
Item 2. The wireless power transmission system according to item 1.

  According to the above aspect, since power is additionally supplied in order from the power transmission device side (front side), there is an advantage that control is simple.

[Item 6]
The power receiving device further includes a power receiving side detector that detects a voltage of the power receiving side DC power,
A power receiving side control circuit that determines whether or not the voltage of the power receiving side DC power has reached a required voltage of the power receiving side load of the power receiving device based on the voltage of the power receiving side DC power detected by the power receiving side detector. And having
6. The wireless power transmission system according to any one of items 1 to 5.

  According to the above aspect, the power receiving side control circuit can transmit a completion notification to the relay device or the power transmitting device when the voltage of the power receiving side DC power reaches the required voltage of the power receiving side load of the power receiving device. The relay device or the power transmission device that has received the completion notification can stably execute the connection to the load.

[Item 7]
A wireless power transmission system comprising: a power transmission device; a power reception device; and N (N is an integer of 2 or more) relay devices disposed between the power transmission device and the power reception device,
The power transmission device,
A transmission-side inverter circuit that converts transmission-side DC power supplied from an external power supply into transmission-side AC power,
A power transmission side power transmission antenna for wirelessly transmitting the power transmission side AC power,
The first relay device among the N relay devices is:
A first relay-side power receiving antenna for receiving the power transmission-side AC power,
A first relay-side rectifier for converting the transmission-side AC power into a first relay-side DC power,
A first relay-side inverter circuit that converts the first relay-side DC power into a first relay-side AC power;
A first relay load;
A first relay disposed between the first relay-side rectifier and the first relay-side load for switching connection / disconnection between the first relay-side rectifier and the first relay-side load; A relay-side switch circuit,
A first relay-side power transmitting antenna that wirelessly transmits the first relay-side AC power,
The i-th (i = 2 to N) relay devices of the N devices are:
An i-th relay-side receiving antenna that receives the (i-1) -th relay-side AC power,
An i-th relay rectifier for converting the (i-1) -th relay AC power into an i-th relay DC power,
An i-th relay-side inverter circuit that converts the i-th relay-side DC power into an i-th relay-side AC power,
an i-th relay load,
An i-th relay-side rectifier disposed between the i-th relay-side rectifier and the i-th relay-side load, for switching connection / disconnection between the i-th relay-side rectifier and the i-th relay-side load; A relay-side switch circuit,
An i-th relay-side power transmitting antenna that wirelessly transmits the i-th relay-side AC power,
The power receiving device,
A power receiving side power receiving antenna for receiving the Nth relay side AC power,
A receiving-side rectifier that converts the N-th relay-side AC power into receiving-side DC power;
Receiving side load,
A power receiving side switch circuit that is disposed between the power receiving side rectifier and the power receiving side load and that switches connection / disconnection of the power receiving side rectifier and the power receiving side load;
In the wireless power transmission system,
First, the i-th (i = 1 to N) switch circuit disconnects the i-th (i = 1 to N) relay-side rectifier and the i-th (i = 1 to N) relay-side load. And, in the state where the power receiving side switch circuit disconnects the power receiving side rectifier and the power receiving side load, the power transmitting side AC power transmitted from the power transmitting side power transmitting antenna is the i-th (i = 1 to i) N) sequentially transmitted to the power receiving side power receiving antenna as the Nth AC power via the relay device,
Next, the i-th (i = 1 to N) switch circuit is connected to the i-th (i = 1 to N) relay-side rectifier at the timing Ti (i = 1 to N) by the i-th (i = 1 to N). N), and the power-receiving-side switch circuit connects the power-receiving-side rectifier and the power-receiving-side load at timing Tr, and at least one of the timing Ti (i = 1 to N) and the timing Tr. Some are different,
Wireless power transmission system.

According to the above aspect,
, N power supply to each load is started after power is transmitted to all of the relay devices and the power receiving devices. The timing of starting power supply to the load in the i-th (i = 1 to N) relay device and the timing of starting power supply to the load in the power receiving device are shifted (at least in part).

  Therefore, also in this mode, the operation at the time of starting can be stabilized.

[Item 8]
The i-th (i = 1 to N) relay device further includes an i-th (i = 1 to N) relay-side control circuit for controlling the i-th (i = 1 to N) relay-side switch circuit. Have
The power receiving device further includes a power receiving side control circuit that controls the power receiving side switch circuit,
The power transmission device further includes a power transmission side control circuit that controls the i-th (i = 1 to N) relay side control circuit and the power reception side control circuit,
The power receiving side control circuit transmits a completion notification that the voltage of the power receiving side DC power has reached a required voltage of the power receiving device to the power transmission side control circuit,
The power transmission side control circuit,
After receiving the completion notification from the power receiving control circuit,
The i-th (i = 1 to N) switch circuit is turned on at timing Ti (i = 1 to N) to connect the i-th (i = 1 to N) relay-side rectifier with the i-th (i = 1 to N). N), and the power receiving side switch circuit is turned on at the timing Tr to connect the power receiving side rectifier to the power receiving side load, and the timing Ti (i = 1 to N) and Making at least a part of the timing Tr different;
Item 8. The wireless power transmission system according to Item 7.

According to the above aspect,
The power transmission side control circuit,
After receiving the completion notification from the power receiving control circuit,
The i-th (i = 1 to N) switch circuit is turned on at timing Ti (i = 1 to N) to connect the i-th (i = 1 to N) relay-side rectifier with the i-th (i = 1 to N). N) and the power receiving side switch circuit is turned on at a timing Tr to connect the power receiving side rectifier and the power receiving side load, and the timing Ti (i = 1 to N) and At least a part of the timing Tr is made different.

  Thereby, the operation at the time of startup in the configuration in which the power transmitting device controls the relay device and the power receiving device can be stabilized.

[Item 9]
The timing Ti (i = 2 to N) is earlier than the timing Ti-1,
The timing Tr is earlier than the timing TN,
9. The wireless power transmission system according to any one of items 7 and 8.

  According to the above aspect, since power is sequentially supplied to the load from the power receiving device side (rear side), for example, there is an advantage that the power can be realized without mounting a bidirectional communication function.

[Item 10]
The i-th (i = 1 to N) relay device further includes an i-th (i = 1 to N) relay-side control circuit for controlling the i-th (i = 1 to N) relay-side switch circuit. Have
The power receiving device further includes a power receiving side control circuit that controls the power receiving side switch circuit,
The power receiving side control circuit transmits first information to the Nth relay side control circuit that the voltage of the power receiving side DC power has reached a required voltage of the power receiving device,
The i-th (i = 2 to N) relay-side control circuit provides the i-th (i = 2 to N) relay-side control circuit with the i-th (i = 2 to N) relay-side DC power. Sequentially transmits second information indicating that the voltage has reached the required voltage of the i-th (i = 2 to N) relay device,
The N-th relay-side control circuit, after receiving the first information, connects the N-th relay-side rectifier and the N-th relay-side load at the timing TN that is later than the timing Tr,
After receiving the (i + 1) -th (i = 1 to N-1) second information, the i-th (i = 1 to N-1) relay-side control circuit performs the timing Ti later than the timing Ti + 1. Connecting the i-th (i = 1 to N-1) relay-side rectifier and the i-th (i = 1 to N-1) relay-side load sequentially;
Item 8. The wireless power transmission system according to Item 7.

  According to the above aspect, since power is sequentially supplied to the load from the power receiving device side (rear side), there is an advantage that the power can be realized without mounting a bidirectional communication function.

  The “required voltage of the relay device” in this item is a predetermined voltage value required by the relay device. The “required voltage of the relay device” may be, for example, a voltage value when the voltage in the relay device is stabilized after the connection between the relay rectifier circuit and the relay load in the relay device. In this case, the “second information” corresponds to the “stability notification” illustrated in FIG. 13B. Similarly, in a certain mode, “first information” corresponds to “stability notification” transmitted by the power receiving device illustrated in FIG. 13B.

  The technology of the present disclosure is applicable to devices that need to transmit data together with power supply, such as surveillance cameras and robots.

50 External power supply (DC power supply)
Reference Signs List 100 power transmission device 130 power transmission side inverter circuit 140 power transmission side power transmission antenna 145 power transmission side power transmission circuit 150 power transmission side control circuit 160 power transmission side pulse output circuit 180 power transmission side demodulator 190 power transmission side receiver 192 power transmission side transmitter 200 relay device 205 relay side Power receiving circuit 210 Relay-side power receiving antenna 220 Relay-side rectifier 225 Relay-side detector 230 Relay-side inverter circuit 240 Relay-side power transmitting antenna 245 Relay-side power transmitting circuit 250 Relay-side control circuit 255 Relay-side switch circuit 260 Relay-side pulse output circuit 270 Relay-side Amplitude modulator 275 Relay side load modulation circuit 280 Relay side demodulator 290 Relay side receiver 292 Relay side transmitter 295 Relay side load 300 Power receiving device 305 Power receiving side power receiving circuit 310 Power receiving side power receiving antenna 320 Power receiving side rectifier 325 Power receiving side detector 350 Power receiving side control Road 355 power receiving side switching circuit 370 power-reception-side amplitude modulator 375 receiving-side load modulation circuit 390 power-receiving-side receiver 392 receiving-side transmitter 395 power-receiving-side load 400 load

Claims (10)

A wireless power transmission system including a power transmission device, a power reception device, and a relay device disposed between the power transmission device and the power reception device,
The power transmission device,
A transmission-side inverter circuit that converts transmission-side DC power supplied from an external power supply into transmission-side AC power,
A power transmission side power transmission antenna for wirelessly transmitting the power transmission side AC power,
The relay device,
A relay-side receiving antenna that receives the power-transmitting-side AC power,
A relay-side rectifier that converts the transmission-side AC power into relay-side DC power,
A relay-side inverter circuit that converts the relay-side DC power into relay-side AC power,
Relay side load,
A relay-side switch circuit that is disposed between the relay-side rectifier and the relay-side load and that switches connection / disconnection between the relay-side rectifier and the relay-side load;
A relay-side power transmitting antenna that wirelessly transmits the relay-side AC power,
The power receiving device,
A power receiving side power receiving antenna for receiving the relay side AC power,
A power receiving side rectifier that converts the relay side AC power into power receiving side DC power,
Receiving side load,
A power-receiving-side switch circuit that is disposed between the power-receiving-side rectifier and the power-receiving-side load and that switches connection / disconnection of the power-receiving-side rectifier and the power-receiving-side load;
In the wireless power transmission system,
First, in a state where the relay side switch circuit disconnects the relay side rectifier and the relay side load and the power receiving side switch circuit disconnects the power receiving side rectifier and the power receiving side load, the power transmission side The power transmitting side AC power is transmitted from the power transmitting antenna to the relay side power receiving antenna, and the relay side AC power is transmitted from the relay side power transmitting antenna to the power receiving side power receiving antenna,
Next, after the voltage of the power receiving side DC power reaches the required voltage of the power receiving device,
The power receiving side switch circuit connects the power receiving side rectifier and the power receiving side load at a timing T2 different from the timing T1 at which the relay side switching circuit connects the relay side rectifier and the relay side load,
Wireless power transmission system. The relay device further includes a relay-side control circuit that controls the relay-side switch circuit,
The power receiving device further includes a power receiving side control circuit that controls the power receiving side switch circuit,
The power transmission device further includes a power transmission side control circuit that controls the relay side control circuit and the power reception side control circuit,
The power receiving side control circuit transmits a completion notification that the voltage of the power receiving side DC power has reached a required voltage of the power receiving device to the power transmission side control circuit,
The power transmission side control circuit,
After receiving the completion notification from the power receiving control circuit,
The power receiving side rectifier and the power receiving side load are connected using the power receiving side control circuit at a timing T2 different from the timing T1 for connecting the relay side rectifier and the relay side load using the relay side control circuit. ,
The wireless power transmission system according to claim 1. The timing T1 is earlier than the timing T2,
The wireless power transmission system according to claim 1. The timing T1 is later than the timing T 2,
The wireless power transmission system according to claim 1. The relay device further includes a relay-side control circuit that controls the relay-side switch circuit,
The power receiving device further includes a power receiving side control circuit that controls the power receiving side switch circuit,
The power receiving side control circuit transmits a completion notification that the voltage of the power receiving side DC power has reached a required voltage of the power receiving device to the relay side control circuit,
The relay-side control circuit,
After receiving the completion notification,
Connecting the power receiving side rectifier and the power receiving side load by using the power receiving side control circuit at a timing T2 later than the timing T1 for connecting the relay side rectifier and the relay side load;
The wireless power transmission system according to claim 1. The power receiving device further includes a power receiving side detector that detects a voltage of the power receiving side DC power,
A power receiving side control circuit that determines whether or not the voltage of the power receiving side DC power has reached a required voltage of the power receiving side load of the power receiving device based on the voltage of the power receiving side DC power detected by the power receiving side detector. And having
The wireless power transmission system according to claim 1. A wireless power transmission system comprising: a power transmission device; a power reception device; and N (N is an integer of 2 or more) relay devices disposed between the power transmission device and the power reception device,
The power transmission device,
A transmission-side inverter circuit that converts transmission-side DC power supplied from an external power supply into transmission-side AC power,
A power transmission side power transmission antenna for wirelessly transmitting the power transmission side AC power,
The first relay device among the N relay devices is:
A first relay-side power receiving antenna for receiving the power transmission-side AC power,
A first relay-side rectifier for converting the transmission-side AC power into a first relay-side DC power,
A first relay-side inverter circuit that converts the first relay-side DC power into a first relay-side AC power;
A first relay load;
Wherein disposed between the first relay side rectifier and the first relay side load, the first relay side for switching connection / disconnection between the first relay side load to the first repeater-side rectifier A switch circuit;
A first relay-side power transmitting antenna that wirelessly transmits the first relay-side AC power,
The i-th (i = 2 to N) relay devices of the N devices are:
an i- th relay-side receiving antenna that receives the ( i-1) -th relay-side AC power,
an i- th relay-side rectifier for converting the ( i-1) -th relay-side AC power into an i-th relay-side DC power,
An i-th relay-side inverter circuit that converts the i-th relay-side DC power into an i-th relay-side AC power,
an i-th relay load,
An i-th relay-side rectifier disposed between the i-th relay-side rectifier and the i-th relay-side load, for switching connection / disconnection between the i-th relay-side rectifier and the i-th relay-side load; A relay-side switch circuit,
An i-th relay-side power transmitting antenna that wirelessly transmits the i-th relay-side AC power,
The power receiving device,
A power receiving side power receiving antenna for receiving the Nth relay side AC power,
A receiving-side rectifier that converts the N- th relay-side AC power into receiving-side DC power;
Receiving side load,
A power receiving side switch circuit that is disposed between the power receiving side rectifier and the power receiving side load and that switches connection / disconnection of the power receiving side rectifier and the power receiving side load;
In the wireless power transmission system,
First, the i-th (i = 1 to N) of the non-connecting the relay-side load of the relay side switching circuit i-th (i = 1 to N) of the repeater-side rectifier and i-th (i = 1 to N), And in the state where the power receiving side switch circuit disconnects the power receiving side rectifier and the power receiving side load, the power transmitting side AC power transmitted from the power transmitting side power transmitting antenna is i- th (i = 1 to N). Are sequentially transmitted to the power-receiving-side receiving antenna as the N-th relay-side AC power,
Next, at the timing Ti (i = 1 to N), the i-th (i = 1 to N) relay-side switch circuit and the i-th (i = 1 to N) relay-side rectifier are connected to the i-th (i = 1 to N). 1 to N), the power receiving side switch circuit connects the power receiving side rectifier and the power receiving side load at timing Tr, and the timing Ti (i = 1 to N) and the timing Tr At least part of is different,
Wireless power transmission system. The i-th (i = 1 to N) relay device further includes an i-th (i = 1 to N) relay-side control circuit for controlling the i-th (i = 1 to N) relay-side switch circuit. Have
The power receiving device further includes a power receiving side control circuit that controls the power receiving side switch circuit,
The power transmission device further includes a power transmission side control circuit that controls the i-th (i = 1 to N) relay side control circuit and the power reception side control circuit,
The power receiving side control circuit transmits a completion notification that the voltage of the power receiving side DC power has reached a required voltage of the power receiving device to the power transmission side control circuit,
The power transmission side control circuit,
After receiving the completion notification from the power receiving control circuit,
The i-th the i-th ON the relay side switching circuit at the timing Ti (i = 1 to N) of the (i = 1 to N) (i = 1 to N) the i-th relay side rectifier (i = 1 to N) is the connection between the relay-side load, and, wherein the power receiving side switching circuit in the oN at the timing Tr is connected with said receiving-side load and the power receiving side rectifier, said timing Ti (i = 1 To N) and at least a part of the timing Tr is made different;
A wireless power transmission system according to claim 7. Timing Ti (i = 2~N) is earlier than the timing Ti-1,
The timing Tr is, faster than the timing TN,
The wireless power transmission system according to claim 7. The i-th (i = 1 to N) relay device further includes an i-th (i = 1 to N) relay-side control circuit for controlling the i-th (i = 1 to N) relay-side switch circuit. Have
The power receiving device further includes a power receiving side control circuit that controls the power receiving side switch circuit,
The power receiving side control circuit transmits, to an Nth relay side control circuit, first information indicating that the voltage of the power receiving side DC power has reached a required voltage of the power receiving device,
i-th (i = 2 to N) relay side control circuit of, i -1-th the i-th relay side control circuit (i = 2~N) (i = 2~N) of the relay side DC power voltage Sequentially transmits second information indicating that the required voltage of the i-th (i = 2 to N) relay device has been reached,
N-th relay side control circuit, after receiving the first information, N-th relay side rectifier and N-th to connect the relay side load slower timing TN said timing Tr,
i-th (i = 1~N-1) relay side control circuit of, i + 1-th (i = 1~N-1) after receiving the second information, the i-th in timing Ti + 1 slower timing Ti (I = 1 to N-1) relay-side rectifier and i- th (i = 1 to N-1) relay-side load are sequentially connected;
A wireless power transmission system according to claim 7.

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