JP6743234B2 - Power receiving device, power transmitting device, power receiving device control method, power transmitting device control method, and program - Google Patents

Description

The present invention relates to wireless power transmission technology.

BACKGROUND ART Conventionally, there is known a wireless power transmission system including a power transmission device that wirelessly transmits power and a power reception device that receives power supplied from the power transmission device. In some wireless power transmission systems, a power transmitting device detects full charge of a power receiving device that is transmitting power and stops power transmission.

In Patent Document 1, when the power receiving device is fully charged, which is a state in which electric energy is sufficiently stored in a storage battery or a battery, the power receiving device sends a command indicating that the power receiving device is fully charged to the power transmitting device. Is listed. Furthermore, Patent Document 1 describes a technique of stopping power transmission to the power receiving device when the power transmitting device receives a command indicating that the power receiving device is fully charged.

JP, 2010-34080, A

In the wireless power transmission system as described above, it is necessary to perform communication connection between the power transmission device and the power reception device in order to exchange control information for wireless power transmission prior to wireless power transmission. As an example of the operation of the wireless power transmission system, the power transmission device communicates with the power reception device when detecting that the power reception device exists in the power transmission range.

However, if the power receiver continues to be placed on the power transmitter that is in the range where power can be transmitted even after the power receiver is fully charged, the power transmitter may re-establish communication connection with the fully charged power receiver. ..

For example, when the power transmitting device is transmitting power to the power receiving device, the power receiving device is fully charged, and thus the power receiving device transmits a command requesting the power transmission device to stop power transmission. The power transmission device stops power transmission to the power receiving device and further cuts off communication with the power receiving device in response to reception of the command requesting stop of power transmission. However, if the power receiving device continues to be placed in the power transmission range of the power transmitting device after that, the power transmitting device detects the power receiving device after disconnection of communication with the power receiving device, and the process for communication connection starts again. Will be done. In this case, for example, the power transmission device receives a command indicating that power transmission is unnecessary from the power reception device after communication connection, and does not perform wireless power transmission to the power reception device. As described above, the power transmission device may perform a process for unnecessary power transmission such as useless communication with respect to a power receiving device that has already transmitted power and is fully charged and thus does not need power transmission.

The present invention has been made in view of the above problems, and an object of the present invention is to reduce unnecessary processing for wireless power transmission.

As a means for solving the above-mentioned problems, a power receiving device according to the present invention is configured to perform power transmission according to the Bluetooth standard via a power receiving device that wirelessly receives power from a power transmitting device via a power receiving antenna and a communication antenna different from the power receiving antenna. after a communication unit that performs communication for device and receiving the power from the power transmission indicating a request response from the previous SL power transmission device and power reception by said receiving means, transmits the advertising packet in the Bluetooth standard by said communication means wherein possess control means for controlling the communication means, the so, the control means, to eliminate the need for power reception by said receiving means, as the advertising packet, information indicating that the state that unnecessary power reception The communication means is controlled so as to transmit an advertising packet containing the communication packet .

According to the present invention, it is possible to reduce unnecessary processing for wireless power transmission.

It is a system configuration diagram of a wireless power transmission system. It is a figure which shows the structure of a power transmission device. It is a figure which shows the structure of a power receiving apparatus. It is a figure which shows the sequence chart of a wireless power transmission system. It is a flowchart which shows operation|movement of a power receiving apparatus. It is a flowchart which shows operation|movement of a power transmission device.

(First embodiment)
A wireless power transmission system for wireless power transmission according to this embodiment is shown in FIG. Note that the wireless power transmission system according to the present embodiment performs wireless power transmission using the magnetic field resonance method. The magnetic field resonance method is a method in which electric power is transmitted by coupling by resonance (resonance) of a magnetic field between a resonator (resonance element) of a power transmission device and a resonator (resonance element) of a power reception device. In the present embodiment, the wireless power transmission system using the magnetic field resonance method will be described as an example, but the wireless power transmission method (contactless power transmission method) is not limited to this, and electromagnetic induction, electric field resonance, A power transmission method using microwave, laser, or the like may be used.

In FIG. 1A, 101 is a power transmitting device and 102 is a first power receiving device. The power transmission device 101 is a power transmission device that transmits power wirelessly. The first power receiving device 102 is a power receiving device that receives the power transmitted wirelessly. In the wireless power transmission system according to the present embodiment, communication for authentication and communication of control information for controlling wireless power transmission are performed between the power transmitting device and the power receiving device. Examples of control information include attributes of the power receiving device (type of device, etc.), power receiving capability (maximum received power, etc.), and feedback information on the power receiving state (power value during power reception, etc.).

Below, the transfer of power between devices is expressed as power transmission, power reception, or power transmission (wireless power transfer), and the exchange for authentication and the exchange of control information between devices is simply referred to as communication (wireless communication). To do.

In FIG. 1A, 110 indicates a power transmission range of the power transmission apparatus 101 (power transmission range), and 120 indicates a communication range of the power transmission apparatus 101 (communication range). It is assumed that the frequency bands of radio waves used for wireless power transmission and wireless communication in this embodiment are different. As shown in FIG. 1A, in the wireless power transmission system of the present embodiment, the communicable range is wider than the power transmitting range of the power transmitting device. This is because the frequency bands of the radio waves used for wireless power transmission and wireless communication are different, and the reach ranges of the radio waves used for each are not the same. The transmittable range of wireless power transmission is narrower than the communicable range of wireless communication because of large loss according to distance and large influence on objects existing in the transmittable range. Further, if the output power of the radio wave for wireless communication is reduced so that the communicable range of wireless communication and the power transmitting range of wireless power transmission are the same, correct communication may not be performed. Therefore, in the present wireless power transmission system, the output power of the radio wave for wireless communication is not reduced more than necessary in this way, and as a result, the communicable range becomes wider than the power transmitting range of the power transmitting device.

Communication that is performed between the devices of the wireless power transmission system according to the present embodiment uses communication that complies with the Bluetooth (registered trademark) 4.0 standard. Bluetooth (registered trademark) 4.0 defines a communication method called Bluetooth (registered trademark) Low Energy (BLE) that enables communication with relatively low power consumption. In the wireless power transmission system, the power transmission device operates as a master station of the network, which is a master defined by BLE. The power transmission device operates as a master because it needs to communicate with each of the plurality of power receiving devices in order to transmit power to the plurality of power receiving devices at one time. Further, the power receiving device operates as a slave defined by BLE, which is connected to the master and communicates under the control of the master.

Although the communication in this embodiment is based on BLE, other communication standards may be used. For example, a wireless LAN (IEEE802.11 series), NFC (Near Field Communication), ZIGBEE (registered trademark), or the like may be used. Further, the communication may be a unique communication method. Although one power transmitting device and one power receiving device are shown here, each may have two or more devices.

Next, the configuration of each device of the wireless power transmission system will be described. FIG. 2 is a diagram showing the configuration of the power transmission device of the wireless power transmission system. In the figure, reference numeral 210 denotes the entire power transmission device (power transmission device 101). A control unit 201 controls the power transmission device 210. The control unit 201 is, for example, a CPU (Central Processing Unit), and controls the entire apparatus by the CPU executing a control program stored in a memory 208 described later. Reference numeral 202 is a power supply that supplies power when wireless power transmission is performed from the power transmission device 210. The power source 202 is a commercial power source or a battery. Reference numeral 203 denotes a power transmission unit that converts direct current or alternating current power input from the power source 202 into alternating current frequency power in a transmission band and generates an electromagnetic wave for causing the power receiving device to receive power via the power transmitting antenna 205.

Reference numeral 204 is a detection unit that detects an input voltage to the power transmission antenna 205. The voltage detected by the detection unit 204 can be converted into electric power output from the power transmitting antenna 205 to the power receiving device. Further, the detection unit 204 may be configured to detect the input current and the input power value to the power transmission antenna 205. Further, the detection unit 204 may be configured to detect at least one of the input voltage, the input current, and the input power from the power supply unit 202 to the power transmission unit 203.

Based on the detection result of the detection unit 204, it is possible to determine whether there is an object that receives the power output by the power transmission device 210. This is because the detection result of the detection unit 204 when there is no object in the power transmission range and the detection result of the detection unit 204 when there is an object that consumes the transmitted power in the power transmission range are different. In addition, a change in power consumption of an object that receives the power output by the power transmission device 210 can be detected based on the detection result of the detection unit 204. For example, when the power transmission device is transmitting power at a constant output, the detection result of the detection unit 204 when the object existing in the power transmission range consumes 1 W and the detection result when the object consumes 2 W This is because the result is different. That is, according to the detection result of the detection unit 204, it is possible to detect a change in the load with respect to the power output by the power transmission device.

A communication unit 206 communicates with the power receiving device. The communication unit 206 includes a chip for controlling BLE-compliant wireless communication and an antenna for transmitting a signal. Note that the power transmission device 210 is not limited to a device dedicated to power transmission, and may be another device, for example, a device such as a printer or a PC.

Next, the configuration of the power receiving device of the wireless power transmission system will be described with reference to FIG. In FIG. 3, reference numeral 320 denotes the entire power receiving device (first power receiving device 102). A control unit 301 controls the power receiving device 320. The control unit 301 is, for example, a CPU, and the CPU executes the control program stored in the memory 310 described later to control the entire apparatus. A communication unit 302 communicates with the power transmission device 210. The communication unit 302 includes a chip for controlling BLE-compliant wireless communication and an antenna for transmitting a signal. Reference numeral 303 denotes a power receiving antenna for receiving wireless power transmission from the power transmission device 210. A change unit 304 changes the impedance of the power receiving antenna 303. When the communication unit 302 receives an instruction to change the impedance from the power transmission device 210, the change unit 304 changes the impedance of the power receiving antenna 303 according to the instruction from the power transmission device 210 received by the communication unit 302. The changing unit 304 changes the impedance of the power receiving antenna 303 to adjust the amount of power received from the power transmitting apparatus 210. The changing unit 304 adjusts the power consumed by the power receiving antenna 303 among the power output from the power transmission device 210 and received. That is, the changing unit 304 changes the load that consumes the electric power received from the power transmission device 210.

A power receiving unit 305 generates power from the electromagnetic waves received by the power receiving antenna 303. The power receiving unit 305 causes resonance due to the electromagnetic waves received by the power receiving antenna 303, and obtains AC power by the resonance. Then, the power receiving unit 305 rectifies the AC power into DC or AC power having a desired frequency and outputs the AC power. A switch 306 switches the input of the received power to the battery 308 that stores the received power. The battery 308 is a rechargeable battery, and the power received by the battery is stored. Reference numeral 307 is a timer for measuring a predetermined period. Reference numeral 309 denotes a first detection unit that converts electric power received from the power transmission device 210 into a voltage value and detects the voltage value. Reference numeral 310 is a memory that stores various types of information. 311 is a second detection unit that detects the voltage of the battery 308. The charging status of the battery 308 can be detected based on the detection result of the second detection unit 311.

Note that the control unit 301 and the communication unit 302 of the power receiving device 320 may operate with the power transmitted from the power transmitting device 210. With such a configuration, the power receiving device 320 can start communication with the power transmitting device 210 even when the power receiving device 320 does not hold the power required to start wireless power transmission from the power transmitting device 210. Note that an example of the power receiving device 320 may be a device such as a digital camera or a mobile phone.

Note that the configurations illustrated in FIGS. 2 and 3 are examples, and the power transmitting device 210 and the power receiving device 320 may include hardware configurations other than the illustrated hardware configurations. For example, the power transmission device 210 and the power reception device 320 may have an operation unit for the user to perform various inputs and operate the devices. Further, it may be provided with a display unit such as an LCD or an LED, which performs various kinds of display having a function of outputting visually recognizable information or outputting sound such as a speaker.

The exchange between the power transmitting device and the power receiving device in the wireless power transmission system having the above configuration includes three phases: a detection phase, a communication establishment phase, and a power transmission phase.

In the detection phase, the electromagnetic wave is intermittently generated from the power transmission antenna 205 to intermittently perform power transmission for detecting the power receiving device 320 (power transmission for detection). When an object is placed in the power transmission range of the power transmission device 210 during the power transmission for detection in the detection phase, the power transmission for detection is supplied to the object. In this case, the load impedance seen from the power transmission device 210 side changes, and a characteristic change in the voltage or current in the power transmission device 210 appears. By detecting a change in voltage or current in the power transmission device 210, it is possible to detect that an object is placed in the power transmission range of the device itself. When the power transmission device 210 detects that an object exists in the power transmission area of the device itself, the power transmission device 210 supplies the detected object with power required to transmit a response to the power transmission device 210 (response request power transmission). To start. When the detected object is the power receiving device 320, the response request power transmission is set to a power value sufficient to activate the control unit 301 and the communication unit 302 of the power receiving device 320. The power value of response request transmission is larger than the power value of detection transmission.

Further, the power receiving device 320 that has received the response request power transmission transmits an advertisement packet for transmitting a communication connection request from another device from the communication unit 302 within a certain period (for example, 100 ms) from the response request power transmission. When the power transmission device 210 receives the advertisement packet from the power reception device 320 that has responded to the response request power transmission, it determines that the power reception device 320 exists in the power transmission range.

The advertisement packet is a signal specified by BLE that is transmitted by broadcasting, and includes information such as the device name of itself and the type of service provided. The advertisement packet is used to notify peripheral devices that their own device is present and that they are waiting for a connection from the peripheral devices. The advertisement packet from the power receiving device 320 includes service information indicating that the wireless power transmission method supported by this system can be executed. In the following description, the advertisement packet will be referred to as a notification signal.

When the power transmission device 210 does not receive the notification signal from the power reception device 320 within a predetermined period (for example, 100 ms) after starting the response request power transmission, the power transmission device 210 stops the response request power transmission. Then, the electromagnetic wave is intermittently generated again from the power transmission antenna 205 to intermittently perform the power transmission for detection.

The communication establishment phase transitions when the power transmission device 210 detects a notification signal from the power reception device 320 in the detection phase. The power transmission device 210 transmits a Connection Request packet (connection request) from the communication unit 206 to the power reception device 320 that is the transmission source of the received notification signal. Then, the power transmission device 210 establishes a communication connection with the power reception device 320 in response to the transmitted connection request. In the communication establishment phase, mutual capability information is communicated (exchanged) with each other during the communication connection established between the power transmitting device 210 and the power receiving device 320. The capability information is, for example, the amount of power that can be transmitted and received, the hardware configuration, the supported power transmission method, the supported power transmission standard version, and the like. In the communication establishment phase, the power transmission device 210 extends (continues) the response request power transmission, and performs power transmission for causing the power receiving device 320 to perform communication required for communication connection and communication of capability information.

When the power transmission device 210 establishes a communication connection with the power reception device 320 in the communication establishment phase and exchanges capability information, the power transmission device 210 transitions to the power transmission phase. In the power transmission phase, the power transmission device 210 transmits power to the power reception device 320 that is higher than the power of the detection phase, the detection power transmission in the communication establishment phase, and the response request power transmission. In the power transmission phase, the power transmission apparatus 210 causes the communication unit 206 to receive control information for controlling wireless power transmission such as a value of received power, a request for increase or decrease in the amount of power transmission, and stop of power transmission from the power reception apparatus 320. To receive. The power transmission device 210 transmits power by generating an electromagnetic wave from the power transmission antenna 205 according to the received control information.

The power transmission phase ends when the power transmission device 210 is requested by the power reception device 320 to stop power transmission or when a power transmission error occurs. When the power receiving apparatus 320 requests the power transmitting apparatus 320 to stop power transmission, the power transmitting apparatus 210 instructs the communication unit 206 to set the impedance of the power receiving antenna 303 to a value at which the power transmitted by the power transmitting apparatus 210 is not substantially consumed. This value is about several KΩ in a state called high impedance. When the power receiving device 320 receives the change instruction to the high impedance from the power transmitting device 210 from the communication unit 302, the power receiving device 320 controls the changing unit 304 according to the instruction to change the impedance of the power receiving antenna 303 to the high impedance. The power transmission device 210 determines whether or not the impedance change is being performed by the power reception device 320 as instructed, based on the detection result of the detection unit 204. Then, when determining that the impedance change is being performed as instructed by the power receiving device 320, the power transmitting device 210 disconnects communication with the power receiving device 320.

When the power transmission device 210 ends the power transmission phase, the power transmission device 210 starts the operation in the detection phase again. When the power transmitting apparatus 210 starts the operation in the detection phase again, even if the power receiving apparatus 320 that has instructed the high impedance continues to exist in the power transmission range, the power receiving apparatus 320 has the high impedance, and therefore the power transmission for detection is performed. Consumes almost no Therefore, the load impedance viewed from the power transmitting device 210 side does not change, and the change in voltage or current is not detected due to the power receiving device 320 that has instructed to set the high impedance. That is, it is possible to reduce re-communication connection with the power receiving device 320 that has already transmitted power, without performing the response request power transmission due to the power receiving device 320 that has instructed to set the high impedance.

The operation of the wireless power transmission system for wireless power transmission according to this embodiment will be described with reference to the sequence chart shown in FIG. FIG. 4 is a diagram for explaining the operation of the power transmission device 101, in which the horizontal axis represents the passage of time and the vertical axis represents the voltage detected by the detection unit 204 provided in the power transmission device 101.

The power transmitting apparatus 101 starts operation in the detection phase in response to power-on or detection of an operation instruction from the user. In the detection phase, the power transmission apparatus 101 starts intermittent detection power transmission (401-1) from the power transmission antenna 205 at time T0. The detection power transmission cycle (from time T0 to time T2) may be any value. Further, the cycle of performing the power transmission for detection may be set randomly for each power transmission device. Furthermore, the power transmission for detection may be performed in a different cycle for each power transmission device.

Here, the power transmitting apparatus 101 stores the detection result aV of the detection unit 204 in the memory 208 during steady state detection power transmission (401-1). Note that the steady state is a state in which no other device is close to or in contact with the power transmission device 210, and is a state in which no power is output from the power transmission device.

At time T1, it is assumed that the user of the first power receiving apparatus 102 mounts the first power receiving apparatus 102 on the power transmitting apparatus 101 within the power transmission range of the power transmitting apparatus 101 in order to receive the power transmission. Since the power transmission device 101 is close to the power reception device, when the detection power transmission is output at time T2, the detection unit 204 detects a voltage value bV lower than the steady state during the detection power transmission. When the power transmitting apparatus 101 outputs power in a state where an object exists within the power transferable range, the output power is received (consumed) by the object, and the detection unit 204 detects a value different from the steady state.

Since the power transmitting apparatus 101 has detected an object close to its own apparatus, the power transmitting apparatus 101 starts response request power transmission (402-1). It should be noted that the detection power transmission and the response request power transmission may have different power values, and the response request power transmission may be higher than the detection power transmission. In this case, the detection result of the detection unit 204 in the steady state during response request power transmission is stored in the memory 208.

When detecting the power transmission for detection (401-2) from the power transmitting apparatus 101, the first power receiving apparatus 102 transmits a notification signal from the communication unit 302 within a certain period (for example, 100 ms) (403-1).

The power used when the first power receiving apparatus 102 transmits the notification signal may be the power received by the power transmission for detection. In this case, the power receiving device can communicate with the power transmitting device and can start wireless power transmission even when the power receiving device does not have the power required to transmit the notification signal.

Since the power transmitting apparatus 101 receives the notification signal from the first power receiving apparatus 102 before the elapse of a certain period (100 ms) after performing the response request power transmission in 402-1, the communication establishing phase with the first power receiving apparatus 102 is performed. The period of response request power transmission for performing is extended between T3 and T4. On the other hand, when the power transmitting apparatus 101 does not receive the notification signal from the power receiving apparatus before the elapse of a certain period (100 ms) after performing the response request power transmission in 402-1, the response request power transmission is stopped at time T3. ..

The power transmitting apparatus 101 that has received the notification signal before the elapse of a certain period transmits a connection request to the first power receiving apparatus 102 that is the transmission source of the received notification signal (404-1). The first power receiving apparatus 102 communicates with the power transmitting apparatus 101 in response to the received connection request from the power transmitting apparatus 101. After that, when the communication in the communication establishment phase is completed between the power transmitting apparatus 101 and the first power receiving apparatus 102, the power transmitting phase shifts, and the power transmitting apparatus 101 operates as the first power receiving apparatus 102 from time T4 to time T5. Power is transmitted to the server (405-1). The first power receiving apparatus 102 charges the battery 308 with the electric power received in the power transmission phase. When the first power receiving apparatus 102 determines from the detection result of the second detection unit 311 that power reception is not necessary, the communication unit 302 transmits a control signal requesting the stop of power transmission to the power transmission apparatus 101 (406). .. The state in which power reception is unnecessary is, for example, a state in which the battery 308 is fully charged (a state in which the amount of electricity stored in the battery is sufficient).

The power transmitting apparatus 101, which has received the control signal requesting the stop of power transmission, transmits an instruction to change the impedance of the power receiving antenna 303 to high impedance to the first power receiving apparatus 102 via the communication unit 206 (407). After that, at time T5, the power transmitting apparatus 101 stops power transmission to the first power receiving apparatus 102 in the power transmission phase and disconnects communication with the first power receiving apparatus 102.

The first power receiving apparatus 102 changes the impedance of the power receiving antenna 303 to the high in-piece by the changing unit 304 according to the impedance change instruction received from the power transmitting apparatus 101. Note that the power receiving antenna 303 of the first power receiving apparatus 102 is assumed to change to a high in-piece according to an instruction from the power transmitting apparatus 101. However, regardless of the instruction from the power transmitting apparatus 101, the first power receiving apparatus 102 may change the power receiving antenna 303 to the high in-piece with the transmission of the control signal requesting the stop of the power transmission. The first power receiving apparatus 102 may disconnect the communication with the power transmitting apparatus 101.

The power transmitting apparatus 101 restarts the operation in the detection phase after ending the power transmission phase at time T5. That is, the power transmission apparatus 101 performs intermittent detection power transmission from the power transmission antenna 205 (401-3, 401-4). At this time, the first power receiving apparatus 102 remains in the power transmission range of the power transmitting apparatus 101 even after the first power receiving apparatus 102 is fully charged and the power reception is completed. However, since the first power receiving apparatus 102 sets the impedance of the power receiving antenna 303 to high impedance, it hardly receives (consumes) the power for detection (401-3, 401-4). Therefore, the detection result of the detection unit 204 of the power transmission apparatus 101 during the power transmission for detection (401-3, 401-4) becomes a value substantially equal to aV which is the steady state. That is, the power transmitting apparatus 101 does not perform the response request power transmission even if the first power receiving apparatus 102 is continuously placed in the power transmission range. Further, if the response request power transmission is not performed, the notification signal is not transmitted from the first power receiving apparatus 101, and the power transmission apparatus 101 does not transmit the connection request, and the power transmitting apparatus 101 and the first power receiving apparatus 102 You can limit unnecessary reconnections.

This reduces reconnection between the first power receiving apparatus 102 and the power transmitting apparatus 101, which does not require further power transmission. That is, it is possible to reduce the number of processes for performing unnecessary power transmission with respect to the first power receiving apparatus 102 whose internal battery is fully charged due to the power transmission. Furthermore, since unnecessary processing is omitted, the power consumption of each device can be reduced.

Next, at time T6, it is assumed that the capacity of the battery 308 of the first power receiving apparatus 102 decreases and needs to be charged. In the first power receiving device 102, the changing unit 304 changes the impedance of the power receiving antenna 303 from a high impedance to an initial value.

The power transmission device 101 performs detection power transmission at time T7 (401-5). The detection result of the detection unit 204 when performing the power transmission for detection 401-5 indicates that the impedance of the power receiving antenna 303 of the first power receiving apparatus 102 has returned to the initial value, and thus the voltage lower than the steady state during the power transmission for detection is used. The value is bV. Although detailed description and illustration thereof are omitted because they have been described above, after that, the power transmission device 101 and the first power reception device 102 again perform power transmission in the power transmission phase at time T8 after a notification signal exchange and a communication connection phase (405). -2). In this way, when the battery needs to be charged again, the first power receiving apparatus 102 can quickly start recharging by returning the impedance of the power receiving antenna 303 to the initial value.

Next, the operation of the power receiving device 320 shown in FIG. 3 in the present embodiment will be described according to the flowchart shown in FIG. Note that the flowchart shown in FIG. 5 is realized by the control unit 301 executing a control program stored in the memory 310, calculating and processing information, and controlling each hardware. Note that some or all of the steps shown in the flowchart in FIG. 5 may be realized by hardware such as ASIC (Application Specific Integrated Circuit).

Upon starting the operation, the changing unit 304 of the power receiving device 320 sets the impedance of the power receiving antenna 303 to the initial value (S500). Subsequently, the first detection unit 309 of the power receiving device 320 determines whether detection power transmission has been detected via the power receiving antenna 303 (S501). When the power receiving device 320 detects the power transmission for detection, the power receiving device operates the control unit 301 and the communication unit 302 by the received power, and the communication unit 302 notifies the information of its own device such as the information about the function and service of the power receiving device 320. The notification signal of is transmitted (S502). The notification signal is a packet that can be transmitted before wireless connection is made, and is broadcast by a surrounding device to transmit a connection request to the device itself. Note that the transmission of the notification signal is stopped after a certain period of time has passed since the detection power transmission was not detected.

In FIG. 4, the first power receiving apparatus 102 detects the detection power transmission transmitted from the power transmission apparatus 101 at time T2 (S501). Then, the first power receiving apparatus 102 transmits the notification signal 403-1 (S502).

Returning to the description of FIG. 5, the control unit 301 determines whether the communication unit 302 has received a connection request from the power transmission device 210 after transmitting the notification signal (S503). Note that steps S501, S502, and S503 are repeated until the connection request is received. If it is determined that the connection request is received in S503, the communication unit 302 transmits a connection response to the power transmission device 210 and establishes a wireless communication connection with the power transmission device 210 (S504).

Then, the communication unit 302 performs communication for exchanging information necessary for power transmission with the connected power transmission device 210 (S505). If communication is not started within a predetermined period (for example, 5 seconds) after the wireless communication connection, the communication with the connected power transmission device 210 may be disconnected and the process may be returned to S501.

When the communication for exchanging information necessary for power transmission is completed, the power receiving device 320 receives the power transmission started by the power transmitting device 210 by the power receiving unit 305 and charges the battery 308 with the received power (S506).

After that, the control unit 301 determines whether to stop the power reception based on the detection result of the second detection unit 311 (S507). Here, if it is detected from the detection result of the second detection unit 311 that the battery 308 is fully charged, it is determined that the power reception is stopped. When it is determined that the power reception is to be stopped, the communication unit 302 transmits control information requesting the power transmission device 210 to stop power transmission (S508). In FIG. 4, the first power receiving apparatus 102 receives the power transmission 405-1 from the power transmitting apparatus 101 and then transmits the control signal 406.

When the communication unit 302 receives the impedance change instruction from the power transmission device 210, the control unit 301 changes the impedance of the power receiving antenna 303 according to the impedance change instruction received by the change unit 304 (S509). That is, the changing unit 304 changes the impedance of the power receiving antenna 303 to a high impedance in response to an impedance change instruction from the power transmission device 210. Then, the power receiving device 320 disconnects the communication with the power transmitting device 210 by the communication unit 302. In FIG. 4, when the first power receiving device 102 receives the change instruction 407 from the power transmitting device 101, the first power receiving device 102 changes the impedance of the power receiving antenna 303 to high impedance. The power receiving device 320 changes the impedance of the power receiving antenna 303 to high impedance, and then disconnects the communication with the power transmitting device 210 by the communication unit 302 (S510).

The control unit 301 measures the amount of electricity of the battery 308 based on the detection result of the second detection unit 311, and determines whether the remaining amount of the battery 308 has decreased (S511). The control unit 301 determines whether or not power re-reception is necessary based on whether or not the remaining amount of the battery 308 has fallen below a predetermined value (for example, 95%) (S512). Further, when the power receiving device 320 is removed from the power transmission range of the power transmitting device 210, it is determined that re-power reception is not necessary.

When it is determined that the power needs to be received again, the control unit 301 then performs the process from S500 again. On the other hand, when it is determined that the re-power reception is not necessary, the processing ends.

Next, the operation of the power transmission device 210 shown in FIG. 2 in the present embodiment will be described according to the flowchart shown in FIG. The flowchart shown in FIG. 6 is realized by the control unit 201 executing a control program stored in the memory 208, calculating and processing information, and controlling each hardware. Note that some or all of the steps shown in the flowchart in FIG. 6 may be realized by hardware such as ASIC.

When the power transmission device 210 starts operating, the power transmission unit 203 starts intermittent detection power transmission (S601). The control unit 201 determines whether or not the load impedance viewed from the power transmission device 210 side has changed, based on whether the detection result of the detection unit 204 during power transmission for detection has changed from the steady state (S602). Note that the steady state is a state in which no other device is close to or in contact with the power transmission device 210. In FIG. 4, the power transmission device starts detection power transmission at time T0.

The control unit 201 detects from the detection result of the detection unit 204 that an object exists in the power transmission area of the own device. That is, when the power receiving device 320 exists in the power transmission area of the power transmitting device 210, the power consumption corresponding to the load of the power receiving device 320 is received, so that the detection voltage of the detection unit 204 decreases by a certain value. The power consumption according to the load of the power receiving device 320 is the power required to operate the control unit 301 and the communication unit 302 or simply the power consumed by the power receiving antenna 303. When there is no change in the detection voltage of the detection unit 204, the process returns to S601 and the power transmission for detection is repeated. In FIG. 4, power transmission device 101 detects a change in the detection voltage of detection unit 204 at time T2.

When the detection voltage of the detection unit 204 changes, the power transmission unit 203 starts the response request power transmission to supply the power for transmitting the response to the power receiving device 320 (S603). Response request transmission is different from intermittent detection transmission, which is transmission of constant power continuously. The control unit 201 determines whether the notification signal is received from the power receiving device 320 within a certain period (for example, 100 ms) after starting the response request power transmission (S604). Whether it is a notification signal from the power receiving device 320 or not is determined by whether or not the received notification signal includes service information indicating that the wireless power transmission method supported by this system can be executed. When the notification signal is not received, the response request power transmission is stopped, the process returns to S601 again, and the detection power transmission is performed.

When it is determined in S604 that the notification signal has been received from the power receiving device 320 within the fixed period, the power transmitting device 210 continues the response request power transmission. Then, the power transmission device 210 transmits a connection request from the communication unit 302 to the transmission source of the notification signal received in S604, and wireless communication connection is established (S605). In FIG. 4, the power transmitting apparatus 101 receives the notification signal (403-1) from the first power receiving apparatus 102 within a certain period after starting the response request power transmission (402-1). Then, the power transmitting apparatus 101 transmits a connection request (404-1) to the first power receiving apparatus 102 and wirelessly connects to the first power receiving apparatus 102.

The communication unit 206 communicates (exchanges) mutual capability information and information necessary for power transmission with the power receiving device 320 wirelessly connected in S605 (S606). Then, the power transmission unit 203 starts wireless power transmission in the power transmission phase (S607).

When the control unit 201 receives a request for stopping power transmission from the power receiving device 320 from the communication unit 206 after starting power transmission, the control unit 201 determines to stop power transmission (S608). When determining to stop power transmission, the power transmitting apparatus 210 transmits an impedance change instruction from the communication unit 302 to the power receiving apparatus 320 that is the transmission source of the request to stop power transmission (S609). The impedance change instruction transmitted in S609 is an instruction to change the impedance of the power receiving antenna 303 to a high impedance. In FIG. 4, when the power transmitting apparatus 101 receives the power transmission stop request (406) from the first power receiving apparatus 102, the power transmitting apparatus 101 transmits an impedance change instruction (407).

After transmitting the impedance change instruction, the power transmission device 210 stops power transmission to the power reception device 320 that is the transmission source of the power transmission stop request (S610), and disconnects communication with the power reception device (S611). Next, the control unit 201 determines whether there is another power receiving device that is transmitting power (S612). If there is another power receiving device that is transmitting power, power transmission to this other power receiving device is continued (S607). If there is no other power receiving device that is transmitting power, the power transmitting device 210 executes the process from S601 again unless the power is stopped. The power transmission device 210 ends the process when the power supply is stopped (S613). Although the determination of S613 is made after S612, the determination may be made at any timing during the process.

As described above, it is necessary to recharge this power receiving device even if the power receiving device, which has fully charged the battery due to charging by wireless power transmission and has finished receiving power, is continuously placed in the power transmission range of the power transmitting device. If not, the reconnection of communication between the power receiving device and the power transmitting device is restricted.

In this way, by restricting unnecessary reconnection between the power receiving device and the power transmitting device, it is possible to reduce processing for performing unnecessary power transmission. Furthermore, since unnecessary processing is omitted, the power consumption of each device can be reduced.

Note that, in the above-described embodiment, the configuration has been described in which the power reception device 320 after being fully charged has a high impedance and the power transmission device 210 cannot detect the power reception device 320, and thus does not perform the response request power transmission. However, even if the power receiving apparatus 320 does not send a notification signal when the power requesting apparatus 320 receives the response request power transmission from the power transmitting apparatus 210 instead of setting the power receiving apparatus 320 after the full charge to high impedance, unnecessary reconnection Can be restricted. When the battery of the power receiving device 320 after being fully charged needs to be recharged, the notification signal may be transmitted when the response request power transmission is received.

In the above-described embodiment, the power transmission device 210 and the power reception device 320 that has been fully charged by power transmission are restricted from being reconnected. However, when the power receiving device 320 that does not require power reception is placed within the power transmission range of the power transmitting device 210, the wireless communication connection between the power receiving device 320 and the power transmitting device 210 may be controlled. .. In this case, when the power reception device 320 receives the response request power transmission from the power transmission device 210, the power reception device 320 transmits an advertisement packet including information indicating that the power reception is unnecessary. The power transmission device 320 that has received the advertisement packet including the information indicating that the power reception is not required does not transmit the connection request to the power reception device 320 that is the transmission source of the advertisement packet. With such a configuration, even when the power receiving device 320 that does not require power reception is placed within the power transmission range, unnecessary wireless communication connection with the power receiving device 320 can be reduced.

(Second embodiment)
A wireless power transmission system for wireless power transmission according to this embodiment is shown in FIG. As a difference from the first embodiment, a case will be described in which the power transmitting apparatus 101 transmits power to the second power receiving apparatus 103 as well as the first power receiving apparatus 102.

Specifically, the second power receiving device 103 is arranged in the power transmission range of the power transmitting device 101 while the power transmitting device 101 is transmitting power to the first power receiving device 102. Then, the power transmitting apparatus 101 transmits power to the first power receiving apparatus 102 and the second power receiving apparatus 103 at the same time. Next, when the first power receiving apparatus 102 is fully charged and does not need to receive power, and the power transmitting apparatus 101 is transmitting power to the second power receiving apparatus 103, the first power receiving apparatus 102 can transmit power to the power transmitting apparatus 101. The operation in the case of being continuously arranged in the range will be described.

The configurations of the power transmitting device 101, the first power receiving device 102, and the second power receiving device 103 according to the present embodiment are the same as those in the first embodiment, and therefore description thereof will be omitted. The power transmission device 101 according to the present embodiment can perform the same operation as the power transmission device 210 described in the first embodiment. The first power receiving apparatus 102 and the second power receiving apparatus 103 according to the present embodiment can perform the same operation as the power receiving apparatus 320 described in the first embodiment. The power transmission device 101 of this embodiment can transmit power to a plurality of power reception devices 320. In this case, the power transmitting apparatus 101 transmits power to each of the plurality of power receiving apparatuses 320 in a time-sharing manner, or transmits to each of the plurality of power receiving apparatuses 320 using electromagnetic waves of different frequencies used for power transmission. As a result, power is transmitted to the plurality of power receiving devices 320.

It is assumed that the second power receiving apparatus 103 is arranged in the power transmission range of the power transmitting apparatus 101 while the power transmitting apparatus 101 is transmitting power to the first power receiving apparatus 102. At this time, the power transmitting apparatus 101 is not transmitting power for detection because it is in the power transmitting phase in which power is transmitted to the first power receiving apparatus 102. Therefore, when the power receiving device (first power receiving device 102, second power receiving device 103) of the present embodiment detects power transmission in the power transmission phase to another power receiving device while being arranged in the power transmission range of the power transmitting device 101, A notification signal is transmitted to establish a wireless connection with the power transmission device 101. With this configuration, even when the power transmitting device capable of transmitting power to the plurality of power receiving devices is transmitting power to a certain power receiving device, it is possible to add a new power receiving device to perform power transmission.

However, when the power transmitting apparatus 101 is transmitting power to the first power receiving apparatus 102 and the second power receiving apparatus 103, if the first power receiving apparatus 102 is continuously arranged in the power transmission range even after being fully charged, The device 101 may make communication connection with the first power receiving device 102 again.

For example, since the first power receiving apparatus 102 is fully charged, the first power receiving apparatus 102 transmits a power transmission stop request to the power transmitting apparatus 101. The power transmitting apparatus 101 stops power transmission to the first power receiving apparatus 102 and disconnects communication with the first power receiving apparatus 102 in response to the reception of the power transmission stop request. However, even if the power transmission apparatus 101 stops transmitting power to the first power receiving apparatus 102, the power transmission apparatus 101 continues to transmit power to the second power receiving apparatus 103, and thus does not shift to the detection phase and remains in the power transmission phase.

Therefore, if the first power receiving apparatus 102 continues to be placed in the power transmission range of the power transmitting apparatus 101 after that, the first power receiving apparatus 102 that has detected the power transmission to the second power receiving apparatus 103 transmits the notification signal. Then, the power transmitting apparatus 101 may respond to the notification signal from the first power receiving apparatus 102 and reestablish the communication connection with the first power receiving apparatus 102.

In this way, the power transmitting apparatus 101 capable of transmitting power to a plurality of power receiving apparatuses has already transmitted power, and has performed a process for unnecessary power transmission on the first power receiving apparatus 102 that is fully charged and does not require power transmission. It may end up.

In order to prevent such a problem from occurring, the power receiving device according to the present embodiment limits reconnection with the power transmitting device 101 even when detecting power transmission to another power receiving device after being fully charged. That is, when the power receiving device is fully charged, stops receiving power from the power transmitting device 101, disconnects communication with the power transmitting device 101, is continuously placed in the power transmission range, and receives power transmission to another power receiving device. Is configured not to transmit the notification signal.

That is, when the power receiving apparatus of the present embodiment detects power transmission of the power transmitting apparatus to another power receiving apparatus when power reception to the own apparatus is necessary, the power receiving apparatus transmits a notification signal and performs processing for establishing a wireless connection with the power transmitting apparatus. .. On the other hand, when power reception has already ended and further power reception is unnecessary, even if the power transmission of the power transmission device to another power reception device is detected, the notification signal is not transmitted and the wireless connection with the power transmission device is limited.

Note that, when the first power receiving device 102 after full charge needs to be recharged, the communication connection with the power transmitting device 101 is performed again by releasing the restriction of the transmission of the notification signal and transmitting the notification signal. Then, the power transmission in the power transmission phase may be started again.

As described above, in a state where the power receiving device that has been fully charged by wireless power transmission and has finished receiving power is continuously placed in the power transmitting range of the power transmitting device and the power transmitting device is transmitting power to another power receiving device. Even if there is, the reconnection of the communication between the power receiving device and the power transmitting device is restricted.

Accordingly, by restricting unnecessary reconnection between the power receiving device and the power transmitting device, it is possible to reduce processing for performing unnecessary power transmission. Furthermore, since unnecessary processing is omitted, the power consumption of each device can be reduced.

(Other embodiments)
The present invention supplies a program that implements one or more functions of the above-described embodiments to a system or apparatus via a network or a storage medium, and one or more processors in a computer of the system or apparatus read and execute the program. It can also be realized by the processing. It can also be realized by a circuit (for example, ASIC) that realizes one or more functions.

101 first power transmission device 102 first power reception device 103 second power transmission device

Claims (7)

Power receiving means for wirelessly receiving power from the power transmitting device via the power receiving antenna;
A communication unit that performs communication for power reception with the power transmission device according to the Bluetooth standard via a communication antenna different from the power reception antenna;
A control unit that controls the communication unit so that the communication unit transmits an advertising packet in the Bluetooth standard after the power reception unit receives the power transmitted by the power transmission indicating the request for the response from the power transmission device. Then
When the power receiving by the power receiving unit is unnecessary, the control unit controls the communication unit to transmit, as the advertising packet, an advertising packet including information indicating that the power receiving is not required. Characteristic power receiving device. Wherein if the power receiving unit receiving is required by, wherein the controller controls the communication unit so as the advertising packet, and transmits the advertising packets to transmit Conection Request packet in the Bluetooth standard to the power transmitting device The power receiving device according to claim 1 . The power transmission indicating a request for a response, the power receiving device according to claim 1 or 2, wherein the power transmitting device is characterized in that which is performed when detecting an object. The case where the required power receiving by receiving means and is in any one of claims 1 to 3, wherein the storage means storing electric been received power is the case is fully charged by the power receiving means The power receiving device described. Further comprising a detection unit for detecting a storage state of the storage unit,
The power receiving device according to claim 4 , wherein the communication unit transmits a signal for stopping power transmission to the power transmission device when the detection unit detects a state in which the power storage unit is fully charged. .. A power receiving device having a power receiving unit that wirelessly receives power from the power transmitting device via the power receiving antenna, and a communication unit that performs communication for power reception with the power transmitting device according to the Bluetooth standard via a communication antenna different from the power receiving antenna. A control method to be performed,
A step of controlling the communication means so as to transmit an advertising packet in the Bluetooth standard after the power reception means receives power by power transmission indicating a response request from the power transmission device,
In the control step, when power reception by the power receiving unit is unnecessary, an advertising packet including information indicating a state in which power reception is unnecessary is transmitted as the advertising packet . The computer program for functioning as a power receiving device according to any one of claims 1 to 5.

Images