JP6787225B2 - Transmitters, power transmission systems, power transmission methods for transmitters, and power receivers - Google Patents

Description

The present invention relates to a transmitter, a power transmission system, a power transmission method of the transmitter, and a power receiver.

Conventionally, at least one target device has a step of transmitting a wakeup request signal for initial communication, and at least one target device has a step of transmitting charging power for charging the at least one target device to the at least one target device. There are communication and power control methods for wireless power transmission and charging systems, including.

The step further includes receiving at least one of the information regarding the reception sensitivity of the wakeup request signal and the information regarding the reception level of the charging power from the at least one target device. Further, it further includes a step of detecting a target device located within the power transmission region of the source device based on at least one of the information regarding the reception sensitivity of the wakeup request signal and the information regarding the reception level of the charging power. (See, for example, Patent Document 1).

Japanese Patent Publication No. 2014-521290

By the way, in the conventional method, when transmitting charging power (transmitting power), power transmission is started in consideration of the travel time for the target device (receiver) to move to the power transmission after the communication is established. not going.

Therefore, when the power receiver moves along one or a plurality of predetermined routes, it is not possible to start power transmission in consideration of the movement time after the communication is established, which is not convenient.

Therefore, it is an object of the present invention to provide a highly convenient power transmission system, a power transmission system, a power transmission method of the power transmission device, and a power receiver.

The transmitter according to the embodiment of the present invention transmits power by magnetic field resonance or electric field resonance to a movable power receiver having a secondary side resonance coil and a power receiving side communication unit that performs data communication by short-range radio communication. When the primary side resonance coil, the high frequency power supply that outputs the high frequency first transmission power to the primary side resonance coil, and the power receiving side communication unit enter the communication region of the short-range wireless communication, the power receiving side communication unit And the transmission side communication unit that establishes communication by the short-range radio communication and performs data communication, and the transmission side communication unit establishes the communication and position information according to the position of the power receiver from the power reception side communication unit. When the movement time of the power receiver between the position represented by the position information and the primary side resonance coil elapses after receiving the above, the power control unit that causes the high frequency power supply to output the first transmitted power is included. ..

It is possible to provide a highly convenient transmitter, a power transmission system, a power transmission method for the transmitter, and a power receiver.

It is a figure which shows the structure of the coil of the power transmission system 50 of embodiment. It is a figure which shows the power receiver 80 and the transmitter 100 of an embodiment. It is a figure which shows the factory 300 which applied the electric power transmission system 50. It is a figure which shows the data of the table format which associated the moving time of a worker with a part area and ID of a worker. It is a flowchart which shows the process which the control part 85 of a power receiving device 80 executes. It is a flowchart which shows the process which the control part 110 of a transmitter 100 executes.

Hereinafter, the transmitter, the electric power transmission system, the electric power transmission method of the transmitter, and the embodiment to which the electric receiver is applied will be described.

<Embodiment>
FIG. 1 is a diagram showing a configuration of a coil of the power transmission system 50 of the embodiment. The power transmission system 50 includes an AC power supply 1, a power transmitter 100 on the primary side (transmission side), and a power receiver 80 on the secondary side (power reception side). The power transmission system 50 may include a plurality of transmitters 100 and receivers 80.

The transmitter 100 has a primary coil 11 and a primary resonant coil 12. The power receiver 80 has a secondary resonance coil 81 and a secondary coil 82. A load device 30 is connected to the secondary coil 82.

As shown in FIG. 1, the transmitter 100 and the power receiver 80 are transmitted by magnetic field resonance (magnetic field resonance) between the primary side resonance coil (LC resonator) 12 and the secondary side resonance coil (LC resonator) 81. Energy (power) is transmitted from the electric device 100 to the power receiving device 80. Here, the power transmission from the primary side resonance coil 12 to the secondary side resonance coil 81 can be not only magnetic field resonance but also electric field resonance (electric field resonance), but in the following description, magnetic field resonance is mainly taken as an example. explain.

Further, in the embodiment, as an example, the frequency of the AC voltage output by the AC power supply 1 is 6.78 MHz, and the resonance frequency of the primary side resonance coil 12 and the secondary side resonance coil 81 is 6.78 MHz. explain.

The power transmission from the primary side coil 11 to the primary side resonance coil 12 is performed by using electromagnetic induction, and the power transmission from the secondary side resonance coil 81 to the secondary side coil 82 also uses electromagnetic induction. Is done.

Next, the power receiver 100 and the power transmission system 50 of the embodiment will be described with reference to FIG.

FIG. 2 is a diagram showing a power receiver 80 and a power transmitter 100 of the embodiment. The transmitter 100 includes an AC power supply 1, a primary coil 11, a primary resonance coil 12, a matching circuit 13, a capacitor 14, a control unit 110, a communication unit 120, and an antenna 121. The AC power supply 1 is the same as that shown in FIG.

The power receiver 80 includes a secondary resonance coil 81, a secondary coil 82, a rectifier circuit 83, a smoothing capacitor 84, a control unit 85, and output terminals 86A and 86B, a voltage detection unit 86V, a current detection unit 86I, and a communication unit 87. , Includes antennas 87A, 87B. A DCDC converter 210 is connected to the output terminals 86A and 86B, and a battery 220 is connected to the output side of the DCDC converter 210. In FIG. 2, the load circuit is a battery 220.

As shown in FIG. 2, the primary side coil 11 is a loop-shaped coil, and is connected to the AC power supply 1 via a matching circuit 13 between both ends. The primary side coil 11 is arranged in close proximity to the primary side resonance coil 12 in a non-contact manner, and is electromagnetically coupled to the primary side resonance coil 12. The primary side coil 11 is arranged so that its own central axis coincides with the central axis of the primary side resonance coil 12. Matching the central axes improves the coupling strength between the primary coil 11 and the primary resonance coil 12, suppresses magnetic flux leakage, and eliminates unnecessary electromagnetic fields from the primary coil 11 and the primary resonance coil. This is to suppress the occurrence around 12.

The primary coil 11 generates a magnetic field by AC power supplied from the AC power supply 1 via the matching circuit 13, and transmits the power to the primary resonance coil 12 by electromagnetic induction (mutual induction).

As shown in FIG. 2, the primary side resonance coil 12 is arranged in close contact with the primary side coil 11 in a non-contact manner and is electromagnetically coupled to the primary side coil 11. Further, the primary resonance coil 12 has a predetermined resonance frequency and is designed to have a high Q value. The resonance frequency of the primary side resonance coil 12 is set to be equal to the resonance frequency of the secondary side resonance coil 81. A capacitor 14 for adjusting the resonance frequency is connected in series between both ends of the primary resonance coil 12.

The resonance frequency of the primary resonance coil 12 is set to be the same frequency as the frequency of the AC power output by the AC power supply 1. The resonance frequency of the primary resonance coil 12 is determined by the inductance of the primary resonance coil 12 and the capacitance of the capacitor 14. Therefore, the inductance of the primary resonance coil 12 and the capacitance of the capacitor 14 are set so that the resonance frequency of the primary resonance coil 12 is the same as the frequency of the AC power output from the AC power supply 1. Has been done.

The matching circuit 13 is inserted to match the impedance between the primary side coil 11, the primary side resonance coil 12, the secondary side resonance coil 81, and the secondary side coil 82 and the AC power supply 1, and is inserted into the inductor L and the capacitor. Including C. If the impedances of the primary side coil 11, the primary side resonance coil 12, the secondary side resonance coil 81, and the secondary side coil 82 and the AC power supply 1 are close to each other, the matching circuit 13 may not be provided.

The AC power supply 1 is a power supply that outputs AC power having a frequency required for magnetic field resonance, and incorporates an amplifier that amplifies the output power. The AC power supply 1 outputs, for example, high-frequency AC power of about several tens of kHz to several tens of MHz.

The capacitor 14 is a variable capacitance type capacitor inserted in series between both ends of the primary resonance coil 12. The capacitor 14 is provided to adjust the resonance frequency of the primary resonance coil 12, and the capacitance is set by the control unit 110.

The control unit 110 controls the output voltage and output frequency of the AC power supply 1, controls the capacitance of the capacitor 14, controls the amount of power (output) transmitted from the primary resonance coil 12, and the like, as follows. Take control. The control unit 110 is an example of a power control unit.

When short-range wireless communication is established between the communication unit 120 and the communication unit 87 of the power receiver 80, the control unit 110 acquires the position information of the power receiver 80 from the communication unit 87 and sets the movement time according to the position information. Count. Then, when the count of the travel time is completed, the AC power source 1 is made to output high frequency power, and the primary side resonance coil 12 transmits power. The movement time is the time for the power receiver 80 to move to the position of the primary resonance coil 12. Details of such control of the control unit 110 will be described later.

The communication unit 120 is a communication unit that performs data communication by short-range wireless communication, and for example, performs data communication by Bluetooth (registered trademark) LE. An antenna 121 is connected to the communication unit 120. The antenna 121 may be any antenna capable of performing short-range wireless communication by Bluetooth (registered trademark) LE. The communication unit 120 is an example of the power transmission side communication unit.

In the transmitter 100 as described above, when the control unit 110 finishes counting the travel time, the AC power supplied from the AC power supply 1 to the primary coil 11 is transmitted to the primary resonance coil 12 by magnetic induction, and the primary side Power is transmitted from the resonance coil 12 to the secondary resonance coil 81 of the power receiver 80 by magnetic field resonance.

The secondary resonance coil 81 has the same resonance frequency as the primary resonance coil 12 and is designed to have a high Q value. The pair of terminals of the secondary resonance coil 81 are connected to the capacitor 81A. The secondary resonance coil 81 is electromagnetically coupled to the secondary coil 82, and transmits electric power to the secondary coil 82 by electromagnetic induction. The secondary resonance coil 81 transmits the AC power transmitted by the magnetic field resonance from the primary resonance coil 12 of the transmitter 100 to the secondary coil 82 by electromagnetic induction. The secondary resonance coil 81 corresponds to the secondary resonant coil 81 shown in FIG.

The secondary coil 82 has a pair of terminals connected to the rectifier circuit 83, and outputs the electric power received by electromagnetic induction from the secondary resonance coil 81 to the rectifier circuit 83.

The rectifier circuit 83 has four diodes 83A to 83D. The diodes 83A to 83D are connected in a bridge shape, and the electric power input from the secondary coil 82 is full-wave rectified and output.

The smoothing capacitor 84 is connected to the output side of the rectifier circuit 83, smoothes the power rectified by the rectifier circuit 83 in full wave, and outputs it as DC power. Output terminals 86A and 86B are connected to the output side of the smoothing capacitor 84. The power that has been full-wave rectified by the rectifier circuit 83 can be treated as approximately DC power because the negative component of the AC power is inverted to the positive component, but it was full-wave rectified by using the smoothing capacitor 84. Stable DC power can be obtained even when the power includes ripples.

A signal representing the voltage detected by the voltage detection unit 86V, a signal representing the current detected by the current detection unit 86I, and a signal representing the charge rate of the battery 220 are input to the control unit 85. Whether the control unit 85 receives power from the transmitter 100 via the secondary resonance coil 81 and the secondary coil 82 based on the signals representing the voltage and current detected by the voltage detection unit 86V and the current detection unit 86I. It is determined whether or not, and the charge rate of the battery 220 is detected based on the signal representing the charge rate input from the battery 220.

A communication unit 87 is connected to the control unit 85. Antennas 87A and 87B are connected to the communication unit 87. The antenna 87A is used for data communication in short-range wireless communication with the transmitter 100, and the antenna 87B is used for data communication in a wireless LAN (Local Area Network) with the server. The communication unit 87 is an example of a power receiving side communication unit. Further, the control unit 85 stores the ID of the worker who performs the work using the cart on which the power receiving device 80 is mounted in the internal memory. The server will be described later with reference to FIG.

When short-range wireless communication is established between the communication unit 120 and the communication unit 87 of the transmitter 100, the control unit 85 receives power from the transmitter 100 via the secondary resonance coil 81 and the secondary coil 82. Determine if it is present. If the voltage and current detected by the voltage detection unit 86V and the current detection unit 86I are equal to or higher than a predetermined value, the control unit 85 determines that power is being received.

The control unit 85 transmits data indicating whether or not power is being received (data indicating the power receiving state), data indicating the charging rate, and data indicating the ID of the worker to the transmitter 100 by short-range wireless communication.

Here, the mode in which the control unit 85 determines that power is being received when the voltage and current detected by the voltage detection unit 86V and the current detection unit 86I are equal to or higher than a predetermined value will be described. If any one of them is equal to or more than a predetermined value, it may be determined that power is being received. In this case, the power receiver 80 may include one of the voltage detection unit 86V and the current detection unit 86I.

The voltage detection unit 86V is provided between the output terminals 86A and 86B, and receives the voltage of the electric power received from the transmitter 100 via the secondary side resonance coil 81 and the secondary side coil 82 of the output terminals 86A and 86B. Detected as voltage between terminals. A signal representing the detected voltage is input to the control unit 85. In addition. The voltage between terminals detected by the voltage detection unit 86V is equal to the input voltage of the DCDC converter 210.

The current detection unit 86I is provided between the positive electrode side terminal (upper terminal in FIG. 2) of the smoothing capacitor 84 and the output terminal 86A, and is provided between the secondary side resonance coil 81 and the secondary side coil 82. The current of the electric power received from the transmitter 100 is detected via.

The DCDC converter 210 has input terminals 210A and 210B connected to output terminals 86A and 86B, and converts the voltage of DC power output from the power receiver 80 into the rated voltage of the battery 220 for output.

The DCDC converter 210 is, for example, a step-down DCDC converter, which steps down the voltage value (input voltage) of the received power supplied via the rectifier circuit 83 to the rated voltage of the battery 220 and supplies the DCDC converter 210 to the battery 220. The step-down type DCDC converter is used because the step-down type has a relatively low current value and is smaller than the step-up type and buck-boost type DCDC converters, and is suitable for the power receiver 80 which is required to be compact and lightweight. is there.

The battery 220 may be a secondary battery that can be recharged repeatedly, and for example, a lithium ion battery can be used. For example, when the power receiver 80 is built in an electronic device such as a tablet computer or a smartphone, the battery 220 is the main battery of such an electronic device. The battery 220 outputs the charge rate data to the control unit 85. As a result, the control unit 85 can grasp the charge rate of the battery 220 and determine whether or not it is in a fully charged state.

The primary side coil 11, the primary side resonance coil 12, the secondary side resonance coil 81, and the secondary side coil 82 are manufactured, for example, by winding a copper wire. However, the material of the primary side coil 11, the primary side resonance coil 12, the secondary side resonance coil 81, and the secondary side coil 82 may be a metal other than copper (for example, gold, aluminum, etc.). Further, the materials of the primary side coil 11, the primary side resonance coil 12, and the secondary side resonance coil 81 may be different.

In such a configuration, the primary side coil 11 and the primary side resonance coil 12 are the power transmission side, and the secondary side resonance coil 81 is the power reception side.

By the magnetic field resonance method, electric power is transmitted from the transmitting side to the receiving side by utilizing the magnetic field resonance generated between the primary side resonance coil 12 and the secondary side resonance coil 81, so that the electric power is electromagnetically induced from the transmitting side to the receiving side. It is possible to transmit electric power over a longer distance than the electromagnetic induction method that transmits electric power.

The magnetic field resonance method has a higher degree of freedom than the electromagnetic induction method in terms of the distance or positional deviation between the resonance coils, and has the advantage of being position-free.

FIG. 3 is a diagram showing a factory 300 to which the power transmission system 50 is applied. The factory 300 has parts areas A, B, C, ..., X, and parts shelves are arranged in each part area. Although a plurality of component areas are shown here as component areas A, B, C, ..., X, any number of component areas may be used as long as there are a plurality of component areas.

The cart 310 used by the worker (not shown) can be moved by four casters 311 and is pushed by the worker by hand to move to the parts areas A, B, C, ..., X. One of the four casters 311 is equipped with a sensor 311A that detects the movement of the cart 310. The sensor 311A may be any sensor that detects the rotation or rotation speed of the caster 311.

As such a sensor 311A, for example, a magnetic rotation detection sensor or a speed sensor can be used. Here, as an example, the sensor 311A is a sensor that detects a speed, and data representing the speed (speed data) is input to the control unit 85 of the power receiver 80. The control unit 85 transmits a signal indicating the speed to the transmitter 100 via the communication unit 87.

A tablet computer 312, a power receiver 80, a DCDC converter 210, and a battery 220 are attached to the cart 310. The tablet computer 312 is driven by the power supplied by the battery 220.

The tablet computer 312 is capable of wireless data communication with the server 500 via a wireless LAN (Local Area Network), and is capable of short-range wireless communication with the power receiver 80.

The parts list data is transmitted from the server 500 to the tablet computer 312 and displayed on the display. In the parts list, the order in which the parts areas A, B, C, ..., X are moved, and the types and quantities of parts to be picked up in the parts areas A, B, C, ..., X are displayed. According to the parts list displayed on the tablet computer 312, the operator pushes the cart 310 to go to the parts areas A, B, C, ..., X, picks up the parts listed in the parts list, and transports them to the assembly area. To do.

Further, the tablet computer 312 transmits data representing the last component area (final component area) among the component areas listed in the component list to the power receiver 80 by short-range wireless communication. The data representing the final component area is an example of position information according to the position of the power receiver.

Further, the tablet computer 312 transmits data representing the worker ID to the power receiver 80 by short-range wireless communication. Since both the tablet computer 312 and the power receiver 80 are mounted on the cart 310 and are arranged within the range where short-range wireless communication is possible, when Bluetooth (registered trademark) LE is used for short-range wireless communication. If the tablet computer 312 and the power receiver 80 are paired in advance, the tablet computer 312 can transmit data representing the final component area and data representing the worker ID to the power receiver 80.

FIG. 3 shows a communication area 120A in which the communication unit 120 of the transmitter 100 can perform data communication by short-range wireless communication with a dashed line. The communication area 120A is a range that extends in a circular shape in a plan view centering on the communication unit 120, but may not actually be a circular shape due to a wall or the like in the factory 300.

The route that the worker pushes the cart 310 to move is as shown by the broken line. A path 320A exists between the transmitter 100 and the component area A. Similarly, a path 320B exists between the transmitter 100 and the component area B, a path 320C exists between the transmitter 100 and the component area C, and the transmitter 100 and the component area X There is a path 320X in between.

The communication unit 87 of the power receiver 80 attached to the cart 310 is short-range radio with the communication unit 120 of the transmitter 100 outside the area 120A from the boundary 120Aa in the path 320A connecting the component area A and the transmitter 100. Although communication is not possible, short-range wireless communication with the communication unit 120 can be performed within the boundary 120Aa. Further, since the worker walks at a constant speed, it can be considered that the time required to move from the component area A to the transmitter 100 along the route 320A is constant. Similarly, it can be considered that the time required for the worker to push the cart 310 and move from the boundary 120Aa to the transmitter 100 is constant.

This is also the case when the worker pushes the cart 310 and moves from the parts areas B, C, ..., X to the transmitter 100. There are routes 320B, 320C, ..., 320X between the component areas B, C, ..., X and the transmitter 100, respectively, and the boundaries 120Ab, 120Ac, ..., 120Ax are provided for each route. Exists.

According to the parts list displayed on the tablet computer 312, the worker pushes the cart 310 to pick up the parts in the parts areas A, B, C, ..., X, and unloads the parts picked up in the assembly area. The transmitter 100 is arranged at this position to charge the battery 220. The transmitter 100 is embedded in the floor of the factory 300 and serves as a charging station. An example of a cart pushed by an employee by hand is shown, but it may be a transport cart that moves automatically. FIG. 4 is a diagram showing tabular data in which the movement time of the worker is associated with the component area and the ID (Identifier) of the worker. The table format data shown in FIG. 4 is stored in the internal memory of the control unit 110 of the transmitter 100.

The travel time shown in the table format data of FIG. 4 is the travel time from the boundaries 120Aa, 120Ab, 120Ac, ..., 120Ax to the transmitter 100. That is, it is the time required for each worker to move to the transmitter 100 after the short-range wireless communication between the communication unit 87 of the power receiver 80 and the communication unit 120 of the transmitter 100 is established.

As described above, the routes 320A, 320B, 320C, ..., 320X for moving from the component areas A, B, C, ..., X to the transmitter 100 are determined. Each worker moves in the parts area (A, B, C, ..., X) listed in the parts list in the order of movement, and routes (320A, 320B, 320C, ...) From the last stopped part area. ..., 320X) to move to the charging station where the transmitter 100 is located, that is, the assembly area.

The part area included in the tabular data of FIG. 4 represents the part area where the worker last stops. The worker ID is an ID (identifier) of each worker. When short-range wireless communication is established with the transmitter 100, the power receiver 80 transmits data indicating the power receiving state, data indicating the charging rate, and data indicating the worker's ID to the transmitter 100 by short-range wireless communication. To do.

FIG. 5 is a flowchart showing a process executed by the control unit 85 of the power receiver 80. The control unit 85 starts the process when the power of the power receiver 80 is turned on (turned on).

The control unit 85 determines whether or not short-range wireless communication with the transmitter 100 has been established (step S1). When using Bluetooth (registered trademark) LE for short-range wireless communication, if the communication unit 87 of the power receiver 80 and the communication unit 120 of the transmitter 100 are paired in advance, the communication area 120A of the communication unit 120 Short-range wireless communication is automatically established when the communication unit 87 enters the inside. The control unit 85 can determine that the short-range wireless communication has been established by receiving the beacon from the communication unit 120. The process of step S1 is repeatedly executed until it is determined that the short-range wireless communication has been established.

When the control unit 85 determines that the short-range wireless communication has been established (S1: YES), the control unit 85 acquires the data requested from the transmitter 100 (step S2). The data required from the transmitter 100 is any one of data representing the power receiving state, data representing the charge rate of the battery 220, data representing the final component area, data representing the worker ID, and speed data.

The control unit 85 generates data representing the power receiving state based on the voltage and current detected by the voltage detection unit 86V and the current detection unit 86I. Further, the control unit 85 acquires data representing the charge rate from the battery 220. Further, the control unit 85 acquires data representing the final component area and data representing the worker ID from the tablet computer 312 by short-range wireless communication. Further, the control unit 85 acquires speed data from the sensor 311A.

The control unit 85 transmits the data requested from the transmitter 100 to the transmitter 100 (step S3). The data transmitted in step S3 is the data requested by the transmitter 100 among the data representing the power receiving state, the data representing the charge rate of the battery 220, the data representing the final component area, the data representing the worker ID, and the speed data. Is.

The control unit 85 determines whether or not to end the process (step S4). The process ends when the power of the receiver 80 is turned off. When the control unit 85 determines that the processing is not completed (S4: NO), the control unit 85 returns the flow to step S1.

The control unit 85 repeatedly executes the flow shown in FIG. 5 while the power is turned on.

FIG. 6 is a flowchart showing a process executed by the control unit 110 of the transmitter 100.

The control unit 110 starts processing when the power of the transmitter 100 is turned on, and causes the communication unit 120 to transmit a beacon (step S11). The communication unit 120 repeatedly transmits the beacon from the antenna 121 at predetermined time intervals. The beacon may be, for example, a signal having a predetermined pulse width and amplitude (voltage value).

The control unit 110 determines whether or not communication with the power receiver 80 has been established (step S12). When the control unit 110 receives the data representing the worker ID and the final component area from the power receiver 80 via the communication unit 120, it determines that the communication has been established.

Here, the power receiver 80 that has received the beacon transmits the worker ID and the final component area to the transmitter 100. The beacon functions as a signal requesting a worker ID and a final component area. The process of step S12 is repeatedly executed until it is determined that communication has been established.

When the control unit 110 determines that the communication has been established (S12: YES), the control unit 110 starts counting the elapsed time from the establishment of the communication by using the timer built in the control unit 110 (step S13).

The control unit 110 reads out the movement time associated with the data representing the worker ID and the final component area received in step S2 in the table format data shown in FIG. 4 (step S14).

Next, the control unit 110 determines whether or not the count time in the timer has reached the movement time (step S15). The control unit 110 repeatedly executes the process of step S15 until the count time reaches the movement time.

When the control unit 110 determines that the count time has reached the travel time (S15: YES), the control unit 110 acquires speed data from the power receiver 80 (step S16). At step S16, the transmitter 100 requests the speed data from the receiver 80, and the receiver 80 transmits the speed data to the transmitter 100 in response to the request from the transmitter 100.

The control unit 110 determines whether or not the power receiver 80 has stopped moving (step S17). This is because if the cart 310 is not stopped, it is determined that the cart 310 is moving, that is, the cart 310 has not come to the power transmission station.

When the control unit 110 determines that the power receiver 80 has not stopped moving (S17: NO), the control unit 110 returns the flow to step S16. That is, the processes of steps S16 and S17 are repeatedly executed until the power receiver 80 is stopped.

When the control unit 110 determines that the power receiver 80 has stopped moving (S17: YES), the control unit 110 sets the count number N to 0 (step S18). The count number N is the number of repetitions when the determination that the power receiver 80 is not receiving power is repeated in the subsequent step S21, and is the number of times that power transmission is stopped in step S25.

Next, the control unit 110 starts power transmission at a predetermined low output (step S19). As a result, electric power is transmitted from the primary resonance coil 12 to the secondary resonant coil 81. The reason why the predetermined low output is set is that it is possible to determine whether or not the power receiver 80 is receiving power even at a low output, which is advantageous from the viewpoint of power consumption and safety.

Next, the control unit 110 acquires data representing the power receiving state and data representing the charge rate of the battery 220 from the power receiving device 80 (step S20). At step S20, the transmitter 100 requests the power receiver 80 for data indicating the power receiving state and the charging rate, and the power receiving device 80 transmits data indicating the power receiving state and the charging rate to the transmitter 100 in response to the request of the transmitter 100. To do.

Next, the control unit 110 determines whether or not the power receiver 80 is receiving power based on the data representing the power receiving state acquired in step S20 (step S21).

When the control unit 110 determines that the power receiving device 80 is receiving power (S21: YES), the control unit 110 determines whether or not the transmitted power is a normal value (step S22). The normal value is the electric power set to be transmitted to charge the battery 220 connected to the power receiver 80, and is higher than the predetermined low output set in step S19. The normal value electric power is an example of the first transmitted electric power. The predetermined low output power is an example of the second transmission power.

When the control unit 110 determines that the electric power is not a normal value (S22: NO), the control unit 110 increases the electric power to be transmitted to the normal value (step S23). By going through step S23 after the process of step 19, the transmitted power is increased to a normal value.

Next, the control unit 110 determines whether or not the charge state of the battery 220 connected to the power receiver 80 is fully charged based on the data representing the charge rate acquired in step S20 (step S24).

If the control unit 110 determines that the battery is not fully charged (S24: NO), the control unit 110 returns the flow to step S20. As a result, the processes of steps S20 to S24 are repeatedly executed. If it is determined in step S22 that the power is a normal value (S22: YES), the control unit 110 advances the flow to step S24.

When the control unit 110 determines that the battery is fully charged (S24: YES), the power transmission is stopped (step S25). This is because there is no need to charge any more.

Further, even when the control unit 110 determines in step S21 that the power receiver 80 is not receiving power (S21: NO), the control unit 110 advances the flow to step S25 and stops power transmission. This is because the power receiver 80 is not receiving power.

Next, the control unit 110 increments the count number N (N = N + 1) (step S26). As a result, the count number N is increased by 1.

Next, the control unit 110 determines whether the count number N is equal to the predetermined number of times M (step S27). The predetermined number of times M is, for example, three times.

When the control unit 110 determines that the count number N is equal to the predetermined number of times M (S27: YES), the control unit 110 returns the flow to step S1. This is because the power transmission has been stopped for a predetermined number of times M, so that the process is restarted from the beginning.

When the control unit 110 determines that the count number N is not equal to the predetermined number of times M (S27: NO), the control unit 110 waits for a predetermined time (step S). In this case, since the count number N has not reached the predetermined number of times M, the flow is returned to step S19 after waiting for a predetermined time. This is to wait for the power receiver 80 to be ready.

The control unit 110 of the transmitter 100 executes the above processing. This process ends when the power of the transmitter 100 is turned off.

As described above, according to the embodiment, when the receiver 80 enters the communication area 120A of the transmitter 100, the receiver 80 and the transmitter 100 start data communication by short-range wireless communication, and the transmitter 100 is the receiver. It waits for the movement time associated with the ID of the worker who uses the cart 310 on which the 80 is mounted and the final part area. The travel time is a unique travel time according to the walking speed of the worker specified by the worker ID.

Then, when the moving time elapses, power transmission is started from the primary resonance coil 12. At this time, it is considered that the worker who pushes the cart 310 while walking and moves will reach the charging station where the transmitter 100 is arranged.

Therefore, in the daily work of the worker, the primary side resonance coil 12 of the power transmission 100 and the secondary side resonance coil 81 of the power receiver 80 mounted on the cart 310 are not contacted by magnetic field resonance. The battery 220 mounted on the cart 310 can be easily charged by performing power transmission in.

Therefore, it is possible to provide a highly convenient power transmission 100, a power transmission system 50, a power transmission method for the power transmission 100, and a power receiver 80. When there are a plurality of such carts 310, if the battery 220 is connected to an outlet via a charging cable to charge the battery, it takes time to connect the charging cable, and charging is performed during a time period when the cart 310 is not used (charging). Although it is subject to restrictions such as being limited to nighttime when the worker does not work), the power transmission system 50 of the present embodiment is not subject to such restrictions and the battery 220 is efficiently used during work. Can be charged.

The number of times a worker who pushes the cart 310 and walks to the charging station may be set to an appropriate number of times according to the capacity of the battery 220 and the like.

Further, in the above description, the mode in which one transmitter 100 is arranged in the factory 300 has been described, but a plurality of transmitters 100 may be arranged.

Further, in the above, the mode in which the worker ID is included in the table format data shown in FIG. 4 and the movement time for each worker is set has been described. However, the movement time is the work without including the worker ID. It does not have to be set for each member. For example, this may be done when there is only one worker or when the walking speeds of all the plurality of workers are substantially the same.

Further, in the flowchart shown in FIG. 6, if the power transmission is stopped in step S25 without performing the processes of steps S26 to S28, the flow may be returned to step S19.

Further, although the case where the process is executed by the control unit 110 of the transmitter 100 is shown in this way, the same process may be performed by the control unit 85 of the power receiver 80 or the tablet computer 312.

Although the transmitter, the power transmission system, the power transmission method of the transmitter, and the power receiver of the exemplary embodiment of the present invention have been described above, the present invention is limited to the specifically disclosed embodiments. Various modifications and changes can be made without departing from the scope of claims.

The following additional notes will be further disclosed with respect to the above embodiments.
(Appendix 1)
A primary resonance coil that transmits power by magnetic field resonance or electric field resonance to a movable receiver having a secondary resonance coil and a power receiving communication unit that performs data communication by short-range wireless communication.
A high-frequency power supply that outputs high-frequency first transmission power to the primary resonance coil, and
When the power receiving side communication unit enters the communication area of the short-range wireless communication, the power receiving side communication unit and the power transmission side communication unit that establishes communication by the short-range wireless communication and performs data communication,
After the power transmission side communication unit establishes the communication and receives the position information corresponding to the position of the power receiver from the power reception side communication unit, between the position represented by the position information and the primary resonance coil. A power transmission including a power control unit that causes the high-frequency power source to output the first power transmission power when the moving time of the power receiver elapses.
(Appendix 2)
Further including a data storage unit for storing data associated with the position information and the travel time,
When the movement time associated with the position information received by the power transmission side communication unit in the data elapses after the power transmission side communication unit receives the position information, the power control unit supplies the high frequency power supply. The transmitter according to Appendix 1, which outputs the first transmitted power.
(Appendix 3)
The data stored in the data storage unit is data in which the position information and the travel time are associated with the user information representing the user of the power receiver.
The power control unit associates the power transmission side communication unit with the position information and the user information received by the power transmission side communication unit in the data after receiving the position information and the user information from the power reception side communication unit. The transmitter according to Appendix 2, wherein when the travel time has elapsed, the high-frequency power source outputs the first transmitted power.
(Appendix 4)
When the moving time of the power receiver elapses, the power control unit transmits the second power transmission power for testing, which is lower than the first power transmission power, and the power transmission side communication unit communicates with the power reception side. The following item 1 to 3, wherein the high-frequency power source is made to output the first transmitted power when the power receiving state information indicating the power receiving state of the power receiving device received from the unit indicates that the power is being received. Transmitter.
(Appendix 5)
The power transmission unit according to Appendix 4, wherein the power control unit stops power transmission to the high-frequency power source when the power reception status information indicates that power is not being received.
(Appendix 6)
A power transmission system comprising a power transmission that transmits power by magnetic field resonance or electric field resonance and a power receiver that receives power from the power transmitter by magnetic field resonance or electric field resonance.
The power receiver
Secondary resonance coil and
It is a mobile power receiver that has a power receiving side communication unit that performs data communication by short-range wireless communication.
The transmitter
A primary resonance coil that transmits electric power by the magnetic field resonance or the electric field resonance,
A high-frequency power supply that outputs high-frequency transmission power to the primary resonance coil, and
When the power receiving side communication unit enters the communication area of the short-range wireless communication, the power receiving side communication unit and the power transmission side communication unit that establishes communication by the short-range wireless communication and performs data communication,
After the power transmission side communication unit establishes the communication and receives the position information corresponding to the position of the power receiver from the power reception side communication unit, the position represented by the position information and the primary resonance coil A power transmission system having a power control unit that outputs the transmitted power to the high-frequency power source when the moving time of the power receiver elapses.
(Appendix 7)
A primary resonance coil that transmits power by magnetic field resonance or electric field resonance to a movable receiver having a secondary resonance coil and a power receiving communication unit that performs data communication by short-range wireless communication.
A high-frequency power supply that outputs high-frequency first transmission power to the primary resonance coil, and
When the power receiving side communication unit enters the communication area of the short-range wireless communication, the power transmission side including the power receiving side communication unit and the power transmitting side communication unit that establishes communication by the short-range wireless communication and performs data communication. It is a power transmission method
After the power transmission side communication unit establishes the communication and receives the position information corresponding to the position of the power receiver from the power reception side communication unit, between the position represented by the position information and the primary resonance coil. A power transmission method for a power transmission that causes the high-frequency power source to output the first power transmission power when the moving time of the power receiver elapses.
(Appendix 8)
It is a movable power receiver
Transmission having a primary side resonance coil that transmits power by magnetic field resonance or electric field resonance, a high frequency power supply that outputs high frequency transmission power to the primary side resonance coil, and a transmission side communication unit that performs data communication by short-range wireless communication. A secondary resonance coil that transmits power from an electric appliance by the magnetic field resonance or the electric field resonance,
When the power transmission side communication unit enters the communication area of the short-range wireless communication, the power transmission side communication unit and the power reception side communication unit that establishes communication by the short-range wireless communication and performs data communication,
When the power receiving side communication unit establishes the communication and the movement time of the power receiving device between the position of the power receiving device and the primary side resonance coil elapses, the power transmitting side communication unit via the power receiving side communication unit A power receiver that includes a control unit that transmits a command to output the transmitted power to the high frequency power source.

1 AC power supply 11 Primary side coil 12 Primary side resonance coil 13 Matching circuit 14 Capacitor 30 Load device 50 Power transmission system 80 Power receiver 81 Secondary side resonance coil 82 Secondary side coil 83 Rectifier circuit 84 Smoothing capacitor 85 Control unit 86A, 86B Output terminal 86V Voltage detector 86I Current detector 87 Communication unit 87A, 87B Antenna 100 Transmitter 110 Control unit 120 Communication unit 121 Antenna 210 DCDC converter 220 Battery 310 Cart 311 Caster 311A Sensor 312 Tablet computer

Claims (8)

A primary resonance coil that transmits power by magnetic field resonance or electric field resonance to a movable receiver having a secondary resonance coil and a power receiving communication unit that performs data communication by short-range wireless communication.
A high-frequency power supply that outputs high-frequency first transmission power to the primary resonance coil, and
When the power receiving side communication unit enters the communication area of the short-range wireless communication, the power receiving side communication unit and the power transmission side communication unit that establishes communication by the short-range wireless communication and performs data communication,
After the power transmission side communication unit establishes the communication and receives the position information corresponding to the position of the power receiver from the power reception side communication unit, between the position represented by the position information and the primary resonance coil. A power transmission including a power control unit that causes the high-frequency power source to output the first power transmission power when the moving time of the power receiver elapses. Further including a data storage unit for storing data associated with the position information and the travel time,
When the movement time associated with the position information received by the power transmission side communication unit in the data elapses after the power transmission side communication unit receives the position information, the power control unit supplies the high frequency power supply. The power transmission according to claim 1, which outputs the first power transmission power. The data stored in the data storage unit is data in which the position information and the travel time are associated with the user information representing the user of the power receiver.
The power control unit associates the power transmission side communication unit with the position information and the user information received by the power transmission side communication unit in the data after receiving the position information and the user information from the power reception side communication unit. The power transmission according to claim 2, wherein the high-frequency power source outputs the first power transmission power when the travel time has elapsed. When the moving time of the power receiver elapses, the power control unit transmits the second power transmission power for testing, which is lower than the first power transmission power, and the power transmission side communication unit communicates with the power reception side. The invention according to any one of claims 1 to 3, wherein the high-frequency power source outputs the first transmitted power when the power receiving state information indicating the power receiving state of the power receiving device received from the unit indicates that power is being received. Power transmission. The power transmission according to claim 4, wherein the power control unit stops power transmission to the high-frequency power source when the power reception status information indicates that power is not being received. A power transmission system comprising a power transmission that transmits power by magnetic field resonance or electric field resonance and a power receiver that receives power from the power transmitter by magnetic field resonance or electric field resonance.
The power receiver
Secondary resonance coil and
It is a mobile power receiver that has a power receiving side communication unit that performs data communication by short-range wireless communication.
The transmitter
A primary resonance coil that transmits electric power by the magnetic field resonance or the electric field resonance,
A high-frequency power supply that outputs high-frequency transmission power to the primary resonance coil, and
When the power receiving side communication unit enters the communication area of the short-range wireless communication, the power receiving side communication unit and the power transmission side communication unit that establishes communication by the short-range wireless communication and performs data communication,
After the power transmission side communication unit establishes the communication and receives the position information corresponding to the position of the power receiver from the power reception side communication unit, the position represented by the position information and the primary resonance coil A power transmission system having a power control unit that outputs the transmitted power to the high-frequency power source when the moving time of the power receiver elapses. A primary resonance coil that transmits power by magnetic field resonance or electric field resonance to a movable receiver having a secondary resonance coil and a power receiving communication unit that performs data communication by short-range wireless communication.
A high-frequency power supply that outputs high-frequency first transmission power to the primary resonance coil, and
When the power receiving side communication unit enters the communication area of the short-range wireless communication, the power transmission side including the power receiving side communication unit and the power transmitting side communication unit that establishes communication by the short-range wireless communication and performs data communication. It is a power transmission method
After the power transmission side communication unit establishes the communication and receives the position information corresponding to the position of the power receiver from the power reception side communication unit, between the position represented by the position information and the primary resonance coil. A power transmission method for a power transmission that causes the high-frequency power source to output the first power transmission power when the moving time of the power receiver elapses. It is a movable power receiver
Transmission having a primary side resonance coil that transmits power by magnetic field resonance or electric field resonance, a high frequency power supply that outputs high frequency transmission power to the primary side resonance coil, and a transmission side communication unit that performs data communication by short-range wireless communication. A secondary resonance coil that transmits power from an electric appliance by the magnetic field resonance or the electric field resonance,
When the power transmission side communication unit enters the communication area of the short-range wireless communication, the power transmission side communication unit and the power reception side communication unit that establishes communication by the short-range wireless communication and performs data communication,
When the power receiving side communication unit establishes the communication and the movement time of the power receiving device between the position of the power receiving device and the primary side resonance coil elapses, the power transmitting side communication unit via the power receiving side communication unit. A power receiver that includes a control unit that transmits a command to output the transmitted power to the high frequency power source.

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