JP2021129409A - Wireless power transfer device and wireless power transfer system - Google Patents

Abstract

To provide a wireless power transfer device capable of allowing a radiation area, into which electromagnetic wave is radiated, to be visually recognized.SOLUTION: A wireless power transfer device comprises a wireless power transfer unit that radiates electromagnetic wave, and an irradiation unit that irradiates visible light. A visualization area into which the irradiation unit irradiates the visible light is an area that indicates at least a part of radiation area into which the electromagnetic wave from the wireless power transfer unit is radiated.SELECTED DRAWING: Figure 1

Description

The present disclosure relates to wireless power transmission devices and wireless power transmission systems.

Research and development of technology for wireless power transmission, which is wireless power transmission, using electromagnetic waves is being carried out.

In this regard, in a power transmission system having a power transmission system that radiates power as electromagnetic waves and a power reception system that receives electromagnetic waves radiated from the power transmission system, the power reception system transmits a direction detection signal having the same frequency as the electromagnetic waves from the power transmission system. It has a signal transmitter that transmits to the power transmission system, and the power transmission system controls the signal receiver that receives the direction detection signal from the power receiving system and the transmission and stop of electromagnetic waves alternately, and during the stop period. A power transmission system having a control unit that detects the direction of a power receiving system based on a direction detection signal received by a signal receiving unit and controls the direction of emitted electromagnetic waves in the direction of the detected power receiving system is known. (See Patent Document 1).

Japanese Unexamined Patent Publication No. 2019-170036

However, in the conventional power transmission system as described in Patent Document 1, a living body such as a human being may unintentionally enter the region where electromagnetic waves are radiated from the power transmission system. This is because the area where electromagnetic waves are emitted from the power transmission system cannot be visually recognized (that is, cannot be seen).

The present disclosure has been made in consideration of such circumstances, and an object of the present invention is to provide a wireless power transmission device and a wireless power transmission system capable of visually recognizing a radiation region in which electromagnetic waves are radiated. ..

One aspect of the present disclosure includes a radio transmission unit that radiates electromagnetic waves and an irradiation unit that irradiates visible light, and an electromagnetic wave is radiated from the radio transmission unit in a visualization region in which the irradiation unit irradiates visible light. It is a wireless power transmission device which is an area showing at least a part of the radiation area.

According to the present disclosure, it is possible to visually recognize the radiation region in which electromagnetic waves are emitted.

It is a figure which shows an example of the structure of the wireless power transmission system 1 which concerns on embodiment. It is a figure which shows an example of the wireless power transmission device 10 after the posture of the wireless power transmission unit 11 shown in FIG. 1 is changed by the posture change mechanism 14. It is a figure which shows an example of the flow of the process which a wireless power transmission device 10 starts the radiation of an electromagnetic wave. It is a figure which shows an example of the flow of the process which changes the radiation direction by a wireless power transmission apparatus 10. It is a figure which shows an example of the state of the radiation region and the visualization region after the wireless power transmission apparatus 10 accepts the operation which weakens the intensity of the radiated electromagnetic wave. It is a figure which shows an example of the flow of the process which changes the size of a visualization area by a wireless power transmission device 10 according to the size of a radiation area. It is a figure which shows an example of the wireless power transmission apparatus 10 which includes a biological detection part 15. It is a figure which shows an example of the flow of the process performed by the wireless power transmission apparatus 10 based on the information output from the biological detection unit 15. It is a figure which shows another example of the flow of the process performed by the wireless power transmission apparatus 10 based on the information output from the biological detection unit 15. It is a figure which shows an example of the wireless power transmission device 10 which includes the power receiving device detection part 16. It is a figure which shows an example of the flow of the process performed by the wireless power transmission device 10 based on the information output from the power receiving device detection unit 16. It is a figure which shows an example of the wireless power transmission apparatus 10 which includes the charge state detection part 17. It is a figure which shows an example of the flow of the process performed by the wireless power transmission apparatus 10 based on the information output from the charge state detection unit 17. It is a figure which shows an example of the structure of the wireless power receiving device 20. It is a figure which shows an example of the configuration of the wireless power transmission system 1 including the wireless power receiving device 20 of the configuration shown in FIG. It is a figure which shows an example of the flow of the process which the wireless power receiving device 20 starts receiving electric power through an electromagnetic wave. It is a figure which shows an example of the structure of the wireless power receiving device 20 which includes a switching part 27. It is a figure which shows an example of the structure of the wireless power receiving device 20 when the operation state detection circuit part 28 is provided together with a switching part 27. It is a figure which shows an example of the flow of the process performed by the wireless power transmission apparatus 10 based on the information output from the operation state detection circuit unit 28. It is a figure which shows an example of the structure of the wireless power receiving device 20 including each of the battery remaining amount detection unit 29A, the first notification unit 29B, and the second notification unit 29C. It is a figure which shows an example of the flow of the process performed by the wireless power receiving device 20 based on the information output from the battery remaining amount detection unit 29A. It is a figure which shows another example of the flow of the process performed by the wireless power receiving device 20 based on the information output from the battery remaining amount detection unit 29A. It is a figure which shows still another example of the flow of the process performed by the wireless power receiving apparatus 20 based on the information output from the battery remaining amount detection unit 29A. It is a figure which shows an example of the flow of the process performed by the wireless power receiving apparatus 20 based on the intensity of the light received by the light receiving part 25.

<Embodiment>
Hereinafter, embodiments of the present disclosure will be described with reference to the drawings. Here, in the present embodiment, for convenience of explanation, wireless power transmission using electromagnetic waves will be referred to as wireless power transmission.

<Overview of wireless power transmission system>
First, an outline of the wireless power transmission system 1 according to the embodiment will be described. FIG. 1 is a diagram showing an example of the configuration of the wireless power transmission system 1 according to the embodiment.

The wireless power transmission system 1 includes a wireless power transmission device 10 and a wireless power receiving device 20. Then, the wireless power receiving device 20 is connected to the load 30 to which the wireless power receiving device 20 supplies electric power. In the wireless power transmission system 1, the wireless power receiving device 20 and the load 30 may be integrally configured or may be configured separately. Hereinafter, as an example, a case where the wireless power receiving device 20 and the load 30 are integrally configured will be described. In this case, the wireless power receiving device 20 is connected to the load 30 inside or outside the housing of the wireless power receiving device 20. Further, the wireless power transmission system 1 may be configured to include a load 30 together with the wireless power transmission device 10 and the wireless power receiving device 20.

In the wireless power transmission system 1, electric power is transmitted from the wireless power transmission device 10 to the wireless power receiving device 20 by wireless power transmission. More specifically, in the wireless power transmission system 1, the wireless power transmission device 10 converts the electric power transmitted to the wireless power reception device 20 into electromagnetic waves. The wireless power transmission device 10 radiates the converted electromagnetic wave to the wireless power receiving device 20. The wireless power receiving device 20 converts the electromagnetic wave radiated from the wireless power transmitting device 10 into electric power. In this way, in the wireless power transmission system 1, electric power is transmitted from the wireless power transmission device 10 to the wireless power receiving device 20 by wireless power transmission.

Further, in the wireless power transmission system 1, the wireless power receiving device 20 supplies the power transmitted from the wireless power transmitting device 10 to the connected load 30. More specifically, the wireless power receiving device 20 converts the voltage of the electric power into a DC voltage, and supplies the converted DC voltage to the load 30.

Therefore, the wireless power transmission system 1 of the present embodiment uses wireless power transmission to the load 30 connected to the wireless power receiving device 20 without connecting the wireless power transmitting device 10 and the wireless power receiving device 20 by a cable. It can supply power.

Here, in the wireless power transmission system 1, the wireless power transmission device 10 radiates electromagnetic waves. Further, in the wireless power transmission system 1, the wireless power transmission device 10 irradiates visible light. The visualization region in which the wireless power transmission device 10 irradiates visible light is a region indicating at least a part of the radiation region in which electromagnetic waves are radiated from the wireless power transmission device 10. For example, the visualization region is a region in which the electromagnetic wave radiated from the wireless power transmission device 10 indicates a region in which the intensity of the electromagnetic wave radiated from the wireless power transmission device 10 is equal to or higher than a predetermined first threshold value. In this case, the visualization region may be a region including a region in which the electromagnetic wave radiated from the wireless power transmission device 10 has an intensity of the electromagnetic wave radiated from the wireless power transmission device 10 equal to or higher than a predetermined first threshold value. The region in which the electromagnetic wave is radiated from the wireless power transmission device 10 may not include a region in which the intensity of the electromagnetic wave radiated from the wireless power transmission device 10 is equal to or higher than a predetermined first threshold value. The first threshold is, for example, 30 [V / m]. The first threshold value may be a value smaller than 30 [V / m] or a value larger than 30 [V / m]. Further, for example, the visualization region may be a region in which the electromagnetic wave is radiated from the wireless power transmission device 10 and which indicates the position where the intensity of the electromagnetic wave is maximum. In this case, the visualization region may be a region including the position where the intensity of the electromagnetic wave is maximum in the region where the electromagnetic wave is radiated from the wireless power transmission device 10, and is a region where the electromagnetic wave is radiated from the wireless power transmission device 10. Of these, it may be a region that does not include the position where the intensity of the electromagnetic wave is maximum. Since the wireless power transmission device 10 irradiates such a visualization region with visible light, the wireless power transmission system 1 can visually recognize the radiation region in which the electromagnetic wave is radiated. Thereby, for example, the wireless power transmission system 1 can prevent a living body such as a human being from unintentionally entering at least a part of the radiation region indicated by the visualization region. Further, thereby, the wireless power transmission system 1 suppresses, for example, preventing at least a part of the wireless power receiving device 20 which should be arranged in the radiating region from being arranged so as to protrude outside the radiating region. Can be done. As a result, the wireless power transmission system 1 can prevent the transmission efficiency of wireless power transmission from being lowered.

Hereinafter, the configurations of the wireless power transmission device 10 and the wireless power receiving device 20 included in such a wireless power transmission system 1 will be described in detail.

<Configuration of wireless power transmission device>
Hereinafter, the configuration of the wireless power transmission device 10 will be described with reference to FIG.

The wireless power transmission device 10 includes a wireless power transmission unit 11, an irradiation unit 12, a radiation direction control unit 13, and an attitude change mechanism 14. The wireless power transmission device 10 may not be provided with the posture changing mechanism 14.

The wireless power transmission unit 11 emits electromagnetic waves. Therefore, the wireless power transmission unit 11 has an antenna that radiates electromagnetic waves. In the example shown in FIG. 1, the wireless power transmission unit 11 has an array antenna composed of four antennas A. The antenna included in the wireless power transmission unit 11 may be another type of antenna such as a parabolic antenna instead of the array antenna. For example, the electromagnetic wave radiated by the wireless power transmission unit 11 is a microwave, a millimeter wave, or the like.

The irradiation unit 12 irradiates the visualization region showing at least a part of the radiation region with visible light. In the following, as an example, a case where the visualization region is a region in which the electromagnetic wave radiated from the wireless power transmission unit 11 is equal to or higher than a predetermined first threshold value will be described. do. Further, in the following, as an example, a case where the visualization region coincides with the region except for deviation due to vibration, error, etc. will be described. Hereinafter, for convenience of explanation, the region will be referred to as a first region. Here, the intensity of the electromagnetic wave described in this paragraph is, for example, the intensity of the electromagnetic wave radiated from the wireless power transmission unit 11 per unit area on the surface radiated from the wireless power transmission unit 11.

The region RA1 surrounded by the dotted line shown in FIG. 1 shows an example of a visualization region. Further, the region RA2 surrounded by the dotted line shown in FIG. 1 shows an example of the first region. That is, as shown in FIG. 1, in this example, the region RA1 which is the visualization region and the region RA2 which is the first region coincide with each other.

Further, in the example shown in FIG. 1, the irradiation unit 12 is attached to the wireless power transmission unit 11. The method of attaching the wireless power transmission unit 11 and the irradiation unit 12 to the respective wireless power transmission devices 10 may be any method as long as the irradiation unit 12 can irradiate the visualization region with visible light. ..

Here, the direction in which the wireless power transmission unit 11 emits electromagnetic waves, that is, the radiation direction is controlled by the radiation direction control unit 13 described later. Then, the position of the first region changes according to the radial direction. Therefore, the irradiation unit 12 changes the position of the visualization region according to the radiation direction (that is, the position of the first region). As a result, the wireless power transmission device 10 can visually recognize at least a part of the radiation region indicated by the visualization region even when the radiation direction is changed in the direction desired by the user. Therefore, for example, the wireless power transmission device 10 can prevent the user of the wireless power transmission device 10 from accidentally matching the radiation direction in an unintended direction. In the following, as an example, a case where the position of the first region is represented by the position of the center of gravity of the radiation region will be described. Further, in the following, as an example, a case where the position of the visualization region is represented by the position of the center of gravity of the visualization region will be described. However, the position of the first region may be represented by another position according to the first region instead of the position of the center of gravity of the first region. Further, the position of the visualization region may be represented by another position according to the visualization region instead of the position of the center of gravity of the visualization region.

The radiation direction control unit 13 controls the radiation direction.

For example, in the radiation direction control unit 13, when the wireless power transmission unit 11 has an array antenna as shown in FIG. 1, the phase of electromagnetic waves radiated from each of the individual antennas A included in the array antenna included in the wireless power transmission unit 11 To change the direction of radiation. In other words, in this case, the radiation direction control unit 13 adjusts the phase of the electromagnetic waves radiated from each of the individual antennas A included in the array antenna included in the wireless power transmission unit 11 to change the position of the first region. .. Further, in this case, the irradiation unit 12 has a mechanism for changing the direction of the optical axis of the irradiation unit 12. Then, the irradiation unit 12 adjusts the phase of the electromagnetic waves radiated from each of the individual antennas A included in the array antenna included in the wireless power transmission unit 11, and changes the position of the first region and the visualization region. Calculate the direction of the optical axis when they match. Then, the irradiation unit 12 controls the mechanism and makes the direction of the optical axis match the calculated direction.

Further, for example, the radiation direction control unit 13 changes the radiation direction by controlling the posture changing mechanism 14 described later and changing the posture of the wireless power transmission unit 11. In other words, the radiation direction control unit 13 changes the position of the first region by changing the posture of the wireless power transmission unit 11. In this case, the direction of the optical axis of the irradiation unit 12 changes with the position of the first region while maintaining the state in which the first region and the visualization region coincide with each other according to the change in the posture of the wireless power transmission unit 11.

Here, FIG. 2 is a diagram showing an example of the wireless power transmission device 10 after the posture of the wireless power transmission unit 11 shown in FIG. 1 is changed by the posture change mechanism 14. As shown in FIG. 2, in the wireless power transmission device 10, when the posture of the wireless power transmission unit 11 changes, the position of the region RA2, which is the first region, changes, and the direction of the optical axis of the irradiation unit 12 also changes. The position of the region RA1 which is the visualization region also changes. As a result, in FIG. 2, even in this case, the state in which the region RA1 and the region RA2 are in agreement is maintained. As a result, the wireless power transmission device 10 can visually recognize at least a part of the radiation region indicated by the visualization region even when the radiation direction is changed in the direction desired by the user. Therefore, for example, the wireless power transmission device 10 can prevent the user of the wireless power transmission device 10 from accidentally matching the radiation direction in an unintended direction.

The radiation direction control unit 13 adjusts the phase of the electromagnetic waves radiated from each of the individual antennas A included in the array antenna included in the wireless power transmission unit 11, and the posture change mechanism 14 adjusts the posture of the wireless power transmission unit 11. The direction of radiation may be changed based on both the change of and the change of. In this case as well, the irradiation unit 12 adjusts the phase of the electromagnetic waves radiated from each of the individual antennas A included in the array antenna included in the wireless power transmission unit 11 to visualize the first region after the position is changed. The direction of the optical axis when the area matches is calculated. Then, the irradiation unit 12 makes the direction of the optical axis match the calculated direction.

Further, although the radiation direction control unit 13 is drawn separately from the wireless power transmission unit 11 in FIG. 1, it may be integrally configured with the wireless power transmission unit 11.

The posture changing mechanism 14 is a mechanism for changing the posture of the wireless power transmission unit 11. Here, the posture of the wireless power transmission unit 11 is represented by, for example, the orientation of each coordinate axis of the virtual three-dimensional coordinate system associated with the wireless power transmission unit 11 so as to move together with the wireless power transmission unit 11. Instead, the posture of the wireless power transmission unit 11 may be represented by another direction according to the wireless power transmission unit 11. In FIG. 1, the three-dimensional coordinate system is omitted in order to prevent the figure from becoming complicated.

<Processing of wireless power transmission equipment to start emitting electromagnetic waves>
Hereinafter, the process of starting the radiation of the electromagnetic wave by the wireless power transmission device 10 will be described with reference to FIG. FIG. 3 is a diagram showing an example of a processing flow in which the wireless power transmission device 10 starts emitting electromagnetic waves. Hereinafter, as an example, a case where the wireless power transmission device 10 accepts an operation of starting the emission of electromagnetic waves at a timing before the processing of step S110 shown in FIG. 3 is performed will be described.

The irradiation unit 12 starts irradiation with visible light (step S110). The reason why the irradiation unit 12 starts irradiating visible light before the radio transmission unit 11 starts radiating the electromagnetic wave in step S110 is that the visible light is always visualized during the period when the electromagnetic wave is radiated by the radio transmission device 10. This is because it is desirable that the area is irradiated. The process of step S110 and the process of step S120, which will be described later, may be performed in parallel by the wireless power transmission device 10 or in the reverse order.

Next, the wireless power transmission unit 11 starts emitting electromagnetic waves (step S120).

Next, the wireless power transmission unit 11 determines whether or not to terminate the emission of the electromagnetic wave (step S130). For example, in step S130, the wireless power transmission unit 11 determines that the radiation of the electromagnetic wave is terminated when the wireless power transmission device 10 accepts the operation of ending the emission of the electromagnetic wave. On the other hand, in step S130, the wireless power transmission unit 11 determines that the radiation of the electromagnetic wave is not terminated when the wireless power transmission device 10 does not accept the operation of ending the emission of the electromagnetic wave. The wireless power transmission unit 11 may be configured to determine in step S130 whether or not to terminate the emission of electromagnetic waves by another method.

When the wireless power transmission unit 11 determines that the emission of the electromagnetic wave is not terminated (step S130-NO), whether or not to continue the emission of the electromagnetic wave started in step S120 and to transition to step S130 to terminate the emission of the electromagnetic wave. Is determined again.

On the other hand, when the wireless power transmission unit 11 determines that the emission of the electromagnetic wave is terminated (step S130-YES), the wireless power transmission unit 11 terminates the emission of the electromagnetic wave started in step S120 (step S140).

Next, the irradiation unit 12 ends the irradiation of visible light started in step S110 (step S150), and ends the process. The reason why the radio transmission unit 11 ends the emission of the electromagnetic wave before the irradiation unit 12 ends the irradiation of visible light in step S150 is that the visible light is always visualized within the period in which the electromagnetic wave is emitted by the radio transmission device 10. This is because it is desirable that the area is irradiated. The process of step S140 and the process of step S150, which will be described later, may be performed in parallel by the wireless power transmission device 10 or in the reverse order.

As described above, the wireless power transmission device 10 radiates electromagnetic waves and irradiates visible light to a visualization region (in this example, a visualization region indicating the first region) indicating at least a part of the radiation region. As a result, the wireless power transmission device 10 can visually recognize at least a part of the radiation region indicated by the visualization region. The visualization region described above may be a region in which at least a part of the radiation region overlaps with the entire radiation region as long as it can show at least a part of the radiation region. Areas that do not completely overlap may be used. That is, the visualization region may be a region along the contour of the radiation region. Further, the visualization region may be a region having another shape such as an arrow-shaped region indicating at least a part of the radiation region, instead of a region having a shape such as a circular shape, an elliptical shape, or a ring shape.

<Processing by wireless power transmission to change the radiation direction>
Hereinafter, the process of changing the radiation direction by the wireless power transmission device 10 will be described with reference to FIG. FIG. 4 is a diagram showing an example of a processing flow in which the wireless power transmission device 10 changes the radiation direction. In the following, as an example, a case where the wireless power transmission device 10 accepts an operation of changing the radiation direction at a timing before the process of step S210 shown in FIG. 4 is performed will be described. Then, in the following, for convenience of explanation, the operation will be referred to as a posture change operation. Further, in the following, as an example, a case where the wireless power transmission device 10 starts both the emission of the electromagnetic wave and the irradiation of the visible light at the timing will be described.

The radiation direction control unit 13 changes the radiation direction according to the attitude change operation received in advance. That is, the radiation direction control unit 13 changes the position of the radiation region in response to the posture change operation (step S210). Here, even if the radiation direction control unit 13 changes the radiation direction in step S210 by adjusting the phase of the electromagnetic waves radiated from each of the individual antennas A included in the array antenna included in the radio transmission unit 11. Often, the radiation direction may be changed by changing the attitude of the radio transmission unit 11 by the attitude change mechanism 14, or the radiation direction may be changed by a combination of these. In the following, as an example, in step S210, the radiation direction control unit 13 changes the radiation direction by adjusting the phase of the electromagnetic waves radiated from each of the individual antennas A included in the array antenna included in the wireless power transmission unit 11. This case will be described. When the radiation direction control unit 13 changes the attitude of the wireless power transmission unit 11 by the attitude change mechanism 14 in step S210, the direction of the optical axis of the irradiation unit 12 changes as described above. Depending on the situation, the first region and the visualization region change with the position of the radiation region while maintaining the coincident state. Therefore, in this case, the process of step S220 is omitted.

Next, the irradiation unit 12 adjusts the phase of the electromagnetic waves radiated from each of the individual antennas A included in the array antenna included in the wireless power transmission unit 11, and changes the position of the first region and the visualization region. The direction of the optical axis of the irradiation unit 12 is calculated when the above coincides with. Then, the irradiation unit 12 matches the direction of the optical axis with the calculated direction and changes the position of the visualization region (step S220). Then, the irradiation unit 12 ends the process.

As described above, the wireless power transmission device 10 changes the position of the visualization region according to the radiation direction. As a result, the wireless power transmission device 10 can visually recognize at least a part of the radiation region indicated by the visualization region even when the radiation direction is changed in the direction desired by the user. Therefore, for example, the wireless power transmission device 10 can prevent the user of the wireless power transmission device 10 from accidentally matching the radiation direction in an unintended direction.

<Modification example 1 of the configuration of the wireless power transmission device>
Hereinafter, a modification 1 of the configuration of the wireless power transmission device 10 will be described. As shown in FIG. 5, for example, the wireless power transmission device 10 may have a configuration in which the size of the visualization region is changed according to the intensity of the electromagnetic wave radiated from the wireless power transmission unit 11. This is because the size of the first region changes according to the intensity (for example, average intensity, maximum intensity, etc.) of the electromagnetic wave radiated from the wireless power transmission unit 11. Here, the intensity of the electromagnetic wave described in this paragraph is, for example, the intensity of the electromagnetic wave when the electromagnetic wave is radiated from the wireless power transmission unit 11.

FIG. 5 is a diagram showing an example of the state of the radiation region and the visualization region after the wireless power transmission device 10 accepts the operation of weakening the intensity of the radiated electromagnetic wave. The size of the region RA2 shown in FIG. 5 is smaller than the size of the region RA2 shown in FIG. This is because the wireless power transmission unit 11 of the wireless power transmission device 10 that has received the operation weakens the strength. Nevertheless, in FIG. 5, region RA1 coincides with region RA2. This is because the wireless power transmission device 10 changes the size of the visualization region according to the intensity of the radiated electromagnetic wave.

Here, with reference to FIG. 6, a process in which the wireless power transmission device 10 changes the size of the visualization region according to the intensity of the radiated electromagnetic wave will be described. FIG. 6 is a diagram showing an example of a processing flow in which the wireless power transmission device 10 changes the size of the visualization region according to the intensity of the radiated electromagnetic wave. In the following, as an example, a case where the wireless power transmission device 10 accepts an operation of changing the intensity of the radiated electromagnetic wave at a timing before the process of step S310 shown in FIG. 6 is performed will be described. Then, in the following, for convenience of explanation, the operation will be referred to as an intensity change operation. Further, in the following, as an example, a case where the wireless power transmission device 10 starts both the emission of the electromagnetic wave and the irradiation of the visible light at the timing will be described.

The wireless power transmission unit 11 changes the intensity of the radiated electromagnetic wave according to the intensity change operation received in advance (step S310). Hereinafter, as an example, a case where the wireless power transmission unit 11 weakens the intensity of the radiated electromagnetic wave in step S310 will be described.

Next, the irradiation unit 12 acquires information indicating the intensity of the electromagnetic wave after the change by the wireless power transmission unit 11 in step S310 from the wireless power transmission unit 11. Then, based on the acquired information, the irradiation unit 12 shields a part of the irradiation port for irradiating the visible light of the irradiation unit 12 with a shielding member such as a film or a plate-shaped member, thereby increasing the size of the visualization region. (Step S320). In this example, in step S310, the intensity of the electromagnetic wave radiated from the wireless power transmission unit 11 is weakened. Therefore, in this example, the irradiation unit 12 shields a part of the visible light emitted from the irradiation unit 12 in step S320 to reduce the size of the visualization region. As a result, the irradiation unit 12 makes the visualization region coincide with the first region. Here, the irradiation unit 12 changes the relative position of the shielding member with respect to the irradiation port based on, for example, the correspondence information stored in advance in the wireless power transmission device 10 and the information acquired from the wireless power transmission unit 11. Let me. The correspondence information is information in which the intensity of the electromagnetic wave radiated from the wireless power transmission unit 11 and the position are associated with each other. By using this correspondence information, the irradiation unit 12 specifies the position when the size of the first region and the size of the visualization region match according to the intensity of the electromagnetic wave radiated from the wireless power transmission unit 11. Can be done. Correspondence information can be generated, for example, by experiments, theoretical calculations, etc. performed in advance. After the process of step S320 is performed, the irradiation unit 12 ends the process.

The irradiation unit 12 described above increases the size of the visualization region in step S320 when the wireless power transmission unit 11 increases the intensity of the electromagnetic wave in step S310.

As described above, the wireless power transmission device 10 changes the size of the visualization region according to the intensity of the radiated electromagnetic wave. As a result, the wireless power transmission device 10 can show at least a part of the radiated region by the visualization region without excess or deficiency even when the intensity of the radiated electromagnetic wave is changed according to the operation received from the user.

<Modification 2 of the configuration of the wireless power transmission device>
Hereinafter, a modification 2 of the configuration of the wireless power transmission device 10 will be described. For example, as shown in FIG. 7, the wireless power transmission device 10 may further include a biological detection unit 15. FIG. 7 is a diagram showing an example of a wireless power transmission device 10 including a biological detection unit 15.

The biological detection unit 15 is a detection device that detects whether or not a living body exists in a target region including at least a part of the visualization region. For example, the biological detection unit 15 is a detection device including a camera and a detection device including an infrared sensor. When the biological detection unit 15 is a detection device provided with a camera, the biological detection unit 15 determines whether or not a living body exists in the target region based on the captured moving image or the captured image captured by the camera. More specifically, in this case, the living body detection unit 15 determines whether or not the living body exists in the target region by the captured moving image or the pattern matching based on the captured image and the machine learning algorithm. Further, when the biological detection unit 15 is a detection device provided with an infrared sensor, the biological detection unit 15 determines whether or not a living body exists in the target region based on the intensity of infrared rays detected by the infrared sensor and the like. judge. The biological detection unit 15 may be any detection device as long as it can detect whether or not a living body exists in the target region including at least a part of the visualization region.

Hereinafter, as an example, a case where the biological detection unit 15 is a detection device provided with a camera will be described. In this case, the biological detection unit 15 is provided at a position where the target region including at least a part of the visualization region can be imaged. Here, the biological detection unit 15 may be provided at a position where the imageable range changes according to the posture of the wireless power transmission unit 11, and the imageable range does not change according to the posture of the wireless power transmission unit 11. It may be provided in. In the example shown in FIG. 7, the biological detection unit 15 is provided in the wireless power transmission unit 11. That is, in this example, the biological detection unit 15 is provided at a position where the imageable range changes according to the posture of the wireless power transmission unit 11. In this case, the biological detection unit 15 is provided at a position where an image can be taken with a region including at least a part of the visualization region as a target region even when the posture of the wireless power transmission unit 11 changes. On the other hand, when the biological detection unit 15 is provided at a position where the imageable range does not change according to the posture of the wireless power transmission unit 11, the biological detection unit 15 may overlap the visualization areas by changing the position of the visualization area. All possible areas are provided at positions where imaging is possible.

Here, the region RA3 surrounded by the dotted line shown in FIG. 7 is an example of the target region. In the example shown in FIG. 7, the region RA3 is a region including both the region RA1 and the region RA2 inside. Further, the person H shown in FIG. 7 shows an example of a living body that has invaded the region RA3, which is the target region. In addition, such a living body may be a person other than a person such as a dog or a cat. Then, in the example shown in FIG. 7, the person H has invaded the region RA3, which is the target region. In other words, in this example, person H is present in region RA3. However, in this example, the person H is present in the region RA3 but not in the regions RA1 and RA2. In such a case, the person H may invade the region RA1 and the region RA2. Therefore, the wireless power transmission device 10 processes the flowchart shown in FIG. As a result, the wireless power transmission device 10 can suppress the possibility that the living body that has inadvertently entered the target area is unnecessarily exposed to electromagnetic waves.

FIG. 8 is a diagram showing an example of the flow of processing performed by the wireless power transmission device 10 based on the information output from the biological detection unit 15. Hereinafter, as an example, a case where the wireless power transmission device 10 accepts an operation of starting the emission of electromagnetic waves at a timing before the processing of step S410 shown in FIG. 8 is performed will be described. That is, in the following, as an example, a case where electromagnetic waves are not radiated from the wireless power transmission device 10 at the timing will be described.

When the wireless power transmission device 10 accepts the operation of starting the emission of electromagnetic waves, the wireless power transmission unit 11 causes the biological detection unit 15 to detect whether or not a living body exists in the target area. The biological detection unit 15 outputs information indicating the detection result to the wireless power transmission unit 11. The wireless power transmission unit 11 acquires the information from the biological detection unit 15, and based on the acquired information, determines whether or not the biological detection unit 15 has detected a living body in the target region (step S410).

When the wireless power transmission unit 11 determines that the living body is detected in the target area by the living body detection unit 15 (step S410-YES), the wireless power transmission unit 11 transitions to step S410 without starting the emission of electromagnetic waves, and the living body is placed in the target area. The biological detection unit 15 is made to detect again whether or not it exists. As described above, the wireless power transmission device 10 does not start radiating the electromagnetic wave when the living body is not radiated and the living body is detected in the target region by the living body detecting unit 15. As a result, the wireless power transmission device 10 can suppress the possibility that the living body that has inadvertently entered the target area is unnecessarily exposed to electromagnetic waves.

On the other hand, when the wireless power transmission unit 11 determines that no living body is detected in the target region by the living body detection unit 15 (step S410-NO), the wireless power transmission unit 11 starts irradiation with visible light (step S420). The reason why the irradiation unit 12 starts irradiating visible light before the radio transmission unit 11 starts radiating the electromagnetic wave in step S420 is that the visible light is always visualized during the period when the electromagnetic wave is radiated by the radio transmission device 10. This is because it is desirable that the area is irradiated. The process of step S420 and the process of step S430 described later may be performed in parallel by the wireless power transmission device 10 or in the reverse order.

Next, the wireless power transmission unit 11 starts emitting electromagnetic waves (step S430).

Next, the wireless power transmission unit 11 causes the biological detection unit 15 to detect whether or not a living body exists in the target region. The biological detection unit 15 outputs information indicating the detection result to the wireless power transmission unit 11. The wireless power transmission unit 11 acquires the information from the biological detection unit 15, and based on the acquired information, determines whether or not the biological detection unit 15 has detected a living body in the target region (step S440).

When the wireless power transmission unit 11 determines that the living body is detected in the target area by the living body detection unit 15 (step S440-YES), the wireless power transmission unit 11 reduces the intensity of the radiated electromagnetic wave (step S480). That is, when the wireless power transmission unit 11 emits an electromagnetic wave and the biological detection unit 15 detects a living body in the target region, the wireless power transmission unit 11 reduces the intensity of the radiated electromagnetic wave. Here, in step S480, the wireless transmission unit 11 may have a configuration in which the intensity of the radiated electromagnetic wave is reduced to a predetermined intensity, and the intensity of the radiated electromagnetic wave is reduced to zero (that is, the emission of the electromagnetic wave is reduced to zero). It may be a configuration to stop). As a result, the wireless power transmission device 10 can more reliably suppress the possibility that the living body that has inadvertently entered the target area is unnecessarily exposed to electromagnetic waves.

After the processing of step S480 is performed, the wireless power transmission unit 11 determines whether or not to end the emission of the electromagnetic wave (step S450). Since the process of step S450 is the same process as the process of step S130 shown in FIG. 3, the description thereof will be omitted.

When the wireless power transmission unit 11 determines that the emission of the electromagnetic wave is not terminated (step S450-NO), the process proceeds to step S440, and the biological detection unit 15 is made to detect again whether or not a living body exists in the target region.
On the other hand, when the wireless power transmission unit 11 determines that the emission of the electromagnetic wave is terminated (step S450-YES), the wireless power transmission unit 11 terminates the emission of the electromagnetic wave started in step S430 (step S460).

Next, the irradiation unit 12 ends the irradiation of visible light started in step S420 (step S470), and ends the process. The reason why the wireless transmission unit 11 terminates the emission of the electromagnetic wave before the irradiation unit 12 ends the irradiation of visible light in step S470 is that the visible light is always visualized within the period in which the electromagnetic wave is emitted by the wireless transmission device 10. This is because it is desirable that the area is irradiated. The process of step S460 and the process of step S470 described later may be performed in parallel by the wireless power transmission device 10 or in the reverse order.

On the other hand, when the wireless power transmission unit 11 determines that the living body has not been detected (step S440-NO), the wireless power transmission unit 11 transitions to step S450 while continuing the radiation of the electromagnetic wave started in step S430.

As described above, the wireless power transmission device 10 reduces the intensity of the radiated electromagnetic wave when the biological detection unit 15 detects a living body in the target region when the electromagnetic wave is radiated. As a result, the wireless power transmission device 10 can suppress the possibility that the living body that has inadvertently entered the target area is unnecessarily exposed to electromagnetic waves.

Further, the wireless power transmission device 10 stops radiating the electromagnetic wave when the living body is detected in the target area by the living body detecting unit 15 when the living body is radiating the electromagnetic wave. As a result, the wireless power transmission device 10 can more reliably suppress the possibility that the living body that has inadvertently entered the target area is unnecessarily exposed to electromagnetic waves.

Further, the wireless power transmission device 10 does not start radiating the electromagnetic wave when the living body is not radiated and the living body is detected in the target area by the living body detection unit 15. As a result, the wireless power transmission device 10 can suppress the possibility that the living body that has inadvertently entered the target area is unnecessarily exposed to electromagnetic waves.

The wireless power transmission device 10 may have a configuration in which the flowchart shown in FIG. 9 is processed instead of the configuration in which the flowchart shown in FIG. 8 is processed.

FIG. 9 is a diagram showing another example of the flow of processing performed by the wireless power transmission device 10 based on the information output from the biological detection unit 15. Since the process of step S410 shown in FIG. 9 is the same process as the process of step S410 shown in FIG. 8, the description thereof will be omitted. Further, since the processes of steps S420 to S480 shown in FIG. 9 are the same as the processes of steps S420 to S480 shown in FIG. 8, the description thereof will be omitted. Further, as an example, a case where the wireless power transmission device 10 accepts an operation of starting the emission of electromagnetic waves at a timing before the processing of step S410 shown in FIG. 9 is performed will be described below. That is, in the following, as an example, a case where electromagnetic waves are not radiated from the wireless power transmission device 10 at the timing will be described.

When the wireless power transmission unit 11 determines in step S410 that no living body is detected in the target area by the biological detection unit 15, the wireless power transmission unit 11 continuously determines that no living body is detected in the target area by the biological detection unit 15 in step S410. It is determined whether or not the time elapsed while the determination is continued is equal to or longer than the predetermined first time (step S510). In FIG. 9, the process of step S510 is shown as "first time elapsed?". Here, the predetermined first time is, for example, 3 seconds. The predetermined first time may be a time shorter than 3 seconds or a time longer than 3 seconds.

The wireless power transmission unit 11 has determined that the time elapsed while continuously determining that no living body is detected in the target area by the living body detection unit 15 in step S410 is less than the predetermined first time. In the case (step S510-NO), the process proceeds to step S410.

On the other hand, the wireless power transmission unit 11 determines that the time elapsed while continuously determining that no living body is detected in the target region by the living body detection unit 15 in step S410 is a predetermined first time or more. If it is determined (step S510-YES), the process proceeds to step S420. That is, when the wireless power transmission unit 11 does not radiate electromagnetic waves and the living body is not detected in the target area by the biological detection unit 15 for a predetermined first time or more, the wireless power transmission unit 11 starts irradiating visible light and radiating electromagnetic waves. do. As a result, the wireless power transmission device 10 can start emitting electromagnetic waves when it is unlikely that a living body that may invade the target area is near the target area.

<Modification 3 of the configuration of the wireless power transmission device>
Hereinafter, a modification 3 of the configuration of the wireless power transmission device 10 will be described. For example, as shown in FIG. 10, the wireless power transmission device 10 may further include a power receiving device detection unit 16. FIG. 10 is a diagram showing an example of a wireless power transmission device 10 including a power receiving device detection unit 16.

The power receiving device detection unit 16 is a detection device that detects whether or not the wireless power receiving device 20 that receives electromagnetic waves exists in the radiation region. For example, the power receiving device detection unit 16 is a detection device including a camera. When the power receiving device detection unit 16 is a detection device including a camera, the power receiving device detection unit 16 determines whether or not the wireless power receiving device 20 exists in the radiation region based on the captured moving image or the captured image captured by the camera. Is determined. More specifically, in this case, the power receiving device detection unit 16 determines whether or not the wireless power receiving device 20 exists in the visualization region by the algorithm of pattern matching and machine learning based on the captured moving image or the captured image. .. The power receiving device detection unit 16 may be any detection device as long as it can detect whether or not the wireless power receiving device 20 that receives electromagnetic waves exists in the radiation region. Further, the power receiving device detection unit 16 is configured to determine whether or not the wireless power receiving device 20 exists in a part of the radiation region based on the captured moving image or the captured image captured by the camera. You may.

Hereinafter, as an example, a case where the power receiving device detection unit 16 is a detection device including a camera will be described. In this case, the power receiving device detection unit 16 is provided at a position where the radiation region can be imaged. Here, the power receiving device detection unit 16 may be provided at a position where the imageable range changes according to the posture of the wireless power transmission unit 11, and the imageable range does not change according to the posture of the wireless power transmission unit 11. It may be provided at a position. In the example shown in FIG. 10, the power receiving device detection unit 16 is provided in the wireless power transmission unit 11. That is, in this example, the power receiving device detection unit 16 is provided at a position where the imageable range changes according to the posture of the wireless power transmission unit 11. In this case, the power receiving device detection unit 16 is provided at a position where the radiation region can be imaged even when the posture of the wireless power transmission unit 11 changes. On the other hand, when the power receiving device detection unit 16 is provided at a position where the imageable range does not change according to the posture of the wireless power transmission unit 11, the power receiving device detection unit 16 may overlap the radiation regions by changing the radiation direction. All possible areas are provided at positions where imaging is possible.

Here, the wireless power transmission device 10 including the power receiving device detection unit 16 processes the flowchart shown in FIG. As a result, the wireless power transmission device 10 can suppress the emission of electromagnetic waves when at least a part of the wireless power receiving device 20 is out of the radiation region. As a result, the wireless power transmission device 10 can prevent the transmission efficiency of wireless power transmission from being lowered in that case.

FIG. 11 is a diagram showing an example of the flow of processing performed by the wireless power transmission device 10 based on the information output from the power receiving device detection unit 16. Since the processes of steps S420 to S430 shown in FIG. 11 are the same as the processes of steps S420 to S430 shown in FIG. 8, the description thereof will be omitted. Further, since the processes of steps S450 to S470 shown in FIG. 11 are the same as the processes of steps S450 to S470 shown in FIG. 8, the description thereof will be omitted. Further, in the following, as an example, a case where the wireless power transmission device 10 accepts an operation of starting the emission of electromagnetic waves at a timing before the processing of step S410 shown in FIG. 11 is performed will be described. That is, in the following, as an example, a case where electromagnetic waves are not radiated from the wireless power transmission device 10 at the timing will be described.

When the wireless power transmission device 10 accepts the operation of starting the emission of electromagnetic waves, the wireless power transmission unit 11 causes the power reception device detection unit 16 to detect whether or not the wireless power reception device 20 exists in the radiation region. The power receiving device detection unit 16 outputs information indicating the detection result to the wireless power transmission unit 11. The wireless power transmission unit 11 acquires the information from the power receiving device detection unit 16, and determines whether or not the wireless power receiving device 20 is detected in the radiation region by the power receiving device detection unit 16 based on the acquired information ( Step S610).

When the wireless power transmitting unit 11 determines that the wireless power receiving device 20 is not detected in the radiation region by the power receiving device detecting unit 16 (step S610-NO), the wireless power transmitting unit 11 transitions to step S610 without starting the emission of electromagnetic waves. The power receiving device detection unit 16 is made to detect again whether or not the wireless power receiving device 20 exists in the radiation region. As described above, the wireless power transmission device 10 does not start radiating the electromagnetic wave when the wireless power transmission device 10 does not radiate the electromagnetic wave and the wireless power receiving device 20 is not detected in the radiation region by the power receiving device detecting unit 16. As a result, the wireless power transmission device 10 can suppress the emission of electromagnetic waves when at least a part of the wireless power receiving device 20 is out of the radiation region. As a result, the wireless power transmission device 10 can suppress an unnecessary increase in power consumption.

On the other hand, when the wireless power transmission unit 11 determines that the wireless power receiving device 20 has been detected (step S610-YES), the wireless power transmission unit 11 transitions to step S420. As described above, when the wireless power receiving device 20 is detected in the radiation region by the power receiving device detecting unit 16 when the wireless power transmitting device 10 does not radiate the electromagnetic wave, the wireless power transmitting device 10 starts irradiating visible light and radiating the electromagnetic wave. .. As a result, the wireless power transmission device 10 can suppress the emission of electromagnetic waves when at least a part of the wireless power receiving device 20 is out of the radiation region. As a result, the wireless power transmission device 10 can prevent the transmission efficiency of wireless power transmission from being lowered in that case.

Further, after the processing of step S430 is performed, the wireless power transmission unit 11 causes the power receiving device detection unit 16 to detect whether or not the wireless power receiving device 20 exists in the radiation region. The power receiving device detection unit 16 outputs information indicating the detection result to the wireless power transmission unit 11. The wireless power transmission unit 11 acquires the information from the power receiving device detection unit 16, and determines whether or not the wireless power receiving device 20 is detected in the radiation region by the power receiving device detection unit 16 based on the acquired information ( Step S620).

When the wireless power transmission unit 11 determines that the wireless power receiving device 20 is not detected in the radiation area by the power receiving device detection unit 16 (step S620-NO), the power receiving device detection unit 16 wirelessly enters the radiation area in step S620. It is determined whether or not the time elapsed while the power receiving device 20 is continuously determined not to be detected is the predetermined second time or more (step S630). In FIG. 11, the process of step S620 is shown as "second time elapsed?". Here, the predetermined second time is, for example, 3 seconds. The predetermined second time may be a time shorter than 3 seconds or a time longer than 3 seconds.

In step S620, the wireless power transmission unit 11 has elapsed less than a predetermined second time while the power receiving device detection unit 16 continuously determines that the wireless power receiving device 20 has not been detected in the radiation region. If it is determined that there is (step S620-NO), the process proceeds to step S450.

On the other hand, the wireless power transmission unit 11 has a predetermined second time while the power receiving device detection unit 16 continuously determines that the wireless power receiving device 20 is not detected in the radiation region in step S630. If it is determined that the above is the case (step S630-YES), it is highly possible that the wireless power receiving device 20 has been removed from the radiation region, so the process proceeds to step S460. That is, when the wireless power transmission unit 11 is radiating electromagnetic waves and the power receiving device detection unit 16 does not detect the wireless power receiving device 20 in the radiation region for a predetermined second time or longer, the wireless power transmission unit 11 stops the radiation of electromagnetic waves. .. As a result, the wireless power transmission device 10 can suppress the continuation of radiation of electromagnetic waves even though the wireless power receiving device 20 is removed from the radiation region. As a result, the wireless power transmission device 10 can suppress an increase in power consumption.

<Modification example 4 of the configuration of the wireless power transmission device>
Hereinafter, a modification 4 of the configuration of the wireless power transmission device 10 will be described. For example, as shown in FIG. 12, the wireless power transmission device 10 may further include a charge state detection unit 17. FIG. 12 is a diagram showing an example of a wireless power transmission device 10 including a charge state detection unit 17. Here, as an example, a case where the load 30 is a battery (storage battery) will be described below.

The charge state detection unit 17 is a detection device that detects the full charge of the load 30 to which power is supplied from the wireless power receiving device 20 that receives electromagnetic waves in the radiation region. For example, the charge state detection unit 17 is a detection device provided with a camera. When the charge state detection unit 17 is a detection device provided with a camera, the charge state detection unit 17 determines whether or not a load 30 exists in the radiation region based on the captured moving image or the captured image captured by the camera. judge. In this example, since the load 30 is integrally configured with the wireless power receiving device 20, the charge state detecting unit 17 is the load of the wireless power receiving device 20 existing in the radiation region based on the captured moving image or the captured image. It is determined whether or not 30 is fully charged. Therefore, in the example shown in FIG. 12, the wireless power receiving device 20 integrally configured with the load 30 includes a display unit 21. The display unit 21 may be an LED (Light Emitting Diode) or a display capable of displaying a marker or the like. When the load 30 of the wireless power receiving device 20 is fully charged, the display unit 21 displays information (for example, light, a marker, etc.) indicating that the load 30 is fully charged. That is, when the information is detected based on the captured moving image or the captured image, the charging state detecting unit 17 detects that the load 30 is fully charged. On the other hand, the charge state detection unit 17 detects that the load 30 is not fully charged when the information is not detected based on the captured moving image or the captured image. The charge state detection unit 17 makes such a determination by an algorithm of pattern matching and machine learning based on the captured moving image or the captured image. The charge state detection unit 17 may be any detection device as long as it can detect the full charge of the load 30 to which power is supplied from the wireless power receiving device 20 that receives electromagnetic waves in the radiation region. good. Further, the charge state detection unit 17 may determine whether or not the load 30 exists in a part of the radiation region based on the captured moving image or the captured image captured by the camera. good.

Here, the wireless power transmission device 10 including the charge state detection unit 17 processes the flowchart shown in FIG. As a result, the wireless power transmission device 10 can suppress the continuous radiation of electromagnetic waves even though the load 30 is fully charged. As a result, the wireless power transmission device 10 can suppress an increase in power consumption.

FIG. 13 is a diagram showing an example of the flow of processing performed by the wireless power transmission device 10 based on the information output from the charge state detection unit 17. Since the processing of steps S110 to S120 shown in FIG. 13 is the same as the processing of steps S110 to S120 shown in FIG. 3, the description thereof will be omitted. Further, since the processes of steps S130 to S150 shown in FIG. 13 are the same as the processes of steps S130 to S150 shown in FIG. 3, the description thereof will be omitted. Further, in the following, as an example, a case where the wireless power transmission device 10 accepts an operation of starting the emission of electromagnetic waves at a timing before the processing of step S110 shown in FIG. 13 is performed will be described. That is, in the following, as an example, a case where electromagnetic waves are not radiated from the wireless power transmission device 10 at the timing will be described.

After the process of step S120 is performed, the wireless power transmission unit 11 informs the charge state detection unit 17 whether or not the load 30 in the radiation region (in this example, the load 30 of the wireless power receiving device 20) is fully charged. Let it be detected. The charge state detection unit 17 outputs information indicating the detection result to the wireless power transmission unit 11. The wireless power transmission unit 11 acquires the information from the charge state detection unit 17, and determines whether or not it is detected that the load 30 in the radiation region is fully charged based on the acquired information (step S710). ).

When the wireless power transmission unit 11 determines that the load 30 is not fully charged (step S710-NO), the wireless power transmission unit 11 proceeds to step S130.

On the other hand, when the wireless power transmission unit 11 determines that it is detected that the load 30 is fully charged (step S710-YES), the wireless power transmission unit 11 does not need to transmit power by wireless power transmission any more, and therefore transitions to step S140. do. That is, the wireless power transmission device 10 (more specifically, the wireless power transmission unit 11) stops emitting electromagnetic waves when the charge state detection unit 17 detects that the load 30 is fully charged. Then, the wireless power transmission device 10 (more specifically, the irradiation unit 12) stops the irradiation of visible light when the charge state detection unit 17 detects that the load 30 is fully charged. As a result, the wireless power transmission device 10 can suppress the continuous radiation of electromagnetic waves even though the load 30 is fully charged. As a result, the wireless power transmission device 10 can suppress an increase in power consumption.

The wireless power transmission device 10 described above may be configured by a combination of the configurations described above. Further, for example, when the wireless power transmission device 10 includes any two detection units or all three detection units of the three detection units of the biological detection unit 15, the power receiving device detection unit 16, and the charging state detection unit 17. One camera may be shared as the two detection units or the three detection units.

Further, the wireless power transmission device 10 described above may be configured to include an aerosol discharge device for spraying a mist-like aerosol such as a fog machine. As a result, the wireless power transmission device 10 can visually recognize the three-dimensional shape (for example, the light cone shape) of visible light emitted from the irradiation unit 12 by reflection by the aerosol. As a result, the wireless power transmission device 10 can more reliably visually recognize at least a part of the region where the electromagnetic wave is radiated from the wireless power transmission unit 11.

<Configuration of wireless power receiving device>
Hereinafter, the configuration of the wireless power receiving device 20 will be described with reference to FIG. FIG. 14 is a diagram showing an example of the configuration of the wireless power receiving device 20.

The wireless power receiving device 20 includes a wireless power receiving unit 22, a rectifying circuit unit 23, a supply circuit unit 24, a light receiving unit 25, and a power supply control unit 26. As described above, in this example, the wireless power receiving device 20 is integrally configured with the load 30. The wireless power receiving device 20 may not be provided with the light receiving unit 25. Therefore, in the explanations and drawings of FIGS. 1 to 13, since the configuration of the wireless power transmission device 10 has been mainly described, the configuration of the wireless power receiving device 20 when the light receiving unit 25 is not provided is shown. Hereinafter, in order to mainly explain the configuration of the wireless power receiving device 20, the case where the wireless power receiving device 20 includes the light receiving unit 25 will be described. Further, the wireless power receiving device 20 may have a configuration including the display unit 21 described above, or may have a configuration not including the display unit 21. Therefore, in the following, as an example, a case where the wireless power receiving device 20 does not include the display unit 21 will be described.

The wireless power receiving unit 22 receives the electromagnetic wave radiated from the wireless power transmitting unit 11 of the wireless power transmission device 10. Therefore, the wireless power receiving unit 22 has an antenna (not shown) that receives electromagnetic waves. This antenna may be any antenna. The wireless power receiving unit 22 converts the electromagnetic wave received by this antenna into electric power, so that the wireless power receiving unit 22 receives electric power corresponding to the electromagnetic wave. Then, the wireless power receiving unit 22 supplies the voltage of the received electric power, that is, the AC voltage corresponding to the electric power to the rectifier circuit unit 23.

The rectifier circuit unit 23 is connected to the wireless power receiving unit 22. The rectifier circuit unit 23 rectifies the AC voltage supplied from the wireless power receiving unit 22 and converts it into a DC voltage. Then, the rectifier circuit unit 23 supplies the rectified DC voltage to the supply circuit unit 24.

The supply circuit unit 24 is connected to the rectifier circuit unit 23. Further, the supply circuit unit 24 is connected to the load 30. The supply circuit unit 24 supplies the power received by the wireless power receiving unit 22 to the load 30. More specifically, in the supply circuit unit 24, when the load 30 is connected to the wireless power receiving device 20 (that is, when the load 30 is connected to the supply circuit unit 24), and the supply circuit unit 24 When the state is a state in which electric power can be supplied to the load 30, the DC voltage supplied from the rectifier circuit unit 23 is supplied to the load 30. When the wireless power receiving device 20 and the load 30 are separately configured, the supply circuit unit 24 is connected to a portion of the portion of the wireless power receiving device 20 to which the load 30 is connected. Further, the supply circuit unit 24 may be integrally configured with the rectifier circuit unit 23.

Further, the supply circuit unit 24 can supply power to the load 30 from the state of the supply circuit unit 24 and the state of the supply circuit unit 24 to the load 30 by the control from the power supply control unit 26 described later. It transitions to one of the states that cannot be supplied. The supply circuit unit 24 may realize the transition of these states by turning on / off the switching element, or may realize the transition of these states by another method. Here, the state in which the power supply circuit unit 24 can supply electric power to the load 30 is equivalent to the state in which the wireless power receiving device 20 can supply electric power to the load 30. Further, the state in which the power supply circuit unit 24 cannot supply electric power to the load 30 is equivalent to the state in which the wireless power receiving device 20 cannot supply electric power to the load 30.

The light receiving unit 25 receives light. For example, the light receiving unit 25 has a light receiving element, and when the light receiving element receives light, the light receiving unit 25 outputs information indicating that the light is received to the power supply control unit 26. Therefore, the light receiving unit 25 is connected to the power supply control unit 26.

When the light receiving unit 25 receives light, the power supply control unit 26 changes the state of the wireless power receiving device 20 to a state in which power can be supplied to the load 30 connected to the wireless power receiving device 20. That is, in this example, in this case, the power supply control unit 26 changes the state of the supply circuit unit 24 to a state in which power can be supplied to the load 30 connected to the supply circuit unit 24. On the other hand, when the light receiving unit 25 does not receive light, the power supply control unit 26 changes the state of the wireless power receiving device 20 to a state in which power cannot be supplied to the load 30 connected to the wireless power receiving device 20. .. That is, in this example, in this case, the power supply control unit 26 changes the state of the supply circuit unit 24 to a state in which power cannot be supplied to the load 30 connected to the supply circuit unit 24.

Here, when the power supply control unit 26 acquires the information output from the light receiving unit 25, the power supply control unit 26 determines that the light receiving unit 25 has received the light. On the other hand, when the power supply control unit 26 does not acquire the information output from the light receiving unit 25, the power supply control unit 26 determines that the light receiving unit 25 does not receive light.

FIG. 15 is a diagram showing an example of the configuration of the wireless power transmission system 1 including the wireless power receiving device 20 having the configuration shown in FIG. As shown in FIG. 15, the housing of the wireless power receiving device 20 is provided with a light receiving unit 25 that receives light.

<Process in which the wireless power receiving device starts receiving power via electromagnetic waves>
Hereinafter, a process of starting the reception of electric power via electromagnetic waves by the wireless power receiving device 20 will be described with reference to FIG. FIG. 16 is a diagram showing an example of a processing flow in which the wireless power receiving device 20 starts receiving electric power via electromagnetic waves. In the following, as an example, a case where both the emission of electromagnetic waves and the irradiation of visible light are started by the wireless power transmission device 10 will be described at a timing before the processing of step S810 shown in FIG. 16 is performed. .. Further, in the following, as an example, a case where the wireless power receiving device 20 is arranged in the first region indicated by the visualization region will be described at that timing.

The power supply control unit 26 waits until the light is received by the light receiving unit 25 (step S810).

When the power supply control unit 26 determines that the light is received by the light receiving unit 25 (step S810-YES), the time elapsed while continuously determining that the light is received by the light receiving unit 25 is predetermined. It is determined whether or not it is the third time or more of (step S820). In addition, in FIG. 16, the process of step S820 is shown as "the third time has passed?". Here, the predetermined third time is, for example, 3 seconds. The predetermined third time may be a time shorter than 3 seconds or a time longer than 3 seconds.

When the power supply control unit 26 determines that the time elapsed while continuously determining that the light is received by the light receiving unit 25 in step S820 is less than a predetermined third time (step S820-NO). ), The process proceeds to step S810, and the process waits again until the light is received by the light receiving unit 25.

On the other hand, when the power supply control unit 26 determines in step S820 that the time elapsed while continuously determining that the light is received by the light receiving unit 25 is the predetermined third time or more (step S820). −YES), the state of the supply circuit unit 24 is changed to a state in which electric power can be supplied to the load 30 connected to the supply circuit unit 24 (step S830). That is, when the light receiving unit 25 receives light for a predetermined third time or longer, the wireless power receiving device 20 changes the state of the wireless power receiving device 20 to a state in which power can be supplied to the load 30 connected to the wireless power receiving device 20. Change. As a result, the wireless power receiving device 20 can start supplying electric power to the load 30 by arranging it in the visualization region. Further, this makes it possible to prevent the wireless power receiving device 20 from starting the supply of unintended electric power to the load 30 when the electromagnetic wave is unintentionally received. As a result, the wireless power receiving device 20 can suppress, for example, overcharging the load 30. In FIG. 16, the process of step S830 is shown as a “state change”.

Here, in the period from the timing when the power supply control unit 26 determines that the light is received by the light receiving unit 25 in step S810 to the timing immediately before the processing in step S830 is performed, the wireless power receiving unit 22 is a wireless power transmission device. The electromagnetic wave radiated from 10 is received. Therefore, during this period, the rectifier circuit unit 23 converts the AC voltage supplied from the wireless power receiving unit 22 into a DC voltage and supplies it to the supply circuit unit 24. However, during the period, the state of the supply circuit unit 24 is a state in which electric power cannot be supplied to the load 30 connected to the supply circuit unit 24. Therefore, although the supply circuit unit 24 is supplied with a DC voltage from the rectifier circuit unit 23, it does not supply electric power to the load 30. That is, when the wireless power receiving device 20 does not receive light, the wireless power receiving device 20 does not change the state of the wireless power receiving device 20 to a state in which power can be supplied to the load 30 connected to the wireless power receiving device 20.

Next, the supply circuit unit 24 starts supplying electric power to the load 30 by starting to supply the DC voltage supplied from the rectifier circuit unit 23 to the load 30 (step S840).

Next, the power supply control unit 26 waits until the light receiving unit 25 stops receiving light (step S850). In addition, in FIG. 16, the process of step S850 is shown as "is not receiving light?".

When the power supply control unit 26 determines that the light receiving unit 25 no longer receives light (step S850-YES), the power supply control unit 26 does not supply power to the load 30 connected to the supply circuit unit 24 in the state of the supply circuit unit 24. By changing to a possible state, the supply of electric power to the load 30 by the supply circuit unit 24 is terminated (step S860). Then, the power supply control unit 26 ends the process.

The light receiving unit 25 detects light having a predetermined wavelength among the received light, and outputs information indicating that the light has been detected to the power supply control unit 26 as information indicating that the light has been received. It may be a configuration. The predetermined wavelength is the wavelength of visible light emitted by the wireless power transmission device 10, and is, for example, the wavelength of visible light of a specific monochromatic color such as red or yellow. As a result, the wireless power receiving device 20 can suppress the start of supplying electric power to the load 30 when the electromagnetic wave is received outside the visualization region. As a result, the wireless power receiving device 20 can suppress, for example, overcharging the load 30.

Further, the power supply control unit 26 may be configured to omit step S820 shown in FIG. That is, when the wireless power receiving unit 22 receives light, the power supply control unit 26 changes the state of the wireless power receiving device 20 to a state in which power can be supplied to the load 30 connected to the wireless power receiving device 20.

<Modification example 1 of the configuration of the wireless power receiving device>
Hereinafter, a modification 1 of the configuration of the wireless power receiving device 20 will be described. The wireless power receiving device 20 may be configured to include a switching unit 27, for example, as shown in FIG. FIG. 17 is a diagram showing an example of the configuration of the wireless power receiving device 20 including the switching unit 27. As shown in FIG. 17, in this case, the power supply control unit 26 is connected to the switching unit 27 instead of the supply circuit unit 24. That is, in the example shown in FIG. 17, the state of the supply circuit unit 24 does not change from the state in which power can be supplied to the load 30 connected to the supply circuit unit 24.

The switching unit 27 switches the conduction state between the wireless power receiving unit 22 and the rectifier circuit unit 23. For example, the switching unit 27 is a switching element such as a field effect transistor. Further, the switching unit 27 switches the conduction state between the wireless power receiving unit 22 and the rectifier circuit unit 23 in response to the control from the power supply control unit 26.

When the power supply control unit 26 includes the switching unit 27, the wireless power receiving unit 22 and the rectifying circuit unit 23 are provided by the switching unit 27 instead of changing the state of the supply circuit unit 24 in step S830 shown in FIG. By switching the conduction state between and, the state of the wireless power receiving device 20 is changed to a state in which power can be supplied to the load 30 connected to the wireless power receiving device 20. More specifically, in this case, the power supply control unit 26 conducts the wireless power receiving unit 22 and the rectifier circuit unit 23 by the switching unit 27 in step S830 shown in FIG. That is, in the period from the timing when the power supply control unit 26 determines that the light is received by the light receiving unit 25 in step S810 to the timing immediately before the processing of step S830 is performed, the switching unit 27 and the wireless power receiving unit 22 It is non-conducting with the rectifier circuit unit 23. As a result, the wireless power receiving device 20 does not change the state of the wireless power receiving device 20 to a state in which power can be supplied to the load 30 connected to the wireless power receiving device 20 when the wireless power receiving unit 22 does not receive light. ..

When the power supply control unit 26 includes the switching unit 27, the switching unit 27 replaces the state of the supply circuit unit 24 with the wireless power receiving unit 22 and the rectifier circuit in step S860 shown in FIG. By switching the conduction state with the unit 23, the state of the wireless power receiving device 20 is changed to a state in which power cannot be supplied to the load 30 connected to the wireless power receiving device 20. More specifically, in this case, the power supply control unit 26 makes the wireless power receiving unit 22 and the rectifier circuit unit 23 non-conducting by the switching unit 27 in step S860 shown in FIG. As a result, when the wireless power receiving unit 22 stops receiving light, the wireless power receiving device 20 changes the state of the wireless power receiving device 20 to a state in which power cannot be supplied to the load 30 connected to the wireless power receiving device 20. Let me.

As described above, when the wireless power receiving device 20 includes the switching unit 27 and the light receiving unit 25 receives light, the switching unit 27 makes the wireless power receiving unit 22 and the rectifier circuit unit 23 conductive. Therefore, the state of the wireless power receiving device 20 is changed to a state in which power can be supplied to the load 30. As a result, the wireless power receiving device 20 can start supplying electric power to the load 30 by arranging it in the visible light region. Further, this makes it possible to prevent the wireless power receiving device 20 from starting the supply of unintended electric power to the load 30 when the electromagnetic wave is unintentionally received. As a result, the wireless power receiving device 20 can suppress, for example, overcharging the load 30.

The wireless power receiving device 20 may be configured by a combination of the configuration shown in FIG. 14 and the configuration shown in FIG. In this case, when the light receiving unit 25 receives light, the wireless power receiving device 20 switches the state of the supply circuit unit 24 to a state in which power can be supplied to the load 30 connected to the supply circuit unit 24. By conducting the wireless power receiving unit 22 and the rectifying circuit unit 23 by the unit 27, the state of the wireless power receiving device 20 is changed to a state in which electric power can be supplied to the load 30. As a result, the wireless power receiving device 20 can more reliably suppress the start of unintended power supply to the load 30 when the electromagnetic wave is unintentionally received.

When the wireless power receiving device 20 is configured by a combination of the configuration shown in FIG. 14 and the configuration shown in FIG. 17, as shown in FIG. 18, the wireless power receiving device 20 further includes an operating state detection circuit unit 28 together with the switching unit 27. It may be a configuration. FIG. 18 is a diagram showing an example of the configuration of the wireless power receiving device 20 when the operating state detection circuit unit 28 is provided together with the switching unit 27.

The operation state detection circuit unit 28 detects whether or not the supply circuit unit 24 is operating. Therefore, the operating state detection circuit unit 28 is connected to the supply circuit unit 24. Then, the operation state detection circuit unit 28 outputs information indicating the result of detecting whether or not the supply circuit unit 24 is operating to the power supply control unit 26. Here, if the supply circuit unit 24 is not operating, there is a high possibility that the supply circuit unit 24 is out of order for some reason. Therefore, when the operating state detection circuit unit 28 determines that the supply circuit unit 24 is not operating, the power supply control unit 26 makes the wireless power receiving unit 22 and the rectifier circuit unit 23 non-conducting, so that the power is generated. It is possible to prevent the power from being supplied to the supply circuit unit 24 via the rectifier circuit unit 23.

Here, the wireless power receiving device 20 including the operating state detection circuit unit 28 processes the flowchart shown in FIG.

FIG. 19 is a diagram showing an example of a flow of processing performed by the wireless power receiving device 20 based on the information output from the operating state detection circuit unit 28. In the following, as an example, a case where both the emission of electromagnetic waves and the irradiation of visible light are started by the wireless power transmission device 10 will be described at a timing before the processing of step S910 shown in FIG. 19 is performed. ..

The power supply control unit 26 causes the operation state detection circuit unit 28 to detect whether or not the supply circuit unit 24 is operating (step S910). The operation state detection circuit unit 28 outputs information indicating the detection result to the power supply control unit 26. The power supply control unit 26 acquires the information from the operation state detection circuit unit 28, and determines whether or not the supply circuit unit 24 is operating based on the acquired information (step S920).

When the power supply control unit 26 determines that the supply circuit unit 24 is operating (step S920-YES), the power supply control unit 26 transitions to step S910 and determines whether or not the supply circuit unit 24 is operating in the operating state detection circuit unit. Let 28 detect it again.

On the other hand, when the power supply control unit 26 determines that the supply circuit unit 24 is not operating (step S920-NO), the power supply control unit 26 continuously determines that the supply circuit unit 24 is not operating in step S920. It is determined whether or not the elapsed time is equal to or longer than the predetermined fourth hour (step S930). In FIG. 19, the process of step S930 is shown as "4th time elapsed?". Here, the predetermined fourth time is, for example, 3 seconds. The predetermined fourth time may be a time shorter than 3 seconds or a time longer than 3 seconds.

When the power supply control unit 26 determines in step S920 that the time elapsed while continuously determining that the supply circuit unit 24 is not operating is less than a predetermined fourth time (step S930-). NO), the transition to step S910 causes the operating state detection circuit unit 28 to detect again whether or not the supply circuit unit 24 is operating.

On the other hand, when the power supply control unit 26 determines in step S920 that the time elapsed while continuously determining that the supply circuit unit 24 is not operating is the predetermined fourth time or more (step). S930-YES), the switching unit 27 makes the wireless power receiving unit 22 and the rectifier circuit unit 23 non-conducting (step S940). Then, the power supply control unit 26 transitions to step S910, and causes the operation state detection circuit unit 28 to detect again whether or not the supply circuit unit 24 is operating.

As described above, when the wireless power receiving device 20 continues to be detected by the operating state detection circuit unit 28 that the supply circuit unit 24 is not operating for a predetermined fourth time or longer, the supply circuit unit 24 is out of order. Therefore, the switching unit 27 makes the wireless power receiving unit 22 and the rectifier circuit unit 23 non-conducting. As a result, the wireless power receiving device 20 can prevent the supply circuit unit 24 from continuing to supply electric power when the supply circuit unit 24 is out of order.

<Modification 2 of the configuration of the wireless power receiving device>
Hereinafter, a modification 2 of the configuration of the wireless power receiving device 20 will be described. For example, as shown in FIG. 20, the wireless power receiving device 20 may be configured to include a battery remaining amount detecting unit 29A. Further, the wireless power receiving device 20 may be configured to include two notification units, a first notification unit 29B and a second notification unit 29C, together with the battery remaining amount detection unit 29A, and the configuration does not include the two notification units. It may be. Hereinafter, as an example, a case where the wireless power receiving device 20 includes the battery remaining amount detecting unit 29A and the two notification units will be described.

FIG. 20 is a diagram showing an example of the configuration of a wireless power receiving device 20 including each of the battery remaining amount detection unit 29A, the first notification unit 29B, and the second notification unit 29C.

The battery remaining amount detecting unit 29A detects the remaining amount of the load 30 which is a battery. The remaining amount of the load 30 is, that is, the remaining amount of electric power that can be supplied by the load 30. The battery level detection unit 29A is connected to the load 30. Further, the battery remaining amount detection unit 29A is also connected to each of the power supply control unit 26, the first notification unit 29B, and the second notification unit 29C. When the remaining battery level detection unit 29A detects the remaining amount of the load 30, the battery remaining amount detection unit 29A outputs the detected information indicating the remaining amount to the battery remaining amount detection unit 29A, the first notification unit 29B, and the second notification unit 29C, respectively. do.

Based on the information output from the battery remaining amount detecting unit 29A, the first notification unit 29B determines whether or not the remaining amount indicated by the information is equal to or greater than a predetermined second threshold value. Here, as an example, a case where the remaining amount is represented by a percentage of 100 will be described below. In this case, the second threshold is also expressed in parts per hundred. The second threshold is, for example, 100%. The second threshold value may be a value lower than 100%. When the first notification unit 29B determines that the remaining amount is equal to or greater than the second threshold value, the first notification unit 29B notifies information indicating that charging is unnecessary. The first notification unit 29B includes, for example, an LED. The first notification unit 29B may include a notification device such as a display capable of transmitting the information instead of the LED.

The second notification unit 29C notifies the information based on the remaining amount indicated by the information based on the information output from the battery remaining amount detecting unit 29A. The second notification unit 29C includes, for example, an LED. The second notification unit 29C may include a notification device such as a display capable of transmitting the information instead of the LED. Here, the information is, for example, information for urging charging when the remaining amount is less than a predetermined value. In this case, the second notification unit 29C determines whether or not the remaining amount indicated by the information output from the battery remaining amount detecting unit 29A is less than a predetermined value. When the second notification unit 29C determines that the remaining amount is less than a predetermined value, the second notification unit 29C notifies information prompting the charging. The information based on the remaining amount may be other information. Further, the second notification unit 29C may be integrally configured with the first notification unit 29B.

Here, the wireless power receiving device 20 including each of the battery remaining amount detection unit 29A, the first notification unit 29B, and the second notification unit 29C performs the processing of the flowcharts shown in FIGS. 21 to 23. As a result, the wireless power receiving device 20 can visually recognize the charging state of the load 30, and as a result, it is possible to prevent the load 30 from being overcharged.

FIG. 21 is a diagram showing an example of a flow of processing performed by the wireless power receiving device 20 based on the information output from the battery remaining amount detecting unit 29A. In the following, as an example, the case where both the radiation of electromagnetic waves and the irradiation of visible light are started by the wireless power transmission device 10 at a timing before the processing of step S1010 shown in FIG. 21 is performed. explain. Further, in the following, as an example, a case where the wireless power receiving device 20 is arranged in the visualization region at the timing will be described. Further, in the following, as an example, a case where power supply to the load 30 by the wireless power receiving device 20 is started at the timing will be described.

The battery remaining amount detecting unit 29A detects the remaining amount of the load 30 (step S1010). Then, the battery remaining amount detection unit 29A outputs information indicating the detected remaining amount to the power supply control unit 26.

Next, the power supply control unit 26 determines whether or not the remaining amount indicated by the information acquired from the battery remaining amount detecting unit 29A is equal to or greater than a predetermined second threshold value (step S1020).

When the power supply control unit 26 determines that the remaining amount indicated by the information acquired from the battery remaining amount detection unit 29A is less than a predetermined second threshold value (step S1020-NO), the battery remaining amount detecting unit 29A is step S1010. And detect the remaining amount of the load 30 again.

On the other hand, when the battery remaining amount detecting unit 29A determines that the remaining amount indicated by the information acquired from the battery remaining amount detecting unit 29A is equal to or higher than a predetermined second threshold value (step S1020-YES), the state of the supply circuit unit 24 Is changed to a state in which power cannot be supplied to the load 30 connected to the supply circuit unit 24, thereby ending the supply of power to the load 30 by the supply circuit unit 24 (step S1030). Then, the power supply control unit 26 ends the process. As a result, the wireless power receiving device 20 can more reliably prevent the load 30 from being overcharged.

FIG. 22 is a diagram showing another example of the flow of processing performed by the wireless power receiving device 20 based on the information output from the battery remaining amount detecting unit 29A. Since the processing of steps S101 to S1020 shown in FIG. 22 is the same as the processing of steps S101 to S1020 shown in FIG. 21, the description thereof will be omitted. However, in step S1010 shown in FIG. 22, the battery remaining amount detecting unit 29A outputs the information indicating the detected remaining amount to the first notification unit 29B. Further, the main body that performs the process of step S1020 shown in FIG. 22 is not the power supply control unit 26 but the first notification unit 29B. The wireless power receiving device 20 repeatedly processes the flowchart shown in FIG. 22 as long as the load 30 is connected, regardless of the light received by the light receiving unit 25 and the electromagnetic wave received by the wireless power receiving unit 22. ..

When the first notification unit 29B determines in step S1020 that the remaining amount of the load 30 is equal to or greater than the second threshold value, the first notification unit 29B notifies information indicating that charging is unnecessary (step S1040). As a result, the wireless power receiving device 20 can prevent the user of the wireless power receiving device 20 from trying to overcharge the load 30. Then, after the process of step S1040 is performed, the battery remaining amount detection unit 29A transitions to step S1010.

FIG. 23 is a diagram showing still another example of the flow of processing performed by the wireless power receiving device 20 based on the information output from the battery remaining amount detecting unit 29A. Since the process of step S1010 shown in FIG. 23 is the same process as the process of step S1010 shown in FIG. 21, the description thereof will be omitted. However, in step S1010 shown in FIG. 23, the battery remaining amount detecting unit 29A outputs the information indicating the detected remaining amount to the second notification unit 29C. The wireless power receiving device 20 repeatedly processes the flowchart shown in FIG. 23 as long as the load 30 is connected, regardless of the light received by the light receiving unit 25 and the electromagnetic wave received by the wireless power receiving unit 22. ..

After the process of step S1010 is performed, the second notification unit 29C determines whether or not the remaining amount indicated by the information acquired from the battery remaining amount detecting unit 29A is less than a predetermined value (step S1050). The predetermined value may be any value as long as it is a value higher than 0% and a value of 100% or less.

When the second notification unit 29C determines that the remaining amount indicated by the information acquired from the battery remaining amount detecting unit 29A is equal to or higher than a predetermined value (step S1050-NO), the battery remaining amount detecting unit 29A transitions to step S1010. , The remaining amount of the load 30 is detected again.

On the other hand, when the second notification unit 29C determines that the remaining amount indicated by the information acquired from the battery remaining amount detecting unit 29A is less than a predetermined value (step S1050-YES), the second notification unit 29C notifies the information based on the remaining amount (step S1050-YES). Step S1060). As a result, the wireless power receiving device 20 can be urged to charge the load 30 when the remaining amount of the load 30 is low, for example.

<Modification 3 of the configuration of the wireless power receiving device>
Hereinafter, a modification 3 of the configuration of the wireless power receiving device 20 will be described. The wireless power receiving device 20 may be configured to change the state of the wireless power receiving device 20 to a state in which power can be supplied to the load 30 based on the intensity of the light received by the light receiving unit 25, for example. More specifically, the wireless power receiving device 20 may be configured to change the state of the wireless power receiving device 20 to a state in which power can be supplied to the load when the strength is included in a predetermined range. In this case, in the wireless power receiving device 20, when the light receiving unit 25 receives light, the light receiving unit 25 also detects the intensity of the light received by the light receiving unit 25. Then, the light receiving unit 25 outputs information indicating the detected intensity to the power supply control unit 26. Then, in this case, the wireless power receiving device 20 performs the processing of the flowchart shown in FIG. 24 instead of the processing of the flowchart shown in FIG.

FIG. 24 is a diagram showing an example of a flow of processing performed by the wireless power receiving device 20 based on the intensity of light received by the light receiving unit 25. Since the process of step S810 shown in FIG. 24 is the same process as the process of step S810 shown in FIG. 16, the description thereof will be omitted. Further, since the processing of steps S820 to S860 shown in FIG. 24 is the same processing as the processing of steps S820 to S860 shown in FIG. 16, the description thereof will be omitted. Further, in the following, as an example, a case where both the radiation of electromagnetic waves and the irradiation of visible light are started by the wireless power transmission device 10 at a timing before the processing of step S810 shown in FIG. 24 is performed. explain. Further, in the following, as an example, a case where the wireless power receiving device 20 is arranged in the visualization region at the timing will be described.

When the power supply control unit 26 determines in step S810 that the light is received by the light receiving unit 25, the power supply control unit 26 determines whether or not the intensity indicated by the information acquired from the light receiving unit 25 is within a predetermined range (step S1110). ). Here, the predetermined range is, for example, a range including the intensity of electromagnetic waves that does not excessively load each circuit included in the wireless power receiving device 20 when the wireless power receiving device 20 receives power, and the wireless power receiving device 20. It is a range including the intensity of the electromagnetic wave that the wireless power receiving device 20 can receive by receiving the signal 20. The predetermined range may be another range instead of this.

When the power supply control unit 26 determines that the intensity indicated by the information acquired from the light receiving unit 25 is not included in the predetermined range (step S1110-NO), the power supply control unit 26 transitions to step S810.

On the other hand, when the power supply control unit 26 determines that the intensity indicated by the information acquired from the light receiving unit 25 is within a predetermined range (step S1110-YES), the power supply control unit 26 transitions to step S820. As a result, the wireless power receiving device 20 can suppress, for example, excessively applying a load to each circuit included in the wireless power receiving device 20 due to the wireless power receiving device 20 receiving power, and the strength is too weak. It is possible to prevent the wireless power receiving device 20 from starting to supply power to the load 30 even though it cannot receive power.

The wireless power receiving device 20 described above may be configured by a combination of the configurations described above.

As described above, the wireless power transmission device according to the embodiment (wireless power transmission device 10 in the example described above) is visible to the wireless power transmission unit (radio power transmission unit 11 in the example described above) that radiates electromagnetic waves. An irradiation unit (in the example described above, the irradiation unit 12) that irradiates light is provided, and the visualization region is a visualization region (in the example described above, region RA1) in which the irradiation unit irradiates visible light. It is a region that indicates at least a part of the radiation region where electromagnetic waves are radiated from the radio transmission unit (region RA2 in the example described above). At least a part can be visually recognized.

Further, in the wireless power transmission device, the visualization region is a region in which the electromagnetic wave radiated from the wireless power transmission unit indicates an region in which the intensity of the electromagnetic wave radiated from the wireless power transmission unit is equal to or higher than a predetermined first threshold value. The configuration may be used.

Further, in the wireless power transmission device, a configuration may be used in which the visualization region is a region indicating the position where the intensity of the electromagnetic wave is the maximum among the regions in which the electromagnetic wave is radiated from the wireless power transmission unit.

Further, the wireless power transmission device further includes a radiation direction control unit (radiation direction control unit 13 in the example described above) that controls the radiation direction in which the radio transmission unit emits electromagnetic waves, and the irradiation unit responds to the radiation direction. A configuration may be used that changes the position of the visualization region.

Further, in the wireless power transmission device, the wireless power transmission unit has an array antenna that emits electromagnetic waves, and the radiation direction control unit is from each of the individual antennas included in the array antenna (antenna A in the example described above). A configuration may be used in which the phase of the emitted electromagnetic wave is adjusted to change the direction of radiation.

Further, in the wireless power transmission device, a configuration may be used in which the radiation direction control unit changes the radiation direction by changing the posture of the radio power transmission unit.

Further, in the wireless power transmission device, the irradiation unit may be configured to change the size of the visualization region according to the intensity of the electromagnetic wave radiated from the wireless power transmission unit.

Further, the wireless power transmission device detects whether or not a living body (person H in the example described above) exists in the target area (region RA3 in the example described above) including at least a part of the visualization region. A biometric detection unit (in the example described above, the biometric detection unit 15) is further provided, and the wireless power transmission unit radiates electromagnetic waves when the biological detection unit detects a living body in the target area. Configurations may be used that reduce the intensity of the electromagnetic waves.

Further, in the wireless power transmission device, a configuration may be used in which the wireless power transmission unit stops radiating electromagnetic waves when a living body is detected in the target area by the biological detection unit when radiating electromagnetic waves.

Further, in the wireless power transmission device, a configuration is used in which the wireless power transmission unit does not start radiating electromagnetic waves when the wireless power transmission unit does not radiate electromagnetic waves and when a living body is detected in the target area by the biological detection unit. You may.

Further, in the wireless power transmission device, the wireless power transmission unit starts emitting electromagnetic waves when the electromagnetic wave is not radiated and the living body is not detected in the target area by the biological detection unit for a predetermined first time or more. The configuration may be used.

Further, the wireless power transmission device is configured to further include a power receiving device detection unit (in the example described above, the power receiving device detection unit 16) for detecting whether or not the wireless power receiving device exists in the radiation region. May be good.

Further, in the wireless power transmission device, the wireless power transmission unit emits electromagnetic waves when the wireless power transmission unit emits electromagnetic waves and the wireless power reception device is not detected in the radiation region for a predetermined second time or longer by the power receiving device detection unit. A stop configuration may be used.

Further, the wireless power transmission device is a charge state detection unit (in the example described above) that detects a full charge of a battery (load 30 in the example described above) to which power is supplied from the wireless power receiving device in the radiation region. , The wireless power transmission unit further includes a charge state detection unit 17), and when the charge state detection unit detects the full charge, the wireless power transmission unit stops radiating electromagnetic waves, and the irradiation unit is charged by the charge state detection unit. A configuration may be used that stops the irradiation of visible light when detected.

Further, in the wireless power transmission system according to the embodiment (in the example described above, the wireless power transmission system 1), the wireless power receiving device receives the electromagnetic wave radiated from the wireless power transmitting unit, and the electric power corresponding to the received electromagnetic power is received. When the wireless power receiving unit (wireless power receiving unit 22 in the example described above), the light receiving unit that receives light (light receiving unit 25 in the example described above), and the light receiving unit receive light. A power supply control unit that changes the state of the wireless power receiving device to a state in which power can be supplied to the load connected to the wireless power receiving device (load 30 in the example described above) (power supply in the example described above). A configuration may be used that comprises a control unit 26).

Further, in the wireless power transmission system, the wireless power receiving device further includes a supply circuit unit (supply circuit unit 24 in the example described above) that supplies the power received by the wireless power receiving unit to the load, and is provided with a power supply control unit. May use a configuration in which when the light receiving unit receives light, the state of the supply circuit unit is changed to a state in which electric power can be supplied to the load.

Further, in the wireless power transmission system, the wireless power receiving device includes a rectifying circuit unit (rectifying circuit unit 23 in the example described above) that rectifies the voltage of the power received by the wireless power receiving unit into a DC voltage, and a wireless power receiving unit. A switching unit (switching unit 27 in the example described above) for switching the conduction state with the rectifying circuit unit is further provided, and the power supply control unit is wirelessly operated by the switching unit when the light receiving unit receives light. A configuration may be used in which the power receiving unit and the rectifying circuit unit are made conductive.

Further, in the wireless power transmission system, the wireless power receiving device receives the electromagnetic wave radiated from the wireless power transmitting unit and receives the electric power corresponding to the received electromagnetic wave, and the voltage of the electric power received by the wireless power receiving unit. Further, a rectifying circuit unit that rectifies to a DC voltage, a supply circuit unit that supplies the DC voltage output from the rectifying circuit unit to the load, and a switching unit that switches the conduction state between the wireless power receiving unit and the rectifying circuit unit. The power supply control unit may be configured such that when the light receiving unit receives light, the switching unit makes the wireless power receiving unit and the rectifying circuit unit conductive.

Further, in the wireless power transmission system, the wireless power receiving device further includes an operation state detection circuit unit (in the example described above, the operation state detection circuit unit 28) for detecting whether or not the supply circuit unit is operating. When the power supply control unit continues to detect that the supply circuit unit is not operating by the operation state detection circuit unit for a predetermined fourth time or longer, the switching unit causes nonconduction between the wireless power receiving unit and the rectifier circuit unit. The configuration may be used.

Further, in the wireless power transmission system, a configuration may be used in which the light receiving unit detects light having a predetermined wavelength and the visible light is light having a predetermined wavelength.

Further, in the wireless power transmission system, the power supply control unit is configured to change the state of the wireless power receiving device to a state in which power can be supplied to the load when the light receiving unit receives light for a predetermined third time or longer. May be done.

Further, in the wireless power transmission system, the load is a battery, and the wireless power receiving device is a battery remaining amount detecting unit that detects the remaining amount of the load which is a battery (in the example described above, the battery remaining amount detecting unit 29A). Further, the power supply control unit changes the state of the wireless power receiving device to a state in which power cannot be supplied to the load when the remaining amount detected by the battery remaining amount detection unit is equal to or higher than a predetermined second threshold value. A configuration may be used in which the state of the wireless power receiving device is not changed to a state in which power can be supplied to the load.

Further, in the wireless power transmission system, the wireless power receiving device is a first notification unit that notifies information indicating that charging is not required when the remaining amount of the load detected by the battery remaining amount detection unit is equal to or greater than the second threshold value. A configuration may be used that further comprises (in the example described above, the first notification unit 29B).

Further, in the wireless power transmission system, the wireless power receiving device is a second notification unit that notifies information based on the remaining amount of the load detected by the battery remaining amount detection unit (in the example described above, the second notification unit 29C). A configuration may be used that further comprises.

Further, in the wireless power transmission system, even if a configuration is used in which the power supply control unit changes the state of the wireless power receiving device to a state in which power can be supplied to the load based on the intensity of the light received by the light receiving unit. good.

Although the embodiment of the present invention has been described in detail with reference to the drawings, the specific configuration is not limited to this embodiment, and changes, substitutions, deletions, etc., are made as long as the gist of the present invention is not deviated. May be done.

Further, a program for realizing the function of an arbitrary component in the apparatus described above may be recorded on a computer-readable recording medium, and the program may be read into a computer system and executed. Here, the device is, for example, a wireless power transmission device 10, a wireless power receiving device 20, and the like. The term "computer system" as used herein includes hardware such as an OS (Operating System) and peripheral devices. The "computer-readable recording medium" refers to a portable medium such as a flexible disk, a magneto-optical disk, a ROM, a CD (Compact Disk) -ROM, or a storage device such as a hard disk built in a computer system. .. Furthermore, a "computer-readable recording medium" is a constant like the volatile memory inside a computer system that serves as a server or client when a program is transmitted via a network such as the Internet or a communication line such as a telephone line. It shall include those holding a time program.

Further, the above program may be transmitted from a computer system in which this program is stored in a storage device or the like to another computer system via a transmission medium or by a transmission wave in the transmission medium. Here, the "transmission medium" for transmitting a program refers to a medium having a function of transmitting information, such as a network such as the Internet or a communication line such as a telephone line.
Further, the above program may be for realizing a part of the above-mentioned functions. Further, the above program may be a so-called difference file or a difference program that can realize the above-mentioned functions in combination with a program already recorded in the computer system.

1 ... Wireless power transmission system, 10 ... Wireless power transmission device, 11 ... Wireless power transmission unit, 12 ... Irradiation unit, 13 ... Radiation direction control unit, 14 ... Attitude change mechanism, 15 ... Biometric detection unit, 16 ... Power receiving device detection unit, 17 ... Charge state detection unit, 20 ... Wireless power receiving device, 21 ... Display unit, 22 ... Wireless power receiving unit, 23 ... Rectifier circuit unit, 24 ... Supply circuit unit, 25 ... Light receiving unit, 26 ... Power supply control unit, 27 ... Switching unit, 28 ... Operating state detection circuit unit, 29A ... Battery level detection unit, 29B ... 1st notification unit, 29C ... 2nd notification unit, 30 ... Load, A ... Antenna

Claims (26)

A wireless power transmission unit that radiates electromagnetic waves,
Irradiation part that irradiates visible light and
With
The visualization region in which the irradiation unit irradiates visible light is a region indicating at least a part of the radiation region in which electromagnetic waves are radiated from the wireless power transmission unit.
Wireless power transmission device. The visualization region is a region among the radiation regions that indicates a region in which the intensity of electromagnetic waves is equal to or higher than a predetermined first threshold value.
The wireless power transmission device according to claim 1. The visualization region is a region among the radiation regions that indicates the position where the intensity of the electromagnetic wave is maximum.
The wireless power transmission device according to claim 2. Further, a radiation direction control unit for controlling the radiation direction in which the wireless power transmission unit emits electromagnetic waves is provided.
The irradiation unit changes the position of the visualization region according to the radiation direction.
The wireless power transmission device according to any one of claims 1 to 3. The wireless power transmission unit has an array antenna that radiates electromagnetic waves.
The radiation direction control unit changes the radiation direction by adjusting the phase of electromagnetic waves radiated from each of the individual antennas included in the array antenna.
The wireless power transmission device according to claim 4. The radiation direction control unit changes the radiation direction by changing the posture of the wireless power transmission unit.
The wireless power transmission device according to claim 4 or 5. The irradiation unit changes the size of the visualization region according to the intensity of electromagnetic waves radiated from the wireless power transmission unit.
The wireless power transmission device according to any one of claims 1 to 6. A biological detection unit for detecting whether or not a living body exists in the target region including at least a part of the visualization region is further provided.
The wireless power transmission unit reduces the intensity of the radiated electromagnetic wave when the living body is detected in the target region by the living body detecting unit when the electromagnetic wave is radiated.
The wireless power transmission device according to any one of claims 1 to 7. The wireless power transmission unit stops radiating electromagnetic waves when a living body is detected in the target area by the biological detection unit when the electromagnetic wave is being emitted.
The wireless power transmission device according to claim 8. The wireless power transmission unit does not start emitting electromagnetic waves when it does not radiate electromagnetic waves and when a living body is detected in the target area by the biological detection unit.
The wireless power transmission device according to claim 8 or 9. The wireless power transmission unit starts emitting electromagnetic waves when the electromagnetic wave is not radiated and when the biological detection unit does not detect a living body in the target region for a predetermined first time or more.
The wireless power transmission device according to any one of claims 8 to 10. A power receiving device detection unit for detecting whether or not the wireless power receiving device exists in the radiation region is further provided.
The wireless power transmission device according to any one of claims 1 to 11. The wireless power transmission unit stops radiating electromagnetic waves when the wireless power transmission unit is radiating electromagnetic waves and the wireless power transmission unit is not detected in the radiation region by the power receiving device detection unit for a predetermined second time or longer.
The wireless power transmission device according to claim 12. In the radiation region, a charge state detection unit for detecting the full charge of the battery to which power is supplied from the wireless power receiving device is further provided.
When the full charge is detected by the charge state detection unit, the wireless power transmission unit stops emitting electromagnetic waves.
The irradiation unit stops the irradiation of the visible light when the full charge is detected by the charge state detection unit.
The wireless power transmission device according to any one of claims 1 to 13. The wireless power transmission device according to any one of claims 1 to 14.
Wireless power receiving device and
A wireless power transmission system equipped with. The wireless power receiving device is
A wireless power receiving unit that receives electromagnetic waves radiated from the wireless power transmitting unit and receives electric power corresponding to the received electromagnetic waves.
A light receiving part that receives light and
When the light receiving unit receives light, a power supply control unit that changes the state of the wireless power receiving device to a state in which power can be supplied to a load connected to the wireless power receiving device.
To prepare
The wireless power transmission system according to claim 15. The wireless power receiving device is
A supply circuit unit that supplies the power received by the wireless power receiving unit to the load is further provided.
When the light receiving unit receives light, the power supply control unit changes the state of the supply circuit unit to a state in which power can be supplied to the load.
The wireless power transmission system according to claim 16. The wireless power receiving device is
A rectifier circuit unit that rectifies the voltage of the power received by the wireless power receiving unit into a DC voltage,
A switching unit that switches the conduction state between the wireless power receiving unit and the rectifying circuit unit, and
Further prepare
When the light receiving unit receives light, the power supply control unit conducts the wireless power receiving unit and the rectifying circuit unit by the switching unit.
The wireless power transmission system according to claim 17. The wireless power receiving device is
A rectifier circuit unit that rectifies the voltage of the power received by the wireless power receiving unit into a DC voltage,
A supply circuit unit that supplies the DC voltage output from the rectifier circuit unit to the load, and
A switching unit that switches the conduction state between the wireless power receiving unit and the rectifying circuit unit, and
Further prepare
When the light receiving unit receives light, the power supply control unit conducts the wireless power receiving unit and the rectifying circuit unit by the switching unit.
The wireless power transmission system according to claim 16. The wireless power receiving device is
An operation state detection circuit unit for detecting whether or not the supply circuit unit is operating is further provided.
When the power supply control unit continues to detect that the supply circuit unit is not operating by the operation state detection circuit unit for a predetermined fourth time or longer, the wireless power receiving unit and the rectifier circuit unit are detected by the switching unit. Non-conducting between
The wireless power transmission system according to claim 18 or 19. The light receiving unit detects light having a predetermined wavelength and receives light.
The visible light is light having the predetermined wavelength.
The wireless power transmission system according to any one of claims 16 to 20. The power supply control unit changes the state of the wireless power receiving device to a state in which power can be supplied to the load when the light receiving unit receives light for a predetermined third time or longer.
The wireless power transmission system according to any one of claims 16 to 21. The load is a battery
The wireless power receiving device is
Further equipped with a battery remaining amount detecting unit for detecting the remaining amount of the load which is a battery,
The power supply control unit changes the state of the wireless power receiving device to a state in which power cannot be supplied to the load when the remaining amount detected by the battery remaining amount detecting unit is equal to or higher than a predetermined second threshold value. Or do not change the state of the wireless power receiving device to a state in which power can be supplied to the load.
The wireless power transmission system according to any one of claims 16 to 22. The wireless power receiving device is
When the remaining amount detected by the battery remaining amount detection unit is equal to or greater than the second threshold value, a first notification unit for notifying information indicating that charging is not required is further provided.
The wireless power transmission system according to claim 23. The wireless power receiving device is
A second notification unit for notifying information based on the remaining amount detected by the battery remaining amount detecting unit is further provided.
The wireless power transmission system according to claim 23 or 24. The power supply control unit changes the state of the wireless power receiving device to a state in which power can be supplied to the load based on the intensity of the light received by the light receiving unit.
The wireless power transmission system according to any one of claims 16 to 25.

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