JP6788435B2 - Contactless power supply system - Google Patents

Description

The present invention relates to a non-contact power supply system that supplies power from a power transmission device to a power receiving device in a non-contact manner.

In a non-contact power supply system, the power transmission device receives information about power supply from the power receiving device and confirms the existence of the power receiving device. For example, Patent Document 1 discloses a wireless charging system including a wireless communication device and a charging providing device that supplies electric power to the wireless communication device.

In the technique disclosed in Patent Document 1, the wireless communication device makes a charging request to the charging providing device by wireless communication, receives a wireless charging acceptance message from the charging providing device, and receives a wireless charging session.

Japanese Patent Application Laid-Open No. 2013-523563

In the technique disclosed in Patent Document 1, since the wireless communication device and the charging providing device use the wireless communication function to send and receive information on charging, each of them is provided with a wireless communication function, which is costly.

The present invention has been made in view of such a problem, and an object of the present invention is to provide a non-contact power feeding system capable of inexpensively transmitting and receiving information regarding power feeding of a power transmission device and a power receiving device.

In order to solve the above problems, the non-contact power supply system according to an embodiment of the present invention includes a power transmission device capable of transmitting electric power and a power receiving device that receives electric power from the power transmission device. The power transmission device includes a power transmission unit that transmits power to the power receiving device, a detection unit that detects light or sound, and a power transmission control unit that controls power transmission by the power transmission unit based on the detection result of the detection unit. The power receiving device controls the output of the power receiving unit that receives power from the power transmitting unit in a non-contact manner, the power storage unit that stores the power received by the power receiving unit, the output unit that outputs light or sound to the space, and the output unit. It has a charge control unit and a charge control unit. The charge control unit controls to output the light or sound of the predetermined stop pattern from the output unit when the predetermined charging condition is satisfied, and the power transmission control unit controls the detection unit to output the light or sound of the stop pattern. When it is detected, the power transmission by the power transmission unit is stopped.

According to the present invention, there is provided a non-contact power feeding system capable of inexpensively transmitting and receiving information regarding power feeding of a power transmission device and a power receiving device.

It is a perspective view for demonstrating the non-contact power feeding system of 1st Example. It is the figure which looked at the non-contact power supply system from the side. It is a figure for demonstrating the functional configuration of the power transmission device provided in the case, the power receiving device provided in an eyeglass type terminal, and a power-source part. It is a flowchart explaining the power transmission process of a power transmission apparatus. It is a flowchart explaining the power receiving process of a power receiving device. It is a figure for demonstrating the power feeding process in a power transmission device and a power receiving device. It is a figure for demonstrating the non-contact power feeding system of a modification. It is a figure for demonstrating the non-contact power feeding system of 2nd Example. It is sectional drawing of a hearing aid. It is a figure for demonstrating the non-contact power feeding system of the modification of the 2nd Example. It is a figure for demonstrating the non-contact power supply system of 3rd Example. It is sectional drawing of the insertion part and the receiving part in the state which the insertion part was inserted into the receiving part.

FIG. 1 is a perspective view for explaining the non-contact power feeding system 10 of the first embodiment. FIG. 2 is a side view of the non-contact power feeding system 10. FIG. 2A shows a state in which the spectacle-type terminal 4 of the first embodiment is housed in the case 2 in a predetermined posture, and FIG. 2B is a modification of the first embodiment and is a modification of the first embodiment. Shows an example in which the postures of the housed eyeglass-type terminals 4 are different from those of the above.

The non-contact power feeding system 10 includes a power transmitting device 12 and a power receiving device 14. Further, a power supply unit (not shown) is connected to the power transmission device 12. Non-contact power feeding is performed by an electromagnetic resonance method or an electromagnetic induction method.

The power receiving device 14 is provided in the spectacle-type terminal 4, and the power transmission device 12 is provided in the case 2 accommodating the spectacle-type terminal 4. The case 2 shown in FIG. 1 is shown by omitting the side wall on the front side and a part of the lid 22. The glasses-type terminal 4 shown in FIG. 1 is housed in the case 2, but the lid 22 of the case 2 is open.

The spectacle-type terminal 4 includes a frame 40, a first arm portion 42, a second arm portion 44, a pair of lenses 45, and a power receiving device 14. The power receiving device 14 is built in the eyeglass-type terminal 4, and has a power receiving unit 46, a speaker 48, a light emitting unit 50, and the like, which will be described in detail later.

The frame 40 is longitudinal and extends laterally to support a pair of lenses 45. The first arm portion 42 and the second arm portion 44 are so-called temples, which are rotatably connected to the frame 40 and hung on the wearer's ear. The shape of the frame 40 is not limited to the longitudinal shape shown in FIG. 1, and may be a shape surrounding the lens 45.

The power receiving portion 46 is a coil in which a conducting wire is spirally wound, and is built in the tip end side of the first arm portion 42. The power receiving unit 46 is an antenna that receives power from the power transmission device 12 in a non-contact manner. By forming the power receiving portion 46 in a spiral shape, it can be easily accommodated in the longitudinal first arm portion 42 as compared with the case where the power receiving portion 46 is formed in a spiral shape. The speaker 48 is built in the tip end side of the second arm portion 44, and outputs sound to the eardrum of the wearer.

The light emitting unit 50 is provided on the frame 40 and can emit light toward the edge of the lens 45, and is, for example, a light emitting diode. Note that FIG. 1 shows a mode in which one light emitting unit 50 is provided for each of the left and right lenses 45, but the present invention is not limited to this mode, and a plurality of light emitting units 50 may be provided for one lens 45.

The light emitting unit 50 is controlled to emit light in any of a plurality of light emitting patterns, and by passing light through the lens 45 at the time of mounting, the wearer is made to visually recognize the light emitted by the light emitting unit 50, and some information is given to the wearer. Notice. The spectacle-type terminal 4 may notify the wearer of information by combining the sound emitted by the speaker 48 and the light emitted by the light emitting unit 50.

As a function other than notifying the wearer, the light emitting unit 50 emits light to the space inside the case 2 when it is housed in the case 2 and sends information on power supply to the power transmission device 12 on the case 2 side. The information regarding the power supply output by the light emitting unit 50 is, for example, information indicating the start of power reception and information indicating the completion of charging.

The case 2 is formed in a box shape and forms a storage space for accommodating the eyeglass-type terminal 4. The case 2 has a built-in power transmission device 12 and has a function of accommodating the spectacle-type terminal 4 and a function of supplying power to the spectacle-type terminal 4 in a non-contact manner. The case 2 has a lid 22 that closes the accommodation space of the eyeglass-type terminal 4, and an attitude control unit 36 that accommodates the circuit board 38 of the power transmission device 12.

As shown in FIG. 2A, the posture regulating portion 36 projects inward from the side wall of the case 2 and projects upward from the bottom 2a side inward. In the spectacle-type terminal 4 shown in FIG. 2A, the frame 40 is placed on the bottom portion 2a, the lens 45 is located above the frame 40, and the lens 45 is housed in a posture at a position away from the posture regulating portion 36. ..

This allows the frame 40 to approach the bottom 2a. The posture regulating unit 36 can regulate the posture of the eyeglass-type terminal 4 housed in the case 2, and can be configured so that it cannot be housed in any posture other than a predetermined posture, for example. Further, the lid 22 cannot be closed unless the eyeglass-type terminal 4 is in a predetermined posture. The posture regulating unit 36 determines the posture of the spectacle-type terminal 4 housed in the case 2, and the power receiving unit 46 can be arranged to face the power transmission unit 24, and the spectacle-type terminal 4 is housed in a posture other than the predetermined posture. You can prevent it from being done. In this way, the posture regulating unit 36 functions as a space for accommodating the circuit board 38 of the power transmission device 12, and functions as a regulating means for regulating the spectacle-type terminal 4 so as to have a predetermined posture.

The spectacle-type terminal 4 shown in FIG. 2B is accommodated in a posture in which the first arm portion 42 and the lens 45 are placed on the bottom portion 102a by the posture regulating unit 36, and the spectacle-type terminal 4 shown in FIG. The terminal 4 and the terminal 4 are housed in the opposite posture. As a result, the first arm portion 42 can approach the power transmission portion 24 at the bottom portion 102a. Further, in FIG. 2B, the case 102 is provided with the ceiling 102b, and the posture of the spectacle-type terminal 4 is further regulated, and the ceiling 102b functions as a means for regulating the posture of the spectacle-type terminal 4.

Return to FIG. The power transmission device 12 includes a power transmission unit 24, a light receiving unit 26, a connector 28, and the like, which will be described in detail later. The power transmission unit 24 is an antenna that transmits electric power to the power reception unit 46 in a non-contact manner. The power transmission unit 24 is a coil in which a conducting wire is spirally wound in a single layer, has an air core in the center, and is built in the bottom portion 2a of the case 2. By forming the power transmitting unit 24 into a single-layer spiral shape, the antenna can be made thin so that it can be easily provided on the bottom 2a, and the area where power can be supplied to the power receiving unit 46 can be widened. By forming the air core, the power transmission efficiency can be improved in the air core portion as compared with the antenna in which the lead wire is wound.

The connector 28 is formed on the side wall of the case 2 and connects to the power supply unit 16. The light receiving portion 26 is provided on the bottom portion 2a of the case 2, and is, for example, a photodiode, which detects light. By closing the lid 22 of the case 2, the light receiving unit 26 can accurately detect the light emission of the light emitting unit 50.

If the power receiving unit 46 is arranged outside the power transmission unit 24, the power transmission efficiency is lowered. Therefore, as shown in FIG. 1, the power receiving unit 46 hardly protrudes radially outward from the outermost diameter of the power transmission unit 24 on the power transmission unit 24. It is arranged so as to face the power transmission unit 24 in the axial direction of the power transmission unit 24.

Further, by enabling the spectacle-type terminal 4 to supply power in a non-contact manner, the spectacle-type terminal 4 can eliminate the need for a connector hole for power supply, and the waterproofness of the spectacle-type terminal 4 can be improved.

FIG. 3 is a diagram for explaining the functional configurations of the power transmission device 12 provided in the case 2, the power receiving device 14 provided in the eyeglass-type terminal 4, and the power supply unit 16. In the embodiment, the power supply unit 16 is a DC power supply, but in the modified example, it may be an AC power supply.

The power transmission device 12 includes a power transmission unit 24, a light receiving unit 26, a connector 28, an inverter 30, an oscillation unit 32, and a power transmission control unit 34. The light receiving unit 26 functions as a detection unit that detects light, and the power transmission control unit 34 controls the power transmission of the power transmission unit 24 based on the detection result of the light receiving unit 26. Further, when the power supply unit 16 is connected to the connector 28, the power transmission control unit 34 causes the power transmission unit 24 to transmit power until at least a predetermined confirmation time, and waits for a response from the power receiving device 14. The predetermined confirmation time is set to several minutes or less, and may be set based on the time required from the empty state to the light emission of the spectacle-type terminal 4.

The power transmission control unit 34 detects whether the light emission pattern received by the light receiving unit 26 is a confirmation pattern or a stop pattern. When the light receiving unit 26 detects the light of the confirmation pattern, the power transmission control unit 34 executes the power transmission of the power transmission unit 24, and the light receiving unit 26 detects the light of the confirmation pattern within a predetermined confirmation time from the start of power transmission. If not, the power transmission unit 24 is controlled so as not to execute power transmission. Further, when the light receiving unit 26 detects the light of the stop pattern, the power transmission control unit 34 stops the power transmission of the power transmission unit 24, assuming that the charging of the power receiving device 14 is completed.

The oscillating unit 32 sets the DC current sent from the power supply unit 16 to a frequency in a preset range. The inverter 30 converts the direct current sent from the oscillator 32 into an alternating current. The oscillating unit 32 and the inverter 30 can vibrate the power transmission unit 24 at a resonance frequency.

The power receiving device 14 includes a power receiving unit 46, a speaker 48, a light emitting unit 50, a rectifying unit 52, a regulator 54, a charging control unit 56, a power storage unit 58, an output control unit 60, and a communication unit 62.

The rectifying unit 52 converts the current received by the power receiving unit 46 from alternating current to direct current. The regulator 54 keeps the voltage of the rectified current constant. The power storage unit 58 stores DC power having a voltage that is received by the power receiving unit 46 and stabilized by the rectifying unit 52 and the regulator 54.

The charge control unit 56 detects that the power receiving unit 46 is receiving power, and detects whether the power storage unit 58 is fully charged. The charge control unit 56 may detect the amount of electricity stored in the electricity storage unit 58. When the charge control unit 56 detects that the power receiving unit 46 has started receiving power, the charge control unit 56 executes control to make the light emitting unit 50 emit light in a confirmation pattern. As a result, information indicating that power reception has started can be output to the power transmission device 12.

Further, the charge control unit 56 executes control to make the light emitting unit 50 emit light in a stop pattern when a predetermined charging condition is satisfied. The predetermined charging condition is satisfied, for example, when the power storage unit 58 is fully charged and charging is completed, or when the power storage amount of the power storage unit 58 exceeds a predetermined threshold value, and the charge control unit 56 is the power storage unit 58. It monitors the voltage and the like to determine whether a predetermined charging condition is satisfied. As a result, information indicating that charging is completed can be output to the power transmission device 12 by light. In this way, the charge control unit 56 causes the light emitting unit 50 to output information regarding the start and end of charging to the space.

At least one of the number of blinks, the interval between blinks, and the emission time is different between the light emission of the confirmation pattern and the light emission of the stop pattern, and the power transmission control unit 34 determines the confirmation pattern and the stop pattern from the detection result of the light receiving unit 26. It is possible to determine which of the light emission is used.

The output control unit 60 controls the outputs of the light emitting unit 50 and the speaker 48 by using the electric power of the power storage unit 58, and notifies the wearer of information using light or sound from the light emitting unit 50 and the speaker 48.

For example, when the output control unit 60 receives information indicating that an email has been received from the mobile terminal, the scheduled time has been reached, an incoming call, or the like via the communication unit 62, the output control unit 60 emits light in any of the light emission patterns. The output of the light emitting unit 50 is controlled so as to do so. Different light emission patterns are preset according to the signals transmitted from the mobile terminal, such as the receipt of an e-mail and the arrival of the set time of the schedule. The output control unit 60 holds information on a plurality of light emission patterns having different colors, blinking times, and lighting times. The light emitting unit 50 outputs light toward the lens 45 of the spectacle-type terminal 4 to show the wearer of the spectacle-type terminal 4 one of a plurality of light emission patterns.

The output control unit 60 controls not only the output of the light emitting unit 50 but also the output of the speaker 48, and outputs the sound of the wearer according to the information received from the mobile terminal. For example, the output control unit 60 may execute a control of blinking the light emitting unit 50 according to the tempo of the music information while outputting the music information transmitted from the mobile terminal from the speaker 48. This can entertain the wearer. Further, the output control unit 60 may transmit information regarding the charge amount of the power storage unit 58 to the mobile terminal via the communication unit 62.

In this way, the light emitting unit 50 outputs light information to the wearer under the control of the output control unit 60, and outputs light information to the power transmission device 12 under the control of the charge control unit 56. By notifying the power transmission device 12 of information regarding power supply using the light emitting unit 50 provided in advance in the spectacle-type terminal 4, it is possible to share the parts to be notified to the wearer and the power transmission device 12, and the non-contact power supply system 10 Cost can be suppressed. In particular, since the power transmission device 12 can eliminate the need for a communication function, information on power supply from the power reception device 14 by the light receiving unit 26, which is much cheaper than the case where the power transmission device 12 is provided with a communication function such as Bluetooth (registered trademark). Will be able to receive.

When the light receiving unit 26 continuously detects light emission of a predetermined threshold value or more, the power transmission control unit 34 may not close the lid 22. Therefore, even if the power supply unit 16 is connected to the connector 28, the power transmission control unit 34 may not be closed. , It is not necessary to start power transmission by the power transmission unit 24.

FIG. 4 is a flowchart illustrating a power transmission process of the power transmission device 12. When the power supply unit 16 is connected to the connector 28 (S10), the power transmission control unit 34 of the power transmission device 12 executes control to transmit power from the power transmission unit 24 (S12).

After temporarily transmitting power to the power transmission unit 24, the power transmission control unit 34 determines whether the light receiving unit 26 has received the light of the confirmation pattern within a predetermined confirmation time (S14). The light of the confirmation pattern is a signal indicating that the power receiving device 14 has started receiving power, and is a signal indicating that the power receiving device 14 is in a position where it can receive power. If the light receiving unit 26 does not receive the light of the confirmation pattern by the predetermined confirmation time (N in S14), the power transmission is terminated (S24). An indicator lamp may be provided on the outer surface of the case 2 to indicate the presence or absence of power supply. For example, the indicator lamp lights up in red during power supply, lights up in green when charging is completed, and does not light up when power supply is not possible.

If the light receiving unit 26 detects the light of the confirmation pattern (Y in S14), it can detect that the power receiving device 14 is housed in a predetermined posture, that is, that it is being charged, so that the power transmission control unit 34 can detect the light. A predetermined charging time is set (S16), control for transmitting power from the power transmission unit 24 is continued (S18), and counting of the charging time is started.

The power transmission control unit 34 determines whether the light receiving unit 26 has detected the light of the stop pattern (S20). The light of the stop pattern is a signal indicating that the power receiving device 14 has been charged. If the light receiving unit 26 detects the light of the stop pattern (Y in S20), the power transmission control unit 34 ends the power transmission (S24) and ends the power transmission process.

If the light receiving unit 26 does not detect the light of the stop pattern (N in S20), the power transmission control unit 34 determines whether the set charging time has elapsed (S22). If the charging time has not elapsed (N in S22), the power transmission control unit 34 again determines whether the light receiving unit 26 has detected the light of the stop pattern (S20). If the charging time has elapsed (Y in S22), the power transmission control unit 34 ends the power transmission (S24) and finishes the power transmission process. By setting the charging time, for example, when the eyeglass-type terminal 4 is taken out from the case 2 during power transmission, power can be saved.

FIG. 5 is a flowchart illustrating a power receiving process of the power receiving device 14. The charge control unit 56 determines whether or not it has detected that the power receiving unit 46 has started receiving power (S30). If the power receiving unit 46 does not start receiving power (N in S30), the charge control unit 56 ends the power receiving process.

If it detects that the power receiving unit 46 has started receiving power (Y in S30), the charge control unit 56 executes the first light emission control for causing the light emitting unit 50 to emit light in a confirmation pattern (S32). The charge control unit 56 determines whether or not the charge of the power storage unit 58 is completed (S36).

The charge control unit 56 continues to detect the completion of charging if the charging of the power storage unit 58 is not completed (N in S36), and if the charging of the power storage unit 58 is completed (Y in S36), the second The light emission control is executed, the light emitting unit 50 emits a stop pattern (S38), and the power receiving process is completed.

FIG. 6 is a diagram for explaining the power feeding process in the power transmitting device 12 and the power receiving device 14. With the spectacle-type terminal 4 housed in the case 2, the power transmission control unit 34 executes power transmission with the power transmission unit 16 connected to the connector 28 as a trigger (S50) (S52).

When the power receiving unit 46 starts receiving power (S54) and the charging control unit 56 detects the start of power receiving, the first light emitting control is executed and the light emitting unit 50 emits light in a confirmation pattern (S56).

When the light receiving unit 26 receives the confirmation pattern (S58) and the power transmission control unit 34 detects that the confirmation pattern is used, it starts counting the preset charging time (S60).

When the charging of the power storage unit 58 is completed (S62) and the charge control unit 56 detects that the predetermined charging condition is satisfied, the second light emission control is executed and the light emitting unit 50 emits light in a stop pattern (S64). ..

When the light receiving unit 26 receives the stop pattern (S66) and the power transmission control unit 34 detects that the stop pattern is used, the power transmission unit 24 terminates the power transmission (S68) and resets the charging time (S70). In this way, the power supply processing to the eyeglass-type terminal 4 can be executed without providing the communication function in the case 2.

FIG. 7 is a diagram for explaining a modified non-contact power feeding system 200. In the non-contact power feeding system 200 of the modified example, the position of the power receiving unit 246 is different from that of the non-contact power feeding system 10 shown in FIG. 1, and the sound output from the speaker 48 is different in that information on power feeding is transmitted.

The power receiving portion 246 is formed not on the arm portion but on the frame 40. When the spectacle-type terminal 4 is housed in the case 2 in a predetermined posture, the power receiving unit 246 is located above the power transmission unit 224 and is arranged so as to face each other.

The speaker 48 outputs information regarding the start and end of charging instead of the light emitting unit 50, and transmits information regarding power supply to the detection unit 226 of the case 2. The charge control unit 56 of the spectacle-type terminal 4 executes control to vibrate the speaker 48 in a predetermined confirmation pattern or stop pattern. The case 2 has a detection unit 226 that detects sound instead of the light receiving unit 26. In this way, by making the speaker 48 function as an output unit for outputting information related to power supply, the parts that notify the wearer and the parts that notify the power transmission device 12 of the case 2 are shared, and the non-contact power supply system 10 Cost can be suppressed.

FIG. 8 is a diagram for explaining the non-contact power feeding system 300 of the second embodiment. In the non-contact power feeding system 300 of the second embodiment, the power receiving device 314 is provided in the hearing aid 304, and the power transmitting device 312 is provided in the case 302. In recent years, hearing aids have been miniaturized to be inconspicuous, requiring detailed work to replace batteries. Therefore, by feeding the hearing aid 304 in a non-contact manner, the work of battery replacement can be eliminated.

Further, the hearing aid 304 outputs sound by using an output unit including a speaker provided in advance, and transmits information regarding power supply to the power transmission device 312 of the case 302. As a result, if the case 302 is provided with the detection unit 326 for detecting sound, the power supply process can be reliably executed without newly providing the communication function in the hearing aid 304 and the case 302, and the cost of the non-contact power supply system 300 can be suppressed. ..

The case 302 has a recess 70 for placing the hearing aid 304 in a predetermined posture. The recess 70 is formed to be recessed according to the outer shape of the hearing aid 304. The pair of recesses 70 are formed according to the hearing aid 304 for the left ear and the hearing aid 304 for the right ear, respectively. The recess 70 for the left ear does not fit the hearing aid 304 for the right ear, and the recess 70 for the right ear. The hearing aid 304 for the left ear may be formed so as not to fit in the. The power transmission device 312 built in the case 302 has the same configuration as the non-contact power supply system 200 shown in FIG. 7, and has a pair of power transmission units 324, detection unit 326, connector 28, inverter 30, oscillation unit 32, and power transmission control. It has a part 34.

The power transmission unit 324 is provided for each pair of hearing aids 304 and transmits power to the hearing aids 304. The detection unit 326 is arranged in the vicinity of the ear pad 90 and detects the sound output from the ear pad 90. Each ear pad 90 is placed in close proximity. The hearing aid 304 will be described with reference to the new drawings.

FIG. 9 is a cross-sectional view of the hearing aid 304. The hearing aid 304 includes a power receiving unit 346, a charging control unit 56, a power storage unit 58, a magnetic sheet 72, an overcoat 74, a sound conduit 76, a speaker 78, a microphone 80, a sound generating unit 84, an amplification unit 86, wiring 88, and an ear pad 90. Has.

The microphone 80 detects an external sound and sends it as a sound signal to the amplification unit 86. The amplification unit 86 amplifies the sound signal detected by the microphone 80 and sends it to the speaker 78. The speaker 78 outputs sound to the sound conduit 76 based on the sound signal amplified by the amplification unit 86.

The sound conduit 76 is a hollow and flexible tube that transmits the sound output by the speaker 78. The ear pad 90 is inserted into the wearer's ear and outputs the sound output from the speaker 78 via the sound conduit 76. In this way, the hearing aid 304 amplifies the sound detected by the microphone 80 and outputs it from the ear pad 90. Sound is output to the eardrum of the hearing aid wearer by the speaker 78.

The power receiving unit 346 is a coil formed in a spiral shape by winding a conducting wire around the outer circumference of the sound conduit 76. By forming the power receiving portion 346 in a spiral shape, it can be easily provided on the outer periphery of the sound conduit 76. Further, by providing the power receiving unit 346 on the outer periphery of the sound conduit 76, the axial length of the power receiving unit 346, that is, the coil length can be lengthened, and the power transmission efficiency can be improved. Further, by providing the power receiving unit 346 on the outer periphery of the sound conduit 76, the power receiving unit 346 can be arranged away from the electronic circuit of the hearing aid 304 and the power storage unit 58. The magnetic sheet 72 is a tubular magnetic material arranged inside the power receiving unit 346. The overcoat 74 covers the magnetic sheet 72 and the power receiving portion 346 and is fixed to the outer peripheral surface of the sound conduit 76. The wiring 88 connects the power receiving unit 346 and the power storage unit 58.

When the charge control unit 56 detects that the power receiving unit 346 has started receiving power, the charge control unit 56 executes control to vibrate the speaker 78 in a confirmation pattern. Further, the charge control unit 56 executes control to vibrate the speaker 78 in a stop pattern when a predetermined charge condition is satisfied. The sound sources of the confirmation pattern and the stop pattern are held by the sound generation unit 84. The sound of the confirmation pattern and the stop pattern may be set to exceed the audible frequency so that the user cannot hear the sound.

The sound of the confirmation pattern and the sound of the stop pattern differ in at least one of frequency, amplitude, number of outputs, output interval and output time, and the power transmission control unit 34 determines the confirmation pattern and the sound of the detection pattern from the detection result of the detection unit 326. It is possible to determine which of the sounds of the stop pattern. The sound of the confirmation pattern and the sound of the stop pattern may be different between the pair of left and right hearing aids 304, and the sound of the confirmation pattern and the sound of the stop pattern output from either the left or right hearing aid 304 by the power transmission control unit 34. It may be possible to determine whether or not there is.

Return to FIG. When the hearing aid 304 is placed in a predetermined posture, the power receiving unit 346 is arranged so as to face the power transmission unit 324 and is placed above the power transmission unit 324. As a result, the power receiving unit 346 can sufficiently receive power from the power transmission unit 324. That is, if the hearing aid 304 is placed so as to fit in the recess 70 of the case 302, the power transmission unit 324 and the power reception unit 346 are in a predetermined posture facing each other so that power can be supplied, and non-contact power supply can be realized.

FIG. 10 is a diagram for explaining a non-contact power feeding system of a modified example of the second embodiment. The non-contact power supply system of the modified example is different from the non-contact power supply system 300 shown in FIG. 8 in that the arrangement of the hearing aid 304 is different and the power transmission unit 324 is configured by one.

With the pair of hearing aids 304 mounted in the recess 70, the pair of power receiving units 346 are arranged close to each other and located above one power transmission unit 324. As a result, power can be supplied from one power transmission unit 324 to a pair of power reception units 346.

The case 2 is provided with detection units 326a and 326b for detecting sound for each ear pad 90, respectively. As a result, information regarding the power supply of both hearing aids 304 can be individually acquired depending on which detection unit 326a or 326b detects the sound.

FIG. 11 is a diagram for explaining the non-contact power feeding system 400 of the third embodiment. In the non-contact power supply system 400 of the third embodiment, the power receiving device 414 is provided on the unmanned aerial vehicle 404, and the power transmission device 412 is provided on the pedestal 402.

The unmanned aerial vehicle 404 is a small propeller airplane called a so-called drone, and flight control is performed by remote control. A plurality of legs 92 are provided at the lower part of the unmanned aerial vehicle 404, and can be seated on the pedestal 402 or the ground.

The insertion portion 96 protrudes from the center of the lower part of the unmanned aerial vehicle 404, and extends downward in a rod shape. The insertion unit 96 is provided with a power receiving unit 446 and a light emitting unit 450 of the power receiving device 414.

The receiving portion 94 is provided in a tubular shape in the center of the pedestal 402 and opens upward. The receiving portion 94 is formed to have a diameter slightly larger than that of the inserting portion 96 so as to accept the inserting portion 96. The receiving unit 94 is provided with a power transmission unit 424. The tip end side of the receiving portion 94 is formed in a conical shape whose diameter increases upward, and the insertion portion 96 can be easily inserted.

FIG. 12 is a cross-sectional view of the insertion portion 96 and the receiving portion 94 in a state where the insertion portion 96 is inserted into the receiving portion 94. In FIG. 12, the leg portion 92 of the unmanned aerial vehicle 404 is seated on the seat surface of the pedestal 402, and the insertion portion 96 is inserted into the receiving portion 94.

Since the insertion unit 96 is inserted into the receiving unit 94, its movement in the radial direction is restricted, and it is possible to prevent the power receiving unit 446 and the power transmitting unit 424 from being displaced in the radial direction from being unable to supply power. Further, if the insertion portion 96 is inserted into the receiving portion 94, the unmanned aerial vehicle 404 will be in a posture capable of supplying power to the pedestal 402 at any rotational position.

The light emitting unit 450 is provided on the tip end side of the insertion unit 96 and is wired to the substrate of the power receiving device 414. The light emitting unit 450 is turned on at night to indicate the position of the unmanned aerial vehicle 404. Further, the light emitting unit 450 is turned on to send information regarding power supply to the power transmission device 412. As described above, by using the light emitting unit 450 provided in advance of the unmanned aerial vehicle 404 for transmitting information regarding power supply, the cost of the contactless power supply system 400 can be suppressed.

The power receiving portion 446 is formed in a spiral shape by winding a lead wire around the outer peripheral surface of the insertion portion 96. A tubular magnetic sheet 98 is provided inside the power receiving unit 446. Further, the power receiving portion 446 and the magnetic sheet 98 are fixed to a part of the outer peripheral surface of the insertion portion 96 by an overcoat. The power receiving unit 446 is wired on the substrate of the power receiving device 414 and sends the received power to the power storage unit 58.

The power transmission unit 424 is formed in a spiral shape by winding a lead wire around the outer peripheral surface of the reception unit 94, and is fixed to a part of the reception unit 94 by an overcoat. The power transmission unit 424 is wired on the substrate of the power transmission device 412. By forming both the power transmission unit 424 and the power reception unit 446 in a spiral shape, the power supply efficiency can be improved.

The light receiving unit 426 is provided at the bottom of the receiving unit 94 in order to detect the light in the receiving unit 94. The light receiving unit 426 sends the light detection result to the power transmission control unit 34. By providing the light receiving unit 426 inside the tubular receiving unit 94, the light emitting pattern of the light emitting unit 450 can be accurately detected even if the outside of the receiving unit 94 is bright. In particular, by arranging the light emitting unit 450 on the tip side of the insertion unit 96 and the light receiving unit 426 on the bottom side of the receiving unit 94, the light emitting unit 450 and the light receiving unit 426 are arranged close to each other on the back side of the receiving unit 94. The light emitting pattern of the light emitting unit 450 can be detected with higher accuracy.

As shown in FIG. 12, the power receiving unit 446 is located above the power transmission unit 424 with the legs 92 seated on the pedestal 402. By shifting the positions of the power receiving unit 446 and the power transmitting unit 424 in the axial direction in this way, the power feeding efficiency can be improved as compared with the case where the power receiving unit 446 and the power transmitting unit 424 are positioned at the same axial height. Further, in the modified example, the center position of the power receiving unit 446 and the center position of the light receiving unit 426 are displaced in the axial direction by at least half of the axial length of the power receiving unit 446, for example, even if the parts of half or less overlap. Good.

In the modified example of the third embodiment, the power receiving unit 446 may be provided on the tip end side of the leg portion 92, and the power transmission unit 424 may be built in the seat surface of the pedestal 402. According to this modification, if the unmanned aerial vehicle 404 is seated on the pedestal 402 at a predetermined position, the power receiving unit 446 and the power transmitting unit 424 are arranged to face each other, and power can be supplied.

The present invention is not limited to each of the above-described embodiments, and modifications such as various design changes can be added to each embodiment based on the knowledge of those skilled in the art, and such modifications are added. The examples given may also be included in the scope of the present invention.

In the modified example, the power transmission device 12 may have a switch between the power transmission control unit 34 and the connector 28. For example, the switch is turned on / off according to the opening / closing of the lid 22 and turned on when the lid 22 is closed. The power transmission device 12 starts power transmission when the switch is turned on, and stops power transmission when the switch is turned off. Further, the switch may be a button provided on the outer surface of the case 2.

In the embodiment, a mode is shown in which the light emitting unit 50 of the power receiving device 14 outputs the light of the confirmation pattern to the power transmission device 12 when the start of power receiving from the power transmission device 12 is detected, but the present invention is not limited to this mode. For example, when the user inputs an instruction to start charging the power receiving device 14 from the mobile terminal and the power receiving device 14 receives an instruction signal to start charging from the communication unit 62, the light emitting unit 50 confirms the pattern. Light may be output. The power transmission device 12 starts power transmission to the power receiving device 14 triggered by detecting the light of the confirmation pattern.

In the embodiment, if the power transmission device 12 does not detect the light of the confirmation pattern within the predetermined confirmation time, the power transmission is terminated without continuing. If the light of the confirmation pattern is detected after the power transmission is finished, the power transmission may be restarted. For example, when the detection unit detects the light of the confirmation pattern after the confirmation time has elapsed, the power transmission device 12 restarts the power transmission. When the power receiving device 14 detects that the power receiving is completed before the charging is completed, the power receiving device 14 may output the light of the confirmation pattern.

2 cases, 4 eyeglass type terminals, 10 non-contact power supply system, 12 power transmission device, 14 power transmission device, 16 power supply unit, 22 lid, 24 power transmission unit, 26 light receiving unit, 28 connector, 30 inverter, 32 oscillator, 34 power transmission control Part, 36 Attitude control part, 38 Circuit board, 40 frame, 42 1st arm part, 44 2nd arm part, 45 lens, 46 Power receiving part, 48 Speaker, 50 Light emitting part, 52 Rectifier part, 54 Regulator, 56 Charging control Unit, 58 power storage unit, 60 output control unit, 62 communication unit.

Claims (6)

A power transmission device that can transmit electric power and
A power receiving device that receives electric power from the power transmitting device is provided.
The power transmission device
A power transmission unit that transmits power to the power receiving device,
A detector that detects light and
It has a power transmission control unit that controls power transmission by the power transmission unit based on the detection result of the detection unit.
The power receiving device is
A power receiving unit that receives power from the power transmitting unit in a non-contact manner,
A power storage unit that stores the power received by the power receiving unit,
An output unit that outputs light to space,
It has a charge control unit that controls the output of the output unit.
The charge control unit controls to output the light of a predetermined stop pattern from the output unit when a predetermined charge condition is satisfied.
When the detection unit detects the light of the stop pattern, the power transmission control unit stops the power transmission by the power transmission unit.
The power receiving device is provided on a spectacle-type terminal and is provided.
The power transmission device is provided in a case for accommodating the eyeglass-type terminal.
The case has a lid for closing the accommodation space of the eyeglass-type terminal.
The lid provides a storage space for the case when the spectacle-shaped terminal is housed in the case in a posture in which the power receiving unit faces the power transmission unit in the axial direction of the power transmission unit. A non-contact power supply system characterized by being configured to block. A power transmission device that can transmit electric power and
A power receiving device that receives electric power from the power transmitting device is provided.
The power transmission device
A power transmission unit that transmits power to the power receiving device,
A detector that detects light and
It has a power transmission control unit that controls power transmission by the power transmission unit based on the detection result of the detection unit.
The power receiving device is
A power receiving unit that receives power from the power transmitting unit in a non-contact manner,
A power storage unit that stores the power received by the power receiving unit,
An output unit that outputs light to space,
It has a charge control unit that controls the output of the output unit.
The charge control unit controls to output the light of a predetermined stop pattern from the output unit when a predetermined charge condition is satisfied.
When the detection unit detects the light of the stop pattern, the power transmission control unit stops the power transmission by the power transmission unit.
The power receiving device is provided on an unmanned aerial vehicle.
The power transmission device is provided on a pedestal on which the unmanned aerial vehicle can be seated.
The output unit is lit to indicate the position of the unmanned aerial vehicle.
The pedestal has a tubular receiving portion that projects upward from the seat surface.
The unmanned aerial vehicle has an insertion portion that projects downward and is inserted into the receiving portion.
The power receiving portion is spirally formed in the insertion portion.
A non-contact power feeding system characterized in that the power transmission unit is spirally formed in the receiving unit and is positioned axially offset from the power receiving unit in a state where the insertion unit is inserted into the receiving unit. The charge control unit controls to output light of a confirmation pattern different from the stop pattern from the output unit.
The non-contact power supply according to claim 1 or 2, wherein the power transmission control unit controls not to execute power transmission of the power transmission unit when the detection unit does not detect light of the confirmation pattern. system. The power transmission control unit controls to continue or start the power transmission of the power transmission unit when the detection unit detects the light of the confirmation pattern within a predetermined time after the power transmission by the power transmission unit is started. The non-contact power transmission system according to claim 3. The first aspect of claim 1, wherein the output unit is used to output light toward the lens of the spectacle-type terminal to show one of a plurality of patterns to the wearer of the spectacle-type terminal. Contactless power supply system. The non-contact power supply system according to claim 5, wherein the spectacle-type terminal further includes an output control unit that controls the output unit to output light of any of a plurality of patterns.

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