WO2015125539A1 - Power transmission system - Google Patents

Abstract

A power transmission system (1) transmits power from a power transmission device (101) to a power reception device (201) by electric coupling. In the power transmission system (1), the power transmission device (101) comprises: a step-up transformer (T1) for stepping up the AC voltage output from an inverter circuit (12) and applying to an active electrode (13) and a passive electrode (14); and a parallel resonant circuit configured by including part of the step-up transformer. The power reception device (201) comprises: a piezoelectric transformer (22) for stepping down the voltage induced on an active electrode (23) and a passive electrode (24); and a series resonant circuit including the piezoelectric transformer (22) and having the same resonant frequency as the parallel resonant circuit. The power transmission device (101) sweeps driving frequency to detect the resonant frequency of the parallel resonant circuit and the series resonant circuit and sets the detected resonant frequency as the driving frequency at a predetermined cycle to PWM control the inverter circuit (12). This provides a power transmission system for transmitting power while avoiding the reduction of transmission efficiency.

Description

Power transmission system

The present invention relates to a power transmission system that wirelessly transmits power from a power transmission device to a power reception device.

As a power transmission system, there is an electric field coupling system in which power is transmitted by electric field coupling between an electrode of a power transmission device and an electrode of a power reception device. Patent Document 1 discloses an electric field coupling type power transmission system, in which a power transmission drive frequency is set in order to increase power transmission efficiency from a power transmission device to a power reception device. In the power transmission system described in Patent Document 1, a resonance circuit is provided in each of the power transmission device and the power reception device, and a frequency sweep is performed in a state where the power reception device is mounted on the power transmission device to search for a resonance frequency (peak value of the drive voltage). The drive frequency is set from the resonance frequency obtained by the search, and the power is transmitted to the power receiving apparatus.

In the power transmission system described in Patent Document 1, the resonance circuit includes a capacitance of the coupling portion of the power transmission device and the power reception device, and an inductor. The power receiving device of the power transmission system is required to be small and thin. Therefore, it is conceivable to use a piezoelectric device (piezoelectric resonator, piezoelectric transformer) for the inductor.

Patent Document 2 discloses a power transmission system using a piezoelectric transformer for stepping down a power receiving device. In the power transmission system according to Patent Document 2, the first resonance circuit and the second resonance circuit are configured in the power receiving device, and a high frequency high voltage frequency generated by the power transmission device is combined with the two resonance circuits. It is set between two resonance frequencies due to resonance. Thus, the ratio between the power receiving device side voltage and the power transmitting device side voltage when load variation or drive frequency variation of the power receiving device occurs can be stabilized.

JP 2012-70614 A International Publication 2012/172929 Pamphlet

However, when a piezoelectric transformer is used as in Patent Document 2, the characteristics of the piezoelectric transformer change due to a temperature change during power transmission, which may cause the resonance condition to shift. If the resonance condition is deviated, there is a problem that high transmission efficiency cannot be obtained even if power transmission is performed at the drive frequency set in the resonance condition before the deviation.

Therefore, an object of the present invention is to provide a power transmission system that performs power transmission while avoiding a decrease in transmission efficiency.

According to the present invention, power is transmitted from the power transmitting device to the power receiving device by electric field coupling between the power transmitting side first electrode and the power transmitting side second electrode of the power transmitting device and the power receiving side first electrode and the power receiving side second electrode of the power receiving device. In the power transmission system for transmission, the power transmission device includes an inverter circuit that converts a DC voltage output from a DC power source into an AC voltage, a PWM control circuit that PWM-controls the inverter circuit at a set drive frequency, and the inverter A step-up transformer that boosts an alternating voltage output from the circuit and applies the boosted voltage to the power transmission side first electrode and the power transmission side second electrode; the step-up transformer; the power transmission side first electrode; and the power transmission side second electrode; A first resonance circuit connected between the step-up transformer and a part of the step-up transformer, and the power reception device includes the power reception side first electrode and the power reception side second power. A piezoelectric transformer for stepping down a voltage induced by the second transformer circuit, and a second resonant circuit configured to include a part of an equivalent circuit of the piezoelectric transformer and having the same resonant frequency as the first resonant circuit, The power transmission device sweeps the drive frequency and detects a resonance frequency of the first resonance circuit and the second resonance circuit, and a resonance detected by the resonance frequency detection unit at a predetermined period. And a drive frequency setting unit that sets the frequency to the drive frequency.

When a piezoelectric transformer is used, due to self-heating with the passage of time, the characteristic change of the resonance condition changes and the drive frequency shifts, resulting in a decrease in transmission efficiency. However, in the configuration of the present invention, the drive frequency is set at a predetermined cycle. By doing so, it is possible to avoid a decrease in transmission efficiency.

The drive frequency setting unit preferably lengthens the predetermined period as the amount of change in the resonance frequency detected by the resonance frequency detection unit at different timings decreases.

In this configuration, if the amount of change in the resonance frequency is small, it is possible to avoid unnecessary power transmission by preventing the influence of unnecessary noise associated with power transmission by extending the period for setting the drive frequency.

The power transmission device includes a current detection unit that detects a current flowing through the inverter circuit, and the resonance frequency detection unit has a frequency characteristic of a current value detected by the current detection unit when the drive frequency is swept. It is preferable to detect the resonance frequency based on the above.

In this configuration, since the resonance frequency is detected by detecting the current flowing through the inverter circuit of the power transmission device, the resonance frequency can be detected without monitoring the state of the piezoelectric transformer on the power reception device side.

The power transmission device stores a transmission power detection unit that detects transmission power to be transmitted to the power receiving device, and a memory that stores detection conditions for the resonance frequencies of the first resonance circuit and the second resonance circuit according to transmission power The resonance frequency detection unit acquires a detection condition according to the transmission power detected by the transmission power detection unit from the storage unit, and when the acquired detection condition and the drive frequency are swept It is preferable to detect the resonance frequency based on the frequency characteristic of the current value detected by the current detection unit.

Since the frequency characteristic of the current value detected by the current detector has a different characteristic curve depending on the transmission power, the resonance frequency detection condition corresponding to the transmission power is stored in advance as in the above configuration. Even if the power changes, an appropriate resonance frequency can be easily detected.

According to the present invention, it is possible to avoid a decrease in transmission efficiency by setting the drive frequency at a predetermined cycle.

Circuit diagram of power transmission system according to Embodiment 1 The figure which shows the equivalent circuit of FIG. Functional block diagram of control circuit The figure which shows the frequency characteristic of the transmission current IDC Perspective view of piezoelectric transformer Sectional view taken along line VI-VI in FIG. Sectional view taken along line VII-VII in FIG. The figure which shows the frequency characteristic of the ratio of the output voltage Vout of a receiving device with respect to the output voltage of a power transmission apparatus. The flowchart which shows the process which a control part performs Flow chart showing drive frequency setting process Circuit diagram of power transmission system according to Embodiment 2 The figure which shows the frequency characteristic of the transmission current IDC

(Embodiment 1)
FIG. 1 is a circuit diagram of a power transmission system according to the first embodiment. FIG. 2 is a diagram showing an equivalent circuit of FIG.

The power transmission system 1 according to this embodiment includes a power transmission device 101 and a power reception device 201. The power receiving apparatus 201 includes a load circuit RL. The load circuit RL includes a charging circuit and a secondary battery. And the power receiving apparatus 201 is a portable electronic device provided with the secondary battery, for example. Examples of portable electronic devices include cellular phones, PDAs (Personal Digital Assistants), portable music players, notebook PCs, and digital cameras. The power transmission device 101 is a charging stand for charging the secondary battery of the power receiving device 201 placed thereon.

The power transmission apparatus 101 includes a DC power supply 11 that outputs a DC voltage Vin. The DC power source 11 is an AC adapter connected to a commercial power source.

The inverter circuit 12 is connected to the DC power source 11. The inverter circuit 12 includes MOS-FET switching elements Q1, Q2, Q3, and Q4. In the inverter circuit 12, switch elements Q1 and Q2 are connected in series, and switch elements Q3 and Q4 are connected in series. Further, the connection point of the switch elements Q1, Q2 and the connection point of the switch elements Q3, Q4 are connected to the primary coil of the step-up transformer T1.

The switching elements Q1, Q2, Q3, and Q4 of the inverter circuit 12 are PWM-controlled by the PWM control circuit 15. In FIG. 2, the PWM control circuit 15 is not shown. The PWM control circuit 15 turns on and off the switch elements Q1 and Q4 and the switch elements Q2 and Q3 alternately. Thereby, the inverter circuit 12 converts the DC voltage Vin into an AC voltage.

The PWM control circuit 15 includes an error amplifier that amplifies the error voltage between the feedback voltage that varies according to the output voltage and the reference voltage and outputs an error voltage signal. Then, a PWM signal having a duty corresponding to the comparison result between the error voltage signal and the triangular wave is generated. The PWM control circuit 15 outputs the generated PWM signal to the gates of the switch elements Q1, Q2, Q3, and Q4.

The power transmission device 101 includes a control circuit 16. The control circuit 16 causes the PWM control circuit 15 to generate a PWM signal having a predetermined duty ratio. The control circuit 16 will be described in detail later.

The step-up transformer T1 has a secondary coil connected to the active electrode 13 and the passive electrode 14. The step-up transformer T1 steps up the AC voltage converted by the inverter circuit 12 and applies it to the active electrode 13 and the passive electrode 14. The active electrode 13 is an example of the “power transmission side first electrode” according to the present invention, and the passive electrode 14 is an example of the “power transmission side second electrode” according to the present invention.

Capacitors C21 and C22 (not shown in FIG. 2) are connected in series to the active electrode 13 and the passive electrode 14. The voltage V1 applied to the active electrode 13 and the passive electrode 14 is capacitively divided by the capacitors C21 and C22. The control circuit 16 rectifies the AC voltage divided in capacity and detects the voltage V1.

Further, a resistor R1 for current detection is connected to the passive electrode 14. The control circuit 16 detects a current I1 flowing through the resistor R1. The control circuit 16 acquires the power transmitted from the power transmission device 101 to the power reception device 201 from the current I1 and the voltage V1.

The capacitor C1 is connected in parallel to the secondary coil of the step-up transformer T1, and the capacitor C1 forms a parallel resonance circuit 17 (see FIG. 2) together with the secondary coil of the step-up transformer T1.

The power receiving apparatus 201 includes an active electrode 23 and a passive electrode 24. The active electrode 23 and the passive electrode 24 face the active electrode 13 and the passive electrode 14 of the power transmission device 101 with a gap when the power receiving device 201 is placed on the power transmission device 101. When a voltage is applied between the active electrode 13 and the passive electrode 14, the active electrodes 13 and 23 that are arranged to face each other are subjected to electric field coupling, and the electrode of the power transmission device 101 and the electrode of the power reception device 201 are not connected via this coupling. Power is transmitted from the power transmitting apparatus 101 to the power receiving apparatus 201 in a contact state.

The active electrode 23 is an example of a “power receiving side first electrode” according to the present invention, and the passive electrode 24 is an example of a “power receiving side second electrode” according to the present invention.

The piezoelectric transformer 22 is connected to the active electrode 23 and the passive electrode 24 of the power receiving apparatus 201. The piezoelectric transformer 22 has a pair of first input electrodes E11 and E12 and a pair of second input electrodes E21 and E22. The first input electrodes E11 and E12 are connected to the active electrode 23. The second input electrodes E21 and E22 are connected to the passive electrode 24.

The piezoelectric transformer 22 includes a pair of first output electrodes E31 and E32, a pair of second output electrodes E41 and E42, and a pair of third output electrodes E51 and E52. The first output electrodes E31 and E32, the second output electrodes E41 and E42, and the third output electrodes E51 and E52 are connected to the rectifying and smoothing circuit 25. The piezoelectric transformer 22 steps down the voltage input from the first input electrodes E11 and E12 and the second input electrodes E21 and E22, and the first output electrodes E31 and E32, the second output electrodes E41 and E42, and the third output electrode. Output from E51 and E52 to the rectifying and smoothing circuit 25.

As shown in FIG. 2, the piezoelectric transformer 22 is represented by a transformer T2, capacitors C21 and C22, a capacitor Cp, an inductor Lp, a resistor Rp, and the like. The capacitor C21 is an equivalent input capacity of the piezoelectric transformer 22, and the capacitor C22 is an equivalent output capacity of the piezoelectric transformer 22. The capacitor Cp and the inductor Lp are electromechanical parameters.

The resonance frequency of the piezoelectric transformer 22 is determined mainly by the resonance of the series resonance circuit 221 by the capacitor Cp and the inductor Lp. Since electrical energy conversion is via elastic vibration, it has a natural resonance frequency determined by the elastic wave propagation velocity and dimensions of the piezoelectric ceramic. The piezoelectric transformer 22 is designed such that the series resonance circuit 221 has the same resonance frequency as the parallel resonance circuit 17 formed on the power transmission device 101 side.

An inductor L 2 is connected to the output side of the piezoelectric transformer 22, and this inductor L 2 constitutes a parallel resonance circuit 222 with a capacitor C 22 that is an equivalent output capacity of the piezoelectric transformer 22. The inductor L2 has a circuit constant set so that the parallel resonant circuit 222 has the same resonance frequency as the parallel resonant circuit 17 and the series resonant circuit 221.

In addition, if electric power transmission is continued by the electric power transmission system 1, the piezoelectric transformer 22 will self-heat, and temperature will rise with progress of time. This heat generation affects the constants of each element equivalently expressed such as the capacitor Cp of the piezoelectric transformer 22. In the present embodiment, the series resonance circuit 221 and the parallel resonance circuit 222 are configured so as to have the same resonance frequency as that of the parallel resonance circuit 17 in a state where the piezoelectric transformer 22 is not generating heat (that is, in a state where the piezoelectric transformer 22 is cooled). A constant is set.

The voltage stepped down by the piezoelectric transformer 22 is output to the rectifying / smoothing circuit 25. The rectifying / smoothing circuit 25 includes a smoothing circuit including a capacitor and an inductor, a diode bridge, and a DC-DC converter that converts the voltage into a predetermined value and outputs the voltage. The rectifying / smoothing circuit 25 rectifies and smoothes the AC voltage and outputs it to the load circuit RL.

The output voltage output from the rectifying / smoothing circuit 25 to the load circuit RL is represented by Vout.

FIG. 3 is a functional block diagram of the control circuit 16. The control circuit 16 includes a microcomputer and has functions such as an IDC detection unit 161, a transmission power acquisition unit 162, a frequency control unit 163, a storage unit 164, and a control unit 165.

The IDC detection unit 161 detects the transmission current IDC. Specifically, a resistance R2 for current detection is connected between the DC power supply 11 and the inverter circuit 12, and the IDC detection unit 161 detects the transmission current IDC flowing through the inverter circuit 12 by the voltage drop of the resistance R2. . The IDC detection unit 161 corresponds to a “current detection unit” according to the present invention.

The transmission power acquisition unit 162 acquires the voltage V1 applied to the active electrode 13 and the passive electrode 14, and the current I1 flowing through the active electrode 13 and the passive electrode 14, and from the voltage V1 and the current I1, from the power transmission device 101. The transmission power to the power receiving apparatus 201 is acquired. The transmission power acquisition unit 162 is an example of the “transmission power detection unit” according to the present invention.

Note that the transmission power from the power transmission apparatus 101 to the power reception apparatus 201 may be obtained from the transmission current IDC detected by the IDC detection unit 161 and the input voltage Vin.

The frequency control unit 163 outputs the duty ratio to the PWM control circuit 15 so that the inverter circuit 12 is PWM-controlled at a predetermined drive frequency. The PWM control circuit 15 controls the inverter circuit 12 with the input duty ratio. Further, the frequency control unit 163 sweeps (sweeps) the frequency at which the PWM control circuit 15 controls driving of the inverter circuit 12. For example, when the PWM control circuit 15 performs PWM control of the inverter circuit 12 at a frequency of 470 kHz, the frequency ranges of 468, 469, 470, 471, 472 kHz and 470 ± 2 kHz are swept in increments of 1 kHz.

The storage unit 164 stores setting conditions (detection conditions) for setting the drive frequency. Specifically, the storage unit 164 stores a plurality of setting conditions according to the transmission power from the power transmission apparatus 101 to the power reception apparatus 201. This setting condition is used when the control unit 165 sets the drive frequency from the frequency characteristic of the transmission current IDC.

The control unit 165 controls the operations of the IDC detection unit 161, the transmission power acquisition unit 162, and the frequency control unit 163. The control unit 165 sets the drive frequency based on the power transmission current IDC detected by the IDC detection unit 161 when the frequency control unit 163 performs frequency sweep, that is, based on the frequency characteristics of the power transmission current IDC.

As shown in FIG. 4, the frequency characteristic of the transmission current IDC varies depending on the transmission power. FIG. 4 is a diagram illustrating frequency characteristics of the transmission current IDC. The horizontal axis in FIG. 4 is the frequency, and the vertical axis is the transmission current IDC, and shows characteristics when the load of the load circuit RL is changed. As shown in FIG. 4, the characteristic curve of the frequency characteristic varies depending on the size of the load.

In the setting conditions stored in the storage unit 164, for example, whether the frequency that takes the maximum value of the obtained characteristic curve of the frequency characteristic is set as the driving frequency or the frequency that takes the minimum value is set as the driving frequency. It has been established. The control unit 165 acquires the setting condition corresponding to the transmission power acquired by the transmission power acquisition unit 162 from the storage unit 164, and sets the drive frequency from the setting condition and the frequency characteristic of the transmission current IDC. Then, the frequency control unit 163 outputs a duty ratio to the PWM control circuit 15 so that the PWM control circuit 15 performs PWM control of the inverter circuit 12 at the drive frequency. Thus, since the setting conditions corresponding to the transmission power are stored in advance, an appropriate resonance frequency can be easily detected even if the transmission power changes.

The control unit 165 is an example of a “resonance frequency detection unit” and a “drive frequency setting unit” according to the present invention.

Hereinafter, the piezoelectric transformer 22 used in the power receiving apparatus 201 will be described.

FIG. 5 is a perspective view of the piezoelectric transformer 22. 6 is a cross-sectional view taken along line VI-VI in FIG. FIG. 7 is a sectional view taken along line VII-VII in FIG.

The piezoelectric transformer 22 includes a rectangular plate-shaped piezoelectric plate 30. The piezoelectric plate 30 is formed by stacking, for example, PZT ceramic sheets. Below, the length direction of the piezoelectric transformer 22 is the X-axis direction, the width direction is the Y-axis direction, and the thickness direction is the Z-axis direction. The piezoelectric transformer 22 vibrates in the length direction in the (7λ / 2) resonance mode. And Here, λ is one wavelength of vibration in the length direction. Therefore, the length of the piezoelectric transformer 22 in the X-axis direction is set to (7λ / 2). Here, the width in the Y-axis direction and the thickness in the Z-axis direction are preferably less than (λ / 2). By doing so, the vibration in the width direction and the thickness direction is not coupled to the vibration in the length direction, and the vibration of the entire piezoelectric transformer 22 is not unstable.

The piezoelectric plate 30 includes a first low voltage region 31, a first high voltage region 32, a second high voltage region 33, a second low voltage region 34, a third high voltage region 35, a fourth, along the X-axis direction. A high voltage region 36 and a third low voltage region 37 are formed. The lengths in the X-axis direction of the regions 31 to 37 are all λ / 2.

The first low voltage region 31, the second low voltage region 34, and the third low voltage region 37 are polarized in the Z-axis direction (thickness direction). The first low voltage region 31 and the third low voltage region 37 are polarized in the same direction, and the second low voltage region 34 is polarized in the opposite direction to the first low voltage region 31 and the third low voltage region 37. . Examples of the polarization treatment method include a method of applying a voltage of 2 kV / mm to the piezoelectric plate in insulating oil at 170 ° C.

In the first low voltage region 31, a pair of first output electrodes E31 and E32 are provided on the side surface of the piezoelectric plate 30 so as to face each other in the Y-axis direction. The first low voltage region 31 is provided with a plurality of internal electrodes E33 stacked in the Z-axis direction. As shown in FIG. 6, the internal electrodes E33 are alternately connected to the first output electrodes E31 and E32.

Similarly, in the second low voltage region 34 and the third low voltage region 37, the pair of second output electrodes E41 and E42 and the third output electrodes E51 and E52 are arranged so as to face each other in the Y-axis direction. It is provided on the side surface of the plate 30. The second low voltage region 34 and the third low voltage region 37 are provided with a plurality of internal electrodes E43 and E53 stacked in the Z-axis direction. The internal electrodes E43 are alternately connected to the second output electrodes E41 and E42, and the internal electrodes E53 are alternately connected to the third output electrodes E51 and E52.

The first high voltage region 32, the second high voltage region 33, the third high voltage region 35, and the fourth high voltage region 36 are polarized in the X-axis direction. In the first high voltage region 32, a pair of second input electrodes E21 and E22 are provided on the side surface of the piezoelectric plate 30 so as to face each other in the Y-axis direction. The first high voltage region 32 is provided with a plurality of internal electrodes E23 stacked in the Z-axis direction. The internal electrode E23 is connected to each of the second input electrodes E21 and E22.

In the fourth high voltage region 36, a pair of first input electrodes E11 and E12 are provided on the side surface of the piezoelectric plate 30 so as to face each other in the Y-axis direction. The fourth high voltage region 36 is provided with a plurality of internal electrodes E13 stacked in the Z-axis direction. The internal electrode E13 is connected to each of the first input electrodes E11 and E12.

In the piezoelectric transformer 22 configured as described above, the first input electrodes E11 and E12 are connected to the active electrode 23, and the second input electrodes E21 and E22 are connected to the passive electrode 24. When power is transmitted from the power transmitting apparatus 101 to the power receiving apparatus 201 and a voltage is induced in the active electrode 23 and the passive electrode 24, the first input electrodes E11 and E12 and the second input electrodes E21 and E22 cause the piezoelectric plate 30 to move in the X-axis direction. A voltage is applied in the length direction. Therefore, an electric field is applied to the first high voltage region 32, the second high voltage region 33, the third high voltage region 35, and the fourth high voltage region 36 in the polarization direction. Then, longitudinal vibration is excited in the direction orthogonal to the polarization direction by the inverse piezoelectric effect, that is, in the X-axis direction of the piezoelectric plate 30.

When longitudinal vibration is excited, mechanical distortion occurs in the Z-axis direction (polarization direction) in the first low-voltage region 31, the second low-voltage region 34, and the third low-voltage region 37, and in the polarization direction due to the piezoelectric transverse effect. A potential difference occurs. Due to this potential difference, the first low voltage region 31, the second low voltage region 34, and the third low voltage region 37 become a low voltage portion, and a low voltage is extracted from each electrode and applied to the load circuit RL.

In the power transmission system 1 configured as described above, the circuit constants are set so that the parallel resonant circuit 17, the series resonant circuit 221, and the parallel resonant circuit 222 have the same resonant frequency. In the present embodiment, the resonance frequency is 470 kHz. The drive frequency is determined by the resonance frequency. At the resonance frequency, the parallel resonance circuit 17 and the parallel resonance circuit 222 have high impedance (maximum), and the series resonance circuit 221 has low impedance (minimum). For this reason, the voltage drop in the parallel resonant circuit 17, the series resonant circuit 221 and the parallel resonant circuit 222, that is, the voltage drop between the inverter circuit 12 and the load circuit RL is small.

FIG. 8 is a diagram illustrating a frequency characteristic of a ratio (voltage conversion ratio) of the output voltage Vout of the power receiving device 201 with respect to the output voltage of the power transmitting device 101. In other words, the output voltage of the power transmission device 101 is a voltage V1 that is capacity-divided by the capacitors C21 and C22 and applied to the active electrode 13 and the passive electrode 14. The horizontal axis in FIG. 8 is the frequency, and the vertical axis is the transformation ratio (Vout / V1), which shows the characteristics when the load of the load circuit RL is changed.

In FIG. 8, when the frequency is about 470 kHz, the transformation ratio is substantially the same regardless of the load. Therefore, the circuit constant is set so that the resonance frequency of the parallel resonance circuit 17, the series resonance circuit 221 and the parallel resonance circuit 222 is about 470 kHz, and the resonance frequency is set as the drive frequency, so that the voltage is not related to the load fluctuation. Variation can be reduced. That is, efficient power transmission is possible regardless of load fluctuations.

As described above, since the piezoelectric transformer 22 self-heats by continuing to transmit power in the power transmission system 1, the resonance condition is deviated. For this reason, with the passage of time, the resonance frequency deviates from the drive frequency, and the transmission efficiency decreases. Therefore, in this embodiment, the resonance frequency is periodically detected and the drive frequency is corrected as needed.

The following explains how to set the drive frequency.

FIG. 9 is a flowchart showing processing executed by the control unit 165. The process illustrated in FIG. 9 is started, for example, when the power receiving apparatus 201 is placed on the power transmitting apparatus 101.

The control unit 165 executes the drive frequency setting process shown in FIG. 10 (S1). FIG. 10 is a flowchart showing the drive frequency setting process. The frequency control unit 163 performs PWM control on the switch elements Q1 to Q4 of the inverter circuit 12 and sweeps the frequency of the output voltage of the inverter circuit 12 (S11). For example, when the current frequency is 470 kHz, sweeping is performed in increments of 1 kHz from 468 kHz to 472 kHz, 468, 469, 470, 471, 472 kHz.

Each time the frequency control unit 163 performs a frequency sweep, the IDC detection unit 161 detects the transmission current IDC, and the control unit 165 acquires the frequency characteristics of the transmission current IDC (S12). The control unit 165 acquires transmission power from the power transmission apparatus 101 to the power reception apparatus 201 from the voltage V1 applied to the active electrode 13 and the passive electrode 14 and the current I1 flowing through the active electrode 13 and the passive electrode 14 (S13). ). The control unit 165 acquires a setting condition opposite to the transmission power from the storage unit 164 (S14). The control unit 165 sets the drive frequency from the frequency characteristic acquired in S12 and the setting condition acquired in S14 (S15).

The characteristic curve of the frequency characteristic of the transmission current IDC varies depending on the transmission power. For this reason, the resonance frequency is detected according to the setting condition corresponding to the transmission power, and the detected resonance frequency is set as the drive frequency. For example, in the frequency characteristic shown in FIG. 4, when the frequency characteristic obtained by the detection is the characteristic curve RC1, and the acquired setting condition is a condition that the maximum value of the obtained frequency is set as the drive frequency, FIG. The maximum value of the characteristic curve RC1 shown in FIG. 4, that is, the frequency of 470 kHz is set as the drive frequency. Further, when the frequency characteristic obtained by detection is the characteristic curve RC2, and the acquired setting condition is a condition that the minimum value of the obtained frequency is set as the drive frequency, the minimum of the characteristic curve RC2 shown in FIG. A value, that is, a frequency of 470 kHz is set as a driving frequency.

Returning to FIG. 9, the control unit 165 determines whether or not to end the process (S2). The case where the process is terminated is, for example, a case where the power receiving apparatus 201 is removed from the power transmitting apparatus 101. When the process ends (S2: YES), this process ends. When the process is not terminated (S2: NO), the control unit 165 determines whether or not the time T has elapsed since the drive frequency was set (S3). This time T can be appropriately changed, for example, 10 s.

When the time T has not elapsed (S3: NO), the control unit 165 executes the process of S2. When the time T has elapsed (S3: YES), the control unit 165 executes a drive frequency setting process (S4). This drive frequency setting process is the process shown in FIG. Thus, in the present embodiment, the drive frequency is set every time T.

When the power transmission is continuously performed, the piezoelectric transformer 22 self-heats with time, and the resonance frequency fluctuates due to the influence. For this reason, if power is always transmitted at the same drive frequency even after time has passed, the efficiency decreases. Therefore, the drive frequency is reset (corrected) every time T. Thereby, even if the resonance frequency of the piezoelectric transformer 22 is deviated, the drive frequency is reset according to the deviation, so that power can be transmitted efficiently.

After the resetting, the control unit 165 determines whether or not the difference between the driving frequencies before and after the resetting is greater than or equal to a threshold value (for example, 50 mV) (S5). If it is equal to or greater than the threshold (S5: YES), the control unit 165 executes the process of S2. When it is not more than a threshold value (S5: NO), the control part 165 sets T to T1 (T1> t) (S6).

High power is transmitted from the power transmitting apparatus 101 to the power receiving apparatus 201. For this reason, if the drive frequency setting process is repeatedly performed in a short period, unnecessary noise due to power transmission may occur, which may affect the power transmission apparatus 101 and the power reception apparatus 201. Therefore, when there is no difference in the change in the resonance frequency detected periodically, the influence of unnecessary noise can be prevented by lengthening the period for performing the drive frequency setting process.

As described above, in this embodiment, since the transmission efficiency is reduced due to self-heating of the piezoelectric transformer 22, the transmission efficiency is reduced by periodically detecting the resonance frequency and resetting the drive frequency. Can be suppressed. Further, although the resonance frequency shifts with self-heating of the piezoelectric transformer 22, in this embodiment, since the resonance frequency is detected from the transmission current IDC by the power transmission apparatus 101, it is not necessary to monitor the piezoelectric transformer 22 on the power reception apparatus 201 side. .

In the present embodiment, the case where the maximum value or the minimum value of the characteristic curve of the frequency characteristic is the resonance frequency has been described, but the method for detecting the resonance frequency is not limited to this. For example, the resonance frequency may be detected by obtaining an inclination from the transmission current IDC detected by the IDC detection unit 161 when frequency sweeping is performed, and detecting inversion of the inclination. The resonance frequency may be detected from the amount of displacement of the transmission current IDC when the frequency is swept.

In the present embodiment, the circuit constants are set in a state where the piezoelectric transformer 22 is not generating heat (that is, in a state where the piezoelectric transformer 22 is cooled), but in a state where the piezoelectric transformer 22 is generating heat (temperature of the piezoelectric transformer 22). The circuit constant may be set in a state where the Even in this case, a decrease in transmission efficiency can be suppressed by periodically detecting the resonance frequency and setting the drive frequency.

(Embodiment 2)
FIG. 11 is a circuit diagram of a power transmission system according to the second embodiment. The power transmission system 2 according to the present embodiment includes a power transmission device 102 and a power reception device 201. The power receiving apparatus 201 is the same as that in the first embodiment.

The power transmission device 102 according to the present embodiment includes a DC power supply 11, an inverter circuit 12, a step-up transformer T1, an active electrode 13, and a passive electrode 14 as with the power transmission device 101 according to the first embodiment. A capacitor C3 is connected to the secondary coil of the step-up transformer T1. The capacitor C3 forms a series resonance circuit 18 together with the leakage inductance (or the actual inductor) L1 of the step-up transformer T1. The series resonance circuit 18 has a circuit constant set so that the resonance frequency thereof becomes the resonance frequency of the resonance circuits 221 and 222 (see FIG. 2) of the power receiving apparatus 201. That is, in the first embodiment, the parallel resonance circuit 17 is formed in the power transmission device 101, whereas in this embodiment, the series resonance circuit 18 is formed in the power transmission device 102, which is different from the first embodiment. .

By setting circuit constants so that the resonance frequencies of the series resonance circuit 18 of the power transmission apparatus 102 and the series resonance circuit 221 and the parallel resonance circuit 222 of the power reception apparatus 201 are the same, the parallel resonance circuit 222 is set at the resonance frequency. Becomes high impedance (maximum), and the series resonance circuit 18 and the series resonance circuit 221 become low impedance (minimum). For this reason, the voltage drop in the series resonant circuit 18, the series resonant circuit 221 and the parallel resonant circuit 222, that is, the voltage drop between the inverter circuit 12 and the load circuit RL is small.

FIG. 12 is a diagram showing the frequency characteristics of the transmission current IDC. The horizontal axis in FIG. 4 is the frequency, and the vertical axis is the transmission current IDC, and shows characteristics when the load of the load circuit RL is changed. As shown in FIG. 4, even when the power transmission device 102 includes the series resonance circuit 18, the frequency characteristic curve varies depending on the load. Therefore, similarly to the first embodiment, the resonance frequency is detected according to the setting condition corresponding to the transmission power, and the detected resonance frequency is set as the drive frequency.

For example, in the frequency characteristic shown in FIG. 12, the frequency characteristic obtained by detection is the characteristic curve RC3 shown in the figure, and the obtained setting condition is a condition that the minimum value of the obtained frequency is set as the drive frequency. In this case, the minimum value of the characteristic curve RC3 shown in FIG. 12, that is, the frequency of 470 kHz is set as the drive frequency. Further, in the frequency characteristic shown in FIG. 12, the frequency characteristic obtained by detection is the characteristic curve RC4 shown in the figure, and the obtained setting condition is a condition that the maximum value of the obtained frequency is set as the drive frequency. In this case, the minimum value of the characteristic curve RC4 shown in FIG. 12, that is, the frequency 470 kHz is set as the drive frequency. In either case, the drive frequency can be set to a frequency of 470 kHz.

Thereby, as described in FIG. 8 of the first embodiment, for example, when the resonance frequency is about 470 kHz, the voltage conversion ratio of the output voltage of the power receiving apparatus 201 to the output voltage of the power transmission apparatus 102 at the resonance frequency is The transformation ratio is almost the same regardless of the load. That is, efficient power transmission is possible regardless of load fluctuations.

In this circuit, similarly to the first embodiment, by periodically detecting the resonance frequency and setting the detected resonance frequency as the drive frequency, even if the piezoelectric transformer 22 self-heats, the transmission efficiency is improved. Electric power can be transmitted without degrading.

C1 ... Capacitor C21, C22 ... Capacitor C3 ... Capacitor Cp ... Capacitor E11, E12 ... First input electrode E13 ... Internal electrode E21, E22 ... Second input electrode E23 ... Internal electrode E31, E32 ... First output electrode E33 ... Internal electrode E41, E42 ... second output electrode E43 ... internal electrodes E51, E52 ... third output electrode E53 ... internal electrode L1 ... leakage inductance L2 ... inductor Lp ... inductors Q1, Q2, Q3, Q4 ... switch elements R1, R2 ... resistance RL ... Load circuit Rp ... Resistance T1 ... Step-up transformer T2 ... Transformers 1 and 2 ... Power transmission system 11 ... DC power supply 12 ... Inverter circuits 13 and 23 ... Active electrodes 14 and 24 ... Passive electrodes 15 ... PWM control circuit 16 ... Control circuit 17 ... Parallel resonant circuit 18 ... Series resonant circuit 22 ... Piezoelectric transformer 25 ... Rectification flat Circuit 30 ... piezoelectric plate 31 ... first low voltage region 32 ... first high voltage region 33 ... second high voltage region 34 ... second low voltage region 35 ... third high voltage region 36 ... fourth high voltage region 37 ... Third low voltage region 101, 102 ... Power transmission device 161 ... IDC detection unit 162 ... Transmission power acquisition unit 163 ... Frequency control unit 164 ... Storage unit 165 ... Control unit 201 ... Power reception device 221 ... Series resonance circuit 222 ... Parallel resonance circuit

Claims (4)

1. Power transmission for transmitting power from the power transmitting device to the power receiving device by electric field coupling between the power transmitting side first electrode and the power transmitting side second electrode of the power transmitting device and the power receiving side first electrode and the power receiving side second electrode of the power receiving device. In the system,
   The power transmission device is:
   An inverter circuit for converting a DC voltage output from a DC power source into an AC voltage;
   A PWM control circuit for PWM controlling the inverter circuit at a set drive frequency;
   A step-up transformer that boosts an alternating voltage output from the inverter circuit and applies the boosted voltage to the power transmission side first electrode and the power transmission side second electrode;
   A first resonance circuit connected between the step-up transformer and the power transmission side first electrode and the power transmission side second electrode, or configured together with a part of the step-up transformer;
   With
   The power receiving device is:
   A piezoelectric transformer for stepping down a voltage induced in the power receiving side first electrode and the power receiving side second electrode;
   A second resonance circuit including a part of an equivalent circuit of the piezoelectric transformer and having the same resonance frequency as the first resonance circuit;
   With
   The power transmission device is:
   A resonance frequency detector that sweeps the drive frequency and detects a resonance frequency of the first resonance circuit and the second resonance circuit;
   A drive frequency setting unit that sets the resonance frequency detected by the resonance frequency detection unit to the drive frequency at a predetermined period;
   With
   Power transmission system.
2. The drive frequency setting unit includes:
   As the amount of change in the resonance frequency detected by the resonance frequency detector at a different timing becomes smaller, the predetermined period is lengthened.
   The power transmission system according to claim 1.
3. The power transmission device includes a current detection unit that detects a current flowing through the inverter circuit,
   The resonance frequency detection unit detects the resonance frequency based on frequency characteristics of a current value detected by the current detection unit when the drive frequency is swept.
   The power transmission system according to claim 1 or 2.
4. The power transmission device is:
   A transmission power detector that detects transmission power to be transmitted to the power receiving device;
   A storage unit for storing a detection condition of a resonance frequency of the first resonance circuit and the second resonance circuit according to transmission power;
   With
   The resonance frequency detector is
   The detection condition according to the transmission power detected by the transmission power detection unit is acquired from the storage unit, the acquired detection condition, and the frequency characteristic of the current value detected by the current detection unit when the drive frequency is swept To detect the resonant frequency based on
   The power transmission system according to claim 3.

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