JP2019161929A - Wireless power transmission system and power reception device - Google Patents

Abstract

To provide a wireless power transmission system capable of suppressing a rapid increase in a charging current of a battery and a power receiving device used therefor.SOLUTION: A wireless power transmission system includes a power transmission device and a power reception device. The power transmission device includes an inverter V1, a power transmission resonator having a power transmission coil L3 and a power transmission capacitor C2, and a T-type circuit connected between the inverter V1 and the power transmission coil L3. The power reception device includes a power reception resonator having a power reception coil L4 and a power reception capacitor C3 that receives AC power transmitted from the power transmission coil L3, an AC/DC converter that converts AC power received by the power reception coil L4 into DC power, and a battery V2 that stores the DC power converted by the AC/DC converter. The absolute value of the impedance of the power reception coil L4 at the frequency of the high frequency current is larger than the absolute value of the impedance of the power reception capacitor C3.SELECTED DRAWING: Figure 1

Description

  Embodiments described herein relate generally to a wireless power transmission system and a power receiving apparatus used therefor.

  As one of wireless power transmission system methods, a method of transmitting power by electromagnetic induction using a power transmission device including a power transmission coil and a power reception device including a power reception coil is known. In a power transmission device of this type of wireless power transmission system, a configuration is known in which a T-type circuit serving as an impedance converter is inserted into the output of a power source. In a wireless power transmission system using such a T-type circuit, the power transmission coil can be driven with a constant current.

  When the technology for inserting a T-type circuit in a power transmission device is applied to a series resonance type wireless power transmission system, it is viewed from the power source of the power transmission device when there is no load on the power reception device side or when the power reception device is in an open state. The system load can be replaced with almost infinite. For this reason, for example, even when power transmission is erroneously started when there is no power receiving device near the power transmitting device, or when power transmission is interrupted in the middle, the power source in the power transmitting device is protected.

Japanese Patent No. 3491178

  The technique of inserting a T-type circuit in a power transmission device can also be applied to a wireless power transmission system that charges a battery by wireless power feeding using a series resonator for both power transmission and reception. However, in the wireless power transmission system in this case, after impedance conversion is performed in the T-type circuit, impedance conversion is also performed in a power transmission / reception series resonator. At this time, the system viewed from the battery is replaced with a voltage source. For this reason, as the voltage of the power supply approaches the voltage of the battery, the charging current of the battery rapidly increases.

  An object of the present embodiment is to provide a wireless power transmission system capable of suppressing a rapid increase in charging current of a battery and a power receiving device used therefor.

  The wireless power transmission system includes a power transmission device and a power reception device. A power transmission device includes an inverter that converts a direct current into a high-frequency current, a power transmission coil that wirelessly transmits AC power corresponding to the high-frequency current converted by the inverter, and a power transmission resonator that is connected in series with the power transmission coil And a T-type circuit connected between the inverter and the power transmission coil and having an inductor and a capacitor. A power receiving device includes a power receiving coil that receives AC power transmitted from a power transmitting coil, a power receiving resonator having a power receiving capacitor connected in series with the power receiving coil, and an AC / DC converter that converts AC power received by the power receiving coil into DC power And a battery for storing the DC power converted by the AC / DC converter. The absolute value of the impedance of the power receiving coil at the frequency of the high frequency current is larger than the absolute value of the impedance of the power receiving capacitor.

FIG. 1 is a circuit diagram showing a configuration of a wireless power transmission system according to one embodiment. FIG. 2 is a diagram showing a change in charging current flowing through the battery when the effective value of the output voltage of the inverter is gradually increased when the absolute value of the impedance of the receiving coil is equal to the absolute value of the impedance of the receiving capacitor. It is. FIG. 3 shows a change in the charging current flowing through the battery when the effective value of the output voltage of the inverter is gradually increased when the absolute value of the impedance of the receiving coil is larger than the absolute value of the impedance of the receiving capacitor. FIG. FIG. 4 is a circuit diagram illustrating a configuration of a wireless power transmission system according to the first modification. FIG. 5 is a circuit diagram illustrating a configuration of a wireless power transmission system according to the second modification.

  Hereinafter, embodiments will be described with reference to the drawings. FIG. 1 is a circuit diagram showing a configuration of a wireless power transmission system according to one embodiment. The wireless power transmission system is represented by a two-terminal pair circuit having a power transmission device and a power reception device. The power transmission device has a power source, and transmits power generated by the power source to the power receiving device. The power receiving apparatus has a battery and charges the battery according to the power transmitted from the power transmitting apparatus. The power transmission device is provided in a fixed charging station, for example. On the other hand, the power receiving device is provided in a movable device. The power transmission device and the power reception device do not have electrical contacts with each other, but wireless power transmission is performed by electromagnetic coupling when the power transmission device and the power reception device are close to each other. Hereinafter, each of the power transmission device and the power reception device will be described.

  The power transmission device includes an inverter V1 as a high-frequency power source, a T-type LCL circuit including inductors L1 and L2, and a capacitor C1, and a power transmission coil L3. A power transmission capacitor C2 is connected in series to the power transmission coil L3. Here, each of the inductors L1 and L2 and the power transmission coil L3 does not need to be a single element, and may be configured as an element having a predetermined inductance by a plurality of elements. Similarly, each of the capacitors C1 and C2 does not need to be a single element, and may be configured as an element having a predetermined capacitance by a plurality of elements. The inductors L1 and L2, the inductance of the power transmission coil L3, and the capacitances of the capacitors C1 and C2 are, for example, the range of battery voltage required for the battery V2 of the power receiving device, the charging current of the battery V2, the power transmission coil L3 and the power receiving coil L4 It is assumed that it is appropriately set according to parameters such as the range of the coupling coefficient required for the transformer constituted by and the upper limit voltage of the inverter V1.

  The inverter V1 is a high frequency power source that generates a high frequency current for charging the battery of the power receiving device. The inverter V1 converts a direct current supplied from a direct current power supply device connected to the power transmission device into a high frequency current and outputs the high frequency current to the T-type LCL circuit.

  The T-type LCL circuit is connected to the output of the inverter V1. The inductor L1 and the inductor L2 of the T-type LCL circuit are connected in series with the output of the inverter V1. On the other hand, the capacitor C1 is shunt-connected to the output of the inverter V1. Here, the inductor L1 and the inductor L2 are elements having the same inductance. Further, the inductances of the inductors L1 and L2 and the capacitance of the capacitor C1 are set so that the absolute value of the sum of the impedances of the inductor L1 and the inductor L2 at the frequency of the high frequency current generated by the inverter V1 is equal to the absolute value of the impedance of the capacitor C1. Value is set. Such a T-type LCL circuit operates as an impedance converter (impedance-admittance converter), and outputs a high-frequency current based on a constant voltage generated by the inverter V1 to the power transmission coil L3 as a constant current. Note that the T-type circuit as the impedance converter may be replaced with a π-type circuit. However, the load on the inverter V1 can be reduced by using the T-type circuit rather than using the π-type circuit.

  The power transmission coil L3 is electromagnetically coupled to the power receiving coil L4 of the power receiving device when the power transmitting device and the power receiving device are close to each other. That is, the power transmission coil L3 operates as a primary coil of the transformer when the power transmission device and the power reception device are close to each other, and transmits AC power corresponding to the high-frequency current output from the T-type LCL circuit to the power reception coil L4. To do.

  Further, as described above, the power transmission capacitor C2 is connected in series to the power transmission coil L3. The inductance of the power transmission coil L3 and the capacitance of the power transmission capacitor C2 are set so as to substantially resonate at the frequency of the high-frequency current generated by the inverter V1. Usually, a gap is generated between the power transmission coil L3 and the power reception coil L4. Due to this gap or the like, magnetic flux leakage occurs between the power transmission coil L3 and the power reception coil L4. This leakage flux acts equivalently as an inductor connected in series with the power transmission coil L3. Due to the influence of the inductor component due to the leakage magnetic flux, the power source power factor in the power transmission device is reduced. The series resonator formed by the power transmission coil L3 and the power transmission capacitor C2 cancels the influence of the inductor component due to the leakage magnetic flux. This compensates for a decrease in power source power factor.

  The power receiving device includes a power receiving coil L4, an AC / DC converter including diodes D1, D2, D3, and D4, and a battery V2. A power receiving capacitor C3 is connected in series to the power receiving coil L4. Here, the power receiving coil L4 does not have to be a single element, and may be configured as an element having a predetermined inductance by a plurality of elements. Similarly, the power receiving capacitor C3 does not have to be a single element, and may be configured as an element having a predetermined capacitance by a plurality of elements. Further, the inductance of the power receiving coil L4 and the capacitance of the power receiving capacitor C3 are, for example, the range of the battery voltage of the battery V2 of the power receiving device, the charging current, the range of the coupling coefficient of the transformer configured by the power transmitting coil L3 and the power receiving coil L4, It is assumed that it is appropriately set according to parameters such as the upper limit voltage of the inverter V1.

  The power reception coil L4 is electromagnetically coupled to the power transmission coil L3 of the power transmission device when the power transmission device and the power reception device are close to each other. That is, the power receiving coil L4 operates as a secondary coil of the transformer when the power transmitting device and the power receiving device are close to each other, and receives AC power transmitted from the power transmitting coil L3. As described above, the power receiving coil L4 is connected to the power receiving capacitor C3 in series. The series resonator formed by the power receiving coil L4 and the power receiving capacitor C3 cancels the influence of the inductor component due to the leakage magnetic flux. This compensates for a decrease in power transmission efficiency. Here, in the present embodiment, a sudden rise in the charging current in the battery V2 is suppressed by intentionally leaving the influence of the leakage magnetic flux without completely resonating the power receiving coil L4 and the power receiving capacitor C3. Details will be described later.

  The AC / DC converter is connected to the power receiving coil L4. The AC / DC converter is, for example, a diode bridge circuit including diodes D1, D2, D3, and D4. This AC / DC converter converts AC power (AC current) output from the power receiving coil L4 into DC power (DC current).

  The battery V2 is a battery such as a lithium ion battery, for example, and accumulates electric power according to the output from the AC / DC converter. The device having the power receiving device performs a desired operation using the power stored in the battery V2.

Here, in the power receiving device of the present embodiment, the impedance of the power receiving coil L4 is set so that the absolute value of the impedance of the power receiving coil L4 at the frequency of the high frequency current generated by the inverter V1 is larger than the absolute value of the impedance of the power receiving capacitor C3. Values of inductance and capacitance of the receiving capacitor C3 are set. That is, the values of the inductance Lr and the capacitance Cr are set so that the following relationship (Equation 1) is satisfied. In Equation 1, ω is the angular frequency of the high-frequency current, Lr is the inductance of L4 of the power receiving coil, and Cr is the capacitance of the power receiving capacitor C3.

  FIG. 2 shows a change in the charging current flowing through the battery V2 when the output voltage effective value of the inverter V1 is gradually increased in the case where the absolute value of the impedance of the power receiving coil L4 is equal to the absolute value of the impedance of the power receiving capacitor C3. FIG. When the absolute value of the impedance of the receiving coil L4 is equal to the absolute value of the impedance of the receiving capacitor C3, that is, when the receiving coil L4 and the receiving capacitor C3 are in series resonance, the system viewed from the battery V2 is replaced with a voltage source. . At this time, the wireless power transmission system of FIG. 1 is replaced with a circuit in which the inverter V1 as the voltage source charges the battery V2 as the voltage source. For this reason, as shown in FIG. 2, the charging current rapidly increases as the output voltage of the inverter V1 approaches the battery voltage Vb of the battery V2.

  FIG. 3 shows the charging current flowing through the battery V2 when the output voltage effective value of the inverter V1 is gradually increased when the absolute value of the impedance of the power receiving coil L4 is larger than the absolute value of the impedance of the power receiving capacitor C3. It is the figure which showed the change. By making the absolute value of the impedance of the power receiving coil L4 larger than the absolute value of the impedance of the power receiving capacitor C3 and intentionally leaving the influence of the leakage magnetic flux, as shown in FIG. It is suppressed. That is, even if the output voltage of the inverter V1 approaches the battery voltage Vb of the battery V2, a rapid increase in charging current does not occur.

  Here, as the absolute value of the impedance of the power receiving coil L4 becomes larger than the absolute value of the impedance of the power receiving capacitor C3, the rapid increase of the charging current is suppressed. On the other hand, as the absolute value of the impedance of the power receiving coil L4 becomes larger than the absolute value of the impedance of the power receiving capacitor C3, the efficiency of power transmission decreases. For this reason, it is necessary to increase the effective value of the output voltage of the inverter V1 in order to increase the voltage to a desired battery voltage, or it may take time to increase the voltage to the desired battery voltage. Therefore, in practice, how much the absolute value of the impedance of the power receiving coil L4 is larger than the absolute value of the impedance of the power receiving capacitor C3 depends on, for example, the battery voltage range required for the battery V2 of the power receiving device, It is desirable to set appropriately according to parameters such as a charging current, a range of a coupling coefficient required for a transformer constituted by the power transmission coil L3 and the power reception coil L4, and an upper limit voltage of the inverter V1.

  As described above, according to the present embodiment, by making the absolute value of the impedance of the power receiving coil L4 larger than the absolute value of the impedance of the power receiving capacitor C3, a rapid increase in the charging current is suppressed.

[Modification 1]
FIG. 4 is a circuit diagram illustrating a configuration of a wireless power transmission system according to the first modification. In FIG. 1, the T-type circuit constituting the impedance converter of the power transmission device is an LCL-type T-type circuit having the capacitor C1 as a shunt element. On the other hand, in FIG. 4, the T-type circuit constituting the impedance converter of the power transmission device is a CLC-type T-type circuit using the inductor L5 as a shunt element. That is, in the T-type circuit of FIG. 4, the capacitor C4 and the capacitor C5 are connected in series with the output of the inverter V1. On the other hand, the inductor L5 is shunt-connected to the output of the inverter V1. Here, the capacitor C4 and the capacitor C5 are elements having the same capacitance. Further, the inductances of the inductors L1 and L2 and the capacitance of the capacitor C1 so that the absolute value of the sum of the impedances of the capacitors C4 and C5 at the frequency of the high-frequency current generated by the inverter V1 is equal to the absolute value of the impedance of the inductor L5. Value is set.

  Thus, even if the T-type circuit is replaced from the LCL type to the CLC type, the charging current increases rapidly by making the absolute value of the impedance of the receiving coil L4 larger than the absolute value of the impedance of the receiving capacitor C3. Is suppressed.

[Modification 2]
FIG. 5 is a circuit diagram illustrating a configuration of a wireless power transmission system according to the second modification. In FIG. 5, a power receiving inductor L6 is further inserted between the power receiving capacitor C3 and the AC / DC converter. In the second modification, the inductance of the power receiving coil L4 and the power receiving inductor L6 and the power receiving capacitor so that the absolute value of the sum of the impedance of the power receiving coil L4 and the impedance of the power receiving inductor L6 is larger than the absolute value of the impedance of the power receiving capacitor C3. A capacitance value of C3 is set. That is, the values of the inductances Lr1, Lr2 and the capacitance Cr are set so that the following relationship (Equation 2) is satisfied. In Equation 2, ω is the angular frequency of the high-frequency current, Lr1 is the inductance of the power receiving coil L4, Lr2 is the inductance of the power receiving inductor L6, and Cr is the capacitance of the power receiving capacitor C3.

  In this manner, the power receiving inductor L6 is further inserted between the power receiving capacitor C3 and the AC / DC converter, and the absolute value of the impedance of the power receiving coil L4 and the impedance of the power receiving inductor L6 is determined from the absolute value of the impedance of the power receiving capacitor C3. Is also increased, a rapid increase in charging current is suppressed.

  The power receiving inductor L6 may be inserted not at a position between the power receiving capacitor C3 and the AC / DC converter but at a position between the power receiving coil L4 and the AC / DC converter.

[Other variations]
In the above-described embodiment and its modification, the inductor L1, the inductor L2, the power transmission capacitor C2, and the power reception capacitor C3 are provided only on one line of the two-terminal pair circuit. On the other hand, the inductor L1, the inductor L2, the power transmission capacitor C2, and the power reception capacitor C3 may be provided separately on both lines of the two-terminal pair circuit. In this case, the inductors provided on both lines form elements having inductances equivalent to the inductors L1 and L2, respectively, and the capacitors provided on both lines are equivalent to the transmission capacitor C2 and the receiving capacitor C3, respectively. The device parameters are set to form a device having capacitance. By providing the inductor L1, the inductor L2, the power transmission capacitor C2, and the power reception capacitor C3 separately for both lines of the two-terminal pair circuit, crosstalk is suppressed.

  Note that the present invention is not limited to the above-described embodiment as it is, and can be embodied by modifying the constituent elements without departing from the scope of the invention in the implementation stage. In addition, various inventions can be formed by appropriately combining a plurality of components disclosed in the embodiment. For example, some components may be deleted from all the components shown in the embodiment. Furthermore, constituent elements over different embodiments may be appropriately combined.

  C1 capacitor, C2 power transmission capacitor, C3 power reception capacitor, D1 diode, D2 diode, D3 diode, D4 diode, L1 inductor, L2 inductor, L3 power transmission coil, L4 power reception coil, L5 inductor, L6 power reception inductor, C4 capacitor, C5 capacitor, V1 inverter, V2 battery.

Claims (8)

An inverter that converts direct current to high frequency current;
A power transmission resonator having a power transmission coil for wirelessly transmitting AC power corresponding to the high-frequency current converted by the inverter, and a power transmission capacitor connected in series with the power transmission coil;
A T-type circuit connected between the inverter and the power transmission coil and having an inductor and a capacitor;
A power transmission device comprising:
A power receiving resonator having a power receiving coil that receives the AC power transmitted from the power transmitting coil, and a power receiving capacitor connected in series with the power receiving coil;
An AC / DC converter that converts the AC power received by the power receiving coil into DC power;
A battery for storing DC power converted by the AC / DC converter;
A power receiving device comprising:
Have
The wireless power transmission system, wherein an absolute value of an impedance of the power receiving coil at a frequency of the high frequency current is larger than an absolute value of an impedance of the power receiving capacitor.   The wireless power transmission system according to claim 1, wherein the T-type circuit is a T-type circuit using the capacitor as a shunt element.   The wireless power transmission system according to claim 1, wherein the T-type circuit is a T-type circuit using the inductor as a shunt element. An inverter that converts direct current to high frequency current;
A power transmission resonator having a power transmission coil for wirelessly transmitting AC power corresponding to the high-frequency current converted by the inverter, and a power transmission capacitor connected in series with the power transmission coil;
A T-type circuit connected between the inverter and the power transmission coil and having an inductor and a capacitor;
A power transmission device comprising:
A power receiving resonator having a power receiving coil that receives the AC power transmitted from the power transmitting coil, and a power receiving capacitor connected in series with the power receiving coil;
An AC / DC converter that converts the AC power received by the power receiving coil into DC power;
A battery for storing DC power converted by the AC / DC converter;
A power receiving inductor connected in series between the AC / DC converter and the power receiving capacitor;
A power receiving device comprising:
Have
The wireless power transmission system, wherein an absolute value of a sum of impedances of the power receiving coil and the power receiving inductor is larger than an absolute value of an impedance of the power receiving capacitor.   The wireless power transmission system according to claim 4, wherein the T-type circuit is a T-type circuit using the capacitor as a shunt element.   The wireless power transmission system according to claim 4, wherein the T-type circuit is a T-type circuit using the inductor as a shunt element. A power transmission resonator including an inverter that converts a direct current into a high frequency current, a power transmission coil that wirelessly transmits AC power corresponding to the high frequency current converted by the inverter, and a power transmission capacitor connected in series with the power transmission coil A power receiving coil that receives the AC power transmitted from the power transmitting coil of a power transmitting device that is connected between the inverter and the power transmitting coil and includes a T-type circuit having an inductor and a capacitor, and the power receiving coil. A power receiving resonator having a power receiving capacitor connected in series;
An AC / DC converter that converts the AC power received by the power receiving coil into DC power;
A battery for storing DC power converted by the AC / DC converter;
With
The power receiving device, wherein an absolute value of impedance of the power receiving coil at a frequency of the high frequency current is larger than an absolute value of impedance of the power receiving capacitor. A power transmission resonator including an inverter that converts a direct current into a high frequency current, a power transmission coil that wirelessly transmits AC power corresponding to the high frequency current converted by the inverter, and a power transmission capacitor connected in series with the power transmission coil A power receiving coil that receives the AC power transmitted from the power transmitting coil of a power transmitting device that is connected between the inverter and the power transmitting coil and includes a T-type circuit having an inductor and a capacitor, and the power receiving coil. A power receiving resonator having a power receiving capacitor connected in series;
An AC / DC converter that converts the AC power received by the power receiving coil into DC power;
A battery for storing DC power converted by the AC / DC converter;
A power receiving inductor connected in series between the AC / DC converter and the power receiving capacitor;
With
A power receiving device in which an absolute value of a sum of impedances of the power receiving coil and the power receiving inductor is larger than an absolute value of an impedance of the power receiving capacitor.