JP2012075200A - Wireless power transmission apparatus - Google Patents

Abstract

PROBLEM TO BE SOLVED: To avoid performing power transmission with foreign matter being present between a transmitting coil and a receiving coil even if they are separated.SOLUTION: An embodiment provides a wireless power transmission apparatus including a first coil, a second coil, a control circuit, a third coil and a determination circuit. The first coil transmits supplied first high frequency energy to a receiving apparatus side coil via magnetic coupling. The second coil generates a magnetic field depending on supplied second high frequency energy. The third coil couples to the second coil via the magnetic field generated by the second coil to receive the second high frequency energy from the second coil. The determination circuit determines whether or not to supply the first high frequency energy to the first coil according to the magnitude of the second high frequency energy received by the third coil.

Description

  Embodiments described herein relate generally to a wireless power transmission apparatus.

  Conventionally, in wireless power transmission between a power transmission coil and a power reception coil, there is a technique for detecting a foreign object such as a metal sandwiched between the power transmission coil and the power reception coil. In this technique, when transmission is performed between the power transmission coil and the power receiving coil in the presence of a foreign object, the temperature of the foreign object is increased, and the foreign object is detected using a temperature sensor. This prevents an abnormal temperature rise of the foreign material and a decrease in transmission efficiency due to transmission in the presence of the foreign material.

  However, when wireless power transmission is performed in a state where the power transmission coil and the power reception coil are separated, there is a possibility that a foreign object exists outside the sensor range of the temperature sensor. In this case, there is a problem that the detection accuracy of the foreign matter is deteriorated.

  Another possible method is to monitor the transmission efficiency between the power transmission coil and the power reception coil and detect foreign matter from the decrease in transmission efficiency. However, since the transmission efficiency varies as the transmission distance changes, it cannot be determined whether the change in the transmission efficiency is due to the change in the transmission distance or the influence of foreign matter. Therefore, this method also has a problem that the detection accuracy of the foreign matter is deteriorated.

JP 2003-153457 A

  The present invention provides a wireless power transmission apparatus that prevents power transmission from being performed in a state in which a foreign object exists between the transmission-side coil and the reception-side coil even when they are separated from each other.

  According to an embodiment of the present invention, a wireless power transmission device including a first coil, a second coil, a control circuit, a third coil, and a determination circuit is provided.

  The first coil receives the supply of the first high-frequency energy, and transmits the supplied first high-frequency energy to the receiver-side coil through magnetic coupling.

  The second coil is supplied with the second high-frequency energy and generates a magnetic field according to the supplied second high-frequency energy.

  The third coil receives the second high-frequency energy from the second coil by being coupled to the second coil via a magnetic field generated by the second coil.

  The control circuit supplies the first high frequency energy to the first coil, and supplies the second high frequency energy to the second coil.

  The determination circuit determines whether to supply the first high-frequency energy to the first coil by the control circuit based on the magnitude of the second high-frequency energy received by the third coil.

1 is a diagram showing a wireless power transmission system according to a first embodiment. It is a figure which shows an example of indirect supply. It is a figure explaining the principle of a foreign material detection. FIG. 5 is a diagram showing a first coil arrangement example. FIG. 6 is a diagram showing a second coil arrangement example. FIG. 10 is a diagram showing a third coil arrangement example. FIG. 10 is a diagram showing a fourth coil arrangement example. FIG. 10 is a diagram showing a fifth example of coil arrangement. 2 is a flowchart showing a flow of operations of the power transmission device of FIG. FIG. 6 is a diagram for explaining the reason for separating the foreign object detection coil from the resonance frequency of the first self-resonant coil. FIG. 6 is a diagram illustrating configurations of a power transmission device and a power reception device according to a second embodiment. It is a figure which shows the structure of each coil. It is a figure which shows the state of the resonant frequency of each coil when performing electric power transmission and a foreign material detection. 6 is a flowchart showing an operation flow of a power transmission device according to a second embodiment. FIG. 6 is a diagram showing a power transmission device and a power reception device according to a third embodiment. It is a figure which shows the example of the resonant frequency control of each coil at the time of electric power transmission and a foreign material detection. FIG. 10 is a plan view showing an arrangement example of coils according to a fourth embodiment. FIG. 10 is a plan view showing an arrangement example of coils according to a fourth embodiment. FIG. 10 is a plan view showing an arrangement example of coils according to a fourth embodiment. 10 is a flowchart showing the operation of the power transmission device according to the fourth embodiment. FIG. 10 is a diagram for explaining a basic idea of a fifth embodiment. 10 is a flowchart showing an operation flow of a power transmission device according to a fifth embodiment. FIG. 10 is a diagram showing a wireless power transmission system according to a seventh embodiment. FIG. 10 is a diagram showing a wireless power transmission system according to an eighth embodiment.

  Hereinafter, the first to eighth embodiments will be described in detail with reference to the drawings.

(First embodiment)
FIG. 1 shows a wireless power transmission system according to the first embodiment.

  The wireless power transmission system in FIG. 1 includes a power transmission device (wireless power transmission device) 1 and a power reception device (wireless power reception device) 2 to which energy (power) is supplied from the power transmission device 1.

  The power transmission device 1 inspects whether or not there is a foreign object between the power reception device 2 and the periphery of the power transmission device 1, and if present, does not perform power transmission, and if not, performs power transmission. Do. By not performing transmission when there is a foreign object, it is possible to prevent an abnormal temperature rise of the foreign object and a decrease in transmission efficiency.

  The power transmission device 1 includes a first self-resonant coil (first coil) 3, a first self-resonant coil for detecting foreign matter (second coil) 4, a second self-resonant coil for detecting foreign matter (third coil) 5, A transmission efficiency measurement circuit 6, a foreign matter detection circuit (determination circuit) 7, a rectifier circuit 10, and a control circuit 11 are provided. A commercial power source 9 is externally connected to the power transmission device 1.

  The power receiving device 2 includes a second self-resonant coil (receiving device side coil) 8, a rectifier circuit 12, and a secondary battery 13.

The first self-resonant coil 3 of the power transmitting device 1 and the second self-resonant coil 8 of the power receiving device 2 are at a predetermined frequency (first frequency) by the inductor (L) of the coil and its own stray capacitance (C). It is a resonating coil. The resonant frequency is determined by 1 / 2π (LC) ^1/2 .

  The first self-resonant coil 3 and the second self-resonant coil 8 are, for example, coils having n turns (n is an integer of 1 or more).

  The shapes of the first self-resonant coil 3 and the second self-resonant coil 8 may be arbitrary. For example, a cylindrical shape, a quadrangular prism shape, a spiral shape, and the like are possible. In the present embodiment, it is assumed that the shapes of the coils 3 and 8 are cylindrical.

  The first self-resonant coil 4 for detecting foreign matter and the second self-resonant coil 5 for detecting foreign matter have the same frequency as the first and second self-resonant coils 3 and 8, depending on the inductor of the coil and its own stray capacitance. It is a coil that resonates at (second frequency). It is assumed that the value of the resonance frequency of the foreign object detection coil 4 is sufficiently separated from the resonance frequency of the first self-resonance coil 3. Details of this will be described later.

  The foreign object detection first self-resonant coil 4 and the foreign object detection second self-resonant coil 5 are, for example, coils having n turns (n is an integer of 1 or more).

  The shapes of the foreign substance detection first self-resonant coil 4 and the foreign substance detection second self-resonant coil 5 may be arbitrary. For example, a cylindrical shape, a quadrangular prism shape, a spiral shape, and the like are possible. In the present embodiment, it is assumed that the shapes of the coils 4 and 5 are cylindrical.

  The commercial power source 9 is an arbitrary power source that can supply power (energy). The commercial power source 9 is a power source having a frequency of 50 Hz, for example. For example, a battery may be used as a commercial power source. In the example of FIG. 1, the commercial power supply 9 is connected to the power transmission device 1 from the outside, but may be provided in the power transmission device 1.

  The rectifier circuit 10 is a circuit that converts AC energy from the commercial power supply 9 into DC energy. The rectifier circuit 10 may be configured by an arbitrary circuit method. For example, the rectifier circuit can be configured using a diode or the like.

  The control circuit 11 receives the direct current energy from the rectifier circuit 10 and generates high frequency energy (first high frequency energy) having a frequency that matches the resonance frequency of the first self-resonant coil 3. The control circuit 11 supplies the generated high frequency energy to the first self-resonant coil 3. Arbitrary methods can be used as a method of converting direct current energy into high frequency energy, and any method may be used.

  The method of supplying high frequency energy from the control circuit 11 to the first self-resonant coil may be direct supply or indirect supply.

In direct supply, the control circuit 11 and the first self-resonant coil 3 are connected by wiring, and the energy generated in the control circuit 11 is directly supplied to the first self-resonant coil 3. Indirect supply uses magnetic coupling. The energy generated by the control circuit 11 is supplied to the first self-resonant coil 3.

  Fig. 2 shows an example of indirect supply.

  In the case of indirect supply, the output from the control circuit 11 is supplied to, for example, the coil 21 having one winding. A coil with one turn is a loop. When the coil having the number of turns of 1 and the first self-resonant coil 22 are close to each other, the energy supplied to the coil having the number of turns of 1 is supplied to the first self-resonant coil 3 by magnetic coupling. A current according to the supplied energy flows through the first self-resonant coil 3.

  When a current flows through the first self-resonant coil 3 by direct supply or indirect supply, a magnetic field is generated by this current.

  The second self-resonant coil 8 of the power receiving device 2 receives energy by coupling with the magnetic field generated from the first self-resonant coil 3. That is, part of the high-frequency energy supplied to the first self-resonant coil 3 is sent to the second self-resonant coil 8 by magnetic resonance (electromagnetic coupling) between the coils 3 and 8.

  The rectifier circuit 12 in the power receiving apparatus converts the high frequency energy received by the second self-resonant coil 8 into DC energy. Similar to the rectifier circuit 10 of the power transmission device 1, the rectifier circuit 12 may be configured by an arbitrary circuit method.

  The secondary battery 13 charges direct current energy output from the rectifier circuit 12. The energy received from the power transmission device 1 may be used to directly operate an electric circuit or light a light bulb without charging the secondary battery. That is, the power consumption method on the power receiving device side is not limited.

  The control circuit 11 generates high-frequency energy (second high-frequency energy) having a frequency that matches the resonance frequency of the foreign object detection first self-resonant coil 4. The control circuit 11 supplies the generated high-frequency energy to the foreign object detection first self-resonant coil 4.

  In the foreign object detection first self-resonant coil 4, a current flows due to the supply of high-frequency energy from the control circuit 11, and a magnetic field is generated by this current.

  The foreign object detection second self-resonant coil 5 receives energy by coupling with the magnetic field generated from the foreign object detection first self-resonant coil 4. That is, a part of the high-frequency energy supplied to the foreign object detection first self-resonant coil 4 is sent to the second self-resonant coil 8 by magnetic resonance (electromagnetic coupling) between the coils 4 and 5.

  The transmission efficiency measuring circuit 6 uses the magnitude of energy supplied from the control circuit 11 to the foreign object detection first self-resonant coil 4 and the magnitude of energy received by the foreign object detection second self-resonant coil 5. Measure the power transmission efficiency between coils 4 and 5. For example, the transmission efficiency is measured by dividing the magnitude of energy received by the coil 5 by the magnitude of energy supplied to the coil 4.

  The magnitude of the energy supplied to the foreign object detection first self-resonant coil 4 is obtained by monitoring the output of the control circuit 11. However, if the output from the control circuit 11 to the first self-resonant coil 4 for foreign object detection is constant, set this value in the transmission efficiency measurement circuit 6 in advance and use this set value without monitoring. May be. Further, this value may be stored in a storage means such as a register accessible from the transmission efficiency measurement circuit 6 and read out from this storage means.

  On the other hand, the transmission efficiency measurement circuit 6 can obtain the magnitude of energy received by the foreign object detection second self-resonant coil 5 by measurement. This energy measurement may be performed by an arbitrary method. For example, the measurement can be performed using a power meter.

  The foreign object detection circuit 7 compares the transmission efficiency measured by the transmission efficiency measurement circuit 6 with a threshold value (predetermined efficiency) to determine whether or not to perform power transmission to the power receiving device 2 by the coil 3 . That is, it is determined whether or not high frequency energy is supplied from the control circuit 11 to the first self-resonant coil.

  If the measured transmission efficiency is lower than the threshold value, it is determined that there is a foreign object such as metal between the power transmission device 1 and the power reception device 2 or in the vicinity of the power transmission device 1, and it is determined not to perform power transmission (electric transmission). .

  If the measured transmission efficiency matches or is larger than the threshold value, it is determined that there is no foreign object such as metal between the power transmission device 1 and the power reception device 2 or in the vicinity of the power transmission device 1, and the transmission is determined.

  The principle of foreign object detection will be described with reference to FIG.

  The rectangle on the left side of the drawing shows a block of the power transmission device, and the foreign object detection first self-resonance coil 31, the first self-resonance coil 35, and the foreign object detection second self-resonance coil 33 are arranged in the power transmission device. Further, the rectangle on the right side of the figure shows a block of the power receiving device, and the second self-resonant coil 36 is provided in the power receiving device. For simplicity of explanation, illustration of other elements in the power transmission device and the power reception device is omitted.

  When high frequency energy is supplied to the foreign object detection first self-resonant coil 31, a magnetic field is generated around the power transmission device. The magnetic field lines 32 shown represent the magnetic field generated at this time. Note that the magnetic field is formed in a loop shape, and in fact, magnetic lines of force extend on the left side of the drawing.

  When there is no foreign object on the path of the magnetic field lines (between the power transmission device and the power reception device or in the vicinity of the power transmission device), most of the magnetic field generated by the coil 31 is received by the second self-resonant coil 33 for foreign object detection. The transmission efficiency at this time is P1.

  On the other hand, when there is a foreign object, for example, when there is a foreign object 34 between the power transmission device and the power receiving device, a part of the lines of magnetic force is blocked by the foreign material 34. As a result, the number of lines of magnetic force reaching the foreign object detection second self-resonant coil 33 is reduced as compared to the case where no foreign object exists. As a result, the magnetic field received by the foreign object detection second self-resonant coil 33 is reduced. The transmission efficiency at this time is smaller than P1.

  A threshold is determined based on the transmission efficiency P1 when there is no foreign object, and the threshold is compared with the measured transmission efficiency. If the measured transmission efficiency is a threshold value or larger than the threshold value, it can be determined that no foreign matter exists. That is, it can be determined that transmission to the power receiving device (energy supply to the first self-resonant coil 3) is performed.

  On the other hand, if the measured transmission efficiency is less than the threshold, it can be determined that there is a foreign object. That is, it is determined that transmission to the power receiving device (energy supply to the first self-resonant coil 3) is not performed.

  Here, the threshold value may be the same value as the transmission efficiency P1, or may be a value smaller than the transmission efficiency P1. For example, depending on the installation environment of the power transmission device, there may be a desk, a floor of a room, a wall of a room, and the like nearby. In this case, depending on the surrounding environment, the transmission efficiency may be deteriorated even if there is no foreign object. Therefore, by adopting a value smaller than the transmission efficiency P1 as the threshold value, it is possible to prevent detection of a foreign object that does not greatly affect the transmission efficiency. That is, the foreign matter detection accuracy is improved. This will be described in more detail below.

  Depending on the situation where the power transmitting device and the power receiving device are placed, a difference in transmission efficiency may occur depending on the surrounding environment. For example, consider a case where a power transmission device or a power reception device is arranged near the wall of a building. In this case, lines of magnetic force are generated around the system including the power transmission device and the power reception device. When the magnetic field lines reach the wall portion, the transmission efficiency between the foreign object detection coils deteriorates due to the influence of the wall. That is, the transmission efficiency in a state where there is no wall in the surrounding environment and no foreign matter is different from the transmission efficiency in a state where there is a wall in the surrounding environment and no foreign matter.

  Therefore, if the transmission efficiency is measured in an environment free of foreign matter and a threshold value is set based on the measured value, foreign matter detection more suitable for the usage situation can be performed. For example, a value smaller than the transmission efficiency in an environment without foreign matter is set as the threshold value. This is effective when it is not desired to detect a foreign object that does not greatly affect the transmission efficiency.

  Note that the transmission efficiency varies depending on various parameters such as transmission distance, transmission power, and transmission frequency. Therefore, when determining the threshold value, the values may be calculated in advance in consideration of these implementations.

  In addition, foreign matter detection is performed only in the space between the power transmission device and the power receiving device, and when foreign matter detection is not required in the space where the power receiving device does not exist (for example, the left side in the drawing), foreign matter detection is not necessary. A shield made of a metal plate and a magnetic plate may be arranged on the side. Thereby, since the generated magnetic field is blocked by the shield, it is possible to prevent detection of unnecessary foreign matter.

  Hereinafter, examples of the arrangement of the first self-resonant coil for detecting foreign matter, the first self-resonant coil, and the second self-resonant coil for detecting foreign matter will be described with reference to FIGS. 4, 5, 6, 7, and 8. .

  FIG. 4 shows a first coil arrangement example.

  The first self-resonant coil 113 for detecting foreign matter, the first self-resonant coil 111, and the second self-resonant coil 115 for detecting foreign matter are wound by winding a conducting wire one or more times perpendicularly to the first central axes 114, 112, and 116, respectively. It has a structure.

  The central axes 114, 112, 116 of the coils 113, 111, 115 are parallel to each other. The longitudinal directions of the coils 113, 111, and 115 are parallel to each other.

  Further, these coils 113, 111, 115 are arranged at the same height (for example, the substrate surface).

  Further, these coils 113, 111, 115 are arranged in a line in a direction perpendicular to the longitudinal direction. That is, these coils 113, 111, 115 are arranged on a straight line 117 shown in the figure. The first self-resonant coil 111 is disposed so as to be sandwiched between two coils 113 and 115 for detecting foreign matter.

  By arranging in this way, the foreign object detection direction can be matched with the power transmission direction. In addition, since magnetic lines of force are generated in a range between the power transmitting device and the power receiving device as shown in FIG. 3, the foreign matter detection accuracy in this range can be increased.

  FIG. 5 shows a second coil arrangement example.

  The foreign object detection first self-resonance coil 103, the first self-resonance coil 101, and the foreign object detection second self-resonance coil 105 have a winding structure in which a conducting wire is wound around the central axes 104, 102, and 106 at least once. Have.

  The central axes 104, 102, 106 of the coils 103, 101, 105 are parallel to each other. The longitudinal directions of the coils 103, 101, 105 are parallel to each other.

  The foreign matter detection coils 103 and 105 are arranged at the same height (for example, the substrate surface), and the first self-resonant coil 101 is arranged at a height higher than these coils 103 and 105. In mounting, the arrangement as shown in FIG. 4 may not be possible due to restrictions on the coil arrangement. In this case, an arrangement as shown in FIG. 5 can be adopted.

  Even with this arrangement, the foreign object detection direction can coincide with the direction of power transmission, and foreign objects in the direction of power transmission can be detected.

  FIG. 6 shows a third coil arrangement example.

  The first self-resonant coil 145 for foreign matter detection, the first self-resonant coil 144, and the second self-resonant coil 146 for foreign matter detection are wound structures in which a conducting wire is wound around the central axes 142, 141, and 143 one or more times. have.

  The coils 145, 144, and 146 are arranged at the same height. The longitudinal direction of the foreign matter detection coils 145 and 146 is symmetrical to the longitudinal direction of the first self-resonant coil 144. That is, the central axes 142 and 143 of the foreign matter detection coils 145 and 146 are symmetrical with respect to the central axis 141 of the first self-resonant coil 144. With this configuration, the foreign object detection range can be expanded.

  That is, the lines of magnetic force generated from the foreign object detection first self-resonant coil 145 are generated in a direction parallel to the central axis 142 where the coil 145 is placed. Further, the magnetic field lines where the foreign substance detection second self-resonant coil 146 is placed are generated in a direction parallel to the central axis 143 thereof. As a result, magnetic field lines 147 are generated in a wide range as shown in the figure. Since foreign matter detection is performed based on whether or not the magnetic force lines 147 block the foreign matter, the foreign matter detection range can be expanded.

  FIG. 7 shows a fourth coil arrangement example.

  The first self-resonant coil 155 for foreign matter detection, the first self-resonant coil 154, and the second self-resonant coil 156 for foreign matter detection are wound structures in which a conducting wire is wound at least once around the central axes 152, 151, 153. have.

  The coils 155, 154, and 156 are arranged at the same height. The longitudinal direction of the foreign matter detection coils 155 and 156 is symmetrical with respect to the longitudinal direction of the first self-resonant coil 154. That is, the central axes 152 and 153 of the foreign matter detection coils 155 and 156 are symmetric with respect to the central axis 151 of the first self-resonant coil 154.

  This arrangement makes it possible to narrow the foreign object detection range. For example, this arrangement is effective when the distance from the power receiving device is determined in advance and it is not necessary to detect a foreign object behind the power receiving device (the side opposite to the side where the power transmitting device is present).

  FIG. 8 shows a fifth example of coil arrangement.

  The first self-resonant coil 132 is arranged in the center of the casing of the power transmission device 131, and the first self-resonant coil for foreign matter detection 133 and the second self-resonant coil for foreign matter detection are arranged at both end portions (corner portions) of the diagonal line in the casing. 134 is arranged. In this case, a wide range of foreign substances can be detected.

  That is, the magnetic field lines can be formed in a wide range by separating the foreign substance detection first self-resonant coil 133 and the foreign substance detection second self-resonant coil 134 as far as possible in the casing. As a result, the foreign object detection range can be expanded.

  FIG. 9 is a flowchart showing a flow of operations of the power transmission device of FIG.

  First, the control circuit 11 generates high-frequency energy having the same frequency (f2) as the resonance frequency of the foreign object detection first self-resonant coil 4 and supplies it to the foreign object detection first self-resonant coil 4 (step S1).

  Part of the energy supplied to the first self-resonant coil 4 for detecting foreign matter is received by the second self-resonant coil 5 for detecting foreign matter due to electromagnetic coupling (magnetic resonance) with the first self-resonant coil 4 for detecting foreign matter. (Step S2).

  The transmission efficiency measurement circuit 6 calculates the wireless power transmission efficiency from the magnitude of energy transmitted from the coil 4 and the magnitude of energy received by the coil 5 (step S3).

The calculated transmission efficiency is compared with a threshold value (predetermined efficiency), and it is determined whether or not power is transmitted from the first self-resonant coil 3 to the power receiving device (step S4). That is, when the calculated transmission efficiency that determines whether or not to supply high-frequency energy to the first self-resonant coil 3 is less than the threshold value, there is a foreign object between the power transmission device and the power reception device or in the vicinity of the power transmission device. Judgment is made (the presence of foreign matter in step S4), and it is determined that no power is transmitted from the first self-resonant coil 3 (step S7). If the transmission has already been performed, the transmission is stopped (step S7). The control circuit 11 may notify the user of foreign object detection by an alarm.

  After step S7, it waits for a predetermined time (step S8), and returns to step S1.

  On the other hand, when the calculated transmission efficiency is equal to or greater than the threshold value, it is determined that there is no foreign matter (no foreign matter in step S4), and high-frequency energy transmission is started from the first self-resonant coil 3 (step S5). That is, supply of energy having the same frequency f1 as the resonance frequency of the first self-resonant coil 3 to the first self-resonant coil 3 is started. If power transmission has already been performed, power transmission is continued. A part of the high frequency energy resonated to the first self-resonant coil 3 is received by the second self-resonant coil 8 by magnetic resonance (magnetic coupling).

  After the start of transmission or after continuation of transmission is determined, the system waits for a predetermined time (step S6) and returns to step S1.

  As described above, the value of the resonance frequency of the foreign matter detection coils 4 and 5 is sufficiently separated from the resonance frequency of the first self-resonance coil 3. Hereinafter, the reason will be described.

  FIG. 10 is a diagram for explaining the reason.

  A foreign object detection first self-resonant coil 43, a first self-resonant coil 41, and a foreign object detection second self-resonant coil 44 are arranged in the power transmission device. Further, the rectangle on the right side of the figure shows a block of the power receiving device, and the second self-resonant coil 42 is provided in the power receiving device. For simplicity of explanation, illustration of other elements in the power transmission device and the power reception device is omitted. Reference numeral 45 represents a foreign substance, and reference numeral 46 represents a line of magnetic force.

  Forming a magnetic field when the resonance frequency of the first self-resonant coil 41 is the first frequency and the resonance frequency of the foreign matter detection coils 43 and 44 is the second frequency sufficiently separated from the first frequency. The explanation is as follows.

  When the high frequency energy of the second frequency is supplied to the foreign object detection first self-resonant coil 43, a magnetic field corresponding to the second frequency is generated. The magnetic field is received by the foreign substance detection second self-resonant coil 44 having the same second frequency as the resonance frequency by magnetic resonance. However, this magnetic field is not received or received by the first and second self-resonant coils 41 and 42.

  On the other hand, the formation of the magnetic field in the case where the resonance frequencies of the first self-resonant coil 41 and the foreign matter detection coils 43 and 44 are the same first frequency will be described as follows.

  When high-frequency energy having the first frequency is supplied to the foreign object detection first self-resonant coil 43, a magnetic field corresponding to the first frequency is generated. This magnetic field is received by the foreign substance detection second self-resonant coil 44 and also by the first and second self-resonant coils 41 and 42 by magnetic resonance. For this reason, when measuring the transmission efficiency between the foreign matter detection coils 43 and 44, it is determined whether the transmission efficiency has been reduced because of the presence of the foreign matter 45, or has become smaller because it has been received by the first and second self-resonant coils. It becomes impossible to judge from the measured value alone. When high frequency energy of the first frequency is supplied to the first self-resonant coil 41, a part of this energy is also received by the foreign matter detection coils 43 and 44, and the transmission efficiency is lowered.

  Therefore, in this embodiment, the resonance frequency of the foreign matter detection coils 43 and 44 is sufficiently separated from the first frequency, thereby improving the foreign matter detection accuracy and achieving high transmission efficiency.

  Here, how far the first frequency and the second frequency should be separated from each other is determined in advance by simulation or experiment. For example, the determination can be performed as follows.

  First, the resonance frequencies of the first self-resonant coil 41 and the foreign object detection coil 44 are both set to the first frequency. High frequency energy of the first frequency is supplied to the first self-resonant coil 41, and the magnitude of energy received by the foreign object detection coil 44 is measured. The value measured at this time is defined as power P (reference value). The same measurement is performed while gradually shifting the value of the resonance frequency of the foreign object detection coil 44 from the first frequency. If the frequency is separated until the measured value at this time becomes P / 2, the coupling between the coils 41 and 44 can be sufficiently prevented. Here, P / 2 is used. However, when it is desired to further prevent the coupling, it is effective to increase the frequency to P / 10 and P / 100.

  However, the present embodiment is not limited to an example in which the resonance frequencies of the first self-resonant coil 41 and the foreign matter detection coils 43 and 44 are different. Even when these resonance frequencies are the same, the foreign object detection accuracy and the transmission efficiency are lowered, but the implementation is possible.

  In this embodiment, in order to obtain efficient magnetic coupling, that is, magnetic resonance, high-frequency energy having a frequency that matches the resonance frequency of the first self-resonant coil 41 and the resonance frequency of the foreign matter detection coils 43 and 33 is supplied. . However, the present embodiment is not limited to this, and high frequency energy having a frequency deviated from the resonance frequency of these coils can be supplied to these coils. The efficiency of magnetic coupling is reduced, but even in that case, foreign object detection is possible.

  As described above, according to the present embodiment, by determining the transmission efficiency between the first self-resonant coil for foreign matter detection and the second self-resonant coil for foreign matter detection, the presence or absence of foreign matter around the power transmission device can be determined. In particular, it is possible to detect a foreign object present at a location away from the power transmission device or the power reception device.

  In addition, by providing the foreign object detection first self-resonance coil and the foreign object detection second self-resonance coil in the power transmission apparatus, it becomes possible to detect the foreign object without depending on the distance between the power transmission apparatus and the power reception apparatus.

  In the above embodiment, the foreign object detection is performed on the power transmission side, but can also be performed on the power reception side. In this case, the first self-resonant coil for foreign matter detection, the second self-resonant coil for foreign matter detection, the transmission efficiency measurement circuit, the foreign matter detection circuit, and the control circuit are provided in the power receiving device, and the power transmission device is the same as described above. The foreign object detection operation may be performed by the power receiving device. When determining that there is no foreign object, the control circuit may transmit a power transmission permission notification to the power transmission device via the wireless circuit and the antenna (see FIG. 11 described later). Further, when detecting foreign matter, the user may be notified of foreign matter detection by an alarm. In the following embodiments, the foreign object detection is performed by the power transmission device, but may be performed by the power reception device.

(Second embodiment)
In the first embodiment, the resonance frequency of the self-resonance coil and the resonance frequency of the foreign object detection coil are made different from each other, and the control circuit generates two types of high-frequency energy of each resonance frequency.

  However, depending on the control circuit, only high-frequency energy having a single resonance frequency may be generated. In this embodiment, even in such a case, a form for obtaining high foreign object detection accuracy is shown.

  FIG. 11 shows configurations of the power transmission device and the power reception device of the present embodiment. Elements having the same names as those in FIG. 1 are denoted by the same reference numerals, and redundant description is omitted except for extended functions.

  A wireless circuit 16 and an antenna 17 are provided in the power transmission device 1. In addition, a radio circuit 18, an antenna 19, and a control circuit 20 are provided in the power receiving device 2.

  The radio circuits 16 and 18 receive transmission information from the control circuits 11 and 20 at the time of transmission, and perform analog transmission signals by performing transmission processing such as encoding, modulation, band limitation, and amplification on the transmission information. Generate. The radio circuits 16 and 18 radiate analog transmission signals as radio waves to the space via the antennas 17 and 19.

  The radio circuits 16 and 18 receive radio wave signals via the antennas 17 and 19 at the time of reception, and perform reception processing such as amplification, band limitation, demodulation, and decoding on the received analog signals, thereby obtaining information. get. The radio circuits 16 and 18 send the acquired information to the control circuits 11 and 20.

  The control circuit 11 in the power transmission device 1 and the control circuit 20 in the power reception device 2 perform information communication with each other via the radio circuits 16 and 18 and the antennas 17 and 19.

  The first self-resonant coil 3 and the foreign matter detection coils 4 and 5 are configured so that the resonance frequency is variable. The control circuit 11 controls the resonance frequency of these coils. The resonance frequency of the second self-resonant coil 8 is variable. The control circuit 20 controls the resonance frequency of the second self-resonant coil 8.

  FIG. 12 shows the configuration of the first and second self-resonant coils 3 and 8 and the foreign matter detection coils 4 and 5.

  A variable capacitor 62 is provided in the middle of the coil 61. By changing the value of the variable capacitor 62, the capacitance value of the coil 61 is changed. The resonance frequency of the coil is determined by the coil inductor and its own stray capacitance (capacitance between coil wires). Therefore, the resonance frequency of the coil 61 can be controlled by changing the value of the variable capacitor 62. The first and second self-resonant coils 3 and 8 and the foreign matter detection coils 4 and 5 have the same configuration as the coil 61.

  The control circuit 11 controls the respective resonance frequencies by adjusting the variable capacitance values of the first self-resonant coil 3 and the foreign matter detection coils 4 and 5. Further, the control circuit 20 controls the resonance frequency of the second self-resonant coil 8 by adjusting the value of the variable capacitance.

  In the present embodiment, foreign object detection and power transmission are performed in different time zones.

  When detecting foreign matter, the resonance frequency of the foreign matter detection coils 4 and 5 is set to a first frequency, and the resonance frequency of the first self-resonant coils 3 and 8 is set to a frequency other than the first frequency. This frequency is a value sufficiently away from the first frequency, and is determined in advance by the method described in the first embodiment. On the other hand, during power transmission, the resonance frequency of the first and second self-resonant coils 3 and 8 is set to the first frequency, and the resonance frequency of the foreign matter detection coils 4 and 5 is set to a frequency other than the first frequency.

  FIG. 13 shows the resonance frequency states of the first and second self-resonant coils 3 and 8 and the foreign object detection coils 4 and 5 when performing power transmission and foreign object detection.

  In this way, by changing the resonance frequency according to the time period during which foreign object detection and power transmission are performed, the foreign object can be detected in a state where the influence of the first self-resonant coil and the second self-resonant coil is eliminated. Further, it is possible to prevent the transmission efficiency from being lowered due to the magnetic field received by the foreign object detection coil during power transmission.

  FIG. 14 is a flowchart showing an operation flow of the power transmission device according to the present embodiment.

  The control circuit 11 controls the resonance frequency of the foreign object detection first self-resonance coil 4 and the foreign object detection second self-resonance coil 5 to the first frequency (step S21).

  The control circuit 11 controls the resonance frequency of the first self-resonant coil 3 and the second self-resonant coil 8 to a frequency different from the first frequency (step S22). At this time, the resonance frequencies of the first self-resonant coil 3 and the second self-resonant coil 8 may be the same or different. The control of the second self-resonant coil 8 is performed by the control circuit 11 communicating with the control circuit 20 in the power receiving apparatus. The control circuit 20 in the power receiving device controls the resonance frequency of the coil 8 in accordance with an instruction from the control circuit 11.

  The control circuit 11 generates high-frequency energy having the same frequency (first frequency) as the resonant frequency of the foreign object detection first self-resonant coil 4 and supplies the high-frequency energy to the foreign object detection first self-resonant coil 4 (step S23).

  Part of the energy supplied to the first self-resonant coil 4 for detecting foreign matter is received by the second self-resonant coil 5 for detecting foreign matter due to electromagnetic coupling (electromagnetic resonance) with the first self-resonant coil 4 for detecting foreign matter. (Step S24).

  The transmission efficiency measurement circuit 6 calculates the wireless power transmission efficiency from the magnitude of energy transmitted from the coil 4 and the magnitude of energy received by the coil 5 (step S25).

  Whether the calculated transmission efficiency is compared with a threshold (predetermined efficiency) and whether power is transmitted from the first self-resonant coil 3 to the power receiving device, that is, whether high-frequency energy is supplied to the first self-resonant coil 3 Whether or not is determined (step S26).

  When the calculated transmission efficiency is less than the threshold value, it is determined that there is a foreign object between the power transmitting apparatus and the power receiving apparatus or in the vicinity of the power transmitting apparatus (the foreign object is present in step S26), and no power is transmitted from the first self-resonant coil 3. Decide that.

  In this case, the process waits for a predetermined time (step S32) and returns to step S21.

  On the other hand, when the calculated transmission efficiency is equal to or greater than the threshold value, it is determined that there is no foreign matter (no foreign matter in step S26), and the control circuit 11 sets the resonance frequencies of the first and second self-resonant coils 3 and 8 to the first The frequency is set (step S27).

  Further, the control circuit 11 sets the resonance frequency of the foreign matter detection coils 4 and 5 to a value different from the first frequency (step S28). At this time, the resonance frequencies of the foreign matter detection coils 4 and 5 may be the same or different.

  Next, power transmission is started from the first self-resonant coil 3 (step S29). That is, energy supply at the frequency f1 is started to the first self-resonant coil 3. Part of the energy supplied to the first self-resonant coil 3 is received by the second self-resonant coil 8 by magnetic resonance (magnetic coupling).

  When a predetermined time has elapsed after the start of power transmission, power transmission is stopped (step S30).

  After power transmission is stopped, after waiting for a predetermined time, the process returns to step S21 (step S31).

  As mentioned above, according to this embodiment, even if it is a case where only the high frequency energy of a single frequency can be produced | generated in a power transmission apparatus, achievement of the high detection accuracy of a foreign material and highly efficient electric transmission are attained.

(Third embodiment)
In this embodiment, a case where the first self-resonant coil for foreign matter detection is shared with the first self-resonant coil is shown.

  FIG. 15 shows a power transmission device and a power reception device according to this embodiment.

  In the power transmission device, a first self-resonant coil (hereinafter referred to as a common coil) 51 shared with the foreign object detection first self-resonant coil and a foreign object detection second self-resonant coil 53 are provided. A second self-resonant coil 52 is provided in the power receiving device. Reference numeral 54 indicates a foreign substance, and reference numeral 55 indicates a magnetic field line. As shown in FIG. 12, the shared coil 51 includes a variable capacitor and is configured to be able to change the resonance frequency. Elements other than these coils 51, 52, and 53 in the power transmitting device and the power receiving device are the same as those in FIG.

  Both the first self-resonant coil and the first foreign object detection first self-resonant coil described so far generate a magnetic field when high-frequency energy is supplied. Therefore, when detecting foreign matter, there is no problem even if the first self-resonant coil is used as the first self-resonant coil for foreign matter detection. By making both coils into one and sharing it, the power transmission device can be reduced in size.

  FIG. 16 shows an example of resonance frequency control of the shared coil 51, the foreign object detection second self-resonant coil 53, and the second self-resonant coil 52 during power transmission and foreign object detection.

  The resonance frequency of the shared coil 51 is always the first frequency. That is, the shared coil 51 does not need to change the resonance frequency between power transmission and foreign object detection.

  On the other hand, the resonance frequencies of the second self-resonant coil 52 and the foreign substance detection second self-resonant coil 53 are changed by power transmission and foreign object detection.

  That is, during power transmission (in the first mode), the resonance frequency of the second self-resonant coil 52 is set to the first frequency, and the resonance frequency of the foreign substance detection second self-resonant coil 53 is set to a frequency other than the first frequency.

  On the other hand, at the time of foreign object detection (second mode), the resonance frequency of the second self-resonant coil 52 is set to a frequency other than the first frequency, and the resonance frequency of the second self-resonant coil 53 for detecting foreign objects is set to the first frequency.

  By controlling the resonance frequency of each coil in this way, the detection accuracy of the foreign matter can be increased and the transmission efficiency between the power transmitting device and the power receiving device can be increased as in the principle already described.

  As described above, according to the present embodiment, the power transmission device can be reduced in size by sharing the foreign object detection first self-resonant coil with the first self-resonant coil.

(Fourth embodiment)
In the present embodiment, a case where the power transmission device achieves high foreign object detection accuracy using three or more foreign object detection coils is shown. The block diagram of this embodiment is the same as FIG. 1 or FIG. 11 except for the coil.

  FIG. 17 is a plan view showing an arrangement example of the first self-resonant coil and the three foreign object detection coils.

  The first self-resonant coil 121 (first coil) and the three foreign substance detecting self-resonant coils 122a, 122b, 122c (second to n-th coils) are arranged on the same plane, that is, at the same height.

  The foreign object detection self-resonant coils 122a, 122b, 122c are arranged at equal intervals along a concentric circle 123 centered on the first self-resonant coil 121.

  That is, the foreign matter detection coils 122a, 122b, and 122c are arranged at equal distances from the first self-resonant coil 121 and at equal intervals so as to surround the periphery of the first self-resonant coil 121.

  In this configuration, foreign matter detection is performed using two selected from three or more foreign matter detection coils. When the combination of coils to be selected is changed, the direction of the magnetic field lines generated in the space is changed. For this reason, even when the location and orientation of the foreign matter changes, high foreign matter detection accuracy can be obtained.

  FIG. 18 is a plan view showing an arrangement example of the first self-resonant coil and the four foreign object detection coils.

  The first self-resonant coil 161 (first coil) and the four foreign substance detecting self-resonant coils 163a, 163b, 163c, 163d (second to n-th coils) are arranged on the same plane, that is, at the same height. Yes.

  The foreign object detection self-resonant coils 163a, 163b, 163c, and 163d are arranged at equal intervals (here, every 90 degrees) along a concentric circle 162 centered on the first self-resonant coil 161.

  The central axes 164a, 164b, 164c, and 164d of the foreign matter detection coils 163a, 163b, 163c, and 163d are parallel to the tangential direction of the concentric circle 162. Here, the central axes 164a, 164b, 164c, and 164d coincide with the tangent line of the concentric circle 162.

  The foreign matter detection coils 163a and 163c are arranged to face each other via the first self-resonant coil 161. Similarly, the foreign matter detection coils 163b and 163d are also arranged to face each other via the first self-resonant coil 161.

  Two types of lines of magnetic force are formed by pairing the coils for detecting foreign matter facing each other. The two types of magnetic field lines are a magnetic field line by a pair of foreign matter detection coils 163a and 163c and a magnetic field line by a pair of foreign matter detection coils 163b and 163d. These magnetic field lines are inclined 90 degrees. Therefore, by detecting foreign matter for each pair, a wide range of foreign matters can be detected.

  FIG. 19 is a perspective view showing an arrangement example of the first self-resonant coil and the six foreign object detection coils.

  The first self-resonant coil 177 (first coil) and the six foreign object detection self-resonant coils 172a, 172b, 174a, 174b, 176a, 176b (second to nth coils) are the X-axis, Y-axis, It is arranged in a three-dimensional space with the Z axis.

  The first self-resonant coil 177 is arranged at the center of the three-dimensional space, that is, the origin of the XYZ coordinates.

  The foreign matter detection coils 172a and 172b are arranged on a circle having the origin at the center and perpendicular to the Y axis. More specifically, these coils 172a and 172b are arranged at the intersection of the circle and the Z axis. Center axes 171a and 171b (longitudinal direction) of the coils 172a and 172b coincide with the X-axis direction. The foreign object detection coils 172a and 172b are opposed to each other via the first self-resonant coil 177 at a position equidistant from the first self-resonant coil 177.

  The foreign matter detection coils 174a and 174b are arranged on a circle with the origin at the center and perpendicular to the Z axis. More specifically, these coils 174a and 174b are arranged at the intersection of the circle and the X axis. Center axes 173a and 173b (longitudinal direction) of the coils 174a and 174b coincide with the Y-axis direction. The foreign matter detection coils 174 a and 174 b are opposed to each other via the first self-resonant coil 177 at a position equidistant from the first self-resonant coil 177.

  The foreign matter detection coils 176a and 176b are arranged on a circle having the origin at the center and perpendicular to the X axis. More specifically, these coils 176a and 176b are arranged at the intersection of the circle and the Y axis. Center axes 175a and 175b (longitudinal direction) of the coils 176a and 176b coincide with the Z-axis direction. The foreign matter detection coils 176a and 176b are opposed to each other via the first self-resonant coil 177 at a position equidistant from the first self-resonant coil 177.

  The direction connecting the foreign matter detection coils 172a and 172b, the direction connecting the foreign matter detection coils 174a and 174b, and the direction connecting the foreign matter detection coils 176a and 176b are orthogonal to each other.

  Magnetic field lines when using a pair of foreign matter detection coils 172a and 172b, magnetic field lines when using a pair of foreign matter detection coils 174a and 174b, and when using a pair of foreign matter detection 176a and 176b The magnetic field lines are in a perpendicular relationship. Therefore, foreign matter inspection for each pair makes it possible to detect foreign matter in a wide range of a three-dimensional space.

  FIG. 20 is a flowchart showing the operation of the power transmission device when there are three or more foreign object detection self-resonant coils.

  The control circuit 11 selects two of the three or more foreign object detection self-resonant coils, the resonance frequency of the selected coil is the first frequency f1, and the resonance frequency of the non-selected coil is other than the first frequency. (Step S41). The two selected coils are called first and second foreign object detection self-resonant coils, respectively. Selectable coil combinations are set in advance. The setting contents are stored in the control circuit 11 or in accessible storage means.

  The control circuit 11 generates high-frequency energy having the same frequency (first frequency) as the resonance frequency of the foreign object detection first self-resonant coil and supplies the high-frequency energy to the foreign object detection first self-resonant coil (step S42). That is, power is transmitted at the first frequency from the foreign object detection first self-resonant coil.

  Part of the energy supplied to the first self-resonant coil for foreign matter detection is received by the second self-resonant coil for foreign matter detection by electromagnetic coupling (electromagnetic resonance) with the first self-resonant coil for foreign matter detection (step S43).

  The transmission efficiency measuring circuit 6 calculates the wireless power transmission efficiency from the magnitude of energy transmitted from the foreign object detection first self-resonant coil and the magnitude of energy received by the foreign substance detection second self-resonant coil ( Step S44).

  Steps S41 to S44 are performed by changing the combination of the foreign object detection self-resonant coils to be selected. Thereby, a plurality of transmission efficiencies are calculated for all selectable coil combinations (step S45).

  Whether the transmission efficiency from the first self-resonance coil is compared with the threshold (predetermined efficiency) among the transmission efficiencies calculated in step S45 and whether or not power is transmitted from the first self-resonance coil, that is, the first self-resonance coil It is determined whether or not to supply high-frequency energy to (step S46).

  When the minimum transmission efficiency is equal to or greater than the threshold value, it is determined that there is no foreign object between the power transmission device and the power reception device or in the vicinity of the power transmission device, and power transmission is started at the frequency f2 from the first self-resonant coil (step S47). The transmitted energy is received by the second self-resonant coil by magnetic coupling. However, when power transmission has already started from the first self-resonant coil, power transmission is continued (step S47).

  When a predetermined time has elapsed after the start of power transmission or the decision to continue power transmission, the process returns to step S41 (step S48).

  On the other hand, when the minimum transmission efficiency is less than the threshold value, it is determined that there is a foreign object between the power transmission device and the power reception device or in the vicinity of the power transmission device, and it is determined that power transmission from the first self-resonant coil is not performed (step). S49). When the power transmission has been started, the power transmission is stopped (step S49).

  After a predetermined time from power transmission stop, the process proceeds to step S51 (step S50).

  In step S51, the transmission efficiency is measured in the same procedure as in steps S42 to S44 using the coil combination corresponding to the minimum transmission efficiency adopted in the previous step S46.

  The transmission efficiency measured in step S51 is compared with a threshold value to determine whether or not to perform power transmission to the power receiving apparatus (step S52).

  When the measured transmission efficiency value is less than the threshold value, it is determined that there is a foreign object, and the process returns to step S50.

  On the other hand, when the measured transmission efficiency value is equal to or greater than the threshold value, the transmission efficiency is measured for each of the coil combinations other than the coil combination used in step S51 in the same procedure as in steps S42 to S44. S53).

  Thereafter, the process returns to step S46, and the minimum transmission efficiency is selected from the transmission efficiencies measured in step S53, and the selected minimum transmission efficiency is compared with the threshold value. When the minimum transmission efficiency is less than the threshold value, it is determined that there is a foreign object, and the process proceeds to step S49. When it is equal to or greater than the threshold value, it is determined that no foreign object exists and the process proceeds to step S47. Thereafter, the above procedure is repeated.

(Fifth embodiment)
The present embodiment shows a case where a threshold value (predetermined efficiency) used in foreign object detection is dynamically changed.

  The block diagram of this embodiment is the same as FIG. However, the function of the control circuit 11 is expanded.

  Consider a case in which the transmission efficiency between a foreign object detection first self-resonance coil and a foreign object detection second self-resonance coil is measured at a plurality of frequencies including a first frequency used for power transmission. In this case, the distribution of frequency and transmission efficiency can be classified into a pattern having the lowest transmission efficiency of the first frequency and a pattern other than that.

  FIG. 21 (a) shows the pattern with the lowest transmission efficiency of the first frequency, and FIG. 21 (b) shows one of the other patterns. Here, the results of measurement performed at three frequencies: a first frequency, a frequency lower than the first frequency, and a frequency higher than the first frequency are shown.

  In Fig. 21 (a), the transmission efficiency of the first frequency is the smallest of the three transmission efficiencies, and in Fig. 21 (b), the transmission efficiency of the first frequency is the middle of the three transmission efficiencies. It is a size.

  In the case as shown in FIG. 21 (a), there is a possibility that the foreign substance absorbs a large amount of energy at the first frequency. That is, there is a possibility that the resonance frequency of the foreign matter is the first frequency or close to it. Such foreign matter concentrates on a specific place of the foreign matter and energy is absorbed, and the temperature of the foreign matter is likely to rise with a little energy absorption.

  On the other hand, in the case as shown in FIG. 21 (b), there is no foreign substance having the first frequency as the self-resonant frequency. In such a case, even if there is a foreign object, the energy is not concentrated and absorbed at a specific location of the foreign object. Even with a small amount of energy absorption, the temperature of the foreign material is unlikely to rise.

  From the above, in the case of the pattern having the lowest transmission efficiency of the first frequency as shown in FIG. 21 (a), a large value can be used as the threshold value. On the other hand, it is necessary to use a small value as the threshold value in a pattern represented by the case of FIG. 21 (b) where the transmission efficiency of the first frequency is not the lowest.

  Note that the first frequency may be a frequency used in another wireless communication system.

  For example, consider an environment in which another wireless communication system is present at the first frequency used for wireless power transmission or at a frequency close thereto.

  In this case, a coil or antenna used in another wireless communication system resonates in this frequency band. If the coil or antenna of this other wireless communication system must also be detected as a foreign object, detect the foreign object using the first frequency that is equal to or close to the resonance frequency of the coil or antenna. It becomes possible to increase the accuracy.

  FIG. 22 is a flowchart showing a flow of operation of the power transmission device in the present embodiment.

  The control circuit 11 controls the resonance frequency of the first self-resonance coil for foreign matter detection and the second self-resonance coil for foreign matter detection to the first frequency, and sets the resonance frequency of the first self-resonance coil and the second self-resonance coil to the first frequency. Control other than the frequency is performed (step S61). The control of the second self-resonant coil is performed by the control circuit 11 communicating with the control circuit 20 in the power receiving device.

  The control circuit 11 supplies high-frequency energy of the first frequency to the foreign object detection first self-resonance coil, and transmits power from the foreign object detection first self-resonance coil at the first frequency (referred to as f1) (step S62).

  The foreign object detection second self-resonant coil receives power by magnetic resonance with the foreign object detection first self-resonant coil (step S63).

  The transmission efficiency measurement circuit 6 calculates the wireless power transmission efficiency (referred to as η1) between the first foreign object detection self-resonant coil and the second foreign object detection self-resonant coil transmitted at the first frequency (step S64). ).

  The control circuit 11 controls the resonance frequency of the first foreign substance detection first self-resonance coil and the second foreign substance detection second self-resonance coil to a second frequency (referred to as f2) lower than the first frequency f1, The resonance frequency of the second self-resonant coil is controlled to other than the second frequency (step S65). Then, the control circuit 11 supplies high-frequency energy of the second frequency to the first foreign substance detection self-resonant coil, and transmits power from the first foreign substance detection self-resonant coil at the second frequency (referred to as f2) (step S65). ).

  The foreign matter detecting second self-resonant coil receives power by magnetic resonance with the foreign matter detecting first self-resonant coil (step S66).

  The transmission efficiency measurement circuit 6 calculates the wireless power transmission efficiency (referred to as η2) between the first foreign object detection self-resonant coil and the second foreign object detection self-resonant coil transmitted at the second frequency (step S64). ).

  The control circuit 11 controls the resonance frequency of the first foreign matter detection first self-resonance coil and the second foreign matter detection second self-resonance coil to a third frequency (referred to as f3) higher than the first frequency f1, The resonance frequency of the second self-resonant coil is controlled to other than the third frequency (step S68). Then, the control circuit 11 supplies high-frequency energy of the third frequency f3 to the foreign object detection first self-resonant coil, and transmits power from the foreign object detection first self-resonant coil at the third frequency f3 (step S68).

  The foreign object detection second self-resonant coil receives power by magnetic resonance with the foreign object detection first self-resonant coil (step S69).

  The transmission efficiency measuring circuit 6 calculates the wireless power transmission efficiency (η3) between the foreign object detection first self-resonant coil and the foreign object detection second self-resonant coil transmitted at the third frequency (step S70).

  The control circuit 11 compares the transmission efficiencies η1, η2, and η3, and checks whether the transmission efficiency η1 is the smallest (step S71). That is, it is checked whether the relationship of η1 <η2 and η1 <η3 is established.

  When the relationship is established, the control circuit 11 sets the threshold value (predetermined efficiency) to the first value (S73).

  If the relationship is not established, the control circuit 11 sets the threshold value (predetermined efficiency) to the second value (S72). The second value is greater than the first value. The first value and the second value are determined in advance and stored in an internal buffer of the control circuit 11 or storage means accessible by the control circuit 11.

  Foreign matter detection is performed based on the threshold value set in step S72 or S73 (step S74).

  More specifically, the control circuit 11 controls the resonance frequency of the first self-resonance coil for foreign matter detection and the second self-resonance coil for foreign matter detection to the first frequency, and controls the first self-resonance coil and the second self-resonance coil. The resonance frequency is controlled to other than the first frequency.

  The control circuit 11 supplies high-frequency energy of the first frequency to the first foreign substance detection first self-resonance coil, and transmits power from the first foreign substance detection first self-resonance coil at the first frequency f1, and the second foreign substance detection second self-resonance coil Receives power by magnetic resonance with the first self-resonant coil for foreign matter detection.

  The transmission efficiency measuring circuit 6 calculates the wireless power transmission efficiency from the magnitude of energy transmitted from the first foreign object detection self-resonant coil and the magnitude of energy received by the second foreign object detection self-resonant coil. .

  If the calculated transmission efficiency is less than the threshold, the control circuit 11 determines that there is a foreign object, and returns to step S61 after a predetermined time (step S75).

  On the other hand, if the calculated transmission efficiency is equal to or greater than the above threshold, the control circuit 11 determines that there is no foreign matter, and sets the resonance frequencies of the first self-resonance coil and the second self-resonance coil to the first frequency f1. Control (step S76).

The control circuit 11 controls the resonance frequency of the first self-resonance coil for foreign matter detection and the second self-resonance coil for foreign matter detection to a frequency different from the first frequency (for example, f2 or f3). High-frequency energy having the first frequency f1 is supplied to the self-resonant coil, and power is transmitted from the first self-resonant coil (step S78).

  The control circuit 11 stops power transmission from the first self-resonant coil after a predetermined time (step S79).

  After a predetermined time, the process returns to step S61 (step S80).

  As described above, according to this embodiment, it is possible to detect a foreign object having a frequency used for power transmission or a frequency close thereto as a self-resonant frequency with high accuracy.

(Sixth embodiment)
In the first to fifth embodiments described so far, foreign object detection is performed based on the measured transmission efficiency. However, foreign object detection may be performed based on a change in received power.

  That is, the difference between the energy supplied to the foreign object detection first self-resonance coil and the energy received by the foreign object detection second self-resonance coil is calculated. If this difference is less than the threshold, it is determined that there is no foreign object, and power transmission between the power transmission device and the power reception device is not performed. On the other hand, if the difference is greater than or equal to the threshold value, it is determined that there is a foreign object, and power is transmitted between the power transmission device and the power reception device.

  As in the third embodiment, the foreign substance detection first self-resonant coil may be shared with the first self-resonant coil.

(Seventh embodiment)
FIG. 23 shows a wireless power transmission system according to the seventh embodiment. Elements having the same names as those in FIG. 1 are denoted by the same reference numerals, and redundant description is omitted except for extended functions.

  The first self-resonant coil 3 is shared with the first self-resonant coil for detecting an abnormal object described so far. The first self-resonant coil 3 includes a variable capacitor, and the resonance frequency can be controlled to the first frequency and the second frequency. The first frequency is a frequency used for power transmission to the power receiving apparatus. The second frequency is a frequency used for foreign object detection.

  The third self-resonant coil 14 corresponds to the abnormal object detection second self-resonant coil of FIG. 1, and is used for detecting an abnormal object. The resonance frequency of the third self-resonant coil 14 is assumed to be the second frequency.

  The resonance frequency of the second self-resonant coil 8 in the power receiving device 2 is assumed to be the first frequency.

  The load modulation circuit 15 is an impedance circuit that can change a load (impedance value). The load modulation circuit 15 is connected to the third self-resonant coil 14.

  Hereinafter, details of the foreign object detection of the present embodiment will be described.

  When the resonance frequency of the first self-resonant coil 3 is controlled to the second frequency and high-frequency energy matching the frequency is supplied to the first self-resonant coil 3, magnetic field lines are formed so as to penetrate the third self-resonant coil 14. . A current is generated in the third self-resonant coil 14 by the magnetic field lines, and the magnetic field lines are re-formed by the current. This regenerated magnetic field line penetrates the first self-resonant coil 3, and as a result, a current flows through the first self-resonant coil 3.

  Changing the value of the load modulation circuit 15 connected to the third self-resonant coil 14 changes the value of the impedance connected to the third self-resonant coil 14, thereby changing the magnitude of the current flowing through the third self-resonant coil 14. . As a result, the strength of the magnetic field lines to be reformed changes. That is, finally, the magnitude of the current flowing through the first self-resonant coil 3 changes.

  Here, when the value of the load modulation circuit 15 is temporally changed to a binary value, the value of the current of the first self-resonant coil 3 changes in accordance with the load modulation. In the control circuit 11, the current of the first self-resonant coil 3 is monitored.

  The resonance frequency of the first self-resonant coil 3 is set to the second frequency, and power is transmitted from the first self-resonant coil 3 without any foreign matter. The change in current of the first self-resonant coil 3 at this time is observed. The amount of current change observed at this time is used as a reference. This reference is stored in the control circuit 11 or in an accessible storage means.

  The control circuit 11 performs the same measurement by detecting power transmission at the second frequency even when a foreign object is detected, and observes the current change in the first self-resonant coil 3 (second mode).

  The control circuit 11 determines that there is no foreign matter if the amount of current change observed at the time of foreign matter detection and the reference are the same or the difference between them is within a threshold value.

  When the difference between the observed current fluctuation amount and the reference is larger than the threshold (that is, when the observed current fluctuation amount is small or absent), it is determined that there is a foreign object that blocks the magnetic field lines between the coils 3 and 14.

  In other words, when there is no foreign object, the change in the value of the load modulation circuit 15 has no or little influence on the current fluctuation of the first self-resonant coil 3, so that there is no change or a small amount of current change. In other words, since the coupling between the third self-resonant coil 14 and the first self-resonant coil 3 that is connected to the load modulation circuit by a foreign object is reduced, there is no effect on the amount of current change due to fluctuations in the value of the load modulation circuit 15 Or smaller.

  If the control circuit 11 determines that no foreign matter is present, the control circuit 11 sets the resonance frequency of the first self-resonant coil 3 to the first frequency and transmits power to the power receiving device (first mode).

  As described above, according to the present embodiment, foreign object detection can be performed using the current change of the first self-resonant coil when the value of the load modulation circuit connected to the third self-resonant coil is changed.

(Eighth embodiment)
FIG. 24 shows a wireless power transmission system according to the eighth embodiment.

  In the power transmission device 1, a first self-resonant coil (first coil) 3a and a third self-resonant coil (second coil) 3b are provided.

  In the power receiving device 2, a second self-resonant coil (first receiving device side coil) 8a and a third self-resonant coil (second receiving device side coil) 8b are provided.

  The power transmitting apparatus 1 and the power receiving apparatus 2 include elements similar to those in FIG. 11 except for the coils, but the illustration of these other elements is omitted for simplicity of description.

  The first self-resonant coil 3a has a variable capacitor and can control the resonance frequency. Here, the resonance frequency of the first self-resonant coil 3a can be controlled to the first frequency and the third frequency.

  The third self-resonant coil 3b includes a variable capacitor and can control the resonance frequency. Here, the resonance frequency of the third self-resonant coil 3b can be controlled to the second frequency and the third frequency.

  The second self-resonant coil 8a has a variable capacitor and can control the resonance frequency. Here, the resonance frequency of the second self-resonant coil 8b can be controlled to the first frequency and the fourth frequency.

  The fourth self-resonant coil 8b has a variable capacitor and can control the resonance frequency. Here, the resonance frequency of the second self-resonant coil 8b can be controlled to the second frequency and the fourth frequency.

  The control circuit in the power transmission device is connected to the first and third self-resonant coils 3a and 3b, respectively. The control circuit can generate first, second, and third high-frequency energy. The said control circuit supplies the produced | generated high frequency energy to the coil which will transmit power from now on among the coils 3a and 3b.

  The second and fourth self-resonant coils 8a and 8b in the power receiving apparatus can supply the received high-frequency energy to the rectifier circuit. The rectifier circuit rectifies the high-frequency energy supplied from each, and stores the rectified energy in the secondary battery.

  A control circuit, a transmission efficiency measurement circuit, and a foreign object detection circuit (not shown) are provided in the power receiving apparatus.

  A control circuit in the power receiving apparatus controls the resonance frequencies of the second self-resonant coil 8a and the fourth self-resonant coil 8b. The control circuit can generate high-frequency energy of the fourth frequency and supply it to the second self-resonant coil 8a.

  The transmission efficiency measurement circuit in the power receiving apparatus measures the transmission efficiency in the same manner as the transmission efficiency measurement circuit in the power transmission apparatus. The transmission efficiency is measured from the energy transmitted from the second self-resonant coil 8a and the energy received by the fourth self-resonant coil 8b.

  The foreign object detection circuit in the power receiving apparatus performs foreign object detection based on the measured transmission efficiency in the same manner as the foreign object detection circuit in the power transmission apparatus. The foreign matter detection may be performed by applying the same configuration as the sixth or seventh embodiment to the power receiving apparatus instead of the transmission efficiency.

  The system of the present embodiment has three transmission states: a first transmission state (first mode), a second transmission state (second mode), and a third transmission state.

  The first transmission state is used for energy transmission from the power transmission device to the power reception device.

  In the first transmission state, the control circuit in the power transmission device transmits power simultaneously from the first self-resonant coil 3a and the third self-resonant coil 3b. The control circuit in the power transmission apparatus sets the resonance frequency of the first self-resonant coil 3a to the first frequency and the resonance frequency of the third self-resonant coil 3b to the second frequency in advance.

  The second self-resonant coil 8a and the fourth self-resonant coil 8b receive power simultaneously. More specifically, the second self-resonant coil 8a receives a part of the energy transmitted from the first self-resonant coil 3a, and the fourth self-resonant coil 8b is the energy transmitted from the third self-resonant coil 3b. To receive a part of. The control circuit in the power receiving apparatus sets the resonance frequency of the second self-resonant coil 8a to the first frequency and the resonance frequency of the fourth self-resonant coil 8b to the second frequency in advance.

  In such a configuration, since parallel transmission is possible, it is possible to transmit twice the maximum power that can be transmitted or received by one self-resonant coil.

  The second transmission state and the third transmission state are used for foreign object detection.

  In the second transmission state, power is transmitted from the first self-resonant coil 3a and received by the third self-resonant coil 3b. The control circuit in the power transmission device sets the resonance frequency of the first self-resonant coil 3a and the third self-resonant coil 3b to the third frequency in advance, and supplies energy of the frequency to the first self-resonant coil 3a. To do. Thereby, in particular, it is possible to detect a foreign object close to the power transmission device.

  In the third transmission state, power is transmitted from the second self-resonant coil 8a and received by the fourth self-resonant coil 8b. The control circuit in the power receiving apparatus sets the resonance frequency of the second self-resonant coil 8a and the fourth self-resonant coil 8b to the fourth frequency in advance, and supplies energy of the frequency to the second self-resonant coil 8a. To do. Thereby, in particular, it is possible to detect a foreign object close to the power receiving device.

  As described above, according to the present embodiment, the self-resonant coil for transmitting power and the self-resonant coil for detecting foreign matter can be shared. For this reason, the apparatus can be miniaturized.

  In addition, although each embodiment described so far showed the foreign object detection in the case of performing wireless power transmission from the power transmitting apparatus to the power receiving apparatus, the foreign object detection can be used for other purposes.

  For example, the foreign object detection can be applied to a system that performs wireless communication in which a transmission device modulates a high-frequency signal to be transmitted and transmits the modulated high-frequency signal to the reception device. In this case, the transmitting device may transmit a signal obtained by modulating the high-frequency energy signal from the first self-resonant coil, and the receiving device may demodulate the signal received by the second self-resonant coil.

  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.

Claims (15)

A first coil that receives the first high-frequency energy and transmits the supplied first high-frequency energy to the receiver-side coil via magnetic coupling and a second high-frequency energy that are supplied and supplied to the second high-frequency energy. A second coil for generating a corresponding magnetic field;
A third coil that receives the second high-frequency energy from the second coil by coupling with the second coil via a magnetic field generated by the second coil;
A control circuit for supplying the first high-frequency energy to the first coil and supplying the second high-frequency energy to the second coil;
A determination circuit for determining whether to supply the first high-frequency energy to the first coil by the control circuit based on the magnitude of the second high-frequency energy received by the third coil;
A wireless power transmission device comprising: The determination circuit performs determination based on a ratio or difference between the magnitude of the second high-frequency energy supplied to the second coil and the magnitude of the second high-frequency energy received by the third coil. 2. The wireless power transmission device according to claim 1, wherein: The resonance frequency of the first coil is the first frequency,
2. The wireless power transmission device according to claim 1, wherein a resonance frequency of the second coil and the third coil is a second frequency different from the first frequency. The first coil, the second coil, and the third coil are each configured to be able to adjust a resonance frequency,
The control circuit includes:
Before supplying the first high-frequency energy to the first coil, set the resonance frequency of the second coil and the third coil to a value different from the first coil,
Before supplying the second high-frequency energy to the second coil, the resonance frequencies of the second coil and the third coil are set to the same value, and the resonance frequency of the first coil is set to the second coil and Set to a value different from the third coil,
2. The wireless power transmission apparatus according to claim 1, wherein The longitudinal directions of the first coil, the second coil, and the third coil are parallel to each other,
2. The wireless power transmission apparatus according to claim 1, wherein The first coil is disposed in the center of the housing,
2. The wireless power transmission device according to claim 1, wherein the second coil and the third coil are arranged at diagonal corners in the casing. The first coil, the second coil, and the third coil are arranged at the same height,
2. The wireless power transmission device according to claim 1, wherein longitudinal directions of the second coil and the third coil are symmetrical to each other with respect to a longitudinal direction of the first coil. The first high frequency energy has a first frequency,
The control circuit includes:
Supplying the second high-frequency energy to the second coil at each of a plurality of frequencies including the first frequency, a second frequency lower than the first frequency, and a third frequency higher than the first frequency;
Compared between the plurality of frequencies, the magnitude of the second high-frequency energy received by the third coil via magnetic coupling with the second coil,
When the magnitude of the second high frequency energy corresponding to the first frequency is the lowest, select the first threshold,
When the magnitude of the second high-frequency energy corresponding to any one frequency other than the first frequency among the plurality of frequencies is the lowest, select a second threshold smaller than the first threshold,
The wireless power transmission device according to claim 1, wherein the determination unit performs the determination based on a comparison with a selected threshold value. 4th to nth (n is an integer of 4 or more) coils,
The control circuit selects different coil pairs consisting of two of the second to n-th coils a plurality of times, and supplies the second high-frequency energy to one coil of the selected coil pair,
The other coil of the selected coil pair receives the second high-frequency energy via magnetic coupling with the one coil,
2. The wireless power transmission device according to claim 1, wherein the determination circuit performs the determination based on the magnitude of the second high-frequency energy received by the other coil for each coil pair. 10. The second to n-th coils are arranged so as to surround the first coil at positions equidistant from the first coil and at equal intervals from each other. Wireless power transmission device. 11. The wireless power transmission device according to claim 10, wherein the control circuit selects a coil pair including coils facing each other via the first coil. The second and third coils are arranged so as to face each other through the first coil at a position equidistant from the first coil,
The fourth and fifth coils are arranged so as to face each other via the first coil at a position equidistant from the first coil,
The sixth and seventh coils are arranged so as to face each other through the first coil at a position equidistant from the first coil,
The direction connecting the second and third coils, the direction connecting the fourth and fifth coils, and the direction connecting the sixth and seventh coils are orthogonal to each other. Item 12. The wireless power transmission device according to Item 11. A first coil and a second coil, each of which can adjust the resonance frequency;
A load modulation circuit connected to the second coil and having a variable impedance value;
A first mode in which the resonance frequencies of the first coil and the second coil are set to different frequencies, and high-frequency energy having the same frequency as the resonance frequency of the first coil is supplied to the first coil;
A second mode for setting the resonance frequency of the first coil and the second coil to the same frequency, and supplying high-frequency energy having the same frequency as the resonance frequency of the first coil to the first coil;
Have
A control circuit for adjusting an impedance value of the load modulation circuit,
The first coil in the first mode transmits the supplied high frequency energy to the receiver side coil via magnetic coupling,
The first coil in the second mode transmits the supplied high frequency energy to the second coil via magnetic coupling,
The control circuit sets the load modulation circuit to each of the first and second impedance values, executes the second mode, calculates the difference in the magnitude of the current flowing through the first coil, And determining whether to execute the first mode based on the wireless power transmission apparatus. A first coil and a second coil, each of which can adjust the resonance frequency;
Resonance frequencies of the first coil and the second coil are set to different frequencies, and high-frequency energy having the same frequency as the resonance frequency is applied to the first coil and the second coil, respectively. A first mode supplied to the coil;
A second mode for setting the resonance frequency of the first coil and the second coil to the same frequency, and supplying high-frequency energy having the same frequency as the resonance frequency of the first coil to the first coil;
A control circuit having
A determination circuit,
The first coil and the second coil in the first mode respectively transmit the supplied high-frequency energy to the first receiver side coil and the second receiver side coil by magnetic coupling,
The second coil in the second mode receives the high frequency energy from the first coil by magnetically coupling with the first coil,
The determination circuit determines whether to execute the first mode by the control circuit based on the magnitude of the high-frequency energy received by the second coil in the second mode. Transmission equipment. A first coil;
A second coil capable of adjusting the resonance frequency;
The resonance frequency of the second coil is set to a value different from that of the first coil, the first mode supplies high frequency energy to the first coil, and the resonance frequency of the second coil is the same value as the first coil. A control circuit having a second mode for supplying the high-frequency energy to the first coil,
A determination circuit,
The first coil transmits the high-frequency energy supplied in the first mode to the receiver-side coil via magnetic coupling,
The first coil transmits the high-frequency energy supplied in the second mode to the second coil via magnetic coupling,
The wireless power transmission device, wherein the determination circuit determines whether or not to execute the first mode based on the magnitude of the high-frequency energy received by the second coil.

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