JP6279305B2 - Wireless power supply system - Google Patents

Description

  The present invention relates to a wireless power feeding system.

  Application of a conventional wireless power supply system to, for example, an EV vehicle (electric vehicle) is being studied. In such an EV vehicle, when charging using the wireless power feeding system, the vehicle is parked at a predetermined position with respect to the power supply side device, and the power transmission side coil on the power supply side and the power reception side coil on the vehicle side are parked. , The power transmission from the power transmission side coil to the power reception side coil is started. As a device for detecting that the vehicle has been parked at a predetermined position, for example, Patent Document 1 discloses a flap type vehicle detection device for a parking lot.

JP 2010-31495 A

  By the way, in the above-described wireless power feeding system, if the relative position between the power transmission side coil and the power reception side coil is shifted from an appropriate position during power transmission, the power transmission efficiency tends to decrease. For this reason, in such a wireless power feeding system, it is desired to suppress a positional shift between the power transmission side coil and the power reception side coil and to suppress a decrease in power transmission efficiency.

  The present invention has been made in view of the above circumstances, and provides a wireless power feeding system that can suppress a positional shift between a power transmission side coil and a power reception side coil and suppress a decrease in power transmission efficiency. For the purpose.

To achieve the above object, a wireless power feeding system according to the present invention includes a power transmission side coil to which power from a power source is supplied, a power reception side coil that receives power from the power transmission side coil in a contactless manner, and the power reception. One of the power storage device connected to the side coil and the power transmission side coil or the power receiving side coil is supported so as to be movable at least in a predetermined plane, and the one is in a predetermined position in the predetermined plane A movable support mechanism that can be switched between a fixed state that is fixed in the above and a released state in which the one is movable in the predetermined plane, and the movable support mechanism that is in the released state from the power source to the power transmission side coil. Positioning for aligning the power transmission side coil and the power reception side coil by the attractive force of the magnetic field generated by supplying a direct current from the power storage device to the power reception side coil. A control device that switches between a mode and a power supply mode in which the movable support mechanism is in the fixed state and an AC current is supplied from the power source to the power transmission side coil and power is transmitted from the power transmission side coil to the power reception side coil. And the control device sets the movable support mechanism to the fixed state after a predetermined time has elapsed after the movable support mechanism is set to the released state and the alignment mode is started. The power supply mode is terminated, and when the power transmission efficiency in the power supply mode is equal to or higher than a predetermined efficiency set in advance, the power supply mode is continued, and the power transmission efficiency in the power supply mode is When the efficiency is less than the predetermined efficiency, the alignment mode is executed again .

  In the wireless power supply system, the control device may switch to the power supply mode after executing the alignment mode and completing alignment of the power transmission side coil and the power reception side coil.

  In the wireless power feeding system, the movable support mechanism is configured to approach and separate from the one of the power transmission side coil or the power reception side coil and a plurality of elastic members that support the one side in the predetermined plane. A plate-like member provided so as to be in the released state by elastically supporting the one by the plurality of elastic members in a state where the plate-like member is separated from the one. The fixed state can be achieved by contacting the one side.

  Further, in the wireless power feeding system, the movable support mechanism is provided along a protrusion provided on the power transmission side coil or the one of the power reception side coil and a first direction in the predetermined plane. A first guide rail that guides movement of the protrusion in the first direction and is movable along a second direction that intersects the first direction in the predetermined plane while supporting the protrusion. And the first in the predetermined plane in a state of guiding the movement of the protrusion in the second direction and supporting the protrusion in the second direction in the predetermined plane. A second guide rail portion that is movable along a direction, and the first guide rail portion and the second guide rail portion are fixed to be in the fixed state, and the first guide rail portion And the second Can be made to be the release state by Idoreru portion is released.

  In the wireless power feeding system, the power receiving coil and the power storage device can be mounted on a vehicle.

  In the wireless power feeding system according to the present invention, the control device executes the alignment mode, so that before the non-contact power feeding by the power transmission side coil and the power reception side coil is started, the positions of the power transmission side coil and the power reception side coil are Therefore, the positional deviation between the power transmission side coil and the power reception side coil can be suppressed, and the reduction in power transmission efficiency can be suppressed.

FIG. 1 is a schematic configuration diagram illustrating a schematic configuration of a wireless power feeding system according to an embodiment. FIG. 2 is a schematic configuration diagram illustrating an example of a movable support mechanism of the wireless power feeding system according to the embodiment. FIG. 3 is a schematic configuration diagram illustrating the operation of the wireless power feeding system according to the embodiment. FIG. 4 is a flowchart illustrating an example of control in the wireless power feeding system according to the embodiment. FIG. 5 is a schematic configuration diagram illustrating an example of a movable support mechanism of a wireless power feeding system according to a modification.

  Embodiments according to the present invention will be described below in detail with reference to the drawings. In addition, this invention is not limited by this embodiment. In addition, constituent elements in the following embodiments include those that can be easily replaced by those skilled in the art or those that are substantially the same.

[Embodiment]
FIG. 1 is a schematic configuration diagram illustrating a schematic configuration of a wireless power feeding system according to an embodiment. FIG. 2 is a schematic configuration diagram illustrating an example of a movable support mechanism of the wireless power feeding system according to the embodiment. FIG. 3 is a schematic configuration diagram illustrating the operation of the wireless power feeding system according to the embodiment. FIG. 4 is a flowchart illustrating an example of control in the wireless power feeding system according to the embodiment.

  A wireless power feeding system 1 according to this embodiment shown in FIG. 1 is a non-contact power feeding system that wirelessly transmits at least a portion when transmitting power from a power source 4 to various devices. The wireless power supply system 1 of the present embodiment will be described as applied to a power supply system for supplying power to a vehicle 2 that is a so-called EV vehicle (electric vehicle). Typically, the wireless power feeding system 1 wirelessly transmits and receives power between the vehicle 2 and the power supply side device 3 to perform non-contact power transmission. In the wireless power feeding system 1, for example, at least a power transmission side coil 5 a described later among the components of the power supply side device 3 is embedded in the ground G or the like of the parking area of the vehicle 2, and the vertical direction of the vehicle 2 from the power transmission side coil 5 a Electric power is transmitted in a non-contact manner to a power receiving side coil 6a, which will be described later, provided on the lower surface side, and the vehicle 2 is charged.

  Specifically, as shown in FIG. 1, the wireless power feeding system 1 includes a power source 4, a power transmission unit 5, a power reception unit 6, a battery 7 as a power storage device, and a control device 8 as a control unit. . The control device 8 includes a power transmission side control device 8a and a power reception side control device 8b. The power source 4, the power transmission unit 5, and the power transmission side control device 8 a of the control device 8 constitute the power supply side device 3 described above. The power receiving unit 6, the battery 7, and the power receiving side control device 8 b of the control device 8 are mounted on the vehicle 2 side. In addition, in FIG. 1, in addition to the power transmission unit 5 including the power transmission side coil 5a, the power supply side device 3 also shows the power source 4 and the power transmission side control device 8a on the ground G side for convenience. The actual arrangement position is not limited to this.

  The power source 4 is a power supply source and is provided on the power supply side device 3 side. The power source 4 is configured by a power storage device such as a commercial power source, a private generator, a battery, or the like. The power transmission unit 5 is provided on the power supply side device 3 side, and includes a power transmission side coil (primary side coil) 5a and a power transmission circuit 5b. The power receiving unit 6 is provided on the vehicle 2 side and includes a power receiving side coil (secondary side coil) 6a and a power receiving circuit 6b. The power transmission side coil 5a is electrically connected to the power source 4 through various cables, connectors, a power transmission circuit 5b, and the like. As described above, the power transmission coil 5a is embedded in the ground G or the like. The power transmission circuit 5b includes an inverter and the like. The power transmission side coil 5a is supplied with power from the power source 4 via these various cables, connectors, power transmission circuit 5b and the like. The power transmission side coil 5a transmits the power from the power source 4 to the power reception side coil 6a. The power receiving side coil 6a receives the power from the power transmitting side coil 5a in a non-contact manner. As described above, the power receiving side coil 6a is provided on the lower side in the vertical direction of the vehicle 2, and is provided at a position that can face the power transmitting side coil 5a along the vertical direction. The power receiving circuit 6b includes a rectifier and the like.

  In the example of FIG. 1, the pair of power transmission side coil 5 a and power reception side coil 6 a are both configured by, for example, a spiral solenoid conductor coil, but are not limited thereto, and are wound in a spiral shape. It may be constituted by a conductor coil. The pair of power transmission side coil 5a and power reception side coil 6a are opposed to each other in the axial direction (vertical direction in the example of FIG. 1) to constitute a set of non-contact power supply transformers 9. The non-contact power supply transformer 9 can transmit power from the power transmission side coil 5a to the power reception side coil 6a in a non-contact manner by various methods such as an electromagnetic induction method and an electromagnetic resonance method. Here, the electromagnetic induction method refers to the power receiving side coil 6a from the power transmitting side coil 5a using electromagnetic induction that generates an electromotive force in the power receiving side coil 6a using a magnetic flux generated by passing an alternating current through the power transmitting side coil 5a as a medium. This is a method for transmitting power to the network. In the electromagnetic field resonance method, the power transmission side coil 5a and the power reception side coil 6a are caused to resonate at a specific frequency by passing an alternating current through the power transmission side coil 5a, and the resonance phenomenon of the electromagnetic field is used to resonate the power transmission side coil. In this method, power is transmitted from 5a to the power receiving coil 6a. Here, both the power transmission side coil 5a and the power reception side coil 6a are arranged in a positional relationship such that the spiral axial direction is along the vertical direction.

  More specifically, when the non-contact power supply transformer 9 transmits power from the power transmission side coil 5a to the power reception side coil 6a, the power transmission side coil 5a and the power reception side coil 6a face each other with an interval therebetween in the axial direction. In the state, the current from the power source 4 is converted into an alternating current of an arbitrary frequency via the power transmission circuit 5b and the like, and supplied to the power transmission side coil 5a. When an alternating current is supplied to the power transmission side coil 5a, for example, the power transmission side coil 5a and the power reception side coil 6a are electromagnetically coupled to the non-contact power supply transformer 9 so that the power from the power transmission side coil 5a is electromagnetic induction or The power is received by the power receiving side coil 6a in a non-contact manner by electromagnetic resonance. The electric power received by the power receiving side coil 6a is converted from an alternating current to a direct current through the power receiving circuit 6b or the like and used in the vehicle 2.

  The battery 7 is mounted on the vehicle 2 side. The battery 7 is a secondary battery capable of storing electric power. The battery 7 is electrically connected to the power receiving side coil 6a via the power receiving circuit 6b, is charged by the power received by the power receiving side coil 6a and supplied via the power receiving circuit 6b, and stores the power. The electric power stored in the battery 7 is used for operating the vehicle 2.

  The control device 8 performs various controls and processes in power feeding by the wireless power feeding system 1, and includes the power transmission side control device 8a and the power reception side control device 8b as described above. The control device 8 includes an electronic circuit mainly composed of a known microcomputer including a CPU, a ROM, a RAM, and an interface, for example. The power transmission side control device 8a is provided on the power supply side device 3 side, and controls each part on the power supply side device 3 side. The power receiving side control device 8b is provided on the vehicle 2 side, and controls each part on the vehicle 2 side. The power receiving side control device 8b may be shared by an ECU (Electronic Control Unit) that comprehensively controls each part of the vehicle 2. The power transmission side control device 8a and the power reception side control device 8b can exchange information such as a detection signal, a drive signal, and a control command with each other by wire / wireless. The power transmission side control device 8a and the power reception side control device 8b are both connected via various connection ports when the vehicle 2 is stopped in the vicinity of the power supply side device 3, for example, when exchanging information by wire. A detachable cable is connected so as to connect, and information is exchanged via the cable or the like. When transmitting and receiving information wirelessly, the power transmission side control device 8a and the power reception side control device 8b, for example, NFC (Near Field Communication), Bluetooth (registered trademark), Wi-Fi (Wireless Fidelity), ZigBee ( Information is exchanged by various wireless communication methods such as registered trademark.

  By the way, the wireless power feeding system 1 of the present embodiment further includes the movable support mechanism 10, and the control device 8 switches the power supply mode between the alignment mode and the power feeding mode and executes the power transmission side coil. The positional deviation of 5a and the power receiving side coil 6a is suppressed, and the fall of the transmission efficiency of the electric power at the time of non-contact transmission is aimed at.

  Specifically, the movable support mechanism 10 supports one of the power transmission side coil 5a or the power reception side coil 6a so as to be movable at least within a predetermined plane. The movable support mechanism 10 of this embodiment supports the power transmission side coil 5a on the power supply side device 3 side so as to be movable at least within a predetermined plane. That is, in the non-contact power supply transformer 9, the power transmission side coil 5a is a movable coil, and the power reception side coil 6a is a fixed coil.

  In addition, here, the predetermined plane is an xy plane defined by two directions (hereinafter sometimes referred to as “x direction and y direction”) that are along the horizontal direction and orthogonal to each other, that is, in the horizontal direction. It is a horizontal plane along. In the following description, the predetermined plane may be referred to as an “xy horizontal plane”. In addition, the vertical direction orthogonal to the predetermined plane may be referred to as the z direction. The x direction, the y direction, and the z direction are directions orthogonal to each other.

  The movable support mechanism 10 supports the power transmission side coil 5a, which is a movable coil, so as to be movable in the xy horizontal plane. The movable support mechanism 10 can be switched between a fixed state and a released state. Here, the fixed state is a state in which the power transmission side coil 5a is fixed at a predetermined position in the xy horizontal plane. On the other hand, the released state is a state in which the power transmission side coil 5a can be moved in the xy horizontal plane. The movable support mechanism 10 is electrically connected to the power transmission side control device 8a, and the fixed state and the released state are switched by the control of the power transmission side control device 8a.

  An example of a specific configuration of the movable support mechanism 10 will be described with reference to FIG.

  The movable support mechanism 10 illustrated in FIG. 2 includes a fixing frame 11, a plurality of elastic members 12, a coil back plate 13 as a plate-like member, and a drive mechanism 14. The fixing frame 11 is a frame-shaped member formed in a square shape. The fixing frame 11 is disposed on the ground G (see FIG. 1) side so as to be parallel to the xy horizontal plane. For example, the fixing frame 11 is fixedly supported by a base member or the like provided on the ground G side. The plurality of elastic members 12 support the power transmission side coil 5a, which is a movable coil, in the xy horizontal plane. Here, the plurality of elastic members 12 are constituted by a plurality of tension springs. A total of four elastic members 12 are provided, one on each side of the square-shaped fixing frame 11. Each elastic member 12 has one end fixed to each side of the fixing frame 11 and the other end connected to the power transmission side coil 5a. Each elastic member 12 elastically supports the power transmission side coil 5 a inside the hollow portion of the fixing frame 11. Each elastic member 12 supports the power transmission side coil 5a so as to be movable in the x direction and the y direction within the hollow portion of the fixing frame 11. The coil back side plate 13 is provided so as to be close to and away from the power transmission side coil 5a. The coil back side plate 13 is a rectangular plate-like member formed to have a size covering almost the entire surface of the hollow portion of the square-shaped fixing frame 11, and is disposed inside the hollow portion of the fixing frame 11. Is done. The coil back plate 13 is disposed so as to be parallel to the xy horizontal plane, and is provided so as to be movable in the z direction, that is, the vertical direction. That is, the coil back side plate 13 is provided so as to be close to and away from the power transmission side coil 5a along the z direction. The drive mechanism 14 supports the coil back side plate 13 so as to be close to and away from the power transmission side coil 5a, and has a drive source for actually moving the coil back side plate 13 close to and away from the power transmission side coil 5a. Yes. The drive mechanism 14 is electrically connected to the power transmission side control device 8a, and its drive is controlled by the control of the power transmission side control device 8a.

  The movable support mechanism 10 configured as described above can switch between the fixed state and the released state by controlling the drive mechanism 14 by the power transmission side control device 8a. That is, in the movable support mechanism 10, the drive mechanism 14 is controlled by the power transmission side control device 8a, and the coil back side plate 13 moves to the side opposite to the power transmission side coil 5a side, so that the coil back side plate 13 becomes the power transmission side coil 5a. In this state, the power transmission side coil 5a is elastically supported by the plurality of elastic members 12 to be in a released state. That is, in the released state, the movable support mechanism 10 is in a state where the coil back side plate 13 is not in contact with the power transmission side coil 5a and the power transmission side coil 5a is released. The elastic member 12 is elastically supported so as to be movable in the x direction and the y direction, and the degree of freedom of position of the power transmission side coil 5a in the x direction and the y direction is ensured. As a result, the movable support mechanism 10 is in a state in which the power transmission side coil 5a can move within the xy horizontal plane.

  On the other hand, in the movable support mechanism 10, the drive mechanism 14 is controlled by the power transmission side control device 8a, and the coil back side plate 13 moves to the power transmission side coil 5a side, so that the coil back side plate 13 comes into contact with the power transmission side coil 5a. In this state, the movement of the power transmission side coil 5a is regulated by the frictional force generated between the coil back side plate 13 and the fixed state. That is, in the fixed state, the movable support mechanism 10 is configured such that when the coil back side plate 13 comes into contact with the power transmission side coil 5a, the power transmission side coil 5a becomes x by the frictional force generated between the power transmission side coil 5a and the coil back side plate 13. -Y Fixed state at a predetermined position in the horizontal plane.

  And the control apparatus 8 of this embodiment exists in the structure by which the power transmission side coil 5a was supported by the movable support mechanism 10, and can perform by switching position alignment mode and electric power feeding mode. Here, the alignment mode executed by the control device 8 is a magnetic field generated by supplying the direct current from the power source 4 to the power transmission side coil 5a and from the battery 7 to the power reception side coil 6a with the movable support mechanism 10 in the released state. This is a power mode in which the power transmission side coil 5a and the power reception side coil 6a are aligned by the attractive force. On the other hand, the power supply mode executed by the control device 8 is a power in which the movable support mechanism 10 is fixed and an alternating current is supplied from the power source 4 to the power transmission side coil 5a and power is transmitted from the power transmission side coil 5a to the power reception side coil 6a. Mode.

  The alignment mode executed by the control device 8 will be described in more detail with reference to FIG.

  When the control device 8 is in the alignment mode, the movable support mechanism 10 is released by the control of the power transmission side control device 8a. The control device 8 performs control to supply a direct current to the power transmission side coil 5a and the power reception side coil 6a by the power transmission side control device 8a and the power reception side control device 8b communicating with each other to cooperate. . In this case, the power transmission side control device 8a transmits an alignment mode start signal to the power transmission circuit 5b, and supplies a direct current from the power supply 4 to the power transmission side coil 5a via the power transmission circuit 5b. Similarly, the power receiving side control device 8b transmits a positioning mode start signal to the power receiving circuit 6b, and supplies a direct current from the battery 7 to the power receiving side coil 6a via the power receiving circuit 6b.

  The power transmission circuit 5b of the present embodiment includes a circuit that supplies a direct current from the power source 4 to the power transmission circuit 5b in addition to a circuit that supplies an alternating current from the power source 4 to the power transmission side coil 5a. The power receiving circuit 6b of the present embodiment includes a circuit that supplies a direct current from the battery 7 to the power receiving circuit 6b, in addition to a circuit that converts the power received by the power receiving coil 6a from an alternating current to a direct current. Is done. That is, in the wireless power feeding system 1, in the alignment mode, the power source 4 functions as a DC power source on the power transmission side coil 5a side, and the battery 7 functions as a DC power source on the power reception side coil 6a side.

  When a direct current is supplied in the alignment mode as described above, the power transmission side coil 5a and the power reception side coil 6a generate a magnetic field and generate an electromagnetic force as illustrated in FIG. It becomes. At this time, in the power transmission side control device 8a and the power reception side control device 8b, in the power transmission side coil 5a and the power reception side coil 6a that have become electromagnets by direct current, the magnetic poles of the surfaces facing each other along the vertical direction are mutually The direction of the direct current flowing through the power transmission side coil 5a and the power reception side coil 6a is controlled so as to have different magnetic poles. In the example of FIG. 3, the power transmission side coil 5a has a surface facing the power reception side coil 6a (vertical upper surface) as an S pole, and the power reception side coil 6a has a surface facing the power transmission side coil 5a (vertical lower surface). N pole.

  As a result, the power transmission side coil 5a and the power reception side coil 6a become an electromagnet when a direct current is supplied in the alignment mode, and the electromagnetic force of the generated magnetic field causes a gap between the power transmission side coil 5a and the power reception side coil 6a. Attracting force (force acting in the direction attracted to each other) is applied. At this time, since the movable support mechanism 10 is in the released state in the alignment mode, the power transmission side coil 5a that is a movable coil is attracted to the power reception side coil 6a that is a fixed coil by the attracting force of the generated magnetic field. It will be. As a result, the power transmission side coil 5a is located close to the power reception side coil 6a, in other words, at a position where the power transmission efficiency is relatively high (hereinafter sometimes referred to as “high efficiency transmission position”). Aligned.

  And the control apparatus 8 switches to electric power feeding mode, after performing alignment mode as mentioned above and completing alignment with the power transmission side coil 5a and the power receiving side coil 6a. In this case, in the control device 8, after the alignment in the alignment mode is completed, the movable support mechanism 10 is fixed by the control of the power transmission side control device 8a. Thereby, the power transmission side coil 5a which is a movable coil is positioned in the highly efficient transmission position which opposes the power receiving side coil 6a as mentioned above.

  And the power transmission side control apparatus 8a transmits the alignment mode end signal to the power transmission circuit 5b, and complete | finishes supply of the direct current to the power transmission side coil 5a. Similarly, the power receiving side control device 8b transmits an alignment mode end signal to the power receiving circuit 6b, and ends the supply of the direct current to the power receiving side coil 6a. Thereafter, the power transmission side control device 8a transmits a power supply mode start signal to the power transmission circuit 5b, and starts supplying an alternating current from the power source 4 to the power transmission side coil 5a via the power transmission circuit 5b. Thereby, the wireless power feeding system 1 is switched to the power feeding mode, the non-contact power transmission from the power transmission side coil 5a to the power reception side coil 6a is started, and the charging of the battery 7 of the vehicle 2 is started.

  Next, an example of control in the wireless power feeding system 1 according to the present embodiment will be described with reference to the flowchart of FIG.

  First, when the power transmission side control device 8 a of the control device 8 detects a power supply request to the vehicle 2 by the power supply side device 3, the power transmission side control device 8 a releases the movable support mechanism 10 that is a movable coil fixing mechanism and fixes the movable support mechanism 10. The state is changed to the released state (step ST1). Here, the power transmission side control device 8a can detect a power supply request to the vehicle 2 by the power supply side device 3 by various methods. The power transmission side control device 8a, for example, when detecting that the vehicle 2 has stopped at a predetermined power supply position near the power supply side device 3 or when receiving a power supply request signal from the vehicle 2, etc. Is detected, and the movable support mechanism 10 is released.

  Next, the control device 8 starts the alignment mode. That is, the power transmission side control device 8a transmits an alignment mode start signal to the power transmission circuit 5b and applies a direct current to the power transmission side coil 5a. The power transmission side control device 8a transmits a positioning mode start command signal to the power reception side control device 8b. Receiving the alignment mode start command signal, the power receiving side control device 8b transmits the alignment mode start signal to the power receiving circuit 6b, and applies a direct current to the power receiving side coil 6a (step ST2).

  Next, the power transmission side control device 8a determines whether or not a predetermined time has elapsed since the start of the alignment mode (step ST3). Here, the elapse of the predetermined time is set based on, for example, an average required time from the start of the alignment mode until the power transmission side coil 5a moves to the high efficiency transmission position facing the power reception side coil 6a. Is done. If the power transmission side control device 8a determines that the predetermined time has not elapsed since the start of the alignment mode (step ST3: No), this determination is performed until it is determined that the predetermined time has elapsed since the alignment mode was started. Repeat.

  When the power transmission side control device 8a determines that a predetermined time has elapsed since the start of the alignment mode (step ST3: Yes), the power transmission side coil 5a, which is a movable coil, changes the movable support mechanism 10 from the released state to the fixed state. Is fixed at the current position (step ST4).

  Next, the control device 8 once ends the alignment mode and tries the power supply mode. That is, the power transmission side control device 8a transmits an alignment mode end signal to the power transmission circuit 5b, and ends the application of the direct current to the power transmission side coil 5a. In addition, the power transmission side control device 8a transmits an alignment mode end command signal to the power reception side control device 8b. Receiving the alignment mode end command signal, the power receiving side control device 8b transmits the alignment mode end signal to the power receiving circuit 6b, and ends the application of the direct current to the power receiving side coil 6a. And the power transmission side control apparatus 8a transmits a power feeding mode start signal to the power transmission circuit 5b, and applies an alternating current to the power transmission side coil 5a (step ST5).

  Next, the power transmission side control device 8a determines whether or not the alignment between the power transmission side coil 5a and the power reception side coil 6a is completed (step ST6). The power transmission side control device 8a can determine whether or not the alignment is completed based on, for example, the power transmission efficiency in the power supply mode. In this case, the power transmission side control device 8a can determine that the alignment has been completed, for example, when the power transmission efficiency in the power supply mode is equal to or higher than a predetermined efficiency set in advance.

Side control unit 8a, when judging that the alignment has not been completed (step ST6: No), repeatedly executes the subsequent processing returns to processing step ST 1. When it is determined that the alignment has been completed (step ST6: Yes), the power transmission side control device 8a continues the power supply mode as it is (step ST7) and ends this control flow.

  In the wireless power feeding system 1 configured as described above, before the control device 8 starts the non-contact power feeding by the power transmission side coil 5a and the power receiving side coil 6a by executing the alignment mode before the power feeding mode. In addition, the power transmission side coil 5a and the power reception side coil 6a can be aligned. As a result, the wireless power feeding system 1 can suppress a positional shift between the power transmission side coil 5a and the power reception side coil 6a, and can suppress a decrease in power transmission efficiency.

  More specifically, the control device 8 releases the movable support mechanism 10 in the alignment mode, and supplies a direct current to the power transmission side coil 5a and the power reception side coil 6a, whereby the power transmission side that has become an electromagnet. Using the coil 5a and the power reception side coil 6a itself, the power transmission side coil 5a and the power reception side coil 6a can be aligned. Here, the power transmission side coil 5a, which is a movable coil, moves to the high efficiency transmission position facing the power reception side coil 6a by the attracting force of the magnetic field of the power transmission side coil 5a and the power reception side coil 6a. , Aligned. Here, in such a wireless power feeding system 1, if the positions of the power transmission side coil 5 a and the power reception side coil 6 a are misaligned with respect to an appropriate position during power transmission, the power transmission efficiency tends to decrease. However, in the wireless power feeding system 1 of the present embodiment, the power transmission side coil 5a and the power reception side coil 6a are aligned by the alignment mode before the transmission of power to the vehicle 2 as described above. The positional deviation between the power transmission side coil 5a on the power supply side device 3 side and the power reception side coil 6a on the vehicle 2 side can be suppressed. As a result, the wireless power feeding system 1 can stably supply power to the vehicle 2 and can improve power transmission efficiency.

  According to the wireless power feeding system 1 described above, the power transmission side coil 5a to which power from the power source 4 is supplied, the power reception side coil 6a that receives power from the power transmission side coil 5a in a non-contact manner, and the power reception side coil 6a. A battery 7, a movable support mechanism 10, and a control device 8 connected to each other. The movable support mechanism 10 supports one of the power transmission side coil 5a or the power reception side coil 6a so as to be movable at least within a predetermined plane, and fixes the one at a predetermined position within the predetermined plane. And a release state in which one of them can be moved within a predetermined plane. The control device 8 executes switching between the alignment mode and the power supply mode. In the alignment mode, the movable support mechanism 10 is released and a direct current is supplied from the power source 4 to the power transmission side coil 5a and from the battery 7 to the power reception side coil 6a. In this mode, alignment with the side coil 6a is performed. The power supply mode is a mode in which the movable support mechanism 10 is in a fixed state, an alternating current is supplied from the power supply 4 to the power transmission side coil 5a, and power is transmitted from the power transmission side coil 5a to the power reception side coil 6a. Therefore, the wireless power feeding system 1 can suppress a positional shift between the power transmission side coil 5a and the power reception side coil 6a, and can suppress a decrease in power transmission efficiency. The wireless power feeding system 1 also uses the power transmission side coil 5a and the power receiving side coil 6a used for non-contact power feeding as a device for aligning the power transmitting side coil 5a and the power receiving side coil 6a. Therefore, the number of components of the wireless power feeding system 1 can be suppressed, and the system can be reduced in size and cost.

  Furthermore, according to the wireless power feeding system 1 described above, the control device 8 switches to the power feeding mode after executing the positioning mode and completing the positioning of the power transmission side coil 5a and the power receiving side coil 6a. Therefore, the wireless power feeding system 1 can align the power transmitting side coil 5a and the power receiving side coil 6a before starting non-contact power feeding by the power transmitting side coil 5a and the power receiving side coil 6a.

  Furthermore, according to the wireless power feeding system 1 described above, the movable support mechanism 10 includes a plurality of elastic members 12 that support one of the power transmission side coil 5a or the power reception side coil 6a in a predetermined plane, and the one And a coil back side plate 13 provided so as to be able to approach and separate. The movable support mechanism 10 is in a released state by elastically supporting one by a plurality of elastic members 12 in a state where the coil back side plate 13 is separated from the one, and a fixed state by the coil back side plate 13 contacting the one. It becomes. Therefore, the wireless power feeding system 1 has a fixed state in which one of the power transmission side coil 5a or the power reception side coil 6a is fixed at a predetermined position in a predetermined plane by the plurality of elastic members 12 and the coil back side plate 13. , It is possible to switch to a released state in which movement is possible within a predetermined plane.

  Furthermore, according to the wireless power feeding system 1 described above, the power receiving side coil 6 a and the battery 7 are mounted on the vehicle 2. Therefore, even when the vehicle 2 stops at a position slightly deviated from the power supply side device 3, the wireless power feeding system 1 performs power transmission by performing the alignment mode if the vehicle 2 deviates within a predetermined range. After aligning the side coil 5a and the power receiving side coil 6a, power transmission from the power transmitting side coil 5a to the power receiving side coil 6a can be started.

  The wireless power feeding system according to the above-described embodiment of the present invention is not limited to the above-described embodiment, and various modifications can be made within the scope described in the claims.

  FIG. 5 is a schematic configuration diagram illustrating an example of a movable support mechanism of a wireless power feeding system according to a modification.

  The wireless power feeding system 1 according to the modification shown in FIG. 5 includes a movable support mechanism 210 instead of the movable support mechanism 10 (see FIG. 2). Similar to the movable support mechanism 10, the movable support mechanism 210 supports the power transmission side coil 5 a that is a movable coil so as to be movable in the xy horizontal plane. The movable support mechanism 210 can be switched between a fixed state and a released state. The movable support mechanism 210 of the present embodiment includes a fixing frame 211, a protrusion 212, a first guide rail 213, a second guide rail 214, a first rail 215, a second rail 216, and a first rail. A first lock mechanism 217 and a second lock mechanism 218 are provided.

  The fixing frame 211 is a frame-shaped member formed in a square shape. The fixing frame 211 is disposed on the ground G (see FIG. 1) side so as to be parallel to the xy horizontal plane. For example, the fixing frame 211 is fixedly supported by a base member or the like provided on the ground G side. The protrusion 212 is a portion including a protrusion provided on one of the power transmission side coil 5a or the power reception side coil 6a, here, the power transmission side coil 5a which is a movable coil. The protrusion 212 is connected to the power transmission side coil 5a via a connection mechanism or the like. The protrusion 212 has a shape protruding along the z direction. The protrusion 212 is movable in an xy horizontal plane integrally with the power transmission side coil 5a.

  The first guide rail portion 213 is provided along a first plane in a predetermined plane, here, an xy horizontal plane. Here, the first direction is the x direction. The first guide rail portion 213 guides the movement of the protruding portion 212 in the x direction and supports the protruding portion 212 along the second direction that intersects the x direction in the xy horizontal plane, in this case, along the y direction. Can be moved. More specifically, the first guide rail portion 213 includes a pair of rod members 213a and 213b that extend along the x direction. The pair of rod members 213a and 213b both extend from one end of the fixing frame 211 to the other end along the x direction. The pair of rod members 213a and 213b are integrated by connecting the both ends thereof with connecting members 213c and 213d at a predetermined interval in the y direction. Both ends of the rod members 213a and 213b integrated by the connecting members 213c and 213d are supported by the first rail 215 so as to be movable in the y direction. The first rail 215 is provided as a pair on the side along the y direction of the fixing frame 211. The pair of first rails 215 both extend from one end of the fixing frame 211 to the other end along the y direction. The integrated rod members 213a and 213b are movable along the y direction while being supported by the pair of first rails 215. The first lock mechanism 217 is provided at one end of the integrated rod members 213a and 213b, and can restrict the movement of the integrated rod members 213a and 213b. The first lock mechanism 217 includes, for example, a gear, a screw, and the like, and can fix the bar members 213a and 213b integrated in the locked state to the first rail 215. The first locking mechanism 217 can move the bar members 213a and 213b integrated by being in the released state along the y direction while being supported by the pair of first rails 215. The first lock mechanism 217 is electrically connected to the power transmission side control device 8a, and its drive is controlled by the control of the power transmission side control device 8a.

  The second guide rail portion 214 is provided along the second direction in the xy horizontal plane. Here, the second direction is the y direction. The second guide rail 214 guides the movement of the protrusion 212 in the y direction and is movable along the first direction in the xy horizontal plane, here the x direction, while supporting the protrusion 212. . More specifically, the second guide rail portion 214 includes a pair of rod members 214a and 214b extending along the y direction. The pair of rod members 214a and 214b both extend from one end of the fixing frame 211 to the other end along the y direction. The pair of rod members 214a and 214b are connected and integrated by connecting members 214c and 214d at predetermined intervals in the x direction. Both ends of the rod members 214a and 214b integrated by the connecting members 214c and 214d are supported by the second rail 216 so as to be movable in the x direction. The second rail 216 is provided as a pair on the side of the fixing frame 211 along the x direction. The pair of second rails 216 both extend from one end of the fixing frame 211 to the other end along the x direction. The integrated rod members 214 a and 214 b are movable along the x direction while being supported by the pair of second rails 216. The second lock mechanism 218 is provided at one end of the integrated rod members 214a and 214b, and can restrict the movement of the integrated rod members 214a and 214b. The second lock mechanism 218 includes, for example, gears, screws, and the like, and can fix the bar members 214a and 214b integrated by being locked to the second rail 216. The second locking mechanism 218 can move the bar members 214a and 214b integrated by being in the released state along the x direction while being supported by the pair of second rails 216. The second lock mechanism 218 is electrically connected to the power transmission side control device 8a, and its drive is controlled by the control of the power transmission side control device 8a.

  In the movable support mechanism 210, the protrusion 212 is supported between the pair of rod members 213a and 213b of the first guide rail portion 213 and the pair of rod members 214a and 214b of the second guide rail portion 214. That is, the protrusion 212 is supported at a portion where the pair of rod members 213a and 213b of the first guide rail portion 213 and the pair of rod members 214a and 214b of the second guide rail portion 214 intersect. The protrusion 212 is supported by the first guide rail portion 213 and the second guide rail portion 214 integrally with the power transmission side coil 5a.

  The movable support mechanism 210 configured as described above can switch between the fixed state and the released state by controlling the first lock mechanism 217 and the second lock mechanism 218 by the power transmission side control device 8a. That is, in the movable support mechanism 210, the first lock mechanism 217 and the second lock mechanism 218 are controlled by the power transmission side control device 8a, and both are released, and the first guide rail portion 213 and the second guide rail portion 214 are released. Is released, the first guide rail portion 213 and the second guide rail portion 214 can move in the x direction and the y direction, and are in a released state. That is, in the movable support mechanism 210, in the released state, the first guide rail portion 213 can move in the y direction and the second guide rail portion 214 can move in the x direction. Along with the side coil 5a, the first guide rail portion 213 and the second guide rail portion 214 are guided to move in the x direction and the y direction. As a result, the movable support mechanism 210 has a degree of freedom of position in the x and y directions of the power transmission side coil 5a, and the power transmission side coil 5a is movable in the xy horizontal plane.

  On the other hand, in the movable support mechanism 210, the first lock mechanism 217 and the second lock mechanism 218 are controlled by the power transmission side control device 8a and both are fixed, and the first guide rail portion 213 and the second guide rail portion 214 are fixed. Is fixed, the movement of the first guide rail portion 213 and the second guide rail portion 214 in the x direction and the y direction is restricted and the fixed state is established. That is, when the movable support mechanism 210 is in the fixed state, the first lock mechanism 217 and the second lock mechanism 218 are locked, so that the first guide rail portion 213 and the second guide rail portion 214 are in the x direction and the y direction. The protrusion 212 supported by these is fixed at a predetermined position in the xy horizontal plane together with the power transmission side coil 5a.

  Even in this case, the wireless power feeding system 1 uses the protruding portion 212, the first guide rail portion 213, and the second guide rail portion 214 to transfer one of the power transmission side coil 5a or the power reception side coil 6a. It is possible to switch between a fixed state that is fixed at a predetermined position within a predetermined plane and a released state that is movable within the predetermined plane. Therefore, the wireless power feeding system 1 can suppress a positional shift between the power transmission side coil 5a and the power reception side coil 6a, and can suppress a decrease in power transmission efficiency.

  In the above description, the movable support mechanisms 10 and 210 have been described as supporting the power transmission side coil 5a on the power supply side apparatus 3 side so as to be movable at least within a predetermined plane (xy horizontal plane). The power receiving side coil 6a on the vehicle 2 side may be supported so as to be movable at least within a predetermined plane. That is, in the wireless power feeding system 1, the power receiving side coil 6a may be a movable coil, and the power transmitting side coil 5a may be a fixed coil.

  In the above description, the predetermined plane is described as an xy horizontal plane along the horizontal direction, but is not limited thereto. The predetermined plane may be an xz vertical plane defined by the x direction and the z direction, or a yz vertical plane defined by the y direction and the z direction. Furthermore, the predetermined plane may be an inclined plane having a predetermined inclination with respect to the xy horizontal plane, the xz vertical plane, and the yz vertical plane.

  Further, the movable support mechanisms 10 and 210 described above have a power transmission side coil 5a or 3D direction in a three-dimensional direction including a direction (z direction) orthogonal to the plane in addition to a predetermined plane (xy horizontal plane). The power receiving side coil 6a may be movably supported. Conversely, the movable support mechanisms 10 and 210 support one of the power transmission side coil 5a and the power reception side coil 6a in a one-dimensional direction within a predetermined plane (xy horizontal plane) so as to be movable. There may be. That is, the movable support mechanisms 10 and 210 are not limited to those having a degree of freedom in the two-dimensional direction, but may be those having a degree of freedom in the one-dimensional direction, or degrees of freedom in the three-dimensional direction. May be secured.

  Moreover, although the movable support mechanism 10 demonstrated above demonstrated that the coil back side board 13 as a plate-shaped member approached / separated with respect to the power transmission side coil 5a, a fixed state and a releasing state were switched, this was demonstrated. Not limited to. For example, the movable support mechanism 10 is fixed so that the coil back side plate 13 does not move in the z direction, and a plurality of engagement holes are formed in the coil back side plate 13 in a grid shape, You may comprise by providing the pin member which can move along az direction on the coil 5a (movable coil) side. In this case, the movable support mechanism 10 is in a fixed state when the pin member moves in the z direction and engages with any of the engagement holes provided in the coil back side plate 13. On the other hand, in this case, the movable support mechanism 10 is released when the pin member moves along the z direction and is disengaged from the engagement hole.

  In the above description, the wireless power feeding system 1 has been described as being applied to a power feeding system for the vehicle 2, but is not limited to this, and other devices other than the vehicle 2 (for example, in-vehicle devices, communication terminal devices, and external devices), etc. May be applied to a power supply system.

DESCRIPTION OF SYMBOLS 1 Wireless power supply system 2 Vehicle 3 Power supply side apparatus 4 Power supply 5 Power transmission part 5a Power transmission side coil 6 Power reception part 6a Power reception side coil 7 Battery (power storage device)
8 Control Device 9 Transformer for Non-Contact Power Supply 10, 210 Movable Support Mechanism 12 Elastic Member 13 Coil Back Side Plate (Plate Member)
212 Protruding portion 213 First guide rail portion 214 Second guide rail portion

Claims (4)

A power transmission coil supplied with power from a power source;
A power receiving side coil for receiving power from the power transmitting side coil in a contactless manner;
A power storage device connected to the power receiving coil;
One of the power transmission side coil or the power reception side coil is supported so as to be movable at least in a predetermined plane, and the one is fixed at a predetermined position in the predetermined plane and the one is A movable support mechanism that can be switched to a released state that is movable within a predetermined plane;
With the movable support mechanism in the released state, a DC current is supplied from the power source to the power transmission side coil and from the power storage device to the power reception side coil. A positioning mode in which the movable support mechanism is in the fixed state, an alternating current is supplied from the power source to the power transmission side coil, and power is transmitted from the power transmission side coil to the power reception side coil. And a control device for switching and executing ,
The control device sets the movable support mechanism to the fixed state after a predetermined time has elapsed since the movable support mechanism is in the released state and starts the alignment mode, and temporarily ends the alignment mode. The power supply mode is tried, and when the power transmission efficiency in the power supply mode is equal to or higher than a predetermined efficiency set in advance, the power supply mode is continued, and the power transmission efficiency in the power supply mode is less than the predetermined efficiency. In some cases, the alignment mode is executed again .
Wireless power supply system. The movable support mechanism includes a plurality of elastic members that support the one of the power transmission side coil or the power reception side coil within the predetermined plane, and a plate-like member provided so as to be able to approach and separate from the one. In the state where the plate-like member is separated from the one, the one is elastically supported by the plurality of elastic members to be in the released state, and the plate-like member contacts the one Become fixed,
The wireless power feeding system according to claim 1 . The movable support mechanism includes a protrusion provided on the power transmission side coil or the one of the power reception side coil, and a first direction of the protrusion provided along a first direction within the predetermined plane. A first guide rail portion that is movable along a second direction that intersects the first direction in the predetermined plane in a state in which the projection is supported and the projection is supported, and in the predetermined plane The projection is provided along the second direction, and guides the movement of the projection in the second direction, and is movable along the first direction in the predetermined plane while supporting the projection. A second guide rail portion, and the first guide rail portion and the second guide rail portion are fixed to be in the fixed state, and the first guide rail portion and the second guide rail are The solution is released The state,
The wireless power feeding system according to claim 1 . The power receiving side coil and the power storage device are mounted on a vehicle.
The wireless power feeding system according to any one of claims 1 to 3 .

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