JP5724658B2 - Contactless power supply system - Google Patents

Description

  The present invention relates to a non-contact power supply system in which power is supplied from an external power source to a vehicle-mounted power storage device in a non-contact manner regardless of plug connection or the like.

  According to the technique described in Patent Document 1, the feeding coil built in the wheel stopper provided on the ground side is urged by the driving operation of the electric vehicle to the wheel of the electric vehicle that abuts the wheel stopper in the horizontal plane. When the electric vehicle is stopped in this state and the electric vehicle is stopped in this state, the feeding coil comes to take a certain posture with respect to the electric vehicle. For example, when the reverse direction of the electric vehicle is deviated from the reference reverse direction of the electric vehicle, one of the pair of rear wheels of the electric vehicle comes into contact with the wheel stopper first and comes in contact with the reverse of the electric vehicle When the rear wheel rotates the wheel stopper, and then both of the pair of rear wheels contact the wheel stopper, the backward movement of the electric vehicle is stopped. In this way, the alignment operation of the power feeding coil and the power receiving coil is performed. By this rotation of the ring stopper, the power feeding coil in the ring stopper overlaps with the power receiving coil in the vertical direction, and as a result, the power transmission efficiency between the two coils is improved.

JP-A-7-227007

  In the technique disclosed in Patent Document 1, the power feeding coil is aligned by being biased by the electric vehicle that contacts the wheel stopper so that the electromagnetic conversion efficiency with the power receiving coil is improved. Therefore, the receiving coil is not located within the range in which the posture of the wheel stopper can be changed because various conditions such as the mounting position of the receiving coil and the height from the ground differ depending on the size and type of the electric vehicle to be supplied with power. In this case, there is a problem that the power receiving coil cannot be positioned so as to have good electromagnetic conversion efficiency with respect to the power feeding coil. In addition, it is practically difficult to arrange the power receiving coil and the power feeding coil in advance so as to have good electromagnetic conversion efficiency for various types of vehicles. In addition, in the mechanical alignment structure as in Patent Document 1, it can be said that it is difficult to achieve satisfactory electromagnetic conversion efficiency for many types of vehicles.

  Therefore, the present invention has been made in view of the above problems, and an object of the present invention is to provide a non-contact power feeding system that can guide a power receiving vehicle to a position with good power receiving efficiency with respect to a power transmitting device. .

In order to achieve the above object, the present invention employs the following technical means. That is, claim 1 generates an electromagnetic field between a power reception coil (121) provided in a vehicle (10) and a power transmission coil (21) provided in a power transmission equipment device (1) outside the vehicle to generate a non-contact state. An invention relating to a non-contact power feeding system for feeding power,
When the vehicle is parked with respect to the power transmission coil in order to perform non-contact power supply, the target power reception voltage received by the power reception coil is calculated, and when the power reception voltage of the power reception coil approaches the target power reception voltage during the parking operation , the vehicle To inform the driver of the current position of
When calculating the target receiving voltage, at least
The inverter output voltage (V ₁ ), the inverter output current (I ₁ ), the coil inductance, and the impedance of the resonance capacitor (7) , which are sent from the power transmission equipment to the vehicle, respectively ,
Using the coil inductance, the impedance of the resonance capacitor (112), and the load (114) on the vehicle side,
A solution in which the input power factor of the high-frequency inverter (5) included in the power transmission equipment is 1 or a value that approximates 1 is obtained, and a target received voltage is derived using the solution .

According to this invention, when the vehicle is about to stop at the parking position for performing non-contact power feeding, the target power receiving voltage is calculated, and the power receiving voltage of the power receiving coil becomes the calculated target power receiving voltage during the parking operation. Since the vehicle is guided so as to approach, the movement of the vehicle during the parking operation is guided so as to approach the parking position that satisfies the target power reception voltage at which the power reception efficiency is good. If the contactless power supply system has control related to this vehicle guidance, the vehicle is guided so that the efficiency of the amount of power received with respect to the amount of power transmitted between the power transmission equipment and the vehicle is improved. A highly versatile system capable of realizing a highly efficient power feeding operation can be obtained regardless of the difference in the position of the power receiving coil due to. Therefore, it is possible to provide a non-contact power feeding system that can guide a power receiving vehicle to a position that is favorable in terms of power receiving efficiency with respect to a power transmission facility device on a power transmission side.
Further, when calculating the target power reception voltage, a solution in which the input power factor of the high-frequency inverter included in the power transmission equipment is 1 or a solution that approximates 1 is obtained, and the target power reception voltage is calculated using the solution. Therefore, the target power reception voltage can be set so that high power reception efficiency can be realized.

According to claim 2 , in the invention according to claim 1, it is provided with distance detection means (30, 40) for detecting the distance between the power transmission coil (21) and the power reception coil (121), and between the distance and the power reception voltage. A map showing the characteristics that hold is stored in advance, and the received voltage is obtained from the distance detected by the distance detecting means and the map. According to the present invention, since the power reception voltage is obtained using the detailed distance information detected by the distance detecting means, the parking accuracy can be improved.

According to claim 3 , in the invention according to claim 2 , when the vehicle is guided during the parking operation, it is detected by the distance detection means as the current position of the vehicle with respect to the optimum parking position for performing non-contact power feeding. Informing means (52) for informing the distance is provided. According to the present invention, since the vehicle user can recognize the detailed distance information by notifying the distance information detected by the distance detecting means, the user can feel safe during the parking operation, or to the present system. It is possible to further improve the reliability.

  In addition, the code | symbol in the parenthesis in each above-mentioned means is an example which shows a corresponding relationship with the specific means as described in embodiment mentioned later.

It is a block diagram of the non-contact electric power feeding system which concerns on 1st Embodiment to which this invention is applied. It is explanatory drawing for demonstrating the calculation method of the target receiving voltage in 1st Embodiment. It is the flowchart which showed the process sequence which concerns on the electric power feeding driving | operation in a vehicle. It is the flowchart which showed the process sequence which concerns on the electric power feeding driving | operation in a power transmission equipment apparatus. It is the figure which showed the 1st display example in the case of alerting | reporting before the electric power feeding start. It is the figure which showed the 2nd display example in the case of alerting | reporting before the electric power feeding start. It is a block diagram of the non-contact electric power feeding system which concerns on 2nd Embodiment to which this invention is applied. It is explanatory drawing for demonstrating the calculation method of the target receiving voltage in 2nd Embodiment. It is a block diagram of the non-contact electric power feeding system which concerns on 3rd Embodiment to which this invention is applied. It is explanatory drawing for demonstrating the calculation method of the target receiving voltage in 3rd Embodiment. It is a block diagram of the non-contact electric power feeding system which concerns on 4th Embodiment to which this invention is applied. It is explanatory drawing for demonstrating the calculation method of the target receiving voltage in 4th Embodiment. It is a block diagram of the non-contact electric power feeding system which concerns on 5th Embodiment to which this invention is applied. It is a characteristic map which concerns on the distance used by control before the electric power feeding start of 5th Embodiment, and a receiving voltage. It is the figure which showed the example of a display when performing alerting | reporting in the control before the electric power feeding operation which concerns on 5th Embodiment.

  A plurality of modes for carrying out the present invention will be described below with reference to the drawings. In each embodiment, parts corresponding to the matters described in the preceding embodiment may be denoted by the same reference numerals, and redundant description may be omitted. When only a part of the configuration is described in each mode, the other modes described above can be applied to the other parts of the configuration. Not only combinations of parts that clearly indicate that the combination is possible in each embodiment, but also a combination of the embodiments even if they are not clearly specified unless there is a problem with the combination. It is also possible.

(First embodiment)
1st Embodiment which applies the non-contact electric power feeding system of this invention is described using FIGS. FIG. 1 is a configuration diagram of a non-contact power feeding system according to the first embodiment.

  As shown in FIG. 1, the non-contact charging system is configured to include a power transmission equipment device 1 installed mainly outside the vehicle 10 and a power receiving equipment device 11 mounted on the vehicle 10.

  The non-contact power supply system can be applied when charging a main battery such as an electric vehicle and a hybrid vehicle. The non-contact power supply system is a state of being magnetically coupled between the power storage device 15 and the system power source 20 which is an example of an external power source installed outside the vehicle 10, for example, power transfer using electromagnetic induction. It is a power transfer system that transmits power in a non-contact manner. This electromagnetic induction method is a method of sending electric power by linking magnetic flux generated on the power transmission side to the power reception side.

  The vehicle 10 is equipped with a power receiving equipment device 11, a power storage device 15, a load device 16, a traveling inverter 17, a motor generator 18, and the like. For example, when the current flows through the power receiving coil 121 by electromagnetic coupling, the power storage device 15 Charging becomes possible. The power receiving equipment 11 is a device including, for example, a power receiving coil 121, a rectifier circuit 110, a step-up / down circuit 111, a charging control device 13, a communication device 14, a resonance capacitor 112, a switch 113, a load 114, a switch 115, and the like. 10 is a device that operates when charging power supplied from the system power supply 20.

  A load device 16 is mounted on the vehicle 10, and the load device 16 is driven using electric power stored in the power storage device 15 or electric power supplied from the system power supply 20. An air conditioner, a navigation device, illumination, an electric power steering unit, other auxiliary machines, and the like can be applied to the load device 16 driven by the power stored in the power storage device 15. The motor generator 18 used for traveling the vehicle operates by controlling the operation of the traveling inverter 17 by a vehicle control device mounted on the vehicle 10. The secondary battery used as the power storage device 15 is set so that its terminal voltage is high. This secondary battery is a battery configured to be chargeable / dischargeable, and for example, a nickel metal hydride battery, a lithium ion battery, or the like can be used.

  In the case of a hybrid vehicle, the motor generator 18 is a three-phase AC rotating electric machine having both functions of an electric motor and a generator. One end of the rotating shaft of the motor generator 18 is directly connected to the output shaft of the internal combustion engine (not shown), and the other end is mechanically connected to the drive wheels via a transmission (not shown). It is connected to. The motor generator 18 functions as an electric motor that controls the number of rotations and the driving torque and applies the driving force required for the driving wheels. In addition, the motor generator 18 functions as a generator that generates AC regenerative power when it is rotationally driven by the driving force from the driving wheels during deceleration.

  The resonant capacitor 112 and the resonant capacitor 7 convert the voltage and current of the output power of the high-frequency inverter 5 so as to coincide with each other and supply the rectifier circuit 110 with power in order to efficiently transmit power. The rectifier circuit 110 includes a diode and a capacitor. The high-frequency power supplied from the power receiving coil 121 is rectified by the diode, smoothed by the capacitor, and then supplied to the step-up / down circuit 111. The step-up / down circuit 111 steps up / down the voltage of the electric power from the rectifying circuit 110 to a predetermined voltage, and supplies it to the power storage device 15.

  The power receiving pad 12 includes a power receiving coil 121 that receives power in a non-contact manner and is provided in the vehicle 10. The power receiving coil 121 performs non-contact power transfer with the power transmitting coil 21. In the power receiving coil 121, the magnetic field generated by the power transmitting coil 21 is linked to the power receiving coil 121, and an induced current is generated in the power receiving coil 121. The power receiving coil 121 supplies the generated high frequency power to the rectifier circuit 110 via the resonance capacitor 112.

  The power receiving equipment 11 includes a power receiving circuit that operates when the vehicle 10 is charged with power supplied from the external system power supply 20. The power receiving circuit outputs the electric power transmitted from the power receiving coil 121 built in the power receiving pad 12 as a DC voltage, and charges the power storage device 15. The communication device 14 is controlled by the charging control device 13 and communicates with the power transmission facility device 1 via the communication device 4 on the power transmission facility side, and various information thus communicated is input to the power transmission control device 3.

  The power transmission equipment 1 includes a power transmission circuit. For example, the power transmission equipment 1 is provided in a parking facility such as a home, an apartment house, a coin parking, a commercial facility, a public facility, and the like. In contrast, this is a device that transmits electric power. The power transmission equipment 1 includes a power transmission pad 2 that covers a power transmission coil 21 that transmits power in a contactless manner and is exposed to the ground, a rectifier circuit 6, a high-frequency inverter 5, a power transmission control device 3, a communication device 4, a resonance capacitor 7, and the like. It has a circuit and operates when power is transmitted to the power receiving coil 121 of the vehicle 10.

  The power transmission control device 3 controls each part of the power transmission equipment device 1 and controls the start and stop of power transmission. The high-frequency inverter 5 is a high-frequency conversion circuit that converts power supplied from the system power supply 20 into high-frequency power and supplies the power to the resonance capacitor 7. The resonant capacitor 7 converts the voltage and current of the power supplied from the high-frequency inverter 5 so as to coincide with each other and supplies the power to the power transmission pad 2 in order to efficiently transmit power. The communication device 4 is controlled by the power transmission control device 3, communicates with the power receiving equipment device 11 via the communication device 14 of the vehicle 10, and various information thus communicated is input to the charging control device 13.

  The power transmission coil 21 is a coil wound around the facility-side core, and is installed or embedded in a parking space defined in the parking facility, and is configured to generate an electromagnetic field by predetermined energization. The power transmission coil 21 detects the approach of the vehicle to the parking space and transfers power in a non-contact manner with the power reception coil 121 provided on the vehicle 10 side. When a high-frequency current flows through the power transmission coil 21, a magnetic flux is generated in a predetermined direction according to the right-handed screw law. When the power receiving coil 121 is stopped in an appropriate direction with respect to the direction of the magnetic flux linked to the power receiving coil 121 on the vehicle side from the power transmitting coil 21 through which a current flows during power feeding, the power receiving coil 121 is stopped. An induced current flows through. Thus, the power transmission coil 21 generates magnetic flux when current flows, and transmits high-frequency power to the vehicle 10 on which the power reception coil 121 is mounted by electromagnetic induction.

  In addition, the equipment side core and the vehicle side core are made of a material having high magnetic permeability, and are formed of, for example, ferrite. The power transmission coil 21 and the power reception coil 121 are made of a material with low electrical resistance, and for example, a litz wire is used.

  In the first embodiment, in the power receiving circuit provided in the vehicle 10, the resonance capacitor 112 is connected in parallel with the power receiving coil 121 and the like, and in the power transmission circuit provided in the power transmission equipment device 1, the resonance capacitor 7 is in series with the power transmission coil 21 and the like. It is an example model connected to. Based on the connection state of the resonant capacitor 7 and the resonant capacitor 112, the contactless power feeding system shown in the first embodiment is used as a series-parallel resonant connection model.

  In the non-contact power supply system shown in the first embodiment, when the vehicle 10 parks against the power transmission coil 21 to perform non-contact power supply, the target power reception voltage received by the power reception coil 121 is calculated and parked. Then, the vehicle 10 is guided so that the power reception voltage received by the power reception coil 121 approaches the calculated target power reception voltage. Thus, the control for guiding the vehicle 10 to an appropriate parking position for power supply before the start of power supply is executed by the power transmission control device 3 and the charge control device 13, so that the vehicle 10 on the power receiving side is connected to the power transmission equipment device. 1 can be guided to a good position in terms of power reception efficiency.

  The calculation of the target power reception voltage will be described later with reference to FIG. A method for obtaining the power reception voltage actually detected by the vehicle 10 is as follows. The switch 113 is turned on before the power transmission coil 21 stops when the vehicle 10 is to obtain power from the power transmission equipment 1. When the switch 113 is turned on, a load 114 that is a resistor having a predetermined resistance value as a characteristic value is connected in parallel with the resonance capacitor 112 and connected in series with the power receiving coil 121. At this time, the switch 115 is OFF, and the power receiving coil 121 and the rectifier circuit 110 are not in a relationship of energization. As described above, before the power supply to the power storage device 15 or the like is started, the resonant capacitor 112 is connected in parallel with the load 114 to detect the voltage applied to the load 114, and the charging control device 13 detects the detected voltage. The power receiving voltage received by the power receiving coil 121 can be measured.

In this embodiment, the primary side coil inductance, the characteristic value of the primary side resonance capacitor, and the connection state of the primary side resonance capacitor in the power transmission circuit from the power transmission side device to the power reception side device (parallel connection to the power transmission coil) Or in series connection), information related to the input voltage (10V, 100V, 200V, etc.) when the vehicle 10 is guided is sent and used to calculate the target received voltage. FIG. 2 is an explanatory diagram for explaining a method of calculating a target received voltage. In the case of the series-parallel resonant connection model of the first embodiment, the electric circuit diagram shown in FIG. 2 is configured, and the impedance of each part is as shown in the right frame of FIG. The procedure for calculating the target mutual inductance and the target voltage will be described with reference to the electric circuit diagram of FIG. In the electrical circuit diagram of FIG. 2, the following relational expressions shown in Equations 1 and 2 can be derived from the relationship that is satisfied between the inverter output voltage V ₁ and the inverter output current I ₁ .

From the above formulas 1 and 2, V ₁ / I ₁ is calculated, and the target mutual inductance when the imaginary part is 0 is obtained. That is, the solving of Z _M that the imaginary part is zero.

Next, from the relationship that is satisfied between the target power reception voltage V ₃ and the inverter output voltage V ₁ , the following relational expressions shown in Equations 3 and 4 can be derived.

By substituting the solution of Equation 4 and the target mutual inductance to the number 3 above (the solution of Z _M), it is possible to calculate the target receiving voltage V _3. As described above, the method for obtaining the target mutual inductance when the imaginary part is 0 is to obtain a solution in which the input power factor of the high-frequency inverter 5 included in the power transmission equipment 1 is 1 or a value that approximates 1. The target received voltage is derived using the solution.

  Next, the operation | movement which concerns on the electric power feeding operation which the non-contact electric power feeding system of this embodiment implements is demonstrated with reference to FIG.3 and FIG.4. FIG. 3 is a flowchart mainly showing a processing procedure before starting the power feeding operation in the vehicle 10. FIG. 4 is a flowchart showing a processing procedure before the start of the power feeding operation and at the end of the power feeding operation in the power transmission equipment device 1. As shown in FIGS. 3 and 4, the vehicle 10 and the power transmission equipment 1 communicate information with each other, and one performs the subsequent processing using information received from the other. For example, information communication is performed by transmitting and receiving data between the communication device 4 and the communication device 14.

  In the power transmission equipment 1, the power transmission control device 3 determines whether or not the vehicle 10 to be transmitted is detected in step 50. In this vehicle detection determination process, for example, when the communication device 4 and the communication device 14 recognize the communication, the information on the “power transmission request” received from the vehicle 10, When it is detected that the vehicle has entered the area (within a range where power can be received), it is determined that the vehicle is detected. If it determines with the power transmission control apparatus 3 having detected the vehicle 10 at step 50, it will transmit the various information of the transmission equipment apparatus 1 with respect to the said vehicle 10 at step 52. FIG. The information to be transmitted is information used for calculation of a target received voltage required in step 28 or step 30 described later. For example, the primary side coil inductance, the characteristic value of the primary side resonance capacitor, and the primary side resonance capacitor Connection state (parallel connection or series connection with respect to the power transmission coil), input voltage (10V, 100V, 200V, etc.) when the vehicle 10 is induced.

  In the vehicle 10, the charging control device 13 determines in step 10 whether various information of the transmission facility device 1 has been received. When the charging control device 13 receives various information of the transmission facility device 1, next, in step 12, the charging control device 13 executes a process of calculating the target mutual inductance by the above-described method, and further calculates the target received voltage in step 14. Execute the process. Then, the charging control device 13 transmits a request for power transmission preparation to the power transmission equipment device 1.

  In step 54, the power transmission equipment device 1 determines whether or not a request for power transmission preparation has been received from the vehicle 10. If it is determined that the request for power transmission preparation has been received, the power transmission preparation required for the power feeding operation in the power transmission equipment device 1 is completed in step 56 with respect to the “power transmission preparation request” information from the vehicle 10, “Ready” information is transmitted to the vehicle 10.

  In the vehicle 10, when the information “Ready for power transmission” is received from the power transmission equipment 1, in Step 16, it is determined whether the information “Ready for power transmission” is received from the power transmission equipment 1. If it is determined that the power transmission preparation completion information has been received, it is determined in step 18 whether or not parking has started to stop the vehicle 10 with respect to the power transmission equipment device 1 in order to perform the power feeding operation. In this parking start determination process, in the vehicle 10, when the shift lever position is set to "reverse", the hazard lamp is lit, the brake is released, the vehicle equipped with the automatic parking guidance control system Then, when the “parking button switch” mounted on the vehicle is operated, it is determined that parking is started.

  If the charging control device 13 determines that parking is started in step 18, the charging control device 13 transmits a request for starting power transmission to the power transmission equipment device 1, and starts power reception preparation in step 20. As described above, this power reception preparation is a preparation that is performed before the power transmission coil 21 stops when the vehicle 10 is to receive power from the power transmission equipment 1, and the switch 113 of the power reception circuit is turned on. In this process, the load 114 is connected in parallel to the resonance capacitor 112 by turning off the switch 115.

  In the power transmission equipment 1, it is determined in step 58 whether or not the information “transmission start requested” is received. When a request for starting power transmission from the vehicle 10 is received, processing for starting power transmission is executed in step 60. The power transmission input voltage at the start of power transmission may be a voltage different from the input voltage at the time of charging. For example, a low input voltage of 10 V can be used for power saving. Further, after the information indicating the power supply start instruction is transmitted from the vehicle 10, the power transmission input voltage may be increased to the power supply input voltage and the power supply operation may be started in earnest.

  In the vehicle 10, it is determined in step 22 whether or not it is in an abnormal state. In this abnormal state determination step, it is determined as “abnormal” when an abnormal signal is received from the power transmission equipment device 1 or when an abnormality associated with a phenomenon occurring in the vehicle 10 is detected. The abnormality on the power transmission equipment device 1 side is associated with, for example, foreign object detection in the power transmission pad 2 and its vicinity, detection of an overvoltage state or overcurrent state, communication abnormality, and the like. The abnormality on the vehicle 10 side is associated with, for example, detection of an overvoltage state or an overcurrent state, communication abnormality, or the like.

  If the charging control device 13 determines that there is an abnormality in step 22, the charging control device 13 executes power reception stop processing in step 24, transmits that fact to the power transmission equipment device 1, and ends this flowchart. If it is determined in step 22 that there is no abnormality, in step 26, a process for measuring the power reception voltage received by the power reception coil 121 during parking is executed by the method described above. This step 26 is continuously executed at a predetermined cycle during the parking operation. Then, in step 28, it is determined whether or not “the power reception voltage measured in step 26” is close to “the target power reception voltage calculated in step 14”. In this determination process, specifically, when the difference between the target power reception voltage and the power reception voltage is within a predetermined value α set in advance, the determination is YES. If the difference between the two exceeds the predetermined value α, it is determined as NO, and the shortage of the measured received voltage with respect to the target received voltage exceeds the predetermined value α, so that the received voltage is considered small. The predetermined value α is 5 V, for example.

  If NO is determined in step 28, it is further determined in step 30 whether or not the difference between the target power reception voltage and the power reception voltage is within a predetermined value β set in advance. The predetermined value β is set to a value larger than the predetermined value α, and when α is 5V, β is set to 30V. In other words, if NO is determined in step 30, the measured power reception voltage is far away from the target power reception voltage by a value exceeding 30 V, and the power reception coil 121 of the vehicle 10 is considerably separated from the power transmission coil 21. Is considered to be. Therefore, if NO is determined in step 30, the process returns to step 22 and subsequent processing is executed.

  If it is determined as YES in step 30, the measured power receiving voltage exceeds 5V with respect to the target power receiving voltage and is within a value of 30V, and the power receiving coil 121 of the vehicle 10 is separated from the power transmitting coil 21. A little away. In this case, the positional relationship between the power receiving coil 121 and the power transmitting coil 21 is not an appropriate positional relationship for starting the power feeding operation, but the two are closer to each other so that it becomes a parking position where the power feeding operation can be started. Show. Therefore, if YES is determined in step 30, the process proceeds to step 32, and the process of notification A is executed for a user such as a driver, and then the process returns to step 22 and subsequent processes are executed.

  The notification A is a notification state indicating that the vehicle 10 is in a state close to the optimal parking position with respect to the power transmission equipment device 1. By this notification, a user such as a driver can recognize that an appropriate parking position necessary before starting the power feeding operation is approaching. Since the user can confirm how much further the direction of travel should be, the user can feel secure. For example, as shown in FIG. 5, the notification A is performed by turning on an LED indicating “close” on the display screen 50. Moreover, as shown in FIG. 6, you may implement by displaying on the display screen 51, such as a meter, "It is within 30 cm to the optimal parking position." The display screen is, for example, a liquid crystal display or the like disposed on a part of an instrument display panel disposed in front of the handle or in the center of the dashboard.

If YES is determined in step 28, the difference between the target power reception voltage and the power reception voltage is within the predetermined value α, so that the vehicle 10 is considered to be in the optimum parking position with respect to the power transmission equipment device 1 . In this case, the process proceeds to step 34 and executes the processing of informing B to the user such as a driver. After execution of the notification B process in step 34, the power supply operation start instruction process is executed in step 36, and a message to that effect is transmitted to the power transmission equipment device 1 and the present flowchart is ended. Note that, in the power feeding operation start instruction process, in the power receiving circuit, the switch 115 is turned on to control the received power to enter the rectifying circuit 110.

  The notification B is a notification state indicating that the vehicle 10 is at the optimal parking position with respect to the power transmission equipment device 1. For example, as shown in FIG. 5, the notification B is performed by turning on an LED indicating “optimum parking position” on a display screen such as a meter. In addition, as shown in FIG. 6, it may be performed by displaying “It is the optimal parking position” on a display screen such as a meter.

  As described above, by repeating the processes in Step 22, Step 26, Step 28, Step 30, and Step 32, the vehicle 10 gradually approaches the optimum parking position before the start of the power feeding operation. When the optimum parking position is satisfied, the power feeding operation starts from step 28 through step 34 and step 36.

  On the other hand, in the power transmission equipment device 1, after the power transmission start process in step 60, it is determined in step 62 whether or not it is in an abnormal state. In this abnormal state determination step, when an abnormal signal is received from the vehicle 10 side or when an abnormality associated with a phenomenon occurring in the power transmission equipment device 1 is detected, “abnormal” is determined. That is, the same processing as in step 22 described above is executed.

  When determining that there is an abnormality in step 62, the power transmission control device 3 executes a power reception stop process in step 63, transmits that fact to the vehicle 10, and ends this flowchart. If it is determined in step 62 that there is no abnormality, the power supply operation is continued until it is determined in step 64 that the power supply end condition is satisfied. The case where the power supply end condition is satisfied is, for example, that the condition of the charge end SOC is satisfied.

  If it is determined in step 64 that the power supply termination condition is not satisfied, the process returns to step 62. If it is determined in step 64 that the power supply condition is satisfied, a process of stopping power transmission to the vehicle 10 is executed in step 66, and this flow is terminated.

  The effect which the non-contact electric power feeding system of this embodiment brings is demonstrated. In the non-contact power supply system, when the vehicle 10 is parked with respect to the power transmission coil 21 to perform non-contact power supply, a target power reception voltage received by the power reception coil 121 is calculated (step 14), and during the parking operation, The vehicle 10 is guided so that the power receiving voltage received by the power receiving coil 121 approaches the target power receiving voltage (steps 22, 26, 28, 30, 32, 34).

  According to this control, when the vehicle 10 is about to stop at the parking position for performing non-contact power supply, the target power reception voltage is calculated, and the power reception voltage of the power reception coil 121 is calculated during the parking operation. The vehicle 10 is guided to approach the voltage. For this reason, the movement of the vehicle 10 during the parking operation is guided so as to approach the parking position that satisfies the target power receiving voltage at which the power receiving efficiency is good. Thus, if the non-contact power feeding system has the control related to the vehicle guidance, the vehicle 10 is guided so that the efficiency of the amount of power received with respect to the amount of power transmitted between the power transmission equipment 1 and the vehicle 10 becomes good. The For this reason, a highly versatile system capable of realizing a highly efficient power feeding operation can be obtained regardless of a difference in position of the power receiving coil 121 due to a difference in vehicle type. Therefore, it is possible to provide a non-contact power feeding system that can guide the vehicle 10 on the power receiving side to a position with good power receiving efficiency with respect to the power transmission equipment 1 on the power transmitting side.

  The target power reception voltage is calculated using at least the coil inductance on the power transmission equipment device 1 side, the coil inductance on the vehicle 10 side, and the characteristic values of the resonance capacitors 112 and 7. According to this, it is possible to calculate the target power receiving voltage with high accuracy so that the vehicle 10 can be guided to the parking position where the highly efficient power feeding operation is realized.

  Further, when calculating the target power reception voltage, a solution in which the input power factor of the high-frequency inverter 5 included in the power transmission equipment device 1 is 1 or a solution that approximates 1 is obtained, and the target power reception is performed using the solution. Deriving the voltage. According to this, the target power receiving voltage can be set so as to realize high power receiving efficiency.

  In addition, according to the contactless power supply system of the present embodiment, when the vehicle 10 is guided during the parking operation, notification means (display) that notifies the current position of the vehicle 10 with respect to the optimum parking position for performing contactless power supply. Screens 50 and 51). According to this configuration, by notifying the current position of the vehicle 10 with respect to the optimum parking position by the notification means, it is possible to roughly recognize how long the user of the vehicle 10 can complete parking. Therefore, a sense of security can be given to the user during the parking operation. In addition, the reliability of the system can be increased.

  In step 10, the power transmission equipment device 1 uses at least coil inductance information, resonance capacitor characteristic value information, and input voltage information on the power transmission equipment device 1 side as information used for guiding the parked vehicle 10. 10 is transmitted. According to this process, by transmitting information related to the guidance of the vehicle 10 from the power transmission equipment 1 to the vehicle 10, the process related to the guidance of the vehicle can be comprehensively performed on the vehicle 10 side. Therefore, a program related to the vehicle guidance control may be provided in the control device on the vehicle 10 side, which contributes to promoting standardization and mass production of the program.

  Conversely, the vehicle 10 may be configured to transmit various types of information necessary as information used for guiding the parked vehicle 10 to the power transmission equipment device 1. According to this configuration, by transmitting information related to guidance of the vehicle 10 from the vehicle 10 to the power transmission equipment 1, processing related to guidance of the vehicle can be comprehensively performed on the power transmission equipment 1 side. Therefore, a program related to the vehicle guidance control may be provided in a batch on the control device on the power transmission equipment device 1 side, and it is not necessary to install the program for various vehicle types.

(Second Embodiment)
The contactless power supply system according to the second embodiment has a configuration in which the configuration of the power transmission circuit of the power transmission facility device 1A is different from the contactless power supply system of the first embodiment. The second embodiment is the same as the first embodiment with respect to the embodiment not specifically described below, for example, the configuration, the operation of each unit, the flowchart before power supply start and during power supply operation, and the operational effects. FIG. 7 is a configuration diagram of the non-contact power feeding system according to the second embodiment. FIG. 8 is an explanatory diagram for explaining a method of calculating a target power reception voltage in the second embodiment.

  In the non-contact power feeding system of the second embodiment, the resonant capacitor 112 in the power receiving circuit of the vehicle 10 is connected in parallel with the power receiving coil 121 and the like as in the first embodiment, but in the power transmitting circuit of the power transmission equipment 1A. Unlike the first embodiment, the resonant capacitor 7 is a model example connected in parallel with the power transmission coil 21 and the like. Based on the connection state of the resonant capacitor 7 and the resonant capacitor 112, the contactless power feeding system shown in the second embodiment is used as a parallel-parallel resonant connection model.

FIG. 8 is an explanatory diagram for explaining a method of calculating a target power reception voltage. In the case of the parallel-parallel resonant connection model of the second embodiment, the electric circuit diagram shown in FIG. 8 is configured, and the impedance of each part is as shown in the right frame of FIG. A procedure for calculating the target mutual inductance and the target voltage will be described with reference to the electric circuit diagram of FIG. In the electric circuit diagram of FIG. 8, the following relational expressions shown in Equations 5, 6, and 7 can be derived from the relationship satisfied between the inverter output voltage V ₁ and the inverter output current I ₁ .

V ₁ / I ₁ is calculated from the above Equations 5, 6, and 7, and the target mutual inductance when the imaginary part is 0 is obtained. That is, the solving of Z _M that the imaginary part is zero.

Next, from the relationship that is satisfied between the target power reception voltage V ₄ and the inverter output voltage V ₁ , the following relational expressions shown in Equations 8 and 9 can be derived.

By substituting a solution having 9 and the target mutual inductance to the number 8 of the a (solution of Z _M), it is possible to calculate the target receiving voltage V _4. Thus, the method for obtaining the target mutual inductance when the imaginary part is 0 is to obtain a solution in which the input power factor of the high-frequency inverter 5 provided in the power transmission equipment 1A is 1 or a value that approximates 1. The target received voltage is derived using the solution.

(Third embodiment)
The contactless power supply system according to the third embodiment is different from the contactless power supply system of the first embodiment in the configuration of the power transmission circuit of the power receiving equipment 11A in the vehicle 10A. The third embodiment is the same as the first embodiment with respect to an embodiment not specifically described below, for example, the configuration, the operation of each unit, the flowchart before power supply start and during power supply operation, and the operational effects. FIG. 9 is a configuration diagram of the non-contact power feeding system according to the third embodiment. FIG. 10 is an explanatory diagram for describing a method of calculating a target power reception voltage in the third embodiment.

  In the non-contact power feeding system of the third embodiment, the resonant capacitor 7 in the power transmission circuit of the power transmission equipment 1 is connected in series with the power transmission coil 21 and the like, as in the first embodiment. Unlike the first embodiment, the resonance capacitor 112 in the power receiving circuit is a model example connected in series with the power receiving coil 121 and the like. Based on the connection state of the resonant capacitor 7 and the resonant capacitor 112, the contactless power feeding system shown in the third embodiment is used as a series-series resonant connection model.

FIG. 10 is an explanatory diagram for explaining a method of calculating a target received voltage. In the case of the series-series resonant connection model of the third embodiment, the electric circuit diagram shown in FIG. 10 is configured, and the impedance of each part is as shown in the right frame of FIG. The procedure for calculating the target mutual inductance and the target voltage will be described with reference to the electric circuit diagram of FIG. In the electric circuit diagram of FIG. 10, the following relational expression 10 can be derived from the relationship satisfied between the inverter output voltage V ₁ and the inverter output current I ₁ .

From the above formula 10, V ₁ / I ₁ is calculated, and the target mutual inductance when the imaginary part is 0 is obtained. That is, the solving of Z _M that the imaginary part is zero.

Next, from the relationship that is satisfied between the target power reception voltage V ₂ and the inverter output voltage V ₁ , the following relational expression 11 can be derived.

By substituting a solution of the target mutual inductance to the number 11 of the a (solution of Z _M), it is possible to calculate the target receiving voltage V _2. As described above, the method for obtaining the target mutual inductance when the imaginary part is 0 is to obtain a solution in which the input power factor of the high-frequency inverter 5 included in the power transmission equipment 1 is 1 or a value that approximates 1. The target received voltage is derived using the solution.

(Fourth embodiment)
The contactless power supply system according to the fourth embodiment is different from the contactless power supply system of the first embodiment in that the configuration of the power transmission circuit of the power transmission facility device 1A and the configuration of the power reception circuit of the power reception facility device 11A are different. ing. The fourth embodiment is the same as the first embodiment with respect to the embodiment not specifically described below, for example, the configuration, the operation of each part, the flowchart before power supply start and during power supply operation, and the operational effects. FIG. 11 is a configuration diagram of a non-contact power feeding system according to the fourth embodiment. FIG. 12 is an explanatory diagram for describing a method of calculating a target received voltage in the fourth embodiment.

  In the contactless power supply system of the fourth embodiment, unlike the first embodiment, the resonance capacitor 112 in the power reception circuit of the vehicle 10A is connected in series with the power reception coil 121 and the like, and the resonance capacitor in the power transmission circuit of the power transmission equipment 1A 7 is a model example in which the power transmission coil 21 and the like are connected in parallel. Based on the connection state of the resonant capacitor 7 and the resonant capacitor 112, the contactless power feeding system shown in the fourth embodiment is used as a parallel-series resonant connection model.

FIG. 12 is an explanatory diagram for explaining a method of calculating a target power reception voltage. In the case of the parallel-series resonant connection model of the fourth embodiment, the electric circuit diagram shown in FIG. 12 is configured, and the impedance of each part is as shown in the right frame of FIG. The procedure for calculating the target mutual inductance and the target voltage will be described with reference to the electric circuit diagram of FIG. In the electric circuit diagram of FIG. 12, the following relational expressions shown in Expressions 12 and 13 can be derived from the relationship satisfied between the inverter output voltage V ₁ and the inverter output current I ₁ .

From the above formulas 12 and 13, V ₁ / I ₁ is calculated, and the target mutual inductance when the imaginary part is 0 is obtained. That is, the solving of Z _M that the imaginary part is zero.

Next, from the relationship that is satisfied between the target power reception voltage V ₃ and the inverter output voltage V ₁ , the following relational expression 14 can be derived.

By substituting a solution of the target mutual inductance to the number 14 of the a (solution of Z _M), it is possible to calculate the target receiving voltage V _3. Thus, the method for obtaining the target mutual inductance when the imaginary part is 0 is to obtain a solution in which the input power factor of the high-frequency inverter 5 provided in the power transmission equipment 1A is 1 or a value that approximates 1. The target received voltage is derived using the solution.

(Fifth embodiment)
The non-contact power feeding system according to the fifth embodiment is different from the non-contact power feeding system according to the first embodiment in that both the power transmission equipment 1B and the vehicle 10B have distance detection means. The fifth embodiment is the embodiment not particularly described below, for example, the configuration, the operation of each part, the flowchart before power supply start and at the time of power supply operation, the effects and the like, except for the contents described below, with the first embodiment. It is the same. FIG. 13 is a configuration diagram of a non-contact power feeding system according to the fifth embodiment. FIG. 14 is a characteristic map relating to the distance and the received voltage used in the control before starting the power feeding operation. FIG. 15 is a diagram illustrating a display example when notification is performed in the control before starting the power feeding operation.

The non-contact power feeding system of the fifth embodiment includes a sensor power receiving unit 30 in the power transmission equipment 1B and a sensor transmitting unit 40 in the vehicle 10B as distance detecting means. The distance detection means can detect the distance between the power transmission equipment 1 </ b> B and the vehicle 10 </ b> B, specifically, the distance between the power transmission coil 21 and the power reception coil 121 by transmitting and receiving a measurement medium using sound waves and lasers, for example.
Therefore, the time required for the measurement medium such as the sound wave and the laser transmitted from the sensor transmission unit 40 of the vehicle 10B to be reflected and returned by the sensor reception unit 30 of the power transmission equipment 1B is emitted from the sensor transmission unit 40. The distance between the two points of the power transmission coil 21 and the power reception coil 121 can be measured by the phase difference between the reference signal and the light reception signal reflected and returned by the sensor receiver 30.

  In the form in which the distance between the power transmission coil 21 and the power reception coil 121 is detected by the distance detection unit as in the present embodiment, the non-contact power supply system has, for example, a characteristic map relating to the distance and the power reception voltage as illustrated in FIG. Is remembered. Such a characteristic map is stored in the charge control device 13 or the power transmission control device 3. FIG. 14 shows characteristic curves corresponding to the model examples of the first to fourth embodiments. The charge control device 13 and the power transmission control device 3 select which model example the characteristic curve should be used by communicating with each other as described above.

  The non-contact power feeding system of the present embodiment executes the parking start determination (step 18), the power reception preparation (step 20), and the no-abnormality determination (step 22) in order in the flowchart of FIG. In addition, the distance between the power transmission coil 21 and the power reception coil 121 is detected by the distance detection means. Then, the detected distance is applied to the characteristic curve selected from FIG. 14 to obtain the received voltage. That is, in the present embodiment, the received voltage is obtained using the characteristic map and the distance detecting means shown in FIG. 14 instead of the process of step 26 in the flowchart shown in FIG. Either the charging control device 13 or the power transmission control device 3 may execute the process for obtaining the power reception voltage. The charging control device 13 executes the determination processing of step 28 and step 30 in FIG. 3 using the power reception voltage thus obtained.

  Further, the contactless power feeding system of the present embodiment displays a display as shown in FIG. 15 on the navigation device screen 52 in the process of notification A in step 32 of FIG. That is, in order to carry out detailed distance detection by the distance detection means, it is possible to clearly display the detailed distance (in the example shown in FIG. 15, “the remaining parking distance is 30 cm”).

  The contactless power supply system of this embodiment includes distance detection means (sensor transmission unit 40 and sensor reception unit 30) that detects the distance between the power transmission coil 21 and the power reception coil 121, and is established between the distance and the power reception voltage. A map indicating the characteristics (see, for example, FIG. 14) is stored in advance, and the power reception voltage is obtained from the distance detected by the distance detection unit and the map. According to this control, the parking accuracy of the vehicle 10B can be further improved by obtaining the received voltage using the detailed distance information detected by the distance detecting means.

  Further, according to the non-contact power feeding system of the present embodiment, when guiding the vehicle 10B during the parking operation, the distance detection unit detects the current position of the vehicle with respect to the optimal parking position for performing non-contact power feeding. Informing means (navigation device screen 52) for informing the distance is provided. According to this configuration, since the driver of the vehicle 10B can recognize the detailed distance information by notifying the distance information detected by the distance detecting means, the user's sense of security during the parking operation, The user's confidence in the non-contact power supply system can be further improved.

(Other embodiments)
The preferred embodiments of the present invention have been described above, but the present invention is not limited to the above-described embodiments, and various modifications can be made without departing from the spirit of the present invention.

  The vehicle guidance in each of the above embodiments includes parking operation by a driver and automatic parking operation not by a driver. Therefore, the guidance of the vehicle is to guide the progress of the vehicle by affecting the driving operation of the driver who drives the vehicle, and when the automatic parking operation is performed, the guidance is performed by the control device that controls the automatic parking operation. It is included.

  In the first embodiment, the vehicle 10 side determines how close the power reception voltage is to the target power reception voltage in Step 28 and Step 30, but it may be determined on the power transmission equipment device 1 side. . Further, the target power receiving voltage may be calculated on the power transmission equipment device 1 side.

In the first embodiment and the fifth embodiment described above, in the notification process in step 34 or step 32, the information is displayed on the display screen of a meter, a navigation device, etc., but is not limited to this form. For example, the notification A and the notification B may be based on voice guidance. For example, in the notification A, the voice guidance can be "within 30 cm", and in the notification B, the voice guidance can be given "Parking. Please put the shift into parking." The non-contact power supply system includes a distance sensor on both the power transmission equipment side and the vehicle side in the configuration of the non-contact power supply system of the first embodiment, but this form is an example and is limited to this embodiment. Not what you want. For example, the configuration including the distance sensor on both the power transmission facility side and the vehicle side can be applied to any form of the second to fourth embodiments.

  In the above embodiment, each core may be formed using a magnetic material other than ferrite, for example, a ferromagnetic material with little AC loss, such as a dust core or a silicon steel plate. Moreover, you may comprise each coil with wires other than a litz wire.

DESCRIPTION OF SYMBOLS 1,1A, 1B ... Power transmission equipment 5 ... High frequency inverter 10, 10A, 10B ... Vehicle 21 ... Power transmission coil 30 ... Sensor receiving part (distance detection means)
40: Sensor transmission unit (distance detection means)
50, 51 ... display screen (notification means)
52. Navigation device screen (notification means)
121 ... Receiving coil

Claims (3)

Non-contact power supply that generates an electromagnetic field between a power reception coil (121) provided in the vehicle (10) and a power transmission coil (21) provided in the power transmission equipment (1) outside the vehicle to perform non-contact power supply A system,
When the vehicle is parked with respect to the power transmission coil to perform the non-contact power supply, a target power reception voltage received by the power reception coil is calculated, and the power reception voltage of the power reception coil is the target power during the parking operation. When approaching the power reception voltage, the current position of the vehicle is notified to the driver,
When calculating the target receiving voltage, at least,
The inverter output voltage (V ₁ ), the inverter output current (I ₁ ), the coil inductance, and the impedance of the resonant capacitor (7) , which are sent from the power transmission equipment to the vehicle, respectively ,
Using the coil inductance, the impedance of the resonant capacitor (112), and the load (114), respectively, on the vehicle side,
A solution in which the input power factor of the high-frequency inverter (5) included in the power transmission equipment device is 1 or a solution close to 1 is obtained, and the target received voltage is derived using the solution. Contactless power supply system. Distance detection means (30, 40) for detecting the distance between the power transmission coil (21) and the power reception coil (121);
Pre-store a map showing characteristics established between the distance and the received voltage,
The contactless power feeding system according to claim 1 , wherein the power reception voltage is obtained from the distance detected by the distance detection unit and the map. As the current position of the vehicle relative to the optimum parking position for feeding current before Symbol contactless, in claim 2, characterized in that it comprises a notifying means (52) for notifying said distance detected by said distance detecting means The non-contact power feeding system described.

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