JP5256672B2 - Vehicle power supply device - Google Patents

Description

  The present invention relates to a power feeding device for a vehicle.

  Conventionally, a system for supplying power to a vehicle by transmitting a radio wave such as a microwave from a power supply device embedded in a road, receiving the radio wave by a rectenna installed in the vehicle, and converting it into electric power is known. It has been. As a technique for increasing power supply efficiency in such a system, a power receiving system disclosed in Patent Document 1 has been proposed. This power receiving system is a power supply device embedded in a road, wherein a transmission-side reflecting plate that reflects radio waves is provided on the outer periphery of a slot antenna, and an outer periphery of a rectenna that receives radio waves in a power receiving device mounted on a vehicle. A receiving-side reflecting plate that reflects microwaves is provided in the part. As a result, leakage of radio waves outside the rectenna is prevented, and the power supply efficiency to the vehicle is increased.

JP 2002-152996 A

  In the electric power receiving system disclosed in Patent Document 1, it is necessary to install a reflector on the vehicle, which affects the outer shape of the vehicle.

A vehicle power supply apparatus according to the present invention is a vehicle power supply apparatus that supplies power to the vehicle by transmitting radio waves to receiving means installed in the vehicle, and transmits the radio waves to the receiving means. Transmitting means; moving means for moving the transmitting means to change a transmission / reception gap between the transmitting means and the receiving means; and using the moving means, the transmitting means and the receiving means between The phase of the radio wave when the radio wave transmitted by the transmission unit reaches the reception unit is moved by moving the transmission unit to a position where a transmission / reception gap substantially coincides with an integral multiple of a half wavelength of the radio wave as the phase control means, radio waves transmitted from said transmitting means by a reflection plate provided inside the guide for moving said transmission means is reflected, the use said moving means By increasing the reception gap, characterized in that it comprises a directional improvement means for improving the radio wave directivity.

  According to the present invention, the power supply efficiency to the vehicle can be improved without affecting the outer shape of the vehicle.

-First embodiment-
FIG. 1 shows a power supply system using the vehicle power supply apparatus according to the first embodiment of the present invention. This power supply system supplies power to the traveling vehicle 10 by transmitting radio waves from a vehicle power supply device embedded in the road toward the vehicle 10 that is an electric vehicle. Fig.1 (a) has shown the front view of this electric power feeding system when the vehicle 10 used as electric power feeding object is seen from the front direction.

  A rectenna 11 is installed in the lower part of the vehicle 10. In the rectenna 11, as shown in FIG. 1 (b), a large number of rectenna elements 11r are arranged in a grid pattern in the vertical and horizontal directions. FIG. 1B shows the rectenna 11 when the vehicle 10 is viewed from the lower side, that is, the road surface side. Each of the rectenna elements 11r includes an antenna unit for receiving microwaves and a rectifier circuit unit that rectifies a microwave component obtained by the antenna unit and converts it into a direct current.

  When a microwave is transmitted from the transmission antenna 21 of the vehicle power supply device and received by the rectenna 11, a direct current corresponding to the intensity of the received microwave is obtained by the rectifier circuit portion of each rectenna element 11r. This direct current is combined for each rectenna element and then sent from the rectenna 11 to a drive system 12 provided in the vehicle 10. As a result, power is supplied from the vehicle power supply apparatus to the vehicle 10, and the drive system 12 obtains received power corresponding to the intensity of the received microwave.

  The drive system 12 drives the vehicle 10 using the direct current from the rectenna 11. The drive system 12 includes, for example, an inverter, a power storage mechanism, a drive motor, various electric circuits, and the like. The configuration of the drive system 12 is the same as that used in a conventional electric vehicle that is connected to a power source for charging.

  The vehicle power supply apparatus includes a transmission antenna 21, a control unit 22, a drive unit 23, a signal generation unit 24, and a guide 25. The transmission antenna 21 transmits a microwave to the rectenna 11 based on the signal transmitted from the signal generator 24. When this microwave is received by the rectenna 11, a direct current is obtained as described above. Thereby, the electric power feeding to the vehicle 10 is performed. In order to efficiently transmit the microwave, the transmission surface of the transmission antenna 21 is provided substantially parallel to the reception surface of the rectenna 11.

  The control unit 22 controls operations of the drive unit 23 and the signal generation unit 24. The control unit 22 is configured by, for example, a microcomputer. The drive unit 23 has a drive mechanism for moving the transmission antenna 21 in the vertical direction in FIG. 1 along the guide 25, and operates the drive mechanism in accordance with control from the control unit 22. When the drive mechanism of the drive unit 23 operates, the transmission antenna 21 is moved along the guide 25, and the distance between the transmission antenna 21 and the rectenna 11 changes. That is, when the transmission antenna 21 is moved upward by the drive unit 23, the distance between the transmission antenna 21 and the rectenna 11 is shortened accordingly. On the contrary, when the transmission antenna 21 is moved downward by the drive unit 23, the distance between the transmission antenna 21 and the rectenna 11 is increased accordingly. In the following description, the distance between the transmission antenna 21 and the rectenna 11 when transmitting a microwave from the transmission antenna 21 is referred to as a transmission / reception gap.

  The signal generation unit 24 generates a signal for the transmission antenna 21 to transmit a microwave in accordance with control from the control unit 22 and transmits the signal to the transmission antenna 21. Based on the signal transmitted from the signal generator 24, a microwave having a predetermined frequency is output from the transmission antenna 21. The guide 25 has a structure for restricting the direction in which the transmission antenna 21 can move in the vertical direction of FIG. With this structure, when the drive unit 23 moves the transmission antenna 21 along the guide 25, the transmission antenna 21 moves in the vertical direction in FIG. A reflector using a material that reflects microwaves, such as metal, is provided inside the guide 25, that is, in a portion adjacent to the transmission antenna 21.

  In the power supply system described above, when the control unit 22 controls the operation of the drive unit 23 and the drive unit 23 moves the transmission antenna 21 to change the transmission / reception gap, the transmission antenna 21 responds to the change. The phase of the microwave when the transmitted microwave reaches the rectenna 11 changes. In accordance with the change in phase, the received power obtained by receiving microwaves in the rectenna 11 changes.

  The graph of FIG. 2 shows an example of an experimental result in which the relationship between the transmission / reception gap and the received power by the rectenna 11 is measured using the power supply system of the present embodiment. In FIG. 2, the horizontal axis indicates the received power in the rectenna 11, and the vertical axis indicates the length of the transmission / reception gap. Here, experimental results when the microwave frequency is 2.45 GHz are shown. When the wavelength of the microwave at this time is λ, λ≈122.4 mm.

  When the graph of FIG. 2 is seen, it turns out that the received power shown on a horizontal axis is changing periodically with respect to the transmission / reception gap shown on a vertical axis | shaft. The period of this change is approximately equal to half the wavelength λ of the microwave, that is, 61.2 mm. In other words, every time the transmission / reception gap changes by the half wavelength of the microwave, the maximum point of the received power appears. Further, at the point indicated by reference numeral 30, the maximum received power P is obtained. The transmission / reception gap at this time substantially coincides with the above-mentioned microwave wavelength λ, that is, about 122.4 mm. Therefore, as shown in FIG. 1, when the transmission / reception gap between the transmission antenna 21 and the rectenna 11 is set to d≈122.4 mm, power can be supplied most efficiently. The size d of the transmission / reception gap is a value that can be sufficiently realized when the minimum ground clearance of the vehicle 10 is taken into consideration.

  As described above, the control unit 22 uses the driving unit 23 to move the transmission antenna 21 to a predetermined position, so that the microwave transmitted by the transmission antenna 21 reaches the rectenna 11. The phase can be controlled. At this time, the received power can be maximized as shown in FIG. 2 by moving the transmitting antenna 21 to a position where the transmission / reception gap and the wavelength of the microwave are substantially coincident with each other.

  Although FIG. 2 shows an example of an experimental result in which the received power is maximized at a point where the transmission / reception gap substantially coincides with the wavelength of the microwave, the received power may be maximized at other maximum points. For example, the received power is maximized when the transmission / reception gap is approximately half the microwave wavelength, or the received power is maximized when the transmission / reception gap is approximately 3/2 times the microwave wavelength. There is also a possibility. Therefore, in order to be able to cope with these cases, the control unit 22 also includes a plurality of maximum points of received power other than the point 30, that is, a plurality of transmission / reception gaps whose transmission / reception gaps substantially coincide with an integral multiple of a half wavelength of the microwave. It is preferable that the transmitting antenna 21 can be moved to the position using the driving unit 23.

According to the first embodiment described above, the following operational effects are obtained.
(1) The microwave is transmitted to the rectenna 11 installed in the vehicle 10 by the transmission antenna 21. The control unit 22 controls the phase of the microwave when the microwave reaches the rectenna 11. Since it did in this way, the electric power feeding efficiency to the vehicle 10 can be improved, without affecting the external shape of the vehicle 10.

(2) The control unit 22 moves the transmission antenna 21 to a predetermined position using the driving unit 23, thereby changing the transmission / reception gap, that is, the distance between the transmission antenna 21 and the rectenna 11, and changing the phase of the microwave. I decided to control it. Since it did in this way, it can be set as the state where electric power feeding efficiency is high reliably.

(3) The control unit 22 moves the transmission antenna 21 to a position where the transmission / reception gap substantially coincides with an integral multiple of a half wavelength of the microwave. Since it did in this way, it can be set as a state with high electric power feeding efficiency by simple control.

-Second embodiment-
Next, a second embodiment of the present invention will be described. In the first embodiment described above, the example in which the transmission efficiency is improved by moving the transmission antenna 21 to a position where the transmission / reception gap substantially coincides with an integral multiple of the half wavelength of the microwave has been described. In contrast, in the present embodiment, an example in which power supply efficiency is improved based on received power obtained by receiving microwaves in vehicle 10 will be described below.

  A power supply system using the vehicle power supply apparatus according to the present embodiment is shown in FIG. The power supply system further includes a receiving unit 26 as compared with the first embodiment shown in FIG. In addition to the functions described in the first embodiment, the drive system 12 further has a function of calculating received power and transmitting the calculation result to the vehicle power supply device.

  In the power supply system of FIG. 3, when the drive system 12 receives the direct current output from the rectenna 11, the drive system 12 calculates received power based on the current value. Then, a high-frequency signal based on the calculated received power value is transmitted to the transmitting antenna 21 via the rectenna 11. When the transmission antenna 21 receives the high-frequency signal transmitted from the drive system 12, the transmission antenna 21 outputs it to the reception unit 26. The receiving unit 26 demodulates the high frequency signal received by the transmitting antenna 21 and outputs the demodulated signal to the control unit 22. As a result, the received power information obtained by the rectenna 11 receiving the microwave in the vehicle 10 is acquired by the receiving unit 26 and output to the control unit 22.

  Based on the received power information acquired by the receiving unit 26 as described above, the control unit 22 uses the drive unit 23 to move the transmitting antenna 21 to a position where the received power is maximized. At the position after this movement, a microwave is transmitted from the transmitting antenna 21 to the rectenna 11. Therefore, even if the position of the transmission antenna 21 at which the received power is maximized varies due to changes in environmental conditions, individual differences in component characteristics in the power feeding system, etc., it is possible to always feed efficiently.

  The graph of FIG. 4 has shown an example of the experimental result which measured the relationship between the transmission / reception gap and the received electric power by the rectenna 11 using the electric power feeding system of this embodiment. In FIG. 4, the horizontal axis indicates the received power in the rectenna 11, and the vertical axis indicates the length of the transmission / reception gap. In this graph, with respect to the transmission / reception gap shown on the vertical axis, the received power shown on the horizontal axis changes periodically with a period λ / 2 as in the graph of FIG.

In power supply system of this embodiment, the default value d _f of the transmitting and receiving gap is preset. Initially at the location of the default values d _f, it transmits a microwave from the transmitting antenna 21 to the rectenna 11. Incidentally, in order to maximum received power in normal use state is obtained, the default value d _f can be set and microwave value wavelength λ substantially matching as described for example in FIG. 2 .

However, due to individual differences of the component characteristics in the change and feed system of environmental conditions, as indicated by reference numeral 30 in FIG. 4, the position of the default values d _f sometimes received power is not a maximum. Therefore, the control unit 22, while the transmitting antenna 21 using the driving unit 23 is moved up and down from the position of the default values d _f, to transmit the microwave from the transmitting antenna 21 to the rectenna 11. The movement range of the transmission antenna 21 at this time is to include any of the maximum point of the received power that varies periodically with a period lambda / 2, respectively above and below the center position of the default values d _f lambda A range of λ / 2 is set in increments of / 4. That is, transmission and reception gap moves the transmitting antenna 21 so as to vary in a range of _{d f ± (λ / 4)} .

When information on received power is transmitted from the drive system 12 via the rectenna 11 while the transmitting antenna 21 is moved within the above range, the information is acquired by the receiving unit 26. Based on the information thus obtained, the control unit 22 detects a change in received power within the moving range of the transmission antenna 21 and sets a transmission / reception gap d ₀ corresponding to the point 31 at which the maximum received power P ₀ is obtained. Identify. When the transmission / reception gap d ₀ corresponding to the maximum received power P ₀ is specified in this way, the control unit 22 moves the transmission antenna 21 to the position of the transmission / reception gap d ₀ again using the drive unit 23.

As described above, when the transmission antenna 21 is moved to the position of the transmission / reception gap d ₀ , power is supplied to the vehicle 10 by transmitting microwaves from the transmission antenna 21 to the rectenna 11. As a result, even _if the position of the transmitting antenna 21 at which the received power is maximum fluctuates from the position of the default value df, power can always be supplied efficiently.

As described above, when specifying the transmission / reception gap d ₀ , the output of the microwave transmitted from the transmission antenna 21 to the rectenna 11 may be set lower than that during power feeding. That is, until receiving gap d ₀ is identified previously kept low the output of the microwave, after receiving the gap d ₀ is identified, raised to the original value of the output of the microwave, for supplying power to the vehicle 10 . In this way, the power supply efficiency can be further improved.

According to the second embodiment described above, the following operational effects are obtained.
(1) The receiving unit 26 acquires information on received power obtained by the rectenna 11 receiving microwaves. Based on this information, the control unit 22 causes the drive unit 23 to move the transmission antenna 21 to a position where the received power is maximized. Since it did in this way, even if the position of the transmitting antenna 21 at which the received power is maximum fluctuates due to changes in environmental conditions, individual differences in component characteristics in the power feeding system, etc., power can be fed efficiently.

(2) The control unit 22 moves the transmission antenna 21 to a position where the received power becomes maximum within a range in which the transmission / reception gap changes by approximately half the wavelength of the microwave. Since it did in this way, the transmission antenna 21 can be reliably moved to the position corresponding to the maximum point of received electric power, suppressing the movement range of the transmission antenna 21 to the minimum.

-Third embodiment-
Next, a third embodiment of the present invention will be described. In the second embodiment, the example in which the position where the received power is maximized within the range in which the transmission / reception gap changes by approximately half the wavelength of the microwave is specified and the transmission antenna 21 is moved to that position has been described. . On the other hand, in the present embodiment, an example will be described below in which the position where the received power becomes maximum exceeds the range in which the transmission / reception gap changes by approximately half the wavelength of the microwave.

  FIG. 5 shows a power supply system using the vehicle power supply apparatus according to this embodiment. This power feeding system has the same configuration as that of the second embodiment shown in FIG.

FIG. 6 is a flowchart of power supply control processing executed by the control unit 22 in the vehicle power supply apparatus according to the present embodiment. In step S01, the control unit 22, by moving the reception antenna 21 by using the driving unit 23, it is set to its default value d _0, which is set to receive gaps in advance. Note that, as described above, a value that substantially matches the wavelength λ of the microwave is set as the default value d ₀ of the transmission / reception gap.

In step S <b> 02, the control unit 22 causes the signal generation unit 24 to generate a predetermined signal, thereby transmitting a microwave from the transmission antenna 21 to the rectenna 11. Thus, the transmission of microwaves is performed in the transmission and reception gap d ₀ set in step S01.

In step S03, the control unit 22 detects the reception power _{P 0} of the microwave in the receiving gap _{d 0.} At this time, when received power information is transmitted from the drive system 12 via the rectenna 11 to the microwave transmitted in step S02 as described above, the information is acquired by the receiving unit 26, and the control unit 22 is output. Thus based on the information of the received power that is output from the receiving unit 26, the control unit 22 can detect the reception power P ₀ of the microwave in the receiving gap d _0.

When the microwave output is constant, the magnitude of the received power in the rectenna 11 is uniquely determined with respect to the transmission / reception gap, so that the received power can be expressed by a function having the value of the transmission / reception gap as a variable. For example, when the function of the received power is P, the received power P ₀ in the transmission / reception gap d ₀ is expressed as P ₀ = P (d ₀ ).

In step S04, the control unit 22, the maximum value _{P max} of the received power, it substitutes the reception power _{P 0} detected in step S03. Further, with respect to transmitting and receiving gap _{d max} corresponding to the maximum value _{P max} of the received power, it substitutes the default value _{d 0} of the transmitting and receiving gap. Thus, P _max = P ₀ and d _max = d ₀ are temporarily set.

In step S05, when the transmission / reception antenna 21 is moved within the predetermined range by moving the transmission / reception antenna 21 using the driving unit 23, the control unit 22 sets the transmission / reception gap value at which the maximum value is obtained in the received power. To detect. The detected value of the receiving gap, _{where, d 1, d 2, ···} , expressed as _{d n.} Note that n is the number of maximum values of the received power within the change range of the transmission / reception gap. A transmission / reception gap is detected according to the number of local maximum values.

The range in which the transmission / reception gap is changed in step S05 is set so that a plurality of maximum values can be obtained in the received power. That is, as described above, the transmission / reception gap is changed beyond λ so that the received power changing at a period of λ / 2 with respect to the transmission / reception gap includes at least twice the range of the period. For example, the transmission / reception gap is changed in the range of d ₀ ± λ or d ₀ ± (λ / 2) around the default value d ₀ .

  In step S06, the control unit 22 sets 1 to the variable i. This variable i is incremented one by one from 1 to n by the processing of steps S10 and S101 described later.

In step S07, the control unit 22, out of the reception gap d ₁ to d _n which is detected according to the number of maximum values in step S05, selects the receiving gap d _i corresponding to the value of the current variable i. Then, in the transmission and reception gap d _i selected, it transmits the microwave from the transmitting antenna 21 to the rectenna 11. When received power information is transmitted from the drive system 12 to the microwave via the rectenna 11, the information is acquired by the receiving unit 26 and output to the control unit 22. Based on the received power information output from the receiving unit 26 in this way, the control unit 22 detects the received power P _i of the microwave in the transmission / reception gap d _i . If the output of the microwave at this time is set to the same output as in step S03, it can be expressed as P _i = P (d _i ) using the function P described above.

In step S08, the control unit 22 compares the received power P _i detected in the current step S07 with the received power P _i-1 detected when the previous step S07 was performed, to determine the current received power P. _i is equal to or previous reception power P _i-1 or more. When variable i is 1, received power P ₁ is compared with received power P _{0 at} transmission / reception gap default value d ₀ . As a result of the comparison, if P _i ≧ P _i−1 , the process proceeds to step S09, and if not, the process proceeds to step S10.

In step S09, the control unit 22 substitutes the received power P _i determined to be equal to or higher than the previous received power P _{i−1 in} step S08 for the maximum value P _max of the received power. Further, the transmission / reception gap d _i corresponding to the received power P _i is substituted for the transmission / reception gap d _max corresponding to the above P _max . Thereby, the values of P _max and d _max are respectively replaced, and P _max = P _i and d _max = d _i are set.

  In step S10, the control unit 22 determines that the currently set value of the variable i is n, which is the number of transmission / reception gaps obtained in step S05, that is, the maximum value of the received power within the transmission / reception gap change range. Determine whether they are equal. If i = n, that is, if the received power has already been detected in step S07 for all transmission / reception gaps detected in step S05, the process proceeds to step S11. On the other hand, if i = n is not satisfied, that is, if the variable i is smaller than n, the process proceeds to step S101. In step S101, the control unit 22 adds 1 to the variable i. Thereafter, the control unit 22 returns to step S07 and repeats the above processing.

In step S11, the control unit 22 moves the transmission / reception antenna 21 using the drive unit 23, and sets a transmission / reception gap so as to be equal to d _max finally determined by the processing in steps S01 to S10. Then, power is supplied to the vehicle 10 by transmitting microwaves from the transmission antenna 21 in accordance with preset power. If step S11 is performed, the control part 22 will complete | finish the flowchart of FIG. 6, and will continue the electric power feeding to the vehicle 10 by the determined transmission / reception gap.

  The graph of FIG. 7 shows an example of an experimental result in which the relationship between the transmission / reception gap and the received power by the rectenna 11 is measured using the power supply system of the present embodiment. In FIG. 7, the horizontal axis indicates the received power in the rectenna 11, and the vertical axis indicates the length of the transmission / reception gap. In this graph, with respect to the transmission / reception gap shown on the vertical axis, the received power shown on the horizontal axis changes periodically with a period λ / 2, as in the graphs of FIGS.

When the processing in step S03 in the flowchart of FIG. 6 is executed, at the point indicated by reference numeral 30 in the graph of FIG. 7, the reception power P ₀ in default value d ₀ of the transmitting and receiving gap is detected. The received power P ₀ is expressed as P ₀ = P (d ₀ ) using the function P as described above. Further, the processing in steps S05 is performed, as shown in FIG. 7, the default value d ₀ centers transceiver gap ± lambda in the, or varied between ± (λ / 2), the received power A local maximum is detected. Note that the transmission / reception gap may be changed within this range.

The above process, in the point indicated by reference numeral 31, the maximum value P ₁ of the reception power corresponding to the transmission and reception gap d ₁ is detected. The received power P ₁ is expressed as P ₁ = P (d ₁ ) using the function P, similarly to P ₀ . Further, the transmission / reception gap d ₁ can be expressed, for example, as d ₁ = d ₀ + (λ / 2). Then, the processing of step S09 and S11, the transmitting antenna 21 as transmission and reception gap is d ₁ is moved to the position indicated by reference numeral 21a in FIG. 5, the power supply to the vehicle 10 is performed in this position.

By performing the power feeding control process as described above, the control unit 22 ensures that the transmitting antenna 21 is located at the position corresponding to the highest received power among the plurality of maximum values of the received power obtained according to the transmission / reception gap. Can be moved. Therefore, even when the position where the received power is maximized is not in the vicinity of the default value d ₀ of the transmission / reception gap, efficient power feeding can be performed to the vehicle 10.

According to the third embodiment described above, the following operational effects are obtained.
(1) The control unit 22 moves the transmission antenna 21 to a position where the received power becomes maximum within a range in which the transmission / reception gap changes beyond the wavelength of the microwave. Since it did in this way, the transmitting antenna 21 can be reliably moved to the position where received electric power becomes the maximum.

-Fourth embodiment-
Next, a fourth embodiment of the present invention will be described. In the first to third embodiments, the example in which the transmission antenna 21 is moved only in the vertical direction has been described. In contrast, in the present embodiment, the transmitting antenna 21 is further moved in a direction perpendicular to the moving direction thereof, that is, in the left-right direction, and power is supplied to the vehicle 10 at a position where the received power is maximized. Is described below.

  A power supply system using the vehicle power supply device according to the present embodiment is shown in FIG. In this power feeding system, the drive unit 23 controls the control unit 22 to add the transmission antenna 21 in the horizontal direction, that is, in a direction substantially parallel to the reception surface of the rectenna 11 in addition to the vertical direction in the figure. Can be moved between.

FIG. 9 is a flowchart of power supply control processing executed by the control unit 22 in the vehicle power supply apparatus according to the present embodiment. In step T01, the control unit 22, similarly to step S01 of FIG. 6, by moving the reception antenna 21 by using the driving unit 23, is set to its default value d _0, which is set to receive gaps in advance.

In step T02, similarly to step S02 of FIG. 6, the control unit 22 causes the signal generation unit 24 to generate a predetermined signal, thereby causing the transmission antenna 21 to transmit the microwave to the rectenna 11. Thus, the transmission of microwaves is performed in the transmission and reception gap d ₀ set in step T01.

In step T03, the control unit 22 detects the received power of the microwave while moving the transmitting antenna 21 in the lateral direction in the range of 0 to e using the driving unit 23. At this time, the received power information is transmitted from the drive system 12 via the rectenna 11 to the microwave transmitted from the transmission antenna 21. The information on the received power is acquired by the receiving unit 26 and output to the control unit 22, whereby the control unit 22 detects the received power. Thus, detecting the maximum received power P ₀ at reception gap d _0. Further, the horizontal position e ₀ of the transmission antenna 21 when the received power P ₀ is obtained is detected.

Note that by making the output of the microwave constant, the magnitude of the received power in the rectenna 11 is uniquely determined with respect to the combination of the transmission / reception gap and the lateral position of the transmission antenna 21. Therefore, the received power can be expressed by a function having the value of the transmission / reception gap and the value of the lateral position of the transmission antenna 21 as variables. That is, assuming that the function of the received power is P as described above, the maximum received power P ₀ in the transmission / reception gap d ₀ is expressed as P ₀ = P (d ₀ , e ₀ ).

In step T04, the control unit 22 substitutes the maximum received power P ₀ in the transmission / reception gap d ₀ detected in step T03 for the maximum value P _max of the received power. When the transmission / reception gap default value d ₀ and the received power P ₀ are obtained with respect to the transmission / reception gap d _max corresponding to the maximum value P _max of the received power and the lateral position e _max of the transmission antenna 21. The horizontal position e ₀ of the transmission antenna 21 is substituted. As a result, P _max = P ₀ , d _max = d ₀ , and e _max = e ₀ are temporarily set.

In step T05, similarly to step S05 in FIG. 6, the control unit 22 moves the transmission antenna 21 in the vertical direction using the drive unit 23 to change the transmission / reception gap within a predetermined range, and the received power is maximized. a transmitting and receiving gap _{d 1,} d 2 comprising, ..., and detects the _{d n.} As described above, n represents the number of maximum values of the received power within the change range of the transmission / reception gap. In order to obtain a plurality of maximum values in the received power, the change range of the transmission / reception gap at this time is, for example, d ₀ ± λ or d ₀ ± (λ / 2) with the default value d ₀ as the center. Set to range. At this time, the horizontal position of the transmitting antenna 21 is fixed to any value within the range of 0 to e.

  In step T06, the control unit 22 sets 1 to the variable i. This variable i is incremented one by one from 1 to n by the processing of steps T10 and T101 described later.

In step T07, the control unit 22, out of the reception gap d ₁ to d _n which is detected according to the number of maximum values in step T05, selecting a reception gap d _i corresponding to the value of the current variable i. In this transmitting and receiving gap d _i, transmitted from the antenna 21 to the rectenna 11 while transmitting the microwave, using the drive unit 23 is moved in a range of 0~e the transmitting antenna 21 in the lateral direction, the receiving portion 26 as described above The received power of the microwave is detected based on the received power information acquired by the above. Then, it detects the maximum received power P _i in transceiver gap d _i, detects the lateral position e _i of the transmitting antenna 21 when the reception power P _i is obtained. At this time, if the output of the microwave is set to the same output as in step T03, it can be expressed as P _i = P (d _i , e _i ) using the function P described above.

In step T08, the control unit 22, the received power P _i detected in the current step T07, by comparing the received power P _i-1, which is detected when carrying out the last step T07, the current received power P _i is equal to or previous reception power P _i-1 or more. When variable i is 1, received power P ₁ is compared with received power P _{0 at} transmission / reception gap default value d ₀ . From this comparison result, if P _i ≧ P _i−1 , the process proceeds to step T09, and if not, the process proceeds to step T10.

In step T09, the control unit 22 substitutes the received power P _i determined to be equal to or higher than the previous received power P _{i-1 in} step T08 for the maximum value P _max of the received power. Further, the transmission / reception gap d _i corresponding to the received power P _i and the lateral position e _i of the transmission antenna 21 are respectively substituted for the transmission / reception gap d _max and the lateral position e _max corresponding to the above P _max . Thereby, the values of P _max , d _max and e _max are respectively replaced, and P _max = P _i , d _max = d _i , and e _max = e _i are set.

  In step T10, the control unit 22 determines whether or not the currently set value of the variable i is equal to the number n of maximum values of received power obtained as the number of transmission / reception gaps in step T05. If i = n, that is, if the maximum received power has been detected in step T07 for all transmission / reception gaps detected in step T05, the process proceeds to step T11. On the other hand, if i = n is not satisfied, that is, if the variable i is smaller than n, the process proceeds to step T101. In step T101, the control unit 22 adds 1 to the variable i. Thereafter, the control unit 22 returns to Step T07 and repeats the above processing.

In step T11, the control unit 22 moves the transmission / reception antenna 21 using the drive unit 23, and sets the transmission / reception gap and the lateral position so as to be equal to the finally determined d _max and e _max . Then, power is supplied to the vehicle 10 by transmitting microwaves from the transmission antenna 21 in accordance with preset power. When step T11 is executed, the control unit 22 ends the flowchart of FIG. 9 and continues to supply power to the vehicle 10 based on the determined transmission / reception gap and the lateral position of the transmission antenna 21.

  The graph of FIG. 10 has shown an example of the experimental result which measured the relationship between the transmission / reception gap and the received electric power by the rectenna 11 using the electric power feeding system of this embodiment. In FIG. 10, the horizontal axis represents the received power in the rectenna 11, and the vertical axis represents the length of the transmission / reception gap.

When the processing in step T03 in the flowchart of FIG. 9 is performed, at the point indicated by reference numeral 30 in the graph of FIG. 10, the maximum received power P ₀ in default value d ₀ of the transmitting and receiving gap, its reception power P ₀ obtained Then, the horizontal position e ₀ of the transmitting antenna 21 is detected. The received power P ₀ is expressed as P ₀ = P (d ₀ , e ₀ ) using the function P as described above. Further, the processing in steps T05 is performed, as shown in FIG. 10, about the default values d _0, and varies in the range of the transmitting and receiving gap for example ± lambda, or ± (λ / 2), receiving The maximum value of power is detected.

With the above processing, the maximum value of the received power corresponding to the transmission / reception gap d ₁ is detected at the point indicated by reference numeral 32. The transmission / reception gap d ₁ can be expressed, for example, as d ₁ = d ₀ + (λ / 2). The maximum value of the received power changes within a range as indicated by an arrow 33, for example, as the transmitting antenna 21 moves in the horizontal direction. When the maximum value of the received power that changes in this way is expressed as P _1v , this can be expressed as P _1v = P (d ₁ , e _v ) using the function P. Incidentally, e _v represents the lateral position of the transmitting antenna 21 vary in the range of 0 to E.

When the process of step ST07 is executed, so that transmission and reception gap is d _1, transmitting antenna 21 is moved to the position shown by reference numeral 21b in FIG. At this position, the lateral position of the transmitting antenna 21 is changed, and the maximum value of the received power at the maximum value P _1v is detected. Thus, the maximum received power P ₁ is detected in the reception gap d _1, lateral position e ₁ of the transmitting antenna 21 when the reception power P ₁ is obtained is detected. Thereafter, the transmission / reception gap d _max and the lateral position e _max corresponding to the maximum value P _max of the received power are finally determined by the process of step T09, and the transmission antenna 21 is moved to this position by the process of step T11. Thus, power is supplied to the vehicle 10.

  When the control unit 22 performs the power supply control process as described above, the transmission antenna 21 is moved in a direction substantially parallel to the reception surface of the rectenna 11 in the transmission / reception gap where the highest received power is obtained. Can be increased. Therefore, even more efficient power feeding can be performed on the vehicle 10.

According to the fourth embodiment described above, the following operational effects are obtained.
(1) The control unit 22 uses the driving unit 23 to further move the transmission antenna 21 in a substantially parallel direction with respect to the reception surface of the rectenna 11. Since it did in this way, much more efficient electric power feeding can be performed with respect to the vehicle 10. FIG.

-Fifth embodiment-
Next, a fifth embodiment of the present invention will be described. In the present embodiment, an example in which the directivity of the microwave is improved by moving the transmission antenna 21 downward to increase the transmission / reception gap will be described below.

A power supply system using the vehicle power supply device according to the present embodiment is shown in FIG. In this power supply system, the center position of the transmitting antenna 21 is separated from the center of the rectenna 11 by a distance d _c. In such a case, the control unit 22, a transmitting antenna 21 is moved downward by a distance d _v using the driving unit 23. At this time, as sending and receiving gap after movement is equal to any of the aforementioned transceiver gap d ₁ to d _n corresponding to the maximum value of reception power, it is preferable to set the moving distance d _v.

For example, among the receiving gap d ₁ to d _n, the received power in each rectenna element 11e provided in the rectenna 11 is less than the predetermined value, and rectenna 11 transmit and receive gaps maximum received power is detected in the whole d _h And This transceiver gap d _h, by subtracting the default value d _f of the transmitting and receiving gap described above, it is possible to determine the moving distance d _v. Note that the rectenna element 11e represents a rectenna element located at the end of the rectenna 11 closer to the transmission antenna 21.

  If it does as mentioned above, a microwave will be reflected in the reflecting plate provided inside the guide 25, the spread of a microwave will be suppressed, and the directivity of a microwave will improve. Therefore, even if the center position of the transmitting antenna 21 is far away from the center of the rectenna 11, leakage of microwaves outside the rectenna 11 is suppressed, and the power supply efficiency can be improved. Furthermore, it is possible to reduce the adverse effects on the surroundings due to unnecessary microwave leakage and improve the radio wave environment.

According to the fifth embodiment described above, the following operational effects are obtained.
(1) The control unit 22 moves the transmission antenna 21 using the drive unit 23 to increase the transmission / reception gap so that the microwave is reflected on the reflection plate provided inside the guide 25. We decided to improve the directivity of the waves. Since it did in this way, even if it is a case where the center position of the transmitting antenna 21 is large away from the center of the rectenna 11, the power feeding efficiency can be improved.

-Sixth embodiment-
Next, a sixth embodiment of the present invention will be described. In the present embodiment, an example in which the power feeding efficiency is improved without moving the transmitting antenna 21 will be described below.

  A power supply system using the vehicle power supply apparatus according to the present embodiment is shown in FIG. Compared with the power supply system of the first embodiment shown in FIG. 1, this power supply system does not have the drive unit 23 and the guide 25 for moving the transmission antenna 21, but has a signal changing unit 27 instead. The signal changing unit 27 changes at least one of the phase and the frequency of the signal generated from the signal generating unit 24 under the control of the control unit 22. Thereby, the phase or frequency of the microwave transmitted from the transmission antenna 21 changes. Note that only one of the microwave phase and frequency may be changed, or both of them may be changed.

As described above, when the control unit 22 changes the phase or frequency of the microwave transmitted from the transmission antenna 21 using the signal changing unit 27, the microwave transmitted by the transmission antenna 21 is changed according to the change. The phase of the microwave when reaching the rectenna 11 changes. In accordance with the change in phase, the received power obtained by receiving microwaves in the rectenna 11 changes. Therefore, even if the transmission antenna 21 is not moved and the transmission / reception gap is fixed to d _p as shown in the figure, power can be efficiently supplied at the maximum point of the received power as described above.

For example, it is assumed that a phase or frequency at which the phase of the microwave when reaching the rectenna 11 is ± nπ (n is a natural number) is preset in the control unit 22 with respect to the transmission / reception gap d _p . In this case, the control unit 22 controls the signal changing unit 27 so that the phase or frequency of the microwave transmitted from the transmission antenna 21 becomes the set value, and the phase or frequency of the signal generated from the signal generating unit 24 is controlled. At least one of the frequencies is changed. As a result, the received power obtained in the rectenna 11 can be a maximum value.

  Note that the power feeding system illustrated in FIG. 12 may further include a receiving unit 26. In this way, the control unit 22 can detect the received power based on the information from the receiving unit 26. Therefore, even if the phase or frequency of the microwave is not preset in the control unit 22, at least one of the phase or frequency of the microwave can be adjusted so that the maximum received power can be obtained. Further, at this time, as described in the fourth embodiment, the position of the transmission antenna 21 may be moved in the horizontal direction. In this way, more efficient power feeding can be performed.

According to the sixth embodiment described above, the following operational effects are obtained.
(1) The signal generator 24 transmits a signal for transmitting a microwave to the transmission antenna 21. Further, the signal changing unit 27 changes at least one or both of the phase and frequency of the signal. The control unit 22 controls the phase of the microwave by changing at least one or both of the phase and frequency of the signal using the signal changing unit 27. Since it did in this way, electric power feeding efficiency can be improved, without moving the transmission antenna 21. FIG. As a result, a power supply system with high power supply efficiency can be realized with a simple structure while ensuring a degree of design freedom for vehicle requirements such as minimum ground clearance.

In each of the embodiments described above, it is preferable to set the microwave intensity based on predetermined laws and guidelines. For example, before the optimum transmission / reception gap is determined, the microwave may leak out of the rectenna 11, so that the transmission intensity of the microwave is less than 10 W / m ² . After setting the optimum transmission / reception gap, the transmission intensity of the microwave is increased to supply power to the vehicle 10.

  In each of the embodiments described above, the microwave frequency is described as 2.45 GHz. However, the frequency of the radio wave that can be used in the present invention is not limited to this. That is, microwaves with other frequencies can be used, and radio waves other than microwaves can be used. For example, a microwave of 5.8 GHz band may be used.

  Furthermore, in each of the embodiments described above, the vehicle 10 to be supplied with power has been described as an electric vehicle. However, the vehicle 10 is not necessarily an electric vehicle. The present invention is applicable to any system that supplies power to any type of vehicle.

  Among the embodiments described above, in the second to fifth embodiments, the received power information calculated in the drive system 12 is transmitted to the transmitting antenna 21 via the rectenna 11, and the received power An example in which the information transmission system is shared with the power supply system has been described. However, the transmission system of received power information may be different from the power feeding system. Alternatively, the received power may be calculated in the vehicle power supply apparatus by transmitting a radio wave with a predetermined transmission power determined in advance from the rectenna 11 and receiving the radio wave with the transmission antenna 21.

  The above description is merely an example, and when interpreting the invention, there is no limitation or restriction on the correspondence between the items described in the embodiments and the items described in the claims.

It is a figure which shows the electric power feeding system using the electric power feeder for vehicles by 1st embodiment of this invention. It is a figure which shows an example of the experimental result which measured the relationship between the transmission / reception gap and received electric power in the electric power feeding system using the electric power feeder for vehicles by 1st embodiment of this invention. It is a figure which shows the electric power feeding system using the electric power feeder for vehicles by 2nd embodiment of this invention. It is a figure which shows an example of the experimental result which measured the relationship between the transmission / reception gap and received electric power in the electric power feeding system using the electric power feeder for vehicles by 2nd embodiment of this invention. It is a figure which shows the electric power feeding system using the electric power feeder for vehicles by 3rd embodiment of this invention. It is a flowchart of the electric power feeding control process performed in the electric power feeder for vehicles by 3rd embodiment of this invention. It is a figure which shows an example of the experimental result which measured the relationship between the transmission / reception gap and received electric power in the electric power feeding system using the electric power feeder for vehicles by 3rd embodiment of this invention. It is a figure which shows the electric power feeding system using the electric power feeder for vehicles by 4th embodiment of this invention. It is a flowchart of the electric power feeding control process performed in the electric power feeder for vehicles by 4th embodiment of this invention. It is a figure which shows an example of the experimental result which measured the relationship between the transmission / reception gap and received electric power in the electric power feeding system using the vehicle electric power feeder by 4th embodiment of this invention. It is a figure which shows the electric power feeding system using the electric power feeder for vehicles by 5th embodiment of this invention. It is a figure which shows the electric power feeding system using the electric power feeder for vehicles by the 6th Embodiment of this invention.

Explanation of symbols

10: vehicle 11: rectenna 12: drive system 21: transmission antenna 22: control unit 23: drive unit 24: signal generation unit 25: guide 26: reception unit 27: signal change unit

Claims (5)

A vehicle power supply device for supplying power to the vehicle by transmitting radio waves to a receiving means installed in the vehicle,
Transmitting means for transmitting radio waves to the receiving means;
Moving means for moving the transmitting means to change a transmission / reception gap between the transmitting means and the receiving means ;
The transmission means transmits the transmission means by moving the transmission means to a position where the transmission / reception gap between the transmission means and the reception means substantially matches an integral multiple of a half wavelength of the radio wave. Phase control means for controlling the phase of the radio wave when the received radio wave reaches the receiving means ;
By increasing the transmission / reception gap using the moving means so that the radio wave transmitted from the transmitting means is reflected by a reflector provided inside the guide for moving the transmitting means, A vehicle power supply apparatus comprising: directivity improving means for improving directivity . The vehicle power supply device according to claim 1 ,
Further comprising information acquisition means for acquiring received power information obtained by the reception means receiving the radio wave;
The phase control means moves the transmission means to a position where the received power is maximized based on the information acquired by the information acquisition means. The vehicle power supply device according to claim 1 or 2 ,
The phase control means moves the transmission means to a position where the received power is maximized within a range in which a transmission / reception gap between the transmission means and the reception means changes by approximately a half wavelength of the radio wave. A vehicle power supply device. The vehicle power supply device according to claim 1 or 2 ,
The phase control means moves the transmission means to a position where the received power is maximized within a range in which a transmission / reception gap between the transmission means and the reception means changes beyond the wavelength of the radio wave. A vehicle power supply device. In the vehicle electric power feeder as described in any one of Claims 1-4 ,
The vehicle power supply apparatus further comprising: a parallel movement unit that moves the transmission unit in a substantially parallel direction with respect to a reception surface of the reception unit.

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