JP5851731B2 - Electric vehicle charging system and charging method - Google Patents

Description

  The present invention relates to a charging system and a charging method for an electric vehicle.

  In recent years, the development of electric vehicles using electric motors as a power source has become active, and they have been put to practical use.

  Here, an automobile using an electric motor as a power source usually refers to an electric vehicle (Electric Vehicle: EV), and a battery car that obtains electric power from an in-vehicle storage battery and electric power to the outside during traveling It is broadly divided into overhead-line vehicles supplied from However, in this paper, the former type of vehicle that obtains power for running from a storage battery is referred to as an electric vehicle.

  In the above-described electric vehicle, it is possible to drive the vehicle as an automobile by storing electric power in an in-vehicle storage battery. In order to store electric power in the storage battery, it is necessary to charge the storage battery (for example, refer to Patent Document 1).

  Patent Document 1 “Electric Vehicle Charging System” described above includes the following description.

  That is, the charging stand for an electric vehicle (electric vehicle) described in Patent Document 1 includes a power supply unit that supplies electric power to a battery of the electric vehicle and an information input unit that can input charging instruction information. doing. In addition, it has information display means, charge collection means for collecting charges from the user, a storage device, and a computing device. A controller that stores the charging instruction information input from the information input unit, calculates charging reservation information including a scheduled charging start time, a scheduled charging end time, and a charging fee, and sets a usable time of the power supply unit; Have. And a control part displays charge reservation information on an information display means, and after collect | recovering charge charges by a charge collection | recovery means, a power supply means is made usable. As a result, the utilization efficiency of the charging device can be improved, and the initial cost and the operation cost can be suppressed.

  The charging stand described in Patent Document 1 described above has a cable for sending charging power to an electric vehicle (electric vehicle). In other words, in order to send charging power to an electric vehicle, power must be sent by a wired system such as a power cable.

  On the other hand, some have proposed that the electric vehicle can be fed in a non-contact manner (see, for example, Patent Document 2).

  The following description is made in Patent Document 2 “Non-contact power feeding device and electric vehicle” described above.

  That is, it is an electromagnetic induction type non-contact power feeding device, in which a secondary coil on the power receiving side of an electric vehicle is constituted by a plurality of divided coils, and a coil polarity inverting circuit capable of individually switching the polarity of each divided coil is provided. . The controller controls the operation of the coil polarity reversing circuit in accordance with the polarity of the interlinkage magnetic flux interlinking with each of the divided coils constituting the secondary coil when the primary coil on the power supply facility side is energized. Thereby, even when the relative position of the primary coil and the secondary coil changes, it is suppressed that magnetic fluxes having different polarities are linked and canceled in the secondary coil, and the reduction of the total flux linkage is suppressed. And so on. As a result, even when the relative position of the primary coil and the secondary coil changes, the mutual inductance between the coils can be increased to enable efficient power transmission.

JP 2010-028913 (pages 5 to 13 and FIGS. 2 to 16) JP 2010-226889 A (pages 4-12, FIGS. 1-21)

  In the charging station described in Patent Document 1 described above, it is necessary to connect a power cable for sending charging power from the charging station to the electric vehicle. And the contact terminal for connecting with an electric vehicle normally exists in the front-end | tip of an electric power cable. Therefore, there is a problem that there is not necessarily a risk of electric leakage from the power cable or the contact terminal or the risk of power being supplied to places other than the electric vehicle. In addition, there is a problem that due to restrictions such as the length of the power cable, some restrictions are required on the installation position of the charging stand, the stop position of the electric vehicle, and the like.

  In the contactless power supply device described in Patent Document 2 described above, the primary coil on the power supply side is installed on the road surface, and the secondary coil on the power reception side is installed on the bottom of the vehicle body of the electric vehicle. Therefore, there is a problem that a passerby may come into contact with the power supply device installed on the road surface and fall down.

  The present invention has been made to solve the above-described problems. Accordingly, an object of the present invention is to provide a charging system and a charging method for an electric vehicle that can improve the safety of the user of the electric vehicle and improve the degree of freedom of the installation position of the charging system. There is.

  The electric vehicle charging system of the present invention includes power transmission means including a power transmission unit that supplies power using an electromagnetic induction method. In addition, power receiving means for charging the traveling storage battery is provided via a power receiving unit that receives power supplied from the power transmitting unit by electromagnetic induction. Furthermore, a control unit is provided that performs operation control of the power transmission unit and the power reception unit via short-range radio.

  The electric vehicle charging method of the present invention includes a control step of performing operation control of a power feeding operation and a power receiving operation using short-range radio, and a power feeding step of performing the power feeding operation by an electromagnetic induction method. And a charging step of receiving the power supplied by the power supply operation by electromagnetic induction by performing the power reception operation, and charging a storage battery for traveling with the received power.

  ADVANTAGE OF THE INVENTION According to this invention, the improvement of the safety | security of the user of an electric vehicle and the improvement of the freedom degree of the installation position of a charging system can be aimed at.

1 is a block diagram showing a first embodiment of a charging system for an electric vehicle of the present invention. It is a sequence chart explaining operation | movement of this embodiment. It is a block diagram which shows 2nd Embodiment of the charging system of the electric vehicle of this invention.

Next, embodiments of the present invention will be described with reference to the drawings.
[First embodiment]
FIG. 1 is a block diagram showing a first embodiment of an electric vehicle charging system according to the present invention.

  The electric vehicle charging system 10 shown in FIG. 1 includes a home controller unit 100, a power receiving unit 200, and an outdoor power transmission unit 300.

  The in-home controller unit 100 is a controller that is installed in a home such as a house 120 owned by an individual and can be operated by a commercial power source 110, and includes a control unit 101, a wireless unit 102, a display operation unit 103, and a storage unit 104. .

  The control unit 101 includes a central processing unit that controls the overall operation of the in-home controller unit 100 and operates according to a program stored in the storage unit 104. The control unit 101 is connected to the wireless unit 102, the display operation unit 103, and the storage unit 104. Note that the power supplied from the commercial power supply 110 is supplied to the control unit 101, the wireless unit 102, the display operation unit 103, and the storage unit 104 through a wiring (not shown).

  The wireless unit 102 is a high-frequency circuit for performing wireless communication with the outdoor power transmission unit 300 and operates under the control of the control unit 101. In the present embodiment, the wireless unit 102 uses any one of wireless standards for near field communication such as a wireless LAN (Local Area Network), Bluetooth, and ZigBee.

  The display operation unit 103 is a part that controls an interface with the user. The display operation unit 103 displays various kinds of information on an LCD (Liquid Crystal Display) or the like, and inputs key operations using a numeric keypad or function keys. Further, the display operation unit 103 makes a sound through a speaker or the like. The display operation unit 103 displays a charging operation screen and various setting screens under the control of the control unit 101, and outputs system state information and alarm information of the charging system 10 of the electric vehicle by display or sound. . Further, information on the key input operation performed on the display operation unit 103 is notified to the control unit 101. When notified of the key input operation information, the control unit 101 executes an operation according to the key input operation information.

  The storage unit 104 stores a program and setting data for operating the control unit 101, and stores data set by the user, for example, a vehicle ID (Identification) or a password of a vehicle that permits charging. .

  The power receiving unit 200 is incorporated in the electric vehicle 220 to be charged, and is a unit for accumulating charging power in a traveling storage battery 206 that supplies electric power to an electric motor (not shown) that causes the electric vehicle 220 to travel. It is. The power receiving unit 200 includes a control unit 201, a wireless unit 202, a display operation unit 203, a storage unit 204, a power receiving unit 205, a traveling system storage battery 206, and a control system storage battery 210.

  The control unit 201 includes a central processing unit that controls the overall operation of the power receiving unit 200 and operates according to a program stored in the storage unit 204. The control unit 201 is connected to the wireless unit 202, the display operation unit 203, the storage unit 204, the power receiving unit 205, and the traveling system storage battery 206. Note that the control system storage battery 210 is a so-called vehicle battery that supplies power to a necessary part in the electric vehicle 220. The power supplied from the control system storage battery 210 is supplied to the control unit 201, the wireless unit 202, the display operation unit 203, and the storage unit 204 through wiring (not shown).

  The wireless unit 202 is a high-frequency circuit for performing wireless communication with the outdoor power transmission unit 300 and operates under the control of the control unit 201. In the present embodiment, the wireless unit 202 uses any one of wireless standards for near field communication, such as wireless LAN, Bluetooth, ZigBee, RFID (Radio Frequency Identification).

  The display operation unit 203 is a part that controls an interface with a user, displays various information on an LCD or the like, and allows a key operation input by a numeric keypad or a function key. In addition, the display operation unit 203 makes a sound through a speaker or the like. The display operation unit 203 displays a charging operation screen and various setting screens under the control of the control unit 201, and outputs system state information and alarm information of the charging system 10 of the electric vehicle by display or sound. . Further, information on the key input operation performed on the display operation unit 203 is notified to the control unit 201. When notified of the key input operation information, the control unit 201 executes an operation according to the key input operation information.

  The storage unit 204 stores a program and setting data for operating the control unit 201, and stores a vehicle ID and a password of the electric vehicle 220.

  The power reception unit 205 is a device for receiving power using electromagnetic induction that generates an induced current in response to fluctuations in magnetic flux from the outdoor power transmission unit 300 installed outside the electric vehicle 220. Contains. As is well known, electromagnetic induction enables power transmission by using a magnetic field between two coils for power transmission and power reception, and is a wireless power feeding method generally called an electromagnetic induction method. is there. The power receiving unit 205 is controlled to be operated or stopped by the control unit 201, and the traveling storage battery 206 is charged by the electric power generated in the power receiving unit 205.

  The traveling system storage battery 206 is a storage battery that supplies power for operating an electric motor for traveling the electric vehicle 220. The control unit 201 monitors the state such as the remaining charge of the traveling storage battery 206.

  The outdoor power transmission unit 300 is a unit for transmitting charging power to the power receiving unit 200 of the electric vehicle 220, having a protective plate 400 on the upper side and installed in a form embedded under the outdoor ground surface 500. The outdoor power transmission unit 300 includes a control unit 301, a wireless unit 302-1, a wireless unit 302-2, a storage unit 304, a power transmission unit 305, and a protection plate 400.

  The control unit 301 includes a central processing unit that controls the overall operation of the outdoor power transmission unit 300 and operates according to a program stored in the storage unit 304. The control unit 301 is connected to the wireless unit 302-1, the wireless unit 302-2, the storage unit 304, and the power transmission unit 305. Note that the power supplied from the commercial power source 330 is supplied to the control unit 301, the wireless unit 302-1, the wireless unit 302-2, and the storage unit 104 by wiring (not shown). The power transmission unit 305 is directly supplied with power from the commercial power source 330.

  The wireless unit 302-1 is a high-frequency circuit for performing wireless communication with the home controller unit 100, and operates under the control of the control unit 301. The wireless unit 302-1 uses the same wireless standard (one of wireless LAN, Bluetooth, ZigBee, etc.) as the short-range communication wireless standard used by the wireless unit 102 of the home controller unit 100. .

  The wireless unit 302-2 is a high-frequency circuit for performing wireless communication with the power receiving unit 200, and operates under the control of the control unit 301. The wireless unit 302-2 uses the same wireless standard (one of wireless LAN, Bluetooth, ZigBee, RFID, etc.) as the short-range communication wireless standard used by the wireless unit 202 of the power receiving unit 200. To do.

  The storage unit 304 stores a program and setting data for operating the control unit 301.

  The power transmission unit 305 transmits power to the power reception unit 205 of the power reception unit 200 using electromagnetic induction, and generates fluctuations in magnetic flux from the power transmission coil. The power transmission unit 305 is controlled to operate or stop by the control unit 301.

  The protective plate 400 is a plate-like plate for protecting the outdoor power transmission unit 300 installed in a form embedded under the outdoor ground surface 500, and has a locking means so that it cannot be easily removed. Yes. With the protection plate 400, the outdoor power transmission unit 300 can be protected from damage such as deterioration due to rain or ultraviolet rays, damage to equipment caused by getting on a vehicle, destruction of equipment due to mischief, or theft. The protective plate 400 is strong enough to easily pass a magnetic field, hardly generate heat due to electromagnetic induction, and withstand the load of a vehicle or the like so as not to reduce the efficiency of wireless power feeding using an electromagnetic induction method as much as possible. It is desirable to be made of a simple material. Further, it is desirable that a surface treatment for reducing the transmittance of ultraviolet rays is performed. Examples of such a material include, but are not limited to, tempered glass, an acrylic plate, or a cast material manufactured by injecting an acrylic raw material between two sheets of glass and curing. It is not a thing. Further, when it is necessary to further increase the strength of the above material, the protective plate 400 may be reinforced with a metal frame or the like. As a reinforcing method, in addition to the outer peripheral frame of the protection plate 400, a metal frame may be reinforced in a lattice shape.

  Next, the operation of the present embodiment will be described with reference to FIG.

  FIG. 2 is a sequence chart for explaining the operation of the present embodiment. In FIG. 2, components corresponding to those in FIG. 1 are denoted by the same reference numerals or symbols, and description thereof is omitted.

  As a precondition in FIG. 2, it is assumed that the electric vehicle 220 is parked on the upper side of the outdoor power transmission unit 300 as shown in FIG. 1. In addition, it is assumed that the home controller unit 100, the power receiving unit 200, and the outdoor power transmission unit 300 are each turned on and in an operable state.

  In FIG. 2, first, a charge start operation (for example, pressing a charge start key of the display operation unit 103) is performed on the display operation unit 103 of the home controller unit 100 (step S <b> 1 in FIG. 2). Then, the home controller unit 100 transmits a vehicle ID confirmation request to the outdoor power transmission unit 300 (step S2). The vehicle ID confirmation request is transmitted from the wireless unit 102 of the home controller unit 100 to the wireless unit 302-1 of the outdoor power transmission unit 300.

  The outdoor power transmission unit 300 that has received the vehicle ID confirmation request transmits a vehicle ID inquiry to the power receiving unit 200 (step S3). The vehicle ID inquiry is transmitted from the wireless unit 302-2 of the outdoor power transmission unit 300 to the wireless unit 202 of the power receiving unit 200.

  In the following, data transmission / reception between the in-home controller unit 100 and the outdoor power transmission unit 300 is performed between the wireless unit 102 and the wireless unit 302-1. Data transmission / reception between the outdoor power transmission unit 300 and the power reception unit 200 is performed between the wireless unit 302-2 and the wireless unit 202. Therefore, in the following description, description regarding data transmission / reception between the radio units is omitted. In data transmission / reception between wireless units, data encryption processing is performed to prevent information leakage to the outside.

  Receiving the vehicle ID inquiry, the power receiving unit 200 transmits a vehicle ID inquiry response to the outdoor power transmission unit 300 (step S4). The information content of the vehicle ID inquiry response includes at least a vehicle ID and a password set in advance in the storage unit 204 of the power receiving unit 200 of the electric vehicle 220.

  The outdoor power transmission unit 300 that has received the vehicle ID inquiry response transmits a vehicle ID confirmation response to the in-home controller unit 100 (step S5). This vehicle ID confirmation response includes at least the vehicle ID and password information notified from the power receiving unit 200 of the electric vehicle 220.

  The in-home controller unit 100 that has received the vehicle ID confirmation response executes vehicle ID permission determination (step S6). In the vehicle ID permission determination, it is determined whether the vehicle ID / password notified from the power receiving unit 200 via the outdoor power transmission unit 300 matches the vehicle ID / password stored in the storage unit 104 of the in-home controller unit 100. judge. And when both correspond, it determines with the electric vehicle 220 carrying the said power receiving unit 200 being a vehicle which permits charge. When it is determined that the electric vehicle 220 on which the power receiving unit 200 is mounted is a vehicle that permits charging (“permitted” in step S6), the home controller unit 100 transmits a charging start request to the outdoor power transmission unit 300. (Step S7). On the other hand, when it is determined that the electric vehicle 220 on which the power receiving unit 200 is mounted is not a vehicle that permits charging (“not permitted” in step S6), the in-home controller unit 100 ends its operation.

  In addition, in the case where the charging of an arbitrary vehicle is permitted according to the intention of the user who operates the home controller unit 100, the procedure for determining the vehicle ID permission from step S2 to step S6 can be omitted. To do. In this case, it is assumed that the procedure from the transmission of the charge start request in step S7 is executed by the user's operation from the display operation unit 103 of the home controller unit 100.

  The outdoor power transmission unit 300 that has received the charge start request transmits a charge start notification to the power receiving unit 200 (step S8).

  Receiving the charging start notification, the power receiving unit 200 transmits a charging start response to the outdoor power transmission unit 300 (step S9). Then, the power receiving unit 200 shifts to a charging start standby state (step S10). The charging start standby state in the power receiving unit 200 refers to a state in which the charging function for the power receiving unit 205 and the traveling storage battery 206 is controlled to be in an effective state by the control of the control unit 201. And if power transmission is started from the power transmission part 305 of the outdoor power transmission unit 300, the traveling storage battery 206 is charged. At this time, the display operation unit 203 of the power receiving unit 200 displays a message and a sound for notifying the user that the charging start standby state has been entered.

  The outdoor power transmission unit 300 that has received the charging start response starts power transmission from the power transmission unit 305 (step S11). Then, the outdoor power transmission unit 300 transmits a charge start response to the home controller unit 100 (step S12). In the power receiving unit 200, the power receiving unit 205 starts receiving power, and charging of the traveling system storage battery 206 is started (step S13).

  The in-home controller unit 100 that has received the charge start response performs message display and sounding to notify the user that charging has been started in the display operation unit 103 (step S14).

  When charging of the traveling storage battery 206 by the power receiving unit 200 is started, the outdoor power transmission unit 300 periodically transmits a charge state inquiry to the power receiving unit 200 (step S15). When receiving the charge state inquiry, the power receiving unit 200 transmits information on the charge state of the traveling storage battery 206 to the outdoor power transmission unit 300 as a charge state response (step S16). The charging state response includes at least information on the vehicle ID, the charging state (whether or not the charging operation is normally performed), and the remaining battery level of the traveling storage battery 206. Each of these pieces of information is collected by the control unit 201 of the power receiving unit 200. The vehicle ID information is read from the storage unit 204, and the charging state information is obtained as a result of determining whether the charging current value from the power receiving unit 205 to the traveling storage battery 206 is within a predetermined normal range. Further, the remaining battery information is obtained as the remaining battery capacity of the traveling storage battery 206. The remaining battery level is calculated by the control unit 201 using the measured voltage value of the traveling storage battery 206, the voltage level stored in the storage unit 204, and the characteristic curve data of the remaining battery level.

  The outdoor power transmission unit 300 that has received the charge state response transmits a charge state notification to the home controller unit 100 (step S17).

  The in-home controller unit 100 that has received the charging state notification starts displaying the charging operation state for notifying the user in the display operation unit 103 (step S18). The display content of the charging operation state includes at least information on the vehicle ID, the charging state (whether the charging operation is normally performed), the remaining battery level of the traveling storage battery 206, and the scheduled charging completion time. Here, the scheduled charging completion time is calculated by the control unit 101 of the home controller unit 100. The scheduled charging completion time is calculated from the power transmission capability of the outdoor power transmission unit 300 that has been obtained in advance through experiments or the like, and information on the remaining battery level of the traveling storage battery 206 received from the power receiving unit 200.

  As described above, the outdoor power transmission unit 300 periodically transmits a charge state inquiry to the power receiving unit 200 while the power receiving unit 200 continues to charge the traveling storage battery 206 (step S19). When receiving the charge state inquiry, the power receiving unit 200 transmits information on the charge state of the traveling storage battery 206 to the outdoor power transmission unit 300 as a charge state response (step S20). The outdoor power transmission unit 300 that has received the charge state response transmits a charge state notification to the home controller unit 100 (step S21). The operations in steps S19 to S21 are the same as the operations in steps S15 to S17 described above.

  The in-home controller unit 100 that has received the charging state notification in step S21 updates the display of the charging operation state in the display operation unit 103 (step S22). Note that, in the electric vehicle charging system 10 of the present embodiment, wireless power feeding using an electromagnetic induction method is adopted as the power transmission method, and therefore the power transmission efficiency varies depending on the positional relationship between the power transmission unit 305 and the power reception unit 205. For this reason, the scheduled charging completion time is sequentially recalculated during charging, and the display on the display operation unit 103 is updated.

  Thereafter, it is assumed that charging of traveling system storage battery 206 by power receiving unit 200 is continued and charging of traveling system storage battery 206 is completed, that is, the charging amount of traveling system storage battery 206 is 100% (full charge).

  Here, when the charge state inquiry several times is transmitted from the outdoor power transmission unit 300 to the power reception unit 200 (step S30), the power reception unit 200 sends a charge state response to the outdoor power transmission unit 300 as before. (Step S31). However, the charging state response in this case includes information indicating that the vehicle ID, the charging state, and the remaining battery level of the traveling storage battery 206 have reached 100% (fully charged).

  When the outdoor power transmission unit 300 receives the charge state response (full charge) in step S31 from the power receiving unit 200, the outdoor power transmission unit 300 transmits a charge state notification (full charge) to the home controller unit 100 (step S32).

  When the home controller unit 100 receives the charge state notification (full charge), it transmits a charge stop request to the outdoor power transmission unit 300 (step S33).

  When receiving the charge stop request, the outdoor power transmission unit 300 transmits a charge stop notification to the power receiving unit 200 (step S34).

  The power receiving unit 200 that has received the charge stop notification transmits a charge stop response to the outdoor power transmission unit 300 (step S35). Then, the power reception unit 200 shifts to a power reception stop state (step S36). The power receiving stop state in the power receiving unit 200 indicates a state in which the charging function for the power receiving unit 205 and the traveling storage battery 206 is controlled to be in an invalid state by the control of the control unit 201. Thereby, even if it is a case where it is a case where it transmits from the power transmission part 305 of the outdoor power transmission unit 300, the charge to the traveling type storage battery 206 is not made. In addition, the display operation unit 203 of the power receiving unit 200 displays a message and a sound for notifying the user that the power receiving stop state has been entered.

  The outdoor power transmission unit 300 that has received the charge stop response stops power transmission from the power transmission unit 305 (step S37). Then, the outdoor power transmission unit 300 transmits a charge stop response to the home controller unit 100 (step S38).

  Upon receipt of the charge stop response, the home controller unit 100 displays a message and a sound for notifying the user that charging has been completed in the display operation unit 103 (step S39). Then, the home controller unit 100 ends the operation.

  The operation of this embodiment has been described above.

  In the above-described operation, the case where charging is performed until the remaining battery level of the traveling storage battery 206 of the power receiving unit 200 reaches 100% (full charge) is shown, but according to the intention of the user operating the home controller unit 100, It is also possible to stop the charging operation with an arbitrary remaining battery level. When this operation is performed, the charging start operation in step S1 is performed after the user sets the remaining battery level to stop charging in the display operation unit 103 of the home controller unit 100 in advance. For example, when it is notified by the charge state notification in step S21 that the set remaining battery level has been reached, the home controller unit 100 immediately transmits the charge stop request shown in step S33 to the outdoor power transmission unit 300. do it.

  Moreover, this embodiment demonstrated as what charges the traveling system storage battery 206 of the electric vehicle 220 which uses an electric motor as a power source using an electromagnetic induction system. However, the present embodiment can also be used to charge a traveling system storage battery of a so-called hybrid vehicle that uses an electric motor and an engine (such as a gasoline engine or diesel engine) as power sources.

  The first embodiment of the present invention has been described above.

  As described above, the electric vehicle charging system 10 of the present invention includes power transmission means (outdoor power transmission unit 300) including a power transmission unit (power transmission unit 305) that supplies power using an electromagnetic induction method. In addition, power receiving means (power receiving unit 200) for charging a storage battery for traveling (traveling storage battery 206) via a power receiving unit (power receiving unit 205) that receives power fed from the power transmitting unit by electromagnetic induction is provided. . Furthermore, a control unit (in-home controller unit 100) that performs operation control of the power transmission unit and the power reception unit via short-range wireless is provided.

  In other words, the electric vehicle charging system 10 of the present invention does not include a power cable for charging a running storage battery and a contact terminal to the electric vehicle. In addition, since transmission / reception of data between the control means and the power transmission means is performed by short-range wireless communication, there is no restriction on the installation position of the power transmission means.

  Therefore, according to this embodiment, it is possible to improve the safety of the user of the electric vehicle and improve the degree of freedom of the installation position of the charging system.

  Further, in the electric vehicle charging system 10 according to the present invention, the power transmission means is installed below the outdoor ground surface (ground surface 500) and below the protective plate (protective plate 400) having locking means. doing. The power receiving means is installed in an electric vehicle (electric vehicle 220), and the control means is installed in a house such as a privately owned house (house 120).

  Therefore, the power transmission means can be protected from deterioration due to the influence of water leakage or the influence of ultraviolet rays or the like outdoors. Further, it is possible to prevent the power transmission means from being damaged by mischief or the like, or from being stolen. Furthermore, it is possible to prevent a user or a passerby from coming into contact with the power transmission means and falling down. Furthermore, since the control means is installed in the house, it is not necessary for the user to go to a charging stand or the like, and the convenience for the user can be improved.

  Further, the control means of the electric vehicle charging system 10 of the present invention is configured so that when the vehicle ID and password acquired from the power receiving means match the vehicle ID and password stored therein, the control means from the power transmission means. Power is supplied to the power receiving means.

Therefore, unauthorized use of the power transmission means can be prevented, and security of the power transmission means can be improved.
[Second Embodiment]
Next, a second embodiment of the present invention will be described with reference to FIG.

  FIG. 3 is a block diagram showing a second embodiment of the electric vehicle charging system of the present invention. In FIG. 3, components corresponding to those in FIG. 1 are denoted by the same reference numerals or symbols, and description thereof is omitted as much as possible.

  The electric vehicle charging system 10-1 shown in FIG. 3 includes a home controller unit 100-1, a power receiving unit 200-1, and an outdoor power transmission unit 300-1.

  The in-home controller unit 100-1 is a controller that is installed in a home such as a house 120 owned by an individual and can be operated by a commercial power source 110, and includes a control unit 101-1, a wireless unit 102, a display operation unit 103, and a storage unit 104. Is included. The controller 101-1 of the home controller unit 100-1 is connected to a telephone line 115 of the public network via a modem 114.

  The control unit 101-1 includes a central processing unit that controls the overall operation of the home controller unit 100-1 and operates according to a program stored in the storage unit 104. The control unit 101-1 is connected to the wireless unit 102, the display operation unit 103, and the storage unit 104. Further, the control unit 101-1 can receive an instruction or an inquiry from a remote cellular phone or the like via the telephone line 115. The power supplied from the commercial power supply 110 is supplied to the modem 114 and is also supplied to the control unit 101-1, the wireless unit 102, the display operation unit 103, and the storage unit 104 through wiring (not shown). Yes.

  Since the wireless unit 102, the display operation unit 103, and the storage unit 104 are the same as those in the first embodiment, further description is omitted.

  Similarly to the first embodiment, the power receiving unit 200-1 is incorporated in the electric vehicle 220 on the charging side and supplies electric power to an electric motor (not shown) that runs the electric vehicle 220. 206 is a unit for accumulating charging power. The power receiving unit 200-1 includes a control unit 201-1, a wireless unit 202, a display operation unit 203, a storage unit 204, a power receiving unit 205, a traveling system storage battery 206, a control system storage battery 210, and a remote starter control unit 207. Yes.

  The control unit 201-1 includes a central processing unit that controls the overall operation of the power receiving unit 200-1 and operates according to a program stored in the storage unit 204. The control unit 201-1 is connected to the wireless unit 202, the display operation unit 203, the storage unit 204, the power receiving unit 205, the traveling system storage battery 206, and the remote starter control unit 207. Note that the control system storage battery 210 is a so-called vehicle battery that supplies power to a necessary part in the electric vehicle 220. The power supplied from the control system storage battery 210 is supplied to the control unit 201-1, the wireless unit 202, the display operation unit 203, the storage unit 204, and the remote starter control unit 207 through a wiring (not shown). Yes.

  Since the wireless unit 202, the display operation unit 203, the storage unit 204, the power receiving unit 205, and the traveling storage battery 206 are the same as those in the first embodiment, further description is omitted.

  The remote starter control unit 207 is a control unit that starts and stops the electric motor of the electric vehicle 220 by remote control. Here, it is assumed that the remote control instruction is input from the display operation unit 103 of the home controller unit 100-1. And the instruction | indication of remote control is notified to the power receiving unit 200-1 from the indoor controller unit 100-1 via the outdoor power transmission unit 300-1, and the remote starter control unit from the control unit 201-1 of the power receiving unit 200-1 207 is notified.

  Similar to the first embodiment, the outdoor power transmission unit 300-1 has a protective plate 400 on the upper side and is installed in a form of being embedded under the outdoor ground surface 500, to the power receiving unit 200-1 of the electric vehicle 220. A unit for transmitting charging power. The outdoor power transmission unit 300-1 includes a control unit 301-1, a wireless unit 302-1, a wireless unit 302-2, a storage unit 304, a power transmission unit 305, a conversion unit 306, a power transmission system storage battery 307, a control circuit 308, and a control system storage battery. 309, the control circuit 310, the sensor part 311 and the protection plate 400 are included.

  And the power supply with respect to the outdoor power transmission unit 300-1 is supplied from the solar power generation part 320 installed on the roof of the house 120. FIG. The power supplied from the solar power generation unit 320 is charged to the power transmission storage battery 307 via the control circuit 308 and charged to the control storage battery 309 via the control circuit 310. The control circuit 308 monitors the charging state of the power transmission storage battery 307, that is, whether or not it is fully charged, and controls to charge the power transmission storage battery 307 if it is not fully charged. The charging of the power transmission storage battery 307 is stopped. The control circuit 310 monitors the state of charge of the control system storage battery 309, that is, whether or not it is fully charged, and controls the control system storage battery 309 to be charged if it is not fully charged. The charging of the control system storage battery 309 is stopped. Note that the solar power generation unit 320 lays out a solar power generation panel that generates electricity from sunlight, and is installed not only on the roof of the house 120 but also in the outdoor power transmission unit 300-1. Good.

  The control unit 301-1 includes a central processing unit that controls the overall operation of the outdoor power transmission unit 300-1 and operates according to a program stored in the storage unit 304. The control unit 301-1 is connected to the wireless unit 302-1, the wireless unit 302-2, the storage unit 304, the power transmission unit 305, and the sensor unit 311. Note that power is supplied to the control unit 301-1, the wireless unit 302-1, the wireless unit 302-2, the storage unit 104, and the sensor unit 311 from the control system storage battery 309 through wiring (not shown). Yes. The power transmission unit 305 is supplied with power from the power transmission storage battery 307. When the power transmission unit 305 transmits power to the power reception unit 205 of the power reception unit 200-1, the power supplied from the power transmission storage battery 307 is converted into alternating current by the conversion unit 306 and supplied. It has become.

  Since the wireless unit 302-1, the wireless unit 302-2, the storage unit 304, the power transmission unit 305, and the protection plate 400 are the same as those in the first embodiment, further description is omitted.

  The sensor unit 311 is a sensor that detects and determines whether or not the electric vehicle 220 is parked above the outdoor power transmission unit 300-1, and notifies the control unit 301-1 of the determination result, that is, the presence or absence of parking. To do. The sensor unit 311 may be configured by an optical sensor, for example. The optical sensor is a sensor that determines that an object or the like has entered the detection area when the near-infrared ray is irradiated and the amount of reflected light of the near-infrared ray changes in the increasing direction.

  The configuration of the second embodiment has been described above.

  Next, the operation of this embodiment will be described.

  First, in this embodiment, an operation when charging the traveling storage battery 206 of the electric vehicle 220 will be described.

  As described with reference to FIG. 3, the present embodiment is different from the first embodiment only in the following points.

  That is, first, the home controller unit 100-1 is connected to the telephone line 115 of the public network via the modem 114.

  Secondly, the power receiving unit 200-1 newly includes a remote starter control unit 207.

  Thirdly, the power of the outdoor power transmission unit 300-1 is supplied from the solar power generation unit 320, not the commercial power (first embodiment). Then, the power supplied from the photovoltaic power generation unit 320 is charged and accumulated in the power transmission storage battery 307 and the control storage battery 309. In addition, the outdoor power transmission unit 300-1 newly includes a sensor unit 311.

  And the mechanism for charging the traveling storage battery 206 of the electric vehicle 220 has not changed.

  Therefore, in the present embodiment, the operation when charging the traveling storage battery 206 of the electric vehicle 220 is the same as the operation of the first embodiment described in FIG. Therefore, further explanation regarding the operation when charging the traveling storage battery 206 of the electric vehicle 220 in this embodiment will be omitted.

  Next, in the present embodiment, an operation for automatically starting charging of the traveling storage battery 206 of the electric vehicle 220 will be described.

  The outdoor power transmission unit 300-1 of this embodiment includes a sensor unit 311. When the electric vehicle 220 is parked on the upper part of the outdoor power transmission unit 300-1, the sensor unit 311 notifies the control unit 301-1 to that effect.

  Therefore, in this embodiment, when the control unit 301-1 of the outdoor power transmission unit 300-1 receives a notification that the electric vehicle 220 is parked on the upper part of the outdoor power transmission unit 300-1, the parking notification is sent to the home. It transmits to the controller unit 100-1. The in-home controller unit 100-1 that has received the parking notification operates in the same manner as the charge start operation (step S1 in FIG. 2) of the first embodiment described in FIG. That is, in the present embodiment, the charging start operation is not performed when the parking notification is received from the outdoor power transmission unit 300-1 instead of performing the charging start operation in the display operation unit 103 of the home controller unit 100-1. The same operation as that performed is performed. The operations after step S2 described in FIG. 2 are executed in the same manner as in the first embodiment.

  As a result, charging of the traveling system storage battery 206 of the electric vehicle 220 is automatically started.

  Next, in this embodiment, an operation when monitoring whether or not the electric vehicle 220 is parked on the upper part of the outdoor power transmission unit 300-1 from a remote place other than the home by a mobile phone or the like will be described.

  The home controller unit 100-1 of this embodiment is connected to a telephone line 115 of a public network via a modem 114. Then, the control unit 101-1 of the home controller unit 100-1 can receive an instruction or an inquiry from a remote cellular phone or the like via the telephone line 115. The outdoor power transmission unit 300-1 includes the sensor unit 311 as described above. And if the electric vehicle 220 parks on the upper part of the outdoor power transmission unit 300-1, the sensor part 311 will transmit a parking notification to the indoor controller unit 100-1 via the control part 301-1.

  Therefore, in the present embodiment, when the control unit 101-1 of the home controller unit 100-1 receives an inquiry from a remote mobile phone or the like via the telephone line 115, it operates as follows. ing.

  That is, when the content of the inquiry is whether or not the electric vehicle 220 is parked at the top of the outdoor power transmission unit 300-1, the control unit 101-1 of the home controller unit 100-1 It is determined whether or not a parking notification is received. When the parking notification is received, the home controller unit 100-1 returns a response to the inquiry source mobile phone or the like that the electric vehicle 220 is parked on the upper part of the outdoor power transmission unit 300-1. Works like this. On the other hand, when the parking notification is not received, the home controller unit 100-1 returns a response that the electric vehicle 220 is not parked on the upper part of the outdoor power transmission unit 300-1 to the inquiring mobile phone or the like. Works like this.

  As a result, whether or not the electric vehicle 220 is parked on the upper part of the outdoor power transmission unit 300-1 can be monitored from a remote place other than the home by a mobile phone or the like.

  It should be noted that the operation for responding to the inquiry from the above-described remote cellular phone or the like can be changed as follows.

  First, when there is an inquiry about the state of charge of the traveling system storage battery 206 of the electric vehicle 220 from a mobile phone or the like at a remote location, the home controller unit 100-1 operates as follows. That is, the in-home controller unit 100-1 makes an inquiry about the state of charge of the traveling storage battery 206 to the power receiving unit 200-1 of the electric vehicle 220 via the outdoor power transmission unit 300-1. From the power receiving unit 200-1, the state of charge of the traveling storage battery 206 is transmitted to the home controller unit 100-1 via the outdoor power transmission unit 300-1. Then, the home controller unit 100-1 operates to return the information on the state of charge of the traveling storage battery 206 as a response to the inquiry source mobile phone or the like.

  As a result, the state of charge of the traveling storage battery 206 of the electric vehicle 220 can be monitored by a mobile phone or the like from a remote place other than home.

  Second, when an instruction for starting charging of the traveling storage battery 206 of the electric vehicle 220 is given from a remote mobile phone or the like, the in-home controller unit 100-1 operates as follows. That is, the home controller unit 100-1 operates in the same manner as the charge start operation (step S1 in FIG. 2) of the first embodiment described in FIG. That is, an instruction for starting charging of the traveling storage battery 206 of the electric vehicle 220 is issued from a remote mobile phone or the like instead of performing an operation of starting charging at the display operation unit 103 of the home controller unit 100-1. If there is, the same operation as the operation for starting charging is performed. The operations after step S2 described in FIG. 2 are executed in the same manner as in the first embodiment.

  As a result, charging of the traveling storage battery 206 of the electric vehicle 220 is started by an instruction from a remote mobile phone or the like.

  Next, in this embodiment, an operation when starting the electric motor of the electric vehicle 220 from the outside of the electric vehicle 220 will be described.

  The power receiving unit 200-1 of the electric vehicle 220 according to this embodiment includes a remote starter control unit 207.

  Therefore, in this embodiment, when an instruction for starting the electric motor of the electric vehicle 220 is input from the display operation unit 103 of the in-home controller unit 100-1 by a key operation or the like, the following operation is performed. Yes.

  That is, the start instruction input from the display operation unit 103 is notified to the control unit 101-1 of the home controller unit 100-1. Then, the start instruction is transmitted from the home controller unit 100-1 to the power receiving unit 200-1 via the outdoor power transmission unit 300-1. The start instruction is notified to the control unit 201-1 of the power receiving unit 200-1, and is notified from the control unit 201-1 to the remote starter control unit 207. The remote starter control unit 207 starts the electric motor of the electric vehicle 220.

  As a result, the electric motor of the electric vehicle 220 can be started from the outside of the electric vehicle 220.

  The above-described remote starter control operation of the electric motor may be replaced with other control operations, such as locking and unlocking the door of the electric vehicle 220, or turning on and off the interior light. In this case, the remote starter control unit 207 of the power receiving unit 200-1 may be replaced with a door lock control unit or an interior light control unit.

  Next, in this embodiment, an operation when the traveling storage battery 206 of the electric vehicle 220 is refreshed will be described. The refreshing means that the traveling system storage battery 206 is sufficiently discharged and then recharged, and the refreshing makes it possible to extend the life of the traveling system storage battery 206.

  In order to perform the refresh of the travel system storage battery 206, in the present embodiment, when an instruction for refreshing the travel system storage battery 206 is input from the display operation unit 103 of the in-home controller unit 100-1 by a key operation or the like, Like to work.

  That is, the refresh instruction input from the display operation unit 103 is notified to the control unit 101-1 of the home controller unit 100-1. Then, the refresh instruction is transmitted from the home controller unit 100-1 to the power receiving unit 200-1 via the outdoor power transmitting unit 300-1. The refresh instruction is notified to the control unit 201-1 of the power receiving unit 200-1. The control unit 201-1 causes the traveling storage battery 206 to discharge. And the control part 201-1 monitors whether the traveling type storage battery 206 was fully discharged.

  When the control unit 201-1 determines that the traveling-system storage battery 206 has been sufficiently discharged, the power receiving unit 200-1 sends a discharge completion notification via the outdoor power transmission unit 300-1 to the home controller unit 100-1. Send to.

  The in-home controller unit 100-1 that has received the discharge completion notification next charges the traveling storage battery 206 of the power receiving unit 200-1. As in the case of FIG. 2 (first embodiment), charging of the traveling storage battery 206 is performed by the display operation unit 103 of the home controller unit 100-1 (step S1 in FIG. 2). ) To start charging.

  As a result, the traveling storage battery 206 of the electric vehicle 220 can be refreshed.

  Note that the above-described refresh operation of the traveling storage battery 206 may be automatically started by the control unit 101-1 of the home controller unit 100-1. That is, the home controller unit 100-1 stores the number of times the traveling system storage battery 206 is charged or the use start date and time of the traveling system storage battery 206 in the storage unit 104. Then, the control unit 101-1 of the home controller unit 100-1 periodically checks the number of times the traveling system storage battery 206 is charged or the use start date and time. As a result of the check, when the number of times of charging reaches a predetermined number of times, or when it is determined that a predetermined period has elapsed from the use start date and time of the traveling system storage battery 206, an operation of refreshing the traveling system storage battery 206 is started. These operations of the control unit 101-1 may be executed by a program stored in the storage unit 104.

  The operation of this embodiment has been described above.

  In the above-described second embodiment, the number of outdoor power transmission units 300-1 is described as one. However, a plurality of outdoor power transmission units 300-1 may be installed. When installing a plurality of outdoor power transmission units 300-1, a unique outdoor power transmission unit ID is assigned to each outdoor power transmission unit 300-1. When data transmission / reception is performed between the outdoor power transmission unit 300-1 and the home controller unit 100-1, an outdoor power transmission unit ID for indicating a data transmission source or transmission destination is attached to the header area of the data to be transmitted / received. You can do it.

  Moreover, you may make it comprise the in-home controller unit 100-1 in 2nd Embodiment mentioned above with a general personal computer. In this case, the program for executing the operation of the second embodiment described above may be installed as an application program for a personal computer. By configuring in this way, it becomes possible to easily modify or add the function of the charging system 10-1 of the electric vehicle by modifying or adding the application program. In addition, the cost of the electric vehicle charging system 10-1 can be reduced.

  The second embodiment has been described above.

  As described above, the configuration of the second embodiment of the present invention differs from the electric vehicle charging system 10 of the first embodiment shown in FIG. 1 only in the following points.

  That is, first, the home controller unit 100-1 is connected to the telephone line 115 of the public network via the modem 114.

  Secondly, the power receiving unit 200-1 newly includes a remote starter control unit 207.

  Thirdly, the power of the outdoor power transmission unit 300-1 is supplied from the solar power generation unit 320, not the commercial power (first embodiment). Then, the power supplied from the photovoltaic power generation unit 320 is charged and accumulated in the power transmission storage battery 307 and the control storage battery 309. In addition, the outdoor power transmission unit 300-1 newly includes a sensor unit 311.

  The operation of the second embodiment differs from the operation of the first embodiment only in the following points.

  That is, it is possible to refresh the traveling storage battery 206 in the power receiving unit 200-1 of the electric vehicle 220 by inputting a refresh instruction to the home controller unit 100-1.

  Therefore, only the parts peculiar to the second embodiment will be described below.

  As described above, the electric vehicle charging system 10-1 of the present embodiment includes power transmission means (outdoor power transmission unit 300-1) including a power transmission unit (power transmission unit 305) that supplies power using an electromagnetic induction method. ing. In addition, power receiving means (power receiving unit 200-1) for charging a traveling storage battery (traveling storage battery 206) via a power receiving unit (power receiving unit 205) that receives power supplied from the power transmitting unit by electromagnetic induction is provided. ing. Furthermore, the control part (home controller unit 100-1) which performs operation | movement control of the said power transmission means and the said power receiving means via near field radio | wireless is provided. Furthermore, the power source of the power transmission means is obtained from a solar power generation unit (solar power generation unit 320).

  Therefore, according to the present embodiment, it is possible to install the power transmission means even in a place where it is difficult to obtain a power supply from a commercial power supply, and it is possible to improve the degree of freedom of the installation position of the charging system.

  The power transmission means includes a sensor (sensor unit 311) capable of detecting whether or not a vehicle is parked on the power transmission means. When the control means receives a notification from the power transmission means that the vehicle is parked, the control means automatically starts charging the storage battery for traveling of the power reception means.

  Therefore, according to this embodiment, it is possible to improve the convenience of the user of the electric vehicle.

  Further, the control means is connected to connection means (modem 114) for connecting to a telephone line (telephone line 115). When the control means receives an inquiry or instruction from a remote cellular phone or the like via the connection means, it responds to the inquiry or executes an operation corresponding to the instruction. ing.

  Therefore, according to this embodiment, it is possible to improve the convenience of the user of the electric vehicle.

  Further, the power receiving means includes second control means (such as a remote starter control unit 207) for controlling a vehicle on which the power receiving means is mounted from outside the vehicle. The power receiving means controls the vehicle by operating the second control means when receiving an instruction to control from outside the vehicle from the control means.

  Therefore, according to this embodiment, it is possible to improve the convenience of the user of the electric vehicle.

In addition, although a part or all of said embodiment can be described also as the following additional remarks, it is not restricted to the following.
(Appendix 1)
A power transmission means including a power transmission unit for supplying power using an electromagnetic induction method;
A power receiving means for charging a traveling storage battery via a power receiving section that receives power fed from the power transmitting section by electromagnetic induction;
Control means for performing operation control of the power transmission means and the power reception means via short-range wireless;
An electric vehicle charging system comprising:
(Appendix 2)
The power transmission means is installed on the lower side of the outdoor ground surface and on the lower side of a protective plate having locking means,
The power receiving means is installed in an electric vehicle,
Installing the control means in a house such as a privately owned house,
The charging system for an electric vehicle according to Supplementary Note 1, wherein
(Appendix 3)
The control means, when the vehicle ID and password acquired from the power receiving means match the vehicle ID and password stored in itself, causes the power transmission means to supply power to the power receiving means.
The charging system for an electric vehicle according to any one of Supplementary Note 1 and Supplementary Note 2, wherein
(Appendix 4)
The power source of the power transmission means is obtained from a solar power generation unit.
The charging system for an electric vehicle according to any one of Supplementary Note 1 to Supplementary Note 3, wherein:
(Appendix 5)
The power transmission means includes a sensor capable of detecting whether a vehicle is parked on the power transmission means,
When the control means receives a notification from the power transmission means that the vehicle is parked, the control means automatically starts charging the storage battery for traveling of the power reception means.
The charging system for an electric vehicle according to any one of Supplementary Note 1 to Supplementary Note 4, wherein:
(Appendix 6)
The control means is connected to connection means for connecting to a telephone line,
The control means, when receiving an inquiry or instruction from a remote mobile phone or the like via the connection means, responds to the inquiry or executes an operation corresponding to the instruction.
The charging system for an electric vehicle according to any one of Supplementary Note 1 to Supplementary Note 5, wherein:
(Appendix 7)
The power receiving means includes second control means for controlling a vehicle equipped with the power receiving means from outside the vehicle,
The power receiving means controls the vehicle by operating the second control means when receiving an instruction to control from outside the vehicle from the control means;
The charging system for an electric vehicle according to any one of Supplementary Note 1 to Supplementary Note 6, wherein:
(Appendix 8)
The instruction to control from outside the vehicle is an instruction for causing the storage battery for refreshing to be refreshed.
The charging system for an electric vehicle according to any one of appendix 1 to appendix 7, wherein
(Appendix 9)
The control means is composed of a personal computer.
The charging system for an electric vehicle according to any one of Supplementary Note 1 to Supplementary Note 8, wherein:
(Appendix 10)
A control step of performing operation control of power feeding operation and power receiving operation using short-range wireless;
A power feeding step for performing the power feeding operation by an electromagnetic induction method;
A charging step of receiving the power supplied by the power supply operation by electromagnetic induction by performing the power reception operation, and charging a storage battery for traveling with the received power;
A method for charging an electric vehicle, comprising:
(Appendix 11)
When the vehicle ID and password obtained from the electric vehicle satisfy a predetermined condition,
Performing the control step, the power feeding step and the charging step;
The charging method of the electric vehicle according to appendix 10, wherein
(Appendix 12)
When the electric vehicle is parked at a predetermined position,
Performing the control step, the power feeding step and the charging step;
The charging method for an electric vehicle according to any one of Supplementary Note 10 and Supplementary Note 11, wherein
(Appendix 13)
Further performing a refresh step of refreshing the battery for traveling of the electric vehicle;
The charging method for an electric vehicle according to any one of Supplementary Note 10 to Supplementary Note 12, wherein

DESCRIPTION OF SYMBOLS 10 Charging system of electric vehicle 10-1 Charging system of electric vehicle 100 Home controller unit 100-1 Home controller unit 101 Control unit 101-1 Control unit 102 Wireless unit 103 Display operation unit 104 Storage unit 110 Commercial power supply 114 Modem 115 Telephone line DESCRIPTION OF SYMBOLS 120 House 200 Power receiving unit 200-1 Power receiving unit 201 Control part 201-1 Control part 202 Radio | wireless part 203 Display operation part 204 Memory | storage part 205 Power receiving part 206 Traveling system storage battery 207 Remote starter control part 210 Control system storage battery 220 Electric vehicle 300 Outdoor power transmission Unit 300-1 Outdoor power transmission unit 301 Control unit 301-1 Control unit 302-1 Radio unit 302-2 Radio unit 304 Storage unit 305 Power transmission unit 306 Conversion unit 307 Power transmission storage battery 308 Control circuit 09 control system battery 310 control circuit 311 sensor unit 320 solar power generator 330 commercial power supply 400 protective plate 500 ground surface

Claims (10)

A power transmission means including a power transmission unit that is installed on the lower side of the ground surface and the lower side of the protective plate and that feeds power using an electromagnetic induction method;
A power receiving means for charging a storage battery for traveling through a power receiving section that receives power fed from the power transmitting section by electromagnetic induction;
Refresh means for sufficiently discharging the storage battery before the charging;
Control means for performing operation control of the power transmission means, the power reception means, and the refresh means via short-range wireless;
An electric vehicle charging system comprising: The power transmission means is installed on the lower side of the outdoor ground surface and on the lower side of a protective plate having locking means,
The power receiving means is installed in an electric vehicle,
Installing the control means in a house such as a privately owned house,
The charging system for an electric vehicle according to claim 1. The control means, when the vehicle ID and password acquired from the power receiving means match the vehicle ID and password stored in itself, causes the power transmission means to supply power to the power receiving means.
The charging system for an electric vehicle according to claim 1, wherein the charging system is an electric vehicle. The power source of the power transmission means is obtained from a solar power generation unit.
The charging system for an electric vehicle according to any one of claims 1 to 3, wherein: The power transmission means includes a sensor capable of detecting whether a vehicle is parked on the power transmission means,
When the control means receives a notification from the power transmission means that the vehicle is parked, the control means automatically starts charging the storage battery for traveling of the power reception means.
The charging system for an electric vehicle according to any one of claims 1 to 4, wherein the charging system is an electric vehicle. The control means is connected to connection means for connecting to a telephone line,
The control means, when receiving an inquiry or instruction from a remote mobile phone or the like via the connection means, responds to the inquiry or executes an operation corresponding to the instruction.
The charging system for an electric vehicle according to any one of claims 1 to 5, wherein: The power receiving means includes second control means for controlling a vehicle equipped with the power receiving means from outside the vehicle,
The power receiving means controls the vehicle by operating the second control means when receiving an instruction to control from outside the vehicle from the control means;
The charging system for an electric vehicle according to any one of claims 1 to 6, wherein the charging system is an electric vehicle. A power supply operation by the power transmitting unit disposed on the lower side of the protective plate to a lower ground surface of the receiving operation, the operation control, the control step performed by using short-range wireless,
A power feeding step for performing the power feeding operation by an electromagnetic induction method;
A charging step of receiving the power supplied by the power supply operation by electromagnetic induction by performing the power reception operation, and charging a storage battery for traveling with the received power;
A refresh step for fully discharging the storage battery before the charging;
A method for charging an electric vehicle, comprising:
When the vehicle ID and password obtained from the electric vehicle satisfy a predetermined condition,
Performing the control step, the power feeding step and the charging step;
The method for charging an electric vehicle according to claim 8. When the electric vehicle is parked at a predetermined position,
Performing the control step, the power feeding step and the charging step;
10. The method for charging an electric vehicle according to claim 8, wherein the electric vehicle is charged.

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