JP6092529B2 - Charging system for electric mobile body and server device included therein - Google Patents

Description

The present invention is, for example, an electric moving body charging system for charging a battery mounted on an electric vehicle and contained in it relates to salicylate over server equipment.

  Conventionally, as this type of device, for example, a power feeding device disclosed in Patent Document 1 is known.

  Patent Document 1 describes an AC power source that is a power source for charging a main battery mounted on an electric vehicle, a power supply connector that is connected to a power receiving connector of the electric vehicle and supplies AC power, and an AC power source and a power supply connector. , A power supply control unit that controls opening and closing of the switch, a charger that converts AC power into DC power and charges the main battery, and a communication unit that communicates with the electric vehicle for authentication With.

  With this configuration, in the case of authentication with the electric vehicle, the power described in Patent Document 1 is supplied to the main battery from the start of power supply until a message to stop charging is received, and the authentication is not established. The power supply is stopped.

JP 2010-124556 A

  However, in the thing of patent document 1, when the main battery of an electric vehicle is fully charged and charging is completed, a message to stop charging is received and power feeding is stopped. Since no consideration is given to the processing, if the user leaves the electric vehicle during charging, there is a risk that the charging connector is left attached to the power receiving connector of the electric vehicle after the charging is completed.

  As a result, in the device described in Patent Document 1, there is a possibility that the power supply connector may be damaged due to a third party mischief or the like, which may interfere with other users who are charging the battery of the electric vehicle. was there.

The present invention aims to provide the above has been made in view of the circumstances, Rusa over server equipment included left acts on the electric moving body charging system and it is possible to suppress the power supply connector To do.

The server device of the present invention is a server device that communicates with a portable communication terminal that communicates with the charging device for an electric mobile body and performs a charging process in a charging service for the electric mobile body, wherein the charging device for the electric mobile body includes: Charging completion detection means for detecting that charging of the battery of the electric mobile body has been completed, and charging for detecting that a predetermined charging end operation performed by the user of the mobile communication terminal after completion of the charging is completed An end work detecting means, and an elapsed time after completion of charging indicating a time from when the charging completion detecting means detects completion of the charging until the charging end work detecting means detects completion of the charging end work. on condition that exceeded, and a first alerting means for transmitting a reminder signal for prompting to finish the charge end working on the portable communication terminal to the user, the One alerting means transmits the alert signal to alert the user, and the mobile communication terminal communicates with the electric mobile charging device via a wireless local area network. Alerting the user based on the alert signal on the condition that the alert signal sent by the first wireless communication means and the first alert means is received by the first wireless communication means A second alerting means for urging the user to finish the charging end operation, a second wireless communication means for communicating with the server device via a network of a communication carrier, and a predetermined time corresponding to the elapsed time after the completion of charging. Display means for displaying an overuse fee, and user information and the electric transfer of the mobile communication terminal from the electric mobile charging device via the mobile communication terminal. A charging start code indicating information for starting charging of the battery of the electric mobile body including charger information having individual identification information of the body charging device, and a charging completion code indicating that charging of the battery of the electric mobile body is completed The management information storage means for storing the user information and the charger information, and the user stored by the management information storage means before starting charging the battery of the electric mobile body The user of the mobile communication terminal is authenticated by checking the information, the charger information, the charging start code received by the receiving means and the charging completion code, and when the user is successfully authenticated, the user Authentication means for outputting a signal permitting the use of the charging device for the electric mobile body to the authentication of the electric mobile body, and after successful authentication of the user Timeout settlement processing means for performing timeout settlement processing in which a predetermined overuse fee is added to the charge for using the charging service on the condition that the elapsed time after authentication until receiving the charge completion code exceeds a predetermined time And a configuration provided with.

The present invention can provide a stand acts to contain that the charging system and its electrical movable body can be suppressed Rusa over server equipment of the power supply connector.

It is a block block diagram in 1st Embodiment of the charging system for electric mobile bodies which concerns on this invention. It is a flowchart in 1st Embodiment of the charging system for electric mobile bodies which concerns on this invention. It is a timing chart of the communication line establishment process in 1st Embodiment of the charging system for electric mobile bodies which concerns on this invention. It is a figure which shows an example of the display screen displayed on a touchscreen in 1st Embodiment of the charging system for electric mobile bodies which concerns on this invention. It is a timing chart of the authentication process in 1st Embodiment of the charging system for electric mobile bodies which concerns on this invention. It is a figure which shows an example of the charge start code | cord | chord in 1st Embodiment of the charging system for electric mobile bodies which concerns on this invention. It is a timing chart of the quick charge process in 1st Embodiment of the charging system for electric vehicles which concerns on this invention. It is a timing chart of transaction processing in a 1st embodiment of a charging system for electric vehicles concerning the present invention. It is a flowchart of electric power feeding connector return determination in 1st Embodiment of the charging system for electric mobile bodies which concerns on this invention. It is a figure which shows an example of the charge completion code | cord | chord in 1st Embodiment of the charging system for electric mobile bodies which concerns on this invention. It is a flowchart of charge completion code reception determination in 1st Embodiment of the charging system for electric mobile bodies which concerns on this invention. It is a block block diagram in 2nd Embodiment of the charging system for electric mobile bodies which concerns on this invention. It is a flowchart in 2nd Embodiment of the charging system for electric mobile bodies which concerns on this invention. It is a timing chart of the authentication process in 2nd Embodiment of the charging system for electric mobile bodies which concerns on this invention. It is a timing chart of the quick charge process in 2nd Embodiment of the charging system for electric mobile bodies which concerns on this invention. It is a timing chart of transaction processing in a 2nd embodiment of a charging system for electric vehicles concerning the present invention. It is a block block diagram in 3rd Embodiment of the charging system for electric mobile bodies which concerns on this invention. It is a timing chart of the authentication process in 3rd Embodiment of the charging system for electric mobile bodies which concerns on this invention. It is a timing chart of transaction processing in a 3rd embodiment of a charging system for electric vehicles concerning the present invention. It is a block block diagram in 4th Embodiment of the charging system for electric mobile bodies which concerns on this invention. It is a timing chart of the authentication process in 4th Embodiment of the charging system for electric mobile bodies which concerns on this invention. It is a timing chart of transaction processing in a 4th embodiment of a charging system for electric vehicles concerning the present invention.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings. An example in which the charging system for an electric vehicle according to the present invention is applied to a quick charging system that rapidly charges a battery mounted on an electric vehicle will be described.

(First embodiment)
First, the configuration of the rapid charging system in the present embodiment will be described.

  As shown in FIG. 1, the quick charging system 1 according to the present embodiment includes a quick charger 10, a mobile communication terminal 20, and a server device 30, and provides a charging service to an electric vehicle. The rapid charging system 1 constitutes an electric mobile charging system according to the present invention.

  The quick charger 10 communicates with the mobile communication terminal 20 by wireless communication in a relatively short distance, for example, wireless communication according to a wireless LAN (Local Area Network) standard. The mobile communication terminal 20 is called a smartphone having both an information management function provided in a PDA (Personal Data Assistance) and a call function provided in a mobile phone. The mobile communication terminal 20 has a function of communicating with the quick charger 10 according to the wireless LAN standard, for example, and a function of communicating with the server device 30 according to a mobile phone communication standard called, for example, the third generation. The server device 30 is configured to perform authentication processing for a user who uses the quick charger 10 and transaction processing for power in a charging service. The quick charging system 1 uses, for example, an encryption method called a public key encryption method in order to perform authentication processing and transaction processing. Each configuration will be described below.

  The quick charger 10 includes a user information acquisition unit 11, a charger information acquisition unit 12, a code generation unit 13, a charge information acquisition unit 14, a first encryption unit 15, a second encryption unit 16, a wireless communication unit 17, and a verification unit 18. , A charging control device 19, a power supply connector holding unit 101, and a warning unit 102. The quick charger 10 constitutes an electric mobile charging device according to the present invention.

  The user information acquisition unit 11 acquires information (for example, user ID) of a user who uses the quick charger 10.

  The charger information acquisition unit 12 acquires, as charger information, individual identification information (for example, charger ID) of the quick charger 10, error information generated in the quick charger 10, current time information output from a built-in clock, and the like. It is supposed to be. The individual identification information and error information are stored in a memory (not shown) provided in the quick charger 10.

  The code generation unit 13 generates a one-time code, which is a disposable code that can be used only once each time a charging service is provided.

  The charging information acquisition unit 14 acquires charging result information indicating a charging result by providing a charging service. The charging result information includes charging time, charging power amount, charging start time, charging end time, remaining battery level at the start of charging, remaining battery level at the end of charging, error information generated at the time of charging, and the like.

  The first encryption unit 15 encrypts input information using a first encryption key (public key) acquired in advance from the server device 30. Hereinafter, the encryption using the first encryption key is referred to as a “first encryption method”.

  The second encryption unit 16 encrypts input information using a second encryption key (public key) acquired in advance from the server device 30. Hereinafter, the encryption using the second encryption key is referred to as a “second encryption method”.

  The wireless communication unit 17 is configured to perform wireless communication with the mobile communication terminal 20 by, for example, the WiFi (registered trademark) system using the IEEE802.11b standard.

  The collation unit 18 collates the output information of the second encryption unit 16 and the reception information of the wireless communication unit 17.

  Although not shown, the charging control device 19 outputs a power feeding connector connected to the power receiving connector of the electric vehicle, a lock drive unit that locks the power receiving connector and the power feeding connector, a power feeding cable connected to the power feeding connector, and a direct current. It has a power unit, an operation panel operated by the user, a display panel for displaying various information, a speaker for outputting various guidance sounds, a control unit for performing overall control in the apparatus, and the like. The charging control device 19 constitutes a charging completion detecting unit according to the present invention. The display panel included in the charge control device 19 constitutes display means according to the present invention.

  The lock drive unit of the charging control device 19 locks the power feeding connector to the power receiving connector at the start of charging, and unlocks the power feeding connector at the end of charging.

  The power supply connector holding unit 101 is configured to removably hold a power supply connector (not shown) at a predetermined storage position. A sensor for detecting whether or not the power supply connector is held at the storage position is attached to the power supply connector holding unit 101, and a detection signal of this sensor is output to the charge control device 19. .

  Therefore, the charging control device 19 can detect whether or not the power feeding connector is held at the storage position. If it is detected that the power feeding connector is held at the storage position, the charging control device 19 is charged. It is determined that a predetermined charging end operation performed by the user after the completion of the charging is completed. That is, the charging control device 19 and the power feeding connector holding unit 101 constitute a charging end work detecting unit according to the present invention.

  When the power supply connector is not held in the storage position after the charging is completed, the charging control device 19 outputs a power supply connector non-return signal indicating that the power supply connector has not been returned to the alerting unit 102. ing.

  Here, the above-described charging end operation will be described. In the present embodiment, the charging end work means that the user returns the power supply connector to the storage position after the charging is ended, but the present invention is not limited to this, and the user who intends to use the quick charger 10 next is authorized. It means that the quick charger 10 can be used in a procedure.

  For example, the charge completion work in the configuration in which the power supply connector is stored in a box having a door means that the user stores the power supply connector in the box and closes the door after the charge is completed. In this case, by providing a sensor that detects that the power supply connector is stored in the box and that the door is closed, the charging control device 19 determines whether or not the charging end work has been completed. Can do.

  The alerting unit 102 includes a timer that measures time, a display panel that displays a predetermined message, and a voice output device that outputs a voice of a message and a warning sound. And the alerting part 102 sends the alerting signal which prompts a user to return the power feeding connector after the elapse of a predetermined time (for example, 1 minute) after inputting the power feeding connector non-return signal from the charging control device 19. In addition to being transmitted to the mobile communication terminal 20, display of a message prompting the user to return the power supply connector, sound output of the message, and output of a warning sound are executed.

  The mobile communication terminal 20 includes a first wireless communication unit 21, a second wireless communication unit 22, a program memory 23, a touch panel 24, and a control unit 25.

  The first wireless communication unit 21 communicates with the wireless communication unit 17 of the quick charger 10 in accordance with, for example, a WiFi communication standard. The first radio communication unit 21 constitutes a first radio reception unit and a first radio transmission unit according to the present invention.

  The second wireless communication unit 22 communicates with the server device 30 via the network 5 possessed by the communication carrier in accordance with, for example, a wideband code division multiple access (W-CDMA) communication standard. It has become. The second radio communication unit 22 constitutes a second radio reception unit and a second radio transmission unit according to the present invention.

  The program memory 23 stores in advance a program for each application that the mobile communication terminal 20 uses for each communication with the quick charger 10 and the server device 30.

  The touch panel 24 has a function of displaying an input / output screen of various information by each application and a function of acquiring information input by a user touching with a finger or a pen.

  The control unit 25 includes a CPU, a ROM, a RAM, an interface, and the like, and operates according to a program stored in the ROM. In addition, the control unit 25 is configured to execute a program for each application stored in the program memory 23.

  The server device 30 includes a wireless communication unit 31, a decryption unit 32, a management information storage unit 33, a charger information storage unit 34, a code verification unit 35, a charger information update unit 36, an encryption unit 37, a billing settlement unit 38, a timeout settlement. The unit 39 is provided.

  The wireless communication unit 31 communicates with the mobile communication terminal 20 via the network 5 in accordance with, for example, a W-CDMA communication standard. The wireless communication unit 31 constitutes a receiving unit according to the present invention.

  The decryption unit 32 decrypts the information encrypted by the first encryption method using a decryption key (secret key) corresponding to the first encryption key.

  The management information storage unit 33 stores user information of each user who uses the quick charging system 1 and information on a plurality of quick chargers including the quick charger 10.

  The charger information storage unit 34 stores charger management information for maintaining and managing a plurality of quick chargers including the quick charger 10. The charger management information includes history information such as a start code, a charging power amount, and error information for each quick charger.

  The code collation unit 35 collates the information decoded by the decoding unit 32 with the information stored in the management information storage unit 33 or the charger information storage unit 34. The code verification unit 35 constitutes an authentication unit according to the present invention.

  The charger information updating unit 36 refers to the charger information and the charging result information included in the charging completion code decoded by the decoding unit 32, and updates the charger management information in the charger information storage unit 34. ing.

  The encryption unit 37 is configured to encrypt predetermined information by the second encryption method based on the collation result by the code collation unit 35 and output it.

  The billing settlement unit 38 communicates with the billing settlement server 41 owned by the credit company via the wireless communication unit 31 and the network 5 based on the collation result by the code collation unit 35, and performs predetermined processing for billing settlement. To do.

  The time-out settlement unit 39 uses a predetermined overuse charge when the time from when the user authentication process is completed until the charge completion code is received exceeds a predetermined time (for example, 2 hours). A time-out settlement process is added to the fee.

  Next, operation | movement of the quick charge system 1 in this embodiment is demonstrated. As shown in FIG. 2, the quick charging system 1 performs a communication line establishment process (step S1), an authentication process (step S2), a quick charge process (step S3), and a transaction process (step S4).

  First, communication line establishment processing (step S1 in FIG. 2) will be described based on the block configuration diagram shown in FIG. 1 and the timing chart shown in FIG.

  The wireless communication unit 17 of the quick charger 10 forms a communication area by transmitting a wireless LAN (for example, WiFi) radio wave (step S11). When the mobile communication terminal 20 enters the communication area, a wireless LAN selection screen is displayed on the touch panel 24 (step S12).

  An example of a wireless LAN selection screen displayed on the touch panel 24 is shown in FIG. In FIG. 4A, the touch panel 24 includes a button 24a for selecting the wireless LAN-A (formed by the quick charger 10), a button 24b for selecting the wireless LAN-B, and a button 24c for selecting the wireless LAN-C. Is displayed. When the user touches the button 24a, the wireless LAN-A formed by the quick charger 10 is selected (step S13 in FIG. 3).

  Thereafter, user information and information such as a personal identification number are transmitted from the mobile communication terminal 20 to the quick charger 10 (step S14), and a communication establishment process between them is executed (step S15).

  After communication is established between the quick charger 10 and the mobile communication terminal 20, when a user executes an application for performing quick charging, for example, a screen as shown in FIG. 4B is displayed on the touch panel 24. The intention of using the quick charger 10 is confirmed. In FIG. 4B, a button 24d for executing “use quick charger” and a cancel button 24e for canceling “use quick charger” are displayed. When the user selects the button 24d, a use request signal is transmitted to the quick charger 10 (step S16 in FIG. 3).

  The quick charger 10 that has received the use request signal transmits a signal designating the server device 30 to the server device 30 via the mobile communication terminal 20 (step S17), and between the mobile communication terminal 20 and the server device 30. The communication establishment process is executed (step S18).

  The server device 30 transmits an authentication request signal for authenticating the user and the quick charger 10 to the quick charger 10 via the mobile communication terminal 20 (step S19).

  Next, the authentication process (step S2 in FIG. 2) will be described based on the block configuration diagram shown in FIG. 1 and the timing chart shown in FIG.

  The 1st encryption part 15 of the quick charger 10 acquires various information (step S21). That is, the first encryption unit 15 acquires user information from the user information acquisition unit 11, charger information from the charger information acquisition unit 12, and one-time code from the code generation unit 13.

  Then, the 1st encryption part 15 produces | generates a charge start code from the acquired various information (step S22).

  FIG. 6 shows an example of the charging start code. In FIG. 6, the charging start code 42 includes user information 42a, charger information 42b, and a one-time code 42c. In the illustrated example, the user information 42a is configured by a user ID. The charger information 42b includes information on a charger ID, a charger model, a charger time, and an error code.

  Returning to FIG. 5, the first encryption unit 15 encrypts the charging start code by the first encryption method (step S <b> 23), and outputs it to the wireless communication unit 17.

  On the other hand, similarly to the first encryption unit 15, the second encryption unit 16 obtains user information, charger information, and a one-time code to generate a charge start code, and encrypts the charge start code by the second encryption method. (Step S24) and output to the collation unit 18.

  The wireless communication unit 17 transmits the encrypted charging start code to the server device 30 via the mobile communication terminal 20 and the network 5 (step S25).

  The wireless communication unit 31 of the server device 30 receives the encrypted charge start code and outputs it to the decryption unit 32. The decryption unit 32 decrypts the encrypted charge start code with the decryption key (step S26), and outputs the decrypted charge start code to the code verification unit 35.

  The code verification unit 35 reads the user information and the charger information from the management information storage unit 33, compares the user information and the charger information included in the charging start code (step S27), and succeeds in the authentication of the user and the charger. It is determined whether or not it has been done (step S28). Here, if the user information and charger information read from the management information storage unit 33 matches the user information and charger information included in the charging start code, the code verification unit 35 authenticates the user and the charger. In other cases, it is determined that the user and the charger are not successfully authenticated. Further, the code verification unit 35 determines that the authentication is not successful even when a predetermined error occurs in the quick charger 10.

  In step S28, when the code verification unit 35 determines that the user and the charger are successfully authenticated, the charger information update unit 36 refers to the charger information included in the charging start code and stores the charger information. The accumulated information in the unit 34 is updated (step S29). Then, the encryption unit 37 encrypts the charging start code as a use permission code by the second encryption method (step S30), and outputs it to the wireless communication unit 31.

  The wireless communication unit 31 transmits the encrypted use permission code to the quick charger 10 via the mobile communication terminal 20 (step S31).

  On the other hand, if the code verification unit 35 does not determine in step S28 that the authentication of the user and the charger has succeeded, the encryption unit 37 encrypts error information indicating that the user information or the charger information is invalid. The data is output to the wireless communication unit 31 without being converted. The wireless communication unit 31 transmits this error information to the quick charger 10 as in step S31 described above.

  In the quick charger 10, the collation unit 18 collates the encrypted use permission code received by the wireless communication unit 17 and the charge start code encrypted by the second encryption unit 16 in step S24 (step S24). S32). Here, when the server device 30 successfully authenticates the user and the charger, the usage permission code and the charging start code match, and the charging control device 19 authenticates to the mobile communication terminal 20 via the wireless communication unit 17. Is transmitted (step S33), and the process proceeds to the quick charge process (step S3 in FIG. 2). On the other hand, if the server device 30 does not succeed in authenticating the user and the charger, the use permission code and the charging start code do not match, and the authentication process is terminated (step S34), and the charging service is not provided. .

  Next, the quick charge process (step S3 in FIG. 2) will be described based on the block configuration diagram shown in FIG. 1 and the timing chart shown in FIG. It is assumed that the power feeding connector of the quick charger 10 is connected to the power receiving connector of the electric vehicle.

  In the quick charger 10, the user and the charger are successfully authenticated in the above-described step S32 (see FIG. 5), and the charging control device 19 displays a charging start screen on the display panel (step S41).

  On the other hand, the mobile communication terminal 20 receives the authentication success signal in the above-described step S33 (see FIG. 5). Based on the authentication success signal, the charging start screen is displayed on the touch panel 24 by the application stored in the program memory 23 (step S42). That is, the user can operate any one of the charging start screens displayed on the quick charger 10 and the mobile communication terminal 20.

  An example of the charge start screen displayed on the touch panel 24 is shown in FIG. 4C, the touch panel 24 displays a charge start button 24f and a cancel button 24g for canceling the charge start. When the user selects the charge start button 24f, the first wireless communication unit 21 transmits a charge start request signal to the quick charger 10 under the control of the control unit 25 (step S43).

  When the wireless communication unit 17 of the quick charger 10 receives the charge start request signal or when the user operates the charge start button on the charge start screen displayed on the display panel of the quick charger 10, the charge control device 19 It communicates with the charging device on the vehicle side, and confirms whether the electric vehicle and the quick charger 10 are in a state in which quick charging can be normally executed (step S44). For example, the charging control device 19 performs an insulation test on the electric vehicle and the quick charger 10. If the normal state cannot be confirmed in step S44, the process ends without performing the quick charge process.

  When it is confirmed in step S44 that the state is normal, the charging control device 19 starts providing the charging service. That is, the charging control device 19 locks the power feeding connector to the power receiving connector (step S45), so that the user cannot remove the power feeding connector from the power receiving connector. And the charging control apparatus 19 outputs an electric current with respect to an electric vehicle (step S46).

  The charging control device 19 transmits charging information during rapid charging to the mobile communication terminal 20 via the wireless communication unit 17 at predetermined time intervals (step S47). The touch panel 24 of the mobile communication terminal 20 displays the received charging information (step S48).

  An example of the charging information displayed on the touch panel 24 is shown in FIG. As shown in FIG. 4D, the touch panel 24 displays charging time information 24h, charging power amount information 24i, and a charge 24j as charging information. These displays are updated every predetermined time. In addition, a charging interruption button 24k for interrupting charging is displayed on the touch panel 24, and the user can interrupt rapid charging by selecting the charging interruption button 24k.

  Returning to FIG. 7, the control unit 25 determines whether or not the charge interruption button 24k has been selected (step S49). Here, when it is not determined that the charging interruption button 24k is selected, the process returns to step S48, and the touch panel 24 displays the charging information.

  If it is determined in step S49 that the charging interruption button 24k has been selected, the control unit 25 transmits a charging interruption signal for interrupting charging to the quick charger 10 via the first wireless communication unit 21 ( Step S50).

  On the other hand, the charging information illustrated in FIG. 4D is also displayed on the display panel of the quick charger 10 (step S51). Then, the charging control device 19 determines whether or not the user has selected the charging interruption button displayed on the display panel (step S52). If it is determined that the charging interruption button has been selected, the process proceeds to step S54. If it is not determined that the charging interruption button has been selected, the process proceeds to step S53.

  In step S53, the charging control device 19 determines whether or not the charging is completed. If it is determined that the charging is completed, the process proceeds to step S54 and stops outputting the current (step S54). On the other hand, if the charging control device 19 does not determine that the charging has ended, the charging control device 19 returns to step S46.

  Then, the charging control device 19 displays a charging end message indicating that charging has ended on the display panel (step S55), and sends a charging end signal indicating that charging has ended via the wireless communication unit 17 to the mobile communication terminal. 20 (step S56). After the mobile communication terminal 20 receives the charging end signal, the touch panel 24 displays a charging end message (step S57).

  In the above description of operation, when the quick charger 10 starts current output (step S46) and the user moves to a range where the quick charger 10 and the mobile communication terminal 20 cannot communicate, steps S47 to S50, S56. , S57 is not performed.

  Next, transaction processing (step S4 in FIG. 2) will be described based on the block configuration diagram shown in FIG. 1 and the timing chart shown in FIG.

  The charging control device 19 unlocks the power supply connector (step S58), and performs a power supply connector return determination that is a determination as to whether or not the power supply connector has been returned to the storage position (step S59). FIG. 9 shows a process for determining whether to return the power supply connector.

  As shown in FIG. 9, the charging control device 19 determines whether or not the power supply connector has been returned to the storage position based on the output signal of the sensor provided in the power supply connector holding unit 101 (step S591).

  In step S591, the charging control device 19 returns to the process shown in FIG. 8 when determining that the power supply connector has been returned to the storage position, and returns to the predetermined time (when not determining that the power supply connector has been returned to the storage position). For example, it waits for 1 minute (step S592).

  The charge control device 19 performs an alerting process (step S593). Specifically, when the charging control device 19 outputs a power supply connector non-return signal to the alerting unit 102, the alerting unit 102 displays a message prompting the user to return the power supply connector on the display panel. The voice of the message and the warning sound are output from the voice output device, and a power supply connector non-return signal is transmitted to the mobile communication terminal 20 (step S594).

  As a result, in the mobile communication terminal 20, a message prompting the user to return the power supply connector is displayed on the touch panel 24 by the control unit 25, and the voice or warning sound of the message is output from the speaker of the mobile communication terminal 20. .

  The charge control device 19 determines whether or not a predetermined first timeout time has elapsed after the alerting process (step S595). The first time-out period is preferably set to a time (for example, 40 minutes) slightly longer than the normal quick charge time (about 30 minutes).

  In step S595, if the charging control device 19 does not determine that the first timeout time has elapsed, the charging control device 19 returns to step S591, and if it is determined that the first timeout time has elapsed, The state is returned to the initial state (step S596), and the process is terminated. When the quick charger 10 is returned to the initial state, the charging control device 19 stores information indicating that the user has not returned the power supply connector, and stores the stored information for the user. It is preferable to transmit to the server 30 at the next use and charge a predetermined overuse fee.

  Returning to FIG. 8, the 1st encryption part 15 of the quick charger 10 acquires various information after charge (step S61). That is, the first encryption unit 15 acquires charger information from the charger information acquisition unit 12 and charging result information from the charging information acquisition unit 14.

  Then, the 1st encryption part 15 produces | generates a charge completion code from the acquired various information (step S62).

  FIG. 10 shows an example of the charging completion code. In FIG. 10, the charging completion code 43 includes charger information 43a and charging result information 43b. The charger information 43a includes a charger ID and an error code. The charging result information 43b includes information such as a charging time, a charging power amount, a charging start time, a charging end time, a remaining battery level at the start of charging, a remaining battery level at the end of charging, and the number of alerts. Note that the number of times of alerting refers to the number of times that the alerting process (step S593) is executed in the determination of the power supply connector return shown in FIG. Instead of the number of times of alerting, for example, the time from when charging is completed until the power feeding connector is returned to the storage position may be used.

  Returning to FIG. 8, the first encryption unit 15 encrypts the charging completion code by the first encryption method (step S <b> 63), and outputs it to the wireless communication unit 17.

  On the other hand, like the first encryption unit 15, the second encryption unit 16 acquires the charger information and the charge result information, generates a charge completion code, and encrypts the charge completion code by the second encryption method (step S64) and output to the collation unit 18.

  If the wireless communication unit 17 can communicate with the mobile communication terminal 20, the wireless communication unit 17 transmits the encrypted charge completion code to the server device 30 via the mobile communication terminal 20 (step S <b> 65), but communicates with the mobile communication terminal 20. If it is not possible, the charging completion code is not transmitted.

  The timeout settlement unit 39 of the server device 30 performs a charging completion code reception determination that is a determination as to whether or not the wireless communication unit 31 has received the encrypted charging completion code (step S60). FIG. 11 shows the process for determining whether the charging completion code is received. This charge completion code reception determination is performed when the user moves out of the communication range of the quick charger 10 during the quick charge and does not complete the charge within a predetermined time after the completion of the quick charge. It is a process to do.

  As shown in FIG. 11, the timeout settlement unit 39 determines whether or not the wireless communication unit 31 has received the encrypted charge completion code (step S601).

  In step S <b> 601, when the timeout settlement unit 39 determines that the wireless communication unit 31 has received the encrypted charge completion code, the process returns to the process illustrated in FIG. 8, and the encrypted charge completion code is transmitted to the wireless communication unit 31. If it is not determined that the second timeout period has been received, it is determined whether or not a predetermined second timeout period has elapsed (step S602). The second timeout time is preferably set to a time (for example, 2 hours) longer than the first timeout time described above.

  If the time-out settlement unit 39 does not determine that the second time-out period has elapsed in step S602, the process returns to step S601. Processing is performed (step S603).

  Specifically, the timeout settlement unit 39 communicates with the billing settlement server 41 via the wireless communication unit 31 and the network 5, and performs a timeout settlement process for adding a predetermined overuse charge to the charge service charge. Then, the process proceeds to step S70 described later.

  Returning to FIG. 8, the decryption unit 32 decrypts the encrypted charge completion code with the decryption key (step S <b> 66), and outputs it to the code collation unit 35.

  The code verification unit 35 reads the charger information from the management information storage unit 33, compares it with the charger information included in the charge completion code (step S67), and determines whether or not the authentication of the charger is successful (step S67). S68). Here, when the charger information read from the management information storage unit 33 matches the charger information included in the charging completion code, the code verification unit 35 determines that the authentication of the charger is successful, Otherwise, it is determined that the charger has not been successfully authenticated.

  If it is determined in step S68 that the code verification unit 35 has succeeded in authenticating the charger, the billing settlement unit 38 communicates with the billing settlement server 41 via the wireless communication unit 31 and the network 5 to perform billing settlement processing. This is performed (step S69). If the number of alerts included in the charge completion code is greater than the predetermined number, the account settlement unit 38 converts the excess fee into a usage fee according to the number of alerts and performs an accounting settlement process.

  The charger information update unit 36 updates the charger management information in the charger information storage unit 34 (step S70).

  Here, when it is determined that the wireless communication unit 31 has received the charging completion code in the charging completion code reception determination (in the case of the process following step S69), the charger information update unit 36 is included in the charging completion code. The charger management information in the charger information storage unit 34 is updated with reference to the charger information and the charging result information.

  On the other hand, when it is determined in the charging completion code reception determination that the wireless communication unit 31 has not received the charging completion code, the charger information update unit 36 starts the charging acquired in step S26 (FIG. 5) of the authentication process. The charger management information in the charger information storage unit 34 is updated including the charger information included in the code (FIG. 6) and the information on the timeout settlement process.

  In the next step S71, when the wireless communication unit 31 receives the charging completion code, the encryption unit 37 encrypts the charging completion code as a transaction completion code by the second encryption method, and outputs it to the wireless communication unit 31. The wireless communication unit 31 transmits a transaction completion code to the mobile communication terminal 20 (step S72a). When the timeout settlement process is performed, the timeout settlement unit 39 transmits the timeout settlement process execution signal indicating that to the mobile communication terminal 20 via the wireless communication unit 31 without encrypting it in step S72a. .

  In the mobile communication terminal 20, the control unit 25 determines whether or not the timeout payment process has been performed based on whether or not the second wireless communication unit 22 has received the timeout payment process execution signal (step S72b).

  In step S72b, when the control unit 25 determines that the timeout settlement process has been performed, the control unit 25 displays a timeout settlement message indicating that the timeout settlement process has been performed on the touch panel 24 (step S72c), and ends the process.

  On the other hand, in step S72b, when the control unit 25 does not determine that the time-out settlement process has been performed, the control unit 25 transmits the encrypted transaction completion code to the quick charger 10 via the first wireless communication unit 21 ( Step S72d).

  In the above-described step S68, when the code verification unit 35 does not determine that the charger authentication has succeeded, the encryption unit 37 performs wireless communication without encrypting error information indicating that the charger information is invalid. To the unit 31. The wireless communication unit 31 transmits this error information to the quick charger 10 via the mobile communication terminal 20.

  In the quick charger 10, the collation unit 18 collates the encrypted transaction completion code received by the wireless communication unit 17 with the charge completion code encrypted by the second encryption unit 16 in step S64 (step S64). S73). Here, when the authentication of the charger is successful in the server device 30, the transaction completion code and the charging completion code match, and the charging control device 19 displays a transaction completion message indicating that the transaction is completed on the display panel. (Step S75), and transmits a transaction completion signal indicating that the transaction has been completed to the mobile communication terminal 20 via the wireless communication unit 17 (step S76). After the mobile communication terminal 20 receives the transaction completion signal, the touch panel 24 displays a transaction completion message (step S77).

  On the other hand, in the quick charger 10, when the transaction completion code and the charging completion code do not match, the charging control device 19 displays a message on the display panel instructing a serviceman to investigate the cause of the authentication failure. Displayed (step S78).

  As described above, the quick charging system 1 according to the present embodiment prompts the user to return the power supply connector after a predetermined time has elapsed after the quick charger 10 inputs the power supply connector non-return signal from the charge control device 19. Since the alerting signal is transmitted to the mobile communication terminal 20 via the wireless communication unit 17 and the alerting unit 102 that executes message display and audio output based on the alerting signal is provided, the act of leaving the power supply connector is performed. Can be suppressed.

  In addition, the quick charging system 1 according to the present embodiment has a predetermined overuse when the server device 30 exceeds a predetermined time after the user authentication process is completed until the charging completion code is received. Since the timeout settlement unit 39 for performing the timeout settlement processing in which the charge is added to the charge for using the charging service is provided, the act of leaving the power supply connector can be suppressed by charging the overuse fee.

  In the above-described embodiment, in order to perform authentication processing and transaction processing, an encryption method called a public key encryption method has been described as an example. However, the present invention is not limited to this, and for example, common key encryption is used. A method may be used.

(Second Embodiment)
First, the structure in 2nd Embodiment of the quick charge system which concerns on this invention is demonstrated.

  As shown in FIG. 12, the quick charging system 2 in the present embodiment includes a quick charger 50, a mobile communication terminal 60, and a server device 30. The rapid charging system 2 constitutes an electric mobile charging system according to the present invention.

  The quick charging system 2 in the present embodiment includes a quick charger 50 and a mobile communication terminal 60 in which the configurations of the quick charger 10 and the mobile communication terminal 20 in the first embodiment (see FIG. 1) are partially changed. Therefore, the same components as those in the first embodiment are denoted by the same reference numerals, and the description of the overlapping components is omitted.

  The quick charger 50 includes a user information acquisition unit 51, a code display unit 52, a code input unit 53, a power supply connector holding unit 101, and an alerting unit 103. The quick charger 50 constitutes an electric mobile charging apparatus according to the present invention. Moreover, the alerting part 103 comprises the alerting means which concerns on this invention.

  For example, the user information acquisition unit 51 is configured by an IC card reader / writer that performs recording and reproduction on a contact or non-contact IC card, and acquires user information from the IC card information recorded on the IC card. It is supposed to be. The user information acquisition unit 51 constitutes a user information acquisition unit according to the present invention. Further, the IC card constitutes a user information recording medium according to the present invention. Note that the user information recording medium is not limited to an IC card, and any user information recording medium that can record user information of the quick charging system 2 may be used.

  The code display unit 52 is composed of, for example, a liquid crystal display, and displays the encryption code encrypted by the first encryption unit 15 using the first encryption method. The code display unit 52 constitutes display means according to the present invention.

  The code input unit 53 is configured by a keyboard, a touch panel, or the like, for example, and inputs an encryption code by a user operation.

  The alerting unit 103 includes a timer that measures time, a display panel that displays a predetermined message, and a voice output device that outputs a voice of a message and a warning sound. Then, the alerting unit 103 displays a message prompting the user to return the power supply connector or outputs a voice message after a predetermined time (for example, 1 minute) has elapsed after inputting the power supply connector non-return signal from the charging control device 19. The warning sound is output.

  The portable communication terminal 60 includes a wireless communication unit 61 that communicates with the server device, a program memory 62 that stores an application program used for communication with the server device 30, a display unit 63 that displays various information, and an operation unit 64 that is operated by the user. A control unit 65 that controls the entire apparatus and executes an application. Here, the wireless communication unit 61 constitutes a transmission unit according to the present invention. The operation unit 64 constitutes input means according to the present invention.

  Next, operation | movement of the quick charge system 2 in this embodiment is demonstrated. As shown in FIG. 13, the quick charge system 2 performs an authentication process (step S5), a quick charge process (step S6), and a transaction process (step S7).

  First, the authentication process (step S5 in FIG. 13) will be described based on the block configuration diagram shown in FIG. 12 and the timing chart shown in FIG. In addition, the description which overlaps with the authentication process (refer FIG. 5) in 1st Embodiment is abbreviate | omitted.

  In the quick charger 50, the user information acquisition unit 51 acquires user information from the IC card information recorded on the IC card (step S81).

  After the processes in steps S21 to S23, the code display unit 52 displays the charge start code encrypted by the first encryption unit 15 using the first encryption method (step S82). The charge start code is displayed as a number of about 8 digits, for example.

  The user operates the operation unit 64 of the mobile communication terminal 60 to start an application used for communication with the server device 30 and inputs the charging start code displayed on the code display unit 52 on the input screen of the application. Thus, the encrypted charging start code is input to the mobile communication terminal 60 (step S83).

  The wireless communication unit 61 transmits the input charging start code to the server device 30 (step S25).

  After the processes of steps S26 to S31 are executed in the server device 30, the display unit 63 of the mobile communication terminal 60 displays the encrypted use permission code (step S84).

  The user operates the code input unit 53 of the quick charger 50 and inputs the use permission code displayed on the display unit 63 of the mobile communication terminal 60, whereby the use permission code is input to the quick charger 50. (Step S85).

  The collation unit 18 collates the encrypted use permission code input by the code input unit 53 and the charge start code encrypted by the second encryption unit 16 in step S24 (step S32). If the server device 30 succeeds in authenticating the user and the charger, the use permission code matches the charge start code, and the process proceeds to the quick charge process (step S6 in FIG. 13).

  Next, FIG. 15 shows a timing chart of the quick charging process (step S6 in FIG. 13). As shown in FIG. 15, the quick charger 50 in the present embodiment performs only the process related to the quick charger 10 in the quick charge process (see FIG. 7) in the first embodiment.

  Next, transaction processing (step S7 in FIG. 13) will be described based on the block configuration diagram shown in FIG. 12 and the timing chart shown in FIG. In addition, the description which overlaps with the transaction process (refer FIG. 8) in 1st Embodiment is abbreviate | omitted.

  In the quick charger 50, after the process of releasing the power supply connector lock (step S58), the power supply connector return determination is performed (step S59). Here, when performing the alerting process of step S593 shown in FIG. 9, the alerting unit 103, after inputting a power supply connector non-return signal from the charging control device 19, passes a predetermined time (for example, 1 minute), It displays a message prompting the user to return the power supply connector, outputs a voice message, and outputs a warning sound. However, the alerting unit 103 does not transmit the power supply connector non-return signal (step S594) illustrated in FIG.

  Subsequently, after the processes of steps S61 to S63, the code display unit 52 displays the charge completion code encrypted by the first encryption unit 15 using the first encryption method (step S91). The charge completion code is displayed as a number of about 8 digits, for example.

  The user operates the operation unit 64 of the mobile communication terminal 60 to input the charge completion code displayed on the code display unit 52 on the input screen of the application, whereby the encrypted charge completion code is transferred to the mobile communication terminal. 60 (step S92).

  The wireless communication unit 61 transmits the input charging completion code to the server device 30 (step S65).

  In the server device 30, after the charge completion code reception determination (step S60), steps S66 to S71, and steps S72a to S72c are executed, the display unit 63 of the mobile communication terminal 60 displays the encrypted transaction completion code. It is displayed (step S93).

  The user operates the code input unit 53 of the quick charger 50 and inputs the transaction completion code displayed on the display unit 63 of the mobile communication terminal 60, whereby the transaction completion code is input to the quick charger 50. (Step S94).

  The collation unit 18 collates the encrypted transaction completion code input by the code input unit 53 with the charge completion code encrypted by the second encryption unit 16 in step S64 (step S73). Here, when the server device 30 successfully authenticates the user and the charger, the transaction completion code and the charging completion code match, and the processing of step S75 is performed to end the transaction processing.

  As described above, the rapid charging system 2 according to the present embodiment prompts the user to return the power supply connector after a predetermined time has elapsed after the quick charger 50 inputs the power supply connector non-return signal from the charge control device 19. Since the alerting unit 103 for executing alert message display and voice output is provided, the act of leaving the power feeding connector can be suppressed.

  In addition, the quick charging system 2 according to the present embodiment has a predetermined overuse when the server device 30 has exceeded a predetermined time after receiving the charging completion code after completing the user authentication process. Since the timeout settlement unit 39 that performs the timeout settlement process in which the charge is added to the charge for using the charging service is provided, the act of leaving the power supply connector can be suppressed.

(Third embodiment)
First, the structure in 3rd Embodiment of the rapid charging system which concerns on this invention is demonstrated.

  As shown in FIG. 17, the quick charging system 3 in the present embodiment includes a quick charger 70, a mobile communication terminal 20, and a server device 80. The rapid charging system 3 constitutes an electric mobile charging system according to the present invention.

  The rapid charging system 3 in the present embodiment is obtained by partially changing each configuration of the rapid charger 10 and the server device 30 in the first embodiment (see FIG. 1). Therefore, the same components as those in the first embodiment are denoted by the same reference numerals, and the description of the overlapping components is omitted.

  Specifically, the quick charger 70 is provided with a charge code generation unit 71 by omitting the first encryption unit 15 and the second encryption unit 16 of the first embodiment. That is, unlike the first embodiment, the quick charger 70 transmits various information to the mobile communication terminal 20 without encryption. The quick charger 70 constitutes a charging device for an electric vehicle according to the present invention.

  The charging code generation unit 71 acquires user information from the user information acquisition unit 11, charger information from the charger information acquisition unit 12, one-time code from the code generation unit 13, and charging result information from the charging information acquisition unit 14. A start code and a charge completion code are generated.

  The server device 80 is obtained by eliminating the decryption unit 32 and the encryption unit 37 of the first embodiment. That is, the server device 80 is configured not to decrypt the received information and to encrypt the information to be transmitted.

  Next, operation | movement of the quick charge system 3 in this embodiment is demonstrated. The operation of the quick charging system 3 is different from the operation of the first embodiment (see FIG. 2) in authentication processing (step S2) and transaction processing (step S4).

  First, the authentication process (step S2 in FIG. 2) will be described based on the block configuration diagram shown in FIG. 15 and the timing chart shown in FIG. In addition, the description which overlaps with the authentication process (refer FIG. 5) in 1st Embodiment is abbreviate | omitted.

  The charge code generation unit 71 acquires various types of information (step S101). That is, the charging code generation unit 71 acquires user information from the user information acquisition unit 11, charger information from the charger information acquisition unit 12, and one-time code from the code generation unit 13.

  Subsequently, the charging code generation unit 71 generates a charging start code from the acquired various information (step S102), and outputs it to the wireless communication unit 17. The charging start code includes various information illustrated in FIG. 6, but is not encrypted unlike the first embodiment.

  The wireless communication unit 17 transmits a charge start code to the server device 80 via the mobile communication terminal 20 and the network 5 (step S103).

  In the server device 80, after the processing of steps S27 to S29, the wireless communication unit 31 transmits a use permission code to the quick charger 70 via the mobile communication terminal 20 (step S104). The use permission code is transmitted without being encrypted.

  Next, transaction processing (step S4 in FIG. 2) will be described based on the block configuration diagram shown in FIG. 17 and the timing chart shown in FIG. In addition, the description which overlaps with the transaction process (refer FIG. 8) in 1st Embodiment is abbreviate | omitted.

  In the quick charger 70, after the power supply connector lock release (step S58) and the power supply connector return determination (step S59), the charging code generation unit 71 acquires various information (step S105). That is, the charging code generation unit 71 acquires charger information from the charger information acquisition unit 12 and charging result information from the charging information acquisition unit 14.

  Subsequently, the charge code generation unit 71 generates a charge completion code from the acquired various information (step S106). The charging completion code includes various information illustrated in FIG. 10, but is not encrypted unlike the first embodiment.

  The wireless communication unit 17 transmits a charge completion code to the server device 80 via the mobile communication terminal 20 and the network 5 (step S107).

  In server device 80, after completion of the charging completion code reception determination (step S60) and the processing of steps S67 to S70, when the time-out settlement process is not performed, the wireless communication unit 31 transmits the transaction completion code via the mobile communication terminal 20. Is transmitted to the quick charger 70 (step S108). The transaction completion code is transmitted without being encrypted. On the other hand, when the timeout payment process is performed in the server device 80, the wireless communication unit 31 transmits a timeout payment process execution signal to the mobile communication terminal 20 in step S108.

  As described above, the quick charging system 3 according to the present embodiment is configured to transmit and receive the charging start code, the use permission code, the charging completion code, and the transaction completion code without encryption, and thus is simpler than the first embodiment. The authentication process can be performed with the configuration, and the act of leaving the power supply connector can be suppressed.

  In the above-described embodiment, the configuration in which the charging start code, the use permission code, the charging completion code, and the transaction completion code are not encrypted is described as an example, but the present invention is not limited to this. A part of these may be encrypted and transmitted / received.

(Fourth embodiment)
First, the structure in 4th Embodiment of the rapid charging system which concerns on this invention is demonstrated.

  As shown in FIG. 20, the quick charging system 4 in the present embodiment includes a quick charger 90, a mobile communication terminal 60, and a server device 80. This rapid charging system 4 constitutes the charging system for an electric vehicle according to the present invention.

  The rapid charging system 4 in the present embodiment is obtained by partially changing the configurations of the rapid charger 50 and the server device 30 in the second embodiment (see FIG. 12). Accordingly, the same components as those of the second embodiment are denoted by the same reference numerals, and the description of the overlapping components is omitted.

  Specifically, the quick charger 90 is provided with a charge code generation unit 71 by eliminating the first encryption unit 15 and the second encryption unit 16 of the second embodiment. That is, unlike the second embodiment, the quick charger 90 does not encrypt various information. The quick charger 90 constitutes an electric mobile charging device according to the present invention. The charging code generation unit 71 is the same as that in the third embodiment, and thus the description of the configuration is omitted.

  The server device 80 is obtained by eliminating the decryption unit 32 and the encryption unit 37 of the first embodiment. That is, the server device 80 is configured not to decrypt the received information and to encrypt the information to be transmitted. Since the server device 80 is the same as that of the third embodiment, the description of the configuration is omitted.

  Next, operation | movement of the quick charge system 4 in this embodiment is demonstrated. The operation of the quick charging system 4 is different from the operation of the second embodiment (see FIG. 13) in authentication processing (step S5) and transaction processing (step S7).

  First, the authentication process (step S5 in FIG. 13) will be described based on the block configuration diagram shown in FIG. 20 and the timing chart shown in FIG. In addition, the description which overlaps with the authentication process (refer FIG. 14) in 2nd Embodiment is abbreviate | omitted.

  The charge code generation unit 71 acquires various types of information (step S111). That is, the charging code generation unit 71 acquires user information from the user information acquisition unit 51, charger information from the charger information acquisition unit 12, and one-time code from the code generation unit 13.

  Subsequently, the charging code generation unit 71 generates a charging start code from the acquired various pieces of information (step S112) and outputs it to the code display unit 52. The charging start code includes various information illustrated in FIG. 6, but is not encrypted unlike the second embodiment.

  After the processing of steps S82 to S83, the wireless communication unit 61 of the mobile communication terminal 60 transmits a charging start code to the server device 80 via the network 5 (step S113).

  In server device 80, after processing of Steps S27-S29, wireless communication part 31 transmits a use permission code to portable communication terminal 60 (Step S114). The use permission code is transmitted without being encrypted.

  Next, transaction processing (step S7 in FIG. 13) will be described based on the block configuration diagram shown in FIG. 20 and the timing chart shown in FIG. In addition, the description which overlaps with the transaction processing (refer FIG. 16) in 2nd Embodiment is abbreviate | omitted.

  In the quick charger 90, after the power supply connector lock is released (step S58) and the power supply connector return determination (step S59), the charge code generation unit 71 acquires various information (step S121). That is, the charging code generation unit 71 acquires charger information from the charger information acquisition unit 12 and charging result information from the charging information acquisition unit 14.

  Subsequently, the charging code generation unit 71 generates a charging completion code from the acquired various information (step S122), and outputs it to the code display unit 52. The charging completion code includes various information illustrated in FIG. 10, but is not encrypted unlike the second embodiment.

  After the processes of steps S91 to S92, the wireless communication unit 61 of the mobile communication terminal 60 transmits a charge completion code to the server device 80 via the network 5 (step S123).

  In the server device 80, after the completion of the charging completion code reception determination (step S60) and the processing of steps S67 to S70, if the timeout settlement process is not performed, the wireless communication unit 31 transmits the transaction completion code to the mobile communication terminal 60. (Step S124). The transaction completion code is transmitted without being encrypted. On the other hand, if the timeout payment process is performed in the server device 80, the wireless communication unit 31 transmits a timeout payment process execution signal to the mobile communication terminal 60 in step S124.

  As described above, the quick charging system 4 according to the present embodiment is configured to transmit and receive the charging start code, the use permission code, the charging completion code, and the transaction completion code without encryption, and thus is simpler than the second embodiment. The authentication process can be performed with the configuration, and the act of leaving the power supply connector can be suppressed.

  In the above-described embodiment, the configuration in which the charging start code, the use permission code, the charging completion code, and the transaction completion code are not encrypted is described as an example, but the present invention is not limited to this. A part of these may be encrypted and transmitted / received.

1, 2, 3, 4 Rapid charging system (charging system for electric vehicles)
10, 50, 70, 90 Quick charger (electric mobile charging device)
19 Charge control device (charge completion detection means, charge end work detection means)
20, 60 Mobile communication terminal 21 First wireless communication unit (first wireless communication means)
22 Second wireless communication unit (second wireless communication means)
24 Touch panel (display means)
25 Control part (second alerting means)
30, 80 Server device 31 Wireless communication unit (reception means)
35 Code verification part (authentication means)
39 Time-out settlement (time-out settlement processing means)
51 User information acquisition unit (user information acquisition means)
52 Code display section (display means)
61 Wireless communication unit (transmission means)
64 Operation unit (input means)
65 control unit 101 power supply connector holding unit (charging end work detection means)
102 attention raising part (attention calling means, first attention calling means)
103 attention raising part (attention calling means)

Claims (5)

A server device that communicates with a mobile communication terminal that communicates with a charging device for an electric mobile body and performs billing processing in a charging service for the electric mobile body ,
The charging device for the electric vehicle is
Charging completion detecting means for detecting that charging of the battery of the electric vehicle is completed;
A charge end work detecting means for detecting that a predetermined charge end work executed by a user of the mobile communication terminal after completion of the charge is completed;
The condition is that the elapsed time after completion of charging exceeds a predetermined time, which indicates the time from when the charging completion detection means detects completion of the charging until the charging completion work detection means detects the completion of the charging completion work. First warning means for transmitting to the mobile communication terminal a warning signal for prompting the user to finish the charging end work;
Equipped with a,
The first alerting means transmits the alert signal in order to alert the user,
The mobile communication terminal is
First wireless communication means for communicating with the electric mobile charging device via a wireless local area network;
The charging end operation is completed by alerting the user based on the alert signal on condition that the alert signal transmitted by the first alert device is received by the first wireless communication device. A second alerting means for encouraging
Second wireless communication means for communicating with the server device via a network of a communication carrier;
Display means for displaying a predetermined overuse fee according to the elapsed time after completion of the charging;
With
Charging the battery of the electric mobile body including the charger information including the user information of the mobile communication terminal and the individual identification information of the electric mobile body charging device from the electric mobile body charging device via the mobile communication terminal. Receiving means for receiving a charging start code indicating information to be started and a charging completion code indicating that charging of the battery of the electric mobile body is completed;
Management information storage means for storing the user information and the charger information;
Before starting charging the battery of the electric vehicle, the user information and the charger information stored by the management information storage unit are compared with the charging start code and the charging completion code received by the receiving unit. The user of the mobile communication terminal is authenticated, and when the user authentication is successful, a signal for permitting the user to use the electric mobile charging device is used for the user authentication. Authentication means to output;
A predetermined overuse fee was added to the charge for using the charging service on the condition that the elapsed time after authentication from when the user was successfully authenticated until the charging completion code was received exceeded a predetermined time. Timeout payment processing means for performing timeout payment processing;
A server device comprising: The server device according to claim 1, wherein the electric mobile charging device further includes display means for displaying an overuse fee predetermined according to an elapsed time after completion of the charging. A charging device for an electric mobile object according to claim 1 , a portable communication terminal according to claim 1 , and a server device according to claim 1 or 2. Charging system for electric mobiles. An electric mobile charging system comprising an electric mobile charging device, a mobile communication terminal, and a server device,
The charging device for the electric vehicle is
User information acquisition means for acquiring user information of the mobile communication terminal;
Charger information acquisition means for acquiring charger information including individual identification information of the electric mobile charging device;
Display means for displaying a charging start code indicating information for starting charging the battery of the electric mobile body including the user information and the charger information, and a charging completion code indicating that the charging is completed;
Charging completion detecting means for detecting that the charging is completed;
A charge end work detecting means for detecting that a predetermined charge end work executed by a user of the mobile communication terminal after completion of the charge is completed;
The condition is that the elapsed time after completion of charging exceeds a predetermined time, which indicates the time from when the charging completion detection means detects completion of the charging until the charging completion work detection means detects the completion of the charging completion work. Alerting means for transmitting to the mobile communication terminal a warning signal for prompting the user to finish the charging end work;
Have
The mobile communication terminal is
Input means for inputting the charge start code and the charge completion code;
Transmitting means for transmitting the charging start code and the charging completion code input by the input means via a wireless local area network;
Have
The server device
Management information storage means for storing the user information and the charger information;
Receiving means for receiving the charging start code and the charging completion code from the mobile communication terminal;
Before starting charging the battery of the electric vehicle, the user information and the charger information stored by the management information storage means and the user information included in the charging start code received by the receiving means and The user of the portable communication terminal is authenticated by collating with charger information, and when the user is successfully authenticated, a signal for permitting the user to use the charging device for the electric mobile body is sent to the electric mobile body. Authentication means for outputting to the charging device for
A time-out obtained by adding a predetermined overuse charge to the charge for using the charging service on the condition that the elapsed time after authentication from the successful authentication of the user to the reception of the charge completion code exceeds a predetermined time Timeout payment processing means for performing payment processing;
A charging system for an electric mobile object characterized by comprising: The electric mobile charging device further includes a user information recording medium that records user information of the mobile communication terminal,
The charging system for an electric mobile body according to claim 4, wherein the user information acquisition unit acquires user information of the mobile communication terminal from the user information recording medium .

Images