JP5984753B2 - Electric vehicle charging device, charging method and charging program - Google Patents

Description

  The present invention relates to an electric vehicle charging device, a charging method, and a charging program, and more particularly to an electric vehicle charging device, a charging method, and a charging program for charging an electric vehicle.

  In recent years, electric vehicles such as an electric vehicle, a plug-in hybrid electric vehicle, and an electric two-wheeled vehicle that use at least a part of a power source as electricity and can be charged from the outside have been developed. Such an electric vehicle is charged by the electric vehicle charging device, but the charging time of the electric vehicle is sufficiently longer than the refueling time of an automobile using gasoline or light oil as a power source. In many cases, the vehicle is not near an electric vehicle while it is being charged. Therefore, there is a case where a malicious person disconnects the power feeding connector of the electric vehicle charging device from the electric vehicle being charged, and connects to the electric vehicle owned by the person to perform so-called theft.

  An anti-theft function that prevents unauthorized power supply by interrupting the power supply circuit when the connection to the electric vehicle is interrupted during power supply and a signal that is output continuously from the electric vehicle is not input. An attached power supply system is disclosed (see Patent Document 1).

  Also disclosed is an outlet device that prevents the outlet from being used on its own by the control unit generating an alarm sound from the speaker when the charging cord is disconnected while the electric vehicle is being charged. (See Patent Document 2).

JP 2012-178913 A JP 2010-055845 A

  In general, it is desired to detect theft without providing a special function to the electric vehicle. In addition, if chattering occurs when the user connects the power supply connector to the electric vehicle, or if the user reconnects the power supply connector without the power supply connector being sufficiently connected to the electric vehicle, it is not determined as theft. Is desired.

  Accordingly, an object of the present invention is to provide an electric vehicle charging device, a charging method, and such a charging method capable of suppressing theft detection while preventing theft, without providing a special function to the electric vehicle. Is to provide a charging program that causes a charging device for an electric vehicle to execute.

  An electric vehicle charging device according to an aspect of the present invention determines a power feeding unit that feeds power, a connection unit that connects the power feeding unit and the electric vehicle, and whether the connection unit is connected to or disconnected from the electric vehicle. A connection determination unit that counts the number of connections that have changed from the state in which the connection unit has been disconnected from the electric vehicle to a connected state based on the determination of the state determination unit, and the number of connections. The power supply control unit that controls the power supply unit to supply power to the electric vehicle via the connection unit only when is less than the predetermined number.

  A charging method according to an aspect of the present invention is a charging method in a charging device for an electric vehicle that includes a power feeding unit that feeds power and a connection unit that connects the power feeding unit and the electric vehicle. Based on the determination step for determining whether the vehicle is connected or disconnected, and the determination in the determination step, the number of times the connection unit has changed from the state where it is disconnected from the electric vehicle for a predetermined time or longer to the connected state A counting step for counting and a control step for controlling the power feeding unit to feed power to the electric vehicle through the connection only when the number of connections is equal to or less than a predetermined number are included.

  A charging program according to one aspect of the present invention is a charging program to be executed by a charging device for an electric vehicle that includes a power feeding unit that performs power feeding and a connection unit that connects the power feeding unit and the electric vehicle. A determination step that determines whether the vehicle is connected to or disconnected from the electric vehicle, and a connection that has changed from a state in which the connecting portion has been disconnected from the electric vehicle for a predetermined time or more to a connected state based on the determination in the determination step A counting step for counting the number of times, and a control step for controlling the power feeding unit to feed power to the electric vehicle through the connection only when the number of times of connection is equal to or less than a predetermined number, Contains instructions to be executed.

  According to the present invention, the charging device for an electric vehicle supplies power to the electric vehicle only when the number of times of connection with the electric vehicle is equal to or less than a predetermined number, and after disconnecting and reconnecting to the electric vehicle, However, if the disconnection time is less than the predetermined time, the number of connections is not incremented. Thereby, without providing a special function to the electric vehicle, the electric vehicle charging device, the charging method, and the electric vehicle charging method capable of suppressing the false detection of theft electric power while preventing theft. A charging program to be executed by the apparatus can be provided.

1 is a schematic configuration diagram of an electric vehicle charging system 1 according to an embodiment. It is a figure which shows the example of schematic structure of CPU120. 4 is a flowchart showing an example of operation of charging processing of electric vehicle 150. It is a schematic block diagram of the charging system 2 for electric vehicles according to other embodiment. It is a figure which shows the example of schematic structure of the charging device 200 for electric vehicles. It is a figure which shows the example of schematic structure of CPU220. 4 is a flowchart showing an example of operation of charging processing of electric vehicle 250. It is a flowchart which shows the example of operation | movement of a charge execution process. 3 is a diagram illustrating an example of a schematic configuration of a server device 300. FIG.

  Hereinafter, an electric vehicle charging device, a charging method, and a charging program according to an aspect of the present invention will be described with reference to the drawings. However, it should be noted that the technical scope of the present invention is not limited to these embodiments, but extends to the invention described in the claims and equivalents thereof.

  FIG. 1 is a diagram showing a schematic configuration of a charging system 1 for an electric vehicle according to the embodiment.

  As shown in FIG. 1, the electric vehicle charging system 1 includes an electric vehicle charging device 100, an electric vehicle 150, and an external power source 160. In the present embodiment, an example in which the electric vehicle charging system 1 is used for home use will be described, and the electric vehicle charging device 100 is assumed to be disposed in a parking space of a house or the like. The electric vehicle 150 is an electric vehicle, a plug-in hybrid electric vehicle, an electric two-wheeled vehicle, or the like that uses at least a part of a power source as electricity and can be charged from the outside. The external power source 160 is a power source that supplies AC power such as a household power source.

  The electric vehicle charging device 100 includes a power supply device 101, a power cable 102, a power supply cable 103, a power supply connector 104, a signal generation device 105, a signal detection device 106, and a reset device 107. Furthermore, the electric vehicle charging device 100 includes a communication device 108, an input device 109, a display device 110, a storage device 111, and a CPU (Central Processing Unit) 120. Hereinafter, each part of the charging device 100 for electric vehicles is demonstrated in detail.

  The power supply apparatus 101 is a power supply unit that supplies power to the electric vehicle 150. The power feeding apparatus 101 is connected to the external power source 160 via the power cable 102 and is connected to the power feeding connector 104 via the power feeding cable 103. The power supply apparatus 101 is a power supply unit, and supplies AC power supplied from the external power supply 160 to the power supply cable 103 side according to control by the CPU 120. The power supply apparatus 101 includes a switch that switches whether power is supplied to the power supply cable 103 side. The power supply apparatus 101 supplies power to the power supply cable 103 when the switch is in a closed state, and to the power supply cable 103 when the switch is in an open state. Does not supply power. Note that the type of power supplied by the power supply apparatus 101 is determined according to the specifications of the electric vehicle charging system 1. The power supply apparatus 101 may convert AC power supplied from the external power source 160 into DC power, and supply the converted DC power to the power supply cable 103 side.

  The power supply connector 104 is a connection unit that connects the power supply apparatus 101 and the electric vehicle 150. The power supply connector 104 is provided at one end of the power supply cable 103 (on the side opposite to the power supply apparatus 101), and is connected to the charging port of the electric vehicle 150 by the user when charging the electric vehicle 150.

  The signal generator 105 generates a control pilot signal (hereinafter referred to as a pilot signal) for communicating with the electric vehicle 150 in accordance with control by the CPU 120 and outputs the control pilot signal to the electric vehicle 150 via the power supply connector 104. The pilot signal is a signal defined by the SAE J1772 standard.

  The signal detection device 106 periodically detects the signal value (voltage value) of the pilot signal, generates a charging state signal indicating the charging state of the electric vehicle 150 based on the detected voltage value, and outputs it to the CPU 120. To do.

  Hereinafter, the pilot signal will be described. Immediately after activation of the electric vehicle charging apparatus 100, the signal generator 105 outputs a signal having a voltage value fixed at 12V as a pilot signal. On the other hand, when electrically powered vehicle 150 is connected to power supply connector 104, the voltage value of the pilot signal is reduced to 9 V using a resistor having a predetermined first resistance value. That is, when the pilot signal is a signal whose voltage value is fixed at 12V, the charging state is a state where power feeding connector 104 is not connected to electric vehicle 150 (hereinafter referred to as state A). On the other hand, when the pilot signal is a signal whose voltage value is fixed at 9 V, the charging state is a state where power feeding connector 104 is connected to electric vehicle 150 (hereinafter referred to as state B1).

  When the signal detector 106 detects that the voltage value of the pilot signal has become 9V, the signal generator 105 outputs the pilot signal as a pulse signal having a predetermined pulse width under the control of the CPU 120. The electric vehicle charging apparatus 100 notifies the electric vehicle 150 of the current amount that can be supplied by the electric vehicle charging apparatus 100 based on the pulse width of the pulse signal. That is, when the pilot signal is a pulse signal having a voltage value of 9 V, the charging state is a state in which the electric vehicle charging device 100 notifies the amount of current that can be supplied to the electric vehicle 150 (hereinafter referred to as state B2). Called).

  When electric vehicle 150 determines that the notified current amount is a usable current amount and completes preparation for charging, electric vehicle 150 reduces the voltage value of the pilot signal to 6 V using a resistor having a predetermined second resistance value. To do. When the signal detection device 106 detects that the pilot signal has become 6V, the electric vehicle charging device 100 starts to supply power to the electric vehicle 150. That is, when the pilot signal is a pulse signal having a voltage value of 6 V, the charging state is a state where the electric vehicle charging device 100 supplies power to the electric vehicle 150 (hereinafter referred to as state C).

  When the electric vehicle 150 is fully charged, the voltage value of the pilot signal is changed to 9V using the resistance having the first resistance value. When the signal detection device 106 detects that the pilot signal has become 9V (state B2), the electric vehicle charging device 100 ends the power supply to the electric vehicle 150. When power supply connector 104 is disconnected from electric vehicle 150, signal detection device 106 detects that the pilot signal has become 12V (state A), and electric vehicle charging device 100 has power supply connector 104 connected to electric vehicle 150. 150 is detected as disconnected.

  The reset device 107 includes a switch that can be operated by the user, and outputs a reset signal for resetting the number of connections described later to the CPU 120 in accordance with the operation of the user. The reset device 107 can be disposed outside the electric vehicle charging device 100 and is disposed in a house or the like so that a person other than the user who owns the electric vehicle 150 cannot operate. Note that the reset device 107 may reset the electric vehicle charging device 100 itself in response to a user operation.

  The communication device 108 includes a wired communication interface circuit for transmitting and receiving signals through a wired communication network such as a wired LAN (Local Area Network) in accordance with a communication standard such as Ethernet (registered trademark). The communication device 108 transmits and receives various types of information via a wired communication network.

  The input device 109 has an input device such as a keypad and an interface circuit that acquires signals from the input device, and outputs a signal corresponding to a user operation to the CPU 120.

  The display device 110 has a display composed of a liquid crystal and the like, and an interface circuit that outputs image data or various information to the display, and is connected to the CPU 120 to display information output from the CPU 120 on the display. Note that the input device 109 and the display device 110 may be integrally configured using a touch panel display.

  The storage device 111 includes a memory device such as a random access memory (RAM) and a read only memory (ROM), a fixed disk device such as a hard disk, or a portable storage device such as a flexible disk and an optical disk. Further, the storage device 111 stores computer programs, databases, tables, and the like used for various processes of the electric vehicle charging device 100. The computer program may be installed in the storage device 111 using a known setup program or the like from, for example, a computer-readable portable recording medium. The portable recording medium can be, for example, a CD-ROM (Compact Disk Read Only Memory), a DVD-ROM (Digital Versatile Disk Read Only Memory), or the like. In addition, the storage device 111 stores a connection counter for counting the number of connections that have changed from the state in which the power supply connector 104 is disconnected from the electric vehicle 150 for a predetermined time or longer to the connected state. Furthermore, the storage device 111 stores a state flag that stores the charge state represented by the charge state signal output from the signal detection device 106. The initial value of the connection counter is set to 0, and the initial value of the status flag is set to status A.

  The CPU 120 is connected to the power supply apparatus 101, the signal generation apparatus 105, the signal detection apparatus 106, the reset apparatus 107, the communication apparatus 108, the input apparatus 109, the display apparatus 110, and the storage apparatus 111, and controls these units. The CPU 120 performs data transmission / reception control through the communication device 108, input control of the input device 109, display control of the display device 110, control of the storage device 111, input control from the reset device 107, and the like. Furthermore, the CPU 120 monitors the charge state based on the charge state signal from the signal detection device 106, controls the signal generation device 105 according to the charge state, and supplies power to the electric vehicle 150 by the power supply device 101. Control.

  FIG. 2 is a diagram illustrating an example of a schematic configuration of the CPU 120.

  As illustrated in FIG. 2, the CPU 120 includes a state determination unit 121, a connection number counting unit 122, and a power supply control unit 123. Each of these units is a functional module implemented by software operating on the processor. Each of these units may be configured by an independent integrated circuit, a microprocessor, firmware, and the like.

  FIG. 3 is a flowchart showing an example of the operation of the charging process of the electric vehicle 150 by the electric vehicle charging device 100. Hereinafter, the operation of the charging process will be described with reference to the flowchart shown in FIG. The operation flow described below is mainly executed by the CPU 120 in cooperation with each element of the electric vehicle charging device 100 based on a program stored in the storage device 111 in advance.

  First, the state determination unit 121 determines whether or not the power supply connector 104 and the electric vehicle 150 have changed from the disconnected state to the connected state (step S101), and waits until the state changes to the connected state.

  The state determination unit 121 receives the charge state signal from the signal detection device 106 and determines whether the power supply connector 104 is connected to or disconnected from the electric vehicle 150 based on the charge state represented by the received charge state signal. . When the state of charge represents state A, state determination unit 121 determines that the current state is a disconnected state, and when the state of charge indicates a state other than state A, the state determination unit 121 determines that the current state is a connected state. . In addition, the state determination unit 121 determines that the previous state is the disconnected state when the state flag stored in the storage device 111 indicates the state A, and the previous state when the state of charge indicates a state other than the state A. It is determined that the state is a connected state. The state determination unit 121 determines that the power supply connector 104 and the electric vehicle 150 have changed from the disconnected state to the connected state when the immediately previous state is the disconnected state and the current state is the connected state. After the determination, the state determination unit 121 stores the charge state represented by the charge state signal in the state flag of the storage device 111.

  Even when the power feeding connector 104 and the electric vehicle 150 are connected when the electric vehicle charging device 100 is activated, the state determination unit 121 is disconnected because the initial value of the state flag is set to the state A. It is determined that the state has changed from the connected state.

  Next, when the power supply connector 104 and the electric vehicle 150 change from the disconnected state to the connected state, the state determination unit 121 disconnects the power supply connector 104 and the electric vehicle 150 from the predetermined time (for example, 3 seconds) or longer. It is determined whether or not (step S102).

  As will be described later, when the power supply connector 104 and the electric vehicle 150 change from the connected state to the disconnected state, the state determination unit 121 starts measuring the disconnection time. Then, when the power supply connector 104 and the electric vehicle 150 change from the disconnected state to the connected state, the state determining unit 121 ends the cutting time and calculates the cutting time. The predetermined time is sufficiently longer than the time when the chattering related to the connection of the power supply connector 104 or the short-time reconnection of the power supply connector 104 by the user occurs and the state changes from the connected state to the disconnected state and returns to the connected state. Set to Further, the predetermined time is set to a time sufficiently shorter than the time required when the power supply connector 104 is replaced from one electric vehicle to another electric vehicle.

  The state determination unit 121 considers that the disconnection time is equal to or longer than a predetermined time when the electric vehicle charging device 100 is activated and then first changes from the disconnected state to the connected state.

  Next, when the state determination unit 121 determines that the disconnection time is equal to or longer than the predetermined time, the connection number counting unit 122 increments the connection counter (step S103). The connection number counting unit 122 increments the connection counter based on the determination of the state determination unit 121, thereby changing the connection from the state where the power supply connector 104 is disconnected from the electric vehicle 150 for a predetermined time or more to the connected state. Count the number of times.

  On the other hand, when the state determination unit 121 determines that the disconnection time is less than the predetermined time, the connection number counting unit 122 does not increment the connection counter and proceeds to step S104. Therefore, when chattering related to the connection of the power supply connector 104 or a short-time reconnection of the power supply connector 104 by the user occurs, the connection counter is not incremented.

  Next, the power supply control unit 123 determines whether or not the connection counter is equal to or less than a predetermined number (step S104). The predetermined number is set to 1, for example. The predetermined number may be set to a value of 2 or more.

  Next, when determining that the connection counter exceeds the predetermined number, the power supply control unit 123 shifts the processing to step S111 without supplying power to the electric vehicle 150, while the connection counter is equal to or less than the predetermined number. If it determines, the electric power feeding to the electric vehicle 150 will be started (step S105). The power supply control unit 123 controls the power supply apparatus 101 to supply power to the electric vehicle 150 via the power supply cable 103 and the power supply connector 104 by closing the switch of the power supply apparatus 101.

  Next, when power supply to the electric vehicle 150 is started, the state determination unit 121 determines whether or not the power supply connector 104 and the electric vehicle 150 have changed from the connected state to the disconnected state (step S106).

  Whether state determination unit 121 is connected to electric vehicle 150 or disconnected based on the state of charge represented by the state of charge signal received from signal detection device 106, as in step S101. Determine. The state determination unit 121 determines that the power supply connector 104 and the electric vehicle 150 have changed from the connected state to the disconnected state when the immediately preceding state is the connected state and the current state is the disconnected state. Also in this case, the state determination unit 121 stores the state of charge represented by the state of charge signal in the state flag of the storage device 111 after the determination.

  If the state determination part 121 determines with having changed into the cutting | disconnection state, it will start time measurement of a cutting | disconnection time (step S107).

  Next, the power supply control unit 123 ends the power supply to the electric vehicle 150 (step S108), shifts the process to step S101, and waits until the connection state is changed again. The power supply control unit 123 controls the power supply apparatus 101 not to supply power to the electric vehicle 150 by opening the switch of the power supply apparatus 101.

  On the other hand, when determining in step S106 that the state has not changed to the disconnected state, the state determination unit 121 determines whether or not charging of the electric vehicle 150 has been completed (step S109).

  State determination unit 121 determines whether or not charging of electrically powered vehicle 150 is completed based on the charge state represented by the charge state signal received from signal detection device 106. If state of charge represents a state other than state C, state determination unit 121 determines that charging of electric vehicle 150 has been completed. After the determination, the state determination unit 121 stores the charge state represented by the charge state signal in the state flag of the storage device 111. In addition, the state determination unit 121 is configured to operate the power supply even when a preset power supply allowable time for each charging process elapses after the power supply control unit 123 starts power supply in step S105. It is determined that charging of vehicle 150 has been completed. On the other hand, state determination unit 121 determines that charging of electrically powered vehicle 150 has not been completed when the state of charge represents state C and the power supply available time has not elapsed since the start of power supply.

  Next, if the state determination part 121 determines with charge not being completed, it will return a process to step S106 and will repeat the process after step S106. On the other hand, when state determination unit 121 determines that charging is complete, power supply control unit 123 ends power supply to electric vehicle 150 (step S110).

  When power supply is terminated or when it is determined in step S104 that the connection counter exceeds a predetermined number, state determination unit 121 determines whether power supply connector 104 and electric vehicle 150 have changed from the connected state to the disconnected state. (Step S111). Similarly to the case of step S106, state determination unit 121 determines whether or not power supply connector 104 and electric vehicle 150 have changed from the connected state to the disconnected state, and waits until the state changes to the disconnected state.

  Next, when the power supply connector 104 and the electric vehicle 150 change from the connected state to the disconnected state, the state determining unit 121 starts measuring the disconnection time (step S112), shifts the process to step S101, and again enters the connected state. Wait until it changes.

  The connection number counting unit 122 always determines whether or not a reset signal has been received from the reset device 107 by a user's switch operation, and resets the connection counter to 0 when the reset signal is received. The user of the electric vehicle 150 can charge the electric vehicle 150 by operating the reset device 107 even when the user or another person inserts or removes the power supply connector 104 from the electric vehicle 150 by a predetermined number or more. Further, by arranging the reset device 107 in a region such as a house where other people cannot operate, it is possible to prevent reset operation by others and prevent power theft.

  In step S102, the connection number counting unit 122 does not determine whether or not the disconnection time is equal to or longer than a predetermined time, but does not connect until the connection state is changed from the previous disconnection state to the connection state. It may be determined whether the interval time is equal to or longer than a predetermined time. In this case, when the connection interval time is equal to or longer than the predetermined time, the connection number counting unit 122 increments the connection number in step S103, and does not increment the connection number when the connection interval time is less than the predetermined time. The state determination unit 121 starts measuring the connection interval time before the process of step S104, and ends measuring the connection interval time before the process of step S102. Also in this case, the connection counter is not incremented when chattering related to the connection of the power supply connector 104 or when the user reconnects the power supply connector 104 for a short time.

  As described above in detail, by operating according to the flowchart shown in FIG. 3, the electric vehicle charging device 100 supplies power to the electric vehicle only when the number of times of connection with the electric vehicle is a predetermined number or less. Even when the electric vehicle charging apparatus 100 is disconnected once and then reconnected after being connected to the electric vehicle, the number of connections is not incremented if the disconnection time is less than the predetermined time. Therefore, the number of connections is not incremented when chattering related to the connection of the power supply connector 104 or when the user reconnects the power supply connector 104 for a short time. Thereby, the charging device 100 for electric vehicles can suppress the false detection of theft while preventing theft without providing a special function to the electric vehicle.

  The electric vehicle 150 may have a timer charging function that is charged at a set time so that the electric vehicle 150 is charged at midnight when the power rate is low. In general, when the electric vehicle 150 is charged by the timer charging function, immediately after the power supply connector 104 is connected to the electric vehicle 150, advance power supply for confirming whether or not the electric vehicle 150 is ready to be charged is performed. This power supply is performed at the set time.

  Therefore, if it is determined whether or not to supply power depending on whether or not the number of times of power supply is equal to or greater than a predetermined number, a problem occurs when the timer charging function is implemented. In other words, if the predetermined number of times is 1, power is supplied in advance power supply, but power is not supplied in main power supply. On the other hand, assuming that the predetermined number of times is two times, if the power supply connector 104 is replaced from the user's electric vehicle 150 to another person's electric vehicle after the pre-power supply and before the main power supply, theft can be made. In this embodiment, since it is determined whether or not to supply power depending on whether or not the number of connections is equal to or greater than a predetermined number, it is possible to prevent theft even when the timer charging function is implemented.

  FIG. 4 is a diagram showing a schematic configuration of an electric vehicle charging system 2 according to another embodiment.

  As shown in FIG. 4, the electric vehicle charging system 2 includes an electric vehicle charging device 200, an electric vehicle 250, an external power supply 260, a server device 300, and portable terminals 400 a and 400 b. In the present embodiment, an example in which the electric vehicle charging system 2 is used for commercial purposes will be described, and the electric vehicle charging device 200 is assumed to be disposed in a parking lot or the like of a commercial facility. Electric vehicle 250 is the same vehicle as electric vehicle 150 shown in FIG. 1. The external power source 260 is a power source that supplies AC power such as a commercial power source. Server device 300 is a server that manages user authentication of electric vehicle charging system 1 and charging for electric vehicle 250 charging. The mobile terminal 400a is a mobile phone carried by a user of the electric vehicle 250, and the mobile terminal 400b is a mobile phone carried by an administrator of the electric vehicle charging device 200.

  The electric vehicle charging device 200 and the server device 300 are connected to an IP network 500 such as an intranet. The IP network 500 is connected to the mobile phone network 600 via a gateway device (not shown). The cellular phone network 600 is a network according to a communication method such as W-CDMA (Wideband Code Division Multiple Access), CDMA2000, or LTE (Long Term Evolution). The mobile terminals 400a and 400b are connected to the mobile phone network 600 through the base station device 700.

  FIG. 5 is a diagram illustrating an example of a schematic configuration of the electric vehicle charging device 200.

  As shown in FIG. 5, the electric vehicle charging device 200 includes a card reader 201 in addition to the components included in the electric vehicle charging device 100 shown in FIG. 1, and includes the CPU 120 included in the electric vehicle charging device 100. Instead, it has a CPU 220. Moreover, in the electric vehicle charging device 200, the reset device 107 is omitted from the components of the electric vehicle charging device 100.

  The card reader 201 is a card reader / writer that can read / write data from / to an IC (Integrated Circuit) card. The card reader 201 reads a user ID and a personal identification number for identifying the user from an IC card possessed by the user, and notifies the CPU 220 of the user ID. The card reader 201 reads the amount charged in the IC card from the IC card possessed by the user, notifies the CPU 220 of the amount, and writes the amount notified from the CPU 220 to the IC card. The card reader 201 is a non-contact type card reader / writer such as FeliCa (registered trademark).

  Storage device 111 stores a user address such as a mail address assigned to a user of electric vehicle 250 in association with a user ID for identifying the user. In addition, the storage device 111 supplies, for each charging process, the user ID of the charged electric vehicle, the power supply start time, the power supply end time, whether or not the power supply connector 104 is disconnected from the electric vehicle during power supply, and the power supply time. Store as history.

  FIG. 6 is a diagram illustrating an example of a schematic configuration of the CPU 220.

  As illustrated in FIG. 6, the CPU 220 includes a state determination unit 221, a connection number counting unit 222, a power supply control unit 223, an authentication processing unit 224, a charging processing unit 225, and a notification unit 226. Each of these units is a functional module implemented by software operating on the processor. Each of these units may be configured by an independent integrated circuit, a microprocessor, firmware, and the like.

  FIG. 7 is a flowchart illustrating an example of an operation of charging processing of the electric vehicle 250 by the electric vehicle charging device 200. Hereinafter, the operation of the charging process will be described with reference to the flowchart shown in FIG. The operation flow described below is executed mainly by the CPU 220 in cooperation with each element of the electric vehicle charging device 200 based on a program stored in the storage device 111 in advance.

  Initially, the authentication process part 224 performs the authentication process of the user of the electric vehicle 250 (step S201).

  The authentication processing unit 224 causes the display device 110 to display a screen requesting the user of the electric vehicle 250 to hold the IC card over the card reader 201. When the user holds the IC card over the card reader 201, the card reader 201 reads the user ID and password stored in the IC card and notifies the CPU 220 of them. Upon receiving the user ID and password from the card reader 201, the authentication processing unit 224 transmits the received user ID and password, and an authentication request for requesting user authentication, to the server device 300 via the communication device 108. .

  Note that the user of the electric vehicle 250 may input the user ID and password through the input device 109, and the authentication processing unit 224 may receive the user ID and password from the input device 109.

  The authentication processing unit 224 receives an authentication response indicating whether the user authentication is successful from the server device 300 via the communication device 108, and determines whether the user authentication is successful from the received authentication response. (Step S202).

  If the user authentication fails, the authentication processing unit 224 ends a series of steps. On the other hand, when the user authentication is successful, the connection number counting unit 222 resets the connection counter to 0 (step S203). The user of the electric vehicle 250 can charge the electric vehicle 250 by receiving authentication again even when the user or another person inserts or removes the power supply connector 104 from the electric vehicle 250 by a predetermined number or more.

  Next, the accounting processing unit 225 determines whether or not the user who has succeeded in authentication is the same as the user who has succeeded in authentication in the past (step S204).

  As will be described later, the power supply control unit 223 performs the charging process, and then the user ID of the charged electric vehicle, the power supply start time, the power supply end time, whether or not the power supply connector 104 is disconnected from the electric vehicle during power supply, and The power supply time or the like is stored in the storage device 111 as a power supply history. The billing processing unit 225 determines whether the user who has succeeded in authentication in the past depends on whether or not the user ID that has succeeded in authentication is the same as the user ID of the electric vehicle charged in the past stored in the storage device 111. It is determined whether the user is the same as the user who succeeded in authentication.

  Next, when the charging processing unit 225 determines that the user who has succeeded in authentication is the same as the user who has succeeded in authentication in the past, the power supply connector 104 during the previous power supply for the user based on the power supply history. It is determined whether or not the vehicle is disconnected from the electric vehicle (step S205).

  Next, when the charging processing unit 225 determines that the power supply connector 104 is disconnected from the electric vehicle during the previous power supply, the charge processing unit 225 reads the previous power supply end time for the user from the storage device 111. Then, the billing processing unit 225 determines whether or not the current time is within a predetermined time (for example, 10 hours) from the previous power supply end time for the user (step S206).

  Next, when the charging processing unit 225 determines that the current time is within a predetermined time from the previous power supply end time for the user, the charge processing unit 225 determines that the user from the power supply available time during which the power supply is permitted for each charging process. The remaining time obtained by subtracting the previous power supply time is calculated (step S207).

  Next, the billing processing unit 225 sets the calculated remaining time to the scheduled power feeding time for which the current power feeding is permitted (step S208), and determines not to perform billing processing for the remaining time (step S209).

  On the other hand, if it is determined in step S204 that the user who has succeeded in authentication is not the same as the user who has succeeded in authentication in the past, the charging processing unit 225 sets a preset power supply possible time as the scheduled power supply time ( Step S210). Even when it is determined in step S205 that the power supply connector 104 is disconnected from the electric vehicle during the previous power supply for the user, the charging processing unit 225 sets the power supply available time as the power supply scheduled time. The charging processing unit 225 also sets the power supply possible time as the power supply scheduled time even when it is determined in step S206 that the current time is not within the predetermined time from the previous power supply end time for the user. Next, the billing processing unit 225 determines to perform billing processing for the scheduled power supply time (step S211).

  After determining that the charging process is not executed in step S209 or after determining that the charging process is executed in step S211, the CPU 220 executes the charge execution process (step S212). Details of the charge execution process will be described later.

  Next, the power supply control unit 223 stores the user ID of the electric vehicle, the power supply start time, the power supply end time, whether or not the power supply connector 104 is disconnected from the electric vehicle during power supply, and the power supply time as a power supply history. (Step S213), and a series of steps is completed.

  The charging processing unit 225 may not execute the charging process for the remaining time only when the user who succeeds in authentication is the same as the user who succeeded in authentication last time. In this case, in step S204, the charging processing unit 225 determines whether or not the user who has succeeded in authentication is the same as the user who has succeeded in authentication last time, and if so, the process proceeds to step S205. If they are not the same, the process proceeds to step S210. Thereby, the charging device 200 for electric vehicles can be made not to perform a charging process only about the user who charges an electric vehicle continuously.

  In step S204, the charging processing unit 225 determines that the user who has succeeded in authentication is the same as the user whose previous power supply end time is within a predetermined time from the current time among the users who have succeeded in authentication in the past. It may be determined whether or not. In this case, if it is determined that they are the same, the charging processing unit 225 proceeds to step S205, and if it is determined that they are not the same, the processing proceeds to step S210. Furthermore, the billing processing unit 225 omits the process of step S206. In other words, when the charging processing unit 225 determines in step S205 that the power supply connector 104 has been disconnected from the electric vehicle during the previous power supply for the user, the process proceeds to step S207. As a result, the electric vehicle charging device 200 does not need to collate the user who has succeeded in authentication with all the users who have succeeded in authentication in the past, and the user who should not perform the billing process can be shortened in a short time. Can be detected.

  FIG. 8 is a flowchart illustrating an example of the operation of the charging execution process. The operation flow shown in FIG. 8 is executed in step S212 of the flowchart shown in FIG. Note that the processes in steps S301 to S305, S308 to S310, S313, S315 to S316 in FIG. 8 are the same as the processes in steps S101 to S105, S106 to S108, S110, and S111 to S112 in FIG. However, in the flowchart of FIG. 8, the state determination unit 221 executes the process executed by the state determination unit 121 in the flowchart of FIG. 3, and the connection number counter 222 executes the process executed by the connection number counter 122. The process executed by the control unit 123 is executed by the power supply control unit 223. Hereinafter, the description of the processes of steps S301 to S305, S308 to S310, S313, S315 to S316 will be omitted, and only the processes of S306 to S307, S311, S312 and S314 will be described.

  In step S305, when the power supply control unit 123 starts supplying power to the electric vehicle 150, the charging processing unit 225 determines whether or not to execute the charging process (step S306). The charging processing unit 225 determines whether or not to execute the charging process according to the result determined in steps S209 and S211 of the flowchart shown in FIG.

  If the billing processing unit 225 determines to perform billing processing in step S211, the billing processing unit 225 performs billing processing according to the power supply available time (step S307).

  Billing processing unit 225 causes display device 110 to display a screen requesting the user of electric vehicle 250 to hold the IC card over card reader 201. When the user holds the IC card over the card reader 201, the card reader 201 reads the charged amount from the IC card and notifies the CPU 220 of charge amount information indicating the charged amount. When the charge processing unit 225 receives charge amount information from the card reader 201, the charge processing unit 225 transmits the received charge amount information and a charge processing request for requesting a charge process to the server device 300 via the communication device 108.

  When the charge processing unit 225 receives the difference information indicating the difference obtained by subtracting the amount corresponding to the power supply available time from the amount indicated in the charge amount information from the server device 300 via the communication device 108, the amount indicated in the difference information To the card reader 201. The card reader 201 writes the amount notified from the charging processing unit 225 to the IC card.

  Instead of requesting the accounting process to the server device 300, the accounting processing unit 225 calculates an amount obtained by subtracting an amount corresponding to the power supply available time from the amount indicated in the charge amount information, and the calculated amount is used as a card reader. 201 may be notified.

  In addition, the electric vehicle charging system 2 may execute the charging process using a credit card or the like instead of executing the charging process using an IC card charged in advance. In that case, the card reader 201 is a magnetic card reader capable of reading a credit card. The electric vehicle charging device 200 transmits the card number, security code, and the like read from the credit card by the card reader 201 to the server device 300 via the communication device 108. The server device 300 executes the charging process by notifying the credit card settlement server (not shown) of the received card number, security code, and the like and the amount corresponding to the power supply available time. In this case, the user authentication process may also be executed using a card number read from a credit card, a security code, or the like.

  On the other hand, if it is determined in step S209 that the charging process is not performed for the remaining time, the charging processing unit 225 does not perform the charging process for the remaining time, and the process proceeds to step S308. This prevents the user of the electric vehicle 250 from being damaged regarding the charging fee when the electric power supply cable is disconnected during charging of the electric vehicle 250 and charging is performed again.

  In step S310, when the power supply control unit 223 finishes supplying power to the electric vehicle 250, the notification unit 226 sets the user address stored in the storage device 111 in association with the user ID that has been successfully authenticated in step S201. Notification is made (step S311). The notification unit 226 transmits, via the communication device 108, an e-mail addressed to the user address indicating that the power supply to the electric vehicle 150 is terminated by disconnecting the power supply connector 104 from the electric vehicle 150.

  The user of the electric vehicle 250 can recognize that another person has disconnected the power supply connector 104 from the electric vehicle 250 during charging of the electric vehicle 250 by receiving an e-mail from the mobile terminal 400a. Therefore, the user can quickly return to the parking lot, reinsert the power feeding connector 104 into the electric vehicle 250, and charge the electric vehicle 250 again. When the user tries to use the electric vehicle 250, the user is fully charged. The situation that is not done can be prevented. Thus, the electric vehicle charging system 2 can shorten the non-feed time as much as possible.

  Note that the notification unit 226 does not notify immediately after the power supply connector 104 is disconnected from the electric vehicle 250 but may also notify when the connection counter is not reset even after a predetermined time (for example, 1 hour) has elapsed. Good. In that case, the notification unit 226 stores in the storage device 111 the fact that the power supply connector 104 is disconnected from the electric vehicle 250 and the time thereof in step S311 instead of performing the notification. The notification unit 226 determines whether or not the connection counter has been reset and whether or not a predetermined time has elapsed from the time stored in the storage device 111 before the authentication processing in step S201 in FIG. If a predetermined time has not passed, notification is made. When the user performs re-authentication immediately after the power feeding connector 104 is disconnected from the electric vehicle 250, the notification is not performed, so that it is possible to prevent the user from feeling troublesome by the notification.

  If state determination unit 221 determines in step S308 that the state has not changed to the disconnected state, state determination unit 221 determines whether or not charging of electric vehicle 250 has been completed (step S312). The state determination unit 221 charges the electric vehicle 250 when the charge state represented by the charge state signal received from the signal detection device 106 represents a state other than the state C, or when the scheduled power supply time has elapsed since the start of power supply. Is determined to be complete. On the other hand, state determination unit 221 determines that charging of electrically powered vehicle 250 has not been completed when the state of charge represents state C and the power supply scheduled time has not elapsed since the start of power supply.

  In step S304, when the power supply control unit 223 determines that the connection counter exceeds the predetermined number, the notification unit 226 stores the user stored in the storage device 111 in association with the user ID that has been successfully authenticated in step S201. The address is notified (step S314). The notification unit 226 transmits an e-mail addressed to the user address indicating that the connection counter has exceeded a predetermined number via the communication device 108.

  The user of the electric vehicle 250 can recognize that he / she can no longer charge the electric vehicle 250 by inserting / removing the power supply connector 104 from the electric vehicle 250 by a predetermined number or more by receiving an e-mail from the portable terminal 400a. .

  Note that the number of times of connection may be reset according to an operation via the reset device 107 as in the case of the electric vehicle charging device 100. In this case, the electric vehicle charging device 200 includes a reset device 107, and the reset device 107 is disposed in an area that can be operated only by an administrator of the electric vehicle charging device 200 having the authority to reset the number of connections. The connection number counting unit 222 always determines whether or not a reset signal has been received from the reset device 107 by a user's switch operation, and resets the connection counter to 0 when the reset signal is received. In that case, the reset process of the number of connections according to the result of the user authentication process shown in step S203 of the flowchart of FIG. 7 may be omitted.

  Further, in steps S311 and S314, the notification unit 226 notifies the administrator address such as the mail address assigned to the administrator of the electric vehicle charging device 200, instead of the user address, via the communication device 108. Also good. In this case, the storage device 111 stores an administrator address. As a result, the administrator can recognize that the power supply connector 104 has been disconnected from the electric vehicle 250 due to power theft, mischief, etc., and take measures such as strengthening the security of the parking lot as necessary. Can do. Further, if the administrator has the authority to reset the number of connections, the connection counter can be reset immediately.

  Note that the notification unit 226 may notify both the user address and the administrator address via the communication device 108. Thus, the administrator confirms whether the user of the electric vehicle 250 has an operation error related to the connection between the power supply connector 104 and the electric vehicle 250 or whether the power supply connector 104 and the electric vehicle 250 are disconnected during charging. The connection counter can be reset.

  FIG. 9 is a diagram illustrating an example of a schematic configuration of the server device 300.

  As illustrated in FIG. 9, the server device 300 includes a server communication device 301, a server input device 302, a server display device 303, a server storage device 304, and a server CPU 320. Hereinafter, each part of the server apparatus 300 will be described in detail.

  Server communication apparatus 301 has an interface circuit similar to communication apparatus 108 of electric vehicle charging apparatus 100, and connects server apparatus 300 and IP network 500.

  The server input device 302 includes an input device such as a keyboard and a mouse, and an interface circuit that acquires signals from the input device, and outputs a signal corresponding to a user operation to the CPU 320.

  The server display device 303 has a display composed of liquid crystal and the like, and an interface circuit that outputs image data or various types of information to the display, and is connected to the CPU 320 to display information output from the CPU 320 on the display. Note that the server input device 302 and the server display device 303 may be integrally configured using a touch panel display.

  The server storage device 304 includes a memory device, a fixed disk device, a portable storage device, and the like similar to the storage device 111 of the electric vehicle charging device 100. The server storage device 304 stores computer programs, databases, tables, and the like used for various processes of the server device 300. In addition, the server storage device 304 stores a user ID and a password for each user registered in advance in the electric vehicle charging system 2 and stores an amount corresponding to a power supply possible time.

  Server CPU 320 operates based on a program stored in server storage device 304 in advance. The server CPU 320 is connected to the server communication device 301, the server input device 302, the server display device 303, and the server storage device 304, and controls these units. The server CPU 320 performs data transmission / reception control with the electric vehicle charging device 100 via the server communication device 301, input control of the server input device 302, display control of the server display device 303, control of the server storage device 304, and the like.

  When the server CPU 320 receives the user ID, password, and authentication request from the electric vehicle charging device 100 via the server communication device 301, the server CPU 320 stores the received user ID and password in the server storage device 304 and the user ID stored in the server storage device 304. Check with your PIN. The server CPU 320 determines that the authentication is successful when the received user ID and password match any one of the user ID and password stored in the server storage device 304. On the other hand, if the received user ID and password do not match any of the user ID and password stored in the server storage device 304, the server CPU 320 determines that the authentication has failed. Then, server CPU 320 transmits an authentication response indicating whether or not the user has been successfully authenticated to electric vehicle charging apparatus 100 via server communication apparatus 301.

  Further, when the server CPU 320 receives the charge amount information and the billing processing request from the electric vehicle charging device 100 via the server communication device 301, the server CPU 320 calculates the amount corresponding to the power supply possible time from the amount indicated in the received charge amount information. Calculate the reduced difference. Server CPU 320 transmits difference information indicating the calculated difference to electric vehicle charging apparatus 100 via server communication apparatus 301.

  As described above in detail, by operating according to the sequence diagrams shown in FIGS. 7 and 8, the electric vehicle charging device 200 is requested to be charged again by the same user even when the cable is disconnected during charging. When it does, the billing process is not executed for the remaining time. Therefore, the user of the electric vehicle can charge the electric vehicle again without being damaged even if the power feeding cable is pulled out by another person during charging of the electric vehicle.

  Moreover, since the charging device 200 for electric vehicles does not execute the charging process for the remaining time only within a predetermined time from the previous power supply end time, the user intentionally disconnects the power supply cable and stops charging the electric vehicle. An attempt to receive power for the remaining time can be prevented.

  The preferred embodiments of the present invention have been described above, but the present invention is not limited to these embodiments. For example, in steps S <b> 311 and S <b> 314, the electric vehicle charging device 200 notifies the user by lighting an unillustrated lighting device, ringing a buzzer, or the like instead of or in addition to sending an e-mail. Also good.

  Moreover, in steps S311 and S314, the electric vehicle charging device 200 may transmit an email to the user's mobile terminal instead of transmitting the email to the user's mobile terminal. In that case, the electric vehicle charging device 200 requests the server device 300 to transmit an e-mail to the user's mobile terminal. The server device 300 stores a user address in the server storage device 304 in association with each user's user ID, and transmits an e-mail to the user's portable terminal in accordance with a request from the electric vehicle charging device 200.

DESCRIPTION OF SYMBOLS 1, 2 Electric vehicle charging system 100, 200 Electric vehicle charging device 101 Power feeding device 104 Power feeding connector 107 Reset device 111 Storage device 121, 221 State determination unit 122, 222 Connection frequency counting unit 123, 223 Power feeding control unit 224 Authentication processing Unit 225 accounting processing unit 226 notification unit

Claims (9)

A power supply unit for supplying power;
A connecting portion for connecting the power feeding portion and the electric vehicle;
A state determination unit for determining whether the connection unit is connected to or disconnected from the electric vehicle;
Based on the determination of the state determination unit, the connection number counting unit that counts the number of connections changed from the state in which the connection unit is disconnected from the electric vehicle for a predetermined time or more to the connected state;
Only when the number of times of connection is a predetermined number or less, a power supply control unit that controls the power supply unit to supply power to the electric vehicle via the connection unit;
A charging device for an electric vehicle comprising: A billing processing unit that executes billing processing according to the power supply possible time;
An authentication processing unit that executes an authentication process of the user of the electric vehicle,
When the user who has succeeded in the authentication process is the same as the user who has succeeded in authentication in the past, the billing processing unit calculates a remaining time obtained by subtracting the previous power supply time for the user from the power supply possible time. The charging device for an electric vehicle according to claim 1, wherein the charging is calculated and the charging process is not executed for the remaining time.   3. The electric vehicle according to claim 2, wherein the charging processing unit does not execute the charging process for the remaining time only within a predetermined time from a previous power supply end time for a user who has succeeded in the authentication process. Charging device.   The charge processing unit does not execute the charge processing for the remaining time only when a user who has succeeded in the authentication process is the same as a user who has succeeded in authentication last time. Electric vehicle charging device.   The electric vehicle charging device according to any one of claims 2 to 4, wherein the connection number counting unit resets the number of connections when authentication is successful in the authentication process. A reset unit that can be arranged outside the electric vehicle charging device and outputs a reset signal according to a user operation,
The electric vehicle charging device according to any one of claims 1 to 5, wherein the connection number counting unit resets the connection number when the reset signal is received. A communication department;
A storage unit for storing a user address of the electric vehicle and an administrator address having authority to reset the number of connections;
The electric motor according to any one of claims 1 to 6, further comprising a notification unit that notifies the user address or the administrator address via the communication unit when the number of connections exceeds the predetermined number. Vehicle charging device. A charging method in a charging device for an electric vehicle having a power supply unit that supplies power and a connection unit that connects the power supply unit and the electric vehicle,
A determination step of determining whether the connection portion is connected to or disconnected from the electric vehicle;
Based on the determination in the determination step, a counting step of counting the number of connections that have changed from the state in which the connection unit is disconnected from the electric vehicle for a predetermined time or more to the connected state;
Only when the number of times of connection is equal to or less than a predetermined number, a control step for controlling the power supply unit to supply power to the electric vehicle via the connection unit;
The charging method characterized by including. A charging program to be executed by a charging device for an electric vehicle having a power supply unit that supplies power and a connection unit that connects the power supply unit and the electric vehicle,
A determination step of determining whether the connection portion is connected to or disconnected from the electric vehicle;
Based on the determination in the determination step, a counting step of counting the number of connections that have changed from the state in which the connection unit is disconnected from the electric vehicle for a predetermined time or more to the connected state;
Only when the number of times of connection is equal to or less than a predetermined number, a control step for controlling the power supply unit to supply power to the electric vehicle via the connection unit;
Including a command for causing the charging device for an electric vehicle to execute.

Images