JPWO2013054387A1 - VEHICLE CHARGE CONTROL DEVICE AND VEHICLE HAVING THE SAME - Google Patents

Abstract

  The charger (24) is configured to charge the power storage device (12). The ECU (28) is configured to control charging of the power storage device by the charger. The ECU operates in the sleep mode in which power consumption is suppressed compared to the wake-up mode in which charge control is being executed before the pilot signal (CPLT) is detected when the power storage device is not being charged. After the charging of the device is completed, the operation is performed in the intermittent activation mode in which the wait mode and the wake-up mode are periodically switched until it is detected that the pilot signal oscillation is stopped.

Description

  The present invention relates to a vehicle charge control device and a vehicle including the same, and more particularly, to a vehicle charge control device configured to be able to charge a power storage device mounted on the vehicle by a power supply external to the vehicle and a vehicle including the same.

  In recent years, electric vehicles and hybrid vehicles have attracted attention as environmentally friendly vehicles. These vehicles are equipped with an electric motor that generates a driving force for driving and a power storage device that stores electric power supplied to the electric motor. A hybrid vehicle is a vehicle in which an internal combustion engine is further mounted as a power source together with an electric motor.

  In such a vehicle, a vehicle is known in which the power storage device can be charged by a power source external to the vehicle (hereinafter also referred to as “external power source”, and charging of the power storage device by the external power source is also referred to as “external charging”). For example, by connecting a power outlet provided in a house and a charging port provided in a vehicle with a charging cable, electric power is supplied from the power supply of a general household to the power storage device. In the following, a vehicle that can charge the power storage device mounted on the vehicle by a power supply outside the vehicle is also referred to as a “plug-in vehicle”.

  Japanese Patent Laying-Open No. 2009-171733 (Patent Document 1) discloses such a plug-in vehicle that uses a pilot signal CPLT generated in a control pilot circuit provided in a charging cable as an activation signal for a vehicle charging system. A control device is disclosed. This pilot signal CPLT is originally used for judging on the vehicle side the connection state of the charging cable, the possibility of power supply from the external power source to the vehicle, the rating of the charging current, etc. The charging control device uses the pilot signal CPLT as a starting signal for the charging system (see Patent Document 1).

JP 2009-171733 A JP 2010-148213 A

  When pilot signal CPLT is used as a system activation signal at the time of external charging, dark current increases in the vehicle in order to detect the input of pilot signal CPLT. Dark current is standby current consumed while the vehicle system is stopped. When the dark current increases, the voltage of the battery decreases while the vehicle system is stopped, which adversely affects various system operations.

  The charging control device described in Patent Document 1 is useful in that the pilot signal CPLT generated in the charging cable can be used as a start signal of the charging system, but the darkness that can be increased to detect the input of the pilot signal CPLT. A method for reducing the current is not particularly studied.

  SUMMARY OF THE INVENTION Therefore, an object of the present invention is to reduce dark current associated with external charging in a vehicle charging control apparatus configured to be capable of external charging of a power storage device mounted on the vehicle.

  According to the present invention, a vehicle charge control device is a vehicle charge control device configured to be able to charge a power storage device mounted on a vehicle with an external power source, and includes the charge device and the control device. The charging device is configured to charge the power storage device. The control device is configured to control charging of the power storage device by the charging device. The control device consumes compared to the normal mode during the execution of the charge control before the predetermined first signal indicating the intention of the charge request by the user is detected when the power storage device is not charged. The sleep mode and the normal mode are operated until a predetermined second signal indicating that the user intends to end the charging is detected after the charging of the power storage device is completed and the battery is operated. Operates in switched intermittent start mode.

  Preferably, before the first signal is detected, the control device operates in the first sleep mode (sleep mode) in which the main clock is stopped and the first signal is accepted as a hardware interrupt, and in the intermittent activation mode. Periodically switches between the second sleep mode (wait mode) in which the main clock is operated and the normal mode (wake-up mode).

  More preferably, when the first signal is detected during the first pause mode, the control device shifts to the normal mode, and when charging of the power storage device is completed, the control device shifts to the intermittent activation mode, and the second signal Is detected, the first sleep mode is entered.

  Preferably, the first signal is a pilot signal (CPLT, S1) input to the vehicle when a charging cable for transmitting power from an external power source to the vehicle is connected to the vehicle.

  Preferably, the first signal is a signal (PISW, C) indicating that a charging cable for transmitting power from an external power source to the vehicle is connected to the vehicle.

  Preferably, the first signal is a signal indicating that the lid of the vehicle to which the charging cable for transmitting power from the external power source to the vehicle is connected has been opened.

  Preferably, when a charging cable for transmitting power from an external power source to the vehicle is connected to the vehicle, a pilot signal is input to the vehicle. The second signal is a non-oscillating or non-input pilot signal (CPLT, S1).

  Preferably, the second signal is a signal (PISW, C) indicating that a charging cable for transmitting power from an external power source to the vehicle is not connected to the vehicle.

  Preferably, the second signal is a signal indicating that the lid of the vehicle to which the charging cable for transmitting power from the external power source to the vehicle is connected is in a closed state.

  According to the invention, the vehicle includes any of the above-described charging control device for the vehicle and a power storage device that is charged by the charging control device.

  In the present invention, when charging of the power storage device is not executed, before the first predetermined signal indicating the intention of the user to request charging is detected, the control device enters the normal mode during execution of charging control. It operates in a sleep mode in which power consumption is suppressed as compared with it. On the other hand, after the charging of the power storage device is completed, the control device is in an intermittent start mode in which the sleep mode and the normal mode are switched until a predetermined second signal indicating the user's intention to end the charging is detected. Works with. Thus, the control device operates in an appropriate power saving mode by distinguishing between a state before the first signal is detected and a state before the second signal is detected after the end of charging.

  Therefore, according to the present invention, dark current associated with external charging can be reduced in a vehicle charge control device configured to be able to externally charge a power storage device mounted on the vehicle.

1 is an overall block diagram of a vehicle to which a charge control device according to Embodiment 1 of the present invention is applied. It is a functional block diagram of ECU shown in FIG. It is the figure which showed transition of the operation mode of ECU. It is an equivalent circuit diagram of a control pilot circuit formed by a CPLT control circuit and an ECU. It is a wave form diagram of a pilot signal. It is the figure which showed the opening / closing detection circuit of the lid of an inlet. It is the figure which showed the charge switch for a user to instruct | indicate the start and completion | finish of external charging. FIG. 5 is an overall block diagram of a vehicle to which a charge control device according to a second embodiment is applied. It is a functional block diagram of ECU shown in FIG.

  Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings. In the drawings, the same or corresponding parts are denoted by the same reference numerals and description thereof will not be repeated.

[Embodiment 1]
1 is an overall block diagram of a vehicle to which a charging control apparatus according to Embodiment 1 of the present invention is applied. Referring to FIG. 1, vehicle 10 includes a power storage device 12, a system main relay (hereinafter referred to as “SMR (System Main Relay)”) 14, a power control unit (hereinafter referred to as “PCU (Power Control Unit)”). 16), a power output device 18, and a drive wheel 20. The vehicle 10 further includes an inlet 22, a charger 24, a charging relay 26, and an electronic control device (hereinafter referred to as “ECU (Electronic Control Unit)”) 28.

  An external power supply 30, an EVSE (Electric Vehicle Supply Equipment) 32, and a connector 38 are provided outside the vehicle 10. The EVSE 32 includes a CCID (Charging Circuit Interrupt Device) 34 and a CPLT control circuit 36.

  The power storage device 12 is a rechargeable DC power supply, and is constituted by, for example, a secondary battery such as nickel metal hydride or lithium ion. The power storage device 12 stores power generated by the power output device 18 in addition to power supplied from the external power supply 30. Note that a large-capacity capacitor can also be employed as the power storage device 12. SMR 14 is provided between power storage device 12 and PCU 16. SMR 14 is a relay for electrically connecting / disconnecting power storage device 12 and PCU 16.

  The PCU 16 collectively represents a power conversion device that receives power from the power storage device 12 and drives the power output device 18. For example, PCU 16 includes an inverter for driving a motor included in power output device 18, a converter for boosting the power output from power storage device 12, and the like. The power output device 18 collectively shows devices for driving the drive wheels 20. For example, the power output device 18 includes a motor and an engine that drive the drive wheels 20. The power output device 18 generates power when the vehicle is braked by a motor that drives the drive wheels 20 and outputs the generated power to the PCU 16.

  The external power supply 30 is constituted by a commercial system power supply, for example. The EVSE 32 is configured to be able to cut off an electric circuit for supplying electric power from the external power supply 30 to the vehicle 10. The EVSE 32 is provided, for example, in a charging cable for supplying electric power from the external power supply 30 to the vehicle 10 or in a charging stand for supplying electric power to the vehicle 10 via the charging cable. The CCID 34 is a circuit breaker provided in a power supply path from the external power supply 30 to the vehicle 10, and is controlled by the CPLT control circuit 36.

  The CPLT control circuit 36 generates a pilot signal CPLT for exchanging predetermined information between the EVSE 32 and the vehicle 10 during external charging, and outputs the pilot signal CPLT to the vehicle 10 via the control pilot line. The potential of pilot signal CPLT is manipulated in vehicle 10, and CPLT control circuit 36 controls CCID 34 based on the potential of pilot signal CPLT. That is, the CCID 34 can be remotely operated from the vehicle 10 by operating the potential of the pilot signal CPLT in the vehicle 10. The pilot signal CPLT conforms to, for example, “SAE J1772 (SAE Electric Vehicle Conductive Charge Coupler)” in the United States.

  The inlet 22 is configured to be connectable to a connector 38 of a charging cable for supplying electric power from the external power supply 30 to the vehicle 10. Then, when the power storage device 12 is externally charged by the external power supply 30, the inlet 22 receives power supplied from the external power supply 30.

  The charger 24 is connected to a positive line PL and a negative line NL disposed between the SMR 14 and the PCU 16 via a charging relay 26. The charger 24 includes a switching element for power conversion, and converts the power supplied from the external power supply 30 into a predetermined charging voltage (direct current) based on a control signal from the ECU 28. The power converted into voltage by the charger 24 is supplied to the power storage device 12 via the charging relay 26, and the power storage device 12 is charged. Charging relay 26 is provided between charger 24 and power storage device 12, and electrically connects / disconnects charger 24 and power storage device 12 based on signal EN from ECU 28.

  The ECU 28 controls the charger 24 and the charging relay 26 by software processing by executing a program stored in advance by a CPU (Central Processing Unit) and / or hardware processing by a dedicated electronic circuit. The ECU 28 performs an on / off operation of the CCID 34 of the EVSE 32 during external charging. Specifically, ECU 28 operates CCID 34 remotely by operating the potential of pilot signal CPLT received from EVSE 32. Then, the ECU 28 generates a start / stop command for the charger 24, a power command indicating a target value of the charging power, and the like and outputs the generated power command to the charger 24.

  Here, the ECU 28 can operate in the following three operation modes, that is, the wake-up mode, the sleep mode, and the intermittent activation mode. The wake-up mode is a state in which the ECU 28 is completely activated, and the ECU 28 is in the wake-up mode when starting and executing external charging. The sleep mode is a state in which the ECU 28 is stopped when external charging is not performed. In the sleep mode, the main clock in the ECU 28 is also stopped, and power consumption is suppressed compared to the wake-up mode. The intermittent activation mode is an operation mode when the charging cable is still connected after the end of external charging. In the intermittent activation mode, the wait mode and the wake-up mode are alternately switched periodically. The wait mode is a state in which the ECU 28 is stopped as in the sleep mode, but the main clock in the ECU 28 operates. Thereby, it is possible to periodically switch to the wake-up mode. In the sleep mode and the wait mode, the power consumption is smaller in the sleep mode because the main clock is stopped.

  Before the input of pilot signal CPLT is detected, ECU 28 enters a sleep mode. When the input of pilot signal CPLT is detected in the sleep mode, ECU 28 enters a wake-up mode. Specifically, the main clock of the ECU 28 is stopped during the sleep mode, and the ECU 28 receives the pilot signal CPLT as a hard interrupt. When the rising (or falling) of pilot signal CPLT is detected, the operation mode shifts from the sleep mode to the wake-up mode, and ECU 28 is activated. The pilot signal CPLT is a signal that is input to the vehicle 10 when the charging cable connector 38 is connected to the inlet 22 and can be regarded as a signal that indicates the intention of the user to request charging.

  When the external charging is completed (the charging cable is still connected), the ECU 28 enters the intermittent activation mode. In the intermittent activation mode, the main clock is operating even during the wait mode in the hibernation state, the ECU 28 is periodically activated, and the pilot signal CPLT is monitored in order to detect resumption of external charging, disconnection of the charging cable, and the like. .

  During the connection of the charging cable, the pilot signal CPLT oscillates as described later. When the oscillation stop of pilot signal CPLT is detected, it is determined that the charging cable is disconnected from vehicle 10 (or the power failure of external power supply 30), and ECU 28 enters the sleep mode. As a result, the activation condition (wake-up mode transition condition) of the ECU 28 is switched from periodic intermittent activation to interrupt detection of the pilot signal CPLT. Since the oscillation of pilot signal CPLT stops when the charging cable is disconnected from vehicle 10, non-oscillating pilot signal CPLT can be regarded as a signal indicating the user's intention to end charging.

  FIG. 2 is a functional block diagram of ECU 28 shown in FIG. Referring to FIG. 1 together with FIG. 2, ECU 28 includes a charge control unit 52, an operation mode control unit 54, and a main clock 56. Charging control unit 52 receives pilot signal CPLT, cable connection signal PISW, and detected values of voltage VAC and current IAC of power supplied from external power supply 30. Voltage VAC and current IAC are detected by a voltage sensor and a current sensor not shown, respectively. In addition, the charging control unit 52 receives a clock signal from the main clock 56. Based on these signals, the charging control unit 52 generates a signal EN for driving the charging relay 26 and a signal DRV for driving the charger 24, and the generated signals EN, DRV Are output to the charging relay 26 and the charger 24, respectively. In addition, the charging control unit 52 notifies the operation mode control unit 54 of the external charging execution status (at least external charging is being executed / not being executed).

  Operation mode control unit 54 receives pilot signal CPLT and cable connection signal PISW. Further, the operation mode control unit 54 receives the execution status of external charging from the charge control unit 52 and receives a clock signal from the main clock 56. The operation mode control unit 54 controls the operation mode of the ECU 28 based on these signals.

  FIG. 3 is a diagram showing the transition of the operation mode of the ECU 28. Referring to FIG. 2 together with FIG. 3, initially, the operation mode is assumed to be a sleep mode. In the sleep mode, no operation command is output from the operation mode control unit 54 to the main clock 56, and the main clock 56 stops. The operation mode control unit 54 is waiting for a hardware interrupt of the pilot signal CPLT.

  When the charging cable connector 38 is connected to the inlet 22 and a hardware interrupt of the pilot signal CPLT output from the EVSE 32 is detected, the operation mode control unit 54 shifts the operation mode to the wake-up mode and transfers to the main clock 56. An operation command is output.

  When the external charging is started by the charging control unit 52 and then the end of the external charging is notified from the charging control unit 52 to the operation mode control unit 54, the operation mode control unit 54 determines whether the wait mode and the wake-up mode are periodically set. The operation mode is shifted to the intermittent start mode that is alternately switched. Thereby, the ECU 28 is intermittently started periodically, and the state of the pilot signal CPLT is periodically monitored.

  Thereafter, when the connector 38 of the charging cable is disconnected from the inlet 22 or the oscillation of the pilot signal CPLT is stopped due to a power failure of the external power supply 30, the operation mode control unit 54 shifts the operation mode of the ECU 28 to the sleep mode. . As a result, the main clock 56 is also stopped, and the operation mode control unit 54 again waits for a hard interrupt of the pilot signal CPLT.

  As described above, in the first embodiment, when external charging is not performed, the ECU 28 enters the sleep mode before the input of the pilot signal CPLT generated by the CPLT control circuit 36 of the EVSE 32 is detected, thereby suppressing power consumption. Is done.

  When charging cable connector 38 is connected to inlet 22 and a hard interrupt of pilot signal CPLT is detected, ECU 28 enters a wake-up mode, and external charging is performed after a predetermined charging execution condition is satisfied. After the end of the external charging, the ECU 28 is in the intermittent start mode until the pilot signal CPLT is stopped due to disconnection of the charging cable or a power failure of the external power supply 30, and the state of the pilot signal CPLT is changed. Power consumption is suppressed while regularly monitoring.

  When it is detected that the pilot signal CPLT has stopped oscillating, it is determined that the charging cable has been disconnected or that the external power source 30 has failed, and the ECU 28 enters a sleep mode.

  FIG. 4 is an equivalent circuit diagram of a control pilot circuit formed by the CPLT control circuit 36 and the ECU 28. Referring to FIG. 4, CPLT control circuit 36 outputs pilot signal CPLT to ECU 28 of the vehicle via connector 38 and inlet 22. The pilot signal CPLT essentially notifies the current value (rated current) of the charging cable to the ECU 28 of the vehicle, and the CCID 34 (FIG. 1) is sent from the ECU 28 based on the potential of the pilot signal CPLT operated by the ECU 28. It is a signal for remote control. Then, the CPLT control circuit 36 controls the CCID 34 based on the potential change of the pilot signal CPLT.

  The CPLT control circuit 36 includes an oscillator 70, a resistance element R1, and a voltage sensor 72. The oscillator 70 generates a pilot signal CPLT that oscillates at a specified frequency (for example, 1 kHz) and a predetermined duty ratio. Voltage sensor 72 detects the potential of pilot signal CPLT.

  Oscillator 70 generates non-oscillating pilot signal CPLT when the potential of pilot signal CPLT detected by voltage sensor 72 is near a prescribed potential V1 (for example, 12 V). Further, when the potential of pilot signal CPLT drops from V1, oscillator 70 generates pilot signal CPLT that oscillates at a prescribed frequency and a predetermined duty ratio.

  The potential of pilot signal CPLT is manipulated by switching the resistance value in resistance circuit 80 of ECU 28 as will be described later. The duty ratio is set based on a predetermined allowable current value of the charging cable. Then, when the potential of pilot signal CPLT decreases to around a prescribed potential V3 (for example, 6V), CPLT control circuit 36 turns on CCID 34. The CPLT control circuit 36 operates by receiving electric power supplied from the external power supply 30 (FIG. 1).

  On the other hand, on the vehicle side, ECU 28 includes a resistance circuit 80, a CPU (Control Processing Unit) 82, and a power supply 84. Resistor circuit 80 includes pull-down resistors R2 and R3 and a switch SW. Pull-down resistor R2 is connected between control pilot line L1 through which pilot signal CPLT is communicated and vehicle ground. The pull-down resistor R3 and the switch SW are connected in series and are connected in parallel to the pull-down resistor R2. The switch SW is turned on / off according to a control signal from the CPU 82.

  Resistor circuit 80 manipulates the potential of pilot signal CPLT. Specifically, when connector 38 is connected to inlet 22, resistance circuit 80 lowers the potential of pilot signal CPLT to a prescribed potential V2 (for example, 9V) by pull-down resistor R2. When the preparation for charging is completed in the vehicle, the switch SW is turned on by the CPU 82, and the resistance circuit 80 reduces the potential of the pilot signal CPLT to the specified potential V3 by the pull-down resistors R2 and R3. Thus, by operating the potential of pilot signal CPLT using resistance circuit 80, CCID 34 can be remotely operated from ECU 28.

  The connector 38 is provided with a limit switch 74. When the inlet 22 and the connector 38 are connected, the signal line L3 and the ground line L2 are connected to both ends of the limit switch 74. A voltage is applied to the signal line L3 from the power source 84. When the connector 38 is connected to the inlet 22, the limit switch 74 is turned on, so that the potential of the signal line L3 becomes the ground level. The cable connection signal PISW is a signal whose logic state changes according to the voltage level of the signal line L3.

  When the CPU 82 receives the pilot signal CPLT as a hard interrupt during the sleep mode, the CPU 82 enters the wake-up mode. When connector 38 is connected to inlet 22, the potential of pilot signal CPLT drops from V1 to V2, and pilot signal CPLT oscillates. Then, CPU 82 detects the allowable current value of the charging cable based on the duty ratio of pilot signal CPLT.

  When the allowable current value of the charging cable is detected and the power storage device 12 (FIG. 1) is ready for charging, the CPU 82 turns on the switch SW. As a result, the potential of pilot signal CPLT drops to V3, and CCID 34 is turned on in EVSE32. Thereafter, the CPU 82 turns on the charging relay 26 (FIG. 1) and drives the charger 24.

  FIG. 5 is a waveform diagram of pilot signal CPLT. Referring to FIG. 4 together with FIG. 5, it is assumed that connector 38 is not connected to inlet 22 before time t1. At this time, the CPU 82 (ECU 28) is in the sleep mode, and the pilot signal CPLT is in the non-oscillating state at the potential V1.

  When connector 38 is connected to inlet 22 at time t1, pilot signal CPLT is input to CPU 82. When the CPU 82 detects a hardware interrupt of the pilot signal CPLT, the CPU 82 enters a wake-up mode. The potential of pilot signal CPLT is lowered from V1 to V2 by pull-down resistor R2, and pilot signal CPLT oscillates.

  When preparation for external charging is completed at time t2, the CPU 82 turns on the switch SW of the resistance circuit 80. Then, the potential of pilot signal CPLT is further lowered from V2 to V3 by pull-down resistors R2 and R3. When the potential of pilot signal CPLT becomes V3, CCID 34 is turned on by CPLT control circuit 36 in EVSE32.

  As described above, in the first embodiment, when external charging is not performed, before the pilot signal CPLT is detected, the ECU 28 operates in a sleep mode in which power consumption is suppressed compared to the wake-up mode. . On the other hand, after the end of external charging, ECU 28 operates in the intermittent activation mode until non-oscillation of pilot signal CPLT is detected. Thereby, the ECU 28 operates in an appropriate power saving mode by distinguishing between a state before the pilot signal CPLT is detected and a state until the non-oscillation of the pilot signal CPLT is detected after the end of charging. Therefore, according to this Embodiment 1, the dark current accompanying external charge can be reduced.

[Modification 1]
In the first embodiment, when the oscillation stop of the pilot signal CPLT is detected, the operation mode of the ECU 28 is shifted from the intermittent activation mode to the sleep mode. However, instead of stopping the oscillation of the pilot signal CPLT, When non-input (voltage 0 V) of pilot signal CPLT is detected, the mode may be shifted to the sleep mode. The non-input of the pilot signal CPLT can also be regarded as indicating the user's intention to end charging.

  As a result, even when the oscillation of the pilot signal CPLT is unstable due to an abnormality in the external power supply 30 or the charging cable, the operation mode can be switched accurately.

[Modification 2]
Regarding the transition from the intermittent activation mode to the sleep mode, the cable connection signal PISW may be used instead of the pilot signal CPLT. That is, when the disconnection between the inlet 22 and the charging cable connector 38 is detected by the cable connection signal PISW, the sleep mode may be entered. This cable connection signal PISW can also be regarded as a signal indicating the user's intention to end charging.

  Since the cable connection signal PISW cannot detect a power failure of the external power supply 30 or a disconnection between the charging cable and the external power supply 30, the pilot signal CPLT is used to shift to the sleep mode even during a power failure of the external power supply 30. It is necessary to monitor separately.

[Modification 3]
In the first embodiment, when the hard interrupt of the pilot signal CPLT is detected, the operation mode of the ECU 28 is shifted from the sleep mode to the wake-up mode. However, in this case as well, the pilot signal CPLT is replaced. The cable connection signal PISW may be used. That is, when a voltage change (change from the power supply voltage to 0 V) of the cable connection signal PISW is detected, the sleep mode may be shifted to the wake-up mode. This cable connection signal PISW can also be taken as a signal indicating the intention of the user to request charging.

  As described above, the cable connection signal PISW cannot detect a power failure of the external power supply 30 or a disconnection between the charging cable and the external power supply 30, so the ECU 28 is intermittently started until the input of the pilot signal CPLT is detected. It is preferable to operate in the mode.

[Modification 4]
Regarding the transition from the sleep mode to the wake-up mode, instead of the hard interrupt of the pilot signal CPLT, the operation mode may be shifted from the sleep mode to the wake-up mode when the open state of the lid of the inlet 22 is detected. .

  FIG. 6 is a diagram showing a lid open / close detection circuit of the inlet 22. Referring to FIG. 6, the detection circuit includes a CPU 82, a power supply 84, and a relay 86. The relay 86 is turned on / off according to the opening / closing of the lid of the inlet 22. As an example, when the lid is opened, the relay 86 is turned on in conjunction with it, and the voltage of the signal LD increases. As a result, the open state of the lid is detected by the CPU 82, and the operation mode of the ECU 28 shifts to the wake-up mode accordingly. This signal LD can also be taken as a signal indicating the intention of the user to request charging.

[Modification 5]
Regarding the transition from the intermittent activation mode to the sleep mode, the lid open / close state of the inlet 22 may be used instead of the hardware interrupt of the pilot signal CPLT. That is, when the closed state of the lid of the inlet 22 is detected, the operation mode may be shifted from the intermittent activation mode to the sleep mode.

  Referring to FIG. 6, when the lid is closed, relay 86 is turned off in conjunction with the lid, and the voltage of signal LD decreases. Thereby, the closed state of the lid is detected in the CPU 82, and the operation mode of the ECU 28 shifts to the sleep mode accordingly. The signal LD can be obtained as a signal indicating the user's intention to end charging.

[Modification 6]
A charge switch is provided for the user to instruct the start and end of external charging, and the charge switch is used instead of the pilot signal CPLT for the transition from the sleep mode to the wake-up mode and the transition from the intermittent activation mode to the sleep mode. ON / OFF may be used.

  FIG. 7 is a diagram showing a charge switch for the user to instruct the start and end of external charging. Referring to FIG. 7, charging switch 88 is operable by the user and is turned on when external charging is performed, and turned off when external charging is completed. Regardless of the connection state of the charging cable and the pilot signal CPLT, the charging switch 88 is turned on / off at the user's will.

  Then, when charging switch 88 is turned on by the user, the operation mode of ECU 28 shifts from the sleep mode to the wake-up mode accordingly. When charging switch 88 is turned off by the user, the operation mode of ECU 28 shifts from the intermittent activation mode to the sleep mode accordingly. The signal generated by the charging switch 88 can also be regarded as a signal indicating a charging request by the user and an intention to end charging.

[Embodiment 2]
The present invention is also applicable to a charging control device that performs external charging by a rapid DC (Direct Current) charging stand.

  FIG. 8 is an overall block diagram of a vehicle to which the charging control apparatus according to the second embodiment is applied. Referring to FIG. 8, vehicle 10 </ b> A does not include charger 24 in the configuration of vehicle 10 illustrated in FIG. 1, and includes ECU 28 </ b> A instead of ECU 28.

  The rapid DC charging stand 40 is provided outside the vehicle. The rapid DC charging stand 40 generates various control signals for external charging, and typically includes a charging start signal S1 indicating the start of external charging, a charging stop signal S2 indicating the stop of external charging, and the like. Generate. The cable connection signal C is a signal for detecting the connection state between the connector 38 on the quick DC charging stand 40 side and the inlet 22 of the vehicle 10A. When the connector 38 is connected to the inlet 22, In contrast, the voltage state changes. Charging start signal S1 and charging stop signal S2 correspond to pilot signal CPLT in the first embodiment, and cable connection signal C corresponds to cable connection signal PISW in the first embodiment.

  The ECU 28A manages external charging (charging start / stop processing and charge amount management by software processing by executing a program stored in advance by a CPU (Central Processing Unit) and / or hardware processing by a dedicated electronic circuit. Etc.) and control of the operation mode.

  Regarding the operation mode, the ECU 28A can also operate in three modes, the wake-up mode, the sleep mode, and the intermittent activation mode, in the same manner as the ECU 28 in the first embodiment. When the input of the charging start signal S1 is detected during the sleep mode, the ECU 28A enters the wake-up mode. Specifically, in the sleep mode, the main clock of the ECU 28A is stopped, and the ECU 28A receives the charging start signal S1 as a hardware interrupt. When the rising (or falling) of charging start signal S1 is detected, the operation mode shifts from the sleep mode to the wake-up mode, and ECU 28A is activated. The charging start signal S1 can be regarded as a signal indicating the user's intention to request charging.

  When the external charging is completed (the charging cable is still connected), the ECU 28A enters the intermittent activation mode. In the intermittent activation mode, the main clock is operating even during the wait mode in the hibernation state, the ECU 28A is periodically activated, and the charge start signal S1 is monitored in order to detect resumption of external charging, disconnection of the charging cable, and the like. The

  For example, when the disconnection between the inlet 22 and the connector 38 of the rapid DC charging stand 40 is detected by the cable connection signal C, the ECU 28A enters the sleep mode. As a result, the activation condition (wake-up mode transition condition) of the ECU 28A is switched from periodic intermittent activation to interrupt detection of the charging start signal S1. The cable connection signal C can be regarded as a signal indicating the user's intention to end charging.

  For the transition from the intermittent start mode to the sleep mode, instead of the cable connection signal C, the fall of the charge start signal S1 or the rise of the charge stop signal S2 may be adopted, and the lid closed state detection is used. May be. Further, regarding the transition from the sleep mode to the wake-up mode, the cable connection signal C or the detection of the open state of the lid may be employed instead of the charging start signal S1.

  FIG. 9 is a functional block diagram of ECU 28A shown in FIG. Referring to FIG. 9, ECU 28A includes a charge management unit 58, an operation mode control unit 54A, and a main clock 56. The charge management unit 58 receives the charge start signal S1, the cable connection signal C, and the detected values of the voltage VDC and the current IDC of the power supplied from the rapid DC charging stand 40. Voltage VDC and current IDC are detected by a voltage sensor and a current sensor, not shown, respectively. In addition, the charge management unit 58 receives a clock signal from the main clock 56. Based on these signals, the charge management unit 58 performs charge start / stop processing (such as on / off control of the charge relay 26) and management of the charge amount of the power storage device 12. In addition, the charge management unit 58 notifies the operation mode control unit 54A of the execution status of external charging (at least during execution / non-execution of external charging).

  Operation mode control unit 54A receives charge start signal S1 and cable connection signal C. Further, the operation mode control unit 54A receives the execution status of external charging from the charge management unit 58. The operation mode control unit 54A controls the operation mode of the ECU 28A based on these signals.

  Specifically, when a hardware interrupt of the charge start signal S1 is detected in the sleep mode, the operation mode control unit 54A shifts the operation mode of the ECU 28A to the wake-up mode and outputs an operation command to the main clock 56.

  When external charging is started and then the end of external charging is notified from the charge management unit 58 to the operation mode control unit 54A, the operation mode control unit 54A shifts the operation mode to the intermittent activation mode. Thus, the ECU 28A is intermittently activated periodically, and the state of the charging start signal S1 is periodically monitored.

  Thereafter, when the disconnection between the inlet 22 and the connector 38 of the rapid DC charging station 40 is detected by the cable connection signal C, the operation mode control unit 54A shifts the operation mode of the ECU 28A to the sleep mode. As a result, the main clock 56 is also stopped, and the operation mode control unit 54A again waits for a hardware interrupt of the charge start signal S1.

  As described above, also in the second embodiment in which external charging is performed using the rapid DC charging stand 40, the same effect as in the first embodiment can be obtained.

  In Embodiment 1 described above, charger 24 is connected between power storage device 12 and SMR 14, but charger 24 may be connected between SMR 14 and PCU 16. Similarly, in Embodiment 2 described above, inlet 22 is connected between power storage device 12 and SMR 14, but inlet 22 may be connected between SMR 14 and PCU 16.

  In the above, charger 24 corresponds to an embodiment of “charging device” in the present invention, and rapid DC charging stand 40 also corresponds to an embodiment of “charging device” in the present invention. The ECUs 28 and 28A correspond to an example of the “control device” in the present invention.

  The embodiment disclosed this time should be considered as illustrative in all points and not restrictive. The scope of the present invention is shown not by the above description of the embodiments but by the scope of claims, and is intended to include all modifications within the meaning and scope equivalent to the scope of claims.

  10, 10A vehicle, 12 power storage device, 14 SMR, 16 PCU, 18 power output device, 20 drive wheel, 22 inlet, 24 charger, 26 charging relay, 28, 28A ECU, 30 external power supply, 32 EVSE, 34 CCID, 36 CPLT control circuit, 38 connector, 40 quick DC charging stand, 52 charge control unit, 54, 54A operation mode control unit, 56 main clock, 58 charge management unit, 70 oscillator, 72 voltage sensor, 74 limit switch, 80 resistance circuit , 82 CPU, 84 power supply, 86 relay, 88 charge switch, R1 resistance element, R2, R3 pull-down resistor, SW switch, L1 control pilot line, L2 ground line, L3 signal line.

Claims (10)

A vehicle charge control device configured to be able to charge a power storage device (12) mounted on a vehicle (10) by a power source external to the vehicle,
A charging device (24, 40) configured to charge the power storage device;
A control device (28, 28A) configured to control charging of the power storage device by the charging device;
The control device consumes compared to the normal mode in which the charge control is executed before the predetermined first signal indicating the intention of the charge request by the user is detected when the power storage device is not charged. The operation is performed in a sleep mode in which power is suppressed, and after the charging of the power storage device is completed, the suspension mode and the normal operation are performed until a predetermined second signal indicating a user's intention to end the charging is detected. A charge control device for a vehicle that operates in an intermittent start mode in which a mode is switched.   Before the first signal is detected, the control device operates in a first pause mode in which the main clock (56) is stopped and the first signal is received as a hard interrupt. The vehicle charge control device according to claim 1, wherein the vehicle is periodically switched between the second pause mode in which the main clock is operated and the normal mode.   The control device shifts to the normal mode when the first signal is detected during the first pause mode, and shifts to the intermittent activation mode when charging of the power storage device is completed. The vehicle charging control device according to claim 2, wherein when the second signal is detected, the vehicle shifts to the first pause mode.   The first signal is a pilot signal (CPLT, S1) input to the vehicle when a charging cable for transmitting power from the power source to the vehicle is connected to the vehicle. The vehicle charge control device according to claim 1.   The first signal according to any one of claims 1 to 3, wherein the first signal is a signal (PISW, C) indicating that a charging cable for transmitting power from the power source to the vehicle is connected to the vehicle. The vehicle charging control device according to claim.   4. The signal according to claim 1, wherein the first signal is a signal (LD) indicating that a lid of the vehicle to which a charging cable for transmitting power from the power source to the vehicle is connected is opened. 5. The vehicle charge control device according to claim 1. When a charging cable for transmitting power from the power source to the vehicle is connected to the vehicle, a pilot signal (CPLT, S1) is input to the vehicle,
4. The vehicle charge control device according to claim 1, wherein the second signal is the pilot signal that is not oscillated or not input. 5.   4. The signal according to claim 1, wherein the second signal is a signal (PISW, C) indicating that a charging cable for transmitting power from the power source to the vehicle is not connected to the vehicle. 5. The vehicle charging control device according to claim.   4. The signal according to claim 1, wherein the second signal is a signal (LD) indicating that a lid of the vehicle to which a charging cable for transmitting power from the power source to the vehicle is connected is closed. The vehicle charge control device according to claim 1. A charging control device for a vehicle according to any one of claims 1 to 3,
A vehicle comprising a power storage device (12) charged by the charge control device.

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