JP5630419B2 - Power supply system and vehicle - Google Patents

Description

  The present invention relates to an electric power supply system and a vehicle, and more particularly to a technique for supplying electric power from a vehicle to a load outside the vehicle.

  In vehicles such as an electric vehicle, a hybrid vehicle, and a fuel cell vehicle configured to be able to generate a vehicle driving force by an electric motor, a power storage device that stores electric power for driving the electric motor is mounted. In such a vehicle, power is supplied from the power storage device to the electric motor when starting or accelerating to generate vehicle driving force, while electric power generated by regenerative braking of the electric motor during downhill driving or deceleration is used. Supply to power storage device.

  In such a vehicle, it is possible to charge the power storage device (hereinafter also simply referred to as “external charging”) by being electrically connected to a power source external to the vehicle such as a commercial power supply (hereinafter also simply referred to as “external power”). Have been proposed. For example, a so-called plug-in hybrid vehicle is known in which a power storage device can be charged from a general household power source by connecting an outlet provided in a house and a charging port provided in the vehicle with a charging cable. . Thereby, the fuel consumption efficiency of a hybrid vehicle can be improved.

  In such a vehicle capable of external charging, as seen in a smart grid or the like, the vehicle is considered as a power supply source, and a concept of supplying power from the vehicle to a load outside the vehicle has been studied.

  For example, Japanese Patent Laying-Open No. 2010-154737 (Patent Document 1) discloses a power supply system capable of bidirectionally supplying power between a vehicle and a house by connecting the vehicle equipped with a power source and the house with a power cable. Is disclosed. In Patent Document 1, a vehicle is provided with a controller for controlling power supply. This vehicle controller communicates with a controller provided in a house by superimposing data on a power line including a power cable. When the vehicle and the house are connected by a power cable, the vehicle controller uses the power from the vehicle power source to the house based on the voltage of the commercial power source in the house and the state of charge of the vehicle power source transmitted from the house controller. The plug-out power supply for supplying power and the plug-in power supply for supplying power to the vehicle from the house power supply are switched.

JP 2010-154637 A JP 2001-008380 A

  In the configuration in which power can be supplied from the vehicle power source to the house as in Patent Document 1 above, when a power failure occurs in the commercial power source, the vehicle is used as an emergency power source for the commercial power source. Can be considered. However, in Patent Document 1, since the operation of the controller of the house stops (shuts down) at the time of a power failure of the commercial power supply, the voltage of the commercial power supply in the house cannot be transmitted to the vehicle controller. In such a situation, since the vehicle controller cannot know the state of the power supply for the house, it cannot determine the specifications of the power (frequency and voltage of the supplied power) to be supplied from the vehicle power supply to the house. . As a result, the vehicle cannot convert the power of the vehicle power source into power suitable for driving home appliances in the house, making it difficult to supply power from the vehicle power source to the house.

  Therefore, the present invention has been made to solve such a problem, and an object of the present invention is to provide a power supply system and a vehicle that can reliably supply power from the vehicle to a load outside the vehicle at the time of a power failure of the external power source. Is to provide.

  According to an aspect of the present invention, an electric power supply system includes a vehicle and a power feeding device for supplying electric power from the vehicle to a load outside the vehicle. The load is configured to receive electric power from an external power source and to drive by receiving electric power from the vehicle when the external power source is interrupted. The vehicle controls the power supply unit, the power supply unit for supplying the power from the power generation unit to the power supply device, and the power supply unit so as to convert the power from the power generation unit into the drive power of the load in the event of a power failure of the external power supply And a control device. The control device controls the power supply unit so as to supply a plurality of specifications with different voltages and frequencies according to a predetermined order in the event of a power failure of the external power supply, and supplies the load when the load is started The specification of the generated power is detected as the specification related to the drive power of the load. The control device controls the power feeding unit based on the detected specification regarding the driving power.

  Preferably, the control device determines whether or not the load has been activated each time power of one specification is supplied, and determines the specification of the power supplied to the load when it is determined that the load has been activated. Detected as specifications related to drive power.

  Preferably, the predetermined order is set so as to be supplied to the load in order from power having a specification with a low voltage.

  According to another aspect of the present invention, there is provided a vehicle for supplying power to a load outside the vehicle, the power generation unit, a power supply unit for supplying power from the power generation unit to the load, and an external power source. And a control device for controlling the power feeding unit so as to convert the power from the power generation unit into the driving power of the load at the time of a power failure. The control device controls the power feeding unit so that power of a plurality of specifications having different voltages and frequencies in accordance with a predetermined order is supplied in the event of a power failure of the external power supply, and is supplied to the load when the load is activated. The specification of the current power is detected as the specification related to the drive power of the load. The control device controls the power feeding unit based on the detected specification regarding the driving power.

  Preferably, the control device determines whether or not the load has been activated each time power of one specification is supplied, and determines the specification of the power supplied to the load when it is determined that the load has been activated. Detected as specifications related to drive power.

  Preferably, the predetermined order is set so as to be supplied to the load in order from power having a specification with low power.

  Preferably, the power generation unit includes a rechargeable power storage device. The power feeding unit converts electric power discharged from the power storage device into driving power for the load.

  Preferably, the vehicle further includes an internal combustion engine as a driving force source. The power generation unit includes a rechargeable power storage device and a generator configured to generate power using the output of the internal combustion engine. The power feeding unit converts at least one of the power discharged from the power storage device and the power generated by the generator into drive power for the load.

  According to the present invention, it is possible to reliably supply power from the vehicle to a load outside the vehicle at the time of a power failure of the external power source.

1 is a schematic configuration diagram of a power supply system according to an embodiment of the present invention. It is a figure explaining the structure of the vehicle in FIG. It is a figure which shows the electric power supply system in case the external power supply has stopped. It is a figure explaining operation | movement in the emergency power generation mode of the electric power supply system by embodiment of this invention. It is a figure which shows an example of the power transmission pattern stored in the memory | storage part of a vehicle. It is a flowchart explaining operation | movement of the vehicle in the electric power supply system by embodiment of this invention.

  Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings. In the drawings, the same reference numerals indicate the same or corresponding parts.

FIG. 1 is a schematic configuration diagram of a power supply system according to an embodiment of the present invention.
Referring to FIG. 1, the power supply system includes a vehicle 10, a charging stand 200, a HEMS (Home Energy Management System) 300, a load device 400, and an external power source (hereinafter referred to as “external power source”). 500) and a switchboard 510.

  Vehicle 10 according to the embodiment of the present invention is a so-called plug-in type electric vehicle that can charge an in-vehicle power storage device with external power supply 500. Note that the configuration of the electric vehicle is not particularly limited as long as it can travel with the electric power from the in-vehicle power storage device. Examples of the vehicle 10 include a hybrid vehicle, an electric vehicle, and a fuel cell vehicle.

  Vehicle 10 includes a power storage device 100, a power output device 135, an ECU (Electronic Control Unit) 130 for controlling the overall operation of the vehicle 10, a communication unit 140, and a storage unit 145 (see FIG. 2). .

  The power storage device 100 is a power storage element configured to be rechargeable, and typically, a secondary battery such as a lithium ion battery or a nickel metal hydride battery is applied. Alternatively, power storage device 100 may be configured by a power storage element other than a battery, such as an electric double layer capacitor. FIG. 1 shows a system configuration related to charge / discharge control of power storage device 100 in vehicle 10. Power storage device 100 is provided with a battery sensor (not shown) for detecting the voltage and current of power storage device 100.

  Monitoring unit 105 (see FIG. 2) detects the state value of power storage device 100 based on the output of a battery sensor provided in power storage device 100. That is, the state value includes the voltage and / or current of power storage device 100. As described above, since a secondary battery is typically used as power storage device 100, the voltage and current of power storage device 100 are also referred to as battery voltage and battery current below. The battery voltage and battery current are also collectively referred to as “battery data”.

  The power output device 135 generates the driving force of the vehicle 10 using the electric power stored in the power storage device 100. Specifically, motive power output device 135 generates a driving force of vehicle 10 based on a driving command from ECU 130, and outputs the generated driving force to driving wheels (not shown) of vehicle 10. The drive command is a control command generated based on the requested vehicle driving force or vehicle braking force while the vehicle 10 is traveling. Specifically, the ECU 130 determines the vehicle driving force and the vehicle necessary for the entire vehicle 10 according to the vehicle state of the vehicle 10 and the driver operation (accelerator pedal depression amount, shift lever position, brake pedal depression amount, etc.). Calculate the braking force. Then, ECU 130 generates a drive command for power output device 135 so as to realize the requested vehicle driving force or vehicle braking force.

  Further, when receiving a power generation command from ECU 130, power output device 135 generates power to be supplied to load device 400 outside the vehicle, and outputs the generated power to power supply unit 120. The power generation command is a control command for instructing generation of power to be supplied to the load device 400 in an emergency power generation mode described later.

With reference to FIG. 2, the configuration of vehicle 10 (FIG. 1) will be further described.
Referring to FIG. 2, power output device 135 includes a power conversion unit (PCU) 150, motor generators 160 and 165, power transmission gear 175, engine 170, and drive wheels 180.

  PCU 150 is connected to power storage device 100. The power storage device 100 supplies power for generating the driving force of the vehicle 10 to the PCU 150. Power storage device 100 stores the electric power generated by motor generators 160 and 165. Specifically, PCU 150 includes a converter 152, inverters 154 and 156, and capacitors C1 and C2.

  Converter 152 performs voltage conversion between power lines PL1 and NL1 and power lines PL2 and NL1 based on control signal PWC from ECU.

  Inverters 154 and 156 are connected in parallel to power lines PL2 and NL1. Inverters 154 and 156 convert DC power supplied from converter 152 into AC power based on control signals PMI1 and PMI2 from ECU 130, and drive motor generators 160 and 165, respectively.

  Capacitor C1 is provided between power lines PL1 and NL1, and reduces voltage fluctuation between power lines PL1 and NL1.

  Motor generators 160 and 165 are AC rotating electric machines, for example, permanent magnet type synchronous motors including a rotor in which permanent magnets are embedded.

  The output torque of motor generators 160 and 165 is transmitted to drive wheel 180 via power transmission gear 175 configured by a speed reducer and a power split mechanism, and causes vehicle 10 to travel. Motor generators 160 and 165 can generate electric power using the rotational force of drive wheels 180 during regenerative braking of vehicle 10. Then, the generated power is converted into charging power for power storage device 100 by PCU 150.

  Motor generators 160 and 165 are also coupled to engine 170 via power transmission gear 175. Then, ECU 130 operates motor generators 160 and 165 and engine 170 in a coordinated manner to generate a necessary vehicle driving force. Further, motor generators 160 and 165 can generate electric power by rotation of engine 170, and can charge power storage device 100 using the generated electric power. In the present embodiment, motor generator 165 is used exclusively as an electric motor for driving drive wheels 180, and motor generator 160 is used exclusively as a generator driven by engine 170.

  FIG. 2 illustrates a configuration in which two motor generators are provided, but the number of motor generators is not limited to this, and a configuration in which one motor generator is provided or more than two motor generators are provided. It is good.

  In the present embodiment, vehicle 10 will be described as an example of a hybrid vehicle as described above. However, the configuration of vehicle 10 may include power generated from a generator driven by engine 170, and / or The configuration is not limited as long as the vehicle can supply power to the load device outside the vehicle using the power from power storage device 100. That is, in addition to the hybrid vehicle that generates vehicle driving force by the engine and electric motor as shown in FIG. 2, the vehicle 10 is not equipped with a vehicle that does not generate vehicle driving force but is provided with a generator that generates electric power by the engine. Includes electric vehicles and fuel cell vehicles.

  Vehicle 10 further includes an inlet 112 provided in the body of vehicle 10, charging unit 110, and charging relay 116 as a configuration for charging power storage device 100 with electric power from external power supply 500. The external power supply 500 is typically constituted by a single-phase AC commercial power supply. However, the power of the external power supply may be supplied by the power generated by the solar cell panel installed on the roof of a house instead of or in addition to the commercial power supply.

  A charging connector 212 of the charging cable 214 is connected to the inlet 112. Then, electric power from the external power source 500 is transmitted to the vehicle 10 via the charging cable 214.

  Charging unit 110 is a device for receiving power from external power supply 500 and charging power storage device 100. Charging unit 110 is provided between inlet 112 and power storage device 100. Charging unit 110 converts AC power from external power supply 500 transmitted via inlet 112 via charging cable 214 into DC power for charging power storage device 100 in accordance with control command PWD 1 from ECU 130. To do.

  Between charging unit 110 and power storage device 100, a charging relay 116 that is inserted and connected to power lines PL3 and NL3 is provided. Charging relay 116 is turned on / off in response to relay control signal SE1 from ECU 130. Charging relay 116 is used as a representative example of an opening / closing device that can cut off a charging path of power storage device 100. That is, any type of switching device can be applied in place of the charging relay 116.

  ECU 130 generates a control command PWD1 for controlling charging unit 110 when power storage device 100 is charged by external power supply 500, and outputs the generated control command PWD1 to charging unit 110. At this time, ECU 130 is connected to an external power source based on a pilot signal received from a charging circuit interrupting device (not shown) provided on the electric wire portion of charging cable 214 for switching between supply and interruption of power from external power source 500. 500 types are specified, and charging unit 110 is controlled in accordance with the specified type of external power supply 500.

  In addition, vehicle 10 further includes an inlet 122 provided in the body of vehicle 10, power supply unit 120, and power supply relay 126 as a configuration for supplying power to load device 400 (FIG. 1) outside the vehicle. .

  A power supply connector 222 of a power supply cable 224 is connected to the inlet 122. Then, the discharged power from power storage device 100 and / or the generated power from power output device 135 (motor generator 160) are transmitted to load device 400 via power supply cable 224. That is, power storage device 100 and / or power output device 135 (motor generator 160) constitute a “power generation unit” for generating power supplied to the outside of the vehicle.

  Power feeding unit 120 is a device for receiving discharged power from power storage device 100 and / or generated power from power output device 135 and feeding power to load device 400 outside the vehicle. In accordance with control command PWD2 from ECU 130, power feeding unit 120 receives the discharged power from power storage device 100 and / or the generated power from power output device 135 (both DC power) transmitted via power lines PL3 and NL3. It converts into the alternating current power for driving the load apparatus 400 outside a vehicle.

  Between power feeding unit 120 and power storage device 100, power feeding relay 126 that is inserted and connected to power lines PL3 and NL3 is provided. The power supply relay 126 is turned on / off in response to a relay control signal SE2 from the ECU 130. Power supply relay 126 is used as a representative example of an opening / closing device that can cut off a discharge path from power storage device 100 and / or power output device 135. In other words, any type of switching device can be applied in place of the power supply relay 126.

  ECU 130 includes a CPU (Central Processing Unit), a storage device, and an input / output buffer, both of which are not shown in FIGS. 1 and 2, and inputs signals from each sensor and outputs control signals to each device. In addition, the vehicle 10 and each device are controlled. These controls are not limited to processing by software, and can be processed by dedicated hardware (electronic circuit).

  ECU 130 calculates a state of charge (SOC) of power storage device 100 based on battery data (battery voltage and battery current) from monitoring unit 105. The SOC is a percentage (0 to 100%) of the current remaining capacity with respect to the full charge capacity. In addition, about calculation of SOC of the electrical storage apparatus 100, since well-known arbitrary methods are applicable, detailed description is abbreviate | omitted.

  ECU 130 generates and outputs a control command for controlling PCU 150, charging unit 110, charging relay 116, power feeding unit 120, and power feeding relay 126.

  The ECU 130 communicates with the communication units 240 and 350 provided in the charging station 200 and the HEMS 300 outside the vehicle via the communication unit 140 by wireless or wired. Then, ECU 130 stores information transmitted from charging station 200 and communication units 240 and 350 of HEMS 300 in storage unit 145.

  In addition, power line communication (PLC: Power Line Communication) can be used for communication between the vehicle 10, the charging station 200, and the HEMS 300. In this case, the communication units 140, 240, and 350 are configured by a PLC unit and transmit information via the power line.

  As described above, vehicle 10 according to the embodiment of the present invention is configured such that in-vehicle power storage device 100 can be charged by external power source 500 and power can be supplied from vehicle 10 to load device 400 outside the vehicle. In the following description, charging of power storage device 100 by external power source 500 is also referred to as “external charging”, and electric power generated from power storage device 100 to the outside of the vehicle and / or power generated by power output device 135 (motor generator 160). Is also referred to as “external power supply”.

  In the present embodiment, it is not essential to perform external charging. In the case of a vehicle that travels only with the driving force from the engine, a configuration for performing external charging may not be provided.

  Also, instead of the configuration shown in FIG. 1 and FIG. 2, a configuration for supplying electric power by electromagnetically coupling an external power source and a vehicle in a non-contact manner, specifically, providing a primary coil on the external power source side, It is good also as a structure which provides a secondary coil in the vehicle side and supplies electric power using the mutual inductance between a primary coil and a secondary coil.

  Referring to FIG. 1 again, charging stand 200 includes a charging cable 214, a charging connector 212, and a relay 210 for external charging. Charging stand 200 also includes a power feeding cable 224, a power feeding connector 222, and a relay 220 for performing external power feeding. Charging stand 200 further includes a controller 230 and a communication unit 240. The charging stand 200 is electrically connected to a switchboard 510 installed in a building such as a house 600 by power supply lines 216 and 226.

  One end of charging cable 214 is connected to relay 210 and the other end is connected to charging connector 212. One end of the power supply cable 224 is connected to the relay 220 and the other end is connected to the power supply connector 222. The charging cable 214 and the power feeding cable 224 may be separable from the charging stand 200. Alternatively, the charging stand 200 and the vehicle 10 may be connected using a charging cable and a power feeding cable provided in the vehicle 10.

  In FIG. 1, the charging cable 214 and the charging connector 212 and the power feeding cable 224 and the power feeding connector 222 are separately provided. However, one cable and one connector are used by switching between charging and power feeding. It is good. In this case, also on the vehicle 10 side, the inlets 112 and 122 are combined into one inlet that can be switched between charging and power feeding.

  At the time of external charging, power is supplied to the vehicle 10 from the external power source 500 via the switchboard 510 and the feeder line 216 of the house 600 with the charging connector 212 connected to the inlet 112 of the vehicle 10 and the relay 210 closed. On the other hand, at the time of external power supply, power is supplied from the vehicle 10 to the house 600 through the power supply line 226 with the power supply connector 222 connected to the inlet 122 of the vehicle 10 and the relay 220 closed. The opening / closing operation of the relays 210 and 220 is controlled by the controller 230.

  As an example, the controller 230 includes a CPU and the like. The controller 230 is configured to be able to communicate with the ECU 130 of the vehicle 10 by wireless or wired via the communication units 240 and 140. Further, the controller 230 is configured to be able to communicate with the CPU 340 of the HEMS 300 via the communication units 240 and 350 by wireless or wired.

  The controller 230 transmits a signal indicating the state of the relays 210 and 220 (open state or closed state) to the CPU 340 of the HEMS 300 and the ECU 130 of the vehicle 10. That is, the controller 230 transmits a signal indicating whether external charging or external power feeding has been selected to the CPU 340 and the ECU 130.

  The HEMS 300 is installed inside or outside the house 600. The HEMS 300 is electrically connected to the switchboard 510 and the charging stand 200 through a power supply line 226. The HEMS 300 includes a DC / AC converter 310, an AC / DC converter 320, a CPU 340, and a communication unit 350.

  The AC / DC converter 320 converts AC power supplied from the charging stand 200 into DC power. The DC / AC converter 310 converts the DC power converted by the AC / DC converter 320 into AC power. AC / DC converter 320 and DC / AC converter 310 are controlled by a control signal generated by CPU 340 based on a signal transmitted from communication unit 240 of charging stand 200 indicating which of external charging and external power feeding has been selected. The

  The load device 400 is an arbitrary electrical device that operates by receiving power from the external power supply 500 via the switchboard 510. Load device 400 may be house 600, for example, or may be an individual appliance. Alternatively, the load device 400 may be a vehicle other than the vehicle 10.

  Here, in the power supply system shown in FIG. 1, when the external power supply 500 fails, the power supply to the load device 400 is cut off. At the time of such a power failure of the external power supply 500, the vehicle 10 is regarded as a power supply source instead of the external power supply 500, and power is supplied from the vehicle 10 to the load device 400. In the following description, a mode in which external power feeding is performed using the vehicle 10 as an emergency power source for the external power source 500 is referred to as an “emergency power generation mode”. In contrast, a mode in which external power supply and external charging are performed when external power supply 500 is normal is referred to as a “normal mode”.

  In the emergency power generation mode, the vehicle 10 on the power supply side needs to generate AC power having specifications that match the specifications of the load device 400 on the power reception side. The specification of the load device 400 (hereinafter, also referred to as “load specification”) is a specification related to the driving power of the load device 400 and includes the frequency and voltage of the external power supply 500. As an example, when the external power supply 500 is a commercial power supply, the frequency of the commercial power supply is typically 50 kHz or 60 kHz. The commercial AC voltage generated by the commercial grid power supply is 100V or 200V.

  In the normal mode, the ECU 130 of the vehicle 10 can acquire the load specification by communicating with the HEMS 300 and the charging station 200 via the communication units 140, 240, and 350. And the vehicle 10 can generate | occur | produce the suitable alternating current power according to the acquired load specification, and can supply it to the load apparatus 400. FIG.

  On the other hand, after the power failure of the external power source 500 occurs, the communication function as described above does not operate normally, so the ECU 130 of the vehicle 10 can no longer obtain the load specification. Therefore, the vehicle 10 cannot generate AC power having an appropriate frequency and voltage according to the load device 400 and supply the AC power to the load device 400. The problem that occurs when the external power source 500 fails will be described with reference to FIG.

FIG. 3 is a diagram showing a power supply system when the external power supply 500 is out of power.
Referring to FIG. 3, HEMS 300 sets the frequency and voltage of external power supply 500, which are load specifications, as power generation parameters. When the power generation parameter is transmitted to the ECU 130 of the vehicle 10 via the communication units 350, 240, and 140, the power generation parameter is used by the ECU 130 for a power feeding operation in the vehicle 10. Specifically, ECU 130 converts the discharged power from power storage device 100 into AC power defined by the power generation parameters and supplies the AC power to the outside of the vehicle. The ECU 130 converts the DC power generated by the power output device 135 into AC power defined by the power generation parameters and supplies the AC power to the outside of the vehicle.

  However, when a power failure occurs in the external power supply 500, the power supply to the HEMS 300 and the charging station 200 is interrupted as shown in FIG. 3, and the operation of the communication unit 350 of the HEMS 300 and the communication unit 240 of the charging station 200 is stopped. To do. Therefore, the power generation parameters cannot be transmitted from the HEMS 300 or the charging station 200 to the vehicle 10.

  On the other hand, in the vehicle 10, when a power failure of the external power supply 500 is detected, the ECU 130 turns the normal mode off while turning the emergency power generation mode on. When emergency power generation mode is turned on, ECU 130 converts DC power from power storage device 100 and / or power output device 135 into AC power suitable for driving load device 400 outside the vehicle. The power conversion operation in the power feeding unit 120 is controlled. However, as described above, ECU 130 cannot control power feeding unit 120 because it cannot obtain power generation parameters for defining the frequency and voltage of AC power.

  In order to solve such problems, in the power supply system according to the present embodiment, when the emergency power generation mode is turned on due to a power failure of external power supply 500, ECU 130 first has a plurality of voltages and frequencies different from each other. The power supply unit 120 is controlled so as to supply the power of the specifications to the load device 400 in a predetermined order. At this time, ECU 130 determines whether or not load device 400 is activated for each power specification. Then, ECU 130 detects the specification of power supplied to load device 400 as the load specification when it is determined that load device 400 is activated. ECU 130 executes a power feeding operation using the detected load specification as a power generation parameter. Thereby, the vehicle 10 can generate | occur | produce the suitable alternating current power according to the acquired load specification, and can supply it to the load apparatus 400. FIG.

  FIG. 4 is a diagram for explaining the operation in the emergency power generation mode of the power supply system according to the embodiment of the present invention.

  Referring to FIG. 4, when the emergency power generation mode is turned on due to the occurrence of a power failure of external power supply 400, vehicle 10 generates electric power of a plurality of specifications in a predetermined order and supplies it to load device 400. The specifications of the plurality of electric powers and the predetermined order are stored in advance in the storage unit 145 in the vehicle 10 as a power transmission pattern. FIG. 5 shows an example of the power transmission pattern stored in the storage unit 145.

  Referring to FIG. 5, the power transmission pattern is composed of a plurality of specifications (n (n is a natural number)) in which at least one of frequency and voltage is different. The n specifications are ordered so as to be supplied to the load device 400 in order from the power having the low voltage specification. Furthermore, it is set so that power having different frequencies is supplied to the load device 400 at each voltage.

  For example, when the external power supply 500 is a commercial power supply, the voltage of n specifications is set to increase by a predetermined voltage (for example, 10V) from 100V to 200V. For each voltage, power having a frequency of 50 kHz and power having a frequency of 60 kHz are included. In FIG. 5, the power of the frequency 50 kHz is set to be ahead of the power of the frequency 60 kHz, but this order may be reversed.

  As shown in FIG. 5, by supplying power to the load device 400 in order from the low-voltage specification power, it is possible to prevent the load device 400 from being suddenly input with an excessive voltage and being damaged. . Further, by gradually increasing the voltage of the power supplied to the load device 400, it is possible to prevent the supply voltage to the load device 400 from changing suddenly and greatly damaging the load device 400 when the power specifications are changed. can do.

  Returning to FIG. 4, ECU 130 controls the power conversion operation in power supply unit 120 so that power is supplied to load device 400 according to the power transmission pattern. The electric power generated by the power supply unit 120 and output to the outside of the vehicle is supplied to the load device 400 via the HEMS 300.

  At this time, when the specification of the power supplied to the load device 400 matches the specification (load specification) of the load device 400 outside the vehicle, the load device 400 is turned on and the load device 400 is activated. When the load device 400 is activated, an energization path is formed between the vehicle 10 and the load device 400, and a current flows through the energization path.

  In the vehicle 10, the ECU 130 detects whether or not the energization path is formed by a current sensor 190 inserted in a power line disposed between the power feeding unit 120 and the inlet 122. Specifically, current sensor 190 detects current IAC flowing through the power line and outputs the detected value to ECU 130. ECU 130 determines that load device 400 is not activated when current IAC is zero, that is, when an energization path is not formed.

  On the other hand, when current IAC is not zero, that is, when an energization path is formed, ECU 130 determines that load device 400 has started. ECU 130 detects the specification (frequency and voltage) of the power supplied to load device 400 as the load specification (power generation parameter) when it is determined that load device 400 has started.

  FIG. 6 is a flowchart illustrating the operation of the vehicle in the power supply system according to the embodiment of the present invention.

  Referring to FIG. 6, when a power failure of external power supply 500 occurs in step S <b> 01, operations of communication unit 350 of HEMS 300 and communication unit 240 of charging stand 200 are stopped. As a result, communication between HEMS 300 and charging station 200 and vehicle 10 is interrupted.

  In the vehicle 10, in step S <b> 02, the ECU 130 determines whether or not the emergency power generation mode is turned on by connecting the charging stand 200 and the vehicle 10 by connecting the power supply connector 222 to the inlet 122. To do. If the emergency power generation mode is not turned on (NO in step S02), the process returns to step S02. When the emergency power generation mode is turned on (YES in step S02), ECU 130 reads the power transmission pattern (FIG. 5) stored in storage unit 145. Then, ECU 130 generates AC power to be supplied from vehicle 10 to load device 400 by controlling power supply unit 120 according to the read power transmission pattern.

  Specifically, first, in step S03, ECU 130 converts the discharged power of power storage device 100 and / or the generated power of power output device 135 into AC power defined by the first specification. The power feeding unit 120 is controlled. In step S04, ECU 130 determines whether or not an energization path is formed between vehicle 10 and load device 400 based on current IAC detected by current sensor 190. When current IAC is zero (when YES is determined in step S04), ECU 130 determines that an energization path is not formed between vehicle 10 and load device 400, that is, load device 400 is not activated. In this case, ECU 130 determines that the first specification does not match the load specification. And it progresses to step S05 and ECU130 controls the electric power feeding part 120 based on the 2nd specification in a power transmission pattern.

  On the other hand, when current IAC is not zero (NO determination in step S04), ECU 130 determines that an energization path is formed between vehicle 10 and load device 400, that is, load device 400 is activated. To do. In this case, the ECU 130 determines that the first specification matches the load specification. Then, ECU 130 sets the first specification as a power generation parameter in step S10. The ECU 130 generates AC power to be supplied from the vehicle 10 to the load device 400 by controlling the power conversion operation of the power feeding unit 120 based on the set power generation parameter (load specification).

  When AC power defined by the second specification is generated from vehicle 10 in step S05, ECU 130 energizes between vehicle 10 and load device 400 based on current IAC from current sensor 190 in step S06. It is determined whether or not a route has been formed. When current IAC is zero (when YES is determined in step S05), ECU 130 determines that load device 400 is not activated. In this case, ECU 130 determines that the second specification does not match the load specification, and controls power feeding unit 120 based on the third specification in the power transmission pattern.

  On the other hand, when current IAC is not zero (NO determination in step S06), ECU 130 determines that load device 400 has started. In this case, the ECU 130 determines that the second specification matches the load specification, proceeds to step S10, and sets the second specification as a power generation parameter.

  In accordance with the above procedure, ECU 130 generates a plurality (n) of specifications of power determined by the power transmission pattern in order from the top and supplies them to load device 400, and every time the power of one specification is generated, load device 400. It is determined whether or not is started.

  When it is determined that the load device 400 is not activated when the power supply unit 120 is controlled based on the nth specification in step S07 (when YES is determined in step S08), the ECU 130 As such, the user is notified that appropriate electric power according to the load specification cannot be supplied from the vehicle 10 (power supply is not possible).

  In the present embodiment, power storage device 100 and power output device 135 (motor generator 160) correspond to “power generation unit”, power supply unit 120 corresponds to “power supply unit”, and ECU 130 corresponds to “control device”. . Further, the HEMS 300 and the charging stand 200 correspond to a “power supply device”.

  As described above, according to the power supply system according to the embodiment of the present invention, at the time of a power failure of the external power supply, electric power having a plurality of specifications with different voltages and frequencies from the vehicle is supplied to the load device according to a predetermined order. By supplying and determining whether or not the load device is activated for each power specification, a specification (load specification) regarding the drive power of the load device can be acquired. Thereby, it becomes possible to supply appropriate electric power according to the load specification from the vehicle. As a result, emergency power generation during a power failure of the external power supply can be reliably executed, and the load device can be driven stably.

  Further, according to the power supply system according to the embodiment of the present invention, the load specification used at the time of external power feeding is acquired based on the detection value of the current sensor in the vehicle when power is supplied from the vehicle to the load device. Therefore, even when the communication between the charging station and the HEMS and the vehicle is disabled during a power failure of the external power supply, the vehicle can acquire the load specification. Even if the power supply system is not equipped with a charging station and a communication function between the HEMS and the vehicle, the vehicle can acquire the load specification.

  1 and 2, the charging unit 110 and the power feeding unit 120 have been described as separate devices. However, a configuration in which one power conversion unit capable of bidirectional power conversion for charging and power feeding may be provided.

  1 illustrates the configuration in which the communication unit is provided in each of the charging stand 200 and the HEMS 300. However, the communication unit for communicating with the vehicle 10 may be provided in either the charging stand 200 or the HEMS 300. .

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

  DESCRIPTION OF SYMBOLS 10 Vehicle, 100 Power storage device, 105 Monitoring unit, 110 Charging unit, 112, 122 Inlet, 116 Charging relay, 120 Power feeding unit, 126 Power feeding relay, 135 Power output device, 140, 240, 350 Communication unit, 145 Storage unit, 152 Converter, 154, 156 Inverter, 160, 165 Motor generator, 170 Engine, 175 Power transmission gear, 180 Driving wheel, 190 Current sensor, 200 Charging stand, 210, 220 Relay, 212 Charging connector, 214 Charging cable, 216, 226 Supply Electric wire, 222 Power supply connector, 224 Power supply cable, 230 Controller, 300 HEMS, 310 AC / DC converter, 320 DC / AC converter, 340 CPU, 400 Load device, 410 Switch , 500 external power supply, 510 switchboard, 600 houses.

Claims (8)

A vehicle,
A power supply device for supplying electric power from the vehicle to a load outside the vehicle,
The load is configured to be driven by receiving power from the vehicle at the time of power failure of the external power supply while receiving power supply from an external power source,
The vehicle is
A power generation unit;
A power feeding unit for supplying power from the power generation unit to the power feeding device;
A control device for controlling the power supply unit so as to convert electric power from the power generation unit into driving power of the load at the time of a power failure of the external power source,
The control device controls the power supply unit so as to supply power of a plurality of specifications having at least one of voltage and frequency different from each other according to a predetermined order at the time of a power failure of the external power supply, and when the load is activated A power supply system that detects a specification of power supplied to the load as a specification related to the drive power of the load and controls the power supply unit based on the detected specification related to the drive power.   The control device determines whether or not the load is activated each time power of one specification is supplied, and determines the specification of power supplied to the load when it is determined that the load is activated. The power supply system according to claim 1, wherein the power supply system is detected as a specification related to driving power of a load.   The power supply system according to claim 1 or 2, wherein the predetermined order is set so that power is supplied to the load in order from power having a specification with a low voltage. A vehicle for supplying power to a load outside the vehicle,
A power generation unit;
A power feeding unit for supplying power from the power generation unit to the load;
A control device for controlling the power feeding unit so as to convert the power from the power generation unit into the driving power of the load at the time of a power failure of an external power source;
The control device controls the power supply unit so as to supply a plurality of specifications with different voltages and frequencies according to a predetermined order at the time of a power failure of the external power source, and when the load is activated The vehicle which detects the specification of the electric power currently supplied to the said load as a specification regarding the drive electric power of the said load, and controls the said electric power feeding part based on the detected specification regarding the drive electric power.   The control device determines whether or not the load is activated each time power of one specification is supplied, and determines the specification of power supplied to the load when it is determined that the load is activated. The vehicle according to claim 4, wherein the vehicle is detected as a specification relating to driving power of a load.   The vehicle according to claim 4 or 5, wherein the predetermined order is set so as to be supplied to the load in order from electric power having a specification with low electric power. The power generation unit includes a rechargeable power storage device,
The vehicle according to any one of claims 4 to 6, wherein the power supply unit converts electric power discharged from the power storage device into driving electric power for the load. The vehicle further includes an internal combustion engine as a driving force source,
The power generation unit
A rechargeable power storage device;
A generator configured to generate electricity using the output of the internal combustion engine,
The vehicle according to any one of claims 4 to 6, wherein the power feeding unit converts at least one of electric power discharged from the power storage device and electric power generated by the generator into driving electric power for the load.

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