JP2008296766A - Hybrid vehicle and control method of hybrid vehicle - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a hybrid vehicle in which for a charging and refueling operation are simplified and a control method thereof. <P>SOLUTION: The hybrid vehicle 100 is equipped with: an electricity accumulation device 102; a charging connector 124 for charging the electricity accumulation device 102; a fuel tank 126; a supply port 128 for supplying fuel to the fuel tank 126; and a control device 114 for controlling refueling and charging. The control device 114 controls at least one of a charging period when the electricity accumulation device 102 is charged through the charging connector 124 and a refueling period when the fuel tank 126 is refueled through the supply port 128 so that both periods can be prevented from overlapping each other. <P>COPYRIGHT: (C)2009,JPO&INPIT

Description

  The present invention relates to a hybrid vehicle that uses both an engine and a motor for traveling and a control method thereof, and more particularly, to a hybrid vehicle configured to be able to be charged from the outside to a power storage device that accumulates electric power used by the motor and a control method thereof.

  In recent years, hybrid vehicles using a motor and an engine in combination for driving wheels have attracted attention as environmentally friendly vehicles. In such a hybrid vehicle, it is also under consideration to make it possible to charge from the outside. In this way, it is convenient for the driver to reduce the number of times that he / she goes to the gas station for refueling by charging at home, etc., and it may be possible to meet the cost by using inexpensive late-night power.

Japanese Patent No. 3016349 (Patent Document 1) discloses a hybrid vehicle having both such an externally chargeable battery and a fuel tank.
Japanese Patent No. 3016349 JP 2001-239847 A

  However, there are various situations where external charging is performed, and there may be cases where it is desired to perform charging and refueling at the same place. For example, there is a case where charging and refueling may be performed together at a gas station or a parking lot of a company.

  The charging control in such a case is not particularly disclosed in Japanese Patent No. 3016349, and there is still room for improvement with regard to simplification of work.

  An object of the present invention is to provide a hybrid vehicle in which charging and refueling operations are simplified and a control method therefor.

  In summary, the present invention relates to a hybrid vehicle, and relates to a power storage device, a charging connector for charging the power storage device, a fuel tank, a supply port for supplying fuel to the fuel tank, and fuel supply and charging. And a control device that performs control. The control device is configured so that the charging period for charging the power storage device via the charging connector and the fuel replenishing period for refueling the fuel tank via the replenishing port do not overlap. Control is performed for at least one of the refueling periods.

  Preferably, the control device instructs the oil supply device to start refueling after the charging period ends.

  Preferably, the control device instructs the charging device to start charging after the refueling period ends.

Preferably, the battery pack further includes a single lid that covers the charging connector and the supply port.
According to another aspect, the present invention is a hybrid vehicle, which is a power storage device, a charging connector for charging the power storage device, a fuel tank, a supply port for supplying fuel to the fuel tank, and a fuel supply And a control device that performs control related to charging. The control device interrupts the charging operation when detecting a preliminary operation for refueling via the replenishment port during a charging operation for charging the power storage device via the charging connector.

  According to still another aspect of the present invention, there is provided a control method for a hybrid vehicle including a power storage device, a charging connector for charging the power storage device, a fuel tank, and a supply port for supplying fuel to the fuel tank. Then, a step of instructing the start of a charging period for charging the power storage device via the charging connector, and after the charging period ends, the fuel tank is replenished with fuel via the replenishment port. And a step of instructing start of a refueling operation.

  According to still another aspect of the present invention, there is provided a control method for a hybrid vehicle including a power storage device, a charging connector for charging the power storage device, a fuel tank, and a supply port for supplying fuel to the fuel tank. And detecting the end of the fuel supply period in which fuel is supplied to the fuel tank via the supply port, and instructing the charging device to start charging after the fuel supply period ends. .

  According to the present invention, the work of charging and refueling an operator is simplified.

  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]
FIG. 1 is a block diagram illustrating the configuration of the vehicle 100 and the fueling / charging device 200.

  Referring to FIG. 1, vehicle 100 includes a wheel 108, a motor 106 that drives wheel 108, an inverter 104 that supplies three-phase AC power to motor 106, and a main battery 102 that supplies DC power to inverter 104. Including.

  The vehicle 100 further includes an engine 109, a generator 107 that generates mechanical power from the engine 109, an inverter 105 that converts three-phase alternating current output from the generator 107 into direct current, and inverters 104 and 105 And a main control unit 114 that performs control. That is, vehicle 100 is a hybrid vehicle that uses both motor 106 and engine 109 for driving.

  Vehicle 100 has a configuration in which main battery 102 can be charged from the outside. In other words, vehicle 100 further includes a connector 124 provided with a terminal for supplying a commercial power supply such as AC 100 V from the outside, and a charging AC supplied to main battery 102 by converting AC power applied to connector 124 to DC power. / DC converter 110, switch 122 that connects connector 124 and charging AC / DC converter 110, and connector connection detector that detects that charging plug 206 of refueling / charging device 200 is connected to connector 124. 120 and a power line communication unit 116.

  Switch 122 and connector 124 serve as a coupling portion for electrically coupling vehicle 100 to an external power supply device. By operating the switch 122, the vehicle and the external power source are electrically coupled.

  Main controller 114 monitors the state of charge (SOC) of main battery 102 and detects connector connection by connector connection detector 120. When the charging state SOC is lower than a predetermined value when the charging plug 206 is connected to the connector 124, the main control unit 114 causes the switch 122 to transition from the open state to the connected state and operates the charging AC / DC conversion unit 110. The main battery 102 is charged.

  The fueling / charging device 200 includes a power line communication unit 210 that receives information such as a power supply request from the vehicle 100 side, an AC power source 202, a charging cable 218, a charging plug 206 provided at an end of the charging cable 218, A switch 204 that connects the AC power source 202 to the cable 218 and a main control ECU 208 that controls opening and closing of the switch 204 are included.

  When the connection is confirmed by the connector connection detection unit 120 and the main battery 102 is charged, the main control unit 114 makes a power supply request to the fuel supply / charging device 200 via the power line communication unit 116. Alternatively, the state of charge SOC is transmitted from the main control unit 114 to the refueling / charging device 200 side via the power line communication unit 116, and the start of power supply is determined based on the state of charge SOC on the refueling / charging device 200 side. Also good.

  When there is a power supply request from the vehicle 100 side to the fuel supply / charging device 200 side, the main control ECU 208 closes the switch 204 to start power supply, and the main control unit 114 operates the charging AC / DC conversion unit 110. The main battery 102 is charged.

  When charging is completed, the state of charge SOC of the main battery 102 becomes higher than a predetermined value, and in response to this, the main control unit 114 stops the charging AC / DC conversion unit 110 and changes the switch 122 from the closed state to the open state. . Then, the fuel supply / charging device 200 is requested to stop power supply via the power line communication unit 116. Then, main control ECU 208 changes switch 204 from the closed state to the open state.

  Further, vehicle 100 includes a fuel tank 126 for accumulating fuel to be supplied to engine 109 and a supply port 128 for supplying fuel to fuel tank 126. In response to this, the fueling / charging device 200 includes a fueling pump 220 for sending fuel, a fueling nozzle 222 for fueling, and a fueling for sending fuel sent from the fueling pump 220 to the fueling nozzle 222. A hose 224.

  FIG. 2 is a view showing an arrangement example of the connector 124 and the fuel supply port 128 provided in the vehicle.

  Referring to FIG. 2, a connector 124 is disposed at any part of the vehicle, and a fuel supply port 128 is disposed below the connector 124. The fuel supply port 128 is provided with a cap (not shown) when fuel is not supplied (for example, when traveling).

  The fuel supply port 128 and the charging connector 124 are normally covered with a common lid 130. When the driver operates a lever or the like disposed in the vehicle, the lid 130 is opened to allow charging and refueling. Note that the fuel supply port 128 and the charging connector 124 do not necessarily have to be covered by the common lid 130, but if they are arranged close enough to be covered by the common lid 130, the same location (for example, When charging and refueling at a gas station, etc., the distance traveled by the worker can be reduced and the work can be facilitated.

  FIG. 3 is a flowchart for illustrating control related to charging and fuel supply executed in vehicle 100 and refueling / charging device 200 in the first embodiment. The processing of this flowchart is called and executed from a predetermined main routine every predetermined time or every time a predetermined condition is satisfied.

  Referring to FIGS. 1 and 3, when processing is started, in step S <b> 1, main controller 114 determines whether charging plug 206 is connected to connector 124 and fuel nozzle 222 is inserted into fuel supply port 128. Judge whether or not. The main control unit 114 can detect whether or not the charging plug 206 and the fuel nozzle 222 are connected based on the output of the connector connection detection unit 120 that detects insertion of the plug.

  If the connection between the charging plug 206 and the fuel nozzle 222 is not detected in step S1, the process of step S1 is executed again, and the process waits until the insertion of the fueling / charging gun is detected.

  If the connection between the charging plug 206 and the fuel nozzle 222 is detected in step S1, the main control unit 114 on the vehicle side issues a charging start instruction to the main control ECU 208 on the charging device side in step S2. This charging start instruction is transmitted to main control ECU 208 via power line communication unit 116, charging cable 218, and power line communication unit 210, for example.

  On the refueling / charging device 200 side, the energization start process of step S11 is performed in accordance with the charge start instruction. In the energization start process, the main control ECU 208 changes the state of the switch 204 from the off state to the on state.

  On the vehicle side, main controller 114 changes the state of switch 122 from the off state to the on state, and causes charging AC / DC converter 110 to start a voltage conversion operation.

  When the charging operation as described above is started, in step S3, main controller 114 determines whether or not a predetermined charging end condition is satisfied. The predetermined charging end condition includes, for example, that the state of charge SOC of the main battery 102 reaches a predetermined value, or that the charging time set by the passenger has elapsed. In addition, if the refueling gun and the charging gun are configured separately, it may be included in the predetermined charging end condition that the charging plug 206 is pulled out from the connector.

  If the charging end condition is not satisfied in step S3, the process of step S3 is executed again, and charging is continued until the charging end condition is satisfied. In step S3, when the charging end condition is satisfied, the process proceeds from step S3 to step S4.

  In step S4, the main control unit 114 on the vehicle side issues a charge end instruction. On the vehicle side, main controller 114 stops the voltage conversion operation of charging AC / DC converter 110 and changes the state of switch 122 from the on state to the off state.

  Further, this charging end instruction is transmitted to main control ECU 208 via power line communication unit 116, charging cable 218, and power line communication unit 210, for example.

  On the refueling / charging device 200 side, an energization end process in step S12 is performed in response to the charge end instruction. In the energization termination process, the main control ECU 208 changes the state of the switch 204 from the on state to the off state.

  When the completion of the charging operation as described above is confirmed, the vehicle-side main control unit 114 issues a refueling permission to the refueling / charging device 200 (step S5). This refueling permission is transmitted to main control ECU 208 via power line communication unit 116, charging cable 218, and power line communication unit 210, for example. In response to the refueling permission, the main control ECU 208 of the refueling / charging device 200 causes the refueling pump 220 to send fuel from a storage tank (not shown) toward the refueling hose 224 and the refueling nozzle 222 (step S13).

  The refueling is executed until a predetermined amount or the fuel tank is full, and the refueling is terminated in step S14. The main control ECU 208 of the fueling / charging device 200 detects that a predetermined amount has been supplied or the fuel tank is full, and stops the fueling pump 220. Instead of stopping by the oil supply pump 220, oil supply may be started and stopped by opening and closing a valve that can be automatically controlled such as an electromagnetic valve.

  Then, main control ECU 208 of refueling / charging device 200 transmits a signal indicating the end of refueling to main control unit 114 on the vehicle side. This signal is transmitted to the main control unit 114 via the power line communication unit 210, the charging cable 218, and the power line communication unit 116, for example.

  The main control unit 114 on the vehicle side detects the presence or absence of the signal in step S6 until a signal indicating the end of refueling is detected. When a signal indicating the end of refueling is detected in step S6, main controller 114 permits removal of the refueling / charging gun from the vehicle in step S7. For example, the permission may be to output a message “Can remove the gun” on the screen or by voice, and the plug 206 and the nozzle 222 are detached from the connector 124 and the supply port 128, respectively. It is also possible to provide a lock mechanism for preventing the vehicle from being locked and to release the lock of the lock mechanism locked during charging and refueling.

  When the processes of step S7 and step S14 are finished, the refueling / charging process is finished in steps S8 and S15, respectively.

  When the charging connector and the fuel supply port are arranged close to each other, it is preferable that the charging period and the fuel supply period are shifted. As described above, the start / end of charging and the start of refueling are instructed to the refueling / charging device from the vehicle side. Since the worker automatically completes both charging and refueling simply by attaching the charging plug and the refueling nozzle, the burden on the worker is reduced. And it is not necessary for the operator to perform timing control for shifting the charging period and the fuel supply period.

  Further, by shifting the charging period and the fuel supply period, the burden on a control device (such as an ECU) that controls charging and refueling is reduced.

[Embodiment 2]
In the first embodiment, an example in which fuel is supplied after charging is completed has been described. In the second embodiment, a case where charging is performed after refueling will be described. Since charging generally takes longer than refueling, it is preferable to use this order when the charging time is not sufficient.

  FIG. 4 is a flowchart for illustrating control related to charging and fuel supply executed in vehicle 100 and refueling / charging device 200 in the second embodiment. The processing of this flowchart is called and executed from a predetermined main routine every predetermined time or every time a predetermined condition is satisfied.

  Referring to FIGS. 1 and 4, when processing is started, in step S <b> 21, main controller 114 determines whether charging plug 206 is connected to connector 124 and fuel nozzle 222 is inserted into fuel supply port 128. Judge whether or not. The main control unit 114 can detect whether or not the charging plug 206 and the fuel nozzle 222 are connected based on the output of the connector connection detection unit 120 that detects insertion of the plug.

  If the connection between the charging plug 206 and the fuel nozzle 222 is not detected in step S21, the process of step S21 is executed again until the insertion of the fueling / charging gun is detected.

  If the connection between the charging plug 206 and the fuel nozzle 222 is detected in step S21, the vehicle-side main control unit 114 instructs the main control ECU 208 on the charging device side to start refueling in step S22. This refueling start instruction is transmitted to main control ECU 208 via power line communication unit 116, charging cable 218, and power line communication unit 210, for example.

  In response to the refueling start instruction, main control ECU 208 of refueling / charging device 200 starts refueling in step S31 and causes fuel pump 220 to send fuel from a storage tank (not shown) toward refueling hose 224 and refueling nozzle 222.

  The refueling is executed until a predetermined amount or the fuel tank is full, and the refueling is terminated in step S32. The main control ECU 208 of the fueling / charging device 200 detects that a predetermined amount has been supplied or the fuel tank is full, and stops the fueling pump 220. Instead of stopping by the oil supply pump 220, oil supply may be started and stopped by opening and closing a valve that can be automatically controlled such as an electromagnetic valve.

  Then, main control ECU 208 of refueling / charging device 200 transmits a signal indicating the end of refueling to main control unit 114 on the vehicle side. This signal is transmitted to the main control unit 114 via the power line communication unit 210, the charging cable 218, and the power line communication unit 116, for example.

  The main control unit 114 on the vehicle side detects the presence or absence of the signal in step S23 until a signal indicating the end of refueling is detected. When a signal indicating the end of refueling is detected in step S23, the process proceeds to step S24, and the main control unit 114 instructs the main control ECU 208 on the charging device side to start charging. This charging start instruction is transmitted to main control ECU 208 via power line communication unit 116, charging cable 218, and power line communication unit 210, for example.

  On the refueling / charging device 200 side, the energization start process of step S33 is performed in accordance with the charge start instruction. In the energization start process, the main control ECU 208 changes the state of the switch 204 from the off state to the on state.

  On the vehicle side, main controller 114 changes the state of switch 122 from the off state to the on state, and causes charging AC / DC converter 110 to start a voltage conversion operation.

  When the charging operation as described above is started, in step S25, the main control unit 114 determines whether or not a predetermined charging end condition is satisfied. The predetermined charging end condition includes, for example, that the state of charge SOC of the main battery 102 reaches a predetermined value, or that the charging time set by the passenger has elapsed. Further, it may be included in the predetermined charging end condition that the charging plug 206 is pulled out from the connector.

  If the charging end condition is not satisfied in step S25, the process of step S25 is executed again and the charging is continued until the charging end condition is satisfied. In step S25, if the charging end condition is satisfied, the process proceeds from step S25 to step S26.

  In step S26, the main control unit 114 on the vehicle side issues a charge end instruction. On the vehicle side, main controller 114 stops the voltage conversion operation of charging AC / DC converter 110 and changes the state of switch 122 from the on state to the off state.

  Further, this charging end instruction is transmitted to main control ECU 208 via power line communication unit 116, charging cable 218, and power line communication unit 210, for example.

  On the refueling / charging device 200 side, an energization end process in step S34 is performed in response to the charging end instruction. In the energization termination process, the main control ECU 208 changes the state of the switch 204 from the on state to the off state.

  When the charging end instruction is output in step S26, the main control unit 114 permits removal of the fueling / charging gun from the vehicle in step S27. For example, the permission may be to output a message “Can remove the gun” on the screen or by voice, and the plug 206 and the nozzle 222 are detached from the connector 124 and the supply port 128, respectively. It is also possible to provide a lock mechanism for preventing the vehicle from being locked and to release the lock of the lock mechanism that has been locked during charging.

  When the processes of step S27 and step S34 are finished, the refueling / charging process is finished in steps S28 and S35, respectively.

  Also in the second embodiment, since the start and end of charging and the start of refueling are instructed from the vehicle side to the refueling / charging device, the worker can automatically charge by simply mounting the charging plug and the refueling nozzle. Since both the refueling operations are completed, the burden on the operator is reduced. And it is not necessary for the operator to perform timing control for shifting the charging period and the fuel supply period.

  Further, by shifting the charging period and the fuel supply period, the burden on a control device (such as an ECU) that controls charging and refueling is reduced.

  Furthermore, even when the charging time is not sufficient, refueling can be preferentially completed.

[Embodiment 3]
In the third embodiment, the charging connector is different from that shown in FIG. 2, and the charging connector 124 and the fuel supply port 128 do not have a common lid. The case determined by will be described. For example, refueling is started when an operator inserts a fuel nozzle into a fuel refill port of a vehicle and pulls a fuel gun trigger.

  In such a case, if the lid of the fuel replenishing port 128 is opened when charging is performed first, it is expected that fuel will be replenished.

  FIG. 5 is a flowchart for illustrating control related to charging and fuel supply executed in vehicle 100 and refueling / charging device 200 in the third embodiment. The processing of this flowchart is called and executed from a predetermined main routine every predetermined time or every time a predetermined condition is satisfied.

  Referring to FIGS. 1 and 5, when the processing is started, first, in step S <b> 41, main controller 114 determines whether or not charging plug 206 is connected to connector 124. The main control unit 114 can detect whether or not the charging plug 206 is connected based on the output of the connector connection detection unit 120 that detects insertion of the plug.

  If the connection between the charging plug 206 and the fuel nozzle 222 is not detected in step S41, the process of step S41 is executed again, and the process waits until the insertion of the charging plug is detected.

  If connection of the charging plug 206 is detected in step S41, charging is started in step S42. On the refueling / charging device 200 side, an energization start process is preferably performed. In the energization start process, the main control ECU 208 changes the state of the switch 204 from the off state to the on state.

  Preferably, on the fuel supply / charging device 200 side, the main control ECU 208 changes the state of the switch 204 from the off state to the on state in response to a charge start instruction from the main control unit 114 on the vehicle side.

  On the vehicle side, main controller 114 changes the state of switch 122 from the off state to the on state, and causes charging AC / DC converter 110 to start a voltage conversion operation. As a result, charging of the main battery 102 is started.

  During charging, it is confirmed in step S43 whether or not the refueling lid is in a closed state. When it is confirmed that the refueling lid is in the closed state, it is further determined in step S44 whether or not a predetermined charging end condition is satisfied. The predetermined charging end condition includes, for example, that the state of charge SOC of the main battery 102 reaches a predetermined value, or that the charging time set by the passenger has elapsed. If the charge termination condition is not satisfied in step S44, the process returns to step S43 again and charging is continued.

  In step S43, when the refueling lid is opened or when the charging end condition is satisfied in step S44, the process proceeds to step S45, and the charging is ended.

  In step S45, on the vehicle side, main controller 114 stops the voltage conversion operation of charging AC / DC converter 110 and changes the state of switch 122 from the on state to the off state.

  Preferably, for example, a charge end instruction is transmitted to main control ECU 208 via power line communication unit 116, charging cable 218, and power line communication unit 210. On the refueling / charging device 200 side, an energization end process in step S12 is performed in response to the charge end instruction. In the energization termination process, the main control ECU 208 changes the state of the switch 204 from the on state to the off state.

  After the charging end process in step S45, the process of this flowchart ends in step S46, and then the operator performs refueling.

  As described above, in the third embodiment, when a preliminary operation for refueling is detected, charging is stopped on the vehicle side. Thereby, the labor which an operator stops charge can be saved. If the charging is terminated in an intermediate state, the charging may be resumed when the operator finishes refueling and closes the lid of the fuel supply port.

  Finally, referring to FIG. 1 again, the embodiment will be generally described. The hybrid vehicle 100 includes a power storage device (main battery 102), a charging connector 124 for charging the power storage device 102, a fuel tank 126, a supply port 128 for supplying fuel to the fuel tank 126, fuel supply and And a control device (main control unit 114) that performs control related to charging. The control device 114 prevents the charging period during which the power storage device 102 is charged via the charging connector 124 and the fuel replenishment period during which fuel is supplied to the fuel tank 126 via the supply port 128 from each other. In addition, control is performed for at least one of the charging period and the fuel supply period.

  Preferably, control device 114 instructs oiling device to start refueling after the charging period ends.

  Preferably, control device 114 commands charging device to start charging after the refueling period ends.

  Preferably, it further includes a single lid 130 that covers the charging connector 124 and the supply port 128.

  A hybrid vehicle according to another aspect of the present invention includes a power storage device 102, a charging connector 124 for charging power storage device 102, a fuel tank 126, a supply port 128 for supplying fuel to fuel tank 126, and a fuel. And a control device 114 that performs control related to replenishment and charging. Control device 114 suspends the charging operation when it detects a preliminary operation for refueling via supply port 128 during the charging operation for charging power storage device 102 via charging connector 124.

  In the present embodiment, fuel is supplied, but gasoline, light oil, alcohol, or the like can be used as the liquid fuel. Further, the present invention can be suitably applied even when gaseous fuel such as natural gas or hydrogen is replenished.

  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.

2 is a block diagram showing a configuration of a vehicle 100 and a fueling / charging device 200. FIG. It is the figure which showed the example of arrangement | positioning of the connector 124 and the fuel supply port 128 which are provided in a vehicle. 4 is a flowchart for illustrating control related to charging and fuel replenishment executed in vehicle 100 and refueling / charging device 200 in the first embodiment. 10 is a flowchart for illustrating control related to charging and refueling executed in vehicle 100 and refueling / charging device 200 in the second embodiment. 10 is a flowchart for illustrating control related to charging and refueling executed in vehicle 100 and refueling / charging device 200 in the third embodiment.

Explanation of symbols

  DESCRIPTION OF SYMBOLS 100 Hybrid vehicle, 102 Main battery, 104,105 Inverter, 106 Motor, 107 Generator, 108 Wheel, 109 Engine, 110 Charging AC / DC conversion part, 114 Main control part, 116, 210 Power line communication part, 120 Connector connection Detection unit, 122, 204 switch, 124 connector, 126 fuel tank, 128 fuel supply port, 130 lid, 200 refueling / charging device, 202 AC power supply, 206 plug, 218 charging cable, 220 refueling pump, 222 nozzle, 224 refueling hose , 208 Main control ECU.

Claims (7)

A power storage device;
A charging connector for charging the power storage device;
A fuel tank,
A replenishing port for refueling the fuel tank;
A control device that performs control related to refueling and charging,
The control device prevents a charging period during which the power storage device is charged via the charging connector and a fuel replenishing period during which fuel is supplied to the fuel tank via the replenishing port from overlapping each other. A hybrid vehicle that controls at least one of the charging period and the fuel supply period.   The hybrid vehicle according to claim 1, wherein the control device instructs a fueling device to start refueling after the charging period ends.   The hybrid vehicle according to claim 1, wherein the control device instructs the charging device to start charging after the refueling period ends.   The hybrid vehicle according to claim 1, further comprising a single lid that covers the charging connector and the supply port. A power storage device;
A charging connector for charging the power storage device;
A fuel tank,
A replenishing port for refueling the fuel tank;
A control device that performs control related to refueling and charging,
The control device interrupts the charging operation when detecting a preliminary operation for refueling via the replenishing port during a charging operation for charging the power storage device via the charging connector. vehicle. A control method for a hybrid vehicle comprising a power storage device, a charging connector for charging the power storage device, a fuel tank, and a supply port for supplying fuel to the fuel tank,
Commanding the start of a charging period for charging the power storage device via the charging connector;
And a step of instructing a fueling device to start a fueling operation for refueling the fuel tank via the replenishing port after the charging period ends. A control method for a hybrid vehicle comprising a power storage device, a charging connector for charging the power storage device, a fuel tank, and a supply port for supplying fuel to the fuel tank,
Detecting the end of a fuel supply period in which fuel is supplied to the fuel tank via the supply port;
And a step of instructing the charging device to start charging after the refueling period ends.

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