JP5757262B2 - Air conditioner and vehicle equipped with the same - Google Patents

Description

  The present invention relates to an air conditioner and a vehicle including the same, and more particularly to an air conditioner mounted on a vehicle having a discharge mode for discharging from the vehicle to the outside of the vehicle as an operation mode.

  In recent years, a technique has been proposed in which the passenger compartment is air-conditioned in advance (hereinafter referred to as pre-air-conditioning) to improve comfort when the passenger gets on. For example, by performing a cooling operation as pre-air conditioning before boarding a vehicle that has been stopped for a long time in midsummer, the heat in the passenger compartment is alleviated during boarding.

  As an air conditioner that air-conditions the interior of a hybrid vehicle using an engine and an electric motor as a drive source, the compressor is driven by the power from the battery to air-condition the interior of the vehicle even when the engine is stopped. Some are pre-conditioned. Japanese Patent Laying-Open No. 2006-298262 (Patent Document 1) discloses a technique for stopping the operation of pre-air conditioning when the remaining capacity of the battery becomes a predetermined value or less so that the battery does not overdischarge.

JP 2006-298262 A JP 2001-063347 A JP 2010-283984 A Japanese Patent Application Laid-Open No. 09-109648 JP 2010-163092 A

  In the technology disclosed in Japanese Patent Laid-Open No. 2006-298262, the pre-air conditioning operation is determined according to the remaining capacity of the battery. On the other hand, the use of a hybrid vehicle as a power source for outdoor use of electric devices and disasters has also been studied (hereinafter, such an operation mode is referred to as a discharge mode).

  The hybrid vehicle having the discharge mode can generate electric power with the engine and discharge the battery outside without reducing the remaining capacity of the battery. If pre-air conditioning is set, the remaining capacity of the battery will not decrease if there is fuel even if the air conditioner is activated. For this reason, in the technique disclosed in Japanese Patent Laid-Open No. 2006-298262, there is a possibility that wasteful power is consumed by continuing air conditioning for a long time in the absence of a passenger. It is preferable to consider so that such wasteful power is not easily generated.

  An object of the present invention is to provide an air conditioner capable of achieving both user convenience and reduction of useless power consumption of the air conditioner in a vehicle operable in a discharge mode, and a vehicle including the same. is there.

  In summary, the present invention is an air conditioner mounted on a vehicle having a discharge mode for discharging to the outside of the vehicle as an operation mode, and includes an air conditioning unit that performs air conditioning of the vehicle interior and a control device that controls the air conditioning unit. . When the control device detects that the operation mode is designated as the discharge mode, the control device stops the operation of the air conditioning unit, and even if it is detected that the operation mode is designated, an occupant is detected in the passenger compartment. When the operation for instructing the operation of the air conditioning unit is performed by a passenger, the operation of the air conditioning unit is permitted.

  Preferably, the vehicle further includes, as an operation mode in addition to the discharge mode, a travel mode specified during travel of the vehicle and a charge mode for charging the in-vehicle power storage device from the outside. The control device includes a storage unit that stores data indicating the operating state of the air conditioner. The control device reads the data from the storage unit when specifying the charging mode and the traveling mode, sets the initial state of the air conditioner to the operating state corresponding to the data, and regardless of the storage contents of the storage unit when specifying the discharge mode The initial state of the air conditioner is set to the stop state.

  More preferably, the control device updates the data stored in the storage unit to data corresponding to the changed operating state when the operating state of the air conditioning unit is changed by an occupant's operation in the discharge mode.

  Preferably, in the discharge mode, the control device stops the operation of the air conditioning unit when the air conditioning unit is operating when the occupant moves from the passenger compartment to the outside of the passenger compartment.

  Preferably, the vehicle includes a generator that is activated as necessary according to the discharge mode to generate power, and a power storage device that can store the power generated by the generator.

  In another aspect, the present invention is a vehicle on which any one of the above air conditioners is mounted.

  According to the present invention, useless power consumption of an air conditioner can be reduced in a vehicle having a discharge mode.

1 is an overall block diagram of a hybrid vehicle 100 according to the present embodiment. It is a figure for demonstrating discharge mode. 3 is a schematic view of a power supply connector 600. FIG. It is a block diagram for demonstrating the electric power feeding operation | movement at the time of using the electric power feeding connector of FIG. It is a flowchart for demonstrating the control which changes the setting of an air conditioner by control mode. 6 is a flowchart for explaining control mode discrimination in S10 of FIG. 5; It is a wave form chart for explaining state transition of an air conditioner in run mode and charge mode. It is a wave form chart for explaining state transition of an air conditioner in run mode and discharge mode.

  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.

[Description of vehicle and charging cable]
FIG. 1 is an overall block diagram of hybrid vehicle 100 according to the present embodiment. Referring to FIG. 1, vehicle 100 includes a power storage device 110, a system main relay (SMR) 115, a PCU (Power Control Unit) 120, an air conditioner 125, motor generators 130 and 135, A transmission gear 140, drive wheels 150, an engine 160, and an ECU (Electronic Control Unit) 300 that is a control device are provided. PCU 120 includes a converter 121, inverters 122 and 123, and capacitors C1 and C2.

  The power storage device 110 is a power storage element configured to be chargeable / dischargeable. The power storage device 110 includes, for example, a secondary battery such as a lithium ion battery, a nickel metal hydride battery, or a lead storage battery, or a power storage element such as an electric double layer capacitor.

  Power storage device 110 is connected to PCU 120 via positive power line PL1 and negative power line NL1. Then, power storage device 110 supplies power for generating driving force of vehicle 100 to PCU 120. Power storage device 110 stores the electric power generated by motor generators 130 and 135. The output of power storage device 110 is, for example, about 200V.

  Although not shown, power storage device 110 includes a voltage sensor and a current sensor, and outputs voltage VB and current IB of power storage device 110 detected by these sensors to ECU 300.

  One of the relays included in SMR 115 is connected to the positive terminal of power storage device 110 and positive power line PL1 connected to PCU 120, and the other relay is connected to the negative terminal of power storage device 110 and negative power line NL1. SMR 115 switches between power supply and cutoff between power storage device 110 and PCU 120 based on control signal SE <b> 1 from ECU 300.

  Converter 121 performs voltage conversion between positive power line PL1 and negative power line NL1, positive power line PL2, and negative power line NL1 based on control signal PWC from ECU 300.

  Inverters 122 and 123 are connected in parallel to positive power line PL2 and negative power line NL1. Inverters 122 and 123 convert DC power supplied from converter 121 to AC power based on control signals PWI1 and PWI2 from ECU 300, respectively, and drive motor generators 130 and 135, respectively.

  Capacitor C1 is provided between positive power line PL1 and negative power line NL1, and reduces voltage fluctuation between positive power line PL1 and negative power line NL1. Capacitor C2 is provided between positive power line PL2 and negative power line NL1, and reduces voltage fluctuation between positive power line PL2 and negative power line NL1.

  Motor generators 130 and 135 are AC rotating electric machines, for example, permanent magnet type synchronous motors having a rotor in which permanent magnets are embedded.

  The output torque of motor generators 130 and 135 is transmitted to drive wheels 150 via power transmission gear 140 including a reduction gear and a power split mechanism, and causes vehicle 100 to travel. Motor generators 130 and 135 can generate electric power by the rotational force of drive wheels 150 during regenerative braking operation of vehicle 100. Then, the generated power is converted into charging power for power storage device 110 by PCU 120.

  Motor generators 130 and 135 are also coupled to engine 160 through power transmission gear 140. Then, ECU 300 causes motor generators 130 and 135 and engine 160 to operate in a coordinated manner to generate a necessary vehicle driving force. Further, motor generators 130 and 135 can generate electric power by rotation of engine 160, and can charge power storage device 110 using the generated electric power. In the present embodiment, motor generator 135 is used exclusively as an electric motor for driving drive wheels 150, and motor generator 130 is used exclusively as a generator driven by engine 160.

  In FIG. 1, a configuration in which two motor generators are provided is shown as an example. However, the number of motor generators is not limited to this, and the number of motor generators is one, or more than two motor generators are provided. It is good also as a structure. The vehicle 100 may be an electric vehicle not equipped with an engine or a fuel cell vehicle.

  Vehicle 100 includes a charger 200, a charging relay CHR 210, and an inlet 220 as a connection unit as a configuration for charging power storage device 110 with electric power from external power supply 500.

  A charging connector 410 of the charging cable 400 is connected to the inlet 220. Then, electric power from external power supply 500 is transmitted to vehicle 100 via charging cable 400.

  In addition to charging connector 410, charging cable 400 includes a plug 420 for connecting to outlet 510 of external power supply 500, and a power line 440 for connecting charging connector 410 and plug 420. Charging circuit interruption device (hereinafter also referred to as CCID (Charging Circuit Interrupt Device)) 430 for switching between supply and interruption of electric power from external power supply 500 is inserted in electric power line 440.

  Charger 200 is connected to inlet 220 through power lines ACL1 and ACL2. Charger 200 is connected to power storage device 110 through positive power line PL2 and negative power line NL2 via CHR 210.

  Charger 200 is controlled by a control signal PWD from ECU 300 and converts AC power supplied from inlet 220 into charging power for power storage device 110.

  Vehicle 100 further includes an AC 100V inverter 201 and a discharge relay DCHR 211 as a configuration for supplying electric power to the outside. The inlet 220 is also used as a connection unit that outputs power. The structure connected to the inlet during discharge will be described later with reference to FIGS.

  AC 100 V inverter 201 can also convert DC power from power storage device 110 or DC power generated by motor generators 130 and 135 and converted by PCU 120 into AC power to supply power to the outside of the vehicle. Instead of the AC 100 V inverter 201, another AC voltage or DC voltage output device may be provided. Moreover, the charger 200 and the AC100V inverter 201 may be one device capable of bidirectional power conversion for charging and feeding.

  CHR 210 is controlled by control signal SE <b> 2 from ECU 300, and switches between supply and interruption of power between charger 200 and power storage device 110. The DCHR 210 is controlled by a control signal SE3 from the ECU 300, and switches between connection and disconnection of a power path between the inlet 220 and the AC 100V inverter 201. Note that during charging shown in FIG. 1, the CHR 210 is controlled to be in a connected state, and the DCHR 211 is controlled to be in a disconnected state.

  ECU 300 includes a non-volatile memory 370 for storing initial settings of air conditioner 125. Although not shown in FIG. 1, ECU 300 further includes a CPU (Central Processing Unit), a storage device, and an input / output buffer, and inputs signals from each sensor and outputs control signals to each device. At the same time, each device of power storage device 110 and vehicle 100 is controlled. Note that these controls are not limited to processing by software, and can be processed by dedicated hardware (electronic circuit).

  ECU 300 calculates a state of charge (SOC) of power storage device 110 based on detected values of voltage VB and current IB from power storage device 110.

  ECU 300 receives a signal PISW indicating the connection state of charging cable 400 from charging connector 410. ECU 300 also receives control pilot signal CPLT (hereinafter referred to as pilot signal CPLT) from CCID 430 of charging cable 400. ECU 300 performs a charging operation based on these signals.

  In FIG. 1, one control device is provided as the ECU 300, but for each function or control target device, such as a control device for the PCU 120 or a control device for the power storage device 110, for example. It is good also as a structure which provides this control apparatus.

[Explanation of charging mode]
The configuration of the pilot signal CPLT and the connection signal PISW, and the shapes and terminal arrangements of the inlet 220 and the charging connector 410 are, for example, US SAE (Society of Automotive Engineers), International Electrotechnical Commission (IEC), etc. Has been standardized.

  Although not shown, CCID 430 includes a CPU, a storage device, and an input / output buffer, inputs and outputs each sensor and control pilot signal, and controls the charging operation of charging cable 400.

  The potential of pilot signal CPLT is manipulated by ECU 300. The duty cycle is set based on the rated current that can be supplied from the external power source 500 to the vehicle 100 via the charging cable 400.

  The pilot signal CPLT oscillates at a specified period when the potential of the pilot signal CPLT decreases from the specified potential. Here, the pulse width of pilot signal CPLT is set based on the rated current that can be supplied from external power supply 500 to vehicle 100 via charging cable 400. That is, the rated current is notified to ECU 300 of vehicle 100 from the control pilot circuit in CCID 430 using pilot signal CPLT by the duty indicated by the ratio of the pulse width to the oscillation period.

  Note that the rated current is determined for each charging cable, and the rated current varies depending on the type of charging cable 400. Therefore, the duty of pilot signal CPLT is different for each charging cable 400.

  ECU 300 can detect the rated current that can be supplied to vehicle 100 via charging cable 400 based on the duty of pilot signal CPLT received via control pilot line L1.

  When the relay contact inside CCID 430 is closed, AC power from external power supply 500 is applied to charger 200, and preparation for charging power storage device 110 from external power supply 500 is completed. CPU 310 converts AC power from external power supply 500 into DC power that power storage device 110 can charge by outputting control signal PWD to charger 200. Then, CPU 310 outputs control signal SE2 and closes the contact point of CHR 210 to execute charging of power storage device 110.

[Explanation of discharge mode]
In vehicles capable of external charging as described above, as seen in smart grids, etc., the vehicle is considered as a power supply source, and the concept of supplying electric power from the vehicle to general electrical equipment outside the vehicle has been studied. ing. In some cases, a vehicle is used as a power source when an electric device is used for camping or outdoor work.

  Next, a discharge mode for supplying electric power from the vehicle to the outside will be described. FIG. 2 is a diagram for explaining the discharge mode.

  Referring to FIG. 2, power feeding connector 600 includes a terminal portion having the same shape as the terminal portion of charging connector 410 of charging cable 400 described in FIG. 1, and charging cable 400 is connected to inlet 220 of vehicle 100. It is possible to connect instead.

  The power of the power storage device 110 can be supplied to the inlet 220 via the AC 100V inverter 201. Electric power stored in the power storage device 110 or electric power generated by driving the engine 160 is supplied to the electric device 700 through the power supply connector 600.

  FIG. 3 is a schematic diagram of the power supply connector 600. With reference to FIG. 3, the power feeding connector 600 is provided with a fitting portion 605 and an operation portion 615. The fitting portion 605 has a shape corresponding to the inlet 220 so that the fitting portion 605 can be fitted to the inlet 220.

  The power supply connector 600 is provided with an output unit 610 to which a power plug 710 of an external electric device 700 can be connected. The output unit 610 may be configured separately from the power feeding connector 600, and the output unit 610 and the power feeding connector 600 may be connected by a cable.

  When power supply connector 600 is connected to inlet 220, a power supply operation is performed in vehicle 100, and electric power from vehicle 100 is supplied to electric device 700 through inlet 220 and power supply connector 600.

  FIG. 4 is a block diagram for explaining a power feeding operation when the power feeding connector of FIG. 3 is used. In FIG. 4, the description of overlapping elements with the same reference numerals as in FIGS. 1 and 2 will not be repeated.

  Referring to FIG. 4, ECU 300 mounted on vehicle 100 includes a power supply node 350, a pull-up resistor R10 and a pull-down resistor R15, a CPU 310, a resistance circuit 320, and an input buffer 340.

  Resistance circuit 320 is a circuit for operating the potential of pilot signal CPLT from vehicle 100 side.

  Input buffer 340 receives connection signal PISW and outputs the received connection signal PISW to CPU 310. Note that a voltage is applied to the connection signal line L3 from the ECU 300, and the potential of the connection signal PISW changes depending on the connection of the charging connector 410 to the inlet 220. CPU 310 detects the connection state and fitting state of charging connector 410 by detecting the potential of connection signal PISW.

  CPU 310 receives connection signal PISW from input buffer 340. CPU 310 detects the potential of connection signal PISW, and detects the connection state and fitting state of power supply connector 600.

  When power feeding connector 600 is connected to inlet 220, power lines ACL1 and ACL2 on vehicle 100 side and output unit 610 are electrically connected via power transmission unit 606.

  The power supply connector 600 includes a connection portion 601 connected to the connection signal line L3, a connection portion 602 connected to the connection portion 601 and the control pilot line L1, a connection portion 603 connected to the ground line L2, and a connection circuit 604. With.

  When the power supply connector 600 is attached to the inlet 220, the connection unit 601 is electrically connected to the connection signal line L3. Connection unit 602 is electrically connected to control pilot line L <b> 1 when power supply connector 600 is attached to inlet 220. When the power feeding connector 600 is attached to the inlet 220, the connecting portion 603 is electrically connected to the ground line L2.

  Power supply connector 600 further includes resistors R30 and R31 and a switch SW30. When power supply connector 600 is connected to inlet 220, resistors R30 and R31 are connected in series between connection signal line L3 and ground line L2.

  The switch SW30 is connected in parallel with the resistor R31. The switch SW30 has its contact closed in a state where the power supply connector 600 is securely fitted to the inlet 220. That is, the switch SW30 is normally closed. When the power supply connector 600 is disconnected from the inlet 220 and the fitting state between the power supply connector 600 and the inlet 220 is uncertain, the contact of the switch SW30 is opened. Further, the contact of the switch SW30 is also opened when the operation unit 615 is operated. Therefore, the state of switch SW30 changes when power feeding connector 600 is attached to vehicle 100 and when power feeding connector 600 is removed from vehicle 100.

  When power supply connector 600 is connected to inlet 220, CPU 310 can determine the connection state and fitting state of power supply connector 600 based on the combined resistance determined by the combination of resistors R10, R15, R30, and R31.

  The power supply connector 600 further includes a switch SW10 in addition to the switch SW30. The switch SW10 is provided between the connection unit 601 and the connection unit 602 on the connection circuit 604. The switch SW10 is normally open.

  The switch SW10 and the switch SW30 are interlocked when the operation unit 615 is operated. When the operation unit 615 is operated by the user, the switch SW10 is closed and the switch SW30 is opened. If the operation unit 615 is not operated, the switch SW10 is opened and the switch SW30 is closed.

  When the switch SW10 is closed, the connection circuit 604 connects the connection unit 601 and the connection unit 602. Therefore, the connection circuit 604 connects the connection signal line L3 and the control pilot line L1 when the power feeding connector 600 is attached to the inlet 220 and the switch SW10 is operated.

  Note that the switch SW30 may be normally open and the switch SW10 may be normally closed. In this case, when the operation unit 615 is operated by the user, the switch SW10 is opened and the switch SW30 is closed. That is, if the operation unit 615 is not operated, the switch SW10 may be closed and the switch SW30 may be opened. The switch SW10 and the switch SW30 are provided to change the potential of the connection signal line L3 and the potential of the control pilot line L1.

  The CPU 310 recognizes that the power feeding connector 600 is attached from the change pattern of the potential of the connection signal line L3 and the change pattern of the potential of the control pilot line L1. More specifically, when the potential of the connection signal line L3 and the potential of the control pilot line L1 increase synchronously and then decrease synchronously, the CPU 310 recognizes that the power supply connector 600 is attached. The potential change pattern for recognizing that the power supply connector 600 is attached is not limited to this. The power supply connector 600 is attached when a potential change pattern obtained by the user operating the operation unit 615 in a predetermined pattern a plurality of times (for example, twice or a combination of 3 times and 7 times) is detected. You may make it recognize.

  The combination of the normal state of the switch SW30 and the normal state of the switch SW10, the number of operations of the operation unit 615, and the like can be variously modified. In ECU 300, software or the like may be changed so that the deformed combination is recognized in a corresponding state.

  When the CPU 310 recognizes that the power supply connector 600 is connected, the CPU 310 opens the CHR 210, closes the DCHR 211, and controls the AC 100V inverter 201 to perform the power supply operation, thereby supplying the electric power from the power storage device 110 to an external electric device. 700 is supplied.

  Further, when the SOC of power storage device 110 decreases or when an instruction is received from the user, CPU 310 drives engine 160 to generate power by motor generator 130, and the generated power is supplied to electric device 700. Supply.

[Control of air conditioner]
FIG. 5 is a flowchart for illustrating control for changing the setting of the air conditioner according to the control mode.

  Referring to FIG. 5, when ECU 300 is activated, first, in step S10, the control mode is determined. The control mode is any one of a travel mode for controlling the vehicle to be able to travel, a charge mode for charging the power storage device of the vehicle from the outside, and a discharge mode for outputting electric power from the power storage device or generator of the vehicle to the outside of the vehicle. However, other modes may exist.

  FIG. 6 is a flowchart for explaining control mode discrimination in S10 of FIG. Referring to FIG. 6, when the determination process is started, it is determined in step S11 whether or not the power position managed in the ECU is in the IG-ON state. The power supply position shifts to the IG-ON state when, for example, the ignition key switch is operated from OFF → ACC → ON. In the case of a push button type start switch, the power position shifts to the ACC state when the push button is pressed once, and shifts to the IG-ON state when the push button is pressed again.

  If it is determined in step S11 that the power supply position is not in the IG-ON state, the process proceeds to step S12. In step S12, it is determined whether or not the power is activated by plug-in charging (whether or not the power position is in the IGP-ON state).

  In step S12, for example, when the charging cable 400 of FIG. 1 is connected to the inlet 220 and the power supply is activated when the charging mode is recognized by the change of the pilot signal CPLT from the CCID 430, the power position is set to IGP-ON. It is determined that it is in a state.

  If it is determined in step S12 that the power supply position is not in the IGP-ON state, in step S13, the process returns to the main routine and waits for the control mode to be set again. If it is determined in step S12 that the power supply position is in the IGP-ON state, the process proceeds to step S17, the control mode is determined to be the charging mode, and then the process proceeds to step S60 in FIG. .

  If it is determined in step S11 that the power supply position is in the IG-ON state, the process proceeds to step S14. In step S14, it is determined whether or not the power position has shifted to the ST-ON state by a predetermined operation. For example, when the position of the ignition key switch is operated from OFF → ACC → ON → START, the power supply position shifts to the ST-ON state. In the case of a push button type start switch, for example, when the push button is pressed once, the power position shifts to the ACC state, and when pressed again, the power position shifts to the IG-ON state, but the shift position is set to the parking position. When the push button is pressed while stepping on the brake while the power position is OFF, ACC, or IG-ON, the power position shifts to the ST-ON state.

  In step S14, if the power supply position is in the ST-ON state, ECU 300 determines that the control mode is the traveling mode.

  In step S14, if the power supply position is not in the ST-ON state, the process proceeds to step S15. In step S15, it is determined whether or not pilot signal CPLT continues to oscillate.

  If the pilot signal CPLT continues to oscillate in step S15, the process proceeds to step S17, where it is determined that the control mode is the charge mode, and then the process proceeds to step S60 in FIG.

  If pilot signal CPLT does not continue to oscillate in step S15, the process proceeds to step S16. In step S16, the ECU 300 determines whether or not the power generation unit (power feeding connector 600) described with reference to FIGS.

  If the attachment of the power generation unit is recognized in step S16, the process proceeds to step S19, the control mode is determined to be the discharge mode, and then the process proceeds to step S110 in FIG.

  On the other hand, if the attachment of the power generation unit is not recognized in step S16, the process proceeds to step S13, and the process returns to the main routine to wait for the control mode to be set to any one again.

  In the above processing, when it is determined that the control mode is any mode, the processing proceeds from step S10 in FIG. 5 to any one of steps S20, S60, and S110.

  Referring to FIG. 5 again, first, when it is determined in step S10 that the control mode is the traveling mode, the process proceeds to step S20, and the initialization operation of the air conditioner such as the air conditioner 125 is executed.

  In step S20, set value SXAC (MEM) stored in nonvolatile memory 370 inside ECU 300 is read as set value SXAC as an initial value after activation of the air conditioner. The content of the operation initial value may be only the operating state (ON / OFF), but may include the air volume, temperature setting, and the like. As a result, the air conditioner such as the air conditioner 125 performs the same operation as the content previously set by the user, so that there are many cases where the user can save the trouble of setting the air conditioner after the vehicle is started.

  After the initialization operation is performed in step S20, it is determined in step S30 whether or not an operation by the user has been performed. The operation by the user is, for example, a switch operation for operating the air conditioner 125 from the stopped state or a switch operation for stopping the air conditioner 125 from the operating state. The operation by the user may include an operation for changing the air volume or changing the temperature.

  If there is an operation by the user in step S30, the process proceeds to step S40, and an update value corresponding to the operation by the user is written in the set value SXAC. Further, in step S50, the same value as the set value SXAC updated in the nonvolatile memory 370 is also written to the set value SXAC (MEM). Since the set value SXAC (MEM) is also updated, it becomes possible to reproduce the state of the air conditioner last set in the travel mode when the vehicle is started next time.

  If the process in step S50 is completed or if there is no user operation in step S30, the process returns to step S30 again and enters a user operation waiting state. And the process of step S30-S50 is repeatedly performed until driving | running | working mode is complete | finished.

  If it is determined in step S10 that the control mode is the charging mode, the process proceeds to step S60, and the initialization operation of the air conditioner such as the air conditioner 125 is executed. In step S60, set value SXAC (MEM) stored in non-volatile memory 370 inside ECU 300 is read as set value SXAC as an initial value after activation of the air conditioner.

  The content of the operation initial value may be only the operating state (ON / OFF), but may include the air volume, temperature setting, and the like. As a result, the air conditioner such as the air conditioner 125 performs the same operation as the content previously set by the user, so that there are many cases where the user can save the trouble of setting the air conditioner after the vehicle is started. This initial value may be a set value of the air conditioner 125 that is activated by a timer after elapse of a predetermined time from the start of charging. For example, if you connect a charging cable to a vehicle and charge it from a home outlet after returning home, if you set the startup time slightly before the next vehicle use, the setting of the air conditioner at the end of the previous run will remain It is reproduced.

  After the initialization operation is performed in step S60, it is determined in step S70 whether or not an operation by the user has been performed. The operation by the user is, for example, a switch operation for operating the air conditioner 125 from the stopped state or a switch operation for stopping the air conditioner 125 from the operating state. The operation by the user may include an operation for changing the air volume or changing the temperature.

  In step S70, if there is an operation by the user, the process proceeds to step S80, and an update value corresponding to the operation by the user is written in the set value SXAC. In this case, unlike the traveling mode, the set value SXAC (MEM) in step S50 is not updated.

  This is because, for example, in a usage where air conditioning is applied during charging and music is listened to in the passenger compartment, it may be possible to set the operating condition of the air conditioning different from that during driving. Further, even if the user stops the air conditioning to save power during charging, the final state of the air conditioner at the time of starting is reproduced at the start of the next driving. Therefore, since the stop state at the time of charging is not stored, it is possible to prevent the user from noticing that the stop state is reproduced and the air conditioner is stopped when the vehicle is started and the comfort is lowered.

  If there is no user operation in step S70, the process proceeds to step S90, and it is determined whether or not the state of charge (SOC: State Of Charge) of power storage device 110 has decreased below a predetermined threshold value. . For example, even in the charging mode, if the power consumed by the air conditioner 125 or the heater is larger than the power charged in the power storage device 110, the SOC gradually decreases. If the SOC decreases too much, the power storage device 110 may be overdischarged, which may adversely affect the life. Moreover, even if the user intends to charge the battery, if the battery is not actually charged, the distance that can be traveled without using the engine is shortened, which is inconvenient.

  Therefore, a threshold value that matches the user's needs is set for the SOC, and the SOC is managed so as not to fall below this threshold value in step S90.

  If the SOC is lower than the threshold value in step S90, the process proceeds to step S100, and ECU 300 sets the set value SXAC to OFF and stops air conditioner 125. Control may be performed so that power supply to a load that consumes a large amount of power, such as a seat heater, is stopped when the air conditioner 125 is stopped.

  In step S90, when the SOC is not lower than the threshold value, or when the process of step S100 is completed, the process returns to step S70 and waits for a user operation. And the process of step S70-S100 is repeatedly performed until charge mode is complete | finished.

  If it is determined in step S10 that the control mode is the discharge mode, the process proceeds to step S110, and the initialization operation of the air conditioner such as the air conditioner 125 is executed. In step S110, regardless of the set value SXAC (MEM) stored in the non-volatile memory 370 inside the ECU 300, the set value SXAC is set to an OFF state as an initial value after activation of the air conditioner.

  In the discharge mode, since electric power is discharged to the outside of the vehicle, it is assumed that the user uses the electric device outside the vehicle. Accordingly, an air conditioner such as the air conditioner 125 may waste power if it reproduces and executes the same operation as previously set by the user. Moreover, since it may be used in a discharge mode in a disaster or the like, it is desirable to give priority to cutting unnecessary power consumption over user convenience.

  After the initialization operation is performed in step S110, it is determined in step S120 whether an occupant has been detected in the passenger compartment. The occupant can be detected by various methods, for example, by a seating sensor or an infrared sensor. If an occupant is detected in the passenger compartment in step S120, the operation of the air conditioner is permitted if instructed. The power consumption due to the operation of the air conditioner when the occupant is in the passenger compartment is treated as not unnecessary power consumption.

  That is, if an occupant is detected in the passenger compartment in step S120, it is determined in step S130 whether or not an operation by the user has been performed. The operation by the user is, for example, a switch operation for operating the air conditioner 125 from the stopped state or a switch operation for stopping the air conditioner 125 from the operating state. The operation by the user may include an operation for changing the air volume or changing the temperature.

  If there is an operation by the user in step S130, the process proceeds to step S140, and an update value corresponding to the operation by the user is written in the set value SXAC. In this case, unlike the traveling mode, the set value SXAC (MEM) in step S50 is not updated.

  On the other hand, if no occupant is detected in the passenger compartment in step S120, the process proceeds to step S150, OFF is written in set value SXAC, and the operation of the air conditioner is stopped.

  When the process of step S140 or S150 is completed, the process returns to step S120 again to enter a state of waiting for passenger detection and user operation. And the process of step S120-S150 is repeatedly performed until discharge mode is complete | finished.

  FIG. 7 is a waveform diagram for explaining the state transition of the air conditioner in the traveling mode and the charging mode.

  Referring to FIGS. 1 and 7, the vehicle is controlled in the traveling mode until time t1. At this time, when the ignition switch or the start switch is operated and the power supply position changes from the IG-ON state to the OFF state, the operation state “ON” of the air conditioner 125 at that timing is stored in the nonvolatile memory 370.

  At time t2, when the power supply position changes from the OFF state to the IGP-ON state due to the connection of the charging cable 400, the operation state “ON” stored in the nonvolatile memory 370 at that time is set to the operation state of the air conditioner 125. The

  At time t3, when the air conditioner 125 OFF command is input by the user's operation or the SOC of the power storage device 110 falls below a predetermined threshold value, the air conditioner operating state changes from the ON state to the OFF state. Transition to.

  At time t4, when charging is completed or the charging cable is removed from the inlet, the power supply position changes from the IGP-ON state to the OFF state. At this time, in particular, the storage contents of the nonvolatile memory 370 are not updated, and the operation state “ON” remains stored.

  At time t5, when the user gets on and operates the ignition key or start switch to change the power position to the IG-ON state, the control mode is set to the traveling mode. Then, based on the operating state “ON” that is the content stored in the nonvolatile memory 370 at this time, the air conditioner 125 also starts to operate even if the user does not perform an operation to start the air conditioner 125.

  FIG. 8 is a waveform diagram for explaining the state transition of the air conditioner in the travel mode and the discharge mode.

  Referring to FIGS. 4 and 8, the vehicle is controlled in the traveling mode until time t11. At this time, when the ignition switch or the start switch is operated and the power supply position changes from the IG-ON state to the OFF state, the operation state “ON” of the air conditioner 125 at that timing is stored in the nonvolatile memory 370.

  At time t12, the ignition switch or start switch is operated, and the power supply position changes from the OFF state to the IG-ON state. Then, when the power supply position changes from the OFF state to the IGP-ON state, the operation state “ON” stored in the nonvolatile memory 370 at that time is set to the operation state of the air conditioner 125.

  At time t13, when the user attaches power feeding connector 600 to inlet 220 and performs a predetermined operation (for example, an operation of pressing operation unit 615 twice), ECU 300 changes the control mode to the discharge mode. Since the initial state of the air conditioner 125 in the discharge mode is set to the OFF state in step S110 in FIG. 5, the air conditioner 125 stops operating at time t13. Then, after time t13, the vehicle is set in the discharge mode, so that power can be supplied to the electric device 700 via the power supply connector 600.

  In the discharge mode, when the operation of the air conditioner 125 is instructed by a user operation as indicated by the broken line at time 14, the air conditioner starts operation (steps S130 and S140 in FIG. 5). When the user moves out of the passenger compartment and no passenger is present in the passenger compartment as indicated by the broken line at time t15, the air conditioner 125 returns to the OFF state (steps S120 and S150 in FIG. 5).

  At time t <b> 16, the power supply position changes from the IG-ON state to the OFF state in response to the user operating the ignition switch or the start switch. At this time, in particular, the storage contents of the nonvolatile memory 370 are not updated, and the operation state “ON” remains stored.

  At time t17, when the user gets on and operates the ignition key or start switch to change the power position to the IG-ON state, the control mode is set to the traveling mode. Then, based on the operating state “ON” that is the content stored in the nonvolatile memory 370 at this time, the air conditioner 125 also starts to operate even if the user does not perform an operation to start the air conditioner 125.

  Finally, the present embodiment will be summarized with reference to the drawings again. Referring to FIG. 4, the air conditioner of the present embodiment is an air conditioner mounted on a vehicle having a discharge mode for discharging to the outside of the vehicle as an operation mode, and an air conditioner (air conditioner 125) for air conditioning the vehicle interior. ) And a control device (ECU 300) for controlling the air conditioning unit. When the control device detects that the operation mode is designated as the discharge mode, the control device stops the operation of the air conditioning unit, and even if it is detected that the operation mode is designated, an occupant is detected in the passenger compartment. When the operation for instructing the operation of the air conditioning unit is performed by a passenger, the operation of the air conditioning unit is permitted.

  By controlling in this way, output reduction can be suppressed by stopping the air conditioning at the time of external discharge, and the user's request can also be satisfied by permitting the air conditioning only at the time of user operation.

  Preferably, the vehicle further includes, as an operation mode in addition to the discharge mode, a travel mode specified during travel of the vehicle and a charge mode for charging the in-vehicle power storage device (power storage device 110) from the outside. The control device includes a storage unit (nonvolatile memory 370) that stores data indicating the operating state of the air conditioner. The control device reads the data from the storage unit when specifying the charging mode and the traveling mode, and sets the initial state of the air conditioner to the operating state corresponding to the data (S20, S60 in FIG. 5, times t2, t5 in FIG. 7). ) When the discharge mode is designated, the initial state of the air conditioner is set to the stop state regardless of the storage contents of the storage unit (S110 in FIG. 5 and time t13 in FIG. 8).

  More preferably, when the operating state of the air conditioning unit is changed by an occupant's operation in the discharge mode (YES in S130 of FIG. 5), the control device responds to the changed operating state of the data stored in the storage unit. To the data to be updated (time t14 in FIG. 8).

  Preferably, in the discharge mode, the control device stops the operation of the air-conditioning unit when the occupant moves from the passenger compartment to the exterior of the passenger compartment in operation in the discharge mode (S150 in FIG. 5 and t15 in FIG. 8). .

  Preferably, the vehicle is activated as necessary according to the discharge mode to generate power (engine 160 and motor generator 130 in FIG. 4), and a power storage device that can store the power generated by the power generator ( Power storage device 110).

In another aspect, the present invention is a vehicle on which any one of the above air conditioners is mounted.
In the present embodiment, a hybrid vehicle is illustrated, but the present invention can also be applied to an electric vehicle, a fuel cell vehicle, and the like. Further, in this embodiment, an example in which a discharging power supply connector is attached to a charging inlet is shown, but it is not always necessary to do so. If the charging mode and the discharging mode are provided as control modes, for example, a vehicle that performs charging via a power receiving unit that receives power in a non-contact manner and has a power feeding connector connection unit dedicated for discharging may be used.

  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.

  100 hybrid vehicle, 110 power storage device, 121 converter, 122, 123, 201 inverter, 125 air conditioner, 130, 135 motor generator, 140 power transmission gear, 150 driving wheel, 160 engine, 200 charger, 220 inlet, 320 resistance circuit, 340 input buffer, 350 power supply node, 370 nonvolatile memory, 400 charging cable, 410 charging connector, 420 plug, 440, ACL1, ACL2 power line, 500 external power supply, 510 outlet, 600 power supply connector, 601 602, 603 connection, 604 connection circuit, 605 fitting section, 606 power transmission section, 610 output section, 615 operation section, 700 electrical equipment, 710 power plug, C1, C2, C1, C2 capacitor, 210 charge Electric relay, CPLT pilot signal, 211 discharge relay, L1 control pilot line, L2 ground line, L3 connection signal line, NL1, NL2 negative power line, PL1, PL2 positive power line, R10, R15, R30, R31 resistance, R10 pull-up resistance , R15 pull-down resistor, SW10, SW30 switch.

Claims (6)

An air conditioner mounted on a vehicle having a discharge mode for discharging outside the vehicle as an operation mode,
An air conditioning unit for air conditioning in the passenger compartment;
A control device for controlling the air conditioning unit,
The control device, wherein the operating mode if specified in the discharge mode, stops the operation of the air-conditioning unit as an initial state, the operation of the air conditioning unit after the operation mode is designated in said discharge mode An air conditioner that permits operation of the air conditioning unit when an operation for instructing is performed by a passenger. The vehicle further includes, as the operation mode in addition to the discharge mode, a travel mode specified during the travel of the vehicle and a charge mode for charging the in-vehicle power storage device from the outside,
The control device includes a storage unit that stores data indicating an operating state of the air conditioner,
The control device reads the data from the storage unit when specifying the charging mode and the traveling mode, sets the initial state of the air conditioner to an operating state corresponding to the data, and when specifying the discharging mode The air conditioner according to claim 1, wherein an initial state of the air conditioner is set to a stopped state regardless of the storage contents of the storage unit.   The said control apparatus updates the data which the said memory | storage part memorize | stores in the data corresponding to the changed operating state, when the operating state of the said air-conditioning part is changed by operation of the passenger | crew in the said discharge mode. 2. The air conditioner according to 2.   4. The control device according to claim 1, wherein the control device stops the operation of the air-conditioning unit when the air-conditioning unit is operating when the occupant moves from the passenger compartment to the exterior of the passenger compartment in the discharge mode. 5. The air conditioner described in 1. The vehicle is
A generator that is activated as necessary according to the discharge mode to generate electricity;
The air conditioner of any one of Claims 1-4 including the electrical storage apparatus which can store the electric power generated with the said generator.   A vehicle equipped with the air conditioner according to any one of claims 1 to 5.

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