JP2020108309A - Garage ventilation system - Google Patents

Abstract

To obtain a garage ventilation system which can reduce a burden when introducing the system.SOLUTION: The garage ventilation system includes: power supply equipment 6 which charges a storage battery 4 mounted on a vehicle 3, and supplies power to the load from storage battery 4; and a ventilation fan 12, which is an exhaust fan to exhaust air in the garage, provided on the garage for storing the vehicle 3 and operated by receiving power supply from the power supply equipment 6. The power supply equipment 6 includes: an exhaust contactor 23 which is an exhaust switch part to switch between power supply to the exhaust fan 12 and the stop of power supply to the exhaust fan 12; and a control unit 27 which detects the state of the vehicle 3 stored in the garage by communication via a power cable 9 which connects between the power supply equipment 6 and the vehicle 3, to control the exhaust contactor 23 based on the detection result of the state of the vehicle 3.SELECTED DRAWING: Figure 2

Description

The present invention relates to a garage ventilation system for ventilating a garage.

2. Description of the Related Art In recent years, systems capable of supplying electric power to a house from a storage battery mounted on an electric vehicle or a plug-in hybrid vehicle have become widespread. When power is supplied from the storage battery of the plug-in hybrid vehicle to the inside of the house, power generation may be performed in the vehicle by operating the engine of the vehicle. By performing power generation in a state where the amount of electric power stored in the storage battery is small, it becomes possible to supplement the electric power that is insufficient by discharging the storage battery. In the case of power generation by a vehicle placed in a garage, the garage is ventilated in order to suppress the exhaust gas exhausted from the vehicle while the engine is operating.

In Patent Document 1, in a power supply system that uses a vehicle placed in a garage as a power supply source in a house, the garage is automatically ventilated when power is supplied to the house by operating an engine of the vehicle. It is disclosed to do. The power supply system according to Patent Document 1 is managed by a home energy management system (Home Energy Management System: HEMS). According to the technique of Patent Document 1, the HEMS operates the ventilation fan of the garage based on the information obtained by communicating with the vehicle.

Patent No. 5853931

In the power supply system according to Patent Document 1, the HEMS requires a communication device for obtaining vehicle information. Further, since the ventilation fan of the power supply system according to Patent Document 1 is controlled based on the information obtained by HEMS, it needs to be a ventilation fan that can be managed by HEMS. The power supply system according to Patent Document 1 has a problem that a load is large when the system is introduced because a communication device and a ventilation fan that can be managed by HEMS are required.

The present invention has been made in view of the above, and an object of the present invention is to obtain a garage ventilation system that can reduce the burden when introducing the system.

In order to solve the above-mentioned problems and achieve the object, a garage ventilation system according to the present invention is a power supply facility for charging a storage battery mounted in a vehicle and supplying power from the storage battery to a load, An exhaust ventilation fan that is provided in a garage in which a vehicle is placed and that operates by receiving power supply from a power supply facility and discharges air in the garage. The power supply facility includes an exhaust switching unit that switches between power supply to the exhaust ventilation fan and stop of power supply to the exhaust ventilation fan, a state of the vehicle in the garage, and the power supply facility and the vehicle. A control unit that controls the exhaust gas switching unit based on the detection result of the vehicle state, which is detected by communication via a power cable to be connected.

According to the present invention, it is possible to reduce the burden when introducing the system.

The figure which shows the house which has a garage ventilation system concerning Embodiment 1 of this invention. The figure which shows the garage ventilation system shown in FIG. 1, and the element connected to a garage ventilation system. The perspective view which shows a part of electric power cable which the garage ventilation system shown in FIG. 1 has. Sectional drawing of the power cable in the IV-IV line shown in FIG. The figure which shows the structure when the ventilation fan for intake is added to the garage ventilation system shown in FIG. The flowchart explaining the control procedure by the control part which the garage ventilation system shown in FIG. 5 has. The figure which shows the hardware constitutions in case the function of the control part which the garage ventilation system shown in FIG. 1 has is implement|achieved using exclusive hardware. The figure which shows the hardware constitutions when the function of the control part which the garage ventilation system shown in FIG. 1 has is implement|achieved using a processor.

Hereinafter, a garage ventilation system according to an embodiment of the present invention will be described in detail with reference to the drawings. The present invention is not limited to the embodiments.

Embodiment 1.
1 is a diagram showing a house 1 having a garage ventilation system according to a first embodiment of the present invention. A garage 2 for housing a vehicle 3 is provided in the house 1. A storage battery 4 is mounted on the vehicle 3. The vehicle 3 is an electric vehicle or a plug-in hybrid vehicle. The garage ventilation system is provided in the garage 2, and a power supply facility 6 that charges the storage battery 4 and supplies power to the load from the storage battery 4, a power cable 9 that connects the power supply facility 6 and the vehicle 3. And a ventilation fan 12 that operates. The ventilation fan 12 is an exhaust ventilation fan that receives power from the power supply facility 6 and operates to discharge the air in the garage 2.

The commercial power supply 7 supplies power to the house 1. The power supply facility 6 supplies the power from the commercial power supply 7 to the house load 5. The electricity meter 8 measures the amount of electricity supplied from the commercial power source 7 to the house 1.

A first end, which is one end of the power cable 9, is connected to the power supply facility 6. The connector 10 is provided at the second end, which is the other end of the power cable 9. The connector 10 is inserted into the charging port 11 when charging the storage battery 4. The power cable 9 connects the vehicle 3 and the power supply facility 6 by inserting the connector 10 into the charging port 11. After the vehicle 3 and the power supply facility 6 are connected, the storage battery 4 is charged by the power supply from the power supply facility 6.

The power supply facility 6 can supply power from the storage battery 4 to the in-house load 5 in an emergency such as a power failure in which power cannot be supplied from the commercial power supply 7. In addition, the power supply facility 6 controls the ventilation fan 12 by supplying power to the ventilation fan 12 according to the result of detecting the state of the vehicle 3.

FIG. 2 is a diagram showing the garage ventilation system shown in FIG. 1 and elements connected to the garage ventilation system. The earth leakage breaker 13 for power reception protects the power wiring of the house 1 and the load 5 in the house. The commercial power source 7 is connected to the AC connection port 14 of the power supply facility 6 via the watt-hour meter 8 and the power receiving earth leakage breaker 13.

The residential distribution board 17 has a main breaker 18 and a plurality of branch breakers 19. An outlet 20 provided in the house 1 is connected to each branch breaker 19. The house load 5 is connected to the outlet 20. In FIG. 2, illustration of the in-house load 5 is omitted. The main breaker 18 is connected to the load connection port 16 of the power supply facility 6.

The power supply facility 6 has an electromagnetic contactor 15 capable of interrupting the supply of AC power from the commercial power supply 7 to the power supply facility 6. A first end, which is one end of the electromagnetic contactor 15, is connected to the AC connection port 14. The second end, which is the other end of the electromagnetic contactor 15, is connected to the load connection port 16. When the electromagnetic contactor 15 is in the closed state, the power supply facility 6 is supplied with AC power from the commercial power supply 7. By changing the electromagnetic contactor 15 from the closed state to the open state, the supply of AC power from the commercial power supply 7 to the power supply facility 6 is cut off. When all of the earth leakage breaker for power reception 13, the electromagnetic contactor 15, the main breaker 18 and the branch breaker 19 are closed, the AC power from the commercial power supply 7 is supplied to the house load 5.

The power supply facility 6 includes a power conversion device 21 that converts AC power from the commercial power supply 7 into DC power and converts DC power from the storage battery 4 into AC power. In FIG. 2, the power conversion device 21 is described as “AC/DC”. The DC side terminal of the power conversion device 21 is connected to the DC connection port 22 of the power supply equipment 6. The AC side terminal of the power conversion device 21 is connected to a connection point P1 between the second end of the electromagnetic contactor 15 and the load connection port 16.

The power supply facility 6 includes an exhaust contactor 23 that is an exhaust switching unit that switches between supplying AC power to the ventilation fan 12 and stopping supplying AC power to the ventilation fan 12. A first end, which is one end of the exhaust contactor 23, is connected to a connection point P2 between the second end of the electromagnetic contactor 15 and the load connection port 16. A second end, which is the other end of the exhaust contactor 23, is connected to the ventilation fan connection port 24 of the power supply facility 6. The ventilation fan 12 is connected to the ventilation fan connection port 24.

The power supply facility 6 has a control unit 27 that controls switching of the electromagnetic contactor 15 and switching of the exhaust contactor 23. The vehicle 3 includes an in-vehicle contactor 25 connected between the charging port 11 and the storage battery 4, and a control unit 26 that controls switching of the in-vehicle contactor 25.

The electromagnetic contactor 15 is closed during normal times when the commercial power supply 7 can be normally used. When the electromagnetic contactor 15 is closed, the power supply facility 6 supplies AC power to the in-house load 5 via the residential distribution board 17. When the electromagnetic contactor 15 is in the closed state, the connector 10 is inserted into the charging port 11 and the in-vehicle contactor 25 is in the closed state, so that the power supply equipment 6 is generated by the conversion in the power conversion device 21. The direct current electric power is output to the vehicle 3. Thereby, the storage battery 4 is charged.

The control unit 26 closes the in-vehicle contactor 25 by obtaining confirmation information described below. The storage battery 4 is charged by closing the in-vehicle contactor 25. When the confirmation information cannot be obtained, the control unit 26 opens the in-vehicle contactor 25. Since the electromagnetic contactor 15 is in the open state, the state in which the supply of the DC power to the storage battery 4 is cut off is maintained, and the storage battery 4 is not charged.

When an abnormality occurs such that power cannot be supplied from the commercial power supply 7, such as a power failure, the control unit 27 instructs the electromagnetic contactor 15 to switch from the closed state to the open state. The electromagnetic contactor 15 switches from the closed state to the open state according to the command. The power supply facility 6 cuts off the electric path of the commercial power source 7 by opening the electromagnetic contactor 15. The power supply facility 6 prevents an overcurrent at the time of power recovery by shutting off the electric path of the commercial power supply 7 in an emergency.

When power is supplied from the storage battery 4 to the in-house load 5, the connector 10 is inserted into the charging port 11 and the in-vehicle contactor 25 is closed. In this state, the vehicle 3 outputs DC power to the power supply facility 6 by discharging the storage battery 4. The power converter 21 converts the DC power input to the DC connection port 22 into AC power. As a result, the power supply facility 6 supplies AC power to the in-house load 5 through the residential distribution board 17.

The power conversion device 21 converts AC power supplied by the commercial power supply 7 into DC power when the storage battery 4 is charged, and converts DC power supplied by the storage battery 4 into AC power when the storage battery 4 is discharged. .. In this way, the power conversion device 21 is responsible for both conversion of AC power to DC power and conversion of DC power to AC power.

In supplying electric power from the storage battery 4 to the in-house load 5, the vehicle 3 may generate power by operating the engine of the vehicle 3. By performing power generation in a state in which the amount of electric power stored in the storage battery 4 is small, it is possible to supplement the electric power that is insufficient by discharging the storage battery 4.

The control unit 27 detects the state of the vehicle 3 placed in the garage 2 when the power is supplied from the storage battery 4 to the in-house load 5, and the exhaust contactor is detected based on the detection result of the state of the vehicle 3. Control 23. The control unit 27 acquires information from the vehicle 3 by communication via the power cable 9 and detects the state of the vehicle 3 based on the acquired information.

When electric power is being supplied from the storage battery 4 to the power supply facility 6 without operating the engine, the control unit 27 detects that the vehicle 3 is not operating the engine based on the information from the vehicle 3. To do. In this case, the exhaust contactor 23 is opened. Since the exhaust contactor 23 is in the open state, the power supply from the storage battery 4 to the ventilation fan 12 is cut off, so that the operation of the ventilation fan 12 is stopped.

After that, when the operation of the engine is started, the control unit 27 detects that the vehicle 3 is operating the engine based on the information from the vehicle 3. The control unit 27 instructs the exhaust contactor 23 to switch from the open state to the closed state based on the detection result that the vehicle 3 is operating the engine. The exhaust contactor 23 switches from the open state to the closed state according to the command. By switching the exhaust contactor 23 from the open state to the closed state, power is supplied from the storage battery 4 to the ventilation fan 12 via the power supply facility 6. The ventilation fan 12 starts operating by receiving power supply. The ventilation fan 12 discharges the air in the garage 2 when the vehicle 3 is operating the engine. As a result, the garage ventilation system suppresses the exhaust gas exhausted from the vehicle 3 while the engine is operating.

FIG. 3 is a perspective view showing a part of the power cable 9 included in the garage ventilation system shown in FIG. FIG. 4 is a cross-sectional view of the power cable 9 taken along the line IV-IV shown in FIG. FIG. 3 shows a part of the power cable 9 including the connector 10. The power cable 9 includes a communication line 28 for communication between the power supply facility 6 and the vehicle 3, a power line 29 for power supply between the power supply facility 6 and the vehicle 3, and various controls. And a control line 30 which is a signal transmission line of the signal.

The power supply facility 6 is a facility that complies with V2H (Vehicle to Home) guidelines. The V2H guideline refers to the “charging/discharging system guideline for electric vehicles V2H DC version” established by the Japan Electric Vehicle Power Supply System Council. The V2H guideline is a guideline for ensuring electrical safety and connection compatibility when power is supplied to indoor wiring by utilizing the charging capacity and power generation capacity of the vehicle. The connection between the power supply facility 6 and the charging port 11, the charging of the storage battery 4, and the power supply from the storage battery 4 to the in-house load 5 are in accordance with the regulations regarding control in the V2H guideline.

The control unit 27 confirms that insulation deterioration does not occur between the power cable 9 and the connector 10 before the positive electrode terminal and the negative electrode terminal that are the main electrodes of the storage battery 4 are connected to the DC side terminal of the power supply facility 6. Do an inspection for. When it is confirmed that the insulation deterioration has not occurred, the control unit 27 transmits confirmation information, which is information indicating that the insulation deterioration has not occurred, to the vehicle 3 via the communication line 28. The control unit 26 commands the in-vehicle contactor 25 to switch from the open state to the closed state by receiving the confirmation information. The power supply facility 6 charges the storage battery 4 when insulation deterioration does not occur between the power cable 9 and the connector 10. The power supply facility 6 does not charge the storage battery 4 when insulation deterioration occurs between the power cable 9 and the connector 10. As a result, the power supply facility 6 can suppress charging and discharging in a state where insulation deterioration has occurred in the power cable 9 or the connector 10.

The control unit 26 and the control unit 27 determine the amount of electric power stored in the storage battery 4 and the charging and discharging operations when the storage battery 4 is being charged and when the storage battery 4 is being discharged. Constantly monitor the charging and discharging status such as voltage and current. When abnormality is confirmed in charging or discharging, the control unit 26 commands the in-vehicle contactor 25 to switch from the closed state to the open state. When abnormality is confirmed in charging or discharging, the control unit 27 instructs the DC contactor between the power conversion device 21 and the DC connection port 22 to switch from the closed state to the open state. In FIG. 2, illustration of the DC contactor is omitted.

The specifications of the power cable 9 and the connector 10 are in accordance with the V2H guidelines. A CAN (Controller Area Network), which is a serial communication protocol with enhanced noise resistance, is used for communication between the vehicle 3 and the power supply facility 6.

Electric power can be supplied from the storage battery 4 to the load 5 in the house not only during an emergency but also during normal times. The power supply facility 6 may be a power conditioner capable of performing power supply in the form of grid interconnection. The power supply from the storage battery 4 in the form of a grid interconnection to the in-house load 5 is defined in “Grid interconnection regulations” JEAC 9701-2016 issued by the Japan Electric Association. According to the definition of the "system interconnection rule", in the power feeding in the form of the system interconnection by the storage battery 4, the DC side terminal of the power supply facility 6 and the main electrode of the storage battery 4 do not pass through a converter or the like in the vehicle 3. It is limited to the case where the DC power is directly connected and the DC power is converted to AC power by the power converter 21. That is, it is limited to the case where the power supply facility 6 and the vehicle 3 are connected by the power cable 9. In the case of a hybrid vehicle, power supply in the form of grid interconnection is limited to when the engine is stopped.

Established by the Japan Electrical Safety and Environment Technology Laboratories (JET), which is a certification body for power conditioners, "system protection devices for storage batteries (DC connection type) installed in electric vehicles, etc. In the “Individual test”, a test is performed to determine whether or not the grid connection is possible with the power conditioner. It has been confirmed by this test that it is possible to determine that power supply in the form of grid interconnection is prohibited if the conditions stipulated in the "Grid interconnection regulations" are not satisfied. There is.

The power supply facility 6 can determine, based on the information sent from the vehicle 3, whether or not power can be supplied in the form of grid interconnection by the storage battery 4. By obtaining information from the vehicle 3, the power supply facility 6 can suppress power supply in the form of grid interconnection under the condition that power supply in the form of grid interconnection is prohibited. In addition to the information for determining the availability of power supply in the form of grid interconnection, the power supply facility 6 that complies with the V2H guideline also includes information about the secondary battery, the internal combustion engine, or the fuel cell that is the power supply source. You can get information.

Next, the control of the ventilation fan 12 in the garage ventilation system according to the first embodiment will be described. The power supply facility 6 cannot supply power by system interconnection operation when the engine is operating. When the information indicating that the operation of the engine is stopped is obtained from the vehicle 3, the control unit 27 determines, based on the information obtained from the vehicle 3, that power can be supplied by the grid interconnection operation. .. The control unit 27 opens the exhaust contactor 23 based on the determination. When the control unit 27 determines that power can be supplied by system interconnection operation, the ventilation fan 12 is in the stopped state because the power is supplied with the engine stopped and exhaust gas is not emitted by the vehicle 3. To be done. Accordingly, the garage ventilation system can bring the ventilation fan 12 into a stopped state when the exhaust gas is not discharged and the operation of the ventilation fan 12 is unnecessary.

When the vehicle 3 put in the garage 2 is an electric vehicle, only the storage battery 4 which is a secondary battery is a power supply source, and the engine which is an internal combustion engine is not mounted in the electric vehicle. When the information indicating that the vehicle 3 is an electric vehicle is obtained from the vehicle 3, the control unit 27 determines, based on the information obtained from the vehicle 3, that the electric power can be supplied in the grid interconnection operation. .. The control unit 27 opens the exhaust contactor 23 based on the determination. Even when the control unit 27 determines that the vehicle 3 is an electric vehicle and can be supplied with power in the system interconnection operation, the exhaust fan 12 does not discharge the exhaust gas, and thus the ventilation fan 12 is stopped. Accordingly, the garage ventilation system can bring the ventilation fan 12 into a stopped state when the exhaust gas is not discharged and the operation of the ventilation fan 12 is unnecessary.

According to the above-mentioned “system interconnection regulation”, when the power supply facility 6 is in a self-sustaining operation state in which it is disconnected from the commercial power source 7, that is, when the electromagnetic contactor 15 is in the open state, the power supply source of the vehicle 3 is used. The power supply from the power generation is allowed. Therefore, in the self-sustained operation state, the power supply facility 6 can generate power by operating the engine and supply power by the obtained power.

When power is supplied from the storage battery 4 to the in-house load 5 in an emergency when power cannot be supplied from the commercial power source 7, the vehicle 3 can generate power by operating the engine. When the information indicating that the engine, which is the internal combustion engine, is the power supply source and the engine is operating is obtained from the vehicle 3, the control unit 27 determines the exhaust gas based on the information obtained from the vehicle 3. The contactor 23 is closed. In the vehicle ventilation system, the control unit 27 determines that power is supplied by operating the engine, so that the ventilation fan 12 is operated in a situation where the exhaust gas is discharged by the vehicle 3 to discharge the air in the garage 2. As a result, the garage ventilation system can suppress the exhaust gas from filling the garage 2.

The garage ventilation system may have an intake ventilation fan that takes in air from outside the garage 2 into the garage 2. FIG. 5: is a figure which shows a structure when the ventilation fan for intake is added to the garage ventilation system shown in FIG. The ventilation fan 31 is an intake ventilation fan that receives power from the power supply facility 6 and operates to suck the air outside the garage 2 into the garage 2. The ventilation fan 31 is provided in the garage 2.

The power supply facility 6 shown in FIG. 5 has an intake contactor 33 that is an intake switching unit that switches between supplying AC power to the ventilation fan 31 and stopping supplying AC power to the ventilation fan 31. A first end, which is one end of the intake contactor 33, is connected to a connection point P3 between the second end of the electromagnetic contactor 15 and the load connection port 16. A second end, which is the other end of the intake contactor 33, is connected to the ventilation fan connection port 32 of the power supply facility 6. The ventilation fan 31 is connected to the ventilation fan connection port 32. The control unit 27 controls switching of the electromagnetic contactor 15, switching of the exhaust contactor 23, and switching of the intake contactor 33.

A fuel cell vehicle generates electric power by a chemical reaction between hydrogen and oxygen in the fuel cell, and drives a motor with electric energy obtained by the electric power generation. Here, it is assumed that the vehicle 3 put in the garage 2 is a fuel cell vehicle. According to the above-mentioned "system interconnection rule", power supply in the form of system interconnection by the storage battery 4 of the fuel cell vehicle is prohibited. However, in the self-sustained operation state in which the power supply facility 6 is disconnected from the commercial power source 7, the power supply facility 6 can perform power supply in the form of grid interconnection by the storage battery 4.

The vehicle 3, which is a fuel cell vehicle, can generate power in the fuel cell when supplying power from the storage battery 4 to the in-house load 5. Since oxygen contained in the air in the garage 2 is used for power generation, if the flow of air from outside the garage 2 into the garage 2 is insufficient during power generation, The oxygen concentration may decrease.

When the information indicating that the fuel cell, which is an internal combustion engine, is the power supply source and the fuel cell is generating power is obtained from the vehicle 3, the control unit 27 determines the information obtained from the vehicle 3 as a basis. Then, the intake contactor 33 is closed. When the control unit 27 determines that the vehicle ventilation system is the power supply by the power generation of the fuel cell, the ventilation fan 31 is operated in the situation where oxygen is consumed by the vehicle 3 to remove the air outside the garage 2 into the garage 2. Import to. As a result, the garage ventilation system can suppress a decrease in oxygen concentration in the garage 2.

FIG. 6 is a flowchart illustrating a procedure of control by the control unit 27 included in the garage ventilation system shown in FIG. FIG. 6 illustrates a control procedure of the control unit 27 when power is supplied by power generation from the power supply source of the vehicle 3. Further, at the start of the control shown in FIG. 6, it is assumed that both the exhaust contactor 23 and the intake contactor 33 are open. Since the exhaust contactor 23 is in the open state, the ventilation fan 12 is in the stopped state. Since the intake contactor 33 is open, the ventilation fan 31 is stopped.

When power is supplied by power generation from the power supply source of the vehicle 3, the vehicle 3 sends information indicating the state of the vehicle 3 and information about the power supply source to the control unit 27 through communication via the communication line 28. Send. In step S1, the control unit 27 determines, based on the information obtained from the vehicle 3, whether or not the power feeding is the power feeding by the grid interconnection operation.

When the power supply is the power supply by the grid interconnection operation, the control unit 27 can determine that the power supply is not the power supply by the operation of the engine or the power generation of the fuel cell but the power supply only by the discharge of the storage battery 4 which is the secondary battery. .. When the control unit 27 determines that the power supply is performed by the grid interconnection operation (Yes in step S1), the control unit 27 does not issue a command for switching both the exhaust contactor 23 and the intake contactor 33. As a result, the vehicle ventilation system keeps both the ventilation fan 12 and the ventilation fan 31 in a stopped state during power supply without exhaust gas emission and oxygen consumption. As a result, the control unit 27 ends the control according to the procedure shown in FIG.

When the power supply is not the power supply by the grid interconnection operation, the control unit 27 can determine that the power supply is the power supply by the independent operation and is the power supply by the operation of the engine or the power generation by the fuel cell. When the control unit 27 determines that the power supply is not performed by the grid interconnection operation (No in step S1), the control unit 27 determines whether the power supply source of the vehicle 3 is the fuel cell in step S2.

When the power supply source of the vehicle 3 is a fuel cell, the control unit 27 can determine that the power supply is power supply by power generation of the fuel cell. When the control unit 27 determines that the power supply source of the vehicle 3 is the fuel cell (Yes in step S2), the intake contactor 33 of the exhaust contactor 23 and the intake contactor 33 is switched for switching. Give a command. By switching the intake contactor 33 from the open state to the closed state, the vehicle ventilation system operates the ventilation fan 31, which is the intake ventilation fan, in step S3. As a result, the vehicle ventilation system operates the ventilation fan 31 during power supply accompanied by oxygen consumption. After step S3, the control unit 27 ends the control according to the procedure shown in FIG.

When determining that the power supply source of the vehicle 3 is not the fuel cell (step S2, No), the control unit 27 determines whether the power supply source of the vehicle 3 is the internal combustion engine in step S4. When the power supply source of the vehicle 3 is an internal combustion engine, the control unit 27 can determine that such power supply is power supply by operating the internal combustion engine to generate power. When the control unit 27 determines that the power supply source of the vehicle 3 is the internal combustion engine (step S4, Yes), the exhaust contactor 23 of the exhaust contactor 23 and the intake contactor 33 is switched for switching. Give a command. By switching the exhaust contactor 23 from the open state to the closed state, the vehicle ventilation system operates the ventilation fan 12 that is the exhaust ventilation fan in step S5. As a result, the vehicle ventilation system operates the ventilation fan 12 during power supply accompanied by exhaust gas emission. After step S5, the control unit 27 ends the control according to the procedure shown in FIG. When it is determined that the power supply source of the vehicle 3 is not the internal combustion engine (step S4, No), the control unit 27 ends the control according to the procedure shown in FIG.

As described above, the garage ventilation system is a system that can supply power from the storage battery 4 to the load 5 in the house, and includes the power supply facility 6 that complies with the V2H guideline. The power supply facility 6 obtains information about the state of the vehicle 3 and information about the power supply source from the vehicle 3 by the control unit 27, and controls the ventilation fan 12 and the ventilation fan 31 based on the obtained information. Therefore, the garage ventilation system does not need to separately provide a control device for power management of the house 1 and a communication device for obtaining information of the vehicle 3. Further, the ventilation fans 12 and 31 of the garage ventilation system do not have to be ventilation fans corresponding to a specific management system such as HEMS, but can be general ventilation fans.

The function of the control unit 27 included in the power supply equipment 6 is realized by using a processing circuit. The processing circuit is dedicated hardware mounted on the power supply facility 6. The processing circuit may be a processor that executes a program stored in the memory.

FIG. 7 is a diagram showing a hardware configuration when the function of the control unit 27 included in the garage ventilation system shown in FIG. 1 is realized by using dedicated hardware. The processing circuit 41 that is dedicated hardware is a single circuit, a composite circuit, a programmed processor, a parallel programmed processor, an ASIC (Application Specific Integrated Circuit), an FPGA (Field-Programmable Gate Array), or a combination thereof. It is a combination.

FIG. 8 is a diagram showing a hardware configuration when the function of the control unit 27 included in the garage ventilation system shown in FIG. 1 is realized by using the processor 42. The processor 42 and the memory 43 are communicably connected to each other. The processor 42 executes the program stored in the memory 43.

The processor 42 is a CPU (Central Processing Unit), a processing device, an arithmetic device, a microprocessor, a microcomputer, or a DSP (Digital Signal Processor). The function of the control unit 27 is realized by the processor 42, software, firmware, or a combination of software and firmware. The software or firmware is described as a program and stored in the memory 43. The memory 43 is nonvolatile or volatile such as RAM (Random Access Memory), ROM (Read Only Memory), flash memory, EPROM (Erasable Programmable Read Only Memory), and EEPROM (registered trademark) (Electrically Erasable Programmable Read Only Memory). It is a built-in memory such as a semiconductor memory.

Part of the function of the control unit 27 may be realized by dedicated hardware, and the other part of the function of the control unit 27 may be realized by software or firmware. As described above, the function of the control unit 27 can be realized by hardware, software, firmware, or a combination thereof.

The function of the control unit 26 included in the vehicle 3 is realized by a processing circuit similarly to the function of the control unit 27. The hardware configuration shown in FIG. 7 and the hardware configuration shown in FIG. 8 may be applied to the control unit 26.

According to the first embodiment, the garage ventilation system detects the state of the vehicle 3 placed in the garage 2 by communication via the power cable 9, and exhausts the vehicle based on the detection result of the state of the vehicle 3. It controls the contactor 23 and the intake contactor 33. The garage ventilation system does not need to separately provide a communication device for obtaining the information of the vehicle 3, and does not need to use the ventilation fans corresponding to a specific management system for the ventilation fans 12 and 31. As a result, the garage ventilation system has the effect of reducing the burden of introducing the system.

The configurations described in the above embodiments are examples of the content of the present invention, and can be combined with other known techniques, and the configurations of the configurations are not departing from the scope of the present invention. It is also possible to omit or change parts.

1 house, 2 garage, 3 vehicle, 4 storage battery, 5 house load, 6 power supply facility, 7 commercial power supply, 8 watt-hour meter, 9 power cable, 10 connector, 11 charging port, 12, 31 ventilation fan, 13 for receiving power Earth leakage breaker, 14 AC connection port, 15 electromagnetic contactor, 16 load connection port, 17 residential distribution board, 18 main breaker, 19 branch breaker, 20 outlet, 21 power conversion device, 22 DC connection port, 23 for exhaust Contactor, 24, 32 ventilation fan connection port, 25 vehicle contactor, 26, 27 control unit, 28 communication line, 29 power line, 30 control line, 33 intake contactor, 41 processing circuit, 42 processor, 43 memory.

Claims (3)

Charging the storage battery mounted on the vehicle, and a power supply facility for supplying power from the storage battery to the load,
An exhaust ventilation fan that is provided in a garage in which the vehicle is placed, operates by receiving power supply from the power supply facility, and discharges air in the garage,
Equipped with
The power supply facility,
An exhaust switching unit that switches between power supply to the exhaust ventilation fan and stop of power supply to the exhaust ventilation fan;
The state of the vehicle placed in the garage is detected by communication via a power cable connecting the power supply facility and the vehicle, and the exhaust switching is performed based on the detection result of the state of the vehicle. A control unit for controlling the unit,
Garage ventilation system characterized by having. The garage ventilation system according to claim 1, wherein the power supply facility is a facility that complies with a charging/discharging system guideline for an electric vehicle. An intake ventilation fan is provided in the garage, which operates by receiving power supply from the power supply facility to take in air outside the garage into the garage,
The power supply facility,
An intake switching unit that switches between supplying power to the intake ventilation fan and stopping supply of power to the intake ventilation fan,
The garage ventilation system according to claim 1 or 2, wherein the control unit controls the intake switching unit based on a detection result of a state of the vehicle.

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