JP6639187B2 - Power conditioner for electric vehicles - Google Patents

Description

  The present invention relates to a power conditioner for an electric vehicle that charges and discharges a storage battery of the electric vehicle.

  2. Description of the Related Art Conventionally, there is known an energy charging / discharging system for supplying electric power from a storage battery of an electric vehicle to a home appliance load or charging a storage battery of the electric vehicle from a commercial power supply for home use.

  In a conventional charge / discharge system, when charging a storage battery of an electric vehicle from a commercial power supply, an AC voltage is converted to a predetermined DC voltage by a power conditioner for an electric vehicle provided as a residential facility, that is, AC power is converted to DC power. Convert and charge. Conversely, when power is supplied from a storage battery of an electric vehicle to a home appliance load, a DC voltage (DC power) output from the storage battery of the electric vehicle is converted into an AC voltage (AC power) by an electric vehicle power conditioner. It is designed to supply a load. As an energy charging / discharging system having such an electric vehicle power conditioner, for example, there is a charging / discharging system disclosed in Patent Document 1.

Japanese Patent No. 5668161 (paragraphs [0001] to [0003], FIG. 1)

  In a power conditioner for an electric vehicle used in a conventional charge / discharge system having a function of charging a storage battery of an electric vehicle, when performing a discharging operation of discharging a storage battery DC voltage from the storage battery of the electric vehicle, the following reasons are given. Therefore, first, a communication process is performed between the electric vehicle power conditioner and the electric vehicle communication, and establishment of the communication process is imposed as an operation start requirement of the discharge operation. Therefore, when the communication processing is not established, the execution of the discharging operation becomes impossible.

  The reason for imposing the communication process as the operation start requirement of the discharging operation is that if a voltage is applied to the charging / discharging terminal of the electric vehicle in a state where the communication process is not established, there is a possibility that a dangerous state where an electric shock or the like is generated may occur. It is.

  Therefore, in order to execute the discharging operation from the electric vehicle in an emergency when the system power supply cannot be used due to a power failure or the like, the power conditioner for the electric vehicle itself needs to be a lead-state so that the communication processing can be performed even in an emergency such as a power failure. It is necessary to have a communication device battery such as a storage battery therein, and to have the communication device execute the above communication process using the communication device battery as an operating power source in an emergency.

  However, even in a configuration in which a battery for a communication device is provided in a power conditioner for an electric vehicle, if an emergency such as a power outage continues for a long time and the electric vehicle is moved to another place, there is no supply source. As a result, the battery for the communication device is discharged, and the power conditioner for the electric vehicle cannot be started (power cannot be supplied to the communication device). As a result, the communication process cannot be executed, and the discharging operation cannot be performed. There was a problem.

  The present invention has been made in order to solve the above-described problems, and provides an environment for reliably performing a communication process serving as a condition for starting a discharge operation even in a case where an emergency in which system power cannot be used, such as a power failure, continues for a long time. An object is to obtain a power conditioner for an electric vehicle that can be secured.

An electric vehicle power conditioner according to claim 1 of the present invention is an electric vehicle power conditioner that is connected to a plurality of power supplies and charges and discharges a storage battery of the electric vehicle, wherein the plurality of power supplies are different from each other. A first power source and a second power source, wherein the second power source is a photovoltaic power generator and a PV power conditioner, and the electric vehicle power conditioner converts a DC voltage of the storage battery into an AC voltage, a converter for converting the power supply alternating voltage into a DC voltage, and a communication device that performs communication with the electric vehicle when discharging the storage battery, when the first power of the plurality of power supply is not available , said first power supply and a separate receiving AC power from said second power supply through the emergency outlet present, converts the AC power into DC power, It is characterized by having a emergency power supply unit for supplying to the serial communication device.

  Since the electric vehicle power conditioner according to the first aspect of the present invention has an emergency power supply unit, even in an emergency when a system power source (first power source) such as a power failure cannot be used, for example, the natural energy power generation system is used. The obtained second power supply can be used as a power supply for the communication device. Therefore, the power conditioner for an electric vehicle according to the present invention can reliably perform a discharge operation with the electric vehicle even in an emergency.

FIG. 1 is a block diagram showing an overall configuration of an energy charging / discharging system according to Embodiment 1 (2) of the present invention. FIG. 1 is a block diagram illustrating an internal configuration of a power conditioner for an electric vehicle according to a first embodiment. FIG. 8 is a block diagram showing an internal configuration of a power conditioner for an electric vehicle according to a second embodiment.

<First Embodiment>
(overall structure)
FIG. 1 is a block diagram showing the overall configuration of an energy charging / discharging system according to Embodiment 1 of the present invention (and Embodiment 2 to be described later).

  The charge / discharge system S1 according to the first embodiment illustrated in FIG. 1 is connected to a system power supply E, and includes a solar power generation system (natural energy generation system) 10, a first distribution board 20, and a second distribution board 30. A distribution board, a power measuring device 60, a HEMS (Home Energy Management System) controller 100, and a stationary electric vehicle power conditioner 120 (hereinafter, referred to as an "EV (Electric Vehicle) power conditioner (hereinafter referred to as an" EV ")" EV power control) ").

  The photovoltaic power generation system 10 has a photovoltaic power generation device (PV (PhotoVoltaic)) 11 and a PV power conditioner (PV power conditioner) 12 and is disposed in a building H such as a detached house, and loads generated power into a load (home electric appliance). Load).

  First, the building H will be described. The building H is connected to a system power supply (system power network) E as a power network for receiving power supply from system power.

  This system power supply E and the electric wire 20a wired to the building H are connected via a first electric energy meter (WHM) M1 and a second electric energy meter M2, and the electric wire 20a is a main power supply of the first distribution board 20. (Not shown), and the main trunk of the first distribution board 20 is connected to the main trunk (not shown) of the second distribution board 30.

  The first watt-hour meter M1 measures the amount of power flowing from the system power supply E to the building H (the first distribution board 20), and the second watt-hour meter M2 measures the power consumption from the building H (the first distribution board 20). The amount of power flowing to the power supply E is measured. That is, the first watt-hour meter M1 integrates the purchased power amount, and the second watt-hour meter M2 integrates the sold power amount.

  In the second distribution board 30, a current sensor (not shown) for detecting a current flowing to the main trunk is provided. A power measuring device 60 is installed near the second distribution board 30.

  Further, a plurality of branch trunks 31 are connected to the main trunk of the second distribution board 30, and each of the plurality of branch trunks 31 is connected to a room outlet (not shown) provided in a room of the building H. It is connected via a power supply line (not shown).

  The photovoltaic power generation system 10 includes a photovoltaic power generation device 11 as a distributed power generation device, and a PV power conditioner (power conditioner for power generation) 12. The photovoltaic power generation device 11 and the PV power conditioner The knife 12 is provided outdoors (outside the building H). The solar power generation device 11 is a device that directly converts solar energy, which is natural energy, into electric power to generate power.

  The PV power conditioner 12 converts DC power generated by the solar power generation device 11 into AC power and outputs the AC power. In addition, the PV power conditioner 12 is connected to a main line (not shown) of the second distribution board 30 by a power supply line 18, and supplies AC power of the PV power conditioner 12 during an interconnection operation with the system power supply E. The main trunk supplies the load to the home connected to the outlet for the room via the branch trunk 31 and the power supply line for the room.

  The charging / discharging system S1 according to the first embodiment has an emergency outlet 13 (emergency connection unit) in the building H. When the PV power conditioner 12 detects an emergency of the system power supply E such as a power outage from a voltage change of the power supply line 18 or the like during an emergency when the system power supply E cannot be used, such as at the time of a power failure, This is an outlet provided to output AC power by independent operation of the PV power conditioner 12 in a system separate from AC power.

  The emergency outlet 13 is supplied with emergency AC power (100 V AC) by an independent operation of the PV power conditioner 12 by switching a switch of the PV power conditioner 12 in an emergency when the system power supply E cannot be used. .

  In the present embodiment, the emergency AC power of AC 100 V is supplied from the photovoltaic power generation system 10 to the EV power conditioner 120 via the emergency outlet 13 and the power supply line 123 in the emergency when the system power supply E is unavailable. The power can be supplied without passing through the switchboard 20 and the second switchboard 30.

  Further, the EV power conditioner 120 and the first distribution board 20 are connected via power supply lines 125 and 126, and AC power from the system power supply E is supplied to the EV power conditioner 120 via the power supply line 125. It has become so.

  The EV power conditioner 120 is arranged so as to face the parking space SC.

  The EV power conditioner 120 performs a charging operation of converting the AC voltage of the system power supply E into a predetermined DC voltage and supplying the DC voltage to the electric vehicle C in the charging mode. That is, the charging operation is performed by converting the AC power of the system power supply E into the DC power by the EV power conditioner 120.

  On the other hand, EV power conditioner 120 performs a discharging operation of receiving a DC voltage output from a storage battery (not shown in FIG. 1) of electric vehicle C in the discharging mode. The EV power conditioner 120 converts the DC voltage of the storage battery into an AC voltage, that is, converts DC power into AC power and supplies the AC power to the first distribution board 20 via the power supply line 126.

  Further, the EV power conditioner 120 for the electric vehicle and the second distribution board 30 are connected via a power supply line 127, and the AC power from the PV power conditioner 12 is supplied to the EV via the second distribution board 30. The power can be supplied to the power conditioner 120. Therefore, EV power conditioner 120 is connected to a plurality of power supplies (system power supply E (first power supply) and PV power conditioner 12 (second power supply) of photovoltaic power generation system 10).

  The remote control 102 is a remote control that sets the charging mode of the EV power conditioner 120 for charging the storage battery of the electric vehicle C or the discharge mode of the EV power conditioner 120 for discharging the storage battery of the electric vehicle C and supplying the battery to the home load. It is possible. When charging the storage battery of the electric vehicle C, the EV power conditioner 120 automatically determines whether to use the power of the system power supply E or the power from the PV power conditioner 12 according to the set conditions. However, when the user sets the PV power conditioner mode by the remote control 102, the EV power conditioner 120 uses the electric power from the PV power conditioner 12 to charge the storage battery of the electric vehicle C. Note that the above operation may be performed by an input device provided in the EV power conditioner 120 instead of the remote control 102.

  The information collection device 100 displays the current power generated by the photovoltaic power generation system 10 and the integrated power amount on a display device (not shown) based on the transmitted measurement data.

  In addition, the HEMS controller 100 is connected to an external communication network such as the Internet via a router (not shown), and can transmit and receive data such as measured values to and from an external server. I have.

(Internal Configuration of EV Power Conditioner 120A)
FIG. 2 is a block diagram showing an internal configuration of the EV power conditioner 120A according to the first embodiment. In the first embodiment, EV power conditioner 120A having the configuration shown in FIG. 2 is arranged as EV power conditioner 120 in FIG.

  The EV power conditioner 120A includes a normal-time power supply unit PR4 provided for AC power (for example, 200 VAC or the like) supplied from the system power supply E using the power supply line 125 as an input line via the switch 8. The normal-time power supply unit PR4 includes a noise filter 41, a rectifier circuit 42, a smoothing circuit 43, and a step-down circuit 44. Then, the communication device 5 is connected to the output of the normal power supply unit PR4. The communication device 5 is connected to the (electric vehicle) communication device 6 of the electric vehicle C via the communication line 15.

  Therefore, during the normal time when the system power supply E can be used, the AC power supplied from the system power supply E to the EV power conditioner 120A via the second distribution board 30, the power supply line 125, and the switch 8 is normally supplied from the system power supply E. When received as an input of the hour power supply unit PR4, the output of the normal time power supply unit PR4 can be used as operating power of the EV power conditioner 120A including the communication device 5. The normal-time power supply unit PR4 converts AC power supplied from the system power supply E into DC power, and supplies the DC power to the communication device 5. That is, the EV power conditioner 120A normally supplies the AC power supplied from the system power supply E (first power supply) to the noise filter 41, the rectifier circuit 42, the smoothing circuit 43, and the step-down circuit in the normal power supply unit PR4. The DC power obtained through 44 can be used as the operating power of the EV power conditioner 120A including the communication device 5.

  However, in an emergency when the system power supply E cannot be used due to a power failure or the like, the normal-time power supply unit PR4 cannot supply operating power.

  Thus, the EV power conditioner 120A uses the power supply line 123 connected to the emergency outlet 13 as an input line, and provides a noise filter 1, a rectifier circuit 2, a smoothing circuit 3, and a step-down circuit provided for emergency AC power. An emergency power supply PR1 having the circuit 4 is further provided. Then, the communication device 5 is connected to the output of the emergency power supply unit PR1.

  When the system power supply E cannot be used due to a power failure or the like, the PV power conditioner 12 detects an emergency such as a power failure from a voltage change of the power supply line 18 or the like. When detecting the emergency, the PV power conditioner 12 stops the interconnection operation with the system power supply E, and stops the normal operation. However, the PV power conditioner 12 can supply power to the emergency outlet 13 even in an emergency due to a user operation or the like. Therefore, the EV power conditioner 120A supplies the AC power from the PV power conditioner 12 (second power supply) via the emergency outlet 13 and the power supply line 123 in an emergency, when the system power supply E cannot be used. When received as an input of the power supply unit PR1, the output of the emergency power supply unit PR1 can be used as an operation power supply of the EV power conditioner 120A. The emergency power supply unit PR1 converts emergency AC power supplied from the PV power conditioner 120A (second power supply) into DC power, and supplies the DC power to the control circuit of the EV power conditioner 120A including the communication device 5. I do. That is, the EV power conditioner 120 </ b> A converts the DC power obtained in the emergency, through the noise filter 1, the rectifier circuit 2, the smoothing circuit 3, and the step-down circuit 4, into the emergency power supply unit PR <b> 1. It can be used as an operation power supply of the EV power conditioner 120A including the communication device 5.

  As a result, the EV power conditioner 120A of the first embodiment can reliably supply power to the communication device 5 even in an emergency, so that the communication process with the electric vehicle C using the communication device 5 is performed. Can be.

  Further, the power supply line 125 is connected to the switch 8, the inverter 51, and the converter 52 in the EV power conditioner 120A in this order, and the converter 52 of the EV power conditioner 120A is connected to the vehicle main body of the electric vehicle C via the connection line 129. Connected to power supply 56. A storage battery to be subjected to a charging operation and a discharging operation is included in the automobile main power supply 56. The communication line 15 and the connection line 129 correspond to the power supply cord 130 shown in FIG.

  Therefore, when normal AC power is supplied from the system power supply E to the switch 8 of the EV power conditioner 120A via the first power distribution panel 20 and the power supply line 125 in the normal time when the system power supply E can be used, the EV power After being converted into DC power by the converter including the inverter 51 and the converter 52 of the conditioner 120A, the storage battery in the vehicle main power supply 56 can be charged via the connection line 129.

  In addition, the power supply line 126 to the home load 16 is connected to the inverter 51 and the converter 52 of the EV power conditioner 120A in this order, and the converter 52 of the EV power conditioner 120A is connected to the vehicle of the electric vehicle C via the connection line 129. Connected to main power supply 56.

  Therefore, in a normal time when the system power supply E can be used, a discharging operation of the DC voltage obtained from the storage battery in the vehicle main power supply 56 can be performed, and this DC voltage is converted into an AC voltage by passing through the converter 52 and the inverter 51. After being converted, it is supplied on the power supply line 126.

  The power supply line 127 from the PV power conditioner 12 is connected to the inverter 51 and the converter 52 of the EV power conditioner 120A in order, and the converter 52 of the EV power conditioner 120A is connected to the electric vehicle C via the connection line 129. Connected to the vehicle main power supply 56.

  Therefore, when AC power is supplied from the PV power conditioner 12 to the EV power conditioner 120A via the second distribution board 30 and the power supply line 127 in an environment where the solar power generation system 10 can be used, the inverter 51 and the inverter 51 After being converted into DC power via the converter including the converter 52, the charging operation for the storage battery in the vehicle main power supply 56 can be performed.

  Under an environment where the photovoltaic power generation system 10 can be used, a discharging operation of a DC voltage obtained from a storage battery in the vehicle main power supply 56 can be performed, and this DC voltage is converted to an AC voltage by passing through the converter 52 and the inverter 51. After being converted, it is supplied on the power supply line 126.

  The switch 8 (switching switch) normally performs an opening / closing operation (switching operation) that takes in the power supply line 125 as an input line of the EV power conditioner 120A. That is, the power supply line 125 is electrically connected to the normal power supply unit PR4 (the noise filter 41). However, when the PV power conditioner mode described later is set, an opening / closing operation is performed in which the connection with the power supply line 125 is invalidated (electrically cut off) by the switch 8.

  In an emergency, the switch 8 performs an opening / closing operation of disabling the power supply line 125 as an input line of the normal power supply unit PR4. However, when the system operation of the PV power conditioner 12 is restarted, an opening / closing operation is performed that enables (electrically connects) the power supply line 125 as an input line of the normal power supply unit PR4.

(motion)
Next, the operation of the charge / discharge system S1 of the first embodiment using the EV power conditioner 120A shown in FIG. 2 as the EV power conditioner 120 of FIG. 1 will be described. 2, the first distribution board 20, the second distribution board 30, the power supply line 18, the electric wire 20a, and the like shown in FIG. 1 are omitted.

  When charging the storage battery in the vehicle main power supply 56 of the electric vehicle C, first, the EV power conditioner 120A for the electric vehicle and the electric vehicle C are connected by the power supply cord 130 as shown in FIG.

  Next, the EV power conditioner 120A is set to the charging mode. The charging mode is set by operating the remote control 102 or an input device (not shown) provided in the EV power conditioner 120.

  When the charging mode is set at the normal time, when charging the storage battery of the electric vehicle C with the AC power output from the system power supply E, the EV power conditioner 120A receives the input power via the power supply line 125 and the switch 8. An AC voltage obtained from AC power from the system power supply E is converted into a DC voltage by the inverter 51 and the converter 52, and a charging operation for charging the storage battery in the vehicle main power supply 56 of the electric vehicle C with the converted DC voltage is performed. Do. By this charging operation, the storage battery in the vehicle main power supply 56 is charged.

  On the other hand, when charging the storage battery of the electric vehicle C with the AC power output from the PV power conditioner 12, the AC power output from the PV power conditioner 12 is supplied via the second distribution board 30 and the power supply line 127. The battery is supplied to the EV power conditioner 120 and the storage battery in the vehicle main power supply 56 is charged through the inverter 51 and the converter 52 in the same manner as described above.

  In the charging mode, when the PV power conditioner mode is set, the storage battery of the electric vehicle C is set not to be charged by the AC power of the system power supply E. Specifically, as described above, when the PV power conditioner mode is set, the connection with the power supply line 125 is electrically cut off by opening and closing the switch 8 in the EV power conditioner 120, and the power supply line 125 is set. Is not input to the inverter 51 and the converter 52 (hereinafter, may be abbreviated as “the inverter 51 etc.”).

  Therefore, in the PV power conditioner mode, the EV power conditioner 120A performs a charging operation on the storage battery of the electric vehicle C by converting an AC voltage supplied from the power supply line 127 into a DC voltage.

  When the discharge mode for discharging the storage battery of the electric vehicle C is set, the EV power conditioner 120A for the electric vehicle transmits the DC voltage obtained from the storage battery in the vehicle main power supply 56 via the converter 52 and the inverter 51. Is converted into an AC voltage, that is, DC power output from the storage battery is converted into AC power and supplied to the first distribution board 20 via the power supply line 126. The AC power supplied to the first distribution board 20 is supplied to the home load 16 via the second distribution board 30 and the plurality of branch trunks 31.

  Next, an emergency operation in which the system power supply E cannot be used at the time of a power failure or the like will be described. When detecting an emergency (power failure state), the PV power conditioner 12 is disconnected from the system by the islanding operation detection function.

  That is, in an emergency, the PV power conditioner 12 shuts off the electric path of the power supply line 127 from the second distribution board 30 with an internal switch (not shown) so that a maintenance worker of the power company does not receive an electric shock.

  Thereafter, the EV power conditioner 120A disables the power supply line 125 as an input line in order to cut off connection with the system by the internal switch 8 at the time of a power failure, and then shifts to the self-sustained operation mode. Therefore, even if the power path from the second distribution board 30 to the power supply line 127 is subsequently restored by the internal switch of the PV power conditioner 12, the maintenance staff of the power company will not receive an electric shock, and power will be supplied to the indoor equipment. Becomes possible.

  At this time, the user performs a switch switching operation on the PV power conditioner 12 to enable a self-sustained operation function of performing an AC output different from the system power supply E. Thereby, the PV power conditioner 12 supplies the emergency AC power of 100 V AC to the emergency outlet 13 by the self-sustaining operation.

  By the operation of the PV power conditioner 12, the emergency AC power of AC100V is supplied to the input unit of the emergency power supply unit PR1 of the EV inverter 120A via the emergency outlet 13 and the power supply line 123. In the emergency power supply unit PR <b> 1, the AC power supplied from the PV power conditioner 12 is filtered by the noise filter 1, input to the rectifier circuit 2, rectified, and input to the smoothing circuit 3. Then, the voltage becomes DC 140 V smoothed by the smoothing circuit 3, and is lowered to DC 12 V by the voltage lowering process by the voltage lowering circuit 4. This voltage (DC12V) is supplied to the communication device 5 as an operation power supply (operation voltage) of the EV power conditioner 120A, so that the EV power conditioner 120A uses the communication device 5 even in an emergency such as a power outage. Communication processing with the communication device 6 via the communication line 15 can be executed.

  When the communication processing between the EV power conditioner 120A and the electric vehicle C using the communication device 5 is established, the discharging operation from the storage battery in the vehicle main power source 56 can be started, and the vehicle main power source of the electric vehicle C can be started. Power is supplied from the storage battery in 56 toward the inside of the EV power conditioner 120A.

  After the discharging operation is started from the electric vehicle C accompanying the discharging operation, power is supplied to the internal control circuit of the EV power conditioner 120A including the communication device 5 by the AC power obtained via the converter 52 and the inverter 51. can do. Further, the AC power obtained by the EV power conditioner 120A can supply power to the first distribution board 20 via the power supply line 126, and the AC power supplied to the first distribution board 20 is changed to the second distribution board. The electric power is supplied to the home load 16 connected to the room outlet via the power board 30, the branch trunk 31, and the room power supply line.

  Then, when the start of the control power supply of the EV power conditioner 120A is confirmed by a display function (not shown) provided in the EV power conditioner 120A, the operator operates a switch to continuously operate the EV power conditioner 120A from the independent operation. Switch to system operation.

  When the EV power conditioner 120A is switched to the interconnection operation, the electric power of the EV power conditioner 120A is restored, and the system interconnection output of the PV power conditioner 12 via the power supply line 127 and the second distribution board 30 (the power supply line) 18) A voltage can be applied. As a result, even in an emergency such as a power outage of the system power supply E, the PV power conditioner 12 detects a voltage change in the system interconnection output, counts up a power recovery timer (not shown), and then starts the self-sustaining operation. Switching to the system operation, restarting the interconnection operation, and outputting power can be performed in the same manner as in normal operation. In addition, the count-up of the power recovery timer is performed in order to restart the grid interconnection of the PV power conditioner 12 after a fixed time after the power recovery of the EV power conditioner 120A.

  Thereafter, the EV power conditioner 120A supplies the AC power supplied via the power supply line 127 during the interconnection operation of the PV power conditioner 12 to the EV power conditioner 120A including the communication device 5 by the normal power supply unit PR4. By using it as an operation power source or passing through an inverter 51 and a converter 52, a charging operation of a storage battery in a vehicle main power source 56 of the electric vehicle C can be performed.

  Therefore, even in an emergency such as a power failure, the charge / discharge system S1 of the first embodiment applies the power from the EV power conditioner 120A to the system interconnection output of the PV power conditioner 12 so that the PV power conditioner 12 can be connected and operated in the same manner as in the normal case. Therefore, the power generated by the photovoltaic power generation system 10 is charged to a storage battery in the vehicle main power supply 56 of the electric vehicle C, or home appliances are driven using the power charged from the storage battery of the electric vehicle C. It becomes possible.

  As described above, the charge / discharge system S1 of the first embodiment controls the communication device 5 from the external AC power supply (second power supply) other than the system power supply E (first power supply) in the EV power conditioner 120A. An emergency power supply unit PR1 is provided so that power can be supplied.

  Since the EV power conditioner 120A includes the emergency power supply unit PR1, even in an emergency when the system power supply E (first power supply) cannot be used due to a power failure or the like, the solar power generation system 10 (second power supply system) that is a natural energy power generation system can be used. The power supply for the communication device 5 can be secured using the emergency AC power obtained from the power supply of the communication device 5. For this reason, the EV power conditioner 120A can omit the communication device battery for securing the power supply for the communication device 5 in an emergency, and can reduce the size and weight.

  That is, the EV power conditioner 120A does not necessarily include a power storage device such as a lead storage battery as a communication device battery for the communication device 5 in an emergency, and even in an emergency when the system power supply E cannot be used, The discharge operation from the electric vehicle C, in which the communication processing by the communication device 5 is imposed as the operation start requirement, can be started without fail. As a result, the power storage device can be omitted, or the size and weight can be reduced. As a result, a compact, lightweight, and maintenance-free EV power conditioner 120A can be obtained.

  Further, even in an emergency when the system power supply E cannot be used, the EV power conditioner 120A outputs the DC voltage obtained by the discharging operation of the storage battery of the electric vehicle C to the system interconnection output of the PV power conditioner 12 (the second power supply By applying the AC power to the first power supply, the PV power conditioner 12 can restart the interconnection operation for supplying the AC power in the normal state. For this reason, the EV power conditioner 120A has an effect of performing a charging operation to the electric vehicle C using the normal AC power obtained from the PV power conditioner 12 even in an emergency.

  Also, the PV power conditioner 12, the power conditioner of the natural energy generator, and the private power generator generate a large amount of noise, and there is a possibility that noise may be mixed into the power supply and cause malfunction, but the EV power conditioner 120A is extremely difficult. Since the noise filter 1 is provided at the first stage as the hourly power supply unit PR1, it is possible to reliably use the noise filter 1 as an operation power supply of the communication device 5 even with a noisy power supply. Therefore, the charging / discharging system S1 having the EV power conditioner 120A may start the discharging operation from the storage battery of the electric vehicle C after reliably establishing the communication process with the electric vehicle C even in an emergency. it can.

  In addition, by providing the noise filter 1 in the emergency power supply unit PR1, an emergency power supply of a private power generator or a power conditioner, which is not supposed to be connected to a power system, is connected to the emergency outlet 13. Even in such a case, there is an effect that a malfunction due to noise from the EV power conditioner 120A side can be suppressed.

  In the first embodiment, the emergency AC voltage output from the PV power conditioner 12 is set to 100 V, but may be set to 200 V, which is the same as the normal state.

  Further, in the first embodiment, the emergency power supply unit PR1 and the normal power supply unit PR4 are separately provided. However, the communication device 5 can be used when one power supply unit is in an emergency or in a normal state. The power may be supplied to the control circuit of the EV power conditioner 120A including the power supply. In that case, a switching device for switching between the input from the switch 8 and the input from the emergency outlet 13 is required before the power supply unit.

<Embodiment 2>
(Internal Configuration of EV Power Conditioner 120B)
FIG. 3 is a block diagram showing an internal configuration of an EV power conditioner 120B according to the second embodiment. In the second embodiment, EV power conditioner 120B having the configuration shown in FIG. 3 is arranged as EV power conditioner 120 in FIG.

  Hereinafter, regarding the EV power conditioner 120B, only portions different from the EV power conditioner 120A of the first embodiment shown in FIG. 2 will be described, and the same portions as those of the EV power conditioner 120A will be denoted by the same reference numerals and description thereof will be appropriately omitted. I do.

  In the EV power conditioner 120B of the second embodiment, the power storage 7 is connected to the output of the emergency power supply PR1. The power storage unit 7 has a power storage function composed of an electrolytic capacitor. That is, the power storage unit 7 stores the DC current output from the step-down circuit 4 and realizes a stable supply of the DC voltage output from the step-down circuit 4 in response to the output fluctuation of the emergency outlet 13.

  In the charge / discharge system S1 of the second embodiment, by providing the EV power conditioner 120B having the power storage unit 7, the amount of power generated by the photovoltaic power generation system 10 such as sudden fluctuations in solar radiation, early morning, sunset, and rain is small. Even at the time, the self-starting of the EV power conditioner 120B, that is, the supply of the operation power of the communication device 5 is enabled. As a result, the charging / discharging system S1 of the second embodiment can perform the charging operation and the discharging operation with the electric vehicle C more stably than in the first embodiment in an emergency.

  As described above, the EV power conditioner 120B according to the second embodiment provides the power storage unit 7 at the output unit of the emergency power supply unit PR1, thereby stabilizing the power generation amount of the PV power conditioner 12 even when the power generation amount is small. And can be used as a power source for the communication device 5. For this reason, the EV power conditioner 120B of the second embodiment has an effect of being able to reliably start up independently even in an emergency.

  Further, in the EV power conditioner 120B of the second embodiment, the power storage unit 7 is configured by the electrolytic capacitor, but it is needless to say that the same effect can be obtained by using a super capacitor or a small storage battery. Also, when a small storage battery is used as the power storage unit 7, it is needless to say that the EV power conditioner 120B can be independently activated even at night when power generation by the PV power conditioner 12 is not possible.

  As shown in FIG. 3, the power storage unit 7 is also connected to the output unit of the normal-time power supply unit PR4, and stores the DC current output from the step-down circuit 44 of the normal-time power supply unit PR4. A stable supply of the DC voltage output from the controller may be realized.

<Others>
In the above-described embodiment, an example is described in which the emergency power supply to the communication device 5 in the EV power conditioner 120 (120A, 120B) is performed from the PV power conditioner 12 of the photovoltaic power generation system 10. Needless to say, the same effect can be obtained by supplying power from a power conditioner or a private power generator of another natural energy power generation system instead of the photovoltaic power generation system 10.

  As described above, in the EV power conditioner 120 according to the above-described embodiment, a lead storage battery can be made unnecessary or the storage capacity can be reduced as a battery for a communication device, so that the EV power conditioner 120 can be reduced in size and weight. Can be achieved.

  Furthermore, by eliminating the need for the lead-acid battery described above, it is possible to prevent a reduction in the life of the lead-acid battery due to a failure, reduce the amount of power consumed for charging the lead-acid battery, and eliminate the need for repair and transportation of the lead-acid battery. For example, transportation can be facilitated.

  In addition, by eliminating the need for the lead storage battery described above, it is possible to reduce the risk of lead outflow, sulfuric acid outflow, etc. from the lead storage battery at the time of product accident or careless dismantling, as well as distribution. As a result, it is not necessary to manage the supplementary charge of the lead storage battery in the stock, and as a result, it is possible to reduce the environmental load at each stage in the product life cycle.

  The power supply line 123 connecting the emergency outlet 13 and the EV power conditioner 120 may be provided permanently or only in an emergency.

  In the present invention, each embodiment can be freely combined, or each embodiment can be appropriately modified or omitted within the scope of the invention.

  1,11 noise filter, 2,42 rectifier circuit, 3,43 smoothing circuit, 4,44 step-down circuit, 7 power storage unit, 10 solar power generation system, 12 PV power conditioner, 13 emergency outlet, 56 automobile main power supply , 123, 125-127 power supply line, C electric vehicle, E system power supply, S1 charge / discharge system, PR1 emergency power supply unit, PR4 normal power supply unit.

Claims (3)

An electric vehicle power conditioner connected to a plurality of power supplies and charging and discharging a storage battery of the electric vehicle, wherein the plurality of power supplies include first and second power supplies different from each other, and the second power supply is a solar power supply. A power generator and a PV power conditioner,
The electric vehicle power conditioner,
A conversion device that converts the DC voltage of the storage battery into an AC voltage, and converts the AC voltage of the power supply into a DC voltage,
A communication device that communicates with the electric vehicle when discharging the storage battery,
When the first power of the plurality of power supply is not available, the first power source and a separate receiving AC power from said second power supply through the emergency outlet present, direct the AC power power And an emergency power supply unit for supplying to the communication device.
Power conditioner for electric vehicles. If the first power source is not available, communicates with the communication device said electric vehicle, wherein the converter converts the DC power from the electric vehicle battery to AC power, wherein the electric vehicle Applying power from the storage battery to an interconnection output point to a load between the first power supply and the second power supply ,
A power conditioner for an electric vehicle according to claim 1. The emergency power supply unit includes a power storage unit that stores DC power obtained by converting AC power from the second power supply,
The power conditioner for an electric vehicle according to claim 1 or 2.

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