JP2009033840A - Power supply system and control method for power supply system - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an uninterruptible power supply system based on a continuous local feeding method and a control method for the power supply system. <P>SOLUTION: When the direct-current voltage of a direct-current bus 37 drops due to an increase in alternating-current load 5, discharge from a power storage device 35, or the like, a direct-current voltage monitor circuit 34h energizes an alternating-current switch 31 to switch a change-over switch 34i to the charge/active filter control circuit 34c side, and a power converter 33 performs a rectifying operation and an active filter operation. When the power storage device 35 is charged by the rectifying operation of the power converter 33 and the direct-current voltage of the direct-current bus 37 rises, the direct-current voltage monitor circuit 34h turns off the alternating-current switch 31 and switches the change-over switch 34i to the inverter control circuit 34b side, and the power converter 33 returns to inverting operation. <P>COPYRIGHT: (C)2009,JPO&INPIT

Description

  The present invention relates to a power feeding system and a method for controlling the power feeding system.

Conventionally, in addition to a commercial power supply, there is a system that has power supply equipment in its own premises and can supply power to a load in the event of a power failure.
For example, in Japanese Patent No. 3725015, when the commercial power source is healthy, power is always supplied to the load via the AC switch, and when a power failure occurs in the commercial power source, the AC switch is shut off in advance to a power supply facility such as a storage battery. This shows an uninterruptible power supply apparatus using a constant commercial power supply system in which stored DC power is converted into AC power by a power converter and power is supplied to a load.
Japanese Patent No. 3725015

Patent Document 1 always supports only the power supply from the grid power to the AC load, from the utilization of the power generated by the DC power generation facility in the own facility, and from the grid power and the AC generator in the own facility. The operation of temporarily storing and discharging the power was not supported. In particular, in the past, the system was completely different from a power supply device using a constant power supply system within the building.
In view of the above, an object of the present invention is to provide an uninterruptible power supply system and a control method for the power supply system that are always based on an in-house power supply system.
In particular, an object of the present invention is to effectively use power generated by a DC power generation facility in the premises while temporarily maintaining uninterruptible power supply, and temporarily store system power and power from an AC power generator in the premises. In addition, the discharge operation is realized.

According to the first solution of the present invention, an AC switch connected to the grid power,
AC bus connected to system power via the AC switch and supplying AC power to an AC load;
A DC bus to which the power storage device is connected;
Connected between the AC bus and the DC bus, performs a forward conversion operation from AC to DC according to a current control command, and an active filter operation that compensates for harmonic current and reactive power flowing through an AC load, and DC according to a voltage control command. A power converter that performs reverse conversion operation from AC to AC;
A basic voltage generation circuit that outputs a reference sine wave signal corresponding to the phase and AC voltage of the system power based on the phase information and voltage information of the system power;
An inverter control circuit that outputs a voltage control command for causing the power converter to perform an inverse conversion operation based on an output of the basic voltage generation circuit;
Based on the output of the basic voltage generation circuit, the voltage of the DC bus, the current of the DC bus, and the current of the AC bus, a current control command for causing the power converter to perform forward conversion operation and active filter operation is output. A charge / active filter control circuit;
Memory that stores preset lower limit preset values that determine preset lower limit voltage for steady state, upper limit preset values that define higher voltage limit than steady state, and lower limit preset value that defines lower voltage limit than steady state And
A changeover switch for switching a control command to be given to the power converter to either the output of the inverter control circuit or the output of the charge / active filter control circuit;
A DC voltage monitoring circuit that compares each preset value given from the storage unit with the voltage of the DC bus, controls the AC switch, and outputs a switching signal to the changeover switch;
With

(1) As a steady state operation,
When the DC voltage monitoring circuit detects that the DC voltage of the DC bus is within a range between an upper limit preset value and a steady lower limit preset value, the AC switch is turned off, and the changeover switch is set to the non-conductive state. Switch to the inverter control circuit side,
The inverter control circuit outputs a voltage control command for causing the power converter to perform an inverse conversion operation,
The power converter performs an inverse conversion operation,

(2) As an operation in state 1,
The DC voltage of the DC bus decreases due to an increase in AC load or continuation of the discharge state of the power storage device, and the DC voltage monitoring circuit confirms that the DC voltage of the DC bus is less than or less than a lower limit preset value. If detected, the AC switch is conducted, and the changeover switch is switched to the charge / active filter control circuit side,
The charge / active filter control circuit outputs a current control command for performing a forward conversion operation and an active filter operation,
The power converter performs a forward conversion operation and an active filter operation that compensates for harmonic current and reactive power flowing in an AC load,

(3) As an operation in state 2,
In the state 1, the power converter is charged by the forward conversion operation so that the power storage device is charged and the DC voltage of the DC bus rises, and the DC voltage monitoring circuit stores the DC voltage of the DC bus in the storage unit. When it is detected that the above-mentioned steady lower limit preset value is exceeded or exceeded, the AC switch is turned off, and the changeover switch is switched to the inverter control circuit side,
The inverter control circuit outputs a voltage control command for causing the power converter to perform an inverse conversion operation,
The power converter is provided with a power feeding system that returns to the reverse conversion operation.

According to the second solution of the present invention, an AC switch connected to the grid power,
An AC bus connected to the system power via the AC switch and supplying AC power to the first and second AC loads;
A first load switch for disconnecting or connecting the second AC load to the AC bus;
A DC bus to which the power storage device is connected;
Connected between the AC bus and the DC bus, performs a forward conversion operation from AC to DC according to a current control command, and an active filter operation that compensates for harmonic current and reactive power flowing through an AC load, and DC according to a voltage control command. A power converter that performs reverse conversion operation from AC to AC;
A basic voltage generation circuit that outputs a reference sine wave signal corresponding to the phase and AC voltage of the system power based on the phase information and voltage information of the system power;
An inverter control circuit that outputs a voltage control command for causing the power converter to perform an inverse conversion operation based on an output of the basic voltage generation circuit;
Based on the output of the basic voltage generation circuit, the voltage of the DC bus, the current of the DC bus, and the current of the AC bus, a current control command for causing the power converter to perform forward conversion operation and active filter operation is output. A charge / active filter control circuit;
A preset steady-state lower limit value that defines a preset lower-limit voltage in a steady state; an upper-limit preset value that defines a higher voltage limit than the steady state; a first threshold preset value that defines a lower-voltage threshold than the steady state; A storage unit for storing a lower limit preset value that defines a lower voltage limit than the threshold preset value;
A changeover switch for switching a control command to be given to the power converter to either the output of the inverter control circuit or the output of the charge / active filter control circuit;
A DC voltage monitoring circuit for comparing each preset value given from the storage unit with the voltage of the DC bus, controlling the AC switch, outputting a switching signal to the selector switch, and controlling the opening and closing of the first load switch When,
With

(1) As a steady state operation When the DC voltage monitoring circuit detects that the DC voltage of the DC bus is within the range between the upper limit preset value and the steady lower limit preset value, the AC switch is turned off. And switch the changeover switch to the inverter control circuit side,
The inverter control circuit outputs a voltage control command for causing the power converter to perform an inverse conversion operation,
The power converter performs an inverse conversion operation,

(2) As an operation in state 1,
The DC voltage of the DC bus decreases due to the increase in the first and / or second AC load or the continuation of the discharge of the power storage device, and the DC voltage monitoring circuit is configured such that the DC voltage of the DC bus is a first threshold preset value. When it is detected that the following is less than or less, an opening command signal is output to the first load switch, and the first load switch is opened,
When the DC voltage monitoring circuit detects that the DC voltage of the DC bus has further decreased to reach the lower limit preset value, the AC switch is turned on, and the changeover switch is turned to the charge / active filter control circuit side. Switching, outputting a current control command for causing the power converter to perform forward conversion operation and active filter operation,
The power converter performs a forward conversion operation and an active filter operation that compensates for harmonic current and reactive power flowing in an AC load,

(3) In state 2,
In the state 1, the power converter is charged by the forward conversion operation to charge the power storage device, the DC voltage of the DC bus rises, and the DC voltage monitoring circuit has a DC voltage of the DC bus that is equal to or greater than a first threshold preset value. Or, when it is detected that it has been exceeded, a closing command signal is output to the first load switch, and the first load switch is closed,
When the DC voltage monitoring circuit detects that the DC voltage of the DC bus is greater than or equal to the steady lower limit preset value, the DC voltage monitoring circuit turns off the AC switch and sets the changeover switch to the inverter control circuit side. switching,
The inverter control circuit outputs a voltage control command for causing the power converter to perform an inverse conversion operation,
The power converter is provided with a power feeding system that returns to reverse voltage conversion operation.

According to a third solution of the present invention, an AC switch connected to the grid power,
AC bus connected to system power via the AC switch and supplying AC power to an AC load;
A DC bus to which the power storage device is connected;
Connected between the AC bus and the DC bus, performs a forward conversion operation from AC to DC according to a current control command, and an active filter operation that compensates for harmonic current and reactive power flowing through an AC load, and DC according to a voltage control command. A power converter that performs reverse conversion operation from AC to AC;
A basic voltage generation circuit that outputs a reference sine wave signal corresponding to the phase and AC voltage of the system power based on the phase information and voltage information of the system power;
An inverter control circuit that outputs a voltage control command for causing the power converter to perform an inverse conversion operation based on an output of the basic voltage generation circuit;
Based on the output of the basic voltage generation circuit, the voltage of the DC bus, the current of the DC bus, and the current of the AC bus, a current control command for causing the power converter to perform forward conversion operation and active filter operation is output. A charge / active filter control circuit;
Memory that stores preset lower limit preset values that determine preset lower limit voltage for steady state, upper limit preset values that define higher voltage limit than steady state, and lower limit preset value that defines lower voltage limit than steady state And
A changeover switch for switching a control command to be given to the power converter to either the output of the inverter control circuit or the output of the charge / active filter control circuit;
A DC voltage monitoring circuit that compares each preset value given from the storage unit with the voltage of the DC bus, controls the AC switch, and outputs a switching signal to the changeover switch;
A method for controlling a power supply system comprising:

(1) As a steady state operation,
When the DC voltage monitoring circuit detects that the DC voltage of the DC bus is within a range between an upper limit preset value and a steady lower limit preset value, the AC switch is turned off, and the changeover switch is set to the non-conductive state. Switch to the inverter control circuit side,
The inverter control circuit outputs a voltage control command for causing the power converter to perform an inverse conversion operation,
The power converter performs an inverse conversion operation,

(2) As an operation in state 1,
The DC voltage of the DC bus decreases due to an increase in AC load or continuation of the discharge state of the power storage device, and the DC voltage monitoring circuit confirms that the DC voltage of the DC bus is less than or less than a lower limit preset value. If detected, the AC switch is conducted, and the changeover switch is switched to the charge / active filter control circuit side,
The charge / active filter control circuit outputs a current control command for performing a forward conversion operation and an active filter operation,
The power converter performs a forward conversion operation and an active filter operation that compensates for harmonic current and reactive power flowing in an AC load,

(3) As an operation in state 2,
In the state 1, the power converter is charged by the forward conversion operation so that the power storage device is charged and the DC voltage of the DC bus rises, and the DC voltage monitoring circuit stores the DC voltage of the DC bus in the storage unit. When it is detected that the above-mentioned steady lower limit preset value is exceeded or exceeded, the AC switch is turned off, and the changeover switch is switched to the inverter control circuit side,
The inverter control circuit outputs a voltage control command for causing the power converter to perform an inverse conversion operation,
The power converter is provided with a method of controlling the power feeding system that returns to the reverse conversion operation.

According to a fourth solution of the present invention, an AC switch connected to the grid power,
An AC bus connected to the system power via the AC switch and supplying AC power to the first and second AC loads;
A first load switch for disconnecting or connecting the second AC load to the AC bus;
A DC bus to which the power storage device is connected;
Connected between the AC bus and the DC bus, performs a forward conversion operation from AC to DC according to a current control command, and an active filter operation that compensates for harmonic current and reactive power flowing through an AC load, and DC according to a voltage control command. A power converter that performs reverse conversion operation from AC to AC;
A basic voltage generation circuit that outputs a reference sine wave signal corresponding to the phase and AC voltage of the system power based on the phase information and voltage information of the system power;
An inverter control circuit that outputs a voltage control command for causing the power converter to perform an inverse conversion operation based on an output of the basic voltage generation circuit;
Based on the output of the basic voltage generation circuit, the voltage of the DC bus, the current of the DC bus, and the current of the AC bus, a current control command for causing the power converter to perform forward conversion operation and active filter operation is output. A charge / active filter control circuit;
A preset steady-state lower limit value that defines a preset lower-limit voltage in a steady state; an upper-limit preset value that defines a higher voltage limit than the steady state; a first threshold preset value that defines a lower-voltage threshold than the steady state; A storage unit for storing a lower limit preset value that defines a lower voltage limit than the threshold preset value;
A changeover switch for switching a control command to be given to the power converter to either the output of the inverter control circuit or the output of the charge / active filter control circuit;
A DC voltage monitoring circuit for comparing each preset value given from the storage unit with the voltage of the DC bus, controlling the AC switch, outputting a switching signal to the selector switch, and controlling the opening and closing of the first load switch When,
A method for controlling a power supply system comprising:

(1) As a steady state operation When the DC voltage monitoring circuit detects that the DC voltage of the DC bus is within the range between the upper limit preset value and the steady lower limit preset value, the AC switch is turned off. And switch the changeover switch to the inverter control circuit side,
The inverter control circuit outputs a voltage control command for causing the power converter to perform an inverse conversion operation,
The power converter performs an inverse conversion operation,

(2) As an operation in state 1,
The DC voltage of the DC bus decreases due to the increase in the first and / or second AC load or the continuation of the discharge of the power storage device, and the DC voltage monitoring circuit is configured such that the DC voltage of the DC bus is a first threshold preset value. When it is detected that the following is less than or less, an opening command signal is output to the first load switch, and the first load switch is opened,
When the DC voltage monitoring circuit detects that the DC voltage of the DC bus has further decreased to reach the lower limit preset value, the AC switch is turned on, and the changeover switch is turned to the charge / active filter control circuit side. Switching, outputting a current control command for causing the power converter to perform forward conversion operation and active filter operation,
The power converter performs a forward conversion operation and an active filter operation that compensates for harmonic current and reactive power flowing in an AC load,

(3) In state 2,
In the state 1, the power converter is charged by the forward conversion operation to charge the power storage device, the DC voltage of the DC bus rises, and the DC voltage monitoring circuit has a DC voltage of the DC bus that is equal to or greater than a first threshold preset value. Or, when it is detected that it has been exceeded, a closing command signal is output to the first load switch, and the first load switch is closed,
When the DC voltage monitoring circuit detects that the DC voltage of the DC bus is greater than or equal to the steady lower limit preset value, the DC voltage monitoring circuit turns off the AC switch and sets the changeover switch to the inverter control circuit side. switching,
The inverter control circuit outputs a voltage control command for causing the power converter to perform an inverse conversion operation,
The power converter is provided with a method for controlling the power feeding system that returns to the reverse voltage conversion operation.

ADVANTAGE OF THE INVENTION According to this invention, the control method of the uninterruptible electric power feeding system and electric power feeding system by a self-power-feeding system always can be provided.
In particular, according to the present invention, while maintaining uninterruptible power supply, effective utilization of power generated by a DC power generation facility within the facility, and temporary storage of system power and power from the AC generator in the facility are temporarily stored. The discharge operation can be realized.

1. 1. First Embodiment 1.1 Configuration FIG. 1 is a configuration diagram of a first embodiment of a power feeding system.
The power supply device includes a system power 1, a power feeding system 3, an AC load 5, a DC power generation device 7, and a power storage device 35.
The grid power 1 is a commercial power source that receives power from an electric power company or the like. The power feeding system 3 is a system that supplies power to the AC load 5. The AC load 5 is a load device for inputting AC power or a group thereof. The DC power generator 7 is a device that generates DC power. The DC power generation device 7 includes a detection unit 7a that detects an output voltage to the DC bus and a storage unit 7b that stores a part or all of preset values stored in a storage unit 34g described later, or other preset values. In this example, the upper limit preset value V _H and the steady upper limit preset value V _HR are stored in the storage unit 7b.
The power feeding system 3 includes an AC switch 31, an AC bus 32, a power converter 33, a control circuit 34, a DC bus 37, a DC detection circuit 38, current transformers CT1 to CT4, and instrument transformers VT1 and VT2.
The AC switch 31 is constituted by a thyristor connected in antiparallel. The AC bus 32 is connected to the system power 1 via the AC switch 31, is connected to the DC bus 37 via the power converter 33, and supplies AC power to the AC load 5. The power converter 33 performs forward conversion (AC side to DC side), active filter (compensates for harmonic current and reactive power flowing through the AC load) operation, and reverse conversion operation (DC side to AC side). It is a switching power supply that is instructed to operate in any of the operations and enables both power supplies.
The control circuit 34 is a circuit that controls the state of the power converter 33 and the AC switch 31. The control circuit 34 includes a basic voltage generation circuit 34a, an inverter control circuit 34b, a charging / active filter control circuit 34c, a DC voltage / current control circuit 34d, a PWM circuit 34e, an ignition circuit 34f, a storage unit 34g, a DC voltage monitoring circuit 34h, A changeover switch 34i is provided.
The basic voltage generation circuit 34a is a circuit that outputs a reference sine wave signal according to the output of the instrument transformer VT1. The reference voltage generation circuit 34a generates a reference sine wave voltage signal whose phase matches that of the AC voltage output from the commercial power supply AC, based on the AC voltage phase information of the commercial power supply captured when the commercial power supply AC is normal. It is prepared and output to the inverter control circuit 34b and the charge / active filter control circuit 34c. Further, the reference voltage generating circuit 34a can output at a reference voltage and a reference frequency determined by itself when the commercial power supply is abnormal. The inverter control circuit 34b is a circuit that outputs a voltage control command for causing the power converter 33 to perform an inverse conversion operation based on the output of the basic voltage generation circuit 34a. The charge / active filter control circuit 34c is a circuit that outputs a current control command for causing the power converter 33 to perform forward conversion operation and active filter operation based on outputs of the basic voltage generation circuit 34a and the DC voltage / current control circuit 34d. is there. The DC voltage / current control circuit 34d compares the output from the DC detection circuit 38 (DC voltage Vdc of the DC bus 37) with a preset DC voltage value not shown in the DC voltage / current control circuit 34d. In order to limit the charging current of the power storage device 35, the current limit value not shown in the DC voltage / current control circuit 34d is compared with the DC current output from the DC detection circuit 38 based on the result of comparison. This circuit outputs a DC voltage command to the charge / active filter control circuit 34c during the conversion operation. Thereby, the power storage device 35 can be charged within the current limit value during the forward conversion operation. For example, the current limit value is compared with the detected value of the DC current, the set DC voltage (command) value not shown is reduced by the amount that the DC current value exceeds the current limit value, and the DC current is within the current limit value. If this is the case, the DC voltage (command) value to be set can be a constant value (constant voltage constant current control for charging the storage battery). Furthermore, an active filter function can be added by inputting the CT1 output signal and the CT3 output signal to the charge / active filter control circuit 34c. The PWM circuit 34 e is a circuit that outputs a PWM control signal for performing PWM control on the power converter 33. The ignition circuit 34f is a circuit that outputs an ignition pulse signal to the thyristor of the AC switch 31 in accordance with the output of the DC voltage monitoring circuit 34h.
The storage unit 34g stores various preset values that are arbitrarily input from a system external or internal input device or the like (in this example, the steady upper limit preset value V _HR shown in FIGS. 2 and 3). The lower limit preset value V _LR , the upper limit preset value V _H , and the lower limit preset value V _{L. The} steady upper limit preset value V _HR may be omitted. The direct current voltage monitoring circuit 34h compares the preset value given from the storage unit 34g with the direct current voltage Vdc of the direct current bus 37 detected by the direct current detection circuit 38 using the direct current detection line, and sends an ignition command signal to the ignition circuit 34f. This circuit outputs a switching signal to the changeover switch 34i. The changeover switch 34i is a switch for switching a signal input to the PWM circuit 34e. The DC voltage monitoring circuit 34 h switches the voltage control command output from the inverter control circuit 34 b and the current control command output from the charge / active filter control circuit 34 c by the changeover switch 34 i and outputs the command to the power converter 33. When the changeover switch 34i is switched to the inverter control circuit 34b side by the changeover signal from the DC voltage monitoring circuit 34h, the power converter 33 is controlled by the voltage control command value, and the changeover switch 34i is charged / active filter controlled. When switched to the circuit 34c side, the power converter 33 is current-controlled by the current control command value. The output of the inverter control circuit 34b and the charge / active filter control circuit 34c outputs a control command value according to the phase and voltage information of the system power output from the basic voltage generation circuit 34a, and the voltage output from the inverter control circuit 34b. The power converter 33 performs a reverse conversion operation according to the control command value, while the power converter 33 performs a forward conversion operation according to the current control command value output from the charging / active filter control circuit 34c.
The power storage device 35 is a storage element that can store and release direct current electric energy. The power storage device 35 is, for example, a sodium-sulfur battery, a redox flow battery, a flywheel power storage facility via a storage battery, a capacitor, and a power converter.
The DC bus 37 is connected to the AC bus 32 via the power converter 33, and the DC power generator 7 and the power storage device 35 are connected.
The instrument current transformers CT1, CT2, and CT3 are devices that output a current (for example, 100A) that passes through an electric wire or cable at a predetermined point by changing it to a smaller current value (for example, 5A). The instrument transformers VT1 and VT2 are devices that change and output a potential difference (for example, 6,600 200V) between electric wires or cables at a predetermined point to a lower voltage (for example, 10V). The DC detection circuit 38 is a detection circuit for measuring the voltage Vdc and current (detected by CT4) of the DC bus 37.

1.2 Operation

FIG. 2 is a diagram (1) showing the relationship between the DC voltage of the DC bus and each state.
Hereinafter, the steady state and the states 1 to 2 will be described.

(1) Steady State In the steady state, the power feeding system 3 always supplies power to the AC load 5 by the power storage device 35 and / or the DC power generation device 7 in a self-contained power supply method.
The DC voltage monitoring circuit 34h compares the output of the DC detection circuit 38 with the preset values (V _HR , V _LR ) stored in the storage unit 34g. The DC voltage monitoring circuit 34h controls the ignition circuit 34f so as not to generate an ignition pulse when the voltage Vdc of the DC bus 37 is within a preset value ( _VHR ) and preset value ( _VLR ) range, The AC switch 31 is turned off (off), and the changeover switch 34i is switched to the inverter control circuit 34b side.
In this example, the DC power generation device 7 is in a state of generating power, and the generated power is matched with the DC voltage Vdc of the DC bus 37 detected by the DC detection circuit 38 to output a current (current control type), thereby converting the power. DC power is supplied to the battery 33 and the power storage device 35 is charged. Note that the DC power generator 7 may be in a state where it does not generate power.
The reference voltage generation circuit 34a receives the AC power detected by the instrument transformer VT1, and based on the voltage information and phase information of the system power 1, a reference sine wave signal that matches the AC voltage and phase of the system power 1 Is output to the inverter control circuit 34b and the charge / active filter control circuit 34c. Alternatively, the reference voltage generation circuit 34a can output any predetermined reference sine wave signal regardless of the output of the instrument transformer VT1.
The inverter control circuit 34b receives the reference sine wave voltage signal output from the reference voltage generation circuit 34a and the AC power detected by the instrument transformer VT2 that detects the AC voltage output from the AC side of the power converter 33. The inverter control command (voltage control command) for causing the power converter 33 to perform the reverse conversion operation is output. The PWM circuit 34e receives the signal from the inverter control circuit 34b, and outputs a command signal for voltage command control that causes the power converter 33 to perform a reverse conversion operation (conversion operation from the DC side to the AC side). The power converter 33 performs an inverse conversion operation, generates an AC voltage that matches the phase of the system power 1 and the AC voltage, and outputs the AC voltage to the AC output side. Alternatively, the power converter 33 can generate a predetermined AC voltage and output it to the AC output side.

(2) State 1 (when DC bus voltage drops due to increased load)
When the demand for the AC load 5 increases and the DC input power (input power from the DC bus 37 side) of the power converter 33 increases, the power storage device 35 starts to discharge, and both the DC power generation device 7 and the power storage device 35 DC power is supplied to the power converter 33. When the discharging state of power storage device 35 continues, DC voltage Vdc of DC bus 37 decreases.
When the DC voltage monitoring circuit 34h detects that the DC voltage Vdc of the DC bus 37 has reached or decreased to the preset value (V _L ) stored in the storage unit 34e, the DC voltage monitoring circuit 34h An ignition command signal is output to the arc circuit 34f, and a switching signal is output to the changeover switch 34i. When the ignition command signal is input, the ignition circuit 34f outputs an ignition pulse signal for making the AC switch 31 conductive. The changeover switch 34i switches the switch to the charge / active filter control 34c side, and changes the operation of the power converter 33 to the forward conversion operation and the active filter operation that compensates the harmonic current and reactive power flowing in the AC load.
The DC voltage / current control circuit 34d obtains a difference voltage between the preset value stored in the storage unit 34g and the DC side voltage Vdc of the power converter 1 detected by the DC detection circuit 38, and the difference voltage is multiplied by a constant (kdc). And output.
The charge / active filter control circuit 34c performs forward conversion operation and active filter operation based on the outputs of the reference voltage generation circuit 34a and the DC voltage / current control circuit 34d and the current detected by the instrument current transformers CT1, CT2, and / or CT3. To output a current control command. For example, the charging / active filter control circuit 34c converts the output current of the DC voltage / current control circuit 34d (a constant multiple of the difference voltage) and the output of the reference voltage generation circuit 34a into the input current of the power converter 33. The corresponding input current command value Io is obtained. Further, from this input current command value Io, the load current value I _CT3 flowing through the AC load 5 detected by the current transformer _CT3 and the power converter 33 detected by the current transformer CT2 are obtained. A value (Io−I _CT3 −I _CT2 ) obtained by subtracting the current value I _CT2 flowing in from the AC side is output as a current control command.
As a result, the power converter 33 performs a forward conversion operation (conversion operation from the AC side to the DC side) and an active filter operation that compensates for harmonic current and reactive power flowing through the AC load 5.

(3) State 2 (during charging by the power converter 33)
When the power converter 33 performs a forward conversion operation, the power storage device 35 is charged and the DC voltage of the DC bus 37 increases.
When the DC voltage monitoring circuit 34h detects that the DC voltage Vdc detected by the DC detection circuit 38 is greater than or equal to the preset value (V _LR ) stored in the storage unit 34g, it turns on the AC switch 31. The ignition command signal (the output of the ignition circuit 34f) is stopped, the AC switch 31 is turned off, and a switching signal is sent to the changeover switch 34i to switch to the inverter control circuit 34b side. As a result, the power converter 33 is switched to perform an inverse conversion operation (conversion operation from the DC side to the AC side) by the output of the inverter control circuit 34b, and the steady state, that is, the DC voltage Vdc becomes the preset value _VLR . Within the range between the preset values _VHR .
As a result, the DC power generator 7 returns to the power generation operation similar to “(1) steady state”.

FIG. 3 is a diagram (2) showing the relationship between the DC voltage of the DC bus and each state.
Next, the steady state and each of the states 3 to 4 will be described with reference to FIG.
Also in this case, the “steady state” is as described in “(1) Steady state”.

(4) State 3 (during DC bus voltage rise)
In a steady state, the generated power of the DC power generator 7 is reduced from the DC input power (from the DC bus 37 side) to the power converter 33 due to a decrease in the demand of the AC load 5 or the discharge or charging of the power storage device 35. DC voltage Vdc detected by the DC detection circuit 38 increases.
The DC power generation device 7 detects the voltage output to the DC bus 37 with the internal detection unit 7a, and the DC voltage is equal to or higher than the preset value (V _H ) stored in the internal storage unit 7b. If this is detected, power generation is automatically stopped.

(5) State 4 (DC generator is stopped)
When the DC power generation device 7 is stopped and the discharge state of the power storage device 35 continues, the DC voltage Vdc of the DC bus 37 decreases.
The DC power generator 7 detects the DC voltage output to the DC bus 37 by the internal detection circuit 7a, and when the voltage is equal to or lower than the preset value (V _HR ) stored in the internal storage unit 7b, The DC power generator 7 is automatically restarted.
As a result, the DC power generator 7 returns to the power generation operation similar to “(1) steady state”.

2. Second Embodiment 2.1 Configuration FIG. 4 is a configuration diagram of a second embodiment of the power feeding system.
The power supply device includes a system power 1, a power feeding system 3, an AC load 5, load switches 6b and 6c, and a DC power generator 7. The load switches 6b and 6c are electromagnetic contactors for arbitrarily disconnecting or connecting an AC load.
In 1st Embodiment, when the electric power input into the alternating current load 5 is large and the electrical storage apparatus 35 does not have sufficient capacity | capacitance with respect to it, the above-mentioned "(2) state 1" and "(3) state" The case where “2” is continuously repeated is assumed. When “(2) state 1” and “(3) state 2” are repeated, the power storage device 35 is charged and discharged each time, and there is a problem that the life of the power storage device 35 is shortened.
Therefore, in the present embodiment, the load switch 6 b and the load switch 6 c are inserted between the AC load 5 and the power feeding system 3 in order to prevent the power storage device 35 from having a short life. Further, it is assumed that the load switch 6b and the load switch 6c can be arbitrarily opened and closed by a command signal from the DC voltage monitoring circuit 34h ′. In addition to the steady lower limit preset value V _LR , the steady upper limit preset value V _HR , the lower limit preset value V _L , and the upper limit preset value V _H , the storage unit 34g ′ has a first threshold preset value V _L1 and a second threshold preset. The value V _L2 is stored. In addition, the storage unit 34g ′ has a priority table that describes the priority of power supply to the AC loads 5a to 5c.
FIG. 5 is an explanatory diagram of a priority order table showing the order of power supply to the AC load.
In this example, it is stored that the AC load 5a is directly connected to the AC bus 32, and the AC loads 5b and 5c are connected via the load switches 6b and 6c connected to the AC bus 32, respectively. The AC load 5a is the highest level, the AC load 5b is the second highest, the AC load 5c is the lowest, and the threshold preset value for switching is set. For the highest level AC load, even if it is connected to the AC bus 32 via a load switch, the threshold value is set lower than the lower limit preset value, so that the alternating current is not always intentionally disconnected. It can be in a state where it is connected to the bus 32. Further, in this example, a first threshold preset value (V _L1 ) is stored as a threshold value for opening and closing the load switch 6c, and a second threshold preset value (V _L2 ) is stored as a threshold value for opening and closing the load switch 6b. Yes. This corresponding preset value can also be omitted.
The direct current voltage monitoring circuit 34h ′ compares the preset value given from the storage unit 34g ′ with the direct current voltage Vdc of the direct current bus 37 detected by the direct current detection circuit 38 using the direct current detection line, and sends an ignition command signal to the ignition circuit 34f. Is a circuit that outputs a switching signal to the changeover switch 34i, and controls the load switches 6b and 6c to be turned ON / OFF.
Other configurations are the same as those in the first embodiment.

2.2 Operation

FIG. 6 is a diagram (3) showing the relationship between the DC voltage of the DC bus and each state.
Hereinafter, the steady state and the states 1 to 2 will be described.

(1) Steady state As in the first embodiment, in the steady state, the power supply system 3 always supplies power to the AC load 5 by the power storage device 35 and / or the DC power generation device 7 in the self-contained power supply method. .
The DC voltage monitoring circuit 34h ′ compares the output of the DC detection circuit 38 with preset values (V _HR , V _LR ) stored in the storage unit 34g ′. When the voltage Vdc of the DC bus 37 is within the preset value (V _HR ) and preset value (V _LR ), the DC voltage monitoring circuit 34h ′ performs control so that the ignition circuit 34f does not emit an ignition pulse. The AC switch 31 is turned off (off), and the changeover switch 34i is switched to the inverter control circuit 34b side. Further, the load switches 6b and 6c are closed by the DC voltage monitoring circuit 34h ′.
The power converter 33 performs an inverse conversion operation, generates an AC voltage that matches the phase of the system power 1 and the AC voltage, and outputs the AC voltage to the AC output side. Alternatively, the power converter 33 can generate a predetermined AC voltage and output it to the AC output side.
Other detailed operations are the same as those in the first embodiment.

(2) State 1 (when DC bus voltage drops due to increased load)
When the demand for the AC load 5 increases and the DC input power (input power from the DC bus 37 side) of the power converter 33 increases, the power storage device 35 starts to discharge, and both the DC power generation device 7 and the power storage device 35 DC power is supplied to the power converter 33. When the discharging state of the power storage device 35 continues, the DC voltage of the DC bus 37 decreases. When the DC voltage monitoring circuit 34h ′ detects that the DC voltage Vdc of the DC bus 37 has reached or below the preset value (V _L1 ) stored in the storage unit 34g, the DC voltage monitoring circuit 34h ′ The load switch corresponding to the AC load having a low priority is obtained by referring to the priority table of the unit 34g ′. In this case, the DC voltage monitoring circuit 34h ′ outputs an open circuit command signal to the load switch 6c. Thereby, the load switch 6c is opened.
Further, when the DC load monitoring circuit 34h ′ detects that the DC voltage Vdc of the DC bus 37 has decreased and has reached or below the preset value (V _L2 ) stored in the storage unit 34g, the DC voltage monitoring circuit 34h 'Refers to the priority table of the storage unit 34g and outputs an open circuit command signal to the load switch 6b having the next lowest priority. Thereby, the load switch 6b is opened.
Furthermore, when the DC voltage monitoring circuit 34h ′ detects that the DC voltage Vdc of the DC bus 37 has decreased and has reached or below the preset value (V _L ) stored in the storage unit 34g, the DC voltage monitoring circuit 34h 'Outputs a firing command signal to the firing circuit 34f and a switching signal to the changeover switch 34i. When the ignition command signal is input, the ignition circuit 34f outputs an ignition pulse signal for making the AC switch 31 conductive. The changeover switch 34i switches the switch to the charge / active filter control 34c side, and changes the operation of the power converter 33 to the forward conversion operation and the active filter operation that compensates the harmonic current and reactive power flowing in the AC load.
As a result, the power converter 33 performs a forward conversion operation and an active filter operation that compensates for harmonic current and reactive power flowing in the AC load. Note that the operation details and the like of each part in the forward conversion operation are the same as “(2) State 1” in the first embodiment.

The load switch that is opened and closed with the preset value (V _L1 ) and the preset value (V _L2 ) as threshold values is stored in the DC voltage monitoring circuit 34h ′ when the correspondence relationship is stored in the priority table. When Vdc reaches the preset value (V _L1 ) or the preset value (V _L2 ), the load switch corresponding to the preset value stored in the priority table can be selected. When the correspondence relationship is not stored in the priority order table, the DC voltage monitoring circuit 34h ′ stores the DC voltage Vdc in the priority order table according to the order of the magnitude of the preset value when the DC voltage Vdc reaches each preset value. According to the priorities set, it is possible to select in order from the load switch with the lower priority.

(3) State 2 (during charging by the power converter 33)
When power converter 33 performs a forward conversion operation, power storage device 35 is charged and DC voltage Vdc of DC bus 37 increases.
When the DC voltage monitoring circuit 34h ′ detects that the DC voltage Vdc of the DC bus 37 detected by the DC detection circuit 38 is greater than or equal to the preset value (V _L2 ) stored in the storage unit 34g, The DC voltage monitoring circuit 34h ′ refers to the priority table of the storage unit 34g and turns on the load switch corresponding to the AC load having a relatively high priority among the AC loads in the OFF state. In this case, the DC voltage monitoring circuit 34h ′ outputs a closing command signal to the load switch 6b. Thereby, the load switch 6b is closed.
Further, when the DC voltage monitoring circuit 34h ′ detects that the DC voltage Vdc of the DC bus 37 rises and exceeds or exceeds the preset value (V _L1 ) of FIG. 4 stored in the storage unit 34g, The voltage monitoring circuit 34h ′ outputs a closing command signal to the load switch 6c having the next highest priority in the OFF state. Thereby, the load switch 6c is closed.
Further, when it is detected that the DC voltage Vdc detected by the DC detection circuit 38 increases and exceeds or exceeds the preset value (V _LR ), the DC voltage monitoring circuit 34h ′ makes the AC switch 31 conductive. Is stopped, the AC switch 31 is turned off, and a switching signal is sent to the switch 34i to switch to the inverter control circuit 34b side, thereby causing the power converter 33 to perform a reverse conversion operation. As a result, the power converter 33 returns to the reverse voltage conversion operation similar to the steady state.
The details of the operation of each part in the inverse conversion operation are the same as those in the first embodiment. Moreover, although the example of the priority is shown in two steps, the present invention is not limited to this, and a plurality of subplot values corresponding to the priority are described.

(4) State 3 (during DC bus voltage rise)
In a steady state, the generated power of the DC power generator 7 is reduced from the DC input power (from the DC bus 37 side) to the power converter 33 due to a decrease in the demand of the AC load 5 or the discharge or charging of the power storage device 35. DC voltage Vdc detected by the DC detection circuit 38 increases.
In this case, as in the first embodiment (see FIG. 3), the DC power generation device 7 detects the voltage output to the DC bus 37 by the internal detection unit 7a, and the DC voltage is stored in the internal storage unit 7b. When it is detected that the preset value (V _H ) that is stored in or exceeds the preset value (V _H ) is exceeded, the power generation is automatically stopped.

(5) State 4 (DC generator is stopped)
When the DC power generation device 7 is stopped and the discharge state of the power storage device 35 continues, the DC voltage Vdc of the DC bus 37 decreases.
In this case, as in the first embodiment (see FIG. 3), the DC power generation device 7 detects a DC voltage output to the DC bus 37 by the internal detection circuit 7a, and the voltage is stored in the internal memory. When it becomes below the preset value (V _HR ) stored in the unit 7b, the DC power generator 7 is automatically restarted.
As a result, the DC power generator 7 returns to the power generation operation similar to “(1) steady state”.

The power feeding system 3 can achieve the object of the present invention by repeating “(2) State 1” and “(3) State 2” even when the DC power generation device 7 is not provided.
The power supply system 3 can achieve the object of the invention even when a DC load is connected in parallel with the DC power generation device 7 and power is supplied to the DC load.
The power feeding system 3 can achieve the object of the invention even when an AC power generation device is connected in parallel with the AC load 5 and it generates power. In this case, when the DC voltage monitoring circuit 34h detects that the DC voltage of the DC bus 37 is greater than or equal to the upper limit preset value, it outputs a stop signal to the AC generator, and is less than or less than the steady upper limit preset value. When this happens, it can be configured to output a start signal to the AC generator.
The start and stop of the AC generator and the DC generator 7 described above may be operated by a schedule operation function in accordance with the daily load fluctuation.

The lineblock diagram of a 1st embodiment of an electric supply system. The figure which shows the direct current voltage of a direct current bus, and the relationship (1) to each state. The figure which shows the direct current voltage of a direct current bus, and the relationship (2) to each state. The block diagram of 2nd Embodiment of an electric power feeding system. Priority table for power supply to AC load. The figure which shows the direct current voltage of a direct current bus, and the relationship (3) to each state.

Explanation of symbols

1 System Power 3 Power Supply System 5 AC Load 7 DC Generator 7a Detector 7b Storage Unit 31 AC Switch 32 AC Bus 33 Power Converter 34 Control Circuit 34a Reference Voltage Generation Circuit 34b Inverter Control Circuit 34c Charging / Active Filter Control Circuit 34d DC Voltage / current control circuit 34e PWM circuit 34f ignition circuit 34g storage unit 34h DC voltage monitoring circuit 34i changeover switch 35 power storage device 37 DC bus 38 DC detection circuit

Claims (15)

An AC switch connected to the grid power,
AC bus connected to system power via the AC switch and supplying AC power to an AC load;
A DC bus to which the power storage device is connected;
Connected between the AC bus and the DC bus, performs a forward conversion operation from AC to DC according to a current control command, and an active filter operation that compensates for harmonic current and reactive power flowing through an AC load, and DC according to a voltage control command. A power converter that performs reverse conversion operation from AC to AC;
A basic voltage generation circuit that outputs a reference sine wave signal corresponding to the phase and AC voltage of the system power based on the phase information and voltage information of the system power;
An inverter control circuit that outputs a voltage control command for causing the power converter to perform an inverse conversion operation based on an output of the basic voltage generation circuit;
Based on the output of the basic voltage generation circuit, the voltage of the DC bus, the current of the DC bus, and the current of the AC bus, a current control command for causing the power converter to perform forward conversion operation and active filter operation is output. A charge / active filter control circuit;
Memory that stores preset lower limit preset values that determine preset lower limit voltage for steady state, upper limit preset values that define higher voltage limit than steady state, and lower limit preset value that defines lower voltage limit than steady state And
A changeover switch for switching a control command to be given to the power converter to either the output of the inverter control circuit or the output of the charge / active filter control circuit;
A DC voltage monitoring circuit that compares each preset value given from the storage unit with the voltage of the DC bus, controls the AC switch, and outputs a switching signal to the changeover switch;
With

(1) As a steady state operation,
When the DC voltage monitoring circuit detects that the DC voltage of the DC bus is within a range between an upper limit preset value and a steady lower limit preset value, the AC switch is turned off, and the changeover switch is set to the non-conductive state. Switch to the inverter control circuit side,
The inverter control circuit outputs a voltage control command for causing the power converter to perform an inverse conversion operation,
The power converter performs an inverse conversion operation,

(2) As an operation in state 1,
The DC voltage of the DC bus decreases due to an increase in AC load or continuation of the discharge state of the power storage device, and the DC voltage monitoring circuit confirms that the DC voltage of the DC bus is less than or less than a lower limit preset value. If detected, the AC switch is conducted, and the changeover switch is switched to the charge / active filter control circuit side,
The charge / active filter control circuit outputs a current control command for performing a forward conversion operation and an active filter operation,
The power converter performs a forward conversion operation and an active filter operation that compensates for harmonic current and reactive power flowing in an AC load,

(3) As an operation in state 2,
In the state 1, the power converter is charged by the forward conversion operation so that the power storage device is charged and the DC voltage of the DC bus rises, and the DC voltage monitoring circuit stores the DC voltage of the DC bus in the storage unit. When it is detected that the above-mentioned steady lower limit preset value is exceeded or exceeded, the AC switch is turned off, and the changeover switch is switched to the inverter control circuit side,
The inverter control circuit outputs a voltage control command for causing the power converter to perform an inverse conversion operation,
The power converter is a power feeding system that returns to an inverse conversion operation. An AC switch connected to the grid power,
An AC bus connected to the system power via the AC switch and supplying AC power to the first and second AC loads;
A first load switch for disconnecting or connecting the second AC load to the AC bus;
A DC bus to which the power storage device is connected;
Connected between the AC bus and the DC bus, performs a forward conversion operation from AC to DC according to a current control command, and an active filter operation that compensates for harmonic current and reactive power flowing through an AC load, and DC according to a voltage control command. A power converter that performs reverse conversion operation from AC to AC;
A basic voltage generation circuit that outputs a reference sine wave signal corresponding to the phase and AC voltage of the system power based on the phase information and voltage information of the system power;
An inverter control circuit that outputs a voltage control command for causing the power converter to perform an inverse conversion operation based on an output of the basic voltage generation circuit;
Based on the output of the basic voltage generation circuit, the voltage of the DC bus, the current of the DC bus, and the current of the AC bus, a current control command for causing the power converter to perform forward conversion operation and active filter operation is output. A charge / active filter control circuit;
A preset steady-state lower limit value that defines a preset lower-limit voltage in a steady state; an upper-limit preset value that defines a higher voltage limit than the steady state; a first threshold preset value that defines a lower-voltage threshold than the steady state; A storage unit for storing a lower limit preset value that defines a lower voltage limit than the threshold preset value;
A changeover switch for switching a control command to be given to the power converter to either the output of the inverter control circuit or the output of the charge / active filter control circuit;
A DC voltage monitoring circuit for comparing each preset value given from the storage unit with the voltage of the DC bus, controlling the AC switch, outputting a switching signal to the selector switch, and controlling the opening and closing of the first load switch When,
With

(1) As a steady state operation When the DC voltage monitoring circuit detects that the DC voltage of the DC bus is within the range between the upper limit preset value and the steady lower limit preset value, the AC switch is turned off. And switch the changeover switch to the inverter control circuit side,
The inverter control circuit outputs a voltage control command for causing the power converter to perform an inverse conversion operation,
The power converter performs an inverse conversion operation,

(2) As an operation in state 1,
The DC voltage of the DC bus decreases due to the increase in the first and / or second AC load or the continuation of the discharge of the power storage device, and the DC voltage monitoring circuit is configured such that the DC voltage of the DC bus is a first threshold preset value. When it is detected that the following is less than or less, an opening command signal is output to the first load switch, and the first load switch is opened,
When the DC voltage monitoring circuit detects that the DC voltage of the DC bus has further decreased to reach the lower limit preset value, the AC switch is turned on, and the changeover switch is turned to the charge / active filter control circuit side. Switching, outputting a current control command for causing the power converter to perform forward conversion operation and active filter operation,
The power converter performs a forward conversion operation and an active filter operation that compensates for harmonic current and reactive power flowing in an AC load,

(3) In state 2,
In the state 1, the power converter is charged by the forward conversion operation to charge the power storage device, the DC voltage of the DC bus rises, and the DC voltage monitoring circuit has a DC voltage of the DC bus that is equal to or greater than a first threshold preset value. Or, when it is detected that it has been exceeded, a closing command signal is output to the first load switch, and the first load switch is closed,
When the DC voltage monitoring circuit detects that the DC voltage of the DC bus is greater than or equal to the steady lower limit preset value, the DC voltage monitoring circuit turns off the AC switch and sets the changeover switch to the inverter control circuit side. switching,
The inverter control circuit outputs a voltage control command for causing the power converter to perform an inverse conversion operation,
The power converter is a power feeding system that returns to a reverse voltage conversion operation. The AC bus further supplies AC power to a third AC load,
A second load switch for disconnecting or connecting the third AC load with the AC bus;
The storage unit further stores a second threshold preset value that defines a voltage between the first threshold preset value and the lower limit preset value;
When the DC voltage monitoring circuit detects that the DC voltage of the DC bus is further lower than the first threshold preset value and is less than or less than the second threshold preset value, the DC voltage monitoring circuit is opened to the second load switch The power supply system according to claim 2, wherein a command signal is output, and the second load switch is opened.   When the DC voltage monitoring circuit detects that the DC voltage of the DC bus rises from the lower limit preset value and exceeds or exceeds the second threshold preset value, the DC voltage monitoring circuit sends a closing command signal to the second load switch. The power supply system according to claim 3, wherein the second load switch is output and the second load switch is closed. The storage unit has a priority table that stores the priority of power supply to each AC load,
The DC voltage monitoring circuit refers to the priority table, and corresponds to an AC load having a low priority when the DC voltage of the DC bus is lower than a steady state and reaches any one of the threshold preset values. Open the circuit first from the load switch,
The DC voltage monitoring circuit refers to the priority table, and when the DC voltage of the DC bus increases toward a steady state, when any of the threshold preset values is reached, an AC load having a high priority 5. The power feeding system according to claim 3, wherein the power supply system is closed from a load switch corresponding to.   3. The AC load having the highest priority is connected to the AC bus without passing through a load switch, or the threshold preset value is set lower than the lower limit preset. The electric power feeding system in any one of thru | or 5.   The power supply system according to claim 1 or 2, wherein a DC power generator is connected to the DC bus. The DC power generator has a detection unit that detects an output voltage to the DC bus, and an internal storage unit that stores an upper limit preset value that defines a limit of a higher voltage than a steady state stored in the storage unit. ,
When the direct current voltage of the direct current bus rises, the direct current generator detects that the output voltage to the direct current bus exceeds or exceeds the upper limit preset value stored in the internal storage unit by the detection unit. In the case, the power generation system is stopped, and the power feeding system according to claim 7 is stopped. The DC power generator has a detection unit that detects an output voltage to the DC bus, and an internal storage unit that stores a steady upper limit preset value that defines a preset steady state upper limit voltage,
When the DC power generator is stopped and the discharge state of the power storage device continues and the DC voltage of the DC bus decreases, the DC power generator detects that the output voltage to the DC bus is 9. The DC power generator is automatically restarted and returns to a steady state when it is detected that the steady upper limit preset value stored in the storage unit is less than or less than the preset value. Power supply system.   In a steady state, the DC power generation device supplies the DC power to the power converter and charges the power storage device by outputting the current by adjusting the generated power to the voltage of the DC bus. The power feeding system according to any one of claims 7 to 9.   11. The power feeding system according to claim 7, wherein starting and stopping of the DC power generation device is operated by a schedule operation function in accordance with load fluctuations of day, week, and month.   The power supply system according to claim 7, wherein a direct current load is connected in parallel with the direct current generator.   When an AC power generator is connected in parallel with the AC load, and the DC voltage monitoring circuit detects that the DC voltage of the DC bus exceeds or exceeds the upper limit preset value, a stop signal is sent to the AC generator. The power feeding system according to any one of claims 1 to 12, wherein the power feeding system outputs a start signal to the AC power generation device when the output is equal to or less than a steady upper limit preset value. An AC switch connected to the grid power,
AC bus connected to system power via the AC switch and supplying AC power to an AC load;
A DC bus to which the power storage device is connected;
Connected between the AC bus and the DC bus, performs a forward conversion operation from AC to DC according to a current control command, and an active filter operation that compensates for harmonic current and reactive power flowing through an AC load, and DC according to a voltage control command. A power converter that performs reverse conversion operation from AC to AC;
A basic voltage generation circuit that outputs a reference sine wave signal corresponding to the phase and AC voltage of the system power based on the phase information and voltage information of the system power;
An inverter control circuit that outputs a voltage control command for causing the power converter to perform an inverse conversion operation based on an output of the basic voltage generation circuit;
Based on the output of the basic voltage generation circuit, the voltage of the DC bus, the current of the DC bus, and the current of the AC bus, a current control command for causing the power converter to perform forward conversion operation and active filter operation is output. A charge / active filter control circuit;
Memory that stores preset lower limit preset values that determine preset lower limit voltage for steady state, upper limit preset values that define higher voltage limit than steady state, and lower limit preset value that defines lower voltage limit than steady state And
A changeover switch for switching a control command to be given to the power converter to either the output of the inverter control circuit or the output of the charge / active filter control circuit;
A DC voltage monitoring circuit that compares each preset value given from the storage unit with the voltage of the DC bus, controls the AC switch, and outputs a switching signal to the changeover switch;
A method for controlling a power supply system comprising:

(1) As a steady state operation,
When the DC voltage monitoring circuit detects that the DC voltage of the DC bus is within a range between an upper limit preset value and a steady lower limit preset value, the AC switch is turned off, and the changeover switch is set to the non-conductive state. Switch to the inverter control circuit side,
The inverter control circuit outputs a voltage control command for causing the power converter to perform an inverse conversion operation,
The power converter performs an inverse conversion operation,

(2) As an operation in state 1,
The DC voltage of the DC bus decreases due to an increase in AC load or continuation of the discharge state of the power storage device, and the DC voltage monitoring circuit confirms that the DC voltage of the DC bus is less than or less than a lower limit preset value. If detected, the AC switch is conducted, and the changeover switch is switched to the charge / active filter control circuit side,
The charge / active filter control circuit outputs a current control command for performing a forward conversion operation and an active filter operation,
The power converter performs a forward conversion operation and an active filter operation that compensates for harmonic current and reactive power flowing in an AC load,

(3) As an operation in state 2,
In the state 1, the power converter is charged by the forward conversion operation so that the power storage device is charged and the DC voltage of the DC bus rises, and the DC voltage monitoring circuit stores the DC voltage of the DC bus in the storage unit. When it is detected that the above-mentioned steady lower limit preset value is exceeded or exceeded, the AC switch is turned off, and the changeover switch is switched to the inverter control circuit side,
The inverter control circuit outputs a voltage control command for causing the power converter to perform an inverse conversion operation,
The power converter is a method for controlling the power feeding system that returns to the reverse conversion operation. An AC switch connected to the grid power,
An AC bus connected to the system power via the AC switch and supplying AC power to the first and second AC loads;
A first load switch for disconnecting or connecting the second AC load to the AC bus;
A DC bus to which the power storage device is connected;
Connected between the AC bus and the DC bus, performs a forward conversion operation from AC to DC according to a current control command, and an active filter operation that compensates for harmonic current and reactive power flowing through an AC load, and DC according to a voltage control command. A power converter that performs reverse conversion operation from AC to AC;
A basic voltage generation circuit that outputs a reference sine wave signal corresponding to the phase and AC voltage of the system power based on the phase information and voltage information of the system power;
An inverter control circuit that outputs a voltage control command for causing the power converter to perform an inverse conversion operation based on an output of the basic voltage generation circuit;
Based on the output of the basic voltage generation circuit, the voltage of the DC bus, the current of the DC bus, and the current of the AC bus, a current control command for causing the power converter to perform forward conversion operation and active filter operation is output. A charge / active filter control circuit;
A preset steady-state lower limit value that defines a preset lower-limit voltage in a steady state; an upper-limit preset value that defines a higher voltage limit than the steady state; a first threshold preset value that defines a lower-voltage threshold than the steady state; A storage unit for storing a lower limit preset value that defines a lower voltage limit than the threshold preset value;
A changeover switch for switching a control command to be given to the power converter to either the output of the inverter control circuit or the output of the charge / active filter control circuit;
A DC voltage monitoring circuit for comparing each preset value given from the storage unit with the voltage of the DC bus, controlling the AC switch, outputting a switching signal to the selector switch, and controlling the opening and closing of the first load switch When,
A method for controlling a power supply system comprising:

(1) As a steady state operation When the DC voltage monitoring circuit detects that the DC voltage of the DC bus is within the range between the upper limit preset value and the steady lower limit preset value, the AC switch is turned off. And switch the changeover switch to the inverter control circuit side,
The inverter control circuit outputs a voltage control command for causing the power converter to perform an inverse conversion operation,
The power converter performs an inverse conversion operation,

(2) As an operation in state 1,
The DC voltage of the DC bus decreases due to the increase in the first and / or second AC load or the continuation of the discharge of the power storage device, and the DC voltage monitoring circuit is configured such that the DC voltage of the DC bus is a first threshold preset value. When it is detected that the following is less than or less, an opening command signal is output to the first load switch, and the first load switch is opened,
When the DC voltage monitoring circuit detects that the DC voltage of the DC bus has further decreased to reach the lower limit preset value, the AC switch is turned on, and the changeover switch is turned to the charge / active filter control circuit side. Switching, outputting a current control command for causing the power converter to perform forward conversion operation and active filter operation,
The power converter performs a forward conversion operation and an active filter operation that compensates for harmonic current and reactive power flowing in an AC load,

(3) In state 2,
In the state 1, the power converter is charged by the forward conversion operation to charge the power storage device, the DC voltage of the DC bus rises, and the DC voltage monitoring circuit has a DC voltage of the DC bus that is equal to or greater than a first threshold preset value. Or, when it is detected that it has been exceeded, a closing command signal is output to the first load switch, and the first load switch is closed,
When the DC voltage monitoring circuit detects that the DC voltage of the DC bus is greater than or equal to the steady lower limit preset value, the DC voltage monitoring circuit turns off the AC switch and sets the changeover switch to the inverter control circuit side. switching,
The inverter control circuit outputs a voltage control command for causing the power converter to perform an inverse conversion operation,
The power converter is a method for controlling a power feeding system that returns to a reverse voltage conversion operation.

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