JP2020078134A - Power conversion device, power supply system, and method for controlling power conversion device - Google Patents

Abstract

To suppress mutual interference between isolated operation detection and voltage fluctuation suppression while avoiding stoppage of a power conversion device.SOLUTION: A power conversion device system-interconnected with a commercial power system is provided between an AC electric path connected to the commercial power system and a DC power supply, and comprises: a power conversion section for power-converting from DC to AC or vice versa; and a control section including a first calculation section for controlling switching operation of the power conversion section, and obtaining a first reactive power to be injected for isolated operation detection on the basis of AC voltage of the AC electric path, and a second calculation section for obtaining active power and a second reactive power for suppressing voltage fluctuation of the AC electric path. When the first calculation section attempts to inject the first reactive power which interferes with the second reactive power, the control section injects the first reactive power in a state in which a present value of the second reactive power is kept constant.SELECTED DRAWING: Figure 2

Description

  The present invention relates to a power converter, a power supply system, and a method for controlling the power converter.

  The power converter (power conditioner) is provided with an isolated operation detection function in order to detect a power failure and disconnect itself from the commercial power system when the commercial power system fails (from the Japan Electrical Manufacturers' Association JEM1498). ). On the other hand, when the voltage of the commercial power system is rising, it is also considered that the power conversion device suppresses the voltage increase by increasing the phase-advancing reactive power to the commercial power system from the viewpoint of itself. Since the islanding detection needs to be performed quickly, it is repeatedly performed in a short time. On the other hand, suppression of voltage rise is performed in a relatively long cycle. If the voltage increase is suppressed at the same time as the islanding operation is detected, both controls may interfere with each other to cause a malfunction. Therefore, it is also proposed to temporarily stop the power conversion device when such interference may occur (for example, refer to Patent Document 1).

JP, 2005-180123, A

  However, if the power conversion device is stopped even for a short time, the power generation efficiency will deteriorate. In view of such a problem, the present invention aims to suppress mutual interference between islanding detection and voltage fluctuation suppression while avoiding stoppage.

  The present disclosure includes the following inventions. However, the present invention is defined by the claims.

  A power conversion device according to one expression of the present invention is a power conversion device that is grid-connected to a commercial power system, and is provided between an AC electric path and a DC power supply that are connected to the commercial power system, and is DC to AC or its A first calculation for controlling a switching operation of the power conversion unit that performs reverse power conversion and the power conversion unit, and obtaining a first reactive power to be injected for islanding operation detection based on the AC voltage of the AC circuit. And a control unit including a second calculation unit that obtains active power and second reactive power for suppressing voltage fluctuations of the AC electric circuit, the first calculation unit interfering with the second reactive power. When injecting the first reactive power, the control unit injects the first reactive power while keeping the current value of the second reactive power constant.

  A power supply system according to one aspect of the present invention is a power supply system that includes a DC power supply and a power conversion device that is connected to the DC power supply and that is grid-connected to a commercial power system. A power conversion unit that is provided between the AC power line connected to the commercial power system and the DC power supply and that performs power conversion from DC to AC or vice versa, and controls the switching operation of the power conversion unit, and the AC power line. A first calculation unit that obtains a first reactive power to be injected for islanding operation detection based on the AC voltage A control unit including a calculation unit, wherein when the first calculation unit tries to inject the first reactive power that interferes with the second reactive power, the control unit controls the second reactive power. The first reactive power is injected in a state where the present value of is kept constant.

  Further, the control method of the power conversion device according to one aspect of the present invention includes a power conversion unit that is provided between the AC power line connected to the commercial power system and the DC power supply and performs power conversion from DC to AC or vice versa. A control method for a power converter, which controls a switching operation of the power converter and determines a first reactive power to be injected for islanding operation detection based on an AC voltage of the AC circuit. When the active power for suppressing the voltage fluctuation of the alternating current circuit and the second reactive power are obtained, and the first arithmetic unit attempts to inject the first reactive power that interferes with the second reactive power. , The first reactive power is injected with the current value of the second reactive power kept constant.

  According to the present invention, mutual interference between islanding detection and voltage fluctuation suppression can be suppressed while avoiding stoppage of the power converter.

FIG. 1 is a circuit diagram showing an example of a power converter and its input / output circuit. FIG. 2 is a control block diagram showing the control function of the control unit. FIG. 3 is a flowchart showing a first example of control for suppressing voltage fluctuation (rise). FIG. 4 is a flowchart showing a second example of the control for suppressing the voltage fluctuation (rise). FIG. 5 is a flowchart showing a third example of the control for suppressing the voltage fluctuation (fall). FIG. 6 is a flowchart showing a fourth example of control for suppressing voltage fluctuation (fall).

[Summary of Embodiment]
The gist of the embodiment of the present invention includes at least the following.

  (1) The present disclosure is a power conversion device that is grid-connected to a commercial power system, and is provided between an AC electric path and a DC power source that are connected to the commercial power system, and performs power conversion from DC to AC or vice versa. A power conversion unit that performs the switching operation of the power conversion unit, and a first calculation unit that determines a first reactive power to be injected for islanding operation detection based on the AC voltage of the AC electric circuit; A first calculation unit that interferes with the second reactive power, the control unit including a second calculation unit that obtains active power and second reactive power for suppressing voltage fluctuations in the AC circuit. When attempting to inject reactive power, the control unit is a power conversion device that injects the first reactive power while keeping the current value of the second reactive power constant.

  In such a power converter, if the first reactive power interferes with the second reactive power when an operation for islanding detection is attempted at the same time as the voltage fluctuation suppressing operation is being performed by the control unit. There is. Therefore, in such a case, the control unit holds the current value of the second reactive power constant and injects the first reactive power. As a result, the voltage fluctuation suppression function is suppressed, interference between the function and the isolated operation detection function is avoided, and isolated operation detection can be performed while the power conversion device is operating.

(2) Further, in the power conversion device of (1), one of the variation amounts of the variation amount of the first reactive power from the previous value and the variation amount of the second reactive power from the previous value is one. When the amount of change is in the advancing direction and the other amount of change is in the decelerating direction, the control unit may inject the first reactive power with the current value of the second reactive power kept constant. Good.
In such a case, the first reactive power interferes with the second reactive power. Therefore, in such a case, the control unit can hold the voltage fluctuation suppressing function in a constant state and perform islanding operation detection.

(3) Further, in the power conversion device of (1), when the amount of change in the first reactive power from the previous value is a value other than 0, the controller controls the current value of the second reactive power. May be held constant.
As a result, the control unit can hold the voltage fluctuation suppressing function in a constant state and perform islanding operation detection, not only when the first reactive power interferes with the second reactive power but also when it does not interfere. it can.

(4) In the power conversion device according to any one of (1) to (3), when the DC power supply supplies power to the AC circuit, the second reactive power is a phase-advancing reactive power, and When the first arithmetic unit attempts to inject the first reactive power that interferes with the second reactive power, the control unit holds the current value of the second reactive power constant and the active power. May be reduced.
With this, in the case of power conversion in which electric power is supplied from the DC power supply to the AC electric circuit, the effective power is reduced, so that the voltage increase of the AC electric circuit can be suppressed.

(5) Further, in the power conversion device according to any one of (1) to (3), when the charging power is supplied from the AC circuit to the DC power supply that is a storage battery, the second reactive power is delayed. When the first arithmetic unit attempts to inject the first reactive power that is reactive power and interferes with the second reactive power, the control unit keeps the current value of the second reactive power constant. You may make it hold | maintain and reduce the said active power.
As a result, in the case of power conversion in which charging power is supplied from the AC power line to the DC power supply, the active power is reduced, so that the voltage drop in the AC power line can be suppressed.

  (6) On the other hand, the present disclosure is a power supply system that includes a DC power supply and a power conversion device that is connected to the DC power supply and that is grid-connected to a commercial power system, wherein the power conversion device is the commercial power. A power conversion unit that is provided between the AC power line connected to the system and the DC power supply, performs a power conversion from DC to AC or vice versa, and controls the switching operation of the power conversion unit to obtain the AC voltage of the AC power line. Based on the first operation unit, a first operation unit that obtains a first reactive power to be injected for islanding operation detection, and a second operation unit that obtains an active power and a second reactive power for suppressing voltage fluctuations of the AC circuit are included. And a control unit, wherein when the first arithmetic unit tries to inject the first reactive power that interferes with the second reactive power, the control unit determines a current value of the second reactive power. It is a power supply system that injects the first reactive power in a state of being kept constant.

  In the power conversion device of such a power supply system, when an operation for islanding detection is attempted at the same time when the control unit is performing the voltage fluctuation suppression operation, the first reactive power becomes the second reactive power. May interfere. Therefore, in such a case, the control unit holds the current value of the second reactive power constant and injects the first reactive power. As a result, the voltage fluctuation suppression function is suppressed, interference between the function and the isolated operation detection function is avoided, and isolated operation detection can be performed while the power conversion device is operating.

  (7) Further, the present disclosure relates to control of a power conversion device including a power conversion unit that is provided between an AC electric path that is connected to a commercial power system and a DC power supply and that converts power from DC to AC or vice versa. A method for controlling a switching operation of the power conversion unit, determining a first reactive power to be injected for isolated operation detection based on an AC voltage of the AC electric circuit, and a voltage of the AC electric circuit. When the active power for fluctuation suppression and the second reactive power are obtained and the first arithmetic unit tries to inject the first reactive power that interferes with the second reactive power, It is a control method for a power conversion device, in which the first reactive power is injected with the current value kept constant.

  In such a control method of the power converter, when the first reactive power interferes with the second reactive power when the islanding detection operation is performed at the same time as the voltage fluctuation suppressing operation is performed. There is. Therefore, in such a case, the current value of the second reactive power is held constant and the first reactive power is injected. As a result, the voltage fluctuation suppression function is suppressed, interference between the function and the isolated operation detection function is avoided, and isolated operation detection can be performed while the power conversion device is operating.

[Details of Embodiment]
Hereinafter, a power conversion device and a control method thereof according to an embodiment of the present invention will be described with reference to the drawings.

<< Example of power converter configuration >>
FIG. 1 is a circuit diagram showing an example of a power conversion device 100 and its input / output circuit. First, the main circuit elements will be described. The power converter 100 includes a DC / DC converter 1 and an inverter 2 as the power converter 50. A DC power source 3 (for example, a storage battery, a solar power generation panel, etc.) is connected to the DC side (left side in the drawing) of the power conversion device 100. Further, the AC electric circuit 4 is connected to the AC side (right side in the figure) of the power conversion device 100.
The DC power supply 3 and the power conversion device 100 form a power supply system.

The two wires of the AC electric circuit 4 are usually single-phase three-wire voltage wires (U wires, W wires). In practice, an intermediate potential (0 V) neutral line (O line) is often created in the power conversion device 100 and connected to the single-phase 3-wire commercial power system 7 in three lines. Illustrated.
A customer's load 5 is connected to the AC circuit 4. Further, an interconnection relay 6 is provided on the AC electric line 4. The interconnection relay 6 is connected to the commercial power system 7.

  Note that, here, the simplest example in which the DC system from the DC power supply 3 to the DC / DC converter 1 is one system is shown, but the present invention is not limited to this, and there are a plurality of systems, and the DC bus 8 mutually connects them. The circuit configuration may be connected in parallel.

  A DC side capacitor 9 is provided between the DC power supply 3 and the DC / DC converter 1. The DC / DC converter 1 is configured by connecting a DC reactor 10, a low-side switching element Q1 and a high-side switching element Q2 as shown in the figure. Diodes d1 and d2 are connected in antiparallel to the switching elements Q1 and Q2, respectively. The DC / DC converter 1 can also operate as a step-up chopper or in the opposite direction as a step-down chopper.

  The illustrated switching elements Q1 and Q2 are IGBTs (Insulated Gate Bipolar Transistors). The same applies to the other switching elements Q3 to Q6. However, a switching element such as a MOS-FET (Metal-Oxide-Semiconductor Field-Effect Transistor) may be used instead of the IGBT.

  An intermediate capacitor 11 is provided between the two wires of the DC bus 8. The inverter 2 is connected to the DC bus 8. The inverter 2 includes switching elements Q3, Q4, Q5, Q6 that form a bridge circuit. Diodes d3, d4, d5 and d6 are connected in antiparallel to the switching elements Q3, Q4, Q5 and Q6, respectively. An AC reactor 12 and an AC side capacitor 13 are provided on the AC side of the inverter 2.

  Regarding the elements related to measurement and control, first, the voltage sensor 14 detects the voltage across the DC side capacitor 9 and sends a detection output to the control unit 20. The current sensor 15 detects a current flowing through the DC / DC converter 1 and sends a detection output to the control unit 20. The voltage sensor 16 detects a voltage between two lines of the DC bus 8 and sends a detection output to the control unit 20. The current sensor 17 detects a current flowing through the AC reactor 12 and sends a detection output to the control unit 20. The voltage sensor 18 detects a voltage between two wires of the AC electric circuit 4 and sends a detection output to the control unit 20.

The control unit 20 controls the switching elements Q1 to Q6 based on the detection output from each sensor. Further, the control unit 20 controls opening / closing of the interconnection relay 6. During the normal operation of the power converter 100, the interconnection relay 6 is closed. When it is detected that the commercial power system 7 has a power failure and the power conversion device 100 is in the independent operation state, the control unit 20 opens the interconnection relay 6.
The control unit 20 includes, for example, a computer, and realizes a necessary control function when the computer executes software (computer program). The software is stored in the storage device (not shown) of the control unit 20.

  The power conversion device 100 is bidirectional and performs power conversion from direct current to alternating current, and when the direct current power supply 3 is a storage battery, performs power conversion from alternating current to direct current to charge the storage battery. You can also

<< Example of normal control >>
During normal operation, as described above, the control unit 20 can perform the grid interconnection operation of the power conversion device 100 by controlling the switching elements Q1 to Q6 based on the detection output from each sensor.

  When the power conversion device 100 is provided between the commercial power system 7 and the DC power supply 3 having a voltage lower than the peak value of the absolute value of the AC voltage, an example of a preferable known control is an AC half cycle. In the inside, a period in which one of the DC / DC converter 1 and the inverter 2 is caused to perform a switching operation and the other is made to rest is caused depending on the phase of the alternating current. Then, the control unit 20 is based on the voltage of the AC power, the voltage change due to the current flowing through the AC reactor 12 and the impedance of the AC reactor 12, the reactive current flowing through the intermediate capacitor 11 and the AC side capacitor 13, and the voltage of the DC power. Then, the current command value of the DC / DC converter 1 is set to be synchronized with the current of the AC power. Further, as the voltage of the AC power, it is possible to use a voltage obtained by supplementing the phase of the fundamental wave extracted based on the detected value of the AC voltage of the commercial power system 7 in consideration of the delay of the detection and control system.

  In such a power converter 100, the control unit 20 causes a period in which one of the DC / DC converter 1 and the inverter 2 performs a switching operation in the AC half cycle in accordance with the phase of the AC, and the other pauses. A "minimum switching conversion method" of causing can be executed. In order to realize this system with high conversion efficiency, the voltage of AC power, the current flowing through the AC reactor 12, and the voltage change due to the impedance of the AC reactor 12, the reactive current flowing through the intermediate capacitor 11 and the AC side capacitor 13, and the DC power, respectively. Based on the voltage of, the control unit 20 sets the current command value of the DC / DC converter 1 so as to be synchronized with the current of the AC power.

  Then, as the voltage of the AC power, the phase is supplemented to the fundamental wave extracted based on the AC voltage detection value (AC voltage detected by the voltage sensor 18) of the commercial power system 7 in consideration of the delay of the detection and control system. By using the voltage, it is possible to suppress the control delay with respect to the voltage phase, eliminate the influence of the disturbance of the system voltage of the commercial power system 7, and obtain a stable AC current with less distortion.

Specifically, the output current command value to the load 5 is Ia *, the capacitance of the AC side capacitor 13 is Ca, the AC voltage of the AC circuit 4 is Va, the voltage of the DC power supply 3 side is _VDC , and the Laplace operator. Be s. In this case, the control unit 20 sets the AC output current command value Iinv * that should flow to the current sensor 17,
Iinv * = Ia * + s CaVa (1)
Set to.

Furthermore, when the impedance of the AC reactor 12 is set to Za, the control unit 20 sets the AC output voltage command value Vinv * at the output end of the inverter 2 (interconnection point between the inverter 2 and the AC reactor 12) to:
Vinv * = Va + ZaIinv * (2)
Set to.

Further, the control unit 20 sets the larger one of the voltage _VDC and the absolute value of the AC output voltage command value Vinv * to the output voltage command value Vo * of the DC / DC converter 1, and sets the intermediate capacitor 11 to the output voltage command value Vo *. When the capacitance is C, the current command value Iin * of the DC / DC converter 1 is
Iin * = {(Iinv * × Vinv *) + (s C Vo *) × Vo *} / V _DC
... (3)
Set to. Then, the AC voltage Va has an effective value of _{Va_rms} and a phase of a timing for instructing a switching operation is ωt,
Va = √2 _{Va_rms} × sin (ωt) (4)
Can be

  According to the control as described above, the current command value Iin * of the DC / DC converter 1 is the voltage of the AC power, the voltage change due to the current flowing through the AC reactor 12 and the impedance of the AC reactor 12, the intermediate capacitor 11 and the AC side capacitor. It reflects all of the reactive current flowing through 13 and the voltage of DC power. Therefore, even when the voltage of the DC power supply 3 or the AC output current changes, it is possible to always output electric power synchronized with the AC output current.

  By such control of the minimum switching conversion method, the DC / DC converter 1 and the inverter 2 can perform DC / AC conversion with the minimum number of times of high frequency switching. As a result, the switching loss of the semiconductor switching element and the iron loss of the AC and DC reactors are significantly reduced, and high conversion efficiency can be obtained. Furthermore, by setting the system voltage Va in this way, a low-distortion alternating current can be obtained.

<< Functions of control unit including islanding operation detection and voltage rise suppression >>
FIG. 2 is a control block diagram showing control functions in the control unit 20. In the figure, the control unit 20 takes in the detected current value of the current flowing through the AC reactor 12 (FIG. 1) from the current sensor 17 and the detected voltage value of the AC circuit 4 from the voltage sensor 18, respectively. Basically, the control unit 20 performs active power calculation according to the operation mode based on the control target (B1) according to the operation mode (B2), and determines the current command value (B3). Based on this current command value, the current control unit (B4) controls the switching operation of the power conversion unit 50.

  Based on the voltage detection value detected by the voltage sensor 18, the control unit 20 calculates the system frequency (B5). The control unit 20 executes active detection (B7) and passive detection (B8) in the islanding operation detection unit (B6) based on the system frequency calculated. If the deviation of the frequency by a predetermined value or more is confirmed, the islanding operation is detected.

  Further, the control unit 20 performs a moving average calculation (B9), a frequency deviation calculation (B10), and a frequency feedback function reactive power calculation (B11) based on the system frequency (B5) obtained by the calculation. The function as the frequency feedback section (B12) is performed by the moving average calculation (B9), the frequency deviation calculation (B10), and the frequency feedback function reactive power calculation (B11).

  On the other hand, based on the detected voltage value, the control unit 20 calculates the fundamental wave voltage (B13) and the harmonic voltage (B14), determines the reactive power step injection generation condition (B15), and disables the step injection function. Electric power calculation (B16) is performed. These processes are processes as a step injection part (B17).

  The control unit 20 performs the reactive power injection calculation for islanding operation detection based on the calculation result of the frequency feedback unit (B12) and the calculation result of the step injection unit (B17) (B18 (first calculation unit)). On the other hand, the control unit 20 calculates the active power and the reactive power for suppressing the voltage rise based on the detected voltage value (B19 (second calculation unit)). The reactive power for detecting the isolated operation and the reactive power for suppressing the voltage rise are added together in the reactive power injection calculation (B20). The active power for suppressing the voltage rise is a target of summation in the active power calculation (B2) according to the operation mode.

  Further, the control unit 20 performs the current control phase difference synchronization process (B21) based on the detected voltage value, and provides the processed signal to the current control unit B4. The current detection signal is also provided to the current controller B4.

  Here, it should be noted that the reactive power injection calculation (B18) for islanding operation detection and the active power / reactive power calculation (B19) for voltage rise suppression are connected in terms of calculation. Specifically, the information about the reactive power for detecting the isolated operation (B18) is notified to the reactive power calculation for suppressing the voltage increase (B19), and when they interfere with each other, the reactive power for suppressing the voltage increase is the current value. Is kept constant. However, active power for suppressing voltage rise is not subject to such a limitation.

《Others》
In the above description, reverse power flow from the power conversion device 100 to the commercial power system 7 is assumed, but conversely, when the DC power supply 3 is a storage battery, the power conversion device 100 is switched from the commercial power system 7 to the commercial power system 7. The same idea can be applied to the case of forward power flow in which the DC power supply 3 is charged after that. However, in the case of forward power flow, the voltage decrease is suppressed instead of the voltage increase suppression. Speaking of rising and falling, it means suppressing voltage fluctuations.

<< Example of control for suppressing voltage fluctuation >>
(Reverse power flow from the power converter to the commercial power system (when considering the direction of reactive power))
<In the case of control pattern 1>
For example, the reactive power for islanding detection is considered as the first reactive power, and the reactive power for suppressing the voltage rise is considered as the second reactive power. In this case, in the calculation process, with respect to the change amount of the first reactive power from the previous value and the change amount of the second reactive power from the previous value, one change amount is in the forward direction and the other change is If the quantity is late, the first reactive power interferes with the second reactive power. Therefore, the control unit 20 injects the first reactive power while keeping the current value of the second reactive power constant. As a result, the control unit 20 can hold the voltage fluctuation suppressing function in a constant state and perform islanding operation detection.

FIG. 3 is a flowchart showing a first example of control for suppressing voltage fluctuation (rise). In the figure, the control unit 20 determines whether the system voltage is equal to or higher than a threshold value based on the detection output of the voltage sensor 18 (FIG. 1) (step S101). When the system voltage is equal to or higher than the threshold value, control for lowering the voltage is necessary, and when it is not higher than the threshold value, control for lowering the voltage is not necessary.
When the system voltage is equal to or higher than the threshold value, the control unit 20 determines whether the power factor is larger than the lower limit value based on the detection outputs of the voltage sensor 18 (FIG. 2) and the current sensor 17 (FIG. 2) ( Step S102).

  When the power factor is larger than the lower limit value, the control unit 20 determines whether or not the delayed reactive power for islanding operation detection is injected at this timing (step S103). If the injection is not performed, there is no risk of interference with the islanding operation detection, and therefore the control unit 20 increases the active phase reactive power without changing the active power (step S107). On the other hand, when the power factor is equal to or lower than the lower limit value in step S102, the reactive power cannot be injected any more, so the active power is reduced and the advanced reactive power is held at the current value (step S108). Further, when the delayed reactive power is injected in step S103, there is a risk of interfering with the islanding operation detection, so the active power is reduced and the advanced reactive power is held at the current value (step S108).

  On the other hand, when the system voltage is lower than the threshold value in step S101, it is not necessary to reduce the voltage. Therefore, the control unit 20 determines whether the active power is suppressed (step S104). If not suppressed, the control unit 20 determines whether or not the advanced reactive power is being injected (step S105). If the injection is in progress, the control unit 20 determines whether or not to advance the advanced reactive power for islanding detection (step S106). When not injecting, the control unit 20 reduces the active phase reactive power without changing the active power (step S110). On the other hand, when the advance reactive power is not being injected in step S105, there is no need to do anything, so the active power and the advance reactive power are held (step S109). Further, when injecting the advance reactive power for islanding detection, the control unit 20 holds the active power and the advanced reactive power (step S109).

  Further, when the active power is suppressed in step S104, the active power is preferentially returned, so the control unit 20 increases the active power and holds the phase advance reactive power at the current value (step S111). ..

(Reverse power flow from the power converter to the commercial power system (when not considering the direction of reactive power))
<In the case of control pattern 2>
As described above, assuming that the reactive power for islanding detection is the first reactive power and the reactive power for suppressing the voltage rise is the second reactive power, and the direction of the reactive power is not considered, the control unit 20 When the amount of change in the first reactive power from the previous value is a value other than 0, the current value of the second reactive power may be held constant. As a result, the control unit 20 holds the voltage fluctuation suppressing function in a constant state and performs islanding operation detection, not only when the first reactive power interferes with the second reactive power but also when it does not interfere. You can In other words, the control is slightly rougher than the control pattern 1.

FIG. 4 is a flowchart showing a second example of control for suppressing voltage fluctuation (rise). In the figure, the control unit 20 determines whether or not the system voltage is equal to or higher than a threshold value based on the detection output of the voltage sensor 18 (FIG. 1) (step S201). When the system voltage is equal to or higher than the threshold value, control for lowering the voltage is necessary, and when it is not higher than the threshold value, control for lowering the voltage is not necessary.
When the system voltage is equal to or higher than the threshold value, the control unit 20 determines whether the power factor is larger than the lower limit value based on the detection outputs of the voltage sensor 18 (FIG. 2) and the current sensor 17 (FIG. 2) ( Step S202).

  When the power factor is larger than the lower limit, the control unit 20 determines at this timing whether or not to inject the advance or delay reactive power for islanding detection (step S203). If the injection is not performed, there is no risk of interference with the islanding operation detection, so the control unit 20 increases the active phase reactive power without changing the active power (step S207). On the other hand, when the power factor is less than or equal to the lower limit value in step S202, the reactive power cannot be injected any more, so the active power is reduced and the advanced reactive power is held at the current value (step S208). Further, when the advance or delay reactive power is injected in step S203, there is a risk of interfering with the islanding operation detection, so the active power is reduced and the advanced reactive power is held at the current value (step S208).

  On the other hand, when the system voltage is lower than the threshold value in step S201, it is not necessary to reduce the voltage. Therefore, the control unit 20 determines whether the active power is suppressed (step S204). If not suppressed, the control unit 20 determines whether or not the advanced reactive power is being injected (step S205). If injecting, the control unit 20 determines whether to inject the advanced or delayed reactive power for islanding detection (step S206). When not injecting, the control unit 20 reduces the advanced reactive power without changing the active power (step S210). On the other hand, when the advanced reactive power is not being injected in step S205, nothing needs to be done, so the active power and the advanced reactive power are held (step S209). Further, when injecting the advance or delay reactive power for islanding detection, the control unit 20 holds the active power and the advance reactive power (step S209).

  Further, when the active power is suppressed in step S204, the active power is desired to be returned preferentially, so the control unit 20 increases the active power and holds the advance reactive power at the current value (step S211). ..

(Forward flow from commercial power system to power converter (when considering the direction of reactive power))
<In the case of control pattern 1>
FIG. 5 is a flowchart showing a third example of the control for suppressing the voltage fluctuation (fall). In the figure, the control unit 20 determines whether or not the system voltage is less than or equal to a threshold value based on the detection output of the voltage sensor 18 (FIG. 1) (step S301). When the system voltage is below the threshold, it is necessary to perform the control to increase the voltage, and when it is not below the threshold, it is not necessary to perform the control to increase the voltage.
When the system voltage is equal to or lower than the threshold value, the control unit 20 determines whether the power factor is larger than the lower limit value based on the detection outputs of the voltage sensor 18 (FIG. 2) and the current sensor 17 (FIG. 2) ( Step S302).

  When the power factor is larger than the lower limit value, the control unit 20 determines at this timing whether to inject the advanced reactive power for islanding operation detection (step S303). If the injection is not performed, there is no risk of interfering with the islanding operation detection, so the control unit 20 increases the lagging reactive power without changing the active power for charging (step S307). On the other hand, when the power factor is less than or equal to the lower limit value in step S302, the reactive power cannot be injected any more, so the active power for charging is reduced and the delayed reactive power is held at the current value (step S308). Further, when the reactive power is injected in step S303, it may interfere with the islanding detection, so the active power for charging is reduced and the lagging reactive power is held at the current value (step S306).

  On the other hand, when the system voltage is higher than the threshold value in step S301, it is not necessary to raise the voltage. Therefore, the control unit 20 determines whether the effective power for charging is suppressed (step S304). If not suppressed, the control unit 20 determines whether or not the delayed reactive power is being injected (step S305). If injecting, the control unit 20 determines whether or not to inject the delayed reactive power for islanding detection (step S306). When not injecting, the control unit 20 reduces the lagging reactive power while keeping the charging active power as it is (step S310). On the other hand, when the lagging reactive power is not being injected in step S305, nothing needs to be done, and thus the charging active power and the lagging reactive power are held (step S309). Further, when injecting the delayed reactive power for islanding detection, the control unit 20 holds the active power and the delayed reactive power of the charging (step S309).

  Furthermore, when the active power for charging is suppressed in step S304, the active power is preferentially returned, so the control unit 20 increases the active power for charging and holds the lagging reactive power at the current value. (Step S311).

(Forward flow from commercial power system to power converter (when the direction of reactive power is not considered))
<In the case of control pattern 2>
FIG. 6 is a flowchart showing a fourth example of control for suppressing voltage fluctuation (fall). In the figure, the control unit 20 determines whether or not the system voltage is less than or equal to a threshold value based on the detection output of the voltage sensor 18 (FIG. 1) (step S401). When the system voltage is below the threshold, it is necessary to perform the control to increase the voltage, and when it is not below the threshold, it is not necessary to perform the control to increase the voltage.
When the system voltage is equal to or lower than the threshold value, the control unit 20 determines whether the power factor is larger than the lower limit value based on the detection outputs of the voltage sensor 18 (FIG. 2) and the current sensor 17 (FIG. 2) ( Step S402).

  When the power factor is larger than the lower limit value, the control unit 20 determines at this timing whether to inject the advance or delay reactive power for islanding detection (step S403). If not injected, there is no risk of interference with islanding detection, so the control unit 20 increases the lagging reactive power without changing the active power for charging (step S407). On the other hand, when the power factor is less than or equal to the lower limit value in step S402, the reactive power cannot be injected any more, so the active power for charging is reduced and the lagging reactive power is held at the current value (step S406). Further, when the advanced or delayed reactive power is injected in step S403, there is a risk of interfering with the islanding operation detection. Therefore, the active power for charging is reduced and the delayed reactive power is held at the current value (step S408). ..

  On the other hand, when the system voltage is higher than the threshold value in step S401, it is not necessary to reduce the voltage. Therefore, the control unit 20 determines whether or not the active power for charging is suppressed (step S404). If not suppressed, the control unit 20 determines whether or not the delayed reactive power is being injected (step S405). If the injection is being performed, the control unit 20 determines whether to inject the advance or delay reactive power for islanding detection (step S406). When not injecting, the control unit 20 reduces the lagging reactive power without changing the active power of charging (step S410). On the other hand, when the delay reactive power is not being injected in step S405, nothing needs to be done, so the control unit 20 holds the active power for charging and the delay reactive power (step S409). Further, when injecting the advance or delay reactive power for islanding operation detection, the control unit 20 holds the active power and the lag reactive power for charging (step S409).

  Furthermore, when the reactive power is suppressed in step S404, the active power is desired to be returned preferentially, so the control unit 20 increases the active power for charging and holds the delayed reactive power at the current value (step S404). S411).

<< Summary of Disclosure >>
The control unit 20 of the power conversion device 100 according to the present disclosure controls the switching operation of the power conversion unit 50 and obtains the first reactive power to be injected for islanding operation detection, based on the AC voltage of the AC circuit 4. It includes a first calculation unit (B18) and a second calculation unit (B19) for obtaining active power and second reactive power for suppressing voltage fluctuations of the AC circuit 4, and the first calculation unit (B18) is the second When trying to inject the first reactive power that interferes with the reactive power, the control unit 20 injects the first reactive power while keeping the current value of the second reactive power constant.

  In such a power conversion device, when the control unit 20 is performing the voltage fluctuation suppressing operation and at the same time attempts to perform the islanding operation detection operation, the first reactive power interferes with the second reactive power. There are cases. Therefore, in such a case, the control unit 20 holds the current value of the second reactive power constant and injects the first reactive power. As a result, the voltage fluctuation suppression function is suppressed, interference between the function and the islanding operation detection function is avoided, and islanding operation can be detected while the power conversion device 100 is operating.

  Specifically, for example, regarding the amount of change in the first reactive power from the previous value and the amount of change in the second reactive power from the previous value, one change amount is in the forward direction and the other change amount is Is delayed, the first reactive power interferes with the second reactive power. Therefore, the control unit 20 injects the first reactive power while keeping the current value of the second reactive power constant. As a result, the control unit 20 can hold the voltage fluctuation suppressing function in a constant state and perform islanding operation detection.

  Further, the control unit 20 may hold the current value of the second reactive power constant when the change amount of the first reactive power from the previous value is a value other than 0. As a result, the control unit 20 holds the voltage fluctuation suppressing function in a constant state and performs islanding operation detection, not only when the first reactive power interferes with the second reactive power but also when it does not interfere. You can

  The present disclosure is also a power supply system including the DC power supply 3 and the power conversion device 100. Further, the present disclosure is a control method for the power converter 100, which controls the switching operation of the power converter 50 and should be injected for islanding operation detection based on the AC voltage of the AC circuit 4. The first reactive power is calculated, the active power for suppressing the voltage fluctuation of the AC circuit 4 and the second reactive power are calculated, and the first arithmetic unit injects the first reactive power that interferes with the second reactive power. When attempting to do so, the first reactive power is injected while keeping the current value of the second reactive power constant.

  According to such a control method for a power converter, when an operation for islanding detection is attempted at the same time as the operation for suppressing voltage fluctuations, the first reactive power interferes with the second reactive power. However, in such a case, the current value of the second reactive power is kept constant and the first reactive power is injected. As a result, the voltage fluctuation suppression function is suppressed, interference between the function and the islanding operation detection function is avoided, and islanding operation can be detected while the power conversion device 100 is operating.

《Supplementary note》
It should be understood that the embodiments disclosed this time are exemplifications in all points and not restrictive. The scope of the present invention is defined by the claims, and is intended to include meanings equivalent to the claims and all modifications within the scope.

DESCRIPTION OF SYMBOLS 1 DC / DC converter 2 Inverter 3 DC power supply 4 AC electric line 5 Load 6 Interconnection relay 7 Commercial power system 8 DC bus 9 DC side capacitor 10 DC reactor 11 Intermediate capacitor 12 AC reactor 13 AC side capacitor 14 Voltage sensor 15 Current sensor 16 Voltage sensor 17 Current sensor 18 Voltage sensor 20 Control section 50 Power conversion section 100 Power conditioner d1, d2, d3, d4, d5, d6 Diodes Q1, Q2, Q3, Q4, Q5, Q6 Switching element

Claims (7)

A power conversion device that is grid-connected to a commercial power system,
A power conversion unit that is provided between the AC power line connected to the commercial power system and the DC power supply, and that performs power conversion from DC to AC or vice versa,
A first operation unit that controls a switching operation of the power conversion unit and obtains a first reactive power to be injected for islanding operation detection based on the AC voltage of the AC circuit, and a voltage fluctuation suppression of the AC circuit. A control unit including a second calculation unit for obtaining active power and second reactive power for
Equipped with
When the first computing unit attempts to inject the first reactive power that interferes with the second reactive power, the control unit maintains the current value of the second reactive power at a constant value. A power converter that injects first reactive power.   Regarding the amount of change in the first reactive power from the previous value and the amount of change in the second reactive power from the previous value, one change amount is in the forward direction and the other change amount is in the delay direction. In this case, the control unit is the power conversion device according to claim 1, wherein the first reactive power is injected while the current value of the second reactive power is kept constant.   The power conversion according to claim 1, wherein the control unit holds the current value of the second reactive power constant when the change amount of the first reactive power from the previous value is a value other than 0. apparatus. In the case of supplying power from the DC power supply to the AC circuit, the second reactive power is a phase-advancing reactive power,
When the first computing unit attempts to inject the first reactive power that interferes with the second reactive power, the control unit maintains the current value of the second reactive power at a constant value and the effective value. The power conversion device according to any one of claims 1 to 3, which reduces power. In the case of supplying charging power from the AC circuit to the DC power supply that is a storage battery, the second reactive power is lagging reactive power,
When the first computing unit attempts to inject the first reactive power that interferes with the second reactive power, the control unit maintains the current value of the second reactive power at a constant value and the effective value. The power conversion device according to any one of claims 1 to 3, which reduces power. DC power supply,
A power supply system that is connected to the DC power supply and has a power conversion device that is grid-connected to a commercial power system, the power conversion device comprising:
A power conversion unit that is provided between the AC power line connected to the commercial power system and the DC power supply, and that performs power conversion from DC to AC or vice versa,
A first operation unit that controls a switching operation of the power conversion unit and obtains a first reactive power to be injected for islanding operation detection based on the AC voltage of the AC circuit, and a voltage fluctuation suppression of the AC circuit. A control unit including a second calculation unit for obtaining active power and second reactive power for
Equipped with
When the first computing unit attempts to inject the first reactive power that interferes with the second reactive power, the control unit maintains the current value of the second reactive power at a constant value. A power supply system injecting a first reactive power. A control method for a power conversion device having a power conversion unit that is provided between an alternating-current circuit connected to a commercial power system and a direct-current power supply and that converts power from direct current to alternating current or vice versa,
While controlling the switching operation of the power conversion unit, the first reactive power to be injected for islanding operation detection is obtained based on the AC voltage of the AC electric circuit, and is effective for suppressing voltage fluctuations of the AC electric circuit. Find the power and the second reactive power,
When the first computing unit attempts to inject the first reactive power that interferes with the second reactive power, the first reactive power is maintained with the current value of the second reactive power kept constant. Inject,
Power converter control method.

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