JP2017085719A - System interconnection inverter device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide high-quality power from a DC power supply to a power system by a system interconnection inverter device incorporating a transformer.SOLUTION: A system interconnection inverter device comprises: (1) an inverter circuit connected to a direct current power supply; (2) a transformer connected to an output side of the inverter circuit; (3) a series circuit of a current limiting resistor and a first switch, connected between an output side of the transformer and a power system; (4) a second switch connected in parallel to the series circuit or the current limiting resistor; and (5) a control circuit for controlling an inverter/gate signal to be given to the inverter circuit to a stop state for a certain period after turning on the second switch and then switching and controlling the inverter/gate signal to be given to the inverter circuit again.SELECTED DRAWING: Figure 5

Description

  The present invention relates to a grid interconnection inverter device.

  Japanese Patent Laying-Open No. 2011-035956 (hereinafter referred to as “Patent Document 1”) describes a grid-connected inverter device that connects a DC power source to a power system. In FIG. 1, the apparatus structure of the grid connection inverter apparatus in patent document 1 is shown. The grid-connected inverter device includes an inverter circuit 2 connected to a DC power source 1 made of a solar battery, a filter composed of an inductor 4 and a capacitor 5, and a switching circuit SW connected to the power system 9 on the output side. It is configured. Here, the switch circuit SW is configured by a series circuit of a current limiting resistor 7 and a first switch 8 and a second switch 6 connected in parallel to the series circuit.

  This grid-connected inverter device is activated by the procedure shown in FIG. First, the control circuit 10 controls the first switch 8 to be on (SP1). Next, the control circuit 10 performs switching control of the inverter gate signal (SP2), and then controls the second switch 6 to the on state and the first switch 8 to the off state (SP3, SP4). That is, the control circuit 10 controls the output current of the inverter circuit 2 (starting period) from when the first switch 8 is controlled to the on state until the second switch 6 is controlled to the on state (starting start period). By controlling the operation of the inverter circuit 2 so that the inverter current I1) becomes 0 (zero), the inrush current from the power system 9 to the filter capacitor 5 is prevented.

JP 2011-035956 A (Patent No. 4913849)

The control method described above can also be applied to a grid-connected inverter device configured to connect the output of the inverter circuit 2 to the power system 9 via a transformer. An example of the apparatus is shown in FIG. In this case, a large magnetizing inrush current may flow at the timing when the second switch 6 is controlled to be turned on. However, in the grid-connected inverter device incorporating the transformer 12, the magnetizing inrush current flowing into the transformer 12 may not converge and the remaining biased magnetic state may continue. This continuation of the biased state distorts the waveform of the output current I ₀ (see FIG. 4E)) and degrades the quality of the power supplied to the power system 9.

  In order to solve such technical problems, the present inventors have (1) an inverter circuit connected to a DC power supply, (2) a transformer connected to the output side of the inverter circuit, and (3) the above-mentioned A series circuit of a current limiting resistor and a first switch connected between the output side of the transformer and the power system; and (4) a second connected in parallel to the series circuit or the current limiting resistor. And (5) an inverter gate signal supplied to the inverter circuit after the inverter gate signal supplied to the inverter circuit is controlled to be in a stopped state for a certain period after the second switch is turned on. A grid-connected inverter device having a control circuit that performs switching control again is proposed.

  According to the present invention, even when a large magnetizing inrush current flows into the transformer when the second switch is turned on, the biased state of the transformer is surely eliminated, and high-quality power is supplied to the power system. be able to.

The figure explaining the structure of a conventional apparatus. The flowchart explaining the control procedure in a conventional apparatus. The figure which shows the structure of the grid connection inverter apparatus incorporating a transformer. FIG. 4 is a diagram for explaining a relationship between a control signal and an output waveform when the apparatus shown in FIG. 3 is operated according to the control procedure shown in FIG. 2. The flowchart explaining the control procedure which concerns on an Example. FIG. 6 is a diagram for explaining the relationship between a control signal and an output waveform when the apparatus shown in FIG. 3 is operated according to the control procedure shown in FIG. 5.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings. The embodiment of the present invention is not limited to the examples described later, and various modifications are possible within the scope of the technical idea.

  First, the configuration of the grid interconnection inverter device shown in FIG. 3 will be described. In FIG. 3, parts corresponding to those in FIG. The grid interconnection inverter device is connected between the DC power source 1 and the power system 9. In the case of the present embodiment, the DC power source 1 is a photovoltaic power generation facility (solar cell). However, the DC power supply 1 may be another DC power supply that extracts DC power from a renewable energy source.

  DC power supplied from the DC power source 1 is converted into AC power by the inverter circuit 2. The inverter circuit 2 is a known inverter circuit having a configuration in which two transistor series circuits each having a pair of transistors connected in series are connected in parallel, and an intermediate point of each transistor series circuit is an AC output terminal. . The operations of the plurality of transistors included in the two transistor series circuits are controlled by an inverter gate signal G1 provided from the control circuit 10 to the inverter circuit 2. For example, when the inverter gate signal G1 is in a stopped state, all the transistors are controlled to be OFF. On the other hand, when the inverter gate signal G1 is in a switching state, each transistor is ON / OFF controlled by an individual gate signal. If normal, the DC power of the DC power supply 1 is converted into AC power by the inverter circuit 2 and supplied to the power system 9 as it is. In the case of the present embodiment, a commercial power system is assumed as the power system 9, but it is not necessarily limited to the commercial power system.

  A first current detector 3 is disposed on the output side of the inverter circuit 2. The first current detector 3 is used to detect the inverter current I1 output from the inverter circuit 2, and outputs the detection result to the control circuit 10. In FIG. 3, the symbol I1 is also used for the meaning of the detection signal. On the output side of the first current detector 3, an inductor 4, a transformer 12, and a filter capacitor 5 are arranged in order. The inductor 4 is connected in series with the output of the inverter circuit 2. The inverter current I1 flows through the inductor 4 to the primary coil of the transformer 12. A filter capacitor 5 is connected to a power line connecting the output side (secondary coil side) of the transformer 12 and the power system 9. The other end of the filter capacitor 5 is connected to another phase power line.

The second current detector 11 is connected in series to the power line described above. The second current detector 11 is used to detect a current (output current I ₀ ) output to the power system 9 and outputs a detection result to the control circuit 10. In FIG. 3, the symbol I ₀ is also used for the meaning of the detection signal. An opening / closing circuit SW is disposed between the second current detector 11 and the power system 9. The switch circuit SW includes a series circuit of a current limiting resistor 7 and a first switch 8 and a second switch 6 connected in parallel to the series circuit.

  Opening and closing of the first switch 8 is controlled by a control signal A2 (switch 8 control signal A2) given from the control circuit 10, and opening and closing of the second switch 6 is controlled by a control signal A1 given from the control circuit 10. It is controlled by (switch 6 control signal A1). The first switch 8 and the second switch 6 are both mechanical switches. In the case of the present embodiment, the voltage appearing on the power line between the second current detector 11 and the switching circuit SW is input to the control circuit 10 as the inverter voltage V1.

  5 and 6 show the relationship between the control timing by the control circuit 10 and the output waveform. After the inverter circuit 2 is activated, the control circuit 10 first controls the first switch 8 to be on (SP11). At this time, a voltage obtained by reducing the system voltage (voltage reduced by the current limiting resistor 7) appears as the inverter voltage V1. Next, the control circuit 10 performs switching control of the inverter gate signal G1 (SP12). As each transistor of the inverter circuit 2 is turned ON / OFF, a voltage having the same magnitude as the system voltage appears in the inverter voltage V1.

The inverter current I1 immediately after the inverter gate signal G1 is subjected to switching control is 0 (zero) A. For this reason, the output current I ₀ is also 0 (zero) A. Further, the inverter circuit 2 immediately after the operation starts, applies 0 (zero) V as a DC voltage component to the primary coil side of the transformer 12. That is, the primary coil side of the transformer 12 is short-circuited at the DC voltage level.

Thereafter, the control circuit 10 controls the second switch 6 that has been in the off state so far to be in the on state (SP13) and controls the first switch 8 that has been in the on state so far to be in the off state. (SP14). At this time, a magnetizing inrush current flows from the power system 9 to the transformer 12 (see FIG. 6E). The magnetizing inrush current is a current containing a large amount of DC component, and the primary coil side of the transformer 12 is short-circuited at the DC voltage level. For this reason, the transformer 12 will be in the state which continues flowing a direct current to the primary coil side by the reactor effect. At this time, the magnetic flux of the transformer 12 is biased in either direction (this state is a “biased state”). As a result, the transformer 12 cannot take a beautiful hysteresis curve and distorts the waveform of the output current I ₀ flowing on the secondary coil side (see FIG. 4E for the conventional method).

Therefore, the control circuit 10 in this embodiment controls the inverter / gate signal G1 to be in a stopped state for a certain period after the second switch 6 is turned on (SP15). Here, the “certain period” is a time sufficient for the above-described convergence of the magnetizing inrush current (elimination of the biased state). In FIG. 6E, “a sufficient time for the magnetizing inrush current to converge” is indicated by a range R1 surrounded by a dotted line. At this time, the direct current that flows into the primary coil side of the transformer 12 due to the influence of the magnetizing inrush current flows to the direct current input side through the diode inside the inverter circuit 2 and is consumed. As a result, the biased state of the transformer 12 is eliminated. With the cancellation of the biased state, the distortion of the output current I ₀ within the range R1 gradually decreases, and eventually becomes a beautiful sine wave without distortion.

  Although the specific numerical value for a certain period depends on the configuration of the grid interconnection inverter device (configuration of the entire circuit including the transformer 12), it is set to 0.1 seconds or more, for example. The timing T1 for controlling the inverter gate signal G1 to the stop state is after the second switch 6 is controlled to be on and before the inverter circuit 2 starts to output power. It is optional. FIG. 6 shows a case where the inverter / gate signal G1 is controlled to be in a stopped state after a while has elapsed since the second switch 6 was turned on.

  When a predetermined period of time elapses, the control circuit 10 performs switching control of the inverter gate signal G1 (SP16). Note that the end point of the certain period ends before the inverter circuit 2 starts to output the output power. Thereafter, when the inverter circuit 2 controlled to be in the ON state starts to output power (that is, inverter current I1), output power having a clean sine wave waveform starts to be output to the power system 9 (SP17).

  Thus, if the grid connection inverter apparatus which employ | adopts the control method which concerns on an Example is used, a big magnetizing inrush current will flow into the transformer 12 immediately after the ON control of the 2nd switch 6, and the reactor effect of the transformer 12 Even if a direct current continues to flow to the primary coil side (even if a biased state), the inverter circuit 2 can be temporarily turned off to cancel the biased state and provide a clean sine wave. Waveform output power can be supplied to the power system 9. That is, the quality of the power supplied to the power system 9 can be improved.

  In the above-described embodiment, the second switch 6 is connected in parallel to the series circuit of the current limiting resistor 7 and the first switch 8, but the second switch is connected to the current limiting resistor 7. 6 may be connected in parallel.

DESCRIPTION OF SYMBOLS 1 ... DC power supply 2 ... Inverter circuit 3 ... 1st current detector (inverter current detector)
4 ... Inductor 5 ... Filter capacitor 6 ... Second switch 7 ... Current limiting resistor 8 ... First switch (current limiting switch)
9 ... Power system 10 ... Control circuit 11 ... Second current detector (output current detector)
12 ... Transformer G1 ... Inverter gate signal A1 ... Switch 6 control signal A2 ... Switch 8 control signal V1 ... Inverter voltage I1 ... Inverter current I ₀ ... Output current

Claims (4)

An inverter circuit connected to a DC power supply;
A transformer connected to the output side of the inverter circuit;
A series circuit of a current limiting resistor and a first switch connected between the output side of the transformer and the power system;
A second switch connected in parallel to the series circuit or the current limiting resistor;
A control circuit for controlling the inverter gate signal applied to the inverter circuit to a stop state for a certain period after the second switch is turned on, and then switching again the inverter gate signal applied to the inverter circuit; A grid interconnection inverter device. In the grid interconnection inverter device according to claim 1,
The start point of the predetermined period is set to a period from when the second switch is turned on to before the inverter circuit starts to output output power. In the grid connection inverter apparatus of Claim 1 or 2,
The grid-connected inverter device, wherein the predetermined period is longer than a sufficient time to eliminate a biased state appearing in the output of the inverter circuit. In the grid connection inverter apparatus of any one of Claims 1-3,
The grid-connected inverter device, wherein the predetermined period ends before the inverter circuit starts to output power.

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