JP2011199980A - Inverter device, and photovoltaic power generation system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an inverter device which enables the accurate correction of DC components by improving dispersion in detection of DC component values.SOLUTION: The inverter device includes an inverter main circuit 7, a DC component detecting circuit 11 which is connected to the output side of the inverter main circuit 7 and detects the DC components of the output current of the inverter main circuit 7, and an inverter main circuit control circuit 8 which receives the input of the DC components of the output currents and corrects the DC components of the inverter main circuit 7 based on the DC components of the output currents. The inverter main control circuit 8 has a recorder 9 which is connected to the DC component detecting circuit 11 and stores the output currents of the inverter main circuit 7 as a DC offset voltage value when the inverter main circuit 7 is in a nonoperation state, a comparator 10 which is connected to the recorder 9 and compares the DC component value of the output current of the inverter main circuit 7 on the basis of the DC offset voltage value, and a corrector 16 which is connected to the comparator 10 and corrects the DC components of the inverter main circuit 7.

Description

  The present invention relates to an inverter device that converts direct current power obtained from a solar cell or the like into alternating current power and supplies alternating current power to a load in conjunction with a commercial power system, and a photovoltaic power generation system. The present invention relates to an inverter device and a photovoltaic power generation system that can detect a direct current component included in an alternating current to be output with high accuracy and suppress the generation of the direct current component.

  In an inverter device that converts DC power obtained from a solar cell or the like into AC power and supplies AC power to a load linked to a commercial power system, the DC component of the AC output current is detected and the DC component is detected. In order to suppress this, switching control of the switching circuit is performed. As a means for detecting the DC component as a conventional example, a correction method is known by combining DC component detection with a current sensor and DC component detection with a shunt resistor. (For example, refer to Patent Document 1).

JP-A-11-051977

In the conventional inverter device and the photovoltaic power generation system, the detected DC component value varies due to variations in components (for example, shunt resistors and filters in Patent Document 1) used in them. Has occurred.
Therefore, an object of the present invention is to provide an inverter device and a photovoltaic power generation system that improve the variation in detection of DC component values and enable highly accurate DC component correction.

  Accordingly, in order to achieve the object, the present invention performs an AC-to-AC conversion operation for converting an input DC voltage supplied from a DC power source into an AC voltage, and supplies AC power to a load connected to a power system. In the inverter device to be supplied, an inverter main circuit that converts input DC power into AC power; a DC component detection circuit that is connected to an output side of the inverter main circuit and detects a DC component of an output current of the inverter main circuit; An inverter main circuit control circuit that inputs a DC component of the output current and corrects the DC component of the inverter main circuit based on the DC component of the output current, the inverter main circuit control circuit detecting the DC component The output current of the inverter main circuit when the inverter main circuit is in a non-operating state is connected as a DC offset voltage value. A recording unit, a comparison unit connected to the recording unit and comparing a DC component value of an output current of the inverter main circuit with reference to the DC offset voltage value; and connected to the comparison unit; And a correction unit that performs DC component correction.

  As described above, in the inverter device and the photovoltaic power generation system of the present invention, the output current of the inverter main circuit 7 when the inverter main circuit 7 is in a non-operating state is stored as a DC offset voltage value, and the DC offset voltage is stored. By comparing the value with the actually measured DC component value and correcting the DC component so as to cancel out the voltage difference, the variation in detection of the DC component value is improved, and high-precision DC component correction is performed. An inverter device and a photovoltaic power generation system that can be provided can be provided.

Configuration diagram of a photovoltaic power generation system using the inverter device in the first embodiment Configuration diagram when measuring DC offset voltage value in the first embodiment

  Hereinafter, embodiments of an inverter device and a photovoltaic power generation system according to the present invention will be described in detail with reference to the drawings.

(Embodiment 1)
FIG. 1 shows a configuration diagram of a photovoltaic power generation system using the inverter device according to the first embodiment.

  The solar cell 1 is connected to the input side of the DC-DC converter 2, and the output side of the DC-DC converter 2 is connected to the input side of the inverter device 3. The DC-DC converter 2 is for boosting the output voltage from the solar cell 1 to a desired voltage value. The inverter device 3 is a circuit for converting DC power input from the DC-DC converter 2 into AC power. A load 4 is connected to the output side of the inverter device 3. Further, a pole transformer 5 and a commercial power source 6 are connected in parallel to the load 4. In this way, the solar power generation system is configured.

  The inverter device 3 includes an inverter main circuit 7 that converts DC power input from the DC-DC converter 2 into AC power, and an inverter that is connected to the inverter main circuit 7 and controls the AC conversion operation of the inverter main circuit 7. A main circuit control circuit 8, a direct current component detection circuit 11 connected to the output side of the inverter main circuit 7 for detecting a direct current component value of the output current of the inverter main circuit 7, and the inverter main circuit control circuit 8 A recording unit 9 that is connected to the detection circuit 11 and stores the value detected by the DC component detection circuit 11 when the inverter main circuit 7 is not operating as a DC offset voltage value, and a DC offset voltage connected to the recording unit 9 The comparison unit 10 that compares the DC component value of the output current of the inverter main circuit 7 based on the value, and the output current of the inverter main circuit 7 And a correction unit 16 for component correction.

The DC component detection circuit 11 includes a shunt resistor 12 connected in series to the output side of the inverter main circuit 7, an amplifier 13 connected to the shunt resistor 12, and an AD converter 14 connected to the amplifier 13. The photocoupler 15 connected to the AD converter 14
It is composed of The photocoupler 15 is connected to the recording unit 9 and the comparison unit 10.

  The inverter main circuit control circuit 8 and the output side of the inverter main circuit 7 (the shunt resistor 12, the DC component detection circuit 11, the load 4, the pole transformer 5, and the commercial system power supply 6) are electrically insulated. This is because the reference potential on the output side of the inverter main circuit 7 is different from the reference potential of the commercial power supply and the reference potential of the inverter main circuit control circuit 8 by about 200 [V].

  Next, a method for determining the DC offset voltage value stored in the recording unit 9 in the present embodiment will be described.

  FIG. 2 shows a configuration for measuring the DC offset voltage value. At this time, the difference from FIG. 1 is that the DC offset voltage value is determined when the inverter main circuit 7 does not output AC power (the inverter main circuit 7 is in the non-operating state), and the inverter device 3 The output is disconnected from the commercial power supply 6. In a state where the inverter main circuit 7 does not output AC power and the inverter device 7 is disconnected from the commercial power supply 6, the DC component current value is theoretically zero. Therefore, the value detected by the DC component detection circuit 11 at this time is the value when the actual DC component is zero. Therefore, by storing the value detected by the DC component detection circuit 11 at this time as a DC offset voltage value in the recording unit 9 in advance, an inherent detection deviation of each inverter device due to component variation or the like can be obtained. It can be corrected.

  Next, an operation of the photovoltaic power generation system using the inverter device according to the first embodiment as shown in FIG. 1 will be described. The DC-DC converter 2 boosts the DC voltage output from the solar cell 1 that stores the power generated by sunlight to a sufficiently large DC voltage and outputs the boosted voltage to the inverter device 3. The inverter device 3 converts the direct-current voltage (that is, direct-current power) input from the DC-DC converter 2 into an alternating voltage (that is, alternating-current power) that can be supplied to a load 9 (e.g., equivalent to a home appliance used in a general household). Convert. The load 9 is supplied with a necessary AC voltage (that is, AC power) from a commercial power supply 6 (corresponding to a power supply from a power company in a general household) via a pole transformer 5.

Here, the operation of the inverter device 3 will be described. The inverter main circuit 7 is specifically controlled by the inverter main circuit control circuit 8 (for example, control of the output power value and control of the frequency of the output power). The detailed configuration and operation of the inverter main circuit 7 and the inverter main circuit control circuit 8 are disclosed in Japanese Unexamined Patent Application Publication No. 2009-142005, so please refer to them. (In particular, the FET bridge 4 in FIG. 1 of JP2009-142005A corresponds to the inverter main circuit 7, and the control unit 42 corresponds to the inverter main circuit control circuit 8.)
Details of the configuration and operation for detecting the DC component of the output voltage from the inverter main circuit 7 will be described.

  A very small resistance (about several [mohm]) is connected in series to the inverter main circuit 7 as a shunt resistor 12. The reason why a very small resistance is used is to suppress the loss due to the shunt resistance as much as possible and supply the power output from the inverter main circuit 7 to the load as much as possible. In the first embodiment, 1 [mohm] is used as the shunt resistor 12.

  Here, the configuration and operation of the DC component detection circuit 11 will be described.

  The DC voltage component detected by the shunt resistor 12 is amplified by the amplifier 13 and input to the AD converter 14. The AD converter 14 converts the input analog value into a digital value, and inputs the digital value to the inverter main circuit control circuit 8 through the photocoupler 15. The inverter main circuit control circuit 8 compares the DC offset voltage value with the DC component of the output current of the inverter main circuit 7, and controls the inverter main circuit 7 so that the difference between the digital values becomes zero.

As a result, when the inverter main circuit 7 is not operating, the output current of the inverter main circuit 7 is stored as a DC offset voltage value, and this DC offset voltage value is compared with the actually measured DC component value. By correcting the DC component so as to cancel out the voltage difference, it is possible to improve the variation in detection of the DC component value and provide an inverter device and a photovoltaic power generation system capable of highly accurate DC component correction. is there.
In the present embodiment, the reason why the DC component is input to the inverter main circuit control circuit 8 via the photocoupler 15 is that, as described above, the reference potential on the output side of the inverter main circuit 7, that is, the commercial system power supply 6 or Since the difference between the reference potential of the DC component detection circuit 11 and the reference potential of the inverter main circuit control circuit 8 is about 200 [V] as described above, the DC component current value detected by the DC component detection circuit 11 has a potential difference. This is because data is transferred to the inverter main circuit control circuit 8 as a digital value.

On the other hand, an inverter circuit (corresponding to the inverter device 3 of the first embodiment of the present application) described in Patent Document 1 (Japanese Patent Laid-Open No. 11-051977) described above has a shunt resistor 9 (the present embodiment of the present application). Only the sign of the DC voltage component of the output detected by the shunt resistor 12 of 1) is different from the main circuit power supply (corresponding to the commercial system power supply 6 of the first embodiment of the present application) and a reference potential different from that of the main circuit power supply. It is input to the microcomputer 16 in the control circuit 19 (corresponding to the inverter main circuit control circuit 8 of the first embodiment of the present application), and its sign and the current sensor 8 (not present in the first embodiment of the present application) According to the result, the DC component of the output voltage of the inverter main circuit 2 (corresponding to the inverter main circuit control circuit 7 of the first embodiment of the present application) is gradually corrected to zero (Japanese Patent Laid-Open No. 11-051977, paragraph [0]). 26] Referring to [0028], wherein) is intended.
However, on the side of the shunt resistor 9 (corresponding to the shunt resistor 12 of the first embodiment of the present application), only positive and negative signs are detected, so that time loss occurs in the correction.

  Compared to Patent Document 1 which is the prior art, in the first embodiment, the detected DC component of the inverter main circuit 7 is used as a reference of the commercial power supply 6 using the shunt resistor 12 and the DC component detection circuit 11. It is converted to a digital value on the same side as the potential and input to the inverter main circuit control circuit 8 that is different from the reference potential of the commercial power supply 6, and the inverter main so that the voltage difference is zero based on the positive / negative sign and the digital value. By controlling the circuit 7, the DC component can be corrected quickly. Therefore, the efficiency of the entire system of the commercial power system can be improved.

  In the present embodiment, the photocoupler 15 is used in the DC component detection circuit 11. However, instead of the photocoupler 15, an electrically insulated portion (in FIG. 1, between the photocoupler 15 recording unit 9). If the data can be transmitted in (), it can be used. For example, an isolator or the like may be used.

  The inverter device according to the present invention is useful as an inverter device for a power conditioner such as a solar battery.

1. 1. Solar cell 2. DC-DC converter Inverter device4. 4. Load Pillar transformer 6. 6. Commercial power supply Inverter main circuit 8. 8. Inverter main circuit control circuit Recording unit 10. Comparison unit 11. DC component detection circuit 12. Shunt resistor 13. Amplifying unit 14. AD converter 15. Photocoupler 16. Correction unit

Claims (4)

In an inverter device that performs an AC conversion operation from a direct current that converts an input direct current voltage supplied from a direct current power source into an alternating current voltage, and that supplies alternating current power to a load connected to a power system,
An inverter main circuit for converting input DC power to AC power;
A DC component detection circuit connected to the output side of the inverter main circuit and detecting a DC component of the output current of the inverter main circuit;
An inverter main circuit control circuit that inputs a DC component of the output current and corrects the DC component of the inverter main circuit based on the DC component of the output current;
With
The inverter main circuit control circuit is:
A recording unit that is connected to the DC component detection circuit and stores the output current of the inverter main circuit when the inverter main circuit is in a non-operating state as a DC offset voltage value;
A comparison unit connected to the recording unit and comparing the DC component value of the output current of the inverter main circuit with reference to the DC offset voltage value;
A correction unit connected to the comparison unit and performing DC component correction of the inverter main circuit;
An inverter device comprising:   2. The inverter apparatus according to claim 1, wherein the DC component detection circuit includes an AD converter, and detects a value including a positive / negative sign and a digital value of the DC component value using the AD converter. In a photovoltaic power generation system using an inverter device that performs an AC conversion operation for converting an input DC voltage supplied from a DC power source into an AC voltage, and supplies an AC voltage to a load in conjunction with a power system,
Solar cells,
A DC-DC converter connected to the solar cell;
The inverter device connected to the output side of the DC-DC converter;
A load connected to the output side of the inverter device;
A pole transformer connected in parallel to the load;
A commercial power supply connected in parallel to the pole transformer;
With
The inverter device is
An inverter main circuit for converting input DC power to AC power;
A DC component detection circuit connected to the output side of the inverter main circuit and detecting a DC component of the output current of the inverter main circuit;
An inverter main circuit control circuit that inputs a DC component of the output current and corrects the DC component of the inverter main circuit based on the DC component of the output current;
With
The inverter main circuit control circuit is:
A recording unit that is connected to the DC component detection circuit and stores the output current of the inverter main circuit when the inverter main circuit is in a non-operating state as a DC offset voltage value;
A comparison unit connected to the recording unit and comparing the DC component value of the output current of the inverter main circuit with reference to the DC offset voltage value;
A correction unit connected to the comparison unit and performing DC component correction of the inverter main circuit;
A photovoltaic power generation system characterized by comprising:   The solar power generation system according to claim 3, wherein the DC component detection circuit includes an AD converter, and detects a digital value using the AD converter.

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