JP6888898B1 - Photovoltaic power control device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To obtain a photovoltaic power generation power control device which has an uninterruptible power supply function and can be modified to perform power control with a reverse power flow prevention function without modifying an existing photovoltaic power generation device. A power supply line that supplies an AC output to a load 40, a series inverter 14 that is connected to a secondary winding of a second transformer 13 to perform power conversion, and a parallel converter 15 that is connected to the power supply line and performs power conversion. A power storage device 16 connected to both the DC side of the series inverter 14 and the DC side of the parallel converter 15 is provided to form a non-disruptive power supply unit, while being connected in parallel to the load 40 to generate electric power. The solar power generation device 30 having a suppression control function, the current detector 20 for detecting the current value of the reverse power flow generated in the solar power generation device 30, and the series inverter 14 are controlled so that the current value of the reverse power flow becomes 0. A series inverter control unit 81 that adjusts the output voltage of the second transformer 13 is provided. [Selection diagram] FIG. 11

Description

The present invention relates to a photovoltaic power generation control device, and particularly to a photovoltaic power generation power control device that controls power generation as much as a load requires without reverse power flow to the AC input side in photovoltaic power generation.

As a power supply system using a photovoltaic power generation panel, for example, the structure shown in Patent Document 1 has been proposed.
As shown in FIG. 20, the power supply system 201 includes a commercial power supply source 205, a photovoltaic power generation system 203, and a power storage battery 223, and the photovoltaic power generation system 203 includes a photovoltaic power generation panel 211 and a power conversion device 213. I have. The power supply system 201 includes a power switch, and when it detects reverse power flow or voltage rise with the commercial power supply source 205, the commercial power supply source 205 is disconnected from the solar power generation system 203. The surplus power supplied is stored in the power storage battery 223, and when a power failure of the commercial power supply source 205 is detected, the commercial power supply source 205 is disconnected and power is supplied from the solar power generation system 203 and the power storage battery 223. Supply to load 209.

According to the power supply system 201, the power of the solar power generation is sold by the power storage device, the surplus power is stored in the power storage battery 223, and when the power of the load 209 is insufficient, the power of the solar power generation is used. The electric power and the electric power from the electric power storage are added to supply the electric power to the load 209, and the electric power storage battery 223 is charged by the midnight electric power.
In addition, when reverse power flow occurs from the photovoltaic power generation system 203, the system voltage rises, or a power failure occurs, the photovoltaic power generation system 203 is separated from the system and loaded by opening the switch 241. It is conceivable to control the power supply to 209.

Japanese Patent No. 4856692

According to the power supply system described in Patent Document 1, when the photovoltaic power generation system 203 is a self-consumption type, when a reverse power flow occurs from the photovoltaic power generation system 203 to the commercial system (commercial power supply source 205) side, Since the reverse power flow is controlled by opening and closing the switch 241, on / off control is performed, which causes a drawback that fine analog control cannot be performed. Deterioration of the switch due to opening and closing operations is also expected.
Further, in order to suppress the voltage rise of the system, when surplus power is generated, the system is disconnected by the switch 241 and the power storage battery 223 is charged, but even when the power storage battery 223 is fully charged, the system is charged. If the voltage is high, the photovoltaic power remains disconnected, and if the load power consumption is greater than the PV power consumption, there is no load that consumes surplus power, so the switch 243 needs to be turned off. There is. Therefore, the photovoltaic power generation device (photovoltaic power generation system 203) cannot be a self-consumption type. In addition, the effective use of photovoltaic power generation cannot be achieved.

In addition, when supplying AC input to the load, if the AC power supply is normal, power is supplied to the load from the AC power supply, and if an abnormality such as a power failure or momentary drop occurs in the AC power supply, it is stored in the storage battery. A non-disruptive power supply device that supplies the current power to a load is known (see, for example, Japanese Patent Application Laid-Open No. 6618210).

When an uninterruptible power supply is used for the photovoltaic power generation device, it is installed in front of the load in order to support backup in the event of a power failure. That is, as shown in FIG. 21, the photovoltaic power generation device 30 is connected to the input side of the uninterruptible power supply device 10 connected to the commercial power supply 50 via the AC switch S1 via the AC switch S2. The photovoltaic power generation device 30 performs a grid interconnection operation operation under the maximum power follow-up operation control (Pmax control) to supply power to the grid line (power supply line).
When the photovoltaic power generation exceeds the power consumption of the load 40 during normal operation of the commercial power source 50, the surplus power is reverse-flowed to the commercial power source 50 and sold. When the photovoltaic power generation falls below the power consumption of the load 40, the shortage power is supplied from the commercial power source 50.
In the conventional method, if the photovoltaic power generation device side is not equipped with the reverse power flow prevention device, the reverse power flow always flows to the commercial system side, so that the photovoltaic power generation device 30 cannot be a self-consumption type. In order to make it a self-consumption type, it is necessary to control the AC switch S2 to be turned on / off when reverse power flow is detected.

When the commercial power supply 50 loses power due to a natural disaster or the like, as shown in FIG. 22, the AC switch S1 and the AC switch S2 are turned off, the photovoltaic power generation device 30 is disconnected from the grid line, and the solar power generation device 30 is operated independently from the grid interconnection operation operation. Switch to operation. At this time, the voltage is supplied to the self-sustaining operation outlet 31 of the photovoltaic power generation device 30, but since the grid interconnection operation is stopped, the voltage cannot be generated on the photovoltaic power generation device side of the AC switch S2. .. Therefore, even if the AC switch S1 is turned off and then the AC switch S2 is turned on, the power cannot be supplied from the photovoltaic power generation device 30 to the load 40, so that the power is supplied from the uninterruptible power supply device 10 to the load 40. Will be.
That is, when the uninterruptible power supply device 10 is used for the photovoltaic power generation device 30 in the above-mentioned connection configuration, it is necessary to turn off the AC switch S2, which hinders the effective use of the photovoltaic power generation device 30.

The present invention has been proposed in view of the above circumstances, and can be modified so as to have an uninterruptible power supply function and a reverse power flow prevention function to perform power control without modifying an existing photovoltaic power generation device. An object of the present invention is to provide a photovoltaic power generation control device.

In order to achieve the above object, the photovoltaic power generation control device according to claim 1 of the present invention is
An AC input is supplied to one end side via a switching element (12), and the primary winding is provided via a transformer (second transformer 13) having a primary winding and a secondary winding on the other end side. A power supply line that supplies AC output to the load (40) from
A series inverter (14) connected to the secondary winding of the transformer (second transformer 13) to perform power conversion, and
A parallel converter (15) connected to the power supply line and performing power conversion,
An uninterruptible power supply unit (uninterruptible power supply 10) is configured by including a power storage device (16) connected to both the DC side of the series inverter (14) and the DC side of the parallel converter (15). on the other hand,
A photovoltaic power generation unit (photovoltaic power generation device 30) that is connected in parallel to a load (40) connected to the transformer (second transformer 13) and has a power generation suppression control function.
A current detector (20) that detects the current value of reverse power flow generated in the photovoltaic power generation unit (photovoltaic power generation device 30), and a current detector (20).
A series inverter control unit (81) that controls the series inverter (14) so that the current value of the reverse power flow becomes 0 and adjusts the output voltage of the transformer (second transformer 13).
It is characterized by being equipped with.

The second aspect is the first input winding and the second input winding between the switching element (12) and the transformer (second transformer 13) in the solar power generation control device of the first aspect. Another transformer having a wire (first transformer 11) is connected, and the parallel converter (15) is connected to the second input winding of the other transformer (first transformer 11). The transformer (second transformer 13) is characterized in that it is connected to an output winding having a leakage inductance of the other transformer (first transformer 11).

A third aspect of the photovoltaic power generation control device according to the first aspect is the series inverter (14), the parallel converter (15), and the parallel converter (15) with respect to the secondary winding of the transformer (second transformer 13). It is characterized in that the power storage devices (16) are connected in parallel.

A fourth aspect of the present invention is the photovoltaic power generation control device according to any one of claims 1 to 3, wherein the current detector (20) is connected to the switching element (12) on the AC input side. It is characterized by that.

5. The solar power generation control device according to any one of claims 1 to 3, wherein the current detector (20) is a DC line of the series inverter (14) and the power storage device (16). ) Is connected to the parallel converter (15) side.

A sixth aspect of the present invention is the photovoltaic power generation control device according to any one of claims 1 to 5, wherein the switching element (12) is composed of a pair of thyristors connected in antiparallel. There is.

According to the solar power generation control device of the present invention, when a reverse current flows to the AC input side, the reverse current is detected by the current detector (20), and the series inverter (14) is detected according to the detected amount. Raises the voltage applied to the load (40) by applying a voltage to the transformer (second transformer 13), and activates the generated power suppression control function of the solar power generation unit (solar power generation device 30). Therefore, it is possible to realize a self-consumption type solar power generation device that reduces the generated power and generates only the amount required by the load (40) without causing the power to flow backward to the AC input side.

Further, by providing the uninterruptible power supply unit (uninterruptible power supply 10), stable power is supplied to the load (40) even when the AC input fluctuates due to the series inverter (14), and a power failure or a momentary decrease occurs. In the case, the electric power stored in the power storage device (16) can be supplied to the load (40) by the photovoltaic power generation unit (photovoltaic power generation device 30) or the parallel converter (15).

It is a block diagram (when the commercial power source is normal) which shows the basic structure of the photovoltaic power generation power control device which concerns on this invention. It is a block diagram (at the time of a commercial power failure) which shows the basic structure of the photovoltaic power generation power control device which concerns on this invention. It is a circuit diagram which shows an example of embodiment of the photovoltaic power generation control device. In the circuit diagram of the photovoltaic power generation control device, it is a figure which shows the power flow when the photovoltaic power generation power is smaller than the power consumption of a load (when the commercial power source is normal). In the circuit diagram of the photovoltaic power generation control device, it is a figure which shows the power flow when the photovoltaic power generation power is larger than the power consumption of a load (when the commercial power source is normal). In the circuit diagram of the photovoltaic power generation control device, it is a figure which shows the power flow when the photovoltaic power generation power is larger than the power consumption of a load, and excessive power is generated in a power storage device (when the commercial power source is normal). In the circuit diagram of the photovoltaic power generation control device, it is a figure which shows the power flow when the photovoltaic power generation power is smaller than the power consumption of a load (at the time of a commercial power failure). In the circuit diagram of the photovoltaic power generation control device, it is a figure which shows the power flow when the photovoltaic power generation power is larger than the power consumption of a load (at the time of a commercial power failure). It is a circuit diagram which shows another example (the connection position of a current detector is different) of the Embodiment of a photovoltaic power generation control device. It is a circuit diagram which shows another example (applying the uninterruptible power supply device of another configuration) of embodiment of the photovoltaic power generation power control device. It is a circuit diagram which shows another example (applying the uninterruptible power supply device of another configuration) of embodiment of the photovoltaic power generation power control device. It is a block diagram which shows the embodiment which embodied the photovoltaic power generation power control device of FIG. It is a block diagram which shows an example of the control by a series inverter control part when the voltage of an AC input is normal. It is a block diagram which shows an example of the control by a parallel converter control part when the voltage of an AC input is normal. It is a block diagram which shows an example of the control by a parallel converter control part when the voltage of an AC input becomes abnormal. It is a block diagram which shows the 2nd basic configuration of the uninterruptible power supply which can apply to a photovoltaic power generation control device. It is a figure which shows the voltage applied to the 1st input winding and the 2nd input winding of the 1st transformer in the 2nd basic configuration. It is a block diagram which shows the embodiment which embodied the photovoltaic power generation power control device of FIG. An embodiment when the uninterruptible power supply device of the present invention is a three-phase machine is shown. It is a figure which shows the example of the specific structure of the 1st transformer. It is a block diagram of the power supply system using the photovoltaic power generation panel described in Patent Document 1. It is a block diagram (when the commercial power supply is normal) when the conventional uninterruptible power supply is connected to the photovoltaic power generation device. It is a block diagram (when a commercial power supply is abnormal) when a conventional uninterruptible power supply is connected to a photovoltaic power generation device.

An outline of an embodiment of the photovoltaic power generation control device according to the present invention will be described with reference to FIGS. 1 and 2.
The photovoltaic power generation power control device according to the present invention is connected to the uninterruptible power supply device (uninterruptible power supply unit) 10 connected to the power supply line of the commercial power supply 50 via the AC switch S1 and the uninterruptible power supply device 10. It is configured to include a photovoltaic power generation device (photovoltaic power generation unit) 30 connected in parallel to the load 40 to be generated via an AC switch S2. Similar to the photovoltaic power generation system 203 of FIG. 17, the photovoltaic power generation device 30 includes a photovoltaic power generation panel that generates electricity by sunlight and an existing photovoltaic power generation device provided with a power conversion device that supplies desired power. Has been done.

During normal commercial operation, as shown in FIG. 1, power is supplied from the photovoltaic power generation device 30 to the load 40 by turning on the AC switch S1 and the AC switch S2. Further, when the power supply from the photovoltaic power generation device 30 to the load 40 is insufficient, the power supply from the commercial power source 50 is performed.

At the time of a commercial power failure, as shown in FIG. 2, the AC switch S1 is turned off to disconnect the commercial power supply 50 from the power supply line, and the uninterruptible power supply 10 serves as a voltage source to supply power to the load 40 instead of the commercial power supply 50. Do. By connecting the photovoltaic power generation device 30 to the output line of the uninterruptible power supply 10, the power of the photovoltaic power generation device 30 can be supplied to the load 40 together with the power of the uninterruptible power supply 10.
Further, since the photovoltaic power generation device 30 is provided with the self-sustaining operation outlet 31, it is possible to supply a voltage to the load connected to the self-sustaining operation outlet 31.

The uninterruptible power supply 10 controls the power supplied to the load 40 by detecting the reverse power flow current when a reverse power flow occurs on the AC input side when the commercial power supply is normal, and consumes the photovoltaic power supply 30 in-house. It is possible to operate with a mold. The specific configuration of the uninterruptible power supply 10 for realizing this function will be described later.

Hereinafter, the configuration of the uninterruptible power supply device 10 applied to the photovoltaic power generation control device of the present invention will be described with reference to FIG.
The non-disruptive power supply device 10 has a first transformer (transformer) 11 and a second transformer (transformer) 13 for adjusting the AC input of the commercial power supply 50 to an AC output to the load 40, and the commercial power supply 50 and the first. The switching element 12 interposed between the transformer 11 and the series inverter 14 that controls the output of the second transformer 13, the input power to the first transformer 11 and the input power to the power storage device 16 are controlled in both directions. Parallel converter 15, storage device 16 that stores excess power from the solar power generation device 30, LC filter 17 that is a low-pass filter that removes high-frequency components, and current detector that detects the reverse current from the solar power generation device 30. 20. It is configured to include a detection means (not shown) for detecting whether the voltage of the AC input is normal or abnormal.

That is, the AC input from the commercial power supply 50 is supplied to one end side of the power supply line via the switching element 12, and the other end side of the power supply line is connected to the input winding of the first transformer (transformer) 11. The output winding of the first transformer (transformer) 11 is connected to the load 40 via the primary winding of the second transformer (transformer) 13, and AC output is supplied to the load 40. .. A series inverter 14 is connected to the secondary winding of the second transformer (transformer) 13. A parallel converter 15 is connected to the first transformer 11 connected to the power supply line via an LC filter 17.
The power storage device 16 is connected to both the DC side of the series inverter 14 and the DC side of the parallel converter 15.

Further, the photovoltaic power generation device 30 is connected in parallel to the load 40 connected to the second transformer (transformer) 13. The photovoltaic power generation device 30 has a power generation suppression control function.

A series inverter control unit (not shown) is connected to the input side of the series inverter 14, and when reverse power flow is generated in the power supply line by the photovoltaic power generation device 30, the reverse power flow current value becomes 0 in series. The inverter 14 is controlled to adjust the output voltage of the second transformer (transformer) 13. The details of the control in the series inverter control unit will be described later.

With the above configuration, AC input is supplied from the commercial power supply 50 to the input side of the first transformer 11 via the power supply line, and from the output side of the first transformer 11 via the primary winding of the second transformer 13. The adjusted AC output is supplied to the load 40.
Then, a current detector 20 for detecting the current value flowing through the power supply line is connected between the commercial power supply 50 and the switching element 12, so that the current value of the reverse power flow generated in the photovoltaic power generation device 30 can be detected. It is configured.

The first transformer 11 is configured by arranging the first input winding, the second input winding, and one output winding on the same iron core, and is composed of the first input winding and the output winding. Leakage inductances 1 and 2 are intentionally provided between the space and between the second input winding and the output winding, respectively. The specific structure of the first transformer 11 will be described later.

The switching element 12 is composed of a pair of thyristors connected in antiparallel, and is provided between the AC input and the first input winding of the first transformer 11. The switching element 12 is turned on when the voltage of the AC input is within the allowable range, that is, when the voltage of the AC input is normal, and when the voltage of the AC input is not within the allowable range, that is, the AC input. When the voltage of is abnormal, it is turned off.

The second transformer (transformer) 13 has a primary winding and a secondary winding, and the primary winding is between the output winding of the first transformer 11 and the load (AC output side). Connected in series, the secondary winding is connected to the AC side of the series transformer 14.

The AC side of the series inverter 14 is connected to the secondary winding of the second transformer 13, and the DC side is connected to the power storage device 16. The series inverter 14 operates so as to keep the load voltage constant by controlling the voltage of the second transformer 13 to be raised or lowered according to the voltage fluctuation of the AC input by the commercial power source 50.

In the parallel converter 15, the AC side is connected to the second input winding of the first transformer 11 through the LC filter 17, and the DC side is connected to the power storage device 16. The parallel converter 15 can control power in both directions. The parallel converter 15 controls the charging current and charging voltage of the power storage device 16 to be maintained at the rated values.

The power storage device 16 is composed of a storage battery, and is connected to both the DC side of the series inverter 14 and the DC side of the parallel converter 15 to serve as an energy source during backup operation.

The LC filter 17 is connected between the AC side of the parallel converter 15 and the second input winding of the first transformer 11.

The detecting means for detecting whether the voltage of the AC input is normal or abnormal detects whether or not the voltage of the AC input is abnormal.

Next, the operation of the photovoltaic power generation control device when the commercial power source is normal will be described with reference to FIGS. 4 to 6.

When the voltage of the AC input is normal, the switching element 12 is turned on. As a result, AC input power is supplied to the load 40 through the switching element 12, the first input and output windings of the first transformer 11, and the primary winding of the second transformer 13. At this time, the series inverter 14 controls the voltage generated in the primary winding of the second transformer 13 to stabilize the voltage applied to the load 40.

The AC input power is supplied to the parallel converter 15 through the first input winding and the second input winding of the first transformer 11 and the LC filter 17. The parallel converter 15 generates a DC output and charges the power storage device 16.

FIG. 4 shows a power flow when the power generated by the photovoltaic power generation device 30 is smaller than the power consumption of the load 40 in a normal state of the commercial power source 50.
In this case, electric power is supplied to the load 40 by the electric power of the photovoltaic power generation and the electric power of the AC input. At the same time, the power storage device 16 is charged from the AC input side. The series inverter 14 operates so as to keep the load voltage supplied to the load 40 constant.

Next, FIG. 5 shows a power flow when the power generated by the photovoltaic power generation device 30 is larger than the power consumption of the load 40.
In this case, the generated power of the photovoltaic power generation is supplied to the load 40 and tries to flow to the AC input side through the primary side of the second transformer 13. At this time, since the voltage applied to the winding on the primary side of the second transformer 13 rises, the voltage applied to the load 40 also rises. At this time, the series inverter 14 absorbs the voltage rise of the AC input from the second transformer 13 to stabilize the voltage applied to the load 40, converts the increase of the power supplied to the load 40 into DC power, and stores the power. Charge the device (storage battery) 16.

Next, FIG. 6 shows a power flow when the power generated by the photovoltaic power generation device 30 is larger than the power consumption of the load 40 and excess power is generated in excess of the charging power required by the power storage device 16.
At this time, the series inverter 14 is controlled so as to keep the load voltage constant, and the charging power and the excess power of the power storage device 16 flow into the power storage device 16 side. The parallel converter 15 controls so as to keep the charging current and the charging voltage of the power storage device 16 at the rated values, and when excessive power tries to flow into the power storage device 16, the excess power is transferred to the parallel converter 15. Passes through the second input winding and the first input winding and flows into the AC input side (generation of reverse power flow of solar power generation).

The reverse power flow current is detected by the current detector 20, and the series inverter 14 operates to raise the voltage of the primary winding of the second transformer 13 according to the detected value.
At this time, the voltage applied to the load 40 also increases. When the load voltage rises, the output voltage of the photovoltaic power generation device 30 also rises, and the photovoltaic power generation device 30 operates its own power generation suppression control to narrow down the generated power (photovoltaic power generation device 30). When the system voltage rises, it operates to lower the system voltage, so it narrows down its own power generation).
If the output voltage of the series inverter 14 is controlled so that the reverse power flow current detection value becomes zero, feedback control is applied to the entire system of the photovoltaic power generation device 30 and the series inverter (first power conversion device) 14. Therefore, the electricity generated by photovoltaic power generation can be consumed in-house without reverse power flow.

That is, according to the non-disruptive power supply device 10 provided with the current detector 20, the current detector 20 detects the reverse power flow current, and the series inverter 14 moves to the second transformer 13 according to the detected amount. The voltage applied to the load 40 is increased by applying a voltage, and the generated power is throttled by activating the generated power suppression control function of the solar power generation device 30, and the load is applied without causing the power to flow back to the AC input side. It can be a self-consumed solar power generation device 30 that generates electric power as much as 40 requires.

Next, FIGS. 7 and 8 show the power flow of the photovoltaic power generation control device at the time of a commercial power failure when the commercial power source 50 has a power failure due to a natural disaster or the like.
As shown in FIG. 7, the photovoltaic power generation control device turns off the switching element 12 and disconnects the AC input when a power failure occurs. Then, the parallel converter 15 switches from synchronous operation with the AC input to self-propelled operation and operates as a voltage source. The series inverter 14 controls so as to keep the load voltage constant. When the photovoltaic power generation is less than the load power consumption, the shortage is supplemented by the power from the power storage device 16.

FIG. 8 shows a power flow when the generated power of the photovoltaic power generation device 30 becomes larger than the load power during a commercial power outage.
At this time, the surplus power charges the power storage device 16 through the series inverter 14, but when the power storage bias 16 is fully charged, the series inverter 14 controls to raise the load voltage. As a result, the photovoltaic power generation device 30 operates its own power suppression control, and the photovoltaic power generation amount and the load power consumption amount become equal to each other. As a result, the photovoltaic power generation can be effectively extracted as compared with the conventional example.

Next, another embodiment of the photovoltaic power generation control device is shown in FIG. In this example, the current detector 20 is installed not on the AC input side of the power supply line but on the parallel converter 15 side of the connection point between the DC line of the series inverter 14 and the power storage device 16.

Further, the uninterruptible power supply 10 applicable to the solar power generation control device includes the series inverter 14 with respect to the secondary winding of the transformer 13 as shown in FIG. 10-1 in addition to the above-mentioned example. In a power conversion device (see Japanese Patent Application Laid-Open No. 2003-259567) in which a parallel converter 15 and a power storage device 16 are connected in parallel and an input reactor and a series inverter 14 are connected to a power supply line, a current detector 20 is located on the AC input side. Can be realized by connecting the above. Alternatively, the current detector 20 (indicated by the dotted line) may be connected on the DC line between the parallel converter 15 and the power storage device 16.

Further, in the non-disruptive power supply device 10, as shown in FIG. 10-2, the series inverter 14, the parallel converter 15, and the power storage device 16 are connected in parallel to the secondary winding of the transformer 13, and the AC input is input. This can be realized by connecting the current detector 20 to the AC input side in a power converter (see Patent No. 4304519) in which the series inverter 14 is connected to the power supply line on the side and the parallel converter 15 is connected to the load side. Alternatively, the current detector 20 (indicated by the dotted line) may be connected on the DC line between the parallel converter 15 and the power storage device 16.
In these photovoltaic power generation control devices, if the series inverter 14 is controlled in the same manner as the photovoltaic power generation power control device of FIG. 3, the load 40 connected in parallel to the photovoltaic power generation device 30 is shown in FIG. The same operation as in 3 can be performed.

FIG. 11 is a block diagram showing an embodiment embodying the uninterruptible power supply device 10 of FIG. In FIG. 11, the same or equivalent parts as those in FIG. 3 are designated by the same reference numerals, and the description thereof will be omitted.

When the voltage of the AC input is normal, an on signal is given to the gate of the thyristor of the switching element 12 to make it conductive. As a result, the AC input power is supplied to the load 40 through the first input winding and output winding of the first transformer 11 and the primary winding (output winding) of the second transformer 13.

In the series inverter 14, the series inverter control unit 81 that inputs the load voltage detection value Vo of the load voltage detector 82 causes the load voltage detection value Vo to be the series inverter output voltage indicated value, so that the second transformer 2 The voltage applied to the next winding (input winding) is feedback-controlled.

FIG. 12 is a block diagram showing an example of control by the series inverter control unit 81 when the voltage of the AC input is normal.

When the AC input voltage is normal, the series inverter control unit 81 calculates the difference between the load voltage detection value Vo and the series inverter output voltage instruction value Vorf, and controls the PWM control unit 91 based on the difference.

When the load voltage detection value Vo is lower than the series inverter output voltage instruction value Vo, the PWM control unit 91 adds the insufficient voltage to the second transformer 13, and the load voltage detection value is lower than the series inverter output voltage instruction value Voref. When Vo is high, a pulse-modulated signal is generated so that the second transformer 13 subtracts the excess voltage, and the series inverter 14 is driven. As a result, the voltage applied to the load 40 is stabilized.

Returning to FIG. 11, the parallel converter control unit 83 has an AC input 1 voltage detection value Vi1 of the AC input 1 voltage detector 84, an AC input 2 voltage detection value Vi2 of the AC input 2 voltage detector 85, and a DC current detector 86. The parallel converter 15 is controlled by inputting the DC current detection value Idc, the DC voltage detection value Vdc of the DC voltage detector 87, and the parallel converter AC output voltage detection value Vac of the parallel converter AC output voltage detector 88.

When reverse power flow occurs, this reverse power flow current is detected by the current detector 20 and compared with Voref, and a high voltage indication value is selected for the series inverter 14 (Voref when the reverse power flow detection value is zero). If the reverse power flow detection value (Vgref) is higher than Voref, the output voltage indication value is replaced with Vgref to prevent reverse power flow.

FIG. 13 is a block diagram showing an example of control by the parallel converter control unit 83 when the voltage of the AC input is normal.

Whether or not the voltage of the AC input is normal is detected by the AC input 1 voltage detection value Vi1 of the AC input 1 voltage detector 84. Therefore, the parallel converter control unit 83 also functions as a detection means for detecting whether the voltage of the AC input is normal or abnormal.

When the voltage of the AC input is normal, the parallel converter 15 charges the power storage device 16 with a constant current and a constant voltage. This constant current / constant voltage charging detects the voltage of the AC input and gives the detected value to the PLL so that the reference sine wave inside the PLL is synchronized with the voltage of the AC input, and further, the phase slide indicated value is applied to the PLL. It can be realized by controlling the phase of the reference sine wave by giving.

The parallel converter 15 controls the phase of the AC voltage output while synchronizing with the AC input voltage. At this time, the voltage of the AC input is applied to the first input winding of the first transformer 11, and the AC voltage is applied from the parallel converter 15 to the second input winding of the first transformer 11. .. As a result, the power storage device 16 is charged at a constant voltage and a constant current.

Specifically, the AC input 2 voltage detection value Vi2 is input to the PLL 101. The PLL 101 synchronizes the reference sine wave inside the PLL with the AC input 2 voltage Vi2. Further, the value obtained by amplifying the difference between the DC current detected value Idc and the charging current indicated value Idcref of the DC current detector 86 and the value obtained by amplifying the difference between the DC voltage detected value Vdc and the charging voltage indicated value Vdcfef of the DC voltage detector 87. Is compared and the smaller value is selected, and the selected value is given to the PLL 101 as a phase slide instruction value.

For example, the logical sum (OR) of the value obtained by amplifying the difference between the detected value of the DC current and the indicated value of the charging current and the value obtained by amplifying the difference between the detected value of the DC voltage and the indicated value of the charging voltage is obtained, and the power storage device 16 is used. When the DC voltage is lower than the indicated value and the DC current flowing through the storage device 16 is large, the difference between the detected value of the DC current and the indicated value of the charging current is selected as the phase slide indicated value, and the charging voltage of the storage device 16 is selected. Is higher than the indicated value and the current flowing through the power storage device 16 is small, the difference between the detected value of the DC voltage and the indicated value of the charging voltage is selected as the slide indicated value.

The PLL 101 controls the phase of the reference sine wave synchronized with the voltage of the AC input by the slide instruction value. As a result, a reference sine wave having a phase indicated by a slide instruction value is output from the PLL 101 in synchronization with the voltage of the AC input.

Further, the parallel converter control unit 83 drives the parallel converter 15 so that the effective value of the output voltage of the parallel converter 15 becomes the effective value of the voltage of the AC input. For this drive, the AC input 2 voltage detection value Vi2 and the parallel converter output voltage detection value Vac are input to the execution value calculators 102 and 103, respectively, and their effective values are calculated. Then, the difference between the effective value of the AC input 2 voltage detection value Vi2 and the execution value of the parallel converter output voltage detection value Vac is amplified, input to the multiplier 104, and multiplied by the reference sine wave output from the PLL 101. The PWM control unit 106 uses the output of the multiplier 104 as an input to generate a pulse modulation signal and drives the parallel converter 15.

By applying the AC voltage from the parallel converter 15 driven by the pulse modulation signal generated as described above to the second input winding of the first transformer 11, the power storage device 16 is subjected to constant voltage and constant current. It can be charged. Further, when the AC input voltage is normal, the effective value of the AC voltage of the parallel converter 15 follows the effective value of the AC input voltage, so that even if the AC input voltage drops, it flows to the switching element 12. The short circuit current is suppressed.

FIG. 14 is a block diagram showing an example of control by the parallel converter control unit 83 when the voltage of the AC input becomes abnormal.

When the voltage of the AC input becomes abnormal, the first switching element 12 (FIG. 11) is turned off. As described above, the parallel converter 15 switches from the operation of charging the power storage device 16 to the backup operation.

The parallel converter control unit 83 calculates the difference between the parallel converter AC voltage detection value Vac of the parallel converter AC output voltage detector 89 and the parallel converter AC output voltage instruction value Vacref, and controls the PWM control unit 105 based on the difference. The PWM control unit 105 generates a pulse modulation signal, thereby driving the parallel converter 15. As a result, the parallel converter 15 is feedback-controlled so that the parallel converter AC output voltage Vac becomes the parallel converter AC output voltage indicated value Vacref.

The power of the power storage device 16 is supplied to the load through the parallel converter 15, the second input and output windings of the first transformer 11, and the primary winding of the second transformer 13. Further, the voltage applied to the load is stabilized by the series inverter 14 and the second transformer 13.

At this time, the short circuit current flowing from the second input winding of the first transformer 11 to the switching element 12 through the output winding and the first input winding is the first input winding and the output of the first transformer 11. It is suppressed by both the leakage inductance 1 between the windings and the leakage inductance 2 between the second input winding and the output winding.

Through the above series of operations, even when the voltage of the AC input becomes abnormal, it is possible to supply the load with completely uninterrupted power at which the rated voltage is maintained.

FIG. 15 is a block diagram showing a second basic configuration of an uninterruptible power supply device applicable to the photovoltaic power generation control device of the present invention.

The uninterruptible power supply of FIG. 15 is different from the uninterruptible power supply of FIG. 3 in that the charger 18 charges the power storage device 16 and the parallel converter 15 controls the power in one direction to load the power of the power storage device 16. It is a point to supply to.

When the AC input voltage is normal, the AC input power is loaded through the switching element 12, the first input and output windings of the first transformer 11, and the primary winding of the second transformer 13. Is supplied to. At this time, the voltage applied to the load is stabilized by the series inverter 14 and the second transformer 13. At this time, the power storage device 16 is charged with a constant voltage and a constant current by the charger 18.

At this time, an AC voltage is applied from the parallel converter 15 to the second input winding of the first transformer 11 through the LC filter 17. The parallel converter 15 operates synchronously with the AC input, and as shown in FIG. 16, the AC voltage value of the capacitor of the LC filter 17 is supplied to the first input winding of the first transformer 11. Operate in voltage control mode so that it is equal to the amplitude value of the input voltage.

The parallel converter 15 controls the electric power in one direction, and the phase and amplitude values of the voltage applied to the second input winding of the first transformer 11 are set by the AC input to the first transformer 11. It operates so as to match the phase, amplitude value, and phase of the voltage applied to the input winding of 1. Therefore, the parallel converter 15 does not charge the power storage device 16.

When the voltage of the AC input becomes abnormal, the switching element 12 is turned off to switch to the backup operation. As a result, the electric power of the power storage device 16 is supplied to the load through the parallel converter 15, the second input winding and the output winding of the first transformer 1, and the primary winding of the second transformer 13.

Even if the backup operation is switched to, the second input winding of the first transformer 11 has the phase and amplitude value of the voltage applied to the first input winding of the first transformer 11 by the AC input. Since an AC voltage matching the phase is applied in advance from the parallel converter 15, the load 40 is supplied with completely uninterrupted power at which the rated voltage is maintained. At this time, the voltage applied to the load 40 is stabilized by the series inverter 14 and the second transformer 13.

Even if the voltage of the AC input becomes abnormal, the above-mentioned series of operations can supply power to the load without interruption while maintaining the voltage applied to the load 40 at the rated voltage. Further, when switching to the backac operation, the overcurrent flowing from the parallel converter 15 to the switching element 12 through the second input winding, the output winding and the first input winding of the first transformer 11 is the first. It is suppressed by the leakage inductances 1 and 2 between the second input winding and the first input winding of the transformer 11.

FIG. 17 is a block diagram showing an embodiment embodying the uninterruptible power supply device 10 of FIG. In FIG. 17, the same or equivalent parts as those in FIG. 15 are designated by the same reference numerals.

When the AC input voltage is normal, the parallel converter control unit 143 synchronizes the AC voltage of the parallel converter 15 with the AC input voltage, and the phase of the AC voltage of the parallel converter 15 matches the phase of the AC input voltage. As described above, the parallel converter 15 is controlled.

Further, the parallel converter control unit 143 controls the charger 18 based on the DC current detection value Idc of the DC current detector 146 and the DC voltage detection value Vdc of the DC voltage detector 147. The charger 18 charges the power storage device 16 with a constant current and a constant voltage. The series inverter 14 and the second transformer 13 stabilize the voltage applied to the load 40. Since the operation is the same as that of the embodiment shown in FIG. 11, the description thereof will be omitted.

When the voltage of the AC input becomes abnormal, the parallel converter 15 performs a backup operation in the same manner as in the embodiment of FIG. At this time, the charger 18 stops operating and does not charge the power storage device 26.

As described above, the parallel converter 15 does not charge the power storage device 16 when the AC input is normal, and performs a backup operation when the voltage of the AC input becomes abnormal. Further, when switching to the backup operation, the short-circuit current flowing from the parallel converter 15 to the switching element 12 through the first transformer 11 is a leakage inductance between the first input winding and the output winding of the first transformer 11. It is suppressed by the leakage inductance 2 between the first and second input windings and the output winding.

The above embodiment is an uninterruptible power supply configured as a single-phase machine, but the uninterruptible power supply can also be configured as a three-phase machine.

FIG. 18 shows an embodiment when the uninterruptible power supply device of the present invention is a three-phase machine.

In this embodiment, three uninterruptible power supply devices having the configuration shown in FIG. 15 are used, and the first transformers 11-1, 11-2, and 11-3 are connected by Δ-Y. The connection of the first transformer may be Δ-Δ, Y-Δ, or YY. Further, a three-phase machine can also be configured by using three uninterruptible power supply devices having the configuration shown in FIG.

FIG. 19 is a diagram showing an example of a specific configuration of the first transformer 11 (11-1, 11-2, 11-3).

In the first transformer 11 (11-1, 11-2, 11-3) of this example, the first input winding 162, the second input winding 163, and the output winding 164 are arranged in the same iron core 161. Has a structure. The iron core 161 has an outer peripheral core and a central core, and the first input winding 162, the second input winding 163, and the output winding 164 are wound around the central core, and the outer peripheral core and the first input winding are wound. A spacer 165 is arranged between the and the second input winding.

The first input winding 162 is located above the output winding 164 and the second input winding 163 is located below the output winding 164, with the first input winding 162 and the output winding 164. A "path core" 166 formed by stacking magnetic materials, for example, silicon steel plates, is inserted between the coil and the output winding 164 and the second input winding 163, respectively. As a result, an intentional leakage inductance 1 is provided between the first input winding 162 and the output winding 164 and between the output winding 164 and the second input winding 163, respectively.

Although the embodiments have been described above, the present invention is not limited to the above embodiments, but includes various modifications within the scope of the technical idea of the invention described in the claims. ..

10 ... Uninterruptible power supply (uninterruptible power supply)
11 ... First transformer (another transformer)
12 ... Switching element (thyristor)
13 ... Second transformer
14 ... Series inverter 15 ... Parallel converter 16 ... Power storage device (storage battery)
17 ... LC filter 18 ... Charger 20 ... Current detector 30 ... Solar power generation device (solar power generation unit)
31 ... Independent operation outlet 40 ... Load 50 ... Commercial power supply 81 ... Series inverter control unit 82 ... Load voltage detector 83 ... Parallel converter control unit 84 ... AC input 1 voltage detector 85 ... AC input 2 voltage detector 86 ... DC Current detector 87 ... DC voltage detector 88 ... Parallel converter AC output voltage detector 91 ... PWM control unit 101 ... PLL
102 ... Effective value calculator 103 ... Effective value calculator 104 ... Multiplier 105 ... PWM control unit 161 ... Iron core 162 ... First input winding 163 ... Second input winding 164 ... Output winding 165 ... Spacer 166 ... Path core

Claims (6)

A power supply line in which an AC input is supplied to one end side via a switching element, and an AC output is supplied from the primary winding to a load via a transformer having a primary winding and a secondary winding on the other end side. When,
A series inverter that is connected to the secondary winding of the transformer and performs power conversion,
A parallel converter that is connected to the power supply line and performs power conversion,
An uninterruptible power supply unit is configured by providing a power storage device connected to both the DC side of the series inverter and the DC side of the parallel converter.
A photovoltaic power generation unit that is connected in parallel to the load connected to the transformer and has a power generation suppression control function.
A current detector that detects the current value of reverse power flow generated in the photovoltaic power generation unit, and
A series inverter control unit that controls the series inverter so that the current value of the reverse power flow becomes 0 and adjusts the output voltage of the transformer.
A photovoltaic power generation control device characterized by being equipped with. Another transformer having a first input winding and a second input winding is connected between the switching element and the transformer.
The parallel converter is connected to the second input winding of the other transformer.
The photovoltaic power control device according to claim 1, wherein the transformer is connected to an output winding having a leakage inductance of the other transformer. The photovoltaic power generation control device according to claim 1, wherein the series inverter, the parallel converter, and the power storage device are connected in parallel to the secondary winding of the transformer. The photovoltaic power generation control device according to any one of claims 1 to 3, wherein the current detector is connected to the AC input side of the switching element. The photovoltaic power generation control device according to any one of claims 1 to 3, wherein the current detector is connected to the parallel converter side from a connection point between the DC line of the series inverter and the power storage device. The photovoltaic power generation control device according to any one of claims 1 to 5, wherein the switching element is composed of a pair of thyristors connected in antiparallel.

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