JPH0833211A - Inverter - Google Patents

Abstract

PURPOSE:To enhance the utilization rate of output from a solar cell by preventing the power conversion efficiency of an inverter from lowering due to lowering of output at the solar cell caused by lowering of insolction. CONSTITUTION:The inverter comprises a plurality of power conversion units 3a-3c connected in parallel for converting DC power from a solar cell 2 into AC power, and means 4 for controlling the number of conversion units 3a-3c to be started depending on the output from the solar cell 2. When the output from the solar cell drops due to lowering of insolation, the number of power conversion units to be started is decreased thus operating the system at high power conversion efficiency.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an inverter device (inverse conversion device) for converting DC power from a solar cell into AC power.
More specifically, the present invention relates to an inverter device suitable for a photovoltaic power generation system that is interconnected with a commercial system.

[0002]

2. Description of the Related Art FIG. 5 is a schematic configuration diagram of a conventional photovoltaic power generation system which is operated in connection with a commercial grid 11.
The solar power generation system includes a solar cell 2 and this solar cell 2
And a supply inverter device 1 ₀ DC power is converted into AC power to the load 10 side from the power conversion unit the inverter apparatus 1 ₀ is a main circuit portion for converting power (inverter circuit) 3 _0, and a control circuit 4 ₀ to control the power conversion unit 3 _0.

[0003]

Inverter device 1
_{Since 0} is directly connected to the solar cell 2, its rated input capacity is substantially equal to the rated output capacity of the solar cell 2.

[0004] Input power to the power conversion unit 3 ₀ of the inverter apparatus 1 _0, is determined by the output power of the solar cell 2, the output power of the solar cell 2 is dependent like solar irradiance, a power conversion input power unit 3 ₀ also varies depending on the intensity of solar radiation.

[0005] Between the power conversion unit 3 ₀ the output power and the power conversion efficiency, as shown in the characteristic diagram of FIG. 6, the relationship is established that improved power conversion efficiency as the output power increases .

[0006] Thus, for example, when the sunlight intensity decreases the output power of the solar battery 2 drops are ₀ inverter device 1 is low power operation, therefore, that the power conversion efficiency is operated in a low state Therefore, the effective use of the output of the solar cell 2 is hindered.

The present invention has been made in view of the above points, and suppresses the decrease in the power conversion efficiency of the inverter device due to the decrease in the output of the solar cell to improve the utilization efficiency of the output of the solar cell. The purpose is to raise.

[0008]

In order to achieve the above-mentioned object, the present invention is constructed as follows.

That is, the inverter device according to claim 1 is
A plurality of power conversion units connected in parallel to each other for converting DC power from the solar cell into AC power, and control means for controlling the number of the power conversion units to be activated according to the output of the solar cell. There is.

In the inverter device according to a second aspect of the present invention, the control means includes a detection section for detecting the output power of the solar cell, and a storage section in which rated power data by the combination of the power conversion units is stored in advance. The number of the power conversion units to be activated is controlled based on the output power of the solar cell detected by the detection unit and the rated power data.

According to another aspect of the inverter device of the present invention, the control means changes the starting order of the power conversion units each time the inverter device starts operating.

An inverter device according to a fourth aspect of the invention is connected to a commercial system.

[0013]

According to the first aspect of the present invention, the number of activated power conversion units connected in parallel to each other is controlled according to the fluctuation of the output of the solar cell. When the output of the battery decreases, the inverter device can be operated in a state where the power conversion efficiency is high by reducing the number of activated power conversion units.

According to the present invention of claim 2, rated power data for a combination of power conversion units is stored in advance, and power conversion is started based on the detected output power of the solar cell and the rated power data. Since the number of units is controlled, the power conversion unit can be efficiently started according to the output power of the solar cell.

According to the third aspect of the present invention, the starting order of the power conversion units is changed every time the inverter device starts operating. Therefore, in a long-term use, among the plurality of power conversion units. It is possible to balance the operating time of each unit by preventing the operating time of a specific unit from becoming extremely long or short.

According to the present invention of claim 4, it can be suitably implemented in a solar power generation system or the like connected to a commercial system.

[0017]

Embodiments of the present invention will now be described in detail with reference to the drawings.

FIG. 1 is a schematic configuration diagram of an embodiment of the present invention, in which parts corresponding to those of the conventional example of FIG. 5 are designated by the same reference numerals.

In this embodiment, description will be made by applying it to a solar power generation system which is operated in connection with the commercial system 11. The solar power generation system includes a solar cell 2 and an inverter device 1 according to the present invention that converts DC power from the solar cell 2 into AC power and supplies the AC power to the load 10.

The inverter device 1 of this embodiment performs power conversion in a high power conversion efficiency state regardless of fluctuations in the output of the solar cell 2 due to fluctuations in solar radiation intensity and the like, and the utilization efficiency of the output of the solar cell 2 is improved. In order to increase the, it is configured as follows.

That is, the inverter device 1 of this embodiment
Is a plurality of units connected in parallel to each other, in this embodiment 3
Power conversion units 3a to 3c, a control circuit 4 that controls the number of power conversion units 3a to 3c to be activated according to the output of the solar cell 2, and a DC current detector that measures the input and output of the inverter device 1. 6, a direct current voltage detector 7, an alternating current detector 8 and an alternating current voltage detector 9, and an interconnection relay 5 for disconnecting the solar power generation system from the commercial grid 11, Each detector 6-9
And the contact signal of the interconnection relay 5 are given to the control circuit 4.

The rated input capacity of this inverter device 1 is
It becomes the sum of the rated input capacities of the three power conversion units 3a to 3c, and this sum is made substantially equal to the rated output capacity of the solar cell 2. In this embodiment, the rated input of each of the power conversion units 3a to 3c. The capacities are equal.

Each of the power conversion units 3a to 3c has a structure similar to that of the conventional example, and as shown in FIG. 2, a bridge system including a backflow prevention diode 12, a capacitor 13, and four switching elements Q1 to Q4. The inverter circuit 14, the reactor 15 as an AC filter, the capacitor 16, and the drive circuit 17 for driving each of the switching elements Q1 to Q4 are provided.
A drive signal from the above-mentioned control circuit 4 is given to.

FIG. 3 is a block diagram showing the configuration of the control circuit 4. In FIG. 3, 25 is a power conversion unit 3a.
3 c is a power factor 1 control circuit for matching the phase of the output current Iout with the phase of the output voltage Vout, and 24 is a sine wave pattern generation circuit 23 so that the product of the output current Iin of the solar cell 2 and the output voltage Iout is maximized. The maximum power control circuit for adjusting the amplitude of the sine wave pattern generated in step 22 is an error amplifier circuit to which the triangle wave signal from the sine pattern and triangle wave signal generating circuit 21 is given, and 20 is based on the output of this error amplifier circuit 22. A PWM control circuit that outputs a drive signal (PWM signal) to the power conversion units 3a to 3c. The above configuration is the same as the configuration of the control circuit of the conventional example.

In the control circuit 4 of this embodiment, the solar cell 2
Power conversion units 3a to 3c that are activated according to the output of
A power conversion unit operation signal generation circuit 26 is provided to control the number of units.

This power conversion unit operation signal generation circuit 2
Reference numeral 6 denotes a multiplication circuit 30 that calculates output power from the output current Iin and output voltage Iout of the solar cell that are respectively supplied from the DC current detector 6 and the DC voltage detector 7 that form the detection unit, and the power conversion units 3a to 3c. Based on the contact signal of the interconnecting relay 5 and the storage circuit 31 in which the rated power data by the combination of is stored in advance and the startup order data of the three power conversion units 3a to 3c is stored in advance. A count circuit 32 that integrates the number of times of operation of the device, a comparison circuit 28 that compares the output power from the multiplication circuit 30 with the rated power data of the storage circuit 31,
A start-up order setting circuit 29 that sets the start-up order based on the start-up order data of the memory circuit 31 and the integrated value of the count circuit 32, and the output of the comparison circuit 28 and the start-up order setting circuit 2
The operation signal setting circuit 27 that forms and outputs the operation signal based on the output of 9 and the three AND gates 33a to 33c individually corresponding to the power conversion units 3a to 3c are provided. A drive signal (PWM signal) is applied from the PWM control circuit 20 to the drive circuit 17 of the corresponding power conversion unit 3a to 3c via the AND gates 33a to 33c to which the high-level operation signal from the setting circuit 27 is applied. Is configured.

In this embodiment, the power conversion units 3a ...
3c is the starting order of the conversion units 3a to 3c in the long term.
Inverter device 1 in order to balance the operating time of
Each time the operation is started, the starting order of the conversion units 3a to 3c is changed according to the starting order data of Table 1 stored in the storage circuit 31 in advance.

[0028]

[Table 1]

In other words, a combination number that coincides with the remainder obtained by accumulating the number of startups of the inverter device 1 by the contact signal of the interconnection relay 5 and dividing this integrated value by the number n (= 3) of the power conversion units 3a to 3c. Is to set the startup order of. The activation order setting circuit 29 sets the activation order.

On the other hand, regarding the operating number of the power conversion units 3a to 3c, rated power data by the combination of the power conversion units 3a to 3c, in this embodiment, the rated input power Q (= rated output power / conversion efficiency) and the number of units. n (=
1 to 3) are stored in advance, the output power P is calculated from the output current Iin and the output voltage Iout of the solar cell 2 by the multiplication circuit 30, and the output power P and the rated input power Q × n (of the inverter device 1 are calculated. The number of operating units is set by comparing n = 1 to 3) by the comparison circuit 28 and finding n such that P ≦ Q × n.

Based on the starting order and the number of operating power conversion units 3a to 3c thus set, each of the power conversion units 3a to 3c in the operation signal setting circuit 27.
Set the driving signal of c.

For example, at the start of the first operation of the inverter device 1, first, one power conversion unit 3b is started according to the starting order of the combination number "1" in Table 1, and the input impedance of the inverter device 1 is changed. The operating point of the solar cell 2 is changed to move from the open voltage side of the solar cell 2 to the maximum power point.

If the output of the solar cell 2 at the maximum output point is less than or equal to the rated input capacity of the power conversion unit 3b, the operation of the inverter device 1 is continued in this state.

Further, when the output of the solar cell 2 becomes equal to the rated input power of the power conversion unit 3b before the operating point of the solar cell 2 reaches the maximum power point, the power conversion units 3c and 3a are sequentially turned on. To start.

Further, in a state where a plurality of power conversion units, for example, three power conversion units 3b, 3c, 3a are activated, the output of the solar cell 2 decreases due to the decrease of the solar radiation intensity, and the solar cell 2 When the output power of the power conversion unit 3a is less than the rated input capacity of the two power conversion units 3b and 3c, the power conversion unit 3a is stopped and
The electric power conversion units 3b and 3c are operated.

In this way, the number of activated power conversion units 3a to 3c is controlled according to the fluctuation of the output power of the solar cell 2, and the power conversion units 3a to 3c are controlled with high power conversion efficiency.
Since 3c is operated, the output of the solar cell 2 is converted into AC power with high conversion efficiency even when the intensity of solar radiation decreases,
The output of the solar cell 2 can be efficiently used. FIG. 4 is a diagram showing output-power conversion efficiency characteristics of the inverter device 1 having the above configuration. In addition, in FIG.
Lines A, B, C each have one power conversion unit
It shows the state of operating one, two, and three units. As shown in FIG. 4, the power conversion efficiency of the inverter device 1 at the time of low output is improved as compared with the power conversion efficiency of the conventional inverter device shown by the broken line.
Even when the intensity of solar radiation decreases, the output of the solar cell 2 can be converted into AC power with high power conversion efficiency.

Although the control circuit 4 including the power conversion unit operation signal generation circuit 26 may be constructed by hardware, it may be constructed by software using a microcomputer or the like.

In the above embodiment, the power conversion unit 3a is used.
Although ~ 3c is three, the present invention is not limited to three, and it goes without saying that any number may be used.

[0039]

As described above, according to the present invention, by controlling the number of startups of a plurality of power conversion units connected in parallel to each other according to the fluctuation of the output of the solar cell, when the intensity of solar radiation decreases, etc. Even when the output of the solar cell is reduced as described above, the inverter device can be operated in a state in which the power conversion efficiency is high, and thus the utilization efficiency of the output of the solar cell can be increased.

Further, since the starting order of the power conversion units is changed every time the inverter device starts operating, the operating time of the plurality of power conversion units can be balanced during long-term use.

[Brief description of drawings]

FIG. 1 is a block diagram of one embodiment of the present invention.

FIG. 2 is a configuration diagram of the power conversion unit in FIG.

3 is a block diagram of the control circuit of FIG.

FIG. 4 is a diagram showing output-power conversion characteristics of the inverter device of the embodiment of FIG.

FIG. 5 is a block diagram of a conventional example.

FIG. 6 is a diagram showing an output-power conversion characteristic of a conventional example.

[Explanation of symbols]

1,1 ₀ inverter 2 solar cells 3 _0, 3 a to 3 c power conversion unit 4 _0, 4 control circuit 26 power conversion unit operating signal generating circuit

Claims (4)

[Claims] 1. An inverter device for converting DC power from a solar cell into AC power, wherein a plurality of power conversion units connected in parallel for converting DC power from the solar cell into AC power, and an output of the solar cell. And a control unit that controls the number of the power conversion units to be activated according to the above. 2. The control unit includes a detection unit that detects the output power of the solar cell, and a storage unit in which rated power data obtained by combining the power conversion units is stored in advance, and the detection unit detects the detection result. The inverter device according to claim 1, wherein the number of the power conversion units to be activated is controlled based on the output power of the solar cell and the rated power data. 3. The inverter device according to claim 1, wherein the control means changes a starting order of the power conversion units every time the inverter device starts to operate. 4. The inverter device according to any one of claims 1 to 3, which is interconnected with a commercial system.