JP2015192511A - Power conditioner and power control method - Google Patents

Abstract

PROBLEM TO BE SOLVED: To improve efficiency of a DC/DC converter in a power conditioner used by being combined with a plurality of distributed power supplies.SOLUTION: A power conditioner 10 used by being combined with a plurality of distributed power supplies comprises: a plurality of DC/DC converters 101, each of which changes an output voltage of a corresponding distributed power supply; an inverter 102 for converting, in a lump, output voltages of the DC/DC converters 101 to an AC voltage; and a control unit 104 for controlling an input voltage of the inverter 102 on the basis of output voltages of the distributed power supplies.

Description

  The present invention relates to a power control apparatus used in combination with a distributed power supply and a control method thereof.

  In recent years, a system in which a distributed power source such as a solar power generation system, a fuel cell, and a storage battery is provided in a consumer and electric power is supplied in conjunction with a system has been put into practical use. When the power generated by the distributed power supply is linked to the grid, a DC voltage is converted into an AC voltage by a power conditioner (power control device) (see, for example, Patent Document 1).

  A power conditioner usually includes an inverter, and the inverter converts a DC voltage into an AC voltage. An input voltage to an inverter (hereinafter referred to as “link voltage”) is conventionally fixed at a predetermined voltage and used.

  A DC / DC converter is connected to the output of each distributed power supply, and the output voltage of the distributed power supply is converted into a predetermined link voltage by stepping up or down.

JP 2007-049770 A

  In general, the efficiency of a DC / DC converter deteriorates as the step-up / step-down ratio increases. Conventionally, the link voltage is often fixed at a non-optimal voltage from the viewpoint of the efficiency of the DC / DC converter, and the difference between the output voltage of the distributed power supply and the link voltage is often large. As a result, the step-up / step-down ratio of the DC / DC converter is increased, causing a reduction in efficiency of the DC / DC converter.

  Further, when the power conditioner is used in combination with a plurality of distributed power supplies, a plurality of DC / DC converters are used. However, since the output voltages of the respective distributed power supplies are various, the step-up / step-down ratio of the DC / DC converter is further increased. There has been a problem that the efficiency is lowered and the reduction in efficiency becomes more remarkable.

  An object of the present invention made in view of such points is to provide a power control device and a power control method capable of improving the efficiency of a DC / DC converter in a power control device used in combination with a plurality of distributed power sources. It is in.

  In order to solve the above problems, a power control apparatus according to the present invention is a power control apparatus used in combination with a plurality of distributed power supplies, each of which includes a plurality of DC / DC converters that change the output voltage of each distributed power supply. An inverter that collectively converts the output voltages of the plurality of DC / DC converters into an AC voltage, and a control unit that controls the input voltage of the inverter based on the output voltages of the plurality of distributed power sources. is there.

  In the power control apparatus according to the present invention, it is preferable that the control unit controls an input voltage of the inverter so that a total sum of power losses of the plurality of DC / DC converters is minimized.

  Further, in the power control apparatus according to the present invention, the control unit controls the input voltage of the inverter so that the power loss of the DC / DC converter connected to the distributed power source having the largest output power is minimized. Is preferred.

  Further, in the power control apparatus according to the present invention, the control unit controls the input voltage of the inverter so that the input voltage to the inverter becomes a substantially average value of the output voltages of the plurality of distributed power sources. preferable.

  Further, in the power control apparatus according to the present invention, the control unit is configured so that an input voltage to the inverter is equal to a maximum output voltage among the output voltages of the plurality of distributed power sources. It is preferable to control the input voltage.

  In the power control apparatus according to the present invention, it is preferable that all of the plurality of DC / DC converters are step-up DC / DC converters.

  Further, in the power control apparatus according to the present invention, the control unit is configured so that an input voltage to the inverter is equal to a minimum output voltage among the output voltages of the plurality of distributed power sources. It is preferable to control the input voltage.

  In the power control apparatus according to the present invention, it is preferable that the plurality of DC / DC converters are all step-down DC / DC converters.

  In order to solve the above problems, a power control method according to the present invention is a power control apparatus used in combination with a plurality of distributed power supplies, each of which includes a plurality of DC / DCs that change the output voltage of each distributed power supply. A power control method in a power control apparatus comprising a converter and an inverter that collectively converts output voltages of the plurality of DC / DC converters into an AC voltage, the input voltage to the inverter being changed, and the DC A step of controlling the degree of step-up or step-down of the DC converter.

  According to the present invention, the efficiency of a DC / DC converter can be improved in a power control device used in combination with a plurality of distributed power supplies.

1 is a block diagram illustrating a schematic configuration of a power control apparatus according to an embodiment of the present invention. It is a figure which shows an example of the relationship between the efficiency of a DC / DC converter, and the step-up ratio of a loss rate. It is a figure which shows an example of a mode that pressure | voltage rise or pressure | voltage fall of the output of a distributed power supply etc. is carried out to a link voltage. It is a figure which shows the calculation example of the link voltage which makes the sum total of electric power loss the minimum. It is a figure which shows an example of a mode that pressure | voltage rise or pressure | voltage fall of the output of a distributed power supply etc. is carried out to a link voltage. It is a figure which shows an example of a mode that pressure | voltage rise or pressure | voltage fall of the output of a distributed power supply etc. is carried out to a link voltage. It is a figure which shows an example of a mode that pressure | voltage rise or pressure | voltage fall of the output of a distributed power supply etc. is carried out to a link voltage.

  Hereinafter, embodiments according to the present invention will be described with reference to the drawings.

  FIG. 1 is a block diagram showing a schematic configuration of a power control apparatus 10 according to an embodiment of the present invention. The power control device 10 is used in combination with a plurality of distributed power sources (solar power generation device 21, fuel cell 22, storage battery 23). In addition, the power control device 10 can supply a DC voltage to the DC power supply device 24. The power control apparatus 10 includes a plurality of DC / DC converters 101, an inverter 102, a storage unit 103, and a control unit 104.

  The DC / DC converter 101 boosts or steps down the DC voltage output from the distributed power supply to the link voltage and supplies it to the inverter 102. For example, the DC / DC converter 101-1 raises or lowers the DC voltage output from the solar power generation device 21 to the link voltage and supplies it to the inverter 102.

  The storage battery 23 can also store electricity, and in this case, the DC / DC converter 101-3 supplies a DC voltage to the storage battery 23.

  The power control device 10 can also supply a DC voltage to the DC power supply device 24. For example, in the example shown in FIG. 1, the DC / DC converter 101-4 supplies a DC voltage to the DC power supply device 24. To do.

  The combination of the power control device 10 with the solar power generation device 21, the fuel cell 22, and the storage battery 23 as a distributed power source is merely an example, and may be combined with other types of power generation devices. For example, wind power generation may be used instead of solar power generation as natural energy power generation, or both may be used. Further, although the configuration in which the power control apparatus 10 supplies a DC voltage to the DC power supply apparatus 24 is shown, this is arbitrary, and the power control apparatus 10 does not have to supply the DC voltage to the DC power supply apparatus 24.

  The inverter 102 converts the DC voltage supplied from the plurality of DC / DC converters 101 into an AC voltage at a time. The AC voltage output from the inverter 102 can be linked to the grid. The inverter 102 includes an element such as an IGBT (Insulated Gate Bipolar Transistor), for example, and generates a sine wave AC voltage from the DC voltage by, for example, PWM (Pulse Width Modulation) control.

  The storage unit 103 stores, for each DC / DC converter 101, a data table for obtaining a loss rate from the input voltage and the output voltage and / or a calculation formula for calculating the loss rate from the input voltage and the output voltage. . The power control apparatus 10 according to the present embodiment can efficiently operate the DC / DC converter 101 using the data table or the calculation formula. Details of the control will be described later.

  The control unit 104 controls and manages the entire power control apparatus 10 and can be configured by a processor, for example. The control unit 104 performs control so as to change the input voltage (link voltage) of the inverter 102. Further, the control unit 104 controls the step-up or step-down ratio so that the input voltage of each DC / DC converter 101 becomes a desired voltage of each distributed power source according to the change of the link voltage.

  For example, the control unit 104 changes the link voltage at the time of installation or when the number of distributed power sources increases.

  As described above, according to the present embodiment, the control unit 104 controls the input voltage to the inverter 102 to be changed, whereby the efficiency of the DC / DC converter 101 can be improved.

(Minimization of total power loss)
Hereinafter, control for minimizing the total power loss of the plurality of DC / DC converters 101 will be described with a specific example.

The power loss of the DC / DC converter 101 is
It can be expressed by the relationship of power loss = loss rate × input power.

  FIG. 2A shows an example of a graph showing the dependency of the efficiency of the DC / DC converter 101 on the boost ratio. As shown in FIG. 2A, when the step-up ratio is 1, the DC / DC converter 101 operates at the maximum efficiency, and the efficiency decreases as the step-up ratio becomes larger than 1. Further, the efficiency decreases as the step-up ratio becomes smaller than 1, that is, as the step-down ratio becomes larger than 1.

  FIG. 2B is a graph showing the relationship with the step-up ratio, with the vertical axis representing the loss rate of the DC / DC converter 101. In the example shown in FIG. 2B, when (boost ratio-1) = 0, that is, when the boost ratio is 1, the loss rate is 0%, and the loss rate increases as the boost ratio increases. Thus, the loss rate is substantially proportional to “boost ratio-1”.

Here, when the output power of the solar power generation device 21 is Pp, the output voltage is Vp, and the link voltage is VL, the power loss of the DC / DC converter 101-1 connected to the solar power generation device 21 is simply as follows. It can be expressed as
α _p | VL / Vp−1 | × Pp = α _p | VL−Vp | / Vp × Pp
Here, α _p is a coefficient specific to the DC / DC converter 101-1.

Furthermore, if we define
Output power of fuel cell 22: Ps
Output voltage of fuel cell 22: Vs
Output power of storage battery 23: Pb
Output voltage of storage battery 23: Vb
DC power supply 24 input power: Pd
DC power supply 24 input voltage: Vd
The total power loss of the plurality of DC / DC converters 101 can be simply expressed as follows.
α _p | VL−Vp | / Vp × Pp + α _s | VL−Vs | / Vs × Ps + α _b | VL−Vb | / Vb × Pb + α _d | VL−Vd | / Vd × Pd
Here, α _s , α _b, and α _d are coefficients specific to the DC / DC converter 101-2, the DC / DC converter 101-3, and the DC / DC converter 101-4, respectively.

  The control unit 104 calculates the link voltage VL that minimizes the total power loss using the above equation, and controls the inverter 102 so that the input voltage of the inverter 102 becomes the link voltage VL.

  In addition, when connecting to the grid, there is a minimum voltage Vmin that can be set as a link voltage, and therefore the control unit 104 has a link voltage VL that minimizes the sum of power losses smaller than the minimum voltage Vmin that can be set. In this case, the inverter 102 is controlled so that the input voltage of the inverter 102 becomes the minimum voltage Vmin.

  The above equation is a simple example. For example, when the step-up / step-down ratio of a certain DC / DC converter 101 is as close as possible to 1, the step-up / step-down operation may not be stable in terms of control. Since the loss can be reduced by stopping the control, the control unit 104 can also correct the operating voltage in consideration of this point.

  FIG. 3A shows the state of step-down or step-up of each DC / DC converter 101 when the input voltage of the inverter 102 is set to the link voltage VL that minimizes the total power loss. The PV, FC, BT, and DC power supplies are respectively a DC / DC converter 101-1 connected to the solar power generation device 21, a DC / DC converter 101-2 connected to the fuel cell 22, and a DC / DC connected to the storage battery 23. The state of step-up or step-down of the DC / DC converter 101-4 connected to the converter 101-3 and the DC power supply device 24 is shown. In each bar graph, the hatched portion indicates the voltage on the power supply device side (solar power generation device 21, fuel cell 22, storage battery 23, DC power supply device 24) of the DC / DC converter 101, and the arrow indicates the amount of step-up or step-down.

  FIG. 3B shows a conventional state in which the high link voltage VL0 is fixed for comparison.

  FIG. 4 shows an example in which the link voltage that minimizes the total power loss is calculated. FIG. 4 shows the case where the output voltage of the solar power generation device 21 is 250 V, the output voltage of the fuel cell 22 is 90 V, the output voltage of the storage battery 23 is 300 V, and the input voltage to the DC power supply device 24 is 141 V. The calculated link voltage is shown in the case where the input power and the input power to the DC power supply device 24 take various values.

  For example, according to the data in the first row, the output power of the solar power generation device 21 is 3 kW, the output power of the fuel cell 22 is 1 kW, the output power of the storage battery 23 is 5 kW, and the input power to the DC power supply device 24 is 1 kW. In this case, the link voltage that minimizes the total power loss is 231V.

  In the example of the sixth row, the value calculated by the control unit 104 is a value smaller than 170V, but the link voltage is 170V because it is lower than the minimum voltage Vmin = 170V that can be set.

  As described above, according to the present embodiment, the control unit 104 controls each DC / DC converter 101 and the inverter 102 such that the sum of the power losses of the plurality of DC / DC converters 101 becomes a minimum link voltage. Therefore, the efficiency of the DC / DC converter 101 can be improved.

(Minimization of power loss of distributed power sources with high impact)
The control unit 104 can also control the link voltage VL so as to minimize the power loss of the DC / DC converter 101 connected to the distributed power source having the greatest influence, that is, the distributed power source having the largest output power. .

For example, when the output power of the solar power generation device 21 is the largest, it is a power loss of the DC / DC converter 101-1 connected to the solar power generation device 21.
α _p | VL−Vp | / Vp × Pp
The control unit 104 can control the link voltage VL so that the link voltage VL is minimized.

  In FIG. 5, each DC / DC converter 101 when the link voltage is set to the link voltage VL that minimizes the power loss of the DC / DC converter 101-1 connected to the photovoltaic power generation device 21 having the largest output power. The state of step-down or step-up is shown.

(Average output voltage)
The control unit 104 can also control the link voltage VL so that the link voltage VL is about the average value of the output voltages of the plurality of distributed power sources. FIG. 6 shows the state of step-down or step-up of each DC / DC converter 101 in this case.

(Unified to the maximum output voltage)
The control unit 104 can also control the link voltage VL so that the link voltage VL is equal to the maximum output voltage among the output voltages of the distributed power supplies. FIG. 7A shows an example when the output voltage of the storage battery 23 is the maximum output voltage.

  In this way, the DC / DC converter 101 is configured only by the boost DC / DC converter by making the link voltage VL equal to the maximum output voltage of the output voltages of the distributed power supplies. Therefore, the cost for the DC / DC converter can be reduced. In addition, the DC / DC converter connected to the distributed power supply with the maximum output voltage can be omitted, and the cost can be further reduced by omitting the DC / DC converter.

(Unified to the minimum output voltage)
The control unit 104 can also control the DC / DC converter 101 so that the link voltage VL is equal to the minimum output voltage among the output voltages of the distributed power supplies. FIG. 7B shows an example when the output voltage of the fuel cell 22 is the minimum output voltage.

  As described above, the DC / DC converter 101 is configured by only the step-down DC / DC converter by making the link voltage VL equal to the minimum output voltage of the output voltages of the distributed power supply. Therefore, the cost for the DC / DC converter can be reduced. Further, the DC / DC converter connected to the distributed power source with the minimum output voltage can be omitted, and the cost can be further reduced by omitting the DC / DC converter.

  Although the present invention has been described based on the drawings and examples, it should be noted that those skilled in the art can easily make various modifications and corrections based on the present disclosure. Therefore, it should be noted that these variations and modifications are included in the scope of the present invention.

  For example, in the present embodiment, the power control device 10 has been described as being linked to the grid, but the power control device 10 may not be linked to the grid.

DESCRIPTION OF SYMBOLS 10 Electric power control apparatus 21 Solar power generation device 22 Fuel cell 23 Storage battery 24 DC power supply apparatus 101 DC / DC converter 102 Inverter 103 Memory | storage part 104 Control part

Claims (9)

A power control device used in combination with a plurality of distributed power sources,
A plurality of DC / DC converters each changing the output voltage of each distributed power source;
An inverter that collectively converts the output voltages of the plurality of DC / DC converters into an AC voltage;
A control unit that controls an input voltage of the inverter based on output voltages of the plurality of distributed power sources;
A power control apparatus comprising:   2. The power control device according to claim 1, wherein the control unit controls an input voltage of the inverter so that a total sum of power losses of the plurality of DC / DC converters is minimized. Control device.   2. The power control device according to claim 1, wherein the control unit controls the input voltage of the inverter so that the power loss of the DC / DC converter connected to the distributed power source having the largest output power is minimized. Control device.   2. The power control device according to claim 1, wherein the control unit controls the input voltage of the inverter so that an input voltage to the inverter becomes a substantially average value of output voltages of the plurality of distributed power sources. 3. apparatus.   2. The power control device according to claim 1, wherein the control unit is configured so that an input voltage to the inverter is equal to a maximum output voltage of output voltages of the plurality of distributed power sources. A power control device that controls the input voltage.   6. The power control apparatus according to claim 5, wherein the plurality of DC / DC converters are all step-up DC / DC converters.   2. The power control device according to claim 1, wherein the control unit is configured so that an input voltage to the inverter is equal to a minimum output voltage among output voltages of the plurality of distributed power sources. A power control device that controls the input voltage.   8. The power control apparatus according to claim 7, wherein the plurality of DC / DC converters are all step-down DC / DC converters. A power control device used in combination with a plurality of distributed power sources, each of which changes a plurality of DC / DC converters that change the output voltage of each of the distributed power sources, and the output voltages of the plurality of DC / DC converters collectively AC A power control method in a power control device comprising: an inverter that converts voltage;
A power control method comprising: changing an input voltage to the inverter and controlling a degree of step-up or step-down of the DC / DC converter.

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