JP2016052238A - Power conversion system, power conversion device, power conversion method, and power conversion program - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a power conversion system, power conversion device, power conversion method, and power conversion program capable of more efficiently transmitting power supplied from a power generation facility to a facility of a power transmission destination.SOLUTION: A power conversion system of an embodiment includes a conversion unit, a detection unit, a power determination unit, and a control unit. The conversion unit converts input DC power to AC power. The detection unit detects a current and voltage of the AC power converted by the conversion unit. The power determination unit determines whether or not calculation power calculated on the basis of the current and voltage detected by the detection unit is equal to or greater than preset setting power. The control unit controls the conversion unit so that a power factor of the conversion unit reduces when it is determined by the power determination unit that the calculation power is equal to or greater than the setting power.SELECTED DRAWING: Figure 2

Description

  Embodiments described herein relate generally to a power conversion system, a power conversion device, a power conversion method, and a power conversion program.

  Conventionally, a power converter for converting DC power supplied from a power generation facility into AC power is known. However, in the conventional apparatus, there are cases where the power supplied from the power generation equipment cannot be efficiently transmitted to the power transmission destination equipment due to various restrictions.

JP-A-8-317563

  The problem to be solved by the present invention is to provide a power conversion system, a power conversion device, a power conversion method, and a power conversion program capable of more efficiently transmitting power supplied from a power generation facility to a power transmission destination facility. That is.

  The power conversion system of the embodiment includes a conversion unit, a detection unit, a power determination unit, and a control unit. The conversion unit converts the input DC power into AC power. The detection unit detects the current and voltage of the AC power converted by the conversion unit. The power determination unit determines whether or not the calculated power calculated based on the current and voltage detected by the detection unit is equal to or greater than a preset set power. The control unit controls the conversion unit so as to decrease the power factor of the conversion unit when the power determination unit determines that the calculated power is equal to or higher than the set power.

The figure which shows the structural example of the power conversion system 1 of 1st Embodiment. The figure which shows the function structural example of the power converter device 20. FIG. The figure which shows the function structural example of the electric power control part. The flowchart which shows the flow of the process performed by the power converter device 20. FIG. The figure which compared the output electric power in the case where a power factor is controlled like a present Example, and the case where a power factor is not controlled. The figure which shows control of the power factor corresponding to output electric power OP. 1 is an overall configuration diagram of a power conversion system 200. FIG. The figure which shows the function structural example of the electric power control part 30 of 2nd Embodiment. The figure which shows the function structural example of the monitoring apparatus. 5 is a flowchart showing a flow of processing executed by the power conversion system 200. The figure for demonstrating the electric power which the power converter device 20 which reduces a power factor should output.

  Hereinafter, a power conversion system, a power conversion device, a power conversion method, and a power conversion program according to embodiments will be described with reference to the drawings.

(First embodiment)
FIG. 1 is a diagram illustrating a configuration example of a power conversion system 1 according to the first embodiment. The power conversion system 1 includes a plurality of power generation devices 10 (power generation array 12), a power conversion device 20, and a power supply destination 60. The power generation device 10 is, for example, a solar power generation device. The power generation device 10 is electrically connected to the power conversion device 20. The power generation device 10 converts sunlight energy into direct-current power and outputs the direct-current power to the power conversion device 20. In the power generation apparatus 10, the output DC power varies depending on the received sunlight energy. The power conversion device 20 converts the DC power supplied from the power generation device 10 into DC power having a desired current and voltage, converts the converted DC power into AC power, and supplies the AC power to the power supply destination 60. The power supply destination 60 includes, for example, a power company that purchases AC power supplied from the power converter 20, a load that uses AC power, a power storage device that stores AC power, and the like. The power generation device 10 may be a wind power generation device, a geothermal power generation device, or the like in addition to the solar power generation device.

  FIG. 2 is a diagram illustrating a functional configuration example of the power conversion device 20. The power conversion device 20 includes a power reception unit 22, a conversion unit 24, a power transmission unit 26, a pulse control unit 28, a power control unit 30, a display operation unit 42, and a communication unit 44. The pulse control unit 28, the maximum power point tracking unit 34 of the power control unit 30, which will be described later, the power determination unit 38, and the power factor control unit 39 are, for example, a processor such as a CPU (Central Processing Unit) of the power converter 20 It is a software function unit that functions by executing a program stored in (not shown). Further, the pulse control unit 28, the maximum power point tracking unit 34 of the power control unit 30 to be described later, the power determination unit 38, and the power factor control unit 39 are composed of hardware such as LSI (Large Scale Integration) and ASIC (Application Specific Integrated Circuit). It may be a wear function unit.

  The power reception unit 22 outputs the DC power transmitted from the power generation device 10 to the conversion unit 24. The conversion unit 24 includes, for example, a DC / DC converter and a DC / AC converter. For example, the DC / DC converter performs a switching operation or the like on the basis of the signal S1 generated by the pulse control unit 28 to convert the DC power output by the power receiving unit 22 into DC power having a desired current and voltage. . The DC / DC converter outputs the converted direct current power to the DC / AC converter.

  The DC / AC converter converts the direct current power output from the DC / DC converter into alternating current power by performing a switching operation and the like based on the signal S2 generated by the pulse control unit 28. The DC / AC converter outputs the AC power converted by the own device to the power transmission unit 26. The power transmission unit 26 transmits the AC power output by the DC / AC converter to the power supply destination 60.

  The pulse control unit 28 generates a signal S1 for performing pulse width modulation (PWM) control based on the signal generated by the maximum power point tracking unit 34. Further, the pulse control unit 28 generates a signal S2 for performing, for example, pulse width modulation control based on the signal generated by the power factor control unit 39. The pulse control unit 28 outputs signals S1 and S2 that determine the current (A) and voltage (Vm) output from the DC / DC converter and the AC / DC converter by pulse width modulation.

  FIG. 3 is a diagram illustrating a functional configuration example of the power control unit 30. The power control unit 30 includes a DC current detection unit 32, a DC voltage detection unit 33, a maximum power point tracking unit 34, an AC current detection unit 36, an AC voltage detection unit 37, a power determination unit 38, and a power factor. And a control unit 39.

  The direct current detection unit 32 detects the current value of the direct current power output by the power reception unit 22. The DC voltage detection unit 33 detects the voltage value of the DC power output by the power reception unit 22. The maximum power point tracking unit 34 performs maximum power point tracking control (MPPT). The maximum power point tracking unit 34 uses the current value of the DC power detected by the DC current detection unit 32 and the voltage value of the DC power detected by the DC voltage detection unit 33 to output the power output by the power generator 10. The optimum current and voltage values that can be maximized (hereinafter referred to as “maximum power point”) are calculated. Since the values of the current (A) and voltage (Vm) of the power output by the power generation device 10 change depending on the amount of solar radiation and the temperature, the maximum power point tracking unit 34 has a maximum power point at a cycle that can track the change. Is calculated. The maximum power point tracking unit 34 outputs a signal corresponding to the generated maximum power point to the pulse control unit 28.

  The AC current detector 36 detects the current value of the AC power output by the converter 24. The AC voltage detection unit 37 detects the voltage value of the AC power output by the conversion unit 24. The power determination unit 38 calculates AC power (calculated power) based on the current value detected by the AC current detection unit 36 and the voltage value detected by the AC voltage detection unit 37. This AC power corresponds to the output power of the converter 24. And the electric power determination part 38 determines whether the calculated alternating current power is more than the preset setting electric power. The power factor control unit 39 outputs a signal for controlling the power factor of the conversion unit 24 so that the power factor of the conversion unit 24 is decreased when the power determination unit 38 determines that the AC power is equal to or higher than the set power. To do.

  The display operation unit 42 includes input devices such as a keyboard, a mouse, and a touch panel. The display operation unit 42 includes a display unit, and displays the amount of DC power and AC power acquired by the power control unit 30 and the result of the control executed by the power control unit 30 on the display unit.

  The communication unit 44 includes an expansion card and a NIC (Network Interface Card) for connecting to other computer devices, a monitoring device for monitoring the power conversion system 1, and a wireless communication device for performing wireless communication. .

  FIG. 4 is a flowchart showing a flow of processing executed by the power conversion device 20. First, the alternating current detection unit 36 detects the current value of the alternating current power converted by the conversion unit 24, and the alternating voltage detection unit 37 detects the voltage value of the alternating current power converted by the conversion unit 24 (step S100). ). Next, the power determination unit 38 calculates AC power based on the current value detected by the AC current detection unit 36 and the voltage value detected by the AC voltage detection unit 37 (step S102). And the electric power determination part 38 determines whether the calculated alternating current power is more than setting electric power (step S104). If the calculated AC power is not equal to or higher than the set power, one routine of this flowchart ends.

  When the AC power is equal to or higher than the set power, the power factor control unit 39 reduces the power factor so that the calculated power calculated by the conversion unit 24 approaches the set power (step S106). The power factor control unit 39 outputs a signal corresponding to the power factor to be reduced to the pulse control unit 28. The pulse control unit 28 generates a signal for performing pulse width modulation control based on the signal output from the power factor control unit 39. The DC / AC converter of the converter 24 converts DC power into AC power based on the signal generated by the pulse controller 28 and outputs the AC power to the power transmitter 26 (step S108).

  Hereinafter, output power output by the electrical conversion system 1 will be described with reference to FIGS. 5 and 6. FIG. 5 is a diagram comparing the output power when the power factor is controlled as in this embodiment and when the power factor is not controlled. The vertical axis in FIG. 5 indicates the output power [kw] output by the converter 24, and the horizontal axis indicates the power generation rate [%] of the solar power generation device. In the figure, “SP” is the set power, “OP” is the output power output by the converter 24 of the power conversion system 1 that controls the power factor, and “PP” is the power conversion system that does not control the power factor ( Hereinafter, output power output by the conversion unit of “another power conversion system”) is shown. “X” indicates a power generation rate when the output power OP matches the set power SP.

  For example, when the power conversion system 1 has a power factor of 1.0, the calculated power increases by 50 kw every time the power generation rate increases by 10%. When the power generation rate is 100%, the maximum power that can be calculated by the power conversion system 1 is 500 kw. The power factor of other power conversion systems is fixed at 0.95. In other power conversion systems, for example, every time the power generation rate increases by 10%, the calculated power increases by 47.5 kw. The maximum power that other power conversion systems can calculate is 475 kw. The set power is 475 kW.

  Here, the set power is, for example, power set by the power company when the power generated by the solar power generator is sold to the power company, and is power that the power company allows to receive. For this reason, in other power conversion systems, the power factor is fixed at 0.95 and the maximum value of the output power is suppressed to 475 kW so that the transmitted power does not exceed the set power.

  On the other hand, as shown in FIG. 5, in the power conversion system 1 of the embodiment, since the calculated power is controlled to operate at the maximum power factor (1.0) until the set power SP reaches the set power SP, the output power OP Is larger than the output power PP by “g” in the figure. Thus, since the power conversion system 1 is operating at the maximum power factor until the generated power OP exceeds the set power SP, the power conversion system 1 is more fixed than other power conversion systems operating at a power factor of 0.95. Can output large electric power. Further, when the output power OP reaches the set power SP, control is performed to reduce the power factor so that the output power OP does not exceed the set power SP. As a result, the output power OP can be prevented from exceeding the set power SP. The power conversion system 1 does not perform control based on the comparison between the output power OP and the set power SP, but operates at the maximum power factor up to the power generation rate X (95%), and the power generation rate X (95%). Control may be performed to reduce the power factor so as not to exceed the set power 475 kW if the power exceeds.

  In the power conversion system 1 of the present embodiment, the power factor is reduced only in a scene where the set power is exceeded, and otherwise the power is calculated with the maximum power factor, so that the set power is not exceeded. Compared with other power conversion systems that always limit the power factor, the power transmission efficiency can be improved as a whole.

  FIG. 6 is a diagram illustrating control of the power factor corresponding to the output power OP. The power conversion device 20 performs control so that the power factor of the conversion unit 24 is maximized up to the power generation rate X. The power conversion system 1 is operating at the maximum power factor corresponding to the power generation rates 0 to Y until the power generation rates 0 to Y. The power conversion system 1 operates at a maximum power factor of 1.0 corresponding to the power generation rates Y to X until the power generation rates Y to X. After the power generation rate X, the power factor is made smaller than 1.0 so that the output power output by the conversion unit 24 matches the set power SP. When the power factor control unit 39 determines that the output power (calculated power) output by the conversion unit 24 is equal to or greater than the set power, for example, the power factor control unit 39 divides the set power by the DC power input to the power receiving unit 22. The value is the power factor of the conversion unit 24.

  According to the power conversion system 1 of the first embodiment described above, when the power determination unit 38 determines that the calculated power is greater than or equal to the set power, the conversion unit is configured to reduce the power factor of the conversion unit 24. 24, and the power factor of the conversion unit 24 is increased (maintained at the maximum value) at other times. Therefore, it is not necessary to limit the power factor unconditionally, and the transmission efficiency can be improved as a whole. . As a result, the power conversion system 1 can more efficiently transmit the power supplied from the power generation equipment to the power transmission destination equipment.

(Second Embodiment)
The second embodiment will be described below. Here, the difference from the first embodiment will be mainly described, and description of functions and the like common to the first embodiment will be omitted. In the second embodiment, the monitoring device 70 determines whether or not the calculated power calculated by the plurality of power conversion devices 20 is greater than or equal to the set power, and if the calculated power is greater than or equal to the set power, the plurality of conversions The conversion unit 24 is controlled so that the power factor of one or more conversion units 24 among the units 24 is reduced.

  The power conversion system 200 will be described with reference to FIG. FIG. 7 is an overall configuration diagram of the power conversion system 200. The power conversion system 200 includes a plurality of solar power generation arrays 12, a plurality of power conversion devices 20-1 to 20-4, and a monitoring device 70. Hereinafter, when it is not distinguished which of the power conversion devices 20-1 to 20-4, it is simply expressed as the power conversion device 20.

  The solar power generation array 12 is configured by electrically connecting a plurality of solar power generation devices. The plurality of solar power generation arrays 12 are electrically connected to the corresponding power conversion devices 20. Each of the plurality of power conversion devices 20 is electrically connected to the power supply destination 60. The plurality of power conversion devices 20 convert the DC power generated by the corresponding solar power generation array 12 into AC power and transmit the AC power to the power supply destination 60. The power conversion device 20 transmits and receives information by performing wireless communication with the monitoring device 70 using the communication unit 44. The communication may be wired communication instead of wireless communication.

  FIG. 8 is a diagram illustrating a functional configuration example of the power control unit 30 according to the second embodiment. In addition, about the structure of the power converter device 20, FIG. 3 is used. The power control unit 30 includes a DC current detection unit 32, a DC voltage detection unit 33, a maximum power point tracking unit 34, an AC current detection unit 36, an AC voltage detection unit 37, and a power factor control unit 39. . The current value detected by the AC current detection unit 36 and the voltage value detected by the AC voltage detection unit 37 are transmitted to the monitoring device 70 by the communication unit 44. The power factor control unit 39 uses the communication unit 44 to generate a signal for controlling the power factor of the conversion unit 24 so as to reduce the power factor of the conversion unit 24 based on the acquired information.

  FIG. 9 is a diagram illustrating a functional configuration example of the monitoring device 70. The monitoring device 70 includes a power determination unit 72, a power generation array control unit 74, and a communication unit 76. The power determination unit 72 uses the communication unit 76 to acquire the current value detected by the AC current detection unit 36 and the voltage value detected by the AC voltage detection unit 37. The electric power determination part 72 calculates the output electric power (calculated electric power) in each power converter device 20 based on the acquired electric current value and voltage value, adds them, and calculates integrated electric power. The power determination unit 72 determines whether or not the integrated power is greater than or equal to the set power. The power generation array control unit 74 determines the power conversion device 20 that reduces the power factor of the conversion unit 24 among the power conversion devices 20-1 to 20-4 when the integrated power is determined to be equal to or higher than the set power. Further, the power generation array control unit 74 calculates the power (hereinafter referred to as “target power”) to be output by the selected power conversion device 20 in order to match the integrated power with the set power. The communication unit 76 transmits the target power calculated by the power generation array control unit 74 by designating the selected power conversion device 20 as a destination. Instead of the above processing, the power conversion device 20 may calculate output power (calculated power) and transmit it to the monitoring device 70. In this case, the monitoring device 70 performs a process of calculating the integrated power by summing the received output power.

FIG. 10 is a flowchart showing a flow of processing executed by the power conversion system 200. First, the electric power determination part 72 acquires the electric current value detected by the alternating current detection part 36, and the voltage value detected by the alternating voltage detection part 37 using the communication part 76 (step S200). Next, the power determination unit 72, based on the acquired current value and the acquired voltage value,
The output power (calculated power) of each power converter 20 and the integrated power that is the total value thereof are calculated (step S202). The power determination unit 72 determines whether or not the calculated integrated power is greater than or equal to the set power (step S204). If the integrated power is not greater than or equal to the set power, one routine of this flowchart ends.

  When the integrated power is greater than or equal to the set power, the power generation array control unit 74 selects the power conversion device 20 that decreases the power factor of the conversion unit 24 among the power conversion devices 20-1 to 20-4 (step S206). .

  Here, a method of selecting the power conversion device 20 that reduces the power factor of the conversion unit 24 by the power generation array control unit 74 will be described. The power generation array control unit 74 selects the power conversion device 20 that reduces the power factor of the conversion unit 24 according to, for example, priority. The monitoring device 70 stores in advance the priority of the power conversion device 20 that lowers the power factor. In the storage unit (not shown) of the monitoring device 70, for example, the power converter 20-1 has the highest priority, then the power converter 20-2 has the highest priority, and then the power converter 20-3 has the priority. Is stored, and the power converter 20-2 has the lowest priority. The priority may be associated with the power generation rate or the amount of power generated, for example. For example, the power conversion device 20 having a high power generation rate may be used as the power conversion device 20 having a high priority. The power generation array control unit 74 selects the power conversion device 20 that decreases the power factor according to the priority.

  Next, the power generation array control unit 74 calculates the power (target power) to be calculated by the power conversion device 20 that decreases the selected power factor (step S208). Here, the calculation method of the target electric power of the power converter device 20 to reduce the power factor by the power generation array control unit 74 will be described. FIG. 11 is a diagram for explaining the power to be output by the power conversion device 20 that lowers the power factor. In the figure, the left vertical axis indicates the power factor of the power conversion devices 20-1 to 20-4, and the right vertical axis indicates the power [kw]. “SP” indicates set power. The white bar graph indicates the power factor, and the hatched bar graph indicates the power calculated by each of the power conversion devices 20-1 to 20-4 and the integrated power. In the left diagram of FIG. 11, the integrated power exceeds the set power, and the excess integrated power is indicated by “CP (hereinafter referred to as“ excess power CP ”). In the example of FIG. 11, it is assumed that the power conversion device 20-1 having a high priority is selected. The power generation array control unit 74 determines whether or not the power currently output by the selected power conversion device 20-1 is equal to or greater than the excess power CP. When the power currently output by the selected power conversion device 20-1 is equal to or greater than the excess power CP, the power generation array control unit 74 causes the power conversion device 20-1 to reduce the power factor to output power (target power). ) Is calculated. The power (right diagram in FIG. 11, power P2) obtained by subtracting the excess power CP from the power output by the power electronics device 20-1 (left diagram in FIG. 11, power P1) is the target of the power converter device 20-1. It becomes electric power.

  Next, the power generation array control unit 74 uses the communication unit 76 to transmit the calculated target power to the selected power conversion device 20-1 (step S210). And the power factor control part 39 changes the power factor of the conversion part 24 so that the calculated electric power of the power converter device 20-1 may approach target power (step S212). Based on the target power transmitted from the monitoring device 70, the power factor control unit 39 of the power conversion device 20-1 changes the power factor so that the calculated power approaches the target power (power P2). Next, the power factor control unit 39 converts DC power into AC power based on the signal generated by the pulse control unit 28, and outputs the AC power to the power transmission unit 26 (step S214). The result of the converter 24 of the power converter 20-1 changing the power factor and outputting AC power is shown in the right diagram of FIG. When the conversion unit 24 of the power conversion device 20-1 changes the power factor so as to match the target power (power P2), the excess power CP is suppressed, and the integrated power is controlled to match the set power SP. Is done.

  As described above, in the power conversion system 200 according to the second embodiment, when the power determination unit 72 determines that the integrated power is equal to or higher than the set power, among the conversion units 24 of the plurality of power conversion devices 20. In order to increase (maintain) the power factor of the conversion unit 24, the conversion unit 24 is controlled so as to decrease the power factor of the conversion unit 24 of one or more power conversion devices 20. There is no need to limit the rate, and overall transmission efficiency can be improved. The power conversion system 200 can transmit the power supplied from the power generation equipment to the power transmission destination equipment more efficiently.

  In the description of the second embodiment, when the calculated power of the power conversion system 200 is suppressed, the power generation array control unit 74 calculates the target power and transmits the calculated target power to the power conversion device 20. The power generation array control unit 74 may calculate the power to be suppressed by the power conversion device 20 and the power factor to be reduced, and transmit the calculated result to the power conversion device 20. In this case, the power conversion device 20 to which the power to be suppressed or the power factor to be reduced is transmitted calculates the power factor of the conversion unit 24 based on the transmitted power to be suppressed or the power factor to be reduced. 24 may be changed to the calculated power factor.

  Moreover, in this embodiment, although the power converter 20-1 with high priority changed the power factor indefinitely so that it might match target power, even if it provides a threshold value in the power factor which a power converter lowers Good. For example, when the threshold value is set to 0.8, the power generation array control unit 74 reduces the power factor of the power conversion device 20 having the highest priority to 0.8, which is the threshold value. Accordingly, when the integrated power is equal to or higher than the set power, the power factor of the power converter 20 having the next highest priority may be lowered to the threshold value 0.8. Moreover, the power generation array control unit 74 may select the four power conversion devices 20 and reduce the power factor or the calculated power of the four power conversion devices 20 on the average.

  Moreover, in 2nd Embodiment, although the monitoring apparatus 70 was provided with the electric power determination part 72 and the electric power generation array control part 74, and calculated the target electric power, a part or all of the power converter devices 20-1 to 20-4 were. The power determination unit 72 and the power generation array control unit 74 may be provided. In this case, the power conversion devices 20-1 to 20-4 communicate with each other and change the power factor according to, for example, a preset priority. As a result, the same effects as those of the second embodiment can be achieved without providing the monitoring device 70.

  In each of the above embodiments, when the power determination unit 38 (72) determines that the output power is greater than or equal to the set power, the conversion unit 24 is controlled to reduce the power factor of the conversion unit 24. The determination by the determination unit 38 (72) and the power factor control can be changed as appropriate. For example, when the power determination unit 38 (72) determines that the output power exceeds the set power for a predetermined time, the power factor of the conversion unit 24 may be decreased. For example, when the power determination unit 38 (72) determines that the output power is less than the set power, the power factor of the conversion unit 24 may be increased.

  According to at least one embodiment described above, the conversion unit 24 reduces the power factor of the conversion unit 24 when the power determination unit 38 (72) determines that the calculated power is greater than or equal to the set power. Therefore, it is not necessary to limit the power factor unconditionally, and the transmission efficiency as a whole can be improved. As a result, the power conversion system 1 (200) can more efficiently transmit the power supplied from the power generation equipment to the power transmission destination equipment.

  Although several embodiments of the present invention have been described, these embodiments are presented by way of example and are not intended to limit the scope of the invention. These embodiments can be implemented in various other forms, and various omissions, replacements, and changes can be made without departing from the spirit of the invention. These embodiments and their modifications are included in the scope and gist of the invention, and are also included in the invention described in the claims and the equivalents thereof.

DESCRIPTION OF SYMBOLS 1,200 ... Power conversion system, 20 (20-1-20-4) ... Power converter, 24 ... Conversion part, 28 ... Pulse control part, 30 ... Power control part, 36 ... Alternating current detection part (detection part) , 37 ... AC voltage detection unit (detection unit), 38 ... Power determination unit, 39 ... Power factor control unit (control unit), 70 ... Monitoring device

Claims (10)

A converter that converts the input DC power into AC power;
A detection unit for detecting the current and voltage of the AC power converted by the conversion unit;
A power determination unit that determines whether or not the calculated power calculated based on the current and voltage detected by the detection unit is greater than or equal to a preset set power;
A control unit that controls the conversion unit to reduce the power factor of the conversion unit when the power determination unit determines that the calculated power is greater than or equal to the set power;
A power conversion device comprising: The control unit changes the power factor of the conversion unit so that the calculated power approaches the set power when the power determination unit determines that the calculated power is less than the set power.
The power conversion device according to claim 1. When the control unit determines that the calculated power is equal to or greater than the set power, a value obtained by dividing the set power by the input DC power is set as a power factor of the conversion unit.
The power converter device of Claim 1 or Claim 2. Power conversion device
The input DC power is converted into AC power by the exchange unit,
Detecting the current and voltage of the converted AC power;
It is determined whether or not the calculated power calculated based on the detected current and voltage is equal to or higher than a preset set power,
When it is determined that the calculated power is equal to or greater than the set power, control is performed so as to reduce the power factor of the exchange unit.
Power conversion method. In the control computer of the power converter,
It is determined whether or not the calculated DC power calculated based on the current and voltage of the AC power converted by the exchange unit is greater than or equal to a preset set power,
When it is determined that the calculated power is equal to or higher than the set power, control is performed so as to reduce the power factor of the exchange unit.
Power conversion program. A plurality of converters for converting input DC power into AC power;
A detection unit for detecting the current and voltage of the AC power converted by the plurality of conversion units;
A power determination unit that determines whether or not an integrated power obtained by summing the calculated power calculated based on the current and voltage detected by the detection unit for the plurality of conversion units is equal to or higher than a preset set power; ,
When the power determination unit determines that the integrated power is greater than or equal to the set power, the conversion unit is controlled to reduce the power factor of one or more conversion units among the plurality of conversion units. A control unit;
A power conversion system comprising: The control unit is configured to select one of the plurality of conversion units so that the product calculated power approaches the set power when the power determination unit determines that the integrated power is less than the set power. Changing the power factor of the conversion unit,
The power conversion system according to claim 6. The control unit calculates excess power obtained by subtracting the set power from the integrated power when it is determined that the integrated power is equal to or greater than the set power, and a conversion unit selected from the plurality of conversion units Calculating a target power obtained by subtracting the excess power from the calculated power, and dividing the target power by the DC power input to the selected converter as a power factor of the selected converter.
The power conversion system according to claim 6 or 7. The input DC power is converted into AC power by a plurality of converters,
Detecting the current and voltage of the AC power converted by the plurality of exchange units;
It is determined whether or not the calculated power calculated based on the detected current and voltage is equal to or higher than a preset set power,
When it is determined that the calculated power is equal to or higher than the set power, the conversion unit is controlled to reduce the power factor of one or more conversion units among the plurality of conversion units.
Power conversion method. In the control computer of the power converter,
It is determined whether or not the calculated DC power calculated based on the current and voltage of the AC power converted by the plurality of converters is greater than or equal to a preset set power,
When it is determined that the calculated power is equal to or higher than the set power, the conversion unit is controlled so as to decrease the power factor of one or more conversion units among the plurality of conversion units.
Power conversion program.

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