JP6050914B1 - Distributed power system and power converter - Google Patents

Abstract

Disclosed is a distributed power supply system that achieves optimization of power supply efficiency while realizing measures for suppressing an increase in system voltage. A distributed power system 1 controls a power factor of a power converter (inverter 33) to a predetermined constant power factor when there is a reverse power flow from the power converter (inverter 33) to a commercial power system 5. The control unit 33b includes a reverse power flow information acquired by the reverse power flow information acquisition unit (CT sensor 7) by the control unit 33b. When it is determined that there is no power factor, the power factor of the power converter (inverter 33) is controlled to a value closer to 1 than the constant power factor. [Selection] Figure 1

Description

  The present invention relates to a distributed power system including a distributed power source such as a solar power generation unit, a power converter configured to be applicable to the distributed power system, and a power factor control method for the power converter. It is.

  In recent years, distributed power sources such as solar power generation have become widespread, and cases where these power generation facilities and the like are connected to low-voltage distribution lines are increasing. Non-Patent Document 1 describes that there is a concern about a voltage increase in a high-voltage distribution line or the like with an increase in the grid connection. Furthermore, as a countermeasure against voltage rise, the power conditioner connected to the distributed power source is provided with a function of always performing phase advance operation at a constant power factor, so-called constant power factor control (for example, power factor 0.9). It is described that it is effective. In this way, by operating the power conditioner with constant power factor control, it is possible to suppress an increase in the system voltage and maintain the system voltage appropriately.

Japan Electric Association, Grid Connection Regulations, JEAC 9701-2012 [2015 Supplement (Part 1)], Page 8, etc.

Japanese Patent No. 5454422

  By the way, as shown in Patent Document 1, for example, in a distributed power supply system including a plurality of distributed power sources (including power generation facilities and power storage facilities), a home appliance, an industrial device, or the like using a distributed power source is used. Power is supplied to the load.

  Here, when the supply power supplied from the distributed power source is larger than the power consumption consumed by the load, it becomes possible to sell power to the power company by flowing backward from the distributed power source to the grid. ing. During this reverse flow, it may be required to perform the above-described constant power factor control.

  On the other hand, when the supply power of the distributed power supply is smaller than the power consumption of the load, the supply power of the distributed power supply is consumed by the load in the power supply system and is not reversely flowed from the distributed power supply to the system. In such a case, if power factor constant control is performed, it is necessary to increase the apparent power, and the power supply efficiency may deteriorate.

  In view of the above problems, an object of the present invention is to provide a distributed power supply system that achieves optimization of power supply efficiency while realizing measures for suppressing an increase in system voltage.

  The distributed power system according to the present invention includes a control unit that controls the power factor of the power converter to a predetermined constant power factor when there is a reverse power flow from the power converter to the commercial power system. Is determined based on the reverse power flow information acquired by the reverse power flow information acquisition unit, the power factor of the power converter is a value closer to 1 than the constant power factor when it is determined that there is no reverse power flow from the power converter to the commercial power system. It was configured to control.

  Here, power efficiency is better when the power factor is close to 1. Therefore, when the control unit determines that there is no reverse power flow as in the above aspect, the power efficiency of the distributed power supply system is increased by controlling the power factor of the power converter with a value closer to 1 than the constant power factor. Can do.

  That is, the distributed power supply system according to the first aspect of the present invention has a plurality of distributed power supplies and a DC / AC conversion function, and performs DC / AC conversion on output power from the plurality of distributed power supplies to load. And a reverse power flow information acquisition unit for acquiring reverse power flow information regarding the presence or absence of a reverse power flow from the power conversion device to the commercial power supply system. And a control unit that controls the power factor of the power conversion device to a predetermined constant power factor when there is a reverse power flow from the power conversion device to the commercial power supply system, the control unit includes the reverse power flow information When the power converter determines that there is no reverse power flow from the power converter to the commercial power supply system, the power factor of the power converter is controlled to a value closer to 1 than the constant power factor.

  According to this configuration, the control unit of the distributed power system sets the power factor of the power converter controlled to a constant power factor when there is a reverse power flow to 1 from the constant power factor when determining that there is no reverse power flow. The value is controlled to a close value. Thereby, as described above, the power efficiency of the distributed power supply system can be increased.

  Here, in the case where a reverse power flow is performed from the reverse power flow permission power source, when the power storage device is included in the distributed power source, the discharge from the power storage device is generally stopped. At this time, the control unit controls the power factor of the power converter to a predetermined constant power factor. After that, when the power consumption of the load exceeds the power supply from the reverse flow permission power source, that is, when there is no reverse flow, it is necessary to supplement the shortage of power with the power storage device. At this time, if the power factor of the power converter is continuously controlled at a constant power factor, the power efficiency is poor, so that the power factor of the power converter is controlled at a value closer to 1 than the constant power factor. There is a problem that the power storage device is consumed quickly.

  On the other hand, in this aspect, when the control unit determines that there is no reverse power flow based on the reverse power flow information, the power factor of the power converter is controlled to a value closer to 1 than the constant power factor. Thereby, even when it is necessary to replenish the shortage of power with the power storage device, higher power efficiency can be realized compared with the case where the power factor of the power conversion device is controlled to a constant power factor. Therefore, the power consumption of the power storage device can be reduced. As a result, the charge power of the power storage device can be used more effectively, and the amount of charge / discharge and the number of times of charge / discharge can be reduced, so that the life of the power storage device can be extended.

  In addition, for example, if the distributed power source includes a power supply that does not allow reverse power flow and that does not allow reverse power flow, and if a reverse power flow is provided from the power supply that allows reverse power flow, the discharge from the power supply that does not allow reverse power flow is stopped. It is common. At this time, the control unit controls the power factor of the power converter to a predetermined constant power factor. After that, when the power consumption of the load exceeds the power supply from the reverse flow permission power supply and the reverse flow does not flow, it is necessary to supplement the shortage of power with the reverse flow non-power supply. At this time, if the power factor of the power converter is continuously controlled at a constant power factor, the power efficiency is poor, so that the power factor of the power converter is controlled at a value closer to 1 than the constant power factor. There is a problem that the power efficiency of a power supply that cannot be reversely flowed deteriorates.

  On the other hand, in this aspect, when the control unit determines that there is no reverse power flow based on the reverse power flow information, the power factor of the power converter is controlled to a value closer to 1 than the constant power factor. As a result, even if it is necessary to replenish the shortage of power with a non-reversible power supply, the power efficiency of the non-reverse power supply is lower than when the power conversion device power factor is controlled to a constant power factor. Can be increased. Thereby, it becomes possible to more effectively utilize the charging power of the power supply that cannot be reversely flowed.

  The reverse power flow information acquisition unit is a current detection unit that detects a power transmission current flowing in a power transmission line connecting the power conversion device and a commercial power supply system, and outputs the current as the reverse power flow information. The power factor of the power converter is controlled to a value closer to 1 than the constant power factor when it is determined that there is no reverse power flow from the power converter to the commercial power system based on the transmission current. May be.

  According to this configuration, since the current detection means outputs the current value flowing through the transmission line connecting the power conversion device and the commercial power supply system as the reverse power flow information, the control unit is more accurate information regarding the presence or absence of the reverse power flow. Can be obtained. Thereby, it becomes possible to control the power factor of the power converter more accurately.

  When the control unit determines that there is no reverse power flow from the power converter to the commercial power supply system based on the reverse power flow information, in addition to the power factor control of the power converter, the load increase / decrease variation The output power control for increasing or decreasing the output power amount of the power conversion device may be performed following the above.

  By controlling the power factor of the power converter to a value closer to 1 than the constant power factor, the power efficiency of the distributed power supply system can be increased as described above. On the other hand, after performing the power factor control, the supply power of a plurality of distributed power may exceed the power consumption of the load, that is, a reverse power flow from the power converter to the commercial power supply system may be performed. . Therefore, when it is determined that there is no reverse power flow from the power conversion device to the commercial power supply system as in this aspect, the output power control is performed in combination with the power factor control, so that a plurality of distributed power supply power Regardless of the magnitude relationship with the power consumption of the load, it becomes possible to continue the state where the reverse power flow is not performed. In this way, for example, in the case where the power storage device is a reverse power non-permissible power source where reverse power flow is not permitted, even if the power storage device is discharged, the discharge from the power storage device is continued. Will be able to.

  In the second aspect of the present invention, the power conversion device performs DC / AC conversion on output power from a plurality of distributed power sources and supplies the power to a load, and an inverter that links the plurality of distributed power sources to a commercial power system And a reverse power flow information acquisition unit that acquires reverse power flow information regarding the presence or absence of reverse power flow from the inverter to the commercial power system, and when there is a reverse power flow from the inverter to the commercial power system, And a control unit that controls the power factor of the inverter to a value closer to 1 than the constant power factor when the control unit determines that there is no reverse power flow based on the reverse power flow information. It is characterized by that.

  According to this configuration, similarly to the first aspect, when the control unit determines that there is no reverse power flow based on the reverse power flow information, the power factor of the inverter is controlled to a value closer to 1 than the constant power factor. The power efficiency of the distributed power system can be increased. For example, when a plurality of distributed power sources include storage batteries, the charging power of the storage batteries can be used more effectively, and the life of the storage batteries can be extended.

  According to the present invention, since the power factor constant control and the control for changing the power factor following the load are switched according to the situation of the reverse power flow from the power converter to the system, the system voltage rises. The power supply efficiency can be optimized while realizing the suppression measures.

It is the figure which showed the whole structure of the distributed power supply system. It is a flowchart which shows the control flow by a system control part. It is a figure for demonstrating power factor fixed control. It is a flowchart which shows the other example of the control flow by a system control part.

  Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings. The following description of the preferred embodiments is merely exemplary in nature and is not intended to limit the invention, its scope of application, or its application.

<Configuration of distributed power supply system>
FIG. 1 is a diagram illustrating a configuration example of a distributed power supply system according to an embodiment.

  The distributed power supply system 1 is for home use in which a plurality of distributed power sources 2, 2,... And a DC power supplied from the plurality of distributed power sources 2, 2,. And a power conditioner 3 that supplies a load 9 (hereinafter, also simply referred to as a load) such as a device or an industrial device.

  1 shows an example in which a plurality of distributed power sources 2, 2,... Include three photovoltaic power generation means 21, 21,. In the following description, based on the grid connection regulations, the solar power generation means 21, 21,... Will be described as being a reverse power flow permitted power source for which reverse power flow is permitted. The storage battery 22 is a secondary battery capable of being charged / discharged, such as a lithium ion battery or a lead storage battery, and will be described as a non-reverse flow power source that does not allow reverse flow.

  The power conditioner 3 is further configured so that a plurality of distributed power sources 2, 2... Can be linked to the commercial power supply system 5 via the power transmission line 4. Between the power conditioner and the commercial power supply system 5 and the load 9, there is provided a distribution board 6 configured to be able to switch on and off the connection between the power conditioner 3, the commercial power supply system 5 and the load. ing. A CT (Current Transformer) sensor 7 that measures the current flowing through the power transmission line 4 is attached to the power transmission line 4 between the distribution board 6 and the commercial power supply system 5.

  Thereby, in the distributed power supply system 1, the power supplied from the plurality of distributed power sources 2, 2... (The plurality of photovoltaic power generation units 21, 21,... And / or the storage battery 22) is less than the power consumption of the load 9. In some cases, all the supplied power is supplied to the load 9. On the other hand, when the power supplied by the solar power generation means 21, 21,... (Reverse power flow permitting power source) out of the plurality of distributed power sources 2, 2,. The surplus power out of the power supplied from the solar power generation means 21, 21,...

-Configuration of the inverter-
The power conditioner 3 includes a plurality of DC / DC converters 31,..., 32, a bidirectional DC / AC inverter 33 (hereinafter also simply referred to as an inverter), and a system control unit 34. The plurality of DC / DC converters 31,..., 32 are provided so as to have a one-to-one correspondence with the solar power generation means and the storage battery.

  Each DC / DC converter 31 connected to the solar power generation means 21 receives a supply power from the solar power generation means 21, and a DC / DC conversion circuit 31 a that boosts or lowers the voltage according to the generated voltage, and a DC / DC conversion. A converter control unit 31b for controlling the conversion operation of the circuit 31a. Each converter control part 31b controls the electric energy taken out from a solar power generation means, for example, is comprised so that maximum operating point tracking control is possible. By performing this maximum operating point tracking control, the maximum power can be extracted from each photovoltaic power generation means 21. Note that the DC / DC conversion circuit 31a and the converter control unit 31b of each DC / DC converter 31 can be realized with the same configuration as the conventional technology described in Patent Document 1, for example. Detailed description thereof is omitted.

  The DC / DC converter 32 connected to the storage battery 22 is a bidirectional DC / DC converter, and includes a DC / DC conversion circuit 32 a provided between the storage battery 22 and the inverter 33, and a connection destination storage battery 22. And a storage battery control unit 32b for controlling the charge / discharge amount. The DC / DC conversion circuit 32a can be realized with the same configuration as that of the prior art, and detailed description thereof is omitted here.

  The storage battery control unit 32 b controls charging / discharging of the storage battery 22 in response to an instruction from the system control unit 34 described later. Moreover, it is comprised so that data communication is possible with BMU (Battery Management Unit) 22a with which the storage battery of a connection destination is provided, and the information which concerns on storage batteries, such as the residual amount of the storage battery 22, charging / discharging electric power, is acquired from BMU22a.

  Here, since the storage battery control unit 32b performs charge / discharge control of the storage battery 22, it is possible to acquire discharge information indicating whether or not the storage battery 22 is discharged based on its own charge / discharge control signal. . That is, the storage battery control unit 32 b is configured to be able to function as a discharge information acquisition unit, and can output discharge information related to whether or not the storage battery 22 is discharged. Here, the distributed power supply system 1 is configured so that no reverse power flow from the distributed power supply system 1 to the commercial power supply system 5 occurs when the storage battery 22 as a power supply that does not allow reverse power flow is discharged. It is preferable. In this case, the discharge information is information (reverse power flow information) that can be determined that there is no reverse power flow. The storage battery control unit 32b may acquire the discharge information by measuring the direction of the charge / discharge current between the storage battery 22 and the DC / DC converter 32 with a sensor or the like.

  The system control unit 34 is realized by, for example, a program stored in a microcomputer, and is configured to be capable of bidirectional data communication with the remote controller 8, the inverter control unit 33b, and the storage battery control unit 32b provided outside the power conditioner 3. Has been. Further, the system control unit 34 acquires a current value detected by the CT sensor 7. The system control unit 34 is acquired by the power factor setting information indicating the presence / absence of the power factor control set by the remote controller 8 and the designated power factor value, the current value detected by the CT sensor 7 and / or the storage battery control unit 32b. Various information such as discharge information of the storage battery 22 is received and centrally managed. Furthermore, the system control unit 34 outputs a storage battery control signal for controlling charging / discharging of the storage battery 22 to the storage battery control unit 32b.

  The inverter 33 includes a bidirectional inverter circuit 33a and an inverter control unit 33b. The output power from the DC / DC conversion circuits 31 a and 32 a of the DC / DC converters 31 and 32 is added and input to the bidirectional inverter circuit 33 a of the inverter 33. Further, the output power of the inverter circuit 33 a is supplied to the distribution board 6.

  The inverter control unit 33b receives the power factor setting information from the system control unit 34 and the reverse power flow information such as the output power amount from each converter control unit 31b, and controls the output power and power factor of the inverter circuit 33a.

<Power factor control of distributed power system (1)>
Hereinafter, a power factor control operation example of the distributed power supply system will be described in detail with reference to FIG. In the following description, it is assumed that the control subject when there is no particular description is the inverter control unit 33b.

  First, the inverter control unit 33b determines the presence / absence of power factor control based on the power factor setting information from the system control unit 34 in ST11. When there is no power factor control (NO in ST11), the power factor control process is terminated without performing the power factor control. On the other hand, when there is power factor control (YES in ST11), the inverter control unit 33b receives a detection result related to the current direction (forward flow / reverse flow) detected by the CT sensor via the system control unit 34. Then, the presence or absence of reverse power flow is determined (ST12). In ST12, when the inverter control unit 33b determines that there is a reverse power flow (YES in ST12), the inverter control unit 33b performs power factor constant control for making the power factor constant (power factor <1) for the inverter circuit 33a ( ST14).

  Here, for example, when the sum of the supply power supplied from the plurality of distributed power sources 2, 2,... When a reverse power flow from the distributed power supply system 1 to the commercial power supply system 5 is performed, that is, when power is sold, the distributed power supply system 1 is predetermined by a power company such as an electric power company as a measure for preventing the voltage increase of the commercial power supply system 5. There is a case where it is requested to connect to the grid at a power factor of.

  Therefore, in ST14, the inverter control unit 33b controls the inverter circuit to add reactive power to the input power from the plurality of distributed power sources, and the power controlled to a predetermined constant power factor is transmitted from the inverter circuit. To be output. FIG. 3 shows an example of output power when the predetermined constant power factor is 0.8. Since the power factor PF is obtained by “PF = apparent power / active power (cos θ in FIG. 3)”, in the example of FIG. 3, reactive power is applied so that the PF value becomes 0.8. .

  Specifically, the control for adding reactive power is realized by performing the advance power factor control or the delay power factor control from the inverter control unit 33b. Advance power factor control is power factor control that advances the phase of current with respect to voltage. The delayed power factor control is a power factor control that delays the phase of the current with respect to the voltage. Note that it is possible to select which of the advance power factor control and the delayed power factor control is applied based on a request from an electric power company, and the same effect can be obtained by either power factor control.

  Then, the inverter control unit 33b performs control so that the power factor of the inverter circuit 33a becomes a predetermined constant power factor (for example, 0.8) during the period in which the state with reverse power flow continues. By controlling the power factor in this way, it is possible to more reliably prevent a voltage increase in the commercial power supply system.

  Returning to FIG. 2, in ST12, when it is determined that there is no reverse power flow (NO in ST12), the inverter control unit 33b controls the inverter circuit 33a so that the power factor becomes 1 (ST13). Specifically, the reactive power is set to “0” so that only the active power is obtained. Thereby, compared with the case where the inverter 33 is controlled to a constant power factor (see, for example, P1 in FIG. 3), it is effective when the output current and output voltage from the plurality of distributed power sources 2, 2,. The power (see, for example, P2 in FIG. 3) can be increased.

  In the present disclosure, “controlling the power factor to be 1” is a concept including those in which the power factor is substantially controlled to 1. That is, the concept includes that the power factor is controlled to a value slightly smaller than 1 depending on circuit characteristics, control characteristics, the surrounding environment, and the like.

<Power factor control of distributed power system (2)>
Hereinafter, an example of the power factor control operation of the distributed power supply system will be described in detail with reference to FIG. In the following description, it is assumed that the control subject when there is no particular description is the inverter control unit 33b. In addition, the same or similar components and flows as those in “power factor control (1) of distributed power supply system (1)” may be denoted by the same reference numerals and description thereof may be omitted.

  First, in ST11, when there is power factor control (YES in ST11), inverter control unit 33b confirms the presence or absence of discharge from the storage battery (ST22). Specifically, the inverter control unit 33b acquires the discharge information of the storage battery 22 from the storage battery control unit 32b via the system control unit 34. In ST22, when the inverter control unit 33b determines that the discharge from the storage battery 22 is being performed, since the reverse flow is not permitted and the discharge is performed from the non-reverse flow impossible power source, Judge that there is no. Therefore, the flow proceeds to ST13, and the inverter control unit 33b controls the inverter circuit 33a so that the power factor becomes 1 (ST13). On the other hand, when it is determined that the storage battery 22 is not discharged (NO in ST22), power factor constant control is performed to make the power factor constant (power factor <1) (ST14). The control content of ST13 and ST14 is the same as or similar to “Power factor control (1) of distributed power supply system”, and detailed description thereof is omitted here.

  As described above, according to the present embodiment, when the inverter control unit 33b determines that there is no reverse power flow based on the current direction detected by the CT sensor 7 as the reverse power flow information or the discharge information of the storage battery 22. Is configured to control the power factor to 1. Thereby, when there is no reverse power flow, that is, when power is supplied to the load 9 from a plurality of distributed power sources 2, 2,..., The power efficiency of the distributed power system 1 can be improved. If there is no reverse power flow and there is power output from the storage battery 22, the power consumption of the storage battery 22 is consumed as compared with the case where the power factor of the power conditioner 3 (power converter) is controlled to a constant power factor. Can be reduced.

<Other embodiments>
While the embodiments of the present invention have been described above, various modifications can be made.

  For example, in ST13 of FIGS. 2 and 4, the inverter control unit 33b is configured to control the power factor to 1 when it is determined that there is no reverse power flow. Is not limited to 1. For example, if the power factor of the inverter circuit 33a is controlled to a value closer to 1 than the constant power factor, an effect of increasing the power efficiency of the distributed power supply system 1 can be obtained. However, when the power factor of the inverter circuit 33a is 1, there is an advantage that the power efficiency can be further improved.

  Moreover, in ST13 of FIG.2 and FIG.4, although the inverter control part 33b shall be comprised so that the power factor of the inverter circuit 33a may be controlled to 1 when it is judged that there is no reverse power flow, In addition to this power factor control, output power control may be performed to increase or decrease the output power amount of the inverter circuit 33a following the fluctuation of the load 9. Specifically, for example, when the power factor of the load 9 decreases and the output power of the inverter circuit 33a becomes larger when the power factor of the inverter circuit 33a is controlled to 1, the inverter circuit 33a The output power (active power) of 33a is decreased. Thereby, even if the discharge from the storage battery 22 is performed, it is possible to prevent the reverse power flow from occurring, so that the discharge from the storage battery 22 can be continued.

  In ST14 of FIG. 2, the case where the predetermined constant power factor is 0.8 has been described. However, the predetermined power factor can be arbitrarily set. For example, the phantom line in FIG. 3 shows an example where the predetermined constant power factor is 0.95. Even in this case, if the inverter control unit 33b determines that there is no reverse power flow, the power efficiency of the distributed power system can be improved by controlling the power factor to a value closer to 1 than 0.95 which is a constant power factor. The effect which raises can be acquired.

  Moreover, in the said embodiment, although the DC / DC converters 31 and 32 provided so as to correspond to each photovoltaic power generation means 21 and the storage battery 22 on the one-to-one basis shall be provided in the power conditioner 3. FIG. However, the present invention is not limited to this. For example, each DC / DC converter 31 may be built in each photovoltaic power generation means 21. Similarly, the DC / DC converter 32 may be provided on the storage battery 22 side.

  Moreover, in the said embodiment, although the reverse power flow permission power supply shall be the solar power generation means 21, it is not limited to this. For example, instead of solar power generation means, other power generation means such as wind power generation means or power storage means may be used. Moreover, these combinations may be sufficient and the same effect is acquired.

  Similarly, although the reverse power flow disable power source is the storage battery 22, it is not limited to this. For example, instead of the storage battery 22, other power generation means such as a fuel cell, a cogeneration system, or a power storage means may be used. The storage battery 22 is not limited to a stationary storage battery, and a storage battery, a fuel cell, etc. mounted on an electric vehicle can be connected. Moreover, these combinations may be sufficient and the same effect is acquired.

  Furthermore, for example, in the above-described embodiment, the storage battery 22 has been described as a non-reverse power flow power supply that is not permitted to reverse flow, but when the reverse flow of the power storage device (storage battery 22) is permitted, The power storage device (storage battery 22) is included in the reverse flow permission power source. The same applies to the power generation means and the power storage means exemplified as other non-reverse flowable power sources in the fuel cell and the like.

  According to the present invention, it is possible to realize optimization of power supply efficiency while realizing countermeasures for suppressing a rise in system voltage. Therefore, it is extremely useful as a distributed power supply system in which a plurality of distributed power supplies are linked to a commercial power supply system. Useful.

DESCRIPTION OF SYMBOLS 1 Distributed power supply system 2 Distributed power supply 3 Power conditioner (power converter)
5 Commercial power system 32b Storage battery control unit (discharge information acquisition means)
33b Inverter control unit (control unit)
33 DC / AC inverter (inverter)
7 CT sensor (current detection means)
9 Load

Claims (4)

Multiple distributed power supplies,
A power conversion device having a DC / AC conversion function, DC / AC-converting output power from the plurality of distributed power sources and supplying the load to a load, and connecting the plurality of distributed power sources to a commercial power supply system; ,
A reverse power flow information acquisition unit for acquiring reverse power flow information on the presence or absence of reverse power flow from the power converter to the commercial power supply system;
A control unit that controls the power factor of the power converter to a predetermined constant power factor when there is a reverse power flow from the power converter to the commercial power supply system;
When the control unit determines that there is no reverse power flow from the power conversion device to the commercial power supply system based on the reverse power flow information, the power factor of the power conversion device is a value closer to 1 than the constant power factor. A distributed power supply system characterized in that The distributed power supply system according to claim 1.
The reverse power flow information acquisition unit is a current detection unit that detects a power transmission current flowing in a power transmission line connecting the power conversion device and a commercial power system, and outputs the current as the reverse power flow information.
When the control unit determines that there is no reverse power flow from the power converter to the commercial power system based on the transmission current, the power factor of the power converter is closer to 1 than the constant power factor. A distributed power supply system characterized by controlling. The distributed power supply system according to claim 1.
When the control unit determines that there is no reverse power flow from the power converter to the commercial power supply system based on the reverse power flow information, in addition to the power factor control of the power converter, the load increase / decrease variation A distributed power supply system that performs output power control to increase or decrease the output power amount of the power conversion device following the above. An output power from a plurality of distributed power sources is DC / AC converted and supplied to a load, and the plurality of distributed power sources are connected to a commercial power system, and an inverter,
A reverse power flow information acquisition unit for acquiring reverse power flow information regarding the presence or absence of reverse power flow from the inverter to the commercial power supply system;
A control unit that controls the inverter to a predetermined constant power factor when there is a reverse power flow from the inverter to the commercial power system,
The said control part controls the power factor of the said inverter to the value close | similar to 1 from the said fixed power factor, when it is judged that there is no reverse power flow based on the said reverse power flow information.

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