JP6489899B2 - Distributed power supply - Google Patents

Description

  The present invention relates to a distributed power supply device interconnected to a power system via a power line.

  When a distributed power supply device that is connected to a power system via a power line is operated, it may be required to prevent reverse power flow from the power line to the power system. That is, the power supplied from the distributed power supply device to the power line is required to be equal to or lower than the power consumption of the power consuming device connected to the power line. In that case, the power supplied from the power system to the power line is measured, and the power supplied from the distributed power supply device to the power line is reduced so that the power does not become a negative value (that is, a reverse power flow is occurring). Need to control.

  Thus, in order to prevent reverse power flow from the power line to the power system, first, it is necessary to accurately measure the power supplied from the power system to the power line. In general, the current and voltage of power on the power line are measured, and the power deriving unit derives the power from the current and voltage.

  Patent Document 1 describes an apparatus for determining whether or not power supplied from a power system to a power line can be accurately measured. Specifically, this device attempts to determine whether or not the power is accurately derived based on a change in current value when a load connected to the power line is turned on / off. In other words, increasing the power consumption of the power consuming device connected to the power line increases the current measured by the power line, and reducing the power consumption of the power consuming device reduces the current measured by the power line. Thus, it is attempted to derive whether or not accurate measurement of electric current and accurate calculation of electric power are performed.

JP 2004-092458 A

  However, increasing the power consumption of the power consuming device connected to the power line increases the current measured by the power line, and decreasing the power consumption of the power consuming device decreases the current measured by the power line. Even if a phenomenon that seems to be normal appears, the power may not be accurately derived. Specifically, if the power deriving unit is out of order, the correct power value may not be derived by the power deriving unit even if a correct current value is detected by the current detecting unit. For example, when a current of 3 (A) and a voltage of 1 (V) are detected, the power deriving unit should derive 3 (W), but a state where an offset of +1 (W) is placed A failure that can be derived as 4 (W) or a failure that can be derived as 2 (W) with an offset of -1 (W) can occur. When such a failure occurs, the derived power in the power deriving unit also increases / decreases as the detected current increases / decreases in the current detecting unit. Therefore, with the device described in Patent Document 1, accurate measurement of current and It is determined that accurate derivation of power is being performed.

In this way, when a failure occurs such that the power deriving unit derives a larger amount of power than the correct power supplied from the power system to the power line, the power from the distributed power supply to the power line is greater than the power consumption of the power consuming device. As a result, the reverse power flow will occur.
In addition, when a failure occurs in which the power deriving unit derives less power than the correct power supplied from the power system to the power line, power is supplied from the distributed power supply to the power line rather than the power consumed by the power consuming device. Since the power is reduced and the purchased power from the power system is increased, it is not possible to obtain the advantages (energy saving, economic efficiency, environment) obtained when the distributed power supply device is operated.

  Furthermore, even if a reverse power relay is provided, there is a problem that the reverse power relay cannot be used properly if the power supplied from the power system to the power line cannot be correctly derived.

  The present invention has been made in view of the above problems, and an object of the present invention is to provide a distributed power supply apparatus that can reliably detect a failure.

In order to achieve the above object, a characteristic configuration of a distributed power supply apparatus according to the present invention is a distributed power supply apparatus linked to a power system via a power line,
A power supply unit that performs power supply operation based on the instructed target power supply power and supplies power to the power line;
Based on the voltage value of the power in the power line and the current value of the power in the power line transmitted from the current detection unit via the current signal line, the power value supplied from the power system to the power line A power deriving unit that performs a power deriving process;
Based on the power reading process in which the power deriving unit derives the power value derived in the power deriving process and the power value read in the power reading process, a reverse power flow from the power line to the power system does not occur. As described above, a target power derivation process for deriving a target power supply power value to be supplied to the power line by the power supply unit, and a power control unit for performing a target power transmission process for transmitting the target power supply power value to the power supply unit;
A current information changing unit provided in the middle of the current signal line and capable of changing an actual current value transmitted from the current detection unit to a predetermined reference current value;
When the current information changing unit changes the actual current value to the reference current value, the power control unit reads the power value read in the power reading process or is transmitted from the power control unit to the power source unit. A failure determination unit that determines whether a failure has occurred in at least one of the power deriving unit and the power supply control unit based on the target power supply power value ;
The failure determination unit includes the power value read by the power supply control unit in the power reading process when the current information change unit is changing the actual current value to the reference current value, and the reference current value. Based on the standard power value to be derived by the power deriving unit based on the deviation,
The power supply unit is configured to perform the power supply operation in consideration of the deviation and the target power supply value transmitted from the power supply control unit .

According to the above characteristic configuration, when the current information changing unit changes the current value transmitted to the power deriving unit to the reference current value, the power deriving unit derives the power value based on the reference current value. The failure determination unit knows what value the power value read by the control unit in the power reading process or the target power supply value transmitted from the power supply control unit to the power supply unit should be.
That is, the failure determination unit is transmitted to the power supply unit from the power value that the power supply control unit should read in the power reading process or when the current information change unit changes the current value to the reference current value. Compare the target power supply power value that should be received and the power supply value actually read by the power supply control unit in the power reading process or the target power supply power value actually transmitted from the power supply control unit to the power supply unit. If so, it can be determined that a failure has occurred in at least one of the power deriving unit and the power supply control unit.
Therefore, it is possible to provide a distributed power supply device that can reliably detect a failure.

The power value read by the power supply control unit in the power reading process when the current information change unit is changing the actual current value to the reference current value, and the reference power value that the power deriving unit should derive based on the reference current value If there is a deviation between the target power supply value transmitted from the power supply control unit to the power supply unit, the influence of the deviation is included. As a result, there is a possibility that the power supplied from the power supply unit to the power line becomes inappropriate for achieving the purpose of preventing the reverse flow of power from the power line to the power system.
Therefore, in this feature configuration, the failure determination unit derives the deviation, and when the current information change unit does not change the actual current value to the reference current value with respect to the power supply unit, the failure and the power supply control unit Electric power is fed in consideration of the transmitted target power supply value. That is, even if such a deviation exists, the influence of the deviation included in the target power supply value transmitted from the power supply control unit to the power supply unit can be eliminated.

Another characteristic configuration of the distributed power supply apparatus according to the present invention is a distributed power supply apparatus interconnected to a power system via a power line,
A power supply unit that performs power supply operation based on the instructed target power supply power and supplies power to the power line;
Based on the voltage value of the power in the power line and the current value of the power in the power line transmitted from the current detection unit via the current signal line, the power value supplied from the power system to the power line A power deriving unit that performs a power deriving process ;
Based on the power reading process that is transmitted from the power deriving unit through the power signal line and reads the power value derived in the power deriving process, and the power value read in the power reading process, the power line reads the power value. A target power derivation process for deriving a target power supply power value to be supplied to the power line by the power supply unit, and the target power supply power value is transmitted to the power supply unit so that a reverse power flow to the power system does not occur A power control unit that performs target power transfer processing;
A power information changing unit provided in the middle of the power signal line and capable of changing an actual power value transmitted from the power deriving unit to a predetermined reference power value;
When the power information changing unit changes the actual power value to the reference power value, the power control unit reads the power value read in the power reading process or is transmitted from the power control unit to the power source unit. A failure determination unit that determines whether a failure has occurred in the power supply control unit based on the target power supply power value.

According to the above characteristic configuration, when the power information changing unit changes the power value transmitted to the power control unit to the reference power value, the power control unit reads the reference power value and sets the target based on the reference power value. In order to derive the power supply power value, the failure determination unit knows what value the power value read by the power supply control unit in the power reading process or the target power supply value transmitted from the power supply control unit to the power supply unit should be. It is.
That is, the failure determination unit is transmitted to the power supply unit from the power value that the power supply control unit should read in the power reading process or when the power information change unit changes the power value to the reference power value. Compare the target power supply power value that should be received and the power supply value actually read by the power supply control unit in the power reading process or the target power supply power value actually transmitted from the power supply control unit to the power supply unit. If so, it can be determined that a failure has occurred in the power supply control unit.
Therefore, it is possible to provide a distributed power supply device that can reliably detect a failure.

  Still another characteristic configuration of the distributed power supply device according to the present invention is that the failure determination unit changes the power value transmitted from the power deriving unit to the reference power value by the power information change unit. The power supply control unit derives a deviation between the target power supply power value actually derived and the reference power supply power value to be derived by the power supply control unit based on the reference power value. The power feeding operation is performed in consideration of the deviation and the target power feeding power value transmitted from the power control unit.

The power control unit derives the power value transmitted from the power deriving unit based on the target power supply value and the reference power value actually derived by the power control unit while the power information changing unit changes the power value to the predetermined reference power value. If there is a deviation from the reference target power supply value to be used, the power supplied to the power line by the power supply unit is not sufficient to achieve the purpose of preventing reverse power flow from the power line to the power system. There is a possibility that the power will be appropriate.
Therefore, in this feature configuration, the failure determination unit derives the above deviation, and when the power value transmitted from the power deriving unit is not changed to the reference power value by the power information changing unit, And the target power supply value transmitted from the power supply controller are taken into consideration. That is, even if such a deviation exists, the influence of the deviation included in the target power supply value transmitted from the power supply control unit to the power supply unit can be eliminated.

Yet another characteristic configuration of the distributed power supply apparatus according to the present invention is configured such that the power supply unit stops the power feeding operation when the failure determination unit determines that a failure has occurred. In the point.
Here, the failure determination unit may determine that a failure has occurred if the deviation is equal to or greater than a predetermined value.

  According to the above characteristic configuration, when it is determined that a failure has occurred, the power supply unit can reliably stop the power feeding operation and avoid a reverse power flow to the power system that can occur when the power feeding operation is continued.

It is a figure which shows the structure of the distributed power supply device of 1st Embodiment. It is a figure explaining the function of the distributed power supply device of a 1st embodiment. It is a figure which shows the structure of the distributed power supply device of 2nd Embodiment. It is a figure explaining the function of the distributed power supply device of 2nd Embodiment. It is a figure explaining the function of the distributed power supply device of 3rd Embodiment. It is a figure explaining the function of the distributed power supply device of 4th Embodiment.

<First Embodiment>
Hereinafter, a distributed power supply device 10A (10) according to a first embodiment of the present invention will be described with reference to the drawings.
FIG. 1 is a diagram illustrating a configuration of a distributed power supply apparatus 10A according to the first embodiment. FIG. 2 is a diagram illustrating functions of the distributed power supply device 10A according to the first embodiment. As illustrated, the distributed power supply device 10 </ b> A is connected to the power system 1 via the power line 2. A power consuming device 3 is connected to the power line 2. The power consuming device 3 can receive power from at least one of the power system 1 and the distributed power supply device 10A. The distributed power supply device 10 </ b> A includes a power supply unit 14, a power deriving unit 11, a power supply control unit 12, a current information changing unit 15, and a failure determination unit 13.

  The power supply unit 14 supplies power to the power line 2 by performing a power feeding operation based on the instructed target power supply power. In the present embodiment, the power supply unit 14 can output power, and the power conversion unit 14a that converts the power output from the power supply device 14b into power of a desired voltage, phase, and frequency and supplies the power to the power line 2. And have. The power supply unit 14 is connected to the connection unit 20 of the power line 2 through the feeder line 9. The power supply device 14b is a power generation device or a charge / discharge device such as a battery.

  The power deriving unit 11 transmits the power line from the power system 1 based on the voltage value of the power on the power line 2 and the current value of the power on the power line 2 transmitted from the current detection unit 4 via the current signal line 6. The power derivation process for deriving the power value supplied to 2 is performed. Specifically, information regarding the current value is transmitted to the power deriving unit 11 from the current detection unit 4 provided on the power line 2 through the current signal line 6 as an analog signal, for example. In addition, information regarding the voltage value is transmitted to the power deriving unit 11 from the voltage detection unit 5 provided in the power line 2 via the voltage signal line 7 as an analog signal, for example. The power deriving unit 11 performs a power deriving process for deriving a power value supplied from the power system 1 to the power line 2.

The power supply control unit 12 reads the power value derived by the power deriving unit 11 in the power deriving process, and the power value read from the power line 2 to the power system 1 based on the power value read in the power reading process. A target power deriving process for deriving a target power supply power value in the power supply unit 14 and a target power transmission process for transmitting the target power supply power value to the power supply unit 14 are performed so that a reverse power flow does not occur.
For example, when power (magnitude: W1) is consumed by the power consuming device 3 connected to the power line 2, the power (magnitude: W1) is supplied to the power consuming device 3 via the power line 2. If power is not supplied from the distributed power supply device 10A to the power line 2, the power derived by the power deriving unit 11 is also power of magnitude W1. Then, the power supply control unit 12 reads the power having the magnitude W1 in the power reading process, derives the target power supply power value (magnitude: W1) in the target power deriving process, and the target power supply power value in the target power transfer process. (Size: W1) is transmitted to the power supply unit 14.

  When the power supply unit 14 receives the target power supply value (size: W1) from the power supply control unit 12, the target power supply value (size: magnitude: W1) is supplied from the power supply unit 14 to the power line 2 at that time. The power of the power value obtained by adding W1) is operated to be supplied to the power line 2. When this series of processing is performed, the value of power supplied from the distributed power supply device 10A to the power line 2 increases by the amount of power W1, and then the power supplied from the power system 1 to the power line 2 is zero. It becomes. That is, the power consumption of the power consuming device 3 is all covered by the power supplied from the distributed power supply device 10A.

  When the power consumption of the power consuming device 3 connected to the power line 2 is increased, the current measured by the power line 2 increases, and when the power consumption of the power consuming device 3 is decreased, the current measured by the power line 2 is increased. Even if a phenomenon that seems to be normal, such as a decrease, may occur, power may not be accurately derived. Specifically, if the power deriving unit 11 is out of order, the correct power value may not be derived by the power deriving unit 11 even if the current detecting unit 4 detects a correct current value. For example, when a current of 3 (A) and a voltage of 1 (V) are detected, the power deriving unit 11 should derive 3 (W), but an offset amount (deviation) of +1 (W) There may be a failure that is derived as 4 (W) in a state where is placed, and a failure that is derived as 2 (W) when an offset of -1 (W) is placed.

In order to solve such a problem, the distributed power supply apparatus 10A according to the present invention further includes a current information change unit 15 and a failure determination unit 13.
The current information changing unit 15 is provided in the middle of the current signal line 6 and has a configuration capable of changing the actual current value transmitted from the current detecting unit 4 to a predetermined reference current value.
The failure determination unit 13 determines whether the power information control unit 12 reads the power value in the power reading process when the current information change unit 15 changes the actual current value to the reference current value, or from the power control unit 12 to the power source unit 14. Based on the transmitted target power supply value, at least one of the power deriving unit 11 and the power control unit 12 determines whether or not a failure has occurred.
For example, the failure determination unit 13 determines that a failure has occurred if the deviation is greater than or equal to a predetermined value.

  The voltage value of the analog signal and the current value of the analog signal are input to the power deriving unit 11 illustrated in FIG. The current information changing unit 15 provided in the middle of the current signal line 6 includes a switch SW1 that can switch the current signal line 6 between a connected state and a disconnected state. Therefore, when the switch SW1 switches the current signal line 6 to the disconnected state, a current value of 0 (A) is transmitted to the power deriving unit 11.

If the power deriving unit 11 is normal, power of 0 (W) is derived by the power deriving process of the power deriving unit 11 and the power value should be transmitted to the power supply control unit 12.
If the power supply control unit 12 is normal, a power value of 0 (W) is read by the power reading process, a target power supply of 0 (W) is derived by the target power derivation process, and 0 by the target power transfer process. The target power supply value (W) should be transmitted to the power supply unit 14.

  Therefore, the failure determination unit 13 issues a change command for switching the switch SW1 to the disconnected state (that is, switching to the reference current value: 0 (A)) with respect to the current information change unit 15, and then the power supply control unit 12 The “power value” read in the power reading process or the “target power supply value” transmitted in the target power transmission process is acquired. Then, if the value is a normal value as described above, the failure determination unit 13 determines that the power deriving unit 11 and the power supply control unit 12 are normal, and the values are abnormal different from those described above. If it is a value, it is determined that a failure has occurred in at least one of the power deriving unit 11 and the power supply control unit 12.

  Specifically, the failure determination unit 13 includes the power value read by the power supply control unit 12 in the power reading process when the current information change unit 15 changes the actual current value to the reference current value, and the reference current value. The power deriving unit 11 derives a deviation from the reference power value to be derived based on the power supply unit 14, and the power supply unit 14 transmits the “deviation” transmitted from the failure determination unit 13 and the “target power supply power” transmitted from the power supply control unit 12. The power supply is configured in consideration of the “value”.

  For example, when the deviation between the two is the electric power of “+ Pm”, the failure determination unit 13 transmits information on the deviation to the power supply unit 14. That is, the power supply control unit 12 derives power that is larger by + Pm (W) than the actual power value. Therefore, the power supply unit 14 actually supplies the power line 2 with a power value obtained by subtracting the power of “Pm” from the “target power supply power value” transmitted from the power supply control unit 12.

  By performing such processing, the power supply unit 14 can affect the influence of the deviation included in the target power supply value transmitted from the power supply control unit 12 to the power supply unit 14 even if the above-described deviation exists. It can be absent.

Second Embodiment
The distributed power supply device 10B (10) of the second embodiment is different from the above-described embodiment in the part where the power information changing unit 16 is provided. The configuration of the distributed power supply apparatus 10B of the second embodiment will be described below, but the description of the same configuration as the above embodiment will be omitted.

FIG. 3 is a diagram illustrating a configuration of a distributed power supply apparatus 10B according to the second embodiment. FIG. 4 is a diagram illustrating functions of the distributed power supply device 10B of the second embodiment. As illustrated, the distributed power supply apparatus 10 </ b> B includes a power supply unit 14, a power derivation unit 11, a power supply control unit 12, a power information change unit 16, and a failure determination unit 13.

  When the power consumption of the power consuming device 3 connected to the power line 2 is increased, the current measured by the power line 2 is increased. When the power consumption of the power consuming device 3 is decreased, the current measured by the power line 2 is decreased. Even if a phenomenon that seems to be normal appears, the power control unit 12 may not normally read and process the power value derived by the power deriving unit 11. Specifically, if the power supply control unit 12 is out of order, even if the power deriving unit 11 derives a correct power value, the power control unit 12 may not read the correct power value. For example, even if the power deriving unit 11 derives 3 (W), the power supply control unit 12 reads a failure such as 4 (W) in a state where an offset of +1 (W) is placed, There may be a failure in which a reading process of 2 (W) is performed with an offset (deviation) of -1 (W).

  Therefore, the distributed power supply apparatus 10B of the present embodiment is provided in the middle of the power signal line 8, and a power information changing unit that can change the actual power value transmitted from the power deriving unit 11 to a predetermined reference power value. 16. Then, the failure determination unit 13 is configured such that when the power information change unit 16 is changing the actual power value to the reference power value, the power value read by the power source control unit 12 in the power reading process or the power source unit from the power source control unit 12 14 determines whether or not a failure has occurred in the power supply control unit 12 based on the target power supply value transmitted to the power supply 14.

  The voltage value of the analog signal and the current value of the analog signal are input to the power deriving unit 11 illustrated in FIG. Then, an analog power value is input to the power supply control unit 12. The power information changing unit 16 provided in the middle of the power signal line 8 includes a switch SW2 that can switch the power signal line 8 between a connected state and a disconnected state. Therefore, when the switch SW2 switches the power signal line 8 to the disconnected state, a power value of 0 (W) should be transmitted to the power control unit 12.

  Therefore, the failure determination unit 13 issues a change command to the power information change unit 16 to switch the switch SW2 to the disconnected state (that is, switch to the reference power value: 0 (W)), and then the power supply control unit 12 The “power value” read in the power reading process or the “target power supply value” transmitted in the target power transmission process is acquired. Then, the failure determination unit 13 determines that the power supply control unit 12 is normal if the value is a normal value as described above, and if the value is an abnormal value different from that described above, It is determined that a failure has occurred in the power supply control unit 12.

  Specifically, the failure determination unit 13 performs the target power supply actually derived by the power supply control unit 12 in a state where the power value transmitted from the power deriving unit 11 is changed to a predetermined reference power value by the power information changing unit 16. Based on the power value and the reference power value, a deviation from the reference target power supply value to be derived by the power supply control unit 12 is derived, and the power supply unit 14 determines the “deviation” transmitted from the failure determination unit 13 and the power supply control unit 12 The power supply operation is performed in consideration of the “target power supply power value” transmitted from.

  For example, when the deviation between the two is the electric power of “+ Pm”, the failure determination unit 13 transmits information on the deviation to the power supply unit 14. Then, the power supply unit 14 actually supplies the power line 2 with a power value obtained by subtracting the power of “Pm” from the “target power supply power value” transmitted from the power supply control unit 12.

  By performing such processing, the power supply unit 14 can affect the influence of the deviation included in the target power supply value transmitted from the power supply control unit 12 to the power supply unit 14 even if the above-described deviation exists. It can be absent.

<Third Embodiment>
In the distributed power supply device 10C (10) of the third embodiment, the configuration of the current information changing unit 15 is different from that of the first embodiment. The distributed power supply device 10C of the third embodiment will be described below, but the description of the same configuration as that of the above embodiment will be omitted.

  FIG. 5 is a diagram illustrating a configuration of a distributed power supply apparatus 10C according to the third embodiment. As shown in the figure, the current information changing unit 15 has a switch SW3. The switch SW3 normally connects the contact A and the contact B, but also has a plurality of contacts a, b, and c. For example, when the switch SW3 connects the contact a and the contact B, the reference current value Ia (for example, 1 (A)) is input to the power deriving unit 11, and when the switch SW3 connects the contact b and the contact B, the power deriving unit 11 Is inputted with a reference current value Ib (for example, 2 (A)), and when the switch SW3 connects the contact c and the contact B, the power deriving unit 11 is inputted with the reference current value Ic (for example, 3 (A)). The That is, the current information changing unit 15 is configured to change an actual current value to a plurality of reference current values. And the failure determination part 13 can acquire the deviation as demonstrated in the said 1st Embodiment according to each reference current value at the time of changing the reference current value from Ia-> Ib-> Ic.

  By adopting such a configuration, the failure determination unit 13 has a relationship between the change amount of the reference current value (that is, the change amount of the power value) and the change amount of the deviation as described in the first embodiment. Can know. Based on this relationship, the failure determination unit 13 derives a deviation corresponding to the “target power supply value” transmitted from the power supply control unit 12 to the power supply unit 14 and transmits the deviation to the power supply unit 14. . Then, the power supply unit 14 considers the “target power supply power value” transmitted from the power supply control unit 12 and the “deviation” transmitted from the failure determination unit 13, and determines the power value actually supplied to the power line 2. decide

<Fourth embodiment>
In the distributed power supply device 10D (10) of the fourth embodiment, the configuration of the power information changing unit 16 is different from that of the second embodiment. The distributed power supply device 10D of the fourth embodiment will be described below, but the description of the same configuration as that of the above embodiment will be omitted.

  FIG. 6 is a diagram illustrating a configuration of a distributed power supply device 10D according to the fourth embodiment. As shown in the figure, the power information changing unit 16 has a switch SW4. The switch SW4 normally connects the contact A and the contact B, but has a plurality of contacts a, b, and c. For example, when the switch SW4 connects the contact a and the contact B, a reference power value Pa (for example, 1 (W)) is input to the power supply control unit 12, and when the switch SW4 connects the contact b and the contact B, the power supply control unit 12 is connected. Is inputted with a reference power value Pb (for example, 2 (W)), and when the switch SW4 connects the contact c and the contact B, the power control unit 12 is inputted with the reference power value Pc (for example, 3 (W)). The That is, the power information changing unit 16 is configured to be able to change the actual power value to a plurality of reference power values. And the failure determination part 13 can acquire the deviation as demonstrated in the said 2nd Embodiment according to each reference power value at the time of changing the reference power value from Pa-> Pb-> Pc.

  By adopting such a configuration, the failure determination unit 13 can know the relationship between the change amount of the reference power value and the change amount of the deviation as described in the first embodiment. Based on this relationship, the failure determination unit 13 derives a deviation corresponding to the “target power supply value” transmitted from the power supply control unit 12 to the power supply unit 14 and transmits the deviation to the power supply unit 14. . Then, the power supply unit 14 considers the “target power supply power value” transmitted from the power supply control unit 12 and the “deviation” transmitted from the failure determination unit 13, and determines the power value actually supplied to the power line 2. decide

<Another embodiment>
<1>
In the above embodiment, the configuration of the distributed power supply apparatus 10 has been described with a specific example, but the configuration can be changed as appropriate.
For example, in the above-described embodiment, an example in which the distributed power supply device 10 has one power supply unit 14 has been described, but the distributed power supply device 10 may have a plurality of power supply units 14.

<2>
In the above embodiment, an example in which the power supply control unit 12 performs the power reading process, the target power derivation process, and the target power transmission process has been described. However, these processes are not performed independently, but are performed simultaneously in combination. It may be. Further, other processing may be performed by the power supply control unit 12.

<3>
In the above embodiment, an example in which the voltage value and the current value are input as analog values to the power deriving unit 11 has been described. However, a configuration in which these values are input as digital values may be employed.

<4>
In the embodiment, the failure determination unit 13 may determine that a failure has occurred if the deviation is equal to or greater than a predetermined value, and transmit information to that effect to the power supply unit 14. The power supply unit 14 may be configured to stop the power feeding operation when the failure determination unit 13 determines that a failure has occurred. With this configuration, when it is determined that a failure has occurred, the power supply unit 14 reliably stops the power feeding operation and generates a reverse power flow to the power system 1 that can occur when the power feeding operation is continued. Can be avoided.

  The present invention can be used in a distributed power supply device that can reliably detect a failure.

DESCRIPTION OF SYMBOLS 1 Power system 2 Power line 3 Power consuming apparatus 4 Current detection part 5 Voltage detection part 6 Current signal line 7 Voltage signal line 8 Power signal line 10 (10A, 10B, 10C, 10D) Distributed type power supply apparatus 11 Power derivation part 12 Power supply control Unit 13 Failure determination unit 14 Power source unit 15 Current information change unit 16 Power information change unit

Claims (6)

A distributed power supply unit interconnected to a power system via a power line,
A power supply unit that performs power supply operation based on the instructed target power supply power and supplies power to the power line;
Based on the voltage value of the power in the power line and the current value of the power in the power line transmitted from the current detection unit via the current signal line, the power value supplied from the power system to the power line A power deriving unit that performs a power deriving process;
Based on the power reading process in which the power deriving unit derives the power value derived in the power deriving process and the power value read in the power reading process, a reverse power flow from the power line to the power system does not occur. As described above, a target power derivation process for deriving a target power supply power value to be supplied to the power line by the power supply unit, and a power control unit for performing a target power transmission process for transmitting the target power supply power value to the power supply unit;
A current information changing unit provided in the middle of the current signal line and capable of changing an actual current value transmitted from the current detection unit to a predetermined reference current value;
When the current information changing unit changes the actual current value to the reference current value, the power control unit reads the power value read in the power reading process or is transmitted from the power control unit to the power source unit. A failure determination unit that determines whether a failure has occurred in at least one of the power deriving unit and the power supply control unit based on the target power supply power value ;
The failure determination unit includes the power value read by the power supply control unit in the power reading process when the current information change unit is changing the actual current value to the reference current value, and the reference current value. Based on the standard power value to be derived by the power deriving unit based on the deviation,
The power supply unit is a distributed power supply device configured to perform the power supply operation in consideration of the deviation and the target power supply value transmitted from the power supply control unit . The failure determination unit determines that a failure has occurred if the deviation is greater than or equal to a predetermined value,
The distributed power supply device according to claim 1, wherein the power supply unit is configured to stop the power feeding operation when the failure determination unit determines that a failure has occurred. A distributed power supply unit interconnected to a power system via a power line,
A power supply unit that performs power supply operation based on the instructed target power supply power and supplies power to the power line;
Based on the voltage value of the power in the power line and the current value of the power in the power line transmitted from the current detection unit via the current signal line, the power value supplied from the power system to the power line A power deriving unit that performs a power deriving process;
Based on the power reading process that is transmitted from the power deriving unit through the power signal line and reads the power value derived in the power deriving process, and the power value read in the power reading process, the power line reads the power value. A target power derivation process for deriving a target power supply power value to be supplied to the power line by the power supply unit, and the target power supply power value is transmitted to the power supply unit so that a reverse power flow to the power system does not occur A power control unit that performs target power transfer processing;
A power information changing unit provided in the middle of the power signal line and capable of changing an actual power value transmitted from the power deriving unit to a predetermined reference power value;
When the power information changing unit changes the actual power value to the reference power value, the power control unit reads the power value read in the power reading process or is transmitted from the power control unit to the power source unit. A distributed power supply apparatus comprising: a failure determination unit that determines whether a failure has occurred in the power supply control unit based on the target power supply power value. The distributed power supply apparatus according to claim 3, wherein the power supply unit is configured to stop the power feeding operation when the failure determination unit determines that a failure has occurred. The failure determination unit is a target power supply value actually derived by the power supply control unit when the power value transmitted from the power deriving unit is changed to the reference power value by the power information changing unit, Deriving a deviation between the reference power supply power value to be derived by the power supply control unit based on the reference power value,
The distributed power supply apparatus according to claim 3, wherein the power supply unit is configured to perform the power supply operation in consideration of the deviation and the target power supply power value transmitted from the power supply control unit. The failure determination unit determines that a failure has occurred if the deviation is greater than or equal to a predetermined value,
The distributed power supply apparatus according to claim 5, wherein the power supply unit is configured to stop the power feeding operation when it is determined by the failure determination unit that a failure has occurred.

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