JP6673784B2 - Power management device - Google Patents

Description

  The present invention relates to a power management device.

  2. Description of the Related Art In recent years, installation of distributed power supply devices such as a solar power generation device, a power storage device, and a fuel cell device in a customer facility has become widespread.

  In a customer facility, a current sensor for measuring a current flowing through a power line connected to a power system is usually installed for controlling a distributed power supply device or the like. For example, when the distributed power supply device is a photovoltaic power generation device and the customer facility has a power sale contract with a power company (power system), a current sensor is installed to calculate the power to be sold.

  An accurate installation position is determined for the current sensor. However, since the current sensor is manually installed by an installer, it may be installed at an incorrect position. If it is installed at an incorrect position, it becomes difficult to correctly control the distributed power supply. Therefore, a method of automatically determining whether or not the installation position of the current sensor is correct is known (for example, Patent Document 1).

JP 2014-72976 A

  For the current sensor, not only the installation position but also the accurate installation direction (polarity) is determined. With the method described in Patent Document 1, it is not possible to determine whether the installation direction is correct or not.

  SUMMARY OF THE INVENTION Accordingly, an object of the present invention, which has been made in view of the above-described problems of the related art, is to provide a power management device that determines an installation direction of a current sensor.

In order to solve the above-described problems, the power management device according to the first aspect is:
A first sub-acquisition unit that acquires a current value from a first current sensor installed on a power line that connects a power system and a load device, and information about buying and selling of power from the power system, the first current sensor Upstream power information corresponding to the power on the power line on the first current sensor side than the distributed power supply connected to the power line on the load device side, output power information corresponding to the power output from the distributed power supply And an acquisition unit having a second sub-acquisition unit for acquiring at least one of drive information indicating a drive state of the distributed power supply;
Generating power information of a power management device corresponding to the power calculated based on the current value, based on the power information of the power management device and the information acquired by the second sub-acquisition unit, A control unit that determines whether the installation direction of the current sensor is correct or not ,
The second sub-acquisition unit acquires the upstream power information,
The control unit is configured to install a second current sensor installed closer to the first current sensor than a connection point between the distributed power source and the power line based on a determination as to whether the installation direction of the first current sensor is correct. it is characterized in that you determine the direction of right or wrong.
The power management device according to the second aspect includes:
A first sub-acquisition unit that acquires a current value from a first current sensor installed on a power line that connects a power system and a load device, and information about buying and selling of power from the power system, the first current sensor Upstream power information corresponding to the power on the power line on the first current sensor side than the distributed power supply connected to the power line on the load device side, output power information corresponding to the power output from the distributed power supply And an acquisition unit having a second sub-acquisition unit for acquiring at least one of drive information indicating a drive state of the distributed power supply;
Generating power information of a power management device corresponding to the power calculated based on the current value, based on the power information of the power management device and the information acquired by the second sub-acquisition unit, A control unit that determines whether the installation direction of the current sensor is correct or not,
The second sub-acquisition unit further acquires the upstream power information and the trading information,
The control unit is configured such that, when the trading information indicates power purchase, the distributed power supply and the power line based on whether a sign of power corresponding to the upstream power information indicates power supply to the load device side. Is judged whether the installation direction of the second current sensor installed on the first current sensor side from the connection point is correct or not.
It is characterized by the following.
The power management device according to the third aspect is:
A first sub-acquisition unit that acquires a current value from a first current sensor installed on a power line that connects a power system and a load device, and information about buying and selling of power from the power system, the first current sensor Upstream power information corresponding to the power on the power line on the first current sensor side than the distributed power supply connected to the power line on the load device side, output power information corresponding to the power output from the distributed power supply And an acquisition unit having a second sub-acquisition unit for acquiring at least one of drive information indicating a drive state of the distributed power supply;
Generating power information of a power management device corresponding to the power calculated based on the current value, based on the power information of the power management device and the information acquired by the second sub-acquisition unit, A control unit that determines whether the installation direction of the current sensor is correct or not,
The control unit includes:
Changing the output of the distributed power source,
Causing the second sub-acquisition unit to acquire the upstream power information before and after a change in output,
A change in the power corresponding to the power information and whether or not the direction of the change in the power corresponding to the power information of the power management apparatus before and after the change in the output of the distributed power supply matches the direction of the change in the output. Determining whether the installation direction of the first current sensor is correct based on the
It is characterized by the following.
The power management device according to the fourth aspect is:
A first sub-acquisition unit that acquires a current value from a first current sensor installed on a power line that connects a power system and a load device, and information about buying and selling of power from the power system, the first current sensor Upstream power information corresponding to the power in the power line on the first current sensor side than the distributed power source connected to the power line on the load device side, output power information corresponding to the power output from the distributed power source And an acquisition unit having a second sub-acquisition unit for acquiring at least one of drive information indicating a drive state of the distributed power supply;
Generating power information of a power management device corresponding to the power calculated based on the current value, and generating the first power information based on the power information of the power management device and the information acquired by the second sub-acquisition unit. A control unit that determines whether the installation direction of the current sensor is correct or not,
The control unit includes:
Changing the output of the distributed power source by a second predetermined value;
Causing the second sub-acquisition unit to acquire the upstream power information before and after a change in output,
Based on whether or not a change in power corresponding to the upstream power information and a change in power corresponding to power information of the power management apparatus before and after a change in the output of the distributed power supply can be considered to be the same, the first The correct orientation of the current sensor installation direction
It is characterized by the following.

  According to the power management device according to the embodiment of the present invention configured as described above, the installation direction of the current sensor can be determined.

1 is a functional block diagram illustrating a schematic configuration of a power management system including a power management device according to a first embodiment. FIG. 2 is a functional block diagram illustrating a schematic configuration of the power management device of FIG. 1. 5 is a flowchart illustrating a direction determination process executed by a control unit of the power management device in the first embodiment. FIG. 6 is a functional block diagram illustrating a schematic configuration of a power management system including a power management device according to a second embodiment. 9 is a flowchart illustrating a direction determination process executed by a control unit of the power management device in the second embodiment. 11 is a flowchart illustrating a direction determination process executed by a control unit of a power management device in a third embodiment. It is a flow chart for explaining direction judgment processing which a control part of a power management device performs in a 4th embodiment. It is a flow chart for explaining direction judgment processing which a control part of a power management device performs in a 5th embodiment. It is a flow chart for explaining direction judgment processing which a control part of a power management device performs in a 6th embodiment.

  Hereinafter, an embodiment of a power management device to which the present invention is applied will be described with reference to the drawings.

  As shown in FIG. 1, a power management system 10 including a power management device 19 according to the first embodiment of the present invention includes a network 11, a watt hour meter 12, a load device 13, a first current sensor 14, a second , A first voltage sensor 16, a second voltage sensor 17, a distributed power supply 18, and a power management device 19.

  In the following figures, the solid lines connecting the functional blocks indicate the flow of electric power. Also, in FIG. 1, broken lines connecting the functional blocks indicate the flow of control signals or information to be communicated. The communication indicated by the broken line may be wire communication or wireless communication.

  In the present embodiment, when the sign of the power at an arbitrary position on the power line 20 is positive, it is determined that the power is being supplied to the load device 13 at that position. Further, when the sign of the power at an arbitrary position on the power line 20 is negative, it is determined that the power is being supplied to the power system 21 at the position.

  Various methods can be adopted for communication of control signals and information. For example, the communication between the power management device 19 and each device such as the watt hour meter 12 and the distributed power source 18 may be communication using a short-range communication method such as ZigBee (registered trademark). The communication between the power management apparatus 19 and the load device 13 may employ various communication methods such as infrared communication, power line communication (PLC), ZigBee, and Echonet Lite (registered trademark). it can.

  The network 11 is, for example, a router, and relays communication of information and instructions among the watt hour meter 12, at least a part of the distributed power source 18, and the power management device 19.

  In the present embodiment, the watt hour meter 12 is, for example, a smart meter. The watt hour meter 12 is connected to the power system 21 and detects power supplied from the power system 21. The watt hour meter 12 can measure the power supplied from the distributed power supply 18 to the power system 21. The watt hour meter 12 calculates the amount of power by integrating the detected power. The watt hour meter 12 periodically notifies the power management apparatus 19 via the network 11 of power trading information, for example, the sign of the calculated power amount. It is assumed that the watt hour meter 12 has been verified at the time of shipment, and it has been confirmed that the sign of the power amount is correct.

  The load device 13 is connected to a power system 21 via a main power line 20 via a wattmeter 12 and a distribution board. The load device 13 is a power load that consumes power, and is, for example, a lighting device, a personal computer, an office device such as a multifunction device, and an air conditioner, a microwave oven, a television, and the like used on the premises of the customer. Various electric appliances.

  In FIG. 1, the power line 20 is represented by a single line, but in detail, is a single-phase three-wire wiring including, for example, two voltage lines and one neutral line. Note that the wiring is not limited to a single-phase three-wire system, and for example, a single-phase two-wire system or a three-phase three-wire system can be used.

  The first current sensor 14 detects a current value flowing through the power line 20 and notifies the power management apparatus 19 of the detected value. Note that the notification in the present embodiment indicates that current information detected by the first current sensor 14 is sent to the power management device 19 via a signal line. The first current sensor 14 is, for example, a split-type clamp sensor that can be attached after the power line 20 is installed. Since the instantaneous current value detected by the clamp sensor is in the form of a voltage value, the instantaneous current value is converted to a current value in the power management device 19. The first current sensor 14 is installed on the power line 20 on the power system 21 side of the first connection point P1. The first connection point P <b> 1 is a connection point between the first distributed power supply 22 and the power line 20 closest to the power system 21. More specifically, the first current sensor 14 is installed on each of two voltage lines (one is a neutral line) in the power line 20. Note that the first current sensor 14 is attached by a contractor after the installation of the power line 20.

  The second current sensor 15 detects the value of the current flowing through the power line 20 and notifies the distributed power supply 18 to which power sale is not permitted. Note that the notification in the present embodiment indicates that current information detected by the second current sensor 15 is sent to the distributed power supply 18 via a signal line. The second current sensor 15 is, for example, a split clamp sensor that can be attached after the power line 20 is installed. As described above, since the instantaneous current value detected by the clamp sensor is in the form of a voltage value, the instantaneous current value is converted to a current value in the distributed power supply 18.

  The second current sensor 15 is installed on the power line 20 between the connection point connecting the distributed power source 18 and the power line 20 corresponding to the second current sensor 15 and the first current sensor 14. More specifically, the second current sensor 15 is installed on each of two voltage lines (one is a center line) in the power line 20.

  In the present embodiment, the second current sensor 15 that notifies the second distributed power source 23 of the current value is provided on the power line 20 between the second connection point P2 and the first current sensor 14. The second distributed power source 23 is the distributed power source 18 connected to the power system 21 next to the first distributed power source 22. The second connection point P2 is a connection point between the second distributed power supply 23 and the power line 20. In the present embodiment, the second current sensor 15 that notifies the third distributed power supply 24 of the current value is provided on the power line 20 between the third connection point P3 and the second connection point P2. . The third distributed power source 24 is the distributed power source 18 connected to the power system 21 next to the second distributed power source 23. The third connection point P3 is a connection point between the third distributed power supply 24 and the power line 20. The second current sensor 15 is attached by a contractor after the installation of the power line 20.

  The first voltage sensor 16 detects a voltage value of the power line 20 and notifies the power management device 19 of the detected voltage value. Note that the notification in the present embodiment indicates that voltage information of the first voltage sensor 16 is sent to the power management device 19 via a signal line. The first voltage sensor 16 may be connected to any place of the power line 20, and may be inside the power management device 19 when the power management device 19 obtains power from the power line 20. More specifically, the first voltage sensors 16 are separately mounted so as to detect the voltage to the neutral line of each of the two voltage lines in the power line 20.

  The second voltage sensor 17 detects the voltage value of the power line 20 and notifies the distributed power supply 18 to which power sale is not permitted. Note that the notification in the present embodiment indicates that the voltage information of the second voltage sensor 17 is sent to the distributed power supply 18 via a signal line. Further, the second voltage sensor 17 may be connected to any place of the power line 20, and may be inside the distributed power supply 18 when the distributed power supply 18 obtains power from the power line 20. More specifically, the second voltage sensors 17 are separately mounted so as to detect a voltage with respect to a neutral line of each of the two voltage lines in the power line 20.

  In the present embodiment, the second voltage sensor 17 that notifies the second distributed power supply 23 of the voltage value is attached to the power line 20 between the first connection point P1 and the second connection point P2. In the present embodiment, the second voltage sensor 17 that notifies the third distributed power supply 24 of the voltage value is attached to the power line 20 between the second connection point P2 and the third connection point P3. I have.

  The distributed power source 18 has a built-in power conditioner, and outputs the power generated by itself or the stored power to the power line 20 as AC power. When the distributed power source 18 is a power storage device, the distributed power source 18 can charge power supplied from the power system 21 or another distributed power source.

  As the distributed power source 18, for example, a solar power generation device, a power storage device, a fuel cell device, an engine power generation device, a wind power generation device, or the like can be used. A plurality of distributed power supplies 18 may be connected to the power line 20. In this embodiment, as described above, the first distributed power supply 22, the second distributed power supply 23, and the third distributed power supply 24 are connected to the power line 20. It is connected to the.

  As described above, the first distributed power source 22, the second distributed power source 23, and the third distributed power source 24 are connected to the power line 20 in order from the power system 21 side to the load device 13 side. Depending on the type of the distributed power supply 18, power supply to the power system 21, that is, power sale is permitted. The distributed power source 18 for which power sale is permitted is connected to the power line 20 on the power system 21 side. On the other hand, the distributed power source 18 that is not permitted to sell power to the power system 21 is connected to the power line 20 on the load device 13 side. In the present embodiment, the distributed power source that is permitted to sell electric power is, for example, a power conversion device that is connected to the power line 20 and that has been certified for reverse power flow by a public organization, and is not permitted to sell power. A non-dispersed power source is, for example, one that has not been certified.

  For example, in the present embodiment, the first distributed power source 22 connected to the power line 20 on the power system 21 side is a photovoltaic power generation device permitted to sell power. Further, the second distributed power source 23 and the third distributed power source 24 connected to the power line 20 on the load device 13 side are a power storage device and a fuel cell device which are not permitted to sell power.

  The distributed power supply 18 for which power sale is not permitted is multiplied by a current value obtained from the second current sensor 15 and a voltage value obtained from the second voltage sensor 17 to obtain a power system 21 or load device 13 side. Is calculated. The distributed power supply 18 notifies the power management apparatus 19 of the power as upstream power information.

  As shown in FIG. 2, the power management device 19 includes a storage unit 25, a display unit 26, an acquisition unit 27, and a control unit 28.

  The storage unit 25 stores information necessary for the operation of the control unit 28 in advance. The storage unit 25 can store information generated by the control unit 28 and the like.

  The display unit 26 displays an image indicating information to be notified to the consumer. The display unit 26 may have a configuration in which a display device is provided outside.

  The acquisition unit 27 includes a first sub-acquisition unit 29 and a second sub-acquisition unit 30. The first sub-acquisition unit 29 acquires a current value from the first current sensor 14. The first sub-acquisition unit 29 acquires a voltage value from the first voltage sensor 16. The second sub-acquisition unit 30 acquires power trading information and upstream power information via the network 11.

  The control unit 28 is configured by causing a dedicated microprocessor or a general-purpose CPU to read a program for executing a specific function. The control unit 28 calculates a power value as power information of the power management device 19 by multiplying the current value and the voltage value obtained by the first sub obtaining unit 29.

  The control unit 28 determines whether the installation direction of the first current sensor 14 is correct based on the power information of the power management device 19 and the information acquired by the second subacquisition unit 30. In the present embodiment, the control unit 28 uses the power trading information in the information acquired by the second sub-acquisition unit 30 to determine whether the installation direction is correct or not.

  More specifically, the control unit 28 determines the installation direction of the first current sensor 14 based on whether the sign of the power value indicated by the power information of the power management device 19 matches the trading status indicated by the trading information. Is judged to be correct. When they match, the control unit 28 determines that the installation direction of the first current sensor 14 is correct. On the other hand, when they do not match, the control unit 28 determines that the installation direction of the first current sensor 14 is incorrect. In the present embodiment, the positive sign of the power indicated by the power information of the power management apparatus 19 matches the power purchase status, and the negative sign matches the power sale status.

  When determining that the installation direction of the first current sensor 14 is correct, the control unit 28 creates an image indicating that the installation direction is correct as data, and causes the display unit 26 to display the image.

  When determining that the installation direction of the first current sensor 14 is incorrect, the control unit 28 creates an image indicating that the installation direction is incorrect as data, and causes the display unit 26 to display the image. Alternatively, when determining that the installation direction of the first current sensor 14 is incorrect, the control unit 28 inverts the sign of the current value acquired from the first current sensor 14 after the determination. After making the determination once, the control unit 28 continues to make correction so that the sign of the current value is automatically inverted. Note that the sign of the current value may be replaced by inverting the sign of the power value. Further, when it is determined that the installation direction of the first current sensor 14 is correct, the control unit 28 does not need to perform the correction by multiplying by the + sign, or may continue to perform the correction by multiplying by the + sign. good.

  Further, when the installation direction of the first current sensor 14 is determined, the control unit 28 controls the second current sensor 15 based on the power trade information and the upstream power information acquired by the second sub-acquisition unit 30. Of the installation direction is determined. More specifically, the control unit 28 determines the second current based on whether or not the sign of the power indicated by the upstream power information when the trading information indicates the power purchase status indicates power supply to the load device 13 side. The correctness of the installation direction of the sensor 15 is determined. When indicating the power supply to the load device 13, the control unit 28 determines that the installation direction of the second current sensor 15 is correct. On the other hand, when the power supply to the load device 13 is not indicated, the control unit 28 determines that the installation direction of the second current sensor 15 is incorrect. In the present embodiment, a positive sign of the power indicated by the upstream power information indicates power supply to the load device 13 side. For example, after it is determined that the installation direction of the first current sensor 14 is correct using the trading information of the watt hour meter 12, the second current sensor 15 connected to the second distributed power source 23 by the power management device 19 is determined. Determine if the installation direction is correct.

  When determining that the installation direction of the second current sensor 15 is correct, the control unit 28 creates an image indicating that the installation direction is correct as data, and causes the display unit 26 to display the image.

  When determining that the installation direction of the second current sensor 15 is incorrect, the control unit 28 creates an image indicating that the installation direction is incorrect as data, and causes the display unit 26 to display the image. Alternatively, when determining that the installation direction is incorrect, the control unit 28 responds to the second current sensor 15 with a command to invert the sign of the current value obtained from the second current sensor 15 after the determination. Notify the distributed power supply 18. Alternatively, when determining that the installation direction is incorrect, the control unit 28 notifies the management company or the like via the network 11 that the distributed power supply 18 cannot operate due to the incorrect installation direction.

  Next, a direction determination process executed by the control unit 28 of the power management apparatus 19 in the first embodiment will be described with reference to the flowchart of FIG. The direction determination processing is started when an input for performing a direction determination is detected with respect to the input device of the power management apparatus 19.

  Steps S100 to S104 relate to the correctness of the installation direction of the first current sensor 14. In step S <b> 100, control unit 28 determines whether or not second sub-acquisition unit 30 has acquired power trading information from watt hour meter 12. If no trade information has been obtained, the process repeats step S100 and waits until trade information is obtained. When the trade information has been acquired, the process proceeds to step S101.

  In step S101, the control unit 28 calculates a power value by multiplying the current value detected by the first current sensor 14 by the voltage value detected by the first voltage sensor 16. After calculating the power value, the process proceeds to step S102.

  In step S102, the control unit 28 determines whether or not the sign of the power value calculated in step S101 matches the trading status indicated by the trading information confirmed to be obtained in step S100. If yes, the process goes to step S103. If not, the process proceeds to step S104.

  In step S103, the control unit 28 causes the display unit 26 to display an image indicating that the installation direction of the first current sensor 14 is correct. After displaying the image, the process proceeds to step S105.

  In step S104, the control unit 28 causes the display unit 26 to display an image indicating that the installation direction of the first current sensor 14 is incorrect. After displaying the image, the process proceeds to step S105. If it is determined that the installation direction is wrong, the subsequent power measurement (current / voltage measurement and power calculation) is stopped. Further, in the present embodiment, the image indicating that the installation direction is incorrect is displayed, but instead of the display, the sign of the current value acquired from the first current sensor 14 is automatically inverted. May be set.

  The process after step S105 relates to the correctness of the installation direction of the second current sensor 15. In step S105, the control unit 28 determines whether or not the second sub-acquisition unit 30 has acquired the trading information indicating the power purchase status. If the trade information has not been obtained, the process repeats step S105 and waits until the trade information is obtained. When the trade information has been acquired, the process proceeds to step S106.

  In step S106, the control unit 28 determines whether or not the second sub-acquisition unit 30 has acquired the upstream power information. When the upstream power information has not been obtained, the process returns to step S105, repeats steps S105 and S106, and waits until the upstream power information is obtained. When the upstream power information has been acquired, the process proceeds to Step S107.

  In step S107, the control unit 28 determines whether or not the sign of the power corresponding to the upstream power information confirmed to be acquired in step S106 matches the power purchase status confirmed to be acquired in step S105. If so, the process proceeds to step S108. If not, the process proceeds to step S109.

  In step S108, the control unit 28 causes the display unit 26 to display an image indicating that the installation direction of the second current sensor 15 is correct. After displaying the image, the direction determination processing ends.

  In step S109, the control unit 28 causes the display unit 26 to display an image indicating that the installation direction of the second current sensor 15 is incorrect. After displaying the image, the direction determination processing ends. If it is determined that the installation direction is wrong, the distributed power supply 18 stops the subsequent operation (power supply to the load). Therefore, instead of displaying an image indicating that the installation direction is incorrect, a command to invert the sign of the current value acquired from the second current sensor 15 may be notified to the distributed power supply 18.

  According to the power management device 19 of the first embodiment having the above-described configuration, the first current sensor based on the power information of the power management device 19 and the power trading information acquired by the second sub-acquisition unit 30. Correctness of the 14 installation directions can be determined. No distributed power supply 18 is provided between the first current sensor 14 and the watt hour meter 12. Therefore, if the installation direction of the first current sensor 14 is correct, the trading status indicated by the trading information and the sign of the power indicated by the power information of the power management apparatus 19 match regardless of the power selling status or the power buying status. . Therefore, the installation direction of the first current sensor 14 can be accurately determined by the determination method of the present embodiment. In particular, even if the distributed power source 18 that cannot communicate with the power management device 19 is connected to the power line 20, the installation direction of the first current sensor 14 can be accurately determined.

  Further, according to the power management device 19 of the first embodiment, when the installation direction of the first current sensor 14 is incorrect, the sign of the current value notified from the first current sensor 14 can be inverted. . According to such a configuration, it is not necessary to pay attention to the installation direction of the first current sensor 14, so that the installation work by the installer is simplified.

  Further, according to the power management apparatus 19 of the first embodiment, it is possible to determine whether the installation direction of the second current sensor 15 is correct based on the upstream power information in the power purchase situation. Regarding the second current sensor 15, another distributed power supply 18 may be connected between the connection point between the distributed power supply 18 and the power line 20 and the watt hour meter 12. Therefore, even if the power meter 12 is in a power sale situation, the distributed power supply 18 on the load device 13 side may supply power to the load device 13 side. On the other hand, when the watt hour meter 12 is in the power purchase state, any of the distributed power supplies 18 supplies power to the load device 13 side. Therefore, if the installation direction of the second current sensor 15 is correct, the power purchase state and the power information The sign of the power indicated by matches. Therefore, the installation direction of the second current sensor 15 can be accurately determined by the determination method of the present embodiment.

  Further, according to the power management apparatus 19 of the first embodiment, when the installation direction of the second current sensor 15 is wrong, the sign of the current value notified from the second current sensor 15 can be inverted. . According to such a configuration, since it is not necessary to pay attention to the installation direction of the second current sensor 15, the installation work by the installer can be simplified. Alternatively, it is possible to notify by a display that the installation direction is wrong, so that even in the case of the distributed power supply 18 in which the sign cannot be inverted, it is possible to early find out the operation stop state due to the installation direction error.

  Next, a power management device 19 according to a second embodiment of the present invention will be described. In the second embodiment, the type of information to be compared with the power information of the power management device 19 is different from that of the first embodiment. Hereinafter, the second embodiment will be described focusing on the differences from the first embodiment. Parts having the same configuration as the first embodiment are denoted by the same reference numerals.

  As shown in FIG. 4, a power management system 100 including a power management device 19 according to the second embodiment includes a network 11, a watt hour meter 12, a load device 13, a first current sensor 14, and a second current sensor. 15, a first voltage sensor 16, a second voltage sensor 17, a distributed power supply 18, a distribution board 31, and a power management device 19.

  The configurations and functions of the network 11, the load device 13, the first current sensor 14, the second current sensor 15, the first voltage sensor 16, and the second voltage sensor 17 are the same as those of the first embodiment. Unlike the first embodiment, the watt hour meter 12 does not need to notify the power management apparatus 19 of the power trading information.

  The distributed power supply 18 has the same function as the distributed power supply 18 in the first embodiment. In the second embodiment, all of the distributed power supplies 18 have a built-in sensor for detecting the power output from the distributed power supplies 18. The sensor is, for example, a combination of a current sensor and a voltage sensor, and a power value is calculated by multiplying the detected current value and voltage value. All distributed power supplies 18 notify the power management apparatus 19 of the calculated power value as output power information.

  The distribution board 31 is, for example, a smart distribution board, and connects the main power line 20 to a plurality of main power lines (a single power line 20 in FIG. 4) on the load device 13 side from the third connection point P3. ). The distribution board 31 detects the power in all the power lines of the trunk, that is, the power supplied to the load devices 13 via the power lines of all the trunks. The distribution board 31 notifies the power management apparatus 19 of total information corresponding to the total value of the detected power. If the output of the distributed power supply 18 can also be detected, the configuration may be such that the smart power distribution panel notifies the power management apparatus 19.

  The configuration of the power management apparatus 19 according to the second embodiment is the same as that of the first embodiment shown in FIG. Unlike the first embodiment, the power management apparatus 19 of the second embodiment differs from the first embodiment in part of the information acquired by the acquisition unit 27 and the control executed by the control unit 28.

  The first sub-acquisition unit 29 acquires a current value and a voltage value from the first current sensor 14 and the first voltage sensor 16, respectively, as in the first embodiment. The second sub-acquisition unit 30 acquires the upstream power information as in the first embodiment. Unlike the first embodiment, the second sub-acquisition unit 30 acquires output power information and total information from all the distributed power sources 18 and the distribution boards 31, respectively. At this time, when the distributed power supply 18 is a power storage device, the output power information also includes identification information indicating whether the power supply state or the charging power consumption state.

  The control unit 28 calculates the power information of the power management device 19 as in the first embodiment, and based on the power information of the power management device 19 and the information acquired by the second sub-acquisition unit 30, Of the installation direction of the current sensor 14 is determined. In the second embodiment, the control unit 28 uses the output power information and the total information in the information acquired by the second sub-acquisition unit 30 to determine whether the installation direction is correct.

  More specifically, the control unit 28 sums up the power values corresponding to all pieces of output power information. At this time, if the distributed power source 18 is a power storage device, the power is treated as supply power during discharging and as power consumption during charging. Next, the control unit 28 calculates a difference obtained by subtracting the total value of the power corresponding to the output power information from the power corresponding to the total information. Next, the control unit 28 installs the first current sensor 14 based on whether or not the trading status indicated by the sign of the difference matches the sign of the power corresponding to the power information of the power management apparatus 19. The correctness of the direction is determined. It should be noted that when the difference obtained by subtracting the total value from the power corresponding to the total information is positive, it is a power purchase situation, and when the difference is negative, it is a power sale situation. Similarly to the first embodiment, the positive sign of the power indicated by the power information of the power management apparatus 19 matches the power purchase situation, and the negative sign matches the power sale situation.

  As in the first embodiment, when they match, the control unit 28 determines that the installation direction of the first current sensor 14 is correct. On the other hand, when they do not match, the control unit 28 determines that the installation direction of the first current sensor 14 is incorrect.

  As in the first embodiment, when determining that the installation direction of the first current sensor 14 is correct, the control unit 28 creates an image indicating that the installation direction is correct as data, and displays the image on the display unit 26. To be displayed.

  As in the first embodiment, when determining that the installation direction of the first current sensor 14 is incorrect, the control unit 28 creates an image indicating that the installation direction is incorrect as data, and Is displayed on the display unit 26. Alternatively, when determining that the installation direction is incorrect, the control unit 28 inverts the sign of the current value acquired from the first current sensor 14 after the determination.

  Unlike the first embodiment, the control unit 28 determines whether or not the first current sensor 14 is installed in the right or wrong direction, the power information of the power management device 19, and the upstream power information. Judge whether the installation direction is correct or not.

  More specifically, when the installation direction is correct and the sign of the power corresponding to the power information of the power management apparatus 19 indicates the power purchase, it can be considered that the customer facility is in the power purchase state. Therefore, the control unit 28 determines whether the sign of the power value corresponding to the upstream power information indicates the power supply to the load device 13 when the power purchase state is based on the right / wrong determination information and the power information of the power management apparatus 19. Determine whether or not. The control unit 28 determines whether the installation direction of the second current sensor 15 is correct based on the determination result.

  Similarly to the first embodiment, when indicating the power supply to the load device 13, the control unit 28 determines that the installation direction of the second current sensor 15 is correct. On the other hand, when the power supply to the load device 13 is not indicated, the control unit 28 determines that the installation direction of the second current sensor 15 is incorrect. Also in the second embodiment, the positive sign of the power value indicated by the power information matches the power supply to the load device 13 side.

  As in the first embodiment, when determining that the installation direction of the second current sensor 15 is correct, the control unit 28 creates an image indicating that the installation direction is correct as data, and displays the image on the display unit 26. To be displayed.

  As in the first embodiment, when determining that the installation direction of the second current sensor 15 is incorrect, the control unit 28 creates an image indicating that the installation direction is incorrect as data, and Is displayed on the display unit 26. Alternatively, when determining that the installation direction is incorrect, the control unit 28 responds to the second current sensor 15 with a command to invert the sign of the current value obtained from the second current sensor 15 after the determination. Notify the distributed power supply 18. Alternatively, when determining that the installation direction is incorrect, the control unit 28 notifies the management company or the like via the network 11 that the distributed power supply 18 cannot operate due to the incorrect installation direction.

  Next, a direction determination process performed by the control unit 28 of the power management apparatus 19 in the second embodiment will be described with reference to the flowchart in FIG. The direction determination processing is started when an input for performing a direction determination is detected with respect to the input device of the power management apparatus 19.

  Steps S200 to S204 relate to the correctness of the installation direction of the first current sensor 14. In step S200, the control unit 28 determines whether the second sub-acquisition unit 30 has acquired output power information and total information from the distribution board 31. If the output power information and the total information have not been obtained, the process repeats step S200 and waits until the output power information and the total information are obtained. If yes, the process goes to step S201.

  In step S201, the control unit 28 executes the same processing as in step S101 of the first embodiment, and proceeds to step S202.

  In step S202, the control unit 28 determines whether or not the trading status indicated by the difference between the power value based on the output power information and the total information obtained in step S200 and the sign of the power value calculated in step S201 match. judge. If so, the process proceeds to step S203. If not, the process proceeds to step S204.

  In steps S203 and S204, the control unit 28 executes the same processing as steps S103 and S104 in the first embodiment, respectively, and proceeds to step S205.

  The process after step S205 relates to the correctness of the installation direction of the second current sensor 15. In step S205, the control unit 28 determines whether the power value corresponding to the power information of the power management apparatus 19 indicates the power purchase status, when the control unit 28 determines in step S202 that it matches, that is, determines that the installation direction is correct. Is determined. If not, the process repeats step S205 and waits until indicating the power purchase status. If so, the process proceeds to step S206. In addition, when it is determined in step S202 that the power does not match, that is, the installation direction is incorrect, the control unit 28 determines whether or not the power corresponding to the power information of the power management apparatus 19 indicates the power sale situation. Is determined. If not, the process repeats step S205 and waits until indicating a power sale status. If so, the process proceeds to step S206.

  In step S206, the control unit 28 determines whether or not the second sub-acquisition unit 30 has acquired the upstream power information, as in step S106 of the first embodiment. If the upstream power information has not been obtained, the process returns to step S205, repeats steps S205 and S206, and waits until the upstream power information is obtained. If the upstream power information has been acquired, the process proceeds to step S207.

  In step S207, the control unit 28 determines whether or not the sign of the power value indicated by the upstream power information confirmed to be obtained in step S206 matches the power purchase status, in other words, the power supply to the load device 13 side. judge. If so, the process proceeds to step S208. If not, the process proceeds to step S209.

  In steps S208 and S209, the control unit 28 executes the same processing as steps S108 and S109 of the first embodiment, respectively, and ends the direction determination processing.

  According to the power management device 19 of the second embodiment having the above-described configuration, the first power management device 19 is configured based on the power information of the power management device 19, the output power information acquired by the second sub-acquisition unit 30, and the total information. Correctness of the installation direction of the current sensor 14 can be determined. When the total value of the electric power in all the main power lines exceeds the total value of the electric power output from all the distributed power sources 18, the customer facility is in a power purchase state. When the total value of the power in all the power lines of the trunk is equal to or less than the total value of the power output from all the distributed power sources 18, the customer facility is in the power selling state. As in the first embodiment, no distributed power supply 18 is provided between the first current sensor 14 and the watt hour meter 12. Therefore, if the installation direction of the first current sensor 14 is correct, the trading status based on the output power information and the total information and the sign of the power indicated by the power information of the power management device 19 indicate the power selling status and the power purchasing status. Matches any of Therefore, the accurate installation direction of the first current sensor 14 can be determined by the determination method as in the second embodiment.

  Further, according to the power management apparatus 19 of the second embodiment, it is possible to determine whether the installation direction of the second current sensor 15 is correct based on the determination whether the installation direction of the first current sensor 14 is correct. The control unit 28 can determine whether or not the sign of the power corresponding to the power information of the power management device 19 is the power purchase status, based on the correctness determination of the installation direction of the first current sensor 14. Therefore, similarly to the first embodiment, the second power is determined by determining whether or not the sign of the power corresponding to the upstream power information indicates the power supply to the load device 13 in the power purchase situation. The accurate installation direction of the current sensor 15 can be determined.

  Also, similarly to the first embodiment, when the installation direction of the first current sensor 14 is incorrect, the power management device 19 of the second embodiment also notifies the first current sensor 14 of the error. The sign of the current value can be reversed. In addition, the power management device 19 of the second embodiment can also reverse the sign of the current value notified from the second current sensor 15 when the installation direction is incorrect. Alternatively, the power management apparatus 19 according to the second embodiment can also notify the installation direction that the error is caused by the display, so that even if the distributed power source 18 cannot reverse the sign, the operation is stopped due to the error in the installation direction. Can be discovered at an early stage.

  Next, a power management device 19 according to a third embodiment of the present invention will be described. In the third embodiment, the type of information to be compared with the power information of the power management device 19 is different from that of the first embodiment. Hereinafter, the third embodiment will be described focusing on the differences from the first embodiment. Parts having the same configuration as the first embodiment are denoted by the same reference numerals.

  The configuration of the power management system 10 including the power management device 19 according to the third embodiment is the same as that of the power management system 10 according to the first embodiment shown in FIG.

  The configurations and functions of the network 11, the load device 13, the first current sensor 14, the second current sensor 15, the first voltage sensor 16, and the second voltage sensor 17 are the same as those of the first embodiment. Unlike the first embodiment, the watt hour meter 12 does not need to notify the power management apparatus 19 of the power trading information.

  As in the first embodiment, the distributed power source 18 outputs the power generated by itself or the stored power to the power line 20 as AC power. Unlike the first embodiment, all the distributed power supplies 18 notify the power management device 19 of the drive information indicating the stop when the distributed power supplies 18 are stopped.

  The configuration of the power management apparatus 19 according to the third embodiment is the same as that of the first embodiment shown in FIG. Unlike the first embodiment, the power management apparatus 19 according to the third embodiment differs from the first embodiment in part of the information acquired by the acquisition unit 27 and control performed by the control unit 28.

  The first sub-acquisition unit 29 acquires a current value and a voltage value from the first current sensor 14 and the first voltage sensor 16, respectively, as in the first embodiment. The second sub-acquisition unit 30 acquires the upstream power information as in the first embodiment. Unlike the first embodiment, the second sub-acquisition unit 30 acquires the drive information of all the distributed power sources 18.

  The control unit 28 calculates the power information of the power management device 19 as in the first embodiment, and based on the power information of the power management device 19 and the information acquired by the second sub-acquisition unit 30, The correct orientation of the current sensor 14 is determined. In the third embodiment, the control unit 28 uses the drive information in the information acquired by the second sub-acquisition unit 30 to determine whether the installation direction is correct.

  More specifically, the control unit 28 checks whether the drive information of all the distributed power sources 18 indicates stop. Alternatively, the control unit 28 may be configured to notify a stop command to all the distributed power supplies 18 and then wait until the drive information indicating the stop is acquired from all the distributed power supplies 18.

  When all the distributed power supplies 18 indicate the stop, the control unit 28 sets the first current sensor based on whether or not the sign of the power corresponding to the power information of the power management apparatus 19 matches the power purchase status. The correctness of the installation direction of 14 is determined. Note that, similarly to the first embodiment, the positive sign of the power indicated by the power information of the power management apparatus 19 matches the power purchase situation, and the negative sign matches the power sale situation.

  As in the first embodiment, when they match, the control unit 28 determines that the installation direction of the first current sensor 14 is correct. On the other hand, when they do not match, the control unit 28 determines that the installation direction of the first current sensor 14 is incorrect.

  As in the first embodiment, when determining that the installation direction of the first current sensor 14 is correct, the control unit 28 creates an image indicating that the installation direction is correct as data, and displays the image on the display unit 26. To be displayed.

  As in the first embodiment, when determining that the installation direction of the first current sensor 14 is incorrect, the control unit 28 creates an image indicating that the installation direction is incorrect as data, and Is displayed on the display unit 26. Alternatively, when determining that the installation direction is incorrect, the control unit 28 inverts the sign of the current value acquired from the first current sensor 14 after the determination.

  In the third embodiment, similarly to the second embodiment, the control unit 28 determines whether the installation direction of the first current sensor 14 is correct, based on the power information of the power management device 19, and the upstream power information. It is determined whether the installation direction of the second current sensor 15 is correct.

  Similarly to the second embodiment, when indicating the power supply to the load device 13 side, the control unit 28 determines that the installation direction of the second current sensor 15 is correct. On the other hand, when the power supply to the load device 13 is not indicated, the control unit 28 determines that the installation direction of the second current sensor 15 is incorrect. Also in the third embodiment, the positive sign of the power indicated by the power information matches the power supply to the load device 13 side.

  As in the first embodiment, when determining that the installation direction of the second current sensor 15 is correct, the control unit 28 creates an image indicating that the installation direction is correct as data, and displays the image on the display unit 26. To be displayed.

  As in the first embodiment, when determining that the installation direction of the second current sensor 15 is incorrect, the control unit 28 creates an image indicating that the installation direction is incorrect as data, and Is displayed on the display unit 26. Alternatively, when determining that the installation direction is incorrect, the control unit 28 responds to the second current sensor 15 with a command to invert the sign of the current value obtained from the second current sensor 15 after the determination. Notify the distributed power supply 18. Alternatively, when determining that the installation direction is wrong, the control unit 28 notifies the distributed power supply 18 of a stop command of the distributed power supply 18 corresponding to the second current sensor 15.

  Next, a direction determination process executed by the control unit 28 of the power management apparatus 19 in the third embodiment will be described with reference to the flowchart in FIG. The direction determination processing is started when an input for performing a direction determination is detected with respect to the input device of the power management apparatus 19.

  Steps S300 to S304 relate to the correctness of the installation direction of the first current sensor 14. In step S300, the control unit 28 determines whether or not the second sub-acquisition unit 30 has acquired drive information indicating stop from all the distributed power sources 18. If not, the process repeats step S300 and waits until drive information indicating stop is obtained from all distributed power supplies 18. If yes, the process goes to step S301.

  In step S301, the control unit 28 executes the same processing as step S101 of the first embodiment, and proceeds to step S302.

  In step S302, the control unit 28 determines whether or not the sign of the power calculated in step S301 matches the power purchase situation. If so, the process proceeds to step S303. If not, the process proceeds to step S304.

  In subsequent steps S303 to S309, the control unit 28 executes the same processing as steps S203 to S209 of the second embodiment, and ends the direction determination processing.

  According to the power management apparatus 19 of the third embodiment having the above-described configuration, the first current is controlled based on the power information of the power management apparatus 19 and the drive information indicating the stop acquired by the second sub-acquisition unit 30. Correctness of the installation direction of the sensor 14 can be determined. When all the distributed power supplies 18 connected to the power line 20 are stopped, the customer facility is generally in a power purchase state. Therefore, the exact installation direction of the first current sensor 14 can be determined by checking the trading status indicated by the power information of the power management device 19 when all the distributed power sources 18 are stopped.

  Also, similarly to the first embodiment, when the installation direction of the first current sensor 14 is incorrect, the power management device 19 of the third embodiment notifies the first current sensor 14 of the wrong orientation. The sign of the current value can be reversed. Also, according to the power management apparatus 19 of the third embodiment, similarly to the second embodiment, based on the right / wrong determination of the installation direction of the first current sensor 14, the installation direction of the second current sensor 15 is determined. Correctness can be determined. Also, according to the power management apparatus 19 of the third embodiment, when the installation direction of the second current sensor 15 is incorrect, the sign of the current value notified from the second current sensor 15 can be inverted. Alternatively, the power management apparatus 19 according to the third embodiment can also display a notification that the installation direction of the second current sensor 15 is incorrect, so that even if the distributed power supply 18 cannot reverse the sign, An operation stop state due to an incorrect installation direction can be found early.

  Next, a power management device 19 according to a fourth embodiment of the present invention will be described. In the fourth embodiment, the type of information to be compared with the power information of the power management apparatus 19 is different from that of the first embodiment. Hereinafter, the fourth embodiment will be described with a focus on differences from the first embodiment. Parts having the same configuration as the first embodiment are denoted by the same reference numerals.

  The configuration of the power management system 10 including the power management device 19 according to the fourth embodiment is the same as that of the power management system 10 according to the first embodiment shown in FIG.

  The configurations and functions of the network 11, the load device 13, the first current sensor 14, the second current sensor 15, the first voltage sensor 16, and the second voltage sensor 17 are the same as those of the first embodiment. Unlike the first embodiment, the watt hour meter 12 does not need to notify the power management apparatus 19 of the power trading information.

  Similarly to the first embodiment, the distributed power source 18 outputs the power generated by itself or the charged power to the power line 20 as AC power. In the fourth embodiment, the distributed power source 18 connected to the power line 20 includes a power storage device. In the fourth embodiment, the distributed power supply 18 stops power generation and executes charging based on a command from the power management device 19.

  Further, in the fourth embodiment, as in the third embodiment, all the distributed power sources 18 (the first distributed power source 22 and the third distributed power source 24) other than the power storage device stop. The power management device 19 is notified of the drive information indicating the occasional stop. In the fourth embodiment, the second distributed power supply 23 that is a power storage device notifies the power management device 19 of driving information indicating a charged state when the second distributed power supply 23 is in a charged state.

  The configuration of the power management device 19 in the fourth embodiment is the same as that of the first embodiment shown in FIG. Unlike the first embodiment, the power management apparatus 19 of the fourth embodiment is different from the first embodiment in a part of the information acquired by the acquisition unit 27 and the control executed by the control unit 28.

  The first sub-acquisition unit 29 acquires a current value and a voltage value from the first current sensor 14 and the first voltage sensor 16, respectively, as in the first embodiment. The second sub-acquisition unit 30 acquires the upstream power information as in the first embodiment. Unlike the first embodiment, the second sub-acquisition unit 30 acquires the drive information of the distributed power supply 18.

  The control unit 28, unlike the first embodiment, notifies the second distributed power source 23 as a power storage device of a charge command. Further, unlike the first embodiment, the control unit 28 notifies the distributed power supply 18 (the first distributed power supply 22 and the third distributed power supply 24) other than the power storage device of a power generation stop command.

  The control unit 28 calculates the power information of the power management device 19 as in the first embodiment, and calculates the first information based on the power information of the power management device 19 and the information acquired by the second sub-acquisition unit 30. Of the installation direction of the current sensor 14 is determined. In the fourth embodiment, the control unit 28 uses the drive information in the information acquired by the second sub-acquisition unit 30 to determine whether the installation direction is correct.

  More specifically, the control unit 28 determines that the drive information from the second distributed power supply 23 that is a power storage device indicates a charging state, and that all of the distributed power supplies 18 (the first distributed power supply 22, the third distributed power supply 22, It is confirmed whether the drive information from the distributed power supply 24) indicates a stop state.

  When the second distributed power supply 23 as a power storage device is in a charged state and all the distributed power sources 18 (the first distributed power supply 22 and the third distributed power supply 24) other than the power storage device are in a stopped state, the customer facility is It can be considered that it is a power sale situation. Therefore, the control unit 28 corresponds to the power information of the power management apparatus 19 when the power is purchased based on the drive information of the first distributed power supply 22, the second distributed power supply 23, and the third distributed power supply 24. It is determined whether the sign of the power to be performed matches the power purchase situation. The control unit 28 determines whether the installation direction of the first current sensor 14 is correct or not based on the determination result. Note that, similarly to the first embodiment, the positive sign of the power indicated by the power information of the power management apparatus 19 matches the power purchase situation, and the negative sign matches the power sale situation.

  As in the first embodiment, when they match, the control unit 28 determines that the installation direction of the first current sensor 14 is correct. On the other hand, when they do not match, the control unit 28 determines that the installation direction of the first current sensor 14 is incorrect.

  As in the first embodiment, when determining that the installation direction of the first current sensor 14 is correct, the control unit 28 creates an image indicating that the installation direction is correct as data, and displays the image on the display unit 26. To be displayed.

  As in the first embodiment, when determining that the installation direction of the first current sensor 14 is incorrect, the control unit 28 creates an image indicating that the installation direction is incorrect as data, and Is displayed on the display unit 26. Alternatively, when determining that the installation direction of the first current sensor 14 is incorrect, the control unit 28 inverts the sign of the current value acquired from the first current sensor 14 after the determination.

  In the fourth embodiment, similarly to the second embodiment, the control unit 28 determines whether the first current sensor 14 is installed correctly or not, based on the power information of the power management device 19, and the upstream power information. It is determined whether the installation direction of the second current sensor 15 is correct.

  Similarly to the first embodiment, when indicating the power supply to the load device 13, the control unit 28 determines that the installation direction of the second current sensor 15 is correct. On the other hand, when the power supply to the load device 13 is not indicated, the control unit 28 determines that the installation direction of the second current sensor 15 is incorrect. Also in the fourth embodiment, the positive sign of the power indicated by the power information matches the power supply to the load device 13 side.

  As in the first embodiment, when determining that the installation direction of the second current sensor 15 is correct, the control unit 28 creates an image indicating that the installation direction is correct as data, and displays the image on the display unit 26. To be displayed.

  As in the first embodiment, when determining that the installation direction of the second current sensor 15 is incorrect, the control unit 28 creates an image indicating that the installation direction is incorrect as data, and Is displayed on the display unit 26. Alternatively, when determining that the installation direction is incorrect, the control unit 28 responds to the second current sensor 15 with a command to invert the sign of the current value obtained from the second current sensor 15 after the determination. Notify the distributed power supply 18. Alternatively, when determining that the installation direction is incorrect, the control unit 28 notifies the management company or the like via the network 11 that the distributed power supply 18 cannot operate due to the incorrect installation direction.

  Next, a direction determination process executed by the control unit 28 of the power management apparatus 19 in the fourth embodiment will be described with reference to the flowchart in FIG. The direction determination processing is started when an input for performing a direction determination is detected with respect to the input device of the power management apparatus 19.

  In step S400, the control unit 28 notifies the second distributed power source 23 as a power storage device of a charge command, and the distributed power source 18 other than the power storage device (the first distributed power source 22, the third distributed power source 24, ) Is notified of a power generation stop command. After the notification, the process proceeds to step S401.

  In step S <b> 401, the control unit 28 determines that the second sub-acquisition unit 30 is driving information indicating that the second distributed power source 23 is in a charged state and that the first distributed power source 22 and the third distributed power source 24 indicate that the driving is stopped. It is determined whether information has been acquired. If not, the process repeats step S401 and waits. If yes, the process goes to step S402.

  In subsequent steps S402 to S410, the control unit 28 executes the same processing as steps S301 to S309 in the third embodiment, and ends the direction determination processing.

  According to the power management apparatus 19 of the fourth embodiment having the above-described configuration, the first current is controlled based on the power information of the power management apparatus 19 and the drive information indicating the stop acquired by the second sub-acquisition unit 30. Correctness of the installation direction of the sensor 14 can be determined. When the second distributed power supply 23 as the power storage device is in a charged state and all the other distributed power supplies 18 (the first distributed power supply 22 and the third distributed power supply 24) connected to the power line 20 are stopped, the demand House facilities are in power purchase status. Therefore, the power of the power management apparatus 19 when the second distributed power supply 23 as a power storage device is charged and all the other distributed power supplies 18 (the first distributed power supply 22 and the third distributed power supply 24) are stopped. By confirming the trading status indicated by the information, it is possible to determine the exact installation direction of the first current sensor 14.

  Also, similarly to the first embodiment, when the installation direction of the first current sensor 14 is erroneous, the power management device 19 of the fourth embodiment also notifies the first current sensor 14 of the error. The sign of the current value can be reversed. Also, according to the power management apparatus 19 of the fourth embodiment, similarly to the second embodiment, the installation direction of the second current sensor 15 is determined based on whether the installation direction of the first current sensor 14 is correct or not. Correctness can be determined. Also, according to the power management device 19 of the fourth embodiment, when the installation direction of the second current sensor 15 is incorrect, the sign of the current value notified from the second current sensor 15 can be inverted. Alternatively, the power management apparatus 19 of the fourth embodiment can also notify the installation direction of the second current sensor 15 that the installation direction of the second current sensor 15 is incorrect. An operation stop state due to an incorrect installation direction can be found early.

  Next, a power management device 19 according to a fifth embodiment of the present invention will be described. In the fifth embodiment, the type of information to be compared with the power information of the power management device 19 is different from that of the first embodiment. Hereinafter, the fifth embodiment will be described focusing on the differences from the first embodiment. Parts having the same configuration as the first embodiment are denoted by the same reference numerals.

  The configuration of the power management system 10 including the power management device 19 according to the fifth embodiment is the same as that of the power management system 10 according to the first embodiment shown in FIG.

  The configurations and functions of the network 11, the load device 13, the first current sensor 14, the second current sensor 15, the first voltage sensor 16, the second voltage sensor 17, and the distributed power source 18 are the same as those of the first embodiment. The same is true. Unlike the first embodiment, the watt hour meter 12 does not need to notify the power management apparatus 19 of the power trading information.

  The configuration of the power management apparatus 19 in the fifth embodiment is the same as that in the first embodiment shown in FIG. Unlike the first embodiment, the power management device 19 of the fifth embodiment is different from the first embodiment in the control executed by the control unit 28.

  The control unit 28 notifies the at least one distributed power source 18 of a command to change the output, unlike the first embodiment. In the fifth embodiment, the change in the output is a decrease. The command to lower the output also includes a command to charge the distributed power supply 18 which is a power storage device. The type of the distributed power supply 18 that reduces the output is not limited.

  For example, when decreasing the output of the distributed power supply 18, which is a power storage device, the power to be discharged may be reduced, switching from discharging or stopping to charging may be performed, or the power to be charged may be increased. When the output of the distributed power source 18 that is a solar power generation device or a fuel cell device is reduced, the power to be generated may be reduced (including stoppage).

  The control unit 28 calculates the power information of the power management device 19 as in the first embodiment, and based on the power information of the power management device 19 and the information acquired by the second sub-acquisition unit 30, The correct orientation of the current sensor 14 is determined. In the fifth embodiment, the control unit 28 uses the upstream power information in the information acquired by the second sub-acquisition unit 30 to determine whether the installation direction is correct.

  More specifically, as described above, the control unit 28 notifies the at least one distributed power source 18 of a command to reduce the output. The control unit 28 acquires the power information and the upstream power information of the power management device 19 before notifying the output reduction command. Since the upstream power information acquired at this time is in a state where the correctness of the installation direction is unknown, the power value (the amount of power supplied to the load and the amount of power sold) during the determination of the installation direction of the first current sensor 14 is determined. May be added to the past power value until the determination is completed, and may be added after the determination is completed. The control unit 28 acquires the power information of the power management device 19 when the change in the power corresponding to the upstream power information after the notification increases in the power supply direction to the load device 13 side, that is, in the present embodiment. The control unit 28 determines whether the change in the power corresponding to the power information of the power management apparatus 19 before and after the notification of the output decrease command is a change in the power supply direction to the load device 13 side. It is determined whether the installation direction of the first current sensor 14 is correct.

  Note that the determination of the correctness of the installation direction of the first current sensor 14 in the control unit 28 may be performed twice or more at predetermined time intervals, and the final determination may be performed based on the determination result. For example, the determination of correctness of the installation direction may be performed an odd number of times at a predetermined time interval, and a determination result with a large number of times may be determined as the final determination.

  As in the first embodiment, when they match, the control unit 28 determines that the installation direction of the first current sensor 14 is correct. On the other hand, when they do not match, the control unit 28 determines that the installation direction of the first current sensor 14 is incorrect.

  As in the first embodiment, when determining that the installation direction of the first current sensor 14 is correct, the control unit 28 creates an image indicating that the installation direction is correct as data, and displays the image on the display unit 26. To be displayed.

  As in the first embodiment, when determining that the installation direction of the first current sensor 14 is incorrect, the control unit 28 creates an image indicating that the installation direction is incorrect as data, and Is displayed on the display unit 26. Alternatively, when determining that the installation direction of the first current sensor 14 is incorrect, the control unit 28 inverts the sign of the current value acquired from the first current sensor 14 after the determination.

  In the fifth embodiment, as in the second embodiment, the control unit 28 determines whether the installation direction of the first current sensor 14 is correct, based on the power information of the power management device 19, and the upstream power information. It is determined whether the installation direction of the second current sensor 15 is correct.

  Similarly to the first embodiment, when indicating the power supply to the load device 13, the control unit 28 determines that the installation direction of the second current sensor 15 is correct. On the other hand, when the power supply to the load device 13 is not indicated, the control unit 28 determines that the installation direction of the second current sensor 15 is incorrect. Also in the fifth embodiment, the positive sign of the power indicated by the power information matches the power supply to the load device 13 side.

  As in the first embodiment, when determining that the installation direction of the second current sensor 15 is correct, the control unit 28 creates an image indicating that the installation direction is correct as data, and displays the image on the display unit 26. To be displayed.

  As in the first embodiment, when determining that the installation direction of the second current sensor 15 is incorrect, the control unit 28 creates an image indicating that the installation direction is incorrect as data, and Is displayed on the display unit 26. Alternatively, when determining that the installation direction is incorrect, the control unit 28 responds to the second current sensor 15 with a command to invert the sign of the current value obtained from the second current sensor 15 after the determination. Notify the distributed power supply 18. Alternatively, when determining that the installation direction is incorrect, the control unit 28 notifies the management company or the like via the network 11 that the distributed power supply 18 cannot operate due to the incorrect installation direction.

  Next, a direction determination process performed by the control unit 28 of the power management apparatus 19 in the fifth embodiment will be described with reference to the flowchart in FIG. The direction determination processing is started when an input for performing a direction determination is detected with respect to the input device of the power management apparatus 19.

  In step S500, the control unit 28 determines whether or not the second sub-acquisition unit 30 has acquired the upstream power information of the distributed power source 18 whose output is to be reduced. If not, the process repeats step S500 and waits until upstream power information is obtained. If yes, the process goes to step S501.

  In step S501, the control unit 28 executes the same processing as step S101 of the first embodiment, and the process proceeds to step S502.

  In step S502, the control unit 28 notifies the distributed power source 18, which has confirmed the acquisition of the upstream power information in step S500, of a command to reduce the output. After the notification, the process proceeds to step S503.

  In step S503, the control unit 28 determines that the second sub-acquisition unit 30 acquires the upstream power information from the distributed power supply 18 that has notified the command to reduce the output in step S502, and the power corresponding to the upstream power information is In step S500, it is determined whether the power has increased from the power corresponding to the upstream power information confirmed to be acquired. If not, the process returns to step S502, repeats steps S302 and S503, and waits for the increase. If so, the process proceeds to step S504. If the output of the distributed power source 18 cannot be further reduced, the determination cannot be continued, and the direction determination processing ends.

  In step S504, the control unit 28 calculates the power information of the power management apparatus 19 in the same manner as in step S501. After the calculation, the process proceeds to step S505.

  In step S505, the control unit 28 determines that the direction of the power change corresponding to the power information of the power management apparatus 19 calculated in steps S501 and 504 is the power change corresponding to the power information whose output has been changed in step S502. It is determined whether or not it matches the direction, in other words, whether it is increasing. If so, the process proceeds to step S506. If not, the process proceeds to step S507.

  In subsequent steps S506 to S512, the control unit 28 executes the same processing as steps S203 to S209 of the second embodiment, and ends the direction determination processing.

  According to the power management device 19 of the fifth embodiment having the above-described configuration, the first current sensor 14 based on the power information of the power management device 19 and the upstream power information acquired by the second sub-acquisition unit 30. It can be determined whether the installation direction is correct or not. In particular, even if the distributed power source 18 that cannot communicate with the power management device 19 is connected to the power line 20, the installation direction of the first current sensor 14 can be determined.

  Further, according to the power management apparatus 19 of the fifth embodiment, the determination of the installation direction of the first current sensor 14 is performed a plurality of times, and the final determination is performed based on the result. Even if a change or the like occurs, the correctness of the installation direction can be determined with high accuracy.

  Also, similarly to the first embodiment, when the installation direction of the first current sensor 14 is incorrect, the power management device 19 of the fifth embodiment also notifies the first current sensor 14 of the error. The sign of the current value can be reversed. Also, according to the power management apparatus 19 of the fifth embodiment, similarly to the second embodiment, the installation direction of the second current sensor 15 is determined based on whether the installation direction of the first current sensor 14 is correct or not. Correctness can be determined. Also, according to the power management apparatus 19 of the fifth embodiment, when the installation direction of the second current sensor 15 is wrong, the sign of the current value notified from the second current sensor 15 can be inverted. Alternatively, the power management device 19 according to the fifth embodiment can also display a notification that the installation direction of the second current sensor 15 is incorrect, so that even if the distributed power source 18 cannot reverse the sign, An operation stop state due to an incorrect installation direction can be found early.

  Next, a power management device 19 according to a sixth embodiment of the present invention will be described. In the sixth embodiment, the type of information to be compared with the power information of the power management device 19 is different from that of the first embodiment. Hereinafter, the sixth embodiment will be described focusing on the differences from the first embodiment. Parts having the same configuration as the first embodiment are denoted by the same reference numerals.

  The configuration of the power management system 10 including the power management device 19 according to the sixth embodiment is the same as that of the power management system 10 according to the first embodiment shown in FIG.

  The configurations and functions of the network 11, the load device 13, the first current sensor 14, the second current sensor 15, the first voltage sensor 16, the second voltage sensor 17, and the distributed power source 18 are the same as those of the first embodiment. The same is true. Unlike the first embodiment, the watt hour meter 12 does not need to notify the power management apparatus 19 of the power trading information.

  The configuration of the power management apparatus 19 according to the sixth embodiment is the same as that of the first embodiment shown in FIG. Unlike the first embodiment, the power management device 19 of the sixth embodiment differs from the first embodiment in the control executed by the control unit 28.

  The control unit 28 notifies at least one or more distributed power supplies 18 of an instruction to change the output, as in the fifth embodiment. Unlike the fifth embodiment, when the output to be changed is, for example, the rated output of the first distributed power supply 22 is 5 kWh, the combined output of the second distributed power supply 23 and the third distributed power supply 24 is 6 kWh. Is a predetermined value (second predetermined value), which is 1.1 times or more of the rated output of the general distributed power supply 18. In this way, by changing the power value at the second predetermined value that is equal to or more than the maximum power value of the general distributed power source, it is possible to secure a fluctuation amount equal to or more than the output of the distributed power source that cannot be grasped by the power management device 19. And the probability that the output can be reduced can be increased as compared with the fifth embodiment. In the sixth embodiment, the change in the output is a decrease. The command to lower the output also includes a command to charge the distributed power supply 18 which is a power storage device. The type of the distributed power supply 18 that reduces the output is not limited.

  The control unit 28 calculates the power information of the power management device 19 as in the first embodiment, and based on the power information of the power management device 19 and the information acquired by the second sub-acquisition unit 30, The correct orientation of the current sensor 14 is determined. In the sixth embodiment, the control unit 28 uses the upstream power information in the information acquired by the second sub-acquisition unit 30 to determine whether the installation direction is correct.

  More specifically, as described above, the control unit 28 notifies the at least one distributed power source 18 of a command to reduce the output by a predetermined value. If the distributed power source 18 is a power storage device, it can be charged, so that the output to be changed can be easily set to the second predetermined value by itself. However, when there are a plurality of distributed power sources 18 and the distributed power source 18 is a power storage device (fully charged state) or when the distributed power source 18 is a solar power generation or a fuel cell, the plurality of distributed power sources are combined. Then, the output to be changed may be instructed to be the second predetermined value. The control unit 28 acquires the power information of the power management apparatus 19 and the upstream power information of the distributed power source 18 before notifying the output reduction command. The control unit 28 acquires the power information of the power management device 19 when the amount of change in the power corresponding to the upstream power information after the notification reaches a predetermined value. The control unit 28 installs the first current sensor 14 based on whether or not the change in power corresponding to the power information of the power management device 19 before and after the notification of the command to decrease the output can be considered to match the predetermined value. The correctness of the direction is determined.

  As in the fifth embodiment, the determination of the correctness of the installation direction of the first current sensor 14 in the control unit 28 is performed twice or more (a plurality of times) within a predetermined time interval, and the final determination is performed based on the determination result. A determination may be made.

  As in the first embodiment, when they match, the control unit 28 determines that the installation direction of the first current sensor 14 is correct. On the other hand, when they do not match, the control unit 28 determines that the installation direction of the first current sensor 14 is incorrect.

  As in the first embodiment, when determining that the installation direction of the first current sensor 14 is correct, the control unit 28 creates an image indicating that the installation direction is correct as data, and displays the image on the display unit 26. To be displayed.

  As in the first embodiment, when determining that the installation direction of the first current sensor 14 is incorrect, the control unit 28 creates an image indicating that the installation direction is incorrect as data, and Is displayed on the display unit 26. Alternatively, when determining that the installation direction of the first current sensor 14 is incorrect, the control unit 28 inverts the sign of the current value acquired from the first current sensor 14 after the determination.

  In the sixth embodiment, similarly to the second embodiment, the control unit 28 determines whether the installation direction of the first current sensor 14 is correct, based on the power information of the power management device 19, and the upstream power information. It is determined whether the installation direction of the second current sensor 15 is correct.

  Similarly to the first embodiment, when indicating the power supply to the load device 13, the control unit 28 determines that the installation direction of the second current sensor 15 is correct. On the other hand, when the power supply to the load device 13 is not indicated, the control unit 28 determines that the installation direction of the second current sensor 15 is incorrect. Also in the sixth embodiment, the positive sign of the power indicated by the upstream power information matches the power supply to the load device 13 side.

  As in the first embodiment, when determining that the installation direction of the second current sensor 15 is correct, the control unit 28 creates an image indicating that the installation direction is correct as data, and displays the image on the display unit 26. To be displayed.

  As in the first embodiment, when determining that the installation direction of the second current sensor 15 is incorrect, the control unit 28 creates an image indicating that the installation direction is incorrect as data, and Is displayed on the display unit 26. Alternatively, when determining that the installation direction is incorrect, the control unit 28 responds to the second current sensor 15 with a command to invert the sign of the current value obtained from the second current sensor 15 after the determination. Notify the distributed power supply 18. Alternatively, when determining that the installation direction is wrong, the control unit 28 notifies the distributed power supply 18 of a stop command of the distributed power supply 18 corresponding to the second current sensor 15.

  Next, a direction determination process executed by the control unit 28 of the power management apparatus 19 in the sixth embodiment will be described with reference to the flowchart in FIG. The direction determination processing is started when an input for performing a direction determination is detected with respect to the input device of the power management apparatus 19.

  In steps S600 and S601, the control unit 28 executes the same processing as step S500 of the fifth embodiment, and the process proceeds to step S602.

  In step S602, the control unit 28 notifies the distributed power source 18, which has confirmed the above acquisition in step S600, of a command to decrease the output of the predetermined value. After the notification, the process proceeds to step S603.

  In step S603, the control unit 28 acquires the upstream power information from the distributed power supply 18 to which the second sub-acquisition unit 30 has notified the instruction to decrease the output in step S602. Further, control unit 28 determines whether or not the power corresponding to the power information has increased by a predetermined value from the power corresponding to the power information confirmed to be acquired in step S500. If not, the process returns to step S602, repeats steps S602 and S603, and waits for the increase. If so, the process proceeds to step S604. If the output of the distributed power source 18 cannot be further reduced, the determination cannot be continued, and the direction determination processing ends.

  In step S604, the control unit 28 calculates the power information of the power management apparatus 19 in the same manner as in step S601. After the calculation, the process proceeds to step S605.

  In step S605, the control unit 28 determines whether or not the change in power corresponding to the power information of the power management apparatus 19 calculated in steps S601 and S604 substantially matches a predetermined value. If so, the process proceeds to step S606. If not, the process proceeds to step S607.

  In subsequent steps S606 to S612, the control unit 28 executes the same processing as steps S203 to S209 of the second embodiment, and ends the direction determination processing.

  According to the power management device 19 of the sixth embodiment having the above-described configuration, the first current sensor 14 based on the power information of the power management device 19 and the upstream power information acquired by the second sub-acquisition unit 30. It can be determined whether the installation direction is correct or not. In particular, even if the distributed power source 18 that cannot communicate with the power management device 19 is connected to the power line 20, the installation direction of the first current sensor 14 can be determined. Further, since the power output from the distributed power source 18 is changed by a predetermined value, even if the distributed power source 18 that cannot communicate with the power management device 19 is connected to the power line 20, the influence of the output fluctuation of the distributed power source 18 that the determination cannot be performed is not affected. Reduce.

  According to the power management apparatus 19 of the sixth embodiment, the determination of the installation direction of the first current sensor 14 is performed a plurality of times, and the final determination is performed based on the determination result. Even if a change or the like occurs, the correctness of the installation direction can be determined with higher accuracy.

  Also, similarly to the first embodiment, when the installation direction of the first current sensor 14 is incorrect, the power management device 19 of the sixth embodiment notifies the first current sensor 14 of the error. The sign of the current value can be reversed. Also, according to the power management device 19 of the sixth embodiment, similarly to the second embodiment, the installation direction of the second current sensor 15 is determined based on whether the installation direction of the first current sensor 14 is correct or not. Correctness can be determined. Also, according to the power management apparatus 19 of the sixth embodiment, when the installation direction of the second current sensor 15 is incorrect, the sign of the current value notified from the second current sensor 15 can be inverted. Alternatively, the power management device 19 according to the sixth embodiment can also notify the installation direction of the second current sensor 15 that the installation direction of the second current sensor 15 is incorrect. An operation stop state due to an incorrect installation direction can be found early.

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

  For example, in the first embodiment, the trading information of the electric power is used to determine whether the installation direction of the second current sensor 15 is correct or incorrect, and the installation of the first current sensor 14 is used in the second to sixth embodiments. Although the right / wrong direction determination information is used, the present invention is not limited to such information.

  For example, among the plurality of distributed power supplies 18, the distributed power supply 18 having a function of determining whether the installation direction of the second current sensor 15 is correct is connected to the power line 20 and connected to the load device 13 side of the distributed power supply 18. If there is another distributed power source 18 to be used, the current sensor of another distributed power source 18 (for example, the third distributed power source 24 in FIG. It is possible to determine whether the current sensor 15) is installed correctly or not. For convenience, the following description is based on an example in which the second distributed power supply 23 and the third distributed power supply 24 in FIG. 1 are used. More specifically, the obtaining unit 27 obtains the correct / incorrect determination information of the installation direction of the second current sensor 15 and the upstream power information of the third distributed power supply 24 from the second distributed power supply 23 that performs the correctness determination. The control unit 28 determines whether the installation direction of the second current sensor 15 corresponding to the third distributed power supply 24 is correct based on the right / wrong determination information of the second distributed power supply 23 and the upstream power information of the third distributed power supply 24. Is determined. For example, the control unit 28 determines that the installation direction of the second current sensor 15 of the second distributed power supply 23 is correct, the power corresponding to the upstream power information indicates the power supply to the load device 13 side, and the third distributed power supply 23 When the power corresponding to the upstream power information of the power supply 24 indicates the power supply to the load device 13 side, it can be determined that the installation direction of the second current sensor 15 corresponding to the third distributed power supply 24 is correct. .

  Further, for example, a plurality of distributed power supplies 18 include a first distributed power supply 22 for which power sale is permitted and a second distributed power supply 23 for which power sale is not permitted, and If the power selling power value exceeds the power value of the output power information (power generation amount) of the first distributed power source 22, it can be determined that the installation direction of the second current sensor 15 is incorrect. The drive of the second distributed power source 23 may be stopped when the power sale from the first distributed power source 22 is detected, or the output from the second distributed power source 23 may be reduced to a level that does not affect the determination. Is also good. More specifically, the acquisition unit 27 acquires the power information of the power management apparatus 19 and the output power information of the first distributed power supply 22. When the power value corresponding to the power information of the power management device 19 exceeds the power value corresponding to the output power information of the first distributed power supply 22, the control unit 28 detects that the installation direction of the second current sensor 15 is incorrect. Is determined.

  Further, in the fourth embodiment, the configuration is such that the driving of the distributed power source 18 other than the power storage device is stopped. However, the configuration may be such that the power generation is performed at a value less than the predetermined value without stopping. In this configuration, the distributed power supply 18 outputs power at a predetermined value (first predetermined value) based on a command from the power management device 19. The first predetermined value is a value smaller than the charging power value of the power storage device, and the driving information indicating the charging state includes the information of the charging power (or charging current). Alternatively, a value obtained by subtracting a value of a predetermined power (for example, 100 W) from the charging power may be used. The predetermined power is an example of a margin amount for preventing a malfunction. In this configuration, similarly to the second embodiment, the distributed power supply 18 has a built-in sensor for detecting the power output by itself, and notifies the power management device 19 of output power information corresponding to the output power. . Unlike the first embodiment, the second sub-acquisition unit 30 acquires drive information and output power information of the distributed power supply 18. Further, unlike the first embodiment, the control unit 28 notifies the distributed power source 18 other than the power storage device of a power output command that is smaller than a predetermined value (first predetermined value). Further, the control unit 28 determines that the drive information from the second distributed power source 23 as a power storage device indicates the charging state, and that all the distributed power sources 18 other than the power storage device (the first distributed power source 22, the third distributed power source 23, It is checked whether the power indicated by the output power information from 24) is less than a predetermined value. Further, the control unit 28 controls the electric power output from all the distributed power supplies 18 (the first distributed power supply 22 and the third distributed power supply 24) other than the power storage apparatus, while the second distributed power supply 23 as the power storage device is in a charged state. Is less than the predetermined value, the correctness of the installation direction of the first current sensor 14 is determined based on whether the sign of the power corresponding to the power information of the power management apparatus 19 matches the power purchase situation.

  In the first embodiment, the fifth embodiment, and the sixth embodiment, the power management apparatus 19 and the first distributed power supply 22 can communicate with each other, but may not communicate with each other. As described above, in these embodiments, the installation direction of the first current sensor 14 can be determined even if the distributed power supply 18 that cannot communicate with the power management device 19 is connected to the power line 20.

  In the fifth and sixth embodiments, the change in the output to at least one distributed power source 18 is a decrease, but may be an increase. In particular, when the distributed power source 18 is a power storage device, switching from charging to discharging and an increase in the amount of discharge may be performed.

  In the fifth embodiment and the sixth embodiment, when the correctness of the installation direction is determined twice or more (a plurality of times), the change in the output to the distributed power supply 18 only decreases, but the output is reduced. The final determination may be performed by mixing the determination when the output is increased and the determination when the output is increased. For example, a final determination may be made for the distributed power supply 18 as a power storage device based on the determination of the installation direction when the output is reduced and the determination of the installation direction when the output is increased.

  In the fifth and sixth embodiments, when the output of the distributed power supply 18 is changed, only the installation direction of the first current sensor 14 is determined. If the power supply to the power supply 13 is to be increased, the installation direction of the second current sensor 15 may be determined at the same time.

10, 100 Power management system 11 Network 12 Watt hour meter 13 Load device 14 First current sensor 15 Second current sensor 16 First voltage sensor 17 Second voltage sensor 18 Distributed power supply 19 Power management device 20 Main power line Reference Signs List 21 power system 22 first distributed power supply 23 second distributed power supply 24 third distributed power supply 25 storage unit 26 display unit 27 acquisition unit 28 control unit 29 first sub acquisition unit 30 second sub acquisition unit 31 power distribution Board P1 First connection point P2 Second connection point P3 Third connection point

Claims (15)

A first sub-acquisition unit that acquires a current value from a first current sensor installed on a power line that connects a power system and a load device, and information about buying and selling of power from the power system, the first current sensor Upstream power information corresponding to the power on the power line on the first current sensor side than the distributed power supply connected to the power line on the load device side, output power information corresponding to the power output from the distributed power supply And an acquisition unit having a second sub-acquisition unit for acquiring at least one of drive information indicating a drive state of the distributed power supply;
Generating power information of a power management device corresponding to the power calculated based on the current value, based on the power information of the power management device and the information acquired by the second sub-acquisition unit, A control unit that determines whether the installation direction of the current sensor is correct or not ,
The second sub-acquisition unit acquires the upstream power information,
The control unit is configured to install a second current sensor installed closer to the first current sensor than a connection point between the distributed power source and the power line based on a determination as to whether the installation direction of the first current sensor is correct. the power management apparatus, wherein you determine the direction of right or wrong. The power management device according to claim 1,
The power management device, wherein the control unit inverts the sign of the current value of the first current sensor when determining that the installation direction of the first current sensor is incorrect. The power management device according to claim 1 or 2 ,
The control unit, when determining that the installation direction of the second current sensor is incorrect, executes one of inversion of the sign of the current value of the second current sensor and stop of the distributed power supply. A power management device characterized by the above-mentioned. The power management device according to claim 1 or 2,
The second sub-acquisition unit acquires the trading information,
The control unit determines whether or not the installation direction of the first current sensor is correct based on whether or not a sign of power corresponding to the output power information matches a trading situation indicated by the trading information. Characteristic power management device. The power management device according to any one of claims 1 to 3 ,
The second sub-acquisition unit, together with the output power information corresponding to all the distributed power supplies connected to the power line, the power line to a plurality of trunks on the load device side than the first current sensor Obtain total information corresponding to the electric power in all the plurality of trunks from the branching distribution board,
The control unit, from the power corresponding to the total information, the trading status indicated by the sign of the difference obtained by subtracting the power corresponding to all the output power information, and the sign of the power corresponding to the power information of the power management device A power management device for determining whether the installation direction of the first current sensor is correct or not, based on whether or not the following conditions are satisfied. The power management device according to any one of claims 1 to 3 ,
The second sub-acquisition unit acquires the drive information corresponding to all the distributed power supplies connected to the power line,
The control unit is configured such that, when the drive information corresponding to all the distributed power sources indicates a stop, whether a sign of power corresponding to power information of the power management apparatus indicates power supply to the load device side or not. A power management device for determining whether the installation direction of the first current sensor is correct or not based on the following. The power management device according to any one of claims 1 to 3 ,
The plurality of distributed power sources include a power storage device,
The second sub-acquisition unit is connected to the power line, and acquires at least one of the drive information and the output power information corresponding to all the distributed power supplies other than the power storage device,
The control unit is configured to control whether the power storage device is in a charged state and the drive information corresponding to all the distributed power sources other than the power storage device indicates stop, or the output corresponding to all the distributed power sources other than the power storage device. When all the power corresponding to the power information is less than a first predetermined value, based on whether or not the sign of the power corresponding to the power information of the power management apparatus indicates power supply to the load device side, A power management device for determining whether the installation direction of a first current sensor is correct or not. The power management device according to any one of claims 1 to 3 ,
The control unit includes:
Changing the output of the distributed power source,
Causing the second sub-acquisition unit to acquire the upstream power information before and after a change in output,
A change in the power corresponding to the power information and whether or not the direction of the change in the power corresponding to the power information of the power management apparatus before and after the change in the output of the distributed power supply matches the direction of the change in the output. A power management device for determining whether the installation direction of the first current sensor is correct or not based on the power management device. The power management device according to any one of claims 1 to 3 ,
The control unit includes:
Changing the output of the distributed power source by a second predetermined value;
Causing the second sub-acquisition unit to acquire the upstream power information before and after a change in output,
Based on whether or not a change in the power corresponding to the upstream power information and a change in the power corresponding to the power information of the power management apparatus before and after the change in the output of the distributed power source can be considered to be the same, the first A power management apparatus for determining whether the current sensor is installed in a correct direction. The power management device according to claim 8 or 9 ,
The acquisition unit acquires information two or more times within a predetermined time interval,
The power management device, wherein the control unit determines the installation direction each time information is obtained, and makes a final determination based on a plurality of installation direction determination results. A power management device according to any one of claims 1 or et 3,
Some of the distributed power supplies among the plurality of distributed power supplies can determine whether the installation direction of the second current sensor installed closer to the first current sensor than the connection point between the distributed power supply and the power line can be determined to be correct. Yes ,
Before SL control unit further power information of the power management device, and on the basis of said upstream power information, the power management apparatus characterized in that it is determined correctness of the installation direction of the second current sensor. A first sub-acquisition unit that acquires a current value from a first current sensor installed on a power line that connects a power system and a load device, and information about buying and selling of power from the power system, the first current sensor Upstream power information corresponding to the power on the power line on the first current sensor side than the distributed power supply connected to the power line on the load device side, output power information corresponding to the power output from the distributed power supply And an acquisition unit having a second sub-acquisition unit for acquiring at least one of drive information indicating a drive state of the distributed power supply;
Generating power information of a power management device corresponding to the power calculated based on the current value, based on the power information of the power management device and the information acquired by the second sub-acquisition unit, A control unit that determines whether the installation direction of the current sensor is correct or not,
The second sub-acquisition unit further acquires the upstream power information and the trading information,
The control unit is configured such that, when the trading information indicates power purchase, the distributed power supply and the power line based on whether a sign of power corresponding to the upstream power information indicates power supply to the load device side. Is judged whether the installation direction of the second current sensor installed on the first current sensor side from the connection point is correct or not.
A power management device characterized by the above-mentioned. A first sub-acquisition unit that acquires a current value from a first current sensor installed on a power line that connects a power system and a load device, and information about buying and selling of power from the power system, the first current sensor Upstream power information corresponding to the power on the power line on the first current sensor side than the distributed power supply connected to the power line on the load device side, output power information corresponding to the power output from the distributed power supply And an acquisition unit having a second sub-acquisition unit for acquiring at least one of drive information indicating a drive state of the distributed power supply;
Generating power information of a power management device corresponding to the power calculated based on the current value, based on the power information of the power management device and the information acquired by the second sub-acquisition unit, A control unit that determines whether the installation direction of the current sensor is correct or not,
The control unit includes:
Changing the output of the distributed power source,
Causing the second sub-acquisition unit to acquire the upstream power information before and after a change in output,
A change in the power corresponding to the power information and whether or not the direction of the change in the power corresponding to the power information of the power management apparatus before and after the change in the output of the distributed power supply matches the direction of the change in the output. Determining whether the installation direction of the first current sensor is correct based on the
A power management device characterized by the above-mentioned. A first sub-acquisition unit that acquires a current value from a first current sensor installed on a power line that connects a power system and a load device, and information about buying and selling of power from the power system, the first current sensor Upstream power information corresponding to the power in the power line on the first current sensor side than the distributed power source connected to the power line on the load device side, output power information corresponding to the power output from the distributed power source And an acquisition unit having a second sub-acquisition unit for acquiring at least one of drive information indicating a drive state of the distributed power supply;
Generating power information of a power management device corresponding to the power calculated based on the current value, based on the power information of the power management device and the information acquired by the second sub-acquisition unit, A control unit that determines whether the installation direction of the current sensor is correct or not,
The control unit includes:
Changing the output of the distributed power source by a second predetermined value;
Causing the second sub-acquisition unit to acquire the upstream power information before and after a change in output,
Based on whether or not a change in power corresponding to the upstream power information and a change in power corresponding to power information of the power management apparatus before and after a change in the output of the distributed power supply can be considered to be the same, the first The correct orientation of the current sensor installation direction
A power management device characterized by the above-mentioned. The power management device according to claim 13 or 14,
The acquisition unit acquires information two or more times within a predetermined time interval,
The control unit performs the determination of the installation direction every time the information is acquired, and performs the final determination based on the determination results of the installation directions a plurality of times.
A power management device characterized by the above-mentioned.

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