JP2014121252A - Power supply system, power consumption measurement device, power consumption measurement method, and program - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a power supply system, power consumption measurement device, power consumption measurement method, and program for enabling the power company system side to measure an amount of power consumed by a power consumer with a simple facility configuration.SOLUTION: A power supply system comprises: an apparatus of a power consumer; a power generation apparatus for supplying power to the apparatus; a power source of a power supplier for supplying power to the apparatus when an amount of power supplied from the power generation apparatus is short as compared with a power consumption amount of the apparatus; a power supply stop unit for stopping the power supply from the power generation apparatus to the apparatus; and a power measurement unit for measuring the power consumption amount of the apparatus by measuring an amount of power supplied from the power source to the apparatus when the power supply from the power generation apparatus to the apparatus stops.

Description

  The present invention relates to a power supply system, a power consumption measuring device, a power consumption measuring method, and a program.

  In recent years, for the purpose of reducing global warming and the like, for the purpose of reducing CO2, establishment of a system for promoting the use of non-fossil energy sources and effective use of fossil energy raw materials has been issued. As such a non-fossil energy source, for example, the use of solar power generation (PV: Photovoltanic Power Generation, hereinafter referred to as PV power generation) using sunlight is promoted to general electric power consumers. A distributed power source using PV power generation is installed on the power consumer side.

JP-A-7-147728 JP 2004-038765 A JP 2010-250945 A

  In PV power generation, the amount of power generation varies depending on the weather (particularly sunshine) or the usage status of power consumers. For this reason, it is preferable for an electric power company to have a system power supply infrastructure that can stably supply power to power consumers through a distribution network regardless of the amount of power generated by PV power generation. For this purpose, it is preferable that the power demand can be predicted on the power provider system side by measuring the amount of power consumed by the power consumer with a simple equipment configuration.

  In one aspect of the present invention, a power supply system, a power consumption measuring device, a power consumption measuring method, and a program capable of measuring the amount of power consumed by a power consumer with a simple equipment configuration on the power provider system side. The purpose is to provide.

  According to one aspect of the invention, there is provided a power supply system, a power consumer device, a power generation device that supplies power to the device, and the amount of power supplied from the power generation device with respect to the power consumption of the device. When the amount is insufficient, the power supply of the power supplier that supplies power to the device, a power supply stop unit that stops power supply from the power generation device to the device, and the power from the power generation device to the device A power supply system is provided that includes a power measurement unit that measures the amount of power consumed by the device by measuring the amount of power supplied from the power source to the device when the supply is stopped.

  According to one embodiment, a power supply system, a power consumption measuring device, a power consumption measuring method, and a program capable of measuring the amount of power consumed by a power consumer with a simple equipment configuration on the power provider system side are provided. can do.

FIG. 1 is a diagram illustrating an example of a power supply system. FIG. 2 is a diagram illustrating an example of the configuration of the PCS. FIG. 3 is a diagram illustrating an example of a power consumption measuring apparatus. FIG. 4 is a diagram illustrating an example of the pseudo isolated operation state generation unit. FIG. 5 is a diagram illustrating an example of the frequency variation unit. FIG. 6 is a diagram illustrating an example of the voltage phase fluctuation unit. FIG. 7 is a flowchart illustrating an example of a processing procedure for measuring power consumption of a power consumer. FIG. 8 is a diagram illustrating an example of PCS model-specific information. FIG. 9 is a flowchart illustrating a specific example of processing performed after the processing of S102 and before the processing of S106. FIG. 10 is a diagram illustrating a modification of the power consumption measuring apparatus. FIG. 11 is a flowchart illustrating a modified example of the procedure of the process of measuring the power consumption of the power consumer. FIG. 12 is a diagram illustrating an example of a measurement result of power consumption.

  Hereinafter, embodiments of the present invention will be specifically described with reference to FIGS. 1 to 12.

  FIG. 1 is a diagram illustrating an example of a power supply system. As illustrated in FIG. 1, the power supply system includes a power provider system 101 that is a power system owned by a power provider, and a home system 102 that is a power system owned by a power consumer.

  The power provider system 101 includes distribution lines 1 a to 1 c, a system power supply 2, a power sale meter 3, a power consumption measuring device 4, and a management server 5. The in-home system 102 includes distribution lines 1 d to 1 f, a distribution board 6, an electric device 7, a power conditioner (PCS: Power Conditioning Subsystem) 8, and a PV power generation device 9. Hereinafter, when the distribution lines are not distinguished and described, the distribution lines 1a to 1f are referred to as the distribution line 1. The power conditioner 8 is referred to as PCS8.

  The power company transmits power from the system power supply 2 using the distribution line 1 and supplies the power to the distribution board 6 owned by the power consumer via the power sale meter 3 and the power consumption measuring device 4. The current used for power transmission is, for example, an alternating current having a frequency of 50 Hz or 60 Hz and a voltage of 100 V or 200 V. The distribution board 6 distributes the electric power supplied from the electric power company to the electrical equipment 7 in the house. When the power consumer installs the PV power generation device 9 as a private power generation device, the PV power generation device 9 is electrically connected to the distribution board 6 via the PCS 8 as shown in FIG.

  The power supplied from the system power source 2 that is the power source of the power provider system 101 and the power generated by the PV power generation device 9 are distributed to the electrical device 7 via the distribution board 6. Further, the amount of power supplied from the system power supply 2 changes according to the amount of power generated by the PV power generation device 9 and the amount of power consumed by the electrical device 7.

  For example, assuming that the amount of power generated by the PV power generation device 9 is Pg and the amount of power consumed by the electrical device 7 is Lc, the amount of power P supplied from the power provider system 101 side is expressed as P = Lc−Pg. Can do. When the amount of electric power Lc consumed by the electric device 7 is smaller than the amount of electric power Pg generated by the PV electric power generating device 9, P = Lc−Pg <0, and the electric power consumed by the electric device 7 is the PV electric power generating device 9 All can be covered by the generated power. Then, a remainder obtained by subtracting Lc from Pg (surplus power), that is, Ps = Pg−Lc is output to the power utility system 101 via the distribution board 6. At this time, the power sale meter 3 measures Ps as the amount of power, and the power consumer sells the power amount Ps to the power company. At the time of power sale, electric power is sent from the in-home system 102 toward the electric power company system 101, and the electric power consumer does not receive power supply from the system power source of the electric power company system 101 at the time of electric power sales.

  On the other hand, the power supply system can also supply the shortage of the amount of power supplied from the PV power generation device 9 with respect to the amount of power consumed by the electrical device 7 from the grid power supply 2 of the power company. For example, when the amount of power Lc consumed by the electrical device 7 is larger than the amount of power Pg generated by the PV power generation device 9, P = Lc−Pg> 0, and the power consumed by the electrical device 7 is PV power generation. The power generated by the device 9 cannot cover all. Therefore, the electric power consumer receives the remainder (underpower) obtained by subtracting Pg from Lc, that is, Pb = Lc−Pg, from the electric power provider system 101 side. When insufficient power Pb is supplied from the system power source 2 of the power provider system 101 to the electrical equipment 7 of the in-home system 102, the power purchase meter provided in the power consumption measuring device 4 measures Pb as the amount of power. The And an electric power consumer purchases this electric power amount Pb from an electric power provider.

  Hereinafter, details of each part of the power supply system will be described.

  The power sale meter 3 is a watt-hour meter for measuring and integrating the power sold by the power consumer to the power company, and measures the surplus power Ps obtained by subtracting Lc from Pg as described above. can do. The power sale meter 3 is used for electric power purchase and sale transactions between electric power companies and electric power consumers.

  The power consumption measuring device 4 is a device installed on the power provider system 101 side of the distribution board 6 in order to measure and grasp the amount of power actually consumed by the power provider in the home of the power consumer. It is. The configuration of the power consumption measuring device 4 will be described later.

  The management server 5 can transmit to the power consumption measuring device 4 via the network 100 an instruction signal for instructing measurement of the amount of power actually consumed by the power company in the home of the power consumer. In addition, the management server 5 can receive the power consumption information measured by the power consumption measurement device 4 from the power consumption measurement device 4 via the network 100 and accumulate the received information.

  The distribution board 6 is a power distributor for distributing and supplying power for each room, which is installed in the home of a power consumer. The distribution board 6 is electrically connected to the electric device 7 by the distribution line 1d. The electric power supplied from the power company to the distribution board 6 is distributed to the electric equipment 7 through the distribution line 1d. In FIG. 1, the electric device 7 electrically connected to the distribution board 6 is illustrated as one block, but the distribution board 6 is electrically connected to a plurality of electric devices 7. May be.

  The PCS 8 is a device that converts generated electricity so that it can be used in an environment such as a home when a power consumer uses a solar power generation system. The PCS 8 also functions as a power supply stop unit that stops power supply from the PV power generation device 9 to the electrical device 7. Hereinafter, the configuration and function of the PCS 8 will be described.

  FIG. 2 is a diagram illustrating an example of the configuration of the PCS 8. As shown in FIG. 2, the PCS 8 includes an inverter circuit 81, an in-phase adjustment circuit 82, and an isolated operation detection circuit 83.

  The inverter circuit 81 is a circuit that converts DC power generated by the PV power generation device 9 into AC power, and can convert it into AC voltage of 100 V, for example.

  The in-phase adjustment circuit 82 is based on the AC PV generated power output from the inverter circuit 81 and the grid power that is the power supplied from the grid power supply 2 of the power provider shown in FIG. This is a circuit in which both voltages and power factors are in phase. The in-phase adjustment circuit 82 has a function of bringing the voltage waveform of the power generated by the PV power generation device 9 into the same phase when the voltage waveform of the power flowing through the power provider system 101 is out of phase. As the in-phase adjustment circuit 82, for example, a phase locked loop (PLL) circuit can be used.

  The islanding operation detection circuit 83 is a circuit responsible for the islanding operation detection function, and is provided on the output side of the inverter circuit 81. The isolated operation detection circuit 83 can generate an isolated operation prevention signal and perform detection according to the isolated operation and control according to the detection. Details of the isolated operation detection function will be described later.

Further, the PCS 8 has an isolated operation detection function linked to the power provider system 101. The isolated operation prevention function is the detection of the loss of grid power when the grid power on the power utility grid 101 side is lost due to an accident (distribution line ground fault, emergency, etc.), and the PCS8 output ( Strictly speaking, the single operation of the PCS 8 is prevented by stopping the generated power of the PV power generation device 9. The islanding operation is a state in which the distributed power source supplies power to the local system load when the system power on the power provider system 101 side is lost, and may cause the following problems.
・ In terms of safety, there may be a risk of electric shock for the electric shock workers due to the continued damage caused by accidents, equipment damage, and public electric shock workers.
-In terms of supply reliability, there may be a delay in power transmission to a healthy section due to reclosing and the inability to reverse power transmission from other lines.
・ In addition, there is a risk of power quality deterioration and load equipment damage due to voltage and frequency fluctuations in the isolated operation system.

  Methods for detecting islanding can be broadly classified into active detection methods and passive detection methods. The passive detection method detects, with high sensitivity, sudden changes in voltage, current, frequency, etc. caused by imbalance between generated power and load when the grid power on the power provider grid 101 side is lost. Known types of passive detection methods include a voltage phase jump detection method, a frequency change rate detection method, and a third harmonic voltage distortion rapid increase detection method.

  On the other hand, the active detection method outputs an active islanding prevention signal obtained by superimposing a minute fluctuation component such as voltage or frequency on the alternating current output from the PCS 8 at a constant period, and is prominent at the time of transition to the islanding operation. It detects the fluctuations that occur.

  The types of active detection methods include a reactive power fluctuation method in which a periodic reactive power fluctuation is given to the output of the inverter circuit 81 of the PCS 8 to detect a frequency fluctuation or the like that appears during an independent operation, and an internal transmitter of the inverter circuit 81 A frequency shift method for detecting a frequency change appearing at the time of single operation, a periodic active power fluctuation at the output of the inverter circuit 81, and a voltage, current, or frequency fluctuation appearing at the time of single operation. An active power fluctuation method for detecting, a load fluctuation method for detecting an abrupt change in voltage or current by inserting an impedance instantaneously and periodically in parallel with the output of the inverter circuit 81 are known. The active isolated operation prevention signal is different for each PCS 8 model, such as a periodically changing signal or a pulse generated signal.

  As described above, the PCS 8 performs control so that the power generated by the PV power generation device 9 is not output to the power provider system 101 side when the power provider system 101 is abnormal in both the active and passive systems. It can be carried out.

  In this embodiment, it is preferable to use a passive detection method in order to measure the power consumption of a power consumer. Without outputting a signal or the like to the PCS 8, the output of the generated power of the PV power generation device 9 from the PCS 8 is stopped based on the frequency or voltage fluctuation of the power itself output from the power consumption measuring device 4. According to the passive detection method, fluctuations in the frequency and voltage of the power provider system 101 can be detected in about 0.1 seconds, so that the output of the generated power from the PCS 8 is stopped and the power consumption of the power consumer is reduced. Measurement can be speeded up.

  The PV power generation device 9 is a solar cell in which a plurality of cells are juxtaposed in the vertical and horizontal directions and are electrically connected to each other, and has, for example, a panel shape. The PV power generation device 9 outputs DC power generated by the irradiation of sunlight to the PCS 8.

  Then, the power consumption measuring apparatus in this embodiment is demonstrated.

  FIG. 3 is a diagram illustrating an example of a power consumption measuring apparatus. As shown in FIG. 3, the power consumption measuring device 4 includes a power purchase meter 10, a measurement control unit 11, a reception unit 12, a first storage unit 13, a second storage unit 14, a transmission unit 15, And a pseudo isolated operation state generating unit 20.

  The power purchase meter 10 is an example of a power measurement unit, and measures and integrates the amount of power supplied from the system power supply 2 to the electrical equipment 7, that is, the amount of power purchased by a power consumer from a power company. It is a watt-hour meter. The power purchase meter 10 is used for a power trading transaction between an electric power company and an electric power consumer in the same manner as the electric power sale meter 3. The electricity purchase meter 10 is connected to the measurement control unit 11 and measures the amount of electric power according to the control by the measurement control unit 11. As described above, the electricity purchase meter 10 can measure the insufficient power Pb obtained by subtracting Pg from Lc.

  The measurement control unit 11 is a control unit for executing a series of processes for measuring the power consumption of an electric power consumer. The power purchase meter 10, the measurement control unit 11, the reception unit 12, the first storage unit 13, The second storage unit 14 and the transmission unit 15 are electrically connected. The measurement control unit 11 is a processor such as a CPU (Central Processing Unit) or an MPU (Micro-Processing Unit).

  The receiving unit 12 is connected to the management server 5 of the electric power company so as to be able to transmit and receive. The receiving unit 12 receives an instruction signal for measuring power consumption transmitted from the management server 5, and outputs the received instruction signal to the measurement control unit 11.

  The 1st memory | storage part 13 can store the power consumption measurement program for performing a series of processes for measuring the power consumption of an electric power consumer. The measurement control unit 11 reads a power consumption measurement program stored in the first storage unit 13 and executes a series of processes for measuring the power consumption of a power consumer by executing each command of the power consumption measurement program. Do.

  The second storage unit 14 stores the power consumption measured by the power measurement unit 11. Moreover, the 2nd memory | storage part 14 stores the information regarding the fluctuation | variation degree of the frequency or voltage phase for every model of PCS8 used in order to generate | occur | produce a pseudo | simulation single operation state. Information on the degree of variation will be described later.

  The first storage unit 13 and the second storage unit 14 are, for example, a semiconductor memory such as a ROM (Read Only Memory) or a flash memory, or a storage device such as an HDD (Hard Disc Drive). Note that a plurality of first storage units 13 and a plurality of second storage units 14 may be provided, or they may be configured by the same memory.

  The transmission unit 15 is connected to the management server 5 of the power company so as to be able to transmit and receive, and transmits information on the amount of power measured by the power purchase meter 10 to the management server 5 of the power company according to control by the measurement control unit 11. To do.

  The pseudo isolated operation state generation unit 20 generates a simulated isolated operation state indicating an abnormal state of the system power supply 2 in a pseudo manner at a predetermined timing. The pseudo isolated operation state is a state in which the frequency or voltage phase of the system power supply 2 of the power provider system 101 is temporarily changed.

  FIG. 4 is a diagram illustrating an example of the pseudo isolated operation state generation unit 20. The quasi-independent operation state generation unit 20 is an electric circuit that temporarily varies the frequency or voltage phase of the system power supply 2 of the power provider system 101. As shown in FIG. 4, the frequency variation unit 21 and the voltage phase variation And a unit 22. And the pseudo | simulation single operation state generation | occurrence | production part 20 can switch the unit to be used suitably according to the model of PCS8.

  First, a specific example of the frequency variation unit 21 will be described.

  FIG. 5 is a diagram illustrating an example of the frequency variation unit 21. The frequency variation unit 21 is an electric circuit for temporarily varying the frequency of the system power supply 2 of the power provider system 101. The frequency variation unit 21 changes the frequency in a pseudo manner in correspondence with a threshold value at which the single operation state can be detected in the PCS 8. In the example shown in FIG. 5, the reference frequency of the power output by the PCS 8 is 50 Hz, and the frequency of 1 Hz, that is, 0.02% can be varied within the frequency variation unit 21.

  The frequency variation unit 21 includes two frequency modulators 211 and 212, an oscillator 213, and a switch 214. The two frequency modulators 211 and 212 are arranged in a column on the distribution line 1 inside the pseudo isolated operation state generating unit 20. These frequency modulators 211 and 212 can be configured by using, for example, mixers 211a and 211b.

  The oscillator 213 oscillates and outputs the 1 Hz frequency to be varied. The oscillation signal of the oscillator 213 is output to the two mixers 211a and 211b. A switch 214 is provided between the oscillator 213 and the two mixers 211a and 211b. The switch 214 is temporarily turned on (conductive) at the timing of occurrence of the pseudo isolated operation state under the control of the measurement control unit 11.

  The frequency modulators 211 and 212 do not perform frequency mixing in the OFF state of the switch 214, and do not perform a frequency variation operation on the power flowing between the system power supply 2 and the PCS 8.

  On the other hand, when the switch 214 is turned on at the timing of occurrence of the pseudo isolated operation state, the frequency modulators 211 and 212 perform frequency mixing as follows. The mixer 211 a provided in the frequency modulator 211 on the PCS 8 side adds (mixes) the oscillation signal 1 Hz of the oscillator 213 to the reference frequency 50 Hz output from the PCS 8 and outputs a frequency of 51 Hz. The mixer 211 b subtracts (mixes) the oscillation signal 1 Hz of the oscillator 213 from the changed frequency 51 Hz output from the mixer 211 a, and outputs the 50 Hz frequency returned to the reference frequency to the distribution line 1 of the power provider system 101. To do.

  In the above configuration example, the frequency modulator 211 on the PV power generation device 9 side fluctuates the power frequency higher than the reference frequency, and the frequency modulator 212 on the system power source 2 side performs control to return the power frequency to the reference frequency. It was. Not limited to this, the frequency modulator 211 on the PV power generation device 9 side changes the power frequency to be lower than the reference frequency, and the frequency modulator 212 on the system power source 2 side performs control to return the power frequency to the reference frequency. Also good.

  According to the above configuration, when the power consumer sells power from the PCS 8, the frequency fluctuation unit 21 temporarily changes the frequency, thereby generating a pseudo isolated operation state for the PCS 8. At this time, as viewed from the PCS 8, the mixer 211a provided on the PCS 8 side operates at 51 Hz after the fluctuation, and the PCS 8 detects the single operation state. On the other hand, the mixer 211b provided on the system power supply 2 side when viewed from the PCS 8 returns the frequency of power to the reference frequency of 50 Hz. Thereby, it can output to the distribution line 1 of the electric power provider system | strain 101 as electric power which sells the electric power of normal reference frequency 50Hz.

  Next, a specific example of the voltage phase fluctuation unit 22 will be described.

  FIG. 6 is a diagram illustrating an example of the voltage phase fluctuation unit 22. The voltage phase variation unit 22 is an electric circuit for temporarily varying (voltage phase jump) the voltage phase of the system power supply 2 of the power provider system 101.

  The voltage phase fluctuation unit 22 changes the voltage phase in a pseudo manner in correspondence with the threshold value that can detect the isolated operation state in the PCS 8. In the illustrated example, the voltage phase of the power output from the PCS 8 is varied in the phase angle α (for example, 5 degrees) within the voltage phase variation unit 22.

  The voltage phase fluctuation unit 22 includes two voltage phase fluctuation units 221 and 222. The two voltage phase changers 221 and 222 are arranged in a column on the distribution line 1 inside the pseudo isolated operation state generation unit 20. The voltage phase variator 221 includes a resistor 221c having one end connected in parallel to the installed inductor 221a and capacitor 221b, and a switch 221d having one end connected to the resistor 221c and the other end connected to the distribution line 1. . The inductor 221a, the capacitor 221b, and the resistor 221c generate the voltage phase of α (for example, 5 degrees).

  The switch 221d is temporarily turned on (conductive) at the timing of occurrence of the pseudo isolated operation state under the control of the measurement control unit 11. The voltage phase variator 222 has the same circuit configuration as that of the voltage phase variator 221 and is given the corresponding reference numerals (222a to 222d).

  The voltage phase changers 221 and 222 do not change the voltage phase when the switches 221d and 222d are in the OFF state, respectively, and do not perform the voltage phase change operation on the power flowing between the system power supply 2 and the PCS 8.

  On the other hand, when both the switches 221d and 222d are turned on at the timing of occurrence of the pseudo isolated operation state, the voltage phase changers 221 and 222 change the voltage phase as follows. The voltage phase variator 221 on the PCS 8 side changes the voltage phase output from the PCS 8 by α = 5 degrees and outputs it. The voltage phase variator 222 on the system power supply 2 side changes the voltage phase changed by α output from the voltage phase variator 221 by −α, returns it to the original voltage phase, and distributes the distribution line of the power provider system 101. Output to 1.

  In the above configuration example, the voltage phase variator 221 on the PCS 8 side causes the voltage phase variator of the power to change more positive than the reference, and the voltage phase variator 222 on the system power supply 2 side returns the voltage phase of the power to the reference voltage phase. It was set as the structure which performs. Not limited to this, the voltage phase variator 221 on the PCS 8 side changes the voltage phase of the power to minus from the reference, and the voltage phase variator 222 on the system power supply 2 side performs control to return the voltage phase of the power to the reference voltage phase. It is good also as a structure to perform.

  According to the above configuration, when the electric power consumer sells power from the PCS 8, the frequency fluctuation unit 21 temporarily varies the voltage phase, thereby generating a pseudo isolated operation state for the PCS 8. At this time, as viewed from the PCS 8, the voltage phase variator 221 provided on the PCS 8 side operates at the phase angle of + α after the fluctuation, and the PCS 8 detects the single operation state. On the other hand, the voltage phase variator 222 provided on the system power supply 2 side when viewed from the PCS 8 returns the voltage phase of the power to the reference phase. Thereby, it can output to the distribution line 1 of the electric power provider system | strain 101 as electric power which sells electric power of a normal phase.

  As described above, the pseudo isolated operation state generation unit 20 includes the frequency fluctuation unit 21 and the voltage phase fluctuation unit 22, and the PCS and the voltage phase for detecting the frequency fluctuation by switching the unit to be used appropriately according to the model of the PCS 8. It is possible to stop the output of both powers of the PCS that detects the fluctuation.

  In addition, according to FIG. 3, although the pseudo | simulation single operation state generation | occurrence | production part 20 is provided in the position close | similar to the power purchase meter 10, if it is the system power supply 2 side rather than the power purchase meter 10, an installation position will not be specified. Since the distribution line 1c closer to the distribution board 6 than the power purchase meter 10 is included in the area of the in-home system 102, the provision of the pseudo isolated operation state generation unit 20 on the system power supply 2 side relative to the power purchase meter 10 The operator can control the power consumption measurement process.

  Next, a method for measuring power consumption of a power consumer will be described.

  FIG. 7 is a flowchart illustrating an example of a processing procedure for measuring power consumption of a power consumer.

  First, the electric power consumer makes a power sale contract and reports the purchase of the PV power generation device 9 to the power company when purchasing the PV power generation device 9 including the PCS 8. This notification content includes information on the PCS 8 model described above. Subsequently, the electric power company registers information on the model of the PCS 8 notified by the electric power consumer in the power consumption measuring device 4 (S101). Specifically, the management server 5 transmits information regarding the variation degree of the frequency or the voltage phase to the receiving unit 12 of the power consumption measuring device 4 as information on the model of the PCS 8. Then, the receiving unit 12 stores the received information in the second storage unit 14.

  FIG. 8 is a diagram illustrating an example of PCS model information. Information on the PCS model is stored in the second storage unit 14 as an information table. As shown in FIG. 8, when the isolated operation detection in the PCS 8 is performed by a passive method, the voltage phase of the power provider system 101 is roughly changed or the frequency is changed.

  In the detection based on the voltage phase fluctuation, for example, the moving average value of the period of the past one to several cycles of the power provider system 101 is updated, and the past moving average value and the current period of one to a plurality of cycles are updated. Compare Then, when the comparison result exceeds a predetermined threshold, the PCS 8 detects that it is in an isolated operation state (abnormality of the power provider system 101). The threshold value corresponds to each voltage phase difference shown in the figure, and the voltage phase difference differs from 3 degrees to 8 degrees depending on the type of PCS8.

  In detection by frequency fluctuation, for example, the past moving average value for the past several cycles of the power provider system 101 is updated, and the current moving average value for one to a plurality of cycles is updated. Compare When the difference between the past and current moving average values continues for a predetermined cycle or more and the difference exceeds a threshold value with respect to the reference frequency (for example, 50 Hz), the PCS 8 detects that it is in the single operation state. The threshold corresponds to each frequency change rate shown in the figure. For example, a variation of 0.3% is detected as the frequency change rate.

  Returning to FIG. 7, the receiving unit 12 receives an instruction signal for instructing the start of measurement of power consumption from the management server 5 of the electric power company (S102). The instruction signal includes an identifier for identifying the PCS 8 model.

  Subsequently, the receiving unit 12 outputs the received instruction signal to the measurement control unit 11. The measurement control unit 11 that has received the instruction signal extracts the model of the PCS 8 from the identifier included in the instruction signal. And the measurement control part 11 reads the information used for generation | occurrence | production of a pseudo | simulation isolated operation state corresponding to the model of PCS8 from the information table stored in the 2nd memory | storage part 14, and the read information is a pseudo | simulation isolated operation state generation part. 20 to send. Based on the PCS 8 model information read from the second storage unit 14, the quasi-independent operation state generation unit 20 temporarily varies the frequency or voltage phase of the system power supply 2 of the electric power provider system 101, An operating state is generated (S103). The PCS 8 has different power harmonic characteristics depending on the model, and accordingly, the degree of independent operation detection (accuracy) with respect to the degree of fluctuation of the power provider system 101 is different. According to the power consumption measuring device 4, the simulated isolated operation state generated by the simulated isolated operation state generation unit 20, that is, the frequency or voltage phase variation degree of the system power of the power provider system 101 is appropriately set according to the PCS 8 model. By changing, it is possible to generate a pseudo isolated operation state suitable for each PCS 8 model.

  Subsequently, when the PCS 8 detects the pseudo isolated operation state generated by the simulated isolated operation state generation unit 20, the PCS 8 stops outputting the generated power of the PV power generation device 9 by the isolated operation prevention function of the PCS 8 (S104). When the output of the generated power of the PV power generation device 9 from the PCS 8 is stopped, the generated power of the PV power generation device 9 is not supplied to the electric device 7 of the power consumer. For this reason, all the electric power consumed by electric power consumers is the electric power supplied by the electric power company. That is, the amount of power measured by the power purchase meter 10 installed on the power provider side is equal to the amount of power consumed by the power consumer.

  Therefore, the power purchase meter 10 measures the power consumption of the electric appliance 7 of the electric power consumer while the output from the PCS 8 of the electric power generated by the PV electric power generator 9 is stopped (S105). Then, information on the measured electric energy is stored in the second storage unit 14.

  After the measurement of power consumption is completed, the quasi islanding operation state generation unit 20 stops the fluctuation of the frequency or voltage phase of the system power supply 2 on the power provider system 101 side and stops the generation of the quasi islanding operation state (S106). .

  When the generation of the pseudo isolated operation state by the simulated isolated operation state generation unit 20 is stopped, the PCS 8 determines that the isolated operation state is released, and restarts the output of the generated power of the PV power generation device 9 from the PCS 8 (S107).

  Subsequently, the measurement control unit 11 reads information on the amount of power consumed by the power consumer from the second storage unit 14 and transmits the information to the management server 5 via the transmission unit 15 (S108). If processing for transmitting information on the amount of power to the management server 5 before restarting the output from the PCS 8 is performed, there is a possibility that the time for stopping the output from the PCS 8 may become longer. According to the above method, since the information on the electric energy is transmitted to the management server 5 after the output from the PCS 8 is resumed, the time during which the output from the PCS 8 is stopped can be shortened.

  As described above, the power consumption of the power consumer can be measured.

  When the PV power generation device 9 is in operation, the power selling meter 3 has information P = Lc− on the difference between the power Lc consumed by the electric power consumer 7 and the amount of power Pg generated by the PV power generation device 9. Only Pg can be obtained. Therefore, it is difficult to grasp the actual amount of power consumed by the power consumer on the power provider system 101 side.

  On the other hand, according to the present embodiment, by generating a pseudo isolated operation state in the simulated isolated operation state generation unit 20 provided on the power provider system 101 side, from the PCS 8 provided in the home system 102, The output of the generated power of the PV power generation device 9 is stopped. Then, while the output is stopped, the amount of power is measured by the power purchase meter 10. According to this method, since Pg = 0, the measured power amount P indicates P = Lc-0 = Lc, that is, the amount of power consumed by the power consumer. As described above, the amount of power consumed by the power consumer who owns the PV power generation device 9 can be specified on the power provider system 101 side with a simple configuration. Then, the power company can store and use the acquired power consumption information in the database in association with the date and time, the weather, and the like.

  In addition, from the viewpoint of minimizing economic loss due to the inability to use the generated power of the PV power generation device 9 by the power consumer, the time during which the output of the generated power of the PV power generation device 9 from the PCS 8 is stopped Is preferably about 1 second or less.

  Moreover, it is preferable that the measurement process of the power consumption with respect to one electric power consumer is performed a plurality of times at a predetermined interval (for example, every 30 minutes), and the power consumption is estimated from the result obtained by performing a plurality of times. By performing the power consumption measurement process a plurality of times, the influence of data variation can be reduced, so that the measurement accuracy can be improved.

  By the way, as already explained, when the simulated isolated operation state is generated by the simulated isolated operation state generation unit 20, the output of the generated power of the PV power generation device 9 from the PCS 8 is stopped in S104. However, the power purchase meter 10 may not be able to detect that the output from the PCS 8 has stopped. In such a case, for example, processing can be performed as follows.

  FIG. 9 is a diagram illustrating a specific example of processing performed after the processing of S102 and before the processing of S106.

  After the process of S102, the pseudo isolated operation state generation unit 20 transmits a synchronization signal to the power purchase meter 10 in synchronization with the generation of the simulated isolated operation state based on the instruction signal (S103a).

  Subsequently, when the power purchase meter 10 receives the synchronization signal, it starts measuring the elapsed time since the reception (S104a). A known time measuring circuit can be used for measuring the elapsed time.

  And the electric power purchase meter 10 measures the power consumption of an electric power consumer after predetermined standby time passes (105a). Note that the waiting time is, for example, 1 second. Further, the standby time information can be stored in, for example, the second storage unit 14 and appropriately changed as necessary. Thereafter, the process proceeds to S106.

  Since the approximate time lag from when the pseudo isolated operation state is generated in the simulated isolated operation state generation unit 20 until the output of power from the PCS 8 is stopped can be grasped, the power purchase meter 10 operates based on the information of this time lag. Can be made. In this embodiment, after the power purchase meter 10 receives the synchronization signal, it waits until the time when it can be estimated that the output from the PCS 8 has stopped (that is, a time longer than the above-mentioned time lag), and after the standby time has elapsed. Start measuring power consumption. According to this method, even if the power purchase meter 10 cannot detect that the output from the PCS 8 is stopped, the power purchase meter 10 measures the power consumption in the time zone in which the output from the PCS 8 is stopped. be able to.

(Modification)
Next, a modified example of the operation of the power consumption measuring device in the embodiment of the present invention will be described.

  FIG. 10 is a diagram illustrating a modification of the power consumption measuring apparatus. In addition, the same code | symbol is attached | subjected about the structure same as the structure shown in FIG. 3, and description is abbreviate | omitted. As shown in FIG. 10, the power consumption measuring device 4 in the modification includes a determination unit 16. The determination unit 16 is connected to the measurement control unit 11, the first storage unit 13, and the second storage unit 14. The determination unit is a processor such as a CPU or an MPU, for example, and can perform a series of determination processes by reading the determination program stored in the first storage unit 13 and executing each instruction of the determination program. Information regarding the power consumption of the power consumer used for the determination process is stored in the second storage unit 14 as will be described later.

  FIG. 11 is a flowchart illustrating a modified example of the procedure of the process of measuring the power consumption of the power consumer. Hereinafter, a procedure of processing in the modification will be described.

  The processing up to S102 is substantially the same as in FIG. After S102, the electricity purchase meter 10 measures the amount of power consumed by the power consumer (S110). Then, information on the measured electric energy is stored in the second storage unit 14. The power consumption measured in S110 is the amount of power transmitted to the system power supply measured before the pseudo isolated operation state occurs.

  Subsequently, processing similar to the processing from S103 to S107 shown in FIG. 7 is executed. During this process, information on the amount of power consumed by the power consumer, measured when the output of power from the PCS 8 is stopped, is acquired.

  After the process of S107, the determination unit 16 determines the amount of power measured before the pseudo isolated operation state occurs in S110, and the amount of power measured when the output of power from the PCS 8 is stopped in S105. Based on the comparison, it is determined whether or not the PCS 8 was operating before the pseudo isolated operation state occurred (S111).

  FIG. 12 is a diagram illustrating an example of a measurement result of power consumption. FIG. 12 is an example in the case where the amount of power Lc consumed by the electrical device 7 is greater than the amount of power Pg generated by the PV power generation device 9.

  When power is output from the PCS 8, power generation by the PV power generation device 9 is performed. Therefore, as shown in FIG. 12A, the electric energy Pb measured by the power purchase meter 10 before stopping the output from the PCS 8 is Pb = Lc−Pg. When the output from the PCS 8 stops due to the occurrence of the pseudo isolated operation state, Pg = 0. For this reason, the electric energy Pb ′ measured by the electricity purchase meter 10 is Pb ′ = Lc, which is larger than Pb. Thereafter, when the generation of the pseudo isolated operation state is stopped and the output from the PCS 8 is restarted, the electric energy Pb ″ measured by the power purchase meter 10 becomes Pb ″ = Lc−Pg, and if there is no change in Lc, Pb Is almost equivalent to

  On the other hand, when no power is output from the PCS 8, power generation by the PV power generation device 9 is not performed. Therefore, as shown in FIG. 12B, since Pg = 0 even before the output from the PCS 8 is stopped, there is a significant difference in power consumption before and after the output from the PCS 8 is stopped. I can't.

  Therefore, according to this modification, the power consumption before and after the output from the PCS 8 stops is measured, and the difference is calculated. Thereby, the electric power amount Pg generated by the PV power generation device 9 can be estimated. Then, by comparing the estimated Pg with a preset threshold value, it is possible to estimate whether or not the PV power generation device 9 was operating on the power provider system 101 side. Further, the power generation amount of the PV power generation device 9 can be grasped on the electric power provider system 101 side.

  In addition, the actual data of the power consumption measured by the power purchase meter 10 is not completely constant and has some variation. For this reason, it is preferable that the threshold value set in advance is set in consideration of data measurement variations.

  The preferred embodiments of the present invention have been described in detail above, but the present invention is not limited to specific embodiments, and various modifications and changes can be made. For example, in the example shown in FIG. 7, after restarting the output of the generated power of the PV power generation device 9 from the PCS 8, the measured power consumption of the power consumer is transmitted to the management server 5. After the power is transmitted to the management server 5, the output of the generated power from the PCS 8 can be resumed.

  Moreover, in the said embodiment, although the PV power generation apparatus 9 was demonstrated to the example as a private power generation apparatus installed in an electric power consumer, the power consumption measuring device 4 is not restricted to the PV power generation apparatus 9, and wind power generation and tidal power Even when other renewable energy power generation methods such as power generation, or other in-house power generation equipment such as human power generation, fuel cells or co-generators are installed, measure the amount of power consumed by power consumers in the same way Can do. The power consumption measurement method described in this embodiment can also be realized by executing a program prepared in advance on a computer such as a personal computer or a workstation. The power consumption measurement program is recorded on a computer-readable recording medium such as a non-volatile memory such as a flash memory, and is executed by being read from the recording medium by the computer. As a recording medium for storing the power consumption measurement program, a hard disk, a flexible disk, a CD-ROM (Compact Disc-Read Only Memory), an MO (Magneto Optical disk), a DVD (Digital Versatile Disk), a DVD-ROM (DVD -Read Only Memory (DVD), DVD-RAM (DVD-Random Access Memory), BD (Blue-ray Disc), etc. can also be used. The power consumption measurement program can also be distributed through a network such as the Internet.

1, 1a to 1f: Distribution line 2: System power supply 3: Power sale meter 4: Power consumption measuring device 5: Management server 6: Distribution board 7: Electrical equipment 8: Power conditioner (PCS)
9: PV power generation device 10: Electricity purchase meter 11: Measurement control unit 12: Reception unit 13: First storage unit 14: Second storage unit 15: Transmission unit 16: Determination unit 20: Pseudo isolated operation state generation unit 21: Frequency Fluctuation unit 211: Frequency modulator 212: Frequency modulator 213: Oscillator 214: Switch 22: Voltage phase fluctuation unit 221: Voltage phase fluctuation unit 222: Voltage phase fluctuation unit 81: Inverter circuit 82: In-phase adjustment circuit 83: Isolated operation detection Circuit 100: Network 101: Electric power company system 102: Home system

Claims (8)

A power supply system,
Equipment of power consumers,
A power generation device for supplying power to the device;
When the amount of power supplied from the power generation device is insufficient with respect to the amount of power consumed by the device, the power supply of the power supplier to which power is supplied to the device;
A power supply stop unit that stops power supply from the power generation device to the device;
A power measurement unit that measures the amount of power consumed by the device by measuring the amount of power supplied from the power source to the device when power supply from the power generation device to the device is stopped;
A power supply system comprising:   The power supply system according to claim 1, wherein the power supply stop unit is provided closer to the power source than the power measurement unit. The power measurement unit measures the amount of power supplied from the power source to the device before power supply from the power generation device to the device is stopped.
By comparing the amount of power measured before power supply from the power generation device to the device is stopped and the amount of power measured when power supply from the power generation device to the device is stopped, The apparatus according to claim 1, further comprising a determination unit that determines whether or not power supply from the power generation device to the device is performed before power supply from the power generation device to the device is stopped. The power consumption measuring device described. A power conditioner that outputs the power supplied from the power generation device to the device;
The power supply stop unit changes a waveform of power supplied from the power source,
The said power conditioner stops the output to the said apparatus, when the change of the waveform of the power supply from the said power supply is detected, The power supply of any one of Claims 1-3 characterized by the above-mentioned. system. The power supply stop unit transmits a synchronization signal generated in synchronization with a time when a change in the waveform of power supplied from the power source occurs to the power measurement unit,
The power consumption measuring apparatus according to claim 4, wherein the power measuring unit measures the power amount after a predetermined time has elapsed after receiving the synchronization signal.
Consumption for measuring the power consumption of the power supply system in which a shortage of the power supply from the power generation device of the power consumer with respect to the power consumption of the power consumer device is supplied from the power supplier power supply A power measuring device,
A power supply stop unit that stops power supply from the power generation device to the device;
A power measurement unit that measures the amount of power consumed by the device by measuring the amount of power supplied from the power source to the device when power supply from the power generation device to the device is stopped;
A power consumption measuring device comprising: Consumption for measuring the power consumption of the power supply system in which a shortage of the power supply from the power generation device of the power consumer with respect to the power consumption of the power consumer device is supplied from the power supplier power supply A power consumption measuring method executed by a power measuring device,
Stop the power supply from the power generation device to the device,
When power supply from the power generation device to the device is stopped, by measuring the amount of power supplied from the power source to the device, to measure the power consumption of the device,
A method for measuring power consumption. Consumption for measuring the power consumption of the power supply system in which a shortage of the power supply from the power generation device of the power consumer with respect to the power consumption of the power consumer device is supplied from the power supplier power supply In the power measuring device,
A process of stopping power supply from the power generation device to the device;
A process of measuring the amount of power consumed by the device by measuring the amount of power supplied from the power source to the device when power supply from the power generation device to the device is temporarily stopped;
A program for running

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