JP2018011469A - Power conditioner, operating method therefor, and distributed power system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To maintain a storage battery in an optimal state in consideration of a system voltage rise, in a power conditioner which is connected to the storage battery.SOLUTION: A power conditioner 3 is disposed between a photovoltaic power generation panel 1, and a storage battery 2, and a commercial power system. The power conditioner 3 includes a control unit which, sets the upper limit value of the residual amount of the storage battery 2 other than a rise suppression time, on the basis of comparison between a voltage threshold which necessitates rise suppression in regard to a system voltage at system interconnection and an actual measurement value, to thereby adjust the charging surplus power to full charge at the rise suppression time.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a power conditioner, an operation method thereof, and a distributed power supply system.

Many power supply systems that use a power generation facility such as solar power generation and a storage battery have already been proposed (see, for example, Patent Documents 1 to 4).
For example, Patent Documents 1 and 2 disclose that in a power conditioner that is connected to the grid, when the grid voltage rises and the control state is suppressed to rise, the generated battery is charged to the storage battery.

  Patent Documents 2 and 3 disclose that an empty capacity is provided in advance in the storage battery in preparation for charging the storage battery when the increase is suppressed. For example, according to Patent Document 2, the timing for suppressing the increase in the system voltage is predicted, and the state in which the remaining amount of the storage battery is reduced before that can be surely stored. According to Patent Document 3, the time when the system voltage rises and exceeds the threshold is predicted, and the length of time exceeding the threshold is predicted. Discharge.

JP 2004-180467 A JP 2012-139019 A JP 2013-5584 A JP 2013-172495 A

  However, in the conventional technology as described above, in the case where it is necessary to suppress the increase by the power conditioner due to the increase in the system voltage, the appropriate state as to what state the storage battery should be maintained from the usual day And the control guide with high accuracy is not shown. “Prediction” naturally lacks accuracy. For example, if a large charge capacity of the storage battery is ensured, if a large amount of discharge power is required, the amount of power storage is insufficient. On the other hand, if the storage battery has insufficient charging capacity, the capacity for receiving generated power is insufficient.

  In view of such conventional problems, an object of the present invention is to maintain a storage battery in an optimum state in consideration of an increase in system voltage in a power conditioner connected to the storage battery.

  A power conditioner according to an expression of the present invention is a power conditioner provided between a photovoltaic power generation panel, a storage battery, and a commercial power system, and a voltage that needs to be suppressed with respect to the system voltage during system interconnection. Based on a comparison between the threshold value and the actual measurement value, a control unit that adjusts the remaining charge capacity until full charge at the time of increase suppression by setting an upper limit value of the remaining amount of the storage battery other than at the time of increase suppression It has a power conditioner.

  In addition, a distributed power system according to an expression of the present invention is a distributed power system configured by a plurality of consumers under a common transformer, and includes a photovoltaic power generation panel and a storage battery. And a power conditioner provided between the photovoltaic power generation panel and the storage battery and the commercial power system, the voltage threshold at which rise suppression is required for the system voltage during grid connection, and actual measurement The upper limit value of the remaining amount of the storage battery at a time other than the time when the increase is suppressed is relatively reduced as the measured value is relatively closer to the threshold value among the plurality of power conditioners. A distributed power supply system in which the upper limit value is set higher as the measured value is farther from the threshold value.

  Further, the operation method of the power conditioner according to one expression of the present invention is an operation method of the power conditioner provided between the photovoltaic power generation panel and the storage battery and the commercial power system, and the system voltage at the time of grid connection By comparing the threshold value of the voltage that needs to be suppressed and the actual measured value, and setting the upper limit value of the remaining amount of the storage battery at the time other than when suppressing the increase When the measured value reaches the threshold value, the storage battery is charged until it is fully charged.

  According to the present invention, the storage battery can be maintained in an optimum state in consideration of an increase in the system voltage.

It is a single line connection figure which shows the structural example of a distributed power supply system. FIG. 2 is a connection diagram with peripheral devices centering on a power conditioner in any one of the consumers in FIG. 1. It is a connection diagram for showing the variation of the internal configuration of the inverter. It is another connection diagram for showing the variation of the internal configuration of the inverter. FIG. 10 is still another connection diagram for showing variations in the internal configuration of the inverter. It is a connection diagram with the peripheral device centering on the power conditioner which concerns on 2nd Embodiment from a viewpoint which sets the upper limit of the residual amount of a storage battery.

[Summary of Embodiment]
The gist of the embodiment of the present invention includes at least the following.

(1) This is a power conditioner provided between the photovoltaic power generation panel and the storage battery and the commercial power system. The system voltage at the time of grid connection, the threshold of the voltage that needs to be suppressed, and the actual A power conditioner having a control unit that adjusts the remaining charge until full charge at the time of rising suppression by setting an upper limit value of the remaining amount of the storage battery other than at the time of rising suppression based on a comparison with the measured value of It is.
Note that the charging capacity here means room (reserving capacity) that can be further charged, and can be said to be free capacity.

The measured value of the system voltage at the time of grid connection varies depending on the impedance of the commercial power system viewed from the power conditioner, and the voltage may be higher than usual. In this case, when the voltage further increases and reaches a voltage threshold that needs to be suppressed, the power conditioner suppresses the increase in voltage. By simply suppressing the increase, the power that can be output is wasted. Therefore, by appropriately setting the upper limit value of the remaining amount in preparation for such a case, the storage battery that stands by without being fully charged has the remaining charge capacity, and can be output from the power conditioner. Electric power can be used to charge the storage battery. On the other hand, if the voltage does not increase so much, it is not a good idea to leave a large charge capacity from the standpoint of emergency and utilization of nighttime power, but it is preferable to have a small charge capacity. .
Such a power conditioner can maintain the storage battery in an optimum state in consideration of an increase in the system voltage.

(2) In the power conditioner of (1), for example, the control unit sets the upper limit value lower as the measured value is closer to the threshold value, and conversely, the measured value is set to the threshold value. The upper limit value can be set higher as the distance from the position increases.
In this case, since the remaining charge capacity increases as the threshold value of the voltage that needs to be suppressed increases, the remaining charge capacity of the storage battery can be used well. On the contrary, as the threshold value is less likely to be reached, the remaining capacity for charging, which is required less frequently, can be kept small, and the remaining capacity of the storage battery can be kept high to effectively utilize the capacity of the storage battery.

(3) In the power conditioner of (2), the control unit may include, for example, an operation for multiplying the measured value by a negative coefficient and adding a positive constant to the operation for obtaining the upper limit value. it can.
In this case, it is possible to easily construct a desired relationship in which the upper limit value decreases as the measured value approaches the threshold value.

(4) In the power conditioner according to any one of (1) to (3), the control unit compares an average value of the measured values of the system voltage in a past predetermined period with the threshold value. Also good.
In this case, an appropriate upper limit value can be set based on the actual situation based on the past results.

(5) In the power conditioner of (4), the control unit may perform real-time control so that the upper limit value decreases as the average value approaches the threshold value.
In this case, if the average value of the system voltage moves closer to the threshold value, the upper limit value decreases in real time, so that the upper limit value can be adjusted quickly. If the average value of the system voltage moves in the opposite direction, the upper limit value decreases in real time.

(6) Moreover, the power conditioner in any one of (1)-(5) may have a function which notifies whether to perform the setting of the said upper limit, and obtains an answer.
In this case, whether or not to set an upper limit value can be left to the user's judgment. That is, the user can select whether to give priority to storing the electric power that can be generated without waste or to place importance on keeping the storage battery fully charged, depending on his / her preference.

(7) Moreover, in the power conditioner of (1), the control unit may further set the upper limit value based on the reverse power flow to the commercial power system.
Since the magnitude of the backflow power is related to the power that is used to charge the storage battery when the rise is suppressed, the upper limit value can be set in consideration of the backflow power.

(8) Moreover, in the power conditioner of (1), the control unit performs at least one of the fast reactive power control and the output control when the storage battery reaches a full charge and the measured value increases. You may make it perform.
Even if the storage battery is charged, if there is surplus power and the measured value increases, such control can suppress an increase in voltage.

  (9) On the other hand, from another point of view, this is a distributed power supply system composed of a plurality of consumers under a common transformer, and each consumer is provided with a photovoltaic power generation panel and a storage battery. And a power conditioner provided between the photovoltaic power generation panel and the storage battery and the commercial power system, the voltage threshold at which rise suppression is required for the system voltage during grid connection, and actual measurement The upper limit value of the remaining amount of the storage battery at a time other than the time when the increase is suppressed is relatively reduced as the measured value is relatively closer to the threshold value among the plurality of power conditioners. A distributed power supply system in which the upper limit value is set higher as the measured value is farther from the threshold value.

The measured value of the system voltage at the time of grid connection varies depending on the impedance of the commercial power system viewed from the power conditioner, and the voltage may be higher than usual. In this case, when the voltage further increases and reaches a voltage threshold that needs to be suppressed, the power conditioner suppresses the increase in voltage. By simply suppressing the increase, the power that can be output is wasted. Therefore, by appropriately setting the upper limit value of the remaining amount in preparation for such a case, the storage battery that stands by without being fully charged has the remaining charge capacity, and can be output from the power conditioner. Electric power can be used to charge the storage battery. On the other hand, if the voltage does not increase so much, it is not a good idea to leave a large charge capacity from the standpoint of emergency and utilization of nighttime power, but it is preferable to have a small charge capacity. .
In other words, the remaining charge capacity of the storage battery can be utilized well by increasing the remaining charge capacity so that the threshold value of the voltage that needs to be suppressed is increased. On the contrary, as the threshold value is less likely to be reached, the remaining capacity for charging, which is required less frequently, can be kept small, and the remaining capacity of the storage battery can be kept high to effectively utilize the capacity of the storage battery.
Such a distributed power supply system can maintain each storage battery in an optimum state in consideration of an increase in system voltage.

  (10) From the viewpoint of the method, this is an operation method of the power conditioner provided between the photovoltaic power generation panel and the storage battery and the commercial power system. Charging up to full charge by comparing the threshold value of the voltage that needs to be suppressed and the actual measured value, and setting the upper limit value of the remaining amount of the storage battery other than during the rise suppression based on the comparison result It is an operation method of a power conditioner that adjusts the remaining power and charges the storage battery until the remaining amount reaches the upper limit value when the measured value reaches the threshold value.

In this case, the same can be said for the power conditioner (1).
According to such an operation method of the power conditioner, the storage battery can be maintained in an optimum state in consideration of an increase in the system voltage.

[Details of the embodiment]
Hereinafter, details of embodiments of the present invention will be described with reference to the drawings.

《Distributed power supply system》
FIG. 1 is a single-line connection diagram illustrating a configuration example of a distributed power supply system. This distributed power supply system 100 is assumed to be composed of a plurality of consumers 101, 102, 103 (the number is an example) under the umbrella of a common transformer 200. Each customer 101, 102, 103 is equipped with a photovoltaic power generation panel 1, a storage battery 2, and a power conditioner 3. The transformer 200 is connected to the high-voltage distribution line 201 and, for example, steps down AC 6600V to single-phase three-wire 202 / 101V. Each customer 101, 102, 103 is connected to a low voltage distribution line 202. The distance seen from the transformer 200 is the order of the consumer 101, the consumer 102, and the consumer 103 from the nearer side.

  The electric power generated by the solar power generation panel 1 of each customer 101, 102, 103 is consumed by the load (home appliances, etc.) in each customer via the power conditioner 3, and the surplus power is The reverse power (power sale) to the low-voltage distribution line 202 is possible beyond the power meters 101m, 102m, and 103m. The reversed power is supplied to other consumers (not shown) connected to the same low voltage distribution line 202 as the distributed power supply system 100.

  Here, the system voltage at each customer 101, 102, 103 connected to the grid increases as the line length from the transformer 200 increases. For example, the actual actual system voltage with a supply of 100 V has a difference such that the customer 101 has 102 V, the customer 102 has 104 V, and the customer 103 has 106 V. The reason why the system voltages are different is that the impedance of the low-voltage distribution line 202 as viewed from each customer 101, 102, 103 varies depending on the line length.

  The Electricity Business Law stipulates that it does not deviate from 101V ± 6V for 100V supply and that it does not deviate from 202V ± 20V for 200V supply. Therefore, in the case of 100V supply, considering the rise of the system voltage, 107V becomes a threshold value and should not be exceeded. When the system voltage reaches the threshold value, the power conditioner 3 voluntarily suppresses the increase and prevents the system voltage from exceeding the threshold value. From the usual grid voltage, the consumer 101 has a threshold of 5V, the consumer 102 has a threshold of 3V, and the consumer 103 has a threshold of 1V. In other words, relatively speaking, the consumer 103 is closest to the threshold value, and therefore easily reaches the threshold value, while the consumer 101 is farthest from the threshold value, and thus is difficult to reach the threshold value.

<< Power Conditioner: First Embodiment >>
FIG. 2 is a connection diagram with peripheral devices centered on the power conditioner 3 in any one of the consumers in FIG. In the figure, the DC side ports P1 and P2 of the power conditioner 3 are connected to the photovoltaic power generation panel 1 and the storage battery 2, respectively. The AC side port P3 of the power conditioner 3 is connected to the commercial power system 20 (the low-voltage distribution line 202 in FIG. 1) via the distribution board 4 in the consumer. The distribution board 4 is connected to a load 5 such as a home appliance in a consumer. Current sensors 6 and 7 are provided on two single-phase three-wire voltage lines connecting the distribution board 4 and the commercial power system 20.

  The power conditioner 3 includes a DC / DC converter 31 connected to the photovoltaic power generation panel 1, a DC / DC converter 32 connected to the storage battery 2, and a direct current common to the two DC / DC converters 31 and 32. A DC bus 33 serving as an electric circuit pair; a smoothing capacitor 34 provided between two lines of the DC bus 33; an inverter 35 connected to the two DC / DC converters 31 and 32 via the DC bus 33; A voltage sensor for detecting a system voltage between one voltage line-neutral line and a system voltage between the other voltage line-neutral line of the control unit 36, the inverter 35 and the distribution board 4 respectively. 37 and 38. Here, the inverter 35 is a 202V two-wire output.

  The control unit 36 controls the switching operation of the two DC / DC converters 31 and 32 and the inverter 35. Further, the control unit 36 receives the detection outputs of the voltage sensors 37 and 38 and the detection outputs of the current sensors 6 and 7. The control unit 36 includes, for example, a microcomputer, and implements necessary control functions by causing the computer to execute software (computer program). The software is stored in a storage device (not shown) of the control unit 36.

  The DC / DC converter 31 during power generation by the photovoltaic power generation panel 1 performs MPPT (Maximun Power Point Tracking) control and performs necessary boosting. The inverter 35 converts the voltage / current output from the DC / DC converter 31 so that the voltage / current of the commercial power system 20 matches the amplitude and phase, thereby realizing system interconnection. The power generated by the photovoltaic power generation panel 1 is consumed by the load 5 in the consumer, and surplus power can be sold.

  Further, the storage battery 2 can be charged by operating the DC / DC converter 32 so as to step down the voltage of the DC bus 33. Therefore, the generated power of the photovoltaic power generation can be used for three purposes: consumption at the load 5 in the consumer, reverse tide (power sale), and charging of the storage battery 2. Further, if the DC / DC converter 32 is operated so as to boost the voltage of the storage battery 2 and send it to the DC bus 33, it is also possible to supply power to the load 5 in the consumer via the DC / AC conversion by the inverter 35. . The inverter 35 is bidirectional and can convert from alternating current to direct current. For example, it is also possible to charge the storage battery 2 from the commercial power system 20 via the inverter 35 and the DC / DC converter 32 at night when solar power generation is not performed.

  Here, returning to FIG. 1, the relationship between the system voltage and the charging of the storage battery 2 will be described. As described above, the usual measured value of the system voltage in the consumers 101, 102, 103 is not the same, and there is also a customer 103 with a measured value close to the increase suppression threshold of the power conditioner 3. Therefore, the measured value of the system voltage is compared with a threshold value, and the degree of proximity is observed. For example, the difference between the threshold value and the measured value or the ratio of the measured value to the threshold value is observed. And the difference is close to 0 or the ratio is close to 100%, and it is considered that the possibility of being caught in the rise suppression is high. Here, the remaining charge capacity is (100−remaining capacity) [%] when the remaining capacity (SOC: State of charge) is expressed in%.

  In addition, about the remaining amount of the storage battery 2, the control part 36 can obtain information from BMS (Battery Management System) which is not shown accompanying the storage battery 2. It is also possible to obtain information by the DC / DC converter 32 integrating the current in / out associated with charging / discharging.

  In the example of FIG. 1, assuming that the capacity of the storage battery 2 is 6 kWh, for example, the storage battery 2 of the customer 101 has an upper limit of 6 kWh (that is, 100% (fully charged)). The storage battery 2 of the customer 102 has an upper limit of the remaining amount of 5.4 kWh (90% charged state). The storage battery 2 of the customer 103 has an upper limit value of 4.8 kWh (80% charge state).

In the above numerical example, assuming that the upper limit value of the remaining amount is W _max [kWh] and the measured value of the system voltage is Vs [V], for example, the measured value Vs is multiplied by a negative coefficient as follows. Is obtained by an arithmetic expression of a linear function for adding.
W _max = −0.3 Vs + 36.6 (1)
From this equation, it is possible to easily construct a desired relationship in which the upper limit value W _max decreases as the measured value Vs approaches the threshold value.

That is, in Formula (1),
When Vs = 102, W _max = 6 (100%)
When Vs = 104, W _max = 5.4 (90%)
When Vs = 106, W _max = 4.8 (80%)
It is.

  The method of determining the remaining amount according to the above formula (1) is merely an example. In general terms, the upper limit value of the remaining capacity of the storage battery 2 is set based on a comparison between the threshold value of the voltage that needs to be suppressed and the actual measurement value for the grid voltage during grid connection. As a result, the remaining charge capacity until the full charge at the time of suppressing the rise is adjusted.

  It should be noted that the measurement value Vs of the system voltage is measured when the current sensors 6 and 7 detect the current value 0, that is, the power output from the power conditioner 3 and the power consumed by the load 5 are mutually It is preferable when they match.

By appropriately setting the upper limit value of the remaining amount in this way, the storage battery 2 (excluding the customer 101) that stands by without being in a fully charged state has a remaining charge capacity, and therefore the power conditioner. The electric power that can be output from the battery 3 can be used for charging the storage battery 2. On the other hand, if the voltage does not increase so much, it is not a good idea to leave a large charge capacity from the standpoint of emergency and utilization of nighttime power, but it is preferable to have a small charge capacity. .
Such a power conditioner 3 can maintain the storage battery 2 in an optimum state in consideration of an increase in the system voltage.

In addition, the above-mentioned “setting the upper limit value of the remaining amount of the storage battery 2 based on the comparison between the threshold value of the voltage that needs to be suppressed and the actual measurement value” is relatively The upper limit value of the remaining amount is set lower as the measured value is closer to the threshold value, and conversely, the upper limit value of the remaining amount is set higher as the measured value is farther from the threshold value.
As a result, the surplus charge capacity increases as the threshold value of the voltage that needs to be suppressed is increased, so that the remaining charge capacity of the storage battery can be used well. Conversely, the more difficult it is to reach the voltage threshold that needs to be suppressed, the less the remaining charging capacity that is needed, the lower the remaining capacity of the storage battery, the higher the remaining capacity of the storage battery, and the effective use of the capacity of the storage battery. it can.

  As a method for obtaining the measured value of the system voltage, for example, the control unit 36 may set an upper limit value based on an average value of measured values in a predetermined period in the past, for example, a predetermined period of the previous day. In this case, it is possible to set an appropriate upper limit value in accordance with the actual situation based on the results of the previous day.

  Moreover, the control part 36 can also control in real time so that an upper limit may become low, so that the average value in a predetermined period of a measured value approaches a threshold value. In this case, if the average value of the system voltage moves closer to the threshold value, the upper limit value decreases in real time, so that the upper limit value can be adjusted quickly. In this case, if the average value of the system voltage moves in the opposite direction, the upper limit value increases in real time.

  In FIG. 2, the control unit 36 is based on the detection output of the current flowing through the current sensors 6 and 7 in the reverse direction (from the distribution board 4 to the commercial power system 20) and the detection outputs of the voltage sensors 37 and 38. The reverse power to the commercial power system can be obtained. Therefore, the control unit 36 may further set an upper limit value based on the reverse power flow. Since the magnitude of the reverse power is related to the power that is used to charge the storage battery 2 when the increase is suppressed, the upper limit value can be set in consideration of the reverse power.

Further, if the measured value of the system voltage rises even when the storage battery 2 reaches full charge, the control unit 36
(I) Phase advance reactive power control (ii) Output control (active power suppression)
Can be suppressed in the order of (i), (ii), or by omitting (i) and performing only (ii).

(Supplement 1)
For example, if it is possible to learn from the past information the length of time for which the rise suppression is required, the remaining charge capacity is only required to charge the amount of power in that case. The past information may be stored in the power conditioner 3 or may be obtained from a home energy management system (HEMS) (not shown) in the consumer. For example, if the output of the photovoltaic power generation panel 1 is rated at 5 kW and the rise suppression is a maximum of 30 minutes from the past information, it is not necessary to leave a remaining charge capacity exceeding 5 kW × 0.5 hours = 2.5 kWh.

(Supplement 2)
In addition, for example, assuming that the storage battery 2 is discharged in the early morning when solar power generation is not performed depending on the season to cover the power of the load 5, if the early morning power consumption can be grasped from past information, the amount is It is preferable to set the amount of power to be stored in the storage battery 2. For example, if the consumer consumes 0.5 kWh on a daily basis, it is preferable to include this 0.5 kWh in the upper limit W _max .

In consideration of the matters (supplement 1) and (supplement 2), the following formula (2) may be adopted instead of the above formula (1).
W _max = (− 0.3 Vs + 36.6) +0.5 (2)
However, W _max ≧ (6-2.5). Here, (6-2.5) is a value obtained by subtracting the empirical maximum charging capacity based on past information from the capacity of the storage battery.

<Modification of inverter>
The internal configuration of the power conditioner 3 shown in FIG. 2 is an example, and there can be various other internal configurations.
3, 4, and 5 are connection diagrams for illustrating variations in the internal configuration of the power conditioner 3. The same parts as those in FIG.

  First, the power conditioner 3 in FIG. 3 is different from that in FIG. 2 in that no DC / DC converter is provided between the storage battery 2 and the DC bus 33. Such a configuration is also possible when the voltage of the storage battery 2 is the same or substantially the same as the voltage of the DC bus 33.

  Next, the power conditioner 3 in FIG. 4 is different from that in FIG. 2 in that no DC / DC converter is provided between the photovoltaic power generation panel 1 and the DC bus 33. Such a configuration is also possible when a sufficiently high voltage is obtained from the photovoltaic power generation panel 1 as a direct input voltage to the inverter 35. In this case, the MPPT control is performed by the inverter 35 under the control of the control unit 36.

  Furthermore, FIG. 5 is an example in which separate power conditioners 3a and 3b are provided for the photovoltaic power generation panel 1 and the storage battery 2, respectively. Each power conditioner 3a, 3b is provided with an inverter and, if necessary, a DC / DC converter on its direct current side. In this case, the power conditioner 3a is only in charge of outputting the generated power of the photovoltaic power generation as AC power. The power conditioner 3b is in charge of charging the storage battery 2 with the generated power of solar power generation or, if necessary, the power of the commercial power system 20, and discharging the storage battery 2 to supply power to the load 5. Since the power due to the discharge of the storage battery 2 cannot be reversed, the power conditioner 3b at the time of discharging the storage battery is connected to the load 5 so as not to reverse the flow based on the detection output of the current sensors 6 and 7 and the measured value of the system voltage. Prevent power supply exceeding power consumption.

<< Power Conditioner: Second Embodiment >>
FIG. 6 is a connection diagram with peripheral devices centered on the power conditioner 3 according to the second embodiment from the viewpoint of setting the upper limit value of the remaining capacity of the storage battery.
The difference from FIG. 2 is that the display / operation unit 39 which is a remote control device of the power conditioner 3 additionally has a predetermined function. The display / operation unit 39 is connected to the control unit 36 so as to be communicable (either wired or wireless).

The control unit 36 in the power conditioner 3 of FIG. 6 notifies the display / operation unit 39 whether or not to set the upper limit value of the remaining amount of the storage battery 2 in advance, and displays it on the display / operation unit 39. The user of the consumer sees the display and selects either “set an upper limit value” or “do not set an upper limit value”. As a result, the control unit 36 obtains an answer as to whether the user wishes to “set an upper limit value” or “do not set an upper limit value”.
In this way, whether or not to set an upper limit value can be left to the judgment of the consumer user. That is, the user can select whether to give priority to storing the electric power that can be generated without waste or to place importance on keeping the storage battery fully charged, depending on his / her preference.

  In addition, the variation of the internal structure of the power conditioner 3 shown in FIGS. 3-5 is applicable similarly to the power conditioner 3 of 2nd Embodiment.

《Supplementary Note》
The embodiment disclosed this time should be considered as illustrative in all points and not restrictive. The scope of the present invention is defined by the terms of the claims, and is intended to include any modifications within the scope and meaning equivalent to the terms of the claims.

DESCRIPTION OF SYMBOLS 1 Solar power generation panel 2 Storage battery 3 Power conditioner 3a, 3b Power conditioner 4 Distribution board 5 Load 6, 7 Current sensor 20 Commercial electric power system 31 DC / DC converter 32 DC / DC converter 33 DC bus 34 Capacitor 35 Inverter 36 Control unit 37, 38 Voltage sensor 39 Display / operation unit 100 Distributed power supply system 101, 102, 103 Customer 101m, 102m, 103m Electric power meter 200 Transformer 201 High voltage distribution line 202 Low voltage distribution line P1, P2 DC side port P3 AC Side port

Claims (10)

A power conditioner provided between a photovoltaic power generation panel and a storage battery and a commercial power system,
By setting the upper limit value of the remaining capacity of the storage battery other than at the time of increase suppression, based on the comparison between the threshold value of the voltage that needs to be suppressed and the actual measured value for the grid voltage at the time of grid connection The power conditioner which has a control part which adjusts the charge remaining capacity until full charge at the time of a rise restraint.   The control unit relatively sets the upper limit value lower as the measurement value is closer to the threshold value, and conversely sets the upper limit value higher as the measurement value is farther from the threshold value. The listed inverter.   The power conditioner according to claim 2, wherein the control unit includes a calculation for multiplying the measurement value by a negative coefficient and adding a positive constant to the calculation for obtaining the upper limit value.   The power conditioner according to claim 1, wherein the control unit compares an average value of the measured values of the system voltage in a past predetermined period with the threshold value.   The power conditioner according to claim 4, wherein the control unit controls the upper limit value in real time so that the upper limit value decreases as the average value approaches the threshold value.   The power conditioner according to any one of claims 1 to 5, which has a function of notifying whether to set the upper limit value and obtaining an answer.   Furthermore, the power conditioner of Claim 1 which sets the said upper limit based on the reverse power flow to the said commercial power grid.   2. The power conditioner according to claim 1, wherein when the storage battery reaches a full charge and the measured value rises, at least one of a phase advance reactive power control and an output control is performed. A distributed power system composed of a plurality of consumers under a common transformer.
Solar power panels,
A storage battery,
A power conditioner provided between the photovoltaic power generation panel and the storage battery and the commercial power system,
For the grid voltage at the time of grid connection, the threshold value of the voltage that needs to be suppressed and the actual measurement value are compared, and the measured value is relatively compared to the threshold value among the plurality of power conditioners. A distributed power supply system that sets the upper limit value of the remaining amount of the storage battery at a time other than when the rise is suppressed to a lower value, and conversely sets the upper limit value to be higher as the measured value is farther from the threshold value. An operation method of a power conditioner provided between a photovoltaic power generation panel and a storage battery and a commercial power system,
For the grid voltage at the time of grid connection, compare the threshold value of the voltage that needs to be suppressed and the actual measured value,
Based on the comparison result, by setting the upper limit value of the remaining capacity of the storage battery other than during the rise suppression, the remaining charge capacity until full charge is adjusted,
When the measured value reaches the threshold, the storage battery is charged to full charge.
How to operate the inverter.