JP7034871B2 - Power conditioner, power system and judgment method - Google Patents

Description

The present invention relates to a power conditioner, a power system and a determination method.

In recent years, a solar power generation system combining a solar cell and a storage battery has become widespread, and the solar cell and the storage battery are connected to an electric power system via a power conditioner. In a solar power generation system, power is supplied from the power system to a storage battery or an indoor load (power purchase state) and a reverse current flow from the power conditioner to the power system (power sale state) in order to buy and sell power. A current sensor is provided between the power conditioner and the power system so as to detect.

In relation to the technique of determining a connection error such as disconnection of a current sensor, Patent Document 1 states that in a photovoltaic power generation system, the output of the current sensor changes when the inverter output fluctuates by a predetermined threshold or more. It has been proposed to determine. Further, Patent Document 2 proposes to determine a connection error of a current sensor from a difference in a detection value of a current sensor when a heater for heating is turned on / off in a fuel cell system.

Japanese Unexamined Patent Publication No. 2018-11732 Japanese Unexamined Patent Publication No. 2017-199502

However, in the technique of Patent Document 1, the determination process is not executed when the inverter output is stable, that is, when the inverter output continues to fluctuate below a predetermined threshold value. Therefore, there is a problem that the determination of the connection error of the current sensor is delayed. Further, the technique of Patent Document 2 relates to a fuel cell system provided with a load (auxiliary device) such as a heater for heating, and the load such as the heater for heating is not provided inside the solar power generation system. .. Therefore, in order to apply the technique of Patent Document 2 to the photovoltaic power generation system, it is necessary to separately add a load for determination and further control the load, which causes a problem that the cost increases.

One aspect of the present invention is to reliably determine the connection state of a current sensor without increasing the cost.

In order to solve the above problems, the power conditioner according to one aspect of the present invention is connected to a current sensor that detects reverse power flow or forward power flow to the power system, and determines the possibility of connection error of the current sensor. Then, when it is determined in the connection error possibility determination that there is a connection error possibility, the output effective current is changed.

Further, in order to solve the above problems, the determination method according to one aspect of the present invention is connected to a current sensor that detects reverse power flow or forward power flow to the power system, and determines the possibility of connection error of the current sensor. Execute, and change the output active current when it is determined that there is a possibility of connection error in the determination of possibility of connection error.

According to one aspect of the present invention, the connection state of the current sensor can be reliably determined without increasing the cost.

It is a block diagram which shows the schematic structure of the electric power system which concerns on Embodiment 1. FIG. It is a flowchart which shows an example of the connection error determination processing which concerns on Embodiment 1. It is a graph which shows an example of the waveform change of the output current of the inverter which concerns on Embodiment 1. FIG. It is a flowchart which shows an example of the connection error determination processing which concerns on Embodiment 2. It is a graph which shows an example of the waveform change of the output current of the inverter which concerns on Embodiment 2. FIG. It is a flowchart which shows an example of the connection error determination processing which concerns on Embodiment 3. It is a graph which shows an example of the waveform change of the output current of the inverter which concerns on Embodiment 3. FIG.

[Embodiment 1]
Hereinafter, the power conditioner according to one aspect of the present invention will be described with reference to FIGS. 1 to 3. In this embodiment, an example of a configuration in which the power conditioner according to one aspect of the present invention is applied to a power system (solar power generation system) including a solar cell as a power generation device will be described. However, the power conditioner according to the present invention can be applied to various electric power systems such as a wind power generation system, a gas power generation system, and a geothermal power generation system.

(Power system configuration)
FIG. 1 is a block diagram showing a schematic configuration of the power system 1. The electric power system 1 is a grid-connected photovoltaic power generation system that is electrically connected to the electric power system 10 and transmits (sells) and receives (purchases) electric power to and from the electric power system 10. The electric power system 1 is installed in a house such as a house or an office.

As shown in FIG. 1, the power system 1 includes a power conditioner 2, a solar cell (power generation device) 3, a storage battery 4, and an RPR sensor (current sensor) 5. A load group 6 is electrically connected between the power conditioner 2 and the power system 10 via a distribution board or the like (not shown). The load group 6 is composed of a plurality of electric devices. Examples of electrical equipment include lighting, televisions, refrigerators, washing machines, air conditioners, microwave ovens, and the like.

The power conditioner 2 is a reverse power flow (selling power) of the electric power generated by the solar cell 3 to the electric power system 10, power supply from the solar cell 3 to the storage battery 4 and the load group 6, and the electric power system 10 to the storage battery 4. It controls power supply (purchase of power). The power conditioner 2 includes an inverter 21, a first DC / DC converter 22, a second DC / DC converter 23, and a control unit 24.

The inverter 21 converts DC power and AC power. The inverter 21 is electrically connected to the solar cell 3 via the first DC / DC converter 22. The inverter 21 converts the DC voltage supplied from the solar cell 3 into an AC voltage and supplies it to the power system 10 and the load group 6. Further, the inverter 21 is electrically connected to the storage battery 4 via the second DC / DC converter 23. When charging the storage battery 4 using the AC voltage supplied from the power system 10, the inverter 21 converts the AC voltage supplied from the power system 10 into a DC voltage and supplies the AC voltage to the second DC / DC converter 23. Further, when the storage battery 4 is discharged, the inverter 21 converts the DC voltage supplied from the second DC / DC converter 23 into an AC voltage and supplies the DC voltage to the load group 6.

The first DC / DC converter 23 is arranged between the solar cell 3 and the inverter 21. The first DC / DC converter 23 performs pressure conversion (boost) of the DC voltage supplied from the solar cell 3. The second DC / DC converter 24 is arranged between the storage battery 4 and the inverter 21. The second DC / DC converter 24 performs voltage conversion of the DC voltage DC voltage supplied from the storage battery 4 when the storage battery 4 is discharged. Further, when the storage battery 4 is charged, the DC voltage supplied from the inverter 21 is converted into a voltage.

The control unit 24 controls the operation of the power conditioner 2. The control unit 24 controls, for example, reverse power flow to the power system 10 (power sale), charging / discharging of the storage battery 4, and power supply (power purchase) from the power system 10. Further, the control unit 24 executes the connection error determination process of the RPR sensor 5 as described later.

The solar cell 3 is composed of a crystalline solar cell, a polycrystalline solar cell, a thin film solar cell, or the like. The solar cell 3 has a photovoltaic power generation panel (not shown), and supplies DC power generated by the photovoltaic power generation panel to the power conditioner 2. The electric power generated by the solar cell 3 is used for selling electricity, supplying the load group 6, charging the storage battery 4, and the like.

The storage battery 4 is a rechargeable power storage element, and is typically composed of a secondary battery such as a lithium ion battery or a nickel hydrogen battery. The storage battery 4 is configured by connecting a plurality of battery cells in series. The electric power discharged from the storage battery 4 is used for supplying the load group 6 and the like.

The RPR (Reverse Power Relay) sensor 5 is a sensor that detects reverse power flow when the storage battery 4 is discharged. The RPR sensor 5 detects the receiving point current with the power system 10. The detected current of the RPR sensor 5 is transmitted to the control unit 24 of the power conditioner 2 wirelessly or by wire. The control unit 24 monitors the occurrence of reverse power flow when the storage battery 4 is discharged, based on the detection current of the RPR sensor 5.

The power system 10 is, for example, a single-phase three-wire commercial AC power system. In a single-phase three-wire commercial AC power system, the neutral wire is grounded via a resistor, and as an example, AC200V is supplied using two wires (R-phase wire and T-phase wire) other than the neutral wire. do.

(Connection error judgment processing)
Next, the connection error determination process of the RPR sensor 5 executed by the control unit 24 will be described. In the operation of the power system 1 provided with the storage battery 4, it is required to install a reverse power relay (RPR) for detecting the reverse power flow so that the reverse power flow does not occur when the storage battery 4 is discharged. In the power system 1, the control unit 24 monitors the reverse power flow at the time of discharging the storage battery 4 based on the detection signal from the RPR sensor 5.

However, the RPR sensor 5 may drop off, and the current (reverse power flow) may not be detected by the RPR sensor 5. In this case, the reverse power flow at the time of discharging the storage battery 4 cannot be correctly detected.

Therefore, the control unit 24 executes a connection error determination process for detecting the disconnection of the RPR sensor 5 or the like in order to determine the connection state of the RPR sensor 5 when the storage battery 4 is discharged. Then, when it is determined that a connection error of the RPR sensor 5 has occurred, the control unit 24 controls such as stopping the output of the inverter 21 so that the reverse power flow from the power system 1 to the power system 10 does not occur. I do.

In addition, the connection error of the RPR sensor 5 includes a state in which the RPR sensor 5 cannot correctly detect the current (including the dropout), such as the RPR sensor 5 being dropped, the RPR sensor 5 failing, or the RPR sensor 5 being installed in the wrong position. Is included.

As a condition for determining whether or not a connection error of the RPR sensor 5 has occurred, it is conceivable to determine that a connection error has occurred, for example, when the following error conditions 1 to 3 are satisfied. This is because when the following error conditions 1 to 3 are satisfied, it is usually considered that the possibility that a connection error of the RPR sensor 5 has occurred is extremely high. The following error conditions 1 to 3 are examples, and the determination conditions can be changed as appropriate.
(Error condition 1) The output power of the power conditioner 2 (inverter 21) at the time of discharging the storage battery 4 is equal to or higher than a predetermined first threshold value (third determination threshold value: for example, about 1000 W).
(Error condition 2) The absolute value of the power receiving point current value detected by the RPR sensor 5 is less than a predetermined second threshold value (first determination threshold value, second determination threshold value), or one cycle detected by the RPR sensor 5. The absolute value of the change width between the previous receiving point current and the receiving point current in the current cycle is less than a predetermined second threshold value (first determination threshold value, second determination threshold value: for example, about 0.57 Arms).
(Error condition 3) The state of the error condition 1 and the error condition 2 continues for the first predetermined period (for example, about 5000 cycles).

However, for example, when the absolute value of the receiving point current value is less than a predetermined second threshold value as the error condition 2, the output power of the inverter 21 and the power consumption of the load group 6 are almost balanced, and the inverter 21 If the state in which the output power is stable continues, the above error conditions 1 to 3 may be satisfied. Further, for example, when the absolute value of the change width of the receiving point current is less than a predetermined second value threshold as error condition 2, the output power of the inverter 21 and the power consumption of the load group 6 change stably. If the non-existent state continues, the above error conditions 1 to 3 may be satisfied. In this case, even though the connection state of the RPR sensor 5 is normal, it may be erroneously determined that a connection error of the RPR sensor 5 has occurred.

Therefore, when the control unit 24 determines in the connection error determination process that there is a relatively high possibility that a connection error has occurred in the RPR sensor 5 (for example, about 4000 cycles), the detection current value of the RPR sensor 5 (for example, about 4000 cycles) Either the absolute value of the receiving point current value) or the absolute value of the change width of the detection current (power receiving point current) of the RPR sensor 5 (hereinafter, may be simply referred to as the detection current) is at least instantaneously the above-mentioned first. The output current of the inverter 21 is positively changed so as to be 2 thresholds or more. When the connection state of the RPR sensor 5 is normal, the detection current of the RPR sensor 5 becomes equal to or higher than the second threshold value as the output current of the inverter 21 changes. As a result, the above-mentioned error condition 3 is not satisfied, so that it is possible to prevent the above-mentioned erroneous determination of the connection error.

FIG. 2 is a flowchart showing an example of the connection error determination process according to the present embodiment. As shown in FIG. 2, the control unit 24 determines in step S1 whether or not the storage battery 4 is in the discharged state. When the storage battery 4 is not in the discharged state (No in step S1), the control unit 24 ends the connection error determination process. On the other hand, when the storage battery 4 is in the discharged state (Yes in S1), the control unit 24 proceeds to S2.

Next, in step S2, the control unit 24 determines whether or not the output power of the inverter 21 is equal to or greater than the first threshold value (1000 W). When the output power of the inverter 21 is less than the first threshold value (No in step S2), the error condition 1 is not satisfied, so that the control unit 24 ends the connection error determination process. On the other hand, when the output power of the inverter 21 is equal to or higher than the first threshold value (Yes in step S2), the control unit 24 proceeds to S3.

Next, in step 3, the control unit 24 determines whether or not the detection current of the RPR sensor 5 is less than the second threshold value (0.57 Arms). Specifically, the control unit 24 determines whether or not the detection current of the RPR sensor 5 is less than the second threshold value throughout one cycle. When the detection current of the RPR sensor 5 is equal to or greater than the second threshold value (No in step S3), the error condition 2 is not satisfied, so the control unit 24 ends the connection error determination process. On the other hand, when the detection current of the RPR sensor 5 is less than the second threshold value (Yes in step S3), the control unit 24 proceeds to S4. The order in which steps S2 and S3 are executed may be reversed, or steps S2 and S3 may be executed at the same time.

Next, when the conditions of steps S1 to S3 are satisfied, the control unit 24 starts counting the timer in step S4. Even after the count is started, the control unit 24 determines whether the storage battery 4 is in a discharged state, determines whether the output power of the inverter 21 is equal to or higher than the first threshold value, and determines whether the RPR sensor 5 detects the current. The determination of whether or not it is less than the second threshold value is continuously performed. Then, when the storage battery 4 is no longer in the discharged state, the output power of the inverter 21 is less than the first threshold value, or the detection current of the RPR sensor 5 is equal to or more than the second threshold value, the timer counts at that time. Is reset and the connection error judgment process is terminated.

Next, in step S5, the control unit 24 determines whether or not the second predetermined period has elapsed from the start of counting the timer. In the second predetermined period, if the states of the error condition 1 and the error condition 2 exceed the second predetermined period within the first predetermined period, it is relatively possible that a connection error of the RPR sensor 5 has occurred. Any period that is determined to be high. That is, the control unit 24 causes a connection error of the RPR sensor 5 by determining whether or not the states of the error condition 1 and the error condition 2 continue for the second predetermined period in the discharged state of the storage battery 4. Judgment whether or not there is a possibility (whether or not there is a relatively high possibility that a connection error has occurred) (connection error possibility judgment). An example of the second predetermined period is 4000 cycles from the start of counting of the timer, but the second predetermined period is appropriately set according to the length of the first predetermined period and the like. If the second predetermined period has not elapsed from the start of counting of the timer (No in step S5), the control unit 24 repeats step S5 until the second predetermined period elapses. On the other hand, when the second predetermined period has elapsed from the start of counting of the timer (Yes in step S5), the control unit 24 determines that there is a possibility of a connection error of the RPR sensor 5 and proceeds to S5.

Next, in step S6, the control unit 24 changes (increases or decreases) the active current (output active current) of the output current of the inverter 21.

FIG. 3 is a graph showing an example of a waveform change in the output current of the inverter 21. W1 is the basic current which is the output current of the inverter 21 before changing the active current, W2 is the active current which is changed, W3 is the superimposed current which is the output current of the inverter 21 after changing the active current W2, and W4 is the electric power. The system voltage of the system 10 is shown.

In step S6, the control unit 24 positively changes the effective current of the output current of the inverter 21, so that the output current (output waveform) of the inverter 21 changes from the basic current W1 to the superimposed current W3 as shown in FIG. do. At this time, the control unit 24 maintains the output power of the inverter 21 to be equal to or higher than the first threshold value (1000 W), and at least instantaneously causes the detected electric current of the RPR sensor 5 to be equal to or higher than the second threshold value (0.57 Arms). In addition, the effective current of the output current of the inverter 21 is changed. As a result, when the connection state of the RPR sensor 5 is normal, the detection current of the second threshold value or more is detected by the RPR sensor 5 as the effective current changes. In the example shown in FIG. 3, by changing the output current of the inverter 21 from the basic current W1 to the superimposed current W3, when the connection state of the RPR sensor 5 is normal, the current of 0.57 Arms or more by the RPR sensor 5 Changes can be detected.

When the detection current of the RPR sensor 5 becomes equal to or higher than the second threshold value due to the change of the effective current in step S6, the error condition 3 is not satisfied, so that the control unit 24 ends the connection error determination process. This makes it possible to prevent the above-mentioned erroneous determination of the connection error. On the other hand, when the detection current of the RPR sensor 5 is still less than the second threshold value, the control unit 24 continues to determine whether or not the detection current of the RPR sensor 5 is less than the second threshold value.

In this step S6, the control unit 24 may gradually change (increase or decrease) the effective current of the output current of the inverter 21 so that the output current of the inverter 21 gradually changes. Alternatively, the control unit 24 may change (increase or decrease) the effective current of the output current of the inverter 21 at once so that the output current of the inverter 21 changes instantaneously. In either case, the connection state can be determined based on the detection current of the RPR sensor 5.

Further, the connection error possibility determination and the connection error determination may be performed based on the detection current value of the RPR sensor 5 itself, or the connection error possibility determination and the connection error determination may be performed based on the change width of the detection current of the RPR sensor 5. ..

Further, the control unit 24 may change the effective current of the output current of the inverter 21 by one cycle. Alternatively, the control unit 24 may intermittently change the active current of the output current of the inverter 21 over a plurality of current cycles, or continuously change the active current of the output current of the inverter 21 over a plurality of current cycles. You may let me. As a result, the connection error of the RPR sensor 5 can be determined more accurately.

When increasing the effective current of the output current of the inverter 21, it is necessary to control the output so as not to exceed the rated output.

Next, in step S7, the control unit 24 determines whether or not the first predetermined period has elapsed from the start of counting the timer. This first predetermined period is an arbitrary period set for appropriately determining the connection error of the RPR sensor 5. An example of the first predetermined period is 5000 cycles from the start of counting of the timer, but it can be changed as appropriate. If the first predetermined period has not elapsed from the start of counting of the timer (No in step S7), the control unit 24 repeats step S7 until the first predetermined period elapses. On the other hand, when the first predetermined period has elapsed from the start of counting of the timer (Yes in step S7), that is, when the above error condition 3 is satisfied, the control unit 24 proceeds to step S8.

Next, the control unit 24 determines in S8 that a connection error of the RPR sensor 5 has occurred, and ends the connection error determination process. When it is determined that a connection error of the RPR sensor 5 has occurred, the control unit 24 performs control such as stopping the output of the inverter 21 so that reverse power flow from the power system 1 to the power system 10 does not occur. .. Further, the control unit 24 may output an error signal indicating that a connection error of the RPR sensor 5 has occurred to a display unit (not shown) to notify the user.

(Effect of Embodiment 1)
As described above, the power conditioner 2 according to the present embodiment is connected to the RPR sensor 5 that detects the reverse power flow or the forward power flow to the power system 10, executes the connection error possibility determination of the RPR sensor 5, and performs the connection error possibility determination. The output effective current is changed when it is determined that there is a possibility of connection error in the determination of possibility of connection error.

In the above configuration, since the power conditioner 2 changes the output effective current when it is determined that there is a possibility of a connection error, the connection state of the RPR sensor 5 is surely based on the detection current detected by the RPR sensor 5. It can be determined. Further, the connection error of the RPR sensor 5 can be determined without attaching a separate determination load to the power conditioner 2.

Therefore, the connection state of the RPR sensor 5 can be reliably determined without increasing the cost.

(Modification example)
In the above embodiment, the connection error determination of the RPR sensor 5 that detects the reverse power flow at the time of discharging the storage battery 4 has been described. However, the determination method according to the present invention may be applied to the connection error determination of a general current sensor that detects the power selling state (reverse power flow) and the power purchasing state (forward power flow) in addition to the RPR sensor 5.

Further, in the above embodiment, the process of executing the connection error possibility determination is described in the connection error determination process of determining that the connection error has occurred when the above error conditions 1 to 3 are satisfied. However, the connection error possibility determination may be executed independently. In this case, the connection error possibility determination may be executed using the same or different determination conditions as the connection error determination described above. For example, if the detected current value of the RPR sensor 5 or the change width of the detected current is less than another threshold value (second determination threshold value) different from the above-mentioned second threshold value, there is a possibility of a connection error. May be determined. Further, when it is determined that there is a possibility of a connection error, the connection error of the RPR sensor 5 may be determined based on whether or not the detection current of the RPR sensor 5 has changed by the changed effective current.

Further, in the above embodiment, a method of changing the effective current of the output current of the inverter 21 after the lapse of the second predetermined period has been described. However, the effective current of the output current of the inverter 21 may be changed periodically over the first predetermined period.

Further, in the above embodiment, a method of changing the waveform of the output current of the inverter 21 by changing the effective current of the output current of the inverter 21 has been described. However, the reactive current may be changed instead of the active current, or the waveform of the output current of the inverter 21 may be changed by injecting a current strain into the output current of the inverter 21. Alternatively, the waveform of the output current of the inverter 21 may be changed by selectively combining the change of the active current, the change of the invalid effective, and the injection of the current strain.

However, by changing the active current of the output current of the inverter 21, the output current of the inverter 21 does not generate the system disturbance that may occur when the reactive current is changed or when the current distortion is injected. The waveform can be changed.

[Embodiment 2]
Other embodiments of the present invention will be described below with reference to FIGS. 4 and 5. For convenience of explanation, the same reference numerals are given to the members having the same functions as those described in the above-described embodiment, and the description thereof will not be repeated.

(Connection error judgment processing)
FIG. 4 is a flowchart showing an example of the connection error determination process according to the present embodiment. The connection error determination process according to the present embodiment is different from the above-described first embodiment in that the control unit 24 changes the reactive current of the output current of the inverter 21.

Since the contents of steps S1 to S5 and S7 to S8 are the same as those in the above embodiment, the description thereof will be omitted.

As shown in FIG. 4, in the present embodiment, when it is determined in S5 that the second predetermined period has elapsed, the control unit 24 changes the reactive current (output reactive current) of the output current of the inverter 21 in step S16. (Increase or decrease).

FIG. 5 is a graph showing an example of a waveform change in the output current of the inverter 21. W1 is the basic current which is the output current of the inverter 21 before changing the invalid current, W12 is the invalid current which is changed, W13 is the superimposed current which is the output current of the inverter 21 after changing the invalid current W12, and W4 is the electric power. The system voltage of the system 10 is shown.

In step S16, the control unit 24 positively changes the reactive current of the output current of the inverter 21, so that the output current (output waveform) of the inverter 21 changes from the basic current W1 to the superimposed current W13 as shown in FIG. do. At this time, the control unit 24 maintains the output power of the inverter 21 to be equal to or higher than the first threshold value (1000 W) so that the detected current of the RPR sensor 5 is at least instantaneously equal to or higher than the second threshold value (0.57 Arms). , The invalid current of the output current of the inverter 21 is changed. As a result, when the connection state of the RPR sensor 5 is normal, the detection current of the second threshold value or more is detected by the RPR sensor 5 as the reactive current changes. In the example shown in FIG. 5, by changing the output current of the inverter 21 from the basic current W1 to the superimposed current W13, when the connection state of the RPR sensor 5 is normal, the current of 0.57 Arms or more by the RPR sensor 5 Changes can be detected.

When the detection current of the RPR sensor 5 becomes equal to or higher than the second threshold value due to the change of the reactive current in step S16, the error condition 3 is not satisfied, so that the control unit 24 ends the connection error determination process. This makes it possible to prevent the above-mentioned erroneous determination of the connection error. On the other hand, when the detection current of the RPR sensor 5 is still less than the second threshold value, the control unit 24 continues to determine whether or not the detection current of the RPR sensor 5 is less than the second threshold value.

In this step S16, the control unit 24 may gradually change (increase or decrease) the reactive current of the output current of the inverter 21 so that the output current of the inverter 21 gradually changes. Alternatively, the control unit 24 may change (increase or decrease) the reactive current of the output current of the inverter 21 at once so that the output current of the inverter 21 changes instantaneously. In either case, the connection state can be determined based on the detection current of the RPR sensor 5.

Further, the control unit 24 may change the reactive current of the output current of the inverter 21 by one cycle. Alternatively, the control unit 24 may intermittently change the reactive current of the output current of the inverter 21 over a plurality of current cycles, or continuously change the reactive current of the output current of the inverter 21 over a plurality of current cycles. You may let me. As a result, the connection error of the RPR sensor 5 can be determined more accurately.

When increasing the reactive current of the output current of the inverter 21, it is necessary to control so as not to exceed the rated output. Further, in the operation of the power system 1, since the reactive current cannot be changed beyond the power factor standard, it is necessary not to exceed the specified amount specified in the grid interconnection regulation or the like. .. If the change in the reactive current alone exceeds the specified amount, the active current may be changed (decreased) as well as the change in the reactive current.

(Effect of Embodiment 2)
As described above, the power conditioner 2 according to the present embodiment is connected to the RPR sensor 5 that detects the reverse power flow or the forward power flow to the power system 10, executes the connection error possibility determination of the RPR sensor 5, and performs the connection error possibility determination. The output invalid current is changed when it is determined that there is a possibility of connection error in the determination of possibility of connection error.

In the above configuration, since the power conditioner 2 changes the output reactive current when it is determined that there is a possibility of a connection error, the connection state of the RPR sensor 5 is surely based on the detection current detected by the RPR sensor 5. It can be determined. Further, the connection error of the RPR sensor 5 can be determined without attaching a separate determination load to the power conditioner 2.

Therefore, the connection state of the RPR sensor 5 can be reliably determined without increasing the cost.

In this embodiment, the waveform of the output current of the inverter 21 is changed by changing the reactive current of the output current of the inverter 21. By changing the reactive current of the output current of the inverter 21 in this way, the waveform of the output current of the inverter 21 can be changed without wasting the active power. Therefore, the generated power can be effectively used.

[Embodiment 3]
Other embodiments of the present invention will be described below with reference to FIGS. 6 and 7. For convenience of explanation, the same reference numerals are given to the members having the same functions as those described in the above-described embodiment, and the description thereof will not be repeated.

(Connection error judgment processing)
FIG. 6 is a flowchart showing an example of the connection error determination process according to the present embodiment. The connection error determination process according to the present embodiment is different from the first embodiment in which the active current is changed and the second embodiment in which the reactive current is changed in that the control unit 24 injects a current strain into the output current of the inverter 21. It's different.

Since the contents of steps S1 to S5 and S7 to S8 are the same as those in the above embodiment, the description thereof will be omitted.

As shown in FIG. 6, in the present embodiment, when it is determined in S5 that the second predetermined period has elapsed, the control unit 24 positively injects current distortion into the output current of the inverter 21 in step S26. , Change the output current distortion.

FIG. 7 is a graph showing an example of a waveform change of the output current of the inverter 21. W1 is the basic current which is the output current of the inverter 21 before injecting the current distortion, W12 is the current distortion to be injected, W23 is the superimposed current which is the output current of the inverter 21 after injecting the current distortion W22, and W4 is the power system. The system voltage of 10 is shown.

In step S26, the control unit 24 positively injects current distortion into the output current of the inverter 21, so that the output current (output waveform) of the inverter 21 changes from the basic current W1 to the superimposed current W23 as shown in FIG. do. At this time, the control unit 24 maintains the output power of the inverter 21 to be equal to or higher than the first threshold value (1000 W) so that the detected current of the RPR sensor 5 is at least instantaneously equal to or higher than the second threshold value (0.57 Arms). , Inject current distortion into the output current of the inverter 21. As a result, when the connection state of the RPR sensor 5 is normal, the detection current of the second threshold value or more is detected by the RPR sensor 5 with the injection of the current strain. In the example shown in FIG. 7, by changing the output current of the inverter 21 from the basic current W1 to the superimposed current W23, when the connection state of the RPR sensor 5 is normal, the current of 0.57 Arms or more by the RPR sensor 5 Changes can be detected.

When the detection current of the RPR sensor 5 becomes equal to or higher than the second threshold value due to the injection of the current strain in step S16, the error condition 3 is not satisfied, so that the control unit 24 ends the connection error determination process. This makes it possible to prevent the above-mentioned erroneous determination of the connection error. On the other hand, when the detection current of the RPR sensor 5 is still less than the second threshold value, the control unit 24 continues to determine whether or not the detection current of the RPR sensor 5 is less than the second threshold value.

In this step S26, the control unit 24 may gradually inject current distortion into the output current of the inverter 21 so that the output current of the inverter 21 gradually changes. Alternatively, the control unit 24 may inject a current distortion into the output current of the inverter 21 at once so that the output current of the inverter 21 changes instantaneously. In either case, the connection state can be determined based on the detection current of the RPR sensor 5.

Further, the control unit 24 may inject a current strain into the output current of the inverter 21 for only one cycle. Alternatively, the control unit 24 may intermittently inject current strain into the output current of the inverter 21 over a plurality of current cycles, or continuously inject current strain into the output current of the inverter 21 over a plurality of current cycles. You may. As a result, the connection error of the RPR sensor 5 can be determined more accurately.

When injecting current distortion into the output current of the inverter 21, it is necessary to control the output so as not to exceed the rated output. Further, in the operation of the power system 1, it is not possible to inject the current strain in excess of the reference amount. Therefore, it is necessary not to exceed the standard amount specified in the grid interconnection regulations.

(Effect of Embodiment 3)
As described above, the power conditioner 2 according to the present embodiment is connected to the RPR sensor 5 that detects the reverse power flow or the forward power flow to the power system 10, executes the connection error possibility determination of the RPR sensor 5, and performs the connection error possibility determination. The output current distortion is changed when it is determined that there is a possibility of connection error in the determination of possibility of connection error.

In the above configuration, since the power conditioner 2 changes the output current distortion when it is determined that there is a possibility of a connection error, the connection state of the RPR sensor 5 is surely based on the detection current detected by the RPR sensor 5. It can be determined. Further, the connection error of the RPR sensor 5 can be determined without attaching a separate determination load to the power conditioner 2.

Therefore, the connection state of the RPR sensor 5 can be reliably determined without increasing the cost.

In this embodiment, the waveform of the output current of the inverter 21 is changed by injecting a current distortion into the output current of the inverter 21. By injecting the current distortion into the output current of the inverter 21 in this way, the waveform of the output current of the inverter 21 can be changed without wasting the active power. Further, since the active power or the active power is not changed, the output in the operation mode requested by the user can be continued. Furthermore, since the magnitude of the peak value of the output current of the inverter 21 does not change, the active power is reduced so as not to exceed the specified amount specified in the grid interconnection regulation, etc., as in the case of changing the reactive power. There is no need to let it. Therefore, the generated power can be effectively used.

Further, as another embodiment, two or three of active current, reactive current, and current distortion may be changed in a complex manner.

〔summary〕
The power conditioner according to the first aspect of the present invention is connected to a current sensor that detects reverse power flow or forward power flow to the power system, executes a connection error possibility determination of the current sensor, and in the connection error possibility determination. The output effective current is changed when it is determined that there is a possibility of a connection error.

In the above configuration, the power conditioner changes the output active current when it is determined that there is a possibility of a connection error. Therefore, the connection state of the current sensor is reliably determined based on the detected current detected by the current sensor. Can be done. Further, the connection error of the current sensor can be determined without attaching a separate determination load to the power conditioner. Therefore, according to the above configuration, it is possible to realize a power conditioner capable of reliably determining the connection state of the current sensor without increasing the cost.

The power conditioner according to the second aspect of the present invention further executes the connection error determination of the current sensor in the above aspect 1, and the condition for determining that there is a connection error in the connection error determination is the detected current value of the current sensor. Alternatively, it may include the case where the state in which the change width of the detected current is less than the first determination threshold value continues for the first predetermined period.

According to the above configuration, the accuracy of the connection error determination can be improved by executing the connection error determination together with the connection error possibility determination.

The power conditioner according to the third aspect of the present invention may change the output effective current in the second aspect so that the change width of the detected current value or the detected current of the current sensor becomes equal to or more than the first determination threshold value. good.

According to the above configuration, when the detected current of the current sensor becomes equal to or higher than the first threshold value due to the change of the output active current, it can be determined that the connection state of the current sensor is normal and there is no connection error.

In the power conditioner according to the fourth aspect of the present invention, in the above aspect 2 or 3, the condition for determining that there is a possibility of the connection error is that the detected current value of the current sensor or the change width of the detected current is less than the second determination threshold value. It may include the case where the state is continued for the second predetermined period.

According to the above configuration, in the connection error determination, if the state in which the detected current value of the current sensor or the change width of the detected current is less than the second determination threshold value continues for the second predetermined period, the connection error of the current sensor may occur. It can be determined that there is.

In the power conditioner according to the fifth aspect of the present invention, the first determination threshold value and the second determination threshold value may be the same value in the fourth aspect.

According to the above configuration, by sharing the determination condition for the connection error possibility determination and the determination condition for the connection error determination, the connection error possibility determination can be suitably executed by being included in the connection error determination.

In the power conditioner according to the sixth aspect of the present invention, in the above aspect 4 or 5, the second predetermined period may be shorter than the first predetermined period.

According to the above configuration, by setting the second predetermined period shorter than the first predetermined period (for example, setting the second predetermined period to a length of about 80% of the first predetermined period), in the connection error determination. , The output effective current can be changed at the timing when the possibility of connection error of the current sensor becomes relatively high.

In any of the above aspects 2 to 6, the power conditioner according to the seventh aspect of the present invention is that the condition for determining that there is a possibility of connection error or the condition for determining that there is a connection error is the output power of the power conditioner. May include being greater than or equal to a predetermined third determination threshold.

According to the above configuration, it is possible to perform more accurate connection error possibility determination or connection error determination in consideration of the output power of the power conditioner.

The power conditioner according to the eighth aspect of the present invention is the power conditioner according to any one of the above aspects 1 to 7, the storage battery electrically connected to the power conditioner, and the power conditioner electrically connected to the power conditioner. Includes a current sensor, which is connected and detects reverse power flow to the power system.

According to the above configuration, it is possible to realize a power system capable of reliably determining the connection state of the current sensor without increasing the cost.

The power system according to the ninth aspect of the present invention is electrically connected to the power conditioner according to any one of the above aspects 1 to 8, a storage battery electrically connected to the power conditioner, and the power conditioner. Includes a current sensor that detects reverse power flow to the power system.

According to the above configuration, it is possible to realize a power system capable of reliably determining the connection state of the current sensor without increasing the cost.

The determination method according to the tenth aspect of the present invention is connected to a current sensor that detects reverse power flow or forward power flow to the power system, executes connection error possibility determination of the current sensor, and connects in the connection error possibility determination. The output effective current is changed when it is determined that there is a possibility of error.

In the above method, since the output effective current is changed when it is determined that there is a possibility of a connection error, the connection state of the current sensor can be reliably determined based on the detected current detected by the current sensor. Further, the connection error of the current sensor can be determined without attaching a separate determination load to the power conditioner. Therefore, according to the above method, it is possible to realize a determination method capable of reliably determining the connection state of the current sensor without increasing the cost.

The present invention is not limited to the above-described embodiments, and various modifications can be made within the scope of the claims, and the embodiments obtained by appropriately combining the technical means disclosed in the different embodiments. Is also included in the technical scope of the present invention. Further, by combining the technical means disclosed in each embodiment, new technical features can be formed.

1 Power system 2 Power conditioner 3 Solar cell (power generation device)
4 Storage battery 5 RPR sensor (current sensor)
10 Power system 21 Inverter W2 Active current W12 Reactive current W22 Current distortion

Claims (10)

Connected to a current sensor that detects reverse power flow or forward power flow to the power system,
A power conditioner that executes the connection error possibility determination of the current sensor and changes the output effective current when it is determined in the connection error possibility determination that there is a connection error possibility. Further, the condition for executing the connection error determination of the current sensor and determining that there is a connection error in the connection error determination is that the detected current value of the current sensor or the change width of the detected current is less than the first determination threshold value. 1 The power conditioner according to claim 1, which includes the case where the current is continued for a predetermined period. The power conditioner according to claim 2, wherein the output effective current is changed so that the detected current value of the current sensor or the change width of the detected current becomes equal to or larger than the first determination threshold value. The condition for determining that there is a possibility of a connection error is claimed, including the case where the state in which the detected current value of the current sensor or the change width of the detected current is less than the second determination threshold value continues for the second predetermined period. Item 2. The power conditioner according to Item 2. The power conditioner according to claim 4, wherein the first determination threshold value and the second determination threshold value are the same values. The power conditioner according to claim 4 or 5, wherein the second predetermined period is shorter than the first predetermined period. The condition for determining that there is a possibility of connection error or the condition for determining that there is a connection error is any one of claims 2 to 6, including that the output power of the power conditioner is equal to or higher than a predetermined third determination threshold value. The power conditioner described in item 1. The power conditioner is connected to a storage battery and
The power conditioner according to any one of claims 1 to 7, wherein the current sensor is an RPR sensor that detects the reverse power flow when the storage battery is discharged. The power conditioner according to any one of claims 1 to 8.
A storage battery electrically connected to the power conditioner and
A current sensor that is electrically connected to the power conditioner and detects reverse power flow to the power system,
Power system including. Connected to a current sensor that detects reverse power flow or forward power flow to the power system,
A determination method for executing the connection error possibility determination of the current sensor and changing the output effective current when it is determined in the connection error possibility determination that there is a connection error possibility.

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