JP2019103162A - Controller, power conversion system and program - Google Patents

Abstract

To reduce the possibility that a converter circuit and an inverter circuit may be erroneously controlled.SOLUTION: A current detection circuit 6 detects an electric current running between a power conversion system 1 and a power system. A control unit 21 controls a converter circuit and an inverter circuit 3 according to a detection current value detected by the current detection circuit 6. A detection section 22 detects the presence/absence of a failure in the current detection circuit 6 according to the detection current value. The detection section 22, when a state in which the detection current value is within a predetermined range continues for a predetermined detection period, detects that a failure exists in the current detection circuit 6.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a control device, a power conversion system, and a program, and more particularly to a control device that controls a converter circuit and an inverter circuit, a power conversion system, and a program.

  The power conversion system of patent document 1 is illustrated as a prior art example. The power conversion system described in Patent Document 1 includes a power conversion device. A power storage unit is connected to the power conversion device. The power conversion device can receive supply of DC power from a power generation device such as a solar cell, for example. The power converter includes a DC-DC converter (converter circuit), a DC-AC converter (inverter circuit), and a control unit. The DC-DC converter charges and discharges the storage unit. The DC-AC converter converts DC power into AC power and outputs the AC power to a distribution line connected to the grid. The control unit controls the DC-DC converter and the DC-AC converter. A current sensor is installed on a distribution line connecting the power conversion device and the grid, and the current sensor detects the value of the current flowing through the distribution line and outputs the value to the control unit.

JP, 2017-135889, A

  However, in the power conversion system described in Patent Document 1, when an abnormality occurs in the circuit (current detection circuit) including the current sensor, the current sensor accurately detects the value of the current flowing through the distribution line connecting the power converter and the grid. If not possible, the control unit may control the DC-DC converter and the DC-AC converter in accordance with the detected current value of the current sensor. As a result, there is a possibility that the DC-DC converter and the DC-AC converter may be erroneously controlled.

  An object of the present invention is to provide a control device, a power conversion system, and a program capable of reducing the possibility of erroneous control of a converter circuit and an inverter circuit.

  In order to solve the above-mentioned subject, a control device concerning one mode of the present invention is provided in a power conversion system. The power conversion system includes an intermediate bus, a converter circuit, an inverter circuit, and a current detection circuit. The intermediate bus is connected to a distributed power supply and DC power is supplied from the distributed power supply. The converter circuit is connected to a storage battery and the intermediate bus. The converter circuit performs a charging operation and a discharging operation. The converter circuit outputs DC power from the intermediate bus to the storage battery in the charging operation. The converter circuit outputs DC power from the storage battery to the intermediate bus in the discharging operation. The inverter circuit is connected to a load and a power system. The inverter circuit is connected to the converter circuit and the distributed power supply via the intermediate bus. The inverter circuit converts DC power from the intermediate bus into AC power and outputs the AC power to the load or the power system. The current detection circuit detects a current flowing between the power conversion system and the power system. The control device includes a control unit and a detection unit. The control unit controls the converter circuit and the inverter circuit in accordance with a detected current value detected by the current detection circuit. The detection unit detects the presence or absence of abnormality of the current detection circuit according to the detected current value. The detection unit detects that there is an abnormality in the current detection circuit when a state in which the detected current value is within a predetermined range continues for a predetermined detection time.

  A power conversion system according to an aspect of the present invention includes the control device and the inverter circuit.

  A program according to an aspect of the present invention causes a computer to function as a control device included in a power conversion system. The power conversion system includes an intermediate bus, a converter circuit, an inverter circuit, and a current detection circuit. The intermediate bus is connected to a distributed power supply and DC power is supplied from the distributed power supply. The converter circuit is connected to a storage battery and the intermediate bus. The converter circuit performs a charging operation and a discharging operation. The converter circuit outputs DC power from the intermediate bus to the storage battery in the charging operation. The converter circuit outputs DC power from the storage battery to the intermediate bus in the discharging operation. The inverter circuit is connected to a load and a power system. The inverter circuit is connected to the converter circuit and the distributed power supply via the intermediate bus. The inverter circuit converts DC power from the intermediate bus into AC power and outputs the AC power to the load or the power system. The current detection circuit detects a current flowing between the power conversion system and the power system. The control device controls the converter circuit and the inverter circuit in accordance with a detected current value detected by the current detection circuit. The control device detects the presence or absence of abnormality of the current detection circuit according to the detected current value. The control device detects that there is an abnormality in the current detection circuit when the state in which the detected current value is within the predetermined range continues for a predetermined detection time.

  According to the control device, the power conversion system, and the program according to one aspect of the present invention, the possibility that the converter circuit and the inverter circuit are erroneously controlled can be reduced.

FIG. 1 is a block diagram of a power conversion system according to an embodiment. FIG. 2 is a flow chart showing the operation of the above power conversion system. FIG. 3 is a flowchart showing the operation of the above power conversion system. FIG. 4 is a diagram showing a first example of temporal changes in detection current value of the current detection circuit and output power of the storage battery in the power conversion system of the same. FIG. 5 is a diagram showing a second example of temporal changes in detection current value of the current detection circuit and output power of the storage battery in the power conversion system of the same.

  Hereinafter, the control device, the power conversion system, and the program according to the embodiment will be described using the drawings. However, the embodiments described below are only some of the various embodiments of the present disclosure. The following embodiments can be variously modified according to the design and the like as long as the object of the present disclosure can be achieved.

  Note that FIG. 1 is a diagram showing the power conversion system 1 in a simplified manner, and the actual circuit configuration of the power conversion system 1 is not necessarily exactly shown.

(1) Overview The power conversion system 1 of the present embodiment is used in each customer such as each dwelling unit of an apartment house, a detached house, a factory, an office, and the like.

  As shown in FIG. 1, the power conversion system 1 includes a control device 2, an inverter circuit 3, a first converter circuit 4 (converter circuit), an intermediate bus W 1, and a current detection circuit 6. The power conversion system 1 further includes a second converter circuit 5.

  The power conversion system 1 is connected to a distributed power supply PV1 including a solar cell, a storage battery SB1, a plurality of (two in FIG. 1) loads 71 and 72, and a power system. The power system and the power conversion system 1 are connected to each other in a single-phase three-wire electric path W2. The storage battery SB1 is charged by being supplied with power from the system power supply PS1 of the power system and the distributed power supply PV1. The plurality of loads 71 and 72 are, for example, electrical devices. Electric power is supplied to the plurality of loads 71 and 72 from the system power supply PS1 of the electric power system and the inverter circuit 3. In the power system, power may reversely flow from the inverter circuit 3. The inverter circuit 3 and the first converter circuit prevent the power corresponding to the current larger than the predetermined current value Ic1 (see FIG. 4) from flowing back from the inverter circuit 3 to the power system when the storage battery SB1 is discharging. 4 is controlled by the controller 2.

(2) Details of Configuration The intermediate bus W1 is connected to the distributed power supply PV1 via the second converter circuit 5. Further, the intermediate bus W1 is connected to the first converter circuit 4 and the inverter circuit 3. That is, the intermediate bus W1 mutually connects the distributed power supply PV1, the first converter circuit 4 and the inverter circuit 3.

  The first converter circuit 4 is connected to the storage battery SB1 in addition to the intermediate bus W1. The first converter circuit 4 is a bidirectional DC / DC converter circuit.

  Storage battery SB1 is charged by receiving the supply of DC power from first converter circuit 4. In addition, storage battery SB1 outputs the stored electric power to first converter circuit 4 as direct current power.

  The first converter circuit 4 performs a charging operation and a discharging operation. In the charging operation, first converter circuit 4 converts (for example, step-up or step-down) DC power from intermediate bus W1 and outputs it to storage battery SB1. In the discharging operation, first converter circuit 4 converts (for example, step-up or step-down) DC power from storage battery SB1 and outputs it to intermediate bus W1. The first converter circuit 4 stops when neither the charging operation nor the discharging operation is performed.

  The distributed power supply PV1 outputs DC power generated by power generation to the second converter circuit 5.

  The second converter circuit 5 converts (for example, step-up or step-down) DC power from the distributed power supply PV1 and outputs it to the intermediate bus W1. That is, DC power from the distributed power supply PV1 is supplied to the intermediate bus W1 via the second converter circuit 5.

  The inverter circuit 3 is connected to the first converter circuit 4 and the distributed power supply PV1 via the intermediate bus W1. The inverter circuit 3 is also connected to the plurality of loads 71 and 72 and the power system.

  The inverter circuit 3 is a bidirectional DC / AC inverter circuit. The inverter circuit 3 converts DC power from the intermediate bus W1 into AC power and outputs the AC power to the plurality of loads 71, 72 or the power system. More specifically, the inverter circuit 3 converts DC power output from the dispersed power source PV1 and the storage battery SB1 and supplied via the intermediate bus W1 into AC power and converts the DC power into a plurality of loads 71, 72 or a power system. Output. Furthermore, inverter circuit 3 converts AC power from the power system (system power supply PS1) into DC power and outputs the DC power to storage battery SB1.

  In this specification, a single-phase three-wire electric path of a power system and a single-phase three-wire electric path of the power conversion system 1 are combined to form an electric path W2. The single-phase three-wire electric path of the power system is connected to the single-phase three-wire electric path of the power conversion system 1. That is, the power system and the power conversion system 1 are connected to each other in the single-phase three-wire electric path W2. The single-phase three-wire type electric path W2 includes an L1-phase wire W21, an L2-phase wire W22, and an N-phase wire W23. The N-phase wire W23 is a neutral wire and is grounded. A current flows in the L1 phase wiring W21 and the L2 phase wiring W22. The voltage between the wiring W21 in the L1 phase and the wiring W23 in the N phase and the voltage between the wiring W22 in the L2 phase and the wiring W23 in the N phase are 100V.

  The power conversion system 1 further includes two capacitors C1 and C2. In the power conversion system 1, the load 71 and the capacitor C1 are connected in parallel between the wiring W21 of the L1 phase and the wiring W23 of the N phase. In the power conversion system 1, the load 72 and the capacitor C2 are connected in parallel between the wiring W22 of L2 phase and the wiring W23 of N phase. The inverter circuit 3 is connected to the wiring W21 of the L1 phase and the wiring W22 of the L2 phase.

  The current detection circuit 6 includes a first current sensor CT1 and a second current sensor CT2. Each of the first current sensor CT1 and the second current sensor CT2 is, for example, a current transformer. In the power conversion system 1, the wire W <b> 21 of the L1 phase is passed through the first current sensor CT <b> 1. In the power conversion system 1, the wire W <b> 22 of the L2 phase is passed through the second current sensor CT <b> 2. The first current sensor CT1 detects the current flowing through the wire W21 of the L1 phase. The second current sensor CT2 detects the current flowing through the wire W22 of the L2 phase. Thus, the current detection circuit 6 detects the current flowing between the power conversion system 1 and the power system.

  The current detection circuit 6 further includes wires W31 and W32. The first current sensor CT1 is connected to the control device 2 via the wire W31. The second current sensor CT2 is connected to the control device 2 via the wire W32. The current detection circuit 6 further includes a circuit connected to the wiring W31 and the wiring W32 among the circuits inside the control device 2.

  The current detection circuit 6 outputs the detected current value to the first control unit 211 and the detection unit 22 of the control device 2. The detected current value detected by the current detection circuit 6 includes the first detected current value I1 (see FIG. 4) detected by the first current sensor CT1 and the second detected current value I2 detected by the second current sensor CT2 (see FIG. 4). The first and second detection current values I1 and I2 are, for example, effective values of the current flowing through the wires W21 and W22.

  The current detection circuit 6 detects the current flowing from the power conversion system 1 to the power system and the current flowing from the power system to the power conversion system 1 as currents having different polarities. That is, the current detection circuit 6 detects the magnitude (effective value) and the direction of the current flowing through the wires W21 and W22. In the following description, when current flows from the power conversion system 1 to the power system, the first and second detection current values I1 and I2 are represented by positive numbers, and current flows from the power system to the power conversion system 1 The first and second detection current values I1 and I2 are represented by negative numbers.

  The control device 2 includes a control unit 21 and a detection unit 22. The control device 2 further includes a notification unit 23. The control unit 21 includes a first control unit 211 and a second control unit 212.

  The execution subject of the control device 2 in the present disclosure includes a computer system. The computer system has a computer. The computer system mainly includes a processor and memory as hardware. The processor executes the program stored in the memory of the computer system to implement a function as an execution subject of the control device 2 in the present disclosure. The program may be pre-recorded in the memory of the computer system, but may be provided through a telecommunication line, or may be a non-transitory memory card, optical disk, hard disk drive (magnetic disk), etc. readable by the computer system. May be provided by being recorded on a physical recording medium. A processor of a computer system is configured of one or more electronic circuits including a semiconductor integrated circuit (IC) or a large scale integrated circuit (LSI). The plurality of electronic circuits may be integrated into one chip or may be distributed to a plurality of chips. The plurality of chips may be integrated into one device or may be distributed to a plurality of devices. The computer system may have a plurality of computers.

  In the control device 2, functions as the first control unit 211 and the second control unit 212 are realized by a single configuration (for example, a single processor). The control unit 21 (a first control unit 211 and a second control unit 212) outputs control signals to switching elements included in each of the first converter circuit 4, the second converter circuit 5, and the inverter circuit 3, for example, The switching element is driven. Thus, the control unit 21 controls the first converter circuit 4, the second converter circuit 5, and the inverter circuit 3. The control unit 21 can operate the first converter circuit 4 to stop the second converter circuit 5 or can stop the first converter circuit 4 to operate the second converter circuit 5.

  The first control unit 211 controls the first converter circuit 4, the second converter circuit 5, and the inverter circuit 3 according to the detected current values (the first detected current value I1 and the second detected current value I2) detected by the current detection circuit 6. Control.

  More specifically, the first control unit 211 causes the first converter circuit 4 to perform the charging operation and the discharging operation according to the detected current value. When the sum of the first and second detection current values I1 and I2 exceeds a predetermined current value Ic1 (see FIG. 4), the first control unit 211 performs the charging operation and the discharging operation of the first converter circuit 4. Of these, only the charging operation can be performed. That is, at this time, the first converter circuit 4 can perform the charging operation according to the control of the control unit 21 or can perform neither the charging operation nor the discharging operation. The predetermined current value Ic1 is, for example, 2.75A. When the upper limit value of reverse flow power flowing from power conversion system 1 to power system at the time of discharge of storage battery SB1 is determined by the regulation of the law etc., predetermined flow value Ic1 does not exceed the upper limit value of reverse flow power. Value is determined.

  Further, the first control unit 211 controls the first converter circuit 4, the second converter circuit 5, and the inverter circuit 3 according to the detected current value, and outputs the load 71, 72 or the power system from the inverter circuit 3 to the plurality of loads. Power is changed. For example, as the first and second detection current values I1 and I2 decrease, the first control unit 211 increases the power output from the inverter circuit 3 to the plurality of loads 71 and 72 or the power system.

  The detection unit 22 detects the presence or absence of abnormality of the current detection circuit 6 according to the detected current value detected by the current detection circuit 6. Specifically, the detection unit 22 detects that the detected current value (at least one of the first and second detected current values I1 and I2) is within a predetermined range RA1 (see FIG. 4) for a predetermined detection time T1 (see FIG. 4). 4) If continuing, it detects that there is an abnormality in the current detection circuit 6. The detection unit 22 detects the presence or absence of an abnormality in the current detection circuit 6 when the first converter circuit 4 is performing the charging operation and when performing the discharging operation. The abnormality of the current detection circuit 6 is, for example, an abnormality such as disconnection or deterioration of the wiring of the current detection circuit 6, or adhesion of foreign matter to the wiring of the current detection circuit 6, and the resistance value of the wiring of the current detection circuit 6 increases. It is abnormal such as The details of how the detection unit 22 detects the presence or absence of an abnormality in the current detection circuit 6 will be described later.

  The second control unit 212 controls the first converter circuit 4, the second converter circuit 5, and the inverter circuit 3 according to the detection result of the detection unit 22.

  More specifically, the second control unit 212 causes the first converter circuit 4 to perform the charging operation and the discharging operation according to the detection result of the detection unit 22. When the detection unit 22 detects that there is an abnormality in the current detection circuit 6, the second control unit 212 allows the first converter circuit 4 to perform only the charging operation among the charging operation and the discharging operation. That is, at this time, the first converter circuit 4 can perform the charging operation according to the control of the control unit 21 or can perform neither the charging operation nor the discharging operation. In addition, when the state in which the detection unit 22 detects that there is an abnormality in the current detection circuit 6 continues for a predetermined time T2 (see FIG. 3), the second control unit 212 controls the first converter circuit 4 and the second converter circuit. 5 and the inverter circuit 3 are stopped. At this time, the notification unit 23 notifies the occurrence of an error. The notification unit 23 includes, for example, a display, and displays information indicating that an error has occurred on the display. Details of control by the second control unit 212 will be described later.

  Further, the control unit 21 sets a discharge upper limit value (unit: watt) in accordance with a user operation on the control device 2 and a detection result of the detection unit 22. The first converter circuit 4 is controlled by the control unit 21 so that the storage battery SB1 does not output the output power larger than the discharge upper limit value to the first converter circuit 4. For example, when the first converter circuit 4 performs a discharging operation under the control of the control unit 21 when the power consumption of the plurality of loads 71 and 72 connected to the electric path W2 is larger than the predetermined power consumption, etc., the storage battery SB1 Outputs an output power equal to the discharge upper limit value to the first converter circuit 4. When the first converter circuit 4 performs a discharging operation under the control of the control unit 21 when the power consumption of the plurality of loads 71 and 72 connected to the electric path W2 is smaller than the predetermined power consumption, the storage battery SB1 Output power smaller than the discharge upper limit value is output to the first converter circuit 4.

  When the charge level of the storage battery SB1 falls below a predetermined level, the first converter circuit 4 performs a charging operation under the control of the control unit 21. In practice, the control device 2 acquires information indicating the output voltage of the storage battery SB1 from the storage battery SB1, and when the output voltage of the storage battery SB1 becomes lower than a predetermined voltage corresponding to a predetermined level, the controller 21 controls the first converter The circuit 4 is caused to perform a charging operation.

  The predetermined time T2 (see FIG. 3) is longer than the time required for the storage battery SB1 to self-discharge from the fully charged state and to have the charge level equal to or lower than the predetermined level. That is, before the state where the first converter circuit 4 does not perform the charging operation continues for the predetermined time T2, the charge level of the storage battery SB1 becomes equal to or less than the predetermined level.

  The control device 2 further includes a counter 24, a timer 25, and a presentation unit 26.

  The counter 24 counts the number of times the detection unit 22 detects that there is an abnormality in the current detection circuit 6 (hereinafter referred to as the number of times of abnormality detection).

  The timer 25 starts measuring time when the detection unit 22 detects that there is an abnormality in the current detection circuit 6. The timer 25 measures an elapsed time (hereinafter referred to as a measurement time) after the detection unit 22 detects that there is an abnormality in the current detection circuit 6. As the detection unit 22 measures the measurement time by the timer 25, whether the detection unit 22 detects that there is an abnormality in the current detection circuit 6 continues for a predetermined time T2 (see FIG. 3). It can be detected.

  When the state where the detection unit 22 detects that there is an abnormality in the current detection circuit 6 continues, the control device 2 subtracts the measurement time during measurement of the timer 25 from the predetermined time T2 (see FIG. 3). The calculated value is presented to the presenting unit 26. That is, the presentation unit 26 presents information indicating the length of time between the current time and the time when the measurement time reaches the predetermined time T2 (hereinafter, referred to as the remaining time). The presentation unit 26 includes, for example, a display, and displays the remaining time on the display.

(3) Operation Flow of Power Conversion System Next, the operation flow of the power conversion system 1 will be described with reference to FIGS.

  When the power switch of the power conversion system 1 is turned on (step S1), the control device 2 resets the discharge upper limit value, the counter 24 and the timer 25 (step S2). That is, the control device 2 sets the discharge upper limit value to 3000 W, sets the number of abnormality detections counted by the counter 24 to zero, and sets the measurement time measured by the timer 25 to zero.

  Next, the detection unit 22 detects an abnormality in the current detection circuit 6 according to the first detection current value I1 detected by the first current sensor CT1 and the second detection current value I2 detected by the second current sensor CT2. The presence or absence is detected (step S3). More specifically, the detection unit 22 detects the state in which at least one of the first detection current value I1 and the second detection current value I2 is within a predetermined range RA1 (see FIG. 4) for a predetermined detection time T1 (for example, 2). Second, when continuing, it detects that there is an abnormality in the current detection circuit 6. When at least one of the first detection current value I1 and the second detection current value I2 does not continue the state in the predetermined range RA1 for the predetermined detection time T1, the detection unit 22 indicates that the current detection circuit 6 is not abnormal. Detect The predetermined range RA1 is, for example, a range of -0.15 A or more and +0.15 A or less. That is, when the absolute value of at least one of the first detection current value I1 and the second detection current value I2 continues the state of the predetermined value (0.15 A) or less continues for a predetermined detection time T1, It detects that there is an abnormality in the current detection circuit 6.

  The center of the predetermined range RA1 coincides with 0. This is because the first and second detection current values I1 and I2 may have values close to 0 if there is an abnormality such as a break in the current detection circuit 6, and in such a case, the current detection circuit 6 This is to enable the detection unit 22 to detect that there is an abnormality.

  In step S3, when the detection unit 22 detects that there is no abnormality in the current detection circuit 6 (step S3: No), the detection unit 22 returns to step S3 through step S12 described later, and the abnormality of the current detection circuit 6 Repeat the detection of the presence or absence of

  When the detection unit 22 detects that there is an abnormality in the current detection circuit 6 in step S3 (step S3: Yes), the control unit 21 gradually decreases the discharge upper limit value in step S4. Then, under the control of control unit 21, first converter circuit 4 gradually reduces the DC power output from storage battery SB1 to first converter circuit 4 (hereinafter referred to as output power BO1 of storage battery SB1: see FIG. 4) Let More specifically, the discharge upper limit value and the output power BO1 of the storage battery SB1 decrease in proportion to time and finally become 0 W. By setting the discharge upper limit value to 0 W, the first converter circuit 4 can perform only the charging operation among the charging operation and the discharging operation.

  Further, in step S4, the control device 2 adds 1 to the number of times of abnormality detection. Furthermore, in step S4, the timer 25 starts measuring the measurement time.

  Next, the detection unit 22 detects whether the current detection circuit 6 continues to have an abnormality (step S5). That is, if at least one of the first detection current value I1 and the second detection current value I2 is within the predetermined range RA1, the detection unit 22 continues that the current detection circuit 6 continues to be in the abnormal state. Detect Whether the first detection current value I1 and the second detection current value I2 deviate from the predetermined range RA1 (step S5: No) or the detection unit 22 detects that there is an abnormality in the current detection circuit 6 for a predetermined time The detection unit 22 continues to detect whether the current detection circuit 6 continues to have an abnormality until T2 (for example, 20 days) continues (until the result of Step S6 is “No”). That is, in the power conversion system 1, steps S5 and S6 are repeated. Furthermore, in steps S5 and S6, the presentation unit 26 presents information indicating the remaining time. That is, the presentation unit 26 presents information indicating the remaining time until the remaining time becomes 0 while the detection unit 22 continues detecting that there is an abnormality in the current detection circuit 6 for a predetermined time T2. .

  If the state in which the detection unit 22 detects that there is an abnormality in the current detection circuit 6 continues for a predetermined time T2 (step S6: No), the second control unit 212 controls the first converter circuit 4 and the second converter circuit 5 And the inverter circuit 3 is stopped, and the notification unit 23 notifies the occurrence of an error (step S7).

  After the first converter circuit 4, the second converter circuit 5, and the inverter circuit 3 are stopped, the first detection current value I1 and the second detection current value I2 both deviate from the prescribed range RA2 (see FIG. 4). When the specified detection time T3 (for example, 5 seconds) is continued (step S8: Yes), the detection unit 22 detects that there is no abnormality in the current detection circuit 6. The prescribed range RA2 is, for example, a range of -0.3 A or more and +0.3 A or less. That is, when the detection unit 22 continues the state in which the absolute value of the first detection current value I1 and the absolute value of the second detection current value I2 are larger than the predetermined value (0.3 A), the predetermined detection time T3 continues. It detects that there is no abnormality in the current detection circuit 6.

  The center of the prescribed range RA2 coincides with 0. The upper limit UP2 of the prescribed range RA2 is larger than the upper limit UP1 of the prescribed range RA1, and the lower limit LO2 of the prescribed range RA2 is smaller than the lower limit LO1 of the prescribed range RA1 (see FIG. 4).

  If the detection unit 22 detects that there is no abnormality in the current detection circuit 6 (step S8: Yes), the control device 2 sets the discharge upper limit value to 3000 W, sets the number of abnormality detections to 0, and the measurement time to 0 in step S2. Make it When the discharge upper limit value becomes a value larger than 0 W, the first converter circuit 4 can perform the discharge operation under the control of the control unit 21.

  The first detection current value I1 and the second detection current value I2 are before the elapsed time from when the detection unit 22 detects that there is an abnormality in the current detection circuit 6 reaches the predetermined time T2. When it deviates from the predetermined range RA1 (step S5: No), the control device 2 compares the number of times of abnormality detection with a predetermined number (four times) (step S9). If the number of times of abnormality detection is less than the predetermined number of times (four times) (step S9: Yes), the detection unit 22 detects that there is no abnormality in the current detection circuit 6. Further, the control device 2 gradually increases the discharge upper limit value to 3000 W, sets the number of abnormality detections to 0, sets the measurement time to 0, and the timer 25 stops measuring the measurement time (step S10). When the discharge upper limit value becomes a value larger than 0 W, the first converter circuit 4 can perform the discharge operation under the control of the control unit 21. Thereafter, the process returns to step S3, and the detection unit 22 detects the presence or absence of abnormality of the current detection circuit 6 according to the first and second detection current values I1 and I2.

  In step S9, when the number of times of abnormality detection is a predetermined number of times (four times) or more (step S9: No), the detection unit 22 performs the first detection current value I1 and the second detection current value I2 under the same conditions as step S8. Is detected within the prescribed range RA2 (step S11). If the first detection current value I1 and the second detection current value I2 both deviate from the prescribed range RA2 continue for the prescribed detection time T3 (step S11: Yes), the controller 2 discharges in step S2 The upper limit is gradually increased from 0 W to 3000 W, the number of abnormality detections is 0, the measurement time is 0, and the timer 25 stops measuring the measurement time.

  That is, before the state in which the detection unit 22 detects that there is an abnormality in the current detection circuit 6 continues for a predetermined time T2 (in other words, before the result of step S6 is "No"), When the detection current value I1 and the second detection current value I2 both deviate from the prescribed range RA2 continue the prescribed detection time T3, the detection unit 22 detects that there is no abnormality in the current detection circuit 6.

  In step S11, when the state in which both the first detection current value I1 and the second detection current value I2 deviate from the prescribed range RA2 does not continue for the prescribed detection time T3 (step S11: No), the process proceeds to step S5. Returning, the detection unit 22 continues to detect the presence or absence of an abnormality in the current detection circuit 6. In this case, since the discharge upper limit value remains 0 W, the control unit 21 maintains a state in which the first converter circuit 4 can perform only the charging operation among the charging operation and the discharging operation. Further, in this case, the timer 25 continues the measurement of the measurement time before the detection unit 22 detects that there is no abnormality in the current detection circuit 6 in step S5 (step S5: No).

  By the way, when the detection unit 22 detects that there is no abnormality in the current detection circuit 6 according to the first and second detection current values I1 and I2 in step S3 (step S3: No), the detection unit 22 It is detected whether or not the (1) detected current value I1 and the second detected current value I2 are within the prescribed range RA2 (step S12). When the first detection current value I1 and the second detection current value I2 both deviate from the prescribed range RA2 continue the prescribed detection time T3 (step S12: Yes), the control device 2 determines the number of times of abnormality detection. It is set to 0 (step S13).

  When the power conversion system 1 is restarted by a user operation or the like, the control device 2 resumes the operation from step S1.

(4) Temporal Change of Output Power of Storage Battery Hereinafter, an example of temporal change of output power BO1 of storage battery SB1 when the first detection current value I1 and the second detection current value I2 change over time This will be described with reference to the graphs of FIGS. 4 and 5, the horizontal axis represents time, and the vertical axis represents the first and second detection current values I1 and I2 and the output power BO1 of the storage battery SB1. In order to simplify the description, it is assumed that the first and second detection current values I1 and I2 are equal to each other. Further, in each of FIGS. 4 and 5, at each time point, the sum of the first and second detection current values I1 and I2 is equal to or less than a predetermined current value Ic1. Further, in FIGS. 4 and 5, it is assumed that the first converter circuit 4 does not perform the charging operation at each time point.

(4.1) First Example First, with reference to FIG. 4, an example of a temporal change in output power BO1 of the storage battery SB1 will be described.

  At time t0, the detection unit 22 detects the presence or absence of an abnormality in the current detection circuit 6 in step S3 (see FIG. 2). At time t0, the first and second detection current values I1 and I2 are larger than the upper limit UP2 of the prescribed range RA2. That is, the first and second detection current values I1 and I2 are out of the defined range RA2.

  At time t1, the first and second detection current values I1 and I2 decrease, and the first and second detection current values I1 and I2 fall within the predetermined range RA1. When the state of the first and second detection current values I1 and I2 within the predetermined range RA1 continues for a predetermined detection time T1 (at time t2), the detection unit 22 detects that the current detection circuit 6 has an abnormality. Therefore, in step S4 (see FIG. 2), the control device 2 gradually reduces the discharge limit value to 0 W, adds 1 to the number of times of abnormality detection, and the timer 25 starts measuring the measurement time. As the discharge limit value gradually decreases from time t2 to time t3, the output power BO1 of the storage battery SB1 gradually decreases. At time t3, the discharge upper limit value becomes 0 W, and the output power BO1 of the storage battery SB1 becomes 0 W. As a result, the first converter circuit 4 can not perform the discharging operation.

  In the first example, the first and second detection current values I1 and I2 decrease at time t1 due to the abnormality of the current detection circuit 6. Due to the abnormality of the current detection circuit 6, after the time point t1, the current detection circuit 6 can not normally detect the current flowing in the electric path W2. Therefore, even if the output power BO1 of the storage battery SB1 decreases between time t2 and time t3, the first and second detection current values I1 and I2 remain within the predetermined range RA1. That is, after time t1, the state in which the detection unit 22 detects that there is an abnormality in the current detection circuit 6 is maintained. As a result, after time t3, the first converter circuit 4 can not perform the discharging operation, and the output power BO1 of the storage battery SB1 remains at 0 W.

(4.2) Second Example Next, another example of the temporal change of the output power BO1 of the storage battery SB1 will be described with reference to FIG. The temporal changes of the first and second detection current values I1 and I2 and the output power BO1 of the storage battery SB1 from time t0 to time t2 are the same as in the first example shown in FIG.

  After time t2, the controller 21 gradually reduces the discharge upper limit value, whereby the output power BO1 of the storage battery SB1 gradually decreases. In the second example, not the abnormality of the current detection circuit 6 but, for example, the increase in the power consumption of the plurality of loads 71 and 72 connected to the electric path W2 or the decrease in the output of the distributed power supply PV1 At t1, the first and second detection current values I1 and I2 decrease. The current detection circuit 6 can normally detect the current flowing through the electric path W2 also after the time point t1. Therefore, when the output power BO1 of the storage battery SB1 gradually decreases after time t2, the first and second detection current values I1 and I2 also gradually decrease.

  At time t4, the first and second detection current values I1 and I2 become smaller than the lower limit value LO1 of the predetermined range RA1. That is, at time t4, the first and second detection current values I1 and I2 are out of the predetermined range RA1 (Step S5: No). Therefore, for example, in step S10 (see FIG. 3), the control unit 21 gradually increases the discharge upper limit value. Then, control unit 21 causes first converter circuit 4 to start the discharging operation, and output power BO1 of storage battery SB1 gradually increases. As a result, the first and second detection current values I1 and I2 also gradually increase.

  At time t5, the first and second detection current values I1 and I2 exceed the upper limit value UP1 of the predetermined range RA1. That is, the first and second detection current values I1 and I2 are out of the predetermined range RA1. The time interval T4 from time t4 to time t5 is shorter than the predetermined detection time T1. Therefore, although the first and second detection current values I1 and I2 fall within the predetermined range RA1 from time t4 to time t5, the detection unit 22 detects that there is an abnormality in the current detection circuit 6. do not do.

  After time t6, the output power BO1 of the storage battery SB1 changes, for example, substantially constant. After that, when the detection unit 22 detects that there is an abnormality in the current detection circuit 6, the control unit 21 gradually reduces the discharge upper limit value, so the output power BO1 of the storage battery SB1 gradually decreases.

  By the way, from time t4 to time t6, control unit 21 gradually increases the discharge upper limit value to cause first converter circuit 4 to start the discharge operation, and output power BO1 of storage battery SB1 gradually increases. At this time, the rate of increase of the discharge upper limit value is the difference between the upper limit value UP1 and the lower limit value LO1 of the predetermined range RA1 for the direct current output from the storage battery SB1 to the first converter circuit 4 during the predetermined detection time T1. The increase rate is such as to increase by a value larger than (0.3 A). Therefore, control unit 21 controls direct current output from storage battery SB1 to first converter circuit 4 for a predetermined detection time T1 by a value larger than the difference between upper limit value UP1 and lower limit value LO1 of predetermined range RA1. To increase.

  More specifically, the direct current output from storage battery SB1 to first converter circuit 4 increases in proportion to time from time t4 to time t6. Therefore, the amount of increase per one second (unit time) of the direct current output from storage battery SB1 to first converter circuit 4 is the difference (0.3 A) between upper limit value UP1 and lower limit value LO1 of predetermined range RA1. , Which is a value divided by a predetermined detection time T1 (2 seconds), which is larger than 0.15 A / second.

  Further, the absolute value of the decrease rate of the discharge upper limit when the control unit 21 gradually decreases the discharge upper limit is the absolute value of the increase rate of the discharge upper limit when the control unit 21 gradually increases the discharge upper limit. Equal to Therefore, in the graph of FIG. 5, the absolute value of the amount of change per unit time of output power BO1 of storage battery SB1 between time t2 and time t4 is the output of storage battery SB1 between time t4 and time t6. It is equal to the absolute value of the amount of change per unit time of the power BO1.

(Modification of the embodiment)
Below, the modification of embodiment is enumerated. The following modifications may be implemented in combination as appropriate.

  In the embodiment, when the detection unit 22 detects that there is an abnormality in the current detection circuit 6, the first converter circuit 4 can perform only the charging operation among the charging operation and the discharging operation. Thereafter, when the detection unit 22 detects that there is no abnormality in the current detection circuit 6, the control unit 21 controls only the charging operation among the charging operation and the discharging operation of the first converter circuit 4 regardless of the number of abnormality detections. It is possible to maintain the state that can be done. For example, in step S5 (see FIG. 3), when the first detection current value I1 and the second detection current value I2 deviate from the predetermined range RA1 (step S5: No), the control device 2 has a discharge upper limit value of 0 W The measurement state may be maintained, the measurement time may be set to 0, and the timer 25 may stop measuring the measurement time. Thus, the state in which the first converter circuit 4 can not perform the discharging operation is maintained. In this case, when the power conversion system 1 is restarted by the user's operation or the like, the control device 2 sets the discharge upper limit value to 3000 W in step S2, and the first converter circuit 4 can perform the discharge operation.

  Alternatively, when the detection unit 22 detects that there is no abnormality in the current detection circuit 6, the control unit 21 may allow the first converter circuit 4 to perform the discharge operation regardless of the number of times of abnormality detection. For example, when the first detection current value I1 and the second detection current value I2 deviate from the predetermined range RA1 in step S5 (step S5: No), the number of times of abnormality detection is compared with the predetermined number of times (four times). The control device 2 may set the discharge upper limit value to 3000 W in step S10 without passing through step S9 so that the first converter circuit 4 can perform the discharge operation.

  Further, after the measurement time reaches the predetermined time T2 and the first converter circuit 4, the second converter circuit 5, and the inverter circuit 3 are stopped in step S7, the first converter circuit 4, the second converter circuit 5, and the inverter circuit 3 are May stop operation until the power conversion system 1 is restarted. That is, the detection unit 22 may not detect the presence or absence of an abnormality of the current detection circuit 6 in step S8.

  In addition, individual components in power conversion system 1 may be integrated in one housing, or individual components may be distributed in a plurality of housings. For example, the control device 2 and the inverter circuit 3 may be integrated in a first housing, the first converter circuit 4 may be housed in a second housing, and the second converter circuit 5 may be housed in a third housing. . Alternatively, the control device 2, the inverter circuit 3 and the second converter circuit 5 may be integrated in the first housing, and the first converter circuit 4 may be accommodated in the second housing. Alternatively, the control device 2, the inverter circuit 3, the first converter circuit 4 and the second converter circuit 5 may be integrated in one case.

  In addition, the distributed power source PV1 is not limited to a solar cell, and for example, a power generation device using energy of wind power, water power, or biomass may be used. Further, as the dispersed power source PV1, a power generation device provided with an internal combustion engine that burns liquid fuel or gaseous fuel may be used. Alternatively, a fuel cell may be used as the distributed power supply PV1.

  Further, the first current sensor CT1 and the second current sensor CT2 are not limited to current transformers. For example, Hall element type current sensors may be used as the first current sensor CT1 and the second current sensor CT2, respectively.

  Moreover, the inverter circuit 3 is not limited to a bidirectional DC / AC inverter circuit. The inverter circuit 3 may be an inverter circuit that performs only an operation of converting DC power from the intermediate bus W1 into AC power.

  Moreover, in the control device 2, it is not essential that the functions as the first control unit 211 and the second control unit 212 are realized by a single configuration (for example, a single processor). That is, the configuration that implements the function of the first control unit 211 and the configuration that implements the function of the second control unit 212 may be provided separately. Further, the control of the first converter circuit 4, the second converter circuit 5, and the inverter circuit 3 may be separately performed by the first control unit 211 and the second control unit 212.

  Moreover, the presentation part 26 is not limited to the structure which displays remaining time on a display. For example, the presentation unit 26 may include a speaker and may notify the user of the remaining time by the sound output from the speaker. Alternatively, the presentation unit 26 may have a configuration such as a display or a speaker outside the control device 2. At this time, the presentation unit 26 may receive information indicating the remaining time (for example, character data or voice data) from the control device 2 by wired communication or wireless communication, and may output the remaining time as characters or display as voice. .

  The second converter circuit 5 is not an essential component of the power conversion system 1 and may be omitted as appropriate. Alternatively, the second converter circuit 5 may be provided as an external component of the power conversion system 1.

  Moreover, the power conversion system 1 should just be equipped with the control apparatus 2 and the inverter circuit 3 at least. For example, the first converter circuit 4, the intermediate bus W1 and the current detection circuit 6 may be provided as an external configuration of the power conversion system 1.

  The plurality of loads 71 and 72 may be provided as an external configuration of the power conversion system 1 or may be provided as a configuration of the power conversion system 1.

  Also, the load 71 may be a circuit including a plurality of loads connected in series, in parallel, or in series-parallel. Similarly, the load 72 may be a circuit including a plurality of loads connected in series, in parallel or in series-parallel with one another.

  The current detection circuit 6 according to the embodiment includes a circuit connected to the wiring W31 and the wiring W32 among the circuits inside the control device 2. The current detection circuit 6 may include a circuit connected to the wiring W31 or the wiring W32 among the circuits inside the control device 2.

  Also, the detection unit 22 may detect the presence or absence of an abnormality in the current detection circuit 6 only when the first converter circuit 4 is performing a discharge operation.

  The second control unit 212 may stop only the first converter circuit 4 when the state in which the detection unit 22 detects that there is an abnormality in the current detection circuit 6 continues for a predetermined time T2.

  Further, the upper limit UP2 of the prescribed range RA2 of the embodiment is larger than the upper limit UP1 of the prescribed range RA1, and the lower limit LO2 of the prescribed range RA2 is smaller than the lower limit LO1 of the prescribed range RA1. The relationship between the prescribed range RA2 and the prescribed range RA1 is not limited to this, as long as the prescribed range RA2 includes the prescribed range RA1. For example, the upper limit UP2 of the prescribed range RA2 may be equal to the upper limit UP1 of the prescribed range RA1, and the lower limit LO2 of the prescribed range RA2 may be smaller than the lower limit LO1 of the prescribed range RA1. Alternatively, upper limit UP2 of prescribed range RA2 may be larger than upper limit UP1 of prescribed range RA1, and lower limit LO2 of prescribed range RA2 may be equal to lower limit LO1 of prescribed range RA1.

  Further, the center of the predetermined range RA1 and the center of the predetermined range RA2 may not coincide with zero.

  In addition, in steps S2 and S10, the control unit 21 sets the discharge upper limit value to 3000 W, but 3000 W is an example, and may be an appropriate value larger than 0 W. Further, an appropriate value set as the discharge upper limit value in steps S2 and S10 may be set by a user operation on the control device 2.

  Further, the first converter circuit 4 gradually reduces the DC power (output power BO1 of the storage battery SB1) output from the storage battery SB1 to the first converter circuit 4. Here, "slowly" includes decreasing the output power BO1 of the storage battery SB1 stepwise or decreasing in proportion to time. In addition, for the reduction rate of the output power BO1 of the storage battery SB1, for example, the time required for the output power BO1 to decrease from the maximum value to 0 W is preferably 5 seconds or more, and the time is 10 seconds or more It is more preferable that the time is 20 seconds or more.

  The detection unit 22 may separately detect the presence or absence of an abnormality in the circuit including the first current sensor CT1, and detect the presence or absence of an abnormality in the circuit including the second current sensor CT2. . For example, when the state in which the first detection current value I1 is within the predetermined range RA1 continues for the predetermined detection time T1, the detection unit 22 detects that there is an abnormality in the circuit including the first current sensor CT1. Good. Further, when the state in which the second detection current value I2 is within the predetermined range RA1 continues for the predetermined detection time T1, the detection unit 22 detects that there is an abnormality in the circuit including the second current sensor CT2. Good. Further, the current detection circuit 6 may include only one of the first and second current sensors CT1 and CT2.

  Further, the power distribution system of the power conversion system 1 is not limited to the single-phase three-wire system, and may be another power distribution system such as a single-phase two-wire system or a three-phase three-wire system. When the power distribution system of the power conversion system 1 is a single-phase two-wire system, only one of the first and second current sensors CT1 and CT2 may be provided. When the power distribution system of the power conversion system 1 is a three-phase three-wire system, one current sensor may be provided for three wires of three phases. The number of current sensors is not particularly limited.

  In addition, when the detection unit 22 detects that there is an abnormality in the current detection circuit 6, the first converter circuit 4 may not be able to perform only the charging operation among the charging operation and the discharging operation. For example, when the detection unit 22 detects that the current detection circuit 6 has an abnormality, the power conversion system 1 may only notify that the current detection circuit 6 has an abnormality. The power conversion system 1 may notify that there is an abnormality in the current detection circuit 6 by, for example, characters or symbols displayed on a display or voice output from a speaker. Alternatively, the power conversion system 1 may notify that the current detection circuit 6 has an abnormality by turning on, off, or blinking the light source. Alternatively, the power conversion system 1 may output information indicating that there is an abnormality in the current detection circuit 6 to an external configuration of the control device 2 by wired communication or wireless communication.

(Summary)
As described above, the control device 2 according to the first aspect is included in the power conversion system 1. The power conversion system 1 includes an intermediate bus W1, a converter circuit (first converter circuit 4), an inverter circuit 3, and a current detection circuit 6. The intermediate bus W1 is connected to the distributed power supply PV1, and DC power is supplied from the distributed power supply PV1. The converter circuit is connected to storage battery SB1 and intermediate bus W1. The converter circuit performs a charging operation and a discharging operation. The converter circuit outputs DC power from the intermediate bus W1 to the storage battery SB1 in the charging operation. The converter circuit outputs DC power from storage battery SB1 to intermediate bus W1 in the discharging operation. The inverter circuit 3 is connected to the load 71 (or 72) and the power system. The inverter circuit 3 is connected to the converter circuit and the distributed power supply PV1 via the intermediate bus W1. The inverter circuit 3 converts the DC power from the intermediate bus W1 into AC power and outputs the AC power to the load 71 (or 72) or the power system. The current detection circuit 6 detects the current flowing between the power conversion system 1 and the power system. The control device 2 includes a control unit 21 and a detection unit 22. The control unit 21 controls the converter circuit and the inverter circuit 3 in accordance with the detected current value detected by the current detection circuit 6. The detection unit 22 detects the presence or absence of abnormality of the current detection circuit 6 according to the detected current value. When the state where the detected current value is within the predetermined range RA1 continues for a predetermined detection time T1, the detection unit 22 detects that there is an abnormality in the current detection circuit 6.

  According to the above configuration, the current detection circuit 6 detects the current flowing between the power conversion system 1 and the power system. The control unit 21 controls the converter circuit (first converter circuit 4) and the inverter circuit 3 in accordance with the detected current value detected by the current detection circuit 6. When the state where the detected current value is within the predetermined range RA1 continues for a predetermined detection time T1, the detection unit 22 detects that there is an abnormality in the current detection circuit 6. Therefore, when there is an abnormality in the current detection circuit 6 and the detected current value of the current detection circuit 6 is an incorrect value, the control unit 21 controls the converter circuit and the inverter circuit 3 according to the erroneous detected current value. Can reduce the possibility of That is, the possibility that the converter circuit and the inverter circuit 3 are erroneously controlled can be reduced. For example, when there is a current flowing backward to the power system, the possibility that the control unit 21 causes the converter circuit to perform the discharging operation can be reduced.

  Further, in the control device 2 according to the second aspect, in the first aspect, the control unit 21 includes the first control unit 211 and the second control unit 212. The first control unit 211 controls the converter circuit (first converter circuit 4) and the inverter circuit 3 in accordance with the detected current value detected by the current detection circuit 6. The second control unit 212 controls the converter circuit according to the detection result of the detection unit 22. When the detection unit 22 detects that there is an abnormality in the current detection circuit 6, the second control unit 212 gradually reduces the DC power output from the storage battery SB1 to the converter circuit.

  Even when there is no abnormality in the current detection circuit 6, the detection current value detected by the current detection circuit 6 temporarily becomes a value within the predetermined range RA1, and if there is an abnormality in the current detection circuit 6, the detection unit 22 There is a possibility of false detection. According to the above configuration, when the detection unit 22 detects that there is an abnormality in the current detection circuit 6, the second control unit 212 outputs DC power output from the storage battery SB1 to the converter circuit (first converter circuit 4). Decrease gradually. Therefore, for example, before the DC power output from storage battery SB1 to the converter circuit decreases to the lower limit, detection unit 22 detects that there is no abnormality in current detection circuit 6 based on the detected current value, and It becomes possible to recover the DC power output to the converter circuit. That is, it is possible to reduce the possibility that the DC power output from storage battery SB1 to the converter circuit to the lower limit due to the erroneous detection of detection unit 22 can be reduced.

  Further, in the control device 2 according to the third aspect, in the first or second aspect, the control unit 21 includes the first control unit 211 and the second control unit 212. The first control unit 211 controls the converter circuit (first converter circuit 4) and the inverter circuit 3 in accordance with the detected current value detected by the current detection circuit 6. The second control unit 212 controls the converter circuit according to the detection result of the detection unit 22. When the converter circuit starts the discharging operation, at least one of first control unit 211 and second control unit 212 sets the DC current output from storage battery SB1 to the converter circuit to the upper limit value UP1 and the lower limit of predetermined range RA1. The value which is larger than the difference with the value LO1 is increased during the predetermined detection time T1.

  When the converter circuit (first converter circuit 4) performs a discharging operation, the detected current value may increase. According to the above configuration, even if the detected current value before the converter circuit performs the discharging operation is within the predetermined range RA1, the detected current value is the upper limit value of the predetermined range RA1 until the predetermined detection time T1 elapses. It is likely to be larger than UP1. That is, while the detected current value is increasing, the state in which the detected current value is within the predetermined range RA1 continues for the predetermined detection time T1, and the detection unit 22 can detect that the current detection circuit 6 has an abnormality. Is reduced. Therefore, the possibility of continuing the discharge operation is increased.

  Further, in the control device 2 according to the fourth aspect, in any one of the first to third aspects, the control unit 21 includes a first control unit 211 and a second control unit 212. The first control unit 211 controls the converter circuit (first converter circuit 4) and the inverter circuit 3 in accordance with the detected current value detected by the current detection circuit 6. The second control unit 212 controls the converter circuit according to the detection result of the detection unit 22. When the detection unit 22 detects that there is an abnormality in the current detection circuit 6, the second control unit 212 enables the converter circuit to perform only the charging operation out of the charging operation and the discharging operation, and thereafter, detects the current When the detection unit 22 detects that there is no abnormality in the circuit 6, the second control unit 212 maintains a state in which only the charge operation can be performed among the charge operation and the discharge operation in the converter circuit.

  According to the above configuration, the converter circuit (first converter circuit 4) is detected when the detection unit 22 detects that there is an abnormality in the current detection circuit 6, and then detects that there is no abnormality in the current detection circuit 6. Can reliably suppress the discharge operation.

  Further, in the control device 2 according to the fifth aspect, in any one of the first to third aspects, the control unit 21 includes a first control unit 211 and a second control unit 212. The first control unit 211 controls the converter circuit (first converter circuit 4) and the inverter circuit 3 in accordance with the detected current value detected by the current detection circuit 6. The second control unit 212 controls the converter circuit according to the detection result of the detection unit 22. When the detection unit 22 detects that there is an abnormality in the current detection circuit 6, the second control unit 212 enables the converter circuit to perform only the charging operation out of the charging operation and the discharging operation, and thereafter, detects the current When the detection unit 22 detects that there is no abnormality in the circuit 6, the second control unit 212 allows the converter circuit to perform at least the discharging operation of the charging operation and the discharging operation.

  According to the above configuration, the converter circuit (first converter circuit 4) is detected when the detection unit 22 detects that there is an abnormality in the current detection circuit 6, and then detects that there is no abnormality in the current detection circuit 6. Can reliably perform the discharging operation.

  Further, in the control device 2 according to the sixth aspect, in the fifth aspect, the detection unit 22 detects that there is no abnormality in the current detection circuit 6, and detects that there is an abnormality in the current detection circuit 6. If the number of times of detection by 22 is equal to or more than the predetermined number, the second control unit 212 maintains a state in which only the charging operation can be performed among the charging operation and the discharging operation in the converter circuit (first converter circuit 4).

  In the first aspect, there is a possibility that the detection unit 22 erroneously detects that there is an abnormality in the current detection circuit 6 even though there is no abnormality in the current detection circuit 6. In such a case, when the detection unit 22 detects the presence or absence of an abnormality in the current detection circuit 6 a plurality of times, the detection unit 22 may detect that the current detection circuit 6 has no abnormality at least once. According to the sixth aspect, the converter circuit (the first converter circuit 4) can not perform the discharging operation when the number of times the detection unit 22 detects that there is an abnormality in the current detection circuit 6 exceeds a predetermined number. On the other hand, if the detection unit 22 detects that there is no abnormality in the current detection circuit 6 before the number of times that the detection unit 22 detects that there is an abnormality in the current detection circuit 6 exceeds a predetermined number, the converter circuit It becomes possible to perform the discharge operation. Therefore, it is possible to reduce the possibility that the discharge operation of the converter circuit can not be performed due to the erroneous detection of the detection unit 22.

  Further, in the control device 2 according to the seventh aspect, in any one of the first to sixth aspects, the current detection circuit 6 is configured to convert the current flowing from the power conversion system 1 to the power system and the power conversion from the power system The currents flowing in the system 1 are detected as currents having different polarities. The upper limit UP1 of the predetermined range RA1 is larger than 0, and the lower limit LO1 of the predetermined range RA1 is smaller than 0.

  According to the above configuration, when there is an abnormality in the current detection circuit 6 and the detected current value becomes 0, the detection unit 22 can detect that the current detection circuit 6 has an abnormality.

  The power conversion system 1 according to the eighth aspect includes the control device 2 according to any one of the first to seventh aspects, and an inverter circuit 3.

  According to the above configuration, the possibility that the converter circuit (first converter circuit 4) and the inverter circuit 3 are erroneously controlled by the control device 2 of the power conversion system 1 can be reduced.

  Moreover, the power conversion system 1 which concerns on a 9th aspect is further provided with the converter circuit (1st converter circuit 4) in the 8th aspect.

  According to the above configuration, the possibility that the converter circuit (first converter circuit 4) and the inverter circuit 3 are erroneously controlled by the control device 2 of the power conversion system 1 can be reduced.

  The power conversion system 1 according to the tenth aspect further includes an intermediate bus W1 and a current detection circuit 6 in the ninth aspect.

  According to the above configuration, the possibility that the converter circuit (first converter circuit 4) and the inverter circuit 3 are erroneously controlled by the control device 2 of the power conversion system 1 can be reduced.

  The program according to the eleventh aspect causes a computer to function as the control device 2 provided in the power conversion system 1. The power conversion system 1 includes an intermediate bus W1, a converter circuit (first converter circuit 4), an inverter circuit 3, and a current detection circuit 6. The intermediate bus W1 is connected to the distributed power supply PV1, and DC power is supplied from the distributed power supply PV1. The converter circuit is connected to storage battery SB1 and intermediate bus W1. The converter circuit performs a charging operation and a discharging operation. The converter circuit outputs DC power from the intermediate bus W1 to the storage battery SB1 in the charging operation. The converter circuit outputs DC power from storage battery SB1 to intermediate bus W1 in the discharging operation. The inverter circuit 3 is connected to the load 71 (or 72) and the power system. The inverter circuit 3 is connected to the converter circuit and the distributed power supply PV1 via the intermediate bus W1. The inverter circuit 3 converts the DC power from the intermediate bus W1 into AC power and outputs the AC power to the load 71 (or 72) or the power system. The current detection circuit 6 detects the current flowing between the power conversion system 1 and the power system. The control device 2 controls the converter circuit and the inverter circuit 3 in accordance with the detected current value detected by the current detection circuit 6. The control device 2 detects the presence or absence of abnormality of the current detection circuit 6 according to the detected current value. When the state where the detected current value is within the predetermined range RA1 continues for a predetermined detection time T1, the control device 2 detects that there is an abnormality in the current detection circuit 6.

  According to the above configuration, it is possible to reduce the possibility that the control device 2 erroneously controls the converter circuit (first converter circuit 4) and the inverter circuit 3.

  The configurations according to the second to seventh aspects are not essential to the control device 2 and can be omitted as appropriate.

DESCRIPTION OF SYMBOLS 1 Power conversion system 2 control apparatus 21 control part 211 1st control part 212 2nd control part 22 detection part 3 inverter circuit 4 1st converter circuit (converter circuit)
6 current detection circuits 71, 72 load LO1 lower limit value PV1 dispersed power source RA1 predetermined range SB1 storage battery T1 predetermined detection time UP1 upper limit value W1 intermediate bus

Claims (11)

A control device provided in a power conversion system, comprising:
The power conversion system is
An intermediate bus connected to the distributed power supply and supplied with DC power from the distributed power supply;
A storage battery and a converter circuit connected to the intermediate bus and performing a charging operation for outputting DC power from the intermediate bus to the storage battery, and a discharging operation for outputting DC power from the storage battery to the intermediate bus;
An inverter connected to a load and a power system, connected to the converter circuit and the distributed power supply via the intermediate bus, converting DC power from the intermediate bus into AC power and outputting the AC power to the load or the power system Circuit,
A current detection circuit that detects a current flowing between the power conversion system and the power system;
The controller is
A control unit configured to control the converter circuit and the inverter circuit in accordance with a detected current value detected by the current detection circuit;
And a detection unit that detects the presence or absence of an abnormality in the current detection circuit according to the detected current value.
The control device detects that there is an abnormality in the current detection circuit when the detection current value continues to be within a predetermined range for a predetermined detection time. The control unit
A first control unit that controls the converter circuit and the inverter circuit according to the detected current value detected by the current detection circuit;
A second control unit that controls the converter circuit according to the detection result of the detection unit;
The second control unit gradually decreases DC power output from the storage battery to the converter circuit when the detection unit detects that there is an abnormality in the current detection circuit. Control device. The control unit
A first control unit that controls the converter circuit and the inverter circuit according to the detected current value detected by the current detection circuit;
A second control unit that controls the converter circuit according to the detection result of the detection unit;
When the converter circuit starts the discharging operation, at least one of the first control unit and the second control unit controls the direct current output from the storage battery to the converter circuit at an upper limit value of the predetermined range. The control device according to claim 1 or 2, wherein the control device is increased during the predetermined detection time by a value larger than the difference between and the lower limit value. The control unit
A first control unit that controls the converter circuit and the inverter circuit according to the detected current value detected by the current detection circuit;
A second control unit that controls the converter circuit according to the detection result of the detection unit;
When the detection unit detects that there is an abnormality in the current detection circuit, the second control unit allows the converter circuit to perform only the charging operation among the charging operation and the discharging operation. Thereafter, when the detection unit detects that there is no abnormality in the current detection circuit, the second control unit maintains a state in which only the charge operation can be performed among the charge operation and the discharge operation in the converter circuit. The control device according to any one of claims 1 to 3, characterized in that: The control unit
A first control unit that controls the converter circuit and the inverter circuit according to the detected current value detected by the current detection circuit;
A second control unit that controls the converter circuit according to the detection result of the detection unit;
When the detection unit detects that there is an abnormality in the current detection circuit, the second control unit allows the converter circuit to perform only the charging operation among the charging operation and the discharging operation. Thereafter, when the detection unit detects that there is no abnormality in the current detection circuit, the second control unit enables the converter circuit to perform at least the discharge operation among the charge operation and the discharge operation. The control device according to any one of claims 1 to 3, characterized in that: When the detection unit detects that there is no abnormality in the current detection circuit and the number of times that the detection unit detects that there is an abnormality in the current detection circuit is equal to or more than a predetermined number, the converter circuit performs the charging operation The control device according to claim 5, wherein the second control unit maintains a state in which only the charging operation can be performed among the charging operation and the discharging operation. The current detection circuit detects a current flowing from the power conversion system to the power system and a current flowing from the power system to the power conversion system as currents having different polarities.
The control device according to any one of claims 1 to 6, wherein an upper limit value of the predetermined range is larger than 0 and a lower limit value of the predetermined range is smaller than 0. The control device according to any one of claims 1 to 7,
And the inverter circuit. The power conversion system according to claim 8, further comprising the converter circuit. Said intermediate bus,
The power conversion system according to claim 9, further comprising: the current detection circuit. A program that causes a computer to function as a control device included in a power conversion system,
The power conversion system is
An intermediate bus connected to the distributed power supply and supplied with DC power from the distributed power supply;
A storage battery and a converter circuit connected to the intermediate bus and performing a charging operation for outputting DC power from the intermediate bus to the storage battery, and a discharging operation for outputting DC power from the storage battery to the intermediate bus;
An inverter connected to a load and a power system, connected to the converter circuit and the distributed power supply via the intermediate bus, converting DC power from the intermediate bus into AC power and outputting the AC power to the load or the power system Circuit,
A current detection circuit that detects a current flowing between the power conversion system and the power system;
The controller is
Controlling the converter circuit and the inverter circuit according to the detected current value detected by the current detection circuit;
Detecting the presence or absence of an abnormality of the current detection circuit according to the detected current value;
A program comprising: detecting that there is an abnormality in the current detection circuit when a state in which the detected current value is within a predetermined range continues for a predetermined detection time.

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