JP3656556B2 - Inverter control device - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
  The present invention relates to a control device for a power conditioner.PlaceAbout.
[0002]
[Prior art]
In recent years, gas cogeneration systems have attracted attention as one of the private power generation systems. This is a system that uses electric power generated by using natural gas or the like as fuel, recovers the exhaust heat, and uses it for boiling water or the like.
[0003]
This system includes a generator that converts fuel energy into electrical energy, a power converter that converts power from the generator into AC power synchronized with the commercial power source, a protective device that detects an abnormality in the commercial power source, and exhaust heat. It consists of an exhaust heat recovery device that recovers. A power conditioner includes the power conversion device and the protection device.
[0004]
In the solar power generation system, the surplus power generated can flow backward to the grid. However, no reverse flow of power generated by the gas cogeneration system has been observed. Therefore, a function for detecting reverse current and preventing it is necessary.
[0005]
And the protection system of the conventional power conditioner has proposed what is shown in FIG. 16, and what is shown in FIG.
[0006]
  The inverter protection system shown in FIG. 16 is connected to the commercial power system 40 and the commercial power system 40.systemThe generated power conditioner 41, the power generation system 42 that outputs the generated power to the power conditioner 41, and exhaust heat recoveryPart46, current detectors (CT) 43 and 44 for detecting the direction and magnitude of each of the U-phase and W-phase currents of the commercial power system 40, and the output of the power conditioner 41 exceeds the load 45, causing reverse power flow. Is generated, a stop signal P is output to the power conditioner 41 based on the detection signals of the current detectors (CT) 43 and 44, and the reverse power relay 4 that stops the power conditioner 41 is output.7(RPR).
[0007]
  And when the output of the power conditioner 41 exceeds the load 45 and a reverse power flow occurs, the reverse power relay 47Outputs a stop signal P to the power conditioner 41 based on the detection signals of the current detectors 43 and 44, and stops the power conditioner 41.
[0008]
Further, the power conditioner protection system shown in FIG. 17 includes a commercial power system 50, a power conditioner 51, a commercial power system 50, and an output side 51A of the power conditioner 51 connected to the contacts 52a and 52b. A changeover switch 52 in which 52c is connected to a load 54 via a circuit breaker 53, a current detector (CT) 55 for detecting the direction and magnitude of current on the intercept 52c side of the changeover switch 52, and this current detector ( And a control device 56 that performs on / off control of the changeover switch 52 based on a detection signal of (CT) 55.
[0009]
Then, the power of the load 54 is monitored by the current detector (CT) 55, and before the protection system of the power conditioner is overloaded, the control device 56 switches the changeover switch 52 so that the power conditioner is connected to the commercial power system 50. NA 51 is cut off so that it is not possible to perform an interconnected operation.
[0010]
[Problems to be solved by the invention]
However, in the above-described protection system for the power conditioner shown in FIG. 16, when the load fluctuation range is wide, the capacity of the power conditioner 41 is adjusted or the time when it does not operate is generated. There is a problem in that the power conditioner 41 cannot be effectively used unless a large amount of power is always required.
[0011]
In the power conditioner protection system shown in FIG. 17, it is necessary to control the load 54 to be connected to the load 54 at high speed and to disconnect the connection. There is a problem that the control device 56 is large and expensive.
[0012]
The present invention has been made paying attention to the above-mentioned problems. The first object of the present invention is to supply necessary power without stopping the power generation system even when the load fluctuation is large. To provide a control device for a power conditioner that can be supplied from a conditioner, eliminates the need for a changeover switch, and can greatly reduce costs and reduce the size of the device. It is.
[0013]
Further, the second object of the present invention is that, when a load is small and a rated output is performed and a reverse power flow occurs, the remaining electricity can be used for other purposes without adjusting the output. It is to provide a control device for a power conditioner.
[0014]
A third object of the present invention is to provide a control device for a power conditioner that can stop the output when a reverse power flow occurs when the rated output is performed with a small load.
[0019]
[Means for Solving the Problems]
  UpIn order to achieve the first object, a power conditioner control device according to the present invention is a power conditioner control device that links power generated by a power generation system to a single-phase three-wire commercial power system. And one load between the U-phase and the center line O of the three-wire commercial power system and the other load between the W-phase and the center line O of the three-wire commercial power system. And an inverter circuit for converting the power generated by the power generation system into AC power synchronized with the commercial power supplied from the single-phase three-wire commercial power system, and the U of the commercial power system. Phase and W phaseFlowA first CT input circuit composed of a U-phase and a W-phase, each of which inputs the direction and magnitude of the signal as a detection signal, an output current measuring instrument for detecting the magnitude of the output current of the power conversion means, and an output current measuring instrument A second CT input circuit for inputting a detection signal, a voltage input circuit composed of a U-phase and a W-phase for inputting the U-phase and W-phase voltages of the commercial power system as detection signals, and a first CT input In response to signals from the circuit, the output current measuring instrument, the second CT input circuit and the voltage input circuit, the forward power supplied from the commercial power system in both load directions is less than or equal to the predetermined power. Control means for controlling the inverter circuit so as to adjust the output power of the conditioner is built-in.
[0020]
  Furthermore, the control meansFirst CT input circuit and voltage input circuitAs a result of comparing the forward power and the predetermined power, if the forward power is greater than the predetermined power, the output power is not changed and output as it is.Inverter circuitIf the forward power is lower than the specified power, the output power is adjusted.Inverter circuitControlRu.
[0021]
With this configuration, the output power of the power conditioner can be adjusted by the control means when the forward power flow is equal to or lower than the predetermined power. That is, when the control means receives signals from the signal input means, the output current detection means, and the voltage input means, and the power of the forward current is equal to or lower than a predetermined power, the power conversion means is adjusted so as to adjust the output power. Control.
[0022]
For this reason, even when the load fluctuation is large, it is possible to supply necessary power from the power conditioner without stopping the power generation system. Further, since the power conditioner is used in conjunction with the commercial power system, a changeover switch or the like is not required, and the cost can be greatly reduced, and the size of the apparatus can be reduced.
[0023]
Further, the power conditioner control device according to the present invention is the above-described power conditioner control device according to the present invention, wherein the control means is configured to control the U-phase forward current and the W-phase forward current of the commercial power system. The power conversion means is controlled so as to adjust the output power using the lower power of the forward flow as the input signal.
[0024]
With this configuration, the control means compares the power of the U-phase forward power and the power of the W-phase forward power, and adjusts the output power of the power conditioner when the smaller one is equal to or less than the predetermined power. In addition, it is possible to secure the power of the forward current more than the predetermined power.
[0025]
For this reason, even when the load fluctuation is large, it is possible to supply necessary power from the power conditioner without stopping the power generation system. Further, since the power conditioner is used in conjunction with the commercial power system, a changeover switch or the like is not required, and the cost can be greatly reduced, and the size of the apparatus can be reduced.
[0026]
  The power generation system is, for example, a gas engine, a generator driven by the gas engine, a wind power generator, etc.SystemThe means is, for example, an MPU.
[0027]
  In order to achieve the first object, a power conditioner control device according to the present invention controls a power conditioner that links power generated by a power generation system to a single-phase three-wire commercial power system. A device, one load between the U phase and the center line O of the three-wire commercial power system, and the other load between the W phase and the center line O of the three-wire commercial power system. An inverter circuit for connecting the power conditioner independently and converting the power generated by the power generation system into AC power synchronized with a commercial power source supplied from a single-phase three-wire commercial power system; and a commercial power system Each of the U and W phasesFlowFirst CT input circuit composed of a U phase and a W phase for inputting the direction and magnitude of the power as a detection signal, and an output current measurement composed of each of the U phase and the W phase for detecting the magnitude of the output current of the power conversion means , A second CT input circuit for inputting a detection signal of the output current measuring instrument, and a voltage input composed of each of the U phase and the W phase for inputting the U phase and W phase voltages of the commercial power system as detection signals. In response to signals from the circuit, the first CT input circuit, the output current measuring instrument, the second CT input circuit, and the voltage input circuit, the signals are supplied from the U phase and W phase of the commercial power system in both load directions, respectively. A control means for adjusting the output current of the power conditioner for each of the U phase and the W phase of the commercial power system when the forward power flow is equal to or lower than the predetermined power is built-in.
[0029]
  Furthermore, the control meansFirst CT input circuitAs a result of comparing the forward power and the predetermined power, the power of the forward current is larger than the predetermined power.Inverter circuitIf the forward power is lower than the specified power, the U-phase output power is adjusted.Inverter circuitControl of the W phaseFirst CT input circuitAs a result of comparing the forward power and the predetermined power, the inverter circuit is controlled so that the forward power is output as it is when the forward power is larger than the predetermined power. If smaller, adjust the output power of the W phaseInverter circuitControlIt is configured as follows.
[0030]
With such a configuration, when the forward power is less than or equal to the predetermined power, the output power of the power conditioner can be adjusted by the control means without causing the power generation system to stop even when the load fluctuation is large. Necessary power can be supplied from the power conditioner, and there is no need for a changeover switch, so the cost can be greatly reduced, the size of the device can be reduced, and the load balance is poor. (The magnitudes of one load and the other load are different.) When the output of the entire inverter is adjusted and efficient operation is hindered, each phase of the U phase and W phase as described above. By performing the control every time, it is possible to eliminate the adjustment of the output of the entire power conditioner and to operate efficiently.
[0033]
  In order to achieve the second object, a power conditioner control device according to the present invention controls a power conditioner that links power generated by a power generation system to a single-phase three-wire commercial power system. A device, one load between the U phase and the center line O of the three-wire commercial power system, and the other load between the W phase and the center line O of the three-wire commercial power system. An inverter circuit for independently connecting the inverter and converting the power generated by the power generation system into AC power synchronized with the commercial power supplied from the single-phase three-wire commercial power system; Power for each of the U phase and W phase of the systemFlowA first CT input circuit composed of a U-phase and a W-phase, each of which inputs the direction and magnitude of the signal as a detection signal, an output current measuring instrument for detecting the magnitude of the output current of the power conversion means, and an output current measuring instrument A second CT input circuit for inputting a detection signal; a voltage input circuit composed of each of the U phase and W phase for inputting the voltages of the U phase and W phase of the commercial power system as detection signals; As a result of comparing the forward power supplied to the one load direction from the commercial power system input by the first CT input circuit of each W phase with the predetermined power, the forward power is larger than the predetermined power. In this case, the inverter circuit is controlled so that it is output as it is, and when the forward power is smaller than the predetermined power, electric energy other than that consumed by both loads is supplied to loads other than both loads. Inn Is characterized in that it has constituted a built-in control means for controlling the over-capacitor circuit.
[0036]
With such a configuration, when the load is large and a reverse power flow occurs when the rated output is performed, the remaining electricity is changed to heat for other purposes, for example, hot water or ice without adjusting the output. Alternatively, it can be stored with electricity.
[0037]
  In order to achieve the third object, a power conditioner control device according to the present invention controls a power conditioner that links power generated by a power generation system to a single-phase three-wire commercial power system. A device, one load between the U phase and the center line O of the three-wire commercial power system, and the other load between the W phase and the center line O of the three-wire commercial power system. An inverter circuit for connecting the power conditioner independently and converting the power generated by the power generation system into AC power synchronized with a commercial power source supplied from a single-phase three-wire commercial power system; and a commercial power system Each of the U and W phasesFlowA first CT input circuit composed of a U-phase and a W-phase, each of which inputs the direction and magnitude of the signal as a detection signal, an output current measuring instrument for detecting the magnitude of the output current of the power conversion means, and an output current measuring instrument A second CT input circuit for inputting a detection signal; a voltage input circuit composed of the U phase and the W phase for inputting the U phase and W phase voltages of the commercial power system as detection signals; When signals from the CT input circuit, the output current measuring instrument, the second CT input circuit and the voltage input circuit are received, and the power of the reverse power flowing from the both load directions to the commercial power system becomes a predetermined power or more, Control means for controlling to stop the output of the inverter is built in.
[0039]
Furthermore, the control means has a timer function for measuring the duration of the reverse power flow, and a reverse power relay function for stopping the output of the power conditioner when the reverse power flow duration time has exceeded a predetermined time. The power conversion means measures the reverse power flow continuation time by the control means when the power of the power exceeds the predetermined power, and stops the output of the power conditioner when the reverse power flow continuation time passes the predetermined time. To control.
[0040]
With such a configuration, when the reverse power flow prevention control does not work due to a failure of the power conditioner or the like, the output can be stopped when the reverse power flow flows for a predetermined time or more. In addition, when the inverter output is stopped, it is also possible to notify the administrator, etc., of the abnormal signal by contact or display such as communication or relay, and the reverse power relay of the control means. When the output of the power conditioner is stopped by the function, the drive of the power generation system can be stopped by a command from the power conditioner.
[0041]
  A power conditioner control device according to the present invention is a power conditioner control device that links power generated by a power generation system to a single-phase three-wire commercial power system. One load is connected between the U phase and the center line O, and the other load is connected independently between the W phase and the center line O of the three-wire commercial power system. An inverter circuit that converts the power generated by the power generation system into AC power synchronized with the commercial power supplied from the single-phase three-wire commercial power system, and each of the U-phase and W-phase power of the commercial power systemFlowA first CT input circuit composed of a U-phase and a W-phase, each of which inputs the direction and magnitude of the signal as a detection signal, an output current measuring instrument for detecting the magnitude of the output current of the power conversion means, and an output current measuring instrument A second CT input circuit for inputting a detection signal; a voltage input circuit composed of the U phase and the W phase for inputting the U phase and W phase voltages of the commercial power system as detection signals; Receives signals from the CT input circuit, the output current measuring instrument, the second CT input circuit, and the voltage input circuit, and supplies them in one load direction from the commercial power system input by the U-phase and W-phase CT input circuits. A timer function that measures the duration when it is detected that the power value of the forward power flow has become zero, and a reverse power relay function that stops the output of the power conditioner when this duration has passed a predetermined time; System with And the control means measures the forward power flow duration time by the control means when the power value of the forward power flow becomes zero, and the forward power flow duration time exceeds a predetermined time. It is configured to perform control to stop the output of the power conditioner.
[0042]
With this configuration, it is possible to detect disconnection of the current detection means (current detector) by performing control while always flowing several A (amperes) in the forward direction. That is, when the power value of the forward power flow is zero for a predetermined time, the output of the power conditioner can be stopped.
[0047]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, embodiments of the present invention will be described with reference to the drawings.
[0048]
(Embodiment 1)
Embodiment 1 of the present invention is shown in FIGS.
[0049]
  FIG. 1 shows a grid interconnection system that links a cogeneration system and a power grid (commercial power grid). In FIG. 1, reference numeral 1 denotes a single-phase three-wire commercial power system of a commercial power source. The U-phase and neutral line O of the commercial power system 1ofBetween the first (one) load 2 between the W phase and the neutral wire OofA second (other) load 3 is connected between them.
[0050]
The cogeneration system A includes a power conditioner 10, a power generation system 20, and an exhaust heat recovery machine 34.
[0051]
The power conditioner body 11 of the power conditioner 10 includes an inverter circuit 13 as power conversion means for converting the power generated by the power generation system 20 into AC power synchronized with the commercial power source, and the U of the commercial power system 1. CT input circuits (A / D converters) 15A and 15B as signal input means for the U phase and W phase for inputting detection signals of the direction and magnitude of the currents flowing through the phases and W phases, and the output current of the inverter circuit 13 An output current measuring device (current transformer) CT3 as output current detecting means for detecting the magnitude of the output current, and a CT input circuit (AD converter) 15C as signal input means for inputting a detection signal of the output current measuring device CT3; The voltage of each of the U phase and the W phase of the commercial power system 1 for inputting the U phase and W phase voltages (system voltage) as detection signals. Voltage input circuit 35A of the power unit has a 35B, the control unit as a control unit and a (MPU) 12.
[0052]
The control unit (MPU) 12 receives the signals from the CT input circuits 15A, 15B, 15C and the voltage input circuits 35A, 35B, and the forward flow from the commercial power system 1 toward the load direction has a predetermined power value. In the following case, the inverter circuit 13 is controlled so as to adjust the output power.
[0053]
That is, the input side of the control unit 12 includes an output signal input unit 12a and first, second, third, and fourth signal input units 12b, 12c, 12d, and 12e, and the output signal input unit 12a. Is connected to the output side of a CT input circuit (AD converter) 15C. Further, the output side of a CT input circuit (AD converter) 15A is connected to the first signal input section 12b, and the output side of a CT input circuit (AD converter) 15B is connected to the second input section 12c. . Further, the output side of the voltage input circuit 35A is connected to the third signal input unit 12d, and the output side of the voltage input circuit 35B is connected to the fourth signal input unit 12e.
[0054]
The output side of the control unit 12 is connected to a control unit (not shown) of the inverter circuit 13, and the output side of the power generation system 20 is connected to the input side of the inverter circuit 13. Is connected to the signal output unit 16. The signal output unit 16 includes a U-phase connection line 17 connected to the U-phase of the commercial power system 1, a neutral connection line 18 connected to the neutral line O of the commercial power system 1, and the commercial power system 1. And a W-phase connection line 19 connected to the W-phase.
[0055]
The signal output unit 16 is provided with an output current detection unit 14, and the output current detection unit 14 is constituted by an output current measuring device CT3. The signal output side of the output current measuring device CT3 is connected to the output signal input unit 12a of the control unit 12 via the CT input circuit 15C.
[0056]
The input side of the voltage input circuit 35A is connected to the signal output unit 16 to detect the U-phase voltage from the U-phase connection line 17 and the neutral connection line 18 of the signal output unit 16, and the signal output unit The input side of the voltage input circuit 35 </ b> B is connected to the signal output unit 16 so as to detect the W-phase voltage from the 16 W-phase connection lines 19 and the neutral connection line 18.
[0057]
The CT input circuit 15A connected to the first signal input unit 12b of the control unit 12 is connected to the signal output side of the current detector (current transformer) CT1 provided in the U phase of the commercial power system 1 of the commercial power source. The CT input circuit 15B connected to the second signal input unit 12c of the control unit 12 outputs a signal output from a current detector (current transformer) CT2 provided in the W phase of the commercial power system 1 of the commercial power supply. The side is connected.
[0058]
The power generation system 20 includes, for example, a gas engine and a generator driven by the gas engine.
[0059]
Next, the operation of the cogeneration system A configured as described above will be described with reference to the flowchart shown in FIG.
[0060]
The direction (forward direction or reverse direction) and magnitude of the current flowing through the commercial power system 1 is detected by the current detector CT1 in the U phase, and is detected by the current detector CT2 in the W phase. In the power conditioner 10, the magnitude of the output current output from the output side of the inverter circuit 13 is detected by the output current measuring device CT3, and the U-phase voltage of the commercial power system 1 is the voltage input circuit 35A. In addition, the W-phase voltage of the commercial power system 1 is read by the voltage input circuit 35B. (Step S1).
[0061]
The forward current value (detection signal), which is the current value of the U-phase forward current detected by the current detector CT1, is input to the first signal input unit 12b of the control unit 12 via the CT input circuit 15A, and current detection is performed. The forward current value (detection signal), which is the current value of the W-phase forward current detected by the detector CT2, is input to the second signal input unit 12c of the control unit 12 via the CT input circuit 15B, and further the output current The current value (detection signal) of the output current detected by the measuring instrument CT3 is input to the output signal input unit 12a of the control unit 12, and the U-phase voltage of the commercial power system 1 is supplied from the voltage input circuit 35A to the first of the control unit 12. 3, and the W-phase voltage is input from the voltage input circuit 35 </ b> B to the fourth signal input unit 12 e of the control unit 12.
[0062]
In this control unit 12, the power value of the U-phase forward flow and the power value of the W-phase forward flow are compared (step S2), and the current flowing from the commercial power system 1 in the load direction is changed to the forward direction. The smaller one is the forward power value. In this case, the power value of the U-phase forward current is set as the power value of the forward current (step S3).
[0063]
When the control unit 12 compares the power value of the forward power flow with a predetermined level α (α is a power value of zero or greater than zero) (step S4), the power value of the forward power flow is greater than the predetermined level α. Instructs the inverter circuit 13 to output the output without changing the output power (step S5).
[0064]
In step S4, as a result of comparing the power value of the forward flow and the predetermined level α, if the power value of the forward flow is smaller than the predetermined level α, a gain that reduces the current output power (GAIN <1). Thus, the output power of the power conditioner 10 is controlled before the reverse power flow occurs. That is, the control unit 12 instructs the inverter circuit 13 to adjust the output power, and ensures a forward power value of a predetermined level α or higher (step S6).
[0065]
In step S2, the power value of the U-phase forward tide and the power value of the W-phase forward tide are compared, and if the smaller one in the forward direction is the power value of the W-phase forward tide, The power value of the W-phase forward tide is set as the power value of the forward tide (step S7), and the process proceeds to step S4.
[0066]
For example, as shown in FIG. 5, when the first load 2 is 2.5 kW, the second load 3 is 2.5 kW, and the power conditioner 10 outputs, the first and second loads 2, 3 is supplied with a current of 24 A from the power conditioner 10 side, and a 1 A CT current is supplied to the current detector CT 1 (current detector CT 2) from the commercial power system 1 (200 V) side in the forward direction A. Make it flow.
[0067]
In this state, when the forward current value of the CT current is larger than a predetermined level α, that is, 1 A, a current of 24 A or less is supplied from the power conditioner 10 side, and the output current is not changed. Is output to the inverter circuit 13.
[0068]
However, when the forward current value of the CT current is smaller than the predetermined level α, that is, 1 A, a current of 24 A or more is supplied from the power conditioner 10 side, which may cause a reverse power flow. In this case, the output current of the power conditioner 10 is controlled before a reverse flow occurs due to a gain (GAIN <1) that lowers the output current. That is, the control unit 12 instructs the inverter circuit 13 to adjust the output current, and secures a predetermined forward current value of 1 A or more.
[0069]
Further, as shown in FIG. 6, when the first load 2 is 1 kW and the second load 3 is 6 kW, when the power conditioner 10 outputs, the first load, which is the smaller load, is output. In order to match 1 kW of the load 2, a current of 9 A is supplied to the first and second loads 2 and 3 from the power conditioner 10 side in the forward direction A. In this case, a 1 A CT current is allowed to flow in the forward direction A from the commercial power system 1 (200 V) side in the direction of the arrow A.
[0070]
In this case, the current of 10 A (9A + 1A) supplied in the forward direction A is sufficient to drive the first load 2 of 1 kW and drive 1 kW of the 6 kW of the second load 3. For the remaining 5 kW of the second load 3, 51A (50A + 1A) is supplied in the forward direction a from the commercial power system 1 (200V) side, and the second load 3 is driven. At this time, 1A is detected in the current detector CT1, and 51A is detected in the current detector CT2.
[0071]
This is because the control unit 12 compares the power value of the U-phase forward current (forward current value) with the power value of the W-phase forward current (forward current value). The smaller one is nothing but the forward power value (CT current).
[0072]
As described above, according to the first embodiment of the present invention, when the power value of the forward current flowing from the commercial power system 1 in the load direction is equal to or lower than the predetermined power value, the control unit 12 controls the power conditioner 10. The output power can be adjusted. That is, when the control unit 12 receives signals from the CT input circuits 15A, 15B, and 15C, the output current measuring device CT3, and the voltage input circuits 35A and 35B, and the power of the forward current becomes a predetermined power value or less, The inverter circuit 13 is controlled so as to adjust the output power.
[0073]
Moreover, according to Embodiment 1 of this invention, the control part 12 has the electric power of the forward tide which is the lower one of the electric power value of the U-phase forward tide and the electric power value of the W-phase forward tide of the commercial power system 1. The inverter circuit 13 is controlled to adjust the output power using the value as an input signal. That is, the control unit 12 compares the power value of the U-phase forward power and the power value of the W-phase forward power, and the smaller one is a predetermined level α (α is a power value of zero or more than zero), for example, When set to 1 A, when the rated output is 1 A or less when the rated output is generated, the output power of the power conditioner 10 can be adjusted, and the power value of the forward flow can be secured to 1 A or more.
[0074]
For this reason, even when the load fluctuation is large, it is possible to supply necessary power from the power conditioner 10 without stopping the power generation system 20. In addition, since the power conditioner 10 is used in conjunction with the commercial power system 1, a changeover switch or the like is not required, so that the cost can be greatly reduced and the size of the apparatus can be reduced. .
[0075]
(Embodiment 2)
A second embodiment of the present invention is shown in FIGS.
[0076]
In Embodiment 2 of the present invention, when the power value of the forward current flowing in the load direction from the U phase and W phase of the commercial power system 1 is less than or equal to a predetermined power value, the U phase and W phase of the commercial power system 1 Every time, the output power of the power conditioner 10 is controlled to be adjusted.
[0077]
  And the power conditioner 10 is a power generation system.2Detects the direction and magnitude of the current flowing through each of the U-phase and W-phase of the commercial power system 1 and the inverter circuit 13 as power conversion means for converting the power generated by 0 into AC power synchronized with the commercial power source CT input circuits 15A and 15B as signal input means for U phase and W phase input as signals, and output current measurement as output current detection means for U phase and W phase for detecting the magnitude of output current of inverter circuit 13, respectively. CT input circuits CT4, CT5, CT input circuits (AD converters) 15D, 15E as signal input means for inputting detection signals of these output current measuring instruments CT4, CT5, and U phase and W phase of the commercial power system 1, respectively Voltage input circuits 35A and 35B as U-phase and W-phase signal input means for inputting the current voltage as a detection signal, and a control unit (MPU) as control means And a 2.
[0078]
The control unit (MPU) 12 receives signals from the CT input circuits 15A, 15B, 15C, and 15D and the voltage input circuits 35A and 35B, and when the forward power flow becomes a predetermined power value or less, The inverter circuit 13 is controlled so as to adjust the output power for each U-phase and W-phase.
[0079]
In the second embodiment of the present invention, the output current measuring device CT4 is provided in the U-phase connection line 17 of the signal output unit 16, the output current measuring device CT5 is provided in the W-phase connection line 19, and the output current measuring device CT4, The signal output side of CT5 is connected to the output signal input units 12a-1 and 12a-2 of the control unit 12 via CT input circuits 15D and 15C. Since the other configuration is the same as that of the first embodiment of the present invention described above, the same reference numerals as those of the first embodiment of the present invention are attached and description thereof is omitted.
[0080]
Next, the operation of the second embodiment of the present invention configured as described above will be described with reference to the flowcharts shown in FIGS.
[0081]
As shown in (1) of FIG. 8, the direction (forward direction or reverse direction) and magnitude of the current flowing through the commercial power system 1 is detected by the current detector CT1 in the U phase, and inside the power conditioner 10 The magnitude of the output current output from the output side of the inverter circuit 13 is detected by the output current measuring device CT4 in the U phase, and the U phase voltage of the commercial power system 1 is read by the voltage input circuit 35A.
[0082]
The U-phase forward current value (detection signal) detected by the current detector CT1 is input to the first signal input unit 12b of the control unit 12 via the CT input circuit 15A and detected by the output current measuring device CT4. The output current (detection signal) is input to the output signal input unit 12a-1 of the control unit 12, and the U-phase voltage is input from the voltage input circuit 35A to the third signal input unit 12d of the control unit 12 (step T1). ).
[0083]
In this control unit 12, as a result of comparing the power value of the U-phase forward current and a predetermined level α (α is a power value of zero or greater than zero) (step T2), the power value of the U-phase forward current is predetermined. Is greater than the level α, the output power is not changed and the output is instructed to the inverter circuit 13 (step T3).
[0084]
In step T2, if the power value of the U-phase forward flow is smaller than the predetermined level α as a result of comparing the power value of the U-phase forward flow and the predetermined level α, the gain (GAIN < 1) Control to prevent reverse power flow is performed. That is, the control unit 12 instructs the inverter circuit 13 to adjust the output power (step T4).
[0085]
Further, as shown in (2) of FIG. 8, the direction (forward direction or reverse direction) and the magnitude of the current flowing through the commercial power system 1 are detected by the current detector CT2 in the W phase, and the power conditioner 10 Internally, the magnitude of the output current output from the output side of the inverter circuit 13 is detected by the output current measuring device CT5 in the W phase, and the W phase voltage of the commercial power system 1 is read by the voltage input circuit 35B. It is done.
[0086]
The W-phase forward current value (detection signal) detected by the current detector CT2 is input to the second signal input unit 12c of the control unit 12 via the CT input circuit 15B and detected by the output current measuring unit CT5. The output current (detection signal) is input to the output signal input unit 12a-2 of the control unit 12, and the W-phase voltage is input from the voltage input circuit 35B to the fourth signal input unit 12e of the control unit 12. (Step V1).
[0087]
The control unit 12 compares the power value of the W-phase forward power and a predetermined level α (α is a power value of zero or more than zero) (step V2). Is greater than the predetermined level α, the output power is not changed and the output is instructed to the inverter circuit (step V3).
[0088]
As a result of comparing the power value of the W-phase forward power and the predetermined level α in step V2, if the power value of the W-phase forward power is smaller than the predetermined level α, the gain (GAIN < 1) Control to prevent reverse power flow is performed. That is, the control unit 12 instructs the inverter circuit 13 to adjust the output power (step V4).
[0089]
As described above, according to the second embodiment of the present invention, the output power of the power conditioner 10 can be adjusted by the control unit 12 when the forward power value is equal to or lower than the predetermined power value. Even when the load fluctuation is large, it is possible to supply necessary power from the power conditioner 10 without stopping the power generation system 20, and the changeover switch or the like is not required, and the cost can be greatly reduced. The size of can also be miniaturized.
[0090]
Further, if the balance between the first load 2 and the second load 3 is poor (the magnitudes of the first load 2 and the second load 3 are different), the output of the entire power conditioner 10 is adjusted. However, efficient operation is hindered, but by adjusting each of the U-phase and W-phase as described above, adjustment of the output of the entire power conditioner 10 is eliminated, and efficient operation is possible. Become.
[0091]
That is, when the first load 2 and the second load 3 are in the same state, in the case of the first embodiment of the present invention, as shown in (1) of FIG. Although the output is controlled by the phase 2-wire system, in the case of the second embodiment of the present invention, the U phase and the W phase are controlled independently as shown in (2) of FIG. It becomes possible to do.
[0092]
Further, when the first load 2 and the second load 3 are different in size, in the first embodiment of the present invention, as shown in (1) of FIG. Although determined by the light load 3 side, in the case of the second embodiment of the present invention, as shown in (2) of FIG. 10, the first and second loads 2 in the two phases of U phase and W phase. 3 can be output.
[0093]
Further, in the above-described cogeneration system A, by setting the value compared with the power value of the forward power flow to a non-zero power value, that is, the power of a predetermined (non-zero) power value is always flowed in the forward direction. However, by performing reverse power flow prevention control, it is possible to provide a margin for control against sudden load fluctuations.
[0094]
(Embodiment 3)
A third embodiment of the present invention is shown in FIGS.
[0095]
In Embodiment 3 of the present invention, when the load is large and a reverse power flow occurs when the rated output is performed, the remaining electricity is changed to heat to make hot water without adjusting the output.
[0096]
In the third embodiment of the present invention, as shown in FIG. 12, an output current measuring device CT4 is provided in the U-phase connection line 17 of the signal output unit 16, and an output current measuring device CT5 is provided in the W-phase connection line 19, respectively. The signal output sides of the current measuring devices CT4 and CT5 are connected to the output signal input units 12a-1 and 12a-2 of the control unit 12 via CT input circuits 15D and 15E, and the commercial power system 1 In addition, a heater or the like 31 is connected in parallel to the first load 2, and a heater or the like 32 is connected in parallel to the second load 3, and the switch means 33 is connected in series to the heater or the like 31. 32, switch means 36 are connected in series. The switch means 33 and 36 are controlled to be turned on / off by a control signal output from the signal output unit 12F of the control unit 12.
[0097]
Since the other configuration is the same as that of the above-described second embodiment of the present invention, the same reference numerals as those of the second embodiment are given and description thereof is omitted.
[0098]
Next, the operation of the third embodiment of the present invention configured as described above will be described with reference to the flowcharts shown in FIGS.
[0099]
As shown in (1) of FIG. 13, the direction (forward direction or reverse direction) and magnitude of the current flowing through the commercial power system 1 is detected by the current detector CT1 in the U phase, and inside the power conditioner 10 The magnitude of the output current output from the output side of the inverter circuit 13 is detected by the output current measuring device CT4 in the U phase, and the U phase voltage is read by the voltage input circuit 35A.
[0100]
Then, the U-phase detection current (detection signal) detected by the current detector CT1 is input to the first signal input unit 12b of the control unit 12 via the CT input circuit 15A, and the output detected by the output current measuring unit CT4. The current (detection signal) is input to the output signal input unit 12a-1 of the control unit 12, and the U-phase voltage is input from the voltage input circuit 35A to the third signal input unit 12d of the control unit 12 (step). X1).
[0101]
In this control unit 12, as a result of comparing the power value of the U-phase forward current and a predetermined level α (α is a power value of zero or more than zero) (step X2), the power value of the U-phase forward current is predetermined. Is greater than the level α, the switch means 33 is turned off, and the output power is not changed, and the output is instructed to the inverter circuit 13 (step X3).
[0102]
In step X2, if the power value of the U-phase forward flow and the predetermined level α are compared, and the power value of the U-phase forward flow is smaller than the predetermined level α, the switch means 33 is turned on. Then, surplus electricity is supplied to a heater 31 or the like to change it into heat to make hot water (step X4).
[0103]
Further, as shown in (2) of FIG. 13, the direction (forward direction or reverse direction) and the magnitude of the current flowing through the commercial power system 1 are detected by the current detector CT2 in the W phase, and the power conditioner 10 Internally, the magnitude of the output current output from the output side of the inverter circuit 13 is detected by the output current measuring device CT5 in the W phase, and the W phase voltage is read by the voltage input circuit 35B.
[0104]
The W-phase detection current (detection signal) detected by the current detector CT2 is input to the second signal input unit 12c of the control unit 12 via the CT input circuit 15B, and the output current (detected by the output current measuring unit CT5 ( Detection signal) is input to the output signal input unit 12a-2 of the control unit 12, and the W-phase voltage is input from the voltage input circuit 35B to the fourth signal input unit 12e of the control unit 12 (step Y1). .
[0105]
In this control unit 12, as a result of comparing the power value of the W-phase forward current and a predetermined level α (α is a power value of zero or greater than zero) (step Y2), the power value of the W-phase forward current is predetermined. Is greater than the level α, the switch means 36 is turned off, and the output power is not changed, and the output is instructed to the inverter circuit 13 (step Y3).
[0106]
In step Y2, if the power value of the W-phase forward power and the predetermined level α are smaller than the predetermined level α, the switch means 36 is turned on. Then, surplus electricity is supplied to the heater 32 or the like to convert it into heat to make hot water (step Y4).
[0107]
In addition, when the output of the power conditioner 10 is stopped, an abnormal signal can be communicated to an administrator or the like through a contact or display such as a communication or a relay, and the reverse power relay of the control means is possible. When the output of the power conditioner 10 is stopped by the electric function, the driving of the power generation system 20 can be stopped by a command from the power conditioner 10.
[0108]
As described above, according to the third embodiment of the present invention, when a load is large and a reverse power flow occurs when the rated output is performed, the remaining electricity is changed to heat without adjusting the output, and hot water is supplied. Can be made.
[0109]
In the third embodiment of the present invention, a heater or the like 31 is connected in parallel to the first load 2, and a heater or the like 32 is connected in parallel to the second load 3. The switch means 33 is connected in series, and the switch means 36 is connected in series with the heater 32. However, a number of heaters and switch means are prepared, and the number of on-operations of the heater or the like is determined by the level α value. You may make it increase.
[0110]
Further, in Embodiment 3 of the present invention, the remaining electricity is changed to heat to make hot water, but ice may be made, or electricity may be stored as it is.
[0111]
(Embodiment 4)
Embodiment 4 of the present invention is shown in FIGS. 7 and 14 (1) and (2).
[0112]
In the fourth embodiment of the present invention, the control unit 12 serving as a control unit measures the duration of the reverse power flow that flows in the direction opposite to the load direction of the commercial power system 1, and the reverse power flow duration time is predetermined. When the reverse power flow function that stops the output of the power conditioner 10 after the elapse of time elapses and the reverse power flow from the load direction to the commercial power system 1 exceeds a predetermined power value, the control unit 12 Thus, the reverse flow continuation time is measured, and the output of the power conditioner 10 is stopped when the reverse flow continuation time has passed a predetermined time.
[0113]
That is, when the reverse power flow prevention control does not work due to a failure of the power conditioner 10 or the like, the output is stopped when the reverse power flow flows for a predetermined time or more than a predetermined time.
[0114]
The configuration of the fourth embodiment of the present invention is a configuration in which a timer function and a reverse power relay function are added to the control unit 12 in the second embodiment of the present invention. It is the same as FIG. 7 used.
[0115]
The operation of the fourth embodiment of the present invention will be described with reference to the flowcharts shown in FIGS. 7 and 14 (1) and (2).
[0116]
As shown in FIG. 7 and FIG. 14 (1), the direction (forward direction or reverse direction) and the magnitude of the current flowing through the commercial power system 1 are detected by the current detector CT1 in the U phase, and the power conditioner 10, the magnitude of the output current output from the output side of the inverter circuit 13 is detected by the output current measuring device CT4 in the U phase, and the U phase voltage is read by the voltage input circuit 35A.
[0117]
Then, the U-phase detection current (detection signal) detected by the current detector CT1 is input to the first signal input unit 12b of the control unit 12 via the CT input circuit 15A, and the output detected by the output current measuring unit CT4. The current (detection signal) is input to the output signal input unit 12a-1 of the control unit 12, and the U-phase voltage is input from the voltage input circuit 35A to the third signal input unit 12d of the control unit 12 (step). Z1).
[0118]
The control unit 12 compares the power value of the U-phase reverse power flow with a predetermined level α ′ (α ′ is the predetermined power value of the reverse power flow) (step Z2). If the power value is smaller than the predetermined level α ′, the process returns to step Z1.
[0119]
If the power value of the U-phase reverse power flow is greater than the predetermined level α ′ as a result of comparing the power value of the U-phase reverse power flow with the predetermined level α in step Z2, the timer function of the control unit 12 The duration of the reverse power flow is measured, and when the predetermined time β has elapsed (step Z3), the output of the power conditioner 10 is stopped by the reverse power relay function of the control unit 12 (step Z4).
[0120]
In step Z3, if the duration of the reverse flow does not elapse the predetermined time β, the process returns to step Z1.
[0121]
Further, as shown in FIG. 7 and FIG. 14 (2), the direction (forward direction or reverse direction) and magnitude of the current flowing through the commercial power system 1 are detected by the current detector CT2 in the W phase, and the power In the conditioner 10, the magnitude of the output current output from the output side of the inverter circuit 13 is detected by the output current measuring device CT5 in the W phase, and the W phase voltage is read by the voltage input circuit 35B.
[0122]
The W-phase detection current (detection signal) detected by the current detector CT2 is input to the second signal input unit 12c of the control unit 12 via the CT input circuit 15B, and the output current (detected by the output current measuring unit CT5 ( Detection signal) is input to the output signal input unit 12a-2 of the control unit 12, and the W-phase voltage is input from the voltage input circuit 35B to the fourth signal input unit 12e of the control unit 12 (step F1). .
[0123]
Then, when the control unit 12 compares the power value of the W-phase reverse power flow with the predetermined level α ′ (step F2), the power value of the W-phase reverse power flow is smaller than the predetermined level α ′. Returns to step F1.
[0124]
In step F2, if the power value of the W-phase reverse power flow is greater than the predetermined level α ′ as a result of comparing the power value of the W-phase reverse power flow with the predetermined level α ′, the timer function of the control unit The duration of the reverse power flow is measured, and when the predetermined time β has elapsed (step F3), the output of the power conditioner 10 is stopped by the reverse power relay function of the control unit 12 (step F4).
[0125]
In step F3, if the duration of the reverse power flow does not pass the predetermined time β, the process returns to step F1.
[0126]
In addition, when the output of the power conditioner 10 is stopped, an abnormal signal can be communicated to an administrator or the like through a contact or a display such as communication or a relay. When the output of the power conditioner 10 is stopped by the relay function, it is also possible to stop the driving of the generator driving engine (gas engine or the like) by a command from the power conditioner 10.
[0127]
As described above, according to the fourth embodiment of the present invention, when the reverse power flow prevention control does not work due to a failure of the power conditioner 10 or the like, the output can be stopped when the reverse power flow flows for a predetermined time or more. it can.
[0128]
(Embodiment 5)
Embodiment 5 of the present invention is shown in FIGS. 7 and 15 (1) and (2).
[0129]
In the fifth embodiment of the present invention, the control unit 12 measures the duration when the power value of the forward current flowing in the load direction of the commercial power system 1 becomes zero, and the duration is a predetermined duration. A reverse power relay function that stops the output of the power conditioner 10 after a lapse of time, and when the power value of the forward power flow becomes zero, the control unit 12 measures the forward power flow duration time, The output of the power conditioner 10 is stopped when the forward flow continuation time has passed a predetermined time.
[0130]
In other words, the CT disconnection can be detected by performing the control while always flowing several A (amperes) in the forward direction. That is, when the CT current remains zero for a predetermined time, the output of the power conditioner 10 is stopped.
[0131]
The configuration of the fifth embodiment of the present invention is a configuration in which a timer function and a reverse power relay function are added to the control unit 12 in the second embodiment of the present invention. It is the same as FIG. 7 used.
[0132]
The operation of the fifth embodiment of the present invention will be described with reference to the flowcharts shown in FIGS. 7 and 15 (1) and (2).
[0133]
As shown in FIG. 7 and FIG. 15 (1), the direction (forward direction or reverse direction) and magnitude of the current flowing through the commercial power system 1 are detected by the current detector CT1 in the U phase, and the power conditioner 10, the magnitude of the output current output from the output side of the inverter circuit 13 is detected by the output current measuring device CT4 in the U phase, and the U phase voltage is read by the voltage input circuit 35A.
[0134]
The U-phase detection current (detection signal) detected by the current detector CT1 is input to the first signal input unit 12b of the control unit 12 via the CT input circuit 15A, and the output current (detected by the output current measuring unit CT4 ( Detection signal) is input to the output signal input unit 12a-1 of the control unit 12, and the U-phase voltage is input from the voltage input circuit 35A to the third signal input unit 12d of the control unit 12 (step G1). .
[0135]
When the control unit 12 compares the power value of the U-phase forward flow with a predetermined level α (α is zero or a power value of zero or more), the power value of the U-phase forward flow is zero. (Step G2), the duration time is measured by the timer function of the control unit 12, and when the predetermined time γ elapses (Step G3), the power conditioner 10 is operated by the reverse power relay function of the control unit 12. Is stopped (step G4). Note that the predetermined time γ is sufficiently longer than the predetermined time β described above.
[0136]
As a result of comparing the power value of the U-phase forward tide and the predetermined level α in step G2, if the power value of the U-phase forward tide is not zero, the duration is set to the predetermined time γ in step G3. If not, the process returns to step G1.
[0137]
Further, as shown in FIG. 7 and FIG. 15 (2), the direction (forward direction or reverse direction) and magnitude of the current flowing through the commercial power system 1 are detected by the current detector CT2 in the W phase, and the power In the conditioner 10, the magnitude of the output current output from the output side of the inverter circuit 13 is detected by the output current measuring device CT5 in the W phase, and the W phase voltage is read by the voltage input circuit 35B.
[0138]
Then, the W-phase detection current (detection signal) detected by the current detector CT2 is input to the second signal input unit 12c of the control unit 12 via the CT input circuit 15B, and the output detected by the output current measuring unit CT5. The current (detection signal) is input to the output signal input unit 12a-2 of the control unit 12, and the W-phase voltage is input from the voltage input circuit 35B to the fourth signal input unit 12e of the control unit 12 (step). H1).
[0139]
When the control unit 12 compares the power value of the W-phase forward current with a predetermined level α (α is a power value of zero or greater than zero), the power value of the W-phase forward power is zero. (Step H2), the duration of the timer function of the control unit 12 is measured, and when the predetermined time γ elapses (Step H3), the power conditioner 10 is operated by the reverse power relay function of the control unit 12. Is stopped (step H4).
[0140]
As a result of comparing the power value of the W-phase forward power and the predetermined level α in Step H2, if the power value of the W-phase forward power is not zero, the duration is set to the predetermined time γ in Step H3. If not, the process returns to step H1.
[0141]
In addition, when the output of the power conditioner 10 is stopped, an abnormal signal can be communicated to an administrator or the like through a contact or a display such as communication or a relay. When the output of the power conditioner 10 is stopped by the relay function, it is also possible to stop the driving of the generator driving engine by a command from the power conditioner 10.
[0142]
As described above, according to the fifth embodiment of the present invention, it is possible to detect CT disconnection by performing control while always flowing a predetermined level α, that is, several A (amperes) in the forward direction. That is, when the state where the forward current value of the CT current is zero continues for a predetermined time, the output of the power conditioner 10 can be stopped.
[0143]
【The invention's effect】
As described above, according to the power conditioner control device of the present invention, when the forward flow current flowing in the load direction from the commercial power system becomes equal to or less than a predetermined current value, the output of the power conditioner is controlled by the control means. The current can be limited.
[0144]
For this reason, even when the load fluctuation is large, it is possible to supply necessary power from the power conditioner without stopping the generator system. Further, since the power conditioner is used in conjunction with the commercial power system, a changeover switch or the like is not required, and the cost can be greatly reduced, and the size of the apparatus can be reduced.
[0145]
Moreover, according to the control method of the power conditioner which concerns on this invention, even if a load fluctuation is large, the control method which can supply required electric power from a power conditioner, without stopping a power generation system is attained. .
[0146]
Further, according to the cogeneration system according to the present invention, it is possible to provide a cogeneration system that can supply necessary power from the power conditioner without stopping the power generation system even when the load fluctuation is large.
[Brief description of the drawings]
FIG. 1 is a configuration explanatory diagram of a cogeneration system having a power conditioner control device (Embodiment 1) according to the present invention.
FIG. 2 is a configuration explanatory diagram of a power conditioner in the control apparatus for the power conditioner according to the present invention.
FIG. 3 is an explanatory diagram of a configuration of a control device (Embodiment 1) of the power conditioner.
FIG. 4 is an operation flowchart of the control device for the power conditioner (Embodiment 1);
FIG. 5 is an operation explanatory diagram with numerical values of the controller of the power conditioner.
FIG. 6 is an operation explanatory diagram with numerical values of the control device of the power conditioner.
FIG. 7 is a diagram illustrating the configuration of a control device (second embodiment) for the power conditioner.
FIGS. 8A and 8B are operation flowcharts of the control apparatus for the power conditioner (Embodiment 2); FIGS.
FIG. 9 is an explanatory diagram of output control in a control device for a power conditioner (Embodiment 1) when one and the other loads are balanced; (2) is explanatory drawing of the output control in the control apparatus (Embodiment 2) of the power conditioner in case one and other loads are balanced.
FIG. 10 is an explanatory diagram of output control in a power conditioner control device (Embodiment 1) when one and other loads are unbalanced. (2) is explanatory drawing of the output control in the control apparatus (Embodiment 2) of a power conditioner in case one and other loads are unbalanced.
FIG. 11 is a diagram illustrating the configuration of a control device for a power conditioner (Embodiment 3) according to the present invention.
FIG. 12 is a configuration explanatory diagram of a power conditioner in the power conditioner control device (Embodiment 3);
FIGS. 13A and 13B are operation flowcharts of the control apparatus for the power conditioner (Embodiment 3); FIGS.
FIGS. 14A and 14B are operation flowcharts of a power conditioner control device (Embodiment 4) according to the present invention. FIGS.
FIGS. 15A and 15B are operational flowcharts of a power conditioner control device according to the present invention (Embodiment 5); FIGS.
FIG. 16 is a configuration explanatory diagram of a protection system in a conventional power conditioner.
FIG. 17 is a configuration explanatory diagram of a protection system in another conventional power conditioner.
[Explanation of symbols]
A Cogeneration system
1 Commercial power system
2 First load (one load)
3 Second load (the other load)
10 Power conditioner
11 Power conditioner body
12 Control unit (MPU) (control means)
12a Output signal input section
12a-1 Output signal input section
12a-2 Output signal input section
12b First signal input section
12c Second signal input section
12d Third signal input section
12e Fourth signal input section
12F signal output section
13 Inverter circuit (power conversion means)
14 Output current detector
15A CT input circuit (AD converter) (U-phase signal input means)
15B CT input circuit (AD converter) (W-phase signal input means)
15C CT input circuit (AD converter)
15D CT input circuit (AD converter)
15E CT input circuit (AD converter)
16 Signal output section
17 U-phase connection line
18 Neutral connection line
19 W-phase connection line
20 Power generation system
31 Heater etc.
32 Heater etc.
33 Switch means
34 Waste heat recovery machine
35A voltage input circuit (voltage input means)
35B Voltage input circuit (voltage input means)
36 Switch means
CT1 Current detector (current transformer)
CT2 Current detector (current transformer)
CT3 Output current measuring instrument (current transformer) (output current detection means)
CT4 Output current measuring instrument (current transformer) (output current detection means)
CT5 Output current measuring instrument (current transformer) (output current detection means)

Claims (9)

A control device for a power conditioner that links power generated by a power generation system to a single-phase three-wire commercial power system,
Independently connect one load between the U phase and the center line O of the three-wire commercial power system and the other load between the W phase and the center line O of the three-wire commercial power system. Connect and
The inverter is
An inverter circuit that converts the power generated by the power generation system into AC power synchronized with the commercial power supplied from the single-phase three-wire commercial power system;
The U-phase to enter the direction and magnitude of U-phase, each current of the W-phase of the commercial power system as a detection signal, a first CT input circuit consisting of W phase respectively,
An output current measuring device for detecting the magnitude of the output current of the power conversion means;
A second CT input circuit for inputting a detection signal of the output current measuring instrument;
A voltage input circuit composed of each of the U phase and the W phase for inputting the U phase and W phase voltages of the commercial power system as detection signals;
The first CT input circuit, the output current measuring device, the second receiving CT input circuit and a signal from the voltage input circuit, power of each supply order tide the both loading direction from the commercial power system Control means for controlling the inverter circuit so as to adjust the output power of the power conditioner when
A control apparatus for a power conditioner, characterized in that it is built in. When the control means compares the forward power and the predetermined power from the first CT input circuit and the voltage input circuit, the forward power is greater than the predetermined power. The inverter circuit is controlled to output the output power as it is without changing the output power, and the inverter circuit is controlled to adjust the output power when the forward power is smaller than the predetermined power. The control apparatus of the power conditioner of Claim 1 . The control means adjusts the output power using, as an input signal, the forward power of the commercial power system, which is the lower power of the forward power of the U phase and the forward power of the W phase. The inverter control device according to claim 1 or 2, wherein the inverter circuit is controlled as described above. A control device for a power conditioner that links power generated by a power generation system to a single-phase three-wire commercial power system,
Independently connect one load between the U phase and the center line O of the three-wire commercial power system and the other load between the W phase and the center line O of the three-wire commercial power system. Connect and
The inverter is
An inverter circuit that converts the power generated by the power generation system into AC power synchronized with the commercial power supplied from the single-phase three-wire commercial power system;
A first CT input circuit composed of the U phase and the W phase for inputting the directions and magnitudes of the currents of the U phase and W phase of the commercial power system as detection signals;
An output current measuring device comprising the U phase and the W phase for detecting the magnitude of the output current of the power conversion means;
A second CT input circuit for inputting a detection signal of the output current measuring instrument;
A voltage input circuit composed of each of the U phase and the W phase for inputting the U phase and W phase voltages of the commercial power system as detection signals;
Receiving signals from the first CT input circuit, the output current measuring instrument, the second CT input circuit, and the voltage input circuit, respectively, from the U phase and W phase of the commercial power system to both load directions. Control means for adjusting the output current of the power conditioner for each of the U-phase and W-phase of the commercial power system when the forward power supplied is equal to or lower than a predetermined power;
A control apparatus for a power conditioner , characterized in that it is built in . It said control means, the result of comparing the U-phase of the first CT input circuit of the forward power flow input power and said predetermined power, when the power of the forward power flow is greater than the predetermined power , Controlling the inverter circuit to output as it is, and controlling the inverter circuit to adjust the output power of the U phase when the forward power is smaller than the predetermined power,
As a result of comparing the forward power and the predetermined power input by the W-phase first CT input circuit, if the forward power is greater than the predetermined power, the power is output as it is. according to control said inverter circuit, when the power of the forward power flow is less than the predetermined power, which is characterized by being configured to control said inverter circuit so as to adjust the output power of the W-phase Item 5. A power conditioner control device according to Item 4 . A control device for a power conditioner that links power generated by a power generation system to a single-phase three-wire commercial power system,
Independently connect one load between the U phase and the center line O of the three-wire commercial power system and the other load between the W phase and the center line O of the three-wire commercial power system. Connect and
The inverter is
An inverter circuit that converts the power generated by the power generation system into AC power synchronized with the commercial power supplied from the single-phase three-wire commercial power system;
A first CT input circuit composed of the U phase and the W phase for inputting the directions and magnitudes of the currents of the U phase and W phase of the commercial power system as detection signals;
An output current measuring device for detecting the magnitude of the output current of the power conversion means;
A second CT input circuit for inputting a detection signal of the output current measuring instrument;
A voltage input circuit composed of each of the U phase and the W phase for inputting the U phase and W phase voltages of the commercial power system as detection signals;
As a result of comparing the forward power supplied in the one load direction from the commercial power system inputted by the first CT input circuit of each of the U phase and the W phase with a predetermined power, the forward power is When the power is larger than the predetermined power, the inverter circuit is controlled to output the current as it is. When the forward power is smaller than the predetermined power, electric energy other than that consumed by the two loads is used. Control means for controlling the inverter circuit so as to supply a load other than both loads;
Power conditioner control apparatus characterized by being configured built. A control device for a power conditioner that links power generated by a power generation system to a single-phase three-wire commercial power system,
Independently connect one load between the U phase and the center line O of the three-wire commercial power system and the other load between the W phase and the center line O of the three-wire commercial power system. Connect and
The inverter is
An inverter circuit that converts the power generated by the power generation system into AC power synchronized with the commercial power supplied from the single-phase three-wire commercial power system;
The U-phase to enter the direction and magnitude of U-phase, each current of the W-phase of the commercial power system as a detection signal, a first CT input circuit consisting of W phase respectively,
An output current measuring device for detecting the magnitude of the output current of the power conversion means;
A second CT input circuit for inputting a detection signal of the output current measuring instrument;
A voltage input circuit composed of each of the U phase and the W phase for inputting the U phase and W phase voltages of the commercial power system as detection signals;
In response to signals from the first CT input circuit, the output current measuring instrument, the second CT input circuit, and the voltage input circuit, the reverse power flowing from the both load directions to the commercial power system has a predetermined power. Control means for controlling to stop the output of the power conditioner when it becomes the above ,
A control apparatus for a power conditioner, characterized in that it is built in. The control means has a timer function that measures the duration of the reverse power flow, and a reverse power relay function that stops the output of the power conditioner when the duration of the reverse power flow passes a predetermined time,
When the reverse power flow becomes equal to or higher than a predetermined power, the control means measures the reverse power flow duration and stops the output of the power conditioner when the reverse power flow duration has passed a predetermined time. The control apparatus for a power conditioner according to claim 7 , wherein the inverter circuit is controlled to do so . A control device for a power conditioner that links power generated by a power generation system to a single-phase three-wire commercial power system,
Independently connect one load between the U phase and the center line O of the three-wire commercial power system and the other load between the W phase and the center line O of the three-wire commercial power system. Connect and
The inverter is
An inverter circuit that converts the power generated by the power generation system into AC power synchronized with the commercial power supplied from the single-phase three-wire commercial power system;
A first CT input circuit composed of the U phase and the W phase for inputting the directions and magnitudes of the currents of the U phase and W phase of the commercial power system as detection signals;
An output current measuring device for detecting the magnitude of the output current of the power conversion means;
A second CT input circuit for inputting a detection signal of the output current measuring instrument;
A voltage input circuit composed of each of the U phase and the W phase for inputting the U phase and W phase voltages of the commercial power system as detection signals;
The commercial signal received from the first CT input circuit, the output current measuring instrument, the second CT input circuit, and the voltage input circuit and input to the U-phase and W-phase first CT input circuits. A timer function for measuring the duration when it is detected that the power value of the forward power supplied from the power system to the one load direction has become zero, and the power conditioner when the predetermined time has elapsed Control means having a reverse power relay function to stop the output of
Built-in,
The control means measures the forward power flow duration time by the control means when the power value of the forward power flow becomes zero, and outputs the output of the power conditioner when the forward power flow duration time has passed a predetermined time. controller of power conditioners characterized by being configured to perform control of stopping.

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