KR101456475B1 - Photovoltaic power generating system with dual inverters and method for controlling thereof - Google Patents

Abstract

The present invention relates to a stand-alone solar power generation system having a dual inverter, and more particularly, to a stand-alone solar power generation system having a dual inverter, A solar cell array 10 comprising: A charge controller (20) for outputting electrical energy output from the solar cell array to a storage battery; A battery unit (30) connected to the charge controller and including a battery for storing electric energy output from the charge controller; A first inverter (40) connected to the charge controller, which receives electric energy from the charge controller and converts the electric power into a predetermined AC power and outputs the converted AC power; A second inverter (50) connected to the battery unit to receive electric energy from the battery and convert it into AC power and output the AC power; And a data control unit (60) for controlling the operation of the charge controller, the first inverter and the second inverter, wherein the data control unit (60) is configured to output the AC power converted from the first inverter and the second inverter And controls the operation of the charge controller, the first inverter, and the second inverter so as to selectively provide at least one to the load.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a stand-alone solar power generation system having a dual inverter and a control method thereof,

The present invention relates to a solar power generation system and a control method thereof, and more particularly, to a stand-alone solar power generation system having a dual inverter and a control method thereof.

Solar power generation is clean energy with no pollution such as air pollution, noise, heat and vibration compared with other power generation. It is almost unnecessary to maintain the transportation and power generation facilities of fuel and long lifetime of equipment, It is easy to construct, and due to the global warming and Japanese nuclear power plant accidents, there is a growing concern about the existing fossil energy and nuclear energy, and as the interest in safe and environment friendly renewable energy is being amplified, And the creation of high added value.

A photovoltaic power generating system converts solar energy into electrical energy using photovoltaic cells using photovoltaic effects, and a device configured to supply power suitable for the load, All.

Solar power generation system is divided into stand-alone type and grid-type solar power generation system generally according to the operation mode, and stand-alone solar power generation system is divided into isolated areas where commercial power is not available, such as book areas, And generally comprises a solar cell module, a charge controller, an inverter, and a battery.

The general stand-alone solar power generation system of FIG. 1 includes a solar cell array including a plurality of solar cell modules for converting incident solar energy into electric energy; A charge regulator for storing electrical energy output from the solar cell array in a capacitor; A battery for storing electrical energy output from the charge regulator; An inverter for converting the direct current electric energy from the rechargeable battery into an alternating current and supplying the alternating current to the load; And a controller for controlling the charge regulator and the inverter.

In the general solar power generation system as described above, since the intensity of the sunlight fluctuates depending on the weather and the time zone, the electric energy from the solar cell array is not directly supplied to the load due to the limit that can not supply a constant power to the load, And it is converted into alternating current required by the load and supplied.

The conventional solar photovoltaic power generation system is designed to supply stable power to a load by using a battery. However, when the intensity of sunlight is continuously changed irregularly, the battery can not be used as a reference voltage for charging and discharging The life of the battery is shortened and the stable power source can not be supplied to the load, thereby damaging the load. Further, the performance of all or a part of the configuration of the solar power generation system such as an inverter is deteriorated, and the service life of the entire system or configuration is shortened.

In addition, as in the following patent document "Control device and control method for power regulator for photovoltaic power generation ", it is possible to check the voltage of the solar cell and the storage battery which supply power to the load in real time to prevent damage to the battery and load There is a technique for shortening the lifetime of the battery and supplying a stable power source. However, this technique is also applied to a case where excessive solar radiation is incident or the battery is overcharged or overdischarged on the side of the battery, And a structure for preventing the load from being damaged, and still has a problem of shortening the lifetime of the above-described battery in a normal operation state or supplying an unstable power source.

Korean Patent Registration No. 10-0452967 "Control Apparatus and Control Method of Power Regulator for Photovoltaic Power Generation"

SUMMARY OF THE INVENTION It is therefore an object of the present invention to solve the above problems of the prior art and to solve the problem of shortening the lifespan of a battery due to repetition of charging / discharging of a stand-alone photovoltaic power generation system, supplying a stable power to a load, And to provide a stand-alone solar power generation system having a dual inverter that prolongs the performance life of the system and a control method thereof.

In order to achieve the above object, the present invention relates to a stand-alone solar power generation system having a dual inverter, comprising: a solar cell array (10) comprising at least one solar cell module for converting incident solar energy into electric energy; A charge controller (20) for outputting electrical energy output from the solar cell array to a storage battery; A battery unit (30) connected to the charge controller and including a battery for storing electric energy output from the charge controller; A first inverter (40) connected to the charge controller, which receives electric energy from the charge controller and converts the electric power into a predetermined AC power and outputs the converted AC power; A second inverter (50) connected to the battery unit to receive electric energy from the battery and convert it into AC power and output the AC power; And a data control unit (60) for controlling the operation of the charge controller, the first inverter and the second inverter, wherein the data control unit (60) is configured to output the AC power converted from the first inverter and the second inverter And controls the operation of the charge controller, the first inverter, and the second inverter so as to selectively provide at least one to the load.

Preferably, the data control unit 60 measures the power consumption state of the load, stops the operation of the first inverter when the power consumption of the load is equal to or more than the electric energy output from the solar cell array, To be operated.

Preferably, the data control unit 60 measures the power consumption state of the load, stops the second inverter when the power consumption of the load is less than the electric energy output from the solar cell array, Respectively.

Here, it is preferable that the data control unit 60 controls the charge controller such that an excess power (PS-PL) which is a difference between the electric energy output from the solar cell array and the power consumption of the load is charged in the battery unit .

Preferably, the data control unit 60 controls the first inverter and the second inverter to stop when the power consumption state of the load is measured and it is determined that the load is no-load state.

The data control unit (60) further includes a communication unit (61) for acquiring power generation status information including information on electric energy output from the solar cell array from the charging controller and transmitting a control command to the charging controller; An inverter operation control section (62) for controlling the operation of the first inverter and the second inverter; An AC power supply (63) controlled to provide at least one of the AC power converted from the first inverter and the second inverter to the load; A microcontroller (64) for controlling the operation of the inverter operation control unit and the AC power supply unit by analyzing the power generation status information and controlling the charge controller by controlling the operation of the inverter operation control unit and the AC power supply unit to generate the control command and transmitting the generated control command to the charge controller via the communication unit; And a power consumption state measuring unit (65) for detecting a current and a voltage supplied to a load necessary for calculation of power consumption consumed in the load and transmitting the detected current and voltage to the microcontroller (64). The microcontroller (64) Determines the power consumption state based on the power consumption calculated from the generated current and voltage, and controls the operation of the first inverter and the second inverter according to the electric energy output from the solar cell array included in the power generation state information and the power consumption state As shown in FIG.

The inverter operation control unit 62 includes a relay circuit for controlling the DC power supplied to the first inverter and the second inverter to be on or off according to the control of the microcontroller 64 .

According to another aspect of the present invention, there is provided a method of controlling a stand-alone solar power generation system having a dual inverter, comprising the steps of monitoring a solar array output power (S10 ); A power consumption state monitoring step (S20) of measuring a power consumption of a load connected to the photovoltaic power generation system and determining a power consumption state of the load; A dual inverter controlling the operation of the first inverter and the second inverter and the charging / discharging of the electric energy of the storage battery based on the measured solar array output power and the power consumption state, and a battery charge / discharge control step S30); And a load power supply control step (S40) of supplying alternating-current power output from at least one of the first inverter and the second inverter to the load.

Here, when the power consumption of the load is less than the electric energy output from the solar cell array in the dual inverter and battery charge / discharge control step S30, the operation of the second inverter is stopped and the first inverter is operated The dual inverter and the battery charging / discharging control step S30 may be performed such that the power storage unit is charged with surplus power (PS-PL) which is a difference between the electric energy output from the solar cell array and the power consumption of the load It is more preferable to control it.

As described above, according to the present invention, it is possible to solve the problem of shortening the lifetime of the battery of the independent photovoltaic power generation system due to repetition of charge / discharge, to prolong the service life of the battery, It is possible to provide a stand-alone photovoltaic power generation system in which the service life of the respective components is extended and the performance life is prolonged.

Specifically, an inverter separate from an inverter connected to a battery, which is independent of the power supply of the battery, is actively controlled according to the power consumption state of the load, thereby controlling the operation of the inverter connected to the battery and the charging / By reducing the number of times, the useful life of the battery and stable supply of power can be achieved.

1 is a schematic configuration diagram of a conventional stand-alone solar power generation system.
2 is a configuration diagram of a stand-alone solar power generation system having a dual inverter according to an embodiment of the present invention.
3 is a functional block diagram of a data control unit according to an embodiment of the present invention.
4 is a circuit diagram illustrating an embodiment of a communication unit of a data control unit according to an exemplary embodiment of the present invention.
5 is an implementation circuit diagram of an inverter operation control unit of a data control unit according to an embodiment of the present invention.
6A is a view for explaining the operation principle of the power consumption state measuring unit of the data control unit according to the embodiment of the present invention.
6B is an implementation circuit diagram of a data control unit according to an embodiment of the present invention.
7 is a view for explaining the inverter operation control condition of the data control unit according to the embodiment of the present invention.
8 is a flowchart of a method of controlling a stand-alone solar power generation system having a dual inverter according to the present invention.
9 is a detailed control flowchart of a stand-alone solar power generation system having a dual inverter according to an embodiment of the present invention.
10 is a configuration example of a solar cell array used in an embodiment of the present invention.

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

These embodiments are described in sufficient detail to enable those skilled in the art to practice the invention. It should be understood that the various embodiments of the present invention are different, but need not be mutually exclusive. For example, certain features, structures, and characteristics described herein may be implemented in other embodiments without departing from the spirit and scope of the invention in connection with an embodiment. It is also to be understood that the position or arrangement of the individual components within each disclosed embodiment may be varied without departing from the spirit and scope of the invention. The following detailed description is, therefore, not to be taken in a limiting sense, and the scope of the present invention is to be limited only by the appended claims, along with the full scope of equivalents to which the claims are entitled, if properly explained. In the drawings, like reference numerals refer to the same or similar functions throughout the several views.

<Independent Solar Power Generation System with Dual Inverters>

2 is a configuration diagram of a stand-alone solar power generation system having a dual inverter according to an embodiment of the present invention.

Referring to FIG. 2, a stand-alone solar power generation system equipped with a dual inverter of the present invention will be described with reference to embodiments.

INDUSTRIAL APPLICABILITY A stand-alone solar photovoltaic power generation system with a dual inverter according to the present invention includes a solar cell array (10) comprising at least one solar cell module for converting incident solar energy into electric energy, an electric energy output from the solar cell array , A battery (30) connected to the charging controller and including a battery for storing electric energy outputted from the charging controller, and a battery controller (30) connected to the charging controller and receiving electric energy from the charging controller A second inverter (50) connected to the battery unit for receiving electric energy from the battery and converting the AC power into AC power and outputting the AC power, and a controller A data control unit (6) for controlling the operation of the first inverter and the second inverter 0).

The solar cell array 10 includes at least one solar cell module that converts incident solar energy into electric energy, and a plurality of solar modules are connected in a serial / parallel manner to form a solar cell An array is constructed.

10 is a configuration example of a solar cell array used in an embodiment of the present invention. In the case of the solar cell array of FIG. 10, two solar modules of production power are connected in series, As shown in FIG. 10, the maximum production power is Pmax (maximum power) = 15.86 A x 60.6 v = 961 watts, and a solar cell array of approximately 1 kw class is constructed.

The charge controller 20 basically functions to output the electric energy output from the solar cell array to the accumulator 30 so as to store the electric energy in the accumulator, and in accordance with the control command of the data control unit 60, And the electric energy outputted from the solar cell array is outputted without interrupting the supply of the electric energy to the accumulator unit 30 or the supply of the electric energy to the accumulator unit 30, The power consumed by the load is output to the first inverter and the remaining power is supplied to the battery unit 30 and stored in the battery.

The charge controller acquires power generation status information including information on electric energy output from the solar cell array serving as a basis of operation control of the data control unit (60), and transmits the power generation status information to the data control unit (60).

The power generation status information acquired by the charge controller 20 and provided to the data control unit 60 basically includes the generation voltage of the solar photovoltaic array and the generation current of the solar photovoltaic array, and the battery voltage (battery voltage) (Charge current), the battery temperature, the heat sink temperature of the charge controller, the power consumption (power consumption) of the power currently produced in the solar cell array, the PWM duty Battery charging is performed by PWM), and the like.

In addition, when an overvoltage sensing circuit (not shown) is provided and excessive cumulative sunlight is incident during operation, that is, when a cumulus cloud cloud is formed due to a change in climate, It is desirable to be configured to sense the voltage at the charge controller at the moment when the intensity of sunlight reaches up to 1400 watts / sec and protect the entire system by shutting off the current.

    In addition, when the charging controller 20 supplies power to the battery unit, it is possible to supply a voltage in a pulse form without supplying a constant constant voltage, thereby limiting the power to be charged. That is, And the electric energy output from the solar cell array is stored in the battery by PWM (Pulse Width Modulation) method which can control the charging to be performed while protecting the battery so as not to overcharge by reducing the pulse width (duty ratio)

In addition, the MPPT charging method, that is, the maximum power tracking method, can be configured to store electric energy output from the solar cell array in a battery. Unlike the ON / OFF method or the PWM method, the MPPT charging method is a method of obtaining the maximum charging efficiency by matching the voltage of the electricity generated in the solar cell with the voltage of the battery.

Furthermore, according to the above-described (1) requirements for overvoltage, overcurrent prevention and protection as well as the environment of use, (2) reverse current prevention function (battery voltage is generated in the solar battery on a cloudy day or night In order to prevent this, a blocking diode should be connected in series so that electricity always flows from the solar cell array to the battery only. ) Overcharge and overvoltage (LVD) protection function (ie, when the battery is overcharged and the battery voltage becomes excessively high, the water in the electrolyte inside the battery is decomposed into oxygen and hydrogen, and gas is generated. In this process, It is possible that the battery will explode or the battery will deteriorate and the service life will be shortened rapidly. In addition, due to the characteristics of the battery, the life of the battery will be shortened if it is consumed below the reference voltage. By adding the overdischarge prevention function (LVD function), the voltage of the battery (4) Overload protection function (that is, the charge controller is connected to the data control unit when a constant current or more flows). (5) Night and day separation (nighttime) function (6) Battery status display function (led) (7) Status data transmission function using RS-232C (8) It is desirable to implement at least one of the functions of temperature compensating function (compensation of 0.05V each deviation of deviation from standard temperature).

The battery unit 30 includes a battery and is connected to the charge controller to store electric energy output from the charge controller. The charge is controlled by the charge controller, and the second inverter, which will be described later, When the inverter is controlled to operate, it discharges the stored electric energy to the load side. Lead-acid batteries, lithium-ion batteries, and the like. The capacities of the secondary batteries can be 3 ~ 3 kW, which is larger than the maximum power of the solar cell array, for example, A battery of 4Kw capacity is used.

In addition, the battery unit 30 may be implemented to measure the status information of the battery unit by the data control unit 60 and provide the measured information in the form of data. In this case, status information of the battery unit in the form of data includes, for example, the total battery pack voltage (for example, 26.12, unit: [V]) constituting the battery, the battery pack charge / discharge current (for example, -123.3, ), The voltage of the cell with the highest voltage (for example: 3.738, unit [V]), the voltage of the cell with the lowest voltage (for example: 3.729 units: Over Temperature Overheat Overheat Overcharge Overcharge Overcharge Overcharge Overcharge Overcharge Overcharge Overcharge Overcharge Overload Overcharge Overload Overcharge Overload Overcharge Byte (0 is normal, 1 is overcharge), Under Voltage_1 Byte (0 is normal, 1 is charge alarm), Under Voltage_2 Byte (0 is normal, 1 is over discharge), Voltage deviation Voltage Gap) Byte (0 is normal, 1 is abnormal), Over Temperature Byte (0 is normal, 1 is overheated), Over Current Byte (0 is normal, 1 is overcurrent) 0 is normal, 1 is abnormal), etc. Lt; / RTI &gt;

1, the first inverter 40 of the present invention is connected to a charge controller without passing through a storage battery, receives electric energy from the charge controller, converts it into a predetermined AC power And outputs it. The operation of the first inverter (operation or stop) is determined based on the electric energy output from the solar cell array by the data control unit and the power consumption state of the load, and is controlled accordingly.

That is, when the load is connected to the first inverter 40 and the power of the load is consumed (when the load is not in a no-load state), the power consumption PL of the measured load is the power PS of the electric energy output from the solar cell array. The supply of electric energy to the load is performed from the battery unit and the second inverter is operated. In the no-load state, the first inverter is controlled to stop operating with the second inverter.

On the other hand, when the measured power consumption PL of the load is less than the power PS of the electric energy output from the solar cell array, the first inverter is activated, and the surplus power PS-PL is charged to the accumulator Respectively.

The second inverter (50) is connected to the battery unit, receives electric energy from the battery, converts the AC power into AC power, and outputs the converted AC power. Like the first inverter, the second inverter (operation or stop) And is determined and controlled based on the output electric energy and the power consumption state of the load.

That is, when the load is connected to the second inverter 50 and the power of the load is consumed (when the load is not in a no-load state), the power consumption PL of the measured load is equal to the power PS of the electric energy output from the solar cell array. , The operation is stopped. In this case, the electric energy is supplied to the load directly from the charge controller and the first inverter is activated. In the no-load state, the second inverter is controlled to stop operating with the first inverter.

The operation of the second inverter means the discharge of the electric energy stored in the battery, and the second inverter operates when the use of the electric energy stored in the battery is necessary. When the operation of the second inverter including the no-load state is stopped, the storage battery of the storage battery is controlled to be charged.

In addition, when the power consumption of the load exceeds the output power of the solar cell array and exceeds the output power of the battery, the power of the electric energy stored in the accumulator is larger than the output power of the solar cell array. Both of the inverters may be operated and temporarily or temporarily controlled in such a manner that the output power of the solar cell array and the electric energy stored in the battery are simultaneously supplied to the load in a time range.

 A data control unit (60) controls the operation of the charge controller, the first inverter and the second inverter and controls the charging of the charge controller, the first inverter and the second inverter so as to selectively provide at least one of the AC power converted from the first inverter and the second inverter A controller, and an operation of the first inverter and the second inverter.

The power consumption of the load is calculated from the electric energy output from the solar cell array included in the power generation status information acquired by the charge controller 20 and the current and voltage value supplied to the measured load of the load, And controls the operation of the first inverter and the second inverter by comparing the power and the power consumption of the load.

Namely, it is possible to classify the power consumption state of the first inverter and the second inverter in accordance with the power consumption state, from the no-load state, the solar cell array output power state, And controls the operation. In addition, it controls the charge / discharge of the battery, which is implemented through control of the charge controller and / or the second inverter according to the embodiment.

Further, according to the embodiment, the charge / discharge can be controlled by directly controlling the battery unit. As a result, the service life of the battery can be extended, stable and efficient power supply can be provided, and energy utilization efficiency can be improved.

An implementation example of the control method of the first inverter and the second inverter according to the power generation status information and the power consumption state in the data control unit 60 is shown in Fig.

      FIG. 3 is a functional block diagram of a data control unit according to an embodiment of the present invention, FIG. 4 is an implementation circuit diagram of a communication unit of a data control unit according to an embodiment of the present invention, and FIG. FIG. 6A is a view for explaining the operation principle of the power consumption state measuring unit of the data control unit according to the embodiment of the present invention, FIG. 6B is a diagram for explaining an operation of the inverter control unit of the data control unit according to an embodiment of the present invention 7 is a view for explaining inverter control conditions of a data control unit according to an embodiment of the present invention

3 to 7, a specific embodiment of the data control unit will be described. The data control unit is defined according to functions, not physically separated. Depending on the embodiment, some of the functional blocks of the data control unit are implemented as self-functions of the charge controller 20 and the battery unit 30, The controller 20 and the battery unit 30, or may be implemented as a separate circuit or function unit.

3, the data control unit 60 includes a communication unit 61 that acquires power generation status information including information on electric energy output from the solar cell array from the charge controller, and transmits a control command to the charge controller, An inverter operation control section 62 for controlling operations of the first inverter and the second inverter, an AC power supply section 63 controlled to provide at least one of the AC power converted from the first inverter and the second inverter to the load, And a microcontroller (64) for controlling the operation of the inverter operation control unit and the AC power supply unit by analyzing the power generation status information and generating the control command and transmitting the generated control command to the charge controller through the communication unit.

And a power consumption state measuring unit 65 for measuring the power consumption state for measuring the connection state of the load and the power consumption consumed in the load.

The communication unit 61 is implemented by a circuit as shown in FIG. 4. Basically, the communication unit 61 receives power generation state information including information on electric energy output from the solar cell array from the charge controller in the form of data or signal, And transmits the control command generated by the microcontroller 64 to the charge controller. As described above, the status information of the battery unit is received.

The inverter operation control section 62 for controlling the operations of the first inverter and the second inverter controls the relay circuits connected to the first inverter and the second inverter in accordance with the control command in the form of control signals generated by the microcontroller 64, And a relay driving circuit as shown in Fig. 5 for turning on / off the DC power supplied to at least one of the charging controllers of the inverter or from the battery.

According to the embodiment, the inverter operation control section 62 for controlling the operation of the first inverter and the second inverter may control the operation of the first inverter and the second inverter in accordance with the control command in the form of the control signal generated by the microcontroller 64 Or may be implemented in such a manner as to turn on / off the power connection of one or more output terminals. In this case, the operation of the first inverter and the second inverter is controlled together with the selective supply of the AC power according to the on / off state of the output stage.

The AC power supply unit 63, which is controlled to supply at least one of the AC power converted from the first inverter and the second inverter to the load, receives the converted AC power of the first inverter and the second inverter, And controls the operation of the first inverter and the second inverter, that is, the on / off of the direct current power supplied to the charge controller by the first inverter and the on / off of the direct current supplied to the charge controller by the first inverter, And is operated in conjunction with control for turning on / off the DC power supplied from the battery unit to the two inverters.

Depending on the embodiment, the AC power supply 63 may be implemented in the form of a simple power interface that passively transfers AC power supplied from one or more of the first and second inverters to the load, and the microcontroller 64 Contact AC switches actively associated with the operation of the first inverter and the second inverter to selectively provide one or more alternating current powers of the first inverter and the second inverter to the load.

On the other hand, the on / off operation of the input or the output power of the first inverter and the second inverter and the switching of the AC power supplied to the load by the on / off operation of the multi-contact AC switch must be considered a time delay. As for the temporal delay, the AC voltage of the AC power is changed to the opposite polarity (+, -) of the voltage 60 times per second (60 Hz). As another characteristic, AC voltage of AC 220 V / 60 Hz In the case of power, the voltage also changes to a sinusoidal curve with time. 7A, that is, when the AC power is cut off at the time when the AC voltage is 0 volt (zero cross point) when the AC power is cut off at the time of load, that is, when the AC power is consumed, Since the power is cut off, there is no electric damage to the inverter and the load body is not damaged. If the switch is turned on when the AC voltage crosses zero volts, the voltage gradually increases from 0 volts (soft start), so that the initial power supply to the load The burden on the load can be minimized.

If you need to turn off your device and turn it back on without any problems, you will need to turn off the zero cross and turn on the next zero cross immediately. As in the ideal power off time of AC 220v / 60Hz in FIG. 7B, the time to turn off the OFF command and the actual power OFF time will be within 1/120 sec, which is 1/60 sec that is close to the maximum half period, The command may be issued but it will be off within 8.33msec.

In addition, if the power-off command is issued and the power is turned off within 8.33 msec and the power-on command is issued again after a maximum delay time of 8.33 msec, an ideal power-on time of AC220v / The power will be turned on. 8.33msec + 8.33msec = 16.66msec is required for the power on / off switching time. Zero cross is applied to switch the AC switch to protect the equipment. Therefore, since the AC voltage fluctuation is 60 Hz, the voltage is switched at zero crossing point passing 0 volt. Therefore, switching is performed after 16.66 msec, which is the maximum 1 / 60Hz time, after the switch-on command is executed.

Therefore, in the case of switching the inverter that provides the AC output to the load by the relay operation circuit and / or the multi-contact AC switch (i.e., the AC power output from the second inverter to supply the AC power output from the first inverter Contact AC switch in the above-mentioned zero-cross-off state after a lapse of a predetermined delay time after the operation stop instruction of the inverter to be turned off and the operation instruction of the inverter to be turned on are performed Is preferably controlled.

The microcontroller 64 controls the operation of the inverter operation control unit and the AC power supply unit by analyzing the power generation status information, and generates the control command so that the control command is transmitted to the charge controller through the communication unit. The power consumption state is determined based on the electric energy output from the array and the electric power supplied from the electric power supplied to the measured load necessary for the calculation of the electric power consumed in the load provided by the electric power consumption state measuring unit 65 and the electric power calculated from the voltage Thereby controlling the operation of the first inverter and the second inverter and the charge / discharge of the battery. The power consumption state can be classified into no-load state, less than solar cell array output power state, and solar cell array output power abnormality state. In the no-load state, when the power consumption is zero or the minimum detectable power, It can be judged as a no-load state.

The power consumption state measuring unit 65 detects the current and voltage supplied to the load necessary for calculating the power consumption consumed in the load and transmits the detected current and voltage to the controller 64. The current measurement is performed by the current transformer CT 9, a voltage sensing circuit as shown in FIG. 9 is implemented to detect a voltage, and the voltage is detected by a microcontroller 64 . Depending on the embodiment, it may be configured to calculate the power consumption based on the measured current and voltage, and then to transmit it to the microcontroller 64. [

&Lt; Control method of independent solar power generation system equipped with dual inverter >

Hereinafter, a method of controlling a stand-alone solar power generation system equipped with a dual inverter according to the present invention will be described in the scope of not overlapping with the description of the embodiment of the system with reference to the drawings.

8 is a flowchart of a method of controlling a stand-alone solar power generation system having a dual inverter according to the present invention.

Referring to FIG. 8, the method of controlling a stand-alone solar power generation system having a dual inverter according to the present invention measures a solar array output power, which is electric energy output from a solar array, and measures the measured solar array output power (S20) for monitoring the power consumption of the load by measuring the power consumption of the load connected to the photovoltaic power generation system and monitoring the power consumption state of the load, A dual inverter and a battery charge / discharge control step (S30) for controlling operation of the first inverter and the second inverter and charging / discharging of electric energy of the storage battery based on the array output power and the power consumption state; And a load power supply control step (S40) of supplying alternating-current power output from at least one of the first inverter and the second inverter to the load, wherein the performance of each step is performed in accordance with an embodiment of the present invention, Each of the constitutions of the independent photovoltaic power generation system equipped with the inverter and the organic operation thereof.

In the dual inverter and battery charging / discharging control step (S30), when the power consumption of the load is less than the electric energy output from the solar cell array, the second inverter stops operating and controls the first inverter to operate, The dual inverter and battery charging / discharging control step S30 is preferably performed such that surplus power (PS-PL), which is a difference between the electric energy output from the solar cell array and the power consumption of the load, is charged in the battery.

 FIG. 9 is a control flowchart of a stand-alone solar power generation system having a dual inverter according to an embodiment of the present invention, and corresponds to an embodiment of a method of controlling a stand-alone solar power generation system having a dual inverter of the present invention.

9, the process of measuring the output of the solar array is included in the power generation status information through the charge controller 20 and is transmitted to the data control unit 60. The data control unit 60 includes the power generation status information The power consumption state is determined from the output power PS of the electric energy output from the solar cell array and the load power consumption PL calculated and measured, and in the no-load state, the operation of the first inverter and the second inverter is stopped , And controls the charge controller to supply electric energy to the battery to perform charging.

When the power consumption state is not a no-load state, the solar cell array output power PS and the load power consumption PL are compared. If the load power consumption PL is equal to or greater than the solar cell array output power PS, And the second inverter is operated so that electric energy stored in the battery is discharged and supplied to the load. When the power consumption state during operation is changed to exceed the solar cell array output power, the operation switching and charge / discharge of each inverter are controlled to be actively converted.

On the other hand, when the load power consumption PL is less than the solar cell array output power PS by comparing the solar cell array output power PS and the load power consumption PL, the second inverter is stopped and the first inverter is operated The output power of the solar cell array is directly supplied to the load through the charge controller. In this case, the surplus power (PS-PL) is transferred to the battery unit to control the charge controller to be used for charging the battery. When the power consumption state during operation is changed to be less than the solar cell array output power, the operation switching and charge / discharge of each inverter are controlled to be actively converted.

The above-described control based on the measurement of the output power of the solar array, the measurement of the power consumption of the load, and the control of the power consumption state can be performed simultaneously or sequentially so that the change of the output of the solar array and the power consumption state The photovoltaic generation system can be controlled so as to actively respond to the change of the photovoltaic power generation system.

10: solar cell array 20: charge controller
30: capacitor section 40: first inverter
50: Second inverter 60: Data control unit

Claims (10)

In a stand-alone solar power generation system equipped with a dual inverter,
A solar cell array (10) comprising at least one solar cell module for converting incident solar energy into electric energy;
A charge controller (20) for outputting electrical energy output from the solar cell array to a storage battery;
A battery unit (30) connected to the charge controller and including a battery for storing electric energy output from the charge controller;
A first inverter (40) connected to the charge controller, which receives electric energy from the charge controller and converts the electric power into a predetermined AC power and outputs the converted AC power;
A second inverter (50) connected to the battery unit to receive electric energy from the battery and convert it into AC power and output the AC power; And
And a data control unit (60) for controlling the operation of the charge controller, the first inverter and the second inverter, wherein the data control unit (60) comprises one of the AC power converted from the first inverter and the second inverter The first inverter and the second inverter so as to selectively provide the load to the load,
The data control unit (60)
A communication unit (61) for acquiring power generation status information including information on electric energy output from the solar cell array from the charging controller and transmitting a control command to the charging controller;
An inverter operation control section (62) for controlling the operation of the first inverter and the second inverter;
An AC power supply (63) controlled to provide at least one of the AC power converted from the first inverter and the second inverter to the load;
A microcontroller (64) for controlling the operation of the inverter operation control unit and the AC power supply unit by analyzing the power generation status information and controlling the charge controller by controlling the operation of the inverter operation control unit and the AC power supply unit to generate the control command and transmitting the generated control command to the charge controller via the communication unit; And
And a power consumption state measuring unit (65) for detecting a current and a voltage supplied to a load necessary for calculation of power consumption consumed in the load and transmitting the detected current and voltage to the microcontroller (64). The microcontroller (64) And a controller for controlling the operation of the first inverter and the second inverter according to the electric energy output from the solar cell array included in the power generation state information and the power consumption state, Wherein the control unit controls the first inverter and the second inverter. The method according to claim 1,
The data control unit 60 measures the power consumption state of the load and controls the first inverter to stop operating when the power consumption of the load is equal to or greater than the electric energy output from the solar cell array, Wherein the solar cell is a solar cell. The method according to claim 1,
The data control unit 60 measures the power consumption state of the load and stops the second inverter when the power consumption of the load is less than the electric energy output from the solar cell array to control the first inverter to operate Wherein the solar cell is a single solar cell. The method of claim 3,
Wherein the data control unit (60) controls the charge controller so that a surplus power (PS-PL) which is a difference between electric energy output from the solar cell array and the power consumption of the load is charged in the battery unit Independent photovoltaic power generation system having an inverter. The method according to claim 1,
Wherein the data control unit (60) controls the first inverter and the second inverter to stop when the power consumption state of the load is determined to be no-load state. delete The method according to claim 1,
The inverter operation control unit 62 includes a relay circuit for controlling the DC power supplied to the first inverter and the second inverter to be on or off according to the control of the microcontroller 64, And a second inverter connected to the second inverter. delete delete delete

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