KR101225198B1 - Grid connected power conversion system - Google Patents

Abstract

The present invention relates to a system-linked power conversion system, which is installed between a renewable energy generator and a grid power supply, converts the power supplied from the renewable energy generator into a voltage for supplying the grid power, and generates the renewable energy generator. Or a power converter for charging or discharging the electric power supplied from the grid power supply; Installed between the power converter and the grid power supply, the system power is cut off or connected according to the abnormality of the grid power supply, and for detecting the synchronization time for connecting the grid power supply and the renewable energy generator when the grid power is restored. Grid power monitoring device; And a central management device that controls and manages operations of the power converter and the grid power monitoring device.

Description

Grid-connected power conversion system

The present invention relates to a grid-linked power conversion system and a control method thereof, and more particularly, to realize a three-phase inverter through a combination of three single-phase inverters to solve the unbalance and stabilize the system for a three-phase unbalanced system. The present invention relates to a grid-connected power conversion system.

Renewable energy means energy used by converting existing fossil fuels or converting renewable energy including sunlight, water, geothermal energy, and bioorganisms, and is a future energy source for a sustainable energy supply system. This renewable energy has grown in importance due to oil price instability and the regulatory response to the climate change convention.

Investing in the expansion and expansion of new and renewable energy such as wind and solar power generation is concentrated all over the world, but power generation by renewable energy sources such as wind and solar power with intermittent power generation characteristics is difficult to predict output and severe output fluctuation characteristics. This will greatly affect the stable operation of the linkage system. Therefore, in order to drastically expand the expansion of renewable energy sources such as wind and solar power, there is an urgent need for stable supply of power generation with high fluctuations in output and improvement of power quality. In addition, in recent years, as the desire for energy redistribution grows, it is necessary to supply necessary energy at a necessary time. In other words, it is possible to generate higher costs by selling renewable energy at the peak of the cooling load in summer or at the peak of the heating load in winter, which requires a separate energy storage unit and an important load at the rear of the inverter. In this case, even if the system is out of power, it is often necessary to supply power continuously without power failure depending on the load situation. When the power is restored after supplying the independent power source, a large accident may occur if the phase, frequency, magnitude, etc. of voltage that may occur during independent operation differ from the value of the power system during the recovery.

On the other hand, in the conventional technology, the general grid-linked inverter has a structure that is difficult to cope with the three-phase unbalanced system and independent load due to the configuration of the three-phase inverter, and because there is no energy storage unit, Most of the energy is reduced to the system. In addition, there is a drawback that it is impossible to apply to an independent load because the output of the inverter is not sent out when there is no power failure or when there is no energy storage. In order to solve the three-phase unbalance, a form in which a three-phase inverter is implemented by combining three single-phase inverters with independent controllers has been generally used. However, the single-phase inverter equipped with a separate controller, the inverter of each phase sharing the DC LINK voltage, the output current is different due to the sensing error of each controller, the load unbalance occurs, especially the input power fluctuates like renewable energy In the case of this severe power supply, due to the unbalanced current of the single phase, a phenomenon occurs that the load is concentrated in any single phase inverter, and the amount of energy reduced in the actual system is different from each other.

The present invention is to overcome the above-mentioned conventional problems, the problem to be solved by the present invention by implementing a three-phase inverter through a combination of three single-phase inverter to solve the unbalance for the three-phase unbalance system, any of the three phase Stable supply of power even in the case of failure of one or two phases of the power supply can be achieved at a high price by controlling the amount of energy desired at peak loads or by the power company, and stabilizing the system by controlling the reactive power. To provide a grid-connected power conversion system.

According to an exemplary embodiment of the present invention, installed between the renewable energy generator and the grid power supply, converts the power supplied from the renewable energy generator into a voltage for supplying the grid power, and the renewable energy generator or grid power A power converter for charging or discharging power supplied from the apparatus; Installed between the power converter and the grid power supply, the system power is cut off or connected according to the abnormality of the grid power supply, and for detecting the synchronization time for connecting the grid power supply and the renewable energy generator when the grid power is restored. Grid power monitoring device; And a central management device that controls and manages operations of the power converter and the grid power monitoring device.

The power converter includes a battery unit for charging a voltage supplied from the renewable energy generator or system power or discharging the stored voltage; A bidirectional DC / DC converter for boosting a DC voltage of the battery unit during a discharge operation of the battery unit, or for supplying a stepped-down DC voltage during a charging operation; A DC / AC inverter unit converting the DC voltage into an AC voltage and converting an AC voltage supplied from a system power supply into a DC voltage during a charging operation and supplying the DC voltage to the DC / DC converter; And a central control unit controlling the operation of the DC / DC converter and the DC / AC inverter unit. And a communication control unit for transmitting a command from the central management apparatus to the central control unit and transmitting data.

The DC / AC inverter unit includes a first single-phase DC / AC inverter, a second single-phase DC / AC inverter, and a third single-phase DC / AC inverter, and the central control unit supplies a common current control reference value to each of the single-phase DC / AC inverters. Each single-phase DC / AC inverter is operated using the received current control reference value.

It is installed in the rear end of the DC / AC inverter unit, and converts the magnitude of the voltage supplied from the DC / AC inverter unit to supply to the grid power supply or to convert the magnitude of the voltage supplied from the grid power supply to the DC / AC inverter The transformer unit further includes a supply unit.

The central control unit measures voltage from the grid power supply to detect phase and magnitude, detects voltage and current from an input power supply, and detects the maximum power point based on the detected phase and magnitude of the grid voltage and the detected input power. An MPPT controller for controlling; And a current controller for generating a current control reference value generation; An inverter current controller for controlling the operation of each single-phase DC / AC inverter according to the current control reference value received from the current controller to reduce the power supplied from the renewable energy generator to the grid power.

The grid power monitoring device includes a grid power monitoring unit that monitors whether a grid power abnormality occurs by measuring and analyzing a voltage state of the grid power; A system power switching unit for shutting off the system power when an abnormality occurs in the system power through the system power monitoring unit and connecting the system power when the system power returns to a normal state; And a synchronization unit configured to detect a synchronization time for connecting the renewable energy generator and the grid power when the grid power is normalized after the grid power is shut off.

The synchronization unit detects the synchronization time point by comparing the power conversion device side synchronization information and the system power supply side synchronization information.

The central management apparatus includes a data communication unit in charge of data transmission and reception; A power rate calculator configured to calculate a power rate during the independent operation when an abnormality occurs in the system power source, thereby shutting off the system power and switching the renewable energy generator to the independent operation mode; And a central control unit for controlling operations of the data communication unit and the power rate calculation unit.

As in the present invention, each single-phase DC / AC inverter receives the current control reference value through the inverter control unit to reduce the effective power in synchronization with the voltage of each phase, thereby supplying the same current without unbalance of each phase of the system phase The effect is to resolve the imbalance.

In addition, according to the command of the central control unit, stable power can be supplied to the load through independent operation during power failure, can flexibly cope with load peak of the power system, and stabilize the system by supplying and supplying reactive power. .

If the system fails while monitoring the system's voltage status, the power stored in the battery compartment can be supplied to critical loads to improve power quality.

In addition, by compensating for unstable output fluctuations caused by renewable energy generation sources that change according to weather conditions or time zones, output fluctuations can be leveled, thereby improving reliability and safety of power quality.

1 is a schematic diagram of a system-linked power conversion system according to an embodiment of the present invention.
FIG. 2 is a schematic configuration diagram of the power converter shown in FIG. 1.
3 is a functional block diagram of an inverter controller of the power converter shown in FIG. 2.
4 is a schematic configuration diagram of a system power monitoring device shown in FIG. 1.
FIG. 5 is a schematic configuration diagram of the central management apparatus shown in FIG. 1.
6 is a schematic diagram of a system-linked power conversion system according to another embodiment of the present invention.
7 is a flowchart illustrating a control process of the system-linked power conversion system according to the present invention.

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

1 is a schematic diagram of a system-linked power conversion system according to an embodiment of the present invention.

Referring to FIG. 1, a system-linked power conversion system according to an embodiment of the present invention includes a central management device such as a renewable energy generator 100, a power converter 200, a system power monitoring device 300, and an EMS. It includes 400, the system power supply 500 is connected to the output terminal of the system-linked power conversion system, the load 600 is connected to the system power supply (500).

The renewable energy generator 100 refers to a generator that converts existing fossil fuels or generates electricity by using renewable energy including sunlight, water, geothermal energy, wind, and bioorganisms. The renewable energy generator 100 is difficult to predict the output, and the severe output fluctuation characteristics of the stable power supply and power quality improvement when linking the power system is essential.

The power converter 200 is installed between the renewable energy generator 100 and the grid power supply 500, and converts the power supplied from the renewable energy generator 100 into a voltage suitable for supplying the grid power supply 500. Supply power to the grid power supply 500. In addition, the power converter 200 charges the power supplied from the renewable energy generator 100 or the grid power supply 500, and abnormality such as a power failure occurs in the grid power supply 500 to generate power from the grid power supply 500. When the supply is interrupted, a function of supplying pre-charged power to the load is performed according to a command of the upper controller.

The system power monitoring device 300 is installed between the power converter 200 and the system power supply 500. The system power monitoring device 300 performs a function of monitoring whether there is an abnormality of the system power supply 500, and when an abnormality occurs in the system power supply 500 such as a power failure, the system power supply 500 is shut off and the system power supply 500 ) Returns to the normal state to perform the function of connecting the grid power supply (500). In addition, after the system power supply 500 is shut off, when the system power supply 500 is normalized, a function of detecting a synchronization time point for connecting the system power supply 500 is performed.

For synchronization, the magnitude, phase, and frequency of the voltage are the biggest factors. When the central management device 400 transmits this information to the central control unit 250, the central control unit may transfer the oil, reactive current command, frequency command, and output voltage command to the power converter 200 to start synchronization.

The central management apparatus 400 controls and manages operations of the power converter 200 and the grid power monitoring apparatus 300. In addition, the central management device 400 performs a function of transmitting and receiving data and commands with the upper system.

2 is a schematic configuration diagram of the power converter shown in FIG. 1, FIG. 3 is a functional block diagram of an inverter controller of the power converter shown in FIG. 2, and FIG. 4 is a system power monitoring device shown in FIG. 1. A schematic configuration diagram of FIG. 5 is a schematic configuration diagram of the central management apparatus shown in FIG. 1.

2, the power converter 200 includes a DC / DC converter 210, a battery unit 220, a DC / AC inverter unit 230, a transformer unit 240, a central control unit 250, and a communication control unit. 260.

The DC / DC converter 210 converts the DC voltage of the battery unit 220 and supplies it to the DC / AC inverter unit 230 during the discharge operation of the battery unit 220. In addition, during the charging operation of the battery unit 220, a function of converting the DC voltage supplied from the DC / AC inverter unit 230 to supply the battery unit 220. In addition, when charging power supplied from the system power supply 500 or power supplied from the renewable energy generator 100 according to the battery charge state information of the battery management unit (BMS; not shown), the renewable energy generator 100 The DC voltage supplied from the converter is converted and supplied to the battery unit 220.

The battery unit 220 charges the voltage supplied from the renewable energy generator 100 or the grid power supply 500 or discharges the stored voltage and the charge state and the remaining life information through the battery management unit (BMS) DC / It serves to deliver to the DC converter.

The DC / AC inverter unit 230 is inputted from the DC / DC converter 210 when the system power supply 500 has an abnormal operation or when the battery unit 220 discharges to stabilize the output of the renewable energy generator 100. It converts the DC voltage to the AC voltage, and converts the AC voltage supplied from the grid power supply to the DC voltage during the charging operation to supply to the DC / DC converter 210. At this time, the DC / AC inverter 230 is implemented to control each phase by modularizing the three single-phase inverters in order to solve the unbalance for the three-phase unbalance system of the grid power supply. Accordingly, in the present embodiment, the DC / AC inverter unit 230 includes a first single phase DC / AC inverter 231, a second single phase DC / AC inverter 232, and a third single phase DC / AC inverter 233. .

The transformer unit 240 is installed at the rear end of the DC / AC inverter unit 230 and converts the magnitude of the voltage supplied from the DC / AC inverter unit 230 to supply the system power 500 or the system power 500 It converts the magnitude of the voltage supplied from the) to supply to the DC / AC inverter 230. The transformer unit 240 includes a first transformer 241, a second transformer 242, and a third transformer 243, and the first transformer 241 is disposed at a rear end of the first single-phase DC / AC inverter 231. The second transformer 242 is installed at the rear end of the second single phase DC / AC inverter 232, and the third transformer 243 is installed at the rear end of the third single phase DC / AC inverter 233.

The inverter controller 250 performs a function of controlling the operation of the DC / AC inverter 230. Inverter of each phase sharing DC LINK voltage has different output current due to sensing error of each controller, causing unbalance of load. Especially, if input power is fluctuating power such as renewable energy, In this case, the load is concentrated in an arbitrary single-phase inverter, and the amount of energy reduced in the actual system is different from each other.

In order to solve this problem, the central control unit 250 transmits a current control reference value to each single-phase DC / AC inverter, and each single-phase DC / AC inverter uses the transferred current control reference value, thereby making a difference in output current due to a sensing error. Can be removed. As a result, the same current can be supplied to three single-phase DC / AC inverters, thereby eliminating the unbalance of the system.

The communication control unit 260 transmits the command transmitted from the central management apparatus 400 such as EMS to the central control unit 250 and transmits data.

Referring to FIG. 3, the central controller 250 includes an MPPT controller (maximum output point controller) 251 and a current controller 252. The MPPT controller 251 calculates input power by measuring voltage and current from a renewable energy power source, and sets a maximum output voltage reference value VDC_REF for outputting a maximum output. The current controller 252 transmits the actually detected DC LINK voltage value VDC_REAL and the effective current control reference value I_REF to each single phase DC / AC inverter. The reactive current control reference value is transmitted to each single-phase DC / AC inverter according to the command from the host system.

Each single-phase DC / AC inverter controls the operation of each single-phase DC / AC inverter by applying the received current control reference value to a current controller (not shown) inside the inverter to phase the power supplied from the renewable energy generator into a grid power supply. It will be reduced to the system according to the size. As a result, each single phase DC / AC inverter reduces power in synchronization with the voltage of each phase according to the same current reference value, thereby supplying the same current without unbalance of each phase, thereby eliminating the burden on the phase unbalance of the system.

In other words, if the current control reference value is a positive command, the active power is sent out to the grid.If a negative value is negative, the active power is absorbed (at the time of converter charging). According to this, the reactive power is sent to the grid by using the serious current, which helps to improve the stabilization of the grid. This reactive current command can be appropriately combined and used for grid linkage operation.

The power company can solve the problem by using the POWER controller instead of the MPPT controller 251 to transmit the desired amount of power in the desired time period. That is, the input value is input to the current controller 252 by comparing the calculated power input value with the POWER command value lowered from the upper level. Thus, the desired power can be supplied through current control. When the output of the renewable energy generator source is weak, the central control unit 250 may set the DC / DC converter 210 to the discharge mode to adjust the VDC value to supply power.

Referring to FIG. 4, the system power monitoring apparatus 300 includes a system power monitoring unit 310, a system power switching unit 320, and a synchronization unit 330.

The system power monitoring unit 310 monitors whether a system power abnormality occurs by measuring and analyzing a voltage state of the system power supply 500.

The system power switching unit 320 cuts off the system power 500 when an abnormality occurs in the system power through the system power monitoring unit 310, and when the system power 500 returns to a normal state, the system power supply ( 500).

The synchronization unit 330 detects a synchronization point for connecting the renewable energy generator 100 and the system power 500 when the system power 500 is normalized after the system power 500 is shut off. do. The synchronization unit 330 measures the system power side synchronization information, that is, the frequency, phase, and voltage magnitude of the system power and transmits the measured power to the central management apparatus 400. Then, the synchronization time point is detected by comparing the power conversion device side synchronization information (that is, frequency, phase and voltage magnitude information of the power output from the power conversion device) received from the power conversion device 200 with the grid power supply synchronization information. The grid power switching unit 320 connects the grid power supply 500 to the renewable energy generator 100 at the synchronization time detected by the synchronization unit 330.

Referring to FIG. 5, the central management apparatus 400 includes a data communication unit 410, a power rate calculator 420, and a central control unit 430.

The data communication unit 410 is responsible for data transmission and reception between the central management unit 400 and a higher system such as a TOC. The data communication unit 410 is responsible for data transmission and reception between the central management apparatus 400, the power converter 200, and the system power monitoring apparatus 300.

When an abnormality occurs in the system power supply and the system power is cut off and the power conversion device 200 is switched to the independent operation mode, the power rate calculation unit 420 calculates the effective power rate during the independent operation. In addition, in the case of grid linkage, it performs the function of separating and calculating the effective power charge.

The central controller 430 controls the operations of the data communication unit 410 and the power rate calculator 420.

6 is a schematic diagram of a system-linked power conversion system according to another embodiment of the present invention.

Referring to FIG. 6, the power converter 200 according to the present embodiment includes a DC / DC converter 210, a battery unit 220 including a BMS, a DC / AC inverter unit 230, a transformer unit 240, And a central control unit 250 and an AC / DC inverter 270. The renewable energy generator 100 includes a wind or diesel generator 110, a fuel cell generator 120, and a solar generator 130.

The AC / DC inverter 270 is installed between the wind generator 110 and the DC / AC inverter unit 230. The AC / DC inverter 270 receives an AC voltage produced by the wind generator 110 and converts the AC voltage into a DC voltage to supply the DC / AC inverter 230.

The DC / DC converter 210 is installed between the fuel cell generator 120 and the DC / AC inverter unit 230, and the DC / DC converter 210 receives the DC voltage produced by the fuel cell generator 120. After output conversion, it is supplied to the DC / AC inverter unit 230 or stored in the battery unit 220. The DC / DC converter 210 may be installed at a rear end of the solar generator 130 or at a wind turbine having a DC output.

7 is a flowchart illustrating a control process of the system-linked power conversion system according to the present invention.

Referring to FIG. 7, the grid power monitoring device 300 performs a process of monitoring a voltage of grid power (S11). When an abnormality such as a power failure occurs in the system power supply, the controller detects this and reports that the abnormality occurs in the system power supply to the central management apparatus 400 (S12 and S13). Then, the grid power monitoring device 300 performs a process of shutting off the grid power and renewable energy generator (S14).

When the central management apparatus 400 receives a system abnormality occurrence report from the system power monitoring device 300 (S15), the power conversion device 200 and the system power monitoring device 300 determine the load state, and this time is the power. Before the inverter recognizes the power failure state and performs the output interruption function to prevent the independent operation, the inverter first converts to the independent operation mode (S16).

The system power monitoring device 300 performs a process of maintaining the separation of the system power and monitoring the restoration state by switching to the independent operation mode (S17). The central management apparatus 400 performs the calculation of the effective power fee according to the independent operation (S18), and the power converter 200 performs the independent operation (S19).

On the other hand, the system power monitoring device 300 monitors the power-up state, and when the power-up of the system power is confirmed, reports the power supply state of the system power to the central management device 400 (S20, S21).

When the central management apparatus 400 receives the restoration state of the grid power supply from the grid power monitoring device 300 (S22), the power conversion device 200 and the grid power monitoring device 300 switch the recovery mode of the power converter. Command (S23).

The grid power monitoring device 300 performs a process of measuring the grid power side synchronization information, that is, the frequency, phase, phase, and voltage of the grid power (S24). Then, the system power side synchronization information is reported to the central management apparatus 400. The central management apparatus 400 transmits the grid power side synchronization information received from the grid power monitoring device 300 to the power converter 200 (S26).

The power converter 200 performs a synchronization operation based on the received grid power supply synchronization information (S27), and transmits the power converter device synchronization information to the central management device 400 and the grid power monitoring device 300 ( S28).

The system power monitoring apparatus 300 receives the power conversion side synchronization information, detects a synchronization time point with reference thereto, and performs a process of connecting the system power supply and the power converter to the detected synchronization time point (S29).

What has been described above is merely an exemplary embodiment of a system-linked power conversion system according to the present invention, and the present invention is not limited to the above-described embodiment, and as claimed in the following claims, the gist of the present invention. Without departing from the technical spirit of the present invention to the extent that any person of ordinary skill in the art to which the present invention pertains various modifications can be made.

100: renewable energy generator
200: power converter
300: grid power monitoring device
400: central management unit
500: grid power
600: load

Claims (7)

In a grid-connected power conversion system,
Installed between the renewable energy generator and the grid power, for converting the power supplied from the renewable energy generator into a voltage for supplying the grid power, and for charging or discharging the power supplied from the renewable energy generator or grid power Power converter;
Installed between the power converter and the grid power supply, the system power is cut off or connected according to the abnormality of the grid power supply, and for detecting the synchronization time for connecting the grid power supply and the renewable energy generator when the grid power is restored. Grid power monitoring device; And
It includes a central management device for controlling and managing the operation of the power converter and grid power monitoring device,
The power converter,
A battery unit for charging a voltage supplied from the renewable energy generator or system power or discharging the stored voltage; A bidirectional DC / DC converter for boosting a DC voltage of the battery unit during a discharge operation of the battery unit, or for supplying a stepped-down DC voltage during a charging operation; A DC / AC inverter unit converting the DC voltage into an AC voltage and converting an AC voltage supplied from a system power supply into a DC voltage during a charging operation and supplying the DC voltage to the DC / DC converter; A communication control unit for transmitting a command from the central management apparatus to the central control unit and transmitting data; And a central control unit controlling the operation of the DC / DC converter and the DC / AC inverter unit.
The battery unit includes a battery management unit for managing the battery unit according to the state of charge and the remaining life of the battery unit,
The DC / AC inverter unit includes a first single phase DC / AC inverter, a second single phase DC / AC inverter, and a third single phase DC / AC inverter to modularize three single phase inverters so as to control each phase. ,
The central control unit detects a voltage and current from the renewable energy generator, calculates an input power, sets an MPPT controller for setting a maximum output voltage reference value for generating a maximum output power, and the maximum output voltage reference value and the actual DC link voltage. A current controller for comparing the values to generate a current control reference value, and transmitting the generated current control reference value to each of the single-phase DC / AC inverters,
The single-phase DC / AC inverter is characterized by controlling the operation of each single-phase DC / AC inverter according to the current control reference value to convert the power supplied from the renewable energy generator into the reactive power to reduce the system power supply Grid-linked power conversion system.
delete delete delete The method of claim 1,
The grid power monitoring device,
A system power monitoring unit that monitors whether a system power abnormality occurs by measuring and analyzing a voltage state of the system power;
A system power switching unit for shutting off the system power when an abnormality occurs in the system power through the system power monitoring unit and connecting the system power when the system power returns to a normal state; And
And a synchronization unit configured to detect a synchronization time for connecting the renewable energy generator and the grid power when the grid power is normalized after the grid power is shut off.
The method of claim 5,
And the synchronization unit detects the synchronization time point by comparing the power conversion device-side synchronization information and the system power supply-side synchronization information.
The method of claim 1,
The central management device,
A data communication unit in charge of data transmission and reception;
When the system power is off and the system power is cut off and the renewable energy generator is switched to the independent operation mode, the power bill is calculated during the independent operation, and the utility bill is calculated when the grid is connected. part; And
And a central control unit for controlling the operation of the data communication unit and the power rate calculation unit.

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