KR102436391B1 - Grid-connected solar power generation control system with ESS - Google Patents

Abstract

The present invention relates to a grid-connected solar power generation control system having an energy storage function. The grid-connected solar power generation control system, according to the present invention, comprises: a distributed solar power generation system (100); a first multi-switch (200); a power conversion system (300); a second multi-switch (400); an energy storage system (500); an ATS-1 (600); an ATS-2 (700); and a control unit (800). According to the present invention, a first grid-connected system for supplying commercial power (AC) to a load, a second grid-connected system composed of a distributed solar power generation system and a power conversion system, and a third grid-connected system composed of a power conversion system and an energy storage system may all be constructed.

Description

Grid-connected solar power generation control system with ESS

The present invention relates to a grid-connected system, and in particular, a distributed solar power system (DSPS), a power conversion system (PEBB, Power Electronic Building Block), and an energy storage system (ESS). , Energy Storage System) enables grid connection with KEPCO commercial power (AC), allows the user to freely configure the power conversion capacity as desired, and has an energy storage function that enables the sale of surplus power. it's about

In general, Grid Tied refers to connecting two or more power systems through a line so that power can move with each other, and a grid-tied power generation system refers to a method of using output electricity by reversely transmitting it to the grid. Simply put, it is to combine the solar output energy with the electricity of the company that supplies the power energy and use it.

Grid-connected photovoltaic power generation systems are often installed in commercial buildings that need to generate photovoltaic on a large scale or in buildings and buildings in the city. can be used together. In addition, if existing electricity is used, the generated surplus electricity can be reversely transmitted to the electricity company. Through this, sales and distribution are possible, so the solar power generation business is being activated to create profits through grid-connected solar power generation and to reduce carbon emissions due to the use of fossil fuels.

However, the grid-connected photovoltaic power generation system so far has a problem in that it is impossible to maintain the grid if power generation is not generated due to a failure or climate change, since the power conversion system using sunlight is integrally configured and transmitted to the inverter.

Even if we look at the global renewable energy grid connection issue, renewable energy resources are a large number of small-capacity power generation resources from the power system perspective, and are somewhat disadvantageous compared to traditional power generation sources in terms of measurement operation and power quality maintenance. In system operation using existing fossil fuels, it is easy for the operator to predict the size of the generated power suitable for the load and secure the reserve power. It has changing characteristics, and it is true that it is impossible to control the generated power when there is a demand for power, so it is difficult to operate.

The issues to be solved in the renewable energy grid connection issue can be divided into three major categories as follows. The first is the reduction of power system inertia energy. A system with a high proportion of asynchronous generators such as new and renewable energy has a problem in that the frequency (60Hz) drops to a steep slope compared to a normal system when a disturbance occurs. In other words, if the frequency falls more than a certain value, the generators are intentionally dropped from the system to protect the equipment, resulting in a power outage. Second, there is a delay in grid connection of new and renewable energy. Due to the nature of new and renewable energy, if a large amount of power generation facilities are concentrated in some densely populated areas, the power grid connection is delayed due to insufficient access capacity of transmission and distribution facilities, causing inconvenience to power generation companies. Third, the operation and management complexity increases, resulting in poor voltage quality and distribution system stability. In other words, as the new and renewable energy is a distribution system linked to distributed power, as the power flow changes from unidirectional to bidirectional from the existing substation to the end of the line, the voltage at the connection point of the distributed power rises, and the substation transmission voltage rises, raising the possibility of overvoltage. This will affect safety and electrical quality.

Korea's KEPCO is preparing for the intermittent characteristics of new and renewable energy sources by installing 1.4GW of ESS as a system stabilization method by 2023 according to the 9th transmission and transformation plan in 2021.11, improving power quality and adjusting the frequency. In addition, KEPCO is responding by developing a multi-line processing method that can be viewed as a new distribution system by using new materials such as ultra-high-strength electric poles and processed insulated cables to resolve the shortage of new renewable energy line withdrawals and expand capacity. As a countermeasure for system inertia reduction, a separate renewable energy management system (RMS) and a local management system (LRMS) of KEPCO are established in the grid operation system (EMS) used in the existing power control center and distributed through the integrated renewable energy control system. Efforts are being made to enhance energy management and capacity.

On the other hand, according to Republic of Korea Patent Publication (B1) No. 10-2030838 (10.10.2019), a control system and method for integrated linkage of a distributed power supply and a power system have been proposed.

However, the above patented technology is only a technology that intermittently charges or discharges each distributed power generation facility by comparing the cumulative connected capacity of the distribution line and the regular operation capacity of the distribution line, so that the power conversion device can be freely used according to the scale of the power grid. Not only cannot be configured, but also grid connection with KEPCO is impossible.

Accordingly, an object of the present invention is to provide a grid-connected system for intermittently controlling a distributed photovoltaic power generation system (DSPS), a power conversion system (PEBB), and an energy storage system (ESS) in order to solve the problems of the prior art. By implementing it, it is possible to implement a grid-connected system through commercial power (AC), as well as a distributed photovoltaic system, a power conversion system, and an energy storage system, and the power conversion capacity can be used by users through the PEBB. can be freely configured as desired, and through the DSPS and ESS, even if any one of the photovoltaic power generation systems fails, it not only prevents the power grid from shutting down, but also reduces the Mean Time To Repair (MTTR) and reduces surplus power. It provides a grid-connected photovoltaic power generation control system with an energy storage function that enables the sale of

According to a feature of the present invention for achieving the above object, a plurality of solar cells (Solar Cell) is a SOG for detecting the state of DC power generated and output from the N solar modules (110a ~ 110n) connected in series and parallel (Sate of Generation) a distributed solar power system having a sensor 120 (Distributed Solar Power System, 100) and; A plurality of contacts or any one of the contacts in order to supply the DC power generated and output from the distributed photovoltaic system 100 to the power conversion system (PEBB, Power Electronic Building Block, 300) by receiving a command from the control unit 800 a first multi-switch (1st Multi Switch, 200) that is switched to be connectable only; N DC-DC converters 310 and the N DC-DC converters that receive DC power from the distributed photovoltaic power generation system 100 through the first multi-switch 200 to adjust the voltage. A power conversion system (PEBB, Power Electronic Building Block, 300) comprising each of the N DC-AC inverters 320 for distributed conversion of DC power to AC power in a modular format; The commercial voltage 10 supplied from KEPCO in response to the command of the control unit 800, the AC power output through the distributed photovoltaic system 100 & the power conversion system 300, and the power conversion system ( 300) and the second Multi Switch that is switched to connect a plurality of contacts or only one of the contacts in order to grid-connect the AC power output through the energy storage system 500 to the load 20. , 400) and; DC power output from the DC-DC converter 320 of the power conversion system 300 is supplied, charged and stored, and the SOG sensor 120 of the distributed photovoltaic system 100 is abnormal in solar power generation. When this occurs, receiving a command from the control unit and supplying DC power to the DC-AC inverter 320 of the power conversion system 300 through the ATS-1 600 to be used as a power source for grid connection to the load 20 an energy storage system (ESS, Energy Storage System, 500); DC-AC inverter of the power conversion system 300 ( 320) and ATS-1 (Automatic Transfer Switch-1, 600) for automatically opening/closing (ON/OFF) the DC power supplied to; Automatically opens and closes the AC voltage supplied to the rectifier 60 to charge the energy storage system 500 by receiving a command from the control unit depending on whether there is a power outage from the first current transformer 30 that monitors the commercial voltage 10 of KEPCO ATS-2 (Automatic Transfer Switch-1, 700) for (ON/OFF); Intermittent control of the switching operation of the first multi-switch 200 according to the phase state information (SOF) of the DC power generated and output from the distributed photovoltaic power generation system 100, the second connected to the KEPCO commercial voltage (10) 1 The maximum allowable current of the second current transformer 40 connected to the first current transformer 30 and the load 20 is sensed to intermittently control the grid-connected switching operation of the second multi-switch 400, and the energy storage system 400 and ATS-1 (600) and ATS-2 (700), and at the same time intermittently control the system, the system linkage having an energy storage function, characterized in that the control unit 800 for transmitting to the monitor 40 is included. A solar power generation control system is provided.

According to another embodiment of the present invention, the control unit 800, when there is no abnormality in the power generation output of the distributed photovoltaic system 100 from the SOG sensor 120, the first multi-switch 200 and The distributed power conversion system 300 and the second multi-switch 400 are intermittently controlled to supply KEPCO's commercial power 10 to the load 20 and the energy storage system through the ATS-1 600 at the same time. When the stored energy supplied from 500 is cut off, and there is an abnormality in the power generation output of the distributed photovoltaic system 100 from the SOG sensor 120, the battery information collection system of the energy storage system 500 ( 530) detects the current state of charge of the lithium-ion battery pack 510 and turns on the ATS-1 600 to load through the DC-AC inverter 320 and the second multi-switch 400 (20) characterized in that the power system is connected so that AC power can be supplied.

According to another embodiment of the present invention, the control unit 800, the SOG sensor 120 of the distributed photovoltaic system 100 to the failure of the photovoltaic modules 110a to 110n and the power generation output state and , the current state of charge and discharge of the lithium-ion battery pack 510 from the battery information collection system 530 of the energy storage system 500 , whether the battery management system 520 operates normally, and the first current transformer 30 ), it is characterized in that the information is provided to the monitor 50 by receiving in real time whether the commercial voltage of KEPCO is outage and the maximum allowable current required by the load from the second current transformer 40 .

According to another embodiment of the present invention, the grid-connected photovoltaic power generation control system having the energy storage function is a first grid-connected system for supplying commercial power (AC) supplied from KEPCO to the load 20 . (1st Grid-connected System), a second grid-connected system consisting of the distributed photovoltaic system 100 and the power conversion system 300, and the power conversion system 300 ) and the third grid-connected system consisting of the energy storage system 500 is characterized in that both construction is possible.

According to another embodiment of the present invention, the control unit 800, when DC power is requested from the load side, it is characterized in that the control so that the DC power can be directly supplied through the ESS and the ATS.

The grid-connected photovoltaic power generation control system having an energy storage function according to a preferred embodiment of the present invention has the following effects.

(1) The present invention provides a first grid-connected system that supplies commercial power (AC) supplied from KEPCO as a load, and a distributed solar power generation system (DSPS) and a power conversion system (2nd Grid-connected System) consisting of (PEBB), and a third grid-connected system (3rd Grid-connected System) consisting of a power conversion system (PEBB) and an energy storage system (500) All builds are possible.

(2) In the present invention, the power conversion capacity supplied to the load through the power conversion system (PEBB) can be freely configured as desired by the user.

(3) The present invention prevents the power grid from shutting down even if any one of the photovoltaic systems fails through the distributed photovoltaic system (DSPS), the power conversion system (PEBB) and the energy storage system (ESS) Of course, it has the effect of reducing the maintenance time (Mean Time To Repair, MTTR) and selling the surplus power.

1 is a view showing the prior art
2 is a block diagram showing the grid connection between KEPCO commercial power (AC) and renewable energy for a grid-connected photovoltaic power generation control system having an energy storage function according to a preferred embodiment of the present invention;
3 is a block diagram specifically showing a power conversion system for a grid-connected photovoltaic power generation control system having an energy storage function according to a preferred embodiment of the present invention;
4 is a block diagram illustrating an energy storage system (ESS) for a grid-connected photovoltaic power generation control system having an energy storage function according to a preferred embodiment of the present invention;
5 is a block diagram showing the overall technical configuration of a grid-connected photovoltaic power generation control system having an energy storage function according to a preferred embodiment of the present invention;

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. First of all, in adding reference numerals to the components of each drawing, it should be noted that the same components are given the same numerals as much as possible even though they are shown in different drawings, and even though the same numerals as in the prior art are displayed. The prior art should be interpreted as such. In addition, in describing the present invention, when it is determined that a detailed description of a related known configuration or function may obscure the gist of the present invention, the detailed description thereof will be omitted.

2 to 5 , the core technical configuration means for the grid-connected photovoltaic power generation control system having an energy storage function according to a preferred embodiment of the present invention is largely a distributed solar power system (Distributed Solar Power). System, 100) and the first multi-switch (1st Multi Switch, 200), the power conversion system (PEBB, Power Electronic Building Block, 300), and the second multi-switch (2nd Multi Switch, 400), and the energy storage system (ESS) , Energy Storage System, 500), ATS-1 (Automatic Transfer Switch-1, 600), ATS-2 (Automatic Transfer Switch-2, 700), and a control unit 800 .

2, 4 and 5, the distributed solar power system (DSPS, Distributed Solar Power System, 100) is a new and renewable energy power generation means using sunlight, a plurality of solar cells (Solar Cell) DC power is generated and output by using sunlight from each of the N solar modules 110a to 110n connected in series and parallel.

Here, each of the photovoltaic modules 110a to 110n connects a plurality of solar cells in series and in parallel to use electricity obtained from photovoltaic power generation and electricity supplied by a power company together. (Solar Cell) is sufficiently connected to produce enough electricity to be applied to (Grid-connected System). In addition, a failure occurs in a specific module among the N photovoltaic modules 110a to 110n, or the amount of power generation varies according to climate change, and the power generation state generated by the N photovoltaic modules 110a to 110n according to the installation angle of the photovoltaic module (Sate of Generation) may be different so that optimal power generation is possible, and it is installed in a distributed manner so that output can be distributed to the distributed type power conversion system (PEBB, Power Electronic Building Block, 300).

In addition, the distributed photovoltaic power generation system 100 according to an embodiment of the present invention is provided with a SOG (Sate of Generation) sensor 120 for detecting the power generation state of the N photovoltaic modules 110a to 110n.

Here, the SOG (Sate of Generation) sensor 120 detects the amount of DC power generated by each of the solar modules 110a to 110n and transmits it to the controller 800 , and the controller 800 controls the SOG (Sate of Generation). Generation) by checking the power generation state of the N solar modules 110a to 110n transmitted from the sensor 120 to intermittently control the first multi-switch 200 to supply DC power to the power conversion system 300 . make it possible

2, 4 and 5, the first multi switch (1st Multi Switch, 200), a kind of automatic transfer switch (ATS, Automatic Transfer Switch) means, the distributed photovoltaic system 100 Switching function so that a plurality of contacts or only one of the contacts can be connected in order to receive the DC power generated and output from the control unit 800 and supply it to the power conversion system (PEBB, Power Electronic Building Block, 300) carry out

Here, the reason for switching the first multi-switch (1st Multi Switch, 200) according to an embodiment of the present invention so that a plurality of contacts or only one of the contacts can be connected is, the distributed photovoltaic system 100 ) is configured with N solar modules 110a to 110n, and N DC-DC converters 310a to 310n and DC-AC inverters 320a to 320n are also configured in the power conversion system 300. . In this configuration, the distributed photovoltaic power generation system 100 is a grid-connected system because the amount of power generation is different depending on the climate change according to the latitude of the sun and the installation angle of the photovoltaic module or the direction facing the sun. The stability of electricity supply and demand becomes unstable when Therefore, in the present invention, the N solar modules 110a to 110n of the distributed photovoltaic power generation system 100 and the N DCs of the power conversion system 300 through the first multi-switch (1st Multi Switch, 200) -Connect the DC converters 310a to 310n and the DC-AC inverters 320a to 320n 1:1 between the N solar modules 110a to 110n of the distributed photovoltaic system 100, The control unit 500 confirms a specific photovoltaic module outputting from the SOG (Sate of Generation) sensor 120 of the distributed photovoltaic system 100 and selectively switches the first multi-switch 200 ( Switching) can be done. In this case, the control unit 800 includes the N DC-DC converters 310a to 310n and DC-AC inverters 320a to 320n connected to the first multi-switch 200 and a second multi-switch 400 to be described later. The switching state between the two is intermittently controlled so that one power grid supply circuit is configured. This switch function is a unique automatic transfer switch (ATS), and it can be said to be a completely different concept from the automatic transfer switch (ATS) that is sold in the market and allows the switch from KEPCO commercial power to emergency generator power in an automatic state. have.

2 to 5, the power conversion system (PEBB, Power Electronic Building Block, 300) is a means for converting the DC power generated in the distributed photovoltaic system 100 to AC power by adjusting, N DC-DC converters 310 and the N DC-DC converters that receive DC power from the distributed photovoltaic system 100 through the first multi-switch 200 to adjust the voltage. Each of the N DC-AC inverters 320 that distributes and converts the DC power of the AC power to the AC power is configured in a modular form.

Here, the PEBB (Power Electronic Building Block) is to connect electricity produced by renewable energy using sunlight to the existing power system that transmits with alternating current (DC) to alternating current (AC). A power conversion system is required at this time. Therefore, in the embodiment of the present invention, the PEBB, which is a type of power conversion system for converting DC to AC, is not an all-in-one type but a modular type composed of N pieces. Although the integrated type cannot change the power conversion capacity during use, the N module type is 1kW to 1MW class and can be configured by attaching several modules in parallel, so the user can freely configure the power conversion capacity according to the load. There are possible features. In particular, the existing centralized power grid has a large and constant scale, but the size of the micro grid (MG) varies from kW to MW. . The microgrid is an alternative concept to the existing centralized power grid, and is a self-sufficient power grid in which both the production and consumption of electricity are generated within a specific area. When relying on a centralized power grid, power loss occurs in the transmission and distribution process and there are limitations in that surplus power cannot be reused, whereas MG can solve all these problems. In addition, the existing centralized power grid has a large and constant scale, but the scale of MG varies from kW to MW, so the power converter can be freely configured to fit the scale of the power grid. In addition, in the case of an integrated structure, if there is a failure, the power grid is inevitably shut down. can increase In addition, in the case of the night time when the electricity demand is low, since the operation of the power conversion system is inevitably less efficient than the operation during the day time, the PEBB (Power Electronic Building) according to an embodiment of the present invention to which a modular type consisting of N is applied. Block, 300) can partially operate the module according to the electricity demand. In other words, if only one is operated and the rest is rested, the maintenance time (Mean Time To Repair) can be secured and the efficiency can be increased compared to the integrated type. In addition, the PEBB 300 according to an embodiment of the present invention can convert DC to AC, so it is easy to combine with an ESS (Energy Storage System) that serves as an electric storage, which is an essential element of renewable energy generation. have.

On the other hand, the reason for configuring each of the N DC-DC converters 310 and N DC-AC inverters 320 in a modular form according to an embodiment of the present invention with reference to FIG. 3 is that the N The reason for configuring each of the DC-DC converter 310 and the N DC-AC inverters 320 in a modular form is the N solar modules 110a to 110n of the distributed photovoltaic power generation system 100 . ) and the N DC-DC converters 310 & DC-AC inverters 320 to ensure stability in power supply and demand by switch matching. In addition, the power conversion system 300 is easy to replace in case of failure, and in order to variably configure the power conversion capacity according to whether the load 20 changes, the N DC-DC converters 310 and N DC-AC inverter 320 with DC-DC converter 1 (310a) & DC-AC inverter 1 (320a), DC-DC converter 2 (310b) & DC-AC inverter 2 (320b), DC-DC converter A modular board in which each of the N (310n) & DC-AC inverter N (320n) is mounted on one printed circuit board (PCB) may be mounted in N slots (not shown), respectively.

In addition, the DC-DC converter 310 and the DC-AC inverter 320 of the power conversion system 300 may be configured in a 1kW to 1MW class to be applicable to various loads.

In addition, the power conversion system 300, in order to distribute and convert the DC power output from the distributed photovoltaic system 100 into AC power, the N modules are connected in parallel in two or more strings (String) ) method, a micro inverter that connects the N modules one by one, and a central that drives and connects all of the DC power output from the distributed photovoltaic system 100 to the power conversion system 300 . All of the centralized inverters of the (Central) method may be configured to be possible.

In addition, the power conversion system 300 is subjected to intermittent control by the control unit 500, and when a frequency bias is input to the internal oscillator of the DC-AC inverter 320, the frequency fluctuations appearing during independent operation A frequency shift method for detecting, an active power variation method for detecting voltage, current, or frequency fluctuations occurring during independent operation when a periodic active power fluctuation is applied to the output of the DC-AC inverter 320, and the DC- When a periodic reactive power fluctuation is given to the output of the AC inverter 320, a reactive power fluctuation method that detects voltage, current or frequency fluctuations appearing during independent operation, and the DC-AC inverter 320 in parallel with the output When an error occurs through an active detection means (not shown), which is a load change method that detects sudden changes in voltage or current by inserting impedance, it may be configured to prevent independent operation.

2 and 4 and 5, the second multi switch (2nd Multi Switch, 400), the AC power output from the power conversion system 300 and KEPCO's commercial power 10 load 20 ) as a switching means for grid connection, the commercial voltage 10 supplied from KEPCO in response to the command of the control unit 800, and the distributed photovoltaic system 100 & power conversion system 300 In order to grid-connect the AC power output through the AC power and the AC power output through the power conversion system 300 and the energy storage system 500 to the load 20, a plurality of contacts or only one of the contacts can be connected. It performs a switching function.

Here, the second multi-switch (2nd Multi Switch, 400) has the same function as the first multi-switch (1st Multi Switch, 200), except that the three types of AC power can be grid-connected to the load (20) There is a difference in the technical configuration of switching to do so.

4 and 5 , the energy storage system (ESS, Energy Storage System, 500) charges and stores the DC power generated by the distributed photovoltaic system 100 to the system as a load 20. As a means for linking, receiving DC power output from the DC-DC converter 320 of the power conversion system 300, charging and storing, and the SOG sensor 120 of the distributed photovoltaic system 100 When an abnormality occurs in the photovoltaic power generation from 20) is used as a power source that is connected to the grid.

Here, the energy storage system (ESS) is the DC-AC inverter 320 of the power conversion system 300 when a failure occurs in the distributed photovoltaic system 100 or power generation is not made due to climate change. After supplying DC power to AC and converting it to AC, a grid-connected system that can supply stable AC power to the load 20 can be built. In addition, the energy storage system 500 is connected in series/parallel by configuring a plurality of battery cells into modules and packs, and a DC-AC inverter 320 of the power conversion system 300 . And, a lithium-ion battery pack (LBP, Lithium-ion Battery Pack, 510) that supplies DC power to a DC load, and intermittent control of charging and discharging of the lithium-ion battery pack 510 to control the entire lifespan of the battery pack A battery management system (BMS, Battery Management System, 520) that extends the battery life and improves performance, and the lithium-ion battery pack 510 are continuously monitored to process and replace the battery cell or module unit when an abnormal condition occurs. A battery information collection system (BDLS, Battery Data Logging System, 530 ) that enables this and manages the life cycle of the battery may be integrated into the energy storage system 500 . In particular, the battery management system 520 controls the charging, discharging and operation of the lithium-ion battery pack 510 to extend the overall lifespan and improve performance, and the battery information collection system 130 for the lithium-ion battery pack (LBP, Lithium-ion Battery Pack, 510) is continuously monitored to enable treatment and exchange in cell or module units when an abnormal condition occurs in battery cells, leading to battery production, reuse, and disposal. The battery life cycle is managed and state of information (SOF) of the energy storage system 500 is provided to the controller.

Referring to FIG. 5 , the Automatic Transfer Switch-1 (ATS-1, 600) receives a command from the control unit according to the presence or absence of an abnormality from the SOG sensor 120 that monitors the distributed photovoltaic system 100, and the It performs a function of automatically opening/closing (ON/OFF) the DC power supplied to the DC-AC inverter 320 of the power conversion system 300 through the energy storage system 400 .

Here, the ATS-1 (600) is a DC-AC inverter (320) of the power conversion system (300) by the control unit (800) according to the power generation state (SOG) of the distributed photovoltaic system (100). Through the function of automatically supplying or shutting off DC power, it safely performs the role of electricity storage, an essential element of renewable energy generation.

Referring to FIG. 5 , the Automatic Transfer Switch-1 (ATS-2) 700 receives a command from the control unit 800 according to whether there is a power failure from the first current transformer 30 that monitors the commercial voltage 10 of KEPCO. It performs a function of automatically opening/closing (ON/OFF) the AC voltage supplied to the rectifier 60 to receive and charge the energy storage system 500 .

Here, the ATS-2 (700), if the distributed photovoltaic system 100 fails or when power generation is not made due to climate change, if the commercial voltage 10 of KEPCO is normally supplied, the control unit 800 ) to automatically supply or cut off the commercial voltage 10 of KEPCO to the rectifier 60 to charge the energy storage system 500 by intermittent control.

Referring to FIG. 5 , the controller 800 is a means for intermittently controlling the grid-connected photovoltaic power generation control system according to a preferred embodiment of the present invention, and the power generation output from the distributed photovoltaic power generation system 100 . The switching operation of the first multi-switch 200 is intermittently controlled according to the phase state information (SOF) of the DC power being 2 The maximum allowable current of the current transformer 40 is sensed to intermittently control the grid-connected switching operation of the second multi-switch 400, and the energy storage system 400 and the ATS-1 (600) and ATS-2 (700) .

Here, the control unit 800 according to an embodiment of the present invention may apply a Maximum Power Point Tracking (MPPT) algorithm to detect the amount of power output through the distributed photovoltaic system 100 . have. That is, the MPPT (Maximum Power Point Tracking) includes an inverter in which an MPPT is integrated into one inverter, and an inverter in which several MPPTs are dispersed in one inverter. In general, the number of MPPTs and the number of input strings are called distributed string inverters and centralized central inverters. Theoretically, as MPPT finds and optimizes the optimal voltage range, it is advantageous as the number and the number of string input channels increase. The wider the operating voltage range of the inverter, the more advantageous it is.

Therefore, the control unit 500 to which the MPPT algorithm is applied according to an embodiment of the present invention, when a power failure is detected in the commercial power supply 10 supplied from KEPCO through the first current transformer 30, the distributed photovoltaic power generation system The first multi-switch 200 is intermittently controlled to supply the optimal DC power generated in 100 to the power conversion system 300 and, at the same time, the AC power converted in the power conversion system 300 is applied to the load 20 By intermittently controlling the second multi-switch 400 to connect to the grid with -connected system) can be built. However, since KEPCO in Korea currently recommends the establishment of a grid-connected system (GCS) equipped with ESS for stable power supply, in the embodiment of the present invention, the role of electric storage, which is an essential element of new and renewable energy generation using sunlight, is played. It is assumed that the energy storage system (ESS, 500) that can be safely performed is configured.

In addition, the control unit 800 according to an embodiment of the present invention, when there is no abnormality in the power generation output of the distributed photovoltaic system 100 from the SOG sensor 120, the first multi-switch 200 and The distributed power conversion system 300 and the second multi-switch 400 are intermittently controlled to supply KEPCO's commercial power 10 to the load 20 and the energy storage system through the ATS-1 600 at the same time. When the stored energy supplied from 500 is cut off, and there is an abnormality in the power generation output of the distributed photovoltaic system 100 from the SOG sensor 120, the battery information collection system of the energy storage system 500 ( 530) detects the current state of charge of the lithium-ion battery pack 510 and turns on the ATS-1 600 to load through the DC-AC inverter 320 and the second multi-switch 400 (20) connects the power system so that AC power can be supplied.

In addition, the control unit 800 according to an embodiment of the present invention, the SOG sensor 120 of the distributed photovoltaic system 100 to the failure of the photovoltaic modules 110a to 110n and the power generation output state, The current state of charge and discharge of the lithium-ion battery pack 510 from the battery information collection system 530 of the energy storage system 500, whether the battery management system 520 operates normally, and the first current transformer 30 Information may be provided to the monitor 50 by receiving in real time whether the commercial voltage of KEPCO is out of service and the maximum allowable current required by the load from the second current transformer 40 .

Here, through the information provided to the monitor 50, the site manager can provide stable power through continuous maintenance and efficient management of the overall solar power generation control system having an energy storage function according to an embodiment of the present invention as well as solar power generation. The efficiency of the control system can be increased. In addition, when the information transmitted to the monitor 50 is connected to a control center (not shown) through a local area network or Internet network, continuous maintenance and more effective management functions can be performed.

In addition, the control unit 800 according to an embodiment of the present invention controls so that DC power can be directly supplied through the ESS and ATS when DC power is requested from the load side.

Here, the DC power supplied to the load 20 required by the control unit 800 requires a lot of DC power for industrial machines, electrical and electronic devices, computers, communication devices, smart phones, etc. as the high-tech industry develops rapidly. is becoming DC power can be directly supplied to these devices.

On the other hand, the grid-connected photovoltaic power generation control system having an energy storage function according to a preferred embodiment of the present invention is a first grid-connected system (1st) that supplies commercial power (AC) supplied from KEPCO to the load 20 . Grid-connected System), a second grid-connected system consisting of the distributed solar power generation system 100 and the power conversion system 300, and the power conversion system 300 and A third grid-connected system consisting of the energy storage system 500 can all be constructed.

Here, the grid-connected photovoltaic power generation control system having an energy storage function according to an embodiment of the present invention includes the SOG sensor 120 of the distributed photovoltaic power generation system 100 to the N photovoltaic modules 110a to 110n. When normal power generation is achieved in the entirety, N energy storage systems 500 are installed and charged, and then distributed and stored or the surplus power of the distributed photovoltaic power generation system 100 can be sold to a power company. (Distributed power grid) can be built.

The above description is merely illustrative of the technical spirit of the present invention, and various modifications and variations will be possible without departing from the essential characteristics of the present invention by those skilled in the art to which the present invention pertains. Therefore, the embodiments disclosed in the present invention are not intended to limit the technical spirit of the present invention, but to explain, and the scope of the technical spirit of the present invention is not limited by these embodiments. The protection scope of the present invention should be construed by the following claims, and all technical ideas within the scope equivalent thereto should be construed as being included in the scope of the present invention.

10: KEPCO commercial voltage (AC) 20: load
30: first current transformer 40: second current transformer
50: monitor 60: rectifier
100: distributed solar power system
110a~110n : N solar modules
120: SOG sensor 200: first multi-switch
300: power conversion system
301a~301n : N DC-DC converters
302a~302n: N DC-AC inverters 310: DC-DC converters
320: DC-AC inverter 400: second multi-switch
500: energy storage system 510: lithium-ion battery pack
520: battery management system 530: battery information collection system
600: ATS-1 700: ATS-2
800: control unit

Claims (5)

Distributed solar having a SOG (Sate of Generation) sensor 120 that detects the state of DC power generated and output from N solar modules 110a to 110n in which a plurality of solar cells are connected in series and in parallel a photovoltaic system (Distributed Solar Power System, 100);
A plurality of contacts or any one of the contacts in order to supply the DC power generated and output from the distributed photovoltaic system 100 to the power conversion system (PEBB, Power Electronic Building Block, 300) by receiving a command from the control unit 800 a first multi-switch (1st Multi Switch, 200) that is switched to be connectable only;
N DC-DC converters 310 and the N DC-DC converters that receive DC power from the distributed photovoltaic system 100 through the first multi-switch 200 to adjust the voltage. A power conversion system (PEBB, Power Electronic Building Block, 300) comprising each of the N DC-AC inverters 320 for distributed conversion of DC power to AC power in a modular format;
The commercial voltage 10 supplied from KEPCO in response to the command of the control unit 800, the AC power output through the distributed photovoltaic system 100 & the power conversion system 300, and the power conversion system ( 300) and the second Multi Switch that is switched to connect a plurality of contacts or only one of the contacts in order to grid-connect the AC power output through the energy storage system 500 to the load 20. , 400) and;
DC power output from the DC-DC converter 320 of the power conversion system 300 is supplied, charged and stored, and the SOG sensor 120 of the distributed photovoltaic system 100 is abnormal in solar power generation. When this occurs, receiving a command from the control unit and supplying DC power to the DC-AC inverter 320 of the power conversion system 300 through the ATS-1 600 to be used as a power source for grid connection to the load 20 an energy storage system (ESS, Energy Storage System, 500);
DC-AC inverter of the power conversion system 300 ( 320) and ATS-1 (Automatic Transfer Switch-1, 600) for automatically opening/closing (ON/OFF) the DC power supplied to;
Automatically opens and closes the AC voltage supplied to the rectifier 60 to charge the energy storage system 500 by receiving a command from the control unit depending on whether there is a power outage from the first current transformer 30 that monitors the commercial voltage 10 of KEPCO ATS-2 (Automatic Transfer Switch-1, 700) for (ON/OFF);
Intermittently control the switching operation of the first multi-switch 200 according to the phase state information (SOF) of the DC power generated and output from the distributed photovoltaic system 100, and the second connected to the KEPCO commercial voltage (10) 1 The maximum allowable current of the second current transformer 40 connected to the first current transformer 30 and the load 20 is sensed to intermittently control the grid-connected switching operation of the second multi-switch 400, and the energy storage system 400 and a control unit 800 for intermittently controlling and simultaneously controlling the ATS-1 (600) and ATS-2 (700) and transmitting the abnormality of the system to the monitor 40,
The control unit 800,
When there is no abnormality in the power generation output of the distributed photovoltaic system 100 from the SOG sensor 120 , the first multi-switch 200 and the distributed power conversion system 300 and the second multi-switch 400 ) to intermittently control KEPCO's commercial power supply 10 to the load 20 and at the same time block the stored energy supplied from the energy storage system 500 through the ATS-1 600,
When there is an abnormality in the power generation output of the distributed photovoltaic system 100 from the SOG sensor 120 , the lithium-ion battery pack 510 is transferred from the battery information collection system 530 of the energy storage system 500 . Power so that AC power can be supplied to the load 20 through the DC-AC inverter 320 and the second multi-switch 400 by detecting the current state of charge and turning on the ATS-1 (600) A grid-connected photovoltaic power generation control system with an energy storage function, characterized in that the grid is connected.
delete The method of claim 1,
The control unit 800, the SOG sensor 120 of the distributed photovoltaic system 100 to the failure of the photovoltaic modules 110a to 110n, and the power generation output state, and the battery of the energy storage system 500 From the information collection system 530 , the current state of charge and discharge of the lithium-ion battery pack 510 , whether the battery management system 520 operates normally, and whether the commercial voltage of KEPCO is out of 2 A grid-connected photovoltaic power generation control system having an energy storage function, characterized in that receiving the maximum allowable current required by the load from the current transformer (40) in real time and providing the information to the monitor (50).
The method of claim 1,
The grid-connected photovoltaic power generation control system having the energy storage function includes a first grid-connected system that supplies commercial power (AC) supplied from KEPCO to the load 20, and the A second grid-connected system consisting of a distributed photovoltaic power generation system 100 and a power conversion system 300, and the power conversion system 300 and an energy storage system 500 A grid-connected photovoltaic power generation control system with an energy storage function, characterized in that it is possible to build a third grid-connected system.
The method of claim 1,
The control unit 800, a grid-connected photovoltaic power generation control system having an energy storage function, characterized in that the control so that DC power can be directly supplied through the ESS and ATS when DC power is required on the load side.

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