KR102194001B1 - Microgrid system considering load environment and the Methods of operation - Google Patents

Abstract

The present invention constructs a power trading system including energy prosumer technology between microgrids, and applies energy prosumer technology to a distributed load power control device (ADR) that purchases energy from other microgrids when a peak load occurs on the microgrid. ) To provide a network system.
The microgrid system in consideration of the load environment according to an exemplary embodiment of the present invention includes a plurality of microgrids, a large solar power plant, a power conversion device, a power control device for a centralized load, a load prosumer control device, and a distributed load. It consists of a power control device.
According to the present invention, it is possible to improve the utilization rate of the entire system by taking advantage of the electricity producer by selling the remaining electric energy through the energy prosumer and the consumer by purchasing electricity cheaper than the system. In addition, there is an effect of reducing losses through low voltage direct current distribution (LVDC) network linkage between multiple microgrids.

Description

Microgrid system considering load environment and the Methods of operation}

The present invention relates to a microgrid system and a method of operating the same in consideration of a load environment. In particular, it relates to the microgrid, energy prosumer operation method, and low voltage direct current distribution (LVDC) technology field.

Microgrid (hereinafter referred to as “MG”) refers to a local power supply system centered on distributed energy resources independent from the existing wide area power system.

Microgrid is a localized power network that connects distributed energy resources such as wind power and solar power of customers, and operates off-grid with the entire power system, enabling self-sufficiency, and connecting with the power system if necessary. It can be operated (on-grid).

The microgrid can be divided into an AC microgrid with alternating current (AC) and a DC microgrid with direct current (DC) that combines distributed power and load.

AC microgrid has the advantage of using the basic distribution network as it is, but there are problems of synchronization, stability, and reactive power consumption, which are disadvantages of the AC system.

It is similar to the smart grid in that it requires functions such as power generation and consumption forecasting, but its application scale is relatively small compared to the smart grid, and large-scale transmission facilities are not required because the location of power generation sources and customers (power consumers) is close. There is no difference.

Unlike the existing centralized power supply system, the microgrid is a regional power supply system composed of distributed power sources including new and renewable energy power, and is divided into grid-connected and independent systems. In addition, depending on the type of load, it can be divided into an urban-type load-dense microgrid and a rural-type load-distributing microgrid. In many cases, the urban type is a system-connected type and the rural type is composed of an independent type.

Independent microgrids that can optimally and stably supply power to islands or remote areas without a commercial power grid will supply power through distributed power sources including new and renewable energy instead of supplying power only with conventional diesel generators.

The low voltage DC distribution system (LVDC) uses a DC distribution system having a voltage of about tens to several hundred volts or 1 kV in place of the conventional 22.9kV AC distribution system. Conventionally, AC power distribution has been mainly used for reasons of ease of voltage variation, but recently, power distribution systems using DC have been in the spotlight due to the development of power electronics technology and a decrease in power prices.

Patent Publication No. 10-1796669 (announcement date: 2017. 11. 10.) Industrial complex microgrid system is disclosed as a prior document related to the present invention. The prior art aims to provide a microgrid system that enables power transactions between factories in industrial complexes using individual DC networks rather than power transactions using conventional AC networks.

1 is a diagram showing a general industrial complex microgrid system.

As shown in Fig. 1, a plurality of power demand units 10 including a distributed power supply unit 3 and a load 11, connected by a commercial power supply unit 6 and an AC network 5, and the plurality of power demands It is connected by the unit 10, the DC network 7 and the data network 8, and includes a power generation business unit 1 equipped with a central controller 4, an energy storage system (ESS) 2, and a distributed power supply unit 3 In addition, the plurality of power demanding units 10 includes at least one power demanding unit group connected to each other through a DC network, and the power generation business unit 1 is a power transaction between the power demanding units through the DC network, It is characterized in that the power demand unit stores excess power and controls the supply of power to the power demand unit that requests the power supply.

As another prior document related to the present invention, the description of the AC/DC converter of the low voltage distribution line of Korean Patent Laid-Open Publication No. 10-2014-0038174 (published on March 28, 2014) and the control method of the AC/DC converter Is initiated.

2 is a diagram showing the configuration of a general low voltage DC distribution (LVDC) line. The LVDC distribution line 20 shown in FIG. 2 includes an electric vehicle charging station battery 25, a solar generator 26, a wind power generator 27, a DC/DC converter 23 and a DC/AC converter for supplying a load. 24) and other various power systems are bottling.

As another prior document related to the present invention, the DC microgrid system of Korean Patent Publication No. 10-1277185 (announcement date: 2013. 6. 24.) and the AC and DC composite micro system using the same are localized based on independent distributed power sources. Among the conventional power supply systems, a DC microgrid system and an AC and DC microgrid system using the same are disclosed.

The DC microgrid system includes at least one distributed power source, a power conversion device that converts the power of the distributed power source into DC, an energy storage device having a protection switch connected to the power conversion device, and a DC power load and a distributed power source. It consists of a controller that controls the charging and discharging modes of the energy storage device by adjusting the output voltage of the power conversion device according to the difference between the total power of and the DC power load power. In the AC and DC hybrid microgrid system, the DC microgrid system described above is connected to the AC microgrid system and a bidirectional power converter. Accordingly, there is no loss due to power conversion in the charging and discharging modes in the energy storage device constituting the DC microgrid system, thereby improving energy use efficiency.

In a hybrid microgrid system using renewable energy, surplus power and underpower are generated in the microgrid according to solar irradiation or load usage. If excess power is generated in the microgrid, it is regarded as wasted energy unless there is a special load factor, and the utilization rate of the system may be reduced.

Existing studies on conventional microgrids have been limited to studies to increase the efficiency of individual distributed power supplies and to system link distributed power supplies to commercial power sources.

Existing research on microgrids has limited to increasing the efficiency of individual distributed power supplies, and has not been able to propose an energy consumer control system that can be efficiently used in parallel with microgrid power supplies.

In particular, the problem of the energy management system (PMS) technology for the stable and economical operation of the system built with engineering technology according to the design and operation of the microgrid (MG) system suitable for the load environment could not be solved.

Korean Registered Patent Publication No. 10-1133328 (Announcement date: 2012. 4. 5.) Korean Patent Publication No. 10-1277185 (announcement date: 2013. 6. 24)

An object to be solved of the present invention is to construct a power trading system to which the energy prosumer technology between microgrids is applied, and to provide a microgrid system in consideration of the load environment using low voltage DC distribution.

Another problem to be solved by the present invention is to provide a network system of a distributed load power control device (ADR) that purchases energy from another microgrid when a peak load occurs on the microgrid by applying energy prosumer technology to the microgrid. Has its purpose.

An example of the present invention for achieving the above-described problem is as follows.

The present invention includes at least one distributed power source, a power conversion device for converting power of the distributed power source to direct current, and a DC power load connected to the power conversion device;
Power produced by the solar panel (hereinafter referred to as'solar cell'), and a lithium-ion battery (hereinafter referred to as'secondary battery') that stores the power generated by the solar panel, and from the solar cell Large solar power consisting of a PV DC/AC inverter that converts the PV output voltage to a preset AC voltage (380V) and a Battery DC/AC inverter that converts the output voltage from a secondary battery to a preset AC voltage (380V). Power plant and;
An AC bus to which the output terminal of the PV DC/AC inverter and the output terminal of the Battery DC/AC inverter are connected in common, an AC/DC power converter that converts AC voltage to a DC voltage, and a DC bus that supplies DC voltage to the microgrid. A power conversion device consisting of; The present invention is an improved invention of a known microgrid system in which an AC voltage is input to the AC bus, and the AC voltage is converted into a DC voltage in an AC/DC power converter to provide low voltage DC distribution to the DC BUS (90).
The microgrid system in consideration of the load environment of the present invention includes a solar cell, a secondary battery, a DC/DC converter converting the output voltage supplied from the DC bus into a preset DC voltage, and the DC/DC converter. A DC/AC inverter that converts the output voltage to a preset AC voltage, a solar cell DC/DC converter that converts the PV output voltage of the solar cell to a preset DC voltage, and the output voltage generated from the secondary battery. A small solar power plant including a secondary battery DC/DC converter converting the DC voltage to a set DC voltage and a distributed load; Constructing a microgrid system including a distributed load power control device connected to the small solar power plant by a communication line;
DC voltage supplied from the DC Bus to DC BUS is distributed to microgrid 1 (MG1), microgrid 2 (MG2), and microgrid 3 (MG3);
The power control device of the distributed load includes a load mode that receives power from DC BUS in a distributed microgrid, an independent mode that is separated from the DC BUS and maintains the load from secondary batteries and sunlight, and the amount of power generated by EMS. It is characterized in that power is controlled in four modes, such as a power generation mode corresponding to and an emergency power generation mode that generates power for DC BUS protection without considering the customer load in case of an emergency.
In addition, the present invention determines the remaining battery capacity of the distributed load and the generation amount of distributed renewable energy.
Monitoring; Distributed load and load demand checking step; Analyzing the surplus power for the energy prosumer and transmitting a command value for power control; A known method of operating a microgrid including a power control step in a distributed load power control system (ADR)
It is an improved invention.
In the microgrid operation method considering the load environment of the present invention, when it is determined that there is no microgrid surplus power in the step of analyzing the surplus power for the energy prosumer and transmitting the command value for power control,
Monitoring the power generation amount, load usage, and charging/discharging of the AC BUS line;
Centralized load and load demand check step; AC/DC bus power converter power control step; It characterized in that it comprises a power control step in the distributed load power control system (ADR).

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According to the present invention, the customer (power consumer) charges the energy storage system (ESS) at a time when the electric charge is low, and uses the required power through the energy storage system discharge at the time when the electric charge is high. There is an effect of saving.

When the energy storage system is applied to each customer, it is possible to solve various power quality problems such as instantaneous voltage drop and rise, instantaneous power outage, and voltage fluctuations, like a transmission and distribution network-connected energy storage system. In addition, an emergency generator is a facility to prepare for the interruption of power supply, and the energy storage system also has the advantage of performing the role of backup power in a situation where power supply is interrupted, such as an emergency generator, using charged power.

By selling surplus electric energy through energy prosumer control, it is possible to improve the utilization rate of the entire system by taking advantage of electricity producers and consumers by purchasing electricity cheaper than the system. There is an effect of reducing losses through low voltage direct current distribution (LVDC) network linkage between multiple microgrids.

According to the present invention, there is an effect of lowering the investment cost of the entire system by introducing energy prosumer technology to consider the microgrid design specification as a normal load level and purchasing energy from another microgrid when a peak load occurs.

1 is a view showing a general industrial complex microgrid system.
2 is a diagram showing the configuration of a general low voltage DC distribution (LVDC) line.
3 is a diagram showing a microgrid system according to the present invention.
4 is a diagram showing a network system of a power control device for a distributed load.
5 is a conceptual diagram of an energy prosumer between distributed loads.
6 is a diagram of a microgrid system in consideration of a load environment according to the present invention.
7 is a flowchart illustrating a method of operating a microgrid in consideration of a load environment.

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

3 is a diagram showing a microgrid system according to the present invention, and FIG. 4 is a diagram showing a network system of a distributed load power control device (ADR).

5 is a conceptual diagram of an energy prosumer between distributed loads, and FIG. 6 is a diagram of a microgrid system in consideration of a load environment according to the present invention. 7 is a flowchart showing a method of operating a microgrid in consideration of a load environment.

It will be described with the drawings shown in FIGS. 3 and 4.

The microgrid system in consideration of the load environment of the present invention includes a microgrid system (parts indicated by dotted lines, MG1, MG2, MG3), a large solar power plant 30, a power conversion device 40, and power of a concentrated load. It consists of a control device (PMS, 60), a load prosumer control device (P (Prosumer)-EMS, 70), and a power control device (ADR, 120) for a distributed load.

The large-scale solar power plant 30 includes a solar cell, a secondary battery, a PV DC/AC inverter 31 that converts the PV output voltage from the solar cell into a preset AC voltage (380V), and a secondary battery. It consists of a Batttery DC/AC inverter 32 that converts the output voltage into a preset AC voltage (380V).

In a large solar power plant 30, the output terminal of the PV DC/AC inverter 31 and the output terminal of the Battery DC/AC inverter 32 are commonly connected to the centralized load 50 through an AC bus (AC BUS, 80). do.

In the power converter 40, the output terminal of the PV DC/AC inverter 31 and the output terminal of the Battery DC/AC inverter 32 are commonly connected to the AC bus 41, so that the AC voltage (380V) is AC/DC power. It is composed of a DC bus 43 that converts the converter 42 to a DC voltage (750V).

The microgrid system MG includes a solar cell, a secondary battery, a DC/DC converter 101 that converts (750V) the output voltage of the power conversion device 40 into a preset DC voltage (380V), and , DC/AC inverter 102 converting the output voltage (380V) generated from the DC/DC converter into a preset AC voltage (220V), and the PV output voltage from the solar cell to a preset DC voltage (380V) A solar cell DC/DC converter 104 converting, a secondary battery DC/DC converter 105 converting the output voltage generated from the secondary battery into a preset DC voltage (380V), and a distributed load 103 A small solar power plant 100 consisting of; It consists of a distributed load power control device 120 connected to the small solar power plant 100 by a communication line.

In one embodiment of the present invention, the capacity of the zero-large solar power plant 30 is 30Kw, and the capacity of the distributed load 103 is usually 3Kw to 5Kw. An AC current of 380 volts (V) flows through the AC BUS (80).

The centralized load 50 is generally 380V as a system load such as a large city housing complex.

A 380V AC voltage is input to the AC Bus 41, and the AC/DC power converter 42 converts it into 750V DC voltage, and the DC BUS 90 becomes 750V low voltage DC distribution (LDVC).

That is, 750V DC voltage is supplied to microgrid 1 (MG1), microgrid 2 (MG2), and microgrid 3 (MG3) through the DC BUS (90) network, which is a low voltage DC distribution (LVDC) line. do.

The configuration of microgrid system 2 (MG2) and microgrid system 3 (MG3) is the same as that of MG1. Depending on the size of the area, a number of microgrid systems (MG) are installed.

The microgrid system (MG) is related to a distributed load 103 such as a general small house or building. The power control device 120 for a distributed load controls power by being connected to the microgrid system MG and the load prosumer control device 70 through a communication line such as Ethernet or MODBUS.

The distributed load power control device 120 shown in FIG. 4 includes a plurality of microgrid systems (MG), the centralized load power control device 60, and the load prosumer control device 70. ) It is a network system connected by a communication line.

Here, the centralized load power control device 60 controls power of the large solar power plant 30, and the load prosumer control device 70 controls power of the microgrid system.

As an example of the present invention, the load prosumer control device 70 is configured by being connected to the microgrid system 1 (MG1) through the power control device 120 of a distributed load,

The microgrid system 1 converts a bidirectional DC/DC converter 101 that converts 750V DC voltage to 380V DC voltage, a secondary battery DC/DC converter 105, and converts the output voltage produced by a solar cell into a 380V DC voltage. It consists of a PV DC/DC converter 104 and a single-phase inverter 102 that converts 380V DC voltage to 220V AC voltage.

Microgrid system 2 (MG2) and microgrid system 3 (MG3) are configured identically to microgrid system 1 (MG1).

The power control device 120 for a distributed load according to an exemplary embodiment of the present invention is connected through an Ethernet-based communication line to receive energy control information.

The power control device 120 of a distributed load may implement the following four power control modes in a distributed microgrid.

(1) Mode 1 (load mode): mode to receive power from DC BUS (mode to receive power from DC BUS by charging the secondary battery and operating the load)

(2) Mode 2 (independent mode): A mode that is separated from the DC BUS and maintains the load from the secondary battery and sunlight (a mode that is independent from the DC BUS and does not collect power)

(3) Mode 3 (Generation Mode): Mode corresponding to the amount of power generated by EMS (a mode that generates power when the amount of power generated by secondary batteries and solar power is greater than the load)

(4) Mode 4 (emergency power generation mode): This is a mode that generates power for DC BUS protection without considering the customer load in an emergency.

The main purpose of the distributed load power control device 120 is to increase the stability of the system through the power generation mode targeting the distributed load. Accordingly, it is possible to control the power of the microgrid (MG) in a distributed load, and to operate the energy puller according to a command instructed by the load prosumer control device 70.

5 shows an energy prosumer between distributed loads.

As shown in FIG. 5, the energy transaction system (energy prosumer) has excess energy in order to solve the problem of generation of excess energy (surplus power) and insufficient energy (lack of power) when constructing a new and renewable energy power generation complex. It is a system capable of trading electricity from the generated power generation system to the system where insufficient energy is generated.

Electricity is purchased due to lack of electricity due to peak load generation or lack of renewable energy generation. Where surplus power is generated, profits are generated from power sales.

The prosumer agent earns a commission profit from the arbitrage through the power relay for the transaction. Each distributed load can be either a prosumer selling surplus power or a consumer buying scarce power.

For example, distributed load 1 becomes a prosumer, distributed load 2 becomes a consumer, vice versa, distributed load 2 becomes a consumer, and distributed load 1 becomes a prosumer.

In the hybrid microgrid system (MG) using renewable energy, surplus and underpower are generated in the microgrid depending on the amount of solar irradiation or the amount of load used. When excess power is generated within the microgrid system (MG), it is regarded as wasted energy unless there is a special load factor, and the utilization rate of the system may be reduced.

In order to solve this problem, it is possible to improve the utilization rate of the entire system by selling the remaining electric energy through the energy prosumer and taking the benefit of the electricity producer and the consumer by purchasing electricity cheaper than the system.

That is, the surplus power generated by microgrid 1 (MG1) can be sold to microgrid 2 (MG2). Conversely, surplus power produced by Migrogrid 2 (MG2) can be sold to Microgrid 1 (MG1).

The most important system among energy prosumer system configurations is the PCS (Power Conversion System), which delivers the generated power to the load. The reliability of PCS affects securing the reliability of the entire system. PCS refers to the power conversion device 40, a converter and an inverter.

The present invention is a technical feature of reducing power loss by linking a low voltage direct current distribution (LVDC) network to a plurality of microgrid systems (MG).

6 is a diagram of a microgrid system in consideration of a load environment according to the present invention.

The present invention applies low-voltage direct current distribution (LVDC) for long-distance energy transmission, and the network of the power control device 120 of a distributed load is configured with a plurality of microgrid systems (MG) by means of an Ethernet (Ethernet/ MODBUS) communication line. It is connected to the load power control device 60 and the load prosumer control device 70.

The microgrid system (MG) connects to small houses or apartments and distributed loads. The composition of microgrid 1 (MG1), microgrid 2 (MG2) and microgrid 3 (MG3) is the same.

According to the present invention, it is possible to control the output of a renewable energy power generation source (solar photovoltaic power generation) to supply stable and clean power to customers, and to increase the efficiency of the entire system through real-time system optimization including the power generation source.

7 is a flowchart showing a method of operating a microgrid in consideration of a load environment.

The microgrid operation method shown in FIG. 7 includes the steps of monitoring a battery (secondary battery) residual amount (SOC) and a distributed renewable energy generation amount of a distributed load; Distributed load and load demand checking step; Analyzing the surplus power for the energy prosumer and transmitting a command value for power control; It characterized in that it comprises a power control step in the distributed load power control system (ADR).

However, when it is determined that there is no microgrid surplus power in the step of analyzing the surplus power for the energy prosumer and transmitting the command value for power control,

Monitoring the power generation amount, load usage, and charging/discharging of the AC BUS 80 line;

Centralized load 50 and load demand check step; AC/DC Bus power conversion device 40 power control step; A microgrid is operated as the power control stage in the distributed load power control system (ADR).

According to the present invention, a stand-alone microgrid capable of optimally and stably supplying power to an island or remote place without a commercial power grid can supply power through a distributed power source including renewable energy instead of supplying power only to a conventional diesel generator.

Customers (power consumers) can reduce the energy cost of customers by charging the energy storage system during times of low electricity rates and discharging the energy storage system during periods when electricity rates are high.

In particular, an embodiment of the present invention proposes an energy prosumer technology capable of coping with the peak load between microgrids MG, since the installation cost of the microgrid system increases when the instantaneous peak load is high, and thus uneconomical investment can be made.

As described above, the present invention is not limited thereto, and the claims can be modified and modified within the scope of the technical idea of the present invention by those of ordinary skill in the art to which the present invention pertains.

30: Large solar power plant
40: power converter
50: centralized load
60: Centralized load power control device (PMS)
70: load prosumer control device (P-EMS)
80: AC bus
90: DC BUS
100: small solar power plant
101: DC/DC converter
102: DC/AC inverter
103: distributed load
120: Distributed load power control device (ADR)
MG1: Microgrid system 1
MG2: Microgrid system 2
MG3: Microgrid system 3

Claims (6)

At least one distributed power source; a power conversion device that converts power of the distributed power source into direct current; and a DC power load connected to the power conversion device;
A solar cell, a secondary battery, a PV DC/AC inverter 31 that converts the PV output voltage from the solar cell into a preset AC voltage, and a battery that converts the output voltage from the secondary battery into a preset AC voltage. A large solar power plant 30 composed of a DC/AC inverter 32;
An AC bus 41 to which the output terminal of the PV DC/AC inverter 31 and the output terminal of the Battery DC/AC inverter 32 are commonly connected, and an AC/DC power converter 42 that converts AC voltage to DC voltage And, a power conversion device 40 composed of a DC bus 43 for supplying a DC voltage to the microgrid; A well-known microgrid system in which an AC voltage is input to the AC bus 41 and converts the AC voltage to a DC voltage in the AC/DC power converter 42 so that the DC BUS 90 becomes a low voltage DC distribution (LDVC). In,
A solar cell, a secondary battery, a DC/DC converter 101 converting the output voltage supplied from the DC bus 43 into a preset DC voltage, and an output voltage generated from the DC/DC converter 101 A DC/AC inverter 102 that converts the PV into a preset AC voltage, a solar cell DC/DC converter 104 that converts the PV output voltage of the solar cell into a preset DC voltage, and the secondary battery. A small solar power plant 100 including a secondary battery DC/DC converter 105 for converting the output voltage to a preset DC voltage and a distributed load 103; And a microgrid system including a distributed load power control device 120 connected to the small solar power plant 100 by a communication line;
The DC voltage supplied from the DC Bus 43 to the DC BUS 90 is distributed to the microgrid 1 (MG1), the microgrid 2 (MG2), and the microgrid 3 (MG3);
The distributed load power control device 120 has a load mode for receiving power from the DC BUS 90 in the distributed microgrid, and is separated from the DC BUS 90 to maintain the load from the secondary battery and sunlight. A load characterized by controlling power in four modes, such as an independent mode, a power generation mode corresponding to the power generation required by EMS, and an emergency power generation mode that generates power to protect the DC BUS 90 without considering the customer load in case of an emergency. Microgrid system considering the environment.
delete delete delete delete Monitoring the remaining amount of the battery and the amount of distributed renewable energy generation of the distributed load; Distributed load and load demand checking step;
Analyzing the surplus power for the energy prosumer and transmitting a command value for power control; In a method for operating a known microgrid including a power control step in a distributed load power control system (ADR),
When it is determined that there is no microgrid surplus power in the step of analyzing the surplus power for the energy prosumer and transmitting the command value for power control,
Monitoring the power generation amount, load usage, and charging/discharging of the AC BUS 80 line;
Centralized load 50 and load demand check step; AC/DC Bus power conversion device 40 power control step; A method of operating a microgrid in consideration of a load environment, comprising a power control step in a distributed load power control system (ADR).

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