KR20110050858A - Micro-grid system and method for controlling load in static transfer switch - Google Patents

Abstract

PURPOSE: A micro-grid system and a method for controlling load in a static transfer switch are provided to protect main components of a micro-grid system by monitoring power quality. CONSTITUTION: A micro-grid system comprises plural loads, an energy storage device, an energy management system(23) and a static switch. The static switch comprises a blocking unit, a current detector, a voltage detector and a control unit, and receives the information on the micro-grid system from the energy management system. In addition, the static switch calculates the load blocking amount based on the information received from the energy management system when being switched into an independent operation.

Description

Load control method for microgrid system and stationary switch {MICRO-GRID SYSTEM AND METHOD FOR CONTROLLING LOAD IN STATIC TRANSFER SWITCH}

The present invention relates to load control in a microgrid system, and more particularly, in a stationary switch connecting a power supply network and a microgrid system, when the microgrid system switches to independent operation of the microgrid system due to an abnormality in the power supply network. The present invention relates to a microgrid system and a load control method of a stationary switch that can directly control a load to eliminate problems that may occur when switching to independent operation.

As a solution for environmental and energy problems, various distributed power sources, including renewable energy, have been supplied, and the demand and capacity are rapidly increasing.

In the case of photovoltaic or wind power generation that utilizes renewable energy among distributed power sources, power production is sensitive to weather conditions, and there is a time lag in the production and demand of electric power. It is necessary to link with In order to efficiently supply the power generated from such distributed power supplies to the load, a small power supply network having an energy storage device and connected to the distribution system is called a micro-grid.

Among the consumers who only consumed microgrids, consumers who have the ability to supply power as well as their own consumption by their power generation facilities appeared on the power supply chain. It is a technology for maximizing the energy utilization of the entire network by utilizing electrical energy produced by self-developed customers scattered in the power supply network, and a new power generation / consumption model. .

Micro-Grids that are made on a small scale for these grids are called Micro-Grids, and those made over a wide area at a national level are Smart Grid, Super Grid, Smart Electric Grid, Smart Power Grid, Intelli-Grid, Future Grid, It is called by various names such as Inter-Grid, Intra-Grid, etc.

1 shows a configuration of a general microgrid system, a distributed power source such as wind power generation 15, photovoltaic power generation 18, fuel cell power generation 20, energy storage devices such as storage battery storage device 19, a plurality of And a protective switch 11, a transformer 12 and a stationary switch 13 for connecting the microgrid system 14 to the power supply network 10 via an interconnection point 24. Is used, and an energy management system 23 for integrally monitoring and controlling these distributed resources 15, 18, 19, 20, the loads 16, 17, and the stationary switch 13 is provided through the communication network 22. It is connected.

The microgrid system 14 may be operated in connection with a commercial power supply network 10. When the power failure occurs in the commercial power supply network 10 due to a power failure, the microgrid system 14 independently powers the plurality of loads 16 and 17. And heat can be supplied. The energy management system 23 collects the heat and power loads 16 and 17 demand information in the microgrid system 14 through the digital calorimeter 21, the solar 18, the wind 15, and the fuel cell ( 20, such as the generation amount information of the distributed power supply, the state information of the energy storage device 19, etc. are collected through communication with the respective control system to minimize the energy cost of the customer in the micro grid system 14 or the commercial power supply network (10). It is a device that controls the distributed resources (15, 18, 19, 20) and the energy storage device (19) for economical operation, such as the optimization of the purchase power from the maximum or suppress the maximum value.

In particular, during independent operation, if the capacity of the distributed resources (15, 18, 19, 20) and the energy storage device (19) in the micro grid system 14 is insufficient compared to the load by controlling the non-critical load (17) directly It is necessary to balance the demand (load) and supply (power generation). In this case, the wind power generation (15) and the photovoltaic power generation (18) may not generate enough power (16, 17) depending on the weather conditions. This can happen if it takes a lot.

Here, the non-critical load 17 may refer to a load capable of stopping operation even if the inconvenience is required, such as an air conditioner or a heating device.

Figure 2 shows the configuration for the protection and monitoring of the microgrid system consisting of existing devices, when configured with existing devices to implement the functions of the microgrid system described above directly for direct load control The load control device 31 should be used, and the synchronous input device 32 should be used in order to operate the microgrid system that is being operated independently to the power supply network 10 again.

In addition, the power quality measuring device 33 and the link protection digital protection relay 34 for power quality measurement at the link point 24 should be used together with the link switch 30.

As such, the conventional microgrid system requires that the direct load control function, the power quality monitoring function, and the resynchronization input function must be configured as individual devices, and each device individually measures and calculates electrical elements such as voltage and current. I had redundant functions. The individual devices include protective relays, switches, direct load controllers, power quality measuring devices and synchronous input devices. Partial combinations of these functions, for example the combination of protective relays and power quality measuring devices, combinations of protective relays and switches There is no such thing as a full-featured device. In addition, in order to apply to a specific application such as a microgrid system, there is no choice but to configure through a combination of these devices, resulting in the complexity of the device configuration, the increase in cost.

3 is a view illustrating the necessity of direct load control in a microgrid system, and the purpose of the direct load control is to protect the critical load 16 from the accident of the power supply network 10 or deterioration of power quality in the microgrid system. The microgrid system 14, which is operated independently due to an imbalance in the amount of generation of the distributed resources 15, 18, 19, 20 in the microgrid system 14 and the demand of the loads 16, 17 when switching to independent operation. This is to prevent the system collapse, that is, power failure due to the voltage, frequency maintenance failure.

Such a collapse of the system is due to the magnitude of positive or negative current at the junction 24 with the power grid 10 of the microgrid system 14, i.e. the amount of electricity generated within the microgrid system 14. The power flow due to the difference in load depends on the amount of inflow or outflow from the power supply network 10 and the response characteristics of the distributed resources 15, 18, 19, and 20 inside the microgrid system 14.

That is, when the generation output of the distributed resources 15, 18, 19, 20 is smaller than the demand of the loads 16, 17, the difference is introduced from the power supply network 10, and vice versa. As much as the flow into the power supply network 10 to balance the power supply-demand in the microgrid system 14. In the case of switching to independent operation, the former is represented by a drop in frequency and voltage, and in the latter case, the frequency and voltage are increased, and in any case, the protection relay operates over the voltage and frequency to shut off the system. . The stable power maintenance range, which is usually determined by the power trade agreement, is in the range of 59.3 to 60.5 [Hz] and voltage ± 10 [%].

3A illustrates a case in which positive current flows from the link point 24, that is, when the amount of power generated inside the microgrid system 14 is smaller than the load amount, the frequency and voltage drop when switching to independent operation. Beyond the frequency variation tolerance (f _range ) and the voltage variation tolerance (V _range ), the system eventually collapses.

3B illustrates a case in which a negative current flows from the link point 24, when the amount of power generated inside the microgrid system 14 is greater than the load, and the frequency and voltage increase when switching to independent operation. Beyond the f _range and V _range , the system eventually collapses.

As such, the direct load control function required for switching from a microgrid system to an independent operation may be implemented in an energy management system that manages, monitors, and controls the microgrid system. However, the energy management system collects and commands information through communication. Since it transmits the power transmission network has a problem that is difficult to apply when the transient is made within a short time of 1 to several cycles of the network frequency (60 Hz).

That is, the microgrid system may cause unstable operation or failure to switch to independent operation due to capacity limitation of distributed resources and limitation of response speed.

An object according to an embodiment of the present invention, which was created to solve the above problems, is a problem that may occur when switching to independent operation by implementing a direct load control function on an electrostatic switch connecting a microgrid system and a power supply network. In order to solve these problems, the present invention provides a load control method for a microgrid system and a stationary switch that can improve the reliability of the system.

Furthermore, another object according to an embodiment of the present invention is to implement a function of measuring and monitoring the power quality inside the microgrid system in the electrostatic switch, thereby disconnecting the system if the load does not meet the required level. Or by instructing the compensator to make the appropriate compensation, it is possible to supply stable quality power to the load to prevent malfunction of precision equipment, and to reduce the complexity of the system and the cost of implementing the system by integrating the functions. And a load control method for a stationary switch.

Furthermore, another object according to an embodiment of the present invention is to provide a microgrid system and a load control method of a stationary switch, which can implement a function for switching from an independent operation to a linked operation to a power supply network in an electrostatic switch. have.

In order to achieve the above object, a microgrid system according to an aspect of the present invention is a microgrid system including a plurality of distributed power supplies, an energy storage device, and a plurality of loads, in connection with a communication network, to each of the plurality of loads. Energy for collecting power demand information, state information including power generation for each of the plurality of distributed power supplies, and state information including capacity for the energy storage device, and integrated management of the microgrid system in connection with a power supply network; Management system; And detecting a power flow between the power supply network and the microgrid system, and using the detected power flow and information received from the energy management system, each of the plurality of loads when switching to independent operation of the microgrid system itself. It may include a stationary switch for controlling directly.

Preferably, the stationary switch calculates the interruption amount or the additional amount of the load when switching to independent operation using the detected power current and the information received from the energy management system, and the interruption calculated when switching to the independent operation. The load corresponding to the quantity or additional quantity can be cut off or added.

Preferably, the stationary switch may block or add a load corresponding to a difference between the size of the power current and the capacity of the energy storage device when the size of the power current is greater than the capacity of the energy storage device. have.

Preferably, the plurality of loads may include a critical load greater than or equal to a reference importance, a non-critical load less than the reference importance, and a dummy load for controlling surplus power according to a predetermined importance.

Preferably, the stationary switch may cut off the load corresponding to the difference between the size of the power current and the capacity of the energy storage device in the non-critical load or add the dummy load when switching to independent operation.

Preferably, the plurality of distributed power sources may include a photovoltaic generator, a wind generator, a diesel generator, a microturbine and a fuel cell, and the energy storage device includes a battery energy storage system (BESS) and a superconducting magnetic energy storage (SMES). , Flywheel, or super capacitor.

In the load control method of the stationary switch according to an aspect of the present invention, in the microgrid system including a plurality of distributed power supplies, energy storage devices, a plurality of loads, a stationary switch and an energy management system, Power demand information for each of the plurality of loads collected in association with a communication network in the energy management system, state information including power generation for each of the plurality of distributed power sources, and state information including capacity for the energy storage device. Receiving; Detecting a power flow between a power supply network and the microgrid system; And directly controlling each of the plurality of loads when switching to independent operation using the detected power current and the information received from the energy management system.

Preferably, the controlling may include calculating an interruption amount or an additional amount of the load at the time of switching to independent operation by using the detected electric current and the information received from the energy management system; And blocking or adding a load corresponding to the cutoff amount or the additional amount calculated when switching to independent operation.

Preferably, the controlling may include comparing the size of the power current and the capacity of the energy storage device; And blocking or adding a load corresponding to a difference between the size of the power bird and the capacity of the energy storage device when the size of the power bird is greater than the capacity of the energy storage device. .

Preferably, the adding step includes the step of checking the direction of the power current if the size of the power current is greater than the capacity of the energy storage device beam; When the direction of the power current is in the direction of the microgrid system, blocking a load corresponding to a difference between the size of the power current and the capacity of the energy storage device among the plurality of loads; And when the direction of the power current is in the direction of the power supply network, adding a load corresponding to a difference between the size of the power current and the capacity of the energy storage device among the plurality of loads.

The present invention integrates a variety of functions, such as the switching function, the function of measuring and monitoring the power quality inside the microgrid system, by integrating the functions of the stationary switch, which is essential to the microgrid system, to ensure stable operation and power quality of the microgrid system. It can be expected to protect important loads by management, actively use distributed resources in microgrids, further reduce system implementation costs, and reduce system configuration complexity.

Other objects and features of the present invention in addition to the above object will be apparent from the description of the embodiments with reference to the accompanying drawings.

Hereinafter, a load control method of a microgrid system and a stationary switch according to an embodiment of the present invention will be described in detail with reference to FIGS. 4 to 7. In the following description of the present invention, a detailed description of known functions and configurations incorporated herein will be omitted when it may make the subject matter of the present invention rather unclear.

4 illustrates a microgrid system according to an embodiment of the present invention.

Referring to FIG. 4, the microgrid system 14 includes a distributed power supply 15, 18, 20, a plurality of loads 16, 17, 38, an energy storage device 19, an energy management system 39, and a stationary switch. (37).

The distributed power sources 15, 18, and 20 generate power in the microgrid system 14 to provide power to the plurality of loads 16, 17, and 38. A solar generator, a wind generator, a diesel generator, and a micro It can include a variety of resources applicable to microgrid systems, such as turbines and fuel cells.

The plurality of loads 16, 17, and 38 consume power coming from the power supply network 10 or power generated in the microgrid system 14, and the important loads 16 having a reference importance or more according to a predetermined importance may be used. It may include a non-critical load 17 of less than the reference importance, and a dummy load 38 for controlling surplus power when switching the independent operation.

Here, the important load 16 is a load excluding a non-critical load and a dummy load among the plurality of loads, and means a load that must be supplied with power even when switching to independent operation, and the non-critical load 17 is as described above. Means a load that can stop the operation even if the inconvenience, such as air conditioning, heating, etc., if necessary, the dummy load 38 is kept in a blocked state when connected to the power supply network 10 when switching to independent operation When the amount of generation of distributed resources (15, 18, 19, 20) in the microgrid system is greater than the load of the critical load and the non-critical load, it means the load to consume surplus power.The non-critical load and the dummy load are divided into several groups. It can also be configured to be disconnected or added at any time as desired when running independently.

The energy storage device 19 is a device for storing energy. The energy storage device 19 is a distributed resource capable of quickly adjusting the inflow or outflow of electrical energy in the microgrid system and allowing the output to be arbitrarily adjusted within the capacity range. It is suitable for stabilization in the transitional state such as transition, and the installed capacity plays a decisive role in improving the characteristics during transition.

In this case, the energy storage device 19 may include all means for storing energy and providing energy as needed, such as a battery energy storage system (BESS), a superconducting magnetic energy storage (SMES), a flywheel, and a super capacitor. .

The energy management system 39 is a system for integrated management of the micro grid system 14 in connection with the power supply network 10. In connection with the communication network 22, power demand information for each of a plurality of loads and a plurality of distributed power sources, respectively. Collecting state information including the amount of power generation and state information including the capacity for the energy storage device is collected and provided to the electrostatic switch.

Here, the energy management system 39 may collect important load and non-critical load demand information through the digital electricity meter 21, and may store dummy load demand information in advance.

Of course, the energy management system 39 may provide not only the above-described information but also various information required by the stationary switch to the stationary switch 37, and the information may be provided to the stationary switch 37 at a predetermined time period or may be constant. It may be provided only if the conditions are met, where a certain period of time and certain conditions may be determined where the microgrid system is provided.

The stationary switch 37 detects a power flow between the protective switch 11 and the power supply network 10 connected to the transformer 12 and the microgrid system 14 through the link point 24, and detects the power flow and energy detected. Insufficient power and surplus power when the microgrid system is switched to independent operation due to problems in the power supply network using information received from the management system 39, for example, the amount of generation of distributed power, the capacity of the energy storage device, and the plurality of loads. Repeat the process of setting the non-critical load (17) to be blocked or the dummy load (38) to be added by a predetermined time period, and cut off the non-critical load set at that time when switching to independent operation. Adding loads eliminates problems that can be caused by supply-demand differences in power in the microgrid system when switching to stand-alone operation. Stem can be stabilized quickly.

In this case, the stationary switch 37 may set a load amount corresponding to the detected difference between the size of the power current and the capacity of the energy storage device 19 among non-critical loads or dummy loads, and the ratio set at that time when switching to independent operation is performed. Critical loads can be interrupted or dummy loads can be added.

Furthermore, the stationary switch 37 calculates the load corresponding to the difference between the size of the power bird and the capacity of the energy storage device only when the size of the power bird is larger than the capacity of the energy storage device, and based on the non-critical load to be cut off based on this. You can set the dummy load you want to set or add.

Furthermore, the stationary switch 37 may add a dummy load to control surplus power when switching to independent operation, but may control the output of the distributed power sources 15, 18, 20, The surplus power may be controlled by separately performing the output control of the distributed power source, but the surplus power may be controlled in parallel.

Of course, the stationary switch 37 preferably cuts off the load corresponding to the difference because when the direction of the detected power flow is introduced into the microgrid system 14, the demand in the system is larger than the generation of distributed resources. In addition, when the detected direction of the power current flows into the power supply network 10, it is preferable to add a load corresponding to the difference since the demand in the system is smaller than the generation of distributed resources.

FIG. 5 shows an embodiment configuration of the stationary switch shown in FIG. 4.

Referring to FIG. 5, the stationary switch 37 includes a blocking means 41, a current detector 43, voltage detectors 40 and 44, and a controller 50.

The blocking means 41 is a means for connecting or disconnecting the power supply network 10 and the micro grid system 14. The blocking means 41 is turned on or off by the control by the controller 50, and thus the power supply network 10 and the micro grid. The system 14 can be connected or disconnected.

Here, the blocking means 41 may use a semiconductor switch such as a thyristor.

The current detector 43 is a means for detecting a current flowing through the blocking means 41, and is installed only at either the microgrid system 14 side or the power supply network 10 side.

This is because in the system operation with the power supply network 10, since the blocking means 41 is turned on, the currents on the power supply network 10 side and the microgrid system 14 side have the same magnitude, but independent operation, that is, interruption. This is because no current flows when the means 41 is open.

The voltage detectors 40 and 44 are means for detecting the voltage on the power supply network 10 side and the voltage on the microgrid system 14 side.

The controller 50 uses the current and voltage detected by the current detector 43 and the voltage detectors 40 and 44 and the information stored from the energy management system to store the direct load control function, power quality monitoring function, and power supply network. Performs power-on detection and synchronization input function.

In this case, the control unit 50 may output the switching control signal to the blocking means 41 according to whether the power supply network is abnormal, thereby connecting or disconnecting the power supply network and the microgrid system.

The controller 50 may determine whether the accident is a power supply network side or a microgrid system side by using the direction information of the current detected by the current detector 43.

The control unit 50 uses the power current detected by the current detector 43 and the voltage detectors 40 and 44, power generation information provided from the energy management system, capacity information of the energy storage device, and the like when switching to independent operation. Calculate the difference between power generation and demand, and perform direct load control function to directly control a plurality of loads when switching to independent operation based on the calculated difference.

In addition, the controller 50 monitors power quality such as power failure, voltage harmonics, voltage drop, and voltage rise during the interlocking operation by using the voltage of the power supply network side and the voltage of the microgrid system detected by the voltage detectors 40 and 44. In the independent operation, it is possible to detect the restoration of the power supply network 10 and perform synchronous injection.

Herein, the controller 50 constantly monitors the power quality in the microgrid system 14 to disconnect the system when the power quality does not satisfy the level required by the load, or allow a compensation device (not shown) to provide appropriate compensation. It can be commanded to do so, which can provide a stable quality power to the load.

In this case, the controller 50 may perform synchronous input with the power supply network by using the voltages detected by the voltage detectors 40 and 44 on both sides, which will be described below.

The control unit 50 checks whether the power supply network has been restored while the blocking means 41 is in an off state, and if the power supply network is not restored, the control state is continuously checked, and when the power supply network is restored, the power supply network voltage The voltage detected by the detector 40 and the voltage detected by the voltage detector 44 on the microgrid system side are used to confirm voltage deviation, frequency deviation, and phase deviation.

The controller 50 outputs a control signal for turning on the shutoff means 41 to the shutoff means 41 only when the voltage deviation, the frequency deviation, and the phase deviation are all within a preset allowable set value range for each. Of course, the controller 50 does not turn on the blocking means by determining that the synchronization input condition is not satisfied when any one of the three conditions, that is, the voltage deviation, the frequency deviation, and the phase deviation, is not within the predetermined allowable set value range.

At this time, the controller 50 sends the reactive power and the active power output commands to the controllable distributed power supply in the microgrid system based on the information received from the energy management system, thereby reducing the voltage deviation and the frequency deviation between the microgrid system and the power supply network. It can be set within a certain allowable set point range, and in the case of a phase deviation, it can be set by waiting for the phase deviation to be within a set allowable set point range.

As shown in FIG. 4, the control unit 50 performing the above operations includes a digital signal processor 52 capable of high-speed operation, and is detected by the voltage detectors 40 and 44 and the current detector 43. The noise included in the voltage and current values can be removed using the filters 45 and 47 and then converted into digital values using the analog-to-digital converter 49 to be read. On-off signal is output through the digital output port 48, which is converted into a control signal for controlling the blocking means 41 by the signal conversion 46 and output.

The digital output buffer 56 outputs a digital output for direct load control, and the signal output from the digital output buffer 56 may be an off signal for blocking a non-critical load or an on signal for adding a dummy load. .

The communication port 53 is connected to a distributed power source, an energy storage device, a multi-meter digital meter and an energy management system through a communication line, and information provided from the energy management system through the communication port, for example, generation amount and load information. Will be transmitted in real time and control such as load control from this information. The memory 55 is a place for storing information provided from an application program and an energy management system, and the display and operation unit 51 is a device for displaying and operating an operation state.

As such, the microgrid system according to an embodiment of the present invention integrates various functions such as a direct load control function, a synchronous input function, and a power quality monitoring function in a stationary switch, thereby reducing the economic cost burden and providing independent operation. The reliability of the system can be improved by solving problems such as system collapse that may occur during the transition.

6 is a flowchart illustrating an operation of a load control method of a stationary switch according to an exemplary embodiment of the present invention.

Referring to FIG. 6, the stationary switch receives information on a microgrid system required to perform a direct load control function from an energy management system that integrates and manages the microgrid system (S610).

At this time, the stationary switch may be provided from the energy management system with information on the amount of power generated by the plurality of distributed power sources, the capacity and charge state of the energy storage device, the consumption capacity of each of the plurality of loads, and the like at a predetermined time period or in real time.

The stationary switch detects a power flow between the power supply network and the microgrid system by using the current detected by the current detector and the power detector provided in the switch, the voltage of the power supply network side, and the voltage of the microgrid side (S620).

The stationary switch calculates the load breaking amount to be cut off or the load addition amount to be added when switching to the independent operation using the detected power current and the information provided from the energy management system (S630).

This process, ie, steps S610 to S630 are repeatedly performed until switching to independent operation (S640).

In step S640, when the stationary switch is switched to independent operation of the microgrid system itself due to a power failure of the power supply network or the like, switching to independent operation is performed by cutting off or adding a load corresponding to the load calculated before the independent operation. Problems that may be caused by an imbalance between supply and demand in the city may be prevented, for example, collapse of the microgrid system that may be caused by the problem illustrated in FIG. 3 (S650).

FIG. 7 is a flowchart illustrating an embodiment of operation S630 of FIG. 6.

Referring to FIG. 7, the stationary switch compares the size (A) of the detected power bird with the capacity (B) of the energy storage device among the information provided from the energy management system, and the size of the power bird is larger than that of the energy storage device. It is determined whether (A> B) (S710, S720).

As a result of determining in step S720, if the size of the power current is smaller than the capacity of the energy storage device, even if the microgrid system is switched to independent operation, the load can be cut off because the power consumption of the distributed power source and the capacity of the energy storage device can be used. Since there is no need to add, the load breaking amount is set to 0 (S790).

On the other hand, if the size of the power bird is greater than the capacity of the energy storage device as a result of the determination in step S720, the direction of the power bird is checked (S730).

Here, the direction of the power current can be known through the direction of the current detected by the current detector.

When the direction of the power flow is the direction flowing into the microgrid system, that is, when the power flows from the power supply network to the microgrid system, when the connection point is cut off, the power consumption of the configured load in the system is larger than the generation of distributed power and the energy storage device is Since the output beyond the capacity is impossible, the difference between the size of the power current and the capacity of the energy storage device (AB) is calculated as the load breaking amount (C), and the closest to the load breaking amount calculated from the predetermined non-critical load among the plurality of loads. Set the load to the breaking load (S750, S760).

This is because the amount of power generated in the microgrid system and the capacity of the energy storage device alone cannot cover the consumption of the load configured in the system when switching to stand-alone operation. The purpose is to reduce the consumed capacity by the difference of the storage capacity AB.

On the other hand, when the direction of the power flow is the direction of leakage from the microgrid system, that is, when the power of the microgrid system flows out to the power supply network, when the connection point is cut off, the power consumption of the configured load in the system is smaller than the generation of distributed power. Calculate the size difference and the capacity difference (AB) of the energy storage device as the load addition amount (C), and sets the load closest to the load addition amount from the dummy load for stabilizing the system among the plurality of loads as additional loads (S770, S780). ).

This is because only the amount of power generated in the microgrid system and the capacity of the energy storage device are used to switch to stand-alone operation, since surplus power is generated even though the power consumption of the load configured in the system is satisfied, power flow is required to match the supply capacity and the capacity when switching to stand-alone operation. We want to add the capacity consumed by the difference between the size and the capacity of the energy storage device (AB).

Of course, if the direction of the power flow is outflow from the microgrid system, by controlling the output limit of the distributed power source separately from adding the consumption capacity, it is possible to reduce the amount of power generated in the microgrid system, can be performed separately, complementary It can also be performed in a relationship.

6 and 7, the capacitive switch determines whether to switch the independent operation by the power supply network monitoring function. If the independent switch is not switched to the independent operation, a new shut-off for the power generation and load changes every minute Or, it can be seen that the additional load amount is calculated / set, and when switching to stand-alone operation, the microgrid system is stably switched to stand-alone operation mode by immediately shutting off a previously set load or outputting an additional load control signal.

The microgrid system is able to maintain the power supply balance within the system by the power supply command of the energy management system in the normal operation of the independent state.

The load control method of the microgrid system and the stationary switch according to the present invention can be modified and applied in various forms within the scope of the technical idea of the present invention and is not limited to the above embodiments. In addition, the embodiments and drawings are merely for the purpose of describing the contents of the invention in detail, not intended to limit the scope of the technical idea of the invention, the present invention described above is common knowledge in the technical field to which the present invention belongs It should be understood that those having a variety of substitutions, modifications, and changes without departing from the spirit and scope of the present invention are not limited to the embodiments and the accompanying drawings. Judgment should be made including scope and equivalence.

1 shows a configuration of a general microgrid system.

Figure 2 shows the configuration for the protection and monitoring of a microgrid system consisting of existing devices.

Figure 3 is shown to explain the need for direct load control in a microgrid system.

4 illustrates a microgrid system according to an embodiment of the present invention.

FIG. 5 shows an embodiment configuration of the stationary switch shown in FIG. 4.

6 is a flowchart illustrating an operation of a load control method of a stationary switch according to an exemplary embodiment of the present invention.

FIG. 7 is a flowchart illustrating an embodiment of operation S630 of FIG. 6.

Claims (14)

A microgrid system comprising a plurality of distributed power supplies, an energy storage device, and a plurality of loads, In connection with the communication network, the power demand information for each of the plurality of loads, the state information including the amount of power generation for each of the plurality of distributed power sources and the state information including the capacity for the energy storage device is collected, and the power supply network and An energy management system for integrated management of the microgrid system in association; And Detects a power flow between the power supply network and the microgrid system, and converts each of the plurality of loads when switching to independent operation of the microgrid system itself using the detected power flow and information received from the energy management system. Directly controlled stop switch Microgrid system comprising a. The method of claim 1, The stationary switch is Using the detected power current and the information received from the energy management system, the breaking amount or addition amount of the load when switching to independent operation is calculated, and the breaking amount or addition amount calculated when switching to independent operation is calculated. Microgrid system, characterized in that the load is interrupted or added. The method according to claim 1 or 2, The stationary switch is And if the size of the power bird is greater than the capacity of the energy storage device, blocking or adding a load corresponding to a difference between the size of the power bird and the capacity of the energy storage device among the plurality of loads. The method according to claim 1 or 2, The plurality of loads A microgrid system comprising a critical load of more than a reference importance, a non-critical load less than the reference importance, and a dummy load for controlling surplus power according to a predetermined importance. The method of claim 4, wherein The stationary switch is When switching to independent operation, the microgrid system, characterized in that the load corresponding to the difference between the size of the power current and the capacity of the energy storage device is cut out of the non-critical load or added from the dummy load. The method of claim 4, wherein The stationary switch is And controlling outputs of the plurality of distributed power supplies to control surplus power corresponding to a difference between the size of the power current and the capacity of the energy storage device when switching to independent operation. The method according to claim 1 or 2, The stationary switch is Blocking means for connecting or disconnecting the power supply network and the microgrid system; A current detector for detecting a current flowing through the blocking means; A voltage detector for detecting a voltage across the power supply network and a voltage across the microgrid system; And Detects a power bird using the current and voltage detected by the current detector and the voltage detector, controls the blocking means according to the abnormality of the power supply network, and receives from the detected power bird and the energy management system Control unit for directly controlling each of the plurality of loads when switching to independent operation of the microgrid system itself using the information obtained Microgrid system comprising a. The method according to claim 1 or 2, The plurality of distributed power supplies Microgrid system comprising a solar generator, a wind generator, a diesel generator, a microturbine and a fuel cell The method according to claim 1 or 2, The energy storage device Microgrid system, characterized in that any one of the BESS (Battery Energy Storage System), SMES (Superconducting Magnetic Energy Storage), flywheel, super capacitor. The method according to claim 1 or 2, The capacitive switch is Detects the voltage on the power supply network side and the voltage on the microgrid system, and if the voltage deviation, frequency deviation, and phase deviation for both detected voltages are within a predetermined allowable set range for each Microgrid system, characterized in that the synchronous input to the power supply network. In the microgrid system including a plurality of distributed power supplies, energy storage device, a plurality of loads, a stationary switch and an energy management system, the load control method of the stationary switch, Power demand information for each of the plurality of loads collected in association with a communication network in the energy management system, state information including power generation for each of the plurality of distributed power sources, and state information including capacity for the energy storage device. Receiving; Detecting a power flow between a power supply network and the microgrid system; And Directly controlling each of the plurality of loads when switching to independent operation using the detected power current and the information received from the energy management system Load control method of a stationary switch comprising a. The method of claim 11, The controlling step Calculating an interruption amount or an additional amount of a load when switching to independent operation by using the detected electric current and the information received from the energy management system; And Cutting off or adding a load corresponding to the cutoff amount or the additional amount calculated when switching to independent operation Load control method of a stationary switch comprising a. 13. The method according to claim 11 or 12, The controlling step Comparing the size of the power current with the capacity of the energy storage device; And Blocking or adding a load corresponding to a difference between the size of the power bird and the capacity of the energy storage device when the size of the power bird is greater than the capacity of the energy storage device. Load control method of a stationary switch comprising a. The method of claim 13, The adding step Checking the direction of the power bird when the size of the power bird is greater than the capacity of the energy storage device beam; When the direction of the power current is in the direction of the microgrid system, blocking a load corresponding to a difference between the size of the power current and the capacity of the energy storage device among the plurality of loads; And Adding a load corresponding to a difference between the size of the power current and the capacity of the energy storage device when the direction of the power current is in the direction of the power supply network; Load control method of a stationary switch comprising a.

Images