KR20120011909A - System for preventing islanding of distributed power in smart grid - Google Patents

Abstract

PURPOSE: An individual operation prevention system of a decentralized power source within a smart grid is provided to attach a system monitoring apparatus to each system, thereby sharing real time electric energy with other nodes. CONSTITUTION: System monitoring apparatuses(122,124,126,132,134,136,142,144,146) are installed in each node within a grid. The system monitoring apparatus transmits a monitoring result with respect to a corresponding node by monitoring the corresponding node. A local area monitoring apparatuses(120,130,140) manages one or more system monitoring apparatuses included in a specific region. The local area monitoring apparatus transmits a command for preventing individual operation of a decentralized power source to a corresponding system monitoring apparatus according to a detected accident based on the monitoring result received from the system monitoring apparatus. The system monitoring apparatus includes a generator monitoring apparatus. The system monitoring apparatus is provided to the local area monitoring apparatus.

Description

System for preventing islanding of distributed power in smart grid

The present invention relates to a system for preventing the operation of distributed power generation in a smart grid, and more particularly, to a system for preventing the operation of distributed power generation in a smart grid that can improve the stability and efficiency of a system.

Smart Grid is a nationwide project that many advanced countries are pushing ahead. Smart grids have been proposed as a solution to the global problem of depletion of fossil fuels and global warming from carbon emissions. However, there are problems in voltage control, voltage unbalance, harmonics, frequency variation, short circuit current, single operation, and stability that occur in a smart grid distributed power supply system.

To date, several methods have been developed for the stand-alone detector method, which are classified into two approaches. The first is a passive method, the most common over / low voltage and frequency detector method. This is the way the inverter stops when the voltage / frequency of the system is out of the set value. Another method, voltage harmonic monitoring, is that the voltage harmonic component is increased due to the excitation current supplied to the distribution transformer when the system is in stand-alone operation. Use The second method, the active method, has an output power variation method for detecting anomalies due to active power imbalance, an active frequency variation method for observing the frequency of the terminal voltage, and a sliding mode frequency variation method for observing a frequency change occurring in a single operation state. .

By the way, these stand-alone detector methods have their respective problems in detecting the stand-alone operation state. The over / low voltage and frequency detector method fails to detect stand-alone operation when the inverter generation output matches the load associated with the same system. The voltage harmonic monitoring technique is almost impossible to set an appropriate harmonic value for shutting off the inverter when there is a nonlinear load. In addition, in the output power variation method, a plurality of distributed power supplies connected to the same system need to be synchronized. If it is not synchronized, the leveling effect has no effect. Active frequency variation is likely to fail when the load phase angle coincides with the phase value generated by the frequency change. Finally, the sliding mode frequency variable technique fails to detect single operation if the load phase is equal to the initial phase of the inverter.

In addition, if the power is managed uniformly in the central, since the central power management system does not know all the information on each distributed power, there is a problem of an inefficient power management structure that must be consumed even when surplus power is generated.

An object of the present invention is to provide a distributed power generation alone operation prevention system in a smart grid that can prevent the distributed power generation alone operation by monitoring and controlling the state of each node in real time.

Distributed power generation alone operation prevention system in the smart grid according to the present invention is provided to each node in the grid to monitor the corresponding node, a system monitoring device for transmitting the monitoring result for the node using wireless communication (End Monitor: EM ); And manages one or more system monitoring devices included in a specific area, receives monitoring results from the system monitoring device, and if an accident is detected based on the received monitoring results, commands for preventing the independent operation of distributed power supplies. It includes a Local Area Monitor (LAM) that transmits to the system.

In addition, the end monitor (EM) system is equipped with an end power monitor (EPM), attached to the generator in the grid, detects the occurrence of the accident and provides the incident information to the local monitoring device, In response to the information receiving the generation stop command from the local monitoring device, it is desirable to stop the generator operation.

In addition, the end monitor (EM) system is equipped with an end load monitor (ELM), attached to a load consuming a load in the grid, and detects the accident of the load accident information It is preferable to transmit to the local monitoring apparatus.

In addition, the end monitor (EM) is provided as an end grid monitor (EMM), located in a power distribution network, and is supplied to the entire grid, power consumption of utilities in the grid, and power. It is desirable to monitor at least one of quality and grid incidents and transmit them to the local monitoring system.

In addition, the local monitoring device (LAM) preferably transmits an on / off command to the generator monitoring device (EPM) or the load monitoring device (ELM) for the load monitored by the generator or load monitoring device monitored by the generator monitoring device. .

In addition, the area monitoring device (LAM) preferably transmits the monitoring results received from the system monitoring device (EM) to a wide area monitor (WAM).

According to the present invention, by attaching a monitoring system monitoring value to each system, the real-time power can be shared with other nodes, and power can be managed efficiently by utilizing generators scattered in various places.

In addition, all nodes are connected to, for example, a ZigBee-based wireless network, so that in case of an accident, a quick response is possible, thereby increasing the stability of the node.

In addition, according to the present invention can prevent the single operation more effectively than the existing single operation prevention method. Conventional stand-alone operation prevention method used the method that the inverter makes a guess through the information such as voltage or frequency or puts a random signal into the output from the generator to measure the change in the signal and judge the power generation quality in this case. There is a risk of developing a non-detect zero (NDZ) that does not detect single operation.

1 is a view showing a system for preventing the operation of distributed power generation alone in a smart grid according to an embodiment of the present invention.
2 is a diagram showing a power grid structure of a region managed by a specific regional monitoring apparatus according to an embodiment of the present invention.
3 is a diagram showing the configuration of a generator monitoring device (End Power Monitor: EPM) according to an embodiment of the present invention.
4 is a diagram illustrating a configuration of an end load monitor (ELM) according to an embodiment of the present invention.
5 is a diagram showing the configuration of a power generation network monitoring apparatus (End Grid Monitor: EGM) according to an embodiment of the present invention.

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

1 is a diagram illustrating a system for preventing the operation of distributed power generation alone in a smart grid according to an embodiment of the present invention.

Referring to FIG. 1, a system for preventing the operation of distributed power generation alone in a smart grid according to the present invention includes a wide area monitor (WAM) 110 and a local area monitor (LAM) 120. 130, 140, solar power generators 121, 131, and 141 included in areas managed by the regional monitoring devices, loads 123, 125, 133, 135, 143, and 145 that consume electricity, generators, or End Monitors (EMs) 122, 124, 126, 132, 134, 136, 142, 144, and 146 for monitoring the load.

The system monitoring devices 122, 124, 126, 132, 134, 136, 142, 144, and 146 are provided at the nodes 121, 131, 141, 123, 125, 133, 135, 143, and 145 in the grid. The node is monitored and wireless communication is used to transmit the monitoring result of the node to the local monitoring apparatuses 120, 130, and 140. In this case, for example, ZigBee based wireless communication may be used as the wireless communication.

For example, when the system monitoring device (EM) is provided as an end power monitor (EPM), the generator monitoring device is attached to the generator in the grid to obtain the amount of electricity generated by the generator, and the corresponding regional monitoring device. (LAM), detects the occurrence of the accident and provides accident information to the relevant local monitoring device (LAM), and when the generation stop command from the corresponding local monitoring device (LAM) corresponding to the accident information, the generator stops operating You can.

In addition, when the system monitoring device (EM) is provided as an end load monitor (ELM), it is attached to a load consuming electricity in the grid to measure the amount of power of the load and to detect an accident of the load. It can detect and transmit the accident information to the local monitoring system (LAM).

In addition, when the grid monitoring device (EM) is provided as an end grid monitor (EGM), it is located in the power distribution network, and is supplied to the entire grid, power consumption of the utility in the grid, power quality, Grid incidents can be monitored and sent to the local monitoring system (LAM).

Local monitoring device (120, 130, 140) manages one or more system monitoring values included in a specific area, receives the monitoring results from the system monitoring device, if the accident is detected based on the received monitoring results of the distributed power alone The command to prevent operation is transmitted to the local monitoring system that transmits to the relevant system monitoring system.

In addition, the area monitoring device (LAM) 120, 130, 140 is a generator monitoring device (EPM) or a load monitoring device (ELM) to turn on / off the load monitored by the generator or load monitoring device monitored by the generator monitoring device. You can send a command.

In addition, the area monitoring device (LAM) 120, 130, 140 may transmit the monitoring result received from the system monitoring device (EM) to the wide area monitoring device (WAM) 110. In this case, the WAM may monitor the monitoring information from each local monitoring device LAM through the Internet (eg, Ethernet).

2 is a diagram illustrating a power grid structure of a region managed by a specific regional monitoring apparatus according to an exemplary embodiment of the present invention.

Referring to FIG. 2, a local monitoring device (LAM) 200 of a specific region is provided in each of the solar generator 202, the second rod 206, and the second rod 210 located in the region. The first system monitoring device 204, the second system monitoring device 208, and the third system monitoring device 212 that monitor each node may be monitored and controlled.

For example, when an accident occurs by monitoring the first rod 206 by the second system monitoring apparatus 208, the corresponding accident information is transmitted to the local monitoring apparatus 200, and accordingly, the local monitoring apparatus 200 Transmits a generator stop command to the first system monitoring device 204 that monitors and controls the solar power generator 202, so that the first system monitoring device 204 may stop the operation of the solar power generator 202.

3 is a diagram showing the configuration of a generator monitoring device (End Power Monitor: EPM) according to an embodiment of the present invention.

Referring to FIG. 3, the generator monitoring apparatus (End Power Monitor: EPM) 300 according to the present invention includes a first sensor 302, a second sensor 304, a controller 306, and a wireless communication unit 308. It includes, and can be attached to the generator 310 in the grid.

The controller 306 may collect the amount of electricity generated by the generator through the sensors 302 and 304 and transmit the amount of electricity generated by the generator to the local monitoring apparatus through the wireless communication unit 308 provided as a ZigBee module.

In addition, the controller 306 may collect accident information of the generator through the sensors 302 and 304 and transmit the accident information of the generator to the corresponding local monitoring apparatus through the wireless communication unit 308 provided as a ZigBee module. Accordingly, the local supervisor may transmit a power generation stop command to the generator monitoring device, and when the generator monitoring device receives the power generation stop command, the generator monitoring device may stop the generator operation to prevent a single driving phenomenon.

4 is a diagram illustrating a configuration of an end load monitor (ELM) according to an embodiment of the present invention.

Referring to FIG. 4, an end load monitor (ELM) 400 according to the present invention includes a first sensor 402, a second sensor 404, a controller 406, and a wireless communication unit 408. It includes, and can be attached to the rod 410 that consumes electricity in the grid.

The control unit 406 is attached to loads that actually use electricity in the home or office through the sensors 402 and 404, and measures the amount of power of the loads, for example, as a ZigBee module. The wireless communication unit 408 may transmit to the local monitoring apparatus.

In addition, the controller 406 may collect the accident information of the load through the sensors 402 and 404, and transmit the incident information to the corresponding local monitoring apparatus through the wireless communication unit 408 provided as a ZigBee module. Accordingly, the local supervisor may transmit a load off command to the load monitoring device, and when the load monitoring device receives the load off command, the load monitoring device may stop the load operation to prevent a single driving phenomenon. Accordingly, when an accident occurs on the load, the load monitoring device may report the incident to the local monitoring device through wireless communication in a short time to solve the accident.

FIG. 5 is a diagram illustrating a configuration of a power generation network monitoring apparatus (End Grid Monitor: EGM) according to an embodiment of the present invention.

Referring to FIG. 5, a power generation network monitoring apparatus (End Grid Monitor: EGM) 500 according to the present invention includes a first sensor 502, a second sensor 504, a controller 506, and a wireless communication unit 508. ), And may be located in the power distribution network, for example, the transmission tower 510.

The controller 506 monitors the power supplied to the entire grid through the sensors 502 and 504, the power consumption of the utility in the grid, the quality of the power, the grid incident, and the like, and displays the monitored information, for example, ZigBee. The wireless communication unit 508 provided as a module can be transmitted to the local monitoring apparatus.

Although the present invention has been described in more detail with reference to the examples, the present invention is not necessarily limited to these embodiments, and various modifications can be made without departing from the spirit of the present invention. Therefore, the embodiments disclosed in the present invention are not intended to limit the technical idea of the present invention but to describe the present invention, and the scope of the technical idea of the present invention is not limited by these embodiments. The protection scope of the present invention should be interpreted by the following claims, and all technical ideas within the equivalent scope should be interpreted as being included in the scope of the present invention.

Claims (6)

An end monitor (EM) provided at each node in the grid to monitor the corresponding node and transmitting a monitoring result for the corresponding node by using wireless communication; And
Manages one or more system monitoring values included in a specific area, receives monitoring results from the system monitoring device, and if an accident is detected based on the received monitoring results, commands for preventing the independent operation of distributed power supply. Local Area Monitor (LAM) for transmitting to the device;
Distributed power alone operation prevention system in a smart grid comprising a.
The method according to claim 1,
The system monitoring device (End Monitor: EM) is provided as a generator monitoring device (End Power Monitor: EPM),
It is attached to the generator in the grid, detects the occurrence of the accident to provide the accident information to the local monitoring device, when receiving a power generation stop command from the local monitoring device corresponding to the accident information, characterized in that to stop the generator operation Distributed power generation single operation prevention system in smart grid.
The method according to claim 1,
The system monitoring device (End Monitor: EM) is provided as an end load monitor (ELM),
Attached to a load consuming a load in the grid, distributed power generation alone prevention system in the smart grid, characterized in that to detect the accident of the load and transmit the accident information to the local monitoring device.
The method according to claim 1,
The end monitor (EM) is provided as an end grid monitor (EGM).
Located in a power distribution network, distributed power alone in the smart grid, characterized in that the monitoring of one or more of the power supplied throughout the grid, the power consumption of the utility in the grid, the quality of the power, grid accidents and transmits to the local monitoring device Driving prevention system.
The method according to claim 2 or 3,
The area monitoring device (LAM) transmits an on / off command to the generator monitoring device (EPM) or the load monitoring device (ELM) for the load monitored by the generator or load monitoring device monitored by the generator monitoring device. Distributed power supply single operation prevention system in the smart grid.
The method according to claim 5,
The area monitoring device (LAM) is a distributed power supply independent operation prevention system in a smart grid, characterized in that for transmitting a wide area monitor (WAM) monitoring results received from the system monitoring device (EM).

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