KR100910904B1 - Electric supply automatic system using multiple communication network - Google Patents

Abstract

The present invention relates to a distribution automation system using multiple communication networks capable of securing economics and reliability.

Distribution automation system using a multi-communication network according to the present invention provides a power supply through a plurality of distribution lines, the substation having a monitoring control unit; And a power pole located between the plurality of distribution lines, the power pole including a power flow controller for controlling the flow of power under the supervision and control of the monitoring controller using communication of multiple communication networks. When a part of a path of the primary communication network using the plurality of distribution lines of the multi-communication network occurs, it is characterized in that it communicates with the monitoring control unit via another bypass path or the path of the secondary communication network of the primary communication network.

Multi-network, gateway, root router, slave router, distribution automation system

Description

Electrical distribution automatic system using multiple communication network {Electric supply automatic system using multiple communication network}

The present invention relates to a distribution automation system using multiple communication networks capable of securing economics and reliability.

The distribution automation system monitors and controls the status of switchgear for distribution lines, which are scattered over long distances, using a computer installed in the central control room of the business office, measures voltage and current, and automatically checks the fault section in the event of a failure. It is a system that performs system operation remotely.

Conventional power distribution automation system is to establish a communication network using optical, cable, wireless, TRS (Trunked Radio System), etc. as a communication line, and to monitor and control the automation switch remotely. However, when building a communication network as described above, it is difficult to expand and disseminate nationwide due to high construction and maintenance costs or line rental costs. In addition, until now, since a communication network is generally constructed using a single line, it has a disadvantage in that it is difficult to immediately deal with a failure in the communication network. In case of one line failure, it is difficult to secure the soundness of the communication network.

An object of the present invention is to provide a distribution automation system using a multi-communication network capable of securing economics and reliability.

Distribution automation system using a multiple communication network according to the present invention for achieving the above object provides a power supply through a plurality of distribution lines, the substation having a monitoring control unit; And a power pole located between the plurality of distribution lines, the power pole including a power flow controller for controlling the flow of power under the supervision and control of the monitoring controller using communication of multiple communication networks. When a part of a path of the primary communication network using the plurality of distribution lines of the multi-communication network occurs, it is characterized in that it communicates with the monitoring control unit via another bypass path or a secondary communication network of the primary communication network.

The primary communication network may be a power line communication network, and the secondary communication network may include at least one communication network selected from an optical communication network, a satellite communication network, a trunked radio system (TRS), and a wireless communication network.

The monitoring control unit may control a power flow control unit connected to another distribution line when a part of a distribution line of the power line communication network fails, so that the power flowing through the distribution line of the power line communication network flows to the other distribution line.

The monitoring control unit includes a distribution automation server for monitoring and controlling the multiple communication network between the monitoring control unit and the power flow control unit; A front end processor interworking with the power distribution automation server to control a line connected to the power distribution automation server; A gateway through which the control signal for the power flow controller to be monitored is transferred from the power distribution automation server through the front end processor; And a route router positioned between the gateway and the power flow controller, which checks the multi-communication network between the power distribution automation server and the power flow controller, and transmits a control signal for the power flow controller to the power flow controller. It may include.

The gateway may perform an address translation function, a data frame conversion function, and a packet monitoring function between the front end processor and the root router.

When the route router receives fault information on a part of the path of the primary communication network from the power flow controller, the monitoring controller and the power flow controller are configured to pass through another bypass path of the primary communication network or a path of the secondary communication network. You can update the routing table to communicate.

The primary communication network is composed of a unit network formed by enclosing a plurality of unit LANs, and the unit LANs may be composed of each of the plurality of distribution lines branched from a substation.

Some paths of the primary communication network are paths through one unit LAN of the unit network, and another bypass path of the primary communication network is one unit LAN and one unit of the unit network. It may be a path through a neighboring unit LAN (LAN) associated with the LAN.

The route router may include at least one selected from a low speed power line communication interface port and a high speed power line communication interface port, at least one selected from an optical communication interface port, a cable communication interface port, and a satellite communication interface port, and a console interface port. have.

The power flow controller is connected to the root router, the slave router for receiving the routing table information and the control signal for the power flow controller of the root router; A Feeder Remote Terminal Unit (FRTU) connected to the slave router to receive a control signal for the power flow controller; And a switch connected to the FRTU to perform an opening / closing operation according to a control signal to the power flow controller received by the FRTU, and to transmit information on whether the plurality of distribution lines have been interrupted to the FRTU. .

The slave router includes at least one selected from a low speed power line communication interface port and a high speed power line communication interface port, at least one selected from an optical communication interface port, a cable communication interface port, and a satellite communication interface port, and the console interface port and FRTU connection. It may include an interface port.

The distribution automation system using multiple communication networks according to an embodiment of the present invention can reduce the cost of construction and maintenance by utilizing economic power line communication as a distribution automation communication network, and does not require a line rental cost separately.

In addition, the distribution automation system using a multi-communication network according to an embodiment of the present invention can increase communication network reliability because it secures another communication network as a bypass path in addition to the power line communication.

In addition, the distribution automation system using a multi-communication network according to an embodiment of the present invention can be applied to a communication network or a home network communication network of various power systems.

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

1 is a schematic configuration diagram of a distribution automation system using multiple communication networks according to an embodiment of the present invention, FIG. 2 is a detailed configuration diagram of the monitoring controller and the power flow controller of FIG. 1, and FIG. 3 is a gate of FIG. 2. 4 is a detailed diagram of the root router and the slave router of FIG. 2, and FIG. 5 is an exemplary diagram showing an example of a standard model of a distribution line network. Here, the power flow controller shown in FIG. 2 is substantially a plurality, but expressed in one unit.

1 and 2, a distribution automation system 300 using multiple communication networks according to an embodiment of the present invention transmits power through a plurality of distribution lines 50, and a substation having a monitoring control unit 110. 100; And a power flow controller 210 positioned between the plurality of distribution lines 50 and configured to control current flow by being monitored and controlled by the monitoring controller 110 through communication of multiple communication networks. It includes. In the distribution automation system 300 using the multi-communication network, if a failure occurs in a part of a path of the primary communication network using the plurality of distribution lines, the monitoring controller 110 may use another bypass path of the primary communication network or 2. The power flow control unit 210 is monitored and controlled using a path of the secondary communication network.

As illustrated in FIG. 2, the monitoring control unit 110 of the substation 100 includes a distribution automation server 111, a shear processor 112, a gateway 113, and a root router 114.

The distribution automation server 111 monitors and controls a multiple communication network between the monitoring control unit 110 and the power flow control unit 210 installed in the electric pole 200. The distribution automation server 111 receives information such as voltage, current, failure, etc. of the plurality of distribution lines 50 from the power flow control unit 210 of the electric pole 200 connected to the monitoring control unit 110 and the multiple communication networks. Save and process. For example, when the distribution automation server 111 receives failure information of the adjacent distribution line 50 of the specific power flow control unit 210 from the specific power flow control unit 210 through the primary communication network, the distribution line ( The failure information of 50) is stored, and the electric power flow path is set so that the electric power flowing in the failed distribution line 50 flows to the distribution line 50 of another path. In addition, when the distribution automation server 111 cannot utilize some paths of the primary communication network used for the monitoring and control of the specific power flow controller 210 due to the failed distribution line 50, the other bypass of the primary communication network. It is set to use the path or to use the path of the secondary communication network. Here, the primary communication network is a power line communication using the wiring line 50, and because it is a technology for transmitting communication information to the existing wiring line 50, it is an economical cheap communication network. The secondary communication network is used when a failure occurs in the primary communication network, and is at least one communication network selected from an optical communication network, a satellite communication network, a trunked radio system (TRS), and a wireless communication network.

In addition, the power distribution automation server 111 separately selects the power flow controller 210 to be monitored and controlled, and generates a control signal for the selected power flow controller 210.

The front end processor 112 collects data transmitted / received on a line connected to the distribution automation server 111 in conjunction with the distribution automation server 111 and controls a line such as error correction of data.

The gateway 113 performs a relay function such as data access, flow control, data buffering, and protocol conversion in bidirectional communication, and is located between the front end processor 112 and the root router 114 and mutually. It performs data frame conversion, mutual address conversion, and mapping function for interworking. In addition, the gateway 113 performs a data packet monitoring function to analyze distributed network protocol (DNP) packets inputted and outputted from the distribution automation server 111, so that the FRTU described later is requested by the distribution automation server 111. Parallel communication processing using multithreading for communication with 212 enables efficient operation of distribution automation.

In addition, the gateway 113 receives a control signal of the power flow controller 210 to be monitored and controlled from the distribution automation server 111 and transmits it to the root router 114. As shown in FIG. 3, the gateway 113 uses, for example, a gateway S / W as software, a TCP / IP (Transmission Control Protocol) as a communication protocol, and as an operating system (OS). Windows XP may be used, and hardware may be configured using a hardware platform including Ethernet connecting to the front end processor 112 and Ethernet connecting to the root router 114.

The route router 114 is located between the gateway 113 and the power flow controller 210 of the pole 200, and maintains a communication network between the power distribution automation server 111 and the power flow controller 210. Manage. That is, the root router 114 periodically checks the situation of the communication network between the power distribution automation server 111 and the power flow control unit 210 and analyzes the data on the power distribution controller 210 to power flow with the power distribution automation server 111. The communication network routing information for configuring an optimal communication network is generated between the control unit 210. Here, the route router 114 communicates the communication between the monitoring control unit 110 and the power flow control unit 210 as a primary communication network, that is, a power line communication network using the distribution line 50 as well as a secondary communication network, that is, an optical communication network and a satellite communication network. It is manufactured to use at least one communication network selected from a frequency public communication network (Trunked Radio System; TRS), and a wireless communication network.

In addition, the root router 114 should first use the power line communication network, which is the primary communication network, for communication between the distribution automation server 111 and the power flow control unit 210, but when a problem occurs, the secondary communication network should be used. In this case, the state of the power line communication network is checked, and if a failure is detected in some sections, the routing table is updated to set the invalid path and replace the communication path using the other route with another bypass path. Accordingly, even if a problem occurs in a part of a communication network path between the distribution automation server 111 and the power flow control unit 210, the root router 114 may pass through the distribution automation server 111 and the power flow control unit through another bypass path. 210) to allow communication.

As shown in FIG. 4, the root router 114 may include, for example, a UART port and a LAN port for a communication modem interface for configuring a primary communication network such as a low speed power line communication modem and a high speed power line communication (PLC) modem. Is provided, and may further comprise a WAN port and LAN port for communication modem interface for configuring a secondary communication network, such as optical or cable modem and satellite modem. In addition, the root router 114 may be configured to further include a UART1 port for the console. In addition, the root router 114 may further include a UART port for setting and checking the router, and has a built-in switch function for interworking between the ports. Therefore, the route router 114 secures a communication path by using a port for the primary communication network and invalidates an existing port when the secondary communication network is used in case of inability to utilize some paths of the primary communication network and the port for the bypass path. Activate to utilize the modified communication path. Meanwhile, the RS232 port for FRTU 212 linkage shown in FIG. 4 need not be configured in the root router 114.

As shown in FIG. 2, the power flow controller 210, which is monitored and controlled by the monitoring controller 110, controls the slave router 211, the Feeder Remote Terminal Unit (FRTU) 212, and the switch 213. Include.

The slave router 211 is connected to the root router 114 of the monitoring control unit 110, periodically receives its own routing table from the root router 114, and maintains the communication path based on this, in the event of a failure, the root By updating its information with the routing table provided by the router 114, the communication path between the distribution automation server 211 and itself is always maintained.

In this case, the slave router 211 basically receives information from the root router 114 through the power line communication network, but when it is difficult to secure a communication path due to a failure in the power line communication network, not only the power line communication but also other power line communication can be used. It is configured to have an interface of a communication network. For example, as shown in FIG. 4, the slave router 211 may include a UART port and a LAN port for a communication modem interface for configuring a primary communication network such as a low speed power line communication modem and a high speed power line communication (PLC) modem. It may further include a WAN port and a LAN port for a communication modem interface for configuring a secondary communication network such as an optical or cable modem and a satellite modem. In addition, the slave router 211 may be configured to further include a UART1 port for the console. In addition, the slave router 211 may further include a UART port for setting and checking the router, and has a built-in switch function for interworking between the ports. Therefore, the slave router 211 secures a communication path by using a port for the primary communication network and invalidates an existing port when the secondary communication network is used in case of inability to utilize some paths of the primary communication network and the port for the bypass path. Activate to utilize the modified communication path. Meanwhile, since the slave router 211 is connected to the FRTU 212, unlike the root router 114, the slave router 211 further includes an RS232 port for linking the FRTU 212.

In addition, the slave router 211 is a control signal for the power flow control unit 21 of the electric pole 200 selected from the distribution automation server 111 through the front end processor 112, the gateway 113, and the root router 114. Receive

The FRTU 212 is connected to the slave router 211 and connected to the distribution automation server 111 through the slave router 211 and operated by the control signal of the distribution automation server 111. The FRTU 212 is installed in each pole 200 to check the current, voltage and the like drawn out through the pole 200 and the information about this through the slave router 211 power distribution automation server of the monitoring control unit 110 ( 111). In addition, the FRTU 212 transmits information on phase and ground fault conditions for each circuit to the distribution automation server 111 of the monitoring controller 110 through the slave router 211 when an accident occurs in the distribution line 50. Accordingly, the FRTU 212 allows the distribution automation server 111 to flow power flowing through the failed distribution line 50 among the plurality of distribution lines 50 through the other distribution line 50.

The switch 213 is connected to the FRTU 212, and transmits information on whether the distribution line 50 has a failure to the distribution automation server 111 through the FRTU 212, or FRTU from the distribution automation server 111 The opening and closing operation is performed according to the control signal transmitted to 212. Such a switch 213 is, for example, an automatic switch 213a, a manual switch 213b, or an associated switch 213c which is normally open between the A substation and the B substation. Can be. Here, a plurality of distribution lines 50 branched between the A substation and the B substation are bundled into three to four units to form a 'unit network', and each distribution line 50 constituting the unit network is referred to as a 'unit LAN ( LAN) '. The power line communication path is configured between the distribution automation server 111 and the switch 213 through a unit LAN to which the switch 213 belongs, but when a failure occurs in the communication path, the neighbor associated with the unit LAN is connected. By using a unit LAN (LAN) can be secured a bypass route for power line communication. For example, referring to FIG. 5, if any switch R fails in the case where a power line communication path OR is established through one unit LAN from point A substation to point X, one unit LAN ( And a bypass path (TR) of power line communication through another unit LAN (LAN) associated with one LAN. However, if there is no power line communication path that can be used as a bypass path, another communication path in the unit network should be used to secure the communication path. In addition, when securing satellite, wireless, or TRS (Trunked Radio System) as a bypass route, only one or two slave routers in a unit network connect satellite, wireless, and TRS modems in consideration of cost or utilization frequency. To provide.

As described above, the distribution automation system using the multi-communication network according to the embodiment of the present invention uses a multi-communication network including a power line communication network and a secondary communication network, which are low-cost primary communication networks, as a communication network between the monitoring control unit and the power flow unit. . Accordingly, the distribution automation system using the multi-communication network according to the embodiment of the present invention is a communication network between the monitoring control unit and the power flow unit even if some paths of the primary communication network fail. Can be used. Therefore, the distribution automation system using the multiple communication network according to an embodiment of the present invention can secure the reliability of the communication network, the economic utilization is high.

On the other hand, the distribution automation system using a multi-communication network according to an embodiment of the present invention is applicable to a variety of communication networks, such as a communication network or a home network communication network of the power system.

Although the present invention has been described with reference to the illustrated embodiments, it is merely exemplary, and the present invention may encompass various modifications and equivalent other embodiments that can be made by those skilled in the art. Will understand.

1 is a schematic configuration diagram of a distribution automation system using multiple communication networks according to an embodiment of the present invention.

FIG. 2 is a detailed configuration diagram of the monitoring control unit and the power flow control unit of FIG. 1.

3 is a configuration diagram of the gateway of FIG. 2.

FIG. 4 is a detailed configuration diagram of the root router and the slave router of FIG. 2.

5 is an exemplary view showing an example of a standard model of a distribution line network.

Explanation of symbols on the main parts of the drawings

50: distribution line 100: substation

110: monitoring control unit 111: distribution automation server

112: shear processor 113: gateway

114: route router 200: telephone pole

210: power flow control unit 211: slave router

212: FRTU 213: switchgear

300: distribution automation system using multiple communication networks

Claims (11)

A substation for providing power through a plurality of distribution lines, the substation including a monitoring control unit; And It is located between the plurality of power distribution lines, including a telephone pole having a power flow control unit for controlling the flow of power under the monitoring and control of the monitoring control unit using the communication of multiple communication networks, The power flow control unit communicates with the monitoring control unit through another bypass path of the primary communication network or a path of the secondary communication network when a failure occurs in a part of the primary communication network using the plurality of distribution lines among the multiple communication networks. The primary communication network is a power line communication network, and the secondary communication network includes at least one communication network selected from an optical communication network, a satellite communication network, a TRS (Trunked Radio System), and a wireless communication network. Distribution automation system using delete The method of claim 1, The monitoring control unit controls the power flow control unit connected to the other distribution line when a part of the distribution line of the power line communication network, so that the power flowing through the distribution line of some of the power line communication network flows to the other distribution line. Distribution automation system using multiple communication networks. The method of claim 1, The monitoring control unit A distribution automation server configured to monitor and control the multiple communication network between the monitoring controller and the power flow controller; A front end processor interworking with the power distribution automation server to control a line connected to the power distribution automation server; A gateway through which the control signal for the power flow controller to be monitored is transferred from the power distribution automation server through the front end processor; And Located between the gateway and the power flow control unit, and checks the multi-communication network between the power distribution automation server and the power flow control unit, and includes a root router for transmitting a control signal for the power flow control unit to the power flow control unit. Distribution automation system using a multiple communication network, characterized in that. The method of claim 4, wherein The gateway is a distribution automation system using a multiple communication network, characterized in that for performing the address translation function, data frame conversion function, and packet monitoring function between the front end processor and the root router. The method of claim 4, wherein When the route router receives fault information on a part of the path of the primary communication network from the power flow controller, the monitoring controller and the power flow controller are configured to pass through another bypass path of the primary communication network or a path of the secondary communication network. Distribution automation system using a multiple communication network, characterized in that for updating the routing table to communicate. The method of claim 6, The primary communication network is composed of a unit network formed by enclosing a plurality of unit LANs, and the unit LAN is configured of each of the plurality of distribution lines branched from a substation. Automation system. The method of claim 7, wherein Some paths of the primary communication network are paths through one unit LAN of the unit network, and another bypass path of the primary communication network is one unit LAN and one unit of the unit network. Distribution automation system using a multi-communication network, characterized in that the path through the neighboring unit LAN (LAN) associated with the LAN (LAN). The method of claim 6, The root router is At least one selected from a low speed power line communication interface port and a high speed power line communication interface port; At least one selected from an optical communication interface port, a cable communication interface port, and a satellite communication interface port; Distribution automation system using a multi-communication network comprising a console interface port. The method of claim 6, The power flow control unit A slave router connected to the root router to receive routing table information of the root router and a control signal for the power flow controller; A Feeder Remote Termianl Unit (FRTU) connected to the slave router to receive a control signal for the power flow controller; And And a switch connected to the FRTU to perform an opening / closing operation according to a control signal to the power flow controller received by the FRTU, and to transmit information on whether the plurality of distribution lines have been interrupted to the FRTU. Distribution automation system using multiple communication networks. The method of claim 10, The slave router At least one selected from a low speed power line communication interface port and a high speed power line communication interface port; At least one selected from an optical communication interface port, a cable communication interface port, and a satellite communication interface port; Distribution automation system using a multi-communication network comprising a console interface port and the FRTU interface interface port.

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