KR101830630B1 - Closed transition transfer switch logical node modelling system and method based on IEC 61850 - Google Patents

Abstract

The present invention relates to IEC 61850 based-closed transition transfer device logical node modeling system and method, and more specifically, to IEC 61850 based-closed transition transfer device logical node modeling system and method which form a logical node regarding a closed transition transfer device based on the international standard IEC 61850 and apply the same a unified distribution automation system. The IEC 61850 based-closed transition transfer device logical node method according to a feature of the invention is a logical node modeling method for implementing a distribution automation system which supplies power to a load by receiving power from a grid or distributed energy resources (DER) using a closed transition transfer device based on IEC 61850. The present invention may include a step (S1) of recognizing manufacturer-specific specifications of the closed transition transfer device and a step (S2) of modeling a distribution automation system using a logical node (LN) defined in IEC 61850.

Description

[0001] The present invention relates to an IEC 61850-based uninterruptible transfer apparatus and method, and more particularly,

The present invention relates to a system and method for an IEC 61850-based unidirectional transfer apparatus logical node, and more particularly, to a system and method for a logical node for an uninterruptible transfer apparatus (CTTS) based on an international standard IEC 61850, To an IEC 61850 based uninterruptible power supply logic node modeling system and method.

Recently, a method of transmitting power system information using a standardized communication technique has been proposed in order to solve the problem of enlargement, diversification and complication of power system caused by an increase in power consumption and an increase in distributed power source.

A smart grid is a power grid in which a system that efficiently monitors and controls the power system using information transmitted through standardized communications is implemented. In order to implement the Smart Grid, it is necessary to apply the international standardized communication protocol for transmitting and integrating the power system information.

On the other hand, conventional conventional substations were unidirectional communication, and the upper was constructed by serial network communication. In addition, each device built into the hardware uses a parallel connection using a copper cable and is connected via a dedicated line.

In addition, while there are standardized protocols for substation protocols, vendor-based communication protocols such as Alstom's Courier, ABB's SPA, Siemens' Profibus, and Schneider's Modbus have often been applied.

In addition, standards such as DNP3 and IEC 60870 have been applied as standard protocols, but in the past, a manufacturer-based proprietary structure has been used and lacks compatibility. In addition, mutual input was impossible by installing and applying different functions.

To overcome these shortcomings is IEC 61850, which is used for the communication of substation automation information as the most widely used power system related standard communication standard in the world at present.

IEC 61850 is a standard for communication networks and systems for power utility automation. It defines an architecture that focuses on applications, including those about communication protocols.

It also contains standardization of XML-based electrical substation communication technology language.

In addition, IEC 61850 includes SCADA-based TCP / IP in the communication protocol in common, and real-time GOOSE, real-time SMV, and self description are added.

We also added new technologies (wind power generation, solar power generation) that are emerging.

However, in the case of an uninterruptible power supply switching apparatus, there is a problem in that safety and reliability of the distribution automation system is deteriorated due to the fact that international standards are not standardized and the specifications are different for each manufacturer and the connection between the facilities is difficult due to the spread of the distribution automation system.

Korean Patent No. 10-0843130 (issued on July 03, 2008)

SUMMARY OF THE INVENTION Accordingly, the present invention has been made keeping in mind the above problems occurring in the prior art, and it is an object of the present invention to define and configure a logical node of an uninterruptible power supply apparatus based on the international standard IEC 61850, It has its purpose.

According to an aspect of the present invention, there is provided a method for modeling an IEC 61850-based uninterruptible power supply logical node using a grid or Distributed Energy Resources (DER) using an uninterruptible power supply based on IEC 61850, And supplies the power to the load.

The present invention may include a step S1 of identifying manufacturer specific specifications of the uninterruptible transfer apparatus and a step S2 modeling the distribution automation system using a logical node LN defined in IEC 61850.

In addition, among the identified manufacturer-specific standards, extracting a protocol that is not modeled into a logical node (LN) defined in IEC 61850 (S3), and extracting a protocol (S4). ≪ / RTI >

The method may further comprise constructing (S5) an integrated distribution automation system based on IEC 61850 using the logical nodes of steps S2 and S4.

The IEC 61850-based uninterruptible power supply logic node modeling system according to the characteristics of the present invention is based on IEC 61850 and is supplied with power from a grid or Distributed Energy Resources (DER) Which is a logic node modeling system for realizing a distribution automation system that supplies the distribution automation system.

The IEC 61850-based uninterruptible power supply switching logic node modeling system according to an aspect of the present invention controls the operation of the uninterruptible power supply switching apparatus so as to selectively supply power supplied from a power grid (GRID) and a distributed generation facility (DER) And a logical node consisting of the IEC 61850 based uninterruptible power supply logic node modeling method for implementing a unified distribution automation system.

As described above, the IEC 61850-based uninterruptible power supply logic node modeling system and method according to the present invention have the effect of securing the integration and safety of the distribution automation system through international standardization of the uninterruptible power supply switching apparatus.

1 is a block diagram illustrating an IEC 61850 based uninterruptible power supply logic node modeling system according to an embodiment of the present invention.
FIG. 2 is a conceptual diagram illustrating a logical node structure for an IEC 61850 based uninterruptible power supply switching logic node modeling system according to an embodiment of the present invention. Referring to FIG.
FIG. 3 is a diagram illustrating a class of ZCTS, which is a logical node for an IEC 61850 based uninterruptible power supply switching logic node modeling system according to an embodiment of the present invention.
4 is a flowchart illustrating an IEC 61850-based uninterruptible power supply logic node modeling method according to an embodiment of the present invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those skilled in the art can easily carry out the present invention. The present invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. In order to clearly illustrate the present invention, parts not related to the description are omitted, and similar parts are denoted by like reference characters throughout the specification.

Throughout the specification, when an element is referred to as "comprising ", it means that it can include other elements as well, without excluding other elements unless specifically stated otherwise. Also, the terms " part, "" ... "," module ", and the like described in the specification mean units for processing at least one function or operation, and may be implemented by hardware or software or a combination of hardware and software .

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

Like reference symbols in the drawings denote like elements.

The present invention relates to a system and method for an IEC 61850-based unstructured transfer unit (CTTS) logical node, which defines and configures a logical node based on the international standard IEC 61850 to perform logical node modeling of the uninterruptible transfer apparatus To an IEC 61850 based uninterruptible power supply logic node modeling system and method for building distributed power automation systems.

FIG. 1 is a block diagram illustrating an IEC 61850-based uninterruptible power supply switching logic node modeling system according to an exemplary embodiment of the present invention. FIG. 2 is a block diagram of an IEC 61850 based uninterruptible power supply switching logic node modeling system according to an embodiment of the present invention. FIG. 3 is a diagram conceptually showing a logical node configuration diagram. FIG.

1 and 2, a distribution automation system 10 includes a grid 100, a distributed energy resource (DER) 200, a load 300, an uninterruptible power supply A closed transition transfer switch (CTTS) 400, and a logic node modeling system 500.

The power grid (GRID) 100 can supply the load 300 with commercial power produced from the grid.

Distributed energy resources (DER) 200 can be supplied to the load 300 by receiving power generated from distributed generation and storage facilities such as wind power generation and photovoltaic generation.

A closed transition transfer switch (CTTS) 400 is installed between a grid (GRID) 100 and a distributed generation facility (DER) 200 and is connected to a power grid (GRID) (DER) 200 to a load (load) 300, as shown in FIG.

The logical node modeling system 500 may include a standard protocol for controlling the operation of the uninterruptible power supply 400 and for implementing the distribution automation system 10.

In one embodiment according to the present invention, the standard protocol may be IEC 61850.

2, a logical node (LN, Logical Node) provided by IEC 61850 for implementing the distribution automation system 10 is provided with a basic logical node LLN0 for the controller of the uninterruptible transfer apparatus 400, PTOV, PTOF, PTUF, and PTOC, which are system protection logic nodes (LN) for abnormal conditions such as voltage, current, and frequency, which are above or below a reference value.

The LLN0 may be used as a logical node zero to address a common issue for a logical device. In addition, the MMXU is a logic node representing measurement, which can be used to calculate current, voltage, power and impedance in a three-phase system and can be used primarily in operational applications.

In addition, the PTUV is a logic node that exhibits undervoltage, and may also function as a zero voltage relay using a suitable low operating curve. The PTOV is a logic node (LN) that indicates overvoltage, and can not be used for applications such as transformer star point or delta surveillance.

The PTOF is a logic node (LN) representing overfrequency, which can be used to model the overcurrent portion and uses one instance per stage.

The PTUF is a logic node (LN) that represents a low frequency (Underfrequency) and can be used to model the low frequency portion. The PTOC is a logical node indicating time overcurrent.

In addition, if the synchronizing condition of the two power sources is satisfied, it may include the CSWI which is the breaker operation signal. The CSWI is a logical node that represents a switch controller, and this logical node (LN) class can be used to control all open / close conditions on a process level.

Also, a logical node (LN) representing a human machine interface may include an IHMI that is a logical node that can be monitored in the field.

In addition, MPRS, MFLW, MHET, SVBR, STMP, MENV, and MMET logic nodes that monitor the status of the generator (temperature, pressure, vibration, etc.) .

However, because the uninterruptible power supply 400 is not specified in IEC 61850, it is necessary to define a new logical node.

According to an embodiment of the present invention, a new logic node, ZCTS, can be configured to define a class for the ZCTS.

FIG. 3 is a diagram illustrating a class of ZCTS, which is a logical node for an IEC 61850 based uninterruptible power supply switching logic node modeling system according to an embodiment of the present invention.

In Fig. 3, P1 represents the name of a logical node defined in an embodiment according to the present invention. The name of a logical node can begin with a letter representing the group to which the logical node belongs. The name of the logical node defined in one embodiment in accordance with the present invention preferably begins with the letter "Z" representing the logical node group for "additional power system equipment ".

In Figure 3, P2 may include a brief description of the data and a method of using the data. P3 may represent transient data.

P4 in FIG. 3 may represent a mandatory (M) or selective (O) state for the instantiation of a particular logical node, data, dataset, control block or service. The letter C can indicate a conditional state.

The IEC 61850-based uninterruptible power supply logic node modeling method according to an embodiment of the present invention can be applied to a power grid 100 or a distributed power generation system (DER) using an uninterruptible power supply switching apparatus 400 based on IEC 61850, A method of logic node modeling of a distribution automation system (10) that receives power from a resource (200) and supplies the same to a load (300), comprising the steps of: (S2) modeling the distribution automation system 10 using the logical node (LN) defined in FIG.

In addition, among the identified manufacturer-specific standards, extracting a protocol that is not modeled into a logical node (LN) defined in IEC 61850 (S3), and extracting a protocol (S4). ≪ / RTI >

It may also comprise constructing (S5) the integrated distribution automation system 10 based on IEC 61850 using the logical nodes of steps S2 and S4.

While the present invention has been described in connection with what is presently considered to be practical exemplary embodiments, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, And all changes to the scope that are deemed to be valid.

10: Distribution automation system 100: Grid
200: Distributed generation facility (DER) 300: Load
400: Uninterruptible Transfer Unit (CTTS) 500: Logical Node Modeling System
510: ZCTS

Claims (3)

(GRID) for supplying a commercial power generated from the grid to a load, a distributed power generation facility (DER) for receiving a power generated from a distributed power generation facility and a power storage facility and supplying the power to the load, (CTTS), which is provided between a power generation facility (DER) and a power generation facility (DER) to selectively supply or cut off power supplied from the grid (GRID) and the distributed generation facility (DER) And a logic node modeling system including a standard protocol for controlling the operation of the transfer apparatus and implementing a distribution automation system. The system includes a grid (Grid) or distributed generation facility (DER And supplying power to the load, the logic node modeling method comprising:
(S1) of recognizing specifications of the manufacturer of the uninterruptible power supply switching device;
Modeling (S2) the distribution automation system using a logical node (LN) defined in IEC 61850;
Extracting a protocol that is not modeled into a logical node (LN) defined in IEC 61850 among the identified manufacturer specific standards (S3);
Constructing a new logical node in a model form defined by IEC 61850 using the extracted protocol and adding it to the logical node modeling system (S4); And
Constructing (S5) an integrated distribution automation system based on IEC 61850 using the logical nodes of steps S2 and S4,
In the step (S4)
The class of the new logical node added to the logical node modeling system is
Data Object name, Common data class, Explanation, and M / O / C items,
The M / O / C includes a state in which a data, a data set, a control block or a service is essential for the instantiation of a specific logical node, an optional (O) state, ) State, and a condition (C) state, respectively, in the IEC 61850-based uninterruptible power supply switching apparatus logic node modeling method.
delete (GRID) for supplying a commercial power generated from the grid to a load, a distributed power generation facility (DER) for receiving a power generated from a distributed power generation facility and a power storage facility and supplying the power to the load, (CTTS), which is provided between the power generation facility (DER) and the grid (GRID) and the distributed generation facility (DER) to selectively supply or shut off power supplied to the load, Modeling system, and based on IEC 61850, the logic node modeling of a distribution automation system that supplies power to a load by receiving power from a grid or Distributed Energy Resources (DER) using the uninterruptible transfer apparatus As a system,
The logical node modeling system
And controls the operation of the UPS to selectively supply or shut off the power supplied from the power grid (GRID) and the distributed generation facility (DER) to the load, and configures a logical node based on the IEC 61850 IEC 61850 based uninterruptible power supply logic node modeling system comprising a logic node according to the method of claim 1 so as to implement a unified distribution automation system.

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