KR102414495B1 - Substation system showing the direction of the tide - Google Patents

Abstract

A current direction display substation system of the present invention, a plurality of switchgear for inputting or opening a power path for each section of the substation; CTs installed on the power line of each switch; image transformers installed on the output lines of each of the CTs; and a substation management server that provides an MMI indicating a current direction of a location for each of the GIS from the values input from the image current transformers.

Description

SUBSTATION SYSTEM SHOWING THE DIRECTION OF THE TIDE

The present invention relates to a substation system that displays the current direction, and more specifically, to a substation system that displays the current direction at a switch point where a monitoring CT is installed.

In the power transmission system or distribution system, substations are installed to step-up or step-down the output of a generator or step-down the voltage of the system. In addition to transformers for step-up or step-down voltage, various devices are installed in substations, such as devices for concentrating and distributing power, devices for controlling currents, or switches for protecting and controlling systems or devices in substations. .

For example, a gas pressure sensor that detects gas pressure, an acceleration sensor that detects an abnormal signal, a current/voltage detector, etc. are installed in a circuit breaker used in a gas insulated switchgear (GIS), and a sensor that detects the state of the transformer is installed in the transformer. As a thermometer, pressure gauge, oil level sensor, current detector, etc. are installed.

Among the sensors, the most installed CT is a sensor for detecting a current, and large-capacity CTs having an externally large size according to the size of the substation are installed.

These sensors are connected to a protection device, a measuring device, a control device, and a device monitoring device via a cable that transmits an electrical signal. Again, the protection device, measuring device, control device, and device monitoring device are each connected to the SCADA system as an upper substation monitoring and control device through a cable that transmits electrical signals.

In individual facilities such as a substation management server or GIS installed in a substation, various interface means for expressing information of the sensors to a manager are provided.

Substations are equipped with very complex facilities to stably supply electricity, and by monitoring the operation status of various devices such as circuit breakers installed in such substations, they can detect and prepare for signs of failure in advance, or recover by quickly responding to a failure that has occurred. To do this, the above-described sensors and interface means are provided.

However, since all existing substation management/monitoring means are tailored to the environment of the central power supply network, there is a slight gap in the distributed power environment.

In most cases, electric power is transmitted from the distribution lines of substations, but although there are cases where power is received through distribution lines due to the recent increase in new and renewable power plants, the existing substation management/monitoring methods and SCADA measurement values cannot accurately grasp this.

1 shows a Man Machime Interface (MMI) screen in a management server of a conventional substation system.

The illustrated MMI of the prior art is an LPS (line life and death display) device, in which only life and death monitoring for each distribution line is possible, and only the operation is uniformly displayed on the MMI monitoring screen regardless of the transmission/reception status for each distribution line. That is, with the illustrated MMI of the prior art, it is not possible to know whether electric power is flowing in or out of a corresponding point at a substation or a power distribution post. Similarly, the amount of power in the peripheral voltage also varies depending on the distribution line, and the maximum load value only fluctuates.

In a distributed power environment, the MMI of the prior art makes it difficult to calculate the net load value excluding the amount of power generation because the measured value of the maximum load for each distribution line is not divided into a + value or a - value due to the influence of the distributed power generation amount. Accordingly, even if the power quality is deteriorated due to the inflow of harmonics from the renewable power plant, it cannot be identified.

Republic of Korea Publication No. 10-2020-0032850

An object of the present invention is to provide a substation system for displaying a current direction that can check whether power is transmitted/received at a point of interest.

An object of the present invention is to provide a substation system displaying a current direction that displays the power transmission/reception status at multiple points related to the substation while minimizing changes to the existing substation system.

A current direction display substation system according to an aspect of the present invention includes a plurality of switchgear for inputting or opening a power path for each section of the substation; CTs installed on the power line of each switch; image transformers installed on the output lines of each of the CTs; and a substation management server that provides an MMI indicating a current direction of a location for each of the GIS from the values input from the image current transformers.

Here, the switchgear is a gas insulated switchgear (GIS), and the current direction may be displayed on a power current direction display device provided on a display device in front of the GIS.

Here, the MMI may display the plurality of switchgear according to the power path, and display the current direction in the direction of the arrow for the power path near the display position for each switchgear.

Here, when the absolute value of the detection result of the image current transformer is continuously maintained within a predetermined reference range for a predetermined time, the substation management server determines the current direction according to the positive (+) / negative (-) of the detection result. can

Here, the MMI may flicker the current direction display when the detection result of the image current transformer is excessive.

Here, the substation management server may transmit information on the direction of the current to the upper SCADA server.

Here, the substation management server may store information on the current direction for a predetermined time, and display the current direction immediately before the accident on the MMI.

If the current direction display substation system according to the spirit of the present invention having the above configuration is implemented, there is an advantage in that it is possible to check whether power is transmitted/received at the point of interest.

The current direction display substation system of the present invention can calculate the real-time ambient voltage and the maximum load of the distribution line by understanding the transmission/reception status for each distribution line.

The current direction indication substation system of the present invention has the advantage of optimizing the system operation by matching the power of the transformer and the power of the supply distribution line.

1 is a screen showing a MMI (Man Machime Interface) in the management server of the conventional substation system.
2 is a conceptual diagram showing the structure of a substation system for displaying a current direction according to the spirit of the present invention.
3 is a perspective view showing an input or output terminal of a gas insulated switchgear (GIS) installed in a substation and the existing CTs 121 installed therein.
Figure 4 is a front view showing the CT terminal block inside the panel of the GIS.
5 is a front view showing a power current direction display device for displaying power current information according to the spirit of the present invention provided on the display device on the front of the GIS.
6 is an MMI-power monitoring screen of the substation management server 200 of the geupjeon substation displaying information on the direction of the current according to the spirit of the present invention.

In describing the present invention, terms such as first, second, etc. may be used to describe various components, but the components may not be limited by the terms. The terms are only for the purpose of distinguishing one component from another. For example, without departing from the scope of the present invention, a first component may be referred to as a second component, and similarly, a second component may also be referred to as a first component.

When a component is referred to as being connected or connected to another component, it may be directly connected or connected to the other component, but it can be understood that other components may exist in between. .

The terminology used herein is used only to describe specific embodiments, and is not intended to limit the present invention. The singular expression may include the plural expression unless the context clearly dictates otherwise.

In this specification, the terms include or include are intended to designate that a feature, number, step, operation, component, part, or combination thereof described in the specification exists, and includes one or more other features or numbers, It may be understood that the existence or addition of steps, operations, components, parts, or combinations thereof is not precluded in advance.

In addition, shapes and sizes of elements in the drawings may be exaggerated for clearer description.

Figure 2 shows an embodiment of a substation system for indicating the direction of the current according to the spirit of the present invention.

The illustrated current direction display substation system includes: a plurality of switchgear 100 for inputting or opening a power path for each section of the substation; CTs (121 to 123) installed on the power line of each switch; image current transformers 210 installed on the output lines of each of the CTs 121 to 123; The substation management server 200 may include a substation management server 200 that provides an MMI indicating a current direction of a location for each of the GIS from the values input from the image current transformers 210 .

In an environment with a high proportion of distributed power such as renewable power generation, it is necessary to develop a device that accurately displays the power transmission/reception status. In the present invention, while minimizing changes to the existing substation system, power As a method of displaying the power transmission/reception status, the illustrated current direction display substation system is presented. That is, we propose a current direction display substation system having a means for indicating a power current direction of a substation distribution line/transmission line.

The switchgear of FIG. 2 may be a gas insulated switchgear (GIS), and FIG. 3 shows an input or output terminal of a gas insulated switchgear (GIS) installed in a substation and the existing CTs 121 installed therein.

GIS is installed at each major point of the substation, and CT 121 for current detection is installed in the input and/or output terminal line of the installed GIS. The point where GIS and/or CT is installed in the substation can be seen as a point where there is a high need to check the direction of the current.

The scale of the GIS installed in the substation is significant, and, as shown, the CT 121 installed to measure the current of the input or output terminal of the GIS is also large enough that it is difficult for a person to lift and work.

In this situation, installing a sensor or means for measuring the current direction in the GIS itself is not only a huge cost burden as the current direction detection sensor itself, but also secures a space to install the current direction detection sensor in the existing GIS facility. Can not.

In the present invention, in consideration of the practical circumstances described above, and considering that detection of the current direction is not urgent in accident handling, the CT 121 installed in the GIS does not directly sense the current direction with respect to the input or output line of the GIS. We propose a method to indirectly detect the signal output of

That is, as shown in FIG. 2, the image current transformer 210 is installed again in the detection signal lines of the CTs 121 to 123 installed on the power lines of each GIS, and the substation management server 200 shown is The current direction is determined based on whether the detection signal of the image current transformer 210 is positive (+)/negative (-). If the GIS is a single-phase GIS, the image transformer 210 may also be applied as a single-phase image transformer.

Depending on the implementation, instead of the image current transformer 210, a directional CT may be installed on the power line of the GIS according to the current direction. , in this case, it can be seen that the image transformer is provided as a part of the directional CT.

According to the re-detection configuration for the detection signal of the CT 121 described above, the high current value of the power line to be detected in the current direction is converted to a small current value. can be applied as

4 shows the CT terminal block inside the panel of the GIS, it can be seen that the image transformer 210 is installed on the CT detection signal line located in the CT terminal block.

When a tidal flow occurs in a power system, one side becomes the source of power and the other side becomes the sink. Since power is consumed on the sink side, it can be seen that a very small current path is shorted, and a very low level signal is detected in the zero-phase current transformer 210 .

In the present invention, according to the positive (+)/negative (-) direction of the detection signal of the image current transformer 210, it is determined that the current flows in the direction where a small amount of short is considered to have occurred.

However, since the signal detected by the image transformer 210 by the above-described current flow is at a very low level, it may be mistaken for noise and the like. On the other hand, if the signal detected by the image current transformer 210 is at a significant level, this is due to an accident occurring in the corresponding power path, not by the current flow.

In order to prevent misunderstanding/confuse with the noise and fault current, the substation management server 200 continuously maintains the absolute value of the detection result of the zero-phase current transformer 210 within a predetermined reference range for a predetermined time. In this case, the current direction can be determined according to the positive (+)/negative (-) of the detection result.

In addition, the zero current transformer 210 cannot substantially detect a current flow after an accident since a large fault current appears when an accident occurs in the power path. However, it is desirable to refer to the current flow in the action of the accident, and the substation management server 200 may display the current flow immediately before the accident when an accident occurs, and provide it to the action worker. In this case, the substation management server 200 may store the information on the current direction for a predetermined time in an internal storage device or the like, and display the current direction immediately before the accident on the MMI or the like. For example, if the current direction appears to the left before the accident, and the current flow due to the accident current is changed to the right due to an accident that has occurred, the time for the current flow to the right to remain within the predetermined reference value is extremely short and does not last for the predetermined time. Therefore, the current direction determination does not change to the right, and the left, which is the current direction just before the failure, is displayed as it is on the MMI or the like.

The substation management server 200 may monitor the operating status of the electric power devices installed in the substation and output it to the manager through MMI or the like. The substation management server may be implemented as a computer device having a general data collection and processing function and an interface device for a manager. The substation management server 200 may be installed in a place where it is easy to monitor the electric power devices installed in the substation, for example, a geupjeon branch. The substation management server 200 may include a facility communication module that receives sensing information from a substation installed power device and performs wired/wireless communication for transmitting an operation instruction. The substation management server may include a higher level communication module that transmits the collected information to an external upper server, for example, a SCADA server, and performs wired/wireless communication to receive information required for substation management.

The information on the current flow on the input/output line of the GIS obtained through the above-described process may be reflected so that the transmission/reception status can be displayed on the GIS in the substation and the MMI screen of the geupjeon substation.

5 shows a power current direction display device 170 for displaying power current information according to the spirit of the present invention provided on the display device on the front side of the GIS 100 .

As shown in FIG. 4, a video current transformer 210 is attached to the CT cable of the inner panel of the GIS 100, and information on the transmission or reception direction determined using the detected current value is displayed on the power current direction display device 170 ) may be displayed on the front of the GIS 100 and provided to the operator.

The power transmission/reception status information in the illustrated power current direction display device 170 is provided to the a/b contact point to the SCADA RTU, and can be used for line life and death monitoring in the SCADA system. In addition, information on whether to transmit/receive power may be used for a harmonic abnormality (voltage distortion rate 3%) alarm function in the SCADA system.

To this end, the substation management server 200 of FIG. 2 may transmit the information on the current direction to the upper SCADA server through a wired/wireless communication channel.

6 shows an MMI-power monitoring screen of the substation management server 200 of the geupjeon substation displaying information on the direction of the current according to the spirit of the present invention.

In the illustrated MMI, the plurality of GISs (switches) are displayed along the power path, and the current direction is indicated in the direction of the arrow for the power path in the vicinity of the displayed position for each GIS (switchgear).

Depending on the implementation, when the detection result of the zero-phase current transformer is excessive, the substation management server 200 may determine a fault current, and in this case, may flicker the tidal current direction indication in the MMI.

Those skilled in the art to which the present invention pertains should understand that the present invention may be embodied in other specific forms without changing the technical spirit or essential characteristics thereof, so the embodiments described above are illustrative in all respects and not restrictive. only do The scope of the present invention is indicated by the following claims rather than the detailed description, and all changes or modifications derived from the meaning and scope of the claims and their equivalent concepts should be construed as being included in the scope of the present invention. .

100: switchgear (GIS)
121 to 123: CTs
170: power current direction display device
200: substation management server
210: image current transformer

Claims (7)

a plurality of switchgear for inputting or opening a power path for each section of the substation;
CTs installed on the power line of each switch;
image current transformers installed on the CT detection signal lines located on the CT terminal blocks of the respective CTs; and
a substation management server that provides an MMI indicating a current direction of a position for each switch from the value input from the image current transformers;
Substation management server,
When the absolute value of the detection result of the image current transformer is continuously maintained within a predetermined reference range for a predetermined time, the substation system determines the direction of the current according to the positive (+)/negative (-) of the detection result.
According to claim 1,
The switchgear is a GIS (Gas Insulated Switchgear),
A substation system in which the current direction is displayed on a power current direction display device provided on a display device in front of the GIS.
According to claim 1,
The MMI is
A substation system for displaying the plurality of switchgear along a power path, and displaying a direction of a current in the direction of an arrow for the power path near a marked position for each switchgear.
delete According to claim 1,
The MMI is
When the detection result of the image current transformer is excessive, the substation system flickers the current direction display.
According to claim 1,
The substation management server,
A substation system that transmits the information on the direction of the current to the upper SCADA server.
According to claim 1,
The substation management server,
A substation system for storing information on the current direction for a predetermined time and displaying the current direction immediately before an accident on the MMI.

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