KR102089090B1 - Method and apparatus for synchronizing status detection in a power system - Google Patents

Abstract

Provided are a synchronization method for detecting a state of a power system and an apparatus thereof. The synchronization method comprises the steps of: transmitting an optical reference signal synchronized with zero crossing of an AC voltage of the power system from a master control device of the power system and time information to a plurality of sensor attachment devices; receiving event-related information generated based on an event detected by an attached sensor based on the optical reference signal and the time information in at least one device of the plurality of sensor attachment devices; and storing the received event-related information.

Description

Method and apparatus for synchronizing status detection in a power system

The present disclosure relates to controlling the power system to be synchronized with the operation of the power system when detecting an event of a plurality of sensors attached devices.

This disclosure is derived from research conducted as part of the Korea Energy Technology Evaluation Institute's energy technology development project. [Task number: 20171210200840, Project name: Demonstration of micro-grid system for small and medium-sized enterprises in developing countries and business model development]

In the power system to which a large number of high-voltage electric or heavy electric machines belong, the importance of the failure detection or failure prevention of each electric machine cannot be overstated when considering the magnitude of the accident. In a power system that includes a large number of high-voltage devices, failures often occur in a certain pattern, as in other systems, so collecting data related to faults and generating related big data in a power system composed of these high-voltage devices can improve safety. It's becoming an essential process.

When collecting big data related to a malfunction or abnormal operation of an electric device in a power system composed of high-voltage devices, it is important to know exactly when and under what circumstances the event related to the operation of the power system occurs. .

In detecting a failure or abnormal operation event in a power system composed of a plurality of high voltage devices or heavy electric devices, it is necessary to collect data related to an accurate time point and surrounding situations in synchronization with the operation of the power system.

In the present disclosure, in order to solve the above problems, transmitting the optical reference signal and time information synchronized with the zero crossing of the AC voltage of the power system in the master control device of the power system to a plurality of sensor attachment devices, the plurality of sensors A state in a power system characterized by receiving at least one of the attached devices, event-related information detected based on the light reference signal and the time information, and storing the received event-related information. A method for synchronizing detection is presented.

Preferably, the optical reference signal is used as a signal for resetting the event detection state of the plurality of sensor attachment devices.

Preferably, the optical reference signal is characterized in that the plurality of sensor attachment devices are used as an event detection reference signal of the plurality of sensor attachment devices as an AC voltage reference signal of the power system.

Preferably, the plurality of sensor attachment devices includes at least one of a temperature sensor attachment device, a vibration sensor attachment device, a partial discharge sensor attachment device, an arc detection sensor attachment device, a current sensor attachment device, and a voltage sensor attachment device. It is characterized by.

Preferably, the optical reference signal is generated when the zero crossing of the AC voltage is zero-crossed from a negative (-) value of the voltage to a positive (+) value of the voltage.

Preferably, the time information is obtained and transmitted through the GPS of the master control device.

Preferably, the detected event-related information includes the event occurrence time information, the relative time information from the light reference signal to the occurrence, and the type of the sensed event.

Preferably, the detected event-related information further comprises voltage information, current information, and location information of the sensor-attached device at which the event was detected at the event occurrence time.

Preferably, the method further includes analyzing the received event-related information to generate a control signal, and transmitting the control signal to a device requiring control related to the event.

In the present disclosure, a power system state detection synchronization device for solving the above problems, a processor generating an optical reference signal synchronized with zero crossing of an AC voltage of a power system, a time information unit generating time information, and the optical reference signal And transmitting the time information to a plurality of sensor-attached devices belonging to the power system, and through at least one of the plurality of sensor-attached devices, the light reference signal and the time information through an attached sensor. It includes a transceiver for receiving event-related information, generated based on the detected event, and a memory for storing the received event-related information.

According to the present disclosure, electric devices of the power system can detect events synchronized with the operation of the power system and analyze data synchronized with the operation of the power system.

1 is a power system diagram according to an embodiment of the present disclosure.
2 is a power system diagram according to an embodiment of the present disclosure.
3 is a block diagram of a master control device according to an embodiment of the present disclosure.
4 illustrates generating a synchronization signal synchronized with an AC voltage of a power system according to an embodiment of the present disclosure.
5 is a flowchart for performing state detection of a power system according to an embodiment of the present disclosure.

Hereinafter, embodiments according to the present invention will be described in detail with reference to the accompanying drawings. However, the present invention is not limited to the embodiments described herein and may be embodied in other forms. Rather, the embodiments introduced herein are provided to ensure that the disclosed contents are thorough and complete and that the spirit of the present invention is sufficiently conveyed to those skilled in the art. Throughout the specification, the same reference numbers indicate the same components. Meanwhile, the terms used in the present specification are for explaining the embodiments and are not intended to limit the present invention. In the present specification, the singular form also includes the plural form unless otherwise specified in the phrase.

In general, a high voltage device or a heavy electric device belonging to a high voltage power system has a high risk according to its operating power level, and thus requires high reliability. In other words, it is essential to detect failures of devices belonging to the power system within a short period of time or to detect and prevent abnormal failures in advance by detecting abnormal behavior before they occur.

In the power system, it is necessary to detect such abnormal operation or failure as an event through a sensor in a short time.

Here, the event may include an occurrence of an arc in an electric device, for example, a Gas Insulated Switched Gear (GIS) device, or an abnormal voltage / current pattern compared to a normal voltage operated in the device. Abnormal voltage / current patterns may cause sudden changes in voltage / current magnitude, such as surge voltage / current generation, and abnormal frequency in the device even when there is little change in voltage / current phase or frequency of the power system. In some cases, changes may occur, and these cases can be said to be events that should be detected as abnormal behavior. In addition, a temperature sensor is often attached to the device to determine whether the device is not overheating. If the temperature of the device rises above or within the allowable range, or if the pattern rises within the allowable range, it is similar to the normal pattern. It will be an object that should be detected as an event. In addition, when an abnormal vibration occurs within the device, a partial discharge occurs in an insulation device or a switch, or an arc occurs in the insulation breakdown part due to the progress of the partial discharge, an optical sensor, etc. It can be detected as an event.

As described above, an abnormal operation, which is a failure or an outbreak stage of a failure, may be detected as an event of the device, but it may also be detected as an event when necessary information is generated in the power system even if it is not necessarily a failure or an abnormal operation.

However, when a specific event occurs in a device belonging to the power system as described above, it is more important to understand in which situation the event occurs in relation to the operation of the power system, than to detect an event related to the failure in a short time. There are many cases. This is because, when looking at the entire power system, it is not only a problem of the device where the event has occurred, but it is often caused by a complex problem among systems participating in the power system.

In such a case, simply checking only when the event occurred may not be a great help in preventing the problem from recurring. That is, it is important to find out when the event occurred at a point in time compared to the operation of the power system, for example, the AC voltage or AC current of the power system, as well as the time information in which the event occurred in order to effectively solve the fault or prevent the fault. Do. Because, as mentioned above, not only is there a high possibility that the AC voltage operation of the power system is related to the event, but even if the event is not necessarily related to the AC voltage operation of the power system, it is applicable at any moment of the AC voltage operation. This is because, by accumulating and analyzing data on whether an event occurs, it is possible to predict in advance how the event will affect the operation of the power system.

By the way, when the event occurs, it is possible to accurately detect the event occurrence time by attaching a device such as a GPS device to a device belonging to the power system, but attaching the GPS device to all devices included in the power system individually causes a cost increase. do. In addition, as described above, it is highly likely that a simple event occurrence time is not very helpful information for troubleshooting or preventing failure. More important information is when the event occurred at "at what point" when synchronized with the operation of the power system.

1 is a power system diagram according to an embodiment of the present disclosure.

The master control device 1000 is a device that manages and controls the power system 100. The master control device 1000 acquires information through communication with the device 1 1100, the device 2 1200, and the device 3 1300 belonging to the power system 100 and transmits a control signal. The device 1 1100, the device 2 1200, and the device 3 1300 may each be a high voltage device, a heavy electric device, or a mechanical device belonging to the power system 100 even if it is not necessarily an electric device.

 As an embodiment, the temperature sensor 1101 is attached to the device 1 1100, the vibration sensor 1201 is attached to the device 2 1200, and the arc sensor 1301 is attached to the device 3 1300, which is an embodiment. In addition, multiple sensors may be attached to a single device, and the sensors are not limited to temperature sensors, vibration sensors, and arc sensors, but current sensors, voltage sensors, sound sensors, image sensors, and partial discharges. Various sensors such as sensors, weight sensors, optical sensors, rotation sensors, and gravity sensors can be used.

The master control device 1000 transmits time information T 1003 to the device 1 1100, the device 2 1200, and the device 3 1300 through time information acquisition means such as the GPS 1010. This is only an example, and the device 1 1100, the device 2 1200, and the device 3 1300 may each include separate time information acquisition means such as GPS. Device 1 (1100), device 2 (1200), and device 3 (1300), which monitor time through time information T (1003), transmit event-related information (1005) to the master control device (1000) when an event occurs The processor 1020 in the master control device 1000 analyzes the received event-related information 1005 and transmits the appropriate corresponding control signal 1007 to the device that transmitted the event-related information 1005 or other event-related control required. Send to the device to perform control. When monitoring an event of the power system 100 according to an embodiment according to FIG. 1, the first reference signal 1001 synchronized with the AC voltage of the power system 100 is assigned to each device 1 1100 and device 2 1200. , And device 3 1300. At this time, it is preferable that the initial reference signal 1001 is transmitted as an optical signal through an optical transmission unit (not shown) to minimize delay error.

At this time, each of the device 1 (1100), the device 2 (1200), and the device 3 (1300), based on the initial reference signal 1001, if the voltage of the power system 100 has a 60 Hz period, every cycle time Calculating at 16.7ms, the cycle can be repeated to perform internal calculations. Therefore, as an embodiment, if the device 2 1200 detects an abnormal vibration at a point 168 ms after receiving the first reference signal 1001, the device 2 1200 has an AC voltage of the power system 100 past 10 cycles. After that, it may be determined that an abnormal vibration has been detected at a point past 1 ms, and the corresponding information may be transmitted to the master control device 1000.

However, if this method is used, the device 1 (1100), the device 2 (1200), and the device 3 (1300) may calculate the time internally according to the initial reference signal 1001. There may be calculation errors or errors, and the AC voltage may not be accurately maintained at 60 Hz, and the frequency value may fluctuate for a variety of complex reasons. It is difficult for the operation of the system to be synchronized.

2 is a power system diagram according to an embodiment of the present disclosure.

Referring to FIG. 2, unlike FIG. 1, the master control device 2000 periodically transmits a reference signal to each device 1 2100, device 2 2200, and device 3 2300 belonging to the power system 200. . This reference signal is an optical reference signal 2001 synchronized with the operation of the power system 200. For example, as the operation of the power system 200, an AC voltage 2009 of the power system 200 is representative. At this time, the optical reference signal 2001 should be transmitted without delay to each device 1 2100, device 2 2200, and device 3 2300 belonging to the power system 200 without any delay error between devices. As it can be used as, it is transmitted as an optical signal through an optical cable.

The optical reference signal 2001 according to FIG. 2 is generated in synchronization with the zero crossing point in which the AC voltage 2009 of the power system 200 is converted from a negative value to a positive value, and then generates the optical reference signal. (Not shown) to each device 1 (2100), device 2 (2200), device 3 (2300) of the power system (200). In addition, the master control device 2000 transmits the time information T (2003) to each device 1 (2100), device 2 (2200), device 3 (of the power system 200) through a time information generator such as the time information unit (2010). 2300). GPS is a typical time information unit 2010 device. The time information T (2003) may be transmitted once when the power system is started, but may be transmitted to each of the device 1 (2100), the device 2 (2200), and the device 3 (2300) in synchronization with the above optical reference signal, for example. have.

When the optical reference signal 2001 is periodically transmitted to devices belonging to the power system 200 in this manner, devices belonging to the power system 200 detect an event based on a more accurate reference point. For example, assume that the device 2 detects a current surge event through the current sensor 2201 2 ms after receiving the third pulse of the optical reference signal 2009. The device 2 includes event generation time information based on the light reference signal 2001 called “2 ms elapsed after the third pulse” in the event related information 2005 transmitted to the master control device 2000 and “current value normally generated at that time 35 Event details such as "surge current of 200 [A] for 1us versus [A]" can be included.

According to an embodiment, event-related information transmitted to the master control apparatus 2000 may include event occurrence time information, relative time information indicating when the event occurred from the optical reference signal, and the type of the sensed event. .

In another embodiment, the detected event-related information may further include at least one of voltage information, current information, and location information of the sensor-attached device at which the event was detected at the time of event occurrence.

As a result of analyzing the received event-related information 2005 through the processor 2020, the master control device 2000 detects that an arc has occurred from the device 3 2300 at a similar time when a current surge occurs in the device 2 2200. It can be predicted that the arc generation of the device 3 2300 and the current surge in the device 2 2200 may be correlated with each other. Based on this event-related information, the master control device 2000 predicts that the insulation in the device 3 2300 is broken or the insulation state is poor, and the device 3 2300 is connected to the power system through a breaker (not shown). A control signal 2007 to be released can be transmitted. The master control device 2000 accumulates information generated in the power system in a database (not shown) to protect the event and the power system, analyzes the event information, and analyzes the event information to the power system according to the pattern analysis of sensed events. It can be analyzed by managing which devices belong to which devices are involved or affected by big data.

In this series of processes, if the event occurrence time of the device 2 2200 and the device 3 2300 is not correctly synchronized by the optical reference signal 2001, difficulties may occur in revealing a correlation between failures in the power system. .

After all, in the power system according to FIG. 2, the periodic light reference signal 2001 is interlocked and synchronized with the operation of the power system 200 and transmitted to devices belonging to each power system, thereby correcting the accuracy of event-related information of devices belonging to the power system. Will be able to write.

3 is a block diagram of a master control apparatus 2000 according to an embodiment of the present disclosure.

The master control device 2000 is composed of a time information unit 2010, a processor 2020, a transceiver 2030, and a memory 2040.

The time information unit 2010 generates time information (or time information) T (2003) that the master device transmits to devices belonging to the power system. GPS 2010 may be exemplified as a representative device for generating time information, but any device capable of generating time information may replace the time information unit 2010.

The master control device 2000 transmits the time information T 2003 generated by the time information unit 2010 to each device in the power system. The time information T 2003 may be transmitted once to each device for the first time, or may be periodically transmitted in synchronization with the optical reference signal 2001. Also, like the optical reference signal 2001, it may be transmitted through an optical cable.

The transmitting and receiving unit 2030 is responsible for transmitting signals or data or receiving signals or data from the master control unit 2000. The master control device 2000 includes a plurality of optical reference signals 2001 synchronized with when the AC voltage 2009 of the power system 200 is zero-crossing as described through FIG. 2 above, which belongs to the power system 200. It transmits to the sensor attachment devices through the transceiver 2030. In addition, the transceiver 2030 receives event-related information detected based on the optical reference signal and the time information T in at least one of a plurality of sensor-attached devices. The master control device 2000 stores the received event-related information in the memory 2040. The processor 2020 analyzes the received event-related information and, if necessary, generates a control signal for controlling sensors attached devices belonging to the power system. The generated control signal is transmitted through the transceiver 2030.

4 illustrates generating a synchronization signal synchronized to an AC voltage of a power system according to an embodiment of the present disclosure.

Referring to FIG. 4, it is shown that the optical reference signal 2001 is generated in synchronization with the zero crossing of the AC voltage 2009 of the power system. The 'optical' in the optical reference signal 2001 is attached because it is finally transmitted to devices belonging to the power system by an optical cable.

The optical reference signal 2001 according to FIG. 4 shows an example that is periodically generated at all zero crossings of the AC voltage 2009, but according to the selection, the optical reference signal 2001 is negative of the AC voltage 2009 of the power system. The optical reference signals 2001 may be generated by selecting only the optical reference signals 20011 and 20013 synchronized only at the moment of zero-crossing with a positive amount, and vice versa. Of course, as shown in FIG. 4, a method of synchronizing with all zero crossings of the AC voltage 2009 of the power system may be selected to increase synchronization accuracy.

In FIG. 4, the AC voltage 2009 of the power system is used as a reference signal for generating and synchronizing the optical reference signal 2001, but the current signal of the power system can be used as a reference signal for generating and synchronizing the optical reference signal 2001. have. However, considering that the AC voltage 2009 has higher accuracy or convenience than the aspect of sensing the AC current, it is preferable to select the AC voltage 2009 of the power system as the reference signal for generating and synchronizing the optical reference signal 2001. It would be more desirable.

The generated light reference signal 2001 is used as an event detection reference signal of an event occurring in connection with a sensor to which a plurality of sensor attachment devices belonging to a power system are attached. That is, it is determined based on the most recent light reference signal 2001 pulse that has received the event detection time point.

In addition, as another embodiment, the light reference signal 2001 may be used as a signal for resetting the event detection state of a plurality of sensors attached devices belonging to the power system. If no event occurs until the first signal among the optical reference signals 2001 is received by a plurality of sensor attachment devices belonging to the power system and receives the second signal of the next optical reference signal 2001, all sensors belonging to the power system are attached. The devices reset the event detection state and start checking whether an event is detected based on the second signal of the light reference signal 2001.

5 is a flowchart for performing state detection of a power system according to an embodiment of the present disclosure.

The master control device 2000 generates an optical reference signal 2001 synchronized with a point at which the AC voltage 2009 of the power system 200 is zero crossing, and the generated optical reference signal 2001 and time information T (2003) To the device 1 (2100), the device 2 (2200), and the device 3 (2300), which are devices with a plurality of sensors belonging to the power system 200. (S501)

Generated according to an event detected based on the light reference signal 2001 and the time information T (2003) in at least one of the plurality of sensor attachment devices 2100, 2200, and 2300 belonging to the power system 200 The master control device 2000 receives the event-related information 2005 (S503).

The master control device 2000 stores received event-related information. (S505) The master control device 2000 analyzes the received event-related information. As a result of the analysis, when it is determined that control is necessary in connection with the event for safe operation or protection of the power system, a control signal is generated. (S507) The master control device 2000 controls a specific device requiring control in the power system. The necessary control signals are transmitted to control the specific device. (S509) As described above, the control may include opening and closing a switch for blocking or blocking the corresponding high voltage device.

As described above, embodiments of the present invention have been disclosed through detailed description and drawings. The terms are used only for the purpose of describing the present invention, and are not used to limit the scope of the present invention as defined in the claims or the claims. Therefore, those skilled in the art will understand that various modifications and other equivalent embodiments are possible from the present specification. Therefore, the true technical protection scope of the present invention should be determined by the technical spirit of the appended claims.

100, 200; Electric power system
1000, 2000; Master control
1010; GPS
2010; Time Information Department
1020, 2020; Processor
2030; Transceiver
2040; Memory
1100, 2100; Device 1
1200, 2200; Device 2
1300, 2300; Device 3
1101, 2101; temperature Senser
1201; Vibration sensor
2201; Current sensor
1301, 2301; Arc sensor
1001; Reference signal
2001; Optical reference signal
2003; Time information T
1005, 2005; Event-related information
1007, 2007; Control signal
2009; AC voltage of power system

Claims (13)

Transmitting, from the master control device of the power system, optical reference signals and time information synchronized with zero crossing of the AC voltage of the power system to a plurality of sensors, and transmitting the optical reference signals as optical signals through an optical cable;
The first device and the second device among the plurality of sensor attachment devices generated based on the first event and the second event detected through the attached sensor based on the light reference signal and the time information, respectively. Receiving each of the first and second event-related information;
Predicting whether there is a correlation between the first event and the second event by analyzing the information related to the first and second events; And
And transmitting a control signal controlling at least one of the first device and the second device based on the correlation. The method of claim 1, wherein the optical reference signal is used as a signal for resetting the event detection state of the plurality of sensors attached devices. The method of claim 1, wherein the optical reference signal is used as an event detection reference signal of the plurality of sensors attached devices. The method of claim 1, wherein the plurality of sensor attachment devices are at least one of a temperature sensor attachment device, a vibration sensor attachment device, a partial discharge sensor attachment device, an arc detection sensor attachment device, a current sensor attachment device, and a voltage sensor attachment device. Method for synchronizing state detection in a power system comprising one. The synchronization of state detection in a power system according to claim 1, wherein the optical reference signal is generated when the zero crossing of the AC voltage is zero-crossed from a negative (-) value of the voltage to a positive (+) value of the voltage. Way. The method of claim 1, wherein the time information is acquired and transmitted through GPS of the master control device. The method of claim 1, wherein each of the detected first and second event-related information is relative to an occurrence time information of each of the first and second events, from the light reference signal to the occurrence of the first and second events. A method of synchronizing state detection in a power system, characterized in that it comprises time information, and the types of the sensed first and second events. The method of claim 7, wherein each of the detected first and second event-related information further includes voltage information, current information, and location information of a sensor attachment device in which the respective event was detected at the time of occurrence of the first and second events. Method for synchronizing state detection in a power system, characterized in that. delete A processor generating an optical reference signal synchronized with the zero crossing of the AC voltage of the power system in the master control device of the power system;
A time information unit for generating time information;
The optical reference signal and the time information are transmitted to a plurality of sensor attachment devices belonging to the power system, and the optical reference signal is transmitted as an optical signal through an optical cable, and the first device and the first of the plurality of sensor attachment devices are Each of the two devices receives and receives each of the first and second event-related information generated based on each of the first and second events detected through the attached sensor based on the optical reference signal and the time information. part;
It includes a memory for storing the received first and second event-related information,
The processor analyzes the information related to the first and second events to predict whether or not there is a correlation between the first event and the second event, and the transceiver transmits and receives the first device and the second based on the correlation. 2 A state detection synchronization device in a power system, characterized in that it transmits a control signal controlling at least one of the devices. The method of claim 10, wherein each of the detected first and second event-related information is relative to an occurrence time information of each of the first and second events, from the light reference signal to the occurrence of the first and second events. Time information, the state detection synchronization device in the power system, characterized in that it comprises a type of the first and second events sensed. 12. The method of claim 11, wherein each of the detected first and second event-related information further includes voltage information, current information, and location information of a sensor attachment device in which the respective event was detected at the time of occurrence of the first and second events. State detection synchronization device in the power system, characterized in that. delete

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