Abstract

As high-voltage circuit breakers (HVCBs) are responsible for switching off the load in the event of anomalies, they suffer various wear and tear, both on their main contacts and on the other actuation mechanisms. Not only load maneuvers but also weather conditions can bring factors that contribute to deterioration and, consequently, contribute to failures of this component that is so important for energy supply. Both failures and maintenance shutdowns generate costs for substations, something that could be minimized if there was monitoring of the condition of the HVCBs. This paper shows a methodology to analyze the vibration signal of HVCB in order to identify and quantify contact failures. The proposed methodology is verified through an experimental setup. The results show that it is possible not only to identify the fault but also to assess its intensity using vibration analysis.

Keywords:
High-voltage HVCBs; Vibration analysis; Signal processing; Fault detection; Predictive Maintenance

HIGHLIGHTS

• A methodology to detect contact fault in HVCB using vibration analysis is proposed.

• A real experimental setup is used to validate the methodology.

• The results show that is possible not only identify failures but also to assess its intensity.

INTRODUCTION

High-voltage circuit breakers (HVCBs) are one of the most crucial components of protection and control in power systems. As a result, its reliability is critical for ensuring the stability and security of these systems [¹1 Rovelli E, Scaroaci S, Lidozzi A, Solero L. An HVCB Electronic Drive for Modern Electrical Substations in Distribution Power Systems. IEEE Trans. Power Deliv. 2015;31.2:665-73.

2 Bagherpoor A, Rahimi-Pordanjani S, Razi-Kazemi AA, Niayesh K. Online condition assessment of interruption chamber of gas HVCBs using arc voltage measurement. IEEE Trans. Power Deliv. 2016;32.4:1776-83.-³3 Yang Q, Ruan J, Zhuang Z, Huang D. Condition evaluation for opening damper of spring operated high-voltage HVCB using vibration time-frequency image. IEEE Sensors J, 2019, 19.18: 8116-26.]. HVCBs must be examined and checked on a regular schedule to prevent incorrect operation. Because HVCBs are made up of various mechanical and electrical components, such as dampers, latches, springs, and coils, flaws can occur for a variety of reasons [⁴4 Niayesh K, Runde M. Power switching components. Springer International Publishing, 2017.-⁵5 Razi-Kazemi AA, Niayesh K. Condition monitoring of high voltage HVCBs: past to future. IEEE Trans. Power Deliv., 2020,36.2:740-50.].

The most common methods for performing HVCB condition checks are measuring contact resistance, contact timing, travel motion, velocity, and coil current [⁶6 Yang Q, Ruan J, Zhuang Z, Huang D. Chaotic analysis and feature extraction of vibration signals from power HVCBs. IEEE Trans. Power Deliv., 2019, 35.3: 1124-35.-⁷7 Charbkeaw N, Suwanasri T, Bunyagul T. Mechanical defect detection of SF6 high voltage HVCB using wavelet based vibration signal analysis. In: 2008 5th International Conference on Electrical Engineering/Electronics, Computer, Telecommunications and Information Technology. IEEE, 2008. p. 901-904.]. However, conventional methods require that the system be stopped to perform the measurements, which generates a cost both in money and time, in addition to possible damage due to excessively invasive maintenance [⁸8 Runde M, Aurud T, Lundgaard LE, Ottesen GE, Faugstad K. Acoustic diagnosis of high voltage circuit-breakers. IEEE Trans. Power Deliv., 1992,7.3:1306-15.-⁹9 Charbkaew N, Suwanasri T, Bunyagul T, Schnettler A. Vibration signal analysis for condition monitoring of puffer‐type high‐voltage HVCBs using wavelet transform. IEEJ transactions on electrical and electronic engineering, 2012, 7.1: 13-22.].

As a result, tests for monitoring and diagnosing the health of HVCBs, particularly using non-invasive procedures, were developed with the goal of easing maintenance and lowering costs. The premise is that it is possible to detect faults in HVCB by measuring other magnitudes that contain fault information without having to turn off the equipment. Vibration analysis, a well-established technique for defect analysis that has been used in rotary engines [¹⁰10 Ribeiro Junior RF, Areias IAdS, Campos MM, Teixeira CE, Da Silva LEB, Gomes GF. Fault detection and diagnosis in electric motors using convolution neural network and short-time fourier transform. J. Vib. Eng. Technol., 2022, 1-12.], composites [¹¹11 Bortoluzzi DB, Diniz CA, Ribeiro Junior RF, Francisco MB, Ancelotti Junior AC, Gomes GF. An Experimental Characterisation on Rectangular Z-Pinned Parameters in the Dynamic Modal Responses of Reinforced Composites. Appl. Compos. Mater., 2023, 1-27.], and other applications, is now being used to detect faults in HVCBs. HVCB vibration signals, on the other hand, are significantly non-stationary and non-linear, making feature extraction more challenging than for other vibration signals, such as those from rotating motors [³3 Yang Q, Ruan J, Zhuang Z, Huang D. Condition evaluation for opening damper of spring operated high-voltage HVCB using vibration time-frequency image. IEEE Sensors J, 2019, 19.18: 8116-26.].

Vibration analysis utilized in HVBC research could be categorized according to the manner of extracting signal characteristics, like the domain of analysis: time domain, frequency domain, and time-frequency domain. Most of the tools identified in this domain for monitoring HVBC are derived from research that attempts to extract characteristics from vibroacoustic sounds [¹²12 Da Silva CL, Reis O, Assunção FdO, Castioni JCO, Martins R, Xavier CE, et al. An Online Non-Invasive Condition Assessment Method of Outdoor High-Voltage SF6 HVCB. Machines, 2023, 11.3: 323.].

Many causes of vibration can be recognized during the closing or opening action, with the working mechanisms including more than half of all potential faults in HVCB [¹³13 Janssen A, Makareinis D, Sölver C-E. International surveys on circuit-breaker reliability data for substation and system studies. IEEE Trans. Power Deliv. 2013;29.2:808-14.]. Each vibration source has a unique vibration signature, which may be used to detect not just the problem but also which component has the issue. This is also a non-invasive procedure, and all measurements can be performed online. Although HVCBs are not the type of equipment with the highest book value in the electrical system, they are the main protection element for other equipment that has a higher price.

In this paper, a diagnostic method based on analyzing the vibration signals in HVCB is proposed. For this, firstly, the vibration signals of a HVCB in healthy condition are collected to serve as a baseline. After collecting the signals, damages are made to the HVCB contacts, and then the vibration signal is measured in order to compare it with the baseline. The results show that the vibration signal is sensitive enough to detect the induced fault in the HVCB.

The article is organized as follows: The next section presents the experimental setup used as well as the entire methodology used in the HVCB failure test. The follow section presents the main results and discussions. Finally, the last section concludes the paper.

MATERIAL AND METHODS

To analyze HVCB failures, two basic approaches can be used. The first involves monitoring an active HVCB and analyzing all changes until it fails. In the second approach, the defects are inserted on purpose in order to be able to compare the faulty HVCB with the healthy one. In this paper, the second approach was adopted, that is, inserting the fault.

Circuit breakers can use air, oil, or gas as an insulating medium. However, circuit breakers using air or oil have a relatively slow arc extinguishing force after contact separation movement, which in the case of high voltage circuit breakers is a negative since they require the shortest possible extinguishing time in order to avoid an increase in tension harmful to the equipment. Hence, for high voltages, SF6 circuit breakers are widely applied.

HVCBs that use SF6 are split into two types (live tank and dead tank) based on their extinguishing chambers. The switching device of the live tank type is in an insulator bushing that is live at line voltage (or some voltage above ground). Living tank circuit breakers are less expensive and take up less space than dead tank breakers. The switching device in the dead tank is housed within a metallic container that is kept at earth potential. Because the incoming and outgoing wires are routed through insulated bushings, current transformers can be installed on them (with a live tank arrangement, this is not possible and separate CTs are required).

SF6-insulated HVCBs are manufactured following the IEC 62271-100 standard, also known as "High Voltage - Part 100: High Voltage Circuit Breakers -- Power Circuit Breakers", which establishes the requirements for HVCBs used in alternating current electrical power systems with a frequency of 50 Hz or 60 Hz. Some of the topics covered by the standard include:

The IEC 62271-100 standard is widely recognized as an important international standard for the manufacture and safe operation of high-voltage circuit breakers.

Experimental setup

This subsection presents the equipment used in the HVCB failure test. The HVCB used was the GL312 Alstom/GE 145 kV, insulated with SF6 gas, and of the live tank type. Figure 1 shows the HVCB used in the tests, and Table 1 shows its main characteristics.

For the vibration measurements, the SI110A PHD accelerometer was used (Table 2), and for the drive mechanism angle measurements, the high-resolution incremental-type encoder DFS60A SICK was used (Table 3). The accelerometer was installed at the base of each pole, in the horizontal direction, in order to eliminate signal saturation and provide a better response in amplitude and frequency, as shown in Figure 2a. The encoder was installed on the axes of the pole, as illustrated in Figure 2b. All signals are collected using the Preditor 4.0® acquisition system, which has an analog-digital converter with 24-bit resolution and a sampling frequency of 46.875 kHz.

Methodology

This subsection presents the methodology used to carry out the tests. The tests carried out consist of measuring the vibration through the accelerometer and the angle of the driver mechanism through the encoder. The tests are carried out during the HVCB operation, that is, closing and opening the contacts. Before inserting the faults, five vibration signals were collected in healthy operating conditions to serve as a baseline in the analysis. Once collected, faults can be inserted into breaker contacts. Faults were simulated by causing a contact finger failure in two different ways. The first time, we removed 5 of the 40 contact fingers (fault 1), and the second time, we removed 11 of the 40 contact fingers (fault 2). Thus, it will be possible to evaluate not only the detection of the fault but also the sensitivity to the intensity of the fault. As in the healthy condition, 5 signals were also collected in each fault condition. In summary, Figure 3 presents the flowchart of the proposed methodology, also, Figure 4 shows the HVCB contact fingers.

RESULTS AND DISCUSSION

In this section, the results obtained through vibration analysis techniques will be discussed. As mentioned, the analysis will be carried out by comparing the vibration signal of a healthy HVCB with that of another with a fault (2 levels of intensity). To aid the interpretation, the angle of the HVCB activation mechanism will also be presented. With this information, it is possible to infer the closing and opening moments of the HVCBs.

Figure 5 shows the signals collected in the 5 vibration tests for the HVCB in healthy condition. These signals will be used as a baseline to compare with the fault signals. Figure 6 shows the signals for the HVCB with fault 1. In the highlighted region, it is possible to perceive a significant increase in amplitude for all tests. It is also possible to notice that this increase in amplitude occurs close to the moment of closing the contacts. This occurs due to the variations caused by the failure inserted in the contact fingers. Figure 7 shows the signals for the HVCB with fault 2. In the highlighted regions, it is also possible to see a significant increase in the amplitude of vibration for all tests. In addition, he notices that this increase is greater than in the case of failure 1, which shows that in addition to being able to detect the defect, it is also possible to measure how serious it is. Finally, in the same way as for fault 1, the increase in vibration amplitude occurs during the closing of the HVCB contacts.

Figure 8 was used to help compare the signals. In it, all the signals 1 from tests were chosen and placed together to better assess the difference between them. With the same thought in mind, Figure 9 was also created, which shows the percentage variation of the vibration signal of the defects in the selected region based on the baseline.

CONCLUSION

This paper presents the application of vibration analysis to detect and quantify faults in HVCBs. The usage and application of vibration analysis methodologies were explored and validated by an experiment. The results show that it is possible not only to identify the fault but also to assess its intensity.

Furthermore, the study is industry-relevant. Through vibration analysis, it is possible to access the condition of the HVCB non-invasively and possibly online. This all generates greater availability and safety in the HVCB, in addition to a reduction in cost. Even though it is very efficient and practical, it must be said that tests have not been carried out on all possible defects that may occur in a HVCB.

Future work will include more tests and evaluate other types of faults that occur in HVCBs. Furthermore, with a larger database, it is possible to develop AI techniques to automate the diagnosis of faults in HVCBs.

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