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Article

Design of Partial Discharge Test Environment for Oil-Filled Submarine Cable Terminals and Ultrasonic Monitoring

1
Key Laboratory of Engineering Dielectrics and its Application, Ministry of Education, Harbin University of Science and Technology, Harbin 150080, China
2
College of Rongcheng, Harbin University of Science and Technology, Rongcheng 264300, China
*
Author to whom correspondence should be addressed.
Energies 2019, 12(24), 4774; https://doi.org/10.3390/en12244774
Submission received: 28 October 2019 / Revised: 6 December 2019 / Accepted: 11 December 2019 / Published: 14 December 2019

Abstract

:
Based on the principle of operating an oil-filled-cable operation and the explanation of the oil-filling process provided in the cable operation and maintenance manual of submarine cables, this study investigated oil-pressure variation caused by gas generated as a result of cable faults. First, a set of oil-filled cables and their terminal oil-filled simulation system were designed in the laboratory, and a typical oil-filled-cable fault model was established according to the common faults of oil-filled cables observed in practice. Thereafter, ultrasonic signals of partial discharge (PD) under different fault models were obtained via validation experiments, which were performed by using oil-filled-cable simulation equipment. Subsequently, the ultrasonic signal mechanism was analyzed; these signals were generated via electric, thermal, and acoustic expansion and contraction, along with electric, mechanical, and acoustic electrostriction. Finally, upon processing the 400 experimental data groups, four practical parameters—maximum amplitude of the ultrasonic signal spectrum, Dmax, maximum frequency of the ultrasonic signals, fmax, average ultrasonic signal energy, Dav, and the ultrasonic signal amplitude coefficient, M—were designed to characterize the ultrasonic signals. These parameters can be used for subsequent pattern recognition. Thus, in this study, the terminal PD of an oil-filled marine cable was monitored.

Graphical Abstract

1. Introduction

Partial discharge (PD) can cause two types of damage to electrical equipment [1,2]: (1) direct damage, owing to the effect of the discharge particles, resulting in local damage to the insulation and further deterioration; and (2) damage due to the PD of companions, such as nitrogen oxide and ozone, in addition to local damage due to a certain degree of corrosion and large heat insulation dielectric loss, resulting in thermal breakdown. In electrical equipment with a solid–liquid composite medium constituting the main body, PD is also caused by a complex structure and an uneven electric field distribution. During PD and other deterioration of insulation, electric pulses, gas products, ultrasonic and electromagnetic radiation, light, local overheating, and energy loss often occur [3,4,5]. Ultrasonic signal detection can be used to effectively monitor the PD of insulation.
Herein, the primary insulation of high-voltage oil-filled cable is an oil–paper structure. During long-term operation, cable oil and insulating paper decompose the generated gas after extended periods of time. This is because of two parts: One part is the oil-filled-cable structure, running environment, condition of the oil, and the inside of the cable joint; the other part is thermal stresses, electrical stresses, and mechanical stresses induced after a several complex chemical changes. This decomposed gas subsequently dissolves in the cable oil, thereby resulting in variations in the cable oil pressure.
Figure 1 illustrates the structure of a 500 kV, oil-filled submarine cable.
The high-voltage cable terminal [6,7,8] is an indispensable accessory for connecting other electrical equipment when high-voltage cables are laid. It is widely used for cable circuits with a voltage level of 110 kV and above. Furthermore, oil-filled terminals account for the majority of high-voltage cable terminals. The primary component of oil-filled terminals is the layer of insulation shielding at the end of the cable that is equipped with a stress cone to achieve better electric field distribution in the casing, as compared to that in ceramic or composite materials. Normally, silicone oil or an insulating medium, such as polybutylene or polyisobutylene, is filled between the stress cone and the bushing at the end of the cable, for the purpose of insulation. The probability of the failure of the power cable circuit failure based on previous incidents indicates that the probabilities of the failures of the intermediate connector and the cable terminal account for approximately 67% of the total failure of the cable circuit [9]. Therefore, the insulation quality of the cable terminal directly affects the safe operation of the entire cable circuit, as the terminal is a key connecting device in the cable circuit.
For oil-filled submarine cable terminals, voltage transformers are not installed in the terminals at both ends of the oil-filled cable. Therefore, the actual voltage signals to ground at the two ends of the cable cannot be obtained, making it impossible to test the insulation performance of the cable. However, the ultrasonic method can be used to monitor the high-voltage terminals of oil-filled submarine cables, to realize warnings of the imminent faults.
The ultrasonic method can effectively reduce electromagnetic interference [10]. Implementation of online monitoring for this method is easy. Furthermore, this method supports noninvasive detection, is simple to implement, and has been widely employed in transformers and gas-insulated substations (GIS), capacitors, motors, cables, and cable terminal power equipment, such as those presented in [11,12]. Furthermore, GIS-electric-joint detection or sound-by-voice detection in transformers has also been realized.
Richárd Cselkó et al. [13] simulated a 10 kV cable termination semiconductor layer scratch with a heat-shrinkable air-gap tube with six defect types, while simultaneously employing the pulse current and ultrasonic methods for PD measurement and the acoustic detection method that employs a glass fiber guide, to introduce the ultrasonic sensor based on the axial and radial axes at 5 mm intervals per point. Richárd Cselkó et al. [13] also obtained the cable terminal PD ultrasonic RMS, periodic component peak, 50-Hz-related component, and 100-Hz-related component and detected position relations. According to their study, the 100-Hz-related component has the highest sensitivity and dynamic range, and it is less sensitive to external noise or noise interference caused by accidental waveguide rod movement. Within a certain range, when the voltage gradually increases, the discharge quantity measured by the pulse current method becomes approximately linearly related to the amplitude of the 100-Hz-related components. Markalous et al. [14] used the ultrasonic and ultrahigh-frequency methods to detect and locate the local electricity inside the transformer. Their results showed that a combination of the ultrahigh-frequency and ultrasonic methods could overcome the disadvantages of the ultrasonic method in terms of positioning by using the time difference between PD signals and the sensor. Such a combination of the two methods can improve both detection and positioning accuracies. Suwarno et al. [15] used the ultrasonic method to detect PD in a gas-insulated substation. By analyzing the frequency spectrum, amplitude, and number of signals in unit time of the ultrasonic signals collected on site, the ultrasonic method could enable detection of typical discharge signals, such as suspension potentials and pin-plate discharges. Wang et al. [16] built the 110 kV XLPE cable intermediate connector at the Sumitomo company, to simulate the four defects of air gap, burr, slide-flash, and suspension discharges in the terminal. The ultrasonic waveforms of the four types of defects were obtained by placing the piezoelectric sensors directly on the outside of the cable’s middle connector.
This article mainly studies from the perspective of oil-pressure changes caused by gas generated by cable failure. We learned the operation of oil-filled cables and the principle of oil replenishment introduced in the submarine cable operation and maintenance manual, and then we designed an oil-filled cable and its terminal recharge simulation system in the laboratory. Additionally, considering the commonly occurring faults in an oil-filled cable during actual operation, a typical oil-filled cable fault model was also established.
Using the research platform of a typical fault model of oil-filled cable equipment, the oil-filled-cable simulation equipment was experimentally verified, the ultrasonic generation mechanism of PD was discussed, the frequency spectrum of different types of PD ultrasonic was analyzed, and the characteristics of local discharge signals were summarized.

2. Test-Device Design

PD is the main manifestation of the early stage of faults in an oil-filled cable terminal, the main factor causing further aging of the terminal insulation, and an important characteristic of the terminal insulation state.

2.1. Oil-Cycle Simulation System

Under normal operating conditions of the cable circuit, the variation in oil pressure remains minimal. In this study, to simulate the changes in the oil pressure in submarine cables, an oil circulation system was built in the laboratory, to simulate the possible faults in the cables. The system was employed to simulate the faults in the cable, e.g., PD and local overheating of degradation products, including the variation of oil pressure within the oil-filled cable being monitored. Figure 2 shows the composition of the simulated oil-path system. The system mainly comprises three parts:
  • An oil-pressure-variation simulation unit for an oil-filled cable;
  • An oil-filled cable-terminal refueling-tank simulation unit;
  • A computer data acquisition and control unit.

2.2. Design of Simulation Unit for Oil-Pressure Variation in Oil-Filled Cable

A sealed pressure vessel was used as the test chamber to monitor oil pressure. To ensure that the vessel was airtight and safe, three valves were installed in the pipeline, as shown in Figure 3:
(1)
High-pressure valve: Owing to the simulated fault gas production, the oil pressure in the tank increased. After monitoring the oil pressure, the high-pressure valve was opened in order to allow oil and gas to flow into the oil-filling system, to achieve the system pressure.
(2)
Check valve: After opening the high-pressure valve, the oil and gas smoothly flowed through the check valve into the oil-filling system. This is because the check valve has directionality, can effectively avoid oil and gas backflow, and can complete the decompression process.
(3)
Low-pressure valve: After the tank simulating the cable was relieved of pressure, the liquid level inside the tank dropped. At this time, the low-pressure valve was opened in order to enable the cable oil in the oil-filling system to independently fill the tank because of gravity, until the whole tank was filled, to prepare for the next experiment.
Generally, there are two reasons for the oil-pressure variation in the oil-filled cable. The second reason is that the cable’s oil-pressure variation is caused by the by-product of PD. For this reason, we designed individual closed-tank test chambers for the thermal aging and PD tests. This article mainly describes the local release test.

2.3. Design of Closed-Tank Test Chamber for Partial-Discharge Test

Figure 4 shows the schematic of the PD test chamber.
A GDJ3-160 flange electrode with a rated voltage of 20 kV was used as the high-voltage electrode (1), as well as the grounding electrode (2), in Figure 4.

2.4. Discharge Model Design

The internal insulation structure of the oil-filled cable terminal is complex, and it may contain many defect types. These different defect types affect the form of PD [17,18,19,20], thereby resulting in the generation of different ultrasonic signals.
There is no unified conclusion regarding the construction of the physical model in many previous studies and the cable terminal failure reports presented in recent years. This article constructs five types of discharge models in order to simulate different defects, as shown in Figure 5, and successfully inspects and records the ultrasonic signals generated by PD.
  • Pin-plate discharge model: This model is used to simulate PD generated by the development of electric branches resulting from the presence of sharp conductors in the cable terminal.
  • Air-gap discharge model: This model is used to simulate PD caused by an air gap or an air bubble in the cable terminal.
  • Suspended electrode model: This model is used to simulate PD caused by the presence of carbon particles, metal particles, or other impurities in the cable terminal insulation oil.
  • Creeping discharge model: This model is used to simulate PD when the electric field intensity at the liquid–solid interface inside the cable terminal exceeds the initial discharge field intensity.
  • Sliding-flash discharge model: This model is used to simulate PD caused by pollution on the surface of the cable terminal.
Currently, the PD test environment of our oil-filled marine cable has been designed. Figure 6 shows the actual discharge-fault simulation system and operating platform.

3. Test

Figure 7 shows the system based on the principle of the circuit diagram. Herein, we address the power frequency voltage observed after usage of isolation transformers, voltage regulator, low-pressure, low-pass type II filter, high-pressure test in transformer PD, and high-pressure processing of low-pass filter to employ the method of the impulse current system in the experimental sample testing. Simultaneously, the test system was discharged for ultrasonic piezoelectric sensors placed near the samples, and the PD of the ultrasonic signal was detected. The jfd-2b-type pulsed current method system produced by Wuhan Nanrui was used. The entire experimental system was placed in a well-shielded room in order to avoid electromagnetic interference from signals in outer space.
When PD occurs, the acoustic wave is emitted outward in the form of a spherical wave in the oil tank. Simultaneously, as sound waves propagate faster in solids, they spread to the side walls of the oil tank and then spread along the side wall to the sensor. The reflection field of sound waves propagating to the sensor, coupled with the face-to-face box wall, affects the normal acquisition of the waveform. Therefore, sound-absorbing materials are positioned on the three tank walls and the bottom of the tank, except for the coupling surface of the sensor. Most of the sound-absorption materials are loose and porous. Herein, polyester fiber was selected as the absorption material.
The following aspects should be noted during the experiment.
  • During the calibration process of the pulse current method, the transformer should be powered off; otherwise the calibration accuracy will be affected, and the test result will be inaccurate.
  • The initial local discharge voltage of the whole system should be measured before the experiment. PD may occur in parts including transformers, high-voltage leads, and lead joints. Consider the needle plate, for example. The high-voltage needle electrode should be removed for testing, and the voltage should be gradually increased until the system detects the discharge. At this time, the voltage is the initial local discharge voltage of the system. To ensure that the measured electrical or ultrasonic signals are generated by PD at the electrode of the discharge model, the applied voltage during the experiment cannot be higher than the initial local discharge voltage of the system. Under normal circumstances, an electrical measurement system and an ultrasonic system have different sensitivities and insulation levels, and it is impossible to simultaneously detect the discharge signal in these systems. During gradual voltage boost, the initial local discharge voltage of the test system should be the voltage at which the discharge signal was detected earlier.
  • The pressurization process should be slow and uniform, and the pressurization time should not exceed 30 min. Excessive pressurization may lead to unstable PD and the breakdown of or damage to the equipment in serious cases.
Then, the characteristics of ultrasonic signals in the pin-plate discharge model are discussed, and the parameters are extracted. The typical time-domain waveform of the pin-plate discharge model is shown in Figure 8. As can be seen, the maximum positive and negative semidocycles of this ultrasonic signal are ±0.4 V, and they last for approximately 4700 μs. As shown in Figure 9 and Figure 10, the time and frequency domain waveforms of ultrasonic signals with a duration of 2200 and 260 microns, respectively, overlap with each other, as do the time-domain and frequency-domain waveforms of an ultrasonic signal with multiple pulse signals shown in Figure 11.
Upon comparison, it can be found that the frequency-domain waveform of the ultrasonic signal and the duration of the signal are independent of each other. Therefore, we conclude that this is consistent for both single and multiple ultrasonic signals. Therefore, the definition and processing method of an ultrasonic pulse signal in the software system introduced previously do not affect the actual detection and analysis results.
Next, PD tests and signal analyses were carried out for the other four discharge models. Figure 12 shows a typical time-domain waveform and frequency-domain waveform of ultrasonic signal for the air-gap discharge model. Figure 13 shows typical time-domain and frequency-domain waveforms of ultrasonic signals for the suspended-electrode discharge model. Figure 14 shows typical time-domain and frequency-domain waveforms of ultrasonic signal for the surface-discharge model. Figure 15 shows the typical time-domain and frequency-domain waveforms of ultrasonic signal for the sliding-flash discharge model.
According to the abovementioned analysis of different discharge models, we conclude that the ultrasonic spectra of different discharge models differ significantly. The peak frequency of the needle-plate discharge model is mainly concentrated in the range of 150–170 kHz. The peak frequency of the air-gap discharge model is mainly concentrated in the range of 160–170 kHz and 240–270 kHz spectra. The peak frequency of the floating-electrode discharge model is mainly concentrated in the range of 50–100 kHz and 150–200 kHz spectra. Moreover, the peak frequency of the creeping discharge model is mainly concentrated in the 50–300 kHz spectra. The peak frequency of the flicker discharge model mainly ranges between 50 and 80 kHz.

4. Results Analysis

Previous scholars have extensively discussed the processing of acoustic signals; however, there has been little discussion on how the energy in PD transforms from electric-field energy to sound-field energy. Herein, we discuss this subject in part.
PDs occur differently in different electric-field environments or with different defects. When the overvoltage is significantly high, a few PDs generate substantial thermal radiation. Contrarily, when the overvoltage is not significantly high, they generate minimal thermal radiation.
This process can be analyzed solely from the physical perspective. A pulsed electric-field force acts on the bubble at the instant PD occurs. At this time, the pressure inside the bubble rises, owing to the high temperature generated by the arc current in the discharge channel.
Two factors play a decisive role in the process of a PD generating an ultrasonic wave: (1) the pressure caused by the expansion of the air bubble owing to the high temperature generated by the arc after discharging electricity under high overvoltage and (2) the electric field force when the power is discharged at a low overvoltage. Owing to the action of the pulsed electric-field force, the bubble will initiate a shock-attenuation process in the local area. Under the action of bubble vibration, the surrounding medium will produce a density wave, which is caused by the electrostrictive effect.
When the bubbles in the transformer oil exposed to a high electric field are punctured and discharged, several uneven spark-discharge channels with a width of several microns are created. The air gap within the surrounding gas-spark-discharge channel—caused by local strong ionization high voltage and the arc produced by high-temperature heating, resulting from high temperature after rapid enlargement of the heating gas discharge channel—expands very fast; this can often occur at a speed close to that of sound waves, and the plasma channel cross-sectional area reaches its maximum value in a few microseconds. This is how spark discharge occurs.
Finally, as the energy of the electric field is gradually transformed into heat, sound, and other energy forms, the electric-field intensity in the air gap gradually weakens, until the arc is extinguished and the discharge stops. When the electric-field energy in the subsequent bubble accumulates to a certain extent, the second discharge occurs, and the same process is repeated. However, in practice, the real PD process is often caused by the simultaneous occurrence of the abovementioned factors to produce ultrasonic signals.
When the ultrasonic wave traverses from one medium to another, both the wave velocity and wavelength change; however, the frequency remains unchanged, and it exhibits the following relationship:
λ = v f
Simultaneously, ultrasonic waves will be refracted and reflected at the interface coupled with two media. The energy loss caused by the refraction angle and reflection is related to the acoustic impedance of the media [21]. Acoustic impedance Z is defined as follows:
Z = ρ c
where ρ is the medium density (kg/m2), and C is the velocity in the medium. In addition, an ultrasonic wave has two characteristic quantities: sound intensity (I) and sound pressure (p). The diffusion, scattering, and absorption of sound waves cause the rapid attenuation of sound waves during propagation. In an ideal medium, sound waves only spread, and the attenuation rules of sound intensity and sound pressure [22] are as follows:
p x = p 0 e α x
I x = I 0 e 2 α x
where p0 and I0 are the initial sound pressure and initial sound intensity, respectively; alpha is the attenuation coefficient; and X is the propagation distance. According to the description of mechanical wave motion in the standard manual, the wave process of acoustic waves can be expressed by using the following differential equation [23]:
2 p = 1 c 2 2 p t 2
The absorption characteristics of different media are different. The higher the frequency is, the larger the absorption coefficient is and the larger the attenuation is. In the gas medium, the attenuation of sound waves is directly proportional to the frequency f and even f2. On the contrary, in the liquid and metal media, the ultrasonic wave achieves better transmission characteristics and slower attenuation, rendering the ultrasonic method highly suitable for PD detection in cable terminals, transformers, and other electrical equipment employing oil–paper insulation.
To effectively analyze different discharge modes, extracting characteristic parameters from ultrasonic signals generated by PD is necessary, as this can enable more effective descriptions of ultrasonic signals generated by PD. The time-domain signal is mainly used to describe the ultrasonic signal generated by PD. The relationship between these generated signals and the aging degree of dielectric materials, physical significance, experimental conditions, and calculation methods should be considered when describing the signals. Existing studies on PD acoustic measurement state that the most appropriate time-domain information to describe the development of PD is amplitude [24]. However, recent studies have shown that time-domain signals cannot be well classified into different discharge modes, and there is no appropriate standard to classify different discharge modes.
To effectively describe different PD types, we must adopt appropriate parameters. Therefore, the following parameters are defined:
  • Maximum spectral amplitude of ultrasonic signal, Dmax;
  • Maximum ultrasonic signal frequency, fmax;
  • Average of ultrasonic signal energy, Dav;
  • Amplitude coefficient of ultrasonic signal, M.
Here, the mean value of the ultrasonic signal is as follows:
D a v = f 1 f 2 D ( f ) f 1 f 2 d f
The root-mean-square value of ultrasonic signal energy is as follows:
D r m s = f 1 f 2 D 2 ( f ) d f f 1 f 2 d f
The amplitude coefficient of ultrasonic wave is as follows:
M = D max D r m s
Table 1 lists the parameters of the different discharge models. The value of each parameter is the average value obtained after calculating 400 waveform samples.
Upon calculating the parameter values of each model, we find that the maximum frequency, fmax, and amplitude coefficient, M, of the pin-plate discharge model in the frequency-domain analysis are obviously different from other discharges. Based on Mason’s formula [25], the electric field of the pin-plate discharge is more concentrated. Therefore, the following conclusions are made:
(1)
When the test voltage reaches the initial discharge voltage, the ultrasonic signal shows a pulse-oscillation attenuation pattern with a large amplitude and fast attenuation, forming a signal pattern with a significantly lower fmax than other discharge models and a significantly higher M, as shown in Figure 8, Figure 9 and Figure 10.
(2)
When the applied voltage is significantly higher than the initial discharge voltage, the electric field of the pin-plate discharge is concentrated, and it assumes the form of repeated and accumulated discharge, resulting in rapid and continuous discharge. The high-amplitude region (wave head) of the newly generated signal is superimposed onto the low-amplitude oscillation (wave tail) of the previous signal. Furthermore, the superposition of the M value increases, and the overall continuous signal fmax declines, as shown in Figure 11.
Moreover, as can be seen from Table 1, in Dmax, the maximum value of spectrum analysis and the parameters of each discharge model are similar, whereas the energy Dav of each discharge model is significantly different. The four parameters proposed herein can be used to distinguish different discharge models.

5. Conclusions

In this study, a research platform for the typical fault model of an oil-filled submarine cable was designed and used to perform confirmative experiments on oil-filled-cable simulation equipment, to explore the ultrasonic generation mechanism of PD, analyze the frequency spectrum of different types of PD ultrasonic waves, and characterize local discharge signals. The conclusions of this study are as follows:
  • The test environment of PD at the end of the oil-filled marine cable was designed, and five types of PD models were designed, considering the complexity of defects in insulating materials, which is highly significant for the study of PD characteristics of liquid/solid composite media.
  • The microscopic process of the electrical–acoustic conversion of PD in the insulating medium was expounded, and the mechanism of local release of ultrasonic signals in the liquid/solid composite medium was further discussed, and it was determined that the electrical–thermal–acoustic thermal expansion and contraction effect and electrical–mechanical-energy–acoustic electrostriction characteristics acted together to produce the ultrasonic wave.
  • Upon analyzing and summarizing the collected ultrasonic signals of various discharge models, four parameters were designed to characterize ultrasonic signals, and it was deemed that they displayed different frequency-domain characteristics and energy characteristics, which could be used for subsequent pattern recognition.

Author Contributions

Conceptualization, Y.W.; data curation, L.L.; formal analysis, Y.W.; funding acquisition, X.Z.; investigation, J.G.; methodology, L.L.; software, J.D.; writing—original draft, Y.W.; writing—review and editing, X.Z.

Funding

This project was supported by the National Natural Science Foundation of China (Grant No. 51577045) and A Project of Shandong Province Higher Educational Science and Technology Program (Grant No. J17KB135).

Conflicts of Interest

The authors declare no conflicts of interest.

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Figure 1. Structure of a 500 kV, oil-filled submarine cable. 1. Oil channel; 2. conductor; 3. conductor shield; 4. insulation; 5. insulation shield; 6. copper braid belt; 7. alloy lead sleeve; 8. copper braid; 9. reinforcement layer; 10. cushion belt; 11. internal anticorrosive layer; 12. mothproof layer; 13. cushion belt; 14. sheath; 15. outer coating.
Figure 1. Structure of a 500 kV, oil-filled submarine cable. 1. Oil channel; 2. conductor; 3. conductor shield; 4. insulation; 5. insulation shield; 6. copper braid belt; 7. alloy lead sleeve; 8. copper braid; 9. reinforcement layer; 10. cushion belt; 11. internal anticorrosive layer; 12. mothproof layer; 13. cushion belt; 14. sheath; 15. outer coating.
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Figure 2. Schematic of the oil circuit system simulating oil-pressure variation in an oil-filled cable.
Figure 2. Schematic of the oil circuit system simulating oil-pressure variation in an oil-filled cable.
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Figure 3. Schematic of valve setting in oil-pressure-monitoring test chamber.
Figure 3. Schematic of valve setting in oil-pressure-monitoring test chamber.
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Figure 4. Schematic of partial-discharge test chamber. 1. High-voltage power supply; 2. low-voltage grounding; 3. data acquisition to the computer; 4. simulation of partial-discharge fault.
Figure 4. Schematic of partial-discharge test chamber. 1. High-voltage power supply; 2. low-voltage grounding; 3. data acquisition to the computer; 4. simulation of partial-discharge fault.
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Figure 5. The five types of discharge models: (a) discharge needle plate, (b) slide-flash discharge, (c) Suspended discharge, (d) creeping discharge, and (e) discharge of plate with air gap. 1. High-voltage leads; 2. polyethylene test board; 3. PTFE bracket; 4. copper electrode; and 5. cable oil.
Figure 5. The five types of discharge models: (a) discharge needle plate, (b) slide-flash discharge, (c) Suspended discharge, (d) creeping discharge, and (e) discharge of plate with air gap. 1. High-voltage leads; 2. polyethylene test board; 3. PTFE bracket; 4. copper electrode; and 5. cable oil.
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Figure 6. Discharge-fault simulation system and operating platform.
Figure 6. Discharge-fault simulation system and operating platform.
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Figure 7. Test-system schematic. T1—isolation transformer; T2—voltage regulator; C1, L1—low-pressure, low-pass PI filter; T3—high-voltage experimental transformer; C2, L2—high-voltage low-pass filter; CK—coupling capacitor; Zin—detection impedance; T—tank; S—piezoelectric sensor; AMP—preamplifier; and DAQ—data acquisition card.
Figure 7. Test-system schematic. T1—isolation transformer; T2—voltage regulator; C1, L1—low-pressure, low-pass PI filter; T3—high-voltage experimental transformer; C2, L2—high-voltage low-pass filter; CK—coupling capacitor; Zin—detection impedance; T—tank; S—piezoelectric sensor; AMP—preamplifier; and DAQ—data acquisition card.
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Figure 8. Waveform of the 4700 μs ultrasound signal.
Figure 8. Waveform of the 4700 μs ultrasound signal.
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Figure 9. Waveform of the 2200 μs ultrasound signal.
Figure 9. Waveform of the 2200 μs ultrasound signal.
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Figure 10. Waveform of the 260 μs ultrasound signal.
Figure 10. Waveform of the 260 μs ultrasound signal.
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Figure 11. Waveform of the multi-pulse ultrasound signal.
Figure 11. Waveform of the multi-pulse ultrasound signal.
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Figure 12. Ultrasound signal waveform of cavity discharge.
Figure 12. Ultrasound signal waveform of cavity discharge.
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Figure 13. Ultrasound signal waveform of floating discharge.
Figure 13. Ultrasound signal waveform of floating discharge.
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Figure 14. Ultrasound signal waveform of surface discharge.
Figure 14. Ultrasound signal waveform of surface discharge.
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Figure 15. Ultrasound signal waveform of sliding discharge.
Figure 15. Ultrasound signal waveform of sliding discharge.
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Table 1. Parameter value of each model.
Table 1. Parameter value of each model.
ParameterPin-Plate Discharge ModelAir-Gap Discharge ModelSuspended-Electrode Discharge ModelSurface Discharge ModelSliding-Flash Discharge Model
Dmax (mv)47.3546.5652.3951.2648.33
fmax (kHz)180.56360.12320.52337.88320.78
Dav (mv)12.5112.8725.3625.3325.64
M2. 351.651.761.351.58

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MDPI and ACS Style

Wang, Y.; Zhang, X.; Li, L.; Du, J.; Gao, J. Design of Partial Discharge Test Environment for Oil-Filled Submarine Cable Terminals and Ultrasonic Monitoring. Energies 2019, 12, 4774. https://doi.org/10.3390/en12244774

AMA Style

Wang Y, Zhang X, Li L, Du J, Gao J. Design of Partial Discharge Test Environment for Oil-Filled Submarine Cable Terminals and Ultrasonic Monitoring. Energies. 2019; 12(24):4774. https://doi.org/10.3390/en12244774

Chicago/Turabian Style

Wang, Yulong, Xiaohong Zhang, Lili Li, Jinyang Du, and Junguo Gao. 2019. "Design of Partial Discharge Test Environment for Oil-Filled Submarine Cable Terminals and Ultrasonic Monitoring" Energies 12, no. 24: 4774. https://doi.org/10.3390/en12244774

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