Your search keyword '"Bang Wook Lee"' showing total 138 results

1. Breakdown Characteristics of a Fluoronitrile Mixture Gas According to Mixing Ratio and Oxygen Content for High-Voltage Power Equipment Application

Author

Jin Yong Na, Ryul Hwang, Sung Joo Cho, Tae Hun Song, and Bang Wook Lee

Subjects

Fluoronitrile mixture gas, mixing ratio, oxygen content, extremely and weakly non-uniform electric fields, breakdown, high-voltage power equipment, Electrical engineering. Electronics. Nuclear engineering, TK1-9971

Abstract

Fluoronitrile (C4F7N) has many advantages, such as high dielectric strength, low global warming potential (GWP), and short atmospheric lifetime compared to sulfur hexafluoride (SF6). C4F7N is mixed with carbon dioxide (CO2) to prevent liquefaction at the operating pressure of high-voltage power equipment. Therefore, it is essential to investigate the dielectric characteristics of the C4F7N/CO2 mixture gas for the development of environmentally friendly power equipment. The dielectric characteristics of C4F7N/CO2 at lower pressures have been previously reported. However, research into the breakdown characteristics of C4F7N/CO2 under high pressure environments is insufficient. Furthermore, the effect of oxygen (O2) content contributing to suppression of carbon soot formation by arc on breakdown characteristics of C4F7N/CO2 has rarely been investigated. Therefore, in this paper, the breakdown characteristics of C4F7N/CO2 according to the mixing ratio and O2 content were investigated while considering a high–pressure environment. The electrode arrangements were determined based on the field utilization factor in order to consider two types of electric field distribution. Alternating current (AC) and negative lightning impulse (-LI) breakdown tests were performed. From these experiments, under an extremely non-uniform electric field, it was confirmed that the dielectric strength of C4F7N 5%/CO2 95% at high pressure was about 75% of the strength of SF6. In a weakly non-uniform electric field, increasing the C4F7N content contributed to the improvement of dielectric strength by 31-77% relative to pure CO2 at the high pressure. Furthermore, it was investigated that the presence of O2 had no significant influence on improving the insulation performance.

Published

2024

2. A Reliable Protection Scheme for Fast DC Fault Clearance in a VSC-Based Meshed MTDC Grid

Author

Rifat Ara, Umer Amir Khan, Aamir Iqbal Bhatti, and Bang Wook Lee

Subjects

MTDC grid, differential current protection, travelling wave-based fault location, fault detection, DC fault current limitation, faulty line isolation, Electrical engineering. Electronics. Nuclear engineering, TK1-9971

Abstract

A multi-terminal high voltage DC (MTDC) grid, is an optimum and cost-effective transmission network to minimize the energy crisis worldwide largely. However, the core demand for a fast DC protection scheme with an extraordinary strict fault clearance time of a few milliseconds, is a key research gap in this network, holding back its development and scalability. To bridge this gap, this paper proposes a novel protection scheme for a meshed MTDC grid. The main goals of the scheme include accurate discrimination of a faulty line, rapid fault detection, fault location estimation, significant fault current reduction, and fully selective isolation of only the faulted line, while continuing normal power flow in the healthy grid zones. Reliability of the scheme for long and extra-long-distance power transmission is increased by aiding the differential protection and Type-D traveling wave (TW)-based algorithms utilizing the distributed optical current sensing technology with the other auxiliary methods and backup plans. These auxiliary methods include independent discrete wavelet transform (DWT), current derivative polarity principles with a minimum sample (short time) window, overcurrent relays, and AC circuit breakers (ACCBs). A faulty segment of a transmission line is accurately discriminated from the healthy ones by measuring a series of multi-point differential currents on it. A faulty line at a particular DC node is accurately discriminated using the differential protection by measuring the current flowing into or out of each line from each side at every node to obtain the algebraic sum. The current sum of a real-time local transient data and a delayed remote data is compared to a preset threshold level. DC fault current is significantly reduced below the breakable levels by coordinating bidirectional hybrid DC circuit breakers (HDCCBs) with the active and passive fault current limiters (FCLs) and the half bridge-VSC-based modular multilevel converters (MMCs). The proposed concepts are successfully verified by the simulation results under a variety of fault scenarios and are found to be accurate.

Published

2020

3. Analysis of Transient Behavior of Mixed High Voltage DC Transmission Line Under Lightning Strikes

Author

Mansoor Asif, Ho-Yun Lee, Umer Amir Khan, Kyu-Hoon Park, and Bang Wook Lee

Subjects

DC cable, dielectric breakdown, HVDC transmission, insulation coordination, insulator flashover, lightning overvoltage, Electrical engineering. Electronics. Nuclear engineering, TK1-9971

Abstract

Growing urbanization coupled with increased power demands have led to increasing use of mixed power transmission lines with sections of overhead lines (OHL) and underground cables. Due to differences in surge impedance of cables and OHL, voltage surges experience reflections and refractions at their boundaries which make the transient behavior of mixed high voltage direct current (HVDC) line quite peculiar. Lightning strikes on overhead sections of lines induce voltage surges that travel along OHL and enter the cable section. Lightning overvoltage can cause OHL insulators to flashover and stress cable insulation or cause its permanent breakdown. In this paper, we simulated a fast front model of a mixed HVDC transmission line using an electromagnetic transient simulation program (PSCAD) to analyze its transient behavior under a lightning strike. The leader progression model has been used to predict the dielectric performance of OHL insulators. It has been shown that transition towers adjacent to the cable section are much less vulnerable to flashover than subsequent towers. The length of a riser section (connecting OHL and cable) and tower footing impedance have shown to significantly influence the flashover performance of OHL insulators. In addition, the length of cable segments and sheath grounding impedance has been found to influence cable overvoltage. This paper can be used to evaluate the insulation coordination and overvoltage protection requirements for a mixed HVDC transmission line.

Published

2019

4. Comparison of AC and DC Partial Discharge by Monitoring of Vacuum Degree in a Distribution Class Vacuum Interrupter

Author

Seungmin Bang, Hyun-Woo Lee, and Bang-Wook Lee

Subjects

AC, DC, distribution class, dielectric strength, partial discharge, PRPD, Electrical engineering. Electronics. Nuclear engineering, TK1-9971

Abstract

The vacuum degree of Vacuum Interrupter (VI) will deteriorate because of gases emitted by arc heat, and leakage through the joints. It is important to select an appropriate maintenance criteria for a VI by monitoring the vacuum degree. However, monitoring of a VI installed inside a solid insulation apparatus in a transmission system is impossible. Only studies on the insulation deterioration because of the decrease of the vacuum degree have been conducted, and important factors such as the maintenance criteria have not been investigated. Moreover, most studies have only been performed using AC voltage, not DC voltage. Therefore, in this paper, AC and DC partial discharge were compared by monitoring of the vacuum degree in a distribution class VI to propose maintenance criteria according to voltage type. Through this, for efficient maintenance, maintenance criteria of VI for each voltage type are presented. The vacuum degree at which the dielectric strength rapidly decreases was confirmed according to voltage type. The coupling capacitor was installed directly on the floating shield of VI. Moreover, to measure the pattern and apparent charge of partial discharge according to the vacuum degree, phase resolved partial discharge (PRPD) for AC partial discharge and pulse sequence analysis (PSA) for DC partial discharge were adopted. It is found that maintenance should be performed when the vacuum degree is in the range of $10^{-3} \boldsymbol {\sim } 10^{-2}$ torr regardless of the voltage type. Moreover, the usefulness of the technology is higher at AC voltage than at DC voltage.

Published

2022

5. Numerical Analysis of Electric Field Characteristics and Interfacial Pressure of HVDC XLPE Cable Joint Considering Load Cycles

Author

Sun-Jin Kim, Do-Gyu Lee, Jae-Hyung Kim, and Bang-Wook Lee

Subjects

HVDC cables, cable insulation, cable accessories, finite element analysis, interface pressure, elastic materials, Technology

Abstract

Recent innovations in HVDC extruded cable systems require the development of reliable and safe cable accessories. Cable accessories are made of several insulating materials and contain several interfaces. Interfaces made of different materials can cause electric field distortion and localized enhancement of the field. In addition, the internal temperature profiles of accessories differ depending on load conditions or installation environments, which may lead to an increase in or loss of interfacial pressure due to changes in the mechanical properties of materials. The loss of interfacial pressure degrades the contact state between materials. The micro voids formed due to pressure loss can cause partial discharge and tree, which in turn can lead to reduced lifespan and failure of the cable system. Therefore, it is necessary to study the electrical and mechanical characteristics of cable accessories considering various transient states. However, there is a limit to experimentally analyzing the actual structure. In this paper, electric field and mechanical stress for pre-molded cable joints were analyzed using an electrical model based on the conductivity of the material and a mechanical model based on elastic theory. Temperature fluctuations were simulated according to the sequence of the cable load cycle test, and time-varying electric fields and mechanical stresses were analyzed. From the simulation results, it was confirmed that the electric field and stress distribution in the joint continuously changed according to the heating and cooling periods. In addition, during the cooling cycle, the field strength at the interface near the conductor increased and the interface pressure decreased. In conclusion, it is important to ensure sufficient initial pressure so that the dielectric strength at the interface does not decrease even if there is a loss of interface pressure due to temperature fluctuations.

Published

2022

6. Surface Dielectric Characteristics of GFRP and PTFE in Cryogenic Environment Under the Switching Impulse Superimposed on DC Voltage

Author

Ho-Seung Kim, Dong-Hun Oh, and Bang-Wook Lee

Subjects

Electrical and Electronic Engineering, Condensed Matter Physics, Electronic, Optical and Magnetic Materials

Published

2022

7. Evaluation of Selection Criteria for the Level of Liquid Nitrogen in HTS Magnet System

Author

Seungmin Bang, Hyun-Woo Lee, Ho-Seung Kim, Jin-Yong Na, Ryul Hwang, and Bang-Wook Lee

Subjects

Electrical and Electronic Engineering, Condensed Matter Physics, Electronic, Optical and Magnetic Materials

Published

2022

8. Real-Time Monitoring of the Vacuum Degree Based on the Partial Discharge and an Insulation Supplement Design for a Distribution Class Vacuum Interrupter

Author

Seungmin Bang, Hyun-Woo Lee, and Bang-Wook Lee

Subjects

distribution class, dielectric strength, FEM, high-voltage apparatus, insulation design, partial discharge, Technology

Abstract

The internal pressure of a vacuum interrupter (VI) is increased by arc heat, ceramic cracking, gas leakage, and manufacturing defects. Accordingly, the dielectric strength of VI rapidly decreases. To improve the reliability of power transmission, efficient maintenance through the real-time monitoring of the vacuum degree is essential. However, real-time monitoring of the vacuum degree is difficult, and related research is scarce. Additionally, due to the insulation problems of this technology, there are few commercially available products. Therefore, this paper proposes a method for real-time monitoring of the vacuum degree and an insulation supplement design for a distribution class VI. First, dielectric experiments were conducted to identify the section in which the dielectric strength of the VI rapidly decreased according to the vacuum degree. Second, for real-time monitoring of the VI, several factors were proposed through the partial discharge in the VI, while the capacitance characteristics of the VI were calculated to improve the signal of the internal partial discharge. Finally, to supplement the dielectric problems of the solid insulation high voltage apparatus that occur when real-time monitoring technology is applied, the insulation supplement design was performed through the finite element method (FEM).

Published

2021

9. Calculation Method of Allowable Continuous Current for Direct Burial Laying HVDC Underground Cable

Author

Kyu-hoon Park, Il Kwon, and Bang-wook Lee

Subjects

allowable current, HVDC underground cable, direct burial laying, thermal resistance, Technology

Abstract

The calculation of the continuous allowable current of an underground cable is determined by various characteristics. To calculate the allowable current in cables with alternating magnetic fields such as AC, special phenomena such as the proximity effect and skin effect must be applied. However, there are no standards or research related to the calculation of the continuous allowable current of a DC power cable that does not have an alternating magnetic field. In this paper, a quantitative DC cable continuous allowable current calculation formula of direct burial laying was derived by applying the existing AC cable continuous allowable current calculation method to the DC system. We developed a calculation tool that can calculate the continuous allowable current of DC cables using the derived formula. Assuming the cable conditions (cable specification, laying conditions, soil characteristics, arrangement, and number of strands, etc.), a continuous allowable current simulation of DC cables was performed. In addition, the level of contribution to the continuous allowable current value was analyzed by classifying the parameter categories into major and minor factors in the order of influence on the allowable current among the determined calculated parameters. As a result, the effectiveness of the DC cable continuous allowable current calculation tool derived by performing the allowable current calculation simulation was evaluated, and the allowable current calculation method of the HVDC cable was established.

Published

2021

10. A Study of Fast Front Transients of an HVDC Mixed Transmission Line Exposed to Bipolar Lightning Strokes

Author

Ayesha Shakeel, Kyu-Hoon Park, Koo-Yong Shin, and Bang-wook Lee

Subjects

backflashover, bipolar lightning strokes, fast front transients, OHL-cable mixed HVDC transmission, PSCAD/EMTDC, shielding failure, Technology

Abstract

Bipolar lightning strokes are associated with multiple polarity electrical discharge with no current intervals in between, making their behavior quite peculiar. This work presents a fast front analysis of a mixed high voltage direct current (HVDC) transmission link, evaluating the factors that influence the line transients due to shielding failures and backflashovers (BFOs), considering both overvoltage and repeated polarity reversal at the cable sending terminal. The research process includes a detailed modeling of a bipolar lightning stroke, frequency-dependent HVDC overhead, and underground transmission line sections. Noticeable findings include the occurrence of only a positive polarity insulator BFO for the adjacent and subsequent tower, despite the dual polarity of the lightning stroke with relatively small values for the lightning parameters. The influence of traveling waves on the insulator flashover performance of the line with varying parameters (such as the riser section length, the tower grounding impedance, and the location of the lightning stroke) is recorded and explained.

Published

2021

11. A Novel Diagnosis Method for Void Defects in HVDC Mass-Impregnated PPLP Cable Based on Partial Discharge Measurement

Author

Dong-Hun Oh, Ho-Seung Kim, and Bang-Wook Lee

Subjects

HVDC MI-PPLP cable, DC void discharge, insulation aging, PSA, pattern analysis, insulation diagnosis, Technology

Abstract

Mass Impregnated PPLP cable, which is applied to various high-voltage direct current (HVDC) projects due to its excellent dielectric and temperature properties, has a problem wherein voids are formed inside the butt-gap due to cavitation. However, there has been no previous research into technology for void defect identification and insulation diagnosis on HVDC MI-PPLP cables. In this paper, to propose an insulation diagnosis method for void defects in HVDC MI-PPLP cable, the direct current (DC) void discharge patterns were analyzed according to the specimen temperature and the magnitude of applied voltage using the pulse sequence analysis method. In addition, to confirm the pre-symptoms of dielectric breakdown in MI-PPLP cable due to DC void discharge, partial discharge patterns were analyzed continuously until dielectric breakdown occurred. From the experimental results, DC void discharge patterns of the same shape were obtained regardless of the specimen temperature and the magnitude of applied voltage. In addition, it was confirmed that new insulation aging patterns were generated as electrical and thermal aging occurred due to the continuous DC void discharge. Therefore, it is demonstrated that identification and insulation diagnosis of void defects in HVDC MI-PPLP cable is possible through the obtained DC void discharge and insulation aging patterns.

Published

2021

12. Consideration of the Insulation Design Method on a ±200 kV Converter Valve Unit in an HVDC Converter Hall

Author

Seungmin Bang, Ho-Seung Kim, Jae-Hong Koo, and Bang-Wook Lee

Subjects

HVDC, converter valve, air clearance, overvoltage, flashover, triple point, Technology

Abstract

A converter valve unit, which converts Alternating Current (AC) to Directing Current (DC) and DC to AC, is one of the key elements of high voltage direct current (HVDC) transmission. The insulation design of a converter valve unit should be considered for air clearance according to the DC superimposed overvoltage and the insulator that maintains the insulation performance and the corona shield to suppress DC corona discharge. There is no prescribed standard for the insulation design of a converter valve unit. Moreover, insulation performance under an applied DC voltage has not yet been thoroughly investigated. Therefore, it is necessary to study the insulation design method of the converter valve unit. In this paper, consideration of the insulation design method on a ±200 kV converter valve unit in an HVDC converter hall is performed. The finite element method (FEM) is used to simulate the 3D model. Additionally, the safety factor (SF) is applied in accordance with the dielectric test in IEC 62271-1. As a result, an insulation design process on the converter valve unit is proposed and the insulation design is carried through the design factors. It is confirmed that design factors on the air clearance, insulator and corona shield have a significant effect on a highly reliable insulation design.

Published

2021

13. Characteristics of Gel Time and Dielectric Strength of Epoxy Composite According to the Mixing Ratio of Micro-Fillers

Author

Dong-Hun Oh, Ho-Seung Kim, Jae-Hun Shim, Young-Ho Jeon, Da-Won Kang, and Bang-Wook Lee

Subjects

epoxy composite, MICRO-filler, SiO2, Al2O3, mixing ratio, gel time, Technology

Abstract

The dielectric strength and gel time of epoxy composites vary with the mixing ratio of epoxy resin, hardener, additives, filler, etc., and especially the gel time affects the productivity and economics of ultra-high-voltage (UHV) equipment. However, previous studies focused only on the dielectric strength of epoxy composites for the reliability of UHV equipment. Therefore, a study considering both the dielectric strength and gel time of the epoxy composite is required. In this paper, the characteristics of the gel time and dielectric strength of the epoxy micro-composites according to the mixing ratio of silica (SiO2) and alumina (Al2O3) micro-fillers without changing the mixing ratio of epoxy resin and hardener are analyzed. Experimental results show that the gel time decreased and the dielectric strength increased as the mixing ratio of the SiO2 micro-filler increased. Therefore, it is concluded that the gel time can be controlled by changing the mixing ratio of micro-fillers without changing the mixing ratio of the epoxy resin and hardener. In addition, experimental data can be used as basic data for economical production considering both the reliability and productivity of UHV power equipment.

Published

2020

14. Numerical Analysis of Space Charge Behavior and Transient Electric Field under Polarity Reversal of HVDC Extruded Cable

Author

Sun-Jin Kim and Bang-Wook Lee

Subjects

bipolar charge transport model, voltage polarity reversal, space charge behavior, cable insulation, dielectrics, Technology

Abstract

The superimposed transient electric field generated by polarity reversal causes severe stress to the high-voltage direct current (HVDC) cable insulation. Especially for polymeric insulation materials, space charge accumulation is prominent, which strengthens local electric field intensity. In order to avoid the risk of dielectric breakdown resulting from an intensified electric field caused by space charge behavior, several numerical analyses have been conducted using the Bipolar Charge Transport (BCT) model. However, these studies have only considered a unidirectional electric field assuming only steady state operating conditions, and there are few works that have analyzed space charge behavior during transient states, especially for the polarity reversal period. In order to analyze the charge behavior under polarity reversal, it is necessary to establish the boundary condition considering the direction and intensity of the field. Therefore, in this paper, we proposed a modified model connecting the steady state to the polarity reversal state, and the transient electric field was investigated depending on the electric potential zero duration. Since space charge behavior is influenced by temperature, different load currents were considered. From the simulation results, it was observed that the capacitive field was dominant on the electric field distribution during the polarity reversal. In addition, the long electric potential zero duration and high load currents could contribute to form a homo-charge at the conductor within the time of polarity reversal, resulting in a noticeable decrease in the maximum electric field intensity.

Published

2020

15. Experimental Assessment on Air Clearance of Multiple Valve Unit Considering Switching Impulse and DC Superimposed Switching Impulse

Author

Jae-Hong Koo, Jae-Kyu Seong, Ryul Hwang, and Bang-Wook Lee

Subjects

air clearance, critical flashover voltage, DC, DC pre-stress, dielectric characteristics, HVDC, Technology

Abstract

Multiple valve unit (MVU), which converts AC to DC and DC to AC, is one of the key elements of high voltage DC (HVDC) transmission. Therefore, the insulation design of MVU against overvoltage should be considered for the stable and reliable operation of HVDC transmission system. Especially, the air clearance of MVU should be calculated based the switching impulse, since it is fatal to MVU in terms of electrical insulation. However, the previous studies were limited to wave front, and the air clearance of the switching impulse is specified only for an ultra-high voltage (UHV) above 750 kV. As a result, it is difficult to calculate the air clearance of MVU which must endure for a switching impulse under 750 kV. In addition, when the switching impulse introduced while the MVU is in normal operation, it is superimposed to DC and creates the most severe situation, but the studies on such subjects are also insufficient. Therefore, as a fundamental step to calculate the air clearance of MVU, the dielectric characteristics of switching impulse and DC superimposed switching impulse in air have been investigated. The experiments on switching impulse showed that the critical flashover voltage was varied according to the curvature of electrode in the gap distance, up to eight times of the electrode radius. However, beyond that gap distance, the critical flashover voltage became similar, regardless of the radius of electrodes. In case of the superimposed experiment, it was performed according to DC pre-stress level and the polarities of switching impulse. The results were most severe when the positive switching impulse was superimposed on the positive DC, and the peak voltage at which flashover occurs was independent of DC pre-stress.

Published

2020

16. Comparison of DC PDIV and BDV of GIS defects between SF6 gas and C4F7N/CO2 gas mixture

Author

Hyeon-Su Song, Ho-Seung Kim, and Bang-Wook Lee

Published

2022

17. Evaluation of mechanical and chemical chacteristics of 6.6 kV AC XLPE cable according to thermal aging

Author

Ho-Seung Kim, Hyeon-Su Song, and Bang-Wook Lee

Published

2022

18. Assessment of Overvoltage and Insulation Coordination in Mixed HVDC Transmission Lines Exposed to Lightning Strikes

Author

Mansoor Asif, Ho-Yun Lee, Kyu-Hoon Park, Ayesha Shakeel, and Bang-Wook Lee

Subjects

cable overvoltage, dc transmission, dielectric breakdown, electromagnetic transient simulation, high voltage, insulation coordination, negative lightning strikes, Technology

Abstract

Many geographical constraints and aesthetic concerns necessitate the partial use of cable sections in the High Voltage DC (HVDC) transmission line, resulting in a mixed transmission line. The overhead sections of mixed lines are exposed to lightning strikes. The lightning strikes can not only result in flashover of overhead line (OHL) insulators but can enter the cable and permanently damage its insulation if adequate insulation coordination measures are not taken. In this work, we have analyzed the factors that affect the level of overvoltage inside the cable by simulating a fast front model in PSCAD. It has been determined that surge arresters must be provided at cable terminals when the length of cable sections is less than 16 km to limit the core-ground overvoltage within the lightning impulse protective level (LIPL). The level of sheath-ground overvoltage is independent of the length of cable; however, it can be limited within LIPL by lowering the sheath grounding impedance to 1.2 Ω. Insulation coordination measures do not impact the likelihood of OHL insulators’ flashover. The flashover performance of OHL can be improved by lowering the footing impedance of the second tower closest to the cable terminals, which is otherwise most likely to flashover.

Published

2019

19. Accurate Evaluation of Steady-State Sheath Voltage and Current in HVDC Cable Using Electromagnetic Transient Simulation

Author

Mansoor Asif, Ho-Yun Lee, Kyu-Hoon Park, and Bang-Wook Lee

Subjects

dc error, high voltage dc (hvdc) cable, pscad/emtdc, sheath grounding scheme, sheath loss calculation, sheath voltage calculation, universal line model (ulm), Technology

Abstract

The current and voltage in High Voltage DC (HVDC) line is not pure DC but contain superimposed ripple components. The current ripple in core of HVDC cable magnetically induces a voltage in the sheath, whereas the voltage ripple causes the flow of charging current from core to sheath. The knowledge of sheath voltage is necessary to ensure compliance with the specification of utility companies. In this work, we have reported that the models available in commercial Electromagnetic Transient (EMT) simulation software erroneously introduce a DC bias in steady-state sheath voltage and sheath current. We have also demonstrated that by removing the DC bias accurate steady-state evaluation of sheath voltage and sheath current is possible. Additionally, we have analyzed the sheath voltage and currents in HVDC cable considering different cable lengths and sheath grounding schemes. It has been found that grounding the sheath at the terminal of HVDC cable can limit the sheath voltage to acceptable levels without causing substantial joule loss in the sheath.

Published

2019

20. Appropriate Protection Scheme for DC Grid Based on the Half Bridge Modular Multilevel Converter System

Author

Ho-Yun Lee, Mansoor Asif, Kyu-Hoon Park, Hyun-Min Mun, and Bang-Wook Lee

Subjects

half bridge (HB), resistive SFCL (R-SFCL), saturated iron core SFCL (SI-SFCL), hybrid SFCL (Hybrid-SFCL), DC circuit breaker (DCCB), Technology

Abstract

The half bridge (HB) modular multilevel converter (MMC) technology is considered a breakthrough to mitigate the shortcomings of the conventional voltage source converter (VSC) in high-voltage direct-current (HVDC) grid application. However, interruption of the DC fault is still a challenge due to fast di/dt and extremely high levels of DC fault current. The fault interruption using a DC circuit breaker (DCCB) causes enormous energy dissipation and voltage stress across the DCCB. Therefore, the use of a fault current limiter is essential, and the superconducting fault current limiter (SFCL) is the most promising choice. Past literature has focused on the operating characteristics of DCCB or limiting characteristics of the SFCL. However, there is little understanding about the fault interruption and system recovery characteristics considering both DCCB and SFCL. In this paper, we have presented a comparative study on fault interruption and system recovery characteristics considering three types of fault limiting devices in combination with circuit breaker. The transient analyses of AC and DC system have been performed, to suggest the most preferable protection scheme. It has been concluded that, amongst the three fault limiting devices, the Hybrid SFCL in combination with circuit breaker, delivers the most desirable performance in terms of interruption time, recovery time, energy dissipation and voltage transients.

Published

2019

21. Evaluation of Electric Field and Space Charge Dynamics in Dielectric under DC Voltage with Superimposed Switching Impulse

Author

Ik-Soo Kwon, Sun-Jin Kim, Mansoor Asif, and Bang-Wook Lee

Subjects

bipolar charge transport model, DC electric field, space charge dynamics, switching impulse superposition, Technology

Abstract

The influx of a switching impulse during DC steady-state operations causes severe electrical stress on the insulation of HVDC cables. Thus, the insulation should be designed to withstand a superimposed switching impulse. All major manufacturers of DC cables perform superimposed switching impulse breakdown tests for prequalification. However, an experimental approach to study space charge dynamics in dielectrics under a switching impulse superposed on DC voltage has not been reported yet. This is because, unlike the DC stress, it is not possible to study the charge dynamics experimentally under complex stresses, such as switching impulse superposition. Hence, in order to predict and investigate the breakdown characteristics, it is necessary to obtain accurate electric field distribution considering space charge dynamics using a numerical approach. Therefore, in this paper, a numerical study on the switching impulse superposition was carried out. The space charge dynamics and its distribution within the dielectric under DC stress were compared with those under a superimposed switching impulse using a bipolar charge transport (BCT) model. In addition, we estimated the effect of a superimposed switching impulse on a DC electric field distribution. It was concluded that the temperature conditions of dielectrics have a significant influence on electric field and space charge dynamics.

Published

2019

22. Fault Protection Strategy for Multi-Terminal HVDC System by use of DC Circuit Breaker

Author

Jong Geon Lee, Hyung Jun Ju, Ki Sun Han, Ji Won Kang, and Bang-Wook Lee

Published

2022

23. Dielectric Breakdown Characteristics of Oil Impregnated Pressboard according to Frequency Change under AC-DC Combined Voltage

Author

Ho-Seung Kim, Dong-Hun Oh, Hyun-Su Song, Seungmin Bang, and Bang-Wook Lee

Published

2022

24. The Analysis on the Dielectric Breakdown Characteristics of Epoxy resin for the Compact of High Voltage Apparatus

Author

Seungmin Bang, Hyun-Woo Lee, Ho-Seung Kim, and Bang-Wook Lee

Published

2022

25. Evaluation of black-box arc model for DC circuit breaker and comparative analysis of arc characteristic parameters

Author

Kyu-Hoon Park, Il Kwon, Yu-Jin Kwak, and Bang-wook Lee

Published

2022

26. Simulation of Space Charge Accumulation and Transient Electric Field within Polymeric Dielectric under Polarity Reversal

Author

Sun-Jin Kim and Bang-Wook Lee

Published

2022

27. Development of Partial Discharge Analysis Model by Void in Solid Insulation Using Nonlinear Characteristics of Black-box Arc Model

Author

Ki-Sun Han, Jong-Geon Lee, Kyu-Hoon Park, Bang-Wook Lee, and Hyung-Jun Ju

Subjects

Nonlinear system, Void (astronomy), Materials science, Arc model, Partial discharge analysis, Solid insulation, Mechanics, Electrical and Electronic Engineering

Published

2020

28. Novel Diagnostic Method of DC Void Discharge in High Temperature Superconducting Cable Based on Pulse Sequence Analysis

Author

Dong-Hun Oh, Ho-Seung Kim, and Bang-Wook Lee

Subjects

Void (astronomy), Diagnostic methods, Materials science, Fabrication, Dielectric strength, Partial discharge, High temperature superconducting, Pulse sequence, Electrical and Electronic Engineering, Composite material, Condensed Matter Physics, Electronic, Optical and Magnetic Materials, Voltage

Abstract

In a high voltage dc (HVDC) high temperature superconducting (HTS) cable composed of polypropylene laminated paper (PPLP), butt-gaps are unavoidable during fabrication, which may lead to formation of voids. When dc voltage higher than partial discharge inception voltage (PDIV) is applied, partial discharge occurs in the void. If void discharge sustains, the electrical ageing of PPLP accelerates, and eventually dielectric breakdown may occur due to the lowering of dielectric strength. Thus, for timely maintenance and repair of HVDC HTS cable, identification technology for void defects is required. However, there is no previous research and technologies for defect identification and insulation diagnosis on HVDC HTS cables. Therefore, in this paper, in order to suggest the insulation diagnosis method for void defects of the HVDC HTS cable based on the pulse sequence analysis (PSA) method, void discharges were measured according to the size of void and magnitude of applied voltage. Also, patterns of the void discharge were obtained using PSA methods and PYTHON program. Experimental results indicate that, although the magnitude, time difference and repetition rate of partial discharge are different depending on the configuration of the void and the applied voltage, but the patterns of void discharge are consistent. Therefore, it is considered that identification and insulation diagnosis for void defects in HVDC HTS cable is possible through the obtained DC void partial discharge patterns.

Published

2020

29. A Reliable Protection Scheme for Fast DC Fault Clearance in a VSC-Based Meshed MTDC Grid

Author

Aamer Iqbal Bhatti, Umer Amir Khan, Bang-Wook Lee, and Rifat Ara

Subjects

Power transmission, General Computer Science, Computer science, 020209 energy, 020208 electrical & electronic engineering, General Engineering, High voltage, 02 engineering and technology, MTDC grid, Fault (power engineering), Grid, fault detection, DC fault current limitation, Fault detection and isolation, differential current protection, Overcurrent, travelling wave-based fault location, Transmission line, Control theory, 0202 electrical engineering, electronic engineering, information engineering, General Materials Science, Node (circuits), lcsh:Electrical engineering. Electronics. Nuclear engineering, lcsh:TK1-9971, faulty line isolation

Abstract

A multi-terminal high voltage DC (MTDC) grid, is an optimum and cost-effective transmission network to minimize the energy crisis worldwide largely. However, the core demand for a fast DC protection scheme with an extraordinary strict fault clearance time of a few milliseconds, is a key research gap in this network, holding back its development and scalability. To bridge this gap, this paper proposes a novel protection scheme for a meshed MTDC grid. The main goals of the scheme include accurate discrimination of a faulty line, rapid fault detection, fault location estimation, significant fault current reduction, and fully selective isolation of only the faulted line, while continuing normal power flow in the healthy grid zones. Reliability of the scheme for long and extra-long-distance power transmission is increased by aiding the differential protection and Type-D traveling wave (TW)-based algorithms utilizing the distributed optical current sensing technology with the other auxiliary methods and backup plans. These auxiliary methods include independent discrete wavelet transform (DWT), current derivative polarity principles with a minimum sample (short time) window, overcurrent relays, and AC circuit breakers (ACCBs). A faulty segment of a transmission line is accurately discriminated from the healthy ones by measuring a series of multi-point differential currents on it. A faulty line at a particular DC node is accurately discriminated using the differential protection by measuring the current flowing into or out of each line from each side at every node to obtain the algebraic sum. The current sum of a real-time local transient data and a delayed remote data is compared to a preset threshold level. DC fault current is significantly reduced below the breakable levels by coordinating bidirectional hybrid DC circuit breakers (HDCCBs) with the active and passive fault current limiters (FCLs) and the half bridge-VSC-based modular multilevel converters (MMCs). The proposed concepts are successfully verified by the simulation results under a variety of fault scenarios and are found to be accurate.

Published

2020

30. Assessment of Appropriate MMC Topology Considering DC Fault Handling Performance of Fault Protection Devices

Author

Ho-Yun Lee, Mansoor Asif, Kyu-Hoon Park, and Bang-Wook Lee

Subjects

half bridge (HB), full bridge (FB), modular multilevel converter (MMC), hybrid HVDC breaker (HCB), Technology, Engineering (General). Civil engineering (General), TA1-2040, Biology (General), QH301-705.5, Physics, QC1-999, Chemistry, QD1-999

Abstract

The eventual goal of high-voltage direct-voltage (HVDC) systems is to implement HVDC grids. The modular multilevel converter (MMC) has been identified as the best candidate for the realization of an HVDC grid by eliminating the shortcomings of conventional voltage source converter (VSC) technology. The related research has focused on efficient control schemes, new MMC topologies, and operational characteristics of an MMC in a DC grid, but there is little understanding about the fault handling capability of two mainstream MMC topologies, i.e., half bridge (HB) and full bridge (FB) MMCs in combination with an adequate protection device. Contrary to the existing research where the fault location is usually fixed (center of the line), this paper considered a variable fault location on the DC line, so as to compare the fault interruption time and maximum fault current magnitude. From the point of view of fault interruption, AC and DC side transient analyses were performed for both MMC topologies to suggest the appropriate topology. The simulation result confirmed that the fault handling performance of an HB-MMC with a DC circuit breaker is superior due to the smaller fault current magnitude, faster interruption time, lower overvoltage magnitude, and lesser stresses on the insulation of the DC grid.

Published

2018

31. Calculation Method of Allowable Continuous Current for Direct Burial Laying HVDC Underground Cable

Author

Bang-Wook Lee, Kyu-Hoon Park, and Il Kwon

Subjects

Technology, Control and Optimization, Renewable Energy, Sustainability and the Environment, business.industry, direct burial laying, Thermal resistance, thermal resistance, Energy Engineering and Power Technology, Structural engineering, Laying, Magnetic field, allowable current, HVDC underground cable, Environmental science, Power cable, Skin effect, Electrical and Electronic Engineering, Current (fluid), Proximity effect (electromagnetism), business, Continuous current, Engineering (miscellaneous), Energy (miscellaneous)

Abstract

The calculation of the continuous allowable current of an underground cable is determined by various characteristics. To calculate the allowable current in cables with alternating magnetic fields such as AC, special phenomena such as the proximity effect and skin effect must be applied. However, there are no standards or research related to the calculation of the continuous allowable current of a DC power cable that does not have an alternating magnetic field. In this paper, a quantitative DC cable continuous allowable current calculation formula of direct burial laying was derived by applying the existing AC cable continuous allowable current calculation method to the DC system. We developed a calculation tool that can calculate the continuous allowable current of DC cables using the derived formula. Assuming the cable conditions (cable specification, laying conditions, soil characteristics, arrangement, and number of strands, etc.), a continuous allowable current simulation of DC cables was performed. In addition, the level of contribution to the continuous allowable current value was analyzed by classifying the parameter categories into major and minor factors in the order of influence on the allowable current among the determined calculated parameters. As a result, the effectiveness of the DC cable continuous allowable current calculation tool derived by performing the allowable current calculation simulation was evaluated, and the allowable current calculation method of the HVDC cable was established.

Published

2021

32. Surface Flashover Characteristics of Ribbed Insulator in Cryogenic Environment

Author

Ryul Hwang, Jae-Hong Koo, Jin-Yong Na, Bang-Wook Lee, and Dong-Hun Oh

Subjects

Materials science, Arc flash, Insulator (electricity), Electrical and Electronic Engineering, Composite material, Condensed Matter Physics, Electronic, Optical and Magnetic Materials

Published

2019

33. Assessment of appropriate SFCL type considering DC fault interruption in full bridge modular multilevel converter HVDC system

Author

Bang-Wook Lee, Mansoor Asif, Kyu-Hoon Park, and Ho-Yun Lee

Subjects

010302 applied physics, business.industry, Computer science, Electrical engineering, Energy Engineering and Power Technology, Topology (electrical circuits), Modular design, Condensed Matter Physics, Fault (power engineering), Grid, 01 natural sciences, Electronic, Optical and Magnetic Materials, Current limiting, Magnetic core, 0103 physical sciences, Fault current limiter, Voltage source, Electrical and Electronic Engineering, 010306 general physics, business

Abstract

The modular multilevel converter (MMC) is the most promising converter topology for implementations of voltage source converter (VSC) high-voltage direct-current (HVDC) grid. Existing research has focused on operational characteristics and improvement of efficiency by optimizing the control. Among various MMC topologies, a full bridge (FB) sub-module (SM) MMC with fault interruption capability has attracted attention because it does not require a dc circuit breaker. However, the most severe faults on dc line, can cause steeply rising fault currents with high peak magnitude, but there is a lack of literature regarding fault current reduction in FB-MMC systems. This problem can be overcome by applying the fault current limiter (FCL) and the superconducting fault current limiters (SFCLs), which have already been developed for the ac grid, have been considered in this paper. We have verified the applicability of two well-known SFCL types i.e., resistive SFCL (R-SFCL) and saturated iron core type SFCL (SIC-SFCL) in FB-MMC grid. Current limiting characteristics and energy dissipation has been according to the location of fault on dc line has been studied. We compared the merits and demerits of the aforementioned SFCLs based on the simulation results. The results indicate, SIC-SFCL to be the most suitable fault current limiter for FB-MMC HVDC system application. © 2001 Elsevier Science. All rights reserved

Published

2019

34. Simulation of DC Electric Fields on the Layer Structure of PPLP for Butt-Gap Conditions in HVDC MI-PPLP Cable

Author

Chae-Kyun Jung, Jae-Sang Hwang, Bang-Wook Lee, and Ik-Soo Kwon

Subjects

010302 applied physics, Polarity reversal, Steady state, Materials science, Electric field, 0103 physical sciences, Thermal, Mechanics, Dielectric, Electrical and Electronic Engineering, 010306 general physics, 01 natural sciences, Layer (electronics)

Abstract

The electric and thermal properties of HVDC MI-PPLP cable have recently been improved such as dielectric performance and maximum allowable temperature. However, its dc electric field characteristics have not been fully investigated. As a lapped cable, its main insulating material is PPLP, which has a special composition of Kraft-PP film-Kraft. This prevents conventional dc electric field analysis for the bulk type model from being directly applied to HVDC MI-PPLP cable. Therefore, the layer structure should be considered for HVDC MI-PPLP cable. In this paper, we focused on the difference in the dc electric field properties between the bulk and layer type model, which were determined at a steady state and polarity reversal. In order to determine the difference in the number of the butt-gap, single and double butt-gaps were simulated and compared in terms of the butt-gap conditions. Particularly for the double butt-gap, it was possible to investigate the effects of size, position, and formations using dc electric field simulation. Based on the dc electric field analysis, meaningful information about the butt-gap characteristics of HVDC MI-PPLP cables was obtained.

Published

2019

35. Influence of Placement of Overhead Ground Wires on Steady State Induction in AC-DC Hybrid Transmission Corridor

Author

Mansoor Asif, Ho-Yun Lee, Bang-Wook Lee, and Kyu-Hoon Park

Subjects

Steady state (electronics), Computer science, business.industry, 020209 energy, Electrical engineering, Energy Engineering and Power Technology, 02 engineering and technology, Electric power transmission, Transmission (telecommunications), Transmission line, 0202 electrical engineering, electronic engineering, information engineering, Overhead (computing), Transient (oscillation), Electrical and Electronic Engineering, business, Electronic circuit, Voltage

Abstract

To meet the growing power demand of the future, utilities and researchers have considered the addition of dc circuits in existing transmission corridors. The previous research has focused on analyzing the field environment, steady state induction and the negative effects of induction in the hybrid transmission lines. The overhead ground wires (OHGWs) have been used only for improving the lightning performance of overhead lines (OHL). In this paper, the spatial position of OHGWs has been studied with the objective of minimizing the steady state induction between power conductors as well as poorly grounded metallic objects like railroads and fences present near the ac-dc OHL. Candidate space for placement of OHGWs having shielding failure rate of less than four is identified using the conventional electro-geometric model. The steady state induction in the power conductors and nearby metallic objects is studied as a function of position of OHGWs using electro-magnetic transient simulation. The results indicate a strong correlation between the height of OHGWs and magnitude of induced voltage in power conductors, and metallic objects underneath the transmission line. The conscious effort in placement of OHGWs can reduce the magnitude of induced voltages while ensuring adequate lightning performance.

Published

2018

36. Improvement of recovery characteristics of a flux-lock type SFCL using a superconductor's trigger

Author

Sung-Hun Lim, Jae-Chul Kim, and Bang-Wook Lee

Subjects

High temperature superconductors -- Usage, Magnetic flux -- Measurement, Superconducting magnets -- Design and construction, Electrical cables -- Fault location, Electrical cables -- Methods, Business, Electronics, Electronics and electrical industries

Published

2010

37. Thermal analysis of PCS for an HTS pancake coil in persistent current mode

Author

Woo-Seok Kim, Yungil Kim, Sang-Ho Park, Seyeon Lee, Ji-Kwang Lee, Chan Park, Bang-Wook Lee, Kyoung-Jun Kim, Haigun Lee, Hee-Gyoun Lee, Gye-Won Hong, and Kyeongdal Choi

Subjects

Barium compounds -- Magnetic properties, Barium compounds -- Thermal properties, Barium compounds -- Electric properties, Copper oxide superconductors -- Magnetic properties, Copper oxide superconductors -- Thermal properties, Copper oxide superconductors -- Electric properties, High temperature superconductors -- Analysis, Yttrium -- Magnetic properties, Yttrium -- Electric properties, Yttrium -- Thermal properties, Business, Electronics, Electronics and electrical industries

Published

2010

38. Hybrid superconducting fault current limiter of the first half cycle non-limiting type

Author

Gyeong-Ho Lee, Kwon-Bae Park, Jungwook Sim, Young-Geun Kim, Il-Sung Oh, Ok-Bae Hyun, and Bang-Wook Lee

Subjects

Electric fault location -- Analysis, Electric resistance -- Evaluation, Superconductive devices -- Design and construction, Business, Electronics, Electronics and electrical industries

Published

2009

39. A compact cryocooling system with subcooled liquid nitrogen for small HTS magnets

Author

Ho-Myung Chang, Min-Jee Kim, Jung Wook Sim, Bang-Wook Lee, and Il-Sung Oh

Subjects

Liquid nitrogen -- Usage, Superconducting magnets -- Design and construction, Superconducting magnets -- Thermal properties, Business, Electronics, Electronics and electrical industries

Abstract

A compact cryogenic cooling system is developed for small high temperature superconductor (HTS) magnets that are continuously refrigerated in subcooled liquid nitrogen at temperatures below 77 K by a cryocooler. A prototype is fabricated and it has shown that the thermal load is effectively removed and temperature is spatially uniform.

Published

2008

40. Relation between DC PDIV and DC BDV of Mass Impregnated Polypropylene Laminated Paper Considering the Thermal Aging Characteristics

Author

Yong-Rok Kim, Dong-Hun Oh, Ho-Seung Kim, and Bang-Wook Lee

Subjects

Permittivity, Arrhenius equation, Void (astronomy), Materials science, Dielectric strength, 0211 other engineering and technologies, 02 engineering and technology, Activation energy, 021001 nanoscience & nanotechnology, Accelerated aging, symbols.namesake, Partial discharge, symbols, Breakdown voltage, 021108 energy, Composite material, 0210 nano-technology

Abstract

Thermal aging of HVDC Mass Impregnated Polypropylene Laminated Paper (MI-PPLP) cable could reduce the dielectric strength. And degradation of the physical and chemical properties of MI-PPLP could be caused by partial discharge in voids created by cavitation phenomenon. If void discharge is maintained, electrical aging is accelerated at the interface between air void and MI-PPLP, and ultimately dielectric breakdown occurs. There are several reports on the dielectric breakdown and partial discharge characteristics for insulation diagnosis of HVDC MI-PPLP cable. However, studies on the dielectric breakdown and partial discharge characteristics of HVDC MI-PPLP cables considering the thermal aging are insufficient. Therefore, in this paper, breakdown voltage (BDV) and partial discharge inception voltage (PDIV) characteristics are analyzed under the influence of the thermal aging of void defects. since it takes a lot of time to evaluate the insulation performance of MI-PPLP due to thermal aging under normal operating conditions, the thermal aging process was shortened through accelerated aging at 120°C. For reliable experiments, the equivalent lifetime between accelerated aging and normal operating conditions was suggested using the Arrhenius model. Since the Arrhenius model shows the reaction rate according to the activation energy of the specimen, the equivalent lifetime must be derived from the activation energy. The activation energy can be derived by applying the Kissinger method to thermos gravimetric analysis (TGA). From the experimental results, As the thermal aging of MI-PPLP proceeded, decrease in BDV is more severe than PDIV due to the increased Permittivity. Consequently, it is considered that relation between BDV and PDIV characteristics due to thermal aging can be estimated based on the equivalent lifetime obtained through the Arrhenius model.

Published

2020

41. Characteristics of Gel Time and Dielectric Strength of Epoxy Composite According to the Mixing Ratio of Micro-Fillers

Author

Bang-Wook Lee, Dong-Hun Oh, Young-Ho Jeon, Jae-Hun Shim, Ho-Seung Kim, and Da-Won Kang

Subjects

Control and Optimization, Materials science, Gel time, Composite number, Energy Engineering and Power Technology, engineering.material, gel time, 01 natural sciences, lcsh:Technology, mixing ratio, Filler (materials), epoxy composite, SiO2, 0103 physical sciences, Mixing ratio, MICRO-filler, Electrical and Electronic Engineering, Composite material, Al2O3, dielectric strength, Engineering (miscellaneous), Power equipment, 010302 applied physics, Dielectric strength, 010405 organic chemistry, Renewable Energy, Sustainability and the Environment, lcsh:T, Epoxy, 0104 chemical sciences, visual_art, engineering, visual_art.visual_art_medium, Energy (miscellaneous)

Abstract

The dielectric strength and gel time of epoxy composites vary with the mixing ratio of epoxy resin, hardener, additives, filler, etc., and especially the gel time affects the productivity and economics of ultra-high-voltage (UHV) equipment. However, previous studies focused only on the dielectric strength of epoxy composites for the reliability of UHV equipment. Therefore, a study considering both the dielectric strength and gel time of the epoxy composite is required. In this paper, the characteristics of the gel time and dielectric strength of the epoxy micro-composites according to the mixing ratio of silica (SiO2) and alumina (Al2O3) micro-fillers without changing the mixing ratio of epoxy resin and hardener are analyzed. Experimental results show that the gel time decreased and the dielectric strength increased as the mixing ratio of the SiO2 micro-filler increased. Therefore, it is concluded that the gel time can be controlled by changing the mixing ratio of micro-fillers without changing the mixing ratio of the epoxy resin and hardener. In addition, experimental data can be used as basic data for economical production considering both the reliability and productivity of UHV power equipment.

Published

2020

42. Feasible Application Study of Several Types of Superconducting Fault Current Limiters in HVDC Grids

Author

Kyu-Hoon Park, Bang-Wook Lee, Mansoor Asif, and Ho-Yun Lee

Subjects

Computer science, 020209 energy, Superconducting fault current limiters, 02 engineering and technology, Dissipation, Condensed Matter Physics, Grid, Electronic, Optical and Magnetic Materials, Current limiting, Fault current limiter, 0202 electrical engineering, electronic engineering, information engineering, Electronic engineering, Electrical and Electronic Engineering, MATLAB, computer, Realization (systems), Dc circuit breaker, computer.programming_language

Abstract

The eventual goal of high-voltage direct-voltage (HVDC) systems is to implement HVDC grids. One of the key obstacles in realization of the HVDC grid is the absence of a dc circuit breaker (DCCB). Several prototypes of DCCBs for the HVDC grid have been proposed, but no commercial solution has been developed yet due to insufficient dc fault current breaking capabilities and an unreliable protection-coordination scheme. In this respect, application of the suitable fault current limiter is necessary, and the use of a superconducting fault current limiter (SFCL), which has already been developed for the ac grid, is a viable solution, but there is no fundamental research about performance evaluation of SFCLs for the dc grid. Therefore, we aim to verify the applicability of the conventional SFCL in HVDC grids and perform a comparative analysis of the performance of several types of SFCLs. To analyze the performance of the conventional SFCL in the HVDC grid, three well-known representative types of SFCLs are modeled in MATLAB/Simulink, and their current limiting and recovery characteristics and energy dissipation are examined in voltage-source converter HVDC system application. From the simulation results, we deduced the strengths and the weakness of different types of SFCLs. Consequently, the likely SFCL candidate for commercialization in dc grid applications is suggested.

Published

2018

43. Surface Flashover Characteristics of PPLP According to Its Orientation in Cryogenic Environment

Author

Ik-Soo Kwon, Jin-Yong Na, Asif Mansoor, Bang-Wook Lee, and Jae-Hong Koo

Subjects

Materials science, Flashover voltage, Breaking point, Arc flash, Dielectric, Electrical and Electronic Engineering, Composite material, Liquid nitrogen, Condensed Matter Physics, Electronic, Optical and Magnetic Materials, Leakage (electronics), Voltage

Abstract

Polypropylene laminated paper (PPLP), which is used as the main insulation material of the stop joint box (SJB), has excellent dielectric characteristics in cryogenic environment. Despite excellent dielectric characteristics of PPLP, the interface between liquid nitrogen (LN2) and PPLP of the SJB is very vulnerable to the surface flashover. Therefore, it is necessary to investigate the surface flashover characteristics of dielectric materials including LN2 and PPLP for the insulation design of the SJB. PPLP has two orientations according to the direction of fiber in Kraft paper that are cross direction (CD) and machine direction (MD). The research on the mechanical properties of PPLP has been reported since there are differences in physical properties depending on its orientation. However, the study of the surface flashover characteristics of PPLP in the cryogenic environment according to its orientation has not been reported yet. Thus, the surface flashover characteristics of PPLP according to its orientations should be examined to ensure the reliability of the SJB connecting the High-temperature superconducting (HTS) dc cable. In this paper, the surface flashover characteristics of the PPLP in cryogenic environment in accordance with its orientation was fully investigated. The dc surface flashover tests were performed with different orientations of PPLP and various gap distances. In addition, the surface leakage currents were measured by increasing voltage at fixed gap distance. From the test results, the dc surface flashover voltage of CD was found to be 15-20% higher than that of MD. In addition, the breaking point of CD was three times higher than MD, and beyond the breaking point, the surface leakage current of CD was lower than that of MD. Consequently, the surface flashover characteristics of PPLP are significantly affected by fiber orientations of PPLP.

Published

2018

44. Determination of Threshold Electric Field for PPLP Specimen in Liquid Nitrogen Based on the Measurement of Electrical Conductivity

Author

Bang-Wook Lee, Ho-Young Lee, Ik-Soo Kwon, and Jin-Yong Na

Subjects

Superconductivity, Materials science, Field (physics), 02 engineering and technology, Conductivity, 021001 nanoscience & nanotechnology, Condensed Matter Physics, 01 natural sciences, Space charge, Electronic, Optical and Magnetic Materials, Stress (mechanics), Electrical resistivity and conductivity, Electric field, 0103 physical sciences, Electrical and Electronic Engineering, Composite material, 010306 general physics, 0210 nano-technology, Current density

Abstract

The externally applied electric field causing sudden increase in electrical conductivity is called the threshold electric field. And the information of this threshold electric field is very important for reliable insulation design of dc power apparatus because dc electric field distribution is governed by electrical conductivity of the insulating material. There are several reports on the threshold electric field of XLPE and polymeric materials used for dc power cables, operated at room temperature. However, there are no previous works on threshold field of cryogenic insulating materials, which is necessary for the reliable insulation design of a superconducting dc cable. Therefore, in this study, we tried to determine the characteristics of threshold electric field of a polypropylene laminated paper (PPLP) specimen in liquid nitrogen by varying the number of PPLP layers. From the experiments, we could observe that there exists the threshold electric field of PPLP in a cryogenic environment. Furthermore, it was found that there was no difference in the measured threshold electric field in spite of different number of PPLP layers. In addition, it was found that if electrical stress exceedes the threshold field on PPLP specimen, the conductivity can be varied according to the number of PPLP layers.

Published

2018

45. Real-time fault detection system for large scale grid integrated solar photovoltaic power plants

Author

Umer Amir Khan, Bang-Wook Lee, Muhammad Saad Iqbal, and Yasir Amir Khan Niazi

Subjects

Computer science, 020209 energy, 020208 electrical & electronic engineering, String (computer science), Detector, Photovoltaic system, Energy Engineering and Power Technology, 02 engineering and technology, Grid, Fault (power engineering), Fault detection and isolation, Power (physics), Reliability engineering, Data logger, 0202 electrical engineering, electronic engineering, information engineering, Electrical and Electronic Engineering

Abstract

A new fault detection system is proposed in this study for large-scale grid-tied PV power plants. The fault detection system performs string level comparison of DC power of Actual PV Plant and a simulated PV plant, referred as Theoretical PV Plant. The comparison is performed with a statistical tool which distinguishes a faulty condition and identifies the nature of the fault. This statistical tool is used as outlier detector based on the William Gosset's (Student's) T-Test. The Theoretical PV Plant generates power in a simulation tool using inputs of irradiance and PV module temperature, both obtained from sensors at the Actual PV Plant. The string power of Actual PV Plant is also obtained in the simulation from the data logger in real-time environment. These string powers of Actual and Theoretical PV Plants are compared to find a faulty condition. A GUI is developed where the fault alarms appear on Real-time Status Monitor whenever a fault occurs in the Actual PV Plant. The proposed fault detection system has been validated on a 125 kWp grid-connected PV plant.

Published

2021

46. Comparison of Surface Flashover Characteristics of Rod and Rib Type Post Insulator for Extra-High Voltage Superconducting Fault Current Limiter

Author

Dong-Hun Oh, Bang-Wook Lee, Jae-Hong Koo, Woo-Ju Shin, and Ryul Hwang

Subjects

Cryostat, Materials science, 020208 electrical & electronic engineering, High voltage, Insulator (electricity), 02 engineering and technology, Impulse (physics), Fibre-reinforced plastic, Condensed Matter Physics, 01 natural sciences, Rod, Electronic, Optical and Magnetic Materials, 0103 physical sciences, 0202 electrical engineering, electronic engineering, information engineering, Arc flash, Electrical and Electronic Engineering, Composite material, 010306 general physics, Voltage

Abstract

One of the most important insulating components for developing a 154 kV superconducting fault current limiter (SFCL) is post insulator, which supports 154-kV SFCL modules in a cryostat. In order to design an optimum post insulator, the top priority is to determine the creepage distance of post insulator. In our previous research, surface flashover voltages along smooth glass fiber reinforced polymer (GFRP) rods immersed in liquid nitrogen (LN2) were experimentally investigated. To reduce the cryostat volume, ribbed post insulators with increased creepage path were then considered. However, due to difficulties with producing ribbed GFRP post insulators, ribbed specimens were made of polytetrafluoroethylene instead. Four kinds of test specimens were prepared to determine the position and the number of ribs attached to the surface. From the experimental results, it was found that the ribbed insulator has shown better insulation performance in LN2 and number of ribs could affect the surface flashover voltage of post insulator. Consequently, ribbed model for 154-kV SFCL post insulator was designed and successfully tested. Finally, real 154-kV SFCL system with newly designed ribbed post insulator was installed and Basic Impulse Level (BIL) test and ac required withstand voltage were successfully carried out.

Published

2017

47. Assessment of Thermal and Electric Field Characteristics of HVDC Cable According to the Inner Filler Size of XLPE

Author

Mansoor Asif, Jae-Sang Hwang, Chae-Kyun Jung, Kim Min-Ju, Ho-Young Lee, Bang-Wook Lee, and Ik-Soo Kwon

Subjects

Stress (mechanics), chemistry.chemical_compound, Filler (packaging), Thermal conductivity, Materials science, chemistry, Electric field, Composite number, Thermal, Thermal management of electronic devices and systems, Polyethylene, Composite material

Abstract

Increasing the rating of the HVDC cable causes an inevitable increase in the heat generated inside cable. Thus, it is necessary to improve the thermal conductivity of the Cross-linked polyethylene (XLPE) insulation material used in the extruded cable for effective thermal management. Also, several methods have been pro-posed so far to increase the thermal conductivity of XLPE. However, the influence of the filler addition on the thermal conductivity has been mainly studied experimentally so far. Therefore, numerical analysis was performed to investigate the effect of filler size and its content on thermal conductivity of XLPE. In the modelling of XLPE composite for numerical analysis spherical Al2O3 particles with a radius of 25, 50, 100 and 200 nm were considered. Additionally, filler contents were considered with up to 20 wt%. Numerical analysis of XLPE composite model showed that the effective thermal conductivity increased with the smaller filler size. Also, as the content of filler increased, the effective thermal conductivity increased. A coupled electro-thermal model considering the previously derived thermal conductivities was used to investigate the influence of the thermal conductivity of XLPE on temperature and electric field distribution. From the simulation results it can be concluded that, higher thermal conductivity of XLPE can reduce the thermal and electrical stress of the cable. Therefore, it is considered that the smaller the size of the filler added to the insulation or the larger the content of the filler, the thermal and electrical stress in the cable can be reduced.

Published

2019

48. DC Dielectric Characteristic Study on Epoxy and Air Insulation Materials for the Development of MVDC Switchgear

Author

Joon-Yeon Kim, Sang-Hyuk Im, Bang-Wook Lee, and Jae-Hong Koo

Subjects

Materials science, Air insulation, visual_art, Electrode, visual_art.visual_art_medium, Epoxy, Dielectric, Impulse (physics), Composite material, Space charge, Switchgear, Voltage

Abstract

This paper deals with the DC dielectric characteristic of an epoxy and air insulation materials for the deduction of insulation design standards for the development of MVDC switchgear. First of all, after the international standards related with DC voltage tests are investigated, the test electrode configurations and the applied voltage conditions are discussed. Based on the investigation of standards, continuous DC voltage test, LI (Lightning Impulse) voltage test, and superimposed lightning impulse voltage test are performed and the results are analyzed about the epoxy and air. In the case of the solid insulation such as the epoxy, the experiment contains the results of the applied time of DC voltage at the insulation material and variable DC voltage levels in order to secure long time dielectric reliability under the operation condition. In the case of the air insulation, the results of superimposed lightning impulse voltage tests are com-pared with the results with those of lightning impulse voltage tests. The results of the experiments show that the applied time of DC voltage doesn’t greatly affect the solid and air insulation performance in contrast with XLPE cable because of the characteristic of space charge about the epoxy. If DC voltage is getting higher, the lightning voltage level is identified to be lowered.

Published

2019

49. SF6 Alternative Gas Lightning Impulse Insulation Breakdown Characteristic in Medium Voltage

Author

Bang-Wook Lee, Ryul Hwang, Yu-Min Kim, In-Seok Choi, and Jae-Hong Koo

Subjects

010302 applied physics, Materials science, Dielectric strength, 020209 energy, chemistry.chemical_element, 02 engineering and technology, Impulse (physics), 01 natural sciences, Sulfur hexafluoride, chemistry.chemical_compound, chemistry, Greenhouse gas, 0103 physical sciences, Electrode, 0202 electrical engineering, electronic engineering, information engineering, Fluorine, Breakdown voltage, Composite material, Voltage

Abstract

Sulfur hexafluoride (SF6), a greenhouse gas, is used as an insulating medium for power equipment due to its excellent insulating properties. However, as global warming and climate change become a global concern, the development of products that minimize the environmental impact is increasing, and SF6 replacement gas is being studied as an environmentally friendly alternative. Currently, there are N 2 , CO 2 , and fluorine mixed gas as substitute gas of SF 6 in medium voltage classes, and research on insulation characteristic for substitute gas is actively proceeding. In this paper, we present the results of a comparative study of breakdown voltage of C 5 F 10 O/CO 2 and SF 6 gases under lightning impulse voltage in a sphere-to-plate electrodes arrangement. The equivalencies between breakdown voltage of SF6 and those of SF6 replacement gases with respect to pressure and percentage of SF 6 and C 5 F 10 O/CO 2 are presented and discussed.

Published

2019

50. The Analysis of Low-Voltage DC Arc behavior on Three Interrupting Phases Based on AC Black-box Arc model

Author

Ho-Yun Lee, Kyu-Hoon Park, and Bang-Wook Lee

Subjects

Materials science, DC distribution system, 020208 electrical & electronic engineering, Topology (electrical circuits), 02 engineering and technology, Topology, 01 natural sciences, 010305 fluids & plasmas, Power (physics), Arc (geometry), 0103 physical sciences, 0202 electrical engineering, electronic engineering, information engineering, Waveform, Commutation, Low voltage, Circuit breaker

Abstract

Among many low voltage power electrical devices, Low-voltage (LV) dc circuit breaker (DCCB) is one of the most essential components and is widely used to protect the overall LV dc distribution system. Therefore, many research institutes and manufacturers have been concentrating a lot of research and interest in LV DCCB in recent years. LV dc arc simulation modeling technique using computational methods is being studied. However, dc arc modeling technique using only finite element method is studied among various modeling methods, and there are no existing researches of dynamic arc-circuit interaction analysis using a black-box model. In this paper, LV dc arc is modeled by using the proposed black-box model as the ac arc modeling technique. The existing LV DCCB has air arc characteristics according to the interrupting topology, and the corresponding LV dc arc interrupting phases can be divided into arc commutation, arc motion, and arc splitting. Arc modeling was performed on three interrupting phases, based on the typical waveform of a LV dc arc and actual experimental data. The black-box model uses the schwarz model, which is known to be best suited for representing the small current and large current regions of the arc. As a result, the applicability of the dc arc was evaluated using the existing ac black-box model, and the behavior of the dc arc for each interrupting phase was described.

Published

2019