Your search keyword '"Lim, Sung-Hun"' showing total 22 results

1. Analysis on DC Fault Current Limiting Operation of Twice-Quench Trigger Type SFCL Using Transformer Considering Magnetizing Current and Current Limiting Reactor.

Author

Lim, Sung-Hun, Park, Min-Ki, Park, Sung-Hoon, and Chung, Jae-Woo

Subjects

*SUPERCONDUCTING fault current limiters, *POWER resources, *FAULT currents

Abstract

As the penetration of distributed energy resources (DER) has increased, research on direct current (DC) power transmission and distribution has been actively performed. The DC system has the advantage of high-power transmission efficiency. However, it has a very large and rapid increase in fault current in the DC system directly after a fault occurs. As one of the countermeasures, studies on the application of the superconducting fault current limiter (SFCL) into the DC system have been conducted to protect major facilities from DC fault current, which is expected to alleviate the power burden on the DC circuit breaker through its quench operation. Among the studied DC SFCLs, the trigger-type DC SFCL using a transformer, which can achieve the peak DC fault current-limiting operation, has been suggested. However, the DC fault current-limiting operation, in the case of the DC SFCL with a current-limiting reactor (CLR), was analyzed to not be effectively executed in the steady state since the transient state directly follows the fault occurrence. In this paper, the DC fault current-limiting operation of a twice-quench trigger type SFCL using a transformer considering magnetizing current and its CLR was analyzed. Through DC fault current-limiting experiments according to the inductance of its current-limiting reactor (CLR), the effective current-limiting design of twice-quench trigger type SFCL using a transformer was described. [ABSTRACT FROM AUTHOR]

Published

2023

2. Study on Malfunction of OCR Due to Penetration of DER into Power Distribution System with SFCL.

Author

Park, Min-Ki and Lim, Sung-Hun

Subjects

*SUPERCONDUCTING fault current limiters, *FAULT currents, *POWER resources, *POWER distribution networks

Abstract

Due to the demand for eco-friendly energy, distributed energy resources (DERs) using renewable energy have increased. The increase in DER has caused the power system to become more complex and caused problems in the protection system. Typical problems include an increase in fault current and a problem that causes malfunction of the overcurrent relay (OCR). If the fault current increases and exceeds the capacity of the existing protection devices, it may lead to a large blackout. The most effective way to limit the fault current is to install a superconducting current limiter (SFCL). The installation of SFCL and system penetration of DER both affect OCR operating characteristics. In this paper, a simulated power distribution system is constructed and OCR malfunctions caused by DER penetration and SFCL installation are analyzed. [ABSTRACT FROM AUTHOR]

Published

2023

3. Impedance Compensation Method Considering Unbalanced Ground Fault with SFCL in a Power Distribution System.

Author

Cho, Yoo-Jung and Lim, Sung-Hun

Subjects

*SUPERCONDUCTING fault current limiters, *ELECTRIC utilities, *FAULT currents

Abstract

As the energy demand increases due to the developing electric power industry, the fault current becomes higher during the fault time. A new approach is needed to reduce a fault current in a power distribution system, since the fault currents influence other protective devices' operation. To decrease the fault current, the superconducting fault current limiter (SFCL) has been suggested. The SFCL has no power loss with no effect on a power distribution system because the SFCL impedance only occurs during the fault time. However, the SFCL can reduce the fault current; it causes the trip time delay of the over current relay (OCR). Compensation methods for the balanced fault have been invented in previous studies, while research on unbalanced ground fault compensation are few. In this paper, the compensation method configured with impedance components of a power distribution system is introduced to eliminate the influence of the SFCL on the OCR. In addition, the components of the SFCL impedance are removed from the characteristic equation of the OCR. To verify the effect of the impedance compensation method, fault simulations are carried out in 3 types of ground faults using PSCAD/EMTDC. [ABSTRACT FROM AUTHOR]

Published

2022

4. Analysis on Protection Coordination of OCRs Using Voltage Components for the Application of SFCL in a Power Distribution System with DG.

Author

Lim, Sung-Hun and Park, Min-Ki

Subjects

*POWER distribution networks, *SUPERCONDUCTING fault current limiters, *POWER system simulation, *FAULT currents, *PROTECTIVE relays, *ELECTRIC relays, *OVERCURRENT protection

Abstract

As the importance of renewable energy increases, the capacity of dispersed generations (DGs) has increased worldwide. However, the connection of DGs in the power distribution system can cause the fault current to increase as well as malfunction of the overcurrent relay (OCR) due to the reverse directional fault current. As the countermeasure to limit the fault current in the power distribution system with DG, though the superconducting fault current limiter (SFCL) is reported to be more effective, the research on the protection algorithm of the protective relay considering the application of SFCL is preferentially required. In this paper, the correction method of the OCR using voltage components for application of SFCL in a power distribution system with DG was suggested. To verify the effectiveness of the suggested method, the fault simulation for the power distribution system with DG including the OCR and the SFCL was performed. By applying the proposed correction method in the OCR, the protection coordination of OCRs for the application of SFCL in power distribution system with DG was confirmed to be improved through the suppression of the malfunction of the OCR. [ABSTRACT FROM AUTHOR]

Published

2021

5. Impedance Compensation Method of Protective Relay for SFCL's Application in a Power Distribution System.

Author

Park, Min-Ki and Lim, Sung-Hun

Subjects

*SUPERCONDUCTING fault current limiters, *PROTECTIVE relays, *ELECTRIC utilities, *ELECTRIC power failures, *ELECTRIFICATION, *FAULT currents, *WATER distribution

Abstract

Recently, the development of the electric power industry has led to an increase in the fault current when a fault occurs. It is important to reduce the fault current, since fault currents exceeding the capacity of protective devices can result in large blackouts. In order to reduce the fault current, there is a method to separate the bus line of main substation. However, this method has the disadvantage of complicating the power system. Another method is to install a superconducting fault current limiter (SFCL). The SFCL has the advantage that the fault current can be quickly limited within 1/4 cycle immediately after the fault occurrence without affecting the power system since its impedance is zero in a normal time. However, the application of SFCL affects the operation of the over-current relay (OCR) due to the reduced fault current such as trip time delay. The trip time delay of OCR was reported to be suppressed by using SFCL's voltage component in previous studies. In this paper, the impedance compensation method was suggested to exclude the effect of SFCL on OCR. To prevent OCR from the influence of SFCL, the component that can exclude the impedance of SFCL was considered to be added to the characteristic formula of OCR. In addition, the effect of correcting this characteristic equation was analyzed by constructing a power distribution system using PSCAD / EMTDC. [ABSTRACT FROM AUTHOR]

Published

2021

6. Magnetization and Power Losses Characteristics Due to Variation in the Number of Windings of a Bridge Type SFCL With Double HTSC Elements.

Author

Ko, Seok-Cheol, Han, Tae-Hee, and Lim, Sung-Hun

Subjects

SUPERCONDUCTING fault current limiters, MAGNETIZATION, MAGNETIC flux, MAGNETIC levitation vehicles, FAULT currents

Abstract

Superconducting fault current limiters (SFCLs) are emerging as an alternative to limit fault current in AC and DC power systems. SFCLs can perform faster current limiting operation and automatic fault current detection and recovery, regardless of the type of fault. In this paper, a laboratory-scale prototype SFCL was fabricated and analyzed for its magnetization characteristics due to the magnetizing current according to the change of the number of windings in pairs. This bridge type SFCL consists of two windings and two high-Tc superconducting (HTSC) elements on one iron core. When the number of windings of the two coils were changed in pairs, the variation of the induced voltage and Joule losses due to the magnetizing current, magnetic flux in each winding, and power losses for the bridge type SFCL were compared with each other. Through comparative analysis, it was confirmed that the size of the number of turns should be considered to reduce the power losses of SFCL while effectively limiting the fault current during the fault cycle. [ABSTRACT FROM AUTHOR]

Published

2021

7. Analysis on Protection Coordination of Protective Devices With a SFCL Due to the Application Location of a Dispersed Generation in a Power Distribution System.

Author

Lim, Sung-Hun and Kim, Jae-Chul

Subjects

*ELECTRIC power distribution, *SUPERCONDUCTING fault current limiters, *SHORT circuits, *WAVE analysis, *ELECTRIC resistance

Abstract

The increase of various dispersed generations (DGs) such as wind power and solar cell in a power distribution system has been reported to increase the short-circuit current. In addition, the introduction of the DG in a power distribution system is expected to affect the operation of the protective device as well. The superconducting fault current limiter (SFCL), which has been continuously studied for the reduction of the circuit breaker's power burden, recently starts to be noticed as effective method to solve the fault current problem due to the introduction of the DG. Since the fault current limiting operation of the SFCL and the operations of the protective devices such as the over-current relay or the recloser are affected by the application location of the DG, the study on the protection cooperation of the protective devices with the SFCL considering the application location of the DG in a power distribution system is firstly required. [ABSTRACT FROM PUBLISHER]

Published

2012

8. Study on Application Method of Superconducting Fault Current Limiter for Protection Coordination of Protective Devices in a Power Distribution System.

Author

Kim, Jin-Seok, Lim, Sung-Hun, and Kim, Jae-Chul

Subjects

*SUPERCONDUCTING fault current limiters, *ELECTRIC power distribution, *ELECTRIC transients, *ELECTRIC power transmission, *ELECTRIC power failures

Abstract

In this paper, the application method of superconducting fault current limiter (SFCL) for the protection coordination of the protective devices in a power distribution system was analyzed. The SFCL has been announced as better solution among many methods to limit a fault current effectively, which has continuously increased due to more complex network of a power system. However, the application of the SFCL in a power system affects the operation of the protection devices and the protection coordination, which requires the study on the protection coordination of the protective devices considering the application of the SFCL in a power distribution system. [ABSTRACT FROM PUBLISHER]

Published

2012

9. Study on Peak Current Limiting Characteristics of a Flux-Lock Type SFCL Using Its Third Winding.

Author

Lim, Sung-Hun, You, Il-Kyoung, and Kim, Jae-Chul

Subjects

*ELECTRIC currents, *ELECTRIC fault location, *SUPERCONDUCTING magnets, *ELECTRIC impedance, *ELECTRIC coils, *MAGNETIC flux, *ELECTRIC windings

Abstract

Generally, the peak amplitude of the fault current after the fault occurrence depends on the transient component of the fault current, which is determined by the fault condition such as the fault angle. In the suggested flux-lock type superconducting fault current limiter (SFCL), the fault current of the lower peak amplitude causes the only high-TC superconducting (HTSC) element connected in series with one of two coils comprising the flux-lock type SFCL to be quenched, which the fault current can be limited by the lower limiting impedance of the flux-lock type SFCL. On the other hand, the fault current with the higher peak amplitude makes another HTSC element connected with the third winding to be quenched after the HTSC element connected in series with one of the SFCL's two coils is quenched, which contributes to the higher limiting impedance of this SFCL. Therefore, the effective fault current limiting operation of the flux-lock type SFCL can be performed by generating the SFCL's limiting impedance in proportion to the peak amplitude of the fault current. To confirm the current limiting operation of the proposed flux-lock type SFCL, the short-circuit tests of the flux-lock type SFCL using its third winding according to the fault angle were carried out and its effective fault current limiting operations were discussed. [ABSTRACT FROM AUTHOR]

Published

2011

10. Operational Characteristics of Hybrid SFCL With First Half Cycle Non-Limiting Operation Considering Its Design Parameter.

Author

You, Il-Kyoung, Lim, Sung-Hun, and Kim, Jae-Chul

Subjects

*HYBRID power systems, *SUPERCONDUCTORS, *ELECTRIC fault location, *ELECTRIC resistance, *ELECTRIC lines, *ELECTRIC resistors, *ELECTRIC coils, *ELECTRIC switchgear

Abstract

The hybrid superconducting fault current limiter (SFCL) can be constructed to perform either first half cycle limiting operation or first half cycle non-limiting operation through rearrangement of the SFCL's components. Especially, the first half cycle non-limiting operation of the hybrid SFCL is expected to be preferred for the protection coordination with the protective device. However, if the components of the hybrid SFCL with the first half cycle non-limiting operation is designed with improper parameter, the hybrid SFCL can result in the continuous conduction of the fault current into the high-TC superconducting (HTSC) element after the fault occurs, which can sometimes bring about the destruction of the HTSC element comprising the hybrid SFCL. In this paper, among the components to affect the operational characteristics of the hybrid SFCL, the current limiting characteristics of the hybrid SFCL with the first half cycle non-limiting operation due to the resistances of HTSC element and the current limiting resistor (CLR) were investigated. Through the short circuit tests, the stable current limiting operation of the hybrid SFCL with the first half cycle non-limiting operation was confirmed to be performed by designing the resistances of both the HTSC element and the CLR to be larger values. [ABSTRACT FROM AUTHOR]

Published

2011

11. Improvement of Recloser-Fuse Operations and Coordination in a Power Distribution System With SFCL.

Author

Kim, Myoung-Hoo, Lim, Sung-Hun, and Kim, Jae-Chul

Subjects

*ELECTRIC power distribution, *SUPERCONDUCTORS, *ELECTRIC lines, *ELECTRIC fault location, *ELECTRIC resistance, *ELECTRIC fuses, *ELECTRIC power, *DELAY lines

Abstract

In this paper, we describes how to coordinate between recloser and fuse in power distribution system with superconducting fault current limiters (SFCL). The recloser and fuses are the main overcurrent protective devices in power distribution system. Universally, to protect against permanent faults, fuses are installed on overhead feeder laterals and the reclosers as a backup protection against temporary faults remove many unnecessary outages. Here, the recloser is set to trip using TCC curve for a temporary fault before any of the fuses can melt. If the fault is a permanent fault, the fuse has to melt just before the last delay trip of the recloser. However, the application of a resistive SFCL in power distribution system affects the recloser- fuse operation and coordination as decreased fault currents. In case that when a permanent fault occurs, the recloser could be locked-out after the last delay trip before the fuses operate. [ABSTRACT FROM AUTHOR]

Published

2011

12. Study on Protective Coordination for Application of Superconducting Fault Current Limiter.

Author

Kim, Jin-Seok, Lim, Sung-Hun, and Kim, Jae-Chul

Subjects

*SUPERCONDUCTORS, *ELECTRIC fault location, *ELECTRIC power, *OPTICAL character recognition devices, *ELECTRIC impedance, *ELECTRIC lines, *ELECTRIC currents

Abstract

In this paper, the effects on the protective coordination of a superconducting fault current limiter (SFCL) with the protective devices were analyzed. The SFCL has been noticed as the best solution to limit fault current effectively, which has continuously increased due to the expansion of the power facilities for the increased power demand. However, the application of the SFCL in the power system affects the protective coordination of the existing protective devices and can deviate their operation time from the original one. Therefore, the studies on the protective coordination considering the introduction of the SFCL are necessary prier to its installation. [ABSTRACT FROM AUTHOR]

Published

2011

13. Assessment of the Impact of SFCL on Voltage Sags in Power Distribution System.

Author

Moon, Jong-Fil, Lim, Sung-Hun, Kim, Jae-Chul, and Yun, Sang-Yun

Subjects

*SUPERCONDUCTORS, *ELECTRIC fault location, *ELECTRIC power distribution, *ELECTRIC potential, *OPTICAL character recognition devices, *ELECTRIC impedance, *METAL quenching, *SUPERCONDUCTIVITY

Abstract

This paper assesses and analyses the effects of superconducting fault current limiter (SFCL) installed in power distribution system on voltage sags. First of all, resistor-type SFCL is modeled using PSCAD/EMTDC to represent the quench and recovery characteristics based on the experimental results. Next, typical power distribution system of Korea is modeled. When the SFCL is installed in various locations from the starting point to end point of feeders, improvement of voltage sag is evaluated using the Information of Technology Industry Council (ITIC) curve of customer's loads when a fault occur. Finally, future studies needing to apply SFCL to power distribution system are presented [ABSTRACT FROM AUTHOR]

Published

2011

14. Improvement of DC Fault Current Limiting and Interrupting Operation of Hybrid DC Circuit Breaker Using Double Quench.

Author

Choi, Sang-Jae, Lee, Jun-Hyup, Lee, Jin-Wook, and Lim, Sung-Hun

Subjects

FAULT currents, HYBRID integrated circuits, ELECTRIC resistors

Abstract

In this paper, direct current (DC) fault current limiting and interrupting operation of hybrid DC circuit breaker (DCCB) using double quench, which consists of DCCB, a series resonance circuit, power electronic switch, surge arrestor, two separated current limiting reactor/resistor, and two superconducting elements, were suggested. The suggested hybrid DCCB can perform the interrupting operation after twice or once DC fault current limiting operation according to DC fault current amplitude. To verify the effective operation of the suggested hybrid DCCB, the modeling for the components of DCCB, the surge arrestor, and the SCE was carried out and its DC operational characteristics were analyzed. Through the analysis of the modeling results for the suggested hybrid DCCB, the advantages of hybrid DCCB were discussed. [ABSTRACT FROM AUTHOR]

Published

2021

15. Impact on Current-Interrupting Characteristic by Parameter Settings of Superconducting Hybrid DC Circuit Breaker.

Author

Choi, Sang-Jae, Lim, Sung-Hun, and Bizon, Nicu

Subjects

*HYBRID integrated circuits, *FAULT currents, *POWER semiconductors, *ELECTRIC inductance, *SUPERCONDUCTORS

Abstract

DC faults cause severe disruption in not only the DC system but also the AC system because the fault current is very large and rapidly increases. The DC circuit breaker used to separate the DC faults from the power system is still being researched, but it is very expensive due to the use of multiple power semiconductors to interrupt a large fault current in a short time. However, if the quench characteristic of a superconductor is used, the amplitude of fault current can be reduced. Therefore, it is possible to effectively interrupt a large fault current even if a relatively cheap mechanically passive DC circuit breaker is used. In the current study, a superconducting hybrid DC circuit breaker is proposed, and the limiting characteristics of each element are analyzed. By using two superconducting elements, the quench occurs sequentially twice according to the magnitude of the fault current, and the current-limiting reactor and resistance are used. If a current-limiting reactor is used in the DC system, the fault current rises slowly at the beginning of the fault, and the use of resistance can reduce the magnitude of the fault current. The inductance of the current-limiting reactor and resistance parameter settings of the hybrid DC circuit breaker was analyzed by the step-changing case method, and the interrupting characteristic of the DC circuit breaker was improved. [ABSTRACT FROM AUTHOR]

Published

2021

16. DC Current Limiting Operation and Power Burden Characteristics of a Flux-Coupling Type SFCL Connected in Series between Two Windings.

Author

Ko, Seok-Cheol, Han, Tae-Hee, Lim, Sung-Hun, and Anvari-Moghaddam, Amjad

Subjects

SUPERCONDUCTING fault current limiters, SUPERCONDUCTING coils, FAULT currents, MAGNETIC flux, SHORT circuits

Abstract

In this paper, a DC fault short circuit was conducted to analyze the DC fault current limiting characteristics of a flux-coupling type superconducting fault current limiter (SFCL) that has two coils connected in series via one iron core. Similar to the AC power system, the flux-coupling type SFCL in a DC system, which has the two coils connected with each other in series and the secondary coil connected with the superconducting element in parallel, remains in the superconducting state before a short-circuit accident occurs. This results in magnetic flux getting generated by the two windings connected in series offsetting each other and the induced voltage at the two windings remaining at zero. However, in the event of a short-circuit accident on the DC line, a resistance is generated on the superconducting element, so that the magnetic flux generated at the two windings no longer offsets each other. Therefore, a voltage is induced on the two windings, and the fault current is limited accordingly. As a result of configuring a DC short-circuit device and experimenting with this SFCL, we could confirm the DC fault current limiting effect of a flux-coupling type SFCL with two windings connected in series. In addition, we could establish performance conditions of the flux-coupling type SFCL in a DC system by inferring the fault current, operating current, and limited impedance equations according to the connection direction of the flux-coupling type SFCL with two windings connected in series and by analyzing fault current limiting degree, power burden, magnetic flux, and energy consumption for each element composing the SFCL. [ABSTRACT FROM AUTHOR]

Published

2021

17. Fault Current Limiting and Breaking Characteristics of SFCLB Using Flux Coupling with Tap Changer.

Author

Lim, Sung-Hun, Kim, Jin-O., and Jeong, Youngjin

Subjects

*FAULT currents, *FLUX (Energy), *POWER transmission, *OCEAN waves

Abstract

In this paper, a superconducting fault current limiting breaker (SFCLB) using flux coupling with a tap changer is suggested and its effective fault current limiting and breaking characteristics due to the winding method using its tap changer are analyzed. The suggested SFCLB using flux coupling, which consists of the SFCLB using flux coupling with a tap changer, mechanical switch and driving coil, can perform the circuit-breaking function without external driving power after the fault current limiting operation. To examine the suggested SFCLB's operation, the small scale SFCLB using flux coupling was fabricated and alternative current (AC) short-circuit experiments due to the winding method using the tap changer of the SFCLB were executed. From the experimental results, a lower fault current limiting rate and faster breaking time in the case of a SFCLB with a series connection could be obtained compared to one with a parallel connection. [ABSTRACT FROM AUTHOR]

Published

2020

18. Analysis of the DC Fault Current Limiting Characteristics of a DC Superconducting Fault Current Limiter Using a Transformer.

Author

Cho, Kang-Cheol, Park, Min-Ki, and Lim, Sung-Hun

Subjects

SUPERCONDUCTING fault current limiters, FAULT currents, ELECTRIC resistors, ELECTRIC power distribution grids

Abstract

Recently, a lot of interesting research has been conducted to solve the fault current problem of the DC system. In long-distance transmission, DC transmission is more economical than AC transmission. The connection of power grids with a DC system can also better control the power flow and provide high stability. However, the control of the fault current in a DC system is more difficult to handle than in an AC system because the DC system does not make a zero point, unlike the AC system. In addition, there is a disadvantage, in that an arc occurs when a circuit breaker operates. In this paper, a new type of DC superconducting fault current limiter (SFCL) is proposed. This new type of SFCL is composed of two superconducting elements, a current limiting resistor/reactor (CLR), and a transformer. With the proposed SFCL, the DC fault current limiting experiments were performed and the DC fault current limiting characteristics of this SFCL due to the component of the CLR were analyzed. [ABSTRACT FROM AUTHOR]

Published

2020

19. Magnetizing Characteristics of Bridge Type Superconducting Fault Current Limiter (SFCL) with Simultaneous Quench Using Flux-Coupling.

Author

Ko, Seok-Cheol, Han, Tae-Hee, and Lim, Sung-Hun

Subjects

SUPERCONDUCTING fault current limiters, SUPERCONDUCTING magnets, FAULT currents, CRITICAL currents, BRIDGES

Abstract

A bridge type superconducting fault current limiter (SFCL) with simultaneous quench using two high-temperature superconducting (HTSC) elements and two coils was fabricated to analyze the fault current limiting characteristics. Before and after the fault occurrence, the current limiting operation and the voltage waveforms of each device were compared according to the change of the input voltage. We also analyzed flux linkages and instantaneous powers of the bridge type SFCL with simultaneous quench using flux-coupling composed of HTSC elements with different critical currents. During the fault period, the magnetization power area and the flux linkage's operating range variation due to the magnetizing current were compared with each other. [ABSTRACT FROM AUTHOR]

Published

2020

20. Fault Current Limiting Characteristics of a Small-Scale Bridge Type SFCL with Single HTSC Element Using Flux-Coupling.

Author

Han, Tae-Hee, Ko, Seok-Cheol, and Lim, Sung-Hun

Subjects

FAULT currents, SUPERCONDUCTING fault current limiters, BRIDGES, DIRECT currents

Abstract

In this paper, a bridge type superconducting fault current limiter (SFCL) with a single high-temperature superconducting (HTSC) element is proposed to allow fault current limiting operation in direct current (DC) conditions. First, the principle of operation of the bridge type SFCL with a single HTSC element using flux-coupling was presented. After the fault occurrence, the fault current limiting operation and voltage characteristics, the power load characteristics of each device, and the energy consumption of the two coils and the HTSC element were analyzed in the proposed SFCL. As a result, it is confirmed that in the case of the additive polarity winding, the power consumption and the energy consumption of the HTSC element were lower than those in the subtractive polarity winding, and the fault current limiting characteristics were excellent. [ABSTRACT FROM AUTHOR]

Published

2020

21. Enhancement on the Fault Ride through Capability of Power Distribution Systems Linked by Distributed Generation due to the Impedance of Superconducting Fault Current Limiters.

Author

Choi, Sang-Jae and Lim, Sung-Hun

Subjects

*SUPERCONDUCTING fault current limiters, *OVERCURRENT protection, *PROTECTIVE relays, *POWER resources, *REACTIVE power, *FAULT currents

Abstract

Recently, studies on connecting distributed generation (DG) to power distribution systems through DC links have been actively conducted. When a fault in feeder of this power distribution system occurs, a voltage dip can happen in the grid. In order to prevent voltage dips, there are several solutions such as the application of a superconducting fault current limiter (SFCL). If a SFCL with a larger impedance is applied, the voltage dip of the grid is effectively prevented. However, this action can bring about the malfunction or the delayed operation of the over-current relay (OCR) due to the decreased fault current, which causes another problem of protection coordination between the protective relays. On the other hand, if the impedance of the SFCL is too low, excessive reactive power is supplied by the fault ride-through (FRT) regulation and the active power is reduced. This causes an active power imbalance on the DC link and increases the DC link's voltage. As previous solutions to prevent the rise of DC links' voltage, the deloading method and the application of a chopper resistor have been suggested. In this paper, a technique called active power tracking control (APTC), was proposed to suppress the rise of DC links' voltage. Case studies considering the impedance of SFCL in the constructed power distribution system were carried out, and the rise of DC links' voltage could be effectively suppressed without any significant delay in the operation of the OCR. This study is expected to solve both the voltage dip of the grid and the rise of DC links' voltage when distributed generation is connected to a grid. [ABSTRACT FROM AUTHOR]

Published

2019

22. Power consumption and cumulative energy of bridge type SFCL with simultaneous quench.

Author

Ko, Seok-Cheol, Han, Tae-Hee, and Lim, Sung-Hun

Subjects

*SUPERCONDUCTING fault current limiters, *ENERGY consumption, *HIGH temperature superconductors, *SHORT circuits, *FAULT currents

Abstract

• A bridge type superconducting fault current limiter (SFCL) with two high-temperature superconducting (HTSC) elements using flux-coupling is proposed to reduce the influence of short-circuit accidents. • A laboratory-scale prototype SFCL was fabricated and short-circuit test was conducted. • The power consumption and the accumulated energy were compared and analyzed according to the winding current when the number between N 1 and N 2 coil changed during the fault period. • The operating range of the flux linkage and the variation of the magnetizing force area were compared according to the magnetizing current. • The usefulness of the proposed SFCL was confirmed through analysis of the fault current limiting operation characteristics and the energy consumed by the simultaneous quench of two HTSC elements. A bridge type superconducting fault current limiter (SFCL) with two high-temperature superconducting (HTSC) elements using flux-coupling is proposed to reduce the influence of short-circuit accidents. A laboratory-scale prototype SFCL was fabricated and short-circuit test was conducted. The power consumption and the accumulated energy were compared and analyzed according to the winding current when the number between N 1 and N 2 coil changed during the fault period. In addition, the operating range of the flux linkage and the variation of the magnetizing force area were compared according to the magnetizing current. The usefulness of the proposed SFCL was confirmed through analysis of the fault current limiting operation characteristics and the energy consumed by the simultaneous quench of two HTSC elements. As a future study, we will apply this modified bridge-type SFCL model to a direct current (DC) distribution system. First, after establishing a DC short circuit accident test environment, this SFCL is constructed in front of the DC load and the fault occurrence resistor to measure and analyze the DC fault current limiting characteristics. [ABSTRACT FROM AUTHOR]

Published

2022