• Proceedings of the KIEE Conference
• /
• 2008.11a
• /
• pp.307-308
• /
• 2008

345kV 4복도체 이상의 가공선로를 GIL로 지중화 대치하기 위한 검토사항 중의 하나로서 GIL-가공선로 연계시의 과전압 접지방식 순환전류 등의 특성을 검토할 필요가 있다. 이를 위해서는 GIL을 포함하는 승전계통을 EMTP로 모델링하여 실계통에 나타날 수 있는 다양한 현상 및 특성을 분석할 필요가 있으나, 현재 전력계통 과도현상을 모의 할 수 있는 ATP/Draw(EMTP) 상에는 GIL을 모델링하기 위한 명시된 모델이나 방법이 존재하지 않아 현상 분석에 어려움이 있다. 따라서, 이 논문은 가공선로 중간의 일부구간에 GIL이 존재할 경우에 있어서 ATP/Draw(EMTP)를 이용한 GIL 및 가공송전선의 혼합선로 모델링에 대한 내용을 다루며, 구체적으로 GIL에 대한 모델링 시 GIS 또는 Cable 모델을 이용한 모의방법을 비교분석하여 적합한 방법을 제안한다.

• JOURNAL OF ELECTRICAL WORLD
• /
• s.335
• /
• pp.37-52
• /
• 2004

접지설비는 다른 설비에 비해서 단지 부속설비처럼 안이하게 취급하는 경우가 많다. 그러나 접지설비는 전로의 이상전압을 억제하고 지락시의 고장전류를 안전하게 대지로 흘려 인체의 보호나 화재, 기기의 손상 등의 재해를 방지하는 것뿐만 아니라 제어기기를 안정하게 동작시키는 등의 역할을 위한 필수불가결한 설비이다. 특히 최근 전자기기의 급격한 증가에 따라 안정된 신호계를 확보하기 위한 접지설비가 다양화, 혼재화하고 있다. 접지를 하여야 할 설비에는 전력설비, 정보$\cdot$통신설비(신호, 제어, 유무선통신, 컴퓨터 등), 피뢰설비(피뢰침, 피뢰도선, 가공지선 등)를 비롯하여 정전기 제거설비, 유도장해 방지설비 등 여러 가지 설비가 있다. 접지는 기본적으로 대지에 전기적 단자를 접속하는 것으로 즉, 금속 등의 도전성 물체를 대지와 전기적으로 접속하여 도전성물체의 전위를 대지와 같은 전위 또는 전위차를 최소화시키는 것을 말한다. 금속체와 대지를 접속하는 단자의 역학을 하는 것이 접지전극(Grounding electrode)이라고 하며 보통은 지중에 매설되어 있는 도체가 사용된다. 접지전극과 접지를 하는 설비를 연결하는 도선을 접지도선 또는 접지선(Grounding conductor)이라고 한다. 따라서 접지설비를 설계하기 위해서는 접지의 목적, 기능, 종류를 정확하게 이해하여 접지시스템을 구축함과 동시에 적절한 접지개소, 접지선, 접지극을 선정하고 시공하여야 한다.

• Proceedings of the Korean Institute of Information and Commucation Sciences Conference
• /
• 2016.05a
• /
• pp.505-508
• /
• 2016

In city, tracing of power transmission lines is difficult due to compound installation of overhead and underground lines, transposition, bad view caused by trees or big buildings. It is hard problem for electrical technician on site to trace power transformers or power lines to serve customers in 3 phase -4 wires power distribution systems. It is necessary that the correct and fast tracing method is required for load balancing among distribution lines. Old technology use to trace lines with high power impulse injection. Our proposed method uses to trace lines with very small power high frequency signal injection. Simulation models for 3-phase power transformers, 3-phase wire lines, and customer loads are described to investigate the transmission characteristics of high frequency power line carrier. Distribution lines have only a limited ability to carry higher frequencies. Typically power transformers in the distribution system prevent propagating the higher frequency carrier signal. The proposed method uses the limited propagation ability to identify the power transformer to serve customers. The system consists of a transmitter and a receiver with power-line communication module. Some experiments are conducted to verify the theoretical concepts in a big commercial building. Also some simulations are done to help and understand the concepts by using MATLAB Simulink simulator.

• Proceedings of the Korean Institute of Electrical and Electronic Material Engineers Conference
• /
• 2007.11a
• /
• pp.228-228
• /
• 2007

전력선 통신용 비접촉식 커플러는 고속형(2~30 MHz)과 저속형(100~450KHz)으로 나누어 볼 수 있는데, 고속형은 현재 국내에서 독자적으로 개발되어 다양한 모델이 적용되고 있는 상황이지만, 저속형은 시작품수준으로 제조되어 있으나 신호전송 특성의 향상절구가 필요한 상황이다. 전력선 통신용 커플러는 전력선 또는 모뎀으로 통신신호를 전달하는 기능을 하는 것으로서, 전력선 통신을 위한 핵심부품이다. 따라서 본 연구에서는 100~450 KHz 대역에서 사용 가능한 저속형 비접촉식 커플러를 제조하기 위해, 권선조건, 대전류형 자심재료의 모의 해석, 노이즈 필터조건, 임피던스 매칭, 하우징방법 등의 각 공정 변수를 확립하고자 하였다. 자심재료의 모의해석에서 자심재료의 높이와 전력선 도체 단면적 변화는 자심재료의 전류포화특성에 영향을 미치지 않으며, 유효길이와 에어-갭 크기가 증가할수록 전류포화특성은 향상되는데, 자심재료의 내경이 64 mm일 때 자심재료의 폭((외경-내경)/2)은 15 mm 이상이어야 하고, 에어-갭은 약 $600\;{\mu}m$ 정도의 에어-갭을 형성시켜야함을 확인할 수 있었다. 또한 저속용 비접촉식 커플러 제조조건 실험에서 내경${\times}$외경${\times}$높이가 $64{\times}94{\times}140mm$인 자심재료를 이용하여 권선 수와 에어-갭을 각각 3회, $400{\sim}600\;{\mu}m$ 삽입했을 때, 가장 우수한 특성을 나타내었다. 그리고 저역 통과 필터를 출력부에 내장하여 통신신호 이외의 노이즈를 제거할 수 있었다. 본 연구에서 제조된 300 A급 지중선용 저속형 비접촉식 커플러는 내경${\times}$외경${\times}$높이가 $58{\times}1144{\times}158mm$이고, 100~450 KHz 통신대역에서 약$7{\pm}2dB$의 삽입손실을 나타내었다.

• Journal of the Korea Academia-Industrial cooperation Society
• /
• v.12 no.11
• /
• pp.5123-5127
• /
• 2011

Research and development for the technology, that is about maintenance and accidents prevention of underground power distribution line, are demanding. The precise detection of leakage point of underground power line is very important, because it is difficult to detect the exact location of a fault in underground power line and to repair faults. When earth electric potential is measured to detect underground electric leakage point after transmitting AC electric pulse wave to underground power line, it must be measured in a specific half period of AC pulse wave because the distribution of the electric earth potential varies with the polarity of the transmitted wave. In this paper we proposed the measurement of half period modulated earth potential as a method to detect a underground leakage point. And We compared the proposed method with other methods. Through experiments we verified that the proposed method can be implemented and operated properly.

• Journal of the Korea Institute of Information and Communication Engineering
• /
• v.23 no.8
• /
• pp.996-1003
• /
• 2019

The undergrounding of diverse ground facilities has led to a decrease in issues, such as foul smell of water supply systems and wastewater, a fall of telephone poles, electromagnetic waves and breaking of wires caused by a railway work. On the other hand, there are new issues, including a fall accident, explosion affected by flammable gas, a choking accident by harmful gas and a lack of oxygen concentration, a fire coming from high-tension wire heating and flooding in the manhole. Besides, these issues damage the civil society and are an anxiety to public safety. Therefore, this paper is focused on a smart manhole device for stable communication environments inside and outside the manhole and wireless communication with various devices for managing facilities in the manhole, and aims to make a contribution to public safety by suggesting a direction of future underground facility management.

• Proceedings of the KIEE Conference
• /
• 2007.07a
• /
• pp.25-26
• /
• 2007

전력계통의 복잡화와 대도시의 지중선로 및 전력전자 설비 사용 확대로 써지성 고주파 성분이 포함된 특이 고장현상이 증가하고 있으며, 이와 관련 있는 것으로 추정되는 보호계전기의 원인 불명 동작 사례도 최근에 발생하고 있다. 보호계전기의 동작은 부동작, 정동작 및 오동작으로 구분할 수 있는데 보호계전기가 부동작 또는 오동작할 경우 광역정전으로 진전될 가능성이 크진다. 따라서 보호계전기의 정상 동작은 광역정전을 예방하는 시발점이 된다. 보호계전기의 비정상 동작사례를 살펴보면 CT비 선정의 부적합으로 인한 설비소손 및 오동작과 CT 포화 또는 원인불명의 차전류로 인한 오동작 사례가 다수 발생하고 있다. 본 논문은 보호계전기의 비정상적 동작을 방지하고 동작 신뢰도를 제고하기 위한 비율차동계전기의 알고리즘 개선 방안과 바람직한 정정 기법에 대해 고찰하였다.

• The Journal of the Korea institute of electronic communication sciences
• /
• v.17 no.1
• /
• pp.77-84
• /
• 2022

A submarine power cable is a transmission cable for carrying electric power below the surface of the water. Recently, submarine cables transfer power from offshore renewable energy schemes to shore, e.g. wind, wave and tidal systems, and these cables are either buried in the seabed or lie on the ocean floor, depending on their location. Since these power cables are used in the extreme environments, they are made to withstand in harsh conditions and temperatures, and strong currents. However, undersea conditions are severe enough to cause all sorts of damage to offshore cables, these conditions result in cable faults that disrupt power transmission. In this paper, we explore the design criteria for such cables and the procedures and challenges of installation, and cable transfer splicing system. The specification of submarine cable designed with 3 circuits of 154kV which is composed of the existing single circuit and new double circuits, and power capacity of 100MVA per cable line. The determination of new submarine cable burial depth and cable arrangement method with both existing and new cables are studied. We have calculated the permission values of cable power capacity for underground route, the values show the over 100MW per cable line.

• Journal of the Korean GEO-environmental Society
• /
• v.21 no.9
• /
• pp.25-32
• /
• 2020

The underground utilities installed under the ground is an important civil engineering structure, such as water supply and sewerage pipes, underground power lines, various communication lines, and city gas pipes. Such underground utilities can be exposed to risk due to external factors such as concentrated rainfall and vehicle load, and it is important to select and construct an appropriate backfill material. Currently, a method mainly used is to fill the soil around the underground utilities and compact it. But it is difficult to compact the lower part of the buried pipe and the compaction efficiency decreases, reducing the stability of the underground utilities and causing various damages. In addition, there are disadvantages such as a decrease in ground strength due to disturbance of the ground, a complicated construction process, and construction costs increase because the construction period becomes longer, and civil complaints due to traffic restrictions. One way to solve this problem is to use a liquid filler. The liquid filler has advantages such as self-leveling ability, self-compaction, fluidity, artificial strength control, and low strength that can be re-excavated for maintenance. In this study, uniaxial compression strength test and fluidity test were performed to characterize the mixed soil using marine clay, stabilizer, and in-situ soil as backfill material. A freezing-thawing test was performed to understand the strength characteristics of the liquid filler by freezing, and in order to examine the effect of the filling materials on the corrosion of the underground pipe, an electrical resistivity test and a pH test were performed.

• Journal of Environmental Impact Assessment
• /
• v.23 no.5
• /
• pp.353-363
• /
• 2014

The purpose of this study was to investigated the ELF-MF emission level of various environments such as 258 facilities near located to high voltage transmission lines and 120 high voltage transmission lines, 17 underground cable lines. In addition, ELF-MF reduction rate according to separation distance was calculated by using simulations. An appropriate separation distance showing below 4mG was at least 70m. In the case of the appropriate separation distance for 120 high voltage transmission lines, 154kV required 20m of separation distance and 345kV required 60m of separation distance. The simulation results showed that the appropriate separation distance showing below 4mG was 40m and 60m for overhead 154kV and 345kV respectively. To adjust the worst conditions considering the aspects of environmental impact assessment study and the electric power currents that will increase in the future, the appropriate minimum separation distance for HVTL is judged to be above 70m in this study. Thus, there is a need to establish the greenbelt or buffer zone within 70m so as to create an environment in which the receptors are not exposed and thereby eliminate the risk factors of ELF-MF against humans.