• 한국주조공학회지
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• 제42권1호
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• pp.61-66
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• 2022

Hydraulic units are important components of agricultural and construction machinery, and thus require high-quality castings. However, gas defects occurring inside the sand cores of the castings due to the resin used is a problem. This study therefore aimed to develop a casting simulation method that can clarify the gas defect positions. Gas defects are thought to be caused by gas generated after the molten metal fills up the mold cavity. The gas constant is the most effective factor for simulating this gas generated from sand cores. It is calculated by gas generating temperature and analysis of composition in the inert gas atmosphere modified according to the mold filling conditions of molten metal. It is assumed that gases generated from the inside of castings remain if the following formula is established. [Time of occurrence of gas generation] + [Time of occurrence of gas floating] > [Time of occurrence of casting surface solidification] The possibility of gas defects is evaluated by the time of occurrence of gas generation and gas floating calculated using the gas constant. The residual position of generated gases is decided by the closed loops indicating the final solidification location in the casting simulation. The above procedure enables us to suggest suitable casting designs with zero gas defects, without the need to repeat casting tests.

• KEPCO Journal on Electric Power and Energy
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• 제8권2호
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• pp.119-126
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• 2022

A growing number of gas-insulated transformers in underground power substations in urban areas are approaching 20 years of operation, the time when failures begin to occur. It is thus essential to prevent failure through accurate condition diagnosis of the given facility. Various solid insulation materials exist inside of the transformers, and the generated decomposition gas may differ for each gas-insulated equipment. In this study, a simulation system was designed to analyze the deterioration characteristics of SF₆ decomposition gas and insulation materials under the conditions of partial discharge and thermal fault for diagnosis of gas-insulated transformers. Degradation characteristics of the insulation materials was determined using an automatic viscometer and FT-IR. The analysis results showed that the pattern of decomposition gas generation under partial discharge and thermal fault was different. In particular, acetaldehyde was detected under a thermal fault in all types of insulation, but not under partial discharge or an arc condition. In addition, in the case of insulation materials, deterioration of the insulation itself rapidly progressed as the experimental temperature increased. It was confirmed that it was possible to diagnose the internal discharge or thermal fault occurrence of the transformer through the ratio and type of decomposition gas generated in the gas-insulated transformer.

• 한국안전학회지
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• 제33권5호
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• pp.28-34
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• 2018

Recently, various engineering approaches have been widely used in the accident investigation field to identify the cause of the accident and to predict damage by accident. Computational analysis is the most commonly used method of accident investigation technique. This technique is mainly used to identify the mechanism of the accident generation and to determine the cause when it is difficult to reproduce the situation at the time of the accident or when it is impossible to perform a reproduction experiment. In this study, The computational fluid dynamics analysis for nitrogen asphyxiation accident generated by defect of building structural between diffusion outlet and cooling tower was performed to determine the inflow path of the suffocation gas, death possibility by concentration of suffocation gas and predicted the time of death due to the accident using 3D modeling and FLACS program. We can quantify diffusion concentration of asphyxiation gas and predict mechanism of death occurrence by accident and evaluate the consequence Analysis through this study. In the future, This method can be widely used in the field of gas safety by improving the reliability and validity of the analysis.

• 한국추진공학회:학술대회논문집
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• 한국추진공학회 2010년도 제35회 추계학술대회논문집
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• pp.369-374
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• 2010

본 연구에서는 가스 연료와 공기 혼합물 내 압력파에 의해 유도되는 화염 가속과 연소폭발천이 현상을 수치적 계산을 통하여 살펴본다. 실험에 기반을 둔 초기 조건 하에서 점성력, 열전단, 몰질량 확산, 그리고 화학 반응을 고려한 reactive compressible Navier-Stokes 방정식을 사용하여 계산을 수행하였다. 반복되는 압력파와 화염의 상호 작용에 의해 발생되는 화염의 Richtmyer-Meshkov (RM) 불안정성에 의해 증가된 화염면을 통하여 생기는 hot spot들에 의한 폭굉의 발생을 모델링하였다. 또한 압력파의 강도 변화에 따른 연소폭발천이 현상의 변화를 살펴보았다.

• 전기학회논문지
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• 제62권9호
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• pp.1297-1301
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• 2013

This paper analyzes of PD occurrence position through an analysis of the arrival time difference between the GIS partial discharge signal. Because of GIS (Gas Insulated Switchgear) is a facility very important power equipment and as part of the equipment that make up the power system, the stabilization of the power industry, which accounted for 88.5% share of GIS substation in the form of a substation is an important equipment for power supply. In the situation where we are gradually expanding the need for preventive diagnosis in order to improve the efficiency of equipment management and failure prevention for Preventive diagnosis. In this paper as a method for extracting pre-defect of failure of GIS Apply the average value method of calculating the 5 times each using a pulse of the first time of the second pulse (${\Delta}t$) with an oscilloscope generation position PD(Partial Discharge). the results of GIS internal inspection, the partial discharge of the actual the position of the partial discharge was confirmed with an accuracy of about 82% of positions. Arrival time difference in the most effective manner if the partial discharge of GIS internal occurs by applying the averaging method and TOA(Time of arrival) method, the partial discharge occurs you through the measurement and analysis of PD signal occurs was confirmed in the experiment are presented and diagnostic methods location tracking.

• 대한방사선치료학회지
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• 제21권2호
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• pp.75-82
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• 2009

목 적: 방사선 치료 시 치료실 내에서 발생하는 오존량을 측정하여 오존 발생으로 인한 오염 정도를 알아보고자 한다. 대상 및 방법: 선형가속기(Clinac 21EX, Varian, USA)와 오존 측정기(series-200, aeroQual, New Zealand)를 이용하여 water phantom (Wellhofer, IBA, Germany)에 방사선을 조사하여 MU, 선량율, 선원-표면간 거리(SSD), 조사야, 에너지, 경과 시간에 따라 발생되는 오존량을 측정 분석하였으며, 실제 환자치료 시 치료실 내에 오존 측정기를 위치하여 일일 오존 변화량을 측정하였다. 결 과: 방사선 발생 중 생성되는 오존의 오염도는 에너지에 따른 영향을 크게 받지 않지만 대체로 광자선보다 전자선 조사 시(0.016~0.028 ppm/hr) 많이 발생하였다. 또한, Dose-Rate가 높을수록(0.016~0.025 ppm/hr), SSD가 멀어지고(0.018~0.030 ppm/hr), 조사야가 넓어지고(0.016~0.025 ppm/hr), MU가 많을수록(0.018~0.046 ppm/hr) 오존 농도가 높아졌다. 시간 경과에 따른 오존의 감소량은 방사선을 조사한 후 10분이 경과된 후부터 background 농도(0.016 ppm/hr)로 변화하였다. 그리고 방사선 치료실 내의 일일 발생하는 오존의 농도는 실내의 오존 허용기준인 0.1 ppm/hr (측정 평균 0.06 ppm/8 hr) 이하이지만, 냄새에 민감한 환자들이 감지할 수 있는 수준인 0.02 ppm/hr 이상의 농도(최대: 0.038 ppm/hr)를 포함하는 것을 확인할 수 있었다. 결 론: 일정한 조건의 변화에 따른 오존 농도를 통하여 실제 치료실 내 오존 발생량은 환자나 작업종사자에 대해 유해한 작용을 미치는 수준은 아니었다. 흔히 오존을 해로운 기체라고 생각하지만 방사선 치료 시 발생되는 미량의 치료실 내 오존은 오히려 병원성 세균이나 바이러스 살균 등의 공기 정화 작용을 함으로써 치료실 내 이로운 오존의 역할을 할 것이라 사료된다.