• 한국전기전자재료학회:학술대회논문집
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• 한국전기전자재료학회 2002년도 하계학술대회 논문집
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• pp.406-409
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• 2002

The primary insulation system used in an oil-filled transformer is Kraft paper, wood, porcelain and, of course, oil. Modern transformers use paper that is chemically treated to improve its tensile strength properties and resistance to aging caused by immersion in oil. These insulation papers are mainly aged to thermal stress. Over the course of the insulation paper and oil's life it is exposed to high temperatures, oxygen and water. Its interaction with the steel of the tank and core plus the copper and aluminium of the windings will eventually cause the chemical properties of the oil to decay. High temperature have an effect on mechanical strength of cellulous paper using the layer insulation. We made two aging cell in which thermal aging tests of insulation papers and mineral oil are conducted. It is measured dielectric strength, number of acid, moisture, etc. of insulation paper and oil aged in the aging cells.

• 대한조선학회논문집
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• 제33권4호
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• pp.97-105
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• 1996

선체 중량이 최소가 되는 설계를 수행하기 위해서는 선체 중량이 최소가 되는 tank 배치의 결정이 선행되어야 하며, 결정된 tank 배치 내에서 선체 중량이 최소가 되는 구조 부재의 배치 및 치수를 결정하여야 한다. 선체 중량이 최소가 되는 tank 배치를 하기 위하여 저자들에 의해 개발된 선급 규정에 의한 종강도 부재의 최소 중량 설계 프로그램과 일반화 경사처짐법에 의한 횡강도 부재의 최소 중량 설계 프로그램을 결합하여 화물창부의 선각 중량을 구하였으며, 중량 추정 공식에 의해 횡격벽 및 선수미부 등의 중량을 구함으로서 선체 전체의 최소 중량 설계 프로그램을 개발하였다. 본 연구에서는 tank의 개수, web의 개수 및 종격벽의 위치 변화에 따른 선각 중량 변화를 알아보았으며, 실선 설계에 적용하고자 MARPOL을 만족하는 다양한 tank 배치를 결정하고 선체 전체의 최소 중량 설계를 수행하여 이들 중 선각 중량이 작게 되는 tank 배치를 구하였으며 실적선의 선각 중량과 비교 검토하였다.

• 수산해양기술연구
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• 제18권1호
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• pp.17-23
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• 1982

한국국적의 유조선 35척의 외판 및 격벽의 부식도를 선령별로 조사한 결과를 요약하면 다음과 같다. 1. 선령 12년급의 외판의 평균부식도는 경흘수선 및 하부 만곡부선에서는 선수부가, 건현 및 상부만곡부선에서는 중앙부가, 양재흘수선에서는 선미부가 가장 높다. 2. 선령 20년급의 외판의 평균부식도는 경흘수선 및 상.하부만곡부선에서는 선수부가, 건현중앙선에서는 중앙부가, 만재 흘수선에서는 선미부가 가장 높다. 3. 측수조와 중앙유조의 횡격벽의 평균부식도는 어느 선령에서나 정부선, 상부선, 중앙선에서는 측수조가 높고, 하부선과 저부선에서는 중앙유조가 높다. 4. 중앙유조와 양측 유조의 횡격벽부식도 어느 선령에서나 중앙유조의 횡격벽 쪽이 높다. 5. 중앙유조의 종.횡격벽의 부식도는 격벽의 중앙선상부에서는 어느 선령에서나 종벽부 쪽이 높다. 6. 내부수조 및 중앙유조의 횡격벽과 같은 높이에 있는 선각외판의 건현부의 평균부식도를 비교하면, 격벽상부의 부식도가 외판의 그것보다 크다.

• 한국전기전자재료학회논문지
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• 제16권12호
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• pp.1136-1141
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• 2003

The primary insulation materials used in an oil filled transformer are kraft paper, wood, porcelain and oil. Modern transformers use chemically treated paper to improve its tensile strength and resistance to aging caused by immersion in oil. But these insulation papers are mainly aged by thermal stress. Over the life time of the insulation paper and oil, it is exposed to high temperatures, oxygen and water. Its interaction with the steel of the tank and core plus the copper and aluminium of the windings will eventually cause the chemical properties of the oil to decay. High temperature have an effect on mechanical strength of cellulous paper used in the layer insulation. We made two aging cells in which insulation papers and mineral oil are conducted to test thermal properties. It is measured dielectric strength, number of acid, moisture, etc. of insulation paper and oil aged in the aging cells.

• 한국해양공학회지
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• 제15권2호
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• pp.1-5
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• 2001

A study on the new active type oil-water separation system including the oil-water separation system of magnetic film was carried out. Separation system is composed of several active types of circulating oil separation steps and one magnetic film separation step at final stage. At the magnetic separation step, ferrofluid easily forms a weak magnetic mixture with oil, which is from the water by magnetic field gradient. The vessel has been designed to run at the maximum speed of 25 knots. And two typical forms of SWATH and Catamaran have been studied as a new type of oil recovery vessel.

• 한국해양공학회지
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• 제35권6호
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• pp.393-402
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• 2021

As greenhouse gas emissions from maritime transport are increasing, the International Maritime Organization is continuously working to strengthen emission regulations. Liquefied natural gas (LNG) fuel is less advantageous as a point of CO₂ reduction due to the methane leakage that occurs during the bunkering and operation of marine engines. In this study, greenhouse gas emissions from an LNG-fueled ship were analyzed from the perspective of the life cycle. The amount ofmethane emission during the bunkering and operation procedures with various boil-off gas (BOG) treatment methods and gas engine specifications was analyzed by dynamic simulation. The results were also compared with those of other liquid fuel engines. As a result, small LNG-fueled ships without a BOG treatment facility emitted 32% more greenhouse gas than ships utilizing marine gas oil or heavy fuel oil. To achieve a greenhouse gas reduction via a BOG treatment method, a gas combustion unit or re-liquefaction system must be mounted, which results in a greenhouse gas reduction effect of about 25% and 30%. As a result of comparing the amount of greenhouse gas generated according to the BOG treatment method used with each tank size from the perspective of the operating cycle with the amounts from using existing marine fuels, the BOG treatment method showed superior effects of greenhouse gas reduction.

• 드라이브 ㆍ 컨트롤
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• 제18권2호
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• pp.32-37
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• 2021

The piston reservoir is mainly used in hydraulic blow-down system for aerospace engineering. The reservoir is heavy due to both hydraulic cylinder and piston in pressurization. The positive expulsion tank with rubber diaphragm has been mostly applied propellant and fuel tank at low pressure to satellites. To reduce weight, the reservoir that can be used at high pressure with rubber diaphragm was developed. In this research, the prediction of life-time for the rubber diaphragm was implemented through an accelerated life test, as a part of development of new reservoir. Also, the diaphragm was stored in an temperature chamber at the same condition as and operation with hydraulic oil. As a result, the life-time for a rubber diaphragm was successfully evaluated via Arrhenius law and Time-Temperature Superposition based on failure times over temperatures in the accelerated test.

• 한국소음진동공학회논문집
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• 제12권3호
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• pp.195-203
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• 2002

In the engine room and the aft part areas of the ship, there exist so many tank structures contacting with fresh water or sea water or oil. If these structures exhibit excessive vibrations during the sea trials, it takes a lot of cost, time and effort to improve vibration situation because the reinforcement work requires emptying the fluid out of the tanks, additional welding and special painting. It is therefore very important to predict a precise vibration characteristics of the tank structures at the design stage, however it is not easy to estimate vibration characteristics of the structures because of difficulties for accurate evaluation of the added (or virtual) mass effect due to the fluid inside the tank. In this paper, numerical and experimental approaches have been performed to present same fundamental data necessary for anti-vibration design of tank structures contacting with fluid, by investigating vibration behaviors of rectangular tank structure for various water depths.

• 한국화재소방학회:학술대회논문집
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• 한국화재소방학회 2001년도 추계학술대회 논문집
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• pp.92-99
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• 2001

• 한국기계가공학회지
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• 제20권7호
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• pp.48-57
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• 2021

The main research content of this paper is to evaluate the structural integrity and the cooling performance of 4250 kVA power transformer with ONAN(Oil Natural and Air Natural) mode. The dynamic analysis is used to verify the structural safety of the transformer by seismic loading. The transformer structure is simplified and NX software is used to build a three-dimensional model, and ANSYS commercial software is used to calculate the stress and deformation by applying corresponding load. The analysis result was evaluated whether it satisfies the design requirements according to the IEEE Std 693 standard. In terms of thermal analysis to evaluate the cooling performance, the thermal physical model is used to calculate the heat exchange between the radiator and the tank in the steady state, and the result is input into the Fluent software to calculate the internal temperature field of the transformer tank, which reduces the calculation cost of thermal fluid. Comparing the simulated hot spot temperature and top oil temperature of the transformer with the calculation results of the IEC60076 classic model, it is found that the error is only 1.9%.