• 콘크리트학회논문집
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• 제23권1호
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• pp.99-107
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• 2011

이 연구는 대용량 지상식 LNG 저장탱크에 사용할 고강도 자기충전 콘크리트의 최적배합 조건을 도출하고, 현장적용을 위한 기본 자료를 제안하기 위한 것이다. 60~80 MPa 고강도 자기충전 콘크리트를 적용하면, 벽체두께의 감소와 자기충전성에 따른 인력절감 및 품질확보 등을 통하여 경제성을 확보할 것으로 예상된다. 시멘트 및 분체는 점성 증대 및 수화열 저감에 우수한 플라이애쉬와 저열 시멘트(벨라이트)를 사용하였다. 플라이애쉬의 치환율은 구속수비 및 배합변수 실험을 통해 정하였으며, 배합변수는 단위수량(W), 플라이애쉬 치환율(FA), 물-결합재비(W/B) 및 잔골재율(S/a)로 하여, 최적배합비 및 경제성 평가를 실시하였다. 실험 결과, 설계기준강도 60 MPa의 경우에는 단위수량 165 $kg/m^3$, 플라이애쉬 치환율 20% 및 물-결합재비 27~30%로 나타났으며, 설계기준강도 80 MPa의 경우에는 단위수량 165 $kg/m^3$, 플라이애쉬 치환율 10% 및 물-결합재비 25%로 나타났다. 또한, 기존의 설계기준강도 40 MPa과 비교해 볼 때, 압축강도 증가에 따른 재료비 상승은 60 MPa의 경우 14~22% 및 80 MPa의 경우 33%로 나타나, 현장관리 및 인력절감 등과 함께 매우 경제적인 것으로 나타났다.

• 한국콘크리트학회:학술대회논문집
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• 한국콘크리트학회 2006년도 춘계 학술발표회 논문집(II)
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• pp.85-88
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• 2006

This study describes the optimum mix proportion of the high strength and self-compacting concrete placed in main structures of LNG above tank. This concrete requires high strength level about $60{\sim}80MPa$, low hydration heat, balance between workability and consistency without vibrating in the actual work. For this purpose, low heat portland cement and fly ash are selected and design factors including water-binder ratio, replacement ratio of fly ash are tested. As experimental results, low heat portland cement shows lower the confined water ratio than another cement type and the optimum replacement ratio of fly ash in order to improve properties of the binder-paste shows 10% by cement weight considering test results of the confined water ratio$({\beta}p)$. Also, flowability of the high strength and self-compacting concrete by using fly ash about $10{\sim}20%$ is improved. The replacement ratio of fly ash 10% and water-binder ratio $25{\sim}27%$ are suitable to the design strength 80MPa and cost, In case of the design strength 60MPa, the replacement ratio of fly ash and water-binder ratio show 20% and $25{\sim}30%$ separately. Based on the results of this study, the optimum mix proportions of the high strength and self-compacting concrete will be applied to the construction of LNG above tank as a new type.

• 한국해양공학회지
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• 제32권2호
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• pp.143-150
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• 2018

In this study, we designed and developed an underwater LED communication system composed of an LED and a photo sensor. In addition, we experimented with video data transmission in a water tank. Two communication modules were installed in the 3 m water tank, and the image data transmission test was successfully performed at a rate of 20 frames per second(FPS), image resolution of $480{\times}272$, and data communication speed of 4 Mbps.

• 수산해양기술연구
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• 제5권1호
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• pp.14-20
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• 1969

$\circled1Connecting Spread를 일정하게 하고 Towing Line의 길이를 변화시킬 때 각 속도에 따른 망고 및 망폭 Towing line의 길이가 길어질수록 망고는 높아지고 망폭은 좁아진다. $\circled2$ Towing line의 길이를 일정하게 하고 Connecting Spread를 변화시킬 때 망고 및 망폭은 Connecting Spread가 넓어질 수록 망폭은 넓어지나 망고는 거의 변화가 없다.

• 한국가스학회지
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• 제26권6호
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• pp.9-15
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• 2022

사용 압력 범위에서 고압 수소 탱크의 내구성을 검증하기 위해서는 수압 파열 시험이 수행되어야 한다. 그런데 물의 초기 주입 과정에서 물과 공기의 상호작용에 의해 생성된 기포가 탱크 내벽에 부착되어 잔류할 경우, 가압된 탱크가 파열되는 과정에서 기포의 급격한 압력 변화로 인해 큰 충격과 소음이 유발된다. 따라서 본 연구에서는 단순화된 수식을 통하여 탱크 내벽에 잔류하는 기포를 제거하기 위해 필요한 유속을 예측하였으며, 수소 버스용수소 용기 형상을 기준으로 해당 유속을 유지하기 위한 주입 노즐의 형상을 결정하였다. 또한 입구 압력에 따른 유속 변화를 예측하기 위하여 수치 해석 모델의 개발이 수행되었고, 예측 결과의 타당성을 입증하기 위하여 모형 제작을 통한 실험이 수행되었다. 실험 결과, 탱크 벽면 근처의 유속은 해석모델 예측 값과 유사하게 나타났으며, 입구 압력이 1.5 ~ 5.5 bar 일 경우 제거 가능한 기포의 최소 크기는 약 2.2 ~ 4.6 mm로 예측되었다.

• 대한조선학회논문집
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• 제40권5호
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• pp.1-9
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• 2003

To predict the powering performance of full scale ships from the towing tank tests, resistance, propeller open water and self-propulsion tests are conducted. Model tests inevitably include the experimental error defined as the sum of two types of uncertainties, bias and precision errors. The induced errors in each element of model test are propagated through various routes and correlated with one another. The correlation coefficients are very important in the uncertainty analysis. The coefficient gives a direction(increase or decrease) for a value of error in individual elements. If the coefficient is not used accurately, the error bounds of the individual elements are overestimated or underestimated. In this study, the new methodology is applied to the uncertainty analysis of HMRI's towing tank tests, thus error bounds of each element is suggested and verified by several repetitive experiments.

• 콘크리트학회논문집
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• 제17권2호
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• pp.293-302
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• 2005

This study describes data from determination of the optimum mix proportion and site application of the mass concrete placed in bottom slab and side wall having a large depth and section as main structures of LNG in-ground tank. This concrete requires low heat hydration, excellent balance between workability and consistency because concreting work of LNG in-ground tank is usually classified by under-pumping, adaptation of longer vertical and horizontal pumping line than ordinary pumping condition. For this purpose, low heat Portland cement and lime stone powder as cementitious materials are selected and design factors including unit cement and water content, water-binder ratio, fine aggregate ratio and adiabatic temperature rising are tested in the laboratory and batch plant. As experimental results, the optimum unit cement and water content are selected under $270kg/m^3$ and $l55{\~}l60 kg/m^3$ separately to control adiabatic temperature rising below $30^{\circ}C$ and to improve properties of the fresh and hardened concrete. Also, considering test results of the confined water ratio($\beta$p) and deformable coefficient(Ep), $30\%$ of lime stone powder by cement weight is selected as the optimum replacement ratio. After mix proportions of 5cases are tested and compared the adiabatic temperature rising($Q^{\infty}$, r), tensile and compressive strength, modulus of elasticity, teases satisfied with the required performances are chosen as the optimum mix design proportions of the side wall and bottom slab concrete. $Q^{\infty}$ and r are proved smaller than those of another project. Before application in the site, properties of the fresh concrete and actual mixing time by its ampere load are checked in the batch plant. Based on the results of this study, the optimum mix proportions of the massive concrete are applied successfully to the bottom slab and side wall in LNG in-ground tank.

• 대한조선학회논문집
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• 제48권5호
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• pp.390-395
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• 2011

The main purpose of ice model basin is to assess and evaluate the performance of the Arctic ships and offshore structures because the full-scale tests in ice covered sea are usually very expensive and difficult. There are various ice conditions, such as level ice, brash ice, pack ice and ice ridge, in the real sea. To estimate their capacities in ice tank accurately, an appropriate model ice sheet and prepared ice conditions copied from actual sea ice conditions are needed. Pack ice is a floating ice that has been driven together into a single mass and a mixture of ice fragments of varying size and age that are squeezed together and cover the sea surface with little or no open water. So Ice-class vessels and Icebreaker are usually operated in pack ice conditions for the long time of her voyage. The most ice model tests include the pack ice test with the change of pack ice concentration. In this paper, the effect of pack ice size and channel breadth in pack ice model test is conducted and analyzed. Also we presented some techniques for the calculation of pack ice concentration in the model test. Finally, we developed a new model test methodology of pack ice condition in square type ice tank.

• 한국양식학회지
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• 제13권3호
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• pp.223-230
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• 2000

사육수에 광물미립자를 현탁시켜 노폐물을 흡착, 분해시킨 후 이를 분리, 배출시킴으로서 사육수를 정화시켜 재 사용할 수 있다는 가설 하에 사육수조와 포말분리장치로만 구성된 사육수 재사용 시스템에서 광물미립자를 현탁시켜 넙치를 실험사육 하였다. 두 종류의 가공황토 (processed residual reddish soil, 50 $\mu$ 이하)와 돌로마이트 (dolomite, 50 ${\mu}$이하) 미립자를 사육수에 현탁시키고 포말분리장치로 이를 분리, 배출시킴으로서 사육수를 정화하였다. 직경 4.8 m의 원형사육수조(사육수량 10 $m^2$), 사육수 순환을 시간당 2회전, 재사용을 90%, 수온 17${\pm}$1$^{\circ}C$에서 평균체중 23.1 g의 넙치 치어(5,555마리, 총중량 128 kg)를 75일간 사육하여 평균체중84.6 g (5,532마리, 총중량 468 kg)으로 육성하였다. 최종수용밀도는 26.0 kg/$m^2$였다. 실험기간 동안 어병은 관찰되지 않았다. 사육수에 광물입자를 현탁시켜 사육수 중의 노폐물을 흡착, 분해시킨 후 포말분리장치로 이를 배출시킴으로서 사육수를 정화하여 재사용하는 방법은 새로운 사육수 재사용 어류양식시스템으로서 가능성이 있다.

• 대한조선학회논문집
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• 제41권6호
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• pp.120-125
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• 2004

There are very few numbers of 115K FPP (Fixed Pitch Propulsion) Tankers for the Baltic ice class IA because the minimum power requirement of FMA (Finish- Swedish Maritime Association) needs quite large engine power and the 40 m Beam is out of calculation range of FMA minimum power requirements. The shipyard has no choice except to increase the engine power to satisfy FMA minimum power requirement Rule. And the operation cost, efficiency of hullform and its building cost are not good from the ship owners' point of view To solve this problem, the experience of ice breaking tanker development and the ice tank test results were adopted. The main idea to reduce the ice resistance is by reducing waterline angle at design load waterline. The reason behind the main idea is to reduce the ice-clearing force. Two hull forms were developed to satisfy Baltic Ice class IA. Two ice tank tests and one towing tank test was performed at MARC (Kvaener-Masa Arctic Research Center) and SSMB (Samsung Ship Model Basin) facilities, respectively. The purpose of these tests was to verify the performance in ice and open water respectively The hull form 2 shows less speed loss compared to Hull form 1 in open water operation but hull form 2 shows very good ice clearing ability. finally the Hull Form 2 satisfying Baltic ice class IA. The merit of this hull form is to use the same engine capacity and no major design changes in hull form and other related designs But the hull structure has to be changed according to the ice class grade. The difference in two hull form development methods, ice model test methods and analysis methods of ice model test will be described in this paper.