• Proceedings of the Korea Committee for Ocean Resources and Engineering Conference
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• 2002.10a
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• pp.119-123
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• 2002

Liquefied Natural Gas(LNG) continues to attract modern gas industries as well as domestic markets as their main energy source in the recent years. This is mainly because LNG is inherently cleaner and more energy efficiency than other fuels. Offshore LNG production plant is of interest to many oil producing companies all over the world. This article discuss about the production process encountered while developing such a production facility. Typical offshore oil and gas processing required for oil stabilization and other optional units that can be added to the facilities. The production process can broadly be divided into five major units namely, (i) Oil Stabilization unit, (ii) Gas Treatment unit, (iii) Methane Recovery unit, (iv) Distillation unit and (v) LNG Liquefaction unit. The process simulation was carried out for each unit with a given wellhead composition. The topside facilities of offshore LNG production plant will be very similar to the process adopted in offshore processing platform along with the typical onshore LNG production plant. However, the process design problems associated with FPSO motion to be taken care of while developing floating LNG production plant.

• Korean Chemical Engineering Research
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• v.59 no.2
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• pp.200-208
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• 2021

Compare to the gaseous hydrogen, liquid hydrogen has various advantages: easy to transport, high energy density, and low risk of explosion. However, the hydrogen liquefaction process is highly energy intensive because it requires lots of energy for refrigeration. On the other hand, the cold energy of the liquefied natural gas (LNG) is wasted during the regasification. It means there are opportunities to improve the energy efficiency of the hydrogen liquefaction process by recovering wasted LNG cold energy. In addition, hydrogen production by natural gas reforming is one of the most economical ways, thus LNG can be used as a raw material for hydrogen production. In this study, a novel hydrogen production and liquefaction process is proposed by using LNG as a raw material as well as a cold source. To develop this process, the hydrogen liquefaction process using hydrocarbon mixed refrigerant and the helium-neon refrigerant is selected as a base case design. The proposed design is developed by applying LNG as a cold source for the hydrogen precooling. The performance of the proposed process is analyzed in terms of energy consumption and exergy efficiency, and it is compared with the base case design. As the result, the proposed design shows 17.9% of energy reduction and 11.2% of exergy efficiency improvement compare to the base case design.

• 한국신재생에너지학회:학술대회논문집
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• 2009.06a
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• pp.686-686
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• 2009

가스하이드레이트는 수소결합을 하는 물분자의 고체상 격자(Lattice)내에 포집되어 들어가는 기체분자로 구성된 결정화합물로서 외형적인 형태는 얼음과 거의 유사하다. 천연가스 하이드레이트 기술의 최대장점으로는 액화천연가스(LNG)는 초저온인 $-162^{\circ}C$의 저장조건이 필요하지만 천연가스하이드레이트(NGH)기술은 비교적 온화한 조건인 $-15^{\circ}C$에서 천연가스를 고체상태로 저장/이용할 수 있다는 것이다. 천연가스를 $-162^{\circ}C$에서 액화시킨 LNG상태로 생산, 수송, 저장하는 경우보다 고체상태인 NGH(Natural Gas Hydrate)로 만들어서 생산, 수송, 저장할 경우 천연가스의 생산, 수송, 저장, 재가스화 등의 일련의 공정과 비교해볼 때 LNG방법보다 약 24%이상의 경비를 절감을 할 수 있다고 보고되어지고 있다. 따라서, 천연가스의 수송 및 저장기술에서의 탁월한 경제성으로 인해 선진국에서는 가스하이드레이트에 대한 활발한 연구가 진행되고 있다. 특히 일본은 5Ton/Day용량의 NGH 생산플랜트를 건설하여 시운전 중에 있다. NGH기술의 주요 활용분야는 대용량의 가스매장량을 요구하여 LNG공정기술을 적용할 수 없는 중소형가스전 또는 한계가스전에 경제적으로 적용하는 해양수송분야와 천연가스 공급망이 갖춰져 있지 못한 지역에 NGH Pellet형태로 수송/재기화하여 활용하는 내륙운송이 분야가 있다. 국내에서는 지식경제부 국책과제인 ETI(Energy Technology Innovation)사업을 시작으로 국가경쟁력 제고 차원에서 이러한 기술의 기반구촉 및 실증화 사업이 진행되고 있다. 주요 내용으로는 NGH Process Flow, Overall NGH Process concept diagram, NGH Carrier outline, NGH Land Transportation chain 등이 포함되어 있다.

• Korean Chemical Engineering Research
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• v.59 no.3
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• pp.345-358
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• 2021

This study focuses on the development of the liquid air production process that uses LNG (liquefied natural gas) cold energy which usually wasted during the regasification stage. The liquid air can be transported to the LNG exporter, and it can be utilized as the cold source to replace certain amount of refrigerant for the natural gas liquefaction. Therefore, the condition of the liquid air has to satisfy the available pressure of LNG storage tank. To satisfy pressure constraint of the membrane type LNG tank, proposed process is designed to produce liquid air at 1.3bar. In proposed process, the air is precooled by heat exchange with LNG and subcooled by nitrogen refrigeration cycle. When the amount of transported liquid air is as large as the capacity of the LNG carrier, it could be economical in terms of the transportation cost. In addition, larger liquid air can give more cold energy that can be used in natural gas liquefaction plant. To analyze the effect of the liquid air production amount, under the same LNG supply condition, the proposed process is simulated under 3 different air flow rate: 0.50 kg/s, 0.75 kg/s, 1.00 kg/s, correspond to Case1, Case2, and Case3, respectively. Each case was analyzed thermodynamically and economically. It shows a tendency that the more liquid air production, the more energy demanded per same mass of product as Case3 is 0.18kWh higher than Base case. In consequence the production cost per 1 kg liquid air in Case3 was $0.0172 higher. However, as liquid air production increases, the transportation cost per 1 kg liquid air has reduced by $0.0395. In terms of overall cost, Case 3 confirmed that liquid air can be produced and transported with $0.0223 less per kilogram than Base case.

• Journal of the Korean Institute of Gas
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• v.8 no.3 s.24
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• pp.57-62
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• 2004

This study is to assess the safety of the process facilities and fire fighting facilities for LNG storage tank which is the main facility in the LNG receiving terminal. The LNG storage tank(capacity : 140,000kl, type : aboveground, inner tank $9\%$ Ni steel plate, outer tank : prestressed concrete) was designed by foreign country up to now, but it has designed by domestic technology as the fifth in the world is under construction now.

• 한국가스학회:학술대회논문집
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• 2005.05a
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• pp.232-232
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• 2005

• Proceedings of the Korea Society for Energy Engineering kosee Conference
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• 1993.11a
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• pp.57-63
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• 1993

냉열발전기술은 일본에서 많이 연구되어 다수의 상업 플랜트가 가동되고 있다. 일본에서는 천연가스 공급압력의 이원화(40 kgf/$\textrm{cm}^2$, 10 kgf/$\textrm{cm}^2$)로 직접 팽창방식을 적용할 수 있어 냉열발전의 경제성이 유리한 반면 국내에서는 비교적 높은 압력(70kgf/$\textrm{cm}^2$)의 단일 압력 공급체계에 적합한 냉열발전 시스템을 모색하여야 한다. 특히 발전용량 규모가 비교적 적은 냉열발전 시스템의 경제성 측면의 불리한 점을 고려할 때 적용 가능한 해당 발전공정들에 대해 전산모사의 방법을 이용하여 다양한 설계조건에서 최적의 조건들을 검토하여야 한다. 따라서 본 연구에서는 LNG의 저온 Exergy를 이용한 Rankine Cycle, LNG의 압력 Exergy를 이용한 부분팽창 Cycle 및 이 두 싸이클의 혼합 공정인 Linde 공정에 대해 현재 인수기지에서 운영되고있는 각종 설비들의 설계 데이타를 기준으로 상용모사기인 ASPEN PLUS를 이용, 국내 천연가스 공급 체계에 의거 각 공정별 최대 및 최적의 전력 발생 조건들을 검토하였다. 공정별 출력 및 엑서지 효율을 비교한 결과 약 3 ~ 6 Mw의 전력을 생산할 수 있음을 알 수 있었으며 최대 엑서지 효율은 37 %를 얻을 수 있었다. 또한 부분직접팽창방식의 최적시스템을 제시하였고 동일한 전열면적인 경우 부분직접팽창과 랭킨 싸이클의 성능은 비슷한 것으로 확인되었다.

• Journal of the Korean Society of Marine Environment & Safety
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• v.26 no.6
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• pp.732-741
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• 2020

Environmental regulations have recently been strengthened. Consequently, floating LNG(Liquefied Natural Gas) power plants are being developed, which are new power generation plants that generate electricity by utilizing LNG. A floating LNG power plant generates BOG(Boil-Off Gas) during its operation, and the system design of such a plant should be capable of removing or re-liquefying BOG. However, the design of an offshore plant differs according to the marine requirements. Hence, a process simulation model of the BOG re-liquefaction system is needed, which can be continuously modified to avoid designing the floating LNG power plant through trial and error. In this paper, to develop a model appropriate for the floating LNG power plant, a commercial process simulation program was employed. Depending on the presence of refrigerants, various BOG re-liquefaction systems were modeled for comparing and analyzing the re-liquefaction rates and liquid points of BOG. Consequently, the BOG re-liquefaction system model incorporating nitrogen refrigerants is proposed as the re-liquefaction system model for the floating LNG power plant.

• Plant Journal
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• v.9 no.3
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• pp.38-42
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• 2013

Submarine gas fields have focused because of the increasing fuel cost, the environmental regulations, and the safety & NIMBY problems. LNG-FPSO which is available for acid gas removal, recovery of the condensate & LPG and Liquefaction in topside process is one of high technology offshore structures. On the other hands, it is necessary to verify the pre-treatment efficiency by the ship motion and to apply to the design for LNG-FPSO. This study is to develop the pre-treatment technology for LNG-FPSO as taking account to the process efficiency by ship motion effects and the area optimization. Based on the simulation results, it founds that hybrid process shows the low circulate rate, the low heat duty and the small size of column dimensions compared to typical amine process. It will be verified the process efficiency in the various conditions by sea states as performing the 6-DOF motion test and CFD simulation.

• Journal of the Korean Institute of Gas
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• v.23 no.1
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• pp.41-46
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• 2019

LNG is supplying to consumers as gas phase vaporized by major seawater vaporizer, i.e.. open rack vaporizers. But as soon as the temperature of seawater drops below $5^{\circ}C$ in winter, the submerged evaporators should be operated and cause a lot of energy consumption because of their natural gas combustion. In order to reduce the consumption amount, in this study new two-way supplying method of seawater instead of the present one-way supplying system is introduced and analysed the technical possibilities and economical savings. The results showed that in case of the temperature of seawater becomes below $2.5^{\circ}C$, LNG can be evaporated using ORV without operating S MV. If this system is applied in Incheon LNG terminal, the energy saving reaches 11,770 Ton of LNG as 11,760 million won. By the analysis, the two-way supplying system of seawater in ORV can be the most effective method to be able to save huge amount of energy every year.