• Title/Summary/Keyword: natural gas hydrate

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Study on Methane Hydrate Formation in Seawater and Pure Water (해수와 순수물에서 메탄 하이드레이트 생성에 대한 연구)

  • Park, Sung-Seek;Kim, Nam-Jin
    • Journal of the Korean Solar Energy Society
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    • v.29 no.4
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    • pp.34-40
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    • 2009
  • $1m^3$ hydrate of pure methane can be decomposed to the maximum of $216m^3$ methane at standard condition. If these characteristics of hydrate are reversely utilized, natural gas is fixed into water in the form of hydrate solid. Therefore, the hydrate is considered to be a great way to transport and store natural gas in large quantity. Especially the transportation cost is known to be 18-24% less than the liquefied transportation. In the present investigation, experiments and theoretical calculation carried out for the formation of methane hydrate in NaCl 3.5wt% solution. The results show that the equilibrium pressure in seawater is more higher than that in pure water, and methane hydrate could be formed rapidly during pressurization if the subcooling is maintained at 9K or above in seawater and 8K or above in pure water, respectively. Also, amount of consumed gas volume in pure water is more higher that in seawater at the same experimental conditions. Therefore, it is found that NaCl acts as a inhibitor.

Excess Pore Water Pressure Calculation Methods due to Gas Hydrate Dissociation (가스 하이드레이트의 해리로 발생하는 간극수압의 계산방법)

  • Park, Sung-Sik
    • Proceedings of the Korean Geotechical Society Conference
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    • 2008.10a
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    • pp.888-892
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    • 2008
  • If gas hydrate dissociates due to natural and/or human activities, it generates large amount of gas and water. Upon gas hydrate dissociation, a generated pore water pressure between soil particles increases and results in the loss of an effective stress and degradation of soil stiffness and strength. In order to predict the generated excess pore water pressure due to gas hydrate dissociation, two methods based on small hydrate concept (SHC) and large hydrate concept (LHC) are proposed. An excess pore water pressure generated by the gas hydrate dissociation in the Storegga Slide was calculated using two proposed methods.

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A Preliminary Study on Submarine Slope Failure of Gas Hydrate-bering Sediments (가스 하이드레이트가 매장된 해저사면의 붕괴에 관한 기초적 연구)

  • Park, Sung-Sik
    • Proceedings of the Korean Geotechical Society Conference
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    • 2008.03a
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    • pp.399-404
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    • 2008
  • The influence of gas hydrate dissociation on submarine slope stability was studied in this paper. Gas hydrates are stable under high pressure and low temperature conditions. Once gas hydrate dissociates due to natural or human activities, it generates large amount of gas and water. During gas hydrate dissociation, a pore pressure between soil particles increases and results in the loss of an effective stress and degradation of soil stiffness. A pore pressures model was proposed to calculated excess pore pressures generated by gas hydrate dissociation at the Storegga Slide. A slope stability analysis for the Storegga Slide using a two dimensional finite difference method was carried out by considering excess pore pressures due to gas hydrate dissociation. Since the excess pore pressure calculated by the proposed method resulted in the considerable loss of stiffness and strength in slope, a submarine slope failure occurred at the Storegga slide was well simulated.

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A Comparative Analysis on characteristics and Manufacture of Methane/Natural Gas Hydrates (메탄/천연가스 하이드레이트의 제조 및 특성 비교 분석)

  • Lee Young-Chul;Cho Byoung-Hak;Baek Young-Soon
    • Journal of the Korean Institute of Gas
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    • v.7 no.3 s.20
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    • pp.32-43
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    • 2003
  • As this paper is observed the phase equilibrium diagram of mono- (methane) and multi-component(natural gas) hydrates, and the hydrate growth behavior is analysed and compared by the experiments during the reaction. The difference of mono and multi-component hydrates is an induction delay time and a plateau region. And the concentration of component of gases is changed during the reaction in multi-component hydrates and the concentration of components is changed during the decomposition of hydrate according to each decomposing rates of gases. At 6 MPa, 276.65 K and 600 rpm, the induction delay time of multi-component hydrate formation is observed shorter than that of mono-component hydrate formation because the hydrate nuclei of gases except methane form faster than those of methane. And the plateau region of mono-component hydrate is observed distinctly at 0.055 mole of $CH_4$/mole of water and that of multi-component hydrate is observed at 0.04 mole of $CH_4$/mole of water.

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Investigation on Formation Behaviors of Synthesized Natural Gas Hydrates (합성 천연가스의 하이드레이트 형성 거동 연구)

  • Lee, Jong-Won;Lee, Ju-Dong
    • Korean Chemical Engineering Research
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    • v.50 no.5
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    • pp.890-893
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    • 2012
  • Gas hydrates are solid crystal structures formed by enclathration of gaseous guest species into 3-dimensional lattice structure of hydrogen-bonded water molecules. These compounds can be potentially used as an energy storage/transportation medium because they can hold a large amount of gas in a small volume of the solid phase. In addition, huge amount of natural gas, buried in seabeds or permafrost region in the form of the solid hydrate, is regarded as a future energy source. In this study, synthesized natural gas, whose composition is 90.0 mol% of methane, 7.0 mol% of ethane, and 3.0 mol% of propane, was used to identify formation behaviors of natural gas hydrates for the purpose of applying the gas hydrate to a storage/transportation medium of natural gas. According to the experimental results obtained by means of the solid-state NMR and high-resolution powder XRD methods, it is found that formed natural gas hydrates have crystal structure of the structure-II hydrate, and that methane occupies both small and large cages, while the others only occupy large ones. In addition, both the NMR spectroscopy and the gas chromatograph showed that there exists preferential occupation among the natural gas components during the hydrate formation. Compositional changes after the hydrate formation revealed that the preferential occupation is in order of propane, ethane, and methane (propane is the most preferential guest species when forming natural gas hydrates).

The Development Prospect for Gas Hydrate as an Energy Source (에너지원으로서의 가스 하이드레이트 개발 전망)

  • Baek Youngsoon;Lee Jeonghwan;Choi Yangmi;Park Seoungmin
    • 한국신재생에너지학회:학술대회논문집
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    • 2005.06a
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    • pp.652-655
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    • 2005
  • Considering the fact that more than $97\%$ of fossil energy resources such as oil and natural gas needed in Korea rely on import, primary concern of the national economy is to secure future energy sources. Gas hydrates. which is non-conventional types of natural gas, distribute worldwide, especially in marine and permafrost Gas hydrates draw great attention recently as a new clean energy resources substituting conventional oil gas due to its presumed huge amount of volume reaching 10 trillion tons of gas and environmentally friendly characteristics. Results of preliminary survey by Korea Gas Corporation (KOGAS) and Korea Institute of Geoscience and Mineral Resources (KIGAM) showed that gas hydrates can be present in deep sea over 1,000m water depth in the East Sea. Gas hydrates can contribute to the rapidly increasing consumption of natural gas in Korea and achieve the self-support target by 2010 with $30\%$ of total natural gas demand. This study presents the potentialities and development prospects of gas hydrate as a future energy source.

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A Study on the Phase Equilibrium Conditions of Mixture Gas Hydrates using CSMHYD (CSMHYD를 이용한 혼합가스 하이드레이트의 상평형에 대한 연구)

  • Seo, Hyang-Min;Park, Yun-Beom;Chun, Won-Gee;Kim, Nam-Jin
    • 한국신재생에너지학회:학술대회논문집
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    • 2007.11a
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    • pp.585-589
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    • 2007
  • Gas hydrate is a special kind of inclusion compound that can be formed by capturing gas molecules to water lattice in high pressure and low temperature conditions. When referred to standard conditions, $1m^3$ solid hydrates contain up to $172Nm^3$ of methane gas, depending on the pressure and temperature of production, Such large volumes make natural gas hydrates can be used to store and transport natural gas. In this study, three-phase equilibrium conditions for forming methane hydrate were theoretically obtained in aqueous single electrolyte solution containing 3wt% Nacl. The results show that Nacl acts as a inhibitor, but help gases such as ethan, propane, i-butane, and n-butane reduce the hydrate formation pressure at the same temperature.

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Phase Equilibrium Conditions of Gas Hydrates for Natural Gas Solid Transportation and Storage (천연가스 고체수송 및 저장을 위한 가스 하이드레이트 상평형 조건에 대한 연구)

  • Jeon, Yong-Han;Kim, Jong-Yoon;Kim, Chong-Bo;Kim, Nam-Jin
    • Korean Journal of Air-Conditioning and Refrigeration Engineering
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    • v.20 no.4
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    • pp.266-273
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    • 2008
  • Natural gas hydrates are ice-like solid substances, which are composed of water and natural gas, mainly methane. They have three kinds of crystal structures of five polyhedra formed by hydrogen-bonded water molecules, and are stable at high pressures and low temperatures. They contain large amounts of organic carbon and widely occur in deep oceans and permafrost regions. Therefore, they are expected as a potential energy resource in the future. Especially, $1m^3$ natural gas hydrate contains up to $172Nm^3$ of methane gas, de pending on the pressure and temperature of production. Such large volumes make natural gas hydrates can be used to store and transport natural gas. In this study, three-phase equilibrium conditions for forming natural gas hydrate were numerically obtained in pure water and single electrolyte solution containing 3 wt% NaCl. The results show that the predictions match the previous experimental values very well, and it was found that NaCl acts as an inhibitor. Also, help gases such that ethane, propane, i-butane, and n-butane reduce the hydrate formation pressure at the same temperature.

n-Pentane & n-Hexane as Coguests of sH Hydrates in the Mixture with 2,2-Dimethylbutane and Methane

  • Lee, Jong-Won;Lu, Hailong;Moudrakovski Igor L.;Ripmeester Christopher I. RatcliffeJohn A.
    • 한국신재생에너지학회:학술대회논문집
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    • 2006.11a
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    • pp.58-61
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    • 2006
  • n-Pentane and n-hexane, previously regarded as non-hydrate formers, are found to form structure H hydrate in mixtures with 2,2-dimethylbutane. Even though they are thought to be too large to fit into the largest cage of the structure H hydrate, powder XRD and NMR measurements show that they form gas hydrates in mixtures with other sH hydrate former. These findings are of fundamental interest and also will impact the composition and location of natural gas hydrates and their potential as global energy resource and climate change materials.

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An overview of R&D for the natural gas hydrate of new energy in the 21st century : a vision of the multi-year project in Korea (21세기 신 에너지 가스 하이드레이트 연구 및 기술개발 현황 : 국내의 중장기 개발 방향)

  • Lee Young Chul;Baek Young Soon;Cho Byoung Hak;Park Ki Whan;Ru Byong Jae
    • The Korean Journal of Petroleum Geology
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    • v.7 no.1_2 s.8
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    • pp.19-27
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    • 1999
  • Korea, an energy-resources-poor country, imports $100{\%}$ of its, oil and, natural gas supply, which accounts for the greater part of its total primary requirements. One of the important task of the government is diversification of available energy resources such as oil and natural gas. Natural gas hydrate, which is non-conventional types of natural gas, distributes worldwide, especially in marine and permafrost. It would become a target of natural gas resources in the near future. Especially sigrificant amount of hydrates are expected to be located in the East Sea around Korea Peninsular. This paper describes about a multi-year overall project framework of basic research and technological development of natural gas hydrate in Korea focused on the interpretation of the seismic survey, the characteristics and physical properties of the natural gas hydrate, and the utilizable technology of natural gas hydrates from the status of research and development of the world.

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