The Role of Natural Gas Hydrate During Natural Gas Transportation

Merey, Şükrü; Longinos, Sotirios Nik.

doi:10.28948/ngumuh.445410

Cited by 11 publications

(10 citation statements)

References 72 publications

(103 reference statements)

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“…The hydration number is the number of water molecules required per guest methane molecule to form hydrate, and we used the hydration number of 6.1 for calculations based on the literature [ 6 , 7 ]. Hydrate productivity is determined as the normalized rate of hydrate formation calculated for the first 30 min from nucleation (the start of hydrate growth), and is given by Equation (4):

where R 30 is the rate of hydrate growth (mol/s) for the first 30 min after the induction time.…”

Section: Reactor Designmentioning

confidence: 99%

“…Under standard conditions of temperature and pressure, methane hydrates can contain 150–180 v / v , hence they indicate significant gas storage properties [ 3 , 4 ]. The gas hydrates topic has attracted the interest of many researchers from different fields due to its application as an alternative energy resource, which is suitable for gas storage technology and gas transportation, along with separation technology and CO 2 sequestration [ 5 , 6 , 7 , 8 ].…”

Section: Introductionmentioning

confidence: 99%

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Kinetic Analysis of Methane Hydrate Formation with Butterfly Turbine Impellers

et al. 2022

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Heat generation during gas hydrate formation is an important problem because it reduces the amount of water and gas that become gas hydrates. In this research work, we present a new design of an impeller to be used for hydrate formation and to overcome this concern by following the hydrodynamic literature. CH4 hydrate formation experiments were performed in a 5.7 L continuously stirred tank reactor using a butterfly turbine (BT) impeller with no baffle (NB), full baffle (FB), half baffle (HB), and surface baffle (SB) under mixed flow conditions. Four experiments were conducted separately using single and dual impellers. In addition to the estimated induction time, the rate of hydrate formation, hydrate productivity and hydrate formation rate, constant for a maximum of 3 h, were calculated. The induction time was less for both single and dual-impeller experiments that used full baffle for less than 3 min and more than 1 h for all other experiments. In an experiment with a single impeller, a surface baffle yielded higher hydrate growth with a value of 42 × 10−8 mol/s, while in an experiment with dual impellers, a half baffle generated higher hydrate growth with a value of 28.8 × 10−8 mol/s. Both single and dual impellers achieved the highest values for the hydrate formation rates that were constant in the full-baffle experiments.

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where R 30 is the rate of hydrate growth (mol/s) for the first 30 min after the induction time.…”

Section: Reactor Designmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Kinetic Analysis of Methane Hydrate Formation with Butterfly Turbine Impellers

et al. 2022

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“…10−12 The most common method of transporting gas in places inaccessible to the pipeline is considered to be liquefaction, but liquefied gas is not appropriate for long-term storage due to boil-off issues and cryogenic temperature requirements. 13,14 Gas storage in a solid hydrated state (as gas hydrate) is considered environmentally friendly, with excellent safety performance and the feasibility of long-distance transportation and large-scale storage. 15−17 Gas hydrates are nonstoichiometric ice-like compounds formed by trapping methane molecules in hydrogen-bonded water cavities at low temperatures and high-pressure conditions.…”

Section: Introductionmentioning

confidence: 99%

“…By 2040, conventional energy sources are expected to be exhausted, which can lead to an increase in demand for unconventional energy sources. Unconventional energy sources such as gas hydrates, coal bed methane, and shale gas would provide great potential for meeting the demand and resolving the problem with the uncertainties that have arisen due to the increasing level of energy consumption, the limited amount of resources, and increasingly stringent environmental regulations in past years. , However, another important aspect of the world agenda 2020–2030 is the environmental aspect. − According to recent studies by scientists and researchers, natural gas, including gas preserved in a solid hydrate form in the regions of permafrost distribution and under the ocean, is the cleanest developing natural nonrenewable source of energy to date. − Increasing the number and directions of gas imports requires the development of new reliable methods of transporting large volumes of natural gas to cater to energy security, resilience, and redundancy. − The most common method of transporting gas in places inaccessible to the pipeline is considered to be liquefaction, but liquefied gas is not appropriate for long-term storage due to boil-off issues and cryogenic temperature requirements. , Gas storage in a solid hydrated state (as gas hydrate) is considered environmentally friendly, with excellent safety performance and the feasibility of long-distance transportation and large-scale storage. − Gas hydrates are nonstoichiometric ice-like compounds formed by trapping methane molecules in hydrogen-bonded water cavities at low temperatures and high-pressure conditions. In such structures, water molecules are the hosts, and gas molecules are the guests.…”

Section: Introductionmentioning

confidence: 99%

Enhanced Methane Hydrate Formation Kinetics in Frozen Particles of Biopolymer Solutions: Applicable to Methane Storage

Kibkalo,

Pandey,

Pletneva

et al. 2023

Energy Fuels

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Water-soluble polymers have shown dual characteristics either as hydrate promoters (enhanced the rate of gas hydrate formation) or inhibitors (retarded the hydrate formation kinetics). Therefore, in this study, we evaluate the promotional/inhibition effect of the environmentally friendly biodegradable, water-soluble polymers for methane hydrate formation. An unstirred highpressure reactor was used to synthesize methane hydrates of frozen biopolymers. A comparative analysis of the hydrate formation growth for concentrations ranging from 0.1 to 4.0 wt % of the frozen crushed bipolymer was performed. Further, to probe the impact of melting rates of the frozen powder on methane hydrate growth, frozen powdered biopolymers were characterized using the nuclear magnetic relaxation (NMR) spectroscopy method at a temperature of 272.2 K. From the kinetic and NMR experiments, a direct correlation between the transition rate of water to hydrate and the melting rate of frozen powdered biopolymers was established. Furthermore, this study allows us to classify the best biopolymers to enhance the kinetics of hydrate formation. Our findings highlight the promise of engaging biopolymers for solidified natural gas technology to store and transport natural gas.

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“…The drive to switch to an alternative transportation fuel is to reduce the dependency on oil and decrease the pressure on the environment [1][2][3][4][5][6][7][8]. The targets set in the RED by the European Commission are to support the development of biofuels [9][10][11][12][13][14].…”

Section: Introductionmentioning

confidence: 99%

A PESTLE Analysis of Biofuels Energy Industry in Europe

et al. 2019

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Biofuels production is expected to be an intrinsic confluence to the renewable energy sector in the coming years under the European regulations for renewable energy. Key standpoints of the biofuels promotions are the reduction of national carbon emissions and rural deployment. Despite jubilant outlook of biofuels for sustainable development, research efforts still tend to link the biofuel industry and regional growth. The aim of this study is to explore and review the biofuels industry through a socio-political, techno-economic, legal and environmental (PESTLE) analysis approach, and discuss the interrelation between technological facets and sustainable deployment.

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The Role of Natural Gas Hydrate During Natural Gas Transportation

Cited by 11 publications

References 72 publications

Kinetic Analysis of Methane Hydrate Formation with Butterfly Turbine Impellers

Kinetic Analysis of Methane Hydrate Formation with Butterfly Turbine Impellers

Enhanced Methane Hydrate Formation Kinetics in Frozen Particles of Biopolymer Solutions: Applicable to Methane Storage

A PESTLE Analysis of Biofuels Energy Industry in Europe

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