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1. Self-adaptive gas flow and phase change behaviors during hydrate exploitation by alternate injection of N2 and CO2.

Author

Bo-Jian Cao, Yi-Fei Sun, Hong-Nan Chen, Jin-Rong Zhong, Ming-Long Wang, Ming Wang, Chang-Yu Sun, and Guang-Jin Chen

Subjects
*GAS flow, *GAS mixtures, *NITROGEN, *GAS reservoirs, *GAS injection, *GAS condensate reservoirs, *GAS seepage
Abstract

Since hydrate resources play a part of the stratigraphic framework structure in sediments, establishing a safe and economic method for hydrates exploitation remains the primary challenge to this day. Among the proposed methods, the spontaneous displacement of CH4 from hydrate cages by CO2 seems to be a perfect mechanism to address gas production and CO2 storage, especially in today's strong demand for carbon reduction and replacing clean energy. After extensive lab researches, in the past decade, injecting a mixture of CO2 and small molecule gas has become a key means to enhance displacement efficiency and has great potential for application. However, there is a lack of in-depth research on gas flow in the reservoir, while the injected gas always passes through low-saturated hydrate areas with high permeability and then occurs gas channel in a short term, finally resulting in the decreases in gas production efficiency and produced gas quality. Therefore, we explored a new injection-production mode of alternate injection of N2 and CO2 in order to fully coordinate the advantages of N2 in enhanced hydrate decomposition and CO2 in solid storage and heat compensation. These alternate "taking" and "storing" processes perfectly repair the problem of the gas channel, achieving self-regulation effect of CH4 recovery and CO2 storage. The 3-D experimental results show that compared to the mixed gas injection, CH4 recovery is increased by >50% and CO2 storage is increased by >70%. Additionally, this alternate injection mode presented a better performance in CH4 concentration of produced gas and showed outstanding N2 utilization efficiency. Further, we analyzed its self-adaptive gas flow mechanism and proposed an application model of "one injection and multiple production". We look forward to this study accelerating the application of CO2-CH4 replacement technology. [ABSTRACT FROM AUTHOR]

Published
2024
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2. Self-adaptive gas flow and phase change behaviors during hydrate exploitation by alternate injection of N2 and CO2.

Author

Bo-Jian Cao, Yi-Fei Sun, Hong-Nan Chen, Jin-Rong Zhong, Ming-Long Wang, Ming Wang, Chang-Yu Sun, and Guang-Jin Chen

Subjects
GAS flow, GAS mixtures, NITROGEN, GAS reservoirs, GAS injection, GAS condensate reservoirs, GAS seepage
Abstract

Since hydrate resources play a part of the stratigraphic framework structure in sediments, establishing a safe and economic method for hydrates exploitation remains the primary challenge to this day. Among the proposed methods, the spontaneous displacement of CH4 from hydrate cages by CO2 seems to be a perfect mechanism to address gas production and CO2 storage, especially in today's strong demand for carbon reduction and replacing clean energy. After extensive lab researches, in the past decade, injecting a mixture of CO2 and small molecule gas has become a key means to enhance displacement efficiency and has great potential for application. However, there is a lack of in-depth research on gas flow in the reservoir, while the injected gas always passes through low-saturated hydrate areas with high permeability and then occurs gas channel in a short term, finally resulting in the decreases in gas production efficiency and produced gas quality. Therefore, we explored a new injection-production mode of alternate injection of N2 and CO2 in order to fully coordinate the advantages of N2 in enhanced hydrate decomposition and CO2 in solid storage and heat compensation. These alternate "taking" and "storing" processes perfectly repair the problem of the gas channel, achieving self-regulation effect of CH4 recovery and CO2 storage. The 3-D experimental results show that compared to the mixed gas injection, CH4 recovery is increased by >50% and CO2 storage is increased by >70%. Additionally, this alternate injection mode presented a better performance in CH4 concentration of produced gas and showed outstanding N2 utilization efficiency. Further, we analyzed its self-adaptive gas flow mechanism and proposed an application model of "one injection and multiple production". We look forward to this study accelerating the application of CO2-CH4 replacement technology. [ABSTRACT FROM AUTHOR]

Published
2024
Full Text
View/download PDF

6. Gas hydrate exploitation using CO2/H2 mixture gas by semi-continuous injection-production mode

Author

Jin-Rong Zhong, Chang-Yu Sun, Yi-Fei Sun, Guang-Jin Chen, Wen-Zhi Li, Bo-Jian Cao, Jing-Yu Kan, Rui Li, and Yun-Fei Wang

Subjects
Work (thermodynamics), Materials science, 020209 energy, Mechanical Engineering, Clathrate hydrate, Analytical chemistry, 02 engineering and technology, Building and Construction, Management, Monitoring, Policy and Law, Carbon sequestration, Decomposition, Steam reforming, General Energy, 020401 chemical engineering, Volume (thermodynamics), 0202 electrical engineering, electronic engineering, information engineering, Gas composition, 0204 chemical engineering, Hydrate
Abstract

The CO2 replacement technique is considered as a promising approach for both gas hydrate recovery and CO2 sequestration. Based on this technique, the continuous CO2/H2 injection-production mode had been studied in our previous work. However, there are limitations on this continuous mode, such as lower CH4 recovery and CO2 sequestration ratios, lower CH4 concentration in produced gas and higher injection-production ratio caused by the fast breakthrough of injected gas. Here we proposed a so called semi-continuous injection-production mode, in which continuous injection-production process is interrupted periodically by stopping injection and production operations for letting injected gas diffuse sufficiently, delaying its breakthrough and increasing its effective sweep region. A series of experimental simulations were performed with respect to this mode in a three-dimensional simulator with a volume of 10.6 L. The results indicated that for the injected gas with low CO2 concentration, the CH4 recovery and concentration in the produced gas could be enhanced dramatically by the semi-continuous gas injection method. Additionally, the fast decomposition stage of CH4 hydrate could be retained separately in the replacement process, thereby effectively improving production efficiency. However, the corresponding CH4 concentration in the produced gas decreased and the injection production ratio increased. Notably, the process combining the CH4 steam reforming with cyclic injection-production was first simulated. The results showed an excellent CO2 storage capability and CH4 hydrate recovery ratio, which was mainly controlled by the gas composition of the re-injected gas. Through systematically comparing and analyzing the CH4 concentration, recovery ratio, production efficiency and injection-production ratio, it is demonstrated that the semi-continuous injection-production mode is superior to the continuous one. The results obtained in this work are of significance for guiding future NGHs exploitation.

Published
2019

7. A new approach to efficient and safe gas production from unsealed marine hydrate deposits

Author

Yi-Fei Sun, Jin-Rong Zhong, Guang-Jin Chen, Daoyi Chen, Bo-Jian Cao, and Rui Li

Subjects
Petroleum engineering, business.industry, 020209 energy, Mechanical Engineering, Clathrate hydrate, Subsidence, 02 engineering and technology, Building and Construction, Management, Monitoring, Policy and Law, Produced water, General Energy, 020401 chemical engineering, Cabin pressurization, Natural gas, 0202 electrical engineering, electronic engineering, information engineering, Environmental science, Seawater, 0204 chemical engineering, Hydrate, business, Seabed
Abstract

The exploitation of unsealed marine hydrate deposits is of greater commercial value, but also more challenging because of the risks of the invading of huge body of sea water and subsidence of the seabed. In this work, we proposed a new method to recover natural gas from the usealed hydrate deposits saturated with water by pressure-retaining gas (CO2 + H2) injection. A series of experimental simulations was performed to prove its feasibility through establishing a highly simulated unsealed marine hydrate-bearing sediments system. The results demonstrated that overlying water invading was almost completely inhibited for the pressure-retaining approach while unimpeded for the simple depressrization process. Further, we designed a temporary depressurization process before gas injection to establish a flow field for gas in the sediments. This combined operation effectively enhanced the migration and spread of the injected gas, eventually increasing gas recovery ratio from 25% to 60% while the produced water/gas ratio remains as low as 12.6 ST kg/m3. Additionally, it is proved that the balance between CO2 sequestered and CH4 recovered could be achieved, which was an excellent support for reservoir stability. The combination method realized a higher CH4 concentration in the produced gas and a lower injection-production ratio, which greatly reduced the costs of gas injection and subsequent treatment of produced gas. For comparison, similar simulation work was also performed with respect to sealed gas-rich hydrate-bearing sediments. Overall, this temporary depressurization aided pressure-retaining gas injection approach is very promising for high efficient and safe exploitation of marine hydrtates.

Published
2021

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