海洋深水钻井含可燃冰地层物性响应大尺寸高仿真实验

周珂锐; 郑明明; 王凯; 李可赛; 王晓宇; 陈禺树; 刘天乐; 吴祖锐

doi:10.3799/dqkx.2022.180

Volume 49 Issue 11

Nov. 2024

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Article Navigation > Earth Science > 2024 > 49(11): 4098-4111

Zhou Kerui, Zheng Mingming, Wang Kai, Li Kesai, Wang Xiaoyu, Chen Oushu, Liu Tianle, Wu Zurui, 2024. Large Scale and High Simulation Experimental Study on Physical Property Response of Combustible Ice Formation in Offshore Deepwater Drilling. Earth Science, 49(11): 4098-4111. doi: 10.3799/dqkx.2022.180

Citation:

Zhou Kerui, Zheng Mingming, Wang Kai, Li Kesai, Wang Xiaoyu, Chen Oushu, Liu Tianle, Wu Zurui, 2024. Large Scale and High Simulation Experimental Study on Physical Property Response of Combustible Ice Formation in Offshore Deepwater Drilling. Earth Science, 49(11): 4098-4111. doi: 10.3799/dqkx.2022.180

Citation:

Zhou Kerui, Zheng Mingming, Wang Kai, Li Kesai, Wang Xiaoyu, Chen Oushu, Liu Tianle, Wu Zurui, 2024. Large Scale and High Simulation Experimental Study on Physical Property Response of Combustible Ice Formation in Offshore Deepwater Drilling. Earth Science, 49(11): 4098-4111. doi: 10.3799/dqkx.2022.180

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Large Scale and High Simulation Experimental Study on Physical Property Response of Combustible Ice Formation in Offshore Deepwater Drilling

doi: 10.3799/dqkx.2022.180

Zhou Kerui^{1
,
,},
Zheng Mingming^{1, 2
,
,
,},
Wang Kai¹,
Li Kesai¹,
Wang Xiaoyu¹,
Chen Oushu¹,
Liu Tianle³,
Wu Zurui¹

1.
State Key Laboratory of Geohazard Prevention and Geoenvironment Protection, Chengdu University of Technology, Chengdu 610059, China
2.
Key Laboratory of Gas Hydrate, Guangzhou Institute of Energy Conversion, Chinese Academy of Sciences, Guangzhou 510640, China
3.
Engineering Research Center of Rock-Soil Drilling & Excavation and Protection, Ministry of Education, China University of Geosciences, Wuhan 430074, China

Received Date: 2022-05-10
Publish Date: 2024-11-25

Abstract

Abstract

When deep water drilling meets combustible ice formation, the invasion of drilling fluid accompanied by mass and heat transfer will have an important impact on the mechanical stability of the formation near the wellbore, changing the physical properties of the formation, and affecting the quality and accuracy of subsequent well logging. To address the problem, this paper takes the Gulf of Mexico Gas Hydrate Joint Industry Project (JIP) as the research object. Firstly, the artificial formation skeleton with physical parameters close to the actual is prepared by pressing cementation method. Then, the physical property response law of the formation near the wellbore during the invasion of drilling fluid under the conditions of in-situ reservoir geology and drilling technology is experimentally studied, and the effects of mass transfer and heat transfer behavior on formation temperature, pressure and resistivity are analyzed. The influence mechanism of temperature difference and pressure difference is obtained, and the functional relationship between invasion depth and time is established. The results show that the porosity and resistivity of the artificial reservoir skeleton optimized by orthogonal test are very close to those of the in-situ formation, with the difference of 1.29% and 4.0% respectively. The influence range of pressure is much faster than that of temperature and resistivity, and their influence range has a strong mathematical relationship with time. The decomposition of hydrate occurs successively with the increase of invasion depth, which is manifested in the change of resistivity. The free gas and water produced by decomposition migrate to the deeper, which is easy to reform hydrate in the area between the temperature and pressure variation range, showing a highly saturated hydrate zone. In the range of formation fracture pressure, the positive differential pressure plays a positive role in maintaining the stability of hydrate phase, which is conducive to the stability of near wellbore formation, while the effect of temperature difference is just the opposite. In the process of field drilling, the impact on the formation can be reduced by increasing the density and salinity of drilling fluid, reducing the filtration loss and adding inhibitors. The 12 hours resistivity variation depth is about 0.65 m. Therefore, in order to obtain the resistivity data of undisturbed hydrate reservoir during resistivity logging, the time interval between drilling and logging should be reduced. Logging while drilling or logging methods with appropriate detection depth, such as non-shallow lateral logging, can be used.
- deep water drilling,
- combustible ice,
- large scale and high simulation experiment,
- drilling fluids,
- physical properties response of the formation,
- resistivity logging,
- geological engineering

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References(50)

References

Allshorn, S. L., Dawe, R. A., Grattoni, C. A., 2019. Implication of Heterogeneities on Core Porosity Measurements. Journal of Petroleum Science and Engineering, 174: 486-494. https://doi.org/10.1016/j.petrol.2018.11.045

Archie, G. E., 1942. The Electrical Resistivity Log as an Aid in Determining Some Reservoir Characteristics. Journal of Petroleum Technology, 5: 1-8. https://doi.org/10.2118/942054⁃G

Boswell, R., Schoderbek, D., Collett, T. S., et al., 2017. The Iġnik Sikumi Field Experiment, Alaska North Slope: Design, Operations, and Implications for CO₂⁃CH₄ Exchange in Gas Hydrate Reservoirs. Energy & Fuels, 31(1): 140-153. https://doi.org/10.1021/acs.energyfuels.6b01909

Chen, Z. R., Li, Y. H., Chen, C., et al., 2021. Aggregation Behavior of Asphalt on the Natural Gas Hydrate Surface with Different Surfactant Coverages. The Journal of Physical Chemistry C, 125(30): 16378-16390. https://doi.org/10.1021/acs.jpcc.1c01747

Chong, Z. R., Yang, S. H. B., Babu, P., et al., 2016. Review of Natural Gas Hydrates as an Energy Resource: Prospects and Challenges. Applied Energy, 162: 1633-1652. https://doi.org/10.1016/j.apenergy.2014.12.061

Cook, A. E., Goldberg, D. S., Malinverno, A., 2014. Natural Gas Hydrates Occupying Fractures: A Focus on Non⁃Vent Sites on the Indian Continental Margin and the Northern Gulf of Mexico. Marine and Petroleum Geology, 58: 278-291. https://doi.org/10.1016/j.marpetgeo.2014.04.013

Dai, J. C., Banik, N., Gillespie, D., et al., 2008. Exploration for Gas Hydrates in the Deepwater, Northern Gulf of Mexico: Part II. Model Validation by Drilling. Marine and Petroleum Geology, 25(9): 845-859. https://doi.org/10.1016/j.marpetgeo.2008.02.005

Fang, C. L., Zheng, M. M., Lu, H. Z., et al., 2018. A Simplified Method for Predicting the Penetration Distance of Cementing Slurry in Gas Hydrate Reservoirs around Wellbore. Journal of Natural Gas Science and Engineering, 52: 348-355. https://doi.org/10.1016/j.jngse.2018.01.042

Lee, M. W., Collett, T. S., Lewis, K. A., 2012. Anisotropic Models to Account for Large Borehole Washouts to Estimate Gas Hydrate Saturations in the Gulf of Mexico Gas Hydrate Joint Industry Project Leg II Alaminos Canyon 21 B Well. Marine and Petroleum Geology, 34(1): 85-95. https://doi.org/10.1016/j.marpetgeo.2011.06.010

Li, J. F., Ye, J. L., Qin, X. W., et al., 2018. The First Offshore Natural Gas Hydrate Production Test in South China Sea. China Geology, 1(1): 5-16. https://doi.org/10.31035/cg2018003

Li, L. J., Luo, Y. J., Peng, J. M., et al., 2019. Theoretical Analysis of the Influence of Drilling Compaction on Compressional Wave Velocity in Hydrate⁃Bearing Sediments. Energy Science & Engineering, 7(2): 420-430. https://doi.org/10.1002/ese3.284

Li, S. X., Li, S., Zheng, R. Y., et al., 2021. Strategies for Gas Production from Class 2 Hydrate Accumulations by Depressurization. Fuel, 286: 119380. https://doi.org/10.1016/j.fuel.2020.119380

Li, S. X., Wang, W., Chen, Y. M., et al., 2011. Experimental Study on Influence Factors of Hot⁃Brine Stimulation for Dissociation of Ngh in Porous Medium. Marine Geology Frontiers, 27(6): 49-54 (in Chinese with English abstract).

Liu, L. G., 2012. Experiment Study of Different Saturated Methane Hydrates Exploitation. Dalian University of Technology, Dalian (in Chinese with English abstract).

Liu, L. P., Sun, Z. L., Zhang, L., et al., 2019. Progress in Global Gas Hydrate Development and Production as a New Energy Resource. Acta Geologica Sinica⁃English Edition, 93(3): 731-755. https://doi.org/10.1111/1755⁃6724.13876

Liu, T. L., Li, L. X., Jiang, G. S., et al., 2015. A New Drilling Fluid for Drilling in Marine Gas Hydrate Bearing Sediments. Earth Science, 40(11): 1913-1921 (in Chinese with English abstract).

Malagar, B. R. C., Lijith, K. P., Singh, D. N., 2019. Formation & Dissociation of Methane Gas Hydrates in Sediments: A Critical Review. Journal of Natural Gas Science and Engineering, 65: 168-184. https://doi.org/10.1016/j.jngse.2019.03.005

Ning, F. L., Zhang, K. N., Wu, N. Y., et al., 2013. Invasion of Drilling Mud into Gas⁃Hydrate⁃Bearing Sediments. Part I: Effect of Drilling Mud Properties. Geophysical Journal International, 193(3): 1370-1384. https://doi.org/10.1093/gji/ggt015

Ren, J. F., Sun, M., Han, B., 2021. A Giant Submarine Landslide and Its Triggering Mechanisms on the Nansha Trough Margin, South China Sea. Earth Science, 46(3): 1058-1071 (in Chinese with English abstract).

Ruppel, C., Boswell, R., Jones, E., 2008. Scientific Results from Gulf of Mexico Gas Hydrates Joint Industry Project Leg 1 Drilling: Introduction and Overview. Marine and Petroleum Geology, 25(9): 819-829. https://doi.org/10.1016/j.marpetgeo.2008.02.007

Sloan, E. D., 2003. Clathrate Hydrate Measurements: Microscopic, Mesoscopic, and Macroscopic. The Journal of Chemical Thermodynamics, 35(1): 41-53. https://doi.org/10.1016/S0021⁃9614(02)00302⁃6

Song, Y. C., Wang, S. J., Cheng, Z. C., et al., 2021. Dependence of the Hydrate⁃Based CO₂ Storage Process on the Hydrate Reservoir Environment in High⁃Efficiency Storage Methods. Chemical Engineering Journal, 415: 128937. https://doi.org/10.1016/j.cej.2021.128937

Sun, J. X., Ning, F. L., Lei, H. W., et al., 2018. Wellbore Stability Analysis during Drilling through Marine Gas Hydrate⁃Bearing Sediments in Shenhu Area: A Case Study. Journal of Petroleum Science and Engineering, 170: 345-367. https://doi.org/10.1016/j.petrol.2018.06.032

Sun, K. M., Wang, T. T., Zhai, C., et al., 2018. Heating Decomposition Interface of Natural Gas Hydrate with Different Saturations. Special Oil & Gas Reservoirs, 25(5): 129-134 (in Chinese with English abstract).

Sun, X., Luo, T. T., Wang, L., et al., 2019a. Numerical Simulation of Gas Recovery from a Low⁃Permeability Hydrate Reservoir by Depressurization. Applied Energy, 250: 7-18. https://doi.org/10.1016/j.apenergy.2019.05.035

Sun, X., Wang, L., Luo, H., et al., 2019b. Numerical Modeling for the Mechanical Behavior of Marine Gas Hydrate⁃Bearing Sediments during Hydrate Production by Depressurization. Journal of Petroleum Science and Engineering, 177: 971-982. https://doi.org/10.1016/j.petrol.2019.03.012

Timothy, J., Kneafsey, George, J., 2014. Moridis. X⁃Ray Computed Tomography Examination and Comparison of Gas Hydrate Dissociation in NGHP⁃01 Expedition (India) and Mount Elbert (Alaska) Sediment Cores: Experimental Observations and Numerical Modeling. Marine and Petroleum Geology, 58: 526-539. https://doi.org/10.1016/j.marpetgeo.2014.06.016

Waite, W. F., Kneafsey, T. J., Winters, W. J., et al., 2008. Physical Property Changes in Hydrate⁃Bearing Sediment Due to Depressurization and Subsequent Repressurization. Journal of Geophysical Research: Solid Earth, 113(B7): 1978-2012. https://doi.org/10.1029/2007jb005351

Wang, L., Sun, X., Shen, S., et al., 2021a. Undrained Triaxial Tests on Water⁃Saturated Methane Hydrate⁃Bearing Clayey⁃Silty Sediments of the South China Sea. Canadian Geotechnical Journal, 58(3): 351-366. https://doi.org/10.1139/cgj⁃2019⁃0711

Wang, Q. B., Wang, R., Sun, J. X., et al., 2021b. Effect of Drilling Fluid Invasion on Natural Gas Hydrate Near⁃Well Reservoirs Drilling in a Horizontal Well. Energies, 14(21): 7075. https://doi.org/10.3390/en14217075

Wang, X. J., Jin, J. P., Guo, Y. Q., et al., 2020. The Characteristics of Gas Hydrate Accumulation and Quantitativre Estimation in the North Slope of South China Sea. Earth Science, 46(3): 1038-1057 (in Chinese with English abstract).

Wei, W., Cai, J. C., Hu, X. Y., et al., 2015. An Electrical Conductivity Model for Fractal Porous Media. Geophysical Research Letters, 42(12): 4833-4840. https://doi.org/10.1002/2015gl064460

Winters, W. J., Dugan, B., Collett, T. S., 2008. Physical Properties of Sediments from Keathley Canyon and Atwater Valley, JIP Gulf of Mexico Gas Hydrate Drilling Program. Marine and Petroleum Geology, 25(9): 896-905. https://doi.org/10.1016/j.marpetgeo.2008.01.018

Xiong, P., Lu, H., Xie, X. N., et al., 2020. Geochemical Responses and Implications for Gas Hydrate Accumulation: Case Study from Site SHC in Shenhu Area within Northern South China Sea. Marine and Petroleum Geology, 111: 650-661. https://doi.org/10.1016/j.marpetgeo.2019.06.032

Yu, M. H., Li, W. Z., Yang, M. J., et al., 2017. Numerical Studies of Methane Gas Production from Hydrate Decomposition by Depressurization in Porous Media. Energy Procedia, 105: 250-255. https://doi.org/10.1016/j.egypro.2017.03.310

Yun, T. S., Santamarina, J. C., Ruppel, C., 2007. Mechanical Properties of Sand, Silt, and Clay Containing Tetrahydrofuran Hydrate. Journal of Geophysical Research: Solid Earth, 112(B4): 1978-2012. https://doi.org/10.1029/2006jb004484

Zhang, H. W., Cheng, Y. F., Li, L. D., et al., 2018. Perturbation Simulation of Invasion of Drilling Fluid Containing Thermodynamic Hydrate Inhibitors into Natural Gas Hydrate Formation. Science Technology and Engineering, 18(6): 93-98 (in Chinese with English abstract).

Zhao, J. F., Liu, Y. Z., Yang, L., et al., 2021. Organics⁃Coated Nanoclays Further Promote Hydrate Formation Kinetics. 12(13): 3464-3467. https://doi.org/10.1021/acs.jpclett.1c00010

Zheng, M. M., Jiang, G. S., Liu, T. L., et al., 2017. Physical Properties Response of Hydrate Bearing Sediments near Wellbore during Drilling Fluid Invasion. Earth Science, 42(3): 453-461 (in Chinese with English abstract).

Zheng, M. M., Liu, T. L., Gao, Z. Y., et al., 2019. Simulation of Natural Gas Hydrate Formation Skeleton with the Mathematical Model for the Calculation of Macro⁃Micro Parameters. Journal of Petroleum Science and Engineering, 178: 429-438. https://doi.org/10.1016/j.petrol.2019.03.051

Zhou, X., Ning, F. L., Sun, J. X., et al., 2015. Numerical Simulation on the Drilling Fluid Flowing in Gas Hydrate⁃Bearing Sediment at the Laboratory Scale. Geological Science and Technology Information, 34(5): 190-198 (in Chinese with English abstract).

李淑霞, 王炜, 陈月明, 等, 2011. 多孔介质中天然气水合物注热开采影响因素实验研究. 海洋地质前沿, 27(6): 49-54.

刘丽国, 2012. 不同饱和度水合物开采实验研究(硕士学位论文). 大连: 大连理工大学.

刘天乐, 李丽霞, 蒋国盛, 等, 2015. 一种海洋水合物地层钻井用新型钻井液. 地球科学, 40(11): 1913-1921. doi: 10.3799/dqkx.2015.172

任金锋, 孙鸣, 韩冰, 等, 2021. 南海南沙海槽大型海底滑坡的发育特征及成因机制. 地球科学, 46(3): 1058-1071. doi: 10.3799/dqkx.2020.185

孙可明, 王婷婷, 翟诚, 等, 2018. 不同饱和度天然气水合物加热分解界面变化规律. 特种油气藏, 25(5): 129-134.

王秀娟, 勒佳澎, 郭依群, 等, 2020. 南海北部天然气水合物富集特征及定量评价. 地球科学, 46(3): 1038-1057. doi: 10.3799/dqkx.2020.321

张怀文, 程远方, 李令东, 等, 2018. 含热力学抑制剂钻井液侵入天然气水合物地层扰动模拟. 科学技术与工程, 18(6): 93-98.

郑明明, 蒋国盛, 刘天乐, 等, 2017. 钻井液侵入时水合物近井壁地层物性响应特征. 地球科学, 42(3): 453-461. doi: 10.3799/dqkx.2017.035

周欣, 宁伏龙, 孙嘉鑫, 等, 2015. 实验尺度下钻井液在含水合物地层流动数值模拟. 地质科技情报, 34(5): 190-198.

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Large Scale and High Simulation Experimental Study on Physical Property Response of Combustible Ice Formation in Offshore Deepwater Drilling

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