Preparation and properties evaluation of multifunctional drilling fluid additive for marine natural gas hydrate
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摘要: 针对海域天然气水合物钻井过程中由于储层水合物分解引起的井壁失稳难题,以2-丙烯酰胺基-2-甲基丙磺酸、二甲基二烯丙基氯化铵和二甲氧基甲基乙烯基硅烷改性纤维素为原料,制备了一种具有天然气水合物分解抑制性和降滤失性的双效处理剂。通过红外光谱表征了产物的分子结构,热重分析显示产物开始分解的温度约290 ℃,具有良好的热稳定性。水合物分解评价实验表明,1%双效处理剂作用下水合物的完全分解时间延长约1倍,水合物分解量降低了19.8%,具有良好的水合物分解抑制性能。在淡水基浆和5 wt% NaCl盐水基浆中的滤失量分别为6.8和8 mL,对于水合物储层具有良好的降滤失性。低温时淡水基浆滤失量为6.5 ml,表明双效处理剂具有良好低温流变性。本文为天然气水合物高性能钻井液的构建提供了重要支撑。Abstract: To address the issue of wellbore instability resulted from hydrate decomposition during offshore drilling for natural gas hydrate, this paper developed a dual-purpose additive which possess both hydrate decomposition inhibition and filtration reduction properties. It was synthesized using 2-acrylamido-2-methylpropane sulfonic acid, dimethyldiallyl ammonium chloride and dimethoxy methylvinylsilane-modified cellulose as the starting materials (named as “CAD”). The molecular structure was characterized through infrared spectroscopy. Thermal analysis revealed that the product decomposition initiated at around 290°C, demonstrating commendable thermal stability. The hydrate decomposition evaluation experiments indicated that the presence of 1% of the dual-function additive extended the total decomposition time of hydrates by approximately 1-fold and reduced the hydrate decomposition rate by 19.8%, which highlights the outstanding performance of hydrate decomposition inhibition. Filtration in freshwater-based slurry and 5 wt% NaCl saline-based slurry measured to be 6.8 and 8 mL respectively, signifying effective filtration reduction capabilities for hydrate reservoirs. The filtration for the freshwater-based slurry amounted to 6.5 mL at low temperatures, indicating the dual-function additive has favorable performance of low-temperature rheology. All these research offers substantial support for the advancement of high-performance drilling fluids designed for natural gas hydrates.
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[1] 孙金声,程远方,秦绪文,等.南海天然气水合物钻采机理与调控研究进展[J].中国科学基金,2021;35(6):940-51.
SUN Jinsheng, CHENG Yuanfang, QIN Xuwen, et al. Research progress on natural gas hydrate drilling & production in the South China Sea[J]. Bulletin of National Natural Science Foundation of China, 2021;35(6):940-51.
[2] [2] Yin FL, Gao YH, Chen Y, et al. Numerical investigation on the long-term production behavior of horizontal well at the gas hydrate production site in South China Sea[J]. Applied Energy, 2022,311:118603.
[3] [3] Yang SX, Zhang HQ, Wu NY, et al. High concentrations of hydrate in disseminated forms found in very fine-grained sediments of Shenhu area, north slope of South China Sea[C]//
6th International Conference on Gas Hydrates .Vancouver, British Columbia , 2008.[4] [4] 刘协鲁,阮海龙,赵义,等.海域天然气水合物保温保压取样钻具研究与应用进展[J].钻探工程,2021,48(7):33-39.LIU Xielu, RUAN Hailong, ZHAO Yi, et al. Progress in research and application of the pressure-temperature core sampler for marine natural gas hydrate[J]. Drilling Engineering, 2021,48(7):33-39..
[5] [5] 孙金声,廖波,王金堂,等.分子模拟技术在天然气水合物相变机理方面的研究进展及应用[J].中南大学学报(自然科学版)2022,53(3):757-771.
SUN Jinsheng, LIAO Bo, WANG Jintang, et al. Research progress and application of molecular simulation technology in phase transition mechanism of natural gas hydrate[J]. Journal of Central South University (Science and Technology), 2022,53(3):757-771.
[6] [6] Li YL, Wu NY, Ning FL, et al. Hydrate-induced clogging of sand-control screen and its implication on hydrate production operation[J]. Energy, 2020,206:118030.
[7] [7] 王志刚,李小洋,张永彬,等.海域非成岩天然气水合物储层改造方法分析[J].钻探工程,2021,48(6):32-38.
WANG Zhigang, LI Xiaoyang, ZHANG Yongbin, et al. Analysis of the stimulation methods for marine non-diagenetic natural gas hydrate reservoirs[J]. Drilling Engineering, 2021,48(6):32-38.
[8] [8] Liao B, Wang J, Han X, et al. Microscopic molecular insights into clathrate methane hydrates dissociation in a flowing system[J]. Chemical Engineering Journal, 2022,430:133098.
[9] [9] Li QC, Cheng YF, Ansari U, et al. Experimental investigation on hydrate dissociation in near-wellbore region caused by invasion of drilling fluid: Ultrasonic measurement and analysis[J]. Environmental Science and Pollution Research, 2022,29(24):36920-36937.
[10] [10] 侯岳,刘春生,刘聃,等.海域天然气水合物浅软地层水平井钻井液技术[J].钻探工程,2022,49(2):16-21.
HOU Yue, LIU Chunsheng, LIU Dan, et al. Drilling fluid technology for natural gas hydrate horizontal wells in marine shallow soft formation[J]. Drilling Engineering, 2022,49(2):16-21.
[11] [11] Ma X, Jiang D, Sun Y, et al. Experimental study on hydraulic fracturing behavior of frozen clayey silt and hydrate-bearing clayey silt[J]. Fuel, 2022,322:124366.
[12] [12] Li B, Ma X, Zhang G, et al. Enhancement of gas production from natural gas hydrate reservoir by reservoir stimulation with the stratification split grouting foam mortar method[J]. Journal of Natural Gas Science and Engineering, 2020,81:103473.
[13] [13] Suryanarayana PV, Bogdanovic M, Thavaras PK, et al. Assessing the impact of shallow gas hydrate dissociation on structural integrity in deepwater wells[C]//
International Petroleum Technology Conference .Virtual , 2021.[14] [14] Wu NY, Li YL, Wan YZ, et al. Prospect of marine natural gas hydrate stimulation theory and technology system[J]. Natural Gas Industry B, 2021,8(2):173-187.
[15] [15] Maiti M, Ranjan R, Chaturvedi E, et al. Formulation and characterization of water-based drilling fluids for gas hydrate reservoirs with efficient inhibition properties[J]. Journal of Dispersion Science and Technology, 2021,42(3):338-351.
[16] [16] 史浩贤,谢文卫,于彦江,等.复合解堵技术在天然气水合物开发中的应用可行性分析[J].钻探工程,2022,49(1):5-15.
SHI Haoxian, XIE Wenwei, YU Yanjiang, et al. Application feasibility of composite plugging removal technology in the development of natural gas hydrate[J]. Drilling Engineering, 2022,49(1):5-15.
[17] [17] 付帆,熊正强,陶士先,等.天然气水合物钻井液研究进展[J].探矿工程(岩土钻掘工程),2018,45(10):71-76.
FU Fan, XIONG Zhengqiang, TAO Shixian, et al. Research Progress in Drilling Fluid for Natural Gas Hydrate[J]. Exploration Engineering (Rock & Soil Drilling and Tunnling), 2018,45(10):71-76.
[18] [18] Liao B, Wang J, Sun J, et al. Microscopic insights into synergism effect of different hydrate inhibitors on methane hydrate formation: Experiments and Molecular Dynamics Simulations[J]. Fuel, 2023,340:127488.
[19] [19] Cao J, Meng L, Yang Y, et al. Novel acrylamide/2-acrylamide-2-methylpropanesulfonic acid/4-vinylpyridine terpolymer as an anti-calcium contamination fluid-loss additive for water-based drilling fluids[J]. Energy & Fuels, 2017,31(11):11963-11970.
[20] [20] Cheng C, Wang F, Zhang J, et al. Cyclic formation stability of 1,1,1,2-tetrafluoroethane hydrate in different SDS solution systems and dissociation characteristics using thermal stimulation combined with depressurization[J]. ACS Omega, 2019,4(7):11397-11407.
[21] [21] Wang J, Sun J, Wang R, et al. Mechanisms of synergistic inhibition of hydrophilic amino acids with kinetic inhibitors on hydrate formation[J]. Fuel, 2022,321:124012.
[22] [22] Sharifi H, Ripmeester J, Walker VK, et al. Kinetic inhibition of natural gas hydrates in saline solutions and heptane[J]. Fuel, 2014,117:109-117.
[23] [23] Mi FY, He ZJ, Jiang GS, et al. Molecular insights into the effects of lignin on methane hydrate formation in clay nanopores[J]. Energy, 2023,276:127496.
[24] [24] Zhao X, Qiu Z, Huang W. Characterization of kinetics of hydrate formation in the presence of kinetic hydrate inhibitors during deepwater drilling[J]. Journal of Natural Gas Science and Engineering, 2015,22:270-278.
[25] [25] Mi F, He Z, Jiang G, et al. Effects of marine environments on methane hydrate formation in clay nanopores: A molecular dynamics study[J]. Science of The Total Environment, 2022,852:158454.
[26] [26] He ZJ, Mi FY, Ning FL, et al. Methane hydrate formation in the salty water confined in clay nanopores: A molecular simulation study[J]. ACS Sustainable Chemistry & Engineering, 2022,10(18):6128-6140.
[27] [27] Liao B, Wang J, Li MC, et al. Microscopic molecular and experimental insights into multi-stage inhibition mechanisms of alkylated hydrate inhibitor[J]. Energy, 2023,279:128045.
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