无机凝胶强化自生泡沫调剖体系性能研究

doi:10.3969/j.issn.2097-2806.2025.04.010

摘要/Abstract

摘要：

为克服常规自生泡沫强度低、调剖能力有限，针对强非均质性储层无法有效封堵高渗层的难题，提出一种无机凝胶强化自生泡沫体系。利用Waring Blender搅拌机、电子显微镜和双填砂管模型研究了体系的泡沫性能和调剖性能，结果表明：无机凝胶强化自生泡沫体系平均粒径为200 μm，析液半衰期达到55.2 min，较常规自生泡沫体系粒径更加细小均匀，稳定性显著增强。常规自生泡沫体系对于渗透率级差为5的并联填砂管模型具有良好的调剖效果，整体采收率可由13%增至30%，但渗透率级差≥10后基本无法动用低渗层；无机凝胶强化自生泡沫体系在不同渗透率级差下都具有良好的调剖效果，渗透率级差≤10时可实现产液率反转，当级差达到15时仍可有效封堵高渗层、启动低渗层，整体采收率可在水驱基础上提高21%。研究结果为在强非均质储层开展自生泡沫调剖提供了参考依据。

关键词: 非均质油藏, 泡沫强度, 自生泡沫, 调剖, 无机凝胶

Abstract:

Conventional in-situ foams are of poor strength and limited profile control ability, which could not effectively plug the high-permeability layers in highly heterogeneous reservoirs. To solve this problem, in this work, an inorganic gel enhanced in-situ foam system was proposed. The foaming performance and profile control performance of conventional in-situ foam system and inorganic gel enhanced in-situ foam system were both studied by using Waring Blender mixer, electron microscope and double sand-filled tube model. The results showed that, the average particle size of the inorganic gel enhanced in-situ foam system was 200 μm, and the drainage half-life reached 55.2 min, which was smaller and more uniform than that of conventional in-situ foam system and exhibited significantly enhanced stability. Conventional in-situ foam system had good profile control effect for parallel sand-filled tube model with permeability ratio of 5, and the overall recovery factor could be increased from 13% to 30%, but low-permeability layers could hardly be used for permeability ratio≥10. In contrast, the inorganic gel enhanced in-situ foam system had good profile control effect at different permeability levels. When the permeability ratio was≤10, the liquid production rate could be reversed. When the permeability ratio reached 15, the high-permeability layer could still be effectively blocked, and the low-permeability layer could be used. The overall recovery factor could be increased by 21% on the basis of water flooding. This work could provide a reference for conducting in-situ foam profile control in highly heterogeneous reservoirs.

Key words: heterogeneous reservoir, foam strength, in-situ foam, profile control, inorganic gel

中图分类号:

TE357

康小斌, 屈亚宁, 马宝鹏. 无机凝胶强化自生泡沫调剖体系性能研究[J]. 日用化学工业（中英文）, 2025, 55(4): 481-486.

Xiaobin Kang, Yaning Qu, Baopeng Ma. Performance evaluation of inorganic gel enhanced in-situ foam profile control system[J]. China Surfactant Detergent & Cosmetics, 2025, 55(4): 481-486.

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参考文献 14

[1]	曹长霄, 宋兆杰, 师耀利, 等. 吉木萨尔页岩油二氧化碳吞吐提高采收率技术研究[J]. 特种油气藏, 2023, 30(3): 106-114. doi: 10.3969/j.issn.1006-6535.2023.03.013
[2]	霍宏博, 刘东东, 陶林, 等. 基于CO₂提高采收率的海上CCUS完整性挑战与对策[J]. 石油钻探技术, 2023, 51(2): 74-80.
[3]	邓宏伟. 超深层低渗透稠油CO₂增溶降黏体系研发与应用[J]. 油气地质与采收率, 2020, 27(1): 81-88.
[4]	金发扬, 周顺明, 高士博, 等. 层内自生CO₂提高采收率技术现状[J]. 油田化学, 2021, 38(3): 564-570.
[5]	Shiau B J B, Hsu T P, Roberts B L, et al. Improved chemical flood efficiency by in situ CO₂ generation[G]// Paper presented at the SPE Improved Oil Recovery Symposium. Tulsa, Oklahoma, USA: Society of Petroleum Engineers, 2010.
[6]	Zhang Guoping, Xiao Liang, Hu Yanxia, et al. Applications of in situ gas generating for enhanced oil recovery to Zhongyuan faulted block oilfield[J]. Petroleum Geology and Recovery Efficiency, 2004, 11(5): 60-61, 85.
[7]	杨付林, 朱伟民, 余晓玲, 等. 层内生气吞吐工艺在江苏油田W5稠油油藏的应用[J]. 复杂油气藏, 2013(3): 71-75.
[8]	Wang J, Wu J, Kang H, et al. Study on water plugging technology of self-generating gel-foam in offshore oilfield[J]. IOP Conference Series: Earth and Environmental Science, 2018, 170(2): 1-6.
[9]	张璐, 邹剑, 高尚, 等. 渤海油田自生热体系室内研究[J]. 科学技术与工程, 2019, 19(16): 75-81.
[10]	李小刚, 黄琴, 李小凡, 等. 自生泡沫体系的研究与性能评价[J]. 应用化工, 2022, 51(7): 1906-1910.
[11]	汤勇, 汪勇, 邓建华, 等. 自生CO₂结合表面活性剂复合吞吐数值模拟[J]. 西南石油大学学报(自然科学版), 2013(4): 107-113. doi: 10. 3863/j. issn. 1674 – 5086. 2013. 04. 015
[12]	刘航, 柳建新, 徐宁宁, 等. 自生气提高采收率技术研究进展[J]. 精细石油化工, 2023, 40(3): 79-84.
[13]	武薛强, 聂士斌, 韩超, 等. 防治煤矿火灾的凝胶泡沫材料制备及其性能研究[J]. 中国安全生产科学技术, 2022, 18(6):78-84.
[14]	于创, 王飞, 贺志宏, 等. 增韧剂改性矿用酚尿醛泡沫的实验研究[J]. 中国矿业, 2021, 30(2): 133-138.

序号	干重/g	湿重/g	孔隙度/%	渗透率/ ×10^-3μm²	渗透率级差
1	2 873.72	2 943.74	29.10	3 003.5	5.8
1	2 810.87	2 863.40	21.82	516.7	5.8
2	2 990.09	3 053.95	26.52	5 195.5	10.5
2	2 892.24	2 954.04	25.67	495.2	10.5
3	2 879.88	2 938.59	24.38	7 034.8	14.9
3	3 000.39	3 054.98	22.69	475.3	14.9
4	2 959.19	3 020.99	25.67	2 546.6	5.1
4	2 929.32	2 993.18	26.52	481.7	5.1
5	2 882.97	2 948.89	27.38	5 627.0	10.1
5	3 005.54	3 063.22	23.96	557.5	10.1
6	2 879.88	2 943.74	26.52	7 768.4	14.6
6	3 011.72	3 062.19	20.96	528.5	14.6

序号	体系名称	体系配方	起泡体积/mL	半衰期/ min
1	常规自生泡沫	10.0% （w/%，下同） A剂50 mL、10.0% B剂+ 1.5%起泡剂+0.05%稳泡剂50 mL	325	27.3
2	无机凝胶强化自生泡沫	10.0% A剂+4.0%凝胶剂50 mL、10.0% B剂+ 1.5%起泡剂+0.05%稳泡剂50 mL	308	55.2