适用于川西中浅层气藏的抗凝析油泡排剂研制及室内性能评价

doi:10.3969/j.issn.2097-2806.2025.07.002

摘要/Abstract

摘要： 泡沫排液采气是低压低产气井稳产最经济有效的措施，然而井底积液常伴随凝析油污染，导致常规泡排剂排液效果变差。考察了8种表面活性剂的泡沫性能，探讨了含油量、温度对泡沫性能的影响，优选出抗油性能较好的月桂酰胺丙基甜菜碱（CAB）作为主剂，进一步复配氟碳表面活性剂和稳泡剂研制了新型抗凝析油泡排剂SCU-7。考察了SCU-7的流动性、不同含油量的泡沫性能、模拟井底高温高压下的泡沫性能，探讨了抗油机理。结果表明，在常压60 ℃且含油量为10%时，0.3%的SCU-7在4×10⁴ mg/L模拟盐水中的起泡高度达到167 mm，3 min泡沫高度达到135 mm，15 min携液量达到206 mL，综合性能优异。含油量增加至30%时，泡沫综合性能有一定程度的下降。在高压6 MPa及80，100，120 ℃下，SCU-7都可在模拟盐水中产生致密的泡沫。机理分析认为，CAB在模拟盐水中具有优异的降低表面张力的性能，复配氟碳表面活性剂后，表面张力进一步降低，而稳泡剂可以增强泡沫液膜的强度，提升泡沫性能。因此，SCU-7具有较优异的抗油性能。

关键词: 泡排剂, 表面活性剂, 泡沫性能, 抗凝析油

Abstract:

The foam drainage gas recovery technique in natural gas production is widely recognized as the most cost-effective and efficient method for removing the water accumulated at the well bottom, which is an essential measure to ensure stable production for low-pressure and low-productivity gas wells. However, the bottomhole liquids are often contaminated by condensate oil, resulting in reduced effectiveness of conventional foaming agents. In this work, the foam properties of eight surfactants were investigated and the effects of oil content and temperature on their foam properties were also examined. The zwitterionic surfactant CAB, which demonstrated relatively good resistance to oil, was selected as the primary component of the foaming agent. By combining CAB with a fluorocarbon surfactant and a foam stabilizer, a new anti-condensate oil foaming agent SCU-7 was developed. The flowability, foaming performance at different oil content, and the foaming performance under simulated high-temperature and high-pressure conditions at the bottom were analyzed to explore the anti-oil mechanism of SCU-7. The results showed that, at 60 ℃ under atmospheric pressure, with an oil content of 10%, a concentration of 0.3% SCU-7 achieved the foam height of 167 mm in simulated saline water with total salinity of 4×10⁴ mg/L; the foam height was 135 mm at 3 min; after 15 min, the liquid-carrying capacity was up to 206 mL, demonstrating excellent overall performance. However, when the oil content was increased to 30%, the overall foaming performance declined to some extent. Under high pressure of 6 MPa and at temperatures of 80 ℃, 100 ℃ and 120 ℃, SCU-7 could generate dense foams in simulated saline water. Mechanism analysis indicated that CAB exhibited excellent ability of surface tension reduction in simulated saline water; mixing CAB with fluorocarbon surfactant could further decrease surface tension, while the presence of foam stabilizer could enhance the strength of foam film and thus improve foaming performance. Therefore, SCU-7 demonstrated good foaming performance with improved anti-oil properties.

Key words: foaming agent, surfactant, foaming performance, anti-condensation oil

中图分类号:

TQ423

鲁光亮, 唐雷, 田文忠, 李嘉明, 冯玉军, 殷鸿尧. 适用于川西中浅层气藏的抗凝析油泡排剂研制及室内性能评价[J]. 日用化学工业（中英文）, 2025, 55(7): 825-830.

Guangliang Lu, Lei Tang, Wenzhong Tian, Jiaming Li, Yujun Feng, Hongyao Yin. Development and laboratory evaluation of anti-condensate oil foaming agent for shallow gas reservoirs in western Sichuan[J]. China Surfactant Detergent & Cosmetics, 2025, 55(7): 825-830.

图/表 8

表1

表2

表3

表4

图1

表5

图2

图3

参考文献 15

[1]	李谦定, 卢永斌, 李善建, 等. 新型高效泡排剂LYB-1的研制及其性能评价[J]. 天然气工业, 2011, 31 (6) : 49-52.
[2]	王旭. 川西中浅层气藏泡沫排水采气工艺技术研究与应用[J]. 钻采工艺, 2020, 43 (2) : 68-71. doi: 10.3969/J. ISSN.1006-768X.2020.02.18
[3]	殷鸿尧, 鲁光亮, 李祖友, 等. 川西气田井底积液污染物分析及对策研究[J]. 油田化学, 2018, 35 (1) : 97-101.
[4]	李祖友, 唐雷, 殷鸿尧, 等. 川西老区中浅层新型泡排药剂研发与应用[J]. 西南石油大学学报(自然科学版), 2022, 44 (3) : 176-187. doi: 10.11885/j.issn.1674-5086.2022.01.26.01
[5]	白晓弘, 吴革生, 王效明, 等. 含凝析油气井泡沫排水采气工艺研究及应用[J]. 石油化工应用, 2008, 27 (2) : 35-39.
[6]	瞿超超, 刘正中, 殷鸿尧, 等. 新型排水采气用抗凝析油泡排剂[J]. 石油学报, 2020, 41 (7) : 865-874. doi: 10.7623/syxb202007008
[7]	中国石油化工集团有限公司.泡排剂技术要求: Q/SH CG135—2021[S]. 北京: 中国石油科, 2021: 3-5.
[8]	黄秋霞. 起泡剂的耐温耐盐耐油性能评价及泡排剂的研制[D]. 北京: 中国地质大学, 2015.
[9]	李农, 蒋华全, 曹世昌, 等. 高温对泡沫排水剂性能的影响[J]. 天然气工业, 2009, 29 (11) : 77-79.
[10]	徐海民. 新型复合泡排剂抗油性能研究与应用[J]. 断块油气田, 2022, 29 (3) : 422-426.
[11]	刘银平. 原油对水相泡沫排液行为的影响[D]. 西安: 西安石油大学, 2013.
[12]	王西亚, 覃孝平, 石琼林, 等. 抗凝析油泡排剂的研究现状[J]. 应用化工, 2023, 52 (7) : 2225-2227, 2233.
[13]	惠艳妮, 付钢旦, 贾友亮, 等. 新型抗凝析油泡排剂的研究及应用[J]. 石油与天然气化工, 2016, 45 (3) : 72-75.
[14]	赵春霞, 徐卡秋, 唐聪明. 氟碳表面活性剂研究[J]. 四川化工, 2004, 7 (3) : 13-16.
[15]	肖进新, 赵振国. 表面活性剂应用原理[M]. 2版. 北京: 化工工业出版社, 2015: 323-330.

表面活性剂类型	表面活性剂名称	起泡高度/mm	3 min高度/mm	5 min高度/mm	15 min携液量/mL
两性	CHSB	158	70	28	170
	CAB	162	95	40	135
	CAO	162	105	56	171
	LHSB	155	75	20	79
阴离子	SDS	32	0	0	0
阴离子	SBDS	12	0	0	0
阳离子	1231	177	0	0	102
阳离子	DTBA	178	0	0	67

温度/℃	表面活性剂名称	起泡高度/mm	3 min高度/mm	5 min高度/mm	15 min携液量/mL
40	CHSB	136	75	45	111
	CAB	102	81	64	128
	CAO	97	55	34	163
	LHSB	146	100	75	42
60	CHSB	158	70	28	170
	CAB	162	95	40	135
	CAO	162	105	56	171
	LHSB	155	75	20	79
80	CHSB	205	20	0	179
	CAB	178	25	0	200
	CAO	150	2	0	216
	LHSB	180	0	0	164

油含量/%	表面活性剂名称	起泡高度/mm	3 min高度/mm	5 min高度/mm	15 min携液量/mL
0	CHSB	179	81	32	230
	CAB	215	115	105	226
	CAO	117	86	45	245
	LHSB	177	70	30	189
10	CHSB	158	70	28	170
	CAB	162	95	40	135
	CAO	162	105	56	171
	LHSB	155	75	20	79
15	CHSB	141	50	25	164
	CAB	155	100	65	150
	CAO	180	112	74	186
	LHSB	133	53	17	84
20	CHSB	139	65	18	161
	CAB	133	84	40	166
	CAO	107	77	37	162
	LHSB	115	54	16	92
30	CHSB	46	23	5	141
	CAB	73	40	24	148
	CAO	82	50	17	160
	LHSB	63	30	8	95

表面活性剂名称	w（TF）/%	起泡高度/mm	3 min高度/mm	5 min高度/mm	15 min携液量/mL
CAB	0	162	95	40	135
	0.5	173	127	100	214
	1.0	177	141	103	227
	1.5	180	145	108	230

油含量/ %	起泡高度/mm	3 min高度/mm	5 min高度/mm	15 min携液量/mL
10	167	135	105	206
20	146	102	75	194
30	136	109	81	212