页岩油藏渗吸驱油剂体系性能评价

doi:10.3969/j.issn.2097-2806.2024.03.002

Abstract

Abstract:

The recovery of crude oil from shale oil reservoirs remains a significant challenge due to the ultra-low permeability and complex pore structures. Surfactants have been increasingly investigated as a potential method to enhance oil recovery in unconventional reservoirs by reducing interfacial tension and altering wettability. In this work, the performance of surfactants for potential application in shale oil reservoirs was evaluated by investigating spontaneous imbibition behavior. The results showed that the interfacial tension of 0.15 wt% CA-90+0.15 wt% SDS was reduced to 1.03×10^-2 mN/m under formation conditions. The wetting contact angle of the oil-wet core sheet was reduced from 135.5° to 49.5°, i.e., the wettability of the rock was changed from oil-wet to water-wet, and the capillary force was thus changed from resistance for oil imbibition to driving force. When the water content was 70%, the viscosity of the emulsion decreased to 23.4 mPa·s which was close to the viscosity of crude oil, but the fluidity was higher, which was more conducive to improving oil recovery. The dynamic adsorption capacities of 0.15 wt% CA-90 and 0.15 wt% SDS were 0.85 mg/g and 0.97 mg/g, respectively, which had good anti-adsorption ability, and the damage rate of shale permeability was less than 8%. The imbibition recovery of slick water+compounded system could reach 31.27%, which was much higher than that of spontaneous imbibition recovery in slick water system （19.43%）, and the imbibition oil displacement efficiency was thus increased by 60.94%, which greatly improved the oil recovery for shale reservoirs.

Key words: shale reservoir, surfactant, interface tension, spontaneous imbibition, recovery

CLC Number:

TQ423

Guofeng Li, Kainan Liu, Wenlong Mo, Teng Ma. Performance evaluation of a system of imbibition oil displacement agent in shale reservoir[J].China Surfactant Detergent & Cosmetics, 2024, 54(3): 250-258.

Figures/Tables 13

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References 25

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含水率/%	乳状液类型	黏度/（mPa·s）	平均粒径/μm	乳化情况
0（原油）	N/A	21.5	N/A	N/A
40	W/O	45.8	0.68	完全乳化
50	W/O，O/W	35.2	0.75	未完全乳化
60	W/O，O/W	27.8	0.72	未完全乳化
70	W/O，O/W	23.4	0.65	未完全乳化

编号	直径/cm	长度/cm	原始渗透率/（10^-3 μm²）	伤害后的渗透率/（10^-3 μm²）	伤害程度/%
1	2.496	3.47	1.463	1.406	3.87
2	2.511	3.53	0.056 8	0.053 6	5.72
3	2.508	3.55	0.829	0.794	4.17
4	2.513	3.36	0.006	0.005 3	7.26
5	2.499	3.41	2.876	2.782	3.28

岩心	直径/cm	长度/cm	孔隙度/%	渗透率/（10^-3 μm²）	初始含油饱和度/%
S1	2.501	3.43	3.22	0.072 2	37.32
S2	2.505	3.36	3.49	0.062 8	38.28

岩心	T₂弛豫时间/ms	采收率/%				累积采收率%	最终采收率%
岩心	T₂弛豫时间/ms	渗吸0~5 d	渗吸5~10 d	渗吸10~15 d	渗吸15~20 d	累积采收率%	最终采收率%
S1	<0.01	0.03	0.07	0.12	0.21	0.43	19.43
	0.01~1	0.46	1.23	0.99	0.16	2.68
	>1	5.86	7.86	2.20	0.40	16.32
S2	<0.01	0.02	0.06	1.82	1.01	2.91	31.27
	0.01~1	0.51	1.93	1.21	0.69	4.24
	>1	8.34	12.41	3.06	0.31	24.12

Performance evaluation of a system of imbibition oil displacement agent in shale reservoir

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