N2对含CO2注入气的物性参数影响实验及相平衡规律研究

doi:10.13809/j.cnki.cn32-1825/te.2025.04.008

油气藏评价与开发 ›› 2025, Vol. 15 ›› Issue (4): 597-604.doi: 10.13809/j.cnki.cn32-1825/te.2025.04.008

N₂对含CO₂注入气的物性参数影响实验及相平衡规律研究

秦楠¹(), 甘笑非², 罗瑜¹, 刘晓旭¹, 温斌³(), 陈星宇³

1.中国石油西南油气田公司勘探开发研究院，四川成都 610041
2.中国石油西南油气田公司，四川成都 610051
3.西南石油大学油气藏地质及开发工程全国重点实验室，四川成都 610500

收稿日期:2024-08-08 发布日期:2025-07-19 出版日期:2025-08-26
通讯作者: 温斌（2000—），男，在读硕士研究生，主要从事CO₂地质封存与CO₂水合物封存相关研究工作。地址：四川省成都市新都区新都大道85号西南石油大学，邮政编码：610500。E-mail：2448260777@qq.com
作者简介:秦楠（1996—），男，硕士，工程师，主要从事CH₄、CO₂等大规模地下储存研究和工程设计工作。地址：成都市高新区天府三街升华路6号，邮政编码：610041。E-mail： qinnan0103@petrochina.com.cn
基金资助:
国家自然科学基金项目“四川盆地有水气藏CO2驱提高采收率及其有效封存研究”(U23A2022)

Experimental study on effect of N₂ on physical parameters and phase equilibrium patterns of CO₂-rich injection gas

QIN Nan¹(), GAN Xiaofei², LUO Yu¹, LIU Xiaoxu¹, WEN Bin³(), CHEN Xingyu³

1.Exploration and Development Research Institute, PetroChina Southwest Oil & Gasfield Company, Chengdu, Sichuan 610041, China
2.PetroChina Southwest Oil & Gasfield Company, Chengdu, Sichuan 610051, China
3.State Key Laboratory of Oil and Gas Reservoir Geology and Exploitation, Southwest Petroleum University, Chengdu, Sichuan 610500, China

Received:2024-08-08 Online:2025-07-19 Published:2025-08-26

摘要/Abstract

摘要：

工业尾气处理成本高昂，将含CO₂的尾气注入枯竭油气藏是实现提高采收率与碳封存的潜在技术。为了给注入过程提供指导，探明N₂对含CO₂注入气物性参数的影响，基于JEFRI相态分析仪和CPA（立方加缔合）状态方程开展含CO₂注入气物性参数实验测量和相平衡规律研究。研究结果表明：当温度较高时，高含CO₂注入气的“乳光现象”较弱，且出现“乳光现象”时的压力较高，当温度接近临界点时，“乳光现象”较强，但是出现“乳光现象”的压力较低，且远离临界压力；当含CO₂注入气存在“乳光现象”时，流体存在临界点，而流体存在临界点时，不一定能观察到“乳光现象”，流体不存在临界点时，未观察到“乳光现象”。含CO₂注入气在压力低于10 MPa时，流体表现出类似气体密度的性质，随压力增加体积快速减小；当压力高于20 MPa时，流体表现出类似液体密度的性质。压力介于10~20 MPa时属于过渡带，在压力介于2~55 MPa时，5种含CO₂注入气的黏度均很小，呈现气态特征。在相同的温度和压力条件下，随着N₂摩尔分数从10%增加到90%，含CO₂注入气的偏差因子增加，流体的密度降低，注气过程中应尽量减少N₂的含量，采用高含CO₂的注入气效果更好。以12 MPa为界限，压力不高于12 MPa时，黏度随N₂增加而增加，压力高于12 MPa时，黏度则随着N₂含量增加而减小，摩尔分数为5%的O₂杂质对CO₂注入气物理性质的影响很小，可以忽略。在相同的组成下，随着温度升高，注入气偏差因子和黏度先增加后降低，压力的交点与温度和组成相关。该研究实验与理论模型结合，揭示了N₂对含CO₂注入气物性参数的影响，为油气藏注烟道气或尾气提高采收率提供了指导。

关键词: 含CO₂注入气, N₂杂质气, 物性参数实验测量, 相态变化规律, CPA状态方程, 乳光现象

Abstract:

The high cost of industrial flue gas treatment makes injecting CO₂-rich exhaust gas into depleted oil and gas reservoirs a potential technology for enhanced recovery and carbon sequestration. This study aims to guide the injection process, and the effect of N₂ on the physical properties of CO₂-rich injection gas remains insufficiently understood. This study conducted experimental measurements of the physical parameters and phase equilibrium studies using a JEFRI phase analyzer and CPA (cubic plus association) equation of state. The results showed that at higher temperatures, the “opalescence phenomenon” in high CO₂-rich injection gas was weaker and occurred at higher pressures. When temperature approached critical point, the opalescence was stronger but occurred at lower pressures, which were far from the critical pressure. When CO₂-rich injection gas exhibited “opalescence phenomenon”, the fluid had critical point. However, the presence of a critical point did not necessarily imply observable opalescence, and no opalescence was observed when the fluid had no critical point. When the pressure was below 10 MPa, the fluid exhibited gas-like densities with volume decreasing rapidly as pressure increased. Above 20 MPa, the fluid showed liquid-like densities. The 10-20 MPa range represented a transition zone. At 2-55 MPa, the viscosities of five CO₂-rich gas mixtures remained low, exhibiting gaseous characteristics. Under identical temperature and pressure conditions, as the N₂ molar fraction increased from 10% to 90%, the deviation factor of CO₂-rich injection gas increased while fluid density decreased. Thus, N₂ content should be minimized during injection, and higher CO₂ molar fractions improved injection performance. With 12 MPa as the threshold, viscosity increased with rising N₂ content below 12 MPa but decreased with higher N₂ molar fraction above this pressure. A 5% O₂ impurity had a negligible effect on the physical properties of CO₂-rich injection gas and can be neglected. At the same composition, both deviation factor and viscosity of the injection gas first increased and then decreased with rising temperature, and the pressure intersection point varied with temperature and composition. By integrating experimental data with theoretical modeling, this study elucidates the effect of N₂ on the physical properties of CO₂-rich injection gas, providing guidance for enhanced recovery rate using flue gas or exhaust gas injection in oil and gas reservoirs.

Key words: CO₂-rich injection gas, N₂ impurity gas, experimental measurement of physical parameters, phase variation pattern, CPA equation of state, opalescence phenomenon

中图分类号:

TE377

秦楠,甘笑非,罗瑜, 等. N₂对含CO₂注入气的物性参数影响实验及相平衡规律研究[J]. 油气藏评价与开发, 2025, 15(4): 597-604.

QIN Nan,GAN Xiaofei,LUO Yu, et al. Experimental study on effect of N₂ on physical parameters and phase equilibrium patterns of CO₂-rich injection gas[J]. Petroleum Reservoir Evaluation and Development, 2025, 15(4): 597-604.

图/表 11

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样品编号	组成
样品编号	CO₂/%	N₂/%	O₂/%
样品1	79.68	20.32	0
样品2	50.00	50.00	0
样品3	31.68	68.32	0
样品4	29.82	65.23	4.95
样品5	13.00	82.00	5.00

样品编号	压力/ MPa	温度/ ℃	偏差因子	体积系数/ （10^-4 mL/mL）	密度/ （kg/m³）	黏度/ （mPa·s）
样品1	2	20	0.909 3	462.76	36.78	0.016 1
	5	30	0.790 2	166.35	102.32	0.017 7
	10	40	0.629 1	68.40	248.82	0.023 1
	15	50	0.585 6	43.80	388.60	0.031 3
	20	60	0.619 5	35.83	475.02	0.038 0
	25	70	0.675 1	32.18	529.04	0.042 9
	35	80	0.774 9	27.15	626.99	0.052 4
	45	90	0.880 9	24.68	689.58	0.059 5
	55	100	0.983 8	23.18	734.43	0.065 3
样品2	2	20	0.947 4	481.28	31.19	0.016 7
	5	30	0.888 5	186.70	80.40	0.018 0
	10	40	0.827 5	89.81	167.13	0.020 7
	15	50	0.814 6	60.82	246.80	0.024 3
	20	60	0.833 3	48.11	312.00	0.028 2
	25	70	0.868 4	41.31	363.36	0.031 8
	35	80	0.941 5	32.93	455.90	0.038 9
	45	90	1.026 9	28.72	522.65	0.044 9
	55	100	1.113 8	26.19	573.15	0.050 0
样品3	2	20	0.965 3	489.93	28.15	0.017 1
	5	25	0.926 1	191.22	72.11	0.018 0
	10	31	0.889 2	93.65	147.37	0.020 1
	15	37	0.882 3	63.17	218.19	0.023 0
	20	43	0.900 1	49.27	280.08	0.026 3
	25	49	0.930 5	41.52	332.39	0.029 6
	30	55	0.967 1	36.63	376.30	0.032 8
	35	61	1.008 6	33.34	413.40	0.035 7
	40	67	1.053 8	31.03	445.08	0.038 4
	45	73	1.096 5	29.21	472.45	0.040 9
	50	79	1.139 2	27.78	496.37	0.043 2
	55	85	1.187 1	26.77	517.47	0.045 3
样品4	2	20	0.976 7	495.42	27.71	0.017 3
	5	25	0.951 1	196.27	69.94	0.018 2
	10	31	0.930 1	97.90	140.22	0.020 1
	15	37	0.934 8	66.89	205.23	0.022 6
	20	43	0.958 6	52.44	261.76	0.025 5
	25	49	0.994 5	44.35	309.52	0.028 3
	30	55	1.037 1	39.26	349.66	0.031 1
	35	61	1.083 0	35.78	383.61	0.033 6
	40	67	1.130 4	33.27	412.65	0.036 0
	45	73	1.177 9	31.36	437.77	0.038 1
	50	79	1.225 0	29.86	459.74	0.040 1
	55	85	1.271 3	28.65	479.15	0.042 0
样品5	2	20	0.990 2	501.96	25.10	0.017 8
	5	25	0.982 8	202.68	62.16	0.018 5
	10	31	0.986 0	103.72	121.49	0.020 1
	15	37	1.005 3	71.89	175.28	0.022 0
	20	43	1.035 7	56.62	222.52	0.024 2
	25	49	1.073 1	47.83	263.45	0.026 5
	30	55	1.114 5	42.16	298.84	0.028 7
	35	61	1.157 9	38.23	329.56	0.030 8
	40	67	1.202 1	35.36	356.41	0.032 8
	45	73	1.246 2	33.16	380.06	0.034 7
	50	79	1.289 8	31.42	401.06	0.036 5
	55	85	1.332 6	30.01	419.84	0.038 2

纯物质	a₀/（Pa·m⁶/mol）	b/（cm³/mol）	c₁
CO₂	0.350 790	27.20	0.760 2
N₂	0.138 063	26.40	0.513 6
O₂	0.139 684	21.80	0.486 6

N₂对含CO₂注入气的物性参数影响实验及相平衡规律研究

Experimental study on effect of N₂ on physical parameters and phase equilibrium patterns of CO₂-rich injection gas

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