油藏改建储气库多周期与单周期多级压力下相间传质研究

doi:10.13809/j.cnki.cn32-1825/te.2025.06.020

油气藏评价与开发 ›› 2025, Vol. 15 ›› Issue (6): 1130-1138.doi: 10.13809/j.cnki.cn32-1825/te.2025.06.020

油藏改建储气库多周期与单周期多级压力下相间传质研究

孔德彬¹(), 杨星星¹(), 张可², 程耀泽², 高嘉豪², 李傲³

1.北京科技大学资源与安全工程学院，北京 100083
2.中国石油勘探开发研究院提高油气采收率全国重点实验室，北京 100083
3.中国石油大学（北京）化学工程与环境学院，北京 102200

收稿日期:2024-09-26 发布日期:2025-10-24 出版日期:2025-12-26
通讯作者: 杨星星（1996—），男，在读硕士研究生，主要从事油气藏流体相态及提高采收率方面研究。地址：北京市海淀区学院路30号，邮政编码：100083。E-mail：M202220168@xs.ustb.edu.cn
作者简介:孔德彬（1989—），男，副教授，博士，主要从事渗流力学和二氧化碳封存与利用方面研究。地址：北京市海淀区学院路30号，邮政编码：100083。E-mail：kongdb@ustb.edu.cn
基金资助:
国家自然科学基金项目“页岩油原位转化过程中纳微米尺度流固界面作用及流动机制”(42102163)

Study on interphase mass transfer under multi-cycle and single-cycle multi-stage pressure conditions during reservoir conversion to gas storage

KONG Debin¹(), YANG Xingxing¹(), ZHANG Ke², CHENG Yaoze², GAO Jiahao², LI Ao³

1. School of Resources and Safety Engineering, University of Science and Technology Beijing, Beijing 100083, China
2. State Key Laboratory of Enhanced Oil & Gas Recovery, PetroChina Research Institute of Petroleum Exploration & Development, Beijing 100083, China
3. College of Chemical Engineering and Environment, China University of Petroleum (Beijing), Beijing 102200, China

Received:2024-09-26 Online:2025-10-24 Published:2025-12-26

摘要/Abstract

摘要：

以5种国内典型陆相油藏原油为研究对象，基于超高压流体相态分析研发的储气库注采油气相行为模拟实验平台，开展了单周期和多周期注采实验。实验研究了3种不同性质原油单周期注采过程中多级压力下的油气性质，以及2种不同性质原油多周期注采的油气特征，揭示了国内陆相油藏建库油气体系相间传质规律与建库周期数的关系，为确定不同性质油藏改建储气库建库周期数提供理论依据。实验结果表明：①注气期间，传质以溶解扩散为主，蒸发抽提为辅，导致原油密度和黏度减小，相包络线向左上偏移，临界点向低温高压方向偏移；②采气期间，传质以蒸发抽提为主，溶解扩散为辅，表现为原油密度和黏度增大，气体密度和黏度减小，当油气体系压力达到下限压力，原油密度和黏度达到最大，气体密度和黏度达到最小，相包络线向左上偏移，临界点向低温高压方向偏移；③单周期内，注气过程使易挥发油和重油变轻，重质组分含量减少，采气至下限压力后，黑油C₇+组分含量较初期减小，易挥发油C₇+组分含量较初期增大；④多周期内，随着注采周期数增加，黑油在采气至下限压力过程中，重质组分含量先减小后增大直至稳定，气顶对原油抽提能力基本为零，标志着建库完成，易挥发油在采气至下限压力过程中，重质组分含量先增大后稳定，气顶对原油抽提能力基本为零，建库完成。

关键词: 油藏型储气库, 多周期, 多级压力, 相间传质, 蒸发抽提, 溶解扩散

Abstract:

Five typical continental reservoir crude oils in China were selected as research objects. Single-cycle and multi-cycle injection and production experiments were conducted using a simulation platform for oil-gas phase behavior during injection and production in gas storage reservoirs, which was developed based on ultra-high-pressure fluid phase analysis. Oil-gas properties under multi-stage pressures during single-cycle injection and production were investigated for three types of crude oils with different properties. Oil-gas characteristics during multi-cycle injection and production were examined for two types of crude oils with different properties. These revealed the relationship between interphase mass transfer patterns and the number of construction cycles in the oil and gas system of continental reservoir gas storage construction, providing theoretical guidance for determining the number of construction cycles for converting reservoirs of different types into gas storage. The experimental results showed that: (1) During gas injection, mass transfer was primarily driven by dissolution and diffusion, supplemented by evaporation and extraction. This led to a decrease in the density and viscosity of crude oil, a left-upward shift of the phase envelope, and a shift of the critical point towards lower temperatures and higher pressures. (2) During gas production, mass transfer was dominated by evaporation and extraction, supplemented by dissolution and diffusion. This manifested as increases in crude oil density and viscosity and decreases in gas density and viscosity. When the pressure of the oil and gas system reached the lower limit, the density and viscosity of crude oil reached their maximum values, while the density and viscosity of gas reached their minimum. Meanwhile, the phase envelope shifted left and upward, and the critical point moved towards lower temperatures and higher pressures. (3) Within a single cycle, the gas injection process lightened both volatile oil and heavy oil, reducing the content of heavy components. After gas production down to the lower limit pressure, the content of black oil C₇+ components decreased compared to the initial stage, while the content of volatile oil C₇+ components increased compared to the initial state. (4) Over multiple cycles, as the number of injection and production cycles increased, during the gas production process down to the lower limit pressure, the content of heavy components in black oil first decreased and then increased until it stabilized. The extraction capacity of the gas cap for crude oil was basically zero, indicating the completion of the reservoir construction. For volatile oil during the gas production process down to the lower limit pressure, the content of heavy components in volatile oil first increased and then stabilized. The extraction capacity of the gas cap for crude oil was also basically zero, marking the completion of gas storage construction.

Key words: reservoir-type gas storage, multi-cycle, multi-stage pressure, interphase mass transfer, evaporation and extraction, dissolution and diffusion

中图分类号:

TE81

孔德彬,杨星星,张可, 等. 油藏改建储气库多周期与单周期多级压力下相间传质研究[J]. 油气藏评价与开发, 2025, 15(6): 1130-1138.

KONG Debin,YANG Xingxing,ZHANG Ke, et al. Study on interphase mass transfer under multi-cycle and single-cycle multi-stage pressure conditions during reservoir conversion to gas storage[J]. Petroleum Reservoir Evaluation and Development, 2025, 15(6): 1130-1138.

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组分	1号原油摩尔分数	2号原油摩尔分数	3号原油摩尔分数	4号原油摩尔分数	5号原油摩尔分数
CO₂	0.07	1.25	0.07	0.52	0.310
N₂	0.57	1.46	0.45	0.37	0.127
C₁	13.86	41.54	51.37	42.43	43.133
C₂	2.66	2.52	3.35	5.30	6.578
C₃	0.80	0.50	0.98	4.36	5.111
iC₄	0.15	0.12	0.46	1.92	6.363
nC₄	0.23	0.08	0.37	3.36	2.589
iC₅	3.18	1.02	2.24	2.28	5.218
nC₅	1.83	1.21	1.30	2.61	0.979
C₆	4.44	2.49	2.64	2.70	1.261
C₇	5.29	4.15	3.85	3.02	1.323
C₈	4.99	5.04	4.39	3.04	1.554
C₉	3.98	4.36	3.58	3.05	1.626
C₁₀	3.53	3.72	3.00	3.01	0.924
C₁₁+	54.42	30.55	21.96	22.03	22.904

组分	摩尔分数
N₂	0.50
CO₂	0.23
C₁	95.05
C₂	1.50
C₃	1.20
iC₄	0.80
nC₄	0.72

油藏改建储气库多周期与单周期多级压力下相间传质研究

Study on interphase mass transfer under multi-cycle and single-cycle multi-stage pressure conditions during reservoir conversion to gas storage

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