砂岩油藏改建储气库渗流仿真实验和产能预测——以大港油田板深37断块为例

doi:10.13809/j.cnki.cn32-1825/te.2025.06.019

摘要/Abstract

摘要：

油藏型储气库作为近年来国内外发展的一种新型开发模式，且中国许多含油构造具有改建储气库的条件，在进一步提高中国油藏采收率、丰富储气库类型和保供区域需求方面有着广泛的应用前景。利用大港油田板深37断块全直径岩心和依据油藏建库注采模式特点，设计多周期驱替交变实验，分析了砂岩油藏改建储气库渗流机理和构建了油藏改建储气库单井产能预测模型。实验结果表明：①气体对水和油均具有驱替和抽提作用，在提高储气库库容中起正向作用；②在气驱水和气驱油多周期驱替交变实验中（分别模拟含水层或水驱油藏开采后期和开发早期的油藏改建储气库），明确扩容能力随着注采次数增加呈幂函数关系，最终扩容能力分别为0.277 3、0.337 4 PV，且适当降低储气库最低运行压力可以实现更好的扩容；③在气驱油水多周期驱替交变实验中（模拟实际开发中的油藏改建储气库），明确在油水共存条件下，含水饱和度越高（实验建立岩心的初始含水饱和度分别为47.04%、63.50%），储气库扩容的能力越弱（实验扩容能力分别为0.325 1、0.318 5 PV）；④基于油气相渗曲线测试结果，提出了不同于数值模拟的油藏改建储气库单井产能快速预测方法，建立不同注采轮次下的产能方程和无阻流量。研究成果为油藏改建储气库的早期库容分析和产能设计提供了重要指导。

关键词: 砂岩油藏, 改建储气库, 产能预测, 采气速度, 室内试验

Abstract:

Reservoir-converted gas storage has emerged as a new development approach worldwide in recent years. Many oil-bearing structures in China meet the conditions for conversion into gas storage, offering broad application prospects for improving oil recovery rates, diversifying gas storage types, and meeting regional gas supply demands. Using a full-diameter core from the Banshen 37 fault block in the Dagang Oilfield and based on the injection-production patterns of reservoir-converted gas storage, a multi-cycle displacement alternating experiment was designed to analyze the seepage mechanisms of converted gas storage in sandstone oil reservoirs and establish a single-well productivity prediction model. The experimental results demonstrate that: (1) Gas exhibits both displacement and extraction effects on water and oil, positively contributing to the enhancement of gas storage capacity. (2) In multi-cycle displacement alternating experiments of gas-water and gas-oil displacement (simulating the late-stage development of water-bearing layers or water-driven oil reservoirs and the early-stage development of converted gas storage in oil reservoirs, respectively), the storage capacity expansion follows a power-law relationship with the number of injection-production cycles, ultimately reaching 27.73% and 33.74%, respectively. Moreover, appropriately lowering the minimum operating pressure of the gas storage can enhance storage capacity. (3) In multi-cycle gas-oil-water displacement alternating experiments (simulating the actual development of converted gas storage in oil reservoirs), under oil-water coexistence conditions, higher water saturation weakens the expansion capacity of the gas storage (with initial water saturation of the core in the two experiments at 47.04% and 63.50%, respectively, leading to expansion capacities of 32.51% and 31.85% , respectively); ④ Based on relative permeability curve tests, a rapid prediction method different from numerical simulation was proposed for single-well productivity of converted gas storage in oil reservoirs. Productivity equations and absolute open flow under different injection-production cycles were established. The findings provide essential guidance for early-stage storage capacity analysis and productivity design of converted gas storage in oil reservoirs.

Key words: sandstone oil reservoir, converted gas storage, productivity prediction, gas production rate, laboratory experiment

中图分类号:

TE357

吕栋梁,黎鸿屿,李健, 等. 砂岩油藏改建储气库渗流仿真实验和产能预测——以大港油田板深37断块为例[J]. 油气藏评价与开发, 2025, 15(6): 1121-1129.

LYU Dongliang,LI Hongyu,LI Jian, et al. Seepage simulation experiment and productivity prediction of converted gas storage in sandstone oil reservoirs: A case study of Banshen 37 fault block in Dagang Oilfield[J]. Petroleum Reservoir Evaluation and Development, 2025, 15(6): 1121-1129.

图/表 14

图1

表1

图2

图3

图4

图5

图6

图7

图8

图9

图10

图11

表2

大港油田板深37断块不同注采周期产能方程和无阻流量"

注采周期	产能方程	q_AOF/（10⁴m³/d）
周期一	$p i 2 - p w f 2 = 147.48 q s c + 0.000 4 q s c 2$	12.54
周期二	$p i 2 - p w f 2 = 9.96 q s c + 7.91 × 10 - 7 q s c 2$	185.67
周期三	$p i 2 - p w f 2 = 9.31 q s c + 7.17 × 10 - 7 q s c 2$	198.52
周期四	$p i 2 - p w f 2 = 9.03 q s c + 6.85 × 10 - 7 q s c 2$	204.85
周期五	$p i 2 - p w f 2 = 8.77 q s c + 6.57 × 10 - 7 q s c 2$	210.73

表2

图12

参考文献 28

[1]	江同文, 王锦芳, 王正茂, 等. 地下储气库与天然气驱油协同建设实践与认识[J]. 天然气工业, 2021, 41(9): 66-74.
	JANG Tongwen, WANG Jinfang, WANG Zhengmao, et al. Practice and understanding of collaborative construction of underground gas storage and natural gas flooding[J]. Natural Gas Industry, 2021, 41(9): 66-74.
[2]	糜利栋, 曾大乾, 刘华, 等. 中国石化地下储气库一体化综合平台研发与应用[J]. 油气藏评价与开发, 2023, 13(6): 781-788.
	MI Lidong, ZENG Daqian, LIU Hua, et al. Development and application of Sinopec integrated management platform for underground gas storage[J]. Petroleum Reservoir Evaluation and Development, 2023, 13(6): 781-788.
[3]	陈芳, 刘万成, 吴津, 等. 吐哈油田超低压储气库钻井工程方案优化设计与应用[J]. 天然气勘探与开发, 2024, 47(3): 70-76.
	CHEN Fang, LIU Wancheng, WU Jin, et al. Drilling programmes for an underground gas storage with ultra-low pressure, Tuha oilfield: Optimization and application[J]. Natural Gas Exploration and Development, 2024, 47(3): 70-76.
[4]	糜利栋, 曾大乾, 刘华, 等. 天然气地下储气库智能化建设关键技术及其发展趋势[J]. 石油与天然气地质, 2024, 45(2): 581-592.
	MI Lidong, ZENG Daqian, LIU Hua, et al. Key technologies and development trends for intelligent construction of underground gas storage facilities[J]. Oil & Gas Geology, 2024, 45(2): 581-592.
[5]	黄兵, 汪勇, 王明华, 等. 黄草峡储气库钻井难点及对策[J]. 天然气勘探与开发, 2024, 47(6): 80-86.
	HUANG Bing, WANG Yong, WANG Minghua, et al. Drilling difficulties in Huangcaoxia UGS and their countermeasures[J]. Natural Gas Exploration and Development, 2024, 47(6): 80-86.
[6]	糜利栋, 曾大乾, 李遵照, 等. 中国石化地下储气库智能化建设进展及展望[J]. 世界石油工业, 2023, 30(6): 88-95.
	MI Lidong, ZENG Daqian, LI Zunzhao, et al. Progress and prospect of intelligent of Sinopec underground gas storage[J]. World Petroleum Industry, 2023, 30(6): 88-95.
[7]	王皆明, 朱亚东, 王莉, 等. 北京地区地下储气库方案研究[J]. 石油学报, 2000, 21(3): 100-104.
	WANG Jieming, ZHU Yadong, WANG Li, et al. Study on underground gas storage facility plans in Beijing Area[J]. Acta Petrolei Sinica, 2000, 21(3): 100-104.
[8]	王洪光, 许爱云, 王皆明, 等. 裂缝性油藏改建地下储气库注采能力评价[J]. 天然气工业, 2005, 25(12): 115-117.
	WANG Hongguang, XU Aiyun, WANG Jieming, et al. Evaluation of injection/recovery capacity for underground gas storage reformed by fractured reservoir[J]. Natural Gas Industry, 2005, 25(12): 115-117.
[9]	郑鑫, 赵昱超, 赵梓寒, 等. 缝洞型碳酸盐岩储气库地应力变化特征及力学完整性研究[J]. 油气藏评价与开发, 2024, 14(5): 814-824.
	ZHENG Xin, ZHAO Yuchao, ZHAO Zihan, et al. Mechanism investigation on in-situ stress characteristics and mechanical integrity of fracture-cavity carbonate underground gas storage reservoir[J]. Petroleum Reservoir Evaluation and Development, 2024, 14(5): 814-824.
[10]	张静楠, 闫锋, 常宝华, 等. 深层洞穴型油藏改建地下储气库的可行性[J]. 油气储运, 2013, 32(12): 1304-1307.
	ZHANG Jingnan, YAN Feng, CHANG Baohua, et al. Feasibility of reconstructing deep cave reservoir into underground gas storage[J]. Oil & Gas Storage and Transportation, 2013, 32(12): 1304-1307.
[11]	杨胜来, 陈浩, 冯积累, 等. 塔里木油田改善注气开发效果的关键问题[J]. 油气地质与采收率, 2014, 21(1): 40-44.
	YANG Shenglai, CHEN Hao, FENG Jilei, et al. A brief discussion on some scientific issues to improve oil displacement during gas injection[J]. Petroleum Geology and Recovery Efficiency, 2014, 21(1): 40-44.
[12]	杨俊丰, 罗敏, 彭海军, 等. 注气提采与战略储气库协同建设经济评价: 以塔里木油田A油藏为例[J]. 天然气技术与经济, 2020, 14(6): 72-78.
	YANG Junfeng, LUO Min, PENG Haijun, et al. Economic evaluation on collaborative constructing gas injection EOR and strategic gas storage: Examples from A oil reservoirs, Tarim oilfield: An example from A oil reservoirs in Tarim oilfield[J]. Natural Gas Technology and Economy, 2020, 14(6): 72-78.
[13]	何睿, 郭平, 孙良田, 等. 高含水油藏储气库建库微观模型可视化实验研究[J]. 特种油气藏, 2006, 13(2): 82-84.
	HE Rui, GUO Ping, SUN Liangtian, et al. Visualization study of gas storage model for high water cut reservoir[J]. Special Oil and Gas Reservoirs, 2006, 13(2): 82-84.
[14]	杜玉洪, 李苗, 杜建芬, 等. 油藏改建储气库注采速度敏感性实验研究[J]. 西南石油大学学报(自然科学版), 2007, 29(2): 27-30.
	DU Yuhong, LI Miao, DU Jianfen, et al. Experimental study on injection-production rate sensibility of reconstructing underground natural gas storage[J]. Journal of Southwest Petroleum University(Science & Technology Edition), 2007, 29(2): 27-30.
[15]	班凡生, 高树生, 王皆明. 枯竭油藏改建储气库注采运行机理研究[J]. 天然气地球科学, 2009, 20(6): 1005-1008.
	BAN Fansheng, GAO Shusheng, WANG Jieming. Gas injection-production mechanism of gas storage in depleted oil reservoirs[J]. Natural Gas Geoscience, 2009, 20(6): 1005-1008.
[16]	熊钰, 徐宏光, 李辉, 等. 废弃油藏建储气库库容变化机理室内实验研究[J]. 科学技术与工程, 2015, 15(6): 173-176.
	XIONG Yu, XU Hongguang, LI Hui, et al. A research on the change mechanism of storage capacity of abandoned oil reservoirs to build gas storage space through indoor test[J]. Science Technology and Engineering, 2015, 15(6): 173-176.
[17]	常进, 高树生, 熊伟, 等. 高含水油藏改建储气库可视化物理模拟实验[J]. 西安石油大学学报(自然科学版), 2015, 30(1): 52-56.
	CHANG Jin, GAO Shusheng, XIONG Wei, et al. Visual physical simulation of high water-cut reservoir being reconstructed as gas storage[J]. Journal of Xi’an Shiyou University (Natural Science Edition), 2015, 30(1): 52-56.
[18]	TOOSEH E K, JAFARI A, TEYMOURI A. Gas-water-rock interactions and factors affecting gas storage capacity during natural gas storage in a low permeability aquifer[J]. Petroleum Exploration and Development, 2018, 45(6): 1123-1128.
[19]	SOHRABI M, TEHRANI D H, DANESH A, et al. Visualization of oil recovery by water-alternating-gas injection using high-pressure micromodels[J]. SPE Journal, 2004, 9(3): 290-301.
[20]	OH J, KIM K Y, HAN W S, et al. Experimental and numerical study on supercritical CO₂/brine transport in a fractured rock: Implications of mass transfer, capillary pressure and storage capacity[J]. Advances in Water Resources, 2013, 62(12): 442-453.
[21]	郑少婧, 郑得文, 孙军昌, 等. 气藏型储气库温度敏感性及其对气井注采能力的影响[J]. 石油实验地质, 2022, 44(2): 365-372.
	ZHENG Shaojing, ZHENG Dewen, SUN Junchang, et al. Temperature-sensitivity of underground gas reservoir storage and its effect on well deliverability[J]. Petroleum Geology and Experiment, 2022, 44(2): 365-372.
[22]	胡书勇, 胡欣芮, 李勇凯, 等. 枯竭气藏型储气库CO₂作垫层气的可行性研究[J]. 油气藏评价与开发, 2018, 8(5): 56-59.
	HU Shuyong, HU Xinrui, LI Yongkai, et al. Feasibility analysis about taking CO₂ as cushion gas for gas storage rebuilt upon depleted gas reservoirs[J]. Petroleum Reservoir Evaluation and Development, 2018, 8(5): 56-59.
[23]	糜利栋, 曾大乾, 刘华, 等. 带油环凝析气藏注气提采协同储气库建设研究[J]. 世界石油工业, 2025, 32(2): 89-98.
	MI Lidong, ZENG Daqian, LIU Hua, et al. Construction of coordinated gas storage for gas injection and extraction of condensate gas reservoir with oil ring[J]. World Petroleum Industry, 2025, 32(2): 89-98.
[24]	胡俊, 杨佳坤, 胥洪成, 等. 复杂地质条件储气库多因素库容复核新方法[J]. 油气藏评价与开发, 2024, 14(5): 795-804.
	HU Jun, YANG Jiakun, XU Hongcheng, et al. A new method for multi-factor capacity review of underground gas storage under complex geological conditions[J]. Petroleum Reservoir Evaluation and Development, 2024, 14(5): 795-804.
[25]	王皆明, 姜凤光. 砂岩气顶油藏改建储气库库容计算方法[J]. 天然气工业, 2007, 27(11): 97-99.
	WANG Jieming, JIANG Fengguang. A method for calculating underground gas storage capacity reconstructed from sand gas-cap reservoir at the late water-driving stage[J]. Natural Gas Industry, 2007, 27(11): 97-99.
[26]	王皆明, 姜凤光. 砂岩油藏改建地下储气库注气能力预测方法[J]. 天然气地球科学, 2008, 19(5): 727-729.
	WANG Jieming, JIANG Fengguang. A method for predicting gas injection ability of UGS rebuilt from a sandstone reservoir[J]. Natural Gas Geoscience, 2008, 19(5): 727-729.
[27]	STONE H L. Estimation of three-phase relative permeability and residual oil data[J]. Journal of Canadian Petroleum Technology, 1973, 12(4): 53-61.
[28]	吕栋梁, 杨健, 林立明, 等. 砂岩储层油水相对渗透率曲线表征模型及其在数值模拟中的应用[J]. 岩性油气藏, 2023, 35(1): 145-159.
	Dongliang LYU, YANG Jian, LIN Liming, et al. Characterization model of oil-water relative permeability curves of sandstone reservoir and its application in numerical simulation[J]. Lithologic Reservoirs, 2023, 35(1): 145-159.

分类	长度/cm	直径/cm	孔隙度/%	渗透率/10^-3μm²	束缚水饱和度/%
实验岩心	9.942	10.02	17.72	18.96	39.3
区块目标值			17.90	18.30	37.0