油气藏评价与开发 ›› 2024, Vol. 14 ›› Issue (3): 402-413.doi: 10.13809/j.cnki.cn32-1825/te.2024.03.010
收稿日期:
2023-10-30
发布日期:
2024-07-10
出版日期:
2024-06-26
通讯作者:
第凯翔(1992—),男,在读博士研究生,主要从事非常规储层非线性有效应力及多尺度孔隙结构描述相关研究。地址:四川省成都市新都区新都大道8号西南石油大学,邮政编码:610500。E-mail: 作者简介:
唐慧莹(1990—),女,博士,副教授,主要从事非常规储层压裂及一体化数值模拟研究。地址:四川省成都市新都区新都大道8号西南石油大学,邮政编码:610500。E-mail: 基金资助:
TANG Huiying(),DI Kaixiang(),ZHANG Liehui,GUO Jingjing,ZHANG Tao,TIAN Ye,ZHAO Yulong
Received:
2023-10-30
Online:
2024-07-10
Published:
2024-06-26
摘要:
基于一种新的核磁共振信号标定法开展了致密砂岩岩样的油水渗吸实验,该方法可以根据回归模型将核磁信号总量换算为含油体积,相较常规方法计算更方便、更准确。研究发现渗吸过程可划分为过渡渗吸和稳定渗吸2个阶段,低黏度煤油渗吸样品最佳渗吸时间集中在68 h左右,高黏度致密油渗吸样品最佳渗吸时间集中在188 h左右。渗吸时间充足的情况下,煤油和致密油的最终换油率相差不大,但如果渗吸时间较短,则黏度越大换油率越低。同层位、同黏度的样品具有相似的渗吸动态特征;同层位、高黏油的样品达到稳定渗吸阶段无因次渗吸时间相较低黏油更短。以半径0.5 μm作为大、小孔隙的分界线,煤油渗吸样品中半径小于0.5 μm的孔隙渗吸换油贡献率平均为83.93%,占据主导地位,原油动用率平均为23.54%;半径大于0.5 μm的孔隙渗吸换油贡献率平均为16.07%,相对较少,原油的动用率平均为8.50%,普遍较低,容易形成水锁。致密油渗吸样品在所有孔隙中的渗吸换油贡献率则相对均衡,半径小于0.5 μm的孔隙原油动用率平均为14.82%,相对较低;而半径大于0.5 μm的孔隙原油动用率平均为29.82%,在焖井过程中普遍会得到有效动用。
中图分类号:
Huiying TANG,Kaixiang DI,Liehui ZHANG, et al. Tight oil imbibition based on nuclear magnetic resonance signal calibration method[J]. Petroleum Reservoir Evaluation and Development, 2024, 14(3): 402-413.
表1
岩心切分前、后基础参数"
岩心切分前 编号 | 长度/ mm | 直径/ mm | 孔隙度/ % | 渗透率/ (10-3 μm2) | 层位 | 岩心切分后 编号 | 干重/ g | 长度/ mm | 直径/ mm | 孔隙度/ % | 渗透率/ (10-3 μm2) |
---|---|---|---|---|---|---|---|---|---|---|---|
22 | 79.78 | 25.31 | 14.13 | 0.011 6 | 长63 | 22-1 | 42.173 | 37.55 | 25.31 | 15.26 | 0.23 |
22-2 | 44.314 | 39.31 | 25.31 | 13.67 | 0.20 | ||||||
49 | 72.50 | 25.17 | 13.86 | 0.223 0 | 长62 | 49-1 | 37.976 | 34.41 | 25.17 | 14.72 | 2.25 |
49-2 | 38.964 | 35.24 | 25.17 | 14.11 | 2.36 | ||||||
57 | 79.15 | 25.27 | 12.54 | 0.051 7 | 长61 | 57-1 | 42.371 | 37.26 | 25.27 | 13.28 | 0.08 |
57-2 | 43.473 | 37.86 | 25.27 | 11.87 | 0.06 | ||||||
58 | 78.80 | 25.27 | 7.90 | 0.020 2 | 长61 | 58-1 | 46.177 | 37.69 | 25.27 | 9.12 | 0.07 |
58-2 | 45.559 | 37.37 | 25.27 | 8.31 | 0.05 | ||||||
19 | 77.86 | 25.20 | 15.18 | 0.050 0 | 长63 | 19-1 | 41.545 | 37.63 | 25.20 | 14.37 | 0.20 |
19-2 | 40.953 | 37.30 | 25.20 | 15.66 | 0.28 | ||||||
17 | 78.73 | 25.22 | 16.36 | 0.108 0 | 长63 | 17-1 | 40.963 | 37.43 | 25.22 | 12.18 | 0.65 |
17-2 | 41.276 | 37.72 | 25.22 | 17.59 | 1.26 | ||||||
47 | 81.40 | 25.28 | 13.83 | 0.102 0 | 长63 | 47-1 | 44.536 | 39.58 | 25.28 | 14.16 | 0.29 |
47-2 | 45.798 | 38.44 | 25.28 | 14.67 | 0.19 | ||||||
50 | 70.92 | 25.26 | 15.14 | 0.354 0 | 长62 | 50-1 | 36.934 | 33.51 | 25.26 | 16.44 | 3.58 |
50-2 | 37.669 | 34.04 | 25.26 | 15.94 | 2.66 |
表2
样品渗吸换油结果信息"
样品 编号 | 含油体积/ mL | 换油量/ mL | 换油率/ % | 渗吸稳定时间/ h |
---|---|---|---|---|
17-1 | 1.917 | 0.373 | 19.44 | 68 |
19-1 | 1.855 | 0.260 | 14.04 | 68 |
22-1 | 1.669 | 0.202 | 12.14 | 68 |
47-1 | 1.260 | 0.212 | 16.81 | 68 |
49-1 | 1.920 | 0.173 | 9.03 | 95 |
50-1 | 1.886 | 0.257 | 13.61 | 195 |
57-1 | 1.840 | 0.414 | 22.52 | 50 |
58-1 | 1.090 | 0.283 | 25.94 | 68 |
17-2 | 2.344 | 0.251 | 10.72 | 166 |
19-2 | 2.238 | 0.302 | 13.50 | 188 |
22-2 | 1.832 | 0.183 | 9.97 | 188 |
47-2 | 1.374 | 0.234 | 17.02 | 188 |
49-2 | 2.434 | 0.234 | 9.63 | 122 |
50-2 | 2.350 | 0.348 | 14.82 | 188 |
57-2 | 2.042 | 0.425 | 20.81 | 188 |
58-2 | 1.205 | 0.295 | 24.51 | 188 |
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