基于岩性相单元和孔隙结构的低孔低渗储层有效性测井识别方法:以西湖凹陷NB1构造为例

doi:10.19657/j.geoscience.1000-8527.2021.144

摘要/Abstract

摘要：

东海西湖凹陷是近海最大的盆地之一,近些年在中深层花港组储层中获得重大发现。然而,由于储层具有厚度大、非均质性强、低孔低渗、孔隙结构复杂等特征,给精细评价和甜点储层的预测带来极大困难。利用高分辨率电成像资料,在岩性和层理构造识别的基础上,将研究区储层划分成槽状交错层理细中砂岩、板状交错层理细中砂岩、槽状交错层理细砂岩、板状交错层理细砂岩、块状层理砂岩及钙质胶结砂岩6种微尺度的岩性相单元,并利用核磁共振测井资料对不同岩性相单元的孔隙结构进行了精细表征。结果表明,槽状交错层理细中砂岩、板状交错层理细中砂岩、槽状交错层理细砂岩3种岩性相的排驱压力<0.5 MPa、平均孔喉半径>0.5 μm,板状交错层理细砂岩岩性相的排驱压力为0.5~1.0 MPa、平均孔喉半径为0.25~0.50 μm,这4种岩性相单元岩性较粗、交错层理发育、排驱压力较小、平均孔喉半径较大,为研究区甜点储层。在此基础上,建立了适用于研究区储层精细评价和甜点储层识别的分类方案,为研究区下一步勘探开发提供可靠依据。

关键词: 西湖凹陷, 中深层储层, 电成像, 岩性相, 孔隙结构, 甜点储层

Abstract:

The Xihu Sag in the East China Sea is one of the largest offshore basins. In recent years, major oil and gas discoveries have been made in the reservoirs of the mid-deep Huagang Formation. However, due to the large thickness, strong heterogeneity, low porosity and low permeability, and complex pore structure of the reservoir, it brings great difficulties to fine evaluation and prediction of sweet spots. This paper classified 6 types of micro-scale lithofacies units for the reservoirs in the study area based on the identification of lithology and bedding structure by using high-resolution electrical imaging data, namely trough cross bedding fine-medium sandstone, plate cross bedding fine-medium sandstone, trough cross bedding fine sandstone, plate cross bedding fine sandstone, massive bedding sandstone and calcareous cemented sandstone. And furthermore, NMR logging data was used to finely characterize the pore structure of different lithofacies units. The results show that the three lithofacies of trough cross bedding fine-medium sandstone, plate cross bedding fine-medium sandstone, and trough cross bedding fine sandstone have a drainage pressure less than 0.5 MPa and an average pore throat radius greater than 0.5 μm. The lithofacies of plate cross bedding fine sandstone has a displacement pressure between 0.5 MPa and 1.0 MPa, and an average pore throat radius between 0.25 μm and 0.5 μm. The above four types of lithofacies have coarser lithology, more developed cross bedding, lower displacement pressure, and larger average pore throat radius, which are favorable sweet spots in the study area. Based on the above studies, a classification scheme suitable for fine reservoir evaluation and sweet spots identification in the study area has been established, which provides a reliable basis for further exploration and development in the study area.

Key words: Xihu Sag, mid-deep formation, electrical imaging, lithofacies, pore structure, sweet spot

中图分类号:

崔维平, 杨玉卿, 刘建新. 基于岩性相单元和孔隙结构的低孔低渗储层有效性测井识别方法:以西湖凹陷NB1构造为例[J]. 现代地质, 2022, 36(01): 140-148.

CUI Weiping, YANG Yuqing, LIU Jianxin. Logging Identification Method of Low Porosity and Low Permeability Reservoir Effectiveness Based on Lithofacies Units and Pore Structures: An Example from NB1 Structure in Xihu Depression[J]. Geoscience, 2022, 36(01): 140-148.

图/表 8

图1 西湖凹陷NB1构造位置图

Fig.1 Location map of NB1 structure in Xihu Sag

图2 低孔低渗储层喉道特征 (a) 管束状喉道;(b)片状喉道;(c)弯片状喉道;(d)缩颈型喉道

Fig.2 Throat characteristics of low porosity and low permeability reservoirs

图3 低孔低渗储层孔喉结构特征

Fig.3 Characteristics of pore throat structure of low porosity and low permeability reservoirs

图4 NB1构造花港组主要岩性相类型

Fig.4 Main lithofacies types of Huagang Formation in NB1 structure

表1 NB1构造3口井岩性相类型与物性统计

Table 1 Physical properties statistics of lithofacies of 3 wells in NB1 structure

岩性相类型	NB1-1井				NB1-2井				NB1-3井
岩性相类型	厚度/m	占比/%	孔隙度 /%	渗透率/ 10^-3μm²	厚度/m	占比/%	孔隙度 /%	渗透率/ 10^-3μm²	厚度/m	占比/%	孔隙度 /%	渗透率/ 10^-3μm²
槽状交错层理细中砂岩					8.3	2.8	14.0	43.10
板状交错层理细中砂岩					13.4	4.5	13.6	32.00
槽状交错层理细砂岩	13.4	5.8	10.8	11.30	15.6	5.3	10.3	13.90	12.7	4.6	12.9	24.20
板状交错层理细砂岩	35.0	15.1	11.5	9.60	43.2	14.5	10.3	8.90	31.7	11.5	10.7	9.20
块状层理砂岩	89.2	35.8	7.4	0.15	109.2	34.8	6.6	0.12	117.2	35.4	6.0	0.13
钙质胶结砂岩	94.1	40.6	9.3	0.01	107.4	36.1	7.6	0.02	114.9	41.6	8.3	0.01
合计	231.7				297.1				276.5

图5 NB1构造NB1-2井花港组目的层砂体岩性相单元解析

Fig.5 Analysis of lithofacies units of target sand body in Huagang Formation in well NB1-2 of NB1 structure

图6 NB1构造不同岩性相孔隙结构特征

Fig.6 Pore structure characteristics of different lithofacies in NB1 structure

表2 NB1构造花港组储层分类表

Table 2 Reservoir classification table of NB1 structure Huagang Formation

储层分类	岩性相	可动孔隙度/%	渗透率/10^-3μm²	排驱压力/MPa	平均孔喉半径/μm
Ⅰ	槽状交错层理细中砂岩、板状交错层理细中砂岩、槽状交错层理细砂岩	>10	>10	<0.5	>0.5
Ⅱ	板状交错层理细砂岩	6~10	1~10	0.5~1.0	0.25~0.5
Ⅲ	块状层理砂岩	3~6	0.1~1.0	1.0~1.5	0.10~0.25
Ⅳ	钙质胶结砂岩	<3	<0.1	>1.5	<0.1

参考文献 24

[1]	谢玉洪. 中国海油近海油气勘探实践与思考[J]. 中国海上油气, 2020, 32(2):1-13.
[2]	许建红. 低渗透油藏产能主要影响因素分析与评价[J]. 西南石油大学学报(自然科学版), 2012, 34(2):144-148.
[3]	毛志强, 李进福. 油气层产能预测方法及模型[J]. 石油学报, 2009, 30(5):58-61.
[4]	宋宣毅, 刘月田, 马晶, 等. 基于灰狼算法优化的支持向量机产能预测[J]. 岩性油气藏, 2020, 32(2):134-140.
[5]	曾大乾, 李淑珍. 中国低渗透砂岩储集层类型及地质特征[J]. 石油学报, 1994, 15(1): 38-46.
[6]	杨晓萍, 赵文智, 邹才能, 等. 低渗透储集层成因机理及优质储集层形成与分布[J]. 石油学报, 2007, 28(4): 57-61.
[7]	杨玉卿, 潘福熙, 田洪, 等. 渤中25-1油田沙河街组低孔低渗储层特征及分类评价[J]. 现代地质, 2010, 24(4): 685-693.
[8]	谢庆宾, 李娜, 刘昊天, 等. 四川盆地东部建南地区三叠系须家河组低孔低渗储集层特征及形成机理[J]. 古地理学报, 2014, 16(1): 89-102.
[9]	张哨楠. 致密天然气砂岩储层成因和讨论[J]. 石油与天然气地质, 2008, 29(1): 1-10.
[10]	王居峰, 郭彦如, 张延玲, 等. 鄂尔多斯盆地三叠系延长组层序地层格架与沉积相构成[J]. 现代地质, 2009, 23(5):803-808.
[11]	杨玉卿, 崔维平, 冯进, 等. 基于岩性相单元的低孔低渗碎屑岩储层质量精细评价--以珠江口盆地HZ25-7构造古近系文昌组为例[J]. 海相油气地质, 2017, 22(3):85-94.
[12]	楚美娟, 郭正权, 齐亚林, 等. 鄂尔多斯盆地延长组长8储层定量化成岩作用及成岩相分析[J]. 天然气地球科学, 2013, 24(3):477-484.
[13]	徐深谋, 林春明, 王鑫峰, 等. 鄂尔多斯盆地大牛地气田下石盒子组盒2-3段储层成岩作用及其对储层物性的影响[J]. 现代地质, 2011, 25(5):909-916.
[14]	蒋凌志, 顾家裕, 郭彬程. 中国含油气盆地碎屑岩低渗透储层的特征及形成机理[J]. 沉积学报, 2004, 22(1):13-18.
[15]	MIALL A D. Lithofacies types and vertical profile models in braided river deposits:A summary[M]//MIALL A D. Fluvial Sedimentology. Calgary: Canada Society of Petroleum Geologist, 1977:597-604.
[16]	杨玉卿, 崔维平, 李俊良, 等. 电成像测井在珠江口盆地西部低阻油层研究中的应用[J]. 中国海上油气, 2011, 23(6):369-373.
[17]	杨玉卿, 崔维平, 田洪. 碎屑岩成像测井沉积学研究及其在海上油田的应用[J]. 海相油气地质, 2012, 17(3):40-46.
[18]	崔维平, 杨玉卿. 利用测井资料识别重力流沉积及意义[J]. 岩性油气藏, 2011, 23(5):78-81.
[19]	崔维平, 杨玉卿, 李俊良, 等. 电成像测井在珠江口盆地西部沉积相研究中的应用[J]. 石油天然气学报, 2012, 34(3):89-95.
[20]	鲁超, 焦养泉, 吴立群, 等. 渤海湾盆地歧北凹陷古近系沙二段复合三角洲内部结构及空间演化[J]. 现代地质, 2010, 24(2):311-320.
[21]	杨玉卿, 崔维平, 王猛. 成像测井沉积学研究进展与发展趋势[J]. 中国海上油气, 2017, 29(3):7-18.
[22]	罗群, 魏浩元, 刘冬冬, 等. 层理缝在致密油成藏富集中的意义、研究进展及其趋势[J]. 石油实验地质, 2017, 39(1):1-7.
[23]	李天降, 李子丰, 赵彦超, 等. 核磁共振与压汞法的孔隙结构一致性研究[J]. 天然气工业, 2006, 26(10):57-59.
[24]	邵维志, 丁娱娇, 刘亚, 等. 核磁共振测井在储层孔隙结构评价中的应用[J]. 测井技术, 2009, 33(1):52-56.