Study on Distribution and Plugging Method of Dominant Seepage Channels after Polymer Flooding

doi:10.3969/j.issn.1006-396X.2021.04.008

Abstract

Abstract:

Most of PI formation reservoir in Daqing Oilfield has entered the subsequent water flooding stage, the cumulative recovery rate is about 57%, and more than 40% of geological reserves are still reserved in underground. After polymer flooding, the dominant seepage channels of PI formation reservoir appeared generally, but the inefficient circulation exist and get more serious. Based on coring, well logging and injection?production dynamic changing data, it is found that the dominant seepage channels are mainly formed at the bottom of the PI2 and PI3 units vertically, as well as interior of channel sandbodies on the plane parallelling to the paleocurrent direction. The thickness of the dominant seepage channel accounts for 10.6%, the remaining reserves 7.8%, and the water absorption proportion as high as 60.2%. In order to effectively block the dominant seepage channel after polymer flooding and decrease the inefficient circulation, PPG particles with high elasticity and strength were developed. The results of indoor flow experiments show that PPG particles have superior shear resistance performance and can flow into the deep reservoir to block the dominant seepage channel. The oil displacement experiments indicate that the enhanced oil recovery of PPG / weak base ASP flooding system can reach 15.6%, which is 3.3% higher than that of weak base ASP flooding, saving 28% of polymer consumption. The results in provide strong technical support for the continuous and efficient development of oilfield.

Key words: Polymer flooding, PI formation reservoir, Dominant seepage channel, Enhanced oil recovery

摘要：

大庆油田葡I 组油层大部分已进入后续水驱阶段，累计采出程度57%左右，仍有40%以上的地质储量留存地下。聚驱后葡I组油层优势渗流通道普遍发育，低效无效循环严重。综合应用取心资料、测井资料及注采动态变化资料，识别出优势渗流通道纵向上主要发育在葡I2、葡I3单元底部，平面上主要发育在河道砂体内部，且大部分平行于古水流方向。优势渗流通道厚度占10.6%，剩余储量占7.8%，吸水比例高达60.2%。为有效封堵聚驱后优势渗流通道、控制低效无效循环，自主研发具有较高弹性及强度的PPG颗粒。室内流动实验表明，PPG颗粒具有较好的抗剪切性能，可以进入油层深部封堵优势渗流通道。驱油实验表明，PPG/弱碱三元复合体系聚驱后提高采收率可达15.6%，较弱碱三元驱提高3.3%，节约聚合物用量28%。该研究成果可为油田的持续高效开发提供强力技术支撑。

关键词: 聚合物驱, 葡I组油层, 优势渗流通道, 提高采收率

CLC Number:

TE341

Guochao Liu. Study on Distribution and Plugging Method of Dominant Seepage Channels after Polymer Flooding[J]. Journal of Petrochemical Universities, 2021, 34(4): 46-52.

刘国超. 聚驱后优势渗流通道分布特征及封堵方法[J]. 石油化工高等学校学报, 2021, 34(4): 46-52.

Figures/Tables 9

Fig.1 Water injection profile of well Z51

Fig.2 Plant distribution characteristics of dominant seepage channels in PI2 and PI3 formation reservoir of block A

Table 1 Development of dominant seepage channels in PI1-7 reservoir of block A

井号	发育层位	注入压力/MPa	层位厚度/m	有效渗透率/μm²	优势渗流通道
井号	发育层位	注入压力/MPa	层位厚度/m	有效渗透率/μm²	厚度/m	厚度比例/%	渗透率/μm²	相对吸入量 /%	强度/ （m³ $⋅$ d^-1 $⋅$ m^-1）
平均单井		9.1	5.9	0.645	1.6	27.3	1.081	60.2	25.6
Z12	PI2	8.5	6.8	0.635	2.2	32.4	1.212	62.8	22.8
Z31	PI2	9.2	7.2	0.624	1.8	25.0	1.085	54.5	19.7
Z22	PI2	9.3	6.3	0.613	1.5	23.8	0.938	45.5	21.2
Z51	PI2	9.9	7.2	0.685	1.5	20.8	1.255	71.9	26.4
Z62	PI2	7.9	6.9	0.599	1.7	24.6	0.963	61.2	21.6
Z71	PI2	8.5	7.1	0.712	1.6	22.5	1.312	58.9	27.6
Z72	PI2	9.1	7.5	0.692	2.0	26.7	0.951	60.6	22.7
Z73	PI2	9.2	6.3	0.628	1.8	28.6	0.996	56.3	25.0
Z11	PI3	9.3	5.5	0.598	1.3	23.6	0.940	59.8	29.9
Z21	PI3	9.5	6.2	0.657	1.4	22.6	1.266	68.5	36.7
Z42	PI3	8.7	5.3	0.624	1.8	34.0	1.107	57.8	25.7
Z52	PI3	9.1	3.8	0.712	1.5	39.5	1.211	52.9	21.2
Z32	PI3	9.6	3.1	0.621	1.5	48.4	0.921	72.9	29.2
Z61	PI5+6	9.9	3.2	0.585	0.9	28.1	0.883	62.9	38.4

Table 1 Development of dominant seepage channels in PI1-7 reservoir of block A

井号	发育层位	注入压力/MPa	层位厚度/m	有效渗透率/μm²	优势渗流通道
井号	发育层位	注入压力/MPa	层位厚度/m	有效渗透率/μm²	厚度/m	厚度比例/%	渗透率/μm²	相对吸入量 /%	强度/ （m³ $⋅$ d^-1 $⋅$ m^-1）
平均单井		9.1	5.9	0.645	1.6	27.3	1.081	60.2	25.6
Z12	PI2	8.5	6.8	0.635	2.2	32.4	1.212	62.8	22.8
Z31	PI2	9.2	7.2	0.624	1.8	25.0	1.085	54.5	19.7
Z22	PI2	9.3	6.3	0.613	1.5	23.8	0.938	45.5	21.2
Z51	PI2	9.9	7.2	0.685	1.5	20.8	1.255	71.9	26.4
Z62	PI2	7.9	6.9	0.599	1.7	24.6	0.963	61.2	21.6
Z71	PI2	8.5	7.1	0.712	1.6	22.5	1.312	58.9	27.6
Z72	PI2	9.1	7.5	0.692	2.0	26.7	0.951	60.6	22.7
Z73	PI2	9.2	6.3	0.628	1.8	28.6	0.996	56.3	25.0
Z11	PI3	9.3	5.5	0.598	1.3	23.6	0.940	59.8	29.9
Z21	PI3	9.5	6.2	0.657	1.4	22.6	1.266	68.5	36.7
Z42	PI3	8.7	5.3	0.624	1.8	34.0	1.107	57.8	25.7
Z52	PI3	9.1	3.8	0.712	1.5	39.5	1.211	52.9	21.2
Z32	PI3	9.6	3.1	0.621	1.5	48.4	0.921	72.9	29.2
Z61	PI5+6	9.9	3.2	0.585	0.9	28.1	0.883	62.9	38.4

Fig.3 Core comprehensive histogram of development inspection well J11 of block A

Fig.4 Performance evaluation of PPG

Fig.5 Variation curve of pressure gradient and injection pore volume ratio

Table 2 Experimental results of PPG/weak base ASP flooding system

实验序号	驱油体系配方				采收率/%
实验序号	$ρ ($ PPG）/(mg $⋅$ L^-1)	$ρ ($ 聚合物)/(mg $⋅$ L^-1)	w(碳酸钠)/%	w(石油磺酸盐)/%	水驱	聚驱提高值	聚驱后提高值	累计
1	300	1 200	1.2	0.3	33.7	15.5	11.2	60.4
2	500	1 200			34.1	15.2	12.4	61.7
3	300	1 400			36.4	17.1	12.0	65.5
4	500	1 400			36.2	17.3	15.6	69.1
5	500	1 600			36.0	16.9	15.5	68.4
6	700	1 400			36.2	17.6	15.1	68.9
7		2 600			35.9	16.9	12.3	65.1

Table 2 Experimental results of PPG/weak base ASP flooding system

实验序号	驱油体系配方				采收率/%
实验序号	$ρ ($ PPG）/(mg $⋅$ L^-1)	$ρ ($ 聚合物)/(mg $⋅$ L^-1)	w(碳酸钠)/%	w(石油磺酸盐)/%	水驱	聚驱提高值	聚驱后提高值	累计
1	300	1 200	1.2	0.3	33.7	15.5	11.2	60.4
2	500	1 200			34.1	15.2	12.4	61.7
3	300	1 400			36.4	17.1	12.0	65.5
4	500	1 400			36.2	17.3	15.6	69.1
5	500	1 600			36.0	16.9	15.5	68.4
6	700	1 400			36.2	17.6	15.1	68.9
7		2 600			35.9	16.9	12.3	65.1

Fig.6 Variation curve of instantaneous diversion rate per unit thickness in different displacement stages of physical model experiment

Fig.7 Numerical simulation curve of PPG/weak alkali ternary composite system after polymer flooding in block A

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