鄂尔多斯盆地临兴区块不同叠置模式深部煤系储层动用策略研究

孙立春; 刘佳; 李新泽; 孙乐; 房茂军; 李娜; 樊伟鹏

doi:10.11781/sysydz2025040921

鄂尔多斯盆地临兴区块不同叠置模式深部煤系储层动用策略研究

doi: 10.11781/sysydz2025040921

中海石油(中国)有限公司北京研究中心, 北京 100028

基金项目:

中海石油(中国)有限公司“十四五”重大科技项目课题7“临兴神府深层煤层气赋存机理及与致密气协同开发关键技术研究” KJGG-2024-1007

详细信息

作者简介:
孙立春(1969—)，男，博士，教授级高级工程师，从事油气田开发、煤层气开发工程等研究。E-mail: sunlch@cnooc.com.cn

通讯作者:
刘佳(1988—)，男，博士，高级工程师，从事油气田开发工程研究。E-mail: liujia33@cnooc.com.cn

中图分类号: TE349
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出版历程
- 收稿日期: 2024-10-08
- 修回日期: 2025-06-18
- 刊出日期: 2025-07-28

Utilization strategies for deep coal-measure reservoirs with different stacking patterns in Linxing block, Ordos Basin

Beijing Research Center, CNOOC Limited, Beijing 100028, China

摘要

摘要: 鄂尔多斯盆地临兴区块已进入致密气、煤层气协同开发阶段，致密砂岩与煤层的叠置模式直接影响开发方式。通过对叠置关系的研究，并从临兴区块不同开发方式生产动态出发，进行深部煤系储层动用策略研究。基于致密砂岩与煤层发育沉积特征和相对位置关系，临兴区块砂煤叠置模式主要包括砂煤互层型和上砂下煤型。对比不同叠置模式下的开发现状，水平井是深层煤层气单独开发时的首选井型，煤层气与致密气两气合采井初期产气能力高于单采煤层直井定向井。进一步建立了以经济效益为优化目标的不同叠置模式下深层煤系储层动用策略优选图版：当煤层丰度小于1.1×10⁸ m³/km²、且致密气层为一类或二类气层时，采用两气合采方式进行开发；当煤层丰度介于(1.1~1.5)×10⁸ m³/km²时，若致密气层不发育，采用水平井单独动用煤层，若致密气层为一类或二类气层时，则采用致密气—煤层气两气合采方式进行开发；当煤层丰度大于1.5×10⁸ m³/km²时，若致密气层不发育或为二类、三类气层，采用水平井单独动用煤，若致密气层为一类气层，则采用致密气、煤层气单独开发方式进行开发。该研究为临兴区块及相似区块等深层煤层气资源两气协同高效开发提供技术支撑。
- 两气合采 /
- 动用策略 /
- 煤系储层 /
- 叠置类型井距 /
- 深层煤层气 /
- 临兴区块 /
- 鄂尔多斯盆地
Abstract: The Linxing block in the Ordos Basin has entered the stage of co-production of tight gas and coalbed methane (CBM), and the stacking patterns of tight sandstone and coal seams directly affect the production methods. By analyzing the stacking relationships and production dynamics using different development methods in the Linxing block, the utilization strategies for deep coal-measure reservoirs were investigated. Based on the sedimentary characteristics and relative spatial positions of tight sandstone and coal seams, the sand-coal stacking patterns in the Linxing block were mainly categorized into interbedded sand-coal type and upper sand-lower coal type. By comparing the development status under different stacking patterns, it was found that horizontal wells were preferred for the independent development of deep CBM, and wells co-producing CBM and tight gas had higher initial gas production capacity than vertical or directional wells producing CBM alone. An optimization chart of deep coal-measure reservoir utilization strategies under different stacking patterns was further established, with economic efficiency as the optimization objective. When CBM abundance is less than 1.1×10⁸ m³/km² and the tight gas reservoir is classified as a Class Ⅰ or Class Ⅱ, a co-production approach should be adopted. Under the condition that CBM abundance ranges from 1.1×10⁸ to 1.5×10⁸ m³/km², if the tight gas reservoir is underdeveloped, horizontal wells should be used for the independent utilization of CBM; if the tight gas reservoir is classified as Class Ⅰ or Ⅱ, a co-production method should be adopted. Under the condition that CBM abundance exceeds 1.5×10⁸ m³/km², if the tight gas reservoir is underdeveloped or classified as Class Ⅱ or Ⅲ, horizontal wells should be used to develop the coal seams solely; if the tight gas reservoir is classified as Class Ⅰ, tight gas and CBM should be developed separately. The research provides technical support for the efficient co-production of deep CBM resources in the Linxing block and other similar blocks.
- co-production of tight gas and CBM /
- utilization strategy /
- coal-measure reservoir /
- well spacing for stacked reservoirs /
- deep coalbed methane /
- Linxing block /
- Ordos Basin
注释:

利益冲突声明/Conflict of Interests

作者声明不存在利益冲突。

The author declares no relevant conflict of interests.

作者贡献/Authors’Contributions

孙立春提出思路；李新泽、樊伟鹏完成动态分析及数据整理；孙立春、刘佳、李新泽完成初稿；孙乐、李娜、房茂军参与讨论和修改；孙乐、刘佳、李新泽完成图件绘制。所有作者均阅读并同意最终稿件的提交。

The research concept was proposed by SUN Lichun. The dynamic analysis and data compilation were completed by LI Xinze and FAN Weipeng. The manuscript was drafted by SUN Lichun, LIU Jia, and LI Xinze. The discussion and revision were conducted by SUN Le, LI Na, and FANG Maojun. The figures were drawn by SUN Le, LIU Jia, and LI Xinze. All authors have read the final version of the paper and consented to its submission.

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图 1 鄂尔多斯盆地临兴区块构造位置^[28]

Figure 1. Tectonic location of Linxing block, Ordos Basin

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图 2 鄂尔多斯盆地临兴区块砂煤叠置模式

Figure 2. Stacking patterns of sandstone and coal in Linxing block, Ordos Basin

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图 3 鄂尔多斯盆地临兴区块不同深层煤层气井产量预测曲线

Figure 3. Production prediction curves of different deep CBM wells in Linxing block, Ordos Basin

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图 4 鄂尔多斯盆地临兴区块下石盒子组盒7段地层特征参数与无阻流量关系

Figure 4. Relationship between stratigraphic characteristic parameters and open-flow potential of the seventh member of Shihezi Formation in Linxing block, Ordos Basin

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图 5 鄂尔多斯盆地临兴区块不同叠置模式下深层煤系储层动用策略优选图版

Figure 5. Optimization chart of deep coal-measure reservoir utilization strategies under different stacking patterns in Linxing block, Ordos Basin

下载: 全尺寸图片幻灯片

表 1 鄂尔多斯盆地临兴区块LX1-79井及相邻井组投产井信息

Table 1. Production well information of well LX1-79 and adjacent well groups in Linxing block, Ordos Basin

井名	含气量/(m³/t)	煤层厚度/m	相邻气层厚度/m	90天峰值平均产气量/(m³/d)
LX1-79-1D	14.3	13.0	0	2 913
LX1-79-2D	14.5	12.1	0	2 352
LX1-79-3D	14.5	12.5	0	2 633
LX1-79-4D	14.5	12.5	2.2	7 115
LXC1-67-5D	14.1	12.7	1.5	6 199
LXC1-67-6D	14.1	12.9	2.5	5 264
LXC1-67-7D	14.1	13.2	2.2	4 769
LXC1-67-8D	14.8	13.0	0	2 698
LXC1-67-9D	14.8	12.8	0	3 352
LXC1-67-10D	14.8	12.8	3.8	5 523
LXC1-67-11D	14.8	12.9	4.5	6 741
LX1-85	14.3	13.1	0	2 908
LX1-85-1D	14.3	13.2	0	3 321
LX1-85-2D	14.3	13.2	0	3 154

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表 2 鄂尔多斯盆地临兴区块6口新井预测90天峰值产量与实际90天峰值产量对比

Table 2. Comparison between predicted and actual 90-day peak production of six new wells in Linxing block, Ordos

钻井	含气量/(m³/t)	压裂砂量/m³	排量/(m³/min)	压裂液量/m³	煤层厚度/m	构造高度/m	实测产量/(m³/d)	预测产量/(m³/d)	误差/%
A井	14.83	220	13	2 066	14	-791	2 723	2 906	7.63
B井	10.20	496	20	4 123	16	-763	6 214	6 666	7.52
C井	8.19	276	16	2 801	13	-802	2 263	2 222	1.24
D井	15.52	219	15	2 026	14	-810	3 274	3 120	2.50
E井	17.07	401	22	3 024	15	-782	7 105	6 637	5.19
F井	18.44	240	20	2 300	16	-758	4 951	4 587	7.34

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表 3 鄂尔多斯盆地大宁—吉县深层煤层气井3年平均产气量与峰值产气量的比例

Table 3. Ratios of three-year average gas production to peak gas production of deep CBM wells in Daning-Jixian area, Ordos Basin

井号	排采时间/d	3年平均产气量/(m³/d)	峰值产气量/(m³/d)	比例
大吉-1	674	2 620	5 791	0.45
大吉-2	454	3 490	4 469	0.78
大吉-3	360	4 940	5 193	0.95
大吉-4	217	3 844	4 300	0.89
大吉-5	217	3 536	4 050	0.87
大吉-6	361	2 033	3 167	0.64
大吉-7	344	1 550	2 425	0.64
大吉-8	390	990	2 142	0.46
大吉-9	459	1 530	2 824	0.54
大吉-10	459	1 320	1 915	0.69
大吉-11	241	1 400	1 810	0.77
大吉-12	459	1 450	2 864	0.51
平均		2 295	3 430	0.67

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表 4 鄂尔多斯盆地临兴区块典型井数值模型参数

Table 4. Numerical model parameters of typical wells in Linxing block, Ordos Basin

参数	参数值	参数	参数值
煤层厚度/m	8.6	割理渗透率/10^-3 μm²	0.08
孔隙度/%	5	地层压力/MPa	19.8
裂缝半长/m	70	裂缝导流能力/(10^-3 μm²·m)	250
兰氏压力/MPa	2.3	兰氏体积/(m³/t)	15.2
含气量/(m³/t)	12.2	临界解吸压力/MPa	18.5

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表 5 鄂尔多斯盆地临兴区块致密气储量分类划分标准

Table 5. Classification criteria for tight gas reserves in Linxing block, Ordos Basin

类别	砂岩厚度/m	渗透率/10^-3 μm²	地层特征参数/(10^-3 μm²·m)	单层无阻流量/(10⁴ m³/d)
Ⅰ类	＞4.0	＞1.0	＞2 164	＞1.5
Ⅱ类	2.0~4.0	0.3~1.0	750~2 164	0.3~1.5
Ⅲ类	＜2.0	＜0.3	＜750	＜0.3

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表 6 鄂尔多斯盆地临兴区块不同叠置模式下不同开发方式经济效益

Table 6. Economic benefits of different development approaches under different stacking patterns in Linxing block, Ordos Basin

煤层丰度/10⁸ m³/km²	致密气地层特征参数/(10^-3 μm²·m)	煤层气累产/10⁴ m³	致密气累产/10⁴ m³	不同开发方式经济指标/10⁴ m³					判断结果
煤层丰度/10⁸ m³/km²	致密气地层特征参数/(10^-3 μm²·m)	煤层气累产/10⁴ m³	致密气累产/10⁴ m³	水平井单采煤层	直井单采致密气层	以煤层气为主的两气合采	以致密气为主的两气合采	两气单独开发	判断结果
0.80	500	2 040	193	-1 747	-2 119	-4 689	-770	-3 866	无效益
0.80	1 000	2 040	386	-1 747	-1 583	-4 153	-233	-3 329	无效益
0.80	2 000	2 040	773	-1 747	-509	-3 080	840	-2 256	以致密气为主的两气合采
0.80	4 000	2 040	1 545	-1 747	1 637	-934	2 986	-110	以致密气为主的两气合采
0.80	8 000	2 040	3 090	-1 747	5 929	3 359	7 278	4 182	以致密气为主的两气合采
0.80	10 000	2 040	3 863	-1 747	8 075	5 505	9 424	6 328	以致密气为主的两气合采
1.50	500	3 825	193	2 830	-2 119	32	410	711	水平井单采煤层
1.50	1 000	3 825	386	2 830	-1 583	569	947	1 247	水平井单采煤层
1.50	2 000	3 825	773	2 830	-509	1 642	2 020	2 320	水平井单采煤层
1.50	4 000	3 825	1 545	2 830	1 637	3 788	4 166	4 466	两气单独开发
1.50	8 000	3 825	3 090	2 830	5 929	8 080	8 458	8 759	两气单独开发
1.50	10 000	3 825	3 863	2 830	8 075	10 226	10 605	10 905	两气单独开发

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