地质力学在永川深层页岩气开发中的应用

doi:10.13809/j.cnki.cn32-1825/te.2021.01.010

摘要/Abstract

摘要：

永川深层山地页岩气区块位于华蓥山褶皱带向南呈帚状撒开的低背斜群,构造褶皱强烈,断层发育,龙马溪组目的层具有埋深差异大、地压地温高、水平应力差异大等特征,过路层研磨性强,井壁易失稳,可钻性差。早期地质认识不足导致钻井时效低、施工周期长、复杂情况频发,多口井压裂改造效果不理想。针对永川工区面临的主要问题,分别进行了可钻性实验、硬度实验、研磨性实验、可钻性剖面建立、地层三压力预测、三维地应力有限元及不同水平应力差模式下的裂缝扩展仿真模拟、水平井地质-工程双甜点预测等针对性的地质力学参数研究。研究表明：永川地区地层可钻性级值较高,安全钻井液密度窗口较窄,地应力方向差异较大,高应力差影响水力压裂缝网形成。利用地质力学研究成果,有针对性地进行了工程工艺调整,钻井提速和压裂增产效果明显,对川南深层页岩气开发具有借鉴意义。

关键词: 深层页岩气, 地质力学, 工艺调整, 钻井提速, 压裂增产

Abstract:

Yongchuan deep mountain shale gas block is located in Huayingshan fold belt, which is a low anticline group with broom like spreading to the south. The structural folds are strong and the faults are developed. The target layer of Longmaxi Formation has the characteristics of great difference in burial depth, high ground pressure and ground temperature and large difference in horizontal stress, while the crossing layer has strong abrasiveness, easy instability of well wall and poor drillability. The lack of early geological knowledge leads to low drilling time, long construction period and frequent complex situations, and the fracturing effect of multiple wells is not ideal. In order to solve the main problems faced by Yongchuan work area, researches on the geomechanical parameters, such as drillability, hardness, abrasiveness laboratory experiments, drillability profile establishment, formation three pressure prediction, 3D in-situ stress finite element, simulation and fracture propagation simulation under different horizontal stress difference modes, and horizontal well geological engineering double sweet spot prediction, have been conducted respectively. The results show that the formation drillability level is high, the safe drilling fluid density window is narrow, the difference of in-situ stress direction is large, and the formation of hydraulic fracturing network is affected by high stress difference. Based on the research results of geomechanics, the engineering technology has been adjusted. The drilling speed and fracturing production increase effect are obvious, which has reference significance for the development of deep shale gas in South Sichuan.

Key words: deep shale gas, geomechanics, process adjustment, drilling acceleration, fracturing stimulation

中图分类号:

TE37

龙章亮,钟敬敏,胡永章,温真桃,李辉,曾贤薇. 地质力学在永川深层页岩气开发中的应用[J]. 油气藏评价与开发, 2021, 11(1): 72-80.

Long Zhangliang,Zhong Jingmin,Hu Yongzhang,Wen Zhentao,Li Hui,Zeng Xianwei. Application of geomechanics in deep shale gas development in Yongchuan[J]. Reservoir Evaluation and Development, 2021, 11(1): 72-80.

图/表 11

表1

图1

表2

图2

表3

图3

表4

图4

图5

图6

图7

参考文献 21

[1]	郭新江, 蒋祖军, 胡永章. 天然气井工程地质[M]. 北京: 中国石化出版社, 2012.
	Guo Xinjiang, Jiang Zujun, Hu Yongzhang. Engineering geology of natural gas wells[M]. Beijing: China Petrochemical Press, 2012.
[2]	刘向君, 罗平亚. 岩石力学与石油工程[M]. 北京: 石油工业出版社, 2004.
	Liu Xiangjun, Luo Pingya. Rock mechanics and petroleum engineering[M]. Beijing: Petroleum Industry Press, 2004.
[3]	鲜成钢, 张介辉, 陈欣, 等. 地质力学在地质工程一体化中的应用[J]. 中国石油勘探, 2017,22(1):75-88.
	Xian Chenggang, Zhang Jiehui, Chen Xin, et al. Application of geomechanics in geology-engineering integration[J]. China Petroleum Exploration, 2017,22(1):75-88.
[4]	Li Y, Zhou D H, Wang W H, et al. Development of unconventional gas and technologies adopted in China[J]. Energy Geoscience, 2020,1(1-2):55-68. doi: 10.1016/j.engeos.2020.04.004
[5]	胡大梁, 郭治良, 李果, 等. 川南威荣气田深层页岩气水平井钻头优选及应用[J]. 石油地质与工程, 2019,33(5):103-106.
	Hu Daliang, Guo Zhiliang, Li Guo, et al. Bit optimization and application of deep shale gas wells in Weirong gas field of southern Sichuan basin[J]. Petroleum Geology and Engineering, 2019,33(5):103-106.
[6]	苏强, 何世明, 胡锡辉, 等. 川西双鱼石构造难钻地层岩石可钻性及钻头选型研究与应用[J]. 钻采工艺, 2019,42(2):124-127.
	Su Qiang, He Shiming, Hu Xihui, et al. Research and application on rock drillability and bit selection of difficult drilling formations in Shuangyushi structure of western Sichuan basin[J]. Drilling & Production Technology, 2019,42(2):124-127.
[7]	宋保健, 孙凯, 乐守群, 等. 涪陵页岩气田钻井提速难点与对策分析[J]. 钻采工艺, 2019,42(4):9-12.
	Song Baojian, Sun Kai, Yue Shouqun, et al. Drilling acceleration challenges at Fuling shale gas field and solutions[J]. Drilling & Production Technology, 2019,42(4):9-12.
[8]	李林, 王存新, 罗朝东. 永川页岩气水平井优快钻井关键技术研究[J]. 钻采工艺, 2018,41(4):105-106.
	Li Lin, Wang Cunxin, Luo Chaodong. Study on key technologies for optimal and fast drilling of shale gas horizontal wells in Yongchuan[J]. Drilling & Production Technology, 2018,41(4):105-106.
[9]	Hamdi Z, Momeni M S, Meyghani B. et al. Oil well compressive strength analysis from sonic log; a case study[C]// paper 012077 presented at the 11th Curtin University Technology, Science and Engineering（CUTSE） International Conference, 26-28 November, 2018, Sarawak, Malaysia.
[10]	Wilson A. Rock-strength analysis and integrated FEA modeling optimize bit selection[J]. Journal of Petroleum Technology, 2018,70(12):879-881.
[11]	马振锋, 于小龙, 杨全枝, 等. 陆相页岩气水平井钻井提速技术[J]. 非常规油气, 2017,4(4):88-92.
	Ma Zhenfeng, Yu Xiaolong, Yang Quanzhi, et al. The technology of improving rate of penetration in continental shale gas horizontal well[J]. Unconventional Oil & Gas, 2017,4(4):88-92.
[12]	王平全, 邓嘉丁, 白杨, 等. 钻井液浸泡对延长组页岩坍塌压力的影响[J]. 特种油气藏, 2018,25(2):159-163.
	Wang Pingquan, Deng Jiading, Bai Yang, et al. Effect of drilling fluid soaking on the shale collapse pressure in Yanchang formation[J]. Special Oil & Gas Reservoirs, 2018,25(2):159-163.
[13]	Darvishpour A, Cheraghi Seifabad M, Wood D A, et al. Wellbore stability analysis to determine the safe mud weight window for sandstone layers[J]. Petroleum Exploration and Development, 2019,46(5):1031-1038. doi: 10.1016/S1876-3804(19)60260-0
[14]	史亚红, 夏宏泉, 彭梦, 等. 一种准确预测钻井液安全密度窗口的新方法[J]. 断块油气田, 2019,26(2):248-252.
	Shi Yahong, Xia Hongquan, Peng Meng, et al. New accurate prediction method of safe window of drilling fluid density[J]. Fault-Block Oil and Gas Field, 2019,26(2):248-252.
[15]	倪伟, 刘桂玲, 林波. 复合断层对地应力的影响研究[J]. 复杂油气藏, 2018,11(4):38-41.
	Ni Wei, Liu Guiling, Lin Bo. Study on the influence of composite faults on ground stress[J]. Complex Hydrocarbon Reservoirs, 2018,11(4):38-41.
[16]	Zhao J Z, Ren L, Li M, et al. Failure pressure calculation of fracturing well based on fluid-structure interaction[J]. Journal of Rock Mechanics and Geotechnical Engineering, 2011,3(S1):450-456.
[17]	Rueda J, Mejia C, Quevedo R, et al. Impacts of natural fractures on hydraulic fracturing treatment in all asymptotic propagation regimes[J]. Computer Methods in Applied Mechanics and Engineering, 2020,371:113296. doi: 10.1016/j.cma.2020.113296
[18]	沈骋, 赵金洲, 任岚, 等. 四川盆地龙马溪组页岩气缝网压裂改造甜点识别新方法[J]. 天然气地球科学, 2019,30(7):937-945.
	Shen Cheng, Zhao Jinzhou, Ren Lan, et al. A new method to identify fracturing sweet spot in Longmaxi Formation of Sichuan Basin, SW China[J]. Natural Gas Geoscience, 2019,30(7):937-945.
[19]	于鹏, 刘福义, 王延忠, 等. 保靖页岩气区块储层可压性评价——以龙马溪组页岩为例[J]. 非常规油气, 2018,5(5):96-103.
	Yu Peng, Liu Fuyi, Wang Yanzhong, et al. Evaluation on fracability of shale gas reservoir in Baojing block——a case of Longmaxi formation[J]. Unconventional Oil & Gas, 2018,5(5):96-103.
[20]	沈骋, 郭兴午, 陈马林, 等. 深层页岩气水平井储层压裂改造技术[J]. 天然气工业, 2019,93(10):68-75.
	Shen Cheng, Guo Xingwu, Chen Malin, et al. Horizontal well fracturing stimulation technology for deep shale gas reservoirs[J]. Natural Gas Industry, 2019,93(10):68-75.
[21]	He X P, Zhang P X, He G S, et al. Evaluation of sweet spots and horizontal-well-design technology for shale gas in the basin-margin transition zone of southeastern Chongqing, SW China[J]. Energy Geoscience, 2020,1(3-4):134-146. doi: 10.1016/j.engeos.2020.06.004

参数	永川工区
参数	北部向斜	南部向斜	中部背斜
优质页岩埋深（m）	4 061 ~ 4 120	3 843 ~ 4 101	3 080 ~ 3 141
优质页岩厚度（m）	32	36	46.3
地层倾角（°）	0.2 ~ 4.7	1.6 ~ 3.0	3.0 ~ 40.0
断层发育情况	不发育	较发育	发育
岩心裂缝数（条）	105	135	362
孔隙度（%）	5.48	5.42	4.49
总有机碳,TOC（%）	3.09	3.12	3.12
含气量（m³/t）	7.53	7.43	7.73
脆性矿物含量（%）	61.35	60.55	62.13
黏土含量（%）	33.79	35.20	29.40
地层压力梯度（MPa/m）	0.016	0.016	0.015
地应力模式	σ_H>σ_v>σ_h	σ_H>σ_v>σ_h	σ_H>σ_v>σ_h
弹性模量（GPa）	21.73	31.60	26.53
泊松比	0.221	0.223	0.265
抗压强度（MPa）	201.80	157.75	125.94
抗张强度（MPa）	2.36	10.50	8.79
水平应力差（MPa）	15.09	11.50	15.92
断裂韧性（MPa·m^0.5）	0.519	0.429	0.672

钻头	平均微钻时
钻头	地面条件	地层条件
牙轮钻头	30.66	461.37
PDC钻头	153.76	75.00

地层	岩性	地层属性	抗压强度（MPa）	抗剪强度（MPa）	抗剪强度标准偏差（MPa）	可钻性级值	研磨性级别	硬度（MPa）	推荐PDC 钻头类型
自流井组	砂、泥、页、灰岩	中硬	103.87	28.33	1.18	4.40	5.77	816	M323,M423
须家河组	砂、页岩夹煤层	中硬	106.42	28.97	1.08	4.90	6.56	939	M323,M423
嘉陵江组	白云岩、灰岩	中硬	129.12	34.31	1.37	7.68	2.96	1 863	M323,M423
飞仙关组	泥质灰岩	中硬	108.75	29.61	1.96	5.29	1.83	1 070	M323,M423
长兴组	灰岩	中硬	122.10	32.75	1.64	7.02	2.63	1 623	M323,M423
龙潭组	泥、页岩、煤	中软	91.94	25.82	1.74	2.75	0.81	430	M223
茅口组	生屑灰岩	中硬	123.68	33.05	1.80	7.10	2.67	1 654	M323,M423
栖霞组	灰岩	中硬	130.61	34.61	1.19	7.88	3.05	1 931	M323,M423
石牛栏组	泥质灰岩	中等	103.23	27.89	0.58	3.99	1.25	678	M322,M323
龙马溪组	页岩	中等	107.53	28.44	0.50	3.67	1.12	597	M322,M323