超高温超深非均质碳酸盐岩储层地质工程一体化体积改造技术

doi:10.7623/syxb201801008

石油学报 ›› 2018, Vol. 39 ›› Issue (1): 92-100.DOI: 10.7623/syxb201801008

超高温超深非均质碳酸盐岩储层地质工程一体化体积改造技术

张以明¹, 才博², 何春明², 张锐锋¹, 李拥军¹, 孙海林³, 康汝坤¹, 程晓东¹, 高跃宾²

1. 中国石油华北油田公司河北任丘 062550;
2. 中国石油勘探开发研究院北京 100083;
3. 中国石油集团渤海钻探工程有限公司井下作业分公司河北任丘 062552

收稿日期:2017-03-15 修回日期:2017-08-28 出版日期:2018-01-25 发布日期:2018-03-09
通讯作者: 才博,男,1979年11月生,2002年获中国地质大学(北京)学士学位,2013年获中国地质大学(北京)博士学位,现为中国石油勘探开发研究院压裂中心高级工程师,主要从事致密油气储层改造技术研究工作。Email:boocai123@126.com
作者简介:张以明,男,1959年4月生,1981年获西南石油学院学士学位,2006年获中国科学院研究生院博士学位,现为中国石油华北油田公司教授级高级工程师,主要从事油气、煤层气勘探研究和管理工作。Email:ktb_zym@petrochina.com.cn
基金资助:
国家重大科技专项（2016ZX05023-005）和中国石油天然气集团公司重大专项"华北油田勘探开发关键技术研究与应用"（2017E-035）资助。

Volume fracturing technology based on geo-engineering integration for ultra-high temperature and ultra-deep heterogeneous carbonate reservoir

Zhang Yiming¹, Cai Bo², He Chunming², Zhang Ruifeng¹, Li Yongjun¹, Sun Hailin³, Kang Rukun¹, Cheng Xiaodong¹, Gao Yuebin²

1. PetroChina Huabei Oilfield Company, Hebei Renqiu 062550, China;
2. PetroChina Research Institute of Petroleum Exploration and Development, Beijing 100083, China;
3. Downhole Operation Branch Company, CNPC Bohai Drilling Engineering Company Limited, Hebei Renqiu 062552, China

Received:2017-03-15 Revised:2017-08-28 Online:2018-01-25 Published:2018-03-09

摘要/Abstract

摘要： 冀中坳陷北部奥陶系潜山碳酸盐岩储层油气资源丰富，但由于岩性复杂（白云岩、灰岩夹杂）、超高温（180℃）、应力梯度高（0.023 MPa/m）、以往虽采用多种工艺尝试都未能实现突破。针对上述储层地质难题，开展以储层地质特点为基础的储层评价、工艺优选、方案设计等研究，形成了超高温超深非均质碳酸盐岩储层地质工程一体化的特色改造技术：1利用1 m³大型岩石物理实验和数值模拟手段，结合地质特点开展复杂缝网的地质与工程改造因素方案论证，结果表明储层虽以微细裂缝为主、连通差、两向应力差高（7.0~9.8 MPa），但通过高排量、低黏高黏液体组合、暂堵转向等工艺仍可实现复杂缝网改造；2实现了超高温深层储层一体化改造技术，通过管柱安全力学校核、施工压力预测、求产与试采产能影响分析等，将以往的多次工序改为勘探求产和开发生产的一体化管柱，降低安全风险；3形成了180℃超高温、5 000 m超深碳酸盐岩储层"多级注入、暂堵转向、加砂酸压"工艺技术，实现了层间暂堵、层内转向的体积改造目标；4优选出180℃超高温羧甲基压裂液和酸液体系，180℃、170 s^-1下剪切120 min压裂液黏度仍保持在80 mPa·s，酸液在180℃条件下，170s^-1剪切60 min，黏度达30 mPa·s。该技术在安探1x井大规模施工，排量达11 m³/min，确保了大规模（3 000 m³）、高泵压（80~90 MPa）、多种组合液体（压裂液、酸液）、超高温（180℃）等各种不利条件下长达6 h安全、高效实施及后续半年以上安全稳产。经微地震监测和模拟表明，改造体积比以往改造技术增加3.5倍，实现了长、宽、高三维立体改造。压后产气量为40.9×10⁴m³/d，产油量为71 m³/d，试采井口压力保持在25 MPa以上，稳定产气量达10×10⁴m³/d，实现了勘探与开发、地质与工程一体化设计目标。

关键词: 冀中坳陷, 超高温, 地质工程一体化, 体积改造, 羧甲基压裂液, 安探1x井, 暂堵转向

Abstract: There are abundant oil-gas resources in Ordovician buried-hill carbonate reservoirs of the northern Jizhong depression. Due to complex lithology (mixed with dolomite and limestone), ultra-high temperature (180℃)and high stress gradient (0.023 MPa/m), various technologies have been used previously, but no breakthrough was achieved. Aiming at the above reservoir geological problem, reservoir evaluation, process optimization, technique design and other research were carried out on basis of reservoir geological characteristics, so as to form the special volume fracturing technology of geo-engineering integration for ultra-high temperature and ultra-deep heterogeneous carbonate reservoir. Firstly, the geological and engineering volume fracturing factor scheme of complex fissure network was validated by the physical test of 1 m³ huge rocks and numerical simulation means in combination with geological characteristics, and the results show that even if the reservoir is mainly characterized by micro fissures, poor connection and high dual-direction stress deviation (7.0-9.8 MPa), complex fissure network hydraulic fractures can also be achieved by high displacement-high-low viscosity liquid combination, temporary plugging diversion and other techniques. Secondly, the integrated volume fracturing technology was applied for ultra-high temperature and ultra-deep reservoir, i.e., through the safety and mechanical check on tubular column, volume fracturing pressure prediction and impact analysis on measuring-pilot production, the previous multi-processes were changed into the integrated tubular column of exploration production and development production so as to reduce the safety ricks. Thirdly, the technology of multistage injection, temporary plugging diversion and sand-adding acid-fracturing was created for 180℃ ultra-temperature and 5 000 m ultra-deep carbonate reservoirs to achieve the volume fracturing objective of inter-layer temporary plugging and inner-layer diversion. Fourthly, the carboxymethyl fracturing fluid and acidizing fluid systems applicable at 180℃ ultra-high temperature were preferentially used, and the viscosity of fracturing fluid through 120 min shearing at 180℃ and 170 s^-1 still remains 80 mPa·s. Through 60 min shearing at 180℃ and 170 s^-1, the viscosity of acidizing fluid reaches 30 mPa·s. The above technology was widely applied in Well Antan 1x with the pumping rate of 11 m³/min to ensure the 6 h safety and high-efficiency implementation as well as subsequent safety and stable production for a half year and above under all kinds of adverse conditions including large scale (3 000 m³), high pressure (80-90 MPa), multiple combination with liquids (fracturing fluid and acidizing fluid)and ultra-high temperature (180℃). Proven by micro-seismic monitoring and simulation, the stimulated reservoir volume was increased by 3.5 times than the past technology to realize the length-width-height 3D simulation. After fracturing, daily gas production was 40.9×10⁴m³, daily oil production was 71 m³, the pressure of pilot production well head kept over 25 MPa, and stable daily gas production reached 10×10⁴m³, which achieved the integrated design objective of exploration, development, geology and engineering.

Key words: Jizhong depression, ultra-high temperature, geo-engineering integration, volume fracturing, carboxymethyl fracturing fluid, Well Antan 1x, temporary plugging diversion

中图分类号:

TE357.1

张以明, 才博, 何春明, 张锐锋, 李拥军, 孙海林, 康汝坤, 程晓东, 高跃宾. 超高温超深非均质碳酸盐岩储层地质工程一体化体积改造技术[J]. 石油学报, 2018, 39(1): 92-100.

Zhang Yiming, Cai Bo, He Chunming, Zhang Ruifeng, Li Yongjun, Sun Hailin, Kang Rukun, Cheng Xiaodong, Gao Yuebin. Volume fracturing technology based on geo-engineering integration for ultra-high temperature and ultra-deep heterogeneous carbonate reservoir[J]. Acta Petrolei Sinica, 2018, 39(1): 92-100.

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超高温超深非均质碳酸盐岩储层地质工程一体化体积改造技术

Volume fracturing technology based on geo-engineering integration for ultra-high temperature and ultra-deep heterogeneous carbonate reservoir

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