理想充填堵漏工艺在温储6井的应用

熊战; 李立昌; 王学龙; 巩建军; 常春来; 徐春章; 李海彪; 刘威

doi:10.3969/j.issn.1001-5620.2020.04.010

理想充填堵漏工艺在温储6井的应用

doi: 10.3969/j.issn.1001-5620.2020.04.010

1. 渤海钻探第二钻井工程分公司, 河北廊坊 065006;
2. 渤海钻探工程技术研究院, 河北任丘 062550;
3. 渤海钻探塔里木钻井分公司, 新疆库尔勒 841000;
4. 渤海钻探第五钻井工程分公司, 河北河间 062450

详细信息

作者简介:
熊战,高级工程师,1970年生,1992年毕业于江汉石油学院钻井工程专业获学士学位,现在主要从事石油工程技术研究。电话(0317)2551464;E-mail:xiongzhan@cnpc.com.cn

中图分类号: TE254
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出版历程
- 收稿日期: 2020-04-23
- 刊出日期: 2020-08-28

Lost Circulation Control with Idea Packing on Well Wenchu-6

1. NO.2 Drilling Engineering Company, BHDC, Langfang, Hebei 065006;
2. Engineering Technology Research Institute, BHDC, Renqiu, Hebei 062550;
3. Korla Drilling Engineering Company, BHZT, Korla, Xinjiang 841000;
4. NO.2 Drilling Engineering Company, BHDC, Hejian, Hebei 062450

摘要

摘要: 温储6井是吐哈油田XX储气库的一口先导试验井，该井三开储层段西山窑组属于超低压枯竭地层，地层压力系数只有0.25~0.27，并且受邻井井下压裂影响，砂岩裂缝明显，在钻进过程中极易发生钻井液失返性恶性漏失。为了实现在三开储层漏失井段的顺利取心，同时保证固井质量，根据储层裂缝宽度，基于理想充填理论优化架桥颗粒粒级分布，结合延迟水化膨胀颗粒、弹性石墨和高效刚性架桥颗粒等特殊堵漏材料，应用该套堵漏工艺在该井三开取心和固井前承压堵漏过程中开展了多次成功堵漏作业，在易漏地层累计取心4桶，长度为32.2 m，收获率为100%；三开固井前，筛除堵漏材料后，最高承压为5.8 MPa，常规密度水泥浆固井期间无漏失发生。理想充填堵漏工艺的成功，为解决类似砂岩低压裂缝漏失难题提供了新的思路，为后续该储气库的有效开发提供了技术保障。
- 低压裂缝漏失 /
- 砂岩储层 /
- 储气库 /
- 精细化堵漏
Abstract: The well Wenchu-6 is a pilot test well for the XX gas storage in Tuha oilfield. This well penetrated in its 3rd interval (reservoir section) the Xishanyao Formation, an ultra-low pressure depleted formation with formation pressure coefficient of only 0.25-0.27. This low formation pressure plus fractures generated in the sandstones by fracturing job in wells nearby easily led to lost return of drilling fluids during drilling. To ensure the success of coring in the reservoir section and well cementing, a mud loss control technique based on ideal packing was adopted involving the optimization of bridging particle size distribution and the use of several special lost circulation additives such as delayed hydration and swelling particles, elastic graphite particles and high-efficiency rigid bridging particles. Several times of mud losses during coring and well cementing in the 3rd interval have been cured with this technique. Four whole drums of cores with length of 32.2 m were taken in the sections of mud losses. Before cementing the 3rd interval, the well was treated with drilling fluid containing the lost circulation additives as said above. The lost circulation additives were then screened out of the mud and the borehole formation was tested for its pressure bearing capacity; it was 5.8 MPa (maximum). No losses were ever encountered during well cementing with cement slurries of normal densities. The successful practice of the lost circulation control technique based on ideal packing theory provides a new clue for lost circulation control in similar sandstones of ultra-low pressures and a technical support for efficient development of the gas storage in subsequent operations.
- Lost circulation into fractures of low-pressure /
- Sandstone reservoir /
- Gas storage /
- Refined lost circulation control practice

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参考文献(10)

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