钻井液用核壳式自解堵暂堵剂JZD的合成与性能评价

贾俊; 李菲; 张小平; 陈磊; 赵雷; 申晓波; 黄维安; 江琳; 赵舒繁

doi:10.12358/j.issn.1001-5620.2026.03.007

钻井液用核壳式自解堵暂堵剂JZD的合成与性能评价

doi: 10.12358/j.issn.1001-5620.2026.03.007

贾俊^1,,
李菲²,
张小平¹,
陈磊¹,
赵雷¹,
申晓波¹,
黄维安^2, ,,
江琳²,
赵舒繁²

1.
中国石油集团川庆钻探工程有限公司钻采工程技术研究院, 西安 710018
2.
中国石油大学(华东)石油工程学院, 山东青岛 266580

基金项目: 国家自然基金项目“引入可靠性理论研究层理性页岩力-化-渗-热耦合井壁稳定化学调控方法与机理”（52374026）、“具有温度开关效应的环保型钻井液封堵剂研制及其作用机理”（51974351）；山东省自然基金项目“基于页岩气非饱和特征的井壁坍塌模型构建与求解”（ZR2024ME125）。

详细信息

作者简介:
贾俊，高级工程师，现在主要从事钻井液技术研发工作。E-mail：jiajun_zcy@cnpc.com.cn

通讯作者:
黄维安，1976年生，教授。E-mail：20070067@upc.edu.cn。

中图分类号: TE 254.4
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- 被引次数: 0
出版历程
- 收稿日期: 2025-12-10
- 修回日期: 2026-02-06
- 网络出版日期: 2026-06-12
- 刊出日期: 2026-06-12

Synthesis and Performance Evaluation of Drilling Fluid Core-Shell Self-Unplugging Temporary Plugging Agent JZD

1.
Drilling & Production Technology Research Institute, CNPC Chuanqing Drilling Engineering Company Limited, Xi’an,Shaanxi 710018
2.
School of Petroleum Engineering, China University of Petroleum (East China), Qingdao, Shandong 266580

摘要

摘要: 传统暂堵剂往往因破胶不彻底、解封滞后或残留物难以清除，极易造成储层孔喉堵塞、渗透率下降等二次伤害，严重制约油气藏采收率提升。开发兼具高效封堵性能与自解堵功能的新型暂堵材料，成为当前油气田储层保护领域的核心研究方向与技术突破新思路。基于Stöber法，以改性聚对苯二甲酸-己二酸丁二酯为核、二氧化硅为壳，成功制备了适用于钻井液的核壳式自解堵暂堵剂，该暂堵剂采用核壳协同机制，内核保封堵强度，外壳带智能响应基团，实现“前期强堵、后期快解”，破解封堵与解堵的矛盾。采用傅里叶变换红外光谱（FT-IR）、场发射扫描电子显微镜（FE-SEM）和同步热重-差热分析（TG-DTA）系统，对该暂堵剂的化学结构、微观形貌及热稳定性进行了系统表征。结果表明，所研制的暂堵剂具有明显的核壳结构，在120 ℃、矿化度为150 000 mg/L条件下，15 d降解率为33.62%，36 d完成全部降解，可满足中长期安全作业需求。同时，该暂堵剂与钻井液体系配伍性良好，抗温能力可达130 ℃，并能耐受25%NaCl盐环境。封堵性能测试表明，随暂堵剂加量增加，砂床封堵深度从8.5 cm降至1.3 cm，封堵率达89.32%，渗透率恢复值为95.45%，兼具优异封堵能力与储层保护效果。
- 钻井液 /
- 储层保护 /
- 自解堵暂堵剂 /
- 核壳结构 /
- 封堵能力
Abstract: Conventional temporary plugging agents often cause secondary formation damage such as blocking of pore throats in reservoir formations and reduced permeability etc. due to incomplete gel-breaking, delayed unplugging or residues that are difficult to remove, severely restricting the recovery enhancement of oil and gas reservoirs. Developing novel temporary plugging materials with both efficient plugging capacity and self-unplugging capability has become a core research direction and a new idea for technical breakthroughs in the field of oil and gas reservoir protection. Based on the Stöber method, a core-shell self-unplugging temporary plugging agent for drilling fluids was successfully developed using modified poly(butylene adipate-co-terephthalate) as the core and silica as the shell. With core-shell synergistical mechanism, the core of this temporary plugging agent ensures plugging strength, while the shell, with its smart responsive groups, achieves the goal of “strong plugging in the early stage and fast unplugging in the later stage”, thus resolving the contradiction of plugging and unplugging. The chemical structure, micromorphology and thermal stability of this temporary plugging agent was systematically characterized using Fourier transform infrared (FT-IR) spectroscopy, field emission scanning electron microscopy (FE-SEM) and simultaneous thermogravimetric-differential thermal analysis (TG-DTA). The results of the characterization show that the temporary plugging agent developed has an obvious core-shell structure. At 120 ℃ and a salinity of 150,000 mg/L, the rate of degradation of the temporary plugging agent reaches 33.62% in 15 days, and it is completely degraded in 36 days, which can meet the requirements of medium- and long-term safe operation. Meanwhile, the temporary plugging agent is well compatible with drilling fluids, it functions normally at temperatures up to 130 ℃, and is resistant to 25% NaCl environment. Plugging capacity test results show that the plugging depth of sand-bed reduced from 8.5 cm to 1.3 cm as the amount of the temporary plugging agent increases, the plugging efficiency reaches 89.32%, and the percent recovery of permeability is 95.45%, demonstrating both excellent plugging capacity and reservoir protection performance.
- Drilling fluid /
- Reservoir protection /
- Self-unplugging temporary plugging agent /
- Core-shell structure /
- Plugging capacity

HTML全文

图 1 暂堵剂JZD合成流程示意图

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图 2 改性前（左）后（右）水在材料表面接触角

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图 3 JZD和PBAT的红外光谱图

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图 4 JZD与PBAT不同放大倍数下形貌对比

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图 5 JZD和PBAT的TGA曲线

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图 6 JZD与PBAT的粒径分布

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图 7 JZD与PBAT降解率曲线

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图 8 JZD在钻井液中的分散情况

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图 9 砂床平均侵入深度随暂堵剂加量变化

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表 1 不同分子量和目数材料降解性

分子量		2万	10万	20万	30万
目数		300			100	150	200	300
降解率/%	15 d	100	57.4	54.2	39.2	46.0	45.0	45.8
降解率/%	30 d	100	76.6	76.0	66.8	68.3	69.3	70.4
注：降解率计算方法为质量损失法，具体计算方式为：降解率=1−残余质量/初始质量。

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表 2 不同JZD加量下实验浆的流变性和滤失性测试结果

暂堵剂/%	实验条件	AV/ mPa·s	PV/ mPa·s	YP/ Pa	YP/PV/ Pa/mPa·s	FL_API/ mL	FL_HTHP/ mL
0	老化前	28.0	16.0	12.0	0.8	20.0	142.0
0	老化后	20.0	14.0	6.0	0.4	30.0	142.0
0.5	老化前	38.0	20.0	18.0	0.9	13.8	84.0
0.5	老化后	35.0	21.0	14.0	0.7	15.6	84.0
1.0	老化前	43.0	23.0	20.0	0.9	9.4	62.0
1.0	老化后	40.5	22.0	18.5	0.8	11.2	62.0
1.5	老化前	40.5	23.0	17.5	0.8	7.2	43.0
1.5	老化后	27.0	17.0	10.0	0.6	9.8	43.0
2.0	老化前	39.5	23.0	16.5	0.7	6.1	36.0
2.0	老化后	33.0	19.0	14.0	0.7	8.0	36.0
注：老化条件为120 ℃、16 h。

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表 3 JZD在实验浆中的抗温性评价

T_老化/ ℃	AV/ mPa·s	PV/ mPa·s	YP/ Pa	YP/PV/ Pa/mPa·s	FL_API/ mL
110	46	25	21	0.8	12
120	43	24	19	0.8	14
130	40	23	17	0.7	16
140	32	20	12	0.6	25
150	26	18	8	0.4	38
注：老化条件为不同温度下热滚16 h。

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表 4 暂堵剂JZD的抗盐性能评价

NaCl/ %	实验条件	AV/ mPa·s	PV/ mPa·s	YP/ Pa	YP/PV/ Pa/mPa·s	FL_API/ mL
0	老化前	43.0	23.0	20.0	0.9	9.4
0	120 ℃、16 h	40.5	22.0	18.5	0.8	11.2
5	老化前	40.0	23.0	17.0	0.7	13.0
5	120 ℃、16 h	32	18.0	14.0	0.8	16.0
10	老化前	42.5	24.0	18.5	0.8	9.0
10	120 ℃、16 h	33.5	19.5	14.0	0.7	18.0
15	老化前	40.8	20.0	20.8	1.0	13.0
15	120 ℃、16 h	38.5	23.0	15.5	0.7	17.0
20	老化前	79.5	35.0	44.5	1.3	11.0
20	120 ℃、16 h	61.0	31.0	30.0	1.0	9.0
25	老化前	77.8	38.0	39.8	0.9	8.0
25	120 ℃、16 h	85.0	44.0	41.0	0.8	3.0

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