摘要
青藏高原由于地质条件的多样性,分布有松散破碎地层、高应力地层、断层破碎带等复杂地层,在地质钻探中经常遇到塌孔、漏浆、缩径、卡钻、埋钻等问题。同时配套使用的冲洗液形成的泥皮质量差、胶结能力较差、携岩粉能力较弱等不足。冲洗液的性能是实现复杂地层顺利钻进的关键。结合青藏高原复杂地层的地质特点,研发了低固相聚合物新型冲洗液,该冲洗液以钠质膨润土和微泡剂等外加剂为基础,具有流动性好、胶结性强、降失水量适中的特点,适宜在青藏高原复杂地层地质钻探中使用。
我国青藏高原成矿地质环境优越,矿产资源丰富,是我国最具大型、超大型矿床的找矿远景区域,也是21 世纪国家经济建设、社会发展的战略性矿产资源基地。同时“世纪工程”川藏铁路和川藏高速建设全面启动,在拟建的川藏线地质勘察、工程施工以及沿线地质灾害防治需要大量的地质钻探工作,而青藏高原复杂的地质条件给地质钻探施工带来了困难。青藏高原具有的松散破碎地层、高应力地层、断层破碎带等复杂地层给地质找矿和钻探施工带来了挑战,因此确保青藏高原复杂地层地质钻探的顺利实施,对确保我国青藏地区的发展后劲具有十分重要的意
冲洗液基浆主要是由造浆粘土(通常为膨润土)在水中充分水化而成。膨润土在冲洗液体系中主要起着提高粘度、切力,改善钻孔的净化能力,形成致密的泥饼,降低滤失量,提高孔壁的稳定性,同时也为各种冲洗液处理剂提供吸附基础,以至于充分发挥其相应作
通过
在青藏高原的地质钻探中,由于地层复杂,地层具有岩体结构破碎、裂隙发育等特点。因此,针对该类地层的主要措施是提高冲洗液体系的胶结防塌性能。室内选用磺化沥青和乳化沥青作为封堵剂进行研究。磺化沥青是在常规沥青分子中引入了-SO3H,由于含有磺酸基,水化作用很强,并能起到填充裂缝的封堵作用,改善泥饼质量,降低滤失
从
微泡冲洗液是把某些表面活性剂与聚合物结合在一起产生的一种微
从
通过对不同沥青的冲洗液试验看出,乳化沥青的胶结性能较好,同时在浆液中也易于分散,采用的微泡剂粘度适当,并且流动性较好。因此将封堵剂和微泡剂相结合,即采用的乳化沥青和WH型微泡剂按照不同的加量配比,在基浆的基础上进行试验,获得的不同加量配比下的冲洗液性能如
通过试验可以看出,钠质膨润土加量在5%~9%,密度在1.02~1.13 g/c
在青藏高原复杂地层钻进过程中,为了提高钻孔冲洗液的携粉能力以及改善冲洗液的流变性,提高松散、破碎地层的孔壁稳定性,往往需要添加适量增粘剂,通常增粘剂也具有一定的降失水效果。增粘剂种类较多,本实验选用CMC聚合物作为增粘剂。CMC为纤维素经过烧碱处理,再在一定温度下与氯乙酸钠进行醚化反应后老化干燥制成的聚合物。由于其较高的聚合度,在水溶液中粘度较高,能较大幅度提高冲洗液体系的粘切
根据试验可以看出,CMC 聚合物作为增粘剂具有较强增粘作用,降失水效果好。
在青藏高原复杂地层进行地质钻探,遇到垮孔严重、浆液漏失的地层,应从控制失水量和提高流动性来考虑,冲洗液配方可以选用:清水+5%钠质膨润土+0.25%4381+0.7%乳化沥青+1%WH型微泡剂+0.2%~0.5%CMC。
(1)青藏高原复杂地层具有松散破碎、高压高应力、断层发育等特点。在青藏高原复杂地层钻探中经常遇到孔内坍塌、浆液漏失、钻孔缩径、卡钻、埋钻等问题,实现复杂地层顺利钻进宜采用超低固相冲洗液,同时具有良好的流变性、防塌性和润滑性能,并且绿色、环保,对生态环境无影响。
(2)目前模块化设计、质量轻体积小、易搬运的便携式钻机在青藏高原地区的地质钻探中得到推广应用,同时与之配套使用的冲洗液属于防塌系列,具有润滑减阻、抑制缩径的功能。但是在复杂地层钻探中形成的胶结能力较差,携岩粉能力较弱。
(3)通过室内试验对比,研发了低固相聚合物新型冲洗液,该冲洗液以钠质膨润土和微泡剂等外加剂为基础,并结合英格尔便携式钻机的配套泥浆,该冲洗液的优化配方为:清水+5%钠质膨润土+0.25%4381+0.7%乳化沥青+1%WH型微泡剂+0.2%~0.5%CMC。研发的该新型冲洗液流动性好、胶结能力强,并且滤失量适中,适宜在青藏高原复杂地层地质钻探中使用。
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