智能可膨胀纤维添加剂防止微环的形成

IF 1.3 4区 工程技术 Q3 ENGINEERING, PETROLEUM
L. Santos, A. D. Taleghani, Guoqiang Li
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引用次数: 8

摘要

许多油气井中出现的一个关键问题是,由于套管柱或地层脱粘,水泥环失效。这导致微环的形成,微环可以成为流体迁移的途径。水泥凝结过程中的收缩被认为是微环形成的主要原因之一。在本文中,一种新型的纤维形式的聚合物基可膨胀添加剂被掺入水泥中,以补偿收缩,从而有助于防止油气井中微环的形成。所提出的纤维添加剂由形状记忆聚合物(SMPs)制成,并且当暴露于高于特定值的温度时膨胀,该特定值根据设计低于胶结区的井下温度。纤维膨胀发生在水泥浆放置之后,但在水泥浆凝固之前,以避免引发任何微裂缝。由于水泥浆的膨胀,流动通道和流体迁移可以显著减少,同时保持水泥护套的机械完整性所需的机械性能。纤维在单个微裂纹上的桥接作用有助于控制小裂纹的传播和聚结。考虑到所提出的添加剂的惰性性质,不需要重新考虑水灰比及其化学性质。水泥延展性的测量增加使水泥系统更耐开裂。如本文所述,使用破坏性和非破坏性方法对含有这些纤维的样品的水泥膨胀、流体损失、凝胶强度、抗压强度、延展性和抗拉强度进行了检测。所提出的一类可膨胀添加剂可以通过增加水泥-套管和水泥-地层界面的接触应力来防止流体迁移和裂缝扩展,从而帮助操作员实现可持续的油井完整性。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Smart Expandable Fiber Additive To Prevent Formation of Microannuli
One of the critical issues that occur in many oil and gas wells is the failure of the cement sheath because of debonding from the casing string or from the formation. This results in the formation of microannuli, which can become pathways for fluid migration. Cement shrinkage during setting is regarded as one of the main causes of the formation of microannuli. In this paper, a new class of polymer-based expandable additives in the form of fibers is incorporated into the cement to compensate for shrinkage and thereby help prevent the formation of microannuli in oil and gas wells. The proposed fiber additives are made from shape-memory polymers (SMPs) and expand when exposed to temperatures above a specific value that is, by design, below the downhole temperature of the cemented zone. Fiber expansion occurs after the placement of the cement slurry but before its setting to avoid the inducement of any microfractures. As a result of the expansion of the cement paste, flow channels and fluid migration may significantly decrease while preserving the mechanical properties required for the mechanical integrity of the cement sheath. The bridging effect of fibers across individual microcracks helps control the propagation and coalescence of small fractures. Considering the inert property of the proposed additive, the water-cement ratio and its chemical properties do not need to be revisited. The measured increase in cement ductility makes the cement system more resistant to cracking. The cement expansion, fluid loss, gel strength, compressive strength, ductility, and tensile strength of the samples containing these fibers are examined using destructive and nondestructive methods, as reported here. The proposed class of expandable additives can help operators reach sustainable well integrity by increasing the contact stress at the cement–casing and the cement–formation interfaces to prevent fluid migration and the propagation of cracks.
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来源期刊
SPE Drilling & Completion
SPE Drilling & Completion 工程技术-工程:石油
CiteScore
4.20
自引率
7.10%
发文量
29
审稿时长
6-12 weeks
期刊介绍: Covers horizontal and directional drilling, drilling fluids, bit technology, sand control, perforating, cementing, well control, completions and drilling operations.
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