C-S-H-PCE Nanofoils: A New Generation of Accelerators for Oil Well Cement

J. Plank, Timon Echt
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引用次数: 3

Abstract

The goal was to search for a replacement of CaCl2 which presents the most widely used accelerator for oil well cement used in cold and arctic environments and sometimes in deepwater drilling. For this purpose, novel calcium silicate hydrate (C-S-H) nanoparticles were synthesized and tested. The C-S-H was synthesized by the precipitation method in an aqueous solution of polycarboxylate (PCE) comb polymer which is widely used as concrete superplasticizer. The resulting C-S-H-PCE suspension was tested in the UCA instrument as seeding material to initiate the crystallization of cement and thus accelerate cement hydration as well as shorten the thickening time at low temperature. It was found that in PCE solution, C-S-H precipitates first as nano-sized droplets (Ø ~20 - 50 nm) exhibiting a PCE shell. Following a rare, non-classical nucleation mechanism, the globules convert slowly to nanofoils (HR TEM images: l ~ 50 nm, d ~ 5 nm) which present excellent seeding materials for the formation of C-S-H from the silicate phases C3S/C2S present in cement. Thickening time tests performed at + 4 °C in an atmospheric consistometer revealed stronger acceleration than from CaCl2 while very low slurry viscosity was maintained, as was evidenced from rheological measurements. Accelerated strength development was checked on UCA cured at + 4 °C and under pressure, especially the wait on cement time was significantly reduced. Furthermore, combinations of C-S-H-PCE and HEC as well as an ATBS-based sulfonated fluid loss polymer were tested. It was found that this C-S-H- based nanocomposite is fully compatible with these additives. The novel accelerator based on a C-S-H-PCE nanocomposite solves the problems generally associated with CaCl2, namely undesired viscosity increase, poor compatibility with other additives and corrosiveness against steel pipes and casing.
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C-S-H-PCE纳米材料:新一代油井固井加速剂
其目标是寻找CaCl2的替代品,CaCl2是在寒冷和北极环境中使用最广泛的油井水泥促进剂,有时也用于深水钻井。为此,合成并测试了新型水合硅酸钙纳米颗粒。采用沉淀法在广泛用作混凝土减水剂的聚羧酸酯(PCE)梳状聚合物水溶液中合成了C-S-H。所得到的C-S-H-PCE悬浮液在UCA仪器中作为种子材料进行测试,以启动水泥的结晶,从而加速水泥的水化,并缩短低温下的稠化时间。在PCE溶液中,C-S-H首先以纳米级液滴(Ø ~20 ~ 50 nm)的形式析出,呈现PCE外壳。遵循一种罕见的非经典成核机制,微球缓慢地转化为纳米纳米(HR TEM图像:1 ~ 50 nm, d ~ 5 nm),为水泥中存在的硅酸盐相C3S/C2S形成C-S-H提供了极好的种子材料。在+ 4°C的大气浓度计中进行的增稠时间测试显示,与CaCl2相比,在保持非常低的浆体粘度的同时,加速度更强,这一点从流变测量中得到了证明。在+ 4°C和压力下,对UCA进行了加速强度发展测试,特别是水泥等待时间显着缩短。此外,还测试了C-S-H-PCE和HEC的组合以及基于atbs的磺化滤失液聚合物。结果表明,C-S-H基纳米复合材料与这些添加剂完全相容。这种基于C-S-H-PCE纳米复合材料的新型加速剂解决了CaCl2普遍存在的问题,即不理想的粘度增加、与其他添加剂的相容性差以及对钢管和套管的腐蚀性。
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