高温高压条件下PAM/PEI聚合物凝胶控水充芯实验:有无交叉流效应

Zulhelmi Amir, Ismail Mohd Saaid, B. Mohamed Jan
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引用次数: 0

摘要

通过岩心驱替实验,评价了PAM/PEI聚合物凝胶在多孔介质中的驱替性能。实验旨在研究PAM/PEI聚合物凝胶封堵高渗透层和向低渗透层引水的效果。这项工作基于四个相关因素,这些因素决定了凝胶在高温高压条件下减轻过量产水的适用性。它们是充分的凝胶时间以达到目标层,降低对水的渗透率,适用的注入能力和长期热稳定性。进行了两种不同的岩心驱替方案,一种是使用天然砂岩进行无侧流驱替,另一种是使用具有渗透率对比的复合岩心进行有侧流驱替。原生岩心和复合岩心分别代表均质和非均质储层。四种不同的凝胶,它们是;1)纯PAM/PEI聚合物胶凝剂;2) PAM/PEI含nh40聚合物胶凝剂;3)高盐度含nh40的PAM/PEI聚合物胶凝剂;4)制备以SiO2纳米颗粒(NP)增强的高矿化度NH4Cl聚合物凝胶注入岩心。所选择的胶凝剂混合物足以代表盐度、缓凝剂NH4Cl和固体纳米颗粒对多孔介质中凝胶的影响。压降是凝胶强度的一个指标。压降越高,凝胶强度越好。用二氧化硅NP增强聚合物凝胶处理的岩心压降最高。与不含二氧化硅NP的凝胶相比,凝胶处理后的水驱压降可以上升到1500 psi。在采收率方面,采用增强聚合物凝胶处理的岩心采收率最高。另外24%的滞留油在处理后被回收。这表明含二氧化硅NP的聚合物凝胶能够有效地将水引入困油所在的位置。良好的凝胶性能可以通过核心切割表面的染料染色可见。当注入盐水时,染料将留在水流路径上。对于用增强凝胶处理的岩心,仅在岩心的入口处发现染料污渍。可以认为,在水进一步到达地表之前,刚性凝胶能够将水引入低渗透层。在高温高压条件下,对天然砂岩岩心和复合砂岩岩心中PAM/PEI聚合物凝胶的不同混合物进行了评价。结果表明,固体二氧化硅NP增强PAM/PEI聚合物凝胶具有较好的导流凝胶强度,可有效提高采收率。通过添加固体颗粒来增强凝胶可以弥补聚合物凝胶的弱化。
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Coreflooding Experiments on PAM/PEI Polymer Gel for Water Control in High-Temperature and High-Pressure Conditions: With and Without Crossflow Effect
This study presents the coreflooding experiments to evaluate the performance of PAM/PEI polymer gels as conformance control agent in porous media. The experiments were designed to investigate the effectiveness of PAM/PEI polymer gels to block a high permeability zone and to divert water to low permeability zone. The work is based on four relevant elements that determine the suitability of a gel to mitigate excessive water production in a high temperature and high pressure conditions. They are adequate gelation time to achieve the target zone, reducing permeability to water, applicable injectivity, and long-term thermal stability. Two different coreflooding schemes were performed, which are coreflooding without crossflow using native sandstone, and coreflooding with crossflow using composite core that has permeability contrast. Native and composite cores represent homogeneous and heterogeneous reservoirs, respectively. Four different set of gelants, which are; 1) pure PAM/PEI polymer gelant; 2) PAM/PEI polymer gelant with NH4O; 3) PAM/PEI polymer gelant with NH4O at high salinity; and 4) Polymer gelant in high salinity and NH4Cl reinforced with SiO2 nanoparticles (NP), were prepared and injected into the cores. The selected mixture of gelants are sufficient to represent the effect of salinity, NH4Cl as retarder and solid nanoparticles on the gel in porous media. The pressure drop is an indication of the gel strength. Higher pressure drop signifies good gel strength. The highest pressure drop can be observed in the core treated with silica NP reinforced polymer gel. Compared to the gel without silica NP, the pressure drop during waterflooding post gel treatment can rise up to 1500 psi. On the oil recovery, highest recovery is established for core treated with reinforced polymer gel. Additional 24% of the trapped oil was recovered after treatment. It signifies the effectiveness of polymer gel with silica NP to divert the flow of water into where trapped oil is located. Good gel performance can be visualized through the dye stain on the surface of the core cut. When brine is injected, the dye stain will be left at the water flow path. For the core treated with reinforced gel, the dye stain is only spotted at the inlet of the core. It can be assumed that rigid gel is able to divert water to low permeability zone before water reaches further surface. The different mixture of PAM/PEI polymer gels were assessed in native and composite sandstone cores at high temperature and pressure. Results showed that PAM/PEI polymer gel reinforced with solid silica NP has proved to provide satisfactory gel strength to divert water flow, thus effective to recover more oil. Strengthening gel by addition of solid particles could be the remedy for the weakened polymer gel.
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