油气固沙用酶诱导方解石沉淀工艺优化

Deem N Alkuroud, Zeeshan Tariq, A. Khalil, M. Mahmoud, Manar Alahmari, Mohammad Bataweel
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引用次数: 1

摘要

在石油工业中,从固结不良的储层中出砂一直被认为是一个具有挑战性的问题。出砂会对井下和地面设备造成侵蚀和腐蚀,造成产量损失。在过去的几十年里,防砂技术越来越受到人们的关注,以改善和增强弱砂层的特性。酶促方解石降水(EICP)被认为是一种较新的土壤改良可持续技术。砂中方解石的原位沉淀可以通过形成桥梁来限制颗粒的运动。这种沉淀物填满孔隙并结合砂粒,从而降低孔隙度,从而提高砂粒的抗剪强度。本研究在实验室中对不同的EICP溶液进行了研究和测试。采用黄原胶(xc -聚合物)作为温度稳定剂对样品进行高温固化。EICP溶液主要由尿素、氯化钙、氯化镁、xc -聚合物和脲酶组成。测试了不同浓度和组成的试剂。混合溶液在不同的固化温度下进行不同的固化时间,以使反应发生。通过pH、电导率、傅里叶变换红外光谱(FTIR)、x射线衍射分析(XRD)和热重分析(TGA)等不同的技术对所产生的沉淀物的性能进行了检测。XRD结果表明,方解石和白云石均有析出。进一步选择产生热稳定方解石量最多、文石量最少、降水效率最高的组合进行固沙试验。以1M尿素、0.5M CaCl2、0.5M MgCl2、5g/L XC-polymer、2g/L脲酶作为EICP工艺的最佳组合。本文的新颖之处在于,它不仅描述了用于防砂和保水的EICP工艺的独特公式的发展,而且还提供了在这些井下应用EICP的选择标准。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Optimization of Enzyme-Induced Calcite Precipitation Process for Oil and Gas Sand Consolidation Applications
Sand production from a poorly consolidated reservoir formation is always considered a challenging problem in the petroleum industry. Sand production can cause erosion and corrosion to downhole and surface equipment and loss of production. Over the past few decades, sand control techniques have attracted increased attention to improve and enhance the characteristics of weak sand formations. Enzyme-induced calcite precipitation (EICP) is considered a relatively new sustainable technique studied for soil improvement. In-situ calcite precipitation in the sand can restrict the movement of the grains by forming bridges. This precipitation fills the pores and binds sand particles causing a reduction in the porosity which as a result improves sand shear strength. In this study, different mixes of EICP solution were studied and tested in the laboratory. To cure the samples at higher temperatures Xanthan Gum (XC-polymer) was used as a temperature stabilizer. EICP solution is primarily composed of urea, calcium chloride, magnesium chloride, XC-polymer, and urease enzyme. Different concentrations and compositions of reagents were tested. The mixed solutions were left for different curing times at different curing temperatures to allow the reaction to happen. The properties of the produced precipitates were examined through different techniques such as pH, conductivity, Fourier-transform infrared spectroscopy (FTIR), X-ray diffraction analysis (XRD), and Thermogravimetric analysis (TGA). The XRD results showed the precipitation of calcite and dolomite. The combination that produced the highest amount of thermally stable calcite with a minimal amount of aragonite, highest precipitation efficiency was further selected for the sand consolidation experiment. A solution containing 1M Urea, 0.5M CaCl2, 0.5M MgCl2, 5g/L XC-polymer, and 2g/L urease was considered as an optimum combination for an EICP process. The novelty of this paper is that it not only describes the development of a unique formula for the EICP process used for sand control and water conformance but also provides a selection criterion for applying the EICP for these downhole applications.
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