地聚合物在高温地热井固井中的应用实验研究

IF 1.3 4区 工程技术 Q3 ENGINEERING, PETROLEUM SPE Drilling & Completion Pub Date : 2023-04-27 DOI:10.2118/212491-pa
Veerabhadra S. Denduluri, George Ulerio, Moneeb Genedy, Maria Juenger, Eric van Oort
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引用次数: 0

摘要

近年来,随着减少碳排放的呼声不断提高,地热能作为一种重要的清洁能源受到越来越多的关注。根据目前的钻井技术,GT井的施工温度非常具有挑战性,现场温度可能高达600°F(315°C)以上。然而,在过去的几十年里,GT固井技术并没有太大的变化,普通波特兰水泥(OPC)仍然是固井材料的主要选择。OPC有几个缺点,包括易脆、坐下后收缩、与地层和套管的结合强度差、易受酸性气体侵蚀、温度引起的强度退化以及对钻井液污染的容错性较低。这些因素可能导致固井作业效果不佳,从而影响井的完整性,无法在GT井的整个生命周期内确保适当的层间隔离。因此,有必要开发一种与GT环境兼容并能够提供长期层间隔离的替代材料。由于低碳足迹、自我修复能力和低收缩敏感性,地聚合物或碱活化材料可能是增强甚至取代OPC的合适选择。之前一些关于地聚合物的研究表明,它们可能是油气井固井和土木工程应用的潜在候选者,其中一些在非常高的温度下(高达1470°F(800°C))保持稳定。地聚合物是通过将铝硅酸盐源(如粉煤灰)与碱活化溶液(如氢氧化钠或氢氧化钾或硅酸盐)混合而形成的。本文研究的目的是证明地质聚合物在GT固井中的适用性。为了解由FA、偏高岭土(MK)和高炉渣制成的地聚合物配方在高温环境下的性能,进行了实验研究。在实验室测试了材料的孔隙率、粘度、增稠/泵送时间、抗压强度、抗拉强度和粘结强度等性能。研究发现,在足够的泵送时间和抗钻井液污染的情况下,地聚合物的配方可以具有理想的流变性能。此外,该配方可以超过GT固井作业所需的抗压和抗拉强度,同时获得优异的粘结强度值。这些发现表明,地聚合物非常适合在高温GT井中提供长期的层间隔离。
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Experimental Investigation of Geopolymers for Application in High-Temperature and Geothermal Well Cementing
Summary With recurrent calls for a reduction in carbon emissions, geothermal (GT) energy has received increasing attention in recent years as a prominent source of clean energy. With current drilling technology, GT wells are being constructed in extremely challenging temperature environments, which could reach more than 600°F (315°C) in situ. However, GT well-cementing technology has not changed much over the past few decades, with ordinary Portland cement (OPC) still being the primary choice of cementing material. OPC has several drawbacks, including brittle behavior, shrinkage upon setting, poor bond strength to formation and casing, susceptibility to an acid gas attack, temperature-induced strength retrogression, and low tolerance toward drilling fluid contamination. These factors could lead to a poor cementing job, thus compromising well integrity and not ensuring proper zonal isolation for the life of the GT well. Thus, there is a need to develop an alternative material that is compatible with the GT environment and able to provide long-term zonal isolation. With a low carbon footprint, self-healing ability, and low shrinkage sensitivity, geopolymers or alkali-activated materials could be a suitable option to augment or even replace OPC. Some of the previous studies on geopolymers have shown that they could be a potential candidate for oil and gas well cementing and civil engineering applications, with some being stable at very high temperatures [up to 1,470°F (800°C)]. Geopolymers are formed by mixing an aluminosilicate source such as fly ash (FA) with an alkali-activating solution, such as sodium or potassium hydroxide or silicate. The aim of the study reported here is to demonstrate the applicability of geopolymers for GT well cementing. An experimental investigation was carried out to understand the behavior of geopolymer formulations made from FA, metakaolin (MK), and blast furnace slag in a high-temperature environment. The material properties such as porosity, viscosity, thickening/pump time, compressive strength, tensile strength, and bond strength were tested in the laboratory. It was found that geopolymer can be formulated to have the desired rheological properties with adequate pump time and resistance to drilling fluid contamination. In addition, the formulations can exceed the required compressive and tensile strength for GT cementing operations, while obtaining excellent bond strength values. These findings indicate that geopolymers are well-suited to provide long-term zonal isolation in high-temperature GT wells.
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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.
期刊最新文献
Combining Magnetic and Gyroscopic Surveys Provides the Best Possible Accuracy Applications of Machine Learning Methods to Predict Hole Cleaning in Horizontal and Highly Deviated Wells Experimental Investigation of Geopolymers for Application in High-Temperature and Geothermal Well Cementing Analysis of Riser Gas Pressure from Full-Scale Gas-in-Riser Experiments with Instrumentation Correlating Surface and Downhole Perforation Entry Hole Measurements Leads to Development of Improved Perforating Systems
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