Carbonic Acid Resistance of Hydroxyapatite Based Cement

Aman Srivastava, R. Ahmed, Subhash N. Shah
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引用次数: 5

Abstract

With the current applications of CO2 in oil wells for enhanced oil recovery (EOR) and sequestration purposes, the dissolution of CO2 in the formation brine and the formation of carbonic acid is a major cause of cement damage. This degradation can lead to non-compliance with the functions of the cement as it changes compressive and shear bond strengths and porosity and permeability of cement. It becomes imperative to understand the degradation mechanism of cement and methods to reduce the damage such as the addition of special additives to improve the resistance of cement against acid attack. Hence, the primary objective of this study is to investigate the effects of hydroxyapatite on cement degradation. To investigate the impacts of hydroxyapatite additive on oil well cement performance, two Class H cement slurry formulations (baseline/HS and hydroxyapatite containing cement/HHO) were compared after exposure to acidic environments. To evaluate the performance of the formulations, samples were prepared and aged in high-pressure high-temperature (HPHT) autoclave containing 2% brine saturated with mixed gas containing methane and carbon dioxide. Tests were performed at different temperatures (38 to 221°C), pressures (21 to 63 MPa) and CO2 concentrations (10 to 100%). After aging for 14 days at constant pressure and temperature, the samples were recovered and their bond and compressive strength, porosity and permeability were measured and compared with those of unaged samples. The results demonstrated that adding hydroxyapatite limits carbonation. Baseline samples that do not contain hydroxyapatite carbonated and consequently their compressive strength, porosity, permeability, and shear bond strength significantly changed after aging while hydroxyapatite-containing samples displayed a limited change in their properties. However, hydroxyapatite-containing samples exhibit high permeability due to the formation of microcracks after exposure to carbonic acid at high temperature (221°C). The formation of microcracks could be attributed to thermal retrogression or other phenomena that cause the expansion of the cement. This article sheds light on the application of hydroxyapatite as a cement additive to improve the carbonic acid resistance of oil well cement. It presents hydroxyapatite containing cement formulation that has acceptable slurry properties for field applications and better carbonic acid resistance compared to conventional cement.
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羟基磷灰石基水泥的耐碳酸性
目前,为了提高采收率(EOR)和封存目的,在油井中应用了二氧化碳,而二氧化碳在地层盐水中的溶解和碳酸的形成是造成水泥破坏的主要原因。这种降解会改变水泥的抗压和剪切粘结强度以及水泥的孔隙率和渗透率,从而导致水泥的功能不符合。了解水泥的降解机理和减少其损害的方法,如添加特殊的添加剂来提高水泥的抗酸侵蚀能力,已成为当务之急。因此,本研究的主要目的是研究羟基磷灰石对水泥降解的影响。为了研究羟基磷灰石添加剂对油井水泥性能的影响,在酸性环境下比较了两种H类水泥浆配方(基线/HS和含羟基磷灰石的水泥/HHO)。为了评估配方的性能,样品被制备并在高压高温(HPHT)高压釜中老化,高压釜中含有2%的盐水,饱和气体含有甲烷和二氧化碳。试验在不同温度(38 ~ 221℃)、压力(21 ~ 63 MPa)和CO2浓度(10% ~ 100%)下进行。在恒压恒温老化14 d后,将试样恢复原状,测量其粘结强度、抗压强度、孔隙率和渗透率,并与未老化试样进行比较。结果表明,羟基磷灰石的加入限制了碳酸化。不含羟基磷灰石的基线样品碳化,因此它们的抗压强度、孔隙率、渗透率和剪切强度在老化后发生了显著变化,而含羟基磷灰石的样品的性能变化有限。然而,含羟基磷灰石的样品在高温(221°C)下暴露于碳酸后,由于形成微裂纹而表现出高渗透性。微裂缝的形成可归因于热回退或其他导致水泥膨胀的现象。本文介绍了羟基磷灰石作为水泥添加剂在提高油井水泥抗碳酸性能中的应用。该水泥配方含有羟基磷灰石,具有可接受的泥浆性能,适合现场应用,与常规水泥相比,具有更好的耐碳酸性。
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