Cement Pulsation Treatment in Wells

Wojtanowicz, Andrew K.; Smith, John R.; Novakovic, Djuro; Chimmalgi, Vishvanath Shivappa; Newman, Ken; Dusterhoft, Dale; Gahan, Brian C.

doi:10.2118/77752-ms

Cited by 4 publications

(1 citation statement)

References 10 publications

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“…Use of nanotechnology in the cement slurry can also achieve solutions to some of the problems pertaining to oil well cementation [21]. Cementing engineering is one of the most applicable considerations in drilling industry where it faces harsh and severe environments with difficulties in temperature and pressure controls [22]. This research is focusing on fantastic remedies for cementing characteristics with great attention on its inherent properties with great capacities of nanotechnology.…”

Section: Introductionmentioning

confidence: 99%

Reduction of fluid migration in well cement slurry using nanoparticles

Bayanak

Zarinabadi

Shahbazi

et al. 2020

Oil Gas Sci. Technol. – Rev. IFP Energies nouvelles

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One of the main problems during oil well completion and cementing operation is fluid migration through cement bulk or behind the cemented casing. Slurry composition and characteristic have been focused and improved in last decades to mitigate gas migration and, recently, aspects such as using nanotechnology have been investigated to amend the conditions. In this research, two moderate base slurries with 95 and 120 Pound per Cubic Feet (PCF) densities containing different percentages of nanosilica have been examined using a perfect test package. The results of Fluid Migration Analyzer (FMA) demonstrated that using correct percentage of nanosilica particles modified rheological behavior of the slurries and decreased fluid migration volume. Moreover, adding nanoparticles did not have any negative effects on any conventional parameters. However, static gel strength analyzer showed significant transient time reduction which is an important key in cement setting profile. Triaxial test results together with Mohr circles analyzing presented considerable progress in cement stability and compressive strength.

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Section: Introductionmentioning

confidence: 99%

Reduction of fluid migration in well cement slurry using nanoparticles

Bayanak

Zarinabadi

Shahbazi

et al. 2020

Oil Gas Sci. Technol. – Rev. IFP Energies nouvelles

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Environmental Control of Well Integrity

Wojtanowicz

2008

Environmental Technology in the Oil Industry

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Theory-Based Review of Limitations With Static Gel Strength in Cement/Matrix Characterization

Vandenbossche

Iannacchione

et al. 2016

SPE Drilling &Amp; Completion

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Summary Gases can migrate into the cemented annulus of a wellbore during early gelation when hydrostatic pressure within the cement slurry drops. Different means to describe hydrostatic-pressure reduction have been proposed and reported in the literature. Among them, static gel strength (SGS) is the most widely accepted concept in describing the strength development of hydrating cement. The classic shear-stress theory uses SGS to quantify the hydrostatic-pressure reduction in the cement column. Approaches derived from the concept of SGS have contributed to understanding mechanisms of gas migration and methods of minimizing it. Unfortunately, these approaches do not accurately predict gas migration. Although SGS was originally adopted to describe the shear stress at interfaces, it has also been used to estimate the shear resistance required to deform slurry during the hydration period. Before early gelation, the hydrostatic pressure will overcome the formation gas pressure and prevent gas migrations. During gelation, the cement develops enough rigidity to withstand the gas invasion. This critical hydration period is defined as the transition time. API STD 65-2 (API 2010a) provides standards for determining the transition time by use of the concept of SGS. Current industry practice is to reduce the transition time, thereby lowering the potential for invading gas introducing migration pathways in the cemented annulus. This approach, although certainly helpful in reducing the risk for gas migration, does not eliminate its occurrence. Experimental results presented in this study demonstrate that the relationship between SGS and hydrostatic-pressure reduction is not linear. Characteristics of the transition-time endpoints depend on slurry properties and downhole conditions. Moreover, SGS is not able to characterize the gas-tight property of a cement slurry. When slurry gels, the mechanical properties are governed by its growing solid fraction. The gel can deform under shear loading, but gases and other fluids will need to break or fracture the bond between solids and push them aside for pathways to form within the cement/matrix domain at this point. To fully understand this process, the bond strength between solid particles and the compressibility of the cement matrix are needed. The bond strength and compressibility are mechanical properties dependent on the changing rigidity of the gelling cement. However, SGS does not address these important properties and, therefore, SGS is limited in its ability to predict gas-migration potential. A better means to characterize the cement/matrix strength by use of fundamental concepts and variables for replacing SGS is desired.

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Cement Pulsation Treatment in Wells

Cited by 4 publications

References 10 publications

Reduction of fluid migration in well cement slurry using nanoparticles

Reduction of fluid migration in well cement slurry using nanoparticles

Environmental Control of Well Integrity

Theory-Based Review of Limitations With Static Gel Strength in Cement/Matrix Characterization

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