Simulation of Collapse Loads on Cemented Casing Using Finite Element Analysis

Rodríguez, W.; Fleckenstein, W. W.; Eustes, A. W.

doi:10.2118/84566-ms

Cited by 35 publications

(18 citation statements)

References 2 publications

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“…Fleckenstein et al (2000) proposes finite element analysis as the best way to analyze the casing-cement-formation properties during the design phase. This proposal has been corroborated by other authors Gray (2007), Heathman and Beck (2006), Rodriguez et al (2003), Schubert et al (2002).…”

Section: Casing-cement -Formation Interactionssupporting

confidence: 77%

“…With FEA, stress variations at different points along the cement sheath radius can be effectively modeled. Several studies (Gray (2007), Heathman and Beck (2006), Rodriguez et al (2003), Schubert et al (2002)) show how finite element analysis was effectively used to model HTHP wells in order to understand and overcome cement sheath failure problem. Ravi et al (2002) sounds a note that cement which may be suitable under one set of conditions may not be suitable under a different set of conditions.…”

Section: Casing-cement -Formation Interactionsmentioning

confidence: 99%

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Estimation of Casing-Cement-Formation Interaction using a new Analytical Model

Teodoriu

Ugwu

Schubert

2010

SPE EUROPEC/EAGE Annual Conference and Exhibition

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The objective of this paper is to develop a better understanding of the performance of the casing -cement bond under HPHT well conditions, leading to a model to predict well life. An analytical model of wellbore stresses based on wellbore parameters was developed. The new model considers the casing as a thin wall cylinder, while cement and formation are modeled using a thick wall cylinder theory. Also the equivalent stress is calculated using different failure criteria that allow the user to simulate all possible load conditions on the casing-cement-formation system. The results were confirmed by finite element simulations. The new model that was implemented in an easy to use calculation sheet will give production engineers a simple tool to estimate the well integrity under various downhole conditions.

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Section: Casing-cement -Formation Interactionssupporting

confidence: 77%

Section: Casing-cement -Formation Interactionsmentioning

confidence: 99%

Estimation of Casing-Cement-Formation Interaction using a new Analytical Model

Teodoriu

Ugwu

Schubert

2010

SPE EUROPEC/EAGE Annual Conference and Exhibition

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“…Other researchers prefer to concentrate on the stress state at a particular stage of life-of-well such as pressure or temperature loading of the set cement, and apply finite element analysis techniques to model this stage [19][20][21]. However, without consideration of the previous loading and history of deformation, it is not possible to specify the initial state of stress, amount of plasticity and damage, interface conditions and other parameters necessary to accurately set-up the problem to be solved.…”

Section: Literature Reviewmentioning

confidence: 99%

Finite Element Studies of Near-Wellbore Region During Cementing Operations: Part I

Podnos

Becker

2007

Production and Operations Symposium

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fax 01-972-952-9435. AbstractA wellbore cement sheath is expected to provide zonal isolation and borehole integrity during well construction and well life. Cement sheaths mechanically interact with other elements in the wellbore region to stresses from geological processes and operational activities. Quantifying these interacting physical components and processes has technical, economic, and environmental implications of great, and growing, significance.Staged finite element procedures during well construction sequentially consider the stress states and displacements at and near the wellbore. The model replicates complicated stress states arising from simultaneous action of far-field stresses, overburden pressure, cement hardening and shrinkage, debonding at the interfaces, and plastic flow of cement sheath and rock formation. Presently, temperature and flow are not included. The technique tracks the time-dependent behavior of cement slurry, curing (with or without shrinkage), and hardened cement during the critical period after slurry placement.Material models for casing, cement and rock formation, failure criteria for cement, formation and interface bonds were calibrated using published information and experimental data. Calculations were conducted for various loading and unloading scenarios, geometric configurations, properties of rock formations, and cement slurry formulations. Results are discussed in terms of field implications, for example: (1) interface micro-channels may or may not develop, depending upon shrinkage magnitudes; (2) simplifying modeling assumptions that are often used, such as 2-D stresses and/or deformations, may obscure critical casing, cement, and formation behavior in the wellbore region, and in the producing horizon.This paper, part of a series quantifying the interacting physical components and processes at and near the wellbore region, initiates useful comparisons of analytical results and field realities. The series illustrates and compares results and practical implications for simple to increasingly complex, but more realistic assumptions, such as isotropic/directional stress states, and isotropic/anisotropic casing, cement, and formation material parameters.

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“…Others found the relation of wear depth and contact force through experimental tests, with each wear depth recorded at a given contact force [5]. Researchers [6,7] have also studied the effect of formation to casing. They concluded that the surrounding formation significantly increased the burst resistance of casing, but the work was applied to the isothermal downhole condition.…”

Section: Introductionmentioning

confidence: 99%

The Mechanism of Wellbore Weakening in Worn Casing-Cement-Formation System

Shen

Beck

Ling

2014

Journal of Petroleum Engineering

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Maintaining casing integrity, in terms of downhole zonal isolations and well stability, is extremely important in oil/gas wells. Casing wear occurs not only in directional drilling, but also in vertical drilling with a slight deviation angle. In most hydrocarbon wells, deteriorated casing was reported from the onset of casing wear by the presence of friction force during the rotation of drillpipe. The friction force against the casing wall causes the reduction of casing strength. Furthermore, the rotation of drillpipe combined with corrosive drilling fluids could dramatically degrade the casing strength. We used a finite element analysis to focus on the stress evolution in worn casings. Comparison study between worn casing and perfect casing was conducted. Our study showed that the thermal load significantly increases the stress concentration of the worn casing in the wellbore. Finite element solutions indicated that the radial stress of the worn casing is not affected as much as the hoop stress. Along with the increased burst pressure or the elevated temperature, the unworn portion of the casing also suffers from severe compression stress. This work is important to broadening the understanding of well engineers through addressing the true stress profile of worn casing in cemented wellbore.

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Simulation of Collapse Loads on Cemented Casing Using Finite Element Analysis

Cited by 35 publications

References 2 publications

Estimation of Casing-Cement-Formation Interaction using a new Analytical Model

Estimation of Casing-Cement-Formation Interaction using a new Analytical Model

Finite Element Studies of Near-Wellbore Region During Cementing Operations: Part I

The Mechanism of Wellbore Weakening in Worn Casing-Cement-Formation System

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