Deformation and damage of cement sheath in gas storage wells under cyclic loading

Li, Juan; Su, Donghua; Tang, Shanjiang; Li, Zaoyuan; Wu, Hua; Huang, Sheng; Sun, Jianbo

doi:10.1002/ese3.869

Cited by 23 publications

(8 citation statements)

References 38 publications

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“…Through previous research, a stress-equivalent method based on equalizing F I G U R E 2 Schematic of wellbore simulation test device the interface stresses of the first and second interfaces of the wellbore cement sheath and the cement sheath interface stress in the device was developed, as shown in Equation 1. 27 In particular, we ensured that the circumferential stress was equal on all sides by making the wellbore cement sheath proportional to the inner and outer diameters of the cement sheath in the device (1). Based on the equalization of the interface pressure (radial stress) between the wellbore cement sheath and the cement sheath in the device, the internal casing pressure and simulated formation confining pressure in the device were calculated (2).…”

Section: Equivalent Theorymentioning

confidence: 99%

“…25,26 Based on the principle that the first and second interface stresses of the cement sheath in the simulation device are equal to that of the wellbore cement sheath, Li et al tested the sealing ability of the cement sheath during the cyclic loading of gas storage wells and found that fatigue failure was the main cause of integrity failure. 27 Extensive research has been conducted to investigate the integrity of cement sheaths and their failure mechanisms; many shortcomings still exist. Prior simulations and tests focused mostly on the effect of high pressure or cyclic loading of the wellbore on the integrity of the cement sheath, ignoring the complex variants such as casing pressure test and the blow off that occur before acid fracturing and production.…”

Section: Introductionmentioning

confidence: 99%

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Experiment and failure mechanism of cement sheath integrity under development and production conditions based on a mechanical equivalent theory

Huang

et al. 2021

Energy Science & Engineering

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During their life cycle, high-pressure gas wells experience circulating working fluid, acid fracturing, blow off, and other development and production conditions. This may lead to the failure of the cement sheath integrity and result in sustained casing pressure (SCP). Therefore, we explored the failure types and mechanisms of the cement sheath using different wellbore operating procedures. In this study, we used the downhole packer as the demarcation point; the integrity of the cement sheath at the upper and lower parts of the packer was tested through a self-developed wellbore simulation device, which is based on the equivalent theory of cement sheath interface differential pressure. Results showed that the lower part of the single-layer cement sheath underwent compressive strength failure due to the pressure drop in the wellbore before perforation. Plastic deformation of the cement sheath occurred during acid fracturing.In addition, the cooling effect caused by the acid fracturing led to the bonding failure at the cement sheath's second interface. The double-layer cement sheath's inner-layer cement sheath was subjected to tensile failure -attributed to highpressure -and the outer-layer cement sheath maintained its integrity under the pressure changes. Considering the risk factors associated with integrity failure, we propose an engineering optimization plan in the study. The retest results showed that reducing the internal casing pressure and temperature and controlling the annular pressure in the production stage was beneficial in ensuring the integrity of the cement sheath at the lower and upper parts of the packer, respectively. The research results provided an important reference for ensuring the integrity of the cement sheath of high-pressure gas wells.

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Section: Equivalent Theorymentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Experiment and failure mechanism of cement sheath integrity under development and production conditions based on a mechanical equivalent theory

Huang

et al. 2021

Energy Science & Engineering

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“…However, cement is a heterogeneous material with numerous micropores, which can considerably influence the deformation and failure of cement sheaths under conditions of in situ stress and hydraulic fracturing [35][36][37] . At present, most researches on the deformation and failure of cement sheaths do not consider the effects of pore structure, and mainly focuses on the mechanical characteristics of cement sheaths, failure crack geometry, and damage laws [38][39][40][41][42][43] . Few studies have been conducted on the distribution characteristics of porous structures in cement sheaths and their influence on the stress distribution and deformation of cement sheaths, especially the effects on the failure mode and failure path of cement sheaths.…”

Section: Introductionmentioning

confidence: 99%

Effects of the porous structure of cement sheaths on the deformation failure mechanism of wellbore cement sheaths

Yao

Sun

2023

Preprint

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Two types of cement sheaths with different porosities were prepared by using cement materials and liquid silicon suspension. The distribution characteristics of the pore radius and space location of two types of cement sheaths were analyzed using CT scanning experiments and statistical principles to obtain their probability density distribution functions. Based on the distribution functions, the “single-layer” and “double-layer” porous models of two types of cement sheaths were constructed using a self-developed program incorporated with the FLAC 3D program. A series of numerical simulations were conducted to study the deformation and failure laws of wellbore cement sheaths under in situ stress and hydraulic pressure. The effects of the porosity and double-layer structure on the breakdown pressure, plastic failure zone, radial deformation, and stress distribution of the cement sheaths were analyzed. As a result, the effect mechanisms of the porosity and double-layer structure on the failure mode, failure path, and interaction between the cement sheath and metal casing were revealed. The failure modes and paths of single- and double-layer cement sheaths were obtained. This research provides a basis for understanding the characteristics of stress distribution, deformation, and failure mode of porous cement sheaths under hydraulic pressure.

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“…[8][9][10][11] Mechanical failure and microannulus can significantly reduce the sealing ability of the cement sheath toward wellbore fluids, 10,12,13 resulting in failure of the hydraulic sealing. [14][15][16] In addition, a weak bonding strength at the interface and poor cementing quality can cause the cement sheath to lose its barrier function. 17,18 In recent years, some scholars further discovered that even if the cement sheath has good strength and deformation ability, the sealing failure of the cement sheath will also occur.…”

Section: Introductionmentioning

confidence: 99%

“…8–11 Mechanical failure and micro-annulus can significantly reduce the sealing ability of the cement sheath toward wellbore fluids, 10,12,13 resulting in failure of the hydraulic sealing. 14–16 In addition, a weak bonding strength at the interface and poor cementing quality can cause the cement sheath to lose its barrier function. 17,18…”

Section: Introductionmentioning

confidence: 99%

Theoretical study on the hydraulic sealing integrity of cement sheath in horizontal shale oil wells under fracturing: Crack propagation mode and mechanism

Huang

et al. 2022

Advances in Mechanical Engineering

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The cement sheath-formation interface is a weak link in wellbore isolation systems, which is prone to the failure of sealing integrity during fracturing, affecting the fracturing effect, and wellbore safety. In this study, we establish a new model to evaluate the failure mode and crack propagation of cement sheath-formation interface. Using the proposed model, we predicted the propagation direction and length of the interface and zigzag cracks caused by the interface stress, fracturing load, and stress intensity factor (SIF) under temperature and pressure in the shale oil well X in the eastern China oil field. The prediction results were consistent with the distribution law of measured microseismic events. In addition, we analyzed the influence of the internal casing pressure, mechanical properties of cement sheath, and formation on the sealing integrity failure and cracks. At the same time, we discussed the influence of these mechanical properties on the propagation length of interface and zigzag cracks and the propagation direction of the zigzag crack in detail, and proposed the optimal mechanical properties design to avoid the crack propagating to the cement sheath and causing its failure. The results can provide effective guidance for sealing integrity prediction and cement sheath mechanical performance design.

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Deformation and damage of cement sheath in gas storage wells under cyclic loading

Cited by 23 publications

References 38 publications

Experiment and failure mechanism of cement sheath integrity under development and production conditions based on a mechanical equivalent theory

Experiment and failure mechanism of cement sheath integrity under development and production conditions based on a mechanical equivalent theory

Effects of the porous structure of cement sheaths on the deformation failure mechanism of wellbore cement sheaths

Theoretical study on the hydraulic sealing integrity of cement sheath in horizontal shale oil wells under fracturing: Crack propagation mode and mechanism

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