Novel Cementing Solutions to Impede Lost Circulation with Highly Crush-Resistant Lightweight Cement System and Engineered Fibers

Putra, T.; Steven, Alan; Wedhaswari, Victoria Rasmi; Awalt, Michael; Natanagara, Bayu Buana; Pasteris, Mathieu; Jaffery, Maimoon Fayyaz; Veisi, Mahdi Sheikh; Rudiantoro, Agung

doi:10.2118/182250-ms

Cited by 3 publications

References 6 publications

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Analysis Behind Casing to Assess Zonal Isolation and Casing Deterioration in a High Pressure Exploratory Well - ABC to Z of Well Integrity Barrier Evaluation

Ahmed

Khan

Bari

et al. 2021

SPE/IADC International Drilling Conference and Exhibition

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The UHP exploratory well subject of this study faced with myriad challenges, including fishing, side-tracking, and other undesirable incidents with consequences to the 9-7/8" production casing. Torque and drag analysis, preliminary casing wear simulations, and actual drilling parameters pointed towards multiple uncertainties concerning barrier integrity. Consequently, a multi-physics evaluation was conducted including well-integrity logs in a combination of thickness-mode with flexural-mode of the casing. Signals from these independent measurements are then processed to provide robust interpretation of solid-liquid-gas behind casing using acquired flexural attenuation and acoustic impedance data. In addition, casing wear is quantified by thickness changes measured through the resonance frequency of the waveform and represented in the form of a joint-by-joint corrosion summary, reporting the average metal loss. Furthermore, propagation of flexural wave-fronts as it leaks to the third interface is tracked to produce a unique image of the annulus geometry in terms of casing eccentricity and acoustic velocity of the medium. Subsequently, the former, provides a quantifiable, unique in-situ casing standoff measurement to be used for centralization evaluation. Application of the developed data-integrated workflow allowed for comprehensively analyzing well integrity barrier condition. Cement barriers were assessed with confidence by flexural imaging, which were difficult to determine solely with pulse-echo. Additionally, annulus imaging using third interface- echo (TIE) helped in characterizing the potential causes of casing wear and quality of cement behind casing by providing actual in-situ casing standoff. It was observed that casing wear was at the low side of the wellbore where the casing had the least standoff as shown by flexural waveform TIE arrivals. Moreover, high percentage of metal loss was correlated to regions with centralization lower than 40-50%. Integration of these results with casing side forces and remaining casing strength (under worst case scenario) was performed to evaluate casing endurance for future drilling, production, and injection operations.

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Analysis Behind Casing to Assess Zonal Isolation and Casing Deterioration in a High Pressure Exploratory Well - ABC to Z of Well Integrity Barrier Evaluation

Ahmed

Khan

Bari

et al. 2021

SPE/IADC International Drilling Conference and Exhibition

View full text Add to dashboard Cite

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Data-Driven Integration to Delineate Zonal Isolation and Casing Deterioration Using Advanced Ultrasonic Technology – A Blueprint to Well Integrity Evaluation

Khan

Ahmed

Bari

et al. 2021

Day 4 Thu, March 25, 2021

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State-of-the-art advanced ultrasonic measurement through the Leaky-Lamb wave imaging technique (more commonly known as the flexural waveform analysis) was introduced nearly two decades ago to expand the envelope beyond which the classical pulse-echo evaluation operated. This technology has proven to be a game-changer in cement evaluation through provision of an integrated analysis which deconvolutes beyond the casing-cement interface and investigates further into the third interface. In this work, we integrate the cutting-edge analysis provided by ultrasonic flexural mode with the classical pulse-echo approach to yield a novel well-integrity evaluation blueprint. Subsequently, it is shown how this workflow is applied to an ultra-high pressure (UHP) exploratory well for integrity evaluation which will aid in future optimization of completion strategies and constitute a continuous improvement cycle for other wells. The subject well faced potential integrity related uncertainties due to fishing and cementing related issues. A three-tier approach was adopted to develop the blueprint, starting off with problem identification with respect to the various operations and incidents that occurred on this well. Next, based on the anticipated problems, associated solutions to evaluate the same were investigated by considering the technologies and standard procedures practiced by the industry. Finally, based on the previous two steps, a multi-physics approach was adopted that makes use of a combination of pulse-echo and flexural ultrasonic analysis, in addition to multiple well integrity workflows. Consequently, combination of flexural attenuation and acoustic impedance allows for a comprehensive evaluation of the medium behind the casing through the Solid-Liquid-Gas map. Simultaneously, it is possible to quantify casing thickness and internal radius variations through pulse-echo amplitude and resonance frequency characterization. Furthermore, the Third-Interface-Echo analysis is conducted to determine annulus geometry descriptions and produce a unique in-situ casing centralization measurement. The proposed well integrity blueprint contains various building blocks that are key to evaluation processes and provide a linkage-based approach to delineate potential problems. Accordingly, application of this blueprint illustrated the investigative approach it delivers with respect to cement barrier classification and casing condition assessment

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Drilling Fluid and Cement Slurry Design for Naturally Fractured Reservoirs

et al. 2021

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For years, drilling engineers have been faced with the challenge of drilling wells through naturally fractured reservoirs that are present around the world. During drilling, the pressure at the bottomhole of a well is frequently intentionally higher than formation pressure, which can result in the loss of mud in surrounding rocks. During well cementing, the bottomhole pressure is even higher than it is during drilling, because the cement slurry density is higher than the density of the mud. Therefore, if natural or induced fractures in the surrounding rocks are not plugged during drilling, the cement slurry can be lost to them, reducing their permeability which is undesirable in the case of a pay zone. To prevent the loss of circulation and the related consequences, it is necessary to apply good drilling and cementing practices and to use adequate methods and carefully selected materials for plugging the loss zones. The aim of this article is to give an overview of the preventive and corrective methods that can be applied in drilling and cementing through fractured zones as well as improvements in drilling and cementing technology to avoid lost circulation issues (e.g., aerated drilling fluid, casing while drilling, managed pressure drilling, expandable tubulars, lightweight cement slurries, etc.).

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Novel Cementing Solutions to Impede Lost Circulation with Highly Crush-Resistant Lightweight Cement System and Engineered Fibers

Cited by 3 publications

References 6 publications

Analysis Behind Casing to Assess Zonal Isolation and Casing Deterioration in a High Pressure Exploratory Well - ABC to Z of Well Integrity Barrier Evaluation

Analysis Behind Casing to Assess Zonal Isolation and Casing Deterioration in a High Pressure Exploratory Well - ABC to Z of Well Integrity Barrier Evaluation

Data-Driven Integration to Delineate Zonal Isolation and Casing Deterioration Using Advanced Ultrasonic Technology – A Blueprint to Well Integrity Evaluation

Drilling Fluid and Cement Slurry Design for Naturally Fractured Reservoirs

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