Application of a Novel Cement Spacer with Biodegradable Polymer to Improve Zonal Isolation in HTHP Wells

Li, Li; Alegria, Adriana; Doan, Angela Anh; Kellum, Matthew G.; Castanedo, Rodrigo

doi:10.4043/27048-ms

Cited by 3 publications

(1 citation statement)

References 7 publications

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“…For example, the use of effective cement materials such as dry polyelectrolyte, which reduces fluid loss of the fluid itself, which in turn reduces the risk of problems with loss of circulation and, most importantly, reducing fluid loss of the cement fluid prevents contamination of the bottomhole formation zone [10]. However, there are spacers based on biodegradable polymer that do not reduce the initial capacity-filtration properties of the bottomhole zone, and which simultaneously solve the problem of loss of circulation, and some of them are well used in HTHP (high temperature high pressure) conditions [11,12].…”

Section: Introductionmentioning

confidence: 99%

Identifying applicability viscoelastic systems in the context of improving well casing processe

Kabdushev,

Delikesheva,

Korgasbekov

et al. 2023

EEJET

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The object of research in this study is viscoelastic systems used as spacer systems in well casing during drilling. Polymer network-metal ion systems display distinctive properties, facilitating effective well coverage through their normal stresses. The primary problem addressed in this research was optimizing viscoelastic system composition for well casing. Researchers sought the ideal sodium dichromate concentration to maximize viscosity in polyacrylamide-based spacer fluids. This optimization is crucial for enhancing casing cementing quality, especially in challenging geological conditions. Utilizing a precise HAAKE MARS III rheometer, various tests, including shear, oscillatory, frequency, creep, and recovery tests, were performed to assess viscoelastic system rheology. Obtained results of optimal deformation interval for a solution with sodium bichromate is 40 Pa and aluminum sulfate, the yield strength was equal to 110 Pa. This research optimized cross-linker concentration, increasing spacer system viscosity. This enhancement improves well cementing efficiency and allows for operation in challenging geological conditions. The precise rheometer unveiled previously unexplored rheological characteristics. The optimized viscoelastic spacer fluid is invaluable in well casing, especially in challenging geological settings. This research guides the design of process fluids, enhancing casing cementing quality, and improving drilling efficiency and safety. Engineers and researchers can leverage the rheological data for informed decisions and better field performance

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Section: Introductionmentioning

confidence: 99%

Identifying applicability viscoelastic systems in the context of improving well casing processe

Kabdushev,

Delikesheva,

Korgasbekov

et al. 2023

EEJET

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Using 1,2 dimethylimidazole to improve gel thermalstability for wellbore plugging in ultra-high temperature fractured reservoirs

Jia

Zheng

2021

Journal of Dispersion Science and Technology

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Application of an Innovative Spacer System Designed for Optimal Performance in HTHP Wells

Doan

Holley

Kellum

et al. 2018

Day 1 Tue, March 06, 2018

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Extreme well conditions, especially higher temperatures, are becoming more commonplace. This in turn requires improvements to our wellbore fluids. This study focuses on the development of a new spacer system designed especially for those wells exhibiting extremely high temperatures. A critical characteristic of this spacer is that the surface rheology must not be overly excessive as to maintain a pumpable fluid; however, the downhole rheology must not diminish due to thermal thinning or degradation of the gelling agent so the spacer remains stable. To ensure the spacer suitably meets these requirements, both ambient and elevated temperature rheologies are analyzed and reported. The stability of the spacer related to settling of solid particulates is examined by conducting dynamic settling tests at 300°F and above. In this study, spacer compositions and densities were adjusted to examine effects on rheology and stability of the solids within the system at elevated temperatures. Results show that conventional spacer systems are not adequate at elevated temperatures especially above 300°F. The newly developed spacer system shows much improved results from dynamic settling tests even up to 400°F. Also, the surface rheology of the new spacer system is not significantly different from that of the conventional system. The innovative spacer system within this paper was shown to add significant value to extreme cementing operations. In addition, by comparing the results between these two testing methods, the dynamic settling test should be considered as an alternate procedure for testing the stability of spacers under high temperature conditions.

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Application of a Novel Cement Spacer with Biodegradable Polymer to Improve Zonal Isolation in HTHP Wells

Cited by 3 publications

References 7 publications

Identifying applicability viscoelastic systems in the context of improving well casing processe

Identifying applicability viscoelastic systems in the context of improving well casing processe

Using 1,2 dimethylimidazole to improve gel thermalstability for wellbore plugging in ultra-high temperature fractured reservoirs

Application of an Innovative Spacer System Designed for Optimal Performance in HTHP Wells

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