Impact of downhole pressure and fluid-access on the effectiveness of wellbore cement expansion additives

T. K.T. Wolterbeek; E.K. Cornelissen; S. J.T. Hangx; C. J. Spiers

doi:10.1016/j.cemconres.2021.106514

Impact of downhole pressure and fluid-access on the effectiveness of wellbore cement expansion additives

T. K.T. Wolterbeek^*, E.K. Cornelissen, S. J.T. Hangx, C. J. Spiers

^*Corresponding author for this work

Royal Dutch Shell PLC

Research output: Contribution to journal › Article › Academic › peer-review

Abstract

Autogenous shrinkage of wellbore cement widely impairs zonal isolation. MgO-based cement expansion additives (CEAs) can mitigate this shrinkage, or even impart net expansion, by creating porosity through displacive crystal growth-processes. However, both MgO hydration and autogenous shrinkage behaviour depend strongly on stress state. Evaluation of CEA performance in wellbore cements therefore requires testing under elevated pressures representative for subsurface environments. We report experiments addressing the chemical and bulk volume changes that occur in cement hydrating at 10 MPa confining pressure and 90 °C. Volumetric response was investigated as function of MgO concentration, external water supply, and pore pressure decrease through water consumption during reaction. Results show the bulk expansion achieved using MgO-based CEAs diminishes markedly with increasing effective confining pressure or, equivalently, upon restricting fluid supply. This reduced expansion-potential under pressure has profound implications for slurry design, notably regarding CEA-concentrations required to counteract micro-annulus formation while maintaining low cement permeability.

Original language	English
Article number	106514
Pages (from-to)	1-16
Number of pages	16
Journal	Cement and Concrete Research
Volume	147
DOIs	https://doi.org/10.1016/j.cemconres.2021.106514
Publication status	Published - Sept 2021

Bibliographical note

Funding Information:
We would like to thank Rien Groenewegen, Thony van der Gon-Netscher, Gerard Kuijper, Floris van Oort and Leonard Bik for assistance in the laboratory. We thank an anonymous reviewer for their constructive feedback. This research was funded by Shell Global Solutions International B.V. , under Amended Contract PT63253 .

Publisher Copyright:
© 2021 The Author(s)

Funding

We would like to thank Rien Groenewegen, Thony van der Gon-Netscher, Gerard Kuijper, Floris van Oort and Leonard Bik for assistance in the laboratory. We thank an anonymous reviewer for their constructive feedback. This research was funded by Shell Global Solutions International B.V. , under Amended Contract PT63253 .

Keywords

Annular fluid migration
Expansion
Hydration
MgO
Oil well cement
Shrinkage
Sustained casing pressure

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1-s2.0-S0008884621001630-mainFinal published version, 3.45 MBLicence: CC BY

Cite this

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abstract = "Autogenous shrinkage of wellbore cement widely impairs zonal isolation. MgO-based cement expansion additives (CEAs) can mitigate this shrinkage, or even impart net expansion, by creating porosity through displacive crystal growth-processes. However, both MgO hydration and autogenous shrinkage behaviour depend strongly on stress state. Evaluation of CEA performance in wellbore cements therefore requires testing under elevated pressures representative for subsurface environments. We report experiments addressing the chemical and bulk volume changes that occur in cement hydrating at 10 MPa confining pressure and 90 °C. Volumetric response was investigated as function of MgO concentration, external water supply, and pore pressure decrease through water consumption during reaction. Results show the bulk expansion achieved using MgO-based CEAs diminishes markedly with increasing effective confining pressure or, equivalently, upon restricting fluid supply. This reduced expansion-potential under pressure has profound implications for slurry design, notably regarding CEA-concentrations required to counteract micro-annulus formation while maintaining low cement permeability.",

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note = "Funding Information: We would like to thank Rien Groenewegen, Thony van der Gon-Netscher, Gerard Kuijper, Floris van Oort and Leonard Bik for assistance in the laboratory. We thank an anonymous reviewer for their constructive feedback. This research was funded by Shell Global Solutions International B.V. , under Amended Contract PT63253 . Publisher Copyright: {\textcopyright} 2021 The Author(s)",

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AU - Cornelissen, E.K.

AU - Hangx, S. J.T.

AU - Spiers, C. J.

N1 - Funding Information: We would like to thank Rien Groenewegen, Thony van der Gon-Netscher, Gerard Kuijper, Floris van Oort and Leonard Bik for assistance in the laboratory. We thank an anonymous reviewer for their constructive feedback. This research was funded by Shell Global Solutions International B.V. , under Amended Contract PT63253 . Publisher Copyright: © 2021 The Author(s)

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Y1 - 2021/9

N2 - Autogenous shrinkage of wellbore cement widely impairs zonal isolation. MgO-based cement expansion additives (CEAs) can mitigate this shrinkage, or even impart net expansion, by creating porosity through displacive crystal growth-processes. However, both MgO hydration and autogenous shrinkage behaviour depend strongly on stress state. Evaluation of CEA performance in wellbore cements therefore requires testing under elevated pressures representative for subsurface environments. We report experiments addressing the chemical and bulk volume changes that occur in cement hydrating at 10 MPa confining pressure and 90 °C. Volumetric response was investigated as function of MgO concentration, external water supply, and pore pressure decrease through water consumption during reaction. Results show the bulk expansion achieved using MgO-based CEAs diminishes markedly with increasing effective confining pressure or, equivalently, upon restricting fluid supply. This reduced expansion-potential under pressure has profound implications for slurry design, notably regarding CEA-concentrations required to counteract micro-annulus formation while maintaining low cement permeability.

AB - Autogenous shrinkage of wellbore cement widely impairs zonal isolation. MgO-based cement expansion additives (CEAs) can mitigate this shrinkage, or even impart net expansion, by creating porosity through displacive crystal growth-processes. However, both MgO hydration and autogenous shrinkage behaviour depend strongly on stress state. Evaluation of CEA performance in wellbore cements therefore requires testing under elevated pressures representative for subsurface environments. We report experiments addressing the chemical and bulk volume changes that occur in cement hydrating at 10 MPa confining pressure and 90 °C. Volumetric response was investigated as function of MgO concentration, external water supply, and pore pressure decrease through water consumption during reaction. Results show the bulk expansion achieved using MgO-based CEAs diminishes markedly with increasing effective confining pressure or, equivalently, upon restricting fluid supply. This reduced expansion-potential under pressure has profound implications for slurry design, notably regarding CEA-concentrations required to counteract micro-annulus formation while maintaining low cement permeability.

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KW - Sustained casing pressure

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Impact of downhole pressure and fluid-access on the effectiveness of wellbore cement expansion additives

Abstract

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Keywords

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