Laboratory experiments on the effects of corrosion inhibitor on the mechanical properties of reservoir rock

Jon Danilo Kortram; Auke Barnhoorn; Anne Pluymakers

doi:10.1186/s40517-023-00257-3

Laboratory experiments on the effects of corrosion inhibitor on the mechanical properties of reservoir rock

Jon Danilo Kortram^*, Auke Barnhoorn, Anne Pluymakers

^*Corresponding author for this work

Applied Geophysics and Petrophysics

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Abstract

Geothermal energy production often involves use of corrosion inhibitors. We performed rock mechanical experiments (room temperature; confining pressure of 10/20/30 MPa) on typical reservoir rocks (Bentheim sandstone and Treuchtlinger limestone) in contact with two different inhibitor solutions or with demineralized water. The sandstone experiments show no discernible difference in rock strength between inhibitors or water, attributed to low quartz reactivity. The limestone experiments show a significant difference in rock strength (and Mohr–Coulomb envelope), dependent on inhibitor type, attributed to high carbonate reactivity. This implies that, depending on the reactivity of the rocks and local stress conditions, inhibitor leakage may lead to unpredicted reservoir failure.

Original language	English
Article number	17
Number of pages	22
Journal	Geothermal Energy
Volume	11
Issue number	1
DOIs	https://doi.org/10.1186/s40517-023-00257-3
Publication status	Published - 2023

Keywords

Corrosion inhibitor
Experimental rock mechanics
Physical rock properties
Rock–fluid interaction

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10.1186/s40517-023-00257-3

Laboratory experiments on the effects of corrosion inhibitor on the mechanical properties of reservoir rockFinal published version, 2.43 MBLicence: CC BY

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abstract = "Geothermal energy production often involves use of corrosion inhibitors. We performed rock mechanical experiments (room temperature; confining pressure of 10/20/30 MPa) on typical reservoir rocks (Bentheim sandstone and Treuchtlinger limestone) in contact with two different inhibitor solutions or with demineralized water. The sandstone experiments show no discernible difference in rock strength between inhibitors or water, attributed to low quartz reactivity. The limestone experiments show a significant difference in rock strength (and Mohr–Coulomb envelope), dependent on inhibitor type, attributed to high carbonate reactivity. This implies that, depending on the reactivity of the rocks and local stress conditions, inhibitor leakage may lead to unpredicted reservoir failure.",

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AB - Geothermal energy production often involves use of corrosion inhibitors. We performed rock mechanical experiments (room temperature; confining pressure of 10/20/30 MPa) on typical reservoir rocks (Bentheim sandstone and Treuchtlinger limestone) in contact with two different inhibitor solutions or with demineralized water. The sandstone experiments show no discernible difference in rock strength between inhibitors or water, attributed to low quartz reactivity. The limestone experiments show a significant difference in rock strength (and Mohr–Coulomb envelope), dependent on inhibitor type, attributed to high carbonate reactivity. This implies that, depending on the reactivity of the rocks and local stress conditions, inhibitor leakage may lead to unpredicted reservoir failure.

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Laboratory experiments on the effects of corrosion inhibitor on the mechanical properties of reservoir rock

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Keywords

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