Anti-corrosion cement for sour gas (H2S-CO2) storage and production of HTHP deep wells

A wellbore cement sheath exposed to an H2S-CO2 rich environment for long time will lose its general purpose (zone isolation, segregation, pipe strength improvement, etc.) due to corrosion, especially under high-temperature and high-pressure (HTHP) formation conditions. H2S-CO2 attacks cement by caus...

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Published inApplied geochemistry Vol. 96; pp. 155 - 163
Main Authors Bihua, Xu, Bin, Yuan, Yongqing, Wang
Format Journal Article
LanguageEnglish
Published Elsevier Ltd 01.09.2018
Subjects
calcium hydroxide
calcium silicate
cement
CO2
compression strength
corrosion
Fe2O3
geochemistry
H2S
HTHP
Oil well cement
permeability
H2S
Oil well cement
HTHP
Fe2O3
CO2
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Abstract A wellbore cement sheath exposed to an H2S-CO2 rich environment for long time will lose its general purpose (zone isolation, segregation, pipe strength improvement, etc.) due to corrosion, especially under high-temperature and high-pressure (HTHP) formation conditions. H2S-CO2 attacks cement by causing leaching, expansion, and dissolution effects. Therefore, this research work intends to investigate the corrosion-resistant properties of corrosion-resistant additive (CRA) for Fe2O3-amended cement. The experimental results indicate that the well cement with CRA has lower original permeability and calcium hydroxide (CH) content than cement without CRA; even after corrosion, it has higher compressive strength, lower permeability and smaller corrosion depth than that of cement without CRA. CRA can react with CH and high-Ca/Si hydration products to generate low-Ca/Si hydration products such as xonotlite and tobermorite. CRA cement has superior corrosion resistance because of reduced its original permeability due to film formation and filling effects and through the reduction of CH to achieve low-Ca/Si hydration products. •H2S-CO2 attacks cement cause leaching and erosion effects.•CRA reduces original permeability of cement by filling and filming effects.•CRA reduces pH by the reaction between noncrystalline nanosilica and Ca(OH)2.
AbstractList A wellbore cement sheath exposed to an H₂S-CO₂ rich environment for long time will lose its general purpose (zone isolation, segregation, pipe strength improvement, etc.) due to corrosion, especially under high-temperature and high-pressure (HTHP) formation conditions. H₂S-CO₂ attacks cement by causing leaching, expansion, and dissolution effects. Therefore, this research work intends to investigate the corrosion-resistant properties of corrosion-resistant additive (CRA) for Fe₂O₃-amended cement. The experimental results indicate that the well cement with CRA has lower original permeability and calcium hydroxide (CH) content than cement without CRA; even after corrosion, it has higher compressive strength, lower permeability and smaller corrosion depth than that of cement without CRA. CRA can react with CH and high-Ca/Si hydration products to generate low-Ca/Si hydration products such as xonotlite and tobermorite. CRA cement has superior corrosion resistance because of reduced its original permeability due to film formation and filling effects and through the reduction of CH to achieve low-Ca/Si hydration products.
A wellbore cement sheath exposed to an H2S-CO2 rich environment for long time will lose its general purpose (zone isolation, segregation, pipe strength improvement, etc.) due to corrosion, especially under high-temperature and high-pressure (HTHP) formation conditions. H2S-CO2 attacks cement by causing leaching, expansion, and dissolution effects. Therefore, this research work intends to investigate the corrosion-resistant properties of corrosion-resistant additive (CRA) for Fe2O3-amended cement. The experimental results indicate that the well cement with CRA has lower original permeability and calcium hydroxide (CH) content than cement without CRA; even after corrosion, it has higher compressive strength, lower permeability and smaller corrosion depth than that of cement without CRA. CRA can react with CH and high-Ca/Si hydration products to generate low-Ca/Si hydration products such as xonotlite and tobermorite. CRA cement has superior corrosion resistance because of reduced its original permeability due to film formation and filling effects and through the reduction of CH to achieve low-Ca/Si hydration products. •H2S-CO2 attacks cement cause leaching and erosion effects.•CRA reduces original permeability of cement by filling and filming effects.•CRA reduces pH by the reaction between noncrystalline nanosilica and Ca(OH)2.
Author Bihua, Xu
Yongqing, Wang
Bin, Yuan
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Keywords H2S
Oil well cement
HTHP
Fe2O3
CO2
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  publication-title: J. Asian Earth Sci.
  doi: 10.1016/j.jseaes.2012.07.007
– volume: 5
  start-page: 880
  year: 2011
  ident: 10.1016/j.apgeochem.2018.07.004_bib30
  article-title: H2S–CO2 reaction with hydrated Class H well cement: acid-gas injection and CO2 Co-sequestration
  publication-title: International Journal of Greenhouse Gas Control
  doi: 10.1016/j.ijggc.2011.02.008
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Snippet A wellbore cement sheath exposed to an H2S-CO2 rich environment for long time will lose its general purpose (zone isolation, segregation, pipe strength...
A wellbore cement sheath exposed to an H₂S-CO₂ rich environment for long time will lose its general purpose (zone isolation, segregation, pipe strength...
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SubjectTerms calcium hydroxide
calcium silicate
cement
CO2
compression strength
corrosion
Fe2O3
geochemistry
H2S
HTHP
Oil well cement
permeability
Title Anti-corrosion cement for sour gas (H2S-CO2) storage and production of HTHP deep wells
URI https://dx.doi.org/10.1016/j.apgeochem.2018.07.004
https://www.proquest.com/docview/2116912365
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