Molecular Structure Design Principles for Clay Hydration Inhibitors

Molecular Structure Design Principles for Clay Hydration Inhibitors

The crucial challenge associated with water-based drilling fluids for the extraction of shale gas is the inhibition of clay hydration in the drilling operation. The inhibition efficiency of shale inhibitors is determined by the content of particular groups in the molecule. In this report we studied...

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Veröffentlicht in:Chemistry and technology of fuels and oils 2020-09, Vol.56 (4), p.718-728
Hauptverfasser: Huang, Danchao, Xie, Gang, Zou, Jianguo, Peng, Niyuan, Xu, Yao, Deng, Mingyi, Luo, Pingya
Format: Artikel
Sprache:eng
Schlagworte:
Amines
Biodegradability
Chemistry
Chemistry and Materials Science
Clay
Drilling and boring
Drilling fluids
Energy & Fuels
Engineering
Engineering, Chemical
Engineering, Petroleum
Geotechnical Engineering & Applied Earth Sciences
Hydration
Hydroxides
Hydroxyl groups
Industrial Chemistry/Chemical Engineering
Inhibitors
Mineral Resources
Molecular chains
Molecular structure
Science & Technology
Shale gas
Shale oils
Technology
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Zusammenfassung:The crucial challenge associated with water-based drilling fluids for the extraction of shale gas is the inhibition of clay hydration in the drilling operation. The inhibition efficiency of shale inhibitors is determined by the content of particular groups in the molecule. In this report we studied the inhibition performance, inhibition mechanism, and environmental friendliness of three inhibitors containing different amine and hydroxyl groups. It is known that amine groups can replace cations in the molecular chain, decrease basal spacing, exhibit superior inhibition performance, and have better biodegradability. However, hydroxyl groups are less toxic. Thus, the inhibitor molecule should contain both amine and hydroxyl groups, where amine groups detarmine inhibition capacity, and hydroxyl groups provide excellent biotoxicity.
ISSN:0009-3092
1573-8310
DOI:10.1007/s10553-020-01184-w