Suppression Effects of Hydroxy Acid Modified Montmorillonite Powders on Methane Explosions

In this paper, montmorillonite inhibitors modified with polyhydroxy functional groups by gluconic acid (GA) were successfully prepared. The particle size distribution, composition, surface functional groups, and pyrolysis characteristics of the pure montmorillonite powders (Mt) and the gluconic acid...

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Published inEnergies (Basel) Vol. 12; no. 21; p. 4068
Main Authors Wang, Yan, Feng, Hao, Zhang, Yimin, Lin, Chendi, Zheng, Ligang, Ji, Wentao, Han, Xuefeng
Format Journal Article
LanguageEnglish
Published Basel MDPI AG 25.10.2019
Subjects
Acids
Coal
Coalbed methane
Damage prevention
Experiments
Explosion suppression
Explosions
Free radicals
Functional groups
Gas explosions
Gases
Gluconic acid
High temperature
Hydroxy acids
hydroxyl functional groups
Hydroxyl groups
Hydroxyl radicals
Inert gases
Inhibitors
Laboratories
Methane
methane explosion suppression
Mist
Montmorillonite
montmorillonite powders
Nanocomposites
Protonation
Studies
suppression effect
Test systems
Zeolites
China
Germany
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Summary:In this paper, montmorillonite inhibitors modified with polyhydroxy functional groups by gluconic acid (GA) were successfully prepared. The particle size distribution, composition, surface functional groups, and pyrolysis characteristics of the pure montmorillonite powders (Mt) and the gluconic acid modified powders (G-Mt) were analyzed by using a laser particle analyzer, X-ray diffraction (XRD), Fourier transform infrared (FTIR) and thermogravimetry–differential scanning calorimetry (TG-DSC), respectively. The suppression effect of Mt and G-Mt on the 9.5% methane–air premixed gas was tested in a 20 L spherical explosion device and a 5 L pipeline experimental system. The results show that G-Mt displays a much better suppression property than that of Mt. The optimal explosion suppression effect concentration of Mt or G-Mt powders is about 0.25 g·L−1. In this concentration, for G-Mt, the maximum explosion pressure declined by 26.7%, the maximum rate of pressure rise declined by 74.63%, and the time for the flame front to reach the top of the pipe was delayed by 242.5%. On the basis of the experimental data, the better suppression effect of G-Mt than Mt might be attributed to the presence of more hydroxyl groups on the surface.
ISSN:1996-1073
1996-1073
DOI:10.3390/en12214068