Surfactant Surface Tension Effects on Promoting Hydrate Formation: An Experimental Study Using Fluorocarbon Surfactant (Intechem-01) + SDS Composite Surfactant

Lin Zhang; Shidong Zhou; Shuli Wang; Lei Wang; Jianmin Li

doi:10.4236/jep.2013.45A005

Journal of Environmental Protection > Vol.4 No.5A, May 2013

Surfactant Surface Tension Effects on Promoting Hydrate Formation: An Experimental Study Using Fluorocarbon Surfactant (Intechem-01) + SDS Composite Surfactant

Lin Zhang, Shidong Zhou, Shuli Wang, Lei Wang, Jianmin Li
China Jiangsu Key Laboratory of Oil & Gas Storage and Transportation Technology, School of Petroleum Engineering, Changzhou University, Changzhou, China.
DOI: 10.4236/jep.2013.45A005 PDF HTML XML 5,641 Downloads 8,514 Views Citations

Abstract

The investigation of surface tension is a very important task for gas hydrate studying. Surfactants can effectively reduce the surface tension, improve the gas storage capability of hydrate and increase the formation rate, shorten the induction time. The objective of this study were to obtain a better understanding of the role of surface tension on hydrate formation and build gas hydrate models involve surfactant. In this study it was highlighted that the surface tension of Intechem-01 + SDS composite surfactants in natural gas hydrate promotion system and the change rules at different temperatures, concentration and proportion. According to the results of experiment, the surface tension of composite surfactants decreased with the increase of Intechem-01. The best cooperating effect was observed in proportion (Intechem-01 content) of 0.6 - 0.7, where the surface tension was the lowest. In this proportion range, the composite surfactants showed the same effect to pure fluorine carbon surfactant. The study shown the surface tension of composite surfactants decreased with the rise of temperature, and they were in a linear relationship within a certain range. Surface tension of composite surfactants decreased with the increase of surfactant concentration, however, it was no longer decreased above critical micelle concentration (CMC). The fitting equation of surface tension with various factors has been obtained.

Keywords

Natural Gas Hydrate; Hydrate Promoter; Surfactant; Surface Tension; Fitting Equation

Share and Cite:

L. Zhang, S. Zhou, S. Wang, L. Wang and J. Li, "Surfactant Surface Tension Effects on Promoting Hydrate Formation: An Experimental Study Using Fluorocarbon Surfactant (Intechem-01) + SDS Composite Surfactant," Journal of Environmental Protection, Vol. 4 No. 5A, 2013, pp. 42-48. doi: 10.4236/jep.2013.45A005.

Conflicts of Interest

The authors declare no conflicts of interest.

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