Preparation and application of a fluoropolymer emulsion as novel wettability reversal agent

A polymer emulsion with multi-fluoromethyl structure was synthesized by emulsion polymerization and its structure and properties were characterized. As a wettability reversal agent, the polymer emulsion has strong dispersibility and adsorption. The particle size of polymer particles in polymer emulsion is at micron level, in which the larger particle sizes are less than 2 mu m. After the treatment of 2.0 wt.% product, the core surface contact angles with water and n-hexadecane changed from 27.8 degrees to 130.1 degrees and from 0 degrees to 66.8 degrees, for which the core surface changed from amphiphilicity to hydrophobicity and to poor lipophilicity. It can also significantly reduce the surface energy of the core surface. When the concentration was at 2.0 wt.%, the surface free energy changed from 65.68 mN/m to 3.90 mN/m. The product can maintain good performance after long term storage. After 60 days storage, the contact angle of core (treated with 2.0 wt.% product) with water and n-hexadecane can still keep at 128.4 degrees and 65.3 degrees. After injection of the polymer emulsion, the permeability of cores with different permeability has been improved to varying degrees, for which the higher the water permeability is, the more the core permeability improves. Finally, the polymer emulsion used as wetting reversal agent tested through visual displacement experiments. The results show that the displacement efficiency can be effectively improved, and the oil recovery efficiency is increased more than 13 % on the basic polymer displacement.

Automated summary

The polymer emulsion with multi-fluoromethyl structure synthesized through emulsion polymerization exhibits strong dispersibility and adsorption as a wettability reversal agent. It can effectively change the wettability of core surfaces and reduce surface energy, maintaining good performance even after long term storage. Additionally, the permeability of cores with different permeability is improved to varying degrees after injection of the polymer emulsion, with higher water permeability resulting in greater improvement in core permeability. Visual displacement experiments show that the displacement efficiency can be effectively improved, with oil recovery efficiency increased by more than 13% compared to basic polymer displacement.