Litcius/Paper detail

Preparation and Foam Stabilization Mechanism of an Ultrahigh-Temperature Colloidal Gas Aphron (CGA) System Based on Nano-SiO<sub>2</sub>

Wenxi Zhu, Bingjie Wang, Xiuhua Zheng

2023ACS Omega10 citationsDOIOpen Access PDF

Abstract

High Resolution Image Download MS PowerPoint Slide Recently, colloidal gas aphron (CGA) drilling fluids have successfully solved the problem of drilling low-pressure depleted oil and gas reservoirs. However, with the increase in the drilling depth and the development of geothermal resources, high-temperature stable CGA drilling fluids need to be developed urgently. This research reports a highly stable nano-SiO 2 -based CGA system with a temperature resistance of 200 °C. Waring-Blender tests show that 1.5–3% nano-SiO 2 greatly improves the high-temperature stability of the CGA system, and the half-life of foam aged at 120–200 °C can reach 6–12 h. Also, the nano-SiO 2 -based CGA system aged at 200 °C can maintain an independent and stable morphology during the observation period (60 min), and there is no obvious drainage and merger in the system. The stabilizing mechanism of nano-SiO 2 has been revealed, which can be summarized as the comprehensive effect of adsorption, viscosity increase, and cross-linking. In other words, the addition of nano-SiO 2 enhanced steric hindrance and liquid film strength by reducing the surface tension, increasing fluid viscosity, and forming a network-like structure.

Topics & Concepts

Drilling fluidNano-ColloidViscosityMaterials scienceDrillingChemical engineeringGeothermal gradientAdsorptionSteric effectsSurface tensionMechanism (biology)Petroleum engineeringComposite materialNanotechnologyChemistryGeologyOrganic chemistryThermodynamicsMetallurgyEngineeringGeophysicsEpistemologyPhysicsPhilosophyDrilling and Well EngineeringEnhanced Oil Recovery TechniquesHydrocarbon exploration and reservoir analysis