Evaluation of Viscosity Changes and Rheological Properties of Diutan Gum, Xanthan Gum, and Scleroglucan in Extreme Reservoirs

Abstract: The chemically synthesized polymer polyacrylamide (HPAM) has achieved excellent oil displacement in conventional reservoirs, but its oil displacement is poor in extreme reservoir environments. To develop a biopolymer oil flooding agent suitable for extreme reservoir conditions, the viscosity changes and rheological properties of three biopolymers, diutan gum, xanthan gum, and scleroglucan, were studied under extreme reservoir conditions (high salt, high temperature, strong acid, and alkali), and the effects of… Show more

“…This model describes the flow curves well, especially at high strain rates [ 83 ]. Xanthan gum, which is widely used as an encapsulating agent, fits the power law model [ 43 , 84 ], as did gum of diutan [ 84 ] and carboxymethylated tara gum [ 6 ], and has been used on numerous occasions to adjust the relationship between the apparent viscosity and the shear rate of biopolymer solutions [ 84 ].…”

“…This model describes the flow curves well, especially at high strain rates [83]. Xanthan gum, which is widely used as an encapsulating agent, fits the power law model [43,84], as did gum of diutan [84] and carboxymethylated tara gum [6], and has been used on numerous occasions to adjust the relationship between the apparent viscosity and the shear rate of biopolymer solutions [84]. Note: τ is the yield strength (Pa), γ is the shear rate (s −1 ), k is the consistency index (Pa•s n ), n is the behavioural index, τ y is the yield strength (Pa), n B is the plastic viscosity (Pa*s), k H is the consistency index (Pa•s n ), and R 2 is the correlation coefficient.…”

Preliminary Assessment of Tara Gum as a Wall Material: Physicochemical, Structural, Thermal, and Rheological Analyses of Different Drying Methods

“…This model describes the flow curves well, especially at high strain rates [ 83 ]. Xanthan gum, which is widely used as an encapsulating agent, fits the power law model [ 43 , 84 ], as did gum of diutan [ 84 ] and carboxymethylated tara gum [ 6 ], and has been used on numerous occasions to adjust the relationship between the apparent viscosity and the shear rate of biopolymer solutions [ 84 ].…”

“…This model describes the flow curves well, especially at high strain rates [83]. Xanthan gum, which is widely used as an encapsulating agent, fits the power law model [43,84], as did gum of diutan [84] and carboxymethylated tara gum [6], and has been used on numerous occasions to adjust the relationship between the apparent viscosity and the shear rate of biopolymer solutions [84]. Note: τ is the yield strength (Pa), γ is the shear rate (s −1 ), k is the consistency index (Pa•s n ), n is the behavioural index, τ y is the yield strength (Pa), n B is the plastic viscosity (Pa*s), k H is the consistency index (Pa•s n ), and R 2 is the correlation coefficient.…”

Preliminary Assessment of Tara Gum as a Wall Material: Physicochemical, Structural, Thermal, and Rheological Analyses of Different Drying Methods

Application of natural materials containing carbohydrate polymers in rheological modification and fluid loss control of water-based drilling fluids: A review

Rheology study of the starch gelatinization to understand the hematite depression process