Internal Breakers for Viscoelastic-Surfactant Fracturing Fluids

Crews, James B.; Huang, Tao

doi:10.2118/106216-ms

Cited by 57 publications

(32 citation statements)

References 6 publications

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“…17 But the reduction of the viscosity by reservoir oil is inefficient. 18,19 Moreover, the gels are detrimental to natural gas production if le in the reservoir.…”

Section: -8mentioning

confidence: 99%

Understanding viscosity reduction of a long-tail sulfobetaine viscoelastic surfactant by organic compounds

2018

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Though the transition from cylindrical micelles to spherical micelles of the anionic surfactant potassium oleate in the presence of oils has been studied, these changes have not been studied for long-tail zwitterionic surfactants. The effects of n-decane, crude oil (CO), extra virgin olive oil (EVOO) and polyglycolic acid (PGA) on the zero-shear viscosity of an aqueous solution of a sulfobetaine surfactant system were investigated at 30 C and 60 C. The main surfactant in the system was erucamidopropyl hydroxypropyl sulfobetaine. The methods employed were rheology and cryo-TEM. The solution with 3.96 wt% surfactant system and 6.2 wt% CaCl 2 was viscoelastic at both test temperatures due to the formation of entangled cylindrical micelle networks. n-Decane induced the following regimes of zeroshear viscosity change at both temperatures: (i) the high viscosity regime (HVR), (ii) the transition regime (TR), and (iii) the low viscosity regime (LVR). The HVR was characterized by high zero-shear viscosities.The TR was characterized by a sharp drop in zero-shear viscosity due to the formation of untangled micelles. The LVR was due to the formation of microemulsions. The formation of these regimes depended on the balance between micellization and oil solubilization. We reveal for the first time that the number of regimes depends on the type of oil: both CO and EVOO induced only one and two regimes at 30 C and 60 C, respectively. PGA did not significantly affect the solution at either temperature with increasing concentration, meaning the solution was resistant to decreasing pH even at higher temperatures.

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“…17 But the reduction of the viscosity by reservoir oil is inefficient. 18,19 Moreover, the gels are detrimental to natural gas production if le in the reservoir.…”

Section: -8mentioning

confidence: 99%

Understanding viscosity reduction of a long-tail sulfobetaine viscoelastic surfactant by organic compounds

2018

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“…Tom B A [16] thought turbulent drag reduction effect of non-Newtonian fluid and its application were to add high molecular polymer solvent to clear water and make it to be shear thinning non-Newtonian fluid, and then raised its head of delivery at a certain rate of turbulent flow field; Toms and Krame successively found polymer dilute solution or elastic protective material could achieve viscosity drag reduction. Other articles [17,18] studied the mechanism of turbulent drag reduction, water due to minimum molecular viscosity, should have the highest degree of freedom, namely the combination vortex motion index should be the biggest, but due to the minimum molecular viscosity, it led to high turbulence and fast kinematic velocity when entering the cyclone. In the process, the friction between the molecules intensified and high turbulent viscosity led to serious internal loss.…”

Section: Phenomenon Of Turbulent Drag Reductionmentioning

confidence: 99%

Numerical analysis of non-Newtonian rheology effect on hydrocyclone flow field

et al. 2015

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a b s t r a c tIn view of the limitations of the existing Newton fluid effects on the vortex flow mechanism study, numerical analysis of non Newton fluid effects was presented. Using Reynolds stress turbulence model (RSM) and mixed multiphase flow model (Mixture) of FLUENT (fluid calculation software) and combined with the constitutive equation of apparent viscosity of non-Newtonian fluid, the typical non-Newtonian fluid (drilling fluid, polymer flooding sewage and crude oil as medium) and Newton flow field (water as medium) were compared by quantitative analysis. Based on the research results of water, the effects of non-Newtonian rheology on the key parameters including the combined vortex motion index n and tangential velocity were analyzed. The study shows that: non-Newtonian rheology has a great effect on tangential velocity and n value, and tangential velocity decreases with non-Newtonian increasing. The three kinds of n values (constant segment) are: 0.564(water), 0.769(polymer flooding sewage), 0.708(drilling fluid) and their variation amplitudes are larger than Newtonian fluid. The same time, non-Newtonian rheology will lead to the phenomenon of turbulent drag reduction in the vortex flow field. Compared with the existing formula calculation results shown, the calculation result of non-Newtonian rheology is most consistent with the simulation result, and the original theory has large deviations. The study provides reference for theory research of non-Newtonian cyclone separation flow field.

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“…9 is that the amount of surfactant retained in the core following acid treatment was significant. This means that there is a need to use external (mutual solvent) or internal breakers (Crews 2005;Crews and Huang 2007) to reduce surfactant retention, especially if a surfactant-based acid is used in a power-water injector or a dry-gas well. …”

Section: Surfactant Retention As a Function Of Acid-injection Ratementioning

confidence: 99%

“…This is exactly what Mohamed et al (2002) noted in the field. Another solution is to use internal breakers to remove the surfactant (Crews 2005;Crews and Huang 2007).…”

Section: Effect Of Mutual Solvent On the Amount Of Surfactant Retainedmentioning

confidence: 99%

Propagation and Retention of Viscoelastic Surfactants Following Matrix-Acidizing Treatments in Carbonate Cores

Mahmoud

Nasr‐El‐Din

2011

SPE Journal

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Viscoelastic surfactants have been used extensively in the field. They have the ability to form long rod-like micelles with an increase in pH and calcium concentration, which results in increasing the viscosity and elasticity of partially spent acids. There is ongoing debate in the industry about whether the gel generated by these surfactants causes formation damage, especially in dry-gas wells. The objectives of the present study are to quantitatively determine surfactant retention in calcite cores and assess the benefits of using mutual solvents to break the surfactant gel formed inside the cores.Coreflood tests were performed using Pink Desert limestone cores (1.5 in. in diameter and 20 in. in length). The cores were injected with a surfactant-based acid that contained 15 wt% HCl, 7 vol% viscoelastic surfactant, and 0.3 vol% corrosion inhibitor. Coreflood tests were conducted at a constant injection flow rate ranging from 1.5 to 40 cm 3 /min. Surfactant and calcium concentrations were measured in the injected acid and core effluent. Mutual solvent (ethylene glycol monobutyl ether) was used in several tests to break surfactant gel.Propagation of viscoelastic surfactants in linear calcite cores was found to be a function of flow rate. Surfactant lagged calcium in the core effluent samples, especially at low flow rates. The volume of acid needed to break through the core and the amount of surfactant retained varied with acid injection rate, and exhibited a minimum at 10 cm 3 /min. A significant amount of surfactant was retained in the cores. Injection of 2 pore volumes (PV) of 10 vol% mutual solvent removed only 20% of the surfactant injected. Based on these results, there is a need to use internal breakers when surfactant-based acids are used in dry-gas wells or water injectors.

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Internal Breakers for Viscoelastic-Surfactant Fracturing Fluids

Cited by 57 publications

References 6 publications

Understanding viscosity reduction of a long-tail sulfobetaine viscoelastic surfactant by organic compounds

Understanding viscosity reduction of a long-tail sulfobetaine viscoelastic surfactant by organic compounds

Numerical analysis of non-Newtonian rheology effect on hydrocyclone flow field

Propagation and Retention of Viscoelastic Surfactants Following Matrix-Acidizing Treatments in Carbonate Cores

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