Performance Enhancements of Viscoelastic Surfactant Stimulation Fluids with Nanoparticles

Crews, James B.; Huang, Tao

doi:10.2118/113533-ms

Cited by 49 publications

(37 citation statements)

References 11 publications

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“…The rheological properties of the fluid were unchanged, which was unexpected because it was previously thought that hydrocarbons disrupt micelles and reduce the viscosity of VESbased solutions. Pseudocrosslinked VES fluids have also been used to remove residual polymer from hydraulic fractures (Crews and Huang 2010). Polymer breakers such as oxidizers or enzymes are combined with the nanoparticle pseudocrosslinked VES matrix during the initial fluid mixing, and are believed to react more slowly than in the absence of a VES network.…”

Section: Discussionmentioning

confidence: 99%

Recent Advances in Viscoelastic Surfactants for Improved Production From Hydrocarbon Reservoirs

2016

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Viscoelastic surfactants (VES) are used in upstream oil and gas applications, particularly hydraulic fracturing and matrix acidizing. A description of surfactant types is introduced along with a description of how they assemble into micelles, what sizes and shapes of micelles can be formed under different conditions, and finally how specific structures can lead to bulk viscoelastic-solution properties. This theoretical discussion leads into a description of the specific VES systems that have been used over the last 20 years in improved oil recovery for upstream applications.VES-based fluids have been used most extensively for hydraulic fracturing. They are preferred over conventional polymer-based fracturing-fluid systems because they are essentially solids-free systems that have demonstrated less damage to the reservoir-rock formation. In fact, approximately 10% of the fracturing treatments use VES-based fluids. Important advancements in VESs have been made by introducing "pseudocrosslinking agents," such as nanoparticles, to enhance the viscosity. Fracturing-fluid systems modeled after VES have also been improved recently by developing internal breakers to lower their viscosity to flow back the well. The flexibility of VES-based fluids has been demonstrated by their application as foamed fluids, as well as their incorporation with brine systems such as produced water.A second key area that has benefited from VES-based systems is matrix acidizing of carbonate-based reservoirs. The viscosity of these VES-based fluids is mostly controlled by pH; at low pH (low viscosity), the acid system flows easily and invades pore spaces in the formation. During acidizing, the acid is spent, and the pH and viscosity increase. Because the spent acid has higher viscosity, fresh acid is diverted to low-permeability, uncontacted zones and penetrates the rocks to form wormholes. A number of experimental studies and field applications to these effects have been performed and will be described in this study.In order for VES-based fluids to play a more-prominent role in the field, inherent limitations such as cost, applicable temperature range, and leakoff characteristics will need to continue to be addressed. If we can efficiently and economically overcome these issues, VES-based fluids offer the industry an excellent clean and nondamaging alternative to conventional polymer-based fluids.

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Section: Discussionmentioning

confidence: 99%

Recent Advances in Viscoelastic Surfactants for Improved Production From Hydrocarbon Reservoirs

2016

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“…The resulting fluid may contain one or more of the following: water-dispersible (soluble) polymers or resins, clays or other insoluble but dispersible fine solids, and soluble salts [9], [12]. The fluids are mixed or sheared for times appropriate to achieve a homogenous mixture and are then set aside to "age."…”

Section: Mixing the Nanoparticles With The Oil Base Mud Mixermentioning

confidence: 99%

Control Fracture in Sand Formation Using Smart Drilling Fluid Throughout Experimental Approach

Noah¹

2016

Geomate

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Control losses in geological formations consider as an important issue in drilling operation. Lost of circulation can be one of the more serious problems that can arise during the drilling of an oil well or gas well. Loss of drilling fluid can result in increased cost, loss of time, plugging of potentially productive zones, blowouts from decreased hydrostatic pressure in formations other than the thief zone, excessive inflow of water, and excessive caving of the formation. Lost circulation occurs through existing high-permeability zones such as highly fractured, vuggy, or cavernous structures or induced fractures when the hydrostatic pressure of drilling fluid exceeds the breaking strength of the formation. Carbonates are good examples of the former case. The following preventive measures can be used however in other cases:1 a) set casing, b) maintain drilling fluid density, c) avoid excessive downhole pressures. d) using high energy ball milling to oil based mud to observe the reduction in fluid loss as a result of the nano-additive, the results were positive indicating up to 27.7% fluid loss reduction due to the ability of the suspended nano-material to form compact impermeable mud cake as a result of its physical properties and increased surface area and interaction potential. Core plugs with pre-determined properties were re-tested after the saturation test and showed encouraging results with up to 15% permeability reduction and 8% porosity reduction.

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“…However, VES fluids have high fluid leakoff volumes due to the absence of wallbuilding, and undesirable viscosity reduction at high temperature for some fluid systems (Maxey et al, 2008;Al-Ghazal et al, 2013). Nanoparticles were used for maintaining viscosity of amine oxide based VES at high temperatures and controlling the fluid loss of VES fluid without generating formation damage (Wu et al, 2013;Huang et al, 2008;Crews et al, 2008;2012;Luo et al, 2008). The nanoparticles associate VES micelles through chemisorption and surface charge attraction and form three dimensional network as shown in Figure 3, Thus they can improve fluid rheology and produce a pseudo-filtercake of viscous VES fluid that significantly reduces the rate of fluid loss and improves fluid efficiency.…”

Section: Energy Exploration and Exploitationmentioning

confidence: 99%

Advances of Nanotechnologies in Oil and Gas Industries

Yang¹,

et al. 2015

Energy Exploration & Exploitation

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Many functional materials have been used in oil and gas industries. Special materials were needed for to withstand the high temperature and pressure harsh environment of oil and gas reservoir. Nanotechnologies have the potential to introduce revolutionary changes of materials used in the areas of the oil and gas industries. This paper gives an overview of the nanotechnology application for enhanced oil recovery, fracturing fluids, flow assurance, drilling, completion and specialty composite in the oil and gas industry in the last few years. Applications of nano-materials, in the form of solid composites and functional nanoparticle-fluid in these areas are reviewed. The future challenges of nanotech-based solutions for the petroleum industry are also discussed.

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Performance Enhancements of Viscoelastic Surfactant Stimulation Fluids with Nanoparticles

Cited by 49 publications

References 11 publications

Recent Advances in Viscoelastic Surfactants for Improved Production From Hydrocarbon Reservoirs

Recent Advances in Viscoelastic Surfactants for Improved Production From Hydrocarbon Reservoirs

Control Fracture in Sand Formation Using Smart Drilling Fluid Throughout Experimental Approach

Advances of Nanotechnologies in Oil and Gas Industries

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