The subject matter of the present application is related to U.S. patent application Ser. No. 12/180,668, filed Jul. 28, 2008 and titled “Flow-Through Apparatus for Testing Particle Laden Fluids and methods of Making and Using Same,” which is hereby incorporated herein by reference in its entirety for all purposes.
Not applicable.
Not applicable.
The present disclosure generally relates to the field of rheometry. More specifically, this disclosure relates to a method for estimating proppant transport and the ability of viscoelastic fluids to suspend solid particles based on elastic properties during simple shear flow conditions.
Sedimentation of solid particles is a basic phenomenon which impacts a wide range of applications and naturally-occurring phenomena. In fact, gravitationally-driven sedimentation and centrifugation are among the simplest and most widely-practiced techniques for liquid-solid separation, used for processes from industrial-scale water clarification to medical laboratory separation of blood components. As a consequence, sedimentation has a long history of study.
Settling in non-Newtonian fluids is of interest in a number of industrial contexts. Often, the goal is to minimize the sedimentation rate. For example, foodstuffs such as jams and yogurt are preferred to have uniform mixing of the solid fruit and seeds with the suspending continuous material. In cement and concrete, settling-induced separation of sand and aggregate particles from the cement paste is highly undesirable, and specialized transportation equipment, e.g., a rotating mixer truck, have been designed to maintain uniform mixing. In general, the methods available for minimizing settling are constrained by processing or end-product demands on the mixture (e.g., texture of a food product, flowability of concrete, etc.).
In hydraulic fracturing, large liquid pressure provided by pumps at the surface of the earth is used to pump a type of servicing fluid, referred to as a carrying fluid, through a wellbore into a subterranean zone at a rate and pressure such that fractures are formed or enhanced in a petroleum-bearing formation. It is to be understood that “subterranean formation” encompasses both areas below exposed earth and areas below earth covered by water such as ocean or fresh water. This is typically followed by the pumping of a carrying fluid having a slurry of solid particles (e.g., sand, an engineered material such as sintered bauxite or alumina, etc.) dispersed therein into the resulting fracture to hold or “prop” the fracture open when the fracturing pressure is removed and production of petroleum commences. The “proppant” particles then become deposited in the fracture and these particles function, inter alia, to hold the fracture open while maintaining conductive channels through which produced fluids may flow upon completion of the fracturing treatment and to release of the attendant hydraulic pressure.
The balance between flow properties and settling characteristics is central to hydraulic fracturing for petroleum well stimulation. For example, quality performance demands that the proppant be placed deep within the fracture, which requires that the excess weight of the solid proppant be supported during flow of the carrying fluid. It is desirable for the solid particles to be uniformly distributed for maximum effectiveness as a proppant and to minimize settling, which may be excessively rapid and detrimental to the process. In principle, settling rates can be reduced by increasing the viscosity of the slurry or carrying liquid, but this option is limited by the large distances under the surface at which the treatments are typically placed and the consequent large pressure drops associated with pumping. As a consequence, the liquids used for proppant slurries are typically viscoelastic polymeric solutions, gels, emulsions, or foams, with aqueous solutions of the naturally-occurring long-chain polymer guar being among the most common. To support the weight of proppants sufficiently well in many applications, it has been found that cross-linking (reversibly or irreversibly) of the guar solution results in an effective suspending medium without excessive viscosity to limit the pumpability of the liquid or slurries formed from it.
Rheology includes the study of the deformation and flow of matter. The rheology of reversible borate cross-linking of guar has been extensively studied. It has been found that shear history has less influence in reversibly cross-linked systems such as borate cross-linked guar than in permanently cross-linked systems, such as a zirconium cross-linked guar. In small-amplitude oscillatory measurements, reversibly cross-linked materials obey linear viscoelastic models, such as a Maxwell model. At high steady shear rates, reversibly cross-linked samples behave similarly to permanently cross-linked gels, which often break into domains and slip. Despite this knowledge, particle motion in reversibly cross-linked solutions under static settling and dynamic conditions is far from fully understood.
It is desirable to test particle-laden fluids or systems to determine if they are suitable for their intended use. However, in particle-laden fluids or suspensions, the particulate matter has a tendency to settle during an experiment, thereby often resulting in inaccurate measurements. Conventional rheometers do not take into account this settling effect in particle-laden fluids, nor do they maintain particle-laden fluids in suspension. Accordingly, reliable testing of the effect of particle settling on particle-laden fluids has been problematic due to the fact that existing rheometers have been unable to measure to a desired accuracy the rheological properties (e.g., viscosity) of a fluid having a high concentration of solids or particles.
Thus, it would be desirable to create methods of estimating proppant transport and the ability of non-Newtonian fluids to suspend particles, in order to assist in correlating base fluid rheology with particle settling, thereby allowing estimation of slurry transport efficiency and design of new fracturing fluid systems.
The foregoing and other advantages of the invention will become apparent upon reading the following detailed description and upon reference to the drawings.
a is a graph of the storage moduli (G′) of guar solution having borate ion concentrations of about 31 ppm, about 62 ppm, about 93 ppm, and about 125 ppm shown as a function of frequency of oscillation at a fixed stress of 1 Pa.
b is a graph of the loss moduli (G″) of guar solution having borate ion concentrations of about 31 ppm, about 62 ppm, about 93 ppm, and about 125 ppm shown as a function of frequency of oscillation at a fixed stress of 1 Pa.
a shows the typical sedimentation behavior for the guar solution sample having a borate concentration of 31 ppm at various shear rates.
b shows the typical sedimentation behavior for the guar solution sample having a borate concentration of 93 ppm at various shear rates.
c illustrates the settling velocity as a function of imposed shear rate for the guar solution sample having a borate concentration of 31 ppm.
d illustrates the settling velocity as a function of imposed shear rate for the guar solution sample having a borate concentration of 93 ppm.
a is a graph of the first normal stress difference (N1) plotted as a function of shear rate (γ).
b is a graph of the steady shear viscosity (η) plotted as a function of shear rate (γ).
a plots height as a function of time for the 1% wt P(AM-co-AA) in 10 times by weight of corn syrup/glycerol mixture.
b plots height as a function of time for the 2% wt P(AM-co-AA) in 10 times by weight of corn syrup/glycerol mixture.
While the invention is susceptible to various modifications and alternative forms, specific embodiments have been shown by way of example in the drawings and will be described in detail herein. It should be understood, however, that the invention is not intended to be limited to the particular forms disclosed. Rather, the invention is to cover all modifications, equivalents, and alternatives falling within the spirit and scope of the invention.
It should be understood at the outset that although illustrative examples of one or more embodiments is provided below, the disclosed systems and/or methods may be implemented using any number of techniques, fluids, fluid components, or the like. The disclosure should in no way be limited to the illustrative implementations, drawings, and techniques illustrated below, including the exemplary methods and implementations illustrated and described herein, but may be modified within the scope of the appended claims along with their full scope of equivalents.
Rheological Data
As used herein, the term “rheometer” encompasses both multiple-speed testing and single-speed testing devices (the latter conventionally being referred to as a “viscometer” even if performed by the identical instrument capable of multiple-speed testing) for obtaining rheological properties of fluids.
The rheological properties of a borate cross-linked guar solution and constant viscosity high elasticity fluids (known as Boger fluids [REF]) were studied and compared using a transparent Couette cell device 200 with a fixed outer cylinder 202 and a rotating inner cylinder or bob 208, as shown in
In the embodiments described herein, the rheological properties of borate cross-linked guar solution and constant viscosity high elasticity fluids were determined using a StressTech (Reologica Instruments AB, Sweden) controlled-stress rheometer, fitted with a cone-plate fixture.
To create the borate cross-linked guar solutions, about 6 grams of underivatized guar powder were added to about 2000 g of tap water. About 360 grams of nearly spherical particles having a density of about 3.7 g/cm3 and particle sizes ranging from about 600 μm to about 700 μm were added, resulting in a viscoelastic suspension with solids occupying the fraction of about 0.02 of the total volume. The ratio of gap space to particle diameter (Ro−Ri)/d was greater than 10.
Separate viscoelastic solutions formed from guar solutions having added borate ion cross-linker concentrations of about 3 1 ppm, about 62 ppm, about 93 ppm, and about 125 ppm were used. The solutions were continuously mixed until the borate cross-linker was uniformly mixed. Each dispersion was then fed into the device where sedimentation experiments were conducted.
Selection criteria of the experimental fluids were based on the ability to differentiate the effects of elasticity, viscosity, and shear thinning on particle settling. The viscosity of the selected fluids was sufficiently high to yield sedimentation times over a distance of one centimeter in the range of minutes.
Storage moduli (G′) and loss moduli (G″) at cross-linker concentrations of 31 ppm, 62 ppm, 93 ppm, and 125 ppm are shown as a function of frequency in
In the high-frequency range, the storage modulus G′ displays a characteristic plateau (G′p) region. The G′p behavior is typical of a “strong gel” material that is observed when the characteristic relaxation time of the material is longer than the process time, that is, time per cycle of oscillation. The G′p behavior also indicates the intrinsic cross-linked network structure of the system. As shown in
As shown in
b shows that G″max is relatively constant over the range of cross-linker concentration, while the value of G″min increases significantly with increasing cross-linker concentration. In the high-frequency range, the loss modulus G″ shows a characteristic upturn from its minimum values G″min in the low-frequency range. This behavior may reflect a transition from the relaxation mechanism dominant at longer time-scales to a new relaxation mechanism dominant at shorter time-scales.
Referring to
As further shown in
Rheological data of the borate crosslinked guar samples obtained using dynamic shear and steady shear techniques is provided in Table 1 below
ωs in Table 1 above represents the critical frequency or deviation frequency where the fluid becomes non-Newtonian (i.e., the frequency at which η is no longer constant). n in Table 1 above is the slope of the curve at frequencies above the given deviation frequencies.
Turning now to
Measuring Settling Velocity Using a Flow-Through Device
Proppant settling velocity may be directly measured under a given shear condition using a developed flow-through device. The methods disclosed herein utilized a flow-through device as described in U.S. patent application Ser. No. 12/180,668, which is hereby incorporated by reference in its entirety. The system used with the embodiments of the present invention may also include at least one mixing vessel, at least one pump, and/or at least one computer system. In some embodiments, the system may further include at least one sample conditioning unit.
A visualization technique was used to capture the settling interface via a high resolution CCD camera equipped with software linked to systematically control the sequence and speed of the camera. A DC light source provided a constant light intensity onto the flow-through device. A simple numerical algorithm was used to convert picture pixel color level (light to dark scale) to 2D settling interface at a given time.
a and 6b show the typical sedimentation behavior for the 31 ppm borate concentration (lightly elastic, viscosity dominant, faster relaxation time) sample and the 93 ppm (lightly viscous, elasticity dominant, slower relaxation time) sample, respectively, at imposed average shear rates of 0 s−1, 5 s−1, 10 s−1, 20 s−1 and 30 s−1. The results are presented as settling height defined as the upper level of the particles above the bottom of the annular section of the device (in cm) versus time (in min). The settling velocity (in cm/min) is then determined as the slope of the settling height vs time data, and is plotted as a function of the imposed shear rate (s−1) in
For the viscously-dominated sample (31 ppm borate), the particles were found to settle more rapidly with increasing shear rate (see
By contrast, the particles settled more gradually with increased shear rate for the elastically dominated sample (93 ppm) (see
For the elastically dominated sample (93 ppm,
Proppant Transport Index
Also presented herein are the relationships between the settling velocity of particles and the dimensionless parameters governing fluid properties—the Deborah number (De) and the Weissenberg number (We). The Deborah number measures the degree of viscosity, or the relaxation time, of the network structure. The Weissenberg number measures the degree of elastic component. The Deborah number, a ratio of the polymer relaxation time to the characteristic flow time, can be estimated as De=λω=(λΩ1R1)/(R2−R1). The Weissenberg number is herein defined as the ratio of a first normal stress difference to shear stress, We=N1/σ, where σ is the shear stress value. A simple physical model and scaling analysis based on this model are presented to explain the observation of normal stress influence on the settling.
A method developed according to the embodiments of the present invention may be used to determine the settling behavior and the relative distance of settling to axial motion in a fracturing application. This method employs the measurement or modeling of fluid rheology with no solid particles (as opposed to the mixture rheology, which includes solids) and the settling behavior of solid particles. The method is used to discriminate between the ability of different fluid formulations to carry solid particles under bounded flow (and hence shearing flow) conditions, as occurs in the pressure-driven flow along a fracture in hydraulic fracturing applications.
The method consists of defining a “proppant transport index (PTI)” and correlating this to the crucial material properties of the fluid. The transport of particles is characterized by the inverse of the fall speed, Vs−1. A vanishing fall speed would imply that the proppant placement may be determined solely by the fluid motion of the mixture. Larger values of Vs−1 imply better performance of the suspending fluid for particle transport purposes. A dimensionless form of the settling velocity may then be obtained by normalizing using the settling velocity in the absence of flow (V*) to its actual value Vs so that PTI=V*/Vs may be considered.
For a dense particle in a flow of a viscoelastic fluid, the force balance in the direction of gravity involves the gravitational force (Fgrav) balanced by a combination of a viscous force due to settling (first in the below equation) and an elastic force:
Fvis+Fel+Fgrav=0 [1]
If we take a typical Stokes drag for the viscous term, and estimate the elastic force based on the magnitude of the normal stress difference, N1, the balance [1] can then be written
with Δρ the excess density of the particle (sphere of radius a); here α is an O(1) parameter which is expected to be related to the strain induced by the weight of the particle but may be viewed as a fitting parameter. Solving for the settling velocity:
showing that the development of elastic stresses characterized by the normal stress difference may offset (due to the negative sign with all other terms defined positive, this reduces settling speed) the gravity effects, even when the viscosity drops.
This shows that a critical material parameter is the ratio N1/η at the shear rate conditions of interest. We can term the hypothetical velocity in the absence of elastic effects, at the actual viscosity V0 and rewrite as
Recognizing that in the application of interest, the material is subjected to a shearing, an alternative form is
so that we see that if either if We (or N1/η) increases the settling velocity will decrease, and PTI increases:
The first equality in the above equation shows that we must measure settling velocity, while the second illustrates how we may properly correlate the data to develop a predictive method.
Thus, for materials with finite settling velocity at zero shear rate:
The method entails 1) determining Vs (by measuring the settling speed under shear at γ) and 2) determining We (or N1/η) as a function of shear rate γ. The method allows the rapid assessment of the particle transport quality of a candidate non-Newtonian fluid. By determining the dependence of Vs as a function of We (or N1/η), the PTI as defined above may be developed, and PTI>1 indicates a good quality fluid, while PTI<1 indicates a poor quality fluid. The method may thus be used to discriminate between two fluids as fracturing fluid candidates, as the variation of PTI with shear rate (at the temperature and other variables of interest) for the two fluids may be used to deduce the superior material for transport of the particles of interest.
The method may be used to predict the method may be used to predict the elastic transport characteristics of a fluid. This may be done without measurement of the settling velocity under shear. As shown by the analytical form of PTI equation above, a material which has an increasing PTI has elastic stresses which more effectively support particles even while its viscosity declines.
The method as outlined in the above provides a screening method for fracturing fluids. In application the reduced viscosity may make the material easier (less costly) to pump, while the ability to support solids is critical to proppant placement, so that an increasing PTI with shear rate may be indicative of a material which can satisfactorily place proppant while being sufficiently low viscosity to pump without excessive expense.
In summary, the correlation of PTI (or Vs) with We or N1/η allows prediction of the quality of proppant transport in a fracture job, and a prediction requiring only pure fluid rheology may be made based on the PTI equation above.
In an alternative embodiment, as above in all respects, the method may be applied with modeling of N1 from linear viscoelastic (LVE) tests. Different expressions of the elastic force and viscous force may be employed. Those provided above are only examples (although other forms should only differ quantitatively and not qualitatively in the information one may deduce from them).
Turning now to
As shown in
The Peclet number is defined by Pe=(3πη0Ususd2)/(kT), where k is Boltzmann's constant and T is temperature. In this work, the Pe was larger than 1010. Hence, for these experimental conditions, hydrodynamic interactions are dominant over Brownian or colloidal effects on the settling particles, which may be considered negligible. Inertia as measured by the well-known Reynolds number
is small and a more relevant Reynolds number based on the particle scale is negligibly small indicating inertia is of very small influence.
Comparison to Boger Fluids
The results obtained above were then compared to Boger fluids, in which viscosity is constant and elasticity changes, to determine which of viscosity or elasticity has a greater affect on settling velocity.
High viscosity Boger fluids were used. The Boger fluids were aqueous solutions of poly(AM-co-AA) (Sigma-Aldrich, St. Louis, Mo.) in a mixture of corn syrup (T. J. Blackburn Syrup Works, Inc., Jefferson, Tex.) and a glycerol solvent. The weight average molar mass of the polymer Mw was about 5×106. The glycerol used was a commercial grade glycerin with about 99.7% purity grade having a density of about 1200 kg/m3 (KIC Chemicals, Inc., New Paltz, N.Y.). The polymer samples were first dissolved in reverse osmosis (RO) purified water to give about 1% wt and about 2% wt solutions before being mixed with 5 folds weight of solvent. The ratio of corn syrup to glycerol in the solvent was about 7/3 (by weight). The resulting samples for rheological measurements were about 0.166% wt and 0.33% wt solutions of poly(AM-co-AA) in 7/3 (w/w) corn syrup/glycerol mixed solvent. About 360 grams of “proppant” particles having a density of 3.7 g/cm3 and a particle size ranging from about 600 μm to about 700 μm and nearly spherical geometry were added, forming a viscoelastic suspension with the solid volume fraction of 0.02.
Six constant viscosity high elasticity samples were used to determine roles of elasticity and viscosity on proppant particle settling rate under static and imposed shear conditions. The steady shear data are shown in
However, as shown in
The rheological behavior observed in
In Table 3, ρ is the density of the solution, ηs is the viscosity of the solvent, η is the viscosity of the mixture, and λs and λs are measures of relaxation times. λt is the transient decay of normal force, and λs is calculated using the Oldroyd-B equation at steady shear.
El in Table 3 is the elasticity number defined as the ratio of the Deborah number (De=λtγ) to the Reynolds number
In the Reynolds number, Ω1 and Ω2 are the rotational speeds of the two cylinders, and the Deborah number is defined as De=(λΩ1R1)/(R2−R1). The elasticity number (El) depends solely on fluid properties and geometric parameters and is, thus, defined as El=De/Re=ηλ/ρ(R2−R1)2.
a, 9b plot height (cm) of the suspended proppant as a function of time (min) for the Boger fluids for various shear rates γ.
Results
The key rheological parameters gathered from the testing described above may be used to optimize a hydraulic fracturing treatment. For example, fracture geometry is generally known from existing simulations. The shear rate may be calculated therefrom for a given pumping rate. Once it is decided which materials (proppant and carrying fluid) are to be used, N1 may be obtained from taking the required rheological measurements. The Weissenberg number may then be obtained, and from that, the proppant settling velocity may be estimated. Alternatively, at a constant viscosity, the proppant transport index of
The proppant transport index (PTI) may be used to quickly assess whether a fluid will have the ability to carry solid particles sufficiently well to work in a given application. For example, the PTI yields the time for settling a given distance, and the application engineer may consider the flow rate imposed to determine the time necessary to flow the resulting distance into a fracture where it is necessary to place proppant. If the PTI indicates that the settling is too large on this time (an engineering judgment based on acceptable performance for the application) then the materials to be used would need to be modified. Note that PTI is specific to the particle size and density considered.
The results presented herein reveal a remarkably strong reduction of settling by elasticity of the liquid, which is seen even for liquids which exhibit shear-thinning if the normal stress is found to grow sufficiently rapidly. A simple conceptual model allows the development of a scaling law which explains the observed dependence of settling velocity upon the Weissenberg number, defined as the ratio of the first normal stress difference to the shear stress, We=N1/σ. A balance of forces shows how flow-induced elastic forces can support part of the weight of a particle and thus reduce the fall speed. This leads to the general conclusion that normal stresses in a viscoelastic fluid may have pronounced effects on the motions and distribution of solids within the fluid.
A simple analysis of the settling of a particle through a viscoelastic liquid undergoing an imposed shearing motion may also be performed. It is assumed that all motions are at low Reynolds numbers. For a particle settling in a viscoelastic liquid, the forces on the particle in the direction of gravity (taking the negative direction along gravity) are the driving excess weight Fg=−(4πa3/3)Δρg, a viscous drag which may be written Fd=−6πηaU where U is the settling velocity, and an elastic force, Fe, which is assumed to resist gravity. The elastic force is of unknown form, but may be expressed in terms of the liquid normal stress difference as Fe=(4πa2)αN1 where 4πa2 is the particle surface area, N1 is the liquid first normal stress difference, and α is an unknown but positive dimensionless coefficient. Assuming the particle to be spherical of radius a and in steady motion, the forces on the particle must balance, Fg+Fd+Fe=0, which may be rewritten as
In a dynamic settling experiment, the liquid is subjected to a shear stress σ. Using this imposed stress and the particle surface area to provide a force scale of 4πa2σ we normalize all terms to arrive at
Here, the Weissenberg number is given by We=N1/σ and characterizes the ratio of shear-induced normal stresses to the imposed shear stress. Because η, U, and σ=ηγ are all rate-dependent, it is useful to replace the stress σ in the second term to yield
Noting that γ increases at least proportionally to σ and faster if the material shear thins, this form immediately provides a prediction of interest. At low rates, where We→0, the velocity is given by
Note that this is a quasi-Newtonian form. The rate-dependence of the viscosity is included, and for fluids showing shear-thinning but negligible elasticity, the expectation is that U increases with increasing shear rate, in agreement with the settling behavior in a lightly cross-linked guar solution fluid of 31 ppm borate (see
For a fluid that exhibits normal stress differences, with We non-negligible, we find
Quite generally, we see that the final “elastic” term offsets the weight of the particle. As We increases, the fall speed U is predicted to decrease as a progressively larger fraction of the excess weight of the particle is balanced by the elastic normal stress exerted by the fluid. We interpret the physics behind this prediction as follows. A particle immersed in shear flow disturbs the streamlines The elastic stresses along the streamlines (σ11 in N1=σ11−σ22) are brought into play because a particle deflects the streamlines of constant stress, and there will be a resulting force opposing this deflection. Because a heavy particle generates a bias, owing to a larger deflection on the lower side of the particle, there is net elastic force up on the particle. The prediction is borne out by the data presented for a more heavily cross-linked guar sample (e.g., 93 ppm borate, see
The results for the Boger fluids indicate that a cross-linked network is not essential, and that a simple force balance captures the idea. The Boger fluid is formed from a polymeric solution, without interchain crosslinking of the macromolecular chains, so that the elasticity is not dependent on a network formation, and can even be shown to result in a slowing of settling at levels of polymer too low to exhibit chain overlap (entanglement).
The results indicate that the settling characteristics for isolated particles as a function of rate may be deduced from a thorough but straightforward rheological characterization. It is not necessary to perform the difficult fluid mechanical calculations of particle motion in shear fields.
According to one process of the present invention, a method of determining one or more minimum rheological properties of a particle laden fluid includes determining one or more rheological properties of the fluid at a first shear rate, determining the settling velocity of the particles at the first shear rate, and obtaining a transport index for the fluid, the transport index indicating a relationship between the settling velocity and the one or more rheological properties.
According to another process, a method of determining proppant supportability of a carrying fluid including the proppant includes determining at least one rheological property of the carrying fluid, the at least one rheological property being associated with elasticity or viscosity, determining the settling velocity of the proppant under imposed shear conditions, and developing a proppant transport index indicating a relationship between the at least one rheological property and the settling velocity.
Number | Name | Date | Kind |
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6782735 | Walters | Aug 2004 | B2 |
7392842 | Morgan et al. | Jul 2008 | B2 |
20080190603 | Brannon | Aug 2008 | A1 |
20100018294 | Tonmukayakul | Jan 2010 | A1 |
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Number | Date | Country | |
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20110219856 A1 | Sep 2011 | US |