Hydraulic Fracturing Treatment Research Articles

A poroelastic numerical model for simulation of hydraulic fracture propagation: Application to Upper Safa formation-Western Desert-Egypt

The hydraulic fracturing in tight sand formations has a significant importance in improving its production potential. In this study, a poroelastic numerical model is presented in order to study the reservoirs and rock mechanical properties that affect the propagation of the hydraulic fracture. The poroelastic model simulate fully coupled fluid flow, pressures and stress changes by using finite element technique. The results show that the formation permeability and fracture toughness are key parameters in the design of hydraulic fracture treatment.A case study applied in Upper Safa formation in a well-located western desert Egypt. The formation is very tight with permeability of 0.1md and the objective here is to optimize the design procedures for hydraulic fracture treatment. The results show that the formation needs to be pumped for about 5 min to produce hydraulic fracture length of 182 ft. In addition, the total pumping time (30 min) is vital to produce the desired total fracture length of 1000 ft.

Study of the effects of hydraulic fractures on gas and water flow in shale gas reservoirs

ABSTRACT Horizontal drilling and multi-stage hydraulic fracturing are the two key technologies for the successful development of shale gas reservoirs. However, there exist large uncertainties in optimizing hydraulic fracturing which affects water retention into shale matrix and gas productivity. In this work, a basic reservoir model with six-stage hydraulic-fracturing treatment was constructed to understand water retention and gas production in shale gas reservoirs. Gas diffusion, gas desorption, Darcy flow as well as non-Darcy flow were considered in this model. Then, a sensitivity study was performed to investigate the effects of hydraulic fractures on water retention and gas conductivity. The results indicate that only 34% of the fracturing water could be recovered back to the surface, and most of them remain in shale formations to interfere with gas production. The increase of fracture half-length, fracture width, fracture permeability, and fracture conductivity will reduce water retention while water retention in shale matrix will increase with the increasing of fracture spacing and fracture number. This work can provide a better understanding of the effects of hydraulic fractures on gas and water flow so as to optimize the hydraulic-fracturing treatment in shale gas reservoirs.

A 2D explicit numerical scheme–based pore pressure cohesive zone model for simulating hydraulic fracture propagation in naturally fractured formation

AbstractIn this work, a 2D pore pressure cohesive zone model is presented to simulate the hydraulic fracture propagation in naturally fractured formation, in which the fracturing process is governed by a bilinear cohesive zone model equipped with Coulomb's friction law and the fluid flow within the hydraulic fracture is described by the lubrication equation. In this model, fluid leak‐off into rock matrix is ignored and a fully explicit temporal integration scheme is adopted to overcome the convergence issue of conventional implicit scheme (eg, Newton‐Raphson method). The advantage of the proposed model is that it does not require any special crossing criterion to determine the interaction behavior when the hydraulic fracture hits the natural fracture. Implementation of the model was described in detail, and then, the model was verified with well‐known analytical solution of KGD problem and criteria of hydraulic fracture crossing natural fracture. The capability of the proposed model to capture the interaction behavior between hydraulic fracture and natural fracture was demonstrated by the good agreement of the modeling result and analytical solution. Several numerical cases were performed to investigate the impact of key factors on fracture network evolution during hydraulic fracturing treatment. Results show that fracture network is not only governed by the spatial distribution of natural fracture, but also greatly affected by the initial hydraulic aperture of natural fracture and in situ stress contrast.

Influence of orientation of vertical crack of hydraulic fracturing treatment on the efficiency of reserve recovery

The article presents the study results of the influence of the orientation of a vertical crack from hydraulic fracturing treatment on the efficiency of oil reserve recovery, indicating the crack propagation direction. It was found that the increase in initial recoverable reserves is the greater, the longer the crack length is, and if the crack is oriented parallel and perpendicular to the filtration flow down to the permeable zone in the stagnant or deadlock zone, then the perpendicular connecting current lines from the injection well to the recovery well is most effective. The presented results show that HFT significantly changes the conditions for the oil reserve recovery in general in the reservoir area. Therefore, it is relevant to assess the contribution of a single HFT to the oil recovery factor of the reservoir area, as well as its effect on the wells density grid.

Wellbore Cleanout in Inclined and Horizontal Wellbores: The Effects of Flow Rate, Fluid Rheology, and Solids Density

Summary Coiled tubing (CT) is extensively used in wellbore-cleanout operations to remove solid particles such as drilled solids or residual proppant from hydraulic-fracturing treatments. The cleanout operation is often associated with nonproductive time and significantly adds to the operational cost. This study is aimed at developing a model to predict the required fluid-circulation rate and time to efficiently remove solids from the wellbore and optimize the cleanout operation. To study the hole-cleaning mechanism, solids-bed-erosion experiments were conducted using a flow loop that has a 10.4-m-long annular test section. The effects of solid density, flow rate, inclination angle, and fluid type (Fluids 1, 2, and 3) on the cleanout operation were investigated by measuring bed erosion and hole-cleaning efficiency. During the experiment, a stable bed was initially formed in the annular test section. Then, the bed was eroded and the amount of solids removed was measured to determine cleanout efficiency. In addition, bed height was measured at different locations in the test section as a function of circulation time. The measurements resulted in the generation of a bed-erosion curve (plot of average bed height vs. circulation time) for each test. The erosion curves obtained from this study are consistent with previously reported measurements. This study indicates that flow velocity, inclination, and fluid rheology are the primary factors in determining hole-cleaning efficiency. Bed erosion is highly prominent at high flow velocities, especially with low-viscosity fluids, because the increase in velocity results in strong turbulence and the lifting of bed particles. Alternatively, an increase in viscosity reduces particle settling and maintains particles in suspension once they enter the flow stream. This is attributed to a greater drag-force generation, which facilitates particle transport by hindering redeposition. However, an increase in viscosity limits the particle-lifting capacity of the fluids by affecting the near-bed velocity profile, which is critical for lifting bed particles. Therefore, it is recommended to use low-viscosity fluids in cleanout operations at high-inclination well sections, and vice versa. Solids density has a moderate (up to 30%) effect on cleanout efficiency compared with fluid velocity and rheology. For different solid densities at a constant flow rate, high-density solids make hole cleaning much more challenging, especially in nearly horizontal well sections. There is a critical angle of inclination between 64 and 69° at which the cleanout efficiencies of all fluids are approximately equal, irrespective of the flow rate. The outcomes of this investigation can be applied in the field to optimize cleanout operations in horizontal and highly deviated wells.

Laboratory Evaluation of a Low pH and Low Polymer Concentration Zirconium-CMHPG Gel System for Hydraulic Fracturing

Low pH fracturing fluids, such as the transition metal cross-linked guar derivative, can reduce the formation damage caused by clay swelling and fines migration in hydraulic fracturing treatments. ...

Hydromechanical modeling of unrestricted crack propagation in fractured formations using intrinsic cohesive zone model

Production from unconventional reservoirs has revolutionized the oil and gas industry strongly through the development of innovative applications, such as horizontal drilling and shale stimulation by hydraulic fracturing. However, the presence of geological discontinuities such as natural fractures (NFs) complicates the hydraulic fracturing treatment and affects the general geometry of the hydraulic fracture (HF). For that reason, it is essential to develop and implement robust numerical methods capable of simulating the phenomena present during hydraulic fracturing in a naturally fractured formation. This paper presents a novel mesh fragmentation technique to simulate unrestricted hydraulic fracture propagation in fractured media. This method is based on the hydromechanical zero thickness interface element combined with the cohesive zone model (CZM). An algorithm for inserting the especial triple-noded interface elements into conventional 2D finite element meshes is described. We introduce a simple but effective topological data structure that considers each finite element independent of others. The proposed topological structure ensures the generation of new nodes and faces which are necessary for the insertion of interface elements. The implementation is validated by simulating some cases of fracturing experiments in laboratory. The numerical procedure provides very good agreement with the laboratory tests and shows the robustness of the proposed computational approach. Some advantages and limitations of the proposed methodology are discussed.

Numerical modelling of hydraulic fracturing procedure in hydrocarbon reservoirs

Due to the increasing demand for the utilization of hydrocarbon fossil fuels in numerous industries, petroleum engineers push themselves into limits to provide novel and sustainable solutions to enhance the volume of produced oil. There are various methods to improve the productivity for reservoirs of which hydraulic fracturing (HF) treatment is one of the most common ones. HF is a treatment during which by injection of high-pressure fluid, mostly water, fractures are initiated and propagated from well to reservoir so that the rate of production rises. One of the holistic and more confidential solutions to address this issue is the appropriate numeration modelling of hydraulic fracturing simulations. The objectives of this study are to create a 3D numerical model simultaneously coupling solid, fluid, and fracture mechanics equations. For this purpose, cohesive zone model based on the traction–separation law, which is implemented in Abacus software, is used to model a conventional condition of HF treatment. It is observed that the fracture pressure values for the depths 1–3 are 76.7, 82.6 and 85.2 MPa, respectively. Furthermore, the fracture extension pressure is 53, 59, and 65 MPa, respectively. The onset and expansion pressures also increased with increasing depth due to increasing initial stresses.

Investigation of Hydraulic Fracturing Behavior in Heterogeneous Laminated Rock Using a Micromechanics-Based Numerical Approach

Understanding hydraulic fracturing mechanisms in heterogeneous laminated rocks is important for designing and optimizing well production, as well as for predicting shale gas production. In this study, a micromechanics-based numerical approach was used to understand the physical processes and underlying mechanisms of fracking for different strata orientations, in-situ stresses, rock strengths, and injection parameters. The numerical experiments revealed a very strong influence of the pre-existing weakness planes on fracking. Geological models for rock without weakness planes and laminated rock behave very differently. Most simulated fractures in the rock without weakness planes were caused by tensile failure of the rock matrix. In an intact rock model, although a radial damage zone was generated around the injection hole, most of the small cracks were isolated, resulting in poor connectivity of the fracture network. For rock models with pre-existing weakness planes, tension and shear failure of these structural planes formed an oval-shaped network. The network was symmetrically developed around the injection well because the strength of the pre-existing weakness planes is generally lower than the rock matrix. The research shows that the angular relations between the orientation of the structural planes and the maximum horizontal stress, as well as the in-situ stress ratios, have significant effects on the morphology and extent of the networks. The strength of the pre-existing weakness planes, their spacing, and the injection rate can dramatically influence the effectiveness of hydraulic fracturing treatments.

Considering Time and Space in Drilling and Completion Can Reduce Well Interference

This article, written by JPT Technology Editor Judy Feder, contains highlights of paper SPE 191836, “When, Where, and How To Drill and Complete Pads of Multiple Wells? Four-Dimensional Considerations for Field Development in the Vaca Muerta Shale,”by Stephane Pichon, SPE, Federico Gaston Cafardi Orihuela, Emilio Lagarrigue, and Gustavo Cavazzoli, SPE, Schlumberger, prepared for presentation at the 2018 SPE Argentina Exploration and Production of Unconventional Resources Symposium, held in Neuquén, Argentina, 14–16 August. The paper has not been peer reviewed. Development of organic shale reservoirs with large hydraulic-fracture treatments not only poses challenges to the completion of a single well, but also to interference with surrounding wells. A direct consequence of interference is production loss. Therefore, the drilling and completion schedule for field development must be 4D in time and space to account for interaction in between wells. The complete paper describes a physics-based model of interference and a sensitivity study to propose guidelines for well spacing and a drilling timeline for multiple horizontal wells in the Vaca Muerta shale. Introduction Effective field development relies on the tradeoff between the capital expenditure (CAPEX) and the production profile generating cash flow. Both CAPEX and the production profile are directly controlled by the number of wells and the pace at which these wells are tied in to the production facilities. With respect to tight rocks, the need for horizontal drilling and hydraulic fracturing adds a layer of geometrical complexity to unlock such resources. In very-low-permeability reservoirs, the drainage area is controlled by the hydraulic-fracture geometry. However, the relatively large size of the fracturing treatments performed in a multistage manner across several different perforation clusters within a same stage makes hydraulic fractures difficult to control. In practice, fracture dimensions are not constant along a lateral. Additionally, because limited contribution of the matrix is expected in a nano-Darcy environment, the spacing between laterals tends to be smaller than the reach of the hydraulic fractures. This has been evidenced by the increasing concern over fracture hits in the industry, and already has been experienced in the Vaca Muerta. Interference can be caused by fracture hits while completing the well, competition for drainage area during production, or fracture-geometry deterioration caused by stress field variation when infill-drilling a child well near a produced parent well. Even if some overlap between the hydraulic fractures of two neighboring wells is advisable to avoid leaving reserves behind, the tradeoff between well spacing, completion intensity, and production interference remains a delicate exercise. Hydraulic fracturing should be considered at the field level, rather than independently for each well, giving completion a multiple-well spatial dimension. As an additional complexity, child wells completed later in the development of a lease tend to perform more poorly than the parent wells. This performance impairment might have several different sources, but one of the most-accepted hypotheses is that the heterogeneous contrast in the stress field generated by the depletion around the parent negatively affects the contact area provided by the hydraulic fractures of the child well.

Shear-tensile fractures in hydraulic fracturing network of layered shale

Understanding hydraulic fractures generation and geometric properties are significant for optimizing hydraulic fracturing treatment design which improves the ultimate production from shale reservoirs. The propagation of the hydraulic fractures is influenced by bedding planes. Simple opening or tensile crack model is not enough to meet the hydraulic fractures generation process, and the fault slipping model which is regarding as the cause of the natural earthquake is also not compatible with the actual physical meaning of fracking induced fractures. Hydraulic fractures consist of not only the opening but also slippage. Acoustic emission monitoring combined with the true triaxial hydraulic experiment provides direct information about the propagation and the geometric parameters of fractures. Moment tensor of acoustic emission is related to the mechanical mechanics of fractures. In this paper, the moment tensor interpretation is based on the shear-tensile crack model, then the orientation and the opening width of the hydraulic fractures are calculated. Computerized tomography scanning figures of the samples give support to the interpretation process. The distributions of hydraulic fractures orientations are different in the two samples with different normal stress applied on the bedding plane. Higher normal stress on the bedding plane led to a more complex fracture orientation. And the opening widths of the fractures in the far area from the wellbore are smaller than the fractures nearby the wellbore. These two parameters quantify the fractures geometric properties and provide information for adjusting the next step of the fracturing process. The findings of this study can help for better understanding of hydraulic fractures generation in the bedding shale. Shear-tensile crack model is supported by actual physical models has good adaptability in explaining the hydraulic fracture propagation process.

Investigation of Rupture and Slip Mechanisms of Hydraulic Fractures in Multiple-Layered Formations

SummaryWeak bedding planes (BPs) that exist in many tight oil formations and shale–gas formations might strongly affect fracture–height growth during hydraulic–fracturing treatment. Few of the hydraulic–fracture–propagation models developed for unconventional reservoirs are capable of quantitatively estimating the fracture–height containment or predicting the fracture geometry under the influence of multiple BPs. In this paper, we introduce a coupled 3D hydraulic–fracture–propagation model considering the effects of BPs. In this model, a fully 3D displacement–discontinuity method (3D DDM) is used to model the rock deformation. The advantage of this approach is that it addresses both the mechanical interaction between hydraulic fractures and weak BPs in 3D space and the physical mechanism of slippage along weak BPs. Fluid flow governed by a finite–difference methodology considers the flow in both vertical fractures and opening BPs. An iterative algorithm is used to couple fluid flow and rock deformation. Comparison between the developed model and the Perkins–Kern–Nordgren (PKN) model showed good agreement.I–shaped fracture geometry and crossing–shaped fracture geometry were analyzed in this paper. From numerical investigations, we found that BPs cannot be opened if the difference between overburden stress and minimum horizontal stress is large and only shear displacements exist along the BPs, which damage the planes and thus greatly amplify their hydraulic conductivity. Moreover, sensitivity studies investigate the impact on fracture propagation of parameters such as pumping rate (PR), fluid viscosity, and Young's modulus (YM). We investigated the fracture width near the junction between a vertical fracture and the BPs, the latter including the tensile opening of BPs and shear–displacement discontinuities (SDDs) along them. SDDs along BPs increase at the beginning and then decrease at a distance from the junction. The width near the junctions, the opening of BPs, and SDDs along the planes are directly proportional to PR. Because viscosity increases, the width at a junction increases as do the SDDs. YM greatly influences the opening of BPs at a junction and the SDDs along the BPs. This model estimates the fracture–width distribution and the SDDs along the BPs near junctions between the fracture tip and BPs and enables the assessment of the PR required to ensure that the fracture width at junctions and along intersected BPs is sufficient for proppant transport.

Analysis and prediction of stimulated reservoir volumes through hydraulic fracturing: Examples from western Arkoma Basin

Geologic models built from well logs and natural fracture (NF) parameters obtained at shale and carbonate outcrops/quarries were employed in understand artificial hydraulic fracture (HF) propagation and stimulated reservoir volume (SRV) geometries. We applied field HF treatment parameters from an Arkoma Basin well, located 20–25 miles (32–40 km) east of the studied quarries. We matched the microseismic cloud (MC) geometries of three field stages, followed by sensitivity analyses of various HF treatment and reservoir parameters.Geometry matches reveal that the average NF permeability in the Viola Group Limestone is nearly eight times that in the Woodford Shale. The sensitivity analyses (forward modeling) disclosed several likely outcomes. First, a minor (5 × 10−6) increase in the minimum horizontal tectonic strain and ensuing increase in the minimum horizontal stress resulted in a sizeable transformation of the SRV geometry. Second, pumping at a higher net pressure (ISIP increased from 6500 to 7000 psi) diminished the stimulation volume and opened more previously non-dilatable NFs closer to the wellbore. Higher net pressure also triggered more stimulation downward and out of the target zone in the studied area. Third, halving the number of NFs and doubling their final storage apertures significantly magnified the fracturing-fluid efficiency (i.e., lowered leak off into NFs) in areas where it was restricted from flowing through non-dilatable NFs. Additionally, this modification caused greater lateral growth and comparatively large downward (out of target zone) growth of the HF and NF reactivation front, lowering the effectiveness of the HF job. However, halving the number of NFs and doubling their final storage apertures did not result in a substantial change in the SRV geometry upon allowing fluid flow through non-dilatable NFs. Fourth, altering the well-landing depth within the Woodford Shale did not result in a major shift in the overall stimulation geometry or volume. Most importantly, the simulated hydraulic fractures emanating from the wellbore do not span the entire recorded microseismic cloud length and height.

Modeling hydraulic fracturing in jointed shale formation with the use of fully coupled discrete element method

During a hydraulic fracturing treatment, sedimentary beddings and preexisting joints in the shale reservoir may cause the deviation of fractures and the diversion of fluid, which ultimately lead to the unexpected fracture patterns. To evaluate the influence of these factors on the fracturing response, a comprehensive study is conducted using the discrete element method simulations. Interactions between the beddings, the preexisting joints and the induced fractures are modeled in a fully coupled manner by idealizing the sedimentary beddings which cause inherent anisotropy as individual horizontal smooth joint and modeling any preexisting joints with continuous smooth joint contacts. The models are first calibrated to reproduce the mechanical properties of the anisotropic rock in field. Results from these simulations indicate that the formation’s anisotropy promotes fracture growth along the sedimentary beddings. Joint characteristics (i.e., orientation, aperture, and healing conditions) could have a major impact on the behavior of shale formation during hydraulic fracturing operations. Open horizontal joints play a more important role in the fracture propagation process than the in situ stress under the stress state considered in this study. The healing in the joints creates a barrier for fracture propagation, which might be effective enough to lead to fracture deviation from the preferred orientation. This study reveals the important factors which may influence the hydraulic fracture propagation and thus can serve as numerical basis for the more exhaustive studies in the future, e.g., models with realistic fracture network and more complex injection scenarios.

Proppant transport in foam fracturing fluid during hydraulic fracturing

During hydraulic fracturing treatments, proppants often settle at the fracture bottom in low viscosity fracturing fluid (e.g., slickwater) and leave a large fraction of the fractured surface unpropped. Severe proppant settling leads to under performance of the well productivity. Polymer-free foams can be used as fracturing fluids for improved transport of proppants after a low viscosity pad. In this paper, proppant transport in foam is studied during hydraulic fracturing. A proppant settling velocity correlation in foam-based fracturing fluid is developed based on laboratory-scale experiments. Foam quality and the foam velocity gradient are found to control proppant settling. Additionally, foam liquid drainage is found to be an important process affecting proppant transport, and a foam drainage model is proposed based on literature studies. The new settling velocity correlation and the foam drainage model are incorporated into an in-house fracturing simulator, and proppant placement in foam fracturing fluid is evaluated at the field-scale. Foams place proppants more uniformly than slickwater. For dry foams, drainage has little effect on the final proppant placement. For wet foams, drainage affects the final proppant distribution. The faster the foam drains, the less uniform is the final proppant placement. The liquid from the foam collects at the bottom where the proppants settle fast and form a small proppant bed.

Multifracture response to supercritical CO 2 ‐EGS and water‐EGS based on thermo‐hydro‐mechanical coupling method

Hydraulic-fracturing treatments have become an essential technology for the development of deep hot dry rocks (HDRs). The deep rock formation often contains natural fractures (NFs) at micro and macroscales. In the presence of the NF, the hydraulic-fracturing process may form a complex fracture network caused by the interaction between hydraulic fractures and NF. In this study, analysis of carbon dioxide (CO2)-based enhanced geothermal system (EGS) and water-based EGS in complex fracture network was performed based on the thermo-hydro-mechanical (THM) coupling method, with various rock constitutive models. The complexity of the fracture geometry influences the fluid flow path and heat transfer efficiency of the thermal reservoir. Compared with CO2-based EGS, water-based EGS had an earlier thermal breakthrough with a rapid decline in production temperature. CO2 can easily gain heat rising its temperature thus reducing the effect of a premature thermal breakthrough. Both CO2-based EGS and water-based EGS are affected by in-situ stress; the increase in stress ratio improved the fracture permeability but resulted in an early cold thermal breakthrough. When the same injection rate is applied to water-based EGS and CO2-based EGS, water-based EGS displayed higher injection pressure buildup. Water-based EGS had higher reservoir deformation area than CO2-based EGS, and thermoelastic constitutive model for water-based EGS showed larger deformed area ratio than thermo-poroelastic rock model. Furthermore, higher values of rock modulus accelerated the reservoir deformation for water-based EGS. This study established a novel discussion investigating the performance of CO2-based EGS and water-based EGS in a complex fractured reservoir. The findings from this study will help in deepening the understanding of the mechanisms involved when using CO2 or water as a working fluid in EGS.

Совершенствование методического подхода к планированию мероприятий по гидроразрыву пласта на нефтяных месторождениях

Goal of the research is development of an integrated approach to the planning of hydraulic fracturing (HF) treatment taking into account geo-technical, hydrodynamic, technological and economic criteria for the selection of wells for inclusion in the programs of HF with increasing importance of economic criteria.Stages of formation of the program for HF of the oil company are selected, systematized and analyzed. It is shown that high potential effectiveness of enhanced oil recovery method in fields with hard-to-recover reserves, on the one hand, and the complexity and high cost of application, on the other, determine the need to optimize the parameters of this business process at all stages of implementation and improve its planning methods. The priority directions for improving the hydraulic fracturing planning were justified: a clear definition of the criterion for the payback period of hydraulic fracturing activities, taking into account their technological features, improving the procedure for calculating the costs of implementing this technology and improving the reasonableness of selecting candidate wells for inclusion in the hydraulic fracturing program.Feasibility of using an additional criterion in the formation of hydraulic fracturing programs – marginal minimum cost-effective wall capacity – has been shown and a method for calculating it has been developed. The use of this criterion will allow to take into account not only technological limitations, but also limits of economic efficiency of conducting hydraulic fracturing at each specific well and, at the preliminary selection of candidate wells, exclude a priori unprofitable measures.It is advisable to take into account proposed directions for improving planning of hydraulic fracturing in the development of corporate regulatory documents, which will help to improve the quality of planning geological and technical measures, minimize investment risks, make more rational use of oil companies' resources for improving oil recovery, choosing the best management decision.

Calculation of hydraulic fracture induced stress and corresponding fault slippage in shale formation

The casing deformation problems during hydraulic fracturing process in shale gas wells seriously affect multi-stage hydraulic fracturing treatment and cause significant impact on efficient exploitation of shale gas in Sichuan, China. But by now, the mechanism of these casing deformation problems has not been completely understood. The tests of the casing deformation show that the shear failure is the main type of casing deformation. Combined with the detected seismic data, the fault slip caused by hydraulic fracturing is identified as the main reason for casing deformation in shale gas wells. A deep understanding of fault reactivation and slip is significant important. Hence, a semi-analytical model for calculating induced stress along the fault caused by hydraulic fracture is established in this paper. Based on the induced stress along the fault, semi-analytical models for calculating two types of fault slip are established, including the reactivated zone located at one fault tip and the reactivated zone located away from fault tips. Additionally, the effects of fluid pressure, dip angle of fault, scale of fluid stimulated area and the friction coefficient on fault slippage are discussed. At last, the method for calculating fault slippage proposed in this paper is applied in field and the calculated result is consistent with the field data. The semi-analytical model proposed in this paper provides a reasonable way for identifying casing deformation in shale gas wells or other wells which need hydraulic fracturing treatments.

Real-Time Formation-Face-Pressure Analysis Improves Acid-Fracturing Operations

This article, written by JPT Technology Editor Judy Feder, contains highlights of paper SPE 194351, “Real-Time Analysis of Formation-Face Pressures in Acid-Fracturing Treatments,” by Vibhas Pandey, SPE, and Robert Burton Jr., SPE, ConocoPhillips, and Kay Capps, Capsher Technology, prepared for the 2019 SPE Hydraulic Fracturing Technology Conference and Exhibition, The Woodlands, Texas, USA, 5–7 February. The paper has not been peer reviewed. Knowledge of formation-face pressures is critical to the success of hydraulic-fracturing treatments, especially in multistage and multiple-cluster-type horizontal-well completions. This knowledge can help in evaluating the effectiveness of acid-fracturing treatments in dynamic mode and also can enable and improve real-time decision-making during treatment execution. This paper contains a detailed discussion of methods and a software tool that has been developed to generate information that predicts formation-face pressures in real time with the help of live bottomhole-pressure data. Introduction Acid-fracturing treatments combine the basic principles of hydraulic fracturing and acid-reaction kinetics to stimulate acid-soluble formations. Unlike propped fracturing treatments, in which a viscous pad is followed by slurry-laden fluid that assists in keeping the fracture propped open to create a conductive flow path for formation fluids, the fracture conductivity in acid fracturing is generated by dissolving the formation face to create an uneven surface on the fracture walls. Multiple pad and acid stages are pumped during the course of the treatment to create a high-conductivity fracture. The acid stage then fingers through the pad and the open fracture to create differentially etched patterns on the fracture walls. The uneven, etched surfaces prevent the fracture from closing completely once the hydraulic pressure is removed, leading to a highly conductive pathway to enhance hydrocarbon flow. Once the acid contacts the formation, the bottomhole treating pressure recedes quickly, and, as acid spending continues, the effective bottomhole pressures can fall below fracture-closure stresses. Not all loss of pressure is a result of acid spending alone. The fluid fingering among fluids of highly contrasting viscosities also can result in such drops. However, the stress relief that results from acid spending dominates this behavior. Pumping additional acid in these cases only results in near-well acid or mineral reactions, which do not extend fracture penetration and may increase wellbore-integrity risks. Unfortunately, without a good estimation of effective fracture pressures, determination of when the fracture-treatment pressure dips from above closure stress to below closure stress is difficult. Determination of this critical transition was a primary driver of the study that led to the creation of a tool that can assist in determining the real-time treating pressures at the entry of the fracture during stimulation treatments. Several acid-fracturing treatments were analyzed using the tool, leading to important conclusions related to fracture-propagation modes, acid-exposure times, and effectiveness of given acid types.

Numerical considerations for the simulation of proppant transport through fractures

Injection of a proppant slurry (fluid mixed with granular material) into a reservoir to keep fractures open is a common procedure in hydraulic fracturing treatments. This article presents the numerical methodology for simulation of proppant transport through a hydraulic fracture using the Finite Volume Method. Proppant models commonly used in the hydraulic fracture literature solve the linearized advection equation; this work presents solution methods for the nonlinear form of the proppant flux equation.The complexities of solving the nonlinear hyperbolic advection equation that governs proppant transport are tackled, particularly handling shock waves that are generated due to the nonlinear flux function and the spatially-varying width and pressure gradient along the fracture. A critical time step is derived for the proppant transport problem solved using an explicit solution strategy. A predictor-corrector algorithm is developed to constrain the proppant from exceeding the physically admissible range. The model is able to capture the mechanism of proppant bridging which occurs in sections of narrow fracture width, tip screen-out which occurs where fracture becomes saturated with proppant, and flushing of proppant into new fracture segments. The results are verified by comparing with characteristic solutions, and the model is used to simulate proppant transport through a KGD fracture.