Design and Appraisal of Hydraulic Fractures PDF Download

Author: Jack R. Jones
Publisher:
ISBN: 9781613993163
Category :
Languages : en
Pages :

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Book Description
Using an interdisciplinary approach, Design and Appraisal of Hydraulic Fractures offers a basic yet comprehensive introduction to the completion and reservoir engineering aspects of hydraulic fracture stimulation. The book is divided into three sections. Section 1 covers the design and placement of a hydraulic fracture stimulation; topics include the basics of the hydraulic fracturing process, stress issues, fracture geometry, controls on generated length and width, fluid and proppant selection, quality control, and quality assurance. Section 2 introduces the use of dynamic data to characteriz.

Author: Hoss Belyadi
Publisher: Gulf Professional Publishing
ISBN: 0128176660
Category : Technology & Engineering
Languages : en
Pages : 632

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Book Description
Hydraulic Fracturing in Unconventional Reservoirs: Theories, Operations, and Economic Analysis, Second Edition, presents the latest operations and applications in all facets of fracturing. Enhanced to include today’s newest technologies, such as machine learning and the monitoring of field performance using pressure and rate transient analysis, this reference gives engineers the full spectrum of information needed to run unconventional field developments. Covering key aspects, including fracture clean-up, expanded material on refracturing, and a discussion on economic analysis in unconventional reservoirs, this book keeps today's petroleum engineers updated on the critical aspects of unconventional activity. Helps readers understand drilling and production technology and operations in shale gas through real-field examples Covers various topics on fractured wells and the exploitation of unconventional hydrocarbons in one complete reference Presents the latest operations and applications in all facets of fracturing

Author: J. L. Miskimins
Publisher: Elsevier Science
ISBN: 9780444517791
Category : Science
Languages : en
Pages :

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Book Description
The Theory and Application of Hydraulic Fracturing provides an examination of classical fracturing theory as it applies to subsurface formations that produce oil and gas. The book progresses from the early chapters which discuss such items as pre-treatment evaluation and characterization of the reservoir to the selection of appropriate fluids and proppants and concludes with design and post-treatment analysis. Theory is presented so that a novice, who knows little to nothing about hydraulic fracturing, can comprehend the subject. However, the book also addresses the topics in such a way that a practicing professional who designs hydraulic fracture treatments on a daily basis will find the book a critical addition to his desktop. Applied theory is an important concept to the authors. The authors take a unique approach by providing not only classical hydraulic fracturing theory but also an analysis at the end of each chapter which discusses the fallacies associated with the standard understanding of the chapter topic. Anyone who is involved in the practice of hydraulic fracturing realizes that there are many issues and problems with hydraulic fracturing that the industry has yet to fully understand. This book seeks to span that gap and prepare the reader for overcoming these obstacles.

Author: Ahmed Alzahabi
Publisher: CRC Press
ISBN: 1351618229
Category : Technology & Engineering
Languages : en
Pages : 288

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Book Description
Shale gas and/or oil play identification is subject to many screening processes for characteristics such as porosity, permeability, and brittleness. Evaluating shale gas and/or oil reservoirs and identifying potential sweet spots (portions of the reservoir rock that have high-quality kerogen content and brittle rock) requires taking into consideration multiple rock, reservoir, and geological parameters that govern production. The early determination of sweet spots for well site selection and fracturing in shale reservoirs is a challenge for many operators. With this limitation in mind, Optimization of Hydraulic Fracture Stages and Sequencing in Unconventional Formations develops an approach to improve the industry’s ability to evaluate shale gas and oil plays and is structured to lead the reader from general shale oil and gas characteristics to detailed sweet-spot classifications. The approach uses a new candidate selection and evaluation algorithm and screening criteria based on key geomechanical, petrophysical, and geochemical parameters and indices to obtain results consistent with existing shale plays and gain insights on the best development strategies going forward. The work introduces new criteria that accurately guide the development process in unconventional reservoirs in addition to reducing uncertainty and cost.

Author: Ralph W. Veatch
Publisher: Pennwell Books
ISBN: 9781593703578
Category : Hydraulic fracturing
Languages : en
Pages : 0

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Book Description
Hydraulic fracturing was first developed in the United States during the 1940s and has since spread internationally. A proven technology that is reaching deeper and tighter formations, hydraulic fracturing now delivers hydrocarbons from fields previously considered economically unviable. Essentials of Hydraulic Fracturing focuses on consolidating the fundamental basics of fracturing technology with advances in extended horizontal wellbores and fracturing applications. It provides the essentials required to understand fracturing behavior and offers advice for applying that knowledge to fracturing treatment design and application. Essentials of Hydraulic Fracturingis a long-awaited text for petroleum engineering students, industry-wide hydraulic fracturing training courses or seminars, and practicing fracturing treatment engineers. Features include: Understanding of fracture propagation geometry and fracture conductivity and how it affects treatment results A focus on safety and environmental prudence Economic optimization of fracturing treatments Fracturing fluid system and propping agent performance Important considerations in designing the fracture treatment for both vertical and horizontal wellbores Algorithms and examples pertinent to treatment design and analysis Pre- and post-fracturing approaches and diagnostics for evaluating treatment performance Hydraulic fracturing model construction and applicability Comparative design examples Construction of spreadsheet calculations key to treatment designs

Author: Jennifer L. Miskimins
Publisher: Newnes
ISBN: 9780080930909
Category : Science
Languages : en
Pages : 0

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Book Description
The Theory and Application of Hydraulic Fracturing provides an examination of classical fracturing theory as it applies to subsurface formations that produce oil and gas. The book progresses from the early chapters which discuss such items as pre-treatment evaluation and characterization of the reservoir to the selection of appropriate fluids and proppants and concludes with design and post-treatment analysis. Theory is presented so that a novice, who knows little to nothing about hydraulic fracturing, can comprehend the subject. However, the book also addresses the topics in such a way that a practicing professional who designs hydraulic fracture treatments on a daily basis will find the book a critical addition to his desktop. Applied theory is an important concept to the authors. The authors take a unique approach by providing not only classical hydraulic fracturing theory but also an analysis at the end of each chapter which discusses the fallacies associated with the standard understanding of the chapter topic. Anyone who is involved in the practice of hydraulic fracturing realizes that there are many issues and problems with hydraulic fracturing that the industry has yet to fully understand. This book seeks to span that gap and prepare the reader for overcoming these obstacles.

Author: Jaber Taheri-Shakib
Publisher:
ISBN:
Category : Technology
Languages : en
Pages :

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Book Description
The behavior of natural fractures at the hydraulic fracturing (HF) treatment is one of the most important considerations in increasing the production from this kind of reservoirs. Therefore, considering the interaction between the natural fractures and hydraulic fractures can have great impact on the analysis and design of fracturing process. Due to the existence of such natural fractures, the perturbation stress regime around the tip of hydraulic fracture leads to some deviation in the propagation of path of hydraulic fracture. Increasing the ratio of transverse stress to the interaction stress results in a reduction in the deviation of hydraulic fracturing propagation trajectory in the vicinity of natural fracture. In this study, we modeled a hydraulic fracture with the extended finite element method (XFEM) using a cohesive-zone technique. The XFEM is used to discrete the equations, allowing for the simulation of induced fracture propagation; no re-meshing of domain is required to model the interaction between hydraulic and natural fractures. XFEM results reveal that the distance and angle of natural fracture with respect to the hydraulic fracture have a direct impact on the magnitude of tensile and shear debonding. The possibility of intersection of natural fracture by the hydraulic fracture will increase with increasing the deviation angle value. At the approaching stage of hydraulic fracture to the natural fracture, hydraulic fracture tip exerts remote compressional and tensile stress on the interface of the natural fracture, which leads to the activation and separation of natural fracture walls.

Author: Michael Berry Smith
Publisher: CRC Press
ISBN: 1466566922
Category : Science
Languages : en
Pages : 793

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Book Description
Hydraulic Fracturing effectively busts the myths associated with hydraulic fracturing. It explains how to properly engineer and optimize a hydraulically fractured well by selecting the right materials, evaluating the economic benefits of the project, and ensuring the safety and success of the people, environment, and equipment. From data estimation

Author: Ana Karen Ortega Perez
Publisher:
ISBN:
Category : Fiber optic cables
Languages : en
Pages : 0

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Book Description
Well-monitoring before, during, and after hydraulic fracturing treatment is essential to accomplish a successful fracture completion program. By knowing the geometry, orientation, and propagation of the hydraulic fractures, we can identify potential completion issues during fracturing operations and help in the design of more efficient unconventional reservoir completions. Distributed Acoustic Sensing (DAS) is an emerging technology in hydraulic fracture monitoring that enables continuous, real-time measurements along the entire length of a fiber optic cable. The low-frequency band of DAS records strain perturbations of the medium, due to fracture propagation, which provides critical constraints on hydraulic fracture geometry. In this study, the low-frequency DAS strain fronts was analyzed, with their corresponding pumping curves, for one hydraulic fracturing treatment to obtain information on the hydraulic fractures like fracture azimuth, propagation speed, number of fractures created during each stage and re-stimulation of pre-existent fractures. Then, the microseismicity of the treatment was analyzed to obtain information on hydraulic fractures like length, height, trajectory and cloud growth over time. The microseismicity was also projected onto the strain fronts to study the development of the events with respect to the fracture signal and to find correlations between the strain changes and the microseismic events. Finally, the PKN model was computed using parameters from the stimulation treatment and the DAS strain fronts to forecast anticipated fracture lengths against observations. The PKN modeling results were compared to the microseismic and DAS results to find stages where the hydraulic fractures did not grow or propagate as expected. The low-frequency DAS is able to obtain information on hydraulic fractures that would need extra processing or might not be picked up using other records as microseismicity. However, the spatial constraint of the measurements in DAS needs to be taken into consideration. This spatial constraint can be addressed by the integration of other records. In general, there is good agreement between the LF DAS data, the pumping information, the microseismic data and the PKN model. But when they do not agree on a stage, that gives us an indication that something unexpected happened during injection. Models describing the expected behavior of the different records analyzed in this research were created to explain some possible scenarios of fracture propagation. Most stages in this treatment fall within one of these models.

Author: Arash Dahi Taleghani
Publisher:
ISBN:
Category : Gas reservoirs
Languages : en
Pages : 0

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Book Description
Large volumes of natural gas exist in tight fissured reservoirs. Hydraulic fracturing is one of the main stimulating techniques to enhance recovery from these fractured reservoirs. Although hydraulic fracturing has been used for decades for the stimulation of tight gas reservoirs, a thorough understanding of the interaction between induced hydraulic fractures and natural fractures is still lacking. Recent examples of hydraulic fracture diagnostic data suggest complex, multi-stranded hydraulic fracture geometry is a common occurrence. The interaction between pre-existing natural fractures and the advancing hydraulic fracture is a key condition leading to complex fracture patterns. Large populations of natural fractures that exist in formations such as the Barnett shale are sealed by precipitated cements which could be quartz, calcite, etc. Even though there is no porosity in the sealed fractures, they may still serve as weak paths for fracture initiation and/or for diverting the path of the growing hydraulic fractures. Performing hydraulic fracture design calculations under these complex conditions requires modeling of fracture intersections and tracking fluid fronts in the network of reactivated fissures. In this dissertation, the effect of the cohesiveness of the sealed natural fractures and the intact rock toughness in hydraulic fracturing are studied. Accordingly, the role of the pre-existing fracture geometry is also investigated. The results provide some explanations for significant differences in hydraulic fracturing in naturally fractured reservoirs from non-fractured reservoirs. For the purpose of this research, an extended finite element method (XFEM) code is developed to simulate fracture propagation, initiation and intersection. The motivation behind applying XFEM are the desire to avoid remeshing in each step of the fracture propagation, being able to consider arbitrary varying geometry of natural fractures and the insensitivity of fracture propagation to mesh geometry. New modifications are introduced into XFEM to improve stress intensity factor calculations, including fracture intersection criteria into the model and improving accuracy of the solution in near crack tip regions. The presented coupled fluid flow-fracture mechanics simulations extend available modeling efforts and provide a unified framework for evaluating fracture design parameters and their consequences. Results demonstrate that fracture pattern complexity is strongly controlled by the magnitude of in situ stress anisotropy, the rock toughness, the natural fracture cement strength, and the approach angle of the hydraulic fracture to the natural fracture. Previous studies (mostly based on frictional fault stability analysis) have concentrated on predicting the onset of natural fracture failure. However, the use of fracture mechanics and XFEM makes it possible to evaluate the progression of fracture growth over time as fluid is diverted into the natural fractures. Analysis shows that the growing hydraulic fracture may exert enough tensile and/or shear stresses on cemented natural fractures that they may be opened or slip in advance of hydraulic fracture tip arrival, while under some conditions, natural fractures will be unaffected by the hydraulic fracture. A threshold is defined for the fracture energy of cements where, for cases below this threshold, hydraulic fractures divert into the natural fractures. The value of this threshold is calculated for different fracture set orientations. Finally, detailed pressure profile and aperture distributions at the intersection between fracture segments show the potential for difficulty in proppant transport under complex fracture propagation conditions. Whether a hydraulic fracture crosses or is arrested by a pre-existing natural fracture is controlled by shear strength and potential slippage at the fracture intersections, as well as potential debonding of sealed cracks in the near-tip region of a propagating hydraulic fracture. We introduce a new more general criterion for fracture propagation at the intersections. We present a complex hydraulic fracture pattern propagation model based on the Extended Finite Element Method as a design tool that can be used to optimize treatment parameters under complex propagation conditions.