Proving It – A Review of 80 Published Field Studies Demonstrating the Importance of Increased Fracture Conductivity

Vincent, Michael C.

doi:10.2118/77675-ms

Cited by 76 publications

(20 citation statements)

References 122 publications

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“…al. 1998;Wahl 1965;Vincent 2002) confirmed that hydraulic fractures provide a much larger surface to allow better communication from the formation to the wellbore.…”

Section: Introductionmentioning

confidence: 86%

Efficient Coiled-Tubing Fracturing for Proppant-Placement Assurance and Contingency-Cost Mitigation

Surjaatmadja

East

2012

All Days

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Combining production from multiple intervals within a well during completion has been used for many years. Many of these reservoirs required hydraulic-fracture stimulation, and a number of promising fracturing methods have been developed where several stages can be performed sequentially, provided there is some method used to isolate previously stimulated intervals.One method claims high efficiency by using high-rate treatments and limited-entry perforating concepts. However, the promises proved to be elusive. Contingencies for early screenout, perforating gun missfires, and other equipment failures have often dramatically impacted completion efficiency. To guard against these failures, the proppant schedules were underdesigned or purposely overflushed, thus reducing the resulting fracture conductivity.To achieve limited-entry diversion, high-treatment rates were used, which required a large amount of hydraulic horsepower onsite. Yet, even when efficiencies were achievable, production logging often showed that, at best, only 50% of the intended fracturing targets would actually produce at fracture-stimulated rates. Discovery of an important phenomenon was recently explained using computational fluid dynamics (CFD) simulation. It was found that the difference in the physical qualities of proppant and the carrying fluid cause the upper intervals to receive mostly proppant-free fluid.Pinpoint-stimulation fracturing methods can allow all of the multiple intervals completed to be stimulated efficiently, such that all intervals received the designed proppant volumes one interval at a time. For the most effective of these methods, coiled tubing (CT) is used to hydrajet perforate intervals for individual fracturing treatments, and proppant plugs are used to isolate stimulated intervals while maximizing near-wellbore (NWB) conductivity. These methods do not require removing the CT from the well between treatments, so early screenouts can be remediated immediately with minimal impact.A new entry in this class of fracturing that allows real-time, on-demand downhole proppant-schedule control can be combined with real-time fracture-mapping diagnostics to optimize stimulated reservoir volume (SRV) on-the-fly, when needed. A 15-stage completion in the Marcellus is used to demonstrate the process.

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“…al. 1998;Wahl 1965;Vincent 2002) confirmed that hydraulic fractures provide a much larger surface to allow better communication from the formation to the wellbore.…”

Section: Introductionmentioning

confidence: 86%

Efficient Coiled-Tubing Fracturing for Proppant-Placement Assurance and Contingency-Cost Mitigation

Surjaatmadja

East

2012

All Days

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“…However, the fractures tend to close after a hydraulic fracturing operation and thus suitable proppants have to be selected, blend in a certain ratio with the fracturing fluid, fill the fractures, and keep them open after fluid injection [2]. Therefore estimation of the residual openings [46,104,105] or the permeability of the fracture openings [106], which are filled with proppants, as well as the optimisation of the used proppants [107] is of great significance for EGR/EOR applications. A number of studies have focused on the transport of suspended proppant particles within the fracture and the interaction between the formation and the proppant.…”

Section: Developments On Modelling Of Hydraulic Fracturing and Enginementioning

confidence: 99%

Recent Developments in Multiscale and Multiphase Modelling of the Hydraulic Fracturing Process

Sheng

Sousani

Ingham

et al. 2015

Mathematical Problems in Engineering

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Recently hydraulic fracturing of rocks has received much attention not only for its economic importance but also for its potential environmental impact. The hydraulically fracturing technique has been widely used in the oil (EOR) and gas (EGR) industries, especially in the USA, to extract more oil/gas through the deep rock formations. Also there have been increasing interests in utilising the hydraulic fracturing technique in geological storage of CO 2 in recent years. In all cases, the design and implementation of the hydraulic fracturing process play a central role, highlighting the significance of research and development of this technique. However, the uncertainty behind the fracking mechanism has triggered public debates regarding the possible effect of this technique on human health and the environment. This has presented new challenges in the study of the hydraulic fracturing process. This paper describes the hydraulic fracturing mechanism and provides an overview of past and recent developments of the research performed towards better understandings of the hydraulic fracturing and its potential impacts, with particular emphasis on the development of modelling techniques and their implementation on the hydraulic fracturing.

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“…Although intuition often suggests that any fracture will provide infinite flow capacity compared to the formation, the immense surface area of propped fractures requires fluid to move hundreds of thousands, or even millions of times faster within the propped fractures than within the matrix (33) . Therefore, conductivity of proppant packs remains critical, both for cleanup of frac fluid and subsequent gas production (34,35) . More research and direct observations of proppant transport phenomena will hopefully shed more light on this important topic in the future.…”

Section: Conductivity and Proppant Transport In Light Sand Fracture Tmentioning

confidence: 99%

Stimulating Unconventional Reservoirs: Maximizing Network Growth While Optimizing Fracture Conductivity

Warpinski

Mayerhofer

Vincent

et al. 2009

Journal of Canadian Petroleum Technology

326

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Unconventional reservoirs such as gas shales and tight gas sands require technology-based solutions for optimum development. The successful exploitation of these reservoirs has relied on some combination of horizontal drilling, multi-stage completions, innovative fracturing and fracture mapping to engineer economic completions. However, the requirements for economic production all hinge on the matrix permeability of these reservoirs, supplemented by the conductivity that can be generated in hydraulic fractures and network fracture systems. Simulations demonstrate that ultra-low shale permeabilities require an interconnected fracture network of moderate conductivity with a relatively small spacing between fractures to obtain reasonable recovery factors. Microseismic mapping demonstrates that such networks are achievable and the subsequent production from these reservoirs supports both the modelling and the mapping. Tight gas sands, having orders of magnitude greater permeability than the gas shales, may be successfully depleted without inducing complex fracture networks, but other issues of damage and zonal coverage complicate recovery in these reservoirs. As with the shales, mapping has proved itself to be valuable in assessing the fracturing results. Introduction Unconventional reservoirs provide a significant fraction of gas production in North America and increasing amounts in some other regions of the world. Such reservoirs include tight gas sands, coalbed methane (CBM), and gas shales; in 2006 these reservoirs provided 43% of the US production of natural gas [Kuuskraa(1)]. Because of their limited permeability, which is foremost among many other complexities, some type of stimulation process (and/or dewatering in the case of CBM) is required to engender economic recovery from wells drilled into these formations. The focus of this paper is on gas shales, with particular emphasis on how these reservoirs perform relative to tight gas sands. The important role of natural fractures in both the stimulation and production processes, the importance of conductivity in the developed fracture or fracture system, and the critical influence of the matrix permeability are investigated using both mapping and modeling results.

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Proving It – A Review of 80 Published Field Studies Demonstrating the Importance of Increased Fracture Conductivity

Cited by 76 publications

References 122 publications

Efficient Coiled-Tubing Fracturing for Proppant-Placement Assurance and Contingency-Cost Mitigation

Efficient Coiled-Tubing Fracturing for Proppant-Placement Assurance and Contingency-Cost Mitigation

Recent Developments in Multiscale and Multiphase Modelling of the Hydraulic Fracturing Process

Stimulating Unconventional Reservoirs: Maximizing Network Growth While Optimizing Fracture Conductivity

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