Application of Flow-Thru Composite Frac Plugs in Tight-Gas Sand Completions

Eberhard, Mike; Meijs, Raymund; Johnson, J. B.

doi:10.2118/84328-ms

Cited by 20 publications

(7 citation statements)

References 9 publications

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“…A modification to the CBP design (specifically for fracturing applications) to allow for upward flow, but sealed from downward flow. This flow-through composite fracture plug (FTCFP) design [12][13] can allow all treated zones to flow back even before removal of the plug. There are several designs of the FTCFP on the market offering three major "check valve" designs.…”

Section: Description Of Msf Methodsmentioning

confidence: 99%

“…1. 13 Before the new CBP and FTCBP designs were available, some of the primary risk factors with BP use were:…”

Section: Description Of Msf Methodsmentioning

confidence: 99%

“…This technology was then taken to the next step by including a ball and seat flow-through composite BP providing downward sealing but instant flow-back without first drilling out the BP. [12][13] The petroleum industry continues to search for methods to reduce the number of well interventions without sacrificing stimulation efficiencies. Both of the most recently developed approaches involve a major alteration in the method that perforating is achieved.…”

Section: Introductionmentioning

confidence: 99%

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Review of Current Fracture Stimulation Techniques for Best Economics in Multilayer, Lower-Permeability Reservoirs

McDaniel

2005

SPE Eastern Regional Meeting

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TX 75083-3836, U.S.A., fax 01-972-952-9435. AbstractCurrently, thousands of wells are being drilled every year in low-to moderate-permeability sandstone and carbonate reservoirs that have many distinct zones or layers that can contribute to production if adequately stimulated. In lowerpermeability reservoirs, and especially for CBM completions, well economics will limit how much can be spent on the stimulation portion of a completion program. Operators may have to execute a "balancing act" with the need to maximize return on investment (ROI) while trying to complete as many contributing zones as possible. This usually drives a well operator toward methods that can minimize the number of separate well interventions while maximizing the number of zones that can be effectively stimulated.This paper provides a State of the Art review on both old and newer completion/stimulation techniques that can help an operator accomplish production goals. When the fracturing treatments are pumped down the casing, different methods applied can vary from simple, single-stage fracturing treatments using "limited entry" perforating to multi-stage fracture treatments with bridge plugs (BP) or ball/baffle stage isolation. Additionally, there are various other techniques incorporating conventional tubing strings with or without packers or BP's, and even various methods for coiled-tubing (CT)-deployed treatments.A "scorecard" approach presented here may offer operators an improved understanding of when a certain completion method is appropriate or flawed, based on the operators' current understanding of specific reservoir characteristics of their field or well. Too often, a multilayer completion technique has been applied to several wells and later found to be a poor choice. The wrong choice may have been made because of a limited understanding of the completion method, or even of the reservoir itself. Often, an operator understands the variances of the reservoir, but does not realize the limitations that these variances should bring to the process of choosing the optimal simulation/completion method. In some cases, the choice has simply been made to take the low-cost completion/stimulation approach, and the resulting well(s) did not produce at (or sustain) economic levels.

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Section: Description Of Msf Methodsmentioning

confidence: 99%

“…1. 13 Before the new CBP and FTCBP designs were available, some of the primary risk factors with BP use were:…”

Section: Description Of Msf Methodsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Review of Current Fracture Stimulation Techniques for Best Economics in Multilayer, Lower-Permeability Reservoirs

McDaniel

2005

SPE Eastern Regional Meeting

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“…Hydraulic fracturing is required to sustain commercial production in these low permeability reservoirs and wells in the Lance are stimulated in multiple fracture stages [6][7][8][9][10] . Each fracture stage may target three to six sand bodies with eight to twelve stages per well.…”

Section: Jonah Field Jonah Fieldmentioning

confidence: 99%

Hydraulic Fracture Diagnostics Used To Optimize Development in the Jonah Field

Wolhart¹,

Harting

Dahlem

et al. 2006

Proceedings of SPE Annual Technical Conference and Exhibition

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TX 75083-3836, U.S.A., fax 01-972-952-9435. AbstractThis paper reports on a study conducted to assist with field development in the Jonah Field in Wyoming. Microseismic and surface tiltmeter fracture mapping was performed on ten wells in two areas of the field and over 100 fracture treatments were mapped. The fracture mapping study was performed as part of a pilot project to evaluate ten-acre well spacing.The Jonah Field is located in the Green River Basin in Sublette County, WY. Production is primarily from overpressured and tight sandstones of the Lance Formation. The Lance in Jonah consists of many stacked low permeability sandstones. Due to the low permeability, stimulation is required for economical production rates. Gross pay intervals vary from 2,800 ft to 3,600 ft and wells are stimulated in multiple fracture stages. Each fracture stage may target three to six sands with eight to twelve total stages for each well.The study shows mapping results for fracture treatments in both mapping areas. Fracture length was longer than expected and varied somewhat by stage. Some stages were contained but for many stages there was significant height growth and treatment overlap. Fracture complexity was observed which could be due to natural fracturing, faulting, depositional heterogeneity and depletion.These fracture mapping results are being combined with geologic, geophysical and engineering data from the field to assist with field development. This paper details the results of the mapping and discusses issues with well placement, stimulation design and treatment staging identified by the study.

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“…As with any adaptation from one application to another, there were equipment and operational modifications required to produce the desired results for the horizontal application. 1,2 …”

Section: Introductionmentioning

confidence: 99%

Using Open Hole Horizontal Completion Technology to More Efficiently Complete Vertical Wells

Seale

Athans

2007

Proceedings of Rocky Mountain Oil &Amp; Gas Technology Symposium

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fax 01-972-952-9435. AbstractHorizontal completion technology has progressed dramatically over the last six years, with the latest technical barriers being eclipsed with open hole technology. These completions have allowed multiple zones to be fractured while mechanically isolating each zone. The efficiencies and benefits of utilizing open hole horizontal completion technology has been well documented. From the enhanced production witnessed using open hole completion with mechanical isolation, to the operational benefits of multiple fracturing operations being pumped in one continuous operation equating to time savings, more efficient fracs, faster cleanup and less safety hazards. Conventional methods of cementing a liner in place, perforating, fracturing and repeating the process for the number of stages required can be very time consuming with the added expense of removing the frac plugs with coiled tubing (CT) after the operations have been completed.The enabling technology that has been used successfully over the last six years for multi-stage fracturing in open hole horizontal wells has been successfully applied to vertical wells. This paper will detail the benefits of using open hole multi-stage fracturing technology with mechanical isolation in vertical wells. In some aspects this may seem a simple transition, however, there are many operational considerations that must be evaluated in many vertical applications that might otherwise not be factored into a horizontal completion. These operational considerations will be thoroughly outlined, including case histories where this technology has been successfully applied.

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Application of Flow-Thru Composite Frac Plugs in Tight-Gas Sand Completions

Cited by 20 publications

References 9 publications

Review of Current Fracture Stimulation Techniques for Best Economics in Multilayer, Lower-Permeability Reservoirs

Review of Current Fracture Stimulation Techniques for Best Economics in Multilayer, Lower-Permeability Reservoirs

Hydraulic Fracture Diagnostics Used To Optimize Development in the Jonah Field

Using Open Hole Horizontal Completion Technology to More Efficiently Complete Vertical Wells

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