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Stimulation rationale for shale gas wells [electronic resource] : a state-of-the-art report.

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Bibliographic Details
Online Access: Online Access
Corporate Author: National Energy Technology Laboratory (U.S.) (Researcher)
Format: Government Document Electronic eBook
Language:English
Published: Morgantown, W.Va. : Oak Ridge, Tenn. : National Energy Technology Laboratory (U.S.) ; distributed by the Office of Scientific and Technical Information, U.S. Dept. of Energy, 1980.
Subjects:
Recovery.
Geologic Formations.
Natural Gas.
Enhanced Recovery.
Fracturing.
Fracturing Fluids.
Document Types.
Wells.
Gas Fuels.
Explosive Fracturing.
Recommendations.
Fuel Gas.
Fuels.
Fluids.
Devonian Period.
Natural Gas Wells.
Hydraulic Fracturing.
Well Stimulation.
Technology Assessment.
Oil Shales.
Energy Sources.
Gases.
Materials.
Bituminous Materials.
Comminution.
Chattanooga Formation.
Carbonaceous Materials.
Black Shales.
Fossil Fuels.
Stimulation.
Paleozoic Era.
Geologic Ages.
Reviews.
Propping Agents.
Description
Abstract:Despite the large quantities of gas contained in the Devonian Shales, only a small percentage can be produced commercially by current production methods. This limited production derives both from the unique reservoir properties of the Devonian Shales and the lack of stimulation technologies specifically designed for a shale reservoir. Since October 1978 Science Applications, Inc. has been conducting a review and evaluation of various shale well stimulation techniques with the objective of defining a rationale for selecting certain treatments given certain reservoir conditions. Although this review and evaluation is ongoing and much more data will be required before a definitive rationale can be presented, the studies to date do allow for many preliminary observations and recommendations. For the hydraulic type treatments the use of low-residual-fluid treatments is highly recommended. The excellent shale well production which is frequently observed with only moderate wellbore enlargement treatments indicates that attempts to extend fractures to greater distances with massive hydraulic treatments are not warranted. Immediate research efforts should be concentrated upon limiting production damage by fracturing fluids retained in the formation, and upon improving proppant transport and placement so as to maximize fracture conductivity. Recent laboratory, numerical modeling and field studies all indicate that the gas fracturing effects of explosive/propellant type treatments are the predominate production enhancement mechanism and that these effects can be controlled and optimized with properly designed charges. Future research efforts should be focused upon the understanding, prediction and control of wellbore fracturing with tailored-pulse-loading charges. 36 references, 7 figures, 2 tables.
Item Description:Published through SciTech Connect.
12/01/1980.
"doe/mc/08216-1336"
"DE84003094"
Young, C.; Barbour, T.; Blanton, T.L.
Science Applications, Inc., Steamboat Springs, CO (USA)
Physical Description:Pages: 43 : digital, PDF file.

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