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PRCI PR-15-414
- Well Casing Response to Buried Explosive Detonations
- Report / Survey by Pipeline Research Council International, 07/01/1985
- Publisher: PRCI
$448.00$895.00
L51482e
Southwest Research Institute
July 1985 2-volumes Consolitdated into 1-Volume on Dec. 1999 Reprint.
Need: Occasionally, buried explosives are used within proximity of producing oil & gas wells which increases the stresses in the casing near the explosion which may result in failure of the well. A procedure was needed for predicting the maximum stresses in producing oil & gas wells, specifically the well casing, induced by nearby, buried, explosive detonations.
Result: An extensive experimental and analytical program were funded and performed by the Southwest Research Institute over a six (6) year period 1975-1981. The program was divided into two (2) parts: In the first part, similitude theory, empirical analyses and test data were used to derive equations for estimating maximum ground displacement and particle velocity. The ground motions provided the forcing function imparted to a buried pipeline. In the second part, similitude theory, conservation of mass and momentum, and approximate energy methods were used to derive functional relationships for the maximum pipe strains and stresses. Experimental data from more than sixty (60) field tests ere used to develop equations for estimating maximum pipe stresses induced by point and parallel line explosive sources buried in homogeneous soil media. The pipe stress and ground motion data from these experiments were used to develop an equation for computing an effective standoff distance so that the point source soil equations could be used to approximate the casing response. The large amount of data used and the wide range of these data make the solutions applicable to most blasting situations near producing oil & gas wells.
Benefit: This report provides comprehensive and detailed information for pipeline as well as oil & gas operators to predict the effect of buried explosives and thus the safety of a well(s) while in-service through proper assessment of stresses and guidelines for the appropriate selection of explosive charges, techniques and methods. This will avoid unexpected damages, operational costs, provide guidance for "operator qualification" for blasting near in-service wells and minimize liabilities to the operator. This study has been used by Pipeline Research Council International, Inc. (PRCI) member companies to generate company standards and procedures related to in-service blasting nearby producing oil & gas wells.
Southwest Research Institute
July 1985 2-volumes Consolitdated into 1-Volume on Dec. 1999 Reprint.
Need: Occasionally, buried explosives are used within proximity of producing oil & gas wells which increases the stresses in the casing near the explosion which may result in failure of the well. A procedure was needed for predicting the maximum stresses in producing oil & gas wells, specifically the well casing, induced by nearby, buried, explosive detonations.
Result: An extensive experimental and analytical program were funded and performed by the Southwest Research Institute over a six (6) year period 1975-1981. The program was divided into two (2) parts: In the first part, similitude theory, empirical analyses and test data were used to derive equations for estimating maximum ground displacement and particle velocity. The ground motions provided the forcing function imparted to a buried pipeline. In the second part, similitude theory, conservation of mass and momentum, and approximate energy methods were used to derive functional relationships for the maximum pipe strains and stresses. Experimental data from more than sixty (60) field tests ere used to develop equations for estimating maximum pipe stresses induced by point and parallel line explosive sources buried in homogeneous soil media. The pipe stress and ground motion data from these experiments were used to develop an equation for computing an effective standoff distance so that the point source soil equations could be used to approximate the casing response. The large amount of data used and the wide range of these data make the solutions applicable to most blasting situations near producing oil & gas wells.
Benefit: This report provides comprehensive and detailed information for pipeline as well as oil & gas operators to predict the effect of buried explosives and thus the safety of a well(s) while in-service through proper assessment of stresses and guidelines for the appropriate selection of explosive charges, techniques and methods. This will avoid unexpected damages, operational costs, provide guidance for "operator qualification" for blasting near in-service wells and minimize liabilities to the operator. This study has been used by Pipeline Research Council International, Inc. (PRCI) member companies to generate company standards and procedures related to in-service blasting nearby producing oil & gas wells.