2018
DOI: 10.2118/191132-pa
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Experimental Investigation of Propellant Fracturing in a Large Sandstone Block

Abstract: Summary Propellants have been used in oil and gas wells to assist with perforating and creating near-wellbore stimulation. Propellants are electrically ignited in the wellbore at the perforated interval. Upon ignition, they rapidly create a large amount of gas, and the pressurization leads to breakdown of the formation. It has been postulated that the pressurization leads to creation of multiple fractures in the formation. This paper describes an experimental study with a new propellant and aims… Show more

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Cited by 22 publications
(5 citation statements)
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“…Numerical modeling and simulation provide us an alternative to gauge the behavior of hydraulic fracture propagation in naturally fractured reservoir that cannot be substituted by small-scale laboratory experiment, where it is difficult to replicate in situ conditions with extremely high confining stress, in addition, the minimum stress tends to elevate (i.e., stress anisotropy can be much lower than designed or even disappear) during fracture propagation because of fixed displacement at the rock sample boundary (Malhotra et al 2018), and the boundary effect cannot be fully eliminated even one can maintain a constant far-field stress field during fracture propagation, and on top of that, the impact of flow-resistance-dependent fluid distribution is not able to fully manifest itself in small-scale experiment, thus, laboratory experiment has the tendency to create hydraulic fracture patterns that are more complex than what is happening in the subsurface (Law and Curtis 2002;Reinicke et al 2010).…”
Section: Introductionmentioning
confidence: 99%
“…Numerical modeling and simulation provide us an alternative to gauge the behavior of hydraulic fracture propagation in naturally fractured reservoir that cannot be substituted by small-scale laboratory experiment, where it is difficult to replicate in situ conditions with extremely high confining stress, in addition, the minimum stress tends to elevate (i.e., stress anisotropy can be much lower than designed or even disappear) during fracture propagation because of fixed displacement at the rock sample boundary (Malhotra et al 2018), and the boundary effect cannot be fully eliminated even one can maintain a constant far-field stress field during fracture propagation, and on top of that, the impact of flow-resistance-dependent fluid distribution is not able to fully manifest itself in small-scale experiment, thus, laboratory experiment has the tendency to create hydraulic fracture patterns that are more complex than what is happening in the subsurface (Law and Curtis 2002;Reinicke et al 2010).…”
Section: Introductionmentioning
confidence: 99%
“…Malhotra et al [20] experimentally investigated the crack growth and pattern of multiple fractures with the new explosive material used in a propellant-based technology. They compared their results with the previously published results by Wieland et al [34].…”
Section: Literature Reviewmentioning
confidence: 99%
“…The pulse fracturing treatment depends on many parameters such as rock strength, in situ stresses, pressurization rate, and technology in hand. Pulse fracturing is commonly known with other names such as dynamic fracturing, propellant gas fracturing, tailored pulse loading, dynamic impact loading fracturing, high energized gas fracturing (HEGF), and multiple radial stress fracturing [10][11][12][13][14][15][16][17][18][19][20]. In HEGF, the downhole combustion is initiated by both oxidizer and fuel to generate the sudden expansion of gas to quickly raise the pressure which results in synthetic sweet spot.…”
Section: Introductionmentioning
confidence: 99%
“…Another modern direction of processing the bottom-hole formation zone of a well with the aim of stimulation is the use of chemical energy sources to create both mechanical and thermal effects on the formation. The use of propellants (components of rocket fuels) [8], which are ignited in the bottom-hole zone of the well, can be quite promising. During combustion, a large number of gases are formed that break the formation.…”
Section: Literature Review and Problem Statementmentioning
confidence: 99%