Evaluation of water saturation effect on mechanical properties and hydraulic fracturing behavior of granite

Hydraulic fracturing is a combined process of mechanical and hydraulic behavior due to in situ stress, well bore pressure, fluid infiltration in the rock mass. The initial state of surrounding well bore prior to hydraulic fracturing can be subject to either dry or saturated condition. We investigate...

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Bibliographic Details
Published in:International journal of rock mechanics and mining sciences (Oxford, England : 1997) England : 1997), 2020-06, Vol.130, p.104321, Article 104321
Main Authors: Zhuang, Li, Kim, Kwang Yeom, Diaz, Melvin, Yeom, Sun
Format: Article
Language:English
Subjects:
Acoustic emission
AE monitoring
Compressive strength
Computed tomography
Crack initiation
Elastic and strength anisotropy
Emission analysis
Environmental monitoring
Fluid infiltration
Fracture propagation
Fracture toughness
Granite
Hydraulic fracturing
Mechanical properties
Microcracks
Modulus of elasticity
P waves
Poisson's ratio
S waves
Saturation
Tensile strength
Velocity
Water saturation effect
Wave velocity
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Summary:Hydraulic fracturing is a combined process of mechanical and hydraulic behavior due to in situ stress, well bore pressure, fluid infiltration in the rock mass. The initial state of surrounding well bore prior to hydraulic fracturing can be subject to either dry or saturated condition. We investigated various mechanical properties and hydraulic fracturing behavior of dry and saturated granite specimens containing pre-existing microcracks. After saturation, P-wave velocity increased by 27%–33% and S-wave velocity increased by 13%–15%. Saturation weakened the material, with a 3%–6% decrease in uniaxial compressive strength, a 3%–9% decrease in Brazilian tensile strength, and 5%–6% decrease in mode-I fracture toughness, but the elastic modulus and Poisson’s ratio varied little. The tensile strength estimated from hydraulic fracturing tests on cylinders, showed a negligible decrease (2%–3%) in saturated specimens compared with initially dry specimens. However, acoustic emission (AE) monitoring analysis results show that water saturation influence hydraulic fracturing initiation and propagation. When comparing the initially saturated specimens to the dry specimens, higher AE hit rates were observed right before and at the breakdown, and the percent of tension correlated AE hit was slightly lower. Moreover, computed tomography observations show that fractures tend to propagate in a wider area in the saturated specimens.
ISSN:1365-1609
1873-4545
DOI:10.1016/j.ijrmms.2020.104321