Gas Shales Testing in Controlled Partially Saturated Conditions

Laboratory measurement of mechanical properties of gas shales represents a challenging topic in geomechanics due to their peculiar features such as heterogeneity, anisotropy, low permeability, and complex physical phenomena related to the hydro-mechanical coupling. Since these geomaterials are partially water saturated in their native state and in-situ changes in water saturation can occur due to drilling and fracturing procedures, the role of partial saturation has to be considered for the experimental assessment of their geomechanical parameters. The paper provides quantitative experimental data that demonstrate the impact of changing partial water saturation on the static elastic and strength (UCS) properties of gas shales from two different unconventional plays. To achieve this goal, a testing set-up and experimental methodology based on the control of total suction were specifically developed. Two core samples from different unconventional shale gas reservoirs were tested. The obtained results clearly show a significant dependence of the Young’s modulus on total suction, where a non-linear decrease of stiffness higher than 50% can be observed when suction is reduced during a wetting process. On the other hand, the Poisson’s ratio is not highly influenced by different saturation states; it can be considered constant for suction values greater than 10 MPa. A significant impact on the uniaxial compressive strength was also observed, where a 20% decrease of this strength parameter was measured when gas shales are conditioned to lower suction value. To include the observed behavior of gas shales in elastic constitutive model, an empirical relationship to express the dependence of Young’s modulus on suction is proposed. Besides a better understanding of the behavior of gas shales during the drilling procedures and hydraulic fracturing phase, the findings of this study are also of great relevance to understand the impact that exposure of core samples to non-controlled air humidity may have on the results of laboratory tests.

The impact of the volumetric swelling behavior on the water uptake of gas shale

Alessio Ferrari, Lyesse Laloui, Alberto Minardi

Water uptake of gas shales is commonly considered one of the most important factors responsible for fluid loss during flowback operations after hydraulic fracturing. Imbibition experiments cover a key role in this context to analyze the impact of several factors (such as mineralogical composition, fluids composition, anisotropic structure, volumetric swelling) that contribute to the water uptake in these unconventional reservoirs. The aim of this study is the quantification of the impact of the volumetric response (swelling and shrinkage) of gas shales on the water uptake during imbibition and desiccation processes. An experimental methodology to quantify the volumetric response during the imbibition process in both free and under-stress conditions is developed. Results from experiments performed through both vapour diffusion and direct flooding with deionized water on three gas shale core samples extracted from different plays are provided. Obtained results clearly highlight the mutual influence between the volumetric response and the water uptake. Significant swelling and shrinkage response are observed during imbibition and desiccation processes, respectively. Specimens tested in free stress conditions exhibited a response much more pronounced than specimens tested under stress. These features provide a clear evidence of the overestimation of the imbibed water volume (higher than 40%) that can be obtained when the volumetric response is not properly considered; these aspects lead to a following impact on the upscaling of the experimental data to estimate fluid loss at field scale. Finally, it is shown that the volumetric behavior of gas shales during the imbibition process is highly anisotropic; this aspect can be related to the smectite content (or CEC) of the material and it can be considered to play a key role on the dependency of the imbibition rates and imbibed water volume on the direction of the lamination planes.

2018

Hydro-mechanical characterization of gas shales and Opalinus Clay shale in partially saturated conditions

Alberto Minardi

An experimental study on the behaviour of shales in partially water saturated conditions is presented in this thesis. The Opalinus Clay shale and gas shales from different unconventional reservoirs have been studied. Opalinus Clay is currently considered as a host rock for the disposal of radioactive waste in Switzerland; the importance of partial saturation is fundamental in predicting the short-term behaviour of the host rock during the excavation-resaturation phases, and the long-term behaviour during the propagation of gas generated by the waste. Shale gas reservoirs are partially saturated in their in-situ state due to the simultaneous presence of gas and liquids; these hydraulic conditions influence the mechanical behaviour during the drilling, fracturing, and extraction stages. The analysis of the geomaterials' behaviour considering partial saturation is a well-established practice in Soil Mechanics. However, in the case of shales several challenges arise. These challenges are mainly related to their features, which make most of the experimental and theoretical frameworks adopted for soils not suitable for providing a comprehensive understanding of the behaviour of shales. The aim of this thesis is to improve upon the existing understanding of the behaviour of partially saturated gas shales and the Opalinus Clay shale and to provide a quantitative assessment of the impact of such conditions on their mechanical behaviour. A key part of this work is dedicated to the establishment of experimental methodologies and testing protocols to highlight the most important features of the response of the tested materials under partially saturated conditions. The high water retention capacity of shales necessitates the use of the vapour equilibrium technique; this experimental technique allows for the imposition of wetting/drying processes on the tested materials and introduces suction as a key parameter when performing the hydro-mechanical characterization in partially saturated conditions. Three different testing set-ups have been developed to investigate the hydro-mechanical response of the tested shales. The obtained experimental results demonstrate that the considering of partial saturation is fundamental for a reliable and comprehensive hydro-mechanical characterization of the tested shales; despite the different origins of these materials, the main outcomes show a very similar impact of wetting and drying processes on the volumetric response and the mechanical properties. The volumetric response observed in the tests performed in free stress conditions is characterized by significant anisotropy and irreversibility. However, when a mechanical stress is applied to simulate in-situ conditions, a less pronounced volumetric response is systematically observed. The elastic response is also highly dependent on the hydraulic state of the tested materials; in particular, significant reductions (up to 50%) of Young's modulus and compressive strength are observed during wetting processes. Gas injection is also studied in the Opalinus Clay to better understand the dominant flow mechanisms and to assess the possible impact of partial saturation on the movement of gas in the host rock. Experimental results obtained with a testing device specifically developed for this purpose indicate the impact of gas injection on the deformation state of the material; this aspect clearly highlights the involved hydro-mechanical coupling.

EPFL2018

The impact of the volumetric swelling behavior on the water uptake of gas shale

Alessio Ferrari, Lyesse Laloui, Alberto Minardi

2018

Hydro-mechanical characterization of gas shales and Opalinus Clay shale in partially saturated conditions

Alberto Minardi

EPFL2018