Swelling and Fluid Transport of Re-sealed Callovo–Oxfordian Claystone

Swelling and Fluid Transport of Re-sealed Callovo–Oxfordian Claystone

Several experimental methods are used to investigate the swelling capacity and transport properties of re-sealed macro-cracked Callovo–Oxfordian (COx) claystone, particularly in the absence of confining pressure. Six COx claystone samples from four different geological locations of the Bure basin (F...

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Bibliographic Details
Published in:Rock mechanics and rock engineering Vol. 55; no. 3; pp. 1143 - 1158
Main Authors: Wang, Chuanrui, Talandier, Jean, Skoczylas, Frédéric
Format: Journal Article
Language:English
Published: Vienna Springer Vienna 01-03-2022
Springer Nature B.V
Springer Verlag
Subjects:
Capacity
Capillary pressure
Civil Engineering
Correlation
Earth and Environmental Science
Earth Sciences
Engineering Sciences
Equivalence
Experimental methods
Fractures
Gas flow
Geophysics/Geodesy
Illite
Illites
Kinetics
Mechanics
Nitrogen
Original Paper
Permeability
Pressure
Properties
Sealing
Smectites
Swelling pressure
Transport
Transport properties
Water
Water injection
X-ray diffraction
Swelling
Claystone
Sealing
Water and gas permeability
X-ray diffraction analysis
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Summary:Several experimental methods are used to investigate the swelling capacity and transport properties of re-sealed macro-cracked Callovo–Oxfordian (COx) claystone, particularly in the absence of confining pressure. Six COx claystone samples from four different geological locations of the Bure basin (France) are tested, five of which are macro-cracked and one remains intact. Sample swelling occurs, during re-hydration with liquid water, leading to the measurement of an apparent swelling pressure. The latter is continuously recorded with a dedicated device. The asymptotic apparent swelling pressure of macro-cracked UT (transitional unit) COx is approximately 1 MPa, while it varies from 3 to 5 MPa for macro-cracked UA (clayey unit) COx. Quantitative X-ray diffraction (QXRD) analysis demonstrates that the amount of smectite, which is a swelling clay, is weakly correlated with apparent swelling pressure. Surprisingly, the interstratified illite/smectite with lower smectite content is highly correlated to apparent swelling pressure. Nitrogen isotherms data imply that the Gurvich total pore volume ( V Gurvich ) and specific surface area (SSA) are highly linearly correlated with the low smectite content interstratified phase. This means that the distribution of smectite strongly affects the swelling capacity of COx. Moreover, nitrogen sorption is an easier and more effective technique than QXRD for assessing COx swelling capacity, since both V Gurvich and SSA have been proven as effective indicators. For both UT and UA COx, self-sealing can cause significant reductions in water permeability (Kw). In particular, UA COx shows higher sealing efficiency and faster kinetics compared to UT COx. After sealing, the equivalent crack aperture (calculated from Poiseuille’s law) decreases from tens of microns to less than 1 micron. According to the gas breakthrough tests, the gas breakthrough pressure (GBP) of re-sealed macro-cracked COx is of the same order of magnitude as the equivalent capillary pressure of residual crack. This indicates that the gas migration in the re-sealed cracked COx claystone mainly occurs through the residual crack and is ‘a priori’ controlled by capillary processes. Highlights A dedicated device was designed to study the transport and swelling properties of a sealed COx claystone under low confinement. The apparent swelling pressure and water permeability were continuously recorded during the sealing test due to water injection in fractures. Water permeability of samples decreased by orders of magnitude to almost meet the intact material permeability. Gas breakthrough experiments performed on sealed samples evidenced gas flow through the residual cracks.
ISSN:0723-2632
1434-453X
DOI:10.1007/s00603-021-02708-4