Nuclear Magnetic Resonance Investigation of Forced Imbibitions in Longmaxi Shales: Consideration of Different Boundary Conditions

Autor(en)
Yong Liu, Yanbin Yao, Dameng Liu, Chi Zhang
Abstrakt

The forced imbibition in shale reservoirs plays a significant role in achieving high-performance recovery of shale gas. Forced imbibition is the main reason for bringing low flowback efficiency (<30%) of fracturing fluid and some reservoir damages in shale reservoirs. When a large amount of fracturing fluid is injected into the reservoir to enhance the production of gas, the effect of the imbibed liquid on the fracturing fluid leak-off remains poorly understood. In this study, we conducted systematic forced imbibition experiments combined with 1D and 2D nuclear magnetic resonance (NMR) to investigate imbibition behaviors in Longmaxi shales with four boundary conditions: all-side-open (ASO), two-side-open (TSO), one-side-open (OSO), and half-side-open (HSO). The NMR imbibition experimental results (T

2 spectra, fluid saturation profiles, and spatial T

2 images) showed that imbibition dynamics of OSO and TSO are more complicated than those of HSO and ASO, which illustrates that the shale bedding structure is the key to determine different imbibition behaviors and imbibition patterns of four boundaries. For four boundaries, ASO imbibition is composed of the dominant imbibition parallel to beddings and the affiliated imbibition against beddings, and HSO is a combination of the imbibition parallel to beddings (the open part) and the imbibition perpendicular to beddings (the sealed part). In contrast, OSO imbibition and TSO imbibition are unidirectional cross-layer imbibition and bidirectional cross-layer imbibition, respectively. Six imbibition parameters including water saturation, gas recovery, imbibition capacity index, diffusion capacity index, imbibition rate, and imbibition potential are adopted to quantificationally analyze the different forced imbibition dynamics. The understanding of how these boundary conditions affect imbibition dynamics in shale gas reservoirs can be applied to interpret fracturing liquid retention and to optimize the hydraulic fracturing design.

Organisation(en)
Institut für Meteorologie und Geophysik
Externe Organisation(en)
China University of Geosciences
Journal
Energy & Fuels
Band
37
Seiten
5853-5866
Anzahl der Seiten
14
ISSN
0887-0624
DOI
https://doi.org/10.1021/acs.energyfuels.3c00404
Publikationsdatum
2023
Peer-reviewed
Ja
ÖFOS 2012
105906 Umweltgeowissenschaften
ASJC Scopus Sachgebiete
Energy Engineering and Power Technology, Allgemeine chemische Verfahrenstechnik, Fuel Technology
Link zum Portal
https://ucrisportal.univie.ac.at/de/publications/2d7a8417-b1dd-4ea6-9691-a5766de20054