Salvato in:
Dettagli Bibliografici
Autori principali: Senevirathna, Shaluka, Zemlyanova, Anna, Kelly, Shaina A., Hu, Qinhong, Zhang, Yong, Ghanbarian, Behzad
Natura: Preprint
Pubblicazione: 2024
Soggetti:
Accesso online:https://arxiv.org/abs/2411.08002
Tags: Aggiungi Tag
Nessun Tag, puoi essere il primo ad aggiungerne!!
_version_ 1866908289342636032
author Senevirathna, Shaluka
Zemlyanova, Anna
Kelly, Shaina A.
Hu, Qinhong
Zhang, Yong
Ghanbarian, Behzad
author_facet Senevirathna, Shaluka
Zemlyanova, Anna
Kelly, Shaina A.
Hu, Qinhong
Zhang, Yong
Ghanbarian, Behzad
contents Spontaneous imbibition (SI) is a process by which liquid is drawn into partially saturated porous media by capillary forces, relevant for subsurface processes like underground fluid storage and withdrawal. Accurate modeling and scaling of counter-current SI have long been challenging. In this study, we proposed a generalized fractional flow theory (GFFT) using the Hausdorff fractal derivative, combined with non-Boltzmann scaling. The model links imbibition distance to time through the power law exponent alpha/2, where alpha is the fractal index (0 < alpha < 2 in this study). We applied the GFFT to various experimental and stimulated datasets of both porous and fractured media, finding that alpha varied with factors such as contact angle (of the imbibing fluid), dynamic viscosity, pore structure, and fracture properties. By analyzing SI data from sandstones, diatomite, carbonate, and synthetic porous media, we demonstrated that the non-Boltzmann scaling provided a better collapse of the SI data than the traditional Boltzmann approach alpha = 1), with alpha values ranging from 0.88 to 1.54. These deviations illustrate the model's adaptability to different porous materials. Using the GFFT, we expect to better predict fluid imbibition rates when properties like porosity, permeability, initial and maximum saturations, viscosity, and wettability are known, offering a more accurate alternative to traditional models.
format Preprint
id arxiv_https___arxiv_org_abs_2411_08002
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Modeling and scaling spontaneous imbibition with generalized fractional flow theory and non-Boltzmann transformation
Senevirathna, Shaluka
Zemlyanova, Anna
Kelly, Shaina A.
Hu, Qinhong
Zhang, Yong
Ghanbarian, Behzad
Fluid Dynamics
Spontaneous imbibition (SI) is a process by which liquid is drawn into partially saturated porous media by capillary forces, relevant for subsurface processes like underground fluid storage and withdrawal. Accurate modeling and scaling of counter-current SI have long been challenging. In this study, we proposed a generalized fractional flow theory (GFFT) using the Hausdorff fractal derivative, combined with non-Boltzmann scaling. The model links imbibition distance to time through the power law exponent alpha/2, where alpha is the fractal index (0 < alpha < 2 in this study). We applied the GFFT to various experimental and stimulated datasets of both porous and fractured media, finding that alpha varied with factors such as contact angle (of the imbibing fluid), dynamic viscosity, pore structure, and fracture properties. By analyzing SI data from sandstones, diatomite, carbonate, and synthetic porous media, we demonstrated that the non-Boltzmann scaling provided a better collapse of the SI data than the traditional Boltzmann approach alpha = 1), with alpha values ranging from 0.88 to 1.54. These deviations illustrate the model's adaptability to different porous materials. Using the GFFT, we expect to better predict fluid imbibition rates when properties like porosity, permeability, initial and maximum saturations, viscosity, and wettability are known, offering a more accurate alternative to traditional models.
title Modeling and scaling spontaneous imbibition with generalized fractional flow theory and non-Boltzmann transformation
topic Fluid Dynamics
url https://arxiv.org/abs/2411.08002