Mechano-Electrochemical Mixture Theories for the Multiphase Fluid Infiltrated Poroelastic Media

According to the results of visualization of streams, the existence of structures in a wide range of scales is noted: from galactic to micron. The use of a fundamental system of equations is substantiated based on the results of comparing symmetries of various flow models with the usage of theoretical group methods. Complete solutions of the system are found by the methods of the singular perturbations theory with a condition of compatibility, which determines the characteristic equation. A comparison of complete solutions with experimental data shows that regular solutions characterize large-scale components of the flow, a rich family of singular solutions describes formation of the thin media structure. Examples of calculations and observations of stratified, rotating and multiphase media are given. The requirements for the technique of an adequate experiment are discussed.

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Derivation of fractional-derivative models of multiphase fluid flows in porous media

Journal of King Saud University - Science ◽

10.1016/j.jksus.2021.101346 ◽

2021 ◽

Vol 33 (2) ◽

pp. 101346

Author(s):

Mohamed F. El-Amin

Keyword(s):

Porous Media ◽

Fractional Derivative ◽

Fluid Flows ◽

Flows In Porous Media ◽

Multiphase Fluid

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Finite Element Analysis of the Distributed Vibration Absorbers for Structural Noise Control

Noise Control and Acoustics ◽

10.1115/imece2005-82798 ◽

2005 ◽

Author(s):

Ashwini Gautam ◽

Chris Fuller ◽

James Carneal

Keyword(s):

Finite Element ◽

Numerical Model ◽

Base Plate ◽

Element Model ◽

Fe Model ◽

Vibration Absorbers ◽

Element Analysis ◽

Poroelastic Media ◽

Hexahedral Elements ◽

Component Models

This work presents an extensive analysis of the properties of distributed vibration absorbers (DVAs) and their effectiveness in controlling the sound radiation from the base structure. The DVA acts as a distributed mass absorber consisting of a thin metal sheet covering a layer of acoustic foam (porous media) that behaves like a distributed spring-mass-damper system. To assess the effectiveness of these DVAs in controlling the vibration of the base structures (plate) a detailed finite elements model has been developed for the DVA and base plate structure. The foam was modeled as a poroelastic media using 8 node hexahedral elements. The structural (plate) domain was modeled using 16 degree of freedom plate elements. Each of the finite element models have been validated by comparing the numerical results with the available analytical and experimental results. These component models were combined to model the DVA. Preliminary experiments conducted on the DVAs have shown an excellent agreement between the results obtained from the numerical model of the DVA and from the experiments. The component models and the DVA model were then combined into a larger FE model comprised of a base plate with the DVA treatment on its surface. The results from the simulation of this numerical model have shown that there has been a significant reduction in the vibration levels of the base plate due to DVA treatment on it. It has been shown from this work that the inclusion of the DVAs on the base plate reduces their vibration response and therefore the radiated noise. Moreover, the detailed development of the finite element model for the foam has provided us with the capability to analyze the physics behind the behavior of the distributed vibration absorbers (DVAs) and to develop more optimized designs for the same.

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Tracing a Multiphase Fluid Flow Path in the Changbaishan Volcanic Geothermal System (Northeast China) by B-Sr Isotope Decoupling

Arabian Journal for Science and Engineering ◽

10.1007/s13369-021-05788-0 ◽

2021 ◽

Author(s):

Rongsheng Zhao ◽

Jian Yi

Keyword(s):

Fluid Flow ◽

Northeast China ◽

Flow Path ◽

Geothermal System ◽

Sr Isotope ◽

Multiphase Fluid Flow ◽

Multiphase Fluid

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A Model Constraint for Polydisperse Solids in Multifluid Flows

Journal of Fluids Engineering ◽

10.1115/1.4030762 ◽

2015 ◽

Vol 137 (11) ◽

Cited By ~ 3

Author(s):

Michael P. Kinzel ◽

Leonard Joel Peltier ◽

Brigette Rosendall ◽

Mallory Elbert ◽

Andri Rizhakov ◽

...

Keyword(s):

Model Development ◽

Fluid Flows ◽

Momentum Exchange ◽

Carrier Fluid ◽

Single Carrier ◽

Cfd Models ◽

Model Constraint ◽

Level Model ◽

Consistency Constraint ◽

Multiphase Fluid

A method to assess computational fluid dynamics (CFD) models for polydisperse granular solids in a multifluid flow is developed. The proposed method evaluates a consistency constraint, or a condition that an Eulerian multiphase solution for a monodisperse material in a single carrier fluid is invariant to an arbitrary decomposition into a pseudo-polydisperse mixture of multiple, identical fluid phases. The intent of this condition is to develop tests to assist model development and testing for multiphase fluid flows. When applied to two common momentum exchange models, the constraint highlights model failures for polydisperse solids interacting with a multifluid flow. It is found that when inconsistency occurs at the algebraic level, model failure clearly extends to application. When the models are reformulated to satisfy the consistency constraint, simple tests and application-scale simulations no longer display consistency failure.

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