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fem simulations coupled fluid–structure interaction (fsi) module  (COMSOL Inc)

 
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    Structured Review

    COMSOL Inc fem simulations coupled fluid–structure interaction (fsi) module
    ( a ) Fluid–structure interaction <t>(FSI)</t> simulation illustrating the distribution of flow fields inside the microchannel and the deformation of the microcantilever; ( b ) Displacement of the cantilever beam corresponding to the four sensing elements (time series data) simulated using the finite element method (FEM) model; ( c ) Displacement amplitude response of the microcantilevers.
    Fem Simulations Coupled Fluid–Structure Interaction (Fsi) Module, supplied by COMSOL Inc, used in various techniques. Bioz Stars score: 90/100, based on 1 PubMed citations. ZERO BIAS - scores, article reviews, protocol conditions and more
    https://www.bioz.com/result/fem simulations coupled fluid–structure interaction (fsi) module/product/COMSOL Inc
    Average 90 stars, based on 1 article reviews
    fem simulations coupled fluid–structure interaction (fsi) module - by Bioz Stars, 2026-05
    90/100 stars

    Images

    1) Product Images from "A Highly Sensitive Deep-Sea Hydrodynamic Pressure Sensor Inspired by Fish Lateral Line"

    Article Title: A Highly Sensitive Deep-Sea Hydrodynamic Pressure Sensor Inspired by Fish Lateral Line

    Journal: Biomimetics

    doi: 10.3390/biomimetics9030190

    ( a ) Fluid–structure interaction (FSI) simulation illustrating the distribution of flow fields inside the microchannel and the deformation of the microcantilever; ( b ) Displacement of the cantilever beam corresponding to the four sensing elements (time series data) simulated using the finite element method (FEM) model; ( c ) Displacement amplitude response of the microcantilevers.
    Figure Legend Snippet: ( a ) Fluid–structure interaction (FSI) simulation illustrating the distribution of flow fields inside the microchannel and the deformation of the microcantilever; ( b ) Displacement of the cantilever beam corresponding to the four sensing elements (time series data) simulated using the finite element method (FEM) model; ( c ) Displacement amplitude response of the microcantilevers.

    Techniques Used:



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    ( a ) Fluid–structure interaction <t>(FSI)</t> simulation illustrating the distribution of flow fields inside the microchannel and the deformation of the microcantilever; ( b ) Displacement of the cantilever beam corresponding to the four sensing elements (time series data) simulated using the finite element method (FEM) model; ( c ) Displacement amplitude response of the microcantilevers.
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    Image Search Results


    ( a ) Fluid–structure interaction (FSI) simulation illustrating the distribution of flow fields inside the microchannel and the deformation of the microcantilever; ( b ) Displacement of the cantilever beam corresponding to the four sensing elements (time series data) simulated using the finite element method (FEM) model; ( c ) Displacement amplitude response of the microcantilevers.

    Journal: Biomimetics

    Article Title: A Highly Sensitive Deep-Sea Hydrodynamic Pressure Sensor Inspired by Fish Lateral Line

    doi: 10.3390/biomimetics9030190

    Figure Lengend Snippet: ( a ) Fluid–structure interaction (FSI) simulation illustrating the distribution of flow fields inside the microchannel and the deformation of the microcantilever; ( b ) Displacement of the cantilever beam corresponding to the four sensing elements (time series data) simulated using the finite element method (FEM) model; ( c ) Displacement amplitude response of the microcantilevers.

    Article Snippet: To gain more insight into the piezopotential distribution on the interdigital electrodes, FEM simulations were conducted using the coupled fluid–structure interaction (FSI) module of COMSOL Multiphysics by placing a sensing unit in a water canal.

    Techniques:

    (A) Representative position tracking of a fluorescent bead in 1% agarose gel upon 10 Hz actuation. (B and C) 3D rendered phase and amplitude difference submerged in DMEM vs water at 37°C. (D) Fluid-structure interaction simulation model setup. (E) Simulation-predicted damping ratio as a function of the gel extrusion length. (F) Simulation-predicted damping ratio at varying viscosity and culture medium density with an extrusion length of 6.5 mm suggesting predominantly mass damping. (G and H) Simulation -predicted damping ratio at various agarose gel elastic moduli (G) and diameters (H) with an extrusion length of 6.5 mm. (I and J) Angle of rotation along central-boundary axis. (K) Angle of rotation along Y axis. (L) Increased deflection along Y axis. (M) Constant Y phase speed under different actuation frequencies suggesting non-dispersive shear wave propagation along the Y axis.

    Journal: bioRxiv

    Article Title: Tissue stiffness mapping by light sheet elastography

    doi: 10.1101/2023.12.09.570896

    Figure Lengend Snippet: (A) Representative position tracking of a fluorescent bead in 1% agarose gel upon 10 Hz actuation. (B and C) 3D rendered phase and amplitude difference submerged in DMEM vs water at 37°C. (D) Fluid-structure interaction simulation model setup. (E) Simulation-predicted damping ratio as a function of the gel extrusion length. (F) Simulation-predicted damping ratio at varying viscosity and culture medium density with an extrusion length of 6.5 mm suggesting predominantly mass damping. (G and H) Simulation -predicted damping ratio at various agarose gel elastic moduli (G) and diameters (H) with an extrusion length of 6.5 mm. (I and J) Angle of rotation along central-boundary axis. (K) Angle of rotation along Y axis. (L) Increased deflection along Y axis. (M) Constant Y phase speed under different actuation frequencies suggesting non-dispersive shear wave propagation along the Y axis.

    Article Snippet: To investigate the impact of system parameters (e.g., gel extrusion length) on the damping behavior and the source of DMEM-induced damping (i.e., mass vs. viscous damping), we conducted COMSOL fluid-structure interaction (FSI) simulations.

    Techniques: Agarose Gel Electrophoresis, Viscosity, Shear