Your search keyword '"Wall shear stresses"' showing total 7 results

1. Determination of Local Heat Transfer Coefficients and Friction Factors at Variable Temperature and Velocity Boundary Conditions for Complex Flows.

Author

Hartmann, Christopher and von Wolfersdorf, Jens

Subjects

TURBULENT boundary layer, HEAT transfer coefficient, TURBULENT heat transfer, ADIABATIC temperature, HEAT transfer

Abstract

Transient conjugate heat transfer measurements under varying temperature and velocity inlet boundary conditions at incompressible flow conditions were performed for flat plate and ribbed channel geometries. Therefrom, local adiabatic wall temperatures and heat transfer coefficients were determined. The data were analyzed using typical heat transfer correlations, e.g., Nu = C Re m Pr n , determining the local distributions of C and m. It is shown that they are closely linked. A relationship ln C = A − m B is observed, with A and B as modeling parameters. They could be related to parameters in log-law or power-law representations for turbulent boundary layer flows. The parameter m is shown to have a close link to local pressure gradients and, therewith, near wall streamlines as well as friction factor distributions. A normalization of the C parameter allows one to derive a Reynolds analogy factor and, therefrom, local wall shear stresses. [ABSTRACT FROM AUTHOR]

Published

2024

2. Arrangement into layers and mechanobiology of multi-cell co-culture models of the uterine wall.

Author

Shlomo, Yael, Gavriel, Mark, Jaffa, Ariel J, Grisaru, Dan, and Elad, David

Subjects

ARTIFICIAL membranes, F-actin, MUSCLE cells, EPITHELIAL cells, SHEARING force

Abstract

STUDY QUESTION Can a co-culture of three cell types mimic the in vivo layers of the uterine wall? SUMMARY ANSWER Three protocols tested for co-culture of endometrial epithelial cells (EEC), endometrial stromal cells (ESC), and myometrial smooth muscle cells (MSMC) led to formation of the distinct layers that are characteristic of the structure of the uterine wall in vivo. WHAT IS KNOWN ALREADY We previously showed that a layer-by-layer co-culture of EEC and MSMC responded to peristaltic wall shear stresses (WSS) by increasing the polymerization of F-actin in both layers. Other studies showed that WSS induced significant cellular alterations in epithelial and endothelial cells. STUDY DESIGN, SIZE, DURATION Human EEC and ESC cell lines and primary MSMC were co-cultured on a collagen-coated synthetic membrane in custom-designed wells. The co-culture model, created by seeding a mixture of all cells at once, was exposed to steady WSS of 0.5 dyne/cm2 for 10 and 30 min. PARTICIPANTS/MATERIALS, SETTING, METHODS The co-culture of the three different cells was seeded either layer-by-layer or as a mixture of all cells at once. Validation of the models was by specific immunofluorescence staining and confocal microscopy. Alterations of the cytoskeletal F-actin in response to WSS were analyzed from the 2-dimensional confocal images through the Z-stacks following a previously published algorithm. MAIN RESULTS AND THE ROLE OF CHANCE We generated three multi-cell in vitro models of the uterine wall with distinct layers of EEC, ESC, and MSMC that mimic the in vivo morphology. Exposure of the mixed seeding model to WSS induced increased polymerization of F-actin in all the three layers relative to the unexposed controls. Moreover, the increased polymerization of F-actin was higher (P -value < 0.05) when the length of exposure was increased from 10 to 30 min. Furthermore, the inner layers of ESC and MSMC, which are not in direct contact with the applied shearing fluid, also increased their F-actin polymerization. LARGE SCALE DATA N/A. LIMITATIONS, RESONS FOR CAUTION The mixed seeding co-culture model was exposed to steady WSS of one magnitude, whereas the uterus is a dynamic organ with intra-uterine peristaltic fluid motions that vary in vivo with different time-dependent magnitude. Further in vitro studies may explore the response to peristaltic WSS or other physical and/or hormonal perturbations that may mimic the spectrum of pathophysiological aspects. WIDER IMPLICATIONS OF THE FINDINGS Numerous in vitro models were developed in order to mimic the human endometrium and endometrium–myometrium interface (EMI) region. The present co-culture models seem to be the first constructed from EEC, ESC, and MSMC on a collagen-coated synthetic membrane. These multi-cell in vitro models better represent the complex in vivo anatomy of the EMI region. The mixed seeding multi-cell in vitro model may easily be implemented in controlled studies of uterine function in reproduction and the pathogenesis of diseases. STUDY FINDING/COMPETING INTEREST(S) This study was supported in part by Tel Aviv University funds. All authors declare no conflict of interest. [ABSTRACT FROM AUTHOR]

Published

2024

3. Vortical Structures Promote Atheroprotective Wall Shear Stress Distributions in a Carotid Artery Bifurcation Model.

Author

Wild, Nora C., Bulusu, Kartik V., and Plesniak, Michael W.

Subjects

SHEARING force, SHEAR walls, STRESS concentration, INTERNAL carotid artery, CAROTID artery diseases, CAROTID artery

Abstract

Carotid artery diseases, such as atherosclerosis, are a major cause of death in the United States. Wall shear stresses are known to prompt plaque formation, but there is limited understanding of the complex flow structures underlying these stresses and how they differ in a pre-disposed high-risk patient cohort. A 'healthy' and a novel 'pre-disposed' carotid artery bifurcation model was determined based on patient-averaged clinical data, where the 'pre-disposed' model represents a pathological anatomy. Computational fluid dynamic simulations were performed using a physiological flow based on healthy human subjects. A main hairpin vortical structure in the internal carotid artery sinus was observed, which locally increased instantaneous wall shear stress. In the pre-disposed geometry, this vortical structure starts at an earlier instance in the cardiac flow cycle and persists over a much shorter period, where the second half of the cardiac cycle is dominated by perturbed secondary flow structures and vortices. This coincides with weaker favorable axial pressure gradient peaks over the sinus for the 'pre-disposed' geometry. The findings reveal a strong correlation between vortical structures and wall shear stress and imply that an intact internal carotid artery sinus hairpin vortical structure has a physiologically beneficial role by increasing local wall shear stresses. The deterioration of this beneficial vortical structure is expected to play a significant role in atherosclerotic plaque formation. [ABSTRACT FROM AUTHOR]

Published

2023

4. An Image-Based Computational Fluid Dynamics Study of Mitral Regurgitation in Presence of Prolapse.

Author

Bennati, Lorenzo, Vergara, Christian, Giambruno, Vincenzo, Fumagalli, Ivan, Corno, Antonio Francesco, Quarteroni, Alfio, Puppini, Giovanni, and Luciani, Giovanni Battista

Abstract

Purpose: In this work we performed an imaged-based computational study of the systolic fluid dynamics in presence of mitral valve regurgitation (MVR). In particular, we compared healthy and different regurgitant scenarios with the aim of quantifying different hemodynamic quantities. Methods: We performed computational fluid dynamic (CFD) simulations in the left ventricle, left atrium and aortic root, with a resistive immersed method, a turbulence model, and with imposed systolic wall motion reconstructed from Cine-MRI images, which allowed us to segment also the mitral valve. For the regurgitant scenarios we considered an increase of the heart rate and a dilation of the left ventricle. Results: Our results highlighted that MVR gave rise to regurgitant jets through the mitral orifice impinging against the atrial walls and scratching against the mitral valve leading to high values of wall shear stresses (WSSs) with respect to the healthy case. Conclusion: CFD with prescribed wall motion and immersed mitral valve revealed to be an effective tool to quantitatively describe hemodynamics in case of MVR and to compare different regurgitant scenarios. Our findings highlighted in particular the presence of transition to turbulence in the atrium and allowed us to quantify some important cardiac indices such as cardiac output and WSS. [ABSTRACT FROM AUTHOR]

Published

2023

5. Measuring the onset of mine tailings erosion.

Author

Haneef-Mian, M., Yanful, Ernest K., and Martinuzzi, Robert

Subjects

EROSION, METAL tailings, SHEAR (Mechanics), MINES & mineral resources, SEDIMENTATION & deposition, STRAINS & stresses (Mechanics)

Abstract

Copyright of Canadian Geotechnical Journal is the property of Canadian Science Publishing and its content may not be copied or emailed to multiple sites or posted to a listserv without the copyright holder's express written permission. However, users may print, download, or email articles for individual use. This abstract may be abridged. No warranty is given about the accuracy of the copy. Users should refer to the original published version of the material for the full abstract. (Copyright applies to all Abstracts.)

Published

2007

6. Modeling and Measurement of Shear Stress for a Slug Flow Inside a Capillary.

Author

Laborie, S. and Cabassud, C.

Subjects

STRAINS & stresses (Mechanics), FLUID dynamics, FLUID mechanics, CHEMICAL engineering, PHYSICAL & theoretical chemistry

Abstract

The aim of the present study is to characterize wall shear stresses generated by a gas-liquid two-phase flow inside a capillary tube. In this case the flow is a slug flow. Two different approaches were used. The first one constituted a calculation of the shear stresses by a two-phase model in which some parameters characteristics of the flow were introduced. These parameters had been determined experimentally in a previous study. The second approach constituted a direct and local measurement of wall shear stresses by an electrochemical method. The shear stresses near liquid and gas slugs were obtained for different operating conditions. Moreover, a calculation of the liquid film thickness around the gas slugs demonstrated that this thickness does not depend on gas velocity. [ABSTRACT FROM AUTHOR]

Published

2005

7. Wall Stresses in Cylinder of Stationary Piped Carriage Using COMSOL Multiphysics.

Author

Yang, Xiaoni, Ma, Juanjuan, Li, Yongye, Sun, Xihuan, Jia, Xiaomeng, and Li, Yonggang

Subjects

SHEARING force, HYDRAULICS, FLOW velocity, STRESS concentration, SHEAR walls, HYDRAULIC structures, HYDRAULIC cylinders, FLUID-structure interaction

Abstract

Hydraulic transportation of the piped carriage is a new energy-saving and environmentally-friendly transportation mode. There are two main states in the conveying process, stationary and moving. In the process of hydraulic transportation of the piped carriage, the study of the stress of the water flow act on the cylinder wall of the piped carriage can help to improve the design of the piped carriage structure and even the selection of piped carriage materials. The distribution of flow velocity around the stationary piped carriage and the stress distribution on the cylinder wall of the stationary piped carriage were investigated by combining numerical simulations with model experiment verification. The commercial finite element software, Comsol Multiphysics, was utilized to solve this problem using the arbitrary Lagrangian–Eulerian (ALE) method. The results showed that the simulation results were in good agreement with the experimental results. It also showed that the ALE method can well be applied for fluid-structure problems in the process of hydraulic transportation of the piped carriage. The simulation results showed that the low velocity region near the inner wall of the pipe was smaller than that near the outer wall of the piped carriage, and both regions decreased with the increase of the discharge. The maximum stress on the cylinder wall of the piped carriage appeared between the two support feet in the middle and rear sections of the cylinder. The influence of the unit discharge on wall stress increased with the increase of the discharge, that is, k1 < k2 < k3. Moreover, the increase of the discharge had the greatest influence on the circumferential component of the principal stress of the cylinder, followed by the axis component, and the smallest influence on the wall shear stress of the cylinder, i.e., k ¯ σ c > k ¯ σ a > k ¯ σ r > k ¯ τ c . [ABSTRACT FROM AUTHOR]

Published

2019