Phenomenon of labyrinth seal with low static pressure difference and large clearance

The endothelium lining human arteries is a continuum of endothelial cells. The flowing blood imposes a shear stress on the endothelium. To compute the internal stress in the endothelium, we use two alternative hypotheses: 1) The cell content is fluid-like so that at steady-state it has no shear stress. 2) The cell content is solid-like. Under hypothesis No. 1, the membrane tension in the upper cell membrane grows in the direction opposite to the blood flow at a rate equal to the blood shear stress. At the junction of two neighboring cells the membrane tension in the downstream cell is transmitted partly to the basal lamina, and partly to the upstream cell. The transmission depends on the osmotic or static pressure difference between the cell and blood. If the static pressure difference is zero, the tension in the upper cell membrane will accumulate upstream. At other values of static pressure, the cell membrane tension may increase, decrease, or fluctuate along the vessel depending on the inclination of the side walls of the cells at the junctions. To determine the sidewall inclinations, we propose to use the complementary energy theorem. Under hypothesis No. 2, the cell content can bear shear, which tends to reduce the cell membrane tension; but the cell membrane tension accumulation phenomenon discussed above remains valid. These results are used to analyze the interaction of the cell membrane and cell nucleus; and the effect of turbulences in the flow on causing large fluctuations in cell membrane tension and vertical oscillations of the nuclei. The implication of tensile stress on the permeability of the cell membrane is discussed. We conclude that for the study of mass transport and stress fibers in the endothelial cells, one should consider the interaction of neighboring endothelial cells as a continuum, and shift attention from the shear stress in the blood to the principal stresses in the cells.

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Analysis of the static pressure difference of blast-furnace gases on the basis of the Clapeyron–Mendeleev equation

Steel in Translation ◽

10.3103/s096709121602008x ◽

2016 ◽

Vol 46 (2) ◽

pp. 118-124 ◽

Cited By ~ 3

Author(s):

V. P. Lyalyuk

Keyword(s):

Blast Furnace ◽

Pressure Difference ◽

Static Pressure ◽

Furnace Gases ◽

Static Pressure Difference

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Experimental and numerical investigation of pressure drop coefficient and static pressure difference in a tangential inlet cyclone separator

Chemical Papers ◽

10.2478/s11696-012-0214-7 ◽

2012 ◽

Vol 66 (11) ◽

Cited By ~ 6

Author(s):

Fuat Kaya ◽

Irfan Karagoz

Keyword(s):

Pressure Drop ◽

Pressure Difference ◽

Static Pressure ◽

Numerical Technique ◽

Pipe Length ◽

Inlet Velocity ◽

Viscous Forces ◽

Static Pressure Difference ◽

High Reynolds ◽

Experimental Data Analysis

AbstractThe aim of this study was to investigate the pressure drop coefficient and the static pressure difference related to the natural vortex length and to evaluate the results for gas-particle applications. CFD simulations were carried out using a numerical technique which had been verified previously. Results obtained from the numerical simulations were compared with the experimental data. Analysis of the results showed that the pressure drop coefficient decreases with the increasing inlet velocity, becoming almost constant above a certain value of the inlet velocity. The reason is that the effect of viscous forces decreases at high Reynolds numbers. The pressure drop coefficient also decreases with the increasing exit pipe diameter and decreasing exit pipe length.

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Influence of ear canal occlusion and static pressure difference on bone conduction thresholds: Implications for mechanisms of bone conduction

International Journal of Audiology ◽

10.1080/14992020500060669 ◽

2005 ◽

Vol 44 (5) ◽

pp. 302-306 ◽

Cited By ~ 5

Author(s):

Hashir Aazh ◽

Brian Moore ◽

Ali Asghar Peyvandi ◽

Stefan Stenfelt

Keyword(s):

Pressure Difference ◽

Static Pressure ◽

Bone Conduction ◽

Ear Canal ◽

Static Pressure Difference

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Influences of Randomly Uncertain Factors on Dynamic Coefficients of an Interlocking Labyrinth Seal-Rotor System

Machines ◽

10.3390/machines10010039 ◽

2022 ◽

Vol 10 (1) ◽

pp. 39

Author(s):

Xin Xiong ◽

Yanfei Zhou ◽

Yiqun Wang

Keyword(s):

Pressure Difference ◽

Gas Flow ◽

Labyrinth Seal ◽

Momentum Equation ◽

Rotor System ◽

Rotor Speed ◽

Bounded Noise ◽

Dynamic Coefficients ◽

Noise Perturbation ◽

Rotor Center

Many randomly uncertain factors inevitably arise when gas flows through a labyrinth seal, and the orbit of the rotor center will not rotate along a steady trajectory, as previously studied. Here, random uncertainty is considered in an interlocking labyrinth seal-rotor system to investigate the fluctuations of dynamic coefficients. The bounded noise excitation is introduced into the momentum equation of the gas flow, and as a result, the orbit of the rotor center is expressed as the combination of an elliptic trajectory with the bounded noise perturbation. Simulation results of the coefficients under randomly uncertain perturbations with various strengths are comparatively investigated with the traditional predictions under ideal conditions, from which the influences of random uncertain factors on dynamic coefficients are analyzed in terms of the rotor speed, pressure difference, and inlet whirl velocity. It is shown that the deviation levels of the dynamic coefficients are directly related to the random perturbations and routinely increase with such perturbation strengths, and the coefficients themselves may exhibit distinct variation patterns against the rotor speed, pressure difference, and inlet whirl velocity.

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Numerical Analysis of Contraction Geometry Effects on Cavitation Choking in a Piping System

Volume 3B: Fluid Applications and Systems ◽

10.1115/ajkfluids2019-5359 ◽

2019 ◽

Author(s):

Motohiko Nohmi ◽

Shusaku Kagawa ◽

Tomoki Tsuneda ◽

Wakana Tsuru ◽

Kazuhiko Yokota

Keyword(s):

Static Pressure ◽

Sudden Expansion ◽

Piping System ◽

Valve Body ◽

Line System ◽

Pipe System ◽

Flow Fluctuation ◽

Supply Pipe ◽

Static Pressure Difference ◽

Pipe Line

Abstract There is a contraction portion in the water supply pipe line system, and cavitation may occur in the contraction when the flow velocity is increased. Such a situation occurs widely in the throat of the fluid machineries and in the vicinity of the valve body of the valve. In operation of the valve, it is well known that a phenomenon occurs in which the flow rate does not increase even if the static pressure difference upstream and downstream of the valve is increased due to the growth of cavitation in the contraction, which is well known as choking . It is not clear what phenomena occurs when cavitation surge occurs in the pipe system in the situation where choking is occurring in the contraction. In this study, cavitation CFD was performed on pipes those have three different geometry contractions. It was revealed that choking occurred when cavitation occurred in any shape. Also, in the case with the sharp contraction part and the sudden expansion, the flow fluctuation at the upstream of the contraction is much weaker than that at the downstream, but in the contraction with the bent part where the centrifugal force acts on the flow, the flow fluctuation at the upstream was found to be strong.

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