MODELLING THE INTERSTITIAL FLUID EFFECT IN TURBULENT DISPERSE SLURRY FLOW IN A VERTICAL PIPE

Ultrasonic Velocity Profile (UVP) method for measurement of single-phase and two-phase flow in a vertical pipe has recently been developed in the Laboratory for industrial and Environmental Fluid Dynamics, Institute of Mechanics, VAST. The signal processings of the UVP method include the ultrasonic pulse Doppler method (UDM)and the ultrasonic time-domain cross-correlation (UTDC) method. For two-phase flow, simultaneous measurements of both liquid and gas are enabled by using a multi-wave ultrasonic transducer (multi-wave TDX). The multi-wave TDX is able to emit and receive ultrasound of two different center frequencies of 2 MHz and 8 MHz at the same time and position. 2 MHz frequency with beam diameter 10 mm is exploited for measurement of gas. 8 MHz one with beam diameter 3 mm is used for liquid. Measurements have been carried out for laminar and turbulent single-phase flows and bubbly counter-current two-phase flows in two flow loops using two vertical pipes of 26 mm inner diameter (I.D.) and 50 mm I.D. respectively. Based on the measured results, assessment of each method is clarified. Applicability of each method for different conditions of pipe flow has been tested. Suggestions for application of the two methods have been recommended.

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MHD Mixed Convection Flow in a Vertical Pipe with Time Periodic Boundary Condition: Steady Periodic Regime

International Journal of Fluid Mechanics Research ◽

10.1615/interjfluidmechres.v43.i4.50 ◽

2016 ◽

Vol 43 (4) ◽

pp. 350-367 ◽

Cited By ~ 1

Author(s):

Basant K. Jha ◽

Babatunde Aina

Keyword(s):

Boundary Condition ◽

Mixed Convection ◽

Periodic Boundary Condition ◽

Periodic Boundary ◽

Convection Flow ◽

Periodic Regime ◽

Mixed Convection Flow ◽

Vertical Pipe ◽

Time Periodic

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Interstitial Fluid Sampling with Open Flow Microperfusion for Investigation of Protein Binding in Tissue

10.26226/morressier.57d6b2bbd462b8028d88ea88 ◽

2016 ◽

Author(s):

Frank Sinner

Keyword(s):

Protein Binding ◽

Interstitial Fluid ◽

Open Flow ◽

Fluid Sampling

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A hydroblasting laborer dies when he falls into an underground vertical pipe and suffocates.

10.26616/nioshsface16ca001 ◽

2016 ◽

Keyword(s):

Vertical Pipe

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Theoretical Post-Dryout Heat Transfer Model

International Journal of Computational Physics Series ◽

10.29167/a1i1p142-150 ◽

2018 ◽

Vol 1 (1) ◽

pp. 142-150

Author(s):

Murat Tunc ◽

Ayse Nur Esen ◽

Doruk Sen ◽

Ahmet Karakas

Keyword(s):

Heat Transfer ◽

Droplet Diameter ◽

Heat Transfer Model ◽

Transfer Model ◽

Operating Pressure ◽

Vertical Pipe ◽

Two Phase ◽

Experimental Values ◽

Reactor Operating ◽

Coolant System

A theoretical post-dryout heat transfer model is developed for two-phase dispersed flow, one-dimensional vertical pipe in a post-CHF regime. Because of the presence of average droplet diameter lower bound in a two-phase sparse flow. Droplet diameter is also calculated. Obtained results are compared with experimental values. Experimental data is used two-phase flow steam-water in VVER-1200, reactor coolant system, reactor operating pressure is 16.2 MPa. On heater rod surface, dryout was detected as a result of jumping increase of the heater rod surface temperature. Results obtained display lower droplet dimensions than the experimentally obtained values.

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Fisiopatología de la hidrocefália idiopática de presión normal (parte 3): sistemaa glinfático

Archivos de Neurociencias ◽

10.31157/archneurosciencesmex.v21i2.116 ◽

2016 ◽

Vol 21 (2) ◽

pp. 28-37

Author(s):

Oscar Solís-Salgado ◽

José Luis López-Payares ◽

Mauricio Ayala-González

Keyword(s):

Amyloid Beta ◽

Interstitial Fluid ◽

Amyloid Β ◽

Bulk Flow ◽

Polyethylene Glycols ◽

Brain Interstitial Fluid ◽

El Sistema ◽

Arterial Pulsation ◽

The Brain

Las vías de drenaje solutos del sistema nervioso central (SNC) participan en el recambio de liquido intersticial con el líquido cefalorraquídeo (LIT-LCR), generando un estado de homeostasis. Las alteraciones dentro de este sistema homeostático afectará la eliminación de solutos del espacio intersticial (EIT) como el péptido βa y proteína tau, los cuales son sustancias neurotóxicas para el SNC. Se han utilizado técnicas experimentales para poder analizar el intercambio LIT-LCR, las cuales revelan que este intercambio tiene una estructura bien organizada. La eliminación de solutos del SNC no tiene una estructura anatómica propiamente, se han descubierto vías de eliminación de solutos a través de marcadores florecentes en el espacio subaracnoideo, cisternas de la base y sistema ventricular que nos permiten observar una serie de vías ampliamente distribuidas en el cerebro. El LCR muestra que tiene una función linfática debido a su recambio con el LIT a lo largo de rutas paravasculares. Estos espacios que rodean la superficie arterial así como los espacios de Virchow-Robin y el pie astrocitico junto con la AQP-4, facilitan la entrada de LCR para-arterial y el aclaramiento de LIT para-venoso dentro del cerebro. El flujo y dirección que toma el LCR por estas estructuras, es conducido por la pulsación arterial. Esta función será la que finalmente llevara a la eliminación de estas sustancias neurotóxicas. En base a la dependencia de este flujo para la eliminación de sustancias se propone que el sistema sea llamado “ la Vía Glinfática”. La bibliografía así como las limitaciones que se encuentran en esta revisión están dadas por la metodología de búsqueda que ha sido realizada principalmente en PubMed utilizando los siguientes términos Mesh: Cerebral Arterial Pulsation, the brain via paravascular, drainage of amyloid-beta, bulk flow of brain interstitial fluid, radiolabeled polyethylene glycols and albumin, amyloid-β, the perivascular astroglial sheath, Brain Glymphatic Transport.

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