Gespeichert in:
Bibliographische Detailangaben
Hauptverfasser: Leskovec, Martin, Zade, Sagar, Niazi, Mehdi, Costa, Pedro, Lundell, Fredrik, Brandt, Luca
Format: Preprint
Veröffentlicht: 2024
Schlagworte:
Online-Zugang:https://arxiv.org/abs/2411.10162
Tags: Tag hinzufügen
Keine Tags, Fügen Sie den ersten Tag hinzu!
_version_ 1866915022064582656
author Leskovec, Martin
Zade, Sagar
Niazi, Mehdi
Costa, Pedro
Lundell, Fredrik
Brandt, Luca
author_facet Leskovec, Martin
Zade, Sagar
Niazi, Mehdi
Costa, Pedro
Lundell, Fredrik
Brandt, Luca
contents Suspensions of finite-size solid particles in a turbulent pipe flow are found in many industrial and technical flows. Due to the ample parameter space consisting of particle size, concentration, density and Reynolds number, a complete picture of the particle-fluid interaction is still lacking. Pressure drop predictions are often made using viscosity models only considering the bulk solid volume fraction. For the case of turbulent pipe flow laden with neutrally buoyant spherical particles, we investigate the pressure drop and overall drag (friction factor), fluid velocity and particle distribution in the pipe. We use a combination of experimental (MRV) and numerical (DNS) techniques and a continuum flow model. We find that the particle size and the bulk flow rate influence the mean fluid velocity, velocity fluctuations and the particle distribution in the pipe for low flow rates. However, the effects of the added solid particles diminish as the flow rate increases. We created a master curve for drag change compared to single-phase flow for the particle-laden cases. This curve can be used to achieve more accurate friction factor predictions than the traditional modified viscosity approach that does not account for particle size.
format Preprint
id arxiv_https___arxiv_org_abs_2411_10162
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Turbulent pipe flow with spherical particles: drag as a function of particle size and volume fraction
Leskovec, Martin
Zade, Sagar
Niazi, Mehdi
Costa, Pedro
Lundell, Fredrik
Brandt, Luca
Fluid Dynamics
Suspensions of finite-size solid particles in a turbulent pipe flow are found in many industrial and technical flows. Due to the ample parameter space consisting of particle size, concentration, density and Reynolds number, a complete picture of the particle-fluid interaction is still lacking. Pressure drop predictions are often made using viscosity models only considering the bulk solid volume fraction. For the case of turbulent pipe flow laden with neutrally buoyant spherical particles, we investigate the pressure drop and overall drag (friction factor), fluid velocity and particle distribution in the pipe. We use a combination of experimental (MRV) and numerical (DNS) techniques and a continuum flow model. We find that the particle size and the bulk flow rate influence the mean fluid velocity, velocity fluctuations and the particle distribution in the pipe for low flow rates. However, the effects of the added solid particles diminish as the flow rate increases. We created a master curve for drag change compared to single-phase flow for the particle-laden cases. This curve can be used to achieve more accurate friction factor predictions than the traditional modified viscosity approach that does not account for particle size.
title Turbulent pipe flow with spherical particles: drag as a function of particle size and volume fraction
topic Fluid Dynamics
url https://arxiv.org/abs/2411.10162