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Laminar and Turbulent Flow01:07

Laminar and Turbulent Flow

Fluid dynamics is the study of fluids in motion. Velocity vectors are often used to illustrate fluid motion in applications like meteorology. For example, wind—the fluid motion of air in the atmosphere—can be represented by vectors indicating the speed and direction of the wind at any given point on a map. Another method for representing fluid motion is a streamline. A streamline represents the path of a small volume of fluid as it flows. When the flow pattern changes with time, the streamlines...
Turbulent Flow: Problem Solving01:09

Turbulent Flow: Problem Solving

Carbonation is a process used to dissolve carbon dioxide gas in a liquid, commonly used in the production of carbonated beverages. Achieving efficient carbonation requires careful control of temperature, pressure, and flow conditions. By adjusting these parameters, carbonation efficiency can be maximized, producing a higher concentration of CO2 in the liquid.
Temperature is a key factor in CO2 solubility. In this case, the CO2 gas and the liquid are cooled to 20°C. Lower temperatures enhance...
Navier–Stokes Equations01:28

Navier–Stokes Equations

For incompressible Newtonian fluids, where density remains constant, stresses show a linear relationship with the deformation rate, defined by normal and shear stresses. Normal stresses depend on the pressure exerted on the fluid and the rate of deformation in specific directions, which determines how fluid flows under varying pressures. Shear stresses, on the other hand, act tangentially across fluid layers. They explain how adjacent fluid layers slide relative to one another, connecting...
Typical Model Studies01:30

Typical Model Studies

Fluid mechanics model studies often utilize scaled-down systems to predict fluid behavior in full-scale environments, such as river flows, dam spillways, and structures interacting with open surfaces. Maintaining Froude number similarity in river models is crucial, as it replicates surface flow features like wave patterns and velocities.
Turbulent Flow01:24

Turbulent Flow

Turbulent flow is characterized by unpredictable fluctuations in velocity and pressure, which result in a chaotic fluid movement distinct from the orderly patterns of laminar flow. While laminar flow is governed by smooth, parallel layers with minimal mixing, turbulent flow exhibits highly irregular, three-dimensional patterns. This behavior arises due to instabilities in the fluid's velocity profile, and amplifies as the flow velocity increases. Minor disturbances, known as turbulent spots,...
Couette Flow01:22

Couette Flow

Couette flow represents the flow of fluid between two parallel plates, with one plate fixed and the other moving with a constant velocity. This configuration allows for a simplified analysis using the Navier-Stokes equations, which govern fluid motion under conditions of viscosity and incompressibility. For Couette flow, the assumptions include a steady, laminar, incompressible flow with a zero-pressure gradient in the flow direction. This flow type is beneficial for understanding shear-driven...

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Related Experiment Video

Updated: Jun 22, 2026

Three-dimensional Particle Tracking Velocimetry for Turbulence Applications: Case of a Jet Flow
13:02

Three-dimensional Particle Tracking Velocimetry for Turbulence Applications: Case of a Jet Flow

Published on: February 27, 2016

Applied large eddy simulation.

Paul G Tucker1, Sylvain Lardeau

  • 1Whittle Laboratory, Department of Engineering, University of Cambridge, Cambridge CB2 1PZ, UK. pgt23@cam.ac.uk

Philosophical Transactions. Series A, Mathematical, Physical, and Engineering Sciences
|June 18, 2009
PubMed
Summary
This summary is machine-generated.

Large eddy simulation (LES) offers detailed flow physics as an alternative to Reynolds-averaged Navier-Stokes (RANS) methods. Its wider industrial adoption requires hybrid approaches and sector-specific models, balancing cost and accuracy.

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Area of Science:

  • Computational Fluid Dynamics
  • Turbulence Modeling

Background:

  • Reynolds-averaged Navier-Stokes (RANS) methods are standard industrial practice.
  • Large eddy simulation (LES) offers superior flow physics detail but incurs higher computational costs.
  • Industry is increasingly adopting advanced computational modeling techniques.

Purpose of the Study:

  • To assess the current capabilities and limitations of LES for industrial practitioners.
  • To explore the application-specific use of LES across diverse fields.
  • To identify pathways for increased industrial adoption of LES technology.

Main Methods:

  • Review of LES models and flow-governing equations.
  • Analysis of errors inherent in LES.
  • Consideration of hybrid RANS-LES approaches.
  • Examination of modeling importance relative to boundary conditions and problem definition.

Main Results:

  • LES provides attractive flow physics detail but is currently cost-prohibitive for widespread industrial use.
  • Hybrid LES/RANS methods are identified as a pragmatic approach for industrial impact.
  • Development of industry-specific model parametrizations is crucial.
  • Successful industrial uptake requires expertise in numerical modeling, turbulence, and computer science.

Conclusions:

  • The industrial application of LES necessitates pragmatic hybrid strategies combining LES, implicit LES, and RANS elements.
  • Further development of sector-specific model parametrizations is essential for LES to address key design parameters.
  • Achieving broader industrial adoption of LES requires a multidisciplinary approach integrating technical expertise, pragmatism, and computational advancements.