Structure and shocks in turbulence

Kevlahan, Nicholas Keville-Reynolds

January 1994

No description available.

532

Turbulent flow

Turbulence and transition modelling in turbomachinery flows

Birch, N. T.

January 1987

No description available.

532

Turbulent flow modelling

Shear-free turbulence and secondary flow near angled and curved surfaces

Wong, H. Y. W.

January 1985

Turbulence near rigid surfaces is studied in the absence of any gradients in the mean velocity. The theory is valid either when the turbulence is convected downstream along a surface or for a short time after the turbulence is turned on.

532

Turbulent flow in ducts

Quantitative methods for the measurement and monitoring of mixing flows using a computer vision system

Novak, Matej

January 2001

No description available.

532

Turbulent flow; Visualisation

Numerical study of three-dimensional flow using fast parallel particle algorithms

Pringle, Gavin J.

January 1994

No description available.

532

Turbulent flow

Computation and measurement of turbulent flow through idealized turbine blade passages

Loizou, Panos A.

January 1989

No description available.

532

Turbulent flow in turbines

Predictions of wave and tidally induced oscillatory flows with Reynolds stress turbulence models

Waywell, M. N.

January 1995

No description available.

551.46

Turbulent flow equations

Polymer adsorption and flocculation of particles in turbulent flow

Wigsten, Anders L.

01 June 1983

No description available.

Flocculation

Polymers

Turbulent flow

A numerical and experimental study of open-channel flow in a pipe of circular cross-section with a flat bed

Hoohlo, Changela

January 1994

Uniform open-channel flow in a pipe of circular cross-section with a flat bed, is studied by experiment and numerical modelling. A pipe of diameter D= 305 nun, and mild bed slopes So = 4.63 x 10-4and 9.27 x 10-4was, studied - the former slope only by experiment. The bed thicknesses( e), e/D = 0.141, and 0.285 were studied experimentally and numerically, with e/D = 0.020, studied only numerically. Five flow depths (Y. ) were studied; (Y. +e)/D = 0.3,0.4 (and 0.416), 0.5,0.667, and 0.751. A smooth bed and bed roughnessesd,5 o= 0.93,4.20, and 1.71 mm were also used. Mono-chromatic Laser Doppler Anemometry (ILDA) was used to measure the local mean longitudinal (primary), and vertical velocities, and their respective turbulence intensifies. The primary velocity contours display dipped maxima and bulging towards the comer. The inwardly-curving side-walls slightly modify these contours. In each channel half there is a surface cell and a bottom cell. These move high momentum fluid away from the centreline towards the comer zone. The primmy and secondary flows are largely similar to those in rectangular channels. The wall shear force ratios obtained by the Vanoni-Brooks separation technique follow the empirical trend from various channel types. Similarity laws for the longitudinal mean velocity in the comer-influenced zones are proposed. The numerical model is based on the SIMPLE technique, and computes the flow on a Cartesian grid, using a non-linear k-e turbulence model with wall functions. The model boundary conditions were modified to reflect the effects of the comers, the curved side-wall, and a roughened bed. Model predictions of the primary mean velocities, and centreline turbulence intensities, are close to the experimental and empirical distributions. Primary velocity predictions for e/D = 0.020 compare well to the case of a clear pipe flowing part-fiffl. The predicted secondary flows are largely similar to the experimental patterns. Usage of a small mesh size (e. g. when (YO + e)/D < 0.5) results in side-wall points lying within the larninar sublayer, leading to inaccurate secondary flow prediction by the k-e model. As in rectangular channels, the predicted local boundary shear stress decreases from the centreline along the bed and minimises at the comer. On the side-walls, the model overpredicts the local boundary shear stresses. Nonetheless, computed wall shear force ratio values follow the empirical trend.

532

Turbulent flow

Gas mixing processes in nuclear AGR boilers

Khan, Mohammed Khurshid

January 1988

No description available.

532

Turbulent flow in boilers