Two aspects of the modelling of suspended sediment transport are investigated. One
is the development of a theoretical base for sediment transport models starting from
the continuum theory of immiscible mixtures (also know as two-phase flow theories).
The other is a comparison with experimental data of numerical predictions from a
number of turbulence models for oscillatory, turbulent boundary layer flow containing
suspended sediment.
A review is given of previous work that has applied continuum mixture theories
to the field of sediment transport. Turbulent averaged forms of the mixture equations
are presented and, in the dilute particle concentration limit and neglecting the
effects of particle inertia, the equations are shown to reduce to those encountered in
traditional approaches to modelling suspended sediment concentrations. Likewise,
the equations governing the motion of the fluid phase reduce to standard forms,
with the effect of the sediment particles appearing as a buoyancy term in the fluid
momentum equation. Particle inertia is taken into account by expanding in terms
of a non-dimensional parameter, the ratio of the response time of the particle to a
characteristic time of the flow. Terms arising from particle inertia are then reduced
to correlations for which models are available in the literature. The assumption of
dilute particle concentrations is made throughout the derivation.
An extensive comparison between a number of turbulence models is made by comparing
numerical predictions with experimental data, whilst making the conventional
assumption of zero particle inertia. The k - c model was found to perform well, with
simpler models also giving reasonable agreement with experiment. Also investigated
is the sensitivity of the solution to a number of factors, including: boundary conditions,
empirical turbulence constants, and the stratifying effect of the suspended
sediment.
The effect of including terms associated with particle inertia are investigated in
turbulent oscillatory boundary layer flows. This is found to lead to an enhancement
of the vertical particle volume flux. However, given the uncertainties of specifying
the boundary condition for the concentration at the bed, the effect is probably not
of significance for small particles (diameter - 0.1 mm). Larger particles (diameter
0.25 mm) show more significant effects due to their inertia. The difference in
mean horizontal velocity between the fluid and particle phases which results from the
inclusion of inertia in the particle momentum equations is calculated. This difference
is found to be very small.
Date of Award | 1990 |
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Original language | English |
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Awarding Institution | |
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A CONTINUUM MIXTURE THEORY APPROACH TO SEDIMENT TRANSPORT WITH APPLICATION TO TURBULENT OSCILLATORY BOUNDARY LAYERS
ALDRIDGE, J. N. (Author). 1990
Student thesis: PhD