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Marine Wastewater Discharges from Multiport Diffusers. II: Unstratified Flowing Water |
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| Authors: | Xiaodong Tian Philip J W Roberts Gregory J Daviero |
| Affiliation: | 1Postdoctoral Researcher, School of Civil and Environmental Engineering, Georgia Institute of Technology, Atlanta, Georgia, 30332. 2Professor, School of Civil and Environmental Engineering, Georgia Institute of Technology, Atlanta, Georgia, 30332. 3Malcolm Pirnie, Inc., 104 Corporate Park Dr., White Plains, NY 10602-0751 |
| Abstract: | Laboratory experiments on the near-field mixing of buoyant plumes discharged from multiport diffusers into unstratified flowing water are reported. The spatial variation of dilution was measured by a newly developed three-dimensional laser-induced fluorescence system and a microconductivity probe. The near-field hydrodynamics are complex. The plumes discharged upstream dilute and merge more rapidly than those discharged downstream. Even with wide port spacing, the plumes eventually merge to form a laterally uniform surface wastefield. The density profile in this wastefield becomes gravitationally stable and suppresses mixing, marking the end of the near field. The value of the port spacing ratio, s/H, below which the discharge approximates a line plume is greater for discharge into a flowing current than into a stationary environment, so the port spacing plays a lesser role in a flowing current. The mixing and dilution that occurs in the surface layer is less than for a discharge into a stationary environment, and it decreases as the current speed increases. Semiempirical equations to predict the major near field characteristics are presented. |
| Keywords: | Ocean disposal Outfall sewers Wastewater disposal Model studies Dilution Multi-port diffuser |