Mixing in Inland and Coastal WatersAcademic Press, 1979 - 483 halaman This book is an outgrowth of research contributions and teaching experiences by all the authors in applying modern fluid mechanics to problems of pollutant transport and mixing in the water environment. It should be suitable for use in first year graduate level courses for engineering and science students, although more material is contained than can reasonably be taught in a one-year course, and most instructors will probably wish to cover only selected potions. The book should also be useful as a reference for practicing hydraulic and environmental engineers, as well as anyone involved in engineering studies for disposal of wastes into the environment. The practicing consulting or design engineer will find a thorough explanation of the fundamental processes, as well as many references to the current technical literature, the student should gain a deep enough understanding of basics to be able to read with understanding the future technical literature evolving in this evolving field. |
Isi
Concepts and Definitions | 1 |
Fickian Diffusion | 30 |
Turbulent Diffusion | 55 |
Shear Flow Dispersion | 80 |
Mixing in Rivers | 104 |
Mixing in Reservoirs | 148 |
Mixing in Estuaries | 229 |
River and Estuary Models | 279 |
Turbulent Jets and Plumes | 315 |
Design of Ocean Wastewater Discharge Systems | 390 |
Appendix A An Estimator for the Density of Seawater | 443 |
Notation for Chapters 19 | 455 |
| 473 | |
Edisi yang lain - Lihat semua
Mixing in Inland and Coastal Waters Hugo B. Fischer,John E. List,C. Robert Koh,Jorg Imberger,Norman H. Brooks Pratinjau terbatas - 2013 |
Istilah dan frasa umum
advective ambient analysis approximately average bottom boundary buoyancy center of mass channel Chapter cloud concentration constant cross section cross-sectional crossflow defined density stratification depth diffusion equation dilution dimensional dimensional analysis dimensionless discharge distance distribution downstream effect effluent energy entrainment epilimnion estimate estuary example Figure fluid Froude number gradient halocline heat horizontal hydraulic hypolimnion inflow initial internal waves kinetic energy lake layer length scale line source m³/sec mass mean velocity mixing coefficient molecular diffusion motion numerical diffusion numerical model obtained ocean offtake one-dimensional outfall parameters particle physical model pipe port problem prototype ratio reservoir Reynolds number Richardson number river salinity scour shear flow shown in Fig solution stratification stream surface temperature thermal thermocline tidal cycle tracer transport transverse mixing turbulent mixing variable velocity velocity profile vertical mixing wave width wind әс дх