On the early development of dispersion in flow through a tube with wall reactions

Lau, Mei-wan., 劉美雲.

January 2007

published_or_final_version / abstract / Mechanical Engineering / Master / Master of Philosophy

Dispersion - Mathematical models.

Fluid dynamics.

Mechanics of viscoelastic mud under water waves

Zhang, Xueyan, 張雪岩

January 2006

The Best M.Phil Thesis in the Faculties of Dentistry, Engineering, Medicine and Science (University of Hong Kong), Li Ka Shing Prize,2005-2006 / published_or_final_version / abstract / Mechanical Engineering / Master / Master of Philosophy

Fluid dynamics

Mudflows.

Water waves.

Modelling fluid flow and heat transfer in some volcanic systems

Kent, Russell Malcolm

January 1995

No description available.

551.21

Lava flow fluid dynamics

Chemical equilibria and fluid flow during compaction diagenesis of organic-rich geopressured sediments.

Capuano, Regina Marie.

January 1988

The effects of geopressuring and kerogen decomposition on mineral-fluid equilibria were calculated in order to predict the diagenetic-alteration mineralogy produced in equilibrium with kerogen-rich, geopressured sediments. These calculations indicate that several processes specific to kerogen-rich geopressured sediments contribute to the development of a characteristic alteration mineralogy. These processes are: (1) the upward flow of fluids in geopressured sediments, in contrast to the generally downward flow of fluids in normally-pressured sediments; (2) the coincidence of the depths of geopressuring (2-3 km; Fertl et al., 1976), with the geothermal temperatures necessary for CO₂ release (100°-135°C; Hunt, 1979), and CH₄ release (>90°C; Hunt, 1979); and (3) the opposing rates of sediment burial and CO₂ and CH₄ transfer into the upward-flowing fluids, which result in the geopressured pore fluids becoming enriched, and in some cases saturated, with respect to CO₂ and CH₄. Three patterns of mineral deposition during diagenesis of kerogen-rich geopressured sediments are predicted. Quartz deposition should occur at the top of the geopressured zone and decrease rapidly with increased depth as a result of the decreased flux of upward fluid flow with increased depth. Carbonate deposition should occur above the zone of CO₂ release from kerogen degradation as a result of the upward flux of CO₂ saturated fluids and subsequent decreases in fluid temperature, pressure and CO₂ solubility. Kaolinite-carbonate could deposit within and above the zone of CO₂ release from kerogen as a result of silicate dissolution by CO₂-rich acid pore fluids, followed by the potential for albite-carbonate deposition upon CO₂ depletion. In contrast, laumontite and anhydrite should not deposit during diagenesis of kerogen-rich geopressured sediments, but could deposit during diagenesis of normally-pressured or kerogen-poor geopressured sediments. An additional difference between these diagenetic environments is that quartz deposition would not be expected in normally-pressured sediments in which fluids are expected to be flowing downward. These mineralogic relationships compare favorably with observed relationships in the kerogen-rich geopressured sandstones of the Frio formation from the Texas Gulf Coast.

Sediment compaction.

Fluid dynamics.

Kerogen.

Enhanced design performance prediction methods for rudders operating downstream of a propeller

Smithwick, Jason Edward Thomas

January 2000

No description available.

623.8

High bandwidth aerodynamic measurements in gas turbine stages

Thomas, C. C.

January 1999

No description available.

621.4352

Computational fluid dynamics; CFD

Degeneracy in acoustic resonance

Peake, M. R.

January 1993

No description available.

534

Nonlinear resonance in fluid dynamics

Aspects of finite volume method for compressible flows

Kolibal, Joseph

January 1989

No description available.

510

Numerical methods][Fluid dynamics

A parallel programming environment for multigrid using BSP

Osoba, Babafemi O.

January 1999

No description available.

005

Computational fluid dynamics; Algorithms

Computational analysis of flow through a transonic compressor rotor

Bochette, Nikolaus J.

09 1900

Approved for public release, distribution unlimited / As the United States Navy prepares to field a single engine jet, the F-35C Joint Strike Fighter, it is important that the causes of the .pop-stall. occurrence be understood. This problem arises as the jet engine ingests steam just prior to being released from the catapult. In examining this problem two Computational Fluid Dynamic (CFD) codes have been used by the Naval Postgraduate School to predict the performance of a transonic compressor rotor that is being tested with steam ingestion. Both codes, developed by NASA, provide a baseline that experimental results and new CFD codes can be compared with. Ansys Inc., a commercial Computer Aided Design (CAD) software company, has developed a new code that allows modeling of two phase flow. ICEM-CFD and CFX-5, both Anys Inc. programs that can model turbomachinery blade passages similar to that used by the NASA codes, were used in the present study. Comparisons were made with the experimental data and the predictions made by NASA codes as part of the initial modeling of the transonic compressor rotor flow field.

Mechanical engineering

Computational fluid dynamics