MASS TRANSFER IN DENSE GAS EXTRACTION USING A HOLLOW FIBER MEMBRANE CONTACTOR

GABELMAN, ALAN

January 2003

No description available.

Engineering, Chemical

membrane contactor

finite element method

supercritical fluid

dense gas

mass transfer

EFFECTS OF MASS-TRANSFER AND KINETIC PARAMETERS ON <i>BURKHOLDERIA CEPACIA</i>LIPASE IMMOBILIZED IN ORDERED MESOPOROUS SBA-15 HOSTS IN A PACKED-BED REACTOR

JALADI, HEMACHAND

02 October 2006

No description available.

Engineering, Chemical

BC Lipase

SBA-15

Mass-transfer limitations

Modeling and simulation

Computational Modeling of Heat and Mass Transfer in Planar SOFC: Effects of Volatile Species/Oxidant Mass Flow Rate and Electrochemical Reaction Rate

VENKATA, PADMA PRIYA

22 April 2008

No description available.

Mechanical Engineering

SOFC

Solid oxide fuel cells

ASR

interconnect

CFD

heat and mass transfer

electrochemistry

CO2 Separation from Coal-Fired Power Plants by Regenerable Mg(OH)2 Solutions

Cheng, Lei

16 September 2013

No description available.

Environmental Engineering

CO2 capture

coal-fired power plant

bubble column reactor

TCA

magnesium hydroxide

mass transfer

Dependence of Film Cooling Effectiveness on 3D Printed Cooling Holes

Aghasi, Paul P.

06 June 2016

No description available.

Aerospace Materials

Film Cooling

Heat transfer

mass transfer

pressure sensitive paint

roughness

3D printing

Development of an integrated information model for computer integrated manufacturing

Dreer, Pascal

January 1995

No description available.

Engineering, Industrial

Computer Integrated Manufacturing

Computer Aided Engineering

CO2 Mass Transfer in a Novel Photobioreactor

Mielnicki, Adam

03 October 2011

No description available.

Chemical Engineering

falling film mass transfer

photobioreactor

falling film thickness measurement

Hydrodynamics and mass transfer studies in high pressure gas-liquid and gas-liquid-solid fluidization

Lau, Wai Man

January 2003

No description available.

Engineering, Chemical

Hydrodynamics

Mass Transfer

Fluidization

Slurry bubble Column

High Pressure

Characterization of hydrodynamic forces and interfacial phenomena in cell culture processes

Hu, Weiwei

05 January 2007

No description available.

Engineering, Chemical

Mammalian cell culture

Microalgae cell culture

Hydrodynamic forces

Surfactants

Mass transfer

Characterization of local mass transfer rate downstream of an orifice

Wang, dongdong

10 1900

<p>Flow accelerated corrosion(FAC) results in wall thinning of pipes, tubes or vessels from exposure to flow due to corrosion. If FAC is not detected, it can lead to sudden failure of piping components. Orifices are used in piping systems to monitor and control the flow. Flow separation and reattachment downstream of an orifice can enhance the mass transfer of the pipe wall. In this thesis, the effect of Reynolds numbers and surface roughness on the mass transfer rate downstream of an orifice was investigated. A dissolving wall method was used to measure the wall mass transfer. The test sections were cast from gypsum with water as the working fluid. Multiple destructive tests were performed for different test times in a 2.5 cm diameter flow loop, and the wear topology measured by a laser scanner to obtain the progression of wear with time over the pipe surface. None-destructive tests were performed in a 20 cm diameter flow loop using test section with an inner gypsum lining, and measured online at selected locations using an ultrasonic method. Experiments were performed at Reynolds numbers of 80000, 140000 and 200000 in the 2.5 cm diameter flow loop, and at 180,000 in the 20 cm diameter flow loop with an orifice to pipe diameter ratio of 0.5. The results show that different surface roughness patterns are developed at different Reynolds numbers from the initially smooth surfaces. The different surface roughness patterns have a significantly different effect on the mass transfer rate downstream of an orifice. A larger population of scallops developed from the smooth pipe surface, as the Reynolds number was increased, which enhanced the mass transfer rate. The mass transfer rate in the 20 cm diameter test section was much smaller than in the 2.5 cm diameter test section at a similar Reynolds number. The pattern of the roughness in the 20 cm diameter test section was formed as isolated roughness which is similar to the roughness pattern in 2.5 cm diameter test section at much lower Reynolds number.</p> / Master of Applied Science (MASc)

mass transfer

orifice

flow accelerated corrosion

Nuclear Engineering

Transport Phenomena

Nuclear Engineering