Vibration-Induced Rectified Motion of a Piston in a Liquid-Filled Cylinder with Bellows to Mimic Gas Regions
Abstract not provided.
Publications
Simulating Rectified Motion in a Piston Assembly Subjected to Vibrational Acceleration
Abstract not provided.
Resonance of a Vibrated Liquid-Filled Piston-Bellows System
Physics of Fluids
Abstract not provided.
Faraday Waves Excited by Random Vibration
Abstract not provided.
Motion of a Bellows and a Free Surface in a Closed Vibrated Liquid-Filled Container
Abstract not provided.
Experimental Study of Stable Levitation of Bubbles in Vertically Vibrating Liquids
Abstract not provided.
BEHAVIOR OF LEVITATED BUBBLES UNDER VIBRATION
Abstract not provided.
Multiscale Modelling of Nuclear Waste Reprocessing
Abstract not provided.
Bubble Oscillations and Motion under Vibration
Proposed for publication in Physics of Fluids.
Abstract not provided.
Mesoscale to plant-scale models of nuclear waste reprocessing
Imported oil exacerabates our trade deficit and funds anti-American regimes. Nuclear Energy (NE) is a demonstrated technology with high efficiency. NE's two biggest political detriments are possible accidents and nuclear waste disposal. For NE policy, proliferation is the biggest obstacle. Nuclear waste can be reduced through reprocessing, where fuel rods are separated into various streams, some of which can be reused in reactors. Current process developed in the 1950s is dirty and expensive, U/Pu separation is the most critical. Fuel rods are sheared and dissolved in acid to extract fissile material in a centrifugal contactor. Plants have many contacts in series with other separations. We have taken a science and simulation-based approach to develop a modern reprocessing plant. Models of reprocessing plants are needed to support nuclear materials accountancy, nonproliferation, plant design, and plant scale-up.
Jets, droplets, and cavities produced by vertically vibrating gas-liquid interfaces
Abstract not provided.
Physical Modeling of Scaled Water Distribution System Networks
Threats to water distribution systems include release of contaminants and Denial of Service (DoS) attacks. A better understanding, and validated computational models, of the flow in water distribution systems would enable determination of sensor placement in real water distribution networks, allow source identification, and guide mitigation/minimization efforts. Validation data are needed to evaluate numerical models of network operations. Some data can be acquired in real-world tests, but these are limited by 1) unknown demand, 2) lack of repeatability, 3) too many sources of uncertainty (demand, friction factors, etc.), and 4) expense. In addition, real-world tests have limited numbers of network access points. A scale-model water distribution system was fabricated, and validation data were acquired over a range of flow (demand) conditions. Standard operating variables included system layout, demand at various nodes in the system, and pressure drop across various pipe sections. In addition, the location of contaminant (salt or dye) introduction was varied. Measurements of pressure, flowrate, and concentration at a large number of points, and overall visualization of dye transport through the flow network were completed. Scale-up issues that that were incorporated in the experiment design include Reynolds number, pressure drop across nodes, and pipe friction and roughness. The scale was chosen to be 20:1, so the 10 inch main was modeled with a 0.5 inch pipe in the physical model. Controlled validation tracer tests were run to provide validation to flow and transport models, especially of the degree of mixing at pipe junctions. Results of the pipe mixing experiments showed large deviations from predicted behavior and these have a large impact on standard network operations models.3
12 Results