41 |
DEVELOPMENT OF A MULTISCALE AND MULTIPHYSICS SIMULATION FRAMEWORK FOR REACTION-DIFFUSION-CONVECTION PROBLEMSMishra, Sudib Kumar January 2009 (has links)
Reaction-diffusion-convection (R-D-C) problems are governed by wide spectrum of spatio-temporal scales associated with ranges of physical and chemical processes. Such Problems are called multiscale, multiphysics problems. The challenge associated with R-D-C problems is to bridge these scales and processes as seamlessly as possible. For this purpose, we develop a wavelet-based multiscale simulation framework that couples diverse scales and physics.In a first stage we focus on R-D models. We treat the `fine' reaction-scales stochastically, with kinetic Monte Carlo (kMC). The transport via diffusion possesses larger spatio-temporal scales which are bridged to the kMC with the Compound Wavelet Matrix (CWM) formalism. Since R-D-C problems are dynamical we extend the CWM method via the dynamic-coupling of the kMC and diffusion models. The process is approximated by sequential increments, where the CWM on each increment is used as the starting point for the next, providing better exploration of phase-space. The CWM is extended to two-dimensional diffusion with a reactive line-boundary to show that the computational gain and error depends on the scale-overlap and wavelet-filtering. We improve the homogenization by a wavelet-based scheme for the exchange of information between a reactive and diffusive field by passing information along fine to coarse (up-scaling) and coarse to fine (down-scaling) scales by retaining the fine-scale statistics (higher-order moments, correlations). Critical to the success of the scheme is the identification of dominant scales. The efficiency of the scheme is compared to the homogenization and benchmark model with scale-disparity.To incorporate transport by convection, we then couple the Lattice Boltzmann Model (LBM) and kMC operating at diverse scales for flows around reactive block. Such model explores markedly different physics due to strong interplay between these time-scales. `Small' reaction induced temperature variations are considered for multiscale coupling of the reactions with the flow, showing the discrepancies in the evolutions and yield comparing to the conventional model. The same framework is used to study the reactions induced by hydrodynamic bubble collapse which shows the similar features of the kinetics and yield comparing to conventional models.We culminate to some problems that could be solved using the developed framework and preliminary results are presented as "proof of concept."
|
42 |
Direct simulations of spherical particle motion in non-Newtonian liquidsPrashant, . Unknown Date
No description available.
|
43 |
Simulation of Combustion Field with Lattice Boltzmann MethodDoolen, Gary D., He, Xiaoyi, Yamamoto, Kazuhiro 04 1900 (has links)
No description available.
|
44 |
LB simulation on soot combustion in porous mediaTakada, Naoki, Yamamoto, Kazuhiro 03 1900 (has links)
No description available.
|
45 |
Lattice Boltzmann simulation on porous structure and soot accumulationMisawa, Masaki, Takada, Naoki, Yamashita, Hiroshi, Satake, Shingo, Yamamoto, Kazuhiro 09 1900 (has links)
No description available.
|
46 |
LATTICE BOLTZMANN SIMULATION ON FLOW WITH SOOT ACCUMULATION IN DIESEL PARTICULATE FILTERMISAWA, MASAKI, TAKADA, NAOKI, YAMASHITA, HIROSHI, SATAKE, SHINGO, YAMAMOTO, KAZUHIRO 04 1900 (has links)
No description available.
|
47 |
DPF内のすす堆積を考慮した流れの数値解析DAIDOU, Shigeki, YAMASHITA, Hiroshi, YAMAMOTO, Kazuhiro, OHORI, Shinya, 大道, 重樹, 山下, 博史, 山本, 和弘, 大堀, 晋也 January 2009 (has links)
No description available.
|
48 |
連続再生式ディーゼルフィルターにおけるすすの燃焼と堆積の数値解析YAMAMOTO, Kazuhiro, MATSUI, Kenta, 山本, 和弘, 松井, 健太 January 2010 (has links)
No description available.
|
49 |
Exploring the Epiphany manycore architecturefor the Lattice Boltzmann algorithmRaase, Sebastian January 2014 (has links)
Computational fluid dynamics (CFD) plays an important role in many scientific applications, ranging from designing more effective boat engines or aircraft wings to predicting tomorrow's weather, but at the cost of requiring huge amounts of computing time. Also, traditional algorithms suffer from scalability limitations, making them hard to parallelize massively. As a relatively new and promising method for computational fluid dynamics, the Lattice Boltzmann algorithm tries to solve the scalability problems of conventional, but well-tested algorithms in computational fluid dynamics. Through its inherently local structure, it is well suited for parallel processing, and has been implemented on many different kinds of parallel platforms. Adapteva's Epiphany platform is a modern, low-power manycore architecture, which is designed to scale up to thousands of cores, and has even more ambitious plans for the future. Hardware support for floating-point calculations makes it a possible choice in scientific settings. The goal of this thesis is to analyze the performance of the Lattice Boltzmann algorithm on the Epiphany platform. This is done by implementing and testing the lid cavity test case in two and three dimensions. In real applications, high performance on large lattices with millions of nodes is very important. Although the tested Epiphany implementation scales very good, the hardware does not provide adequate amounts of local memory and external memory bandwidth, currently preventing widespread use in computational fluid dynamics.
|
50 |
A novel lattice Boltzmann method for treatment of multicomponent convection, diffusion, and reaction phenomena in multiphase systems /Parker, James Muirhead. January 1900 (has links)
Thesis (Ph. D.)--Oregon State University, 2009. / Printout. Includes bibliographical references (leaves 220-225). Also available on the World Wide Web.
|
Page generated in 0.0739 seconds