Computational Fluid Dynamics - Fall 2003 The syllabus Term project CFD references (Text books and papers) Course Tools Course Web Site: Blackboard Computing Facilities available to the class (accounts info will be provided) SOM Metlab workstations and OSCER ( IBM Supercomputerhttp://oscer.ou.edu Unix and Fortran Helps – Consult Links at CFD Home page
Introduction – Principle of Fluid Motion 1.Mass Conservation 2.Newton’s Second of Law 3.Energy Conservation 4.Equation of State for Idealized Gas These laws are expressed in terms of mathematical equations, usually as partial differential equations. Most important equations – the Navier-Stokes equations
Approaches for Understanding Fluid Motion Traditional Approaches Theoretical Experimental Newer Approach Computational - CFD emerged as the primary tool for engineering design, environmental modeling, weather prediction, among others, thanks to the advent of digital computers
Theoretical FD Science for finding usually analytical solutions of governing equations in different categories and studying the associated approximations / assumptions; h = d/2,
Experimental FD Understanding fluid behavior using laboratory models and experiments. Important for validating theoretical solutions. E.g., Water tanks, wind tunnels
Computational FD A Science of Finding numerical solutions of governing equations, using high-speed digital computers
Why Computational Fluid Dynamics? Analytical solutions exist only for a handful of typically simple problems Much more flexible – each change of configurations, parameters Can control numerical experiments and perform sensitivity studies, for both simple and complicated problems Can study something that is not directly observable (black holes). Computer solutions provide a more complete sets of data in time and space than observations of both real and laboratory phenomena
Why Computational Fluid Dynamics? - Continued We can perform realistic experiments on phenomena that are not possible to reproduce in reality, e.g., the weather Much cheaper than laboratory experiments (e.g., crash test of vehicles, experimental launches of spacecrafts) May be much environment friendly (testing of nuclear arsenals) We can now use computers to DISCOVER new things (drugs, sub ‑ atomic particles, storm dynamics) much quicker Computer models can predict, such as the weather.
An Example Case for CFD – Thunderstorm Outflo/Density Current Simulation
Thunderstorm Outflow in the Form of Density Currents
=1 =-1 Negative Internal Shear Positive Internal Shear
=1 =-1 Negative Internal Shear Positive Internal Shear T=12 No Significant Circulation Induced by Cold Pool
Simulation of an Convective Squall Line in Atmosphere Infrared Imagery Showing Squall Line at 12 UTC January 23, ARPS 48 h Forecast at 6 km Resolution Shown are the Composite Reflectivity and Mean Sea-level Pressure.
Difficulties with CFD Typical equations of CFD are partial differential equations (PDE) that requires high spatial and temporary resolutions to represent the originally continuous systems such as the atmosphere Most physically important problems are highly nonlinear ‑ true solution to the problem is often unknown therefore the correctness of the solution hard to ascertain – need careful validation! It is often impossible to represent all relevant scales in a given problem ‑ there is strong coupling between scales in atmospheric flows and most CFD problems. ENERGY TRANSFERS
Difficulties with CFD The initial condition of a given problem often contains significant uncertainty – such as that of the atmosphere We often have to impose nonphysical boundary conditions. We often have to parameterize processes which are not well understood (e.g., rain formation, chemical reactions, turbulence). Often a numerical experiment raises more questions than providing answers!!
POSITIVE OUTLOOK New numerical schemes / algorithms Bigger and faster computers Faster network Better desktop computers Better programming tools and environment Better visualization tools Better understanding of dynamics / predictabilities etc.