SwRI: Computational Fluid Dynamics. SwRI has discovered the underlying physical processes that control a system's response.

Staff have been developing, enhancing, and applying advanced computational fluid dynamics (CFD) simulation tools at Southwest Research Institute (SwRI) to solve clients' problems for more than 20 years.

To discover the underlying physical processes that control a system's response, the SwRI staff has internationally recognized expertise in:

• Algorithm development

• Modeling and simulation of a broad range of applied engineering problems

• Fundamental analyses

	Evaluation of different numerical methods; unbounded versus bounded convective schemes

	Aerodynamic simulation of airflow distribution around an aircraft during a pitching maneuver; wake region of aircraft is visualized by streamline ribbons.
	Simulation of detonation of a condensed explosive in a rigid, liquid-filled structure. Pressure field spatial distribution is visualized by contour surfaces.

The staff utilizes a suite of CFD codes and computer resources to solve a broad spectrum of problems such as:

• First-principles analysis of complex fundamental flows

• Multiphase flow in complex pipeline systems with phase change

• External aerodynamic analysis for a range of body shapes

• Atmospheric dynamics for Earth and Mars

• Turbomachinery flows analyzing stall and surge characteristics

• Turbulent mixing of chemical species with reaction kinetics

• Explosive hazard analysis for dispersed phase mixtures

• Fluid-structure interaction with six-degrees-of-freedom dynamics

• Simulation of subsurface flow through porous and fractured materials

• Turbulent flows accounting for cavitation and phase change

• Particle and droplet dynamics

The Engineering Dynamics Department staff has the expertise to develop, enhance, and apply CFD codes to existing or new classes of problems that clients may need to address and can accomplish this within the client's cost and schedule constraints. An integrated approach using physical experiments, numerical simulations, and analytical methods is routinely employed to investigate and solve complex nonlinear fluid flow and heat transfer problems.

Simulation of the breakup of a liquid jet streaming into a quiescent air volume.		Simulation of surge onset in a centrifugal compressor impeller inlet duct, showing overall geometry with a cut plane revealing the 14-inlet ducts (left) and velocity field distribution in one inlet duct (right)
Illustration of parallel performance for a computer code on different parallel computers.		Simulation of development of a fuel/air plume with low density fuel (top) and higher density fuel (bottom) released from a tank. Contours display the yield potential within the plume.

 

 

Computational Fluid Dynamics Capabilities

SwRI maintains a suite of CFD software and computer resources that provide a broad foundation to support modeling and simulation projects of widely different sizes and scope.

SwRI is a member organization of Internet2.

For more information about computational fluid dynamics capabilities at SwRI or how you can contract with SwRI, please contact Christopher Freitas, Ph.D., P.E., at cfreitas@swri.org or (210) 522-2137.