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System-Level Computational Fluid Dynamics
 

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  image of simulation of explosive detonation in an urban center surrounded by four rigid buildings
 

Simulation of explosive detonation in an urban center surrounded by four rigid buildings

Advanced computational fluid dynamics (CFD) modeling and simulation tools have been developed, enhanced, and applied by Southwest Research Institute (SwRI) staff  to solve clients' problems for more than 20 years. In particular, the staff uses these computational tools to solve problems related to the operational conditions and states of large-scale engineered and natural systems.

 

CFD Capabilities

SwRI maintains and utilizes a suite of CFD software codes and computer resources to support modeling and simulation projects of widely different sizes and scopes to solve a broad spectrum of large-scale system problems such as:

  image of global circulation simulations for Earth (top) and Mars (bottom); contours display temperature fields at 300 km for Earth and 49 km for Mars
  image of global circulation simulations for Earth (top) and Mars (bottom); contours display temperature fields at 300 km for Earth and 49 km for Mars
 

Global circulation simulations for Earth (top) and Mars (bottom); contours display temperature fields at 300 km for Earth and 49 km for Mars

  • Large-scale system design and analysis

  • Explosive hazard analysis in and around complex structures

  • Hydraulic transient analysis in complex pipeline networks

  • External aerodynamic analysis for complete structures

  • Atmospheric dynamics for Earth and Mars

  • Airflow distribution in multiroom buildings and hangars

  • Chemical hazard and biohazard assessment in multiroom buildings and urban environments

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

  • Simulation of fate and transport in atmospheric and regional subsurface environments

image of simulation of airflow distribution in a paint hangar showing airflow streamline ribbons
image of Simulation of airflow distribution in a paint hangar showing airflow contours of velocity magnitude

Simulation of airflow distribution in a paint hangar showing airflow streamline ribbons (top) and contours of velocity magnitude (bottom)

 

image of aerodynamic simulation of a high-speed train showing contours of surface pressure

Aerodynamic simulation of a high-speed train showing contours of surface pressure

 

The Engineering Dynamics Department staff have 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.

 

image of simulation of explosive detonation in a hardened structure showing results for the actual structure   image of simulation of explosive detonation in a hardened structure showing results for an experimental facility with a structure designed to collect biological samples

Simulation of explosive detonation in a hardened structure showing results for the actual structure (left) and results for an experimental facility with a structure designed to collect biological samples (right). Video: Windows Media or QuickTime.


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.
  image of curvilinear grid system used in the six-degrees-of-freedom simulation of twin rockets
 

Curvilinear grid system used in the six-degrees-of-freedom simulation of twin rockets

 

SwRI is a member organization of Internet2.

 

Software

Source

NSC Codes

SwRI

FLOW-3D

Flow Science

Overflow

NASA

CTH

Sandia

Multiflo

SwRI

ASPEN

SwRI

HYTTAP

SwRI

PHAT-LPS

SwRI

 

Hardware

Capabilities

Linux Cluster 1

32 nodes, AMD Athlon XP/MP 1.6 GHz, 32 Gb RAM, 2.8 Tb Disk Farm

Linux Cluster 2

64 nodes, AMD Opteron 64 1.4 GHz, 128 Gb RAM, 2.3 Tb Disk Farm

Linux Cluster 3

32 nodes, AMD Opteron 64 1.4 GHz, 64 Gb RAM, 1.6 Tb Disk Farm

HP Workstations

180 to 450 MHz, 1 to 4 Gb RAM, 1 Tb Disk Farm

PC Workstations

2.4 to 3.2 GHz, 1 Gb RAM, 60 Gb

 

For more information about system-level 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.

 

Contact Information

Christopher Freitas, Ph.D., P.E.

System-Level CFD

(210) 522-2137

cfreitas@swri.org

Related Terminology

computational fluid dynamics

CFD

explosive hazard analysis

vehicle aerodynamics

hydraulic transient analysis

global circulation modeling

space weather

fluid-structure interaction

subsurface transport modeling

uncertainty analysis

numerical methods

algorithm development

parallel computing methods

nonlinear modeling and simulation

homeland security analysis

Related Information

image of System-Level Computational Fluid Dynamics flyer

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Southwest Research Institute® (SwRI®), headquartered in San Antonio, Texas, is a multidisciplinary, independent, nonprofit, applied engineering and physical sciences research and development organization with 12 technical divisions.

September 01, 2009