CFD has become an essential tool to predict fluid motion
complicated with phenomena such as turbulence, heat and
mass
transfer, phase change, movement of boundaries, etc. CFD is
now routinely used and has become an invaluable tool for
design and analysis of complicated engineering systems and
complex flow problems in aerospace, automotive, chemical,
electronics, environmental, biomedical, and host of other
industries. CFD provides the ability to visualize and
understand complicated flow phenomena and the dynamical
behavior for systems that are too expensive or difficult to
prototype.
CFD is highly interdisciplinary and is the fusion of three
major and distinct disciplines of engineering (fluid
dynamics), applied mathematics, and computer science. In
the
past decade, the proliferation of commercial CFD software
has significantly reduced the need for a deep knowledge of
mathematics and computer science for application of CFD.
Conversely, this proliferation has resulted in significant
interests by analysts and organization not traditionally
involved or heavily experienced in the field of fluid
dynamics. Furthermore, if past trend is any indication, CFD
will continue to be considered for problems that are far
more challenging and complex than before and its use will
grow in industrial arenas not traditionally known for their
fluid problems.
The reduced need for expert knowledge in mathematics and
computer science to use CFD in addition to proliferation of
CFD ensures that more organizations and newer analysts
would
embark on using CFD in their design and analysis processes.
It is then imperative that these new organizations and
analysts know and understand the physical principles of
fluid dynamics in addition to acquiring working knowledge
of
CFD. A thorough understanding of principles, theories, and
assumption in fluid dynamics is paramount for the
effective,
proper, and optimized use of the CFD tool.
The Course
This course offers the attendees the fundamental knowledge
for using CFD in real life engineering applications.
Through
a simple and moderately technical approach mixed with real
world problems, this course describes the steps in the CFD
process and provides benefits and issues for using CFD
analysis in understanding of complicated flow phenomena and
its use in the design process. It also includes the
governing principles and important concept of fluid
dynamics
to help understand the physical principles behind CFD for
its correct and effective use. Turbulence modeling,
computational heat transfer, and multiphase modeling will
be
introduced and choices will be discussed in this course.
The
course will also include best practices for reducing errors
and uncertainties in CFD analysis
The course is completely software independent. Attendees
are
welcome to bring laptops to take notes, but they are not
required. A full set of printed and bound notes will be
issued to every attendee.
Who Should Attend?
The target audience for this course is engineers and
managers who are interested or are considering to
incorporate CFD in their design practices in the most
effective manner. This course is ideally suited for
practicing engineers with limited knowledge of CFD or in
need of refresher who wish to learn more about how to
choose
and effectively apply methodologies, schemes, and
techniques
in their CFD analysis. The material that is presented is
independent of any particular software package, making it
ideally suited to current and potential users of all
commercial and non-commercial CFD software systems. Active
participation, interaction, and questions are encouraged
throughout the course to create a unique experience for
each
attendee.
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