Subham Sett
Engineering Specialist
Simulia
Providence, R. I.
Multiphysics
is used in industry to simulate
airplane-wing flutter,
underwater shock effects
on naval structures,
and so on. Improved
software technology and
rising hardware capacity
now allow the simulation
of many such real-world
problems.
FSI (fluid-structure interactions)
is a class of
multiphysics that studies the effects
of fluid flow on structures
and subsequent interactions. Primary
fields that interact across
domains are pressures for fluid
and displacements for structure.
Problems where thermal effects
are significant also involve an
additional temperature field in
both domains. Besides primary
fields there are secondary fields,
such as piezoelectric effects in
the structural domain and cavitation
effects in the fluid domain,
that indirectly contribute to fluidstructure
interaction.
What is called the partitioned
approach to FSI provides the most
general-purpose technique. In
Abaqus FEA software, for example,
a partitioned or cosimulation approach
can be used to solve complex
FSI analyses by coupling the
program to external computationfluid-
dynamics (CFD) solvers. In
this scheme, Abaqus and the external
solver run concurrently and
solve structural and fluid equations
independently while exchanging
converged solution quantities at
the fluid-structure interface.
Communication is critical
Seamless communication between
FEA and CFD is critical to the
coupled approach because the programs
are likely running on remote
systems or different hardware.
Communication takes place with either an independent coupling
or a direct-coupling interface. The
recently introduced Simulia multiphysics
program supports both.
Deciding which to use depends
on how far
the analysis
needs to go
to get needed
results — in
other words,
traditional
engineering
insight. Each
coupling
has certain
advantages.
For example, an
independent
coupling such as MpCCI (the Meshbased
parallel Code Coupling Interface),
a code-coupling interface
from the Fraunhofer SCAI in Germany,
provides flexibility by letting
users link Abaqus to CFD code
they may already have. MpCCI
also works with Star-CD from CD-adapco
and Fluent from Ansys. The
independent-coupling approach
helps foster collaboration between
existing FEA and CFD engineering
groups.
Use of the Simulia Direct Coupling
Interface (DCI), on the other
hand, provides a tighter integration
between Abaqus and certain
third-party CFD solvers, without
requiring additional software components.
This approach comes in
handy for FEA engineering groups
who must solve FSI problems on
their own. The direct coupling became
available with Abaqus Version
6.7 and works with AcuSolve
CFD software from Acusim.
Although this discussion focuses
on FSI, it is worth noting that
either approach works with other
external physics solvers as well.
Another helpful element comes
into play here. An FSI module available
as a plug-in to Abaqus provides
a user-friendly way to manage the
FSI workflow. The workflow is standardized
regardless of the CFD code
used and includes these steps: define
the CFD model, interactions,
and properties, run the analysis,
and postprocess the solution.
Analysis of a peristaltic pump
A good example of an FSI problem
comes from the analysis of a peristaltic pump. The pumps
are used in a wide array of industries,
pumping everything
from clean or sterile fluids in
biomedical devices to corrosive
fluids in chemical-processing
applications.
The first step to running an
analysis is a single Abaqus/
CAE database with two models:
one for the flexible hose
and the relevant pump structural
parts, the other for the
corresponding fluid region.
The structural model is fully
defined and set up to run as
an Abaqus/Explicit analysis.
A mesh is also generated for the
fluid model. Basic CFD settings for
the fluid model will be provided in
the FSI module.
The overall FSI model is defined
in what is called the Study. Here
users select the CFD code, identify
the coupling step in the structural
model, and define the basic CFD
model by specifying material type
and boundary conditions. The fluid
model data is then written in a format
supported by the selected CFD
code. The appropriate CFD preprocessor
launches and users can then
define the rest of the CFD model.
The next step associates the
structural and the fluid models. A
“Create Interaction” dialogue box
lets users select from the list of regions
in the structural model (for
example, the hose exterior and
interior), and in the fluid model
(for example, blood flow in, flow
out, and wall boundary) that can
be coupled. Next comes using a
“Create Interaction” property to
select solution quantities. Users
then define coupling specifics such
as time-step values. MpCCI users can specify additional settings for
the coupling. The analysis is then
executed.
Solution results are postprocessed
in the Visualization module
of Abaqus. Fluid data is extracted
in the Abaqus output database
format and viewed in conjunction
with structural results. Coupled results
illustrate the pumping action
of the pump.
Beyond couplings
A partitioned approach as illustrated
by the FSI solution above is
an excellent tool for solving a wide
range of multiphysics problems.
But it has limitations. For example,
numerical distortions can happen
when handling interfaces in the
structural domain that include extreme
contact, severe deformation,
and damage or failure.
An example of such a problem
comes from the sloshing of liquid
inside a tanker that is hit by an outside
force. What is the maximum
impact load the tanker can withstand?
The liquid is responsible for
a significant portion of the container
loading, and any severe deformation
of the tank can lead to rupture
and potential spillage. The event is
thus highly dynamic and requires
studying progressive damage and
failure of the interface material.
To tackle problems like this,
a coupled Eulerian-Lagrangian
(CEL) method is being developed
in Abaqus/Explicit. CEL uses multimaterial
finite-element formulations
to handle the structure and
simple fluids behavior, in a single
framework. It thus alleviates requirements
for continuity in fluid
mesh topology, necessary for a
coupled approach. CEL will be suitable
for solving many interesting
FSI problems in industry including
tire hydroplaning, automotive airbag
inflation, and liquid-product
dispensing.
— Edited by Leslie Gordon