Use of CFD Simulation in the
beginning of product Development cycle by Mechanical Design Engineers has
become an emerging trend. Previously faced challenges like difficult to
integrate, cost, etc. in utilizing CFD Analysis has gradually being overcome as
flow simulation becomes more embedded in the mechanical design process. As a
result simulation results are becoming available practically as quickly as modifications are
done in the design cycle, thus CFD plays a crucial role in
design, decision making as well as optimization processes.
CFD
Analysis is employed to design products that rely on fluid flow and heat
transfer phenomena, like airplanes and automobiles; to enhance its performance.
CFD Analysis utilizes computer to employ numerical methods and algorithms to
solve and analyze problems adhering to fluid flows and simulate the
interaction of liquids and gases with surfaces defined by boundary
conditions. This aids in predicting flow velocity, temperature, and
species concentrations that are used to enhance the products design and
development processes.
Benefits
of Simulating Early
Simulating Mechanical Design early in development cycle helps in developing an efficient design and helps
in reducing the time spent in the verification and testing phase of product
development. It enables manufacturers to minimize the number of prototypes
essential to pass quality tests and avoid unnecessary changes after design
completion. Simulation is usually embedded in the computer aided design (CAD)
application and relocated from CAD to pre-processor applications. This keeps
the engineer in an acquainted environment and eliminates the
additional step of relocating geometry to an additional application.
Challenges
in executing CFD Analysis
- CFD codes that are linked to CAD software take a copy of the 3D geometry, convert it by means of a neutral format like Parasolid or ACIS, and include boundary conditions to generate a model for fluid analysis that loses intelligence like assembly hierarchy, constraints, and features.
- As Empty flow space that forms the basis of the fluid model does not exist as a discrete object in the original CAD design, most integrated CFD codes extract all of the cavities from the CAD model, add them to the feature-tree as new objects, and then grid them separately using grid generation software.
- The data persistence as well as links to the original CAD model is lost, that makes it impossible to retain model history as well as parameterization.
Combating
the Challenges Faced
- Requirement of high level expertise for CFD Simulation is overcome by means of advance CFD tools that are fully embedded in mechanical design.
- CFD software operates as an extension of CAD software, automates schedule simulation operations and allows direct interaction between CFD software and CAD data to retain pace with continuous design changes.
- CAD data is utilized for CFD simulations without any requirement for translations or copies.
- CFD software utilizes same feature tree and geometry model as CAD software thus design modifications are executed directly in the CAD system.
·
All
auxiliary data like material properties and boundary conditions are linked with
the CAD model.
·
CFD
software stores fluid flow parameters, temperatures, flow rates, etc as
object-based features, maintained in the feature tree like other
object-based data, and applied directly to update the simulation software.
This allows a large number of model variants to be simulated automatically.
Thus, CFD
Analysis by means of CFD software uses CAD data, automatic grid flow space, and
manages the flow parameters as object-based features eliminating the need for
engineers to understand the computational part of CFD. Integrating CFD into the
mechanical design provides rapid and more certain results that justify the cost
for executing CFD Analysis.