Flow Simulator is an integrated flow, heat
transfer, and combustion design software that enables mixed
fidelity simulations to optimize machine and systems design.
This fluid system design tool provides interdisciplinary modeling and optimization capabilities within a single platform for machine design with respect to fluid dynamics/thermal/combustion within a 3D design environment. This tool allows users to import actual hardware and utilization of 3D CAD point-cloud to automatically create the computational model overlaid on the machine hardware.
An extended library of preconfigured elements/components is available to model/simulate a wide-range of physical phenomena including compressible/incompressible fluid flow, buoyancy-driven flow, rotating cavity system flow, conduction/convection/radiation heat transfer, combustion equilibrium-chemistry & species transport.
Eight combinations of analysis modes (steady state, quasi steady
state, and transient analysis for fluid dynamics, thermal, and
combustions) are available to predict system/subsystem run
conditions during a cycle/mission simulation (flight mission, power
ramp up, shut down…etc). Control system components (proportional
integral derivative (PID) controllers, feedforward, and mission)
can be integrated with computational model system/subsystem to
optimize the simulated-machine operation during cycle/mission
Key Features & Benefits:
- Fast and accurate mixed-fidelity (1D, 2D, and 3D) flow simulations that handle complex geometry and long transient missions. A flexible common platform that allows different groups to perform modeling with respect to their verticals and thus be combined to create system models.
- Modern graphic user interface with the ability to overlay/integrate the 3D digital CAD with the analytical models. The GUI is geared for design where the Pre/Solver/and Post are all embedded in a single interface. The fully integrated optimization module provides the capability to quickly explore the entire design space within 3D modeling environment; system models can be parametrized based on flow configuration, shape, dimension, and thermal characteristics to achieve an optimal cost-benefit design.
- Extended library of preconfigured elements/components leveraging a large set of publicly-available experimental data for pressure drop and heat transfer characteristics. This fully extensible platform provides customers the capability to integrate their own IP and element formulations seamlessly utilizing Python scripting.