Parametric Design
Automation in the design process:
Streamlining the design process and automating the optimization process is recognized as an essential tool for designers. The TNB software platform includes modules for generating parametric geometry, generating computational grids, fluid analysis, and finally optimization. The designer can use this platform to produce their desired design parametrically, then evaluate it based on the objective in mind, and achieve the desired design.
Deformation of airplane components such as wings, fuselage, and control surfaces, and achieving optimal aerodynamic design by adjusting parameters such as airfoil profiles, wing displacement angles, and fuselage lines.
Designing the hull, propellers, and other marine structures with optimized hydrodynamic and hydrostatic performance, static balance, safety, seakeeping, and optimal maneuverability
Optimizing the dynamic performance of mechanical systems, including vibration characteristics, natural frequencies, and damping properties, reducing resonance phenomena and fatigue failures, and increasing the lifespan of mechanical components and systems
Deformation of airplane components such as wings, fuselage, and control surfaces, and achieving optimal aerodynamic design by adjusting parameters such as airfoil profiles, wing displacement angles, and fuselage lines
Designing the hull, propellers, and other marine structures with optimized hydrodynamic and hydrostatic performance, static balance, safety, seakeeping, and optimal maneuverability
Optimizing the dynamic performance of mechanical systems, including vibration characteristics, natural frequencies, and damping properties, reducing resonance phenomena and fatigue failures, and increasing the lifespan of mechanical components and systems
Parametric geometry
Parametric geometry is applicable in various fields such as computer-aided design (CAD) and engineering. In CAD software, designers can create complex shapes that are easily modifiable and adaptable to different needs by defining parametric models. Generally, parametric geometry provides a powerful framework for describing and altering geometry using parameters. In the TNB software platform, users have the ability to generate, control, and modify parametric geometry.
2D and 3D computational grids
Generating a computational grid is a crucial step in many numerical simulations, particularly in Computational Fluid Dynamics (CFD), Finite Element Analysis (FEA), and other computational engineering problems and scientific applications. Mesh generation in the TNB software platform allows the user to create the desired computational grid with minimal user intervention.
Fast solvers
The tonb software platform includes computational methods and algorithms used for the fast and efficient solution of aerodynamic flow problems. These types of solvers are applicable in various engineering fields such as optimization, design, and analysis of different scenarios.
Optimization
Parametric geometry optimization involves the iterative refinement of parameters that define a geometric shape to achieve specific objectives, such as minimizing drag or maximizing lift. All of this is achievable in the TNB software platform. This optimization process is crucial for aerodynamic design, such as airplane wings, car bodies, or wind turbine blades, that meet performance requirements while also satisfying various constraints such as weight, cost, and manufacturability