OMNIS™/Turbo & Agile (incl FINE™/Turbo & Agile)

Best-in-class turbomachinery design tools

Engineers looking to combine speed and accuracy for their virtual turbomachinery designs trust NUMECA for their toughest challenges.

We have designed a unique toolset that encompasses a complete end-to-end solution: 1D to 3D, Meshing, CFD and Optimization, all in one single environment. Thanks to more than 75 years of expertise in rotating machinery, the environment displays an unsurpassed ease-of-use and accuracy.

Configurations range from multi-stage axial to radial to mixed-flow configurations (compressors, turbines, pumps, fans, propellers or contra-rotating propellers).

 

The OMNIS™/Turbo & Agile solution includes access to the trusted FINE™/Turbo and FINE™/Agile tools.

Preliminary and detailed design

 

Extend the power of the Turbo CFD software with integrated preliminary and detailed design tools of the Agile package, thanks to our parnership with Concepts NREC. 

Concepts NREC’s Computer-Aided Engineering (CAE) modules each have a unique Design Wizard that leads the user through all the necessary steps for design, analysis, and data reduction.

The meanline design can then easily be sent to AxCent® for detailed 3D design.


Structured & Unstructured seamlessly combined

The structured Turbo solver for rotating parts OMNIS™/Turbo with OMNIS™/AutoGrid structured meshes, offers unsurpassed speed and accuracy.

Combined with the unstructured OMNIS™/Open-DBS solver, with OMNIS™/Hexpress meshes, for peripherals such as volutes, inlets, etc.. the complete application is solved using the most optimal approach for each part.

Components range from multi-stage axial to radial to mixed-flow configurations: compressors, turbines, pumps, fans, propellers, contra-rotating propellers...


Non-Linear Harmonic method

KJ66 static pressure 

Gaining 3 orders of magnitude in solving speed for unsteady simulation.

With the Non-Linear Harmonic method, users can solve transient behavior 100 times faster, capturing clocking, blade row interactions, tonal noise, inlet distortion etc...

This unique technique computes the unsteady flow field by means of the Fourier decomposition of the periodic fluctuations, based on a pre-selected number of harmonics, typically associated with the blade passing frequencies and their multiples.

Users choose the frequencies and as many rotor-stator interactions as needed for their analysis.


Would you like to know more?    View Webinar


Turnaround time 20x faster than any other solution on the market

The OMNIS™/Turbo CFD solution is optimized by scaling linearly on thousands of CPU cores, as well as on GPU (the latter provides a 2,4 times speed-up vs CPU).

Combined with our patented CPUBooster™ technology, a unique convergence acceleration technique, computation time is reduced even further, by a factor 3-5.

This package renders the solution up to 20 times faster than any other solution on the market.


Simplifying complex physics

Cavitation inception: Left, no local refinement - Right, dynamic mesh adaptation

Solutions for some of the more challenging topics that CFD engineers still face today, such as:

  • Conjugate Heat Transfer (CHT)
  • Combustion (premixed and non-premixed)
  • Cavitation
  • and many more...

For a detailed example of cavitation   read more


Full-engine 3D CFD simulation

With the purpose to meet the future requirements of aircraft engines in terms of low emissions, high reliability and efficiency, a novel highly efficient fully-coupled RANS-based approach has been developed, enabling the simulation of a full aero-engine within a single code.

One of the advantages of a fully coupled approach over a component-by-component approach, is that the boundary conditions at the interfaces do not need to be guessed.

A Smart Interface methodology ensures a direct coupling between the different engine components, compressor- combustor-turbine, and allows the CFD models to vary between each component within the same CFD code.

For the simulation of the combustion process, the Flamelet Generated Manifold (FGM) method is applied. While the approach is superior to classical tabulated chemistry approaches and reliably captures finite-rate effects, it is also computationally inexpensive.

The Nonlinear Harmonic method is used to model the unsteady interaction between the blade rows as well as the influence of the non-homogeneities at the combustor outlet on the downstream turbine blade rows. This method is 2 to 3 orders of magnitude faster than a classical URANS simulation.

Computation of a full engine using FINE™/Open-DBS's NLH and combustion models


Would you like to know more?  

READ WHITE PAPER       VIEW WEBINAR


Fluid-Structure Interaction

 

Set-up and start complete FSI simulations using only one software. FSI-OOFELIE couples the Finite Element solver Oofelie of Open Engineering with NUMECA’s fast and accurate parallel flow solver OMNIS™/Open-DBS with OpenLabs™ into one single environment.

The direct coupling within one single environment, allows for great gains in set-up time and reliability.


Aero-Vibro-Acoustics analysis

FINE™/Acoustics is a complete simulation suite for the analysis of a broad range of industrial applications involving Acoustics, Vibro-Acoustics and Aero-Acoustics.

Simultaneous tonal noise source and propagation analysis with the Non-Linear Harmonic method (NLH).

Broadband flow-noise source reconstruction based on steady RANS. Noise propagation with Boudnary Element Method (BEM) and Finite Element Method (FEM).

 


For an interesting case study   READ MORE


Optimization and Uncertainty Quantification

Automatic pump optimization with a limited number of design iterations​

Maximizing performance and minimizing performance variability

The optimization framework FINE™/Design3D provides access to the Minamo optimization engine, boasting a number of cutting edge features in terms of Design of Experiments (DoE), model reduction, optimization algorithms and post processing.

Take into account uncertainties and quantify the influence of variability on the simulation prediction to ensure your optimization is in real life conditions.

To see OMNIS™/Turbo in action, watch this 25 minute tutorial

Case Studies


Key Features

Meanline design

For all major turbomachinery configurations. Meanline options include: 

  • COMPAL® for radial and mixed-flow compressors
  • PUMPAL® for radial, mixed-flow, axial pumps
  • RITAL™ for radial and mixed-flow turbines
  • AXIAL™ for axial compressors and turbines

Detailed 3D design

For geometry and blading using AxCent®, including throughflow, 2D blade to blade and streamline curvature calculation.

  • 2D and radial blading
  • Agile links to COMPAL®, PUMPAL®, RITAL™,AXIAL™, OMNIS™/Turbo, pbFEA and MAX-PAC
  • Bezier-based cross-section (axial) and geometry generation (radial)
  • Blade generation sheets
  • Blade lean
  • CAD output (IGES, STEP, ACIS, Parasolid, STL)
  • Circular-arc and line segment contours
  • Fillets (single-radious, variable, elliptical)
  • Ideal and real fluids
  • Independent hub and shroud
  • Multistreamtube (MST) calculation for both compressible and incompressible flow
  • Radial stacking of up to 3-cross-sections at LE, TE or CG
  • Rapid loading calculation for both compressible and incompressible flow
  • Single-blade raw capability
  • Suitable for compressors, fans, pumps and turbines
  • Swept leading and trailing edges
  • Throat area calculation
  • Add: BANIG
  • Add: Blade stacking of 2 to unlimited number of cross sections
  • Enhanced flank milling -  confirming ruled surface
  • Flow cuts and trims/extensions
  • Flow injection and extraction
  • Inlet boundary layer calculations
  • Non-axisymmetric walls
  • Parameterized blade types (MCA, DCA, Pritchard, Enhanced Pritchard)
  • Parameterized blade types (NACA, Constant Passage, simple airfoil)
  • Simple and independently-specified splitter blades (Independent was option)
  • Stacking curve adjustment in meridional and tangential directions

OMNIS™/AutoGrid

Parallel Mesh Generation

  • Wizard mode: optimal mesh topology based on configuration
  • Advanced geometry features: blade fillets, cooling systems, axisymmetric and non-axisymmetric effects
  • Advanced configurations: multistage, bulb, unshrouded and by-pass
  • Automated blocking and meshing of axisymmetric effects
  • Python scripting technology

OMNIS™/HEXPRESS

  • Full Hexahedral Grids (no prism, no tetrahedra, no pyramid)
  • Direct CAD import capabilities
  • CAD manipulation and decomposition tools
  • Mesh wizard for rapid solution set-up and easy back and forth operation
  • Buffer cell and boundary layer insertion for high quality cells in boundary layer regions
  • Automatic refinement procedures based on user defined sensors either next to solid walls or at specified area in the domain
  • Multi domain capabilities allowing the treatment of CHT and multi-part geometry models
  • Full non-matching multi-block connection, allowing multi-row turbomachinery meshing

 

OMNIS™/Turbo flow solver

  • One single code for all types of fluids (incompressible, perfect or real gas, compressible liquid and condensable) and speed (low speed to hypersonic regime)
  • Acceleration with the CPU Booster™ module provides 3-5 times gain in convergence speed
  • Non Linear Harmonic (NLH) module for full unsteady rotor-stator interactions with gains of 1 to 3 orders of magnitude in CPU time
  • Cross-out High Performance Computing (HPC) on supercomputers with linear speed-up on up to 5,000 to 10,000 cores
  • Embedded Fluid Structure Interaction (FSI) with the Modal and Flutter Analysis module
  • Uncertainty Quantification module to study the variability with respect to geometrical or operational uncertainties
  • Automated performance curve creation
  • Multigrid convergence acceleration
  • Full Non-Matching Boundaries capability
  • Laminar-turbulent transition
  • Congugate heat transfers
  • Cavitation
  • Python scripting technology

OMNIS™/Open-DBS flow solver

  • One single code for all types of fluids (incompressible, low-compressible, condensable and fully compressible) and speed (low speed to hypersonic regime)
  • Acceleration with the CPU-Booster™ module provides 3-5 times gain in convergence speed
  • Embedded fluid structure interaction with the Modal and Flutter Analysis module
  • Multigrid convergence acceleration
  • Multidomain capability
  • Combustion
  • Radiation
  • Lagrangian multiphase
  • Cavitation
  • Multispecies reacting flows
  • Thermodynamics tables and combustion tables generation
  • Python scripting technology

OpenLabs™

  • OpenLabs™ allows users to customize or add physical models
  • Flexible and user-friendly Graphical User Interface
  • Users don’t need to care about programming details and code structure
  • OpenLabs can be used in a wide variety of industrial and academic applications
  • Identical computing and memory costs compared to source-coded models
  • Free access to all OMNIS™/Open community

OMNIS™/Post

  • Multi-projects and multi-views graphical user interface
  • Python scripting technology
  • Surface and 3D local value
  • Iso-lines
  • Color contour
  • Vector
  • Iso-surfaces
  • Cloud of particles
  • Line chart
  • Integral
  • Formula and operator derived quantities
  • Live co-processing

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