December 28, 2018
There are a lot of things attendees can do at aerospace engineering conferences, including:
Conferences are also a great place to meet aerospace customers, partners and young professionals.
6 Simulation Technologies Aerospace Engineers Don’t
Want to Miss in 2019
However, not everyone can attend events like the American Institute of Aeronautics and Astronautics’ (AIAA) SciTech Forum.
Therefore, I thought it would be nice to level the playing field by sharing highlights engineers should expect to see in this year’s conference circuit. After all, no engineer should fall behind on the latest tech news.
So, here are six Ansys technologies I think every aerospace engineer should research in 2019.
Shortened design cycles and sensor placement limitations prevent aerospace engineers from relying on physical testing.
As a result, aerospace engineers use computational fluid dynamics (CFD) and chemistry solvers to develop the next generation of aircraft engines.
Ansys’ combustion portfolio helps aerospace engineers design engines.
Ansys’ combustion portfolio is well suited to these multiphysics simulations. The software’s high-performance computing (HPC) scalability enables engineers to use turbulence models — like large eddy simulations (LES) — on meshs with more than a million elements.
To learn more, engineers attending the AIAA’s SciTech Forum can meet at a presentation on this combustion technology. If you can’t attend, read the application brief: Using Simulation to Optimize Reacting Flows and Combustion.
It’s tedius to merge CFD meshes. They have to be tight near the boundary layer and coarse in the bulk. The nodes, element types and element sizes just won’t align.
To address this, Ansys has released the new Mosaic meshing methodology. It can automatically mesh large scale models in high-lift configurations.
This Mosaic mesh of an aircraft includes small elements near the
boundary layer and coarse elements in the bulk with polyhedral elements in between.
This Mosaic meshing technology automatically combines a variety of boundary layer meshes using high-quality polyhedral elements.
Research shows that Mosaic meshing creates a better grid with fewer elements. This grid is able to deliver results faster and more accurately than traditional high-lift–configuration meshes.
Engineers can also catch me at a presentation on Mosaic meshing at AIAA’s SciTech Forum. Otherwise, read the white paper Ansys Fluent Mosaic Technology Automatically Combines Disparate Meshes with Polyhedral Elements for Fast, Accurate Flow Resolution.
Sometimes, aerospace engineers just need to visualize their simulations.
Maybe they need to experience how a cockpit’s human machine interface (HMI) feels. Or maybe they have to assess how a proximity sensor sees through a cloud.
In 2018, Ansys announced the acquisition of CEI and the visualization capabilities it brought to our customers — namely EnSight.
Design the next-generation cockpit with Ansys VRXPERIENCE and SPEOS.
The VRXPERIENCE is used to create virtual realities. It can also be coupled with the display solution Ansys SCADE. This enables engineers to explore and validate cockpit designs and other aerospace HMI.
SPEOS simulates light, human vision and physics-based visualization. It predicts illumination and the optical performance of systems. This way, engineers can prototype the optical performance of sensors digitally instead of in the real world.
Aerospace engineers can also couple the VRXPERIENCE and SPEOS to create a virtual world that tests their sensor designs. This technology would be ideal for the development of autonomous drones.
To learn more about VRXPERIENCE and SPEOS, I recommend reading about Ansys' Optics & Virtual Reality offerings.
Additive manufacturing can build novel geometries that are not possible to create using traditional methods.
This provides unique light-weighting solutions for companies in the aerospace sector. They can also produce low volume parts without investing in specialized tools.
However, engineers who implement 3D printers need to learn how to ensure their designs are built properly.
Ansys Additive Suite ensures parts print properly the first time.
The tool offers engineers an end-to-end design solution for metal additive manufacturing.
For instance, it enables engineers to calculate deformations and stresses during the printing process. This data helps them optimize their geometry to print correctly the first time.
To learn more about Additive Suite, I suggest you read Structural Optimization & Additive Manufacturing: A Winning Combination.
We have seen the aerospace industry pay more attention to pre-design. This is because the sooner the engineers make informed decisions about their products, the fewer redesigns they will need later in the development cycle.
This is where Ansys Discovery Live shines. It provides simulation insights in real time.
The ease of use and speed of the tool help designers test ideas before engaging an analyst. Discovery Live can model mechanical and CFD simulations in real time.
Discovery Live enables designers to model mechanical and CFD simulations in
For instance, engineers can set up a parameter study to better understand the trends and trade-offs of their designs in only a few minutes. Using that data, engineers can pass on near optimal designs to the analysts.
The results are so fast that engineers might want to play around with the design a bit and see how the simulation reacts.
To learn how to play around with designs, I recommend reading the blog Modern Product Development Encourages Engineers to Play with Designs.
Electrification is another major initiative in the aerospace industry. Electric aircraft will help engineers simplify their designs and implement new features like the IoT and digital twin.
Ansys multiphysics solutions will play a key role in the implementation of aerospace electrification.
Multiphysics simulations will help engineers drive the electrification trend in the aerospace industry.
These multidomain tools allows engineers to design and optimize key components, including: