Bringing in cable harness definition enables mesh and real-world simulations within a full vehicle structure.Īnsys Mechanical Thermal solver is now available inside AEDT for a streamlined workflow, linking EM designs from HFSS, Maxwell and Ansys Q3D for quick thermal insight.Īnsys SIwave’s new wizard provides an automated workflow to improve setup time required for PCB designs with DDR.Īnsys Maxwell in Ansys 2021 R1– More Detailed Simulation for Electric Drive Applications This extends EM interaction to rigid body dynamics and enhances the overall noise-vibration solution.Īnsys EMA3D Cable generates S-parameter models of cables with all electromagnetic effects. Ansys’ digital twin solutions enable remote monitoring of assets and are a critical component for predictive maintenance.Ĭollectively, these resources will help users generate larger, more complex designs easier and faster than ever, increase productivity, spur development of high-quality products and expedite time to market.Īnsys HFSS Mesh Fusion enables simulation of large, never before possible electromagnetic systems with efficiency and scalability.Įncrypted 3D components supported in HFSS 3D Layout for PCBs, IC packages and IC designs enable suppliers to share detailed 3D component designs for creating highly accurate simulations.Īnsys Maxwell leverages cyclic repeatability by slice-only solving within cyclically repeated non-planar radial boundary conditions, including auto-extraction of full-model outputs.Ībility to output transient electromagnetic forces from Maxwell into Ansys Motion. Platform solutions enhanced with powerful workflows deliver a streamlined user experience with enhanced functionality for data and configuration management, dependencies visualization and decision support, as well as user-friendly workflows for process integration and design optimization and materials management. Updates in Ansys Cloud offerings, such as virtual desktop infrastructure support, unites Ansys’ flagship simulation solutions with highly scalable compute power delivered by cloud-based high-performance computing (HPC). The results of airdrop test demonstrate that our method can be further applied to the guidance and control of precision airdrop systems.Ansys 2020 R2 helps engineering teams accelerate innovation in any environment and create cutting-edge designs by harnessing new workflows and dynamic capabilities across Ansys’ flagship suites. Finally, a linear five-degree-of-freedom (5DOF) dynamic model is developed, the perturbation characteristics and the motion laws of the parachute and payload under a wind gust are analyzed by the linearization method and verified by a comparison with flight test data. With the available aerodynamic data obtained from the FSI simulation, a nine-degree-of-freedom (9DOF) dynamic model of a parachute–payload system is built and solved to simulate the descent trajectory of the multi-body dynamic system.
The inflation behavior of a disk-gap-band parachute is specifically investigated using the arbitrary Lagrangian–Euler (ALE) penalty coupling method. To analyze the parachute dynamics and stability characteristics of precision airdrop system, the fluid–structure interaction (FSI) dynamics coupling with the flight trajectory of a parachute–payload system is comprehensively predicted by numerical methods.