Understanding NVH Prediction: The Role of Modal Analysis in the Automotive Industry
NVH (noise, vibration, and harshness) prediction is a critical process in the automotive industry to ensure customer satisfaction, safety, and compliance with regulatory requirements.
Simcenter 3D FE Model Correlation
Simcenter™ 3D FE Model Correlation provides engineers with the necessary tools to align geometric models, compare modes from different solutions, visualize mode shapes side-by-side, and calculate correlation metrics. This enables them to gain a comprehensive understanding of how closely the simulation aligns with the physical test data. By leveraging this software, engineers can confidently assess the accuracy and reliability of their simulations, thereby improving the overall design and development process.
Experimental Characterization and Simulation of Vibration Environmental Test
This article covers the basics of vibration environmental testing, including the different types of vibration simulation methods, test equipment and instrumentation, test procedures, vibration measurement techniques, data acquisition and analysis, and test standards and guidelines. It also discusses the applications of vibration environmental testing in various industries and future trends in the field, such as emerging technologies, integration of test and simulation, and use of artificial intelligence and machine learning. By understanding the fundamentals of vibration environmental testing and staying up-to-date on the latest trends and technologies, manufacturers and engineers can ensure that their products are reliable, durable, and high-performing in a variety of real-world environments.
Modal Analysis for NVH Prediction: The Role of Testing and Simulation
NVH (noise, vibration, and harshness) prediction is a critical process in the automotive industry to ensure customer satisfaction, safety, and compliance with regulatory requirements. Modal analysis is a popular technique used for NVH prediction, involving both testing and simulation. The goal of modal analysis is to measure the natural frequencies, damping ratios, and mode shapes of a structure, which can be used to identify the sources of noise and vibration and make improvements to the design. While modal analysis offers several benefits, such as cost savings and faster time to market, there are also some challenges associated with the technique, including complexity and cost. In this article, we will explore modal analysis for NVH prediction, its benefits, and its challenges.
Reducing Aircraft Noise with Innovative Performance-Enhancing Tools
Aircraft manufacturers are facing stricter regulations for aircraft emissions, including environmental noise, and increased pressure to improve cabin acoustic comfort. Vertical take-off and landing (VTOL) vehicles, currently being developed to enable urban air mobility (UAM), must also be optimized to minimize noise pollution in densely populated areas. This challenges engineering teams to efficiently troubleshoot noise issues and develop quieter aircraft designs without compromising weight and performance objectives. Simcenter™ software and hardware offer a complete solution for detailed acoustic testing and sound engineering. The solution features a number of technological advancements that help engineers perform acoustic measurements more efficiently for both exterior and interior noise.
How ICE Technology Can Create The Perfect Gelato Experience
The engineers at engineering consultancy R&D CFD are accustomed to applying CFD simulation to the challenges of Internal Combustion Engine (ICE) design. A recent project called on them to apply their analysis techniques to a different type of “ICE”--ICE cream. Their approach, however, was the same—using Simcenter STAR-CCM+ Multiphysics CFD software allowed the engineers to simulate 2000 variegator design variants in 17 days, and then optimize the design of the feeding chamber to guarantee that the final product would have the desired home-made, variegated appearance each time.