If you're heading off for a well-deserved holiday break, make sure your vibration shaker is not left out in the cold. Our comprehensive guide provides essential tips to safeguard your equipment during your absence, ensuring a seamless return to work. From a detailed inspection to practical steps for storage, we've got you covered. Read more to discover how a little pre-holiday care can go a long way in preserving the longevity and efficiency of your vibration shaker.

Andrea's recent Texas trip sparked insights into thermal comfort, leading to the exploration of advanced models in Simcenter STAR-CCM+ 2310. This article dives into the complexities of modeling human responses for electric vehicle cabin design, from summer HVAC optimization to winter energy consumption. The ultimate balancing act faced by HVAC engineers is succinctly captured, emphasizing Simcenter STAR-CCM+ 2310's role in addressing these challenges. Read more about the intricate choices between comfort and efficiency in the electric era.

In 'What's the Fastest Way to Dry Your Hands?', Robin Bornoff scientifically explores hand-drying efficiency using Simcenter FLOEFD. He uncovers the importance of the '90% dry' standard, explains the role of evaporation and condensation, and surprises us by revealing that keeping hands vertical is the quickest drying method. Plus, he urges us to think green by comparing the sustainability of hand dryers and paper towels.

Gas turbine efficiency improvement relies on increasing temperatures at the combustor exit and high-pressure turbine stage inlet. However, this poses a challenge as higher temperatures can endanger the integrity of turbine components. To address this issue, film cooling techniques have been adopted, where cool air is bled from the compressor stage and directed through small holes in the turbine blade and vane walls, creating a thin, cool insulating layer.

In the pursuit of excellence and innovation, PSA Peugeot Citroën embraced the power of Siemens Digital Industries Software's Simcenter™. The comprehensive simulation and testing capabilities enabled them to revolutionize the automotive industry and set new standards for vehicle performance, safety, and environmental sustainability. As technology continues to advance, embracing cutting-edge solutions like Simcenter™ will be crucial for any automotive manufacturer seeking to stay ahead in this dynamic and competitive landscape.

Siemens Simcenter SCADAS XS 6 stands as a powerful solution for engineers seeking efficient data acquisition and analysis capabilities. With its high-speed data acquisition, scalability, real-time monitoring, and advanced signal processing features, SCADAS XS 6 empowers engineers to make informed decisions and optimize the performance of various systems. Whether in the automotive, aerospace, energy, or structural domains, SCADAS XS 6 delivers valuable insights for improving safety, reliability, and efficiency.

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.

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.

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.

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.

Thermal characterization is crucial for comprehending the behavior of complex electronics. It involves analyzing and measuring heat generation, dissipation, and management. This article provides a basic overview of thermal characterization, including structure and function of electronic components, and various techniques and tools used in the field. Get a better understanding of thermal characterization and its significance in ensuring the reliability and safety of electronic components.

The evolution of power, size, and temperature in electronics design has led to new challenges in system reliability and lifetime. In the past, overheating of critical components was the major cause of system breakdown, but today, other issues also arise. Cooling is a 3D effect, and accurate thermal characterization is necessary for optimal design. The development of thermal transient measurements has culminated in the Cauer-ladder network model and the Simcenter T3STER™ thermal transient analysis software system. Using structure functions, engineers can now identify the physical characteristics of layers and evaluate the thermal performance at the system level, from LED packages to laptops and laser printers.

Transformer noise is caused by a phenomenon called magnetostriction. In very simple terms this means that if a piece of magnetic sheet steel is magnetized it will extend itself. When the magnetization is taken away. It goes back to its original condition. A transformer is magnetically excited by an alternating voltage and current so that it becomes extended and contracted twice during a full cycle of magnetization.

Strength and fatigue analysis made easier in simulations. Templates for fatigue analysis and their strength-only counterparts are relatively recent additions to Simcenter 3D. As a result, many engineers are unaware of them or the benefits that they can bring.

The strength analysis case provides static and fatigue strength analysis for any finite element set-ups created in Simcenter 3D. It is fully integrated into finite element workflows and fatigue workflows. You can use material data from a material database (inherited from finite element analysis) or directly in the analysis case.

If the prototype cost of our product is relatively small or if development time of our product does not really matter, due to no competition, then we may consider the vibration testing is not really relevant. But if our product is part of vital system in automotive where development time is getting shorter and crucial, or part of vital system in aerospace where prototype cost is relatively expensive and where safety has become very big issue, then having a vibration testing system may be considered as vital investment.

The Siemens Industry Software Simcenter engineers put the end-to-end durability solution to the test on the rough tracks of a German proving ground. The outcome is a step-by-step account of a test campaign that demonstrates the effectiveness of the solution. The story starts with a small but punchy electric sports vehicle that grew into a test vehicle for a condensed but complete durability measurement campaign.

Vibration testing is a key part of quality control for many products. It helps ensure that products can withstand the rigors of shipping and handling, as well as everyday use. There are many different ways to measure vibration, but the most important thing is to choose a method that will give you accurate results.

The use of CFD simulations has allowed engineers to greatly improve the aerodynamics of aircraft. By accurately predicting the flow of air around an aircraft, engineers can make design changes that result in a more efficient and faster airplane. This technology is constantly evolving and improving, and it is likely that we will see even more amazing advances in the future.

Vibration testing equipment is used to test the response of materials and structures to vibration. It is an essential tool for engineers to understand the behavior of materials and structures under vibrational loading. Vibration testing equipment can be used to test a wide range of materials, including metals, plastics, composites, and even human tissue.

Welcome to the blog section for "What's a Shock Response Spectrum?". In this section, we'll provide an introduction to the topic, as well as some definitions of key terms. We hope you find this information helpful in understanding the main article. A shock response spectrum is a graphical representation of how a system responds to a shock. The x-axis represents the amplitude of the shock, while the y-axis represents the resulting response of the system. The response can be in terms of displacement, velocity, or acceleration.