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Learn the basics and advanced features of this software, which is utilized by the computer-aided design (CAD), mechanical, structural, and aerospace industries, by joining our Ansys Workbench Online Course. Register Now!!- https://lnkd.in/dknzMJvM #ansysworkbenchonline #ansysworkbenchtraining #ansysworkbenchcourse

🌊 Exploring the Adaptive Floating Mechanism 🚀 Ever wondered how structures adapt to changing environmental conditions? The answer lies in the incredible Adaptive Floating Mechanism! 🌟 In my latest video, I delve into the mechanics and technology behind this fascinating mechanism, explaining how it helps achieve optimal stability under various conditions. From basic concepts to advanced functionalities, this video covers it all. Whether you’re an engineer, a technology enthusiast, or just curious about these innovations, this is a must-watch! Check out the video and let’s discuss the exciting world of advanced mechanisms. #Technology #Engineering #AdaptiveFloatingMechanism #TechExplained #Innovation #3DPrinting #SolarEnergy #Sustainability #Engineering #RenewableEnergy #TechSolutions #MechanicalDesign #ClampingMechanism #RackAndPinion #Manufacturing #Automation #engineering #mechanical #mechanism #cad #solidworks #mechanic

#snsinstitutions #snsdesignthinking #snsdesignthinkers #snsct #snsmct SOLID MECHANICS Solid mechanics, a cornerstone of mechanical engineering, delves into the study of how solid materials respond to external forces and deformations. From the design of everyday objects to the construction of skyscrapers, solid mechanics plays a pivotal role in ensuring structural integrity, safety, and efficiency. In this article, we will delve into the fundamental principles, analysis techniques, and real-world applications of solid mechanics, highlighting its importance in various fields. - Stress and Strain: Stress refers to the internal resistance of a material to external forces, while strain represents the resulting deformation. Understanding the stress-strain relationship is crucial for predicting material behavior under load. - Elasticity and Plasticity: Materials exhibit elastic behavior when they return to their original shape after the removal of applied forces. Plasticity occurs when materials undergo permanent deformation beyond their elastic limit. - Hooke's Law: Hooke's law describes the linear relationship between stress and strain in an elastic material, providing a foundational principle for analyzing material behavior under small deformations. - Finite Element Analysis (FEA): FEA is a powerful numerical technique used to simulate and analyze the behavior of complex structures under various loading conditions. It divides the structure into finite elements to approximate the continuous behavior of the system. - Beam Theory: Beam theory provides simplified models for analyzing the behavior of structural elements subjected to bending moments and shear forces. It is widely used in the design of beams, columns, and other load-bearing components. - Mohr's Circle: Mohr's circle is a graphical method used to visualize and analyze stress states in materials subjected to complex loading conditions. It provides insights into principal stresses, maximum shear stresses, and stress transformations. -Solid mechanics serves as the bedrock of mechanical engineering, providing the theoretical framework and analytical tools for understanding and designing structures and materials. By applying principles of stress analysis, deformation behavior, and material science, engineers can create innovative solutions across a diverse range of industries, driving progress and shaping the future of technology and infrastructure.

Dynamic Response Analysis of the Rotor Using the Jeffcott Method and Performance Improvement Using Active Magnetic Bearing https://lnkd.in/dqUUMMRz Abstract The most common component of mechanical systems today is rotating machines. In these systems, vibration is caused by rotating components. As a result, to decrease the amplitude of vibrations created by rotating equipment, it’s required to understand the behavior of the system. In this work, the problem of vibrations in conventional bearing systems and the effect of adding active magnetic bearings to rotating machines to reduce the amplitude of vibrations are discussed. In this paper, the vibrations in the rotary bearing system were studied theoretically and analytically by using simulation programs to calculate the natural frequencies and parameters affecting the performance. In the theoretical part, the shaft of the rotating bearing was analyzed by the Jeffcott method depending on several parameters changed with the frequency value to observe the amplitude of the vibrations in the shaft. In an analytical aspect by simulation, a representative model of active magnetic bearings was built using the COMSOL 2020 program, and the effect of adding these bearings on capacitance, vibration reduction, and frequency behavior was examined. SolidWorks 2018 software was used to analyze the magnetic field and its distribution in the magnetic bearing coil. The results indicate that when magnetic active bearings were introduced to the rotating bearing shafts, the vibration amplitude was reduced by approximately 60%. From this work, it can be concluded that the system becomes more stable when the active magnetic bearing is added to the rotating bearing shaft, giving it a more stable and firm nature. Highlights: • Dealing with the Jeffcott method to change the parameters affecting the rotating shaft. • The greater the current flowing through the AMB coil at an appropriate air gap distance, the greater the controllability of the rotating shaft. • There is a significant reduction in the amplitude of vibrations when the active magnetic bearing is added. Keywords: • Vibrations • Rotating-Bearing System • Jeffcott method • Magnetic bearing • Active magnetic bearing (AMB) Journal: https://lnkd.in/dgnvtdte Issue: https://lnkd.in/d9W-V9tn Article: https://lnkd.in/eW9WVMa3 ETJ LinkedIn: https://lnkd.in/d_8SPqAt #Engineering_and_Technology_Journal #UOT #engineering #technology #etj

Making progress on mechanical services modeling

#snsinstitutions #snsdesignthinkers #snsdesignthinking It seems like there might be a slight typo in your question ("Design thinning" instead of "Design thinking"). Assuming you are referring to applying design thinking to the field of Mechanics of Materials or Matrix Mechanics, let's explore a design thinking approach for Mechanics of Materials: 1. **Empathize:** - Understand the challenges and requirements of materials under different loads. - Consider the perspectives of engineers, manufacturers, and end-users who interact with materials subjected to mechanical forces. 2. **Define:** - Clearly define the mechanical problem or opportunity related to material behavior and structural integrity. - Set specific criteria for success, such as load-bearing capacity, durability, and safety standards. 3. **Ideate:** - Generate creative ideas for improving material properties and structural designs. - Explore innovative materials, composite structures, and manufacturing processes to enhance mechanical performance. 4. **Prototype:** - Develop prototypes or simulations that represent potential material and structural solutions.

🌉 Altair's Inspire and SimSolid: Engineering's Quantum Leap! 🚀 From conceptualization to validation, The software empowers teams to optimize designs, ensure compliance, and accelerate innovation in structural engineering. 🔗 Check the article to to witness the pinnacle: https://lnkd.in/gSRHdEFt 💡 With Altair, you can:  1️⃣ Explore design iterations with Altair® Inspire™'s topology optimization. 2️⃣ Validate structures against design codes with Altair® S-FRAME®.  3️⃣ Streamline digital testing with Altair SimSolid®. 🎓 Gain valuable technical skills and access industry-grade analysis tools. #SteelBridge #AISC #TopologyOptimization #DigitalValidation #EngineeringSoftware #CAD #FiniteElementAnalysis #Altair #Futurescape

What is #Designengineering ? #Design #engineering is a multidisciplinary field that involves creating and developing products, systems, and structures through a combination of creative design and technical engineering principles. It encompasses a broad range of activities, including: #ConceptualDesign: Developing ideas and concepts for new products or systems based on customer needs, market research, and technological possibilities. #DetailDesign: Creating detailed drawings, specifications, and models that outline the exact dimensions, materials, and processes needed to manufacture the product. #Prototyping Building and testing prototypes to evaluate design concepts and identify any necessary improvements or modifications. #Analysis and #Simulation: Using computer-aided design (CAD) software and other simulation tools to analyze the performance, reliability, and safety of the design. #Optimization: Refining designs to improve efficiency, reduce costs, and ensure compliance with industry standards and regulations. #Manufacturing Support: Collaborating with manufacturing teams to ensure that designs can be efficiently and effectively produced. #ProjectManagement: Overseeing the entire design process, managing timelines, budgets, and communication among various stakeholders. Design engineers often work in various industries, including #automotive, #aerospace, #electronics, consumer products, and industrial machinery. Their role is critical in transforming ideas into tangible products that are functional, reliable, and aesthetically pleasing.

🚀 Unlock Your Potential: 5 Essential Skills Every Engineering Designer Should Master 🛠️ Are you an aspiring engineering designer looking to level up your skill set? Here are the top 5 must-have skills that will set you apart in the competitive world of engineering design: 1️⃣ Fundamental Engineering Principles: Lay a strong foundation by mastering key principles in mechanics, thermodynamics, materials science, and electrical theory. 2️⃣ Design Process Proficiency: Learn to navigate the design process like a pro, from problem definition to prototyping, testing, and iteration. 3️⃣ CAD Mastery: Harness the power of Computer-Aided Design (CAD) software to bring your ideas to life with precision and efficiency. 4️⃣ Manufacturing Know-How: Understand various manufacturing processes to design products that are not only innovative but also feasible to produce at scale. 5️⃣ Collaboration Skills: Embrace interdisciplinary collaboration and hone your communication skills to work effectively with diverse teams and integrate different perspectives into your designs. Ready to take your engineering design game to the next level? Start mastering these essential skills today! 💡💼 #EngineeringDesign #CareerDevelopment #SkillsDevelopment #automationsolutions #designexperts

STOP ENGINEERING NOW! But of course, you must be ready to give up a few things! Life without engineering would be very different. Here are some stuff that would not exist: - Cars - Airplanes - Bridges - Skyscrapers - Electricity - Clean water supply - Healthcare machinery - Smartphones - Laptops ...Should I add more? Engineering has shaped the world and will continue to turn ideas, imagination and vision into tangible, functional solutions. Without it, innovation and progress in critical fields such as healthcare, transportation and communication would come to a halt. What would you miss the most if engineering didn't exist? #FEA #engineering #ansys #solidworks #mechanicalengineering #CFD #CAE #CAD #innovation #sheetmetal