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Multi Body Dynamics - Ansys - charlie - 30-12-2025
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![[Obrazek: 92f2497f3eb0228144b2f8a2ee4f5666.jpg]](https://i126.fastpic.org/big/2025/1230/66/92f2497f3eb0228144b2f8a2ee4f5666.jpg)
Multi Body Dynamics - Ansys
Published 12/2025
MP4 | Video: h264, 1920x1080 | Audio: AAC, 44.1 KHz
Language: English | Size: 2.23 GB [/center] | Duration: 2h 24m
Ansys
What you'll learn
Understand the fundamentals of Multi-Body Dynamics (M D)
Build and simulate multi-body systems using ANSYS
Perform analysis of mechanisms
Apply MB D concepts to automotive and industrial applications
Requirements
Mechanical Engineering
Mechanical Engineering Students
Mechanical Engineering Diploma Students
Description
Chapter 1: Four-Bar MechanismDescription:This chapter introduces the four-bar linkage, one of the most fundamental mechanisms in mechanical engineering. Learners will study the kinematic structure, degrees of freedom, Grashof condition, and motion characteristics of four-bar mechanisms. Using ANSYS MB D, students will model links, define revolute joints, apply motion drivers, and analyze displacement, velocity, acceleration, and joint reaction forces. The chapter also covers motion transmission, coupler curves, and dynamic load behavior under varying operating conditions.Implementation in Other Applications:Knowledge of four-bar mechanisms is widely applicable in:Automotive windshield wipers, suspension linkages, and door hingesIndustrial presses, packaging machines, and conveyor systemsAerospace control linkagesConsumer products such as folding mechanisms and adjustable furnitureRobotics end-effectors and motion transmission systemsUnderstanding this mechanism builds a strong foundation for analyzing any planar linkage system.Chapter 2: CAM and Follower MechanismDescription:This chapter focuses on cam-follower mechanisms, which convert rotary motion into prescribed follower motion. Learners will explore different cam profiles, follower types, motion laws (uniform velocity, SHM, cycloidal), and contact forces. In ANSYS MB D, students will create cam geometries, define contact interactions, simulate follower motion, and evaluate dynamic parameters such as contact forces, follower acceleration, and vibration tendencies.Implementation in Other Applications:Cam mechanism knowledge is essential in:IC engines (valve train mechanisms)Automated assembly lines and pick-and-place machinesTextile and printing machineryPackaging and labeling equipmentHigh-speed automation systems requiring precise motion controlThis chapter helps learners design motion systems with accuracy and reliability.Chapter 3: Serial RobotDescription:This chapter introduces serial robotic manipulators, where links are connected end-to-end through joints. Learners will study forward and inverse kinematics, joint motion definition, and workspace analysis. Using ANSYS MB D, students will build serial robot models, assign revolute and prismatic joints, apply motion profiles, and analyze joint loads, link motions, and dynamic response during operation.Implementation in Other Applications:Serial robot modeling skills are applicable to:Industrial robots for welding, painting, and assemblyCNC machine tool kinematicsMedical and surgical robotic systemsAerospace assembly robotsAutomation systems and material handling equipmentThis chapter enables learners to understand robot motion behavior beyond simple kinematic equations.Lesson 4: Parallel RobotDescription:This lesson covers parallel robotic mechanisms, where multiple kinematic chains connect the base to the moving platform. Learners will explore system stiffness, redundancy, and dynamic performance advantages over serial robots. In ANSYS MB D, students will model parallel link structures, define constraints, and analyze motion accuracy, load distribution, and dynamic stability.Implementation in Other Applications
arallel robot knowledge is used in:High-precision machining centersFlight and driving simulatorsPick-and-place delta robotsMedical rehabilitation and motion platformsPrecision positioning and vibration isolation systemsThis chapter prepares learners for high-end robotic and precision engineering applications.Lesson 5: Mechanical Model AssemblyDescription:This lesson focuses on complete mechanical system assembly in ANSYS MB D. Learners will integrate multiple components, define joint hierarchies, manage constraints, and simulate full-system behavior. Emphasis is placed on importing CAD data, simplifying geometry, setting contacts, and validating results for real-world applications.Implementation in Other Applications:Mechanical assembly modeling is critical for:Automotive subsystems (suspension, steering, seat mechanisms)Heavy machinery and construction equipmentAerospace mechanical assembliesConsumer product mechanism validationDigital prototyping and virtual testingThis lesson bridges the gap between academic mechanisms and industrial-scale simulation.Overall Skill Transfer & Industry RelevanceThe knowledge gained from these chapters enables learners to:Analyze motion, forces, and dynamic behavior of complex systemsSupport design optimization and failure preventionReduce physical prototyping costs through simulationApply MB D concepts across automotive, robotics, aerospace, manufacturing, and automation industriesMechanical, Automotive, and Mechatronics Engineering students who want to gain practical skills in dynamic simulation and CAE tools.,Final-year and postgraduate (B Tech / M Tech) students seeking industry-oriented exposure in Multi-Body Dynamics and ANSYS Motion. Working professionals and design engineers looking to upskill in mechanism simulation, system dynamics, and virtual prototyping. CAE and simulation engineers aiming to integrate MB D with structural and fatigue analysis for real-world applications. Automotive engineers interested in suspension, steering, powertrain, and vehicle subsystem simulations. Faculty members and researchers who want to incorporate MB D simulations into teaching, projects, or research work. Fresh graduates and career switchers aspiring to enter the CAE, automotive, or product design domain.
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