This week’s episode explores the critical process of balancing rotating machinery to reduce unwanted vibrations and forces that can cause premature component failure. It begins by discussing static unbalance, which can be observed when a rotor consistently rests at a particular position, and explains how it can be corrected by adding or removing mass. The episode then addresses dynamic unbalance, occurring when a statically balanced rotor still wobbles due to uneven mass distribution, requiring corrections in multiple planes. Various techniques for analyzing and correcting unbalance are covered, including graphical, vector, and numerical methods. The episode also introduces different dynamic balancing machines—such as pivoted-cradle, nodal-point, and mechanical-compensation types—each designed to measure and correct unbalance in rotating systems.

The content was created using an AI notebook, with material adapted from textbook excerpts and lecture slides to provide a structured and accessible learning resource.

This week’s episode focuses on acceleration analysis in planar mechanisms, building on the velocity concepts covered in Week 4. We begin with a review of vector operations, including dot and cross products, and the right-hand rule, emphasizing their role in determining acceleration directions. The episode then explores how to calculate the acceleration of a point in both fixed and moving coordinate systems, highlighting the contributions of different components, such as the Coriolis acceleration. To demonstrate practical application, a worked example of a four-bar linkage is presented, showing step-by-step how to determine the angular accelerations of the links.

The content was created using an AI notebook, with material adapted from five sources, including textbook excerpts, lecture slides, and class examples, to provide a structured and accessible learning resource.

This week’s episode introduces the fundamental concepts of velocity analysis in planar mechanisms, building on the kinematics foundation from previous weeks. The episode begins with a review of vector operations, including dot and cross products, and explains how these mathematical tools are used to determine quantities like angular velocity. It then covers the velocity of a point, principles of relative motion, and the velocity of a point within a moving coordinate system, breaking down each component for clarity. To demonstrate practical application, the episode includes a worked example involving a four-bar linkage, showing how these velocity analysis techniques are applied to solve for unknown angular velocities in real mechanisms.

The content was created using an AI notebook, with material adapted from textbook excerpts, lecture slides, and worked examples to provide a structured and accessible learning resource.

This week’s episode builds on the foundational concepts introduced in Week 2 to focus on the practical analysis of planar mechanisms. While Week 2 covered the core definitions of position, posture, and displacement, here we apply those tools to actual mechanical systems. The episode explores how to describe the path, or locus, of a moving point and determine its position using vector notation, considering absolute and apparent positions from different reference frames. It also demonstrates the posture of a rigid body—its combined position and orientation—using analytical and graphical techniques such as loop-closure equations and complex algebra. Practical applications, including slider-crank mechanisms, internal combustion engines, and train driving wheels, illustrate the importance of understanding these kinematic principles in real-world mechanisms.

The content was created using an AI notebook, with material adapted from textbook excerpts, lecture slides, and worked examples to form a clear and structured learning resource.

This week’s episode explores the fundamentals of kinematics, focusing on the position, posture, and displacement of points and rigid bodies in mechanical systems. We begin with how to mathematically define a point’s locus and position using vector notation within fixed and moving reference frames. The discussion then extends to a rigid body’s posture—its combined position and orientation—along with techniques such as loop-closure equations and both graphic and algebraic posture analysis for solving complex mechanisms. The episode also distinguishes between absolute and apparent displacement, explaining how motion can be viewed from different perspectives and how it is composed of translation and rotation.

The content was created using an AI notebook, with material adapted from textbook excerpts and lecture slides to provide a clear and structured learning resource.

In this episode, we dive into the fascinating world of machines and mechanisms, uncovering the building blocks that power movement and motion in engineering. Starting with the fundamentals, we explore engines such as internal combustion, Wankel, and radial types, before shifting focus to key components like cams, gears, and gear trains that bring complex systems to life. We also highlight specialized mechanisms, including the Geneva wheel and escapements, explaining their unique roles in precision devices. To wrap up, we examine coupling mechanisms and how they enable smooth transmission of motion between shafts. Whether you’re new to mechanical engineering or looking to refresh your knowledge, this episode offers clear explanations and practical examples to deepen your understanding of mobility in machines.

In this episode, we dive into the foundational principles of dimensional tolerancing and dimensioning guidelines in engineering drawings. Learn why every dimension needs a tolerance, how tighter tolerances impact manufacturing cost, and what factors determine tolerance size.

We’ll explore key drawing standards—including projection and dimension lines, arrowheads, and text placement—along with best practices for indicating diameters, radii, and centre lines. You'll also hear why avoiding over-dimensioning and hidden detail dimensioning is essential, and how a clear tolerance table supports efficient production.

Based on 4 core sources, this episode distills the essentials to help you apply tolerancing more effectively in your technical drawings.