9: Advanced Topic in Column Buckling

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9.1: The Tallest Column
This page explores the buckling of columns, detailing Euler's 1757 findings on critical lengths for pin-pin and clamped-free columns under axial loads. It presents closed-form solutions using cosine functions and discusses the implications of increased height on stability. Notably, a 32 m column buckles at 26 m due to critical length constraints.
9.2: Deflection Behavior for Beam with Compressive Axial Loads and Transverse Loads
This page explores the behavior of a simply supported beam under a central and axial compressive load, detailing the total potential energy and the shift from classical buckling concepts. It demonstrates that beam deflection can be modeled using a sine function, leading to a formula highlighting the linear relationship between lateral load and deflection.
9.3: Snap-through of a Two Bar System
This page details the mechanics of a three-hinge elastic rod system under axial loads, highlighting its behavior, including snap-through and buckling. It explains the impact of the slenderness ratio and provides equilibrium equations showing stability until an instability point causes a sudden shift to tensile configuration.
9.4: Dynamic Snap-Through
This page explores the dynamic analysis of a snap-through problem in a two-bar system under load control, focusing on stable equilibrium paths and transition points. It introduces inertia forces to examine dynamic behavior through differential equations and uses dimensionless variables for analysis. The phase plane approach leads to the derivation of a velocity equation, showing that dynamic responses can overshoot static limits, followed by an analysis of free vibrations.

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