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5: Moderately Large Deflection Theory of Beams

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    • 5.1: General Formulation
      This page covers the moderately large deflection theory of beams, highlighting changes in strain-displacement relations and vertical equilibrium while preserving horizontal equilibrium. It introduces new terms for finite rotations and nonlinear curvature, remaining valid for rotations up to 10 degrees. The modifications impact vertical but not horizontal equilibrium equations, and solutions are influenced by boundary conditions for axial force.
    • 5.2: Solution for a Beam on Roller Support
      This page focuses on zero axial force beams, explaining their lack of axial extension and the differential equation for deflection under load. It provides a deflection profile for a pin-pin beam with a mid-span load and discusses relative horizontal displacement, noting potential for significant sliding.
    • 5.3: Solution for a Beam with Fixed Axial Displacements
      This page covers the analysis of beams under distributed cosine loads, emphasizing the effects of axial forces on deflection through differential equations. It details the transition from bending to membrane action as deflections increase, particularly in axially restrained conditions, and discusses the role of material properties and loading intensity.
    • 5.4: Galerkin Method of Solving Non-linear Differential Equation
      This page explores Russian scientist Beris Galerkin's contributions to structural mechanics during World War I, focusing on his method for analyzing plate deflections based on the Principle of Virtual Work. It details the Galerkin method's application to beam deflection under various loads, providing equations for trial shapes and approximations for uniform load scenarios.
    • 5.5: Generalization to Arbitrary Non-linear Problems in Plates and Shells
      This page covers the Galerkin method for solving non-linear ordinary differential equations, focusing on beam responses and partial differential equations for plates and shells. It distinguishes between exact and approximate solutions, introducing the concept of residue that averages to zero over a domain when paired with a weighting function.

    This page titled 5: Moderately Large Deflection Theory of Beams is shared under a CC BY-NC-SA 4.0 license and was authored, remixed, and/or curated by Tomasz Wierzbicki (MIT OpenCourseWare) via source content that was edited to the style and standards of the LibreTexts platform.