PROBLEM II) In the following figure ignore the given harmonic displacement xg and assume that a harmonic force of F = F,coswt is acting on the yellow block. Assume that the mass of yellow block is mg and it is displacemet is denoted by xg. Assume that the mass of red cylinder is m, and its displacement is denoted by x4. The L-shape connecting bar has a mass of m, and its mass moment of inertia can be calculated by assuming slender rod assumption. Write the equation of motion of this system using Lagrange equation. Develope an analytic procedure to solve the reponse of the system using modal analysis. k2 k1 ww b TxB = bo cos ot

PROBLEM II) In the following figure ignore the given harmonic displacement xg and assume that a harmonic force of F = F,coswt is acting on the yellow block. Assume that the mass of yellow block is mg and it is displacemet is denoted by xg. Assume that the mass of red cylinder is m, and its displacement is denoted by x4. The L-shape connecting bar has a mass of m, and its mass moment of inertia can be calculated by assuming slender rod assumption. Write the equation of motion of this system using Lagrange equation. Develope an analytic procedure to solve the reponse of the system using modal analysis. k2 k1 ww b TxB = bo cos ot

International Edition---engineering Mechanics: Statics, 4th Edition

4th Edition

ISBN:9781305501607

Author:Andrew Pytel And Jaan Kiusalaas

Publisher:Andrew Pytel And Jaan Kiusalaas

Chapter5: Three-dimensional Equilibrium

Section: Chapter Questions

Problem 5.15P: In Sample Problem 5.5, determine Oy with one scalar equilibrium equation.

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