Abstract
The problem of a compressed Timoshenko beam of finite length in frictionless and bilateral contact with an elastic half-plane is investigated here. The problem formulation leads to an integro-differential equation which can be transformed into an algebraic system by expanding the rotation of the beam cross sections in series of Chebyshev polynomials. An eigenvalue problem is then obtained, whose solution provides the buckling loads of the beam and, in turn, the corresponding buckling mode shapes. Beams with sharp or smooth edges are considered in detail, founding relevant differences. In particular, it is shown that beams with smooth edges cannot exhibit a rigid-body buckling mode. A limit value of the soil compliance is found for beam with sharp edges, below which an analytic buckling load formula is provided without loss of reliability. Finally, in agreement with the Galin solution for the rigid flat punch on a half-plane, a simple relation between the half-plane elastic modulus and the Winkler soil constant is found. Thus, a straightforward formula predicting the buckling loads of stiff beams resting on compliant substrates is proposed.
Highlights
The knowledge of the critical load of elastic bars, beams, plates, shell panels and layered systems bonded to a deformable support is a key task for many engineering problems with specific reference to foundation beams, bridge decks, end-bearing piles and thin-film based devices (MEMS and NEMS) or composite systems (Bazant and Cedolin, 20 03; Foraboschi, 20 09)
The edge effects on the buckling loads and mode shapes are investigated in detail
I = Pi,Sh /Pi,Sm will be defined the edge effect parameter, being the ratio between the eigenvalues obtained for a beam with sharp and smooth edges corresponding to the same mode number i
Summary
The knowledge of the critical load of elastic bars, beams, plates, shell panels and layered systems bonded to a deformable support is a key task for many engineering problems with specific reference to foundation beams, bridge decks, end-bearing piles and thin-film based devices (MEMS and NEMS) or composite systems (Bazant and Cedolin, 20 03; Foraboschi, 20 09). The support is represented by a series of discrete infinitesimal and mutually independent elastic springs These springs provide to the beam axis a distributed transverse reactive pressure proportional to the beam deflection through the Winkler constant k. Lanzoni and Radi (2016) extended the analysis by considering a shear deformable Timoshenko beam resting on an elastic and isotropic half-plane and loaded by transversal forces. In this case, a complex power stress singularity is found at the beam ends, which depends on the Poisson ratio of the half-plane. The 2D problem of a compressed Timoshenko beam of finite length in frictionless and bilateral contact with an elastic and isotropic half-plane is investigated.
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