Buckling of circular cylindrical shells subject to uniform lateral pressure

A theoretical investigation of the buckling of cylindrical shells under uniform external lateral pressure loading is presented, based on Flugge's stability equations in coupled form; these lead to great accuracy. The numerical process gives the buckling pressure for a selected circumferential buckling mode, material, geometry and boundary conditions. The influence of 17 different homogeneous boundary conditions placed on the displacements u, v and w, and on the slope dw/dx is investigated. A wide range of geometries (0.5 ≤ L/R ≤ 5 and 300 ≤ R/h ≤ 3000) is considered. Comparisons are made with some analyses in the literature. It is also found that, contrary to the widespread understanding that the critical pressure for a free cylinder is the same as for a ring, the present model obtains a slightly lower buckling pressure which depends on the length.