https://yuzhe-liu-lab.github.io/tag/tubular-structures/Tubular StructuresHugo Blox Builder (https://hugoblox.com)en-usSat, 01 Oct 2016 00:00:00 +0000https://yuzhe-liu-lab.github.io/media/icon_hu12240421747060588630.pnghttps://yuzhe-liu-lab.github.io/tag/tubular-structures/https://yuzhe-liu-lab.github.io/publication/2016-axial-compression-tubular-structures/Sat, 01 Oct 2016 00:00:00 +0000https://yuzhe-liu-lab.github.io/publication/2016-axial-compression-tubular-structures/<p> <figure > <div class="d-flex justify-content-center"> <div class="w-100" ><img alt="Representative tubular structures under axial compression." srcset=" /publication/2016-axial-compression-tubular-structures/featured_hu18029595973911694047.webp 400w, /publication/2016-axial-compression-tubular-structures/featured_hu1485693687679287191.webp 760w, /publication/2016-axial-compression-tubular-structures/featured_hu15627925404650108334.webp 1200w" src="https://yuzhe-liu-lab.github.io/publication/2016-axial-compression-tubular-structures/featured_hu18029595973911694047.webp" width="760" height="402" loading="lazy" data-zoomable /></div> </div></figure> </p> <h2 id="abstract">Abstract</h2> <p>Tubular structures such as circular tubes and square tubes under axial compression are widely used as structural components in engineering applications. Considering differences in tube geometries, boundary conditions and material properties, this review classifies tube failure under axial compression into five mechanisms: progressive buckling, global buckling, inversion, expansion and splitting. Theoretical, experimental and numerical studies on these failure modes are reviewed, and the mechanical responses and energy absorption properties are compared and discussed.</p>