The use of additive manufacturing technologies to produce lightweight or functional
structures is widespread. Especially Ti6Al4V plays an important role in this development …

The concept of designed cellular lattice materials is motivated by the desire to put material
only where it is needed for a specific application. From a mechanical engineering viewpoint …

Lattice structures, whose manufacturing has been enabled by additive technologies, are
gaining growing popularity in all the fields where lightweighting is imperative. Since the …

Selective laser melting (SLM) enables the manufacture of lattice structures with highly
engineered mechanical properties that are optimised for the associated design …

Additive manufacturing (AM) technology has undergone an evolutionary process from
fabricating test products and prototypes to fabricating end-user products—a major …

This study carries out an experimental characterization of lattice structures that are based on
cubic cells fabricated through selective laser melting (SLM) and electron beam melting …

The effect of using multiple materials within hexagonal and re-entrant (auxetic) cellular
structures was investigated. For each topology, three different material configurations …

Cellular solids are attractive materials due to their high specific static and dynamic
mechanical properties. Even though these mechanical domains are interdependent, they …

The design of cellular materials has recently undergone a paradigm shift, enabled by
developments in Additive Manufacturing and design software. No longer do cellular …

Additive manufacturing (AM) techniques such as selective laser melting (SLM) enable the
fabrication of complex metallic lattice structures. By tuning geometric and topological …