The application relates to a method for producing a hollow support from a fiber composite material, to a core designed as a hollow body, to the use of said core, and to the use of said hollow support made from fiber composite material.

The present invention relates to a process for manufacturing a silicone elastomer article comprising the following step: 1) providing a composition C, comprising water and at least 20% by weight of at least one poloxamer, into a container; 2) placing the container comprising the composition C at the required temperature T1 to form a gel; 3) printing a crosslinkable silicone composition X into the gel obtained in 2) with a 3D printer at the required temperature T1; 4) optionally allowing the printed composition X to partially or totally crosslink, optionally by heating, to obtain a silicone elastomer article, into the container; 5) optionally placing the container obtained in step 4) at a temperature T3 lower than the sol-gel transition temperature of composition C; 6) recovering the silicone elastomer article; and 7) optionally washing the obtained silicone elastomer article for example with water at a temperature T3 lower than the sol-gel transition temperature of composition C.

A multi-matrix composite socket includes struts formed from a first matrix composite and inner and outer layers relative to the struts formed from at least a second matrix composite. Each matrix composite is comprised of fibers embedded in a resin. The fibers create spaces into which a flowable resin infuses during manufacturing and also reinforce the resin. A base and a plurality of struts are assembled and positioned over a first fabric layer and a second fabric layer is positioned over the struts. A resin is infused into the spaces defined by the first and second fabric layers and around the struts to form an over-molded multi-composite matrix socket.

The application relates to a method for producing a hollow support from a fiber composite material, to a core designed as a hollow body, to the use of said core, and to the use of said hollow support made from fiber composite material.

Embodiments of the present invention relates to an acoustic metamaterial, as well as to a method for manufacturing the same. The acoustic metamaterial includes a plurality of channels or columns each having the same cross-section with a hydraulic radius between 5 and 300 ?m, which channels or columns are arranged with a periodic spacing between 2 and 600 ?m. This results in a highly dense network that can provide optimal acoustic absorption and/or impedance over a wide frequency range. The method for manufacturing the same includes additive manufacturing with a plurality of consecutive material deposition steps to form, in each step, a layer comprising a plurality of periodically repeated cells separated by walls. The layers deposited in the consecutive material deposition steps are stacked with their respective cells aligned to form channels.

A method for producing three-dimensional parts, which includes printing the three-dimensional parts and associated support structures onto soluble build sheets, marking each three-dimensional part with information relating to the three-dimensional part, and removing the associated support structures and the soluble build sheets from the printed three-dimensional parts with an aqueous solution using a support removal process. The markings remain applied to the three-dimensional parts after the support removal process, and preferably do not detract from aesthetic qualities of the three-dimensional parts.