Embodiments relate to a method for forming a three-dimensional structure. The method includes determining one or more locations for positioning a sensing device based on structural coordinate information relating to a three-dimensional structure to be formed. The method further includes forming a portion of the three-dimensional structure based on the structural coordinate information. The method further includes positioning the sensing device at a location of the one or more locations.

A double walled stator housing includes a first stator housing wall, a second stator housing wall located radially outward from the first stator housing wall, and an air gap located between the first and the second stator housing walls. The housing also includes at least one support structure attached to the first stator housing wall and the second stator housing wall, spanning the air gap and configured to minimize heat transfer between the first wall and the second wall.

A double walled stator housing includes a first stator housing wall, a second stator housing wall located radially outward from the first stator housing wall, and an air gap located between the first and the second stator housing walls. The housing also includes at least one support structure attached to the first stator housing wall and the second stator housing wall, spanning the air gap and configured to minimize heat transfer between the first wall and the second wall.

An exemplary cushion for a fuel system is constructed of a lattice structure formed of a material that is substantially nonabsorbent of fuel and has a network of nodes and beams defining cells, an exterior surface of the lattice structure is configured to be oriented toward a fuel cell and an interior surface of the lattice structure is configured to fit to a mounting surface.

An exemplary cushion for a fuel system is constructed of a lattice structure formed of a material that is substantially nonabsorbent of fuel and has a network of nodes and beams defining cells, an exterior surface of the lattice structure is configured to be oriented toward a fuel cell and an interior surface of the lattice structure is configured to fit to a mounting surface.

A method for generating or enhancing a shell for a printed three-dimensional (3D) object includes converting a 3D print file representing the 3D object to at least one vector file representing the 3D object; using a vector trapping algorithm on the at least one vector file to generate or enhance the shell in the at least one vector file; processing the at least one vector file with the shell to produce at least one rasterized vector file; and printing, using the at least one rasterized vector file, the 3D object with the shell.

A method for generating or enhancing a shell for a printed three-dimensional (3D) object includes converting a 3D print file representing the 3D object to at least one vector file representing the 3D object; using a vector trapping algorithm on the at least one vector file to generate or enhance the shell in the at least one vector file; processing the at least one vector file with the shell to produce at least one rasterized vector file; and printing, using the at least one rasterized vector file, the 3D object with the shell.

A three-dimensional porous catalyst, catalyst carrier or absorbent structure of stacked strands of catalyst, catalyst carrier or absorbent material, composed of layers of spaced-apart parallel strands, wherein parallel strands within a layer are arranged in groups of two or more closely spaced-apart, equidistant strands separated by a small distance, wherein the groups of equidistant strands are separated from adjacent strands or adjacent groups of strands by a larger distance.

In an embodiment, an article comprises a plurality of structural units, wherein each structural unit comprises a first portion; a second portion; wherein the second portion contacts the first portion; and a third portion; wherein the third portion is in communication with the first portion and the second portion and is more compressible than the first portion and the second portion; wherein the first portion comprises a first shape memory alloy having a first preset state and wherein the second portion comprises a second shape memory alloy that has a second preset state; wherein the second preset state is different from the first preset state.

In an embodiment, an article comprises a plurality of structural units, wherein each structural unit comprises a first portion; a second portion; wherein the second portion contacts the first portion; and a third portion; wherein the third portion is in communication with the first portion and the second portion and is more compressible than the first portion and the second portion; wherein the first portion comprises a first shape memory alloy having a first preset state and wherein the second portion comprises a second shape memory alloy that has a second preset state; wherein the second preset state is different from the first preset state.