A method for manufacturing a part includes fabricating an object in an additive fabrication stage, the object including a solid mold forming a cavity in the shape of a part with uncured or incompletely cured build material disposed therein. The build material in the cavity is cured in a curing stage that occurs at least partially after the additive fabrication stage. The build material undergoes a phase change mechanism occurring during the additive fabrication stage and a distinct polymerization mechanism occurring during the curing stage and at least partly after the additive fabrication stage of the object and cures the build material by a polymerization process.

A method of forming a bathtub includes forming a core from a core material, coupling the core to a bathtub shell, applying a reinforcing material to the bathtub shell over the core to form a reinforcement structure, forming one or more openings in the bathtub shell, and substantially removing the core from between the bathtub shell and the reinforcement structure to define one or more fluid channels of the bathtub.

A method of forming a sandwich structure including at least partially filling an open volume of an open cellular core with a sacrificial mold material, consolidating the sacrificial mold material to form a sacrificial mold, laying up a composite facesheet on each of at least two surfaces of the open cellular core, co-curing the composite facesheets by applying a consolidation temperature and a compaction pressure to the composite facesheets to form the sandwich structure, and removing the sacrificial mold. The compaction pressure is greater than a compressive strength of the open cellular core and less than a combined compressive strength of the open cellular core and the sacrificial mold.

A method for manufacturing a fiber reinforced structure includes the following. A mandrel of a first material comprises a hollow interior and an aperture that allows a fluid to enter the interior. A layer of a second material provided on the mandrel includes an uncured resin and fibers. The mandrel and the layer are placed in a mold cavity formed by a mold. A pressurized fluid is introduced into the interior of the mandrel via the aperture to generate a force acting to expand the mandrel outward. The mandrel is heated so that it becomes deformable and expand outward to press the layer against the mold. The layer is heated so that it cures. The mandrel is then heated to a temperature above its melting point of the first material so that it melts, after which it is removed.

A method for manufacturing a fiber reinforced structure includes the following. A mandrel of a first material comprises a hollow interior and an aperture that allows a fluid to enter the interior. A layer of a second material provided on the mandrel includes an uncured resin and fibers. The mandrel and the layer are placed in a mold cavity formed by a mold. A pressurized fluid is introduced into the interior of the mandrel via the aperture to generate a force acting to expand the mandrel outward. The mandrel is heated so that it becomes deformable and expand outward to press the layer against the mold. The layer is heated so that it cures. The mandrel is then heated to a temperature above its melting point of the first material so that it melts, after which it is removed.

A liquid resin composition comprising: a first proportion of acryloyl morpholine monomers; a second proportion of a photoinitiator exhibiting photodissociation into reactive subspecies responsive to selective exposure to radiation within a spectrum, the reactive subspecies polymerizing the first proportion of acryloyl morpholine; a third proportion of a radiation blocker absorbing radiation within the spectrum to limit penetration depth of incident radiation within the spectrum in the liquid resin; a fourth proportion of a polymerization inhibitor limiting an average chain length of acryloyl morpholine polymer polymerized from the first proportion of acryloyl morpholine monomers; and a fifth proportion of a temperature-stabilizer increasing the heat-deflection temperature of acryloyl morpholine polymer polymerized from the first proportion of acryloyl morpholine monomers.

A liquid resin composition comprising: a first proportion of acryloyl morpholine monomers; a second proportion of a photoinitiator exhibiting photodissociation into reactive subspecies responsive to selective exposure to radiation within a spectrum, the reactive subspecies polymerizing the first proportion of acryloyl morpholine; a third proportion of a radiation blocker absorbing radiation within the spectrum to limit penetration depth of incident radiation within the spectrum in the liquid resin; a fourth proportion of a polymerization inhibitor limiting an average chain length of acryloyl morpholine polymer polymerized from the first proportion of acryloyl morpholine monomers; and a fifth proportion of a temperature-stabilizer increasing the heat-deflection temperature of acryloyl morpholine polymer polymerized from the first proportion of acryloyl morpholine monomers.

A method of manufacturing a core for a production process and to a core manufactured in accordance with the method are provided. The method includes providing a mold containing a soluble substance and one or more fibers and causing the soluble substance to solidify around the one or more fibers.

A structural component having an internal support structure extending between outer wall portions of the component with one or more compartments included within the support structure. The support structure has support members including internal walls positioned between and/or defined by the compartments. At least one support member connects between the outer wall portions of the component to enhance the structural integrity of the component. The structural component, including the internal support, are cast from a molten material, and in some cases the support members of the internal support structure are formed with a rectilinear configuration. In some cases the cast structural component is a container and the one or more compartments are configured to store a fluid, such as a gas or a liquid. One or more preforms can be used to form a container and may be retained or eliminated from the container after casting.

A method for manufacturing a part includes fabricating an object in an additive fabrication stage, the object including a solid mold forming a cavity in the shape of a part with uncured or incompletely cured build material disposed therein. The build material in the cavity is cured in a curing stage that occurs at least partially after the additive fabrication stage. The build material undergoes a phase change mechanism occurring during the additive fabrication stage and a distinct polymerization mechanism occurring during the curing stage and at least partly after the additive fabrication stage of the object and cures the build material by a polymerization process.