Abstract: An apparatus for shaping an extrudable material comprises a sleeve, comprising a first sleeve end, a sleeve inlet at the first sleeve end, a second sleeve end, opposite the first sleeve end, and a sleeve outlet at the second sleeve end. The extrudable material enters the sleeve through the sleeve inlet and exits the sleeve through the sleeve outlet. The apparatus further comprises an actuation mechanism, selectively operable to change at least one of a size or a shape of the sleeve outlet. The sleeve is sufficiently flexible to enable the actuation mechanism to change at least one of the size or the shape of the sleeve outlet. The sleeve is insufficiently stretchable to enable the actuation mechanism to stretch the sleeve.

Abstract: Systems for thermal control of additive manufacturing comprise a build volume within which a part is additively manufactured; a heat source positioned relative to the build volume and configured to actively deliver heat to discrete sections of the part as it is being additively manufactured; and a controller operatively coupled to the heat source and configured to direct delivery of heat from the heat source to discrete sections of the part as it is being additively manufactured to impart desired physical properties to the part. Methods of additively manufacturing a part comprise additively building a part from a feedstock material; and actively heating discrete sections of the part as the part is being additively built to impart desired physical properties to the part.

Abstract: Methods of additively manufacturing a part comprise dispensing a multi-part filament in three dimensions. The multi-part filament comprises an elongate filament body comprising a first body part extending longitudinally along the elongate filament body and comprising a first material that is configured to be cured responsive to a first cure condition, and a second body part extending longitudinally along the elongate filament body and comprising a second material that is configured to be cured responsive to a second cure condition that is different from the first cure condition. Methods also comprise concurrently with the dispensing, delivering curing energy corresponding to the first cure condition to impart a desired rigidity characteristic to the first body part to facilitate printing of self-supporting structures from the multi-part filament.

Abstract: Systems and methods for additively manufacturing composite parts are disclosed. Methods comprise combining a plurality of pre-consolidated tows to define a macro tow and dispensing the macro tow in three dimensions to define the composite part. Each pre-consolidated tow comprises a fiber tow within a non-liquid binding matrix. The combining comprises actively altering a shape and/or size of a cross-sectional profile of the macro tow along a length of the macro tow as it is being defined.

Abstract: A method for protecting an underlying structure from directed energy including combining an intumescent material with the underlying structure. The intumescent material forms a barrier to directed energy received on the intumescent material, the barrier suppressing or impeding transmission of the directed energy, and heat generated in the barrier by the directed energy, to the underlying structure.

Abstract: Various techniques are provided for an expandable energy absorbing fluid bladder. In one example, the fluid bladder includes a primary portion and a secondary portion. The secondary portion can be configured to expand or increase in volume when the fluid bladder is subjected to a pulse greater than a threshold pulse. Expansion of the secondary portion can allow fluid or additional fluid to flow into the secondary portion and thus decrease a peak pulse and, thus, avoid rupture of the fluid bladder.

Abstract: An apparatus for shaping an extrudable material comprises a sleeve, comprising a first sleeve end, a sleeve inlet at the first sleeve end, a second sleeve end, opposite the first sleeve end, and a sleeve outlet at the second sleeve end. The extrudable material enters the sleeve through the sleeve inlet and exits the sleeve through the sleeve outlet. The apparatus further comprises an actuation mechanism, selectively operable to change at least one of a size or a shape of the sleeve outlet. The sleeve is sufficiently flexible to enable the actuation mechanism to change at least one of the size or the shape of the sleeve outlet. The sleeve is insufficiently stretchable to enable the actuation mechanism to stretch the sleeve.

Abstract: Systems for cure control of additive manufacturing comprise a build volume, a curing energy source, and a controller. The curing energy source is configured to actively deliver curing energy to discrete sections of a part as it is being additively manufactured. The controller is programmed to direct delivery of curing energy to impart desired cure properties to the discrete sections and/or according to predetermined cure profiles for the discrete sections. Methods of additively manufacturing a part comprise additively building a part from a feedstock material, and actively curing discrete sections of the part as it is being additively built to impart desired cure properties to the part and/or desired cure profiles to the part.

Abstract: An apparatus for shaping an extrudable material comprises a sleeve, comprising a first sleeve end, a sleeve inlet at the first sleeve end, a second sleeve end, opposite the first sleeve end, and a sleeve outlet at the second sleeve end. The extrudable material enters the sleeve through the sleeve inlet and exits the sleeve through the sleeve outlet. The apparatus further comprises an actuation mechanism, selectively operable to change at least one of a size or a shape of the sleeve outlet. The sleeve is sufficiently flexible to enable the actuation mechanism to change at least one of the size or the shape of the sleeve outlet. The sleeve is insufficiently stretchable to enable the actuation mechanism to stretch the sleeve.

Abstract: Additive manufacturing fiber composites comprise a bundle of elongate fibers and a matrix material that holds or encompasses the elongate fibers of the additive manufacturing fiber tow. The matrix material includes an energy-emissive dopant that emits a curing energy in response to receiving an activating energy. The curing energy effects curing of the solidifiable matrix material so that it solidifies to a rigid or semi-rigid matrix material. Methods of additively manufacturing an article include dispensing an additive manufacturing fiber tow, a solidifiable matrix material, and an energy-emissive dopant to form a solidifiable composite, and applying the activating energy to the energy-emissive dopant to activate the energy-emissive dopant to emit the curing energy. Systems to additively manufacturing an article may be configured to employ such additive manufacturing fiber composites and/or methods.

Abstract: Systems for additive manufacturing comprise a delivery guide configured to dispense a curable material to additively manufacture a part in sequential layers of the curable material, and a source of curing energy configured to direct the curing energy to a discrete region of the curable material forward of or at a location where a subsequent layer of the curable material is dispensed from the delivery guide against a preceding layer of the curable material to cure together the subsequent layer and the preceding layer. Methods of additively manufacturing comprise dispensing a subsequent layer of a curable material against a preceding layer of the curable material, and concurrently with the dispensing, directing curing energy to a discrete region of the curable material to cure together the subsequent layer and the preceding layer.

Abstract: An optical waveguide is configured such that when electromagnetic radiation enters a first end face of an optical core, an initial portion of the electromagnetic radiation exits the optical core via a peripheral surface, and a final portion of the electromagnetic radiation, remaining in the optical core after the initial portion of the electromagnetic radiation exits the optical core, exits the optical core via a second end face.

Abstract: Various techniques are provided for an energy absorbing fluid bladder. In one example, the fluid bladder includes a bladder body and a perforated baffle structure. The perforated baffle structure can be disposed within the bladder body and configured to mitigate a pulse of fluid (e.g., fuel) moving within the bladder body before the pulse reaches the bladder body. Related methods are also disclosed.

Abstract: Methods of additively manufacturing a part comprise dispensing a multi-part filament in three dimensions. The multi-part filament comprises an elongate filament body comprising a first body part extending longitudinally along the elongate filament body and comprising a first material that is configured to be cured responsive to a first cure condition, and a second body part extending longitudinally along the elongate filament body and comprising a second material that is configured to be cured responsive to a second cure condition that is different from the first cure condition. Methods also comprise concurrently with the dispensing, delivering curing energy corresponding to the first cure condition to impart a desired rigidity characteristic to the first body part to facilitate printing of self-supporting structures from the multi-part filament.

Abstract: A system for additively manufacturing an object comprises feedstock-line supply, delivery guide, and curing mechanism. The feedstock-line supply dispenses a feedstock line that comprises elongate filaments, a resin that covers the elongate filaments, and at least one optical modifier that is interspersed among the elongate filaments. The delivery guide is movable relative to a surface, receives the feedstock line, and deposits it along a print path. The curing mechanism is directs electromagnetic radiation at the exterior surface of the feedstock line after it is deposited along the print path. When the electromagnetic radiation strikes the outer surface of at least one optical modifier, the optical modifier causes the electromagnetic radiation to irradiate, in the interior volume of the feedstock line, the resin that, due at least in part to the elongate filaments, is not directly accessible to the electromagnetic radiation, incident on the exterior surface of the feedstock line.

Abstract: A feedstock line comprises elongate filaments, a resin, and a full-length optical waveguide, comprising a full-length optical core. The full-length optical waveguide is configured such that when electromagnetic radiation enters the full-length optical core via at least one of a first full-length-optical-core end face, a second full-length-optical-core end face, or a full-length peripheral surface that extends between the first full-length-optical-core end face and the second full-length-optical-core end face, at least a portion of the electromagnetic radiation exits the full-length optical core via the full-length peripheral surface to irradiate, in an interior volume of the feedstock line, the resin that, due at least in part to the elongate filaments, is not directly accessible to the electromagnetic radiation, incident on the exterior surface of the feedstock line.

Abstract: A feedstock line comprises elongate filaments, a resin, and a full-length optical waveguide, comprising a full-length optical core. The full-length optical waveguide is configured such that when electromagnetic radiation enters the full-length optical core via at least one of a first full-length-optical-core end face, a second full-length-optical-core end face, or a full-length peripheral surface that extends between the first full-length-optical-core end face and the second full-length-optical-core end face, at least a portion of the electromagnetic radiation exits the full-length optical core via the full-length peripheral surface to irradiate, in an interior volume of the feedstock line, the resin that, due at least in part to the elongate filaments, is not directly accessible to the electromagnetic radiation, incident on the exterior surface of the feedstock line.

Abstract: Multi-part filaments for additive manufacturing comprise an elongate filament body. The elongate filament body comprises a first body part extending longitudinally along the elongate filament body, and a second body part extending longitudinally along the elongate filament body. The first body part comprises a first material, and the second body part comprises a second material. One of the first body part and the second body part is more rigid than the other of the first body part and the second body part and is sufficiently rigid to print self-supporting structures from the multi-part filament.

Abstract: A feedstock line comprises elongate filaments, a resin, and a full-length optical waveguide, comprising a full-length optical core. The full-length optical waveguide is configured such that when electromagnetic radiation enters the full-length optical core via at least one of a first full-length-optical-core end face, a second full-length-optical-core end face, or a full-length peripheral surface that extends between the first full-length-optical-core end face and the second full-length-optical-core end face, at least a portion of the electromagnetic radiation exits the full-length optical core via the full-length peripheral surface to irradiate, in an interior volume of the feedstock line, the resin that, due at least in part to the elongate filaments, is not directly accessible to the electromagnetic radiation, incident on the exterior surface of the feedstock line.

Abstract: Systems and methods for additively manufacturing composite parts are disclosed. Methods comprise combining a plurality of pre-consolidated tows to define a macro tow and dispensing the macro tow in three dimensions to define the composite part. Each pre-consolidated tow comprises a fiber tow within a non-liquid binding matrix. The combining comprises actively altering a shape and/or size of a cross-sectional profile of the macro tow along a length of the macro tow as it is being defined.