A method may include fused filament fabricating a fused filament fabricated component by delivering a softened filament to selected locations at or adjacent to a build surface. The softened filament may include a sacrificial binder and a powder including a shape memory alloy (SMA). The method also may include removing substantially all the sacrificial binder from the fused filament fabricated component to leave an unsintered component; and sintering the unsintered component to join particles of the SMA and form an SMA component.

A method may include fused filament fabricating a fused filament fabricated component by delivering a softened filament to selected locations at or adjacent to a build surface. The softened filament may include a sacrificial binder and a powder including a shape memory alloy (SMA). The method also may include removing substantially all the sacrificial binder from the fused filament fabricated component to leave an unsintered component; and sintering the unsintered component to join particles of the SMA and form an SMA component.

Herein disclosed is a method of treating a component of a fuel cell, which includes the step of exposing the component of the fuel cell to a source of electromagnetic radiation (EMR). The component comprises a first material. The EMR has a wavelength ranging from 10 to 1500 nm and the EMR has a minimum energy density of 0.1 Joule/cm2. Preferably, the treatment process has one or more of the following effects: heating, drying, curing, sintering, annealing, sealing, alloying, evaporating, restructuring, foaming. In an embodiment, the substrate is a component in a fuel cell. Such component comprises an anode, a cathode, an electrolyte, a catalyst, a barrier layer, a interconnect, a reformer, or reformer catalyst. In an embodiment, the substrate is a layer in a fuel cell or a portion of a layer in a fuel cell or a combination of layers in a fuel cell or a combination of partial layers in a fuel cell.

Herein disclosed is a method of treating a component of a fuel cell, which includes the step of exposing the component of the fuel cell to a source of electromagnetic radiation (EMR). The component comprises a first material. The EMR has a wavelength ranging from 10 to 1500 nm and the EMR has a minimum energy density of 0.1 Joule/cm2. Preferably, the treatment process has one or more of the following effects: heating, drying, curing, sintering, annealing, sealing, alloying, evaporating, restructuring, foaming. In an embodiment, the substrate is a component in a fuel cell. Such component comprises an anode, a cathode, an electrolyte, a catalyst, a barrier layer, a interconnect, a reformer, or reformer catalyst. In an embodiment, the substrate is a layer in a fuel cell or a portion of a layer in a fuel cell or a combination of layers in a fuel cell or a combination of partial layers in a fuel cell.

Described herein are additive manufacturing systems and methods for printing 3D objects.

Described herein are additive manufacturing systems and methods for printing 3D objects.

Disclosed are 3D printing equipment, a system, and a method for food design and production. The 3D printing equipment has a bipolar microwave heating antenna for focusing heating on a material in an extrusion nozzle. The extrusion nozzle is between the anode antenna and the cathode antenna of the bipolar microwave heating antenna. The anode antenna and the cathode antenna limit a microwave electric field between them, thereby implementing focused heating on the material.

Disclosed are 3D printing equipment, a system, and a method for food design and production. The 3D printing equipment has a bipolar microwave heating antenna for focusing heating on a material in an extrusion nozzle. The extrusion nozzle is between the anode antenna and the cathode antenna of the bipolar microwave heating antenna. The anode antenna and the cathode antenna limit a microwave electric field between them, thereby implementing focused heating on the material.

Various implementations include a three-dimensional printing device. The device includes a primary extruder, a secondary extruder, and a build plate. The primary extruder has a hollow primary body for accepting a printing material. An end of the primary body defines a primary extruder opening shaped to extrude a primary extrusion of melted printing material. The secondary extruder has a hollow secondary body for accepting a printing material. An end of the secondary body defines a secondary extruder opening shaped to extrude a secondary extrusion of melted printing material. A first primary extrusion extruded from the primary extruder disposed side by side with a second primary extrusion extruded from the primary extruder adjacent the build plate in a first layer defines a gap between adjacent edges of the first and second primary extrusions. A first secondary extrusion extruded from the secondary extruder is disposable in a second layer in the gap.

Various implementations include a three-dimensional printing device. The device includes a primary extruder, a secondary extruder, and a build plate. The primary extruder has a hollow primary body for accepting a printing material. An end of the primary body defines a primary extruder opening shaped to extrude a primary extrusion of melted printing material. The secondary extruder has a hollow secondary body for accepting a printing material. An end of the secondary body defines a secondary extruder opening shaped to extrude a secondary extrusion of melted printing material. A first primary extrusion extruded from the primary extruder disposed side by side with a second primary extrusion extruded from the primary extruder adjacent the build plate in a first layer defines a gap between adjacent edges of the first and second primary extrusions. A first secondary extrusion extruded from the secondary extruder is disposable in a second layer in the gap.