A 3D printer includes an ejector device for mixing and ejecting print material, the ejector device comprising a substrate and a plurality of ejector conduits on the substrate. The ejector conduits are arranged in an array, each ejector conduit comprising: a first passageway fluidly connecting a first end of the ejector conduit to a conduit junction, the first end configured to accept a first print material; a second passageway fluidly connecting a second end of the ejector conduit to the conduit junction, the second end configured to accept a second print material; and a third passageway fluidly connecting a third end of the ejector conduit to the conduit junction. The third end comprises an ejector nozzle, the ejector nozzle comprising a first electrode and a second electrode, at least one surface of the first electrode being exposed in the third passageway and at least one surface of the second electrode being exposed in the third passageway. A current pulse generating system is in electrical connection with the first electrode and the second electrode of the plurality of ejector conduits. A magnetic field source is sufficiently proximate the second end of the plurality of ejector conduits so as to generate a flux region disposed within the ejector nozzle of the plurality of ejector conduits during operation of the 3D printer. The 3D printer further comprises a positioning system for controlling the relative position of the ejector device with respect to a print substrate in a manner that would allow the print substrate to receive print material jettable from the ejector nozzle of the plurality of ejector conduits during operation of the 3D printer.

A three-dimensional (“3D”) printer. The 3D printer includes: a plurality of ejector conduits arranged in an array, each ejector conduit comprising a first end positioned to accept a print material, a second end comprising an ejector nozzle, and a passageway defined by an inner surface of the ejector conduit for allowing the print material to pass through the ejector conduit from the first end to the second end, the ejector nozzle comprising a first electrode and a second electrode, at least one surface of the first electrode being exposed in the passageway and at least one surface of the second electrode being exposed in the passageway; a current pulse generating system in electrical contact with the ejector nozzle of each of the plurality of ejector conduits; a magnetic field source sufficiently proximate the second end of the ejector conduit so as to generate a flux region disposed within the ejector nozzle during operation of the 3D printer; and a positioning system for controlling the relative position of the array with respect to a print substrate in a manner that would allow the print substrate to receive print material jettable from the ejector nozzle of each of the plurality of ejector conduits during operation of the 3D printer.

An ejector for an additive manufacturing printing system is disclosed, including an ejector body having a nozzle, a heating element to heat a solid printing material in the ejector, causing the solid printing material to change to a liquid printing material, and a piston disposed within the ejector body capable of translational motion. The ejector may include a segmented solenoid coil wrapped at least partially around the ejector body, which may be powered to cause the piston to translate along a longitudinal axis of the ejector thereby causing one or more drops of the liquid printing material to be jetted out of the nozzle. A method of ejecting liquid from an ejector is also disclosed, including melting a printing material within an ejector to form a liquid printing material, and moving a piston towards an ejector nozzle, and ejecting a drop of liquid printing material from the ejector nozzle.

A three-dimensional (3D) printer includes an ejector and a heating element configured to heat a solid printing material in the ejector, thereby causing the solid printing material to change to a liquid printing material within the ejector. The 3D printer also includes a coil wrapped at least partially around the ejector. The 3D printer also includes a power source configured to supply one or more pulses of power to the coil, which cause one or more drops of the liquid printing material to flow out of the ejector through a nozzle of the ejector. The 3D printer also includes a gas-controlling device configured to control a gas in the 3D printer.

A method of controlling drop mass in a liquid ejector is disclosed which includes advancing a printing material feed source to introduce a quantity of a printing material into a liquid ejector, counting a quantity of ticks produced by an encoder coupled to the printing material source during a time period to calculate a mass of the printing material, counting a quantity of pulses produced by the liquid ejector during the time period, and entering into a control system the quantity of ticks produced by the encoder and the quantity of pulses produced by the liquid ejector. The method may include comparing the quantity of printing material calculated by using the quantity of ticks produced by the encoder to the quantity of printing material measured by using a level sensing system. The method of controlling drop mass in a liquid ejector may include steps performed by a microprocessor.

A method for metal jetting is disclosed. The method for metal jetting includes introducing a first gas into an outer nozzle of an ejector nozzle from a first gas source introducing an additive to the first gas from a second source, combining the additive with the first gas. The method for metal jetting also includes ejecting a droplet of molten metal printing material from the ejector nozzle. The method for metal jetting includes allowing the additive to react with the droplet of molten metal printing material to form a modified molten metal printing material.

A three-dimensional (3D) metal object manufacturing apparatus is equipped with a movable directed energy source to melt hardened metal drops and form an oxidation layer. A metal support structure can be formed over the oxidation layer, an object feature can be formed over the oxidation layer, or both a metal support structure and an object feature can be formed over oxidation layers located at opposite sides of a metal support structure. The oxidation layers weakly attach the metal support structure to the object feature supported by the metal support structure so the support structure can be easily removed after manufacture of the object is complete.

A metal ejecting apparatus is disclosed. The metal ejecting apparatus includes a nozzle orifice in connection with the inner cavity and configured to eject one or more droplets of the liquid metal printing material, a float in contact with a surface of the liquid metal printing material, where the float is buoyant within the liquid printing material, and a filament attached to the float on a first end and attached to a level sensing system on a second end. The level sensing system may include an ultrasonic sensor, a visual sensor, a mechanical force sensor, a laser sensor, or a combination thereof. A method of sensing and controlling a level of liquid printing material in a metal jetting apparatus is also disclosed.

A method for operating a printer can include placing a first print material into a supply reservoir of the printer. The method also includes placing a second print material into the supply reservoir to combine with the first print material to form a diluted print material. The method also includes causing the diluted print material to exit the supply reservoir. Another method for operating a printer includes adding a first print material having a first melting point to a supply reservoir at a first rate. The method also includes adding a second print material having a second melting point to a supply reservoir at a second rate. The method for operating a printer also includes allowing the first print material and the second print material to combine to form a diluted print material. A printing system is also disclosed.

A system for forming a bulk material having insulated boundaries from a metal material and a source of an insulating material is provided. The system includes a heating device, a deposition device, a coating device, and a support configured to support the bulk material. The heating device heats the metal material to form particles having a softened or molten state and the coating device coats the metal material with the insulating material from the source and the deposition device deposits particles of the metal material in the softened or molten state on the support to form the bulk material having insulated boundaries.