An electrochemical additive manufacturing method includes coupling a first electronic device to a build plate and positioning the build plate into an electrolyte solution. The method also includes positioning a deposition anode array into the electrolyte solution, connecting the cathode portion of the build plate and one or more deposition anodes of the abide array to a power source. The method also includes transmitting electrical energy from the power source, through the one or more deposition anodes, through the electrolyte solution, and to the cathode portion of the build plate, such that material is deposited onto the cathode portion and forms at least a sidewall of a shell that encases the first electronic device against the build plate when the first electronic device is coupled to the build plate. The shell and the first electronic device form a second electronic device.

An electrochemical additive manufacturing method includes positioning a build plate into an electrolyte solution. The conductive layer comprises at least one conductive-layer segment forming a pattern corresponding with a component. The method further comprises connecting the at least one conductive-layer segment and one or more deposition anodes to a power source. The one or more deposition anodes correspond with at least a portion of the pattern formed by the at least one conductive-layer segment. The method additionally comprises transmitting electrical energy from the power source through the one or more deposition anodes of the plurality of deposition anodes corresponding with the at least the portion of the pattern formed by the at least one conductive-layer segment, through the electrolyte solution, and to the at least one conductive-layer segment, such that material is deposited onto the at least one conductive-layer segment and forms at least a portion of the component.

A method of forming a near-net shape structure comprises forming a structure comprising non-stoichiometric metal oxide comprising at least one metal and less than a stoichiometric amount of oxygen, and electrochemically reducing the non-stoichiometric metal oxide in an electrochemical cell to form a structure having a near-net shape and comprising the at least one metal having less than about 1,500 ppm oxygen. Related methods of forming a non-stoichiometric metal oxide by sintering, annealing, or additive manufacturing, and forming a near-net shape structure from the non-stoichiometric metal oxide, as well as related electrochemical cells are also disclosed.

A method to control the density of a three-dimensional photonic crystal template involves changing the irradiation time from at least four laser beams to yield a periodic percolating matrix of mass and voids free of condensed matter from a photoresist composition. The photoresist composition includes a photoinitiator at a concentration where the dose or irradiation is controlled by the irradiation time and is less than the irradiation time that would convert all photoinitiator to initiating species such that the density of the three-dimensional photonic crystal template differs for different irradiation times. A deposition of reflecting or absorbing particles can be patterned on the surface of the photoresist composition to form a template with varying densities above different areas of the substrate.

An electroforming system and method for electroforming a component that includes a first housing and a second housing, where the second housing can define a conformable electroforming reservoir with a base structure. An electrically insulating sheet covers at least a portion of the base structure and defines a fluid passage where the component is to be located.

In one embodiment, a method for manufacturing an aperture plate includes depositing a releasable seed layer above a substrate, applying a first patterned photolithography mask above the releasable seed layer, the first patterned photolithography mask having a negative pattern to a desired aperture pattern, electroplating a first material above the exposed portions of the releasable seed layer and defined by the first mask, applying a second photolithography mask above the first material, the second photolithography mask having a negative pattern to a first cavity, electroplating a second material above the exposed portions of the first material and defined by the second mask, removing both masks, and etching the releasable seed layer to release the first material and the second material. The first and second material form an aperture plate for use in aerosolizing a liquid. Other aperture plates and methods of producing aperture plates are described according to other embodiments.

The present invention relates to a 3D printing device using selective electrochemical deposition and particularly to a 3D printing device capable of selectively depositing metal materials onto a substrate by using additive manufacturing by electrochemical deposition (electrochemical additive manufacturing, ECAM).

Described herein are electrochemical-additive manufacturing methods and systems using such methods. A method comprises depositing a material onto a deposition electrode by flowing a current between that deposition electrode and each of multiple individually-addressable electrodes, forming an electrode array. These currents are independently controlled based on a target map and using deposition control circuits, each coupled to one individually-addressable electrode. The target map is generated by a system controller based on various characteristics of the system (e.g., the performance of each deposition control circuit and/or individually-addressable electrode, electrolyte composition) and the desired characteristics of the deposited material (e.g., deposition location, uniformity, morphology). Furthermore, when the deposition electrode and the electrode array move relative to each other, the system controller dynamically updates the target map based on their relative positions. This movement can provide a fresh electrolyte between the electrodes and enable deposition at new locations.

An electroforming system and method for electroforming a component that includes a first housing and a second housing, where the second housing can define a conformable electroforming reservoir with a base structure that defines a fluid passage. The first housing can include a dissolution reservoir containing an electrolytic fluid that is fluidly coupled to the fluid passage of the second housing.

The present invention relates to a three-dimensional printing device using selective electrochemical deposition and particularly to a three-dimensional printing device capable of selectively depositing metal materials onto a substrate by using additive manufacturing by electrochemical deposition (electrochemical additive manufacturing, ECAM).