Methods and apparatus to identify additively manufactured parts are disclosed. An example apparatus includes a body, formed of layers layered substantially parallel to a base layer, composed of a first material having a first density, a first indicium embedded internally in the body as a void, and a second indicium on an external surface of the body, the second indicium aligning with the first indicium.

A system for removing and evenly completing cure of residual collected uncured resin from within a 3D printed part, which includes an enclosure which shields UV electromagnetic radiation from entering a space positioned within the enclosure. The system further includes a rotator device positioned in the space within the enclosure and a 3D printed part positioned within the space and associated with the rotator device.

A system for removing and evenly completing cure of residual collected uncured resin from within a 3D printed part, which includes an enclosure which shields UV electromagnetic radiation from entering a space positioned within the enclosure. The system further includes a rotator device positioned in the space within the enclosure and a 3D printed part positioned within the space and associated with the rotator device.

A system and method of using electrochemical additive manufacturing to add interconnection features, such as wafer bumps or pillars, or similar structures like heatsinks, to a plate such as a silicon wafer. The plate may be coupled to a cathode, and material for the features may be deposited onto the plate by transmitting current from an anode array through an electrolyte to the cathode. Position actuators and sensors may control the position and orientation of the plate and the anode array to place features in precise positions. Use of electrochemical additive manufacturing may enable construction of features that cannot be created using current photoresist-based methods. For example, pillars may be taller and more closely spaced, with heights of 200 μm or more, diameters of 10 μm or below, and inter-pillar spacing below 20 μm. Features may also extend horizontally instead of only vertically, enabling routing of interconnections to desired locations.

A synthetic barrier material includes a light-cured polymer and graphene nanoplatelets in parallel alignment in the polymer. Disclosed further is a method for manufacturing the synthetic barrier material. The graphene nanoplatelets are dispersed in a photocurable resin and polarically aligned by an electric field. Furthermore, disclosed is a synthetic barrier film manufactured from the aforementioned synthetic barrier material or the aforementioned method.

A synthetic barrier material includes a light-cured polymer and graphene nanoplatelets in parallel alignment in the polymer. Disclosed further is a method for manufacturing the synthetic barrier material. The graphene nanoplatelets are dispersed in a photocurable resin and polarically aligned by an electric field. Furthermore, disclosed is a synthetic barrier film manufactured from the aforementioned synthetic barrier material or the aforementioned method.

One or more embodiments of the present disclosure relate to partitioning of objects for additive manufacture. A method may include defining one or more partition lines in an object of a build file. The build file may comprise instructions for additively manufacturing the object. The method may also include generating part build files based on the build file and the one or more partition lines. The part build files may comprise instructions for additively manufacturing parts of the object. The method may also include generating a physical instance of each part of the object according to the part build files. The method may also include assembling the physical instances of the parts into a physical instance of the object. The method may also include applying heat to the physical instance of the object. Related devices, systems and methods are also disclosed.

A method for wetting volatile material positioned on a filter from an additive manufacturing process includes passing a passivation fluid to an interior space of a filtration system including an outer housing, a filtration medium, detecting an amount of passivation fluid passed to the interior space with a volume detection device, determining whether the amount of passivation fluid passed to the interior space is less than a configurable threshold, in response to determining that the amount of passivation fluid passed to the interior space is less than the configurable threshold, continuing to pass the passivation fluid to the interior space, and in response to determining that the amount of passivation fluid passed to the interior space is not less than the configurable threshold, stopping the passing of passivation fluid to the interior space.

The present disclosure is directed ion-exchange systems and devices that include composite ion-exchange membranes having 3D printed spacers on them. These 3D printed spacers can drastically reduce the total intermembrane spacing within the system/device while maintaining a reliable sealing surface around the exterior border of the membrane. By adding the spacers directly to the membrane using additive manufacturing, the amount of material used can be reduced without adversely impacting the manufacturability of the composite membrane as well as allow for complex spacer geometries that can reduce the restrictions to flow resulting in less pressure drop associated with the flow in the active area of the membranes.

The present disclosure is directed ion-exchange systems and devices that include composite ion-exchange membranes having 3D printed spacers on them. These 3D printed spacers can drastically reduce the total intermembrane spacing within the system/device while maintaining a reliable sealing surface around the exterior border of the membrane. By adding the spacers directly to the membrane using additive manufacturing, the amount of material used can be reduced without adversely impacting the manufacturability of the composite membrane as well as allow for complex spacer geometries that can reduce the restrictions to flow resulting in less pressure drop associated with the flow in the active area of the membranes.