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.

Manufacturing systems with coolant supply systems and related methods. A manufacturing system includes an additive manufacturing (AM) assembly, a milling assembly, and a coolant supply system. The AM assembly includes a support assembly that supports a build component and that is in thermal communication with the build component. The coolant supply system is configured to remove heat from the support assembly by flowing the coolant through at least a portion of the support assembly. A method of operating a manufacturing system during a manufacturing process includes detecting a manufacturing mode of the manufacturing system, forming a build component via the manufacturing process, and, at least partially concurrent with the forming the build component, selectively supplying a coolant to a support assembly and/or a milling tool. The selectively supplying the coolant is based, at least in part, on the detecting the manufacturing mode.

Methods and apparatus for producing and assessing at least part of an object (2), the methods comprise: performing, using Additive Manufacturing apparatus (8), an Additive Manufacturing process to produce a test specimen (30, 34, 38) and at least part of an object (2); performing, using micro-tomography apparatus (40), on the test specimen (30, 34, 38), a micro-tomography process to create a digital model (50) of the internal structure of the test specimen (30, 34, 38); determining whether or not the model (50) satisfies one or more criteria; and, if the model (50) satisfies the criteria, determining that the at least part of the object (2) produced by performing the Additive Manufacturing process is acceptable, or, if the model (50) does not satisfy the criteria, determining that the at least part of the object (2) produced by performing the Additive Manufacturing process is not acceptable.

A printer pressing assembly for forming material layers is provided. The printer pressing assembly includes a support assembly having a support surface, a driver and a press stop. The driver is able to change an elevation of the support surface relative to an elevation of the press stop. A nozzle is capable of dispensing a material onto the support surface. Further, a press is positionable opposite to the support surface and capable of moving relative to the support. Additionally, the press stop is capable of being elevated above the support surface so as to engage an abutment surface of the press to set a pre-determined distance between the contact surface of the press and the support surface.

A robot system is configured to fabricate three-dimensional (3D) objects using closed-loop, computer vision-based control. The robot system initiates fabrication based on a set of fabrication paths along which material is to be deposited. During deposition of material, the robot system captures video data and processes that data to determine the specific locations where the material is deposited. Based on these locations, the robot system adjusts future deposition locations to compensate for deviations from the fabrication paths. Additionally, because the robot system includes a 6-axis robotic arm, the robot system can deposit material at any locations, along any pathway, or across any surface. Accordingly, the robot system is capable of fabricating a 3D object with multiple non-parallel, non-horizontal, and/or non-planar layers.

A method for 3D printing a patient-specific bone implant having variable density, in various aspects, comprises: (1) providing a thermoplastic polymer composition comprising: (A) between about 20% and about 50% bioactive agent by weight; (B) between about 0.5% and about 10% chemical foaming agent by weight; and (C) balance structural polymer by weight; (2) receiving, by computing hardware, a scan of a bone, the scan comprising at least a 3D image of the bone and radiodensity data for the bone; and (3) causing, by the computing hardware, a 3D printer to form the patient-specific bone implant from the 3D image using the thermoplastic polymer by modifying a 3D printing temperature of the 3D printer during printing of the patient-specific bone implant such that each portion of the patient-specific bone implant is produced at a temperature that corresponds to a desired density defined by the radiodensity data for the bone.

This disclosure describes systems, methods, and apparatus for adjusting at least one actuator using at least one control output value to control a plasma processing system. More specifically, the controlling is based on receiving a reference signal defining target values for a parameter that is controlled at an output within the plasma processing system; obtaining a measure of the parameter, where the parameter is measured at a first sampling frequency; calculating one or more internal control signal values at a second sampling frequency; predicting, using an internal model, one or more internal measurements of the controlled parameter at the second sampling frequency; and adjusting, based upon the one or more control output values, at least one actuator at the first sampling frequency, where the control output values are based on the internal control signal values and the predicted internal measurements.

A system for additive metal manufacturing, including a deposition mechanism, a translation mechanism mounting the deposition mechanism to the working volume, and a stage. A method for additive metal manufacturing including: selectively depositing a material carrier within the working volume; removing an additive from the material carrier; and treating the resultant material.

A system for additive metal manufacturing, including a deposition mechanism, a translation mechanism mounting the deposition mechanism to the working volume, and a stage. A method for additive metal manufacturing including: selectively depositing a material carrier within the working volume; removing an additive from the material carrier; and treating the resultant material.

A reactor system includes a first reaction chamber, a second reaction chamber, a resource, one or more processors, and a computer readable medium storing instructions that, when executed by the one or more processors, cause the one or more processors to perform functions. The functions include making a first determination that providing a first reaction chamber access to a resource of a reactor system requires that the first reaction chamber have exclusive access to the resource. The resource includes a reactant source and/or a vacuum pump. The functions also include making a second determination that a second reaction chamber does not require access to the resource. The functions also includes providing the first reaction chamber exclusive access to the resource in response to making the second determination.