Abstract: Systems and methods for predicting weld and/or part defects during additive manufacturing process are disclosed. Additionally, systems and methods related to controlling an additive manufacturing process using predicted weld and/or build defects are disclosed.

Abstract: Laser control systems and related methods for controlling arrays of lasers are disclosed. A laser control system may include a first controller configured to generate a trigger signal based on a position of a laser array, and a second controller configured to send a firing signal to one or more lasers of the laser array upon receiving the trigger signal. The one or more lasers may be selected based on a desired pattern of laser energy to be formed at a particular position of the laser array.

Abstract: Laser control systems and related methods for controlling arrays of lasers are disclosed. A laser control system may include a first controller configured to generate a trigger signal based on a position of a laser array, and a second controller configured to send a firing signal to one or more lasers of the laser array upon receiving the trigger signal. The one or more lasers may be selected based on a desired pattern of laser energy to be formed at a particular position of the laser array.

Abstract: An additive manufacturing system may include a build surface and an optics assembly movable relative to the build surface. The optics assembly may direct laser energy from one or more laser energy sources toward the build surface to melt a portion of the build surface. The system may further comprise a gas flow head operatively coupled to the optics assembly and moveable relative to the build surface. The gas flow head may define a partially enclosed volume between the optics assembly and the build surface. The gas flow head may generate a non-uniform flow of gas through the gas flow head in a direction that is opposite a direction of motion of the optics assembly. A velocity of the gas flow may be sufficient to entrain particles ejected from the melted portion of the layer of material in order to remove the ejected particles from the partially enclosed volume.

Abstract: Systems and methods for additive manufacturing are described. In some embodiments, a method of controlling the one or more laser energy sources of an additive manufacturing system may be based at least in part on a scan angle and/or desired energy density. Systems and methods for controlling melt pool spacing are also described.

Abstract: Systems and methods for additive manufacturing are described. In some embodiments, a method of controlling a weld height in an additive manufacturing process includes determining a desired melt pool width based, at least in part, on a desired weld height; selectively activating one or more laser energy sources based, at least in part, on the desired melt pool width; and melting a portion of a layer of material on a build surface via exposure to laser energy from the one or more activated laser energy sources to form a melt pool on the build surface having the desired melt pool width. Systems and methods to the use of staggered laser energy sources are also described.

Abstract: Laser control systems and related methods for controlling arrays of lasers are disclosed. A laser control system may include a first controller configured to generate a trigger signal based on a position of a laser array, and a second controller configured to send a firing signal to one or more lasers of the laser array upon receiving the trigger signal. The one or more lasers may be selected based on a desired pattern of laser energy to be formed at a particular position of the laser array.

Abstract: The present invention relates to crystals of pyruvate dehydrogenase kinase (PDHK) wherein the PDHK protein includes PDHK-2 amino acid sequence as shown in SEQ ID NO: 2 but starting at amino acid position 16, or a homologue, fragment, variant or derivative thereof.). The invention also relates to high resolution three dimensional structures of PDHK in the presence and absence of physiological and synthetic ligands obtained by X-ray diffraction and use of the structures to identify, design or select compounds that bind to PDHK. The invention further relates to compounds identified, designed or selected using high resolution structures of PDHK. Also provided are nucleotide sequences used to obtain crystallisable PDHK protein.