Abstract: Composite parts (100) and methods of making the same are disclosed. A composite part may include an internal insert component (124) made of a first material. The internal insert component may be provided with surface features such as mechanical surface features or material surface features, on at least a portion of its surface. The composite part may further include an external part component (136) that is cast around at least a portion of the internal insert component, and is made of a second material different from the first material. The surface features of the internal insert component may help establish a bond within the composite part between the internal insert component and the external part component.

Abstract: A method of preparing aluminum metal pieces for welding, along with welded sheet metal assemblies formed from the prepared aluminum metal pieces. In one embodiment, a scanning beam of a laser is directed at an edge portion of the sheet metal piece such that a portion of the scanning beam is configured to impact an oxide layer at the edge portion. The laser is pulsed in a series of ablating pulses at the edge portion, with the ablating pulses creating an ablation plume that includes ablated material from the oxide layer of the primary surface and the peripheral surface of the edge portion. The ablation plume is analyzed, and ablation and analyzing continues until a threshold of at least one constituent in the ablation plume or the analysis plume is met or exceeded. One or more operating parameters of the laser are adjusted based on the analysis of the ablation plume or analysis plume. In some embodiments, two aluminum metal pieces are simultaneously prepared.

Abstract: Composite parts (10), methods of making the same (400), and tooling systems (200) for making the same are disclosed. According to one example, a high-pressure die casting process is used to manufacture a composite part (10) that is made from a composite metal material (12) with a metal matrix phase (20) and a particle phase (22) and includes an interior region (14) and an exterior region (16), where an average concentration of the particle phase (22) in the composite metal material (12) is higher in the exterior region (16) than in the interior region (14). An interior surface (206a, 206b) of a die mold (206) may be coated with a particle phase (22) (e.g., a ceramic-based material) and a molten metal matrix phase (20) (e.g., an aluminum-based material) may then be introduced into the die mold (206) such that a composite part (10) is formed with an exterior region (16) or outer layer that is particle-rich compared to an interior region (14).

Abstract: Welded parts and methods of manufacturing the same are disclosed. A welded part may include first and second metal workpieces having respective first and second edges forming a butt joint. The welded part may further include a first laser weld joining the first and second edges on one side of the first and second metal workpieces, and a second laser weld joining the first and second edges on another opposite side of the first and second metal workpieces. Some example parts may have laser welds that cooperate to extend across an entire depth of the butt joint and form an overlap zone between the first and second laser welds. In some examples, the first and second laser welds may be formed with substantially zero macroporosity.

Abstract: A method of preparing zinc coated sheet metal pieces for welding, along with welded sheet metal assemblies formed from the prepared zinc coated sheet metal pieces. In one embodiment, a scanning beam of a laser is directed at an edge portion of the sheet metal piece such that a portion of the scanning beam is configured to impact the zinc coating layer at the edge portion. The laser is pulsed in a series of ablating pulses at the edge portion, with the ablating pulses creating an ablation plume that includes ablated material from the zinc coating layer of the primary surface and the peripheral surface of the edge portion. The ablation plume is analyzed, and ablation and analyzing continues until a threshold of at least one constituent in the ablation plume or the analysis plume is met or exceeded. One or more operating parameters of the laser are adjusted based on the analysis of the ablation plume or analysis plume. In some embodiments, two sheet metal pieces are simultaneously prepared.

Abstract: Composite parts and methods for making the same are disclosed. A composite part may include an internal insert component that is coated on at least a portion of its surface with certain types of particles, an external part component cast around the coated insert, and a particle-rich region that is formed between the two components, where the particle-rich region includes particles from the coated insert. A method for producing a composite part may include the steps of: positioning an internal insert component that is coated on at least a portion of its surface within a mold cavity of a casting die; casting a molten material of the external part component around the coated insert; and solidifying the molten material to form the external part component of the composite part.

Abstract: Composite parts (100) and methods of making the same are disclosed. A composite part may include an internal insert component (124) made of a first material. The internal insert component may be provided with surface features such as mechanical surface features or material surface features, on at least a portion of its surface. The composite part may further include an external part component (136) that is cast around at least a portion of the internal insert component, and is made of a second material different from the first material. The surface features of the internal insert component may help establish a bond within the composite part between the internal insert component and the external part component.