Abstract: A method of additive manufacturing is provided. The method comprises first forming a part injecting a first gas into a build chamber and depositing a first layer of metal-containing powder over a build platform. The first layer of powder is melted a laser and then cooled. The above steps can be optionally repeated to build additional layers. A coating is formed on the surface of the part by injecting a second, different gas into the chamber over the surface of the part. A portion of the surface is selectively heated with a second laser device, thereby chemically altering the heated portion to form the coating. After forming the coating, an additional aliquot of the first gas is injected into the chamber while venting the second gas from the chamber.

Abstract: Methods and systems comprise new design procedures that can be implemented for additive manufacturing technologies that involve evaluation of stress concentration sites using finite element analysis and implementation of scanning strategies during fabrication that improve performance by spatially adjusting thermal energy at potential failure sites or high stress regions of a part.

Abstract: Methods and systems comprise new design procedures that can be implemented for additive manufacturing technologies that involve evaluation of stress concentration sites using finite element analysis and implementation of scanning strategies during fabrication that improve performance by spatially adjusting thermal energy at potential failure sites or high stress regions of a part.

Abstract: A kitchen exhaust air cleaning system includes a dispenser and a receiver, with a supply spool of grease absorbent material provided in the dispenser. Contaminated portions of the web can be selectively removed from the air flow path into the receiver while drawing uncontaminated portions of the web from the dispenser to the path of air flow.

Abstract: The present invention provides a method for removing a proteinaceous component from a liquid-phase surfactant preparation comprising (a) providing a liquid-phase surfactant preparation containing a proteinaceous component; (b) adding a complexing agent to the preparation of step (a) and allowing the complexing agent to form a complex with the surfactant; (c) simultaneously with step (b), or subsequently, adding a miscible precipitating agent to the preparation of step (a) or the product of step (b), io respectively, to form a liquid-phase reaction mixture and allowing the miscible precipitating agent to precipitate the proteinaceous component within the liquid-phase reaction mixture; and (d) separating the said complex from the precipitated proteinaceous component in the product of step (c) to provide a purified liquid-phase surfactant preparation; wherein the complex remains in solution within the liquid-phase reaction mixture, and wherein step (d) retains the complex in the liquid phase.

Abstract: A rectangular outer sash frame has extruded plastic frame members with inwardly projecting flange portions overlapping a peripheral edge portion of an outer glass panel of an insulated glass unit. A removable inner sub-sash frame interconnects with the outer sash frame and has extruded plastic frame members with inwardly projecting flange portions overlapping and bonded to a peripheral edge portion of at least one of the glass panels. Extruded plastic glazing members have flange portions overlapping a peripheral edge portion of the inner glass panel and include retaining flange portions projecting between the outer sash frame and the inner sub-sash frame. In another embodiment, the sub-sash frame has integrally extruded parallel spaced walls projecting inwardly between and bonded to the peripheral edge portions of both the inner and outer glass panels.