Abstract: A multi-purpose cap adapted to fit onto fluid ports of different sizes and configurations of medical devices used for purifying or concentrating biological samples, wherein the cap is adapted to press fit onto diverse fluid ports on dialyzers and other blood treatment devices.

Abstract: A multi-purpose cap adapted to fit onto fluid ports of different sizes and configurations of medical devices used for purifying or concentrating biological samples, wherein the cap is adapted to press fit onto diverse fluid ports on dialyzers and other blood treatment devices.

Abstract: Aspects of the present disclosure include branching fluid passages in an apparatus that reduce turbulent flow and generate evenly distributed fluid pressure as the fluids branch off into the different passages. In some embodiments, the branching passages may be subdivided into two sets: the branching passages for the liquid fuel and the branching passages for the liquid oxidizer. In some embodiments, the two sets of passages are carefully designed in an elegant yet extremely intricate manner that is optimized for proper fluid flow and maximal burn efficiency. The ends of all of the passages meet at the injector interface, which dispense the liquids into the combustion chamber for ignition. Generally, these designs are achieved through additive manufacturing, and would be extremely difficult, if not impossible, to be manufactured using traditional techniques.

Abstract: Aspects of the present disclosure include branching fluid passages in an apparatus that reduce turbulent flow and generate evenly distributed fluid pressure as the fluids branch off into the different passages. In some embodiments, the branching passages may be subdivided into two sets: the branching passages for the liquid fuel and the branching passages for the liquid oxidizer. In some embodiments, the two sets of passages are carefully designed in an elegant yet extremely intricate manner that is optimized for proper fluid flow and maximal burn efficiency. The ends of all of the passages meet at the injector interface, which dispense the liquids into the combustion chamber for ignition. Generally, these designs are achieved through additive manufacturing, and would be extremely difficult, if not impossible, to be manufactured using traditional techniques.

Abstract: Aspects of the present disclosure include branching fluid passages in an apparatus that reduce turbulent flow and generate evenly distributed fluid pressure as the fluids branch off into the different passages. In some embodiments, the branching passages may be subdivided into two sets: the branching passages for the liquid fuel and the branching passages for the liquid oxidizer. In some embodiments, the two sets of passages are carefully designed in an elegant yet extremely intricate manner that is optimized for proper fluid flow and maximal burn efficiency. The ends of all of the passages meet at the injector interface, which dispense the liquids into the combustion chamber for ignition. Generally, these designs are achieved through additive manufacturing, and would be extremely difficult, if not impossible, to be manufactured using traditional techniques.

Abstract: Aspects of the present disclosure are presented for a combustion engine design with an optimized amount of materials used to generate the necessary components of the engine. The engine may be generated as a single piece, having no joints, fasteners, or any other areas that could present a risk for damage. The designs are described may also reduce weight of the engine, due to eliminating the need for fasteners and other extraneous hardware. In general, the weight of the engine may be optimized to also preclude the inclusion of extraneous material around needed structures. Also, the engine may be designed to be highly energy efficient, with optimal flows for fuel and other fluid with minimal head loss while maintaining higher pressures.

Abstract: A Field Device Tool (FDT)-based application is provided. The FDT-based application includes at least one communication Device Type Manager (communication DTM) and a router Device Type Manager (DTM). The communication DTM corresponds with a type of communication protocol that an at least one plant asset follows. The communication DTM is configured to provide an interface for communication between the FDT-based application and the communication protocol that the plant asset follows. The router DTM is coupleable to an asset optimization device manager that includes electronic device description language (EDDL), the router DTM is configured to transfer data from the asset optimization device manager to the at least one communication DTM for communication with the plant asset.

Abstract: A Field Device Tool (FDT)-based application is provided. The FDT-based application includes at least one communication Device Type Manager (communication DTM) and a router Device Type Manager (DTM). The communication DTM corresponds with a type of communication protocol that an at least one plant asset follows. The communication DTM is configured to provide an interface for communication between the FDT-based application and the communication protocol that the plant asset follows. The router DTM is coupleable to an asset optimization device manager that includes electronic device description language (EDDL), the router DTM is configured to transfer data from the asset optimization device manager to the at least one communication DTM for communication with the plant asset.