Abstract: The present disclosure is directed to a method for manufacturing a thermoset component having a weldable thermoplastic interface. The method includes forming a polymerized thermoplastic component having a removable protective layer on a portion thereof. Another step includes placing a plurality of dry plies and the thermoplastic component into a mold of the thermoset component with the removable protective layer facing an outer surface of the thermoset component mold. Thus, the method further includes co-infusing the dry plies and thermoplastic component with a resin material so as to form the thermoset component having a weldable thermoplastic interface.

Abstract: A hand held appliance comprising a fluid flow path extending from a fluid inlet into the appliance to a fluid outlet from the appliance, the fluid flow path being at least partially defined by a wall, a switch mechanism housed by the wall having a cooperating externally accessible actuating button and a switch cover extending within the wall and containing the switch mechanism. The switch cover may maintain a spatial location of the switch mechanism relative to the actuating button. The switch cover may encase the switch mechanism. The switch cover may isolate the switch mechanism from the fluid flow path. The switch cover may maintain a spatial location of the switch mechanism relative to the wall. The switch cover may be curved towards an upstream end to reduce disturbance to the flow of fluid within the fluid flow path.

Abstract: Provided herein are compositions of virus like particles (VLPs) of poliovirus (PV) that have one or more stabilizing mutations that confer a higher degree of thermostability to the N-antigenic form of the VLPs. These VLPs are non-infectious, and thus safer for use in vaccine development and administration to clinical subjects.

Abstract: A structure for a semiconductor device includes a copper (Cu) layer and a first nickel (Ni) alloy layer with a Ni grain size a1. The structure also includes a second Ni alloy layer with a Ni grain size a2, wherein a1<a2. The first Ni alloy layer is between the Cu layer and the second Ni alloy layer. The structure further includes a tin (Sn) layer. The second Ni alloy layer is between the first Ni alloy layer and the Sn layer.

Abstract: A method for fabricating a copper pillar. The method includes forming a layer of titanium tungsten (TiW) over a semiconductor wafer, forming a layer of zinc (Zn) over the layer of TiW, and forming a copper pillar over the via. In addition, the method includes performing an anneal to diffuse the layer of Zn into the copper pillar. A semiconductor device that includes a layer of TiW coupled to a via of a semiconductor wafer and a copper pillar coupled to the layer of TiW. The copper pillar has interdiffused Zn within its bottom portion. Another method for fabricating a copper pillar includes forming a layer of TiW over a semiconductor wafer, forming a first patterned photoresist, forming a layer of Zn, and then removing the first patterned photoresist. The method further includes forming a second patterned photoresist and forming a copper pillar.

Abstract: A microelectronic device is formed by thinning a substrate of the microelectronic device from a die attach surface of the substrate, and forming a copper-containing layer on the die attach surface of the substrate. A protective metal layer is formed on the copper-containing layer. Subsequently, the copper-containing layer is attached to a package member having a package die mount area. The protective metal layer may optionally be removed prior to attaching the copper-containing layer to the package member. Alternatively, the protective metal layer may be left on the copper-containing layer when the copper-containing layer is attached to the package member. A structure formed by the method is also disclosed.

Abstract: A rotor blade for a wind turbine may generally include a first blade component formed from a first fiber-reinforced composite including a first thermoplastic resin material and a second blade component configured to be coupled to the first blade component at a joint interface. The second blade component may be formed from a second fiber-reinforced composite including a second thermoplastic resin material, wherein the second thermoplastic resin material differs from the first thermoplastic resin material. The rotor blade may also include an additional layer(s) of thermoplastic resin material positioned on or integrated into the second fiber-reinforced composite at the joint interface that differs from the second thermoplastic resin material. Moreover, the first thermoplastic resin material of the first fiber-reinforced composite may be welded to the additional layer(s) of the thermoplastic resin material to form a welded joint at the joint interface between the first and second blade components.

Abstract: The present disclosure is directed to thermoplastic airflow modifying elements for a rotor blade for a wind turbine and methods of assembling same. The rotor blade may be constructed from at least one of a thermoset material or a thermoplastic material. Further, the rotor blade includes a blade shell defining an outer surface. Moreover, the rotor blade includes one or more layers of thermoplastic material infused to the outer surface of the blade shell so as to define one or more attachment locations. In addition, the rotor blade includes at least one airflow modifying element constructed, at least in part, from a thermoplastic material. Thus, the airflow modifying element(s) is welded to one of the attachment locations on the outer surface of the blade shell.

Abstract: A nanostructure barrier for copper wire bonding includes metal grains and inter-grain metal between the metal grains. The nanostructure barrier includes a first metal selected from nickel or cobalt, and a second metal selected from tungsten or molybdenum. A concentration of the second metal is higher in the inter-grain metal than in the metal grains. The nanostructure barrier may be on a copper core wire to provide a coated bond wire. The nanostructure barrier may be on a bond pad to form a coated bond pad. A method of plating the nanostructure barrier using reverse pulse plating is disclosed. A wire bonding method using the coated bond wire is disclosed.

Abstract: A microelectronic device includes a reflow structure. The reflow structure has a copper-containing member and a solder member, and a barrier layer between them. The barrier layer has metal grains, with a diffusion barrier filler between the metal grains. The metal grains include at least a first metal and a second metal, each selected from nickel, cobalt, lanthanum, and cerium, with each having a concentration in the metal grains of at least 10 weight percent. The diffusion barrier filler includes at least a third metal, selected from tungsten and molybdenum. A combined concentration of tungsten and molybdenum in the diffusion barrier filler is higher than in the metal grains to provide a desired resistance to diffusion of copper. The barrier layer includes 2 weight percent to 15 weight percent of the combined concentration of tungsten, and molybdenum. A bump bond structure and a lead frame package are disclosed.

Abstract: In one aspect, a method for manufacturing a spar cap for a wind turbine rotor blade may generally include stacking a plurality of plates together to form a plate assembly, wherein each of the plates is formed from a fiber-reinforced composite including a plurality of fibers surrounded by a thermoplastic resin material. The method may also include positioning the plate assembly relative to a mold defining a mold surface, wherein the mold surface is shaped so as to correspond to at least one blade parameter of the wind turbine rotor blade. In addition, the method may include applying pressure to the plate assembly via the mold such that at least a portion of the plate assembly conforms to the shape of the mold surface.

Abstract: A light fixture is disclosed. The light fixture includes a frame, a light source disposed within and coupled to the frame, and a lens coupled to the light source. The light also includes a first fabric layer coupled to the frame at a first distance from the lens and a second fabric layer coupled to the frame at a second distance from the lens. The first fabric layer has a plurality of dots printed thereon.

Abstract: A joint assembly for joining rotor blade segments of a wind turbine rotor blade includes a female structural member secured within a first rotor blade segment. The female structural member includes first bore holes on opposing sides thereof that are aligned in a chord-wise direction. Further, the joint assembly includes a male structural member extending longitudinally from an end face of a second rotor blade segment. As such, the male structural member is received within the female structural member of the first rotor blade segment such that the first and second rotor blade segments are aligned and connected. The male structural member includes second bore holes on opposing sides thereof. Further, the second bore holes are aligned with the first bore holes. Moreover, the joint assembly includes at least one chord-wise extending pin extending through the first and second bore holes so as to join the first and second rotor blade segments.

Abstract: Methods for joining surface features to wind turbine rotor blades are provided. A method includes providing the surface feature after forming of the rotor blade. The surface feature includes a thermoplastic resin. The formed rotor blade includes a plurality of blade components joined together to form an exterior surface defining a pressure side, a suction side, a leading edge, and a trailing edge each extending between a tip and a root. The formed rotor blade further includes a thermoplastic resin. The method further includes positioning the surface feature adjacent the exterior surface, and welding the thermoplastic resin of the surface feature and the thermoplastic resin of the formed rotor blade together.

Abstract: Techniques are disclosed for systems and methods to provide augmented reality sonar imagery for mobile structures. An augmented reality sonar imagery system includes a portable imaging device, a sonar transducer assembly, and a logic device in communication with the sonar transducer assembly and the portable imaging device. The sonar transducer assembly is adapted to be mounted to a mobile structure and placed in a body of water, and the portable imaging device includes a display and an imager position and/or orientation sensor. The logic device is configured to determine a waterline of the body of water relative to a field of view of the display and render sonar data in a portion of the field of view that extends below the waterline. Subsequent user input and/or the sonar data may be used to adjust a steering actuator, a propulsion system thrust, and/or other operational systems.

Abstract: Rotor blades and methods for joining blade components of rotor blades are provided. A method includes positioning an insert between and in contact with a first blade component and a second blade component. At least one of the first blade component or the second blade component includes a thermoplastic resin. The insert includes a thermoplastic resin and an energy absorptive pigment. The method further includes heating the thermoplastic resin of the at least one of the first blade component or the second blade component and the thermoplastic resin of the insert. The method further includes cooling the thermoplastic resin of the at least one of the first blade component or the second blade component and the thermoplastic resin of the insert. The heating step and the cooling step join the first blade component, the second blade component and the insert together.

Abstract: Rotor blades and methods for joining shear clips in wind turbine rotor blades are provided. A method includes positioning the shear clip adjacent a shear web of the rotor blade, the shear clip including a thermoplastic resin, the shear web including a thermoplastic resin. The method further includes welding the thermoplastic resin of the shear clip and the thermoplastic resin of the shear web together. The method further includes positioning the shear clip adjacent a spar cap of the rotor blade, the spar cap including a thermoplastic resin. The method further includes welding the thermoplastic resin of the shear clip and the thermoplastic resin of the spar cap together. The method further includes joining the shear web and the spar cap together.

Abstract: A heat shield for a thrust bearing assembly of a pump. The heat shield includes a member having an inner surface and an outer surface. A raised flange is formed on a perimeter of the inner surface. The raised flange is configured to seal with a back surface of a thrust shoe holder, and form a cavity between the inner surface and the back surface of the thrust shoe holder. At least one weep hole is on the flange. The weep hole is configured to allow water to enter the cavity to form an insulating stagnant water layer.