Abstract: A method includes applying a coating composition to a substrate through a high transfer efficiency applicator, wherein the coating composition comprises a polyamide wax; wherein the coating composition has a wet film thickness of at least about 30 microns measured at about 45 degrees without visible sag after cure, wherein the viscosity measured at a shear rate of about 1 s-1 recovers, after a high shear rate of about 10000 s-1 is applied for about 20 seconds, to within about 95% of a steady state viscosity achieved at greater than about 100 seconds of continuous shearing at about 1 s-1, in less than about 5 seconds; and wherein the coating composition has a complex viscosity measured at a temperature of about 60° C. that is reduced to from about 60 to about 500 mPa-s when the complex viscosity measured at about 30° C. is from about 800 to about 8000 mPa-s.

Abstract: Methods of coating a substrate are provided. In an exemplary embodiment, a coating composition is applied to the substrate with a high transfer efficiency applicator to produce a coating layer, where the high transfer efficiency applicator and the substrate remain spatially separate while the coating composition is applied. A droplet of the coating composition expelled from the high transfer efficiency applicator has a particle size of about 10 microns or greater. The coating composition has a viscosity of from about 1,000 to about 1,000,000 centipoise when the coating composition is subject to a shear rate of about 0.1 reciprocal seconds (s?1). However, the coating composition is non-Newtonian such that a coating composition viscosity decreases when the shear rate is increased to the coating composition. The coating layer is impinged with a gas such that a coating layer surface moves upon impingement with the gas.

Abstract: A method includes applying a coating composition to a substrate through a high transfer efficiency applicator to form the coating layer on the substrate wherein a loss of volatiles is less than about 0.5 weight, and wherein the coating composition comprises: A. a resin comprising an acrylic, a polyester, or combinations thereof; B. a melamine cross-linker; C. an optional pigment; D. an organic solvent; and E. at least one polyurea crystal sag control agent that is the reaction product of an amine and an isocyanate, that has a melting point of from about 50° C. to about 150° C., and that is present in an amount of from about 0.1 to about 4 weight percent based on a total weight of the coating composition; and wherein the coating composition has a wet film thickness of at least about 30 microns measured at about 45 degrees without visible sag.

Abstract: Functional in vitro assays are provided for determining patient specific responsiveness to immunotherapy agents within a clinically actionable time frame.

Abstract: Functional in vitro assays are provided for determining patient specific responsiveness to immunotherapy agents within a clinically actionable time frame.

Abstract: A puncture-resistant, electrically-energized sheet heater comprises a conductive polymeric film laminated between a top puncture-resistant, polymeric protective layer and a bottom backing layer that may comprise an insulated backing layer of extruded polystyrene closed-cell foam board. The heater is appointed to be placed beneath, or embedded in, a pavement material, and energized to provide heat to remove frozen precipitation from the pavement, or prevent it from accumulating thereon.

Abstract: A non-fibrous oriented polyethylene monolayer comprising ultra high molecular weight polyethylene, the polyethylene having a viscosity-average molecular weight of 2,000,000 or greater, wherein (i) the monolayer has a width of 10.0 mm or greater and a modulus of at least 100 N/tex, (ii) the monolayer has a tan ? when measured in dynamic mechanical analysis (DMA) of tensile response in a frequency sweep between 0.1 Hz?f?1.0 Hz meeting the inequality of tan ?<1/(f×a)+b?(f×c) where a=120, b=0.045 and c=0.016, and (iii) the monolayer has a maximum areal weight of no greater than 45 gsm.

Abstract: A staking tool assembly for staking a pin coupling a turbine blade with a turbine disk is disclosed. The staking tool assembly includes a guide block configured to be positioned between a space defined between two consecutive turbine blades mounted on the turbine disk. The guide block includes a bottom surface configured to abut a blade root of the turbine blade. The guide block further includes a groove extending from the bottom surface through the guide block. The groove is configured to receive a portion of the pin extending outwardly from the blade root to facilitate a staking of the pin.

Abstract: A fabric comprises a highly drawn UHMWPE non-filamentary sheet having a width of at least 10 mm and a plurality of impalements wherein one impalement is separated from the next impalement by a distance of at least 1 mm. The fabric may further comprise a plurality of said sheets wherein each sheet is stacked one on top of the other.

Abstract: A fabric comprises a highly drawn UHMWPE non-filamentary sheet having a width of at least 10 mm and a plurality of impalements wherein one impalement is separated from the next impalement by a distance of at least 1 mm. The fabric may further comprise a plurality of said sheets wherein each sheet is stacked one on top of the other.

Abstract: A staking tool assembly for staking a pin coupling a turbine blade with a turbine disk is disclosed. The staking tool assembly includes a guide block configured to be positioned between a space defined between two consecutive turbine blades mounted on the turbine disk. The guide block includes a bottom surface configured to abut a blade root of the turbine blade. The guide block further includes a groove extending from the bottom surface through the guide block. The groove is configured to receive a portion of the pin extending outwardly from the blade root to facilitate a staking of the pin.

Abstract: A non-fibrous oriented polyethylene monolayer comprising ultra high molecular weight polyethylene, the polyethylene having a viscosity-average molecular weight of 2,000,000 or greater, wherein (i) the monolayer has a width of 10.0 mm or greater and a modulus of at least 100 N/tex, (ii) the monolayer has a tan ? when measured in dynamic mechanical analysis (DMA) of tensile response in a frequency sweep between 0.1 Hz?f?1.0 Hz meeting the inequality of tan ?<1/(f×a)+b?(f×c) where a=120, b=0.045 and c=0.016, and (iii) the monolayer has a maximum areal weight of no greater than 45 gsm.

Abstract: An unconsolidated impact and penetration resistant laminate comprises a plurality of cross-plied sheets, each cross-plied sheet further comprising (i) first and second layers of fibrous or non-fibrous ultra-high molecular weight polyethylene and (ii) first and second layers of thermoplastic adhesive, each adhesive layer having a basis weight of no greater than 5 gsm, wherein (a) the layers of polyethylene and thermoplastic adhesive alternate within the sheet, (b) at least 50 percent of the polyethylene layers are arranged such that the orientation of the first polyethylene layer is offset with respect to the orientation of the second polyethylene layer, and (c) the plurality of cross-plied sheets form a stack that, when subjected to compaction at a pressure of 255 bar and a temperature of 132 degrees C., will not suffer a pressure loss greater than 8 bar within the first two minutes as measured by Test Method B.

Abstract: An impact penetration resistant laminate comprises a plurality of alternating layers of (i) non-fibrous ultra-high molecular weight polyethylene monolayers and (ii) a thermoplastic adhesive, the adhesive having a basis weight of no greater than 5 gsm and a zero-shear-rate viscosity, determined from an oscillating disc rheometer in a frequency sweep between 0.1 rad/s and 100 rad/s, conducted per ASTM D 4440 at 125° C., and calculated from fitting to a Carrea-Yasuda four parameter model, of at least 1500 Pa-s, wherein (a) at least 90 percent of the monolayers are arranged such that the orientation of one monolayer is offset with respect to the orientation of an adjacent monolayer, and (b) the modulus of elasticity through the thickness of the laminate is at least 3 GPa.

Abstract: An impact penetration resistant laminate comprises a plurality of alternating layers of (i) non-fibrous ultra-high molecular weight polyethylene monolayers and (ii) a thermoplastic adhesive, the adhesive having a basis weight of no greater than 5 gsm and a zero-shear-rate viscosity, determined from an oscillating disc rheometer in a frequency sweep between 0.1 rad/s and 100 rad/s, conducted per ASTM D 4440 at 125° C., and calculated from fitting to a Carrea-Yasuda four parameter model, of at least 1500 Pa-s, wherein (a) at least 90 percent of the monolayers are arranged such that the orientation of one monolayer is offset with respect to the orientation of an adjacent monolayer, and (b) the modulus of elasticity through the thickness of the laminate is at least 3 GPa.

Abstract: Functional in vitro assays are provided for determining patient specific responsiveness to immunotherapy agents within a clinically actionable time frame.

Abstract: This invention is related to articles containing a heat source and a heat spreader to conduct heat from the heat source. The heat spreader comprises a core of one or more drawn UHMWPE sheets. The sheets are planar, i.e., have dimensions in two directions that are considerably greater than that of the third dimension. No solvent is used during the drawing process. The draw ratio is typically 100 to 150. The density of a sheet is less than 0.90 g/cm3. A sheet has good thermal conductivity k? the direction of the draw. k? is at least 30 W/mK. The thermal conductivity perpendicular to the plane of the sheet k? is greatly reduced. k? is less than. 0.20 W/mK.

Abstract: A magnetic assembly includes a bobbin with two end flanges. A passageway extends longitudinally between the end flanges. An inner core extends through, and is centered in, the passageway. The inner core has first and second end surfaces, each surface proximate to one of the end flanges. A rectangular outer core is positioned around the bobbin with inner surfaces of the outer core close to the outer surfaces of the end flanges of the bobbin. A respective gap is formed between each end of the inner core and the adjacent inner surface of the outer core. The passageway includes crushable ribs that secure the inner core within the passageway. The outer surfaces of the end flanges include crushable ribs that secure the core with respect to the bobbin. The passageway and inner core may have an oval-shaped profile. The passageway and inner core may have a circular profile.

Abstract: An apparatus includes a pair of connectors and two or more conductive paths formed in each connector in the pair of connectors. The pair of connectors includes a first connector and a second connector. The first connector is substantially more flexible than the second connector, and each connector in the pair of connectors includes a bulkhead. Each of the two or more conductive paths in each connector in the pair of connectors is electrically isolated from all other conductive elements in the respective connector. A shroud may be located between the bulkheads and disposed about the pair of connectors when the pair of connectors are coupled together electrically.