Abstract: A portable reciprocating pump assembly delivers lubricant from a reservoir and includes a housing mountable on the reservoir and a pumping tube assembly for directing lubricant from the reservoir and into the housing. The tube assembly has a reciprocating plunger and a shovel assembly attached to the lower end of the plunger and having a disk member and a valve. A drive mechanism for operating the pumping tube assembly is disposed within the housing and includes a drive shaft and a cam mounted eccentrically on the shaft and disposed within an opening of a follower. The follower is coupled with the plunger such that rotation of the drive shaft reciprocates the plunger along a vertical axis. A motor is connected with the drive shaft and actuates the drive mechanism and a battery provides power to the motor such that the pump assembly operates without connection to a separate power source.

Abstract: A player identification system for identifying players from recorded video content, the system including a video content analysis unit operable to analyse one or more frames of video content, a player name identification unit operable to identify player names in one or more analysed frames of the video content, and a data generation unit operable to generate data relating to the video in dependence upon one or more identified player names.

Abstract: Polymeric compositions, methods, and delivery devices for inhibiting bleeding are disclosed. The method includes applying a dried material topically to a wound site, where the material may include a cross-linked biologically compatible polymer which forms a hydrogel when exposed to blood and where the material may not include an active agent such as thrombin. A spring-loaded delivery device as described herein may be used to apply the dried material.

Abstract: A liquid-absorbing, liquid barrier bag comprising a liquid-permeable envelope within which a super-absorbent material in powder or granular form is disposed, the absorbent material being characterized in that it greatly increases in volume upon liquid absorption. The super-absorbent material is adhered to one or more of the inner surfaces of the liquid-permeable envelope such that the desired distribution and pattern is maintained during handling, shipping and activation of the liquid-absorbing. Upon contact with liquid, such as by soaking the bag in water, the super-absorbent material releases from the inner surfaces and swells to create a three-dimensional body suitable for stacking to form a liquid-impermeable barrier wall.

Abstract: A knuckle of a coupler of a rail vehicle includes a main body including a recess formed in one or more surfaces. One or more weld fillers are disposed within the recess. A method of forming a knuckle of a coupler of a rail vehicle includes forming a recess in one or more surfaces of a main body, and disposing one or more weld fillers within the recess.

Abstract: Polymeric compositions, methods, and delivery devices for inhibiting bleeding are disclosed. The method includes applying a dried material topically to a wound site, where the material may include a cross-linked biologically compatible polymer which forms a hydrogel when exposed to blood and where the material may not include an active agent such as thrombin. A spring-loaded delivery device as described herein may be used to apply the dried material.

Abstract: Embodiments are disclosed for a method for generating a metal-oxide film. The method includes providing a metal ligand complex having a metal and a reactive moiety. The metal ligand complex is dissolved in a solvent that coats at least part of a substrate. Additionally, the method includes inducing a combustion process involving the metal ligand complex, in the absence of any additional fuel, to generate a film that is formed over at least part of the substrate. The film includes an oxide of the metal.

Abstract: A rail flaw detector is configured for locating flaws in rails of a railroad track and for use with a vehicle travelling on the railroad track. The detector includes at least one signal applicator configured for applying ultrasonic signals to the rail and for receiving return signals; a mechanical subsystem connected to the applicator and to the vehicle and configured for maintaining the at least one signal applicator in operational position on the track. A human-machine interface is connected to the at least one signal applicator, is configured to control the detector and to monitor sensed rail condition. In one embodiment, the human-machine interface includes a schematic display of the rail being monitored and at least one touch screen control for controlling the mechanical subsystem and the at least one signal applicator.

Abstract: Candidate material for polymerization can be received. One or more desired features in the candidate material can be identified. A machine learning model can be trained to generate a new material having one or more of the desired features. Permissively, the candidate material can be determined from running a machine learning classification model that ranks a plurality of material as candidates. Permissively, the generated new material can be input to the machine learning classification model, for the machine learning classification model to include in ranking the plurality of material as candidates.

Abstract: A set of material candidates expected to yield materials with target properties can be generated. A subject matter expert's decision indicating accepted and rejected material candidates from the set of material candidates can be received. Based on the subject matter expert's input, a machine learning model can be trained to replicate the subject matter expert's decision.

Abstract: A compound shown by the following general formula (1-1), AR1 and AR2 each independently represent an aromatic ring or an aromatic ring containing at least one nitrogen and/or sulfur atom, two AR1s, AR1 and AR2, or two AR2s are optionally bonded; AR3 represents a benzene, naphthalene, thiophene, pyridine, or diazine ring; A represents an organic group; B represents an anionic leaving group; Y represents a divalent organic group; “p” is 1 or 2; “q” is 1 or 2; “r” is 0 or 1; “s” is 2 to 4; when s=2, Z represents a single bond, divalent atom, or divalent organic group; and when s=3 or 4, Z represents a trivalent or quadrivalent atom or organic group. This compound cures to form an organic film, and also forms an organic under layer film.

Abstract: A turbine airfoil (10) includes an elongated hollow body (26) defining a radial cavity (T1, T2) positioned in an airfoil interior (11). A pair of radial flow passes (B,E/C,D) incorporating near-wall cooling (72, 74) channels are formed on opposite sides of the elongated hollow body (26), which are in serial flow relationship conducting a coolant in opposite radial directions, forming a serpentine cooling path (60a, 60b). A downstream radial flow pass (C, D) of the serpentine cooling path (60a, 60b) is fluidically connected to the radial cavity (T1, T2). Relatively heated coolant from the serpentine cooling path is directed into the radial cavity (T1, T2) to warm the elongated hollow body (26). The coolant is subsequently discharged via impingement openings (90) on the elongated hollow body (26) into first and second impingement volumes (102, 104) that respectively adjoin the pressure and suction side walls (16, 18).

Abstract: An airfoil (10) includes at least one internal cooling channel (A-F) extending in the radial direction and adjoined on opposite sides by an airfoil pressure sidewall (16) and an airfoil suction sidewall (18). An internal surface (16a) of the airfoil pressure sidewall (16) and an internal surface (18a) of the airfoil suction sidewall (18) define heat transfer surfaces in relation to a coolant flowing through the internal cooling channel (A-F). A flow splitter feature (90) is located in a flow path of the coolant in the internal cooling channel (A-F) between the pressure and suction sidewalls (16, 18). The flow splitter feature (90) is effective to create a flow separation region downstream of the flow splitter feature (90), whereby coolant flow velocity is locally increased along the internal surfaces (16a, 18a) of the pressure and suction sidewalls (16, 18).

Abstract: A plurality of mandrels and silicon dioxide spacer structures are formed, with the spacer structures interdigitated between the mandrels. An organic planarization layer is applied, as are a thin oxide layer and a layer of photoresist patterned in hole tone over the oxide layer, thereby defining a domain. At least one hole is etched in the thin oxide layer and the organic planarization layer to expose a portion of a hard mask layer surface between the spacer structures. A selective polymer brush is applied, which grafts only to the exposed hard mask surface, followed by solvent rinsing the domain to remove ungrafted polymer brush. At least one precursor is infused to an etch resistant material into the polymer brush by a sequential infiltration synthesis process. The organic planarization layer is ashed to convert the infused precursor into oxide form to further enhance etch selectivity to the hard mask layer.

Abstract: A plurality of mandrels and silicon dioxide spacer structures are formed, with the spacer structures interdigitated between the mandrels. An organic planarization layer is applied, as are a thin oxide layer and a layer of photoresist patterned in hole tone over the oxide layer, thereby defining a domain. At least one hole is etched in the thin oxide layer and the organic planarization layer to expose a portion of a hard mask layer surface between the spacer structures. A selective polymer brush is applied, which grafts only to the exposed hard mask surface, followed by solvent rinsing the domain to remove ungrafted polymer brush. At least one precursor is infused to an etch resistant material into the polymer brush by a sequential infiltration synthesis process. The organic planarization layer is ashed to convert the infused precursor into oxide form to further enhance etch selectivity to the hard mask layer.

Abstract: A turbine airfoil (10) includes a flow blocking body (26) positioned an internal cavity (40). A first near-wall cooling channel (72) is defined between the flow blocking body (26) and an airfoil pressure sidewall (16). A second near-wall cooling channel (74) is defined between the flow blocking body (26) and an airfoil suction sidewall (18). A connecting channel (76) is defined between the flow blocking body (26) an internal partition wall (24) that connects the airfoil pressure (16) and suction (18) sidewalls. The connecting channel (76) is connected to the first (72) and second (74) near-wall cooling channels along a radial extent. Turbulating features (90, 90a-b) are located in the connecting channel (76) and are formed on the flow blocking body (26) and/or on the partition wall (24). The turbulating features (90, 90a-b) are effective to produce a higher coolant flow rate through the first (72) and second (74) near-wall cooling channels in comparison to the connecting channel (76).

Abstract: The present invention provides non-anticoagulant sulfated or sulfonated polysaccharides (NASPs), which accelerate the blood clotting process. Also provided are pharmaceutical formulations comprising a NASP of the invention in conjunction with a pharmaceutically acceptable excipient and, in various embodiments, these formulations are unit dosage formulations. The invention provides a NASP formulation, which is orally bioavailable. Also provided are methods for utilizing the compounds and formulations of the invention to promote blood clotting in vivo as therapeutic and prophylactic agents and in vitro as an aid to studies of the blood clotting process.

Abstract: A rail flaw detector is configured for locating flaws in rails of a railroad track and for use with a vehicle travelling on the railroad track. The detector includes at least one signal applicator configured for applying ultrasonic signals to the rail and for receiving return signals; a mechanical subsystem connected to the applicator and to the vehicle and configured for maintaining the at least one signal applicator in operational position on the track. A human-machine interface is connected to the at least one signal applicator, is configured to control the detector and to monitor sensed rail condition. In one embodiment, the human-machine interface includes a schematic display of the rail being monitored and at least one touch screen control for controlling the mechanical subsystem and the at least one signal applicator.

Abstract: A turbine airfoil (10) includes an impingement structure (26A, 26B) comprising a hollow elongated main body (28) positioned in an interior portion (11) of an airfoil body (12). The main body (28) extends lengthwise along a radial direction and defines coolant cavity (64) therewithin that receives a cooling fluid (60). The main body (28) is spaced from a pressure side wall (16) and a suction side wall (18) of the airfoil body (12) and may be spaced from an airfoil tip (52), to define respective passages (72, 74, 77) therebetween. A plurality of impingement openings (25) are formed through the main body (28) that connect the coolant cavity (64) with one or more of the respective passages (72, 74, 77). The impingement openings (25) direct the cooling fluid (60) flowing in the coolant cavity (64) to impinge on the pressure and/or suction side walls (16, 18) and/or the airfoil tip (52).

Abstract: A compound includes two or more structures shown by the following general formula (1-1) in the molecule, “Ar” represents an aromatic ring or one that contains at least one nitrogen atom and/or sulfur atom optionally having a substituent, and two Ars are optionally bonded with each other to form a ring structure; the broken line represents a bond with Y; Y represents a divalent or trivalent organic group having 6 to 30 carbon atoms that contains an aromatic ring or a heteroaromatic ring optionally having a substituent, the bonds of which are located in a structure of the aromatic ring or the heteroaromatic ring; R represents a hydrogen atom or a monovalent group having 1 to 68 carbon atoms. This compound can be cured even in an inert gas not only in air atmosphere without forming byproducts, and can form an organic under layer film.