Abstract: A process is disclosed herein comprising the steps: a) contacting an esterifying agent and a polysaccharide in the presence of a first solvent and suitable reaction conditions for a reaction time sufficient to form a product comprising a polysaccharide ester composition, the polysaccharide ester composition comprising a polysaccharide ester having a degree of substitution of about 0.001 to about 3; wherein the esterifying agent comprises an acyl halide, a phosphoryl halide, a carboxylic acid anhydride, a haloformic acid ester, a carbonic acid ester, or a vinyl ester; and the ratio of esterifying agent to polysaccharide is in the range of about 0.001:1 to about 3:1 on a molar equivalent basis; b) combining the product obtained in step a) with polyacrylonitrile; and c) spinning fibers.

Abstract: A self-lubricated sliding bearing for a rotary X-ray tube comprises a first bearing member, a second bearing member configured to concentrically enclose a portion of the first bearing member, and a lubricant comprised in a gap between cooperating surfaces of the first bearing member and the second bearing member. The cooperating surface of the second bearing member or the first bearing member comprises a first region comprising a pumping pattern configured to pump the lubricant. The cooperating surface of the second bearing member or the first bearing member comprises a second region having a modified pumping pattern or a smooth surface.

Abstract: In order to facilitate product development, such as pharmaceutical product development, a computer implemented method and an apparatus are proposed that enable formulators to develop robust drug formulations in a cost- and time-efficient manner. To start the development process, the user selects the preferred dosage form (e.g., granules, pellets, capsules, tablets etc.), defines a target profile (e.g., amount of active ingredient per unit, size of dosage form, mechanical strength of dosage form, desired release behaviour etc.) and enters key characteristics of the active ingredient (e.g., true density, particle size distribution data, bulk and tapped density, angle of repose, compressibility and compactibility profile etc.). The identity (e.g., chemical name or structure) of the active ingredient is not necessarily disclosed. The apparatus processes the provided data and calculates key parameters of the AI (e.g.

Abstract: A process is disclosed herein comprising the steps: a) contacting an esterifying agent and a polysaccharide in the presence of a first solvent and suitable reaction conditions for a reaction time sufficient to form a product comprising a polysaccharide ester composition, the polysaccharide ester composition comprising a polysaccharide ester having a degree of substitution of about 0.001 to about 3; wherein the esterifying agent comprises an acyl halide, a phosphoryl halide, a carboxylic acid anhydride, a haloformic acid ester, a carbonic acid ester, or a vinyl ester; and the ratio of esterifying agent to polysaccharide is in the range of about 0.001:1 to about 3:1 on a molar equivalent basis; b) combining the product obtained in step a) with polyacrylonitrile; and c) spinning fibers.

Abstract: As gantry speeds experienced in CT scanners increase, so too does the radial load force exerted on components attached to the gantry. A self-lubricating sliding bearing used inside a rotary X-Ray source of a CT scanner is particularly susceptible to increasing radial load force, because in operation, a self-lubricating bearing floats on a film of liquid lubricant. Thus, the radial load force will tend to act on the floating portion of the bearing to develop an eccentricity in the longitudinal axis of the floating portion of the bearing as compared to the longitudinal axis of the stationary part of the bearing. The eccentricity will eventually cause the floating portion of the bearing to contact the stationary part of the bearing in operation, thus limiting the load carrying characteristic of the self-lubricating sliding bearing.

Abstract: A process is disclosed herein comprising the steps: a) contacting an esterifying agent and a polysaccharide in the presence of a first solvent and suitable reaction conditions for a reaction time sufficient to form a product comprising a polysaccharide ester composition, the polysaccharide ester composition comprising a polysaccharide ester having a degree of substitution of about 0.001 to about 3; wherein the esterifying agent comprises an acyl halide, a phosphoryl halide, a carboxylic acid anhydride, a haloformic acid ester, a carbonic acid ester, or a vinyl ester; and the ratio of esterifying agent to polysaccharide is in the range of about 0.001:1 to about 3:1 on a molar equivalent basis; b) combining the product obtained in step a) with polyacrylonitrile; and c) spinning fibers.

Abstract: A process is disclosed herein comprising the steps: a) contacting an esterifying agent and a polysaccharide in the presence of a first solvent and suitable reaction conditions for a reaction time sufficient to form a product comprising a polysaccharide ester composition, the polysaccharide ester composition comprising a polysaccharide ester having a degree of substitution of about 0.001 to about 3; wherein the esterifying agent comprises an acyl halide, a phosphoryl halide, a carboxylic acid anhydride, a haloformic acid ester, a carbonic acid ester, or a vinyl ester; and the ratio of esterifying agent to polysaccharide is in the range of about 0.001:1 to about 3:1 on a molar equivalent basis; b) combining the product obtained in step a) with polyacrylonitrile; and c) spinning fibers.

Abstract: An automotive splash guard includes first and second molded pieces. The first molded piece has a shape configured to have at least a portion thereof installed outside an automobile wheel well, and the second molded piece has a shape configured to be installed in an automobile wheel well. The first piece has an exterior painted surface, the first piece is separate from the second piece while the first piece is being painted and is attached to the second piece after being painted by mechanical joining or adhering. A method for manufacturing a splash guard includes molding the first piece; molding the second piece; painting the first piece while it is separate from the second piece; and then attaching the second piece to the first piece.

Abstract: The present invention relates to hydrodynamic bearings, X-ray tubes, X-ray systems, and a method of manufacturing a hydrodynamic bearing for an X-ray tube. The rotor of a hydrodynamic bearing is supported, in steady-state operation, by the pressure of lubricant which is pumped through grooves in the rotor. When the rotor is speeding up or slowing down, the pumping force will not be sufficient to lift the rotor clear of a stationary bushing, and damage, caused by direct contact of the metal surfaces of the bearing, can occur. Providing special coatings on the bearing surfaces can ameliorate this effect.

Abstract: A self-acting, sealed hydrodynamic bearing includes a bearing shaft; a bearing bushing arranged to seal a length of the bearing shaft; a lubricant provided in the sealed length of the hydrodynamic bearing; and a bearing arrangement between the shaft and bushing. The bearing shaft and/or the bearing bushing are configured to be rotatable. The bearing arrangement includes a primary bearing surface disposed on the bearing bushing, arranged to face a secondary bearing surface disposed on the bearing shaft. The primary and/or secondary bearing surfaces includes first regions having a first fluid slip characteristic, and second regions having a second fluid slip characteristic substantially different to that of the first fluid slip characteristic. The second and first regions are in a same plane of a cross-section of the primary and/or secondary bearing surfaces, and are disposed in an interleaved pattern over the primary and/or secondary bearing surfaces.

Abstract: An automotive splash guard includes first and second molded pieces. The first molded piece has a shape configured to have at least a portion thereof installed outside an automobile wheel well, and the second molded piece has a shape configured to be installed in an automobile wheel well. The first piece has an exterior painted surface, the first piece is separate from the second piece while the first piece is being painted and is attached to the second piece after being painted by mechanical joining or adhering. A method for manufacturing a splash guard includes molding the first piece; molding the second piece; painting the first piece while it is separate from the second piece; and then attaching the second piece to the first piece.

Abstract: Hydrodynamic bearings exploit the properties of pumping action in a fluid to support a bearing load. Conventionally, the pumping action is provided by grooved surfaces in a bearing surface of the bearing. The provision of grooves leads to functional and practical problems, though. The action of grooves on a lubrication material leads inevitably to shear stress being exerted in the fluid. This has a detrimental effect on the load performance of a hydrodynamic bearing. In practical terms, the accurate manufacture of grooves is onerous. This application discusses a way of producing a hydrodynamic bearing using a portion of a bearing surface with an interleaved pattern of materials, wherein the materials have alternate high and low (or zero) fluid slip characteristics. The varying fluid slip characteristic of the surface induces a pumping effect analogous to that provided by a grooved surface.

Abstract: The present invention relates to hydrodynamic bearings, X-ray tubes, X-ray systems, and a method of manufacturing a hydrodynamic bearing for an X-ray tube. The rotor of a hydrodynamic bearing is supported, in steady-state operation, by the pressure of lubricant which is pumped through grooves in the rotor. When the rotor is speeding up or slowing down, the pumping force will not be sufficient to lift the rotor clear of a stationary bushing, and damage, caused by direct contact of the metal surfaces of the bearing, can occur. Providing special coatings on the bearing surfaces can ameliorate this effect.

Abstract: An atmospheric pressure chemical vapor deposition method for producing an N-type semiconductive metal sulfide thin film on a heated substrate includes converting an indium-containing precursor to at least one of a liquid phase and a gaseous phase. The indium-containing precursor is mixed with an inert carrier gas stream and hydrogen sulfide in a mixing zone so as to form a mixed precursor. A substrate is heated to a temperature in a range of 100° C. to 275° C. and the mixed precursor is directed onto the substrate. The hydrogen sulfide is supplied at a rate so as to obtain an absolute concentration of hydrogen sulfide in the mixing zone of no more than 1% by volume. The In-concentration of the indium containing precursor is selected so as to produce a compact indium sulfide film.

Abstract: A system, computer-readable storage medium storing at least one program, and a computer-implemented method for online workflow implementation is provided. An input identifier identifying a digital content to be processed is received. A workflow identifier is also received, the work flow identifier identifying a workflow comprised of a plurality of ordered applications. The digital content is then processed in accordance with the workflow to generate a final output.

Abstract: For making ceramic or oxidic layers (CL/OL) on substrates (S), the method according to the invention therefore provides that following application (I) and drying (II) of a suitable precursor (P) the formed precursor layer (PLD) is gassed (III) with a moist reactant gas (RG) for conversion into a corresponding hydroxide or complex layer (HL) and then thermally treated (IV) for forming a ceramic or oxidic layer (CL/OL). For the alternative production of other chalcogenidic layers of increased material conversion additional gassing is carried out with a reactant gas containing chalcogen hydrogen. Metallic layers may alternatively be made by use of a reducing reactant gas. The methods in accordance with the invention may be used wherever surfaces, even those of shaded structures, must be protected or modified or provided with functional layers, particularly in solar and materials technology.

Abstract: A method of producing, at atmospheric pressure, an n-type semiconductive indium sulfide thin film on a substrate using an indium-containing precursor, hydrogen sulfide as a reactive gaseous precursor, and an inert carrier gas stream includes cyclically repeating first and second steps so as to produce an indium sulfide thin film of a desired thickness. The first method phase includes converting the indium-containing precursor to at least one of a dissolved and a gaseous phase, heating the substrate to a temperature in a range of 100° C. to 275° C., directing the indium containing precursor onto the substrate and supplying hydrogen sulfide to the indium-containing precursor in a mixing zone in an amount so as to provide an absolute concentration of hydrogen sulfide that is greater than zero and no greater than 1% by volume. The indium concentration of the indium-containing precursor is set so as to produce a compact In(OHx,Xy,Sz)3 film, where X=halide and x+y+2z=1 with z?0.

Abstract: An atmospheric pressure chemical vapor deposition method for producing an N-type semiconductive metal sulfide thin film on a heated substrate includes converting an indium-containing precursor to at least one of a liquid phase and a gaseous phase. The indium-containing precursor is mixed with an inert carrier gas stream and hydrogen sulfide in a mixing zone so as to form a mixed precursor. A substrate is heated to a temperature in a range of 100° C. to 275° C. and the mixed precursor is directed onto the substrate. The hydrogen sulfide is supplied at a rate so as to obtain an absolute concentration of hydrogen sulfide in the mixing zone of no more than 1% by volume. The In-concentration of the indium containing precursor is selected so as to produce a compact indium sulfide film.

Abstract: A method of producing, at atmospheric pressure, an n-type semiconductive indium sulfide thin film on a substrate using an indium-containing precursor, hydrogen sulfide as a reactive gaseous precursor, and an inert carrier gas stream includes cyclically repeating first and second steps so as to produce an indium sulfide thin film of a desired thickness. The first method phase includes converting the indium-containing precursor to at least one of a dissolved and a gaseous phase, heating the substrate to a temperature in a range of 100° C. to 275° C., directing the indium containing precursor onto the substrate and supplying hydrogen sulfide to the indium-containing precursor in a mixing zone in an amount so as to provide an absolute concentration of hydrogen sulfide that is greater than zero and no greater than 1% by volume. The indium concentration of the indium-containing precursor is set so as to produce a compact In(OHx,Xy,Sz)3 film, where X=halide and x+y+2z=1 with z?0.

Abstract: The problem addressed by the invention is that of improving on an electrodeposition method for the production of nanostructured ZnO in such a manner that this method enables the production of nanostructured ZnO with a high internal quantum efficiency (IQE) without additional tempering steps. According to the invention, the electrodeposition method use an aqueous solution of a Zn salt, for example Zn(NO3)2, and a doping agent, for example HNO3 or NH4NO3. ZnO nanotubes produced in this way show an intense emission band edge in the UV range and only a weak emission in the range from 450 to 700 nm in the photoluminescence spectrum.