Abstract: An apparatus for generating electric power from wind energy includes a blade device rotatable relative to a base to convert wind energy into a mechanical rotary power output, and having an upright rod connected with upright blades and coupled to a generator in the base to convert the mechanical rotary power output into electric power. Each blade has spaced wind-collecting ribs extending vertically from a first side surface thereof, thereby defining a wind-collecting space between any two adjacent wind-collecting ribs. A wind-collecting unit includes upright plates mounted on the base, angularly equidistant and disposed around the blade device. Any two adjacent plates define an inwardly converging wind-guiding channel therebetween. The plates are non-flat so that wind is guided by the plates to blow onto the first side surfaces of the blades via the wind-guiding channels.

Abstract: A composite material comprising a multitude of masses and fibers supported on a flexible substrate arranged in a manner to absorb energy from a ballistic projectile and thereby protect persons or property from ballistic injury or damage. An array of small, tough disc-like masses are suspended in a three dimensional cradle of high-tensile elastomeric fibers such that energy from an incoming ballistic projectile is first imparted to one or more masses and the motion of the masses are restrained by tensile strain of elastomeric fibers substantially in the direction of travel of the incoming projectile. The projectile is eventually decelerated to harmless velocity through a combination of transfer of momentum to the masses and the elastic and plastic tensile deformation of the fibers.

Abstract: The present invention is directed to materials treatable by electron beam (EB) processing, such as materials for flexible packaging. The material comprises a substrate; an ink formulation on at least a portion of the substrate, the ink formulation comprising ink and at least one monomer selected from acrylate esters, vinyl ethers, cycloaliphatic diepoxides, and polyols; and a lacquer on at least a portion of the ink formulation, the lacquer comprising at least one monomer selected from acrylate esters, vinyl ethers, cycloaliphatic diepoxides, and polyols. The processing apparatus for EB treating the material operates at a low voltage, such as 125 kVolts or less.

Abstract: The present invention is directed to a particle beam processing apparatus that is smaller in size and operates at a higher efficiency, and also directed to an application of such apparatus to treat a coating on a substrate of a treatable material, such as for flexible packaging. The processing apparatus includes a particle beam generating assembly, a foil support assembly, and a processing assembly. In the particle beam generating assembly, electrons are generated and accelerated to pass through the foil support assembly. In the flexible packaging application, the substrate is fed to the processing apparatus operating at a low voltage, such as 110 kVolts or below, and is exposed to the accelerated electrons to treat the coating on the substrate.

Abstract: A thermal interface includes nanofibrils. The nanofibrils may be attached to a flat base or membrane, or may be attached to the tip portions of larger diameter fibers. The nanofibrils have a diameter of less than about 1 micron, and may advantageously be formed from single walled and/or multi-walled nanotubes.

Abstract: A fiber velvet comprising nano-size fibers or nanofibrils attached to micro-size fibers is disclosed. Methods of manufacturing the velvet as well as various uses of the velvet are also described. For example, the fiber velvet can be used as a thermal interface or as an adhesive material. The nanofibrils may be attached to a flat base or membrane, or may be attached to the tip portions of the micro-size or larger diameter fibers. Various attributes of the micro-size fibers and of the nano-size fibers, for example, geometry (e.g. size, length, packing density) material type (e.g. carbon, metal, polymer, or ceramic) and properties (e.g. conductivity, modulus, surface energy, dielectric constant, surface roughness) can be selected depending on the desired attributes of the fiber velvet. The nanofibrils have a diameter of less than about 1 micron, and may advantageously be formed from single walled and/or multi-walled carbon nanotubes.

Abstract: Methods, and materials made by the methods, are provided herein for treating materials with a particle beam processing device. According to one illustrative embodiment, a method for treating a material with a particle beam processing device is provided that includes: providing a particle beam generating assembly including at least one filament for creating a plurality of particles; applying an operating voltage greater than about 110 kV to the filament to create the plurality of particles; causing the plurality of particles to pass through a thin foil having a thickness of about 10 microns or less; and treating a material with the plurality of particles.

Abstract: A thermal interface includes nanofibrils. The nanofibrils may be attached to a flat base or membrane, or may be attached to the tip portions of larger diameter fibers. The nanofibrils have a diameter of less than about 1 micron, and may advantageously be formed from single walled and/or multi-walled nanotubes.

Abstract: The present invention is directed to a particle beam processing apparatus that is smaller in size and operates at a higher efficiency. The processing apparatus includes a particle beam generating assembly, a foil support assembly, and a processing assembly. In the particle beam generating assembly, a cloud of particles, for example, electrons, are generated by heating at least one tungsten filament. The electrons are then extracted to travel at a high speed to the foil support assembly which is set at a much lower voltage than the particle beam generating assembly. A substrate is fed to the processing apparatus through the processing zone and is exposed to the electrons exiting the particle beam generating assembly and entering the processing zone. The electrons penetrate and cure the substrate causing a chemical reaction, such as polymerization, cross-linking, or sterilization.

Abstract: The present invention is directed to a particle beam processing apparatus that is smaller in size and operates at a higher efficiency. The processing apparatus includes a particle beam generating assembly, a foil support assembly, and a processing assembly. In the particle beam generating assembly, a cloud of particles, for example, electrons, are generated by heating at least one tungsten filament. The electrons are then extracted to travel at a high speed to the foil support assembly which is set at a much lower voltage than the particle beam generating assembly. A substrate is fed to the processing apparatus through the processing zone and is exposed to the electrons exiting the particle beam generating assembly and entering the processing zone. The electrons penetrate and cure the substrate causing a chemical reaction, such as polymerization, cross-linking, or sterilization.

Abstract: The present invention is directed to a particle beam processing apparatus that is smaller in size and operates at a higher efficiency, and also directed to an application of such apparatus to treat a coating on a substrate of a treatable material, such as for flexible packaging. The processing apparatus includes a particle beam generating assembly, a foil support assembly, and a processing assembly. In the particle beam generating assembly, electrons are generated and accelerated to pass through the foil support assembly. In the flexible packaging application, the substrate is fed to the processing apparatus operating at a low voltage, such as 110 kVolts or below, and is exposed to the accelerated electrons to treat the coating on the substrate.

Abstract: The present invention is directed to a particle beam processing apparatus that is smaller in size and operates at a higher efficiency. The processing apparatus includes a particle beam generating assembly, a foil support assembly, and a processing assembly. In the particle beam generating assembly, a cloud of particles, for example, electrons, are generated by heating at least one tungsten filament. The electrons are then extracted to travel at a high speed to the foil support assembly which is set at a much lower voltage than the particle beam generating assembly. A substrate is fed to the processing apparatus through the processing zone and is exposed to the electrons exiting the particle beam generating assembly and entering the processing zone. The electrons penetrate and cure the substrate causing a chemical reaction, such as polymerization, cross-linking, or sterilization.

Abstract: A novel parallel-filament type electron gun for electron beam irradiation accelerators or generators and the like having a plurality of longitudinally extending parallel transversely spaced substantially co-planar similar filaments for generating electrons and disposed between a lower co-extensive extractor grid and an upper co-extensive electrostatic lens surface for shaping the electron beam profile, and with constructional features that enable variable width and extremely wide guns to be achieved and with improved beam uniformity.

Abstract: A novel heatable filament wire support is provided embodying flexible and rigid support and current-providing bracket beams terminating in inherent resilient clip springs for accurately clamping the ends of the filament with mechanical and electrical reliability, enabling facile filament wire alignment and replacement, and accommodation for thermal displacement upon filament heating.

Abstract: This invention embraces a method of controlling the impermeability of an organic polymer film to gases such as oxygen, aroma, flavor and fragrance and the like to produce gas impermeable organic polymer films by coating with a mixture of a siloxane monomer with carboxylic acid in an alcohol solvent and evaporating the solvent to complete the formation of Si--O--Si bonds; and then polymerizing and grafting the coating, preferably by electron beam radiation, to the polymer film. Improved coated polymer films and formulation products therefor are also provided.

Abstract: A novel technique and apparatus for shielding electron beam and similar product irradiation zones with a separable shielding housing extending transversely of the longitudinal line of product flow and slidably openable in a transverse direction orthogonal to both the electron beam and the direction of product flow, both in passing the beam and along the line, resulting in substantial space saving, more facile accelerating to the irradiation and product feed zone and less costly and sizeable shielding apparatus.

Abstract: A novel electron beam apparatus and technique wherein a plurality of longitudinally extending heated filaments is employed, each similarly offset laterally of a central longitudinal axis, but with successive filaments alternately disposed on opposite sides of said axis and cooperating with a first low velocity accelerating stage comprising staggered grid slots and openings, and a high velocity second accelerating stage to provide long uniform longitudinal electron beams.

Abstract: Through the use of a hybrid or the combination of inexpensive relatively impure, and expensive pure, nitrogen purging at various locations of electron-beam processing of polymer and other coatings, high speed efficient processing can be obtained at reduced cost.

Abstract: A method of imbuing polymer films as of polyethylene and polypropylene with gas, aroma, fragrance, flavor, grease and oil impermeable surface characteristics involving coating the film with appropriate silane compounds and cross-linking the same while providing physical adsorption adherence to the film, and in sufficient coating micron thickness to produce gas and related barrier characteristics; with chemical grafting, including by eb techniques, further providing improved bonding. Preferred barrier-coated polymer films with reduced haze and clarity are formed by such method.

Abstract: A process is described for modifying the surface of polymers such as polyolefins and the like to improve the wetability by barrier and other coatings and to enhance interlayer adhesion by graft polymerization through initiation by electron-beam radiation, optionally with an added electron energy acceptor.