A method for applying base paint non-uniformly to a golf shaft includes: inserting a portion of a golf shaft lengthwise through an aperture in a paint applicator, the paint applicator having a first surface and a second surface opposite the first surface, where one of (a) the aperture is non-circular and (b) the aperture includes a plurality of slits formed circumferentially around the aperture; actuating a painting apparatus, thereby causing the base paint to contact the golf shaft and the second surface of the paint applicator; and pulling the golf shaft lengthwise through the aperture in the paint applicator, thereby non-uniformly applying the base paint lengthwise along the portion of the golf shaft.

One aspect is a method for producing a plurality of wire elements, including providing a metal wire, coating the metal wire with a first layer to obtain a first coated wire, subjecting the first coated wire to a first quality control process, marking any first defects identified in the first quality control process, coating the first coated wire with a further layer to obtain a further coated wire, and cutting the further coated wire to obtain a plurality of wire elements. Prior to cutting the further coated wire to obtain the plurality of wire elements, a first length of the first coated wire is less than 10% longer than a further length of the further coated wire.

A method of manufacturing an implantable stimulation device includes providing a circuit board of the implantable stimulation device, the circuit board being equipped with circuit components and an antenna, adhering one or more electrodes to the circuit board, and applying an insulation material to the circuit board such that the insulation material forms a housing that surrounds the circuit board, the circuit components, and the antenna, while leaving the one or more electrodes exposed for stimulating a tissue.

An object of the present invention is to provide a threadlike adhesive body having high impact resistance. The present invention relates to a threadlike adhesive body including a core material having a plurality of filaments and an adhesive, in which the adhesive covers the core material, the core material is impregnated with the adhesive, and the threadlike adhesive body contains 1 vol % to 55 vol % of voids.

A method of manufacturing an implantable stimulation device includes providing a circuit board of the implantable stimulation device, the circuit board being equipped with circuit components and an antenna, adhering one or more electrodes to the circuit board, and applying an insulation material to the circuit board such that the insulation material forms a housing that surrounds the circuit board, the circuit components, and the antenna, while leaving the one or more electrodes exposed for stimulating a tissue.

A device for coating a fiber includes a fiber receiving arrangement and a coating arrangement which includes an application unit which wets the fiber with a coating agent, and a curing unit arranged downstream of the application unit which optically cures the coating agent. The curing unit includes a lamp which emits at least one light beam which is aimed directly or indirectly at a surface of the fiber. A main radiation direction of the lamp includes a beam angle between the main radiation direction and a longitudinal direction of the fiber of less than 40°. The fiber receiving arrangement and the application unit are movable relative to each other in the longitudinal direction of the fiber via a translational motion arrangement so that a wetting process is implemented substantially along an entire length of the fiber.

An apparatus for the continuous hot dip coating of a metal strip is provided The apparatus includes a vessel intended to contain a liquid metal bath, a bottom roller and a scroll casing of the metal strip. The casing includes, at its lower end, a pouring box delimiting a front pouring compartment for liquid metal and a rear pouring compartment for liquid metal. Each pouring compartment is inwardly delimited by an inner wall and outwardly delimited by an outer wall. The outer wall of the rear pouring compartment forms, with the passage plane of the metal strip, an angle greater than or equal to 15 in the usage configuration. A method is also provided.

A method for coloring a carbon nanotube (CNT) product is provided, including placing a CNT product in an electric circuit to ground the product, charging a plurality of pigment molecules with an opposite charge from the CNT product, applying a coating of the charged pigment molecules to a surface of the CNT product, and exposing the coating to a temperature sufficient to cure the coating, while allowing the coating to form a substantially conformal film on the surface of the CNT product.

Provided are methods for extending the life of in-service electrical cable having polymeric insulation, comprising injecting into the cable a dielectric gel formulation containing: (a) SiH endblocked polydiorganosiloxane (H(R.sub.2SiO).sub.x(R.sub.2Si)H); (b) polydiorganosiloxane endblocked with unsaturated carbon-carbon functionality; (c) hydrosilylation catalyst suitable to cure (a) and (b); and (d) at least one organoalkoxysilane functional additive (e.g., anti-oxidant-based alkoxysilane, voltage stabilizer-based alkoxysilane, hindered amine light stabilizer (HALS)-based alkoxylsilane, UV absorber-based alkoxysilane, etc.), wherein (a) and (b) are cured post-injection into a non-flowable gel, and wherein (d) diffuses into the insulation. The methods may further comprise a hydrolysis/condensation catalyst compatible with the hydrosilylation catalyst so as not to interfere with the cure of (a), (b) and (c), and/or be compatible with optional siloxane crosslinkers, and/or with optional hydrosilylation inhibitors.

One aspect refers to a method for preparing a processed filament, including providing a filament, which comprises a multitude of segments, which follow one another in a longitudinal direction of the filament, wherein each of the segments of the multitude of segments comprises a multitude of sections, which are disposed circumferentially around the filament; and processing the filament in n processing steps, thereby obtaining the processed filament. For each integer i in the range from 1 to n, the i.sup.th processing step comprises, for each integer j in the range from 1 to m, processing the j.sup.th section of the (i+j1).sup.th segment. N and m are integers which are, independent from one another, at least 2. Sections of different number are at different circumferential locations of the filament. The processing of each section of each segment of the filament comprises an interaction of the section of the segment of the filament with at least one processing beam.