Proposed are an apparatus and a method for manufacturing an interior material for a vehicle, in which a core and a skin can be integrated by a pressing operation. The apparatus includes a first mold unit having a first molding surface, and a second mold unit having a second molding surface corresponding to the first molding surface. The core is mounted on the second molding surface. The first mold unit includes a first fixing part, and the second mold unit includes a second fixing part. The first fixing part and the second fixing part are configured to fix an outer peripheral portion of a skin placed between the first mold unit and the second mold unit.

A coating apparatus includes a support unit configured to support a film over a work to be coated. The support unit includes first support unit and second support unit which are arranged with a distance therebetween in a first direction so as to be positioned on both sides of the work. The first support unit includes a first lower member and a first upper member which vertically hold therebetween a first end of the film. The second support unit includes a second lower member and a second upper member which vertically hold therebetween a second end of the film. Each of the first lower member and the second lower member includes a support surface which extends in a second direction intersecting with the first direction while curving in an up-down direction, and is configured to support the film from below.

A preparation method of a polytetrafluoroethylene (PTFE)-based membrane for preventing and removing ices covering wind turbine blades is provided and the method comprises: preparing a membrane into a PTFE rod material with polymerized monomers by using monomer polymerization methods such as blending, pre-compressing and pushing; making the membrane into a PTFE-based homogeneous membrane with micropores and nano and micron scale concave-convex geometrical ultra-structure morphologies under the condition that the membrane is cracked to generate a laminar exfoliated fabric-like structure in the hot calendaring process of the PTFE rod material by using a hot calendaring and fusion polymerization method; and applying the PTFE-based homogeneous membrane to blades of a large wind turbine in operation.

A gripper is disclosed for a draping frame having a gripper chassis and at least two opposing mutually movable gripper jaw elements for gripping a film element. The gripper jaw elements are provided on a gripper head part of the gripper. The gripper head part of the gripper is movably mounted, at least with one degree of freedom, relative to the gripper chassis.

Methods and apparatuses for mounting a material (1) on a carrier (6) are provided. To this end, the material is arranged on a porous layer (2) of an air bearing arrangement (2, 3).

An adhesive-applying method is disclosed herein. The method comprises: providing a film comprising pressure sensitive adhesive coated on a major surface thereof; heating the film to a softening point of the film; and pressing the film against a substrate with an application device, the application device comprising a film-contacting portion, the film-contacting portion comprising a foam material and having a thermal conductivity of less than 1.8 BTU in/(hr ft.sup.2 F.); wherein the pressure sensitive adhesive on the major surface of the film adheres to the substrate. Application devices and kits that may be used in conjunction with the method are also disclosed herein.

An elevator maintenance kit is provided for surfacing an elevator sheave that engages with an elevator tension member. The kit includes a substrate with an adhesive backing, and a substrate applicator that is operable to apply the substrate to the sheave as the sheave is rotated. The adhesive backing is operable to attach the substrate to the sheave during the sheave rotation.

A thin ribbon spirally wound polymer conduit and method of forming, wherein a helical reinforcing bead is interposed adjacent overlapping layers of ribbon. Further, a method of continuously forming spirally wound conduit wherein a sacrificial layer, preferably having a different base polymer to that of the conduit, is first applied to the former before the conduit is formed overtop.

A method of bonding substrates includes steps as follows. Providing a curved glass substrate and a flexible light-transmissive film; moving a roller to press the flexible light-transmissive film onto the curved glass substrate so that the flexible light-transmissive film matches a curvature of the curved glass substrate to gradually fit and bond onto the curved glass substrate; sensing the attaching level of at least one local area of the flexible light-transmissive film bonded on the curved glass substrate; and adjusting a press force exerted by the roller to the local area of the flexible light-transmissive film according to the attaching level during the flexible light-transmissive film is bonded onto the curved glass substrate.

A method and an article of manufacture are disclosed for reinforcing various structures, such as pipes, ducts, vessels, tanks, silos, chimneys, columns and the like, constructed from various materials including steel, concrete, masonry, wood, plastics, and the like. Some of the various structures may be used to transport water, gas, oil, and the like. Multiple layers of various material sheets, each sheet having substantially the same or different properties, may be wrapped around or be attached to the inside of a structure to be reinforced. The multiple layers together constitute a structure reinforcement wrap (SRW) and in an embodiment it may include a 3D fabric layer surrounded by other reinforcement layers to reinforce the structure against external and internal loads, such as weight, impact load, blast load, internal pressure, ballistic load, and the like. In some embodiment the SRW may only include 3D fabric layers.