A method for connecting insulation panels, each of the panels comprising a cellulosic web having two sides and an outside edge, and comprising layers of cellulosic fibers, the method comprising: a) arranging a portion of each panel to be adjacent to the other, thereby forming an edge portion where the two webs can be connected; b) relaxing the fibers of cellulosic material in the edge portion of each insulation panel by applying heat to the edge portion at a temperature of 150? F. to 450? F., thereby forming a relaxed fiber edge portion; c) compressing the relaxed fiber edge portion of each insulation panel at a pressure of at least 5 psig, thereby forming a compressed panel portion having a thickness and a density; and d) fastening the compressed panel portions together using sewing, riveting, adhesive, tape, interlacing, stamping, ply bonding or stapling thereby forming a fastened area, wherein step (c) can be conducted at the same time or following step (b).

A manufacturing method of a thermoplastic continuous-discontinuous fiber composite sheet is provided, including providing a thermoplastic composite including a continuous fiber and a first thermoplastic resin. A mechanical treatment is performed on the thermoplastic composite to form a plurality of fragments such that the continuous fiber is changed into a discontinuous fiber. At least one thermoplastic discontinuous fiber aggregate layer is formed using the plurality of fragments as a raw material. The at least one thermoplastic discontinuous fiber aggregate layer is thermally compressed with at least one thermoplastic continuous fiber layer.

A cylindrical or tubular filter insert (10) of a filter material (2) for liquid media (7) is disclosed. A filtration arrangement (30) serves to receive the cylindrical or tubular filter insert (10). The filtration arrangement (30) comprises a filter housing (31) with an inlet (32) for the medium (7) to be filtered and an outlet (34) for the filtered medium (7).

Disclosed is technology addressing lighting issues using a signature perforated design diffuser panel that provides a dual purposeartistic and artificial light source. Stated differently, the disclosed technology provides diffused lighting while creating a signature geometric perforated pattern. When turned off, the technology is wall art, and, when turned on, it is wall art that provides a signature lighting experience. Embodiments also include the same diffuser technology used to modify and condition natural light sources (e.g. sun light).

The invention relates to novel processes for the lamination of semi-crystalline, high-melting point, low glass transition polymeric films, which are extruded and subsequently laminated on various thermally sensitive substrates to form laminated medical device constructs in a specific time interval to allow low processing temperatures to avoid polymer film and/or substrate degradation or heat-related distortions. Also disclosed are laminated medical device constructs made from such processes.

A transparent conductive film (10) that has a substrate (14) having a surface (14a, 14b), a nanowire layer (12, 12a) over one or more portions of the surface (14a, 14b) of the substrate (14), and a conductive layer (16, 16a) on the portions comprising the nanowire layer (12, 12a), the conductive layer (16, 16a) comprising carbon nanotubes (CNT) and a binder.

This disclosure describes a reinforced thermosetting resin piping system that is protected from external impact and UV damage by an outer polyurea-based layer. The embodiments described herein can be favorably used for underground and aboveground applications. In some implementations, an RTR pipe includes a core layer that includes a resin and fibers, an outer layer that includes a polyurea-based layer, and an interface layer between the core layer and the outer layer. The methods described herein also outline the process of producing the pipe structure.

A fiber reinforced plastic material is provided, the material including a fiber layer comprising a plurality of continuous carbon fiber reinforced thermoplastic sheets, a veil layer comprising fibers selected from at least one of glass fiber and carbon fiber, and a resin layer comprising a resin film, wherein the veil layer is impregnated by at least a portion of the resin film.

In one aspect, a method for manufacturing a spar cap for a wind turbine rotor blade may generally include stacking a plurality of plates together to form a plate assembly, wherein each of the plates is formed from a fiber-reinforced composite including a plurality of fibers surrounded by a thermoplastic resin material. The method may also include positioning the plate assembly relative to a mold defining a mold surface, wherein the mold surface is shaped so as to correspond to at least one blade parameter of the wind turbine rotor blade. In addition, the method may include applying pressure to the plate assembly via the mold such that at least a portion of the plate assembly conforms to the shape of the mold surface.

A density of a nanofiber sheet can be changed using an edged surface, and in particular an arcuate edged surface. As described herein, a nanofiber sheet is drawn over (and in contact with) an arcuate edged surface. Depending on whether the arcuate surface facing a direction opposite the direction in which the nanofiber sheet is being drawn is convex or concave determines whether the nanofiber sheet density is increased relative to the as-drawn sheet or decreased relative to the as-drawn sheet.