Provided is a transmissive wire of a micrometer or nanometer scale diameter, and a method of forming such a transmissive wire, that can be produced and handled at macrometer scale, and which has a mechanical strength suitable for being formed and handled at a macrometer scale. A transmissive element having micrometer or nanometer scale thickness may be continuously applied, such as fixedly applied, to a nanomaterial structure, or vice versa, and the combined structure jointly wrapped about an axis of the nanomaterial structure to produce a wire. In one example, a continuously formed transmissive element may be continuously applied to a continuously formed length of a nanomaterial sheet with the combined structure being wrapped about a longitudinal axis of the nanomaterial sheet to form a transmissive wire having a micrometer or nanometer scale diameter along the longitudinal axis of the formed transmissive wire.

Provided is a transmissive wire of a micrometer or nanometer scale diameter, and a method of forming such a transmissive wire, that can be produced and handled at macrometer scale, and which has a mechanical strength suitable for being formed and handled at a macrometer scale. A transmissive element having micrometer or nanometer scale thickness may be continuously applied, such as fixedly applied, to a nanomaterial structure, or vice versa, and the combined structure jointly wrapped about an axis of the nanomaterial structure to produce a wire. In one example, a continuously formed transmissive element may be continuously applied to a continuously formed length of a nanomaterial sheet with the combined structure being wrapped about a longitudinal axis of the nanomaterial sheet to form a transmissive wire having a micrometer or nanometer scale diameter along the longitudinal axis of the formed transmissive wire.

A self-wrapping sleeve and method of construction thereof is provided. The sleeve includes an elongate multilayered tubular wall having opposite edges extending along a longitudinal axis of the sleeve between opposite ends of the sleeve. The opposite edges are biased into a self-wrapping configuration about the longitudinal axis to define an internal cavity bounded by the tubular wall. The tubular wall includes a non-woven layer of intertwined fibers and a textile layer of interlaced filaments, wherein the non-woven layer is fixed to the textile layer via needled fibers of the non-woven layer being entangled with filaments of the textile layer.

A convolutely wound tube (1) is formed of a composite sheet including a first sheet (6) and a second sheet (5). The convolutely wound tube includes a first segment (66) formed of a plurality of convolute windings (2) of the first sheet, a second segment (70) formed of directly adhered and overlapping portions of the first sheet and the second sheet, and a third segment (68) formed of the second sheet wrapped about and overlying the first sheet. The second segment is an underwrap portion positioned between a layer of the first sheet and a layer of the second sheet.

A fin assembly apparatus which comprising a product dispensing stand for supporting a fabric product, a movable fin insertion apparatus for overlapping the fabric product and forming a fin opening, a movable fin sandwiching apparatus for forming a fin member, a pair of spaced apart guide tracks for supporting the movable fin sandwiching apparatus and the movable fin insertion apparatus, and a control panel for controlling operation of the fin assembly apparatus during manufacture of the fin member.

A method for producing a convolute paper core of a desired width and thickness, the method including unwinding paper from a paper roll, thereby creating unwound paper, conveying the unwound paper to a cutting position in a feeding direction, cutting the unwound paper, thereby creating a paper sheet having a length L, conveying the paper sheet from the cutting position to a mandrel in a winding direction, wherein the winding direction is perpendicular to the feeding direction, adhesively and convolutely winding the paper sheet on the mandrel so as to produce a paper core, so that a width W of the paper core is equal to the length L, and repeating the steps of unwinding, conveying, cutting, conveying and adhesively and convolutely winding a plurality of paper sheets until the paper core has the desired thickness.

A method for producing a convolute paper core of a desired width and thickness, the method including unwinding paper from a paper roll, thereby creating unwound paper, conveying the unwound paper to a cutting position in a feeding direction, cutting the unwound paper, thereby creating a paper sheet having a length L, conveying the paper sheet from the cutting position to a mandrel in a winding direction, wherein the winding direction is perpendicular to the feeding direction, adhesively and convolutely winding the paper sheet on the mandrel so as to produce a paper core, so that a width W of the paper core is equal to the length L, and repeating the steps of unwinding, conveying, cutting, conveying and adhesively and convolutely winding a plurality of paper sheets until the paper core has the desired thickness.

Machine (10) for the production of coiled gaskets from continuous strips, i.e. a master backing strip (1a) and sealing filler strip (1b), to be spirally wound onto rings, templates or inner rings (11), comprising at least: means (2) for feeding the strips (1a,1b) to be wound, a unit (100) for straightening and forming the backing strip (1a), a unit (200) for making incisions in and cutting the backing strip (1a), arranged downstream of the forming unit (100), a unit (300) for joining together the master strip (1a) and filler strip (1b) so as to form a combined strip (1) and cutting the filler strip (1b), a rotating spindle unit (400) for winding the combined strip (1), arranged downstream of the strip joining unit (300); a unit (500) for driving the ring or inner-ring (11) arranged downstream of the spindle (400), and a unit (600) for welding the master strip (1a), said units being designed to be able to produce automatically and in sequence a finished gasket, in accordance with a program managed by means (1000) for programming, controlling and actuating the operations.

Machine (10) for the production of coiled gaskets from continuous strips, i.e. a master backing strip (1a) and sealing filler strip (1b), to be spirally wound onto rings, templates or inner rings (11), comprising at least: means (2) for feeding the strips (1a,1b) to be wound, a unit (100) for straightening and forming the backing strip (1a), a unit (200) for making incisions in and cutting the backing strip (1a), arranged downstream of the forming unit (100), a unit (300) for joining together the master strip (1a) and filler strip (1b) so as to form a combined strip (1) and cutting the filler strip (1b), a rotating spindle unit (400) for winding the combined strip (1), arranged downstream of the strip joining unit (300); a unit (500) for driving the ring or inner-ring (11) arranged downstream of the spindle (400), and a unit (600) for welding the master strip (1a), said units being designed to be able to produce automatically and in sequence a finished gasket, in accordance with a program managed by means (1000) for programming, controlling and actuating the operations.

A full motion wrapping apparatus includes a wrapper unit and a product support unit. The wrapper unit is configured for stretch wrapping a product. The product support unit includes a plurality of supports. The supports are movably disposed in, on or around a track with the wrapper unit. The wrapper unit may be positioned between corresponding pairs of the supports. The product support unit permits the stretch wrapping of the product while the product remains in a substantially stationary position.