Provided a composite material forming method capable of easily using a composite material that is formed by causing a resin to react in a state where it is joined to another member; and a composite material. The composite material forming method includes a first material preparation step (magnetic field circuit forming material preparation step S11), a second material preparation step (magnetic field circuit non-forming material preparation step S12), a material assembly step S13, and a first heating step (magnetic field heating step S14). In the first material preparation step, a first material including a first resin is prepared. In the second material preparation step, a second material including a second resin is prepared. In the material assembly step S13, the first material and the second material are assembled to each other.

An optical cable and method for forming an optical cable is provided. The cable includes a cable jacket including an inner surface defining a channel and an outer surface and also includes a plurality of optical fibers located within the channel. The cable includes a seam within the cable jacket that couples together opposing longitudinal edges of a wrapped thermoplastic sheet which forms the cable jacket and maintains the cable jacket in the wrapped configuration around the plurality of optical fibers. The method includes forming an outer cable jacket by wrapping a sheet of thermoplastic material around a plurality of optical core elements. The method includes melting together portions of thermoplastic material of opposing longitudinal edges of the wrapped sheet such that a seam is formed holding the sheet of thermoplastic material in the wrapped configuration around the core elements.

A non-woven textile may be formed from a plurality of thermoplastic polymer filaments. The non-woven textile may have a first region and a second region, with the filaments of the first region being fused to a greater degree than the filaments of the second region. A variety of products, including apparel (e.g., shirts, pants, footwear), may incorporate the non-woven textile. In some of these products, the non-woven textile may be joined with another textile element to form a seam. More particularly, an edge area of the non-woven textile may be heatbonded with an edge area of the other textile element at the seam. In other products, the non-woven textile may be joined with another component, whether a textile or a non-textile.

A non-woven textile may be formed from a plurality of thermoplastic polymer filaments. The non-woven textile may have a first region and a second region, with the filaments of the first region being fused to a greater degree than the filaments of the second region. A variety of products, including apparel (e.g., shirts, pants, footwear), may incorporate the non-woven textile. In some of these products, the non-woven textile may be joined with another textile element to form a seam. More particularly, an edge area of the non-woven textile may be heatbonded with an edge area of the other textile element at the seam. In other products, the non-woven textile may be joined with another component, whether a textile or a non-textile.

A pair of thermoplastic resin members are placed on an anvil. A pressing force of a tool horn vibrating ultrasonically in a direction not perpendicular to but along upper surfaces of the pair of thermoplastic resin members is applied to the upper surfaces. The application of the pressing force of the tool horn vibrating ultrasonically allows melting of a vicinity of the upper surfaces of the pair of thermoplastic resin members. A welded structure part is formed on an unwelded structure part, thereby welding the pair of thermoplastic resin members as an overlap structure including the welded structure part arranged on the unwelded structure part. The distance and positional relationship between the pair of thermoplastic resin members after the welding are unchanged before and after the welding. The surfaces, placed on the anvil, of the thermoplastic resin members are neither burned nor discolored.

A system and method for thermoplastic composite welding comprising a cooling means and a heat source. The cooling means cools a heat-side laminate so as to create a thermal gradient in the heat-side laminate. The heat source heats the heat-side laminate after the cooling step is initiated but before the thermal gradient dissipates so that a first side of the heat-side laminate closer to the heat source does not deform as faying surfaces of the heat-side laminate and another laminate farther away from the heat source are welded together.

A method of induction welding a first thermoplastic composite (TPC) to a second thermoplastic composite (TPC) includes inductively heating a weld interface area between the first TPC and the second TPC, and cooling a surface of the first TPC opposite the weld interface area while inductively heating the weld interface area.

A part assembly including a curing shield and a method for secondarily bonding two parts of the part assembly utilizing the curing shield. The method for secondary bonding includes fixing a base of a clip of a curing shield to a first surface of a first part. The curing shield includes a pad fixed to the clip. The clip has the base and a spine fixed to and extending away from the base and terminating at a distal end. The pad extends along at least a portion of a length of the spine between the base and the distal end. The method also includes applying adhesive along a faying surface of one of the first part and a second part. The second part is assembled to the first part along the faying surface so that the distal end of the clip extends toward the second surface and the curing shield defines a pocket adjacent the faying surface at least partly enclosed by the pad.

A part assembly including a curing shield and a method for secondarily bonding two parts of the part assembly utilizing the curing shield. The method for secondary bonding includes fixing a base of a clip of a curing shield to a first surface of a first part. The curing shield includes a pad fixed to the clip. The clip has the base and a spine fixed to and extending away from the base and terminating at a distal end. The pad extends along at least a portion of a length of the spine between the base and the distal end. The method also includes applying adhesive along a faying surface of one of the first part and a second part. The second part is assembled to the first part along the faying surface so that the distal end of the clip extends toward the second surface and the curing shield defines a pocket adjacent the faying surface at least partly enclosed by the pad.

The present invention relates to a machine comprising: an unwinding unit (11) for unwinding a flexible band (1), a folding unit (14) of a flexible band (1), a drive unit (31) configured for moving the flexible band (1) in a forward movement direction (DA), a welding unit (16) and a cutting unit (17) for cutting the flexible band, wherein the cutting unit (17) is a laser beam cutting unit (53) separating each individual flexible package from the flexible band (1) and providing a fill opening in each flexible package by means of at least one fill opening cut. The laser beam cutting unit (53) has associated therewith a separator device, movable in a vertical direction and including an insertable separator element (41), interposed between the opposite faces of the folded flexible band (1), in an area adjacent to the fill opening (3), for separating the opposite faces of the flexible band (1) during cutting operations to prevent the fusion thereof.