In an example, a wearable article includes a nonwoven textile sheet having a first portion and a second portion contiguous with the first portion. The first portion has a first density and a first modulus of elasticity. The second portion has a second density less than the first density and has a second modulus of elasticity less than the first modulus of elasticity. The first portion is shaped differently than the second portion as an integral implement of the wearable article. A method of manufacturing a wearable article may comprise thermoforming the first portion while the second portion contiguous with the thermoformed first portion is not thermoformed.

A method for fabricating a preform for a portion of an aircraft includes acquiring a sheet of broad good fiber reinforced material, trimming the sheet to form layup pieces having boundaries, placing the boundaries into alignment, arranging the layup pieces in a layup pattern to form a ply, performing a placement operation that transports the layup pattern onto a layup mandrel, and shaping the layup pattern into conformance with a contour of the layup mandrel.

A method of mechanically securing a first object including a thermoplastic material in a solid state to a second object with a generally flat sheet portion, with a perforation of the sheet portion, and with the sheet portion having an edge along the perforation is provided, wherein the first object is positioned relative to the second object so that the edge is in contact with the thermoplastic material and wherein mechanical vibration energy is coupled into the assembly including the first and second objects until a flow portion of the thermoplastic material due to friction heat generated between the edge and the thermoplastic material becomes flowable and flows around the edge to at least partially embed the edge in the thermoplastic material. After the mechanical vibration stops, the thermoplastic material is caused to re-solidify, whereby the re-solidified thermoplastic material at least partially embedding the edge anchors the first object in the second object.

A composite material shell having a base plate made of thermoplastic resin and reinforcing fibers and multiple decorative pieces. Each of the multiple decorative pieces is made of a composite material containing thermoplastic resin and reinforcing fibers. An area of each of the multiple decorative pieces is smaller than an area of the base plate, wherein the multiple decorative pieces are non-directionally arranged, are overlapped, and are welded on the base plate whereby the composite material shell provides unique reflection and depth variations of visual effect.

The invention relates to a transport device (10) for piece goods, comprising a base part (14) which has a base plate (16) and side walls (18) which are elevated from the base plate (16) and are circumferential, the side walls (18) delimiting a placement surface of the base plate (16), a number of first compartments (22), wherein each of the first compartments (22) has circumferential walls (24) which each have a lower edge on the placement surface, an intermediate base (26) which bears on the first compartments (22) and has a downwardly projecting edge (28), which surrounds the first compartments (22) at upper edges (24b) of their circumferential walls (24), and an upwardly pointing further placement surface (30), a number of second compartments (32), wherein each of the second compartments (32) has circumferential walls (34) which each have a lower edge (34a) on the further placement surface (30), and wherein the first and second compartments (22, 32) are foldable for the purpose of volume reduction. The intermediate base (26) has two base parts (44, 46) which are connected to one another in an articulated manner, have each a part (50, 52) of the further placement surface (30) and are pivotable relative to one another about a pivot axis (48) up to a contact of the parts (50, 52) of the further placement surface (30), wherein each of the base parts (44, 46) has a rectangular or square contour, one side (56, 58) of which is shorter than both sides of the placement surface and the other side (60, 62) of which is shorter than at least one of the sides of the placement surface.

A method of producing a composite article is disclosed that includes generating composite plies from a low tack composite prepreg material, connecting, by an ultrasonic welding device, two or more of the composite plies by increasing their tackiness to form a composite stack, and forming, by a compression molding device, a composite article from the composite stack.

A multi-cavity mould (1) comprising:—an upper tool (11) and a lower tool (12) arranged in a cooperating manner; characterized in that the upper tool (11) comprises a knife pressure box (13) comprising:—a horizontal top plate (131);—first and second end plates (132) and first and second side plates (133) extending orthogonally downwardly from a lower surface of the plate (131); the plates (132, 133) are connected such that the plate (131) and the plates (132, 133) form a downwardly open rectangular parallelepiped enclosure; the plates (132, 133) are made from tool steel with a thickness (t) from 6.35-10 mm and a cutting surface (130) defined along an orthogonally downwardly projecting end of plates (132, 133) wherein—the surface (130) has a substantially V-shaped profile comprising a micro flat face (M) with a width from 0.02-0.1 mm and is positioned such that when the pressure box (13) is pressed against the sheet (3), the surface (130) partially penetrates the sheet (3) in order to form a seal around the pressure box (13) by pressing a zone of the sheet (3) which was partially trimmed and situated inside the enclosure against the surface (130).

An apparatus and method for joining pipes includes a plate for melting mating surfaces of the pipes to be joined. Additionally, the apparatus utilizes a vacuum in order to push the first and second pipes together in lieu of hand or mechanical pressure which may be inconsistent. Additionally, the vacuum allows the pipes to be joined to settle on each other in order to create a pressure about a periphery of the end of the pipe being joined to the other pipe. The consistent pressure creates a very strong joint between the first and second pipes.

A thermoforming device includes: a base configured to hold a substrate; a hot plate including a heating surface facing vertically downward; a sheet transport portion that supplies a sheet onto the heating surface of the hot plate; and a substrate supply portion configured to attach the substrate to the base and detach the substrate from the base, and to dispose the substrate at a substrate supply position positioned in a lower area of the sheet which is opposite to a side of the sheet in which the heating surface is provided. In the thermoforming device, heating of the sheet using the hot plate and attachment and detachment of the substrate with respect to the base are performable at the same time, and the sheet heated and softened by the hot plate is attached to the substrate at the substrate supply position.

A composite stiffener for a stiffener reinforced panel is disclosed. The stiffener has a longitudinal direction and a run-out region which terminates at an end of the stiffener. The stiffener also has a constant section region inboard of the run-out region in the longitudinal direction and having a constant cross section transverse to the longitudinal direction with a crown between adjacent foot portions. The run-out region has a changing cross section transverse to the longitudinal direction with a crown between adjacent foot portions and the crown reduces in height towards the end of the stiffener forming a ramp. The composite stiffener comprises a number of blankets of non-crimp fabric layers.