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 bending method and a bending device, wherein a composite bar comprising a bundle of reinforcing fibres embedded in a polymer matrix is bent at a bending point. To make it bendable, the composite bar is heated locally at the bending point using an ultrasonic device with a sonotrode. After the bending point has been heated, an infeeding movement between the composite bar and the sonotrode is used to deform a region of the composite bar at the bending point to create a deformed portion of which the outer dimensions are different from the outer dimensions of the bar portions of the composite bar adjoining the bending point. The two bar portions are then moved or angled away in relation to one another, and so the composite bar is curved at the bending point. Once the desired bending has been achieved, the composite bar is cured at the bending point.

A bending method and a bending device, wherein a composite bar comprising a bundle of reinforcing fibres embedded in a polymer matrix is bent at a bending point. To make it bendable, the composite bar is heated locally at the bending point using an ultrasonic device with a sonotrode. After the bending point has been heated, an infeeding movement between the composite bar and the sonotrode is used to deform a region of the composite bar at the bending point to create a deformed portion of which the outer dimensions are different from the outer dimensions of the bar portions of the composite bar adjoining the bending point. The two bar portions are then moved or angled away in relation to one another, and so the composite bar is curved at the bending point. Once the desired bending has been achieved, the composite bar is cured at the bending point.

A curved electronic device (10c) can be formed by a stack with a curved substrate (13) comprising a thermoplastic material (Ms), and at least one electronic component (14) connected to an electronic circuit (15) disposed on the substrate (13). A component area (11) of the substrate surface (11.12) around the electronic component (14) comprises a first material (M1) providing relatively low absorption (A1) to light (L) and a surrounding area (12) of the substrate (13) outside the component area (11), comprises a second material (M2) providing relatively high absorption (A2) of the light (L). E.g. as a result of differential heating and thermoforming a first thickness (T1) of the substrate (13) in the component area (11) may be relatively high compared to a second thickness (T2) of the substrate (13) in the surrounding area (12).

A curved electronic device (10c) can be formed by a stack with a curved substrate (13) comprising a thermoplastic material (Ms), and at least one electronic component (14) connected to an electronic circuit (15) disposed on the substrate (13). A component area (11) of the substrate surface (11.12) around the electronic component (14) comprises a first material (M1) providing relatively low absorption (A1) to light (L) and a surrounding area (12) of the substrate (13) outside the component area (11), comprises a second material (M2) providing relatively high absorption (A2) of the light (L). E.g. as a result of differential heating and thermoforming a first thickness (T1) of the substrate (13) in the component area (11) may be relatively high compared to a second thickness (T2) of the substrate (13) in the surrounding area (12).

A nylon tube automatic thermoforming apparatus includes a main body, a conveying assembly, a heating assembly and a tube bending assembly. The heating assembly includes an oven communicated with the conveying assembly and an electrically heated cylinder arranged between the oven and the tube bending assembly. A heating coil is arranged in the electrically heated cylinder. A nylon tube is conveyed from the conveying assembly and enters the tube bending assembly via the oven and the heating coil. The electrically heated cylinder and the tube bending assembly are arranged outside the main body. A nylon tube shaping process includes the steps of drawing, heating inside a main body, heating outside the main body, bending, staying, feeding, angle adjusting, repeating the above steps until the length and the curvature of the nylon tube meet the requirements, and cutting off.

A nylon tube automatic thermoforming apparatus includes a main body, a conveying assembly, a heating assembly and a tube bending assembly. The heating assembly includes an oven communicated with the conveying assembly and an electrically heated cylinder arranged between the oven and the tube bending assembly. A heating coil is arranged in the electrically heated cylinder. A nylon tube is conveyed from the conveying assembly and enters the tube bending assembly via the oven and the heating coil. The electrically heated cylinder and the tube bending assembly are arranged outside the main body. A nylon tube shaping process includes the steps of drawing, heating inside a main body, heating outside the main body, bending, staying, feeding, angle adjusting, repeating the above steps until the length and the curvature of the nylon tube meet the requirements, and cutting off.

A system for constructing a composite structure includes a braiding machine, a winding tool and a forming machine. The composite structure is constructed of a wound tubular braiding. The wound tubular braiding is constructed of a biaxial or triaxial tubular braid of unidirectional tape.

A system for constructing a composite structure includes a braiding machine, a winding tool and a forming machine. The composite structure is constructed of a wound tubular braiding. The wound tubular braiding is constructed of a biaxial or triaxial tubular braid of unidirectional tape.

Provided are a method of producing a curved member, the method containing preparing a polycarbonate resin laminate with a hard coat layer for heat bending that includes a permeation layer (B layer) and a hard coat layer (C layer) sequentially layered on at least one surface of a polycarbonate resin base material layer (A layer) having a thickness of from 0.1 mm to 20 mm, and satisfying the requirements (a) to (d), pre-heating the polycarbonate resin laminate at from a temperature higher than Tg by 5° C. to a temperature higher than Tg by 70° C., in which Tg (° C.) is a glass transition temperature of a polycarbonate resin of the prepared polycarbonate resin laminate, and curving the polycarbonate resin laminate obtained by the pre-heating by applying pressure to the polycarbonate resin laminate, and a polycarbonate resin laminate with a hard coat layer for heat bending.