The composite 3D-printed curved elements and methods of making same provide arches and domes with high resistance to shear and flexural failure, thereby allowing the production of large, curved 3D-printed elements. The elements include a primary composite fused deposition modeling (FDM) 3D-printed component in the form of an arch or dome with one or more grooves on the outer surface, the inner surface, or both the outer and inner surfaces of the component. Each groove includes a plurality of deep, blind bores or slots spaced longitudinally along the bottom of the groove. In adjacent grooves, the slots are alternated in a zig-zag pattern, so that no two slots are too close to one another. Composite reinforcement materials are sequentially applied to the grooves and slots until they are filled.

The composite 3D-printed curved elements and methods of making same provide arches and domes with high resistance to shear and flexural failure, thereby allowing the production of large, curved 3D-printed elements. The elements include a primary composite fused deposition modeling (FDM) 3D-printed component in the form of an arch or dome with one or more grooves on the outer surface, the inner surface, or both the outer and inner surfaces of the component. Each groove includes a plurality of deep, blind bores or slots spaced longitudinally along the bottom of the groove. In adjacent grooves, the slots are alternated in a zig-zag pattern, so that no two slots are too close to one another. Composite reinforcement materials are sequentially applied to the grooves and slots until they are filled.

The composite 3D-printed curved elements and methods of making same provide arches and domes with high resistance to shear and flexural failure, thereby allowing the production of large, curved 3D-printed elements. The elements include a primary composite fused deposition modeling (FDM) 3D-printed component in the form of an arch or dome with one or more grooves on the outer surface, the inner surface, or both the outer and inner surfaces of the component. Each groove includes a plurality of deep, blind bores or slots spaced longitudinally along the bottom of the groove. In adjacent grooves, the slots are alternated in a zig-zag pattern, so that no two slots are too close to one another. Composite reinforcement materials are sequentially applied to the grooves and slots until they are filled.

Devices for accumulating material within a limited space, such that at most insignificant amount of material leaves the device prior to the device being at full capacity. One embodiment comprises an expandable structure to be filled, comprising a material receiving member for receiving expansible material, such that the expansible material is inserted into the member and expands within the member prior to part of the material exiting the material receiving member into another member, wherein the expansible material expands and rigidizes within the material receiving member and within the another member to form a rigid structure having a required form.

A foldable, frameless emergency shelter is constructed from a radial array of bendable yet rigid panels such as of a foamed plastic. Panels have adjoining edges with matching convexly curved profiles. The edges are always held to each other with a flexible fastener such as an adhesive tape. During erection, a flat panel inherently deforms into a curved cylindrical tapered shape enclosing a space. A door and an optional floor are provided. The shelter has a rigid conical cap including holes for guy ropes, a door and an optional window.

A foldable, frameless emergency shelter is constructed from a radial array of bendable yet rigid panels such as of a foamed plastic. Panels have adjoining edges with matching convexly curved profiles. The edges are always held to each other with a flexible fastener such as an adhesive tape. During erection, a flat panel inherently deforms into a curved cylindrical tapered shape enclosing a space. A door and an optional floor are provided. The shelter has a rigid conical cap including holes for guy ropes, a door and an optional window.

The composite 3D-printed curved elements and methods of making same provide arches and domes with high resistance to shear and flexural failure, thereby allowing the production of large, curved 3D-printed elements. The elements include a primary composite fused deposition modeling (FDM) 3D-printed component in the form of an arch or dome with one or more grooves on the outer surface, the inner surface, or both the outer and inner surfaces of the component. Each groove includes a plurality of deep, blind bores or slots spaced longitudinally along the bottom of the groove. In adjacent grooves, the slots are alternated in a zig-zag pattern, so that no two slots are too close to one another. Composite reinforcement materials are sequentially applied to the grooves and slots until they are filled.

The invention relates to a heating device (1) which is designed to heat a packaging film in a deep drawing process, over the course of which the heated packaging film is molded into the cavity of a deep drawing mold. The surface region of the heating device (1) which is brought into contact with the film section to be molded into the cavity has at least one depression (50), the opening area (40) of which equals 40 to 95% of the opening area (40) of the cavity. The invention also relates to a deep drawing device comprising the aforementioned heating device (1).

A method for producing a portion unit with at least one filled receiving chamber surrounded by a film, comprising the steps of a) transporting a first film in the direction of a heating device; b) bringing the first film into contact with a surface of the heating device; c) heating the first film by means of the heating device; d) breaking the contact between the first film and the heating device; e) molding the first heated film into the cavities of a thermoforming mold, thereby forming a receiving container with at least one receiving chamber; f) filling the at least one receiving chamber; g) optionally closing and separating the filled receiving containers, thereby forming the portion unit, wherein the region on the surface of the heating device that is brought into contact with the film has at least one depression and, in step b), the at least one depression is covered by the subregions of the first film that are molded into the cavity of the thermoforming mold in step e).