Abstract: Provided is a package made of a composite material is represented and described, including a package base with two front base corners and with two rear base corners, a package gable with two front gable corners and with two rear gable corners, and a package base body with a front panel, a first side panel, a second side panel and a rear panel. The package base and the package gable are arranged on opposite sides of the package base body. The composite material has a polymer inner layer, a polymer outer layer and a fibrous support layer, which is arranged between the polymer outer layer and the polymer inner layer. In order to enable the manufacture of packages with even more complex geometries without impairing the rigidity of the package, it is proposed to provide a third sleeve fold line, which has a plurality of sections, which each adjoin a side panel and the rear panel, and of which at least one section is curved.

Abstract: A flat-shaped composite material is represented and described for manufacturing a package, including: a polymer outer layer, a polymer inner layer, a fibrous support layer, which is arranged between the polymer outer layer and the polymer inner layer. The flat-shaped composite material has a plurality of fold lines, which are arranged and designed such that a closed package can be manufactured by folding the flat-shaped composite material along the fold lines and by connecting seam surfaces of the flat-shaped composite material and a sleeve surface. The sleeve surface includes a front surface, a first side surface, a second side surface, a first rear surface and a second rear surface, and base surfaces. The base surfaces include triangular base surfaces, quadrangular base surfaces, and gable surfaces. The gable surfaces include triangular gable surfaces and quadrangular gable surfaces. The base surfaces and the gable surfaces are arranged on opposite sides of the sleeve surface.

Abstract: Provided is a package made of a composite material is represented and described, including a package base with two front base corners and with two rear base corners, a package gable with two front gable corners and with two rear gable corners, and a package base body with a front panel, a first side panel, a second side panel and a rear panel. The package base and the package gable are arranged on opposite sides of the package base body. The composite material has a polymer inner layer, a polymer outer layer and a fibrous support layer, which is arranged between the polymer outer layer and the polymer inner layer. In order to enable the manufacture of packages with even more complex geometries without impairing the rigidity of the package, it is proposed to provide a third sleeve fold line, which has a plurality of sections, which each adjoin a side panel and the rear panel, and of which at least one section is curved.

Abstract: A flat-shaped composite material is represented and described for manufacturing a package, including: a polymer outer layer, a polymer inner layer, a fibrous support layer, which is arranged between the polymer outer layer and the polymer inner layer. The flat-shaped composite material has a plurality of fold lines, which are arranged and designed such that a closed package can be manufactured by folding the flat-shaped composite material along the fold lines and by connecting seam surfaces of the flat-shaped composite material, and a sleeve surface. The sleeve surface includes a front surface, a first side surface, a second side surface, a first rear surface, a second rear surface, and base surfaces. The base surfaces include triangular base surfaces, quadrangular base surfaces, and gable surfaces. The gable surfaces include triangular gable surfaces and quadrangular gable surfaces. The base surfaces and the gable surfaces are arranged on opposite sides of the sleeve surface.

Abstract: A flat-shaped composite material is represented and described for manufacturing a package, including: a polymer outer layer, a polymer inner layer, a fibrous support layer, which is arranged between the polymer outer layer and the polymer inner layer. The flat-shaped composite material has a plurality of fold lines, which are arranged and designed such that a closed package can be manufactured by folding the flat-shaped composite material along the fold lines and by connecting seam surfaces of the flat-shaped composite material and a sleeve surface. The sleeve surface includes a front surface, a first side surface, a second side surface, a first rear surface and a second rear surface, and base surfaces. The base surfaces include triangular base surfaces, quadrangular base surfaces, and gable surfaces. The gable surfaces include triangular gable surfaces and quadrangular gable surfaces. The base surfaces and the gable surfaces are arranged on opposite sides of the sleeve surface.

Abstract: A package made of a composite material is represented and described, including: a package base with two front base corners and with two rear base corners, a package gable with two front gable corners and with two rear gable corners, and a package base body with a front panel, a first side panel, a second side panel and a rear panel. The package base and the package gable are arranged on opposite sides of the package base body. The composite material has a polymer inner layer, a polymer outer layer and a fibrous support layer, which is arranged between the polymer outer layer and the polymer inner layer. In order to enable the manufacture of packages with even more complex geometries without impairing the rigidity of the package, it is proposed that the package base body has at least one stress-relief panel, which is arranged between the front panel and one of the two side panels.

Abstract: A flat-shaped composite material is represented and described for manufacturing a package, including: a polymer outer layer, a polymer inner layer, a fibrous support layer, which is arranged between the polymer outer layer and the polymer inner layer. The flat-shaped composite material has a plurality of fold lines, which are arranged and designed such that a closed package can be manufactured by folding the flat-shaped composite material along the fold lines and by connecting seam surfaces of the flat-shaped composite material and a sleeve surface. The sleeve surface includes a front surface, a first side surface, a second side surface, a first rear surface and a second rear surface, and base surfaces. The base surfaces include triangular base surfaces and quadrangular base surfaces and gable surfaces. The gable surfaces include triangular gable surfaces and quadrangular gable surfaces. The base surfaces and the gable surfaces are arranged on opposite sides of the sleeve surface.

Abstract: A pouring element for a composite packaging, in particular a beverage carton for liquid foodstuffs is shown and described, comprising a basic body having a fastening flange and a pouring tube, a cutting element which is arranged and guided in the pouring tube and a closure cap which can be joined to the basic body, wherein during actuation for the first time, the cutting element can be driven by first drive means formed on the closure cap and by second drive means formed on the inner wall of the cutting element and wherein the movement of the cutting element follows different gradients, and a composite packaging is also shown and described, in particular a beverage carton for liquid foodstuffs, having a pack gable-top panel which is suitable for receiving a pouring element.

Abstract: A pouring element for a composite packaging, in particular for a beverage carton for liquid food, comprising a fastening flange and a pouring tube, a cutting element arranged and guided in the pouring tube, first guide means formed in the pouring tube and second guide means formed on the cutting element, wherein the first and second guide means cooperate correspondingly, and a composite packaging, in particular a beverage carton for liquid foods, with a packaging gable panel suitable for accommodating a pouring element. The first guide means is formed by a surrounding and self-contained rib.

Abstract: A pouring element for a composite packaging, in particular a beverage carton for liquid foodstuffs is shown and described, comprising a basic body having a fastening flange and a pouring tube, a cutting element which is arranged and guided in the pouring tube and a closure cap which can be joined to the basic body, wherein during actuation for the first time, the cutting element can be driven by first drive means formed on the closure cap and by second drive means formed on the inner wall of the cutting element and wherein the movement of the cutting element follows different gradients, and a composite packaging is also shown and described, in particular a beverage carton for liquid foodstuffs, having a pack gable-top panel which is suitable for receiving a pouring element.

Abstract: A pouring element for a composite packaging, in particular for a beverage carton for liquid foods, comprising a fastening flange and a pouring tube, a cutting element arranged and guided in the pouring tube, first guide means formed in the pouring tube and second guide means formed on the cutting element, wherein the first and second guide means cooperate correspondingly, and a composite packaging, in particular a beverage carton for liquid foods, with a packaging gable panel suitable for accommodating a pouring element. The first guide means is formed by a surrounding and self-contained rib.