Method and device for inspecting flexible container

The invention claimed is: 1. A method for testing a flexible container, comprising the steps: arranging the flexible container ( 3 ) on a winding core ( 5 ), which can be rotated about a winding axis (W) and forms an internal support ( 5 ), a separating means ( 9 ) which is formed as a windable sheet ( 41 ) being fastened on the winding core ( 5 ) with a width extent (X) parallel to the winding axis (W); winding the separating means ( 9 ) together with the flexible container ( 3 ) around the winding axis (W) so that each successive winding of the separating means ( 9 ) and the flexible container ( 3 ) is farther from the winding axis (W); arranging an external support ( 17 ) around the wound container ( 3 ); connecting at least one container opening ( 13 ) of the container ( 3 ) to a fluid source ( 33 ); filling the container ( 3 ) with a fluid from the fluid source ( 33 ) in order to generate a predetermined positive pressure (P 1 ) in the flexible container ( 3 ) at a first time (T 1 ); determining whether the container ( 3 ) is sufficiently leaktight. 2. The method as claimed in claim 1 , wherein an at least locally fluid-permeable and/or structured reception sheet ( 7 ) is arranged on the internal support ( 5 ) and/or on the external support ( 17 ), and/or wherein the separating means ( 9 ) arranged between the wound layers of the flexible container ( 3 ) is at least locally fluid-permeable and/or structured. 3. The method as claimed in claim 1 , wherein the external support ( 17 ) is formed by winding a further layer of a material around the coil of the flexible container ( 3 ). 4. An apparatus for testing a flexible container ( 3 ), comprising: a winding core ( 5 ) that is rotatable about a winding axis (W) and forms an internal support, a flexible container ( 3 ) being fastenable on the winding core ( 5 ) and windable around the winding axis (W) so that each successive revolution of the flexible container ( 3 ) around the winding core ( 5 ) is farther from the winding axis (W); a fluid supply, to which at least one container opening ( 13 ) of the flexible container is releasably connected fluidically; an external support ( 17 ) arranged around the wound container ( 3 ); and a separating means ( 9 ) that is windable together with the flexible container ( 3 ) around the winding axis (W), wherein the separating means ( 9 ) is formed as a windable sheet ( 41 ) that is fastened on the winding core ( 5 ) with a width extent (X) parallel to the winding axis (W). 5. The apparatus as claimed in claim 4 , wherein the sheet ( 41 ) is formed at least locally fluid-permeably and/or with a structured surface. 6. The apparatus as claimed in claim 5 , wherein the sheet ( 41 ) is formed from a multiplicity of lamellae ( 39 ) connected to one another in an articulated fashion. 7. The apparatus as claimed in claim 6 , wherein the lamellae ( 39 ) or guide elements, which are fastened to ends of the lamellae ( 39 ) separated from one another along the width extent (X), engage in an associated guide groove ( 43 ) in order to wind the lamellae ( 39 ) at a predetermined distance from one another. 8. The apparatus as claimed in claim 4 , wherein the winding core ( 5 ) is connected to a drive ( 25 ). 9. The apparatus as claimed in claim 4 , wherein an at least locally fluid-permeable and/or structured reception sheet ( 7 ) is arranged on the internal support ( 5 ) and/or on the external support ( 17 ), and/or wherein the separating means ( 9 ) arranged between the wound layers of the flexible container ( 3 ) is at least locally fluid-permeable and/or structured. 10. The apparatus as claimed in claim 4 , further comprising: a fluid source ( 33 ) that is connected fluidically to the fluid supply, and/or a testing device configured to determine whether the container ( 3 ) is sufficiently leaktight. 11. The apparatus as claimed in claim 4 , wherein the separating means ( 9 ) is disposed around the winding axis (W) so that each successive revolution of the separating means ( 9 ) around the winding core ( 5 ) is farther from the wind axis (W). 12. An apparatus for testing a flexible container ( 3 ), comprising: a winding core ( 5 ) that can be rotated about a winding axis (W) and forms an internal support, a flexible container ( 3 ) being fastenable on the winding core ( 5 ) and windable around the winding axis (W); a fluid supply, to which at least one container opening ( 13 ) of the flexible container can be fluidically connected; an external support ( 17 ) that can be arranged around the wound container ( 3 ); and a separating means ( 9 ) that can be wound together with the flexible container ( 3 ) around the winding axis (W), wherein the separating means ( 9 ) is formed as a windable sheet ( 41 ) that is fastened on the winding core ( 5 ) with a width extent (X) parallel to the winding axis (W), and wherein the flexible container ( 3 ) and the separating means ( 9 ) are wound on the winding core ( 5 ) to define alternating layers at farther respective distances from the winding axis (W). 13. The method as claimed in claim 1 , wherein the step of filling the container ( 3 ) with the fluid from the fluid source ( 33 ) to generate the predetermined positive pressure (P 1 ) in the flexible container ( 3 ) comprises filling the container ( 3 ) sufficiently to generate a pressure against the external support ( 17 ).