Cryogenic vessel

The invention claimed is: 1. A cryogenic vessel ( 300 a , 300 b ) comprising: an inner container ( 301 ) having a side wall, a first end wall, and a second end wall, where in the walls of the inner container define an internal space for the storage of fluid, an outer container ( 302 ), an intermediate space ( 303 ), which can be evacuated, between the inner container ( 301 ) and the outer container ( 302 ), and a fluid distribution container ( 100 , 200 ), said fluid distribution container having an internal volume ( 120 , 220 ) that, proceeding from an edge of a through-hole in the first end wall or the second end wall of the inner container ( 301 ), extends into the intermediate space ( 303 ), wherein the fluid distribution container is arranged at least partially within the intermediate space ( 303 ) and is fluidically connected to the inner container ( 301 ) by the through-hole through which fluid in the internal space of the inner container can flow into the fluid distribution container and fluid in fluid distribution container can flow into the internal space of the inner container, wherein the diameter of the fluid distribution container corresponds to the diameter of the through-hole in the first end wall or the second end wall of the inner container, and the fluid distribution container is welded to the edge of the through-hole, wherein the internal volume ( 120 , 220 ) of the fluid distribution container is delimited by a further wall ( 121 , 221 ) which extends from the first end wall or the second end wall and which has a plurality of openings ( 111 , 112 , 113 , 211 , 212 , 213 ) that are each configured for the connection of a line ( 311 , 312 , 313 ) or are each connected to such a line ( 311 , 312 , 313 ), and the further wall ( 121 , 221 ) has a convex section ( 101 , 201 ) wherein the convex section ( 101 , 201 ) is hemispherical ( 101 ), and wherein a wall thickness of the further wall ( 121 , 221 ) at at least one point is less than 90% of a wall thickness of the inner container ( 301 ) and more than 10% of said wall thickness of the inner container ( 301 ). 2. The cryogenic vessel ( 300 a , 300 b ) according to claim 1 , wherein a center point (M) of one or more of the plurality of openings ( 111 , 112 , 113 , 211 , 212 , 213 ) is arranged at a position deviating from a position of an apex (S) of the convex section ( 101 , 201 ) of the further wall. 3. The cryogenic vessel ( 300 a , 300 b ) according to claim 1 , wherein a center point (M) of one or more of the plurality of openings ( 111 , 112 , 113 , 211 , 212 , 213 ) is arranged between two planes intersecting the further wall ( 121 , 221 ) in the convex section ( 101 , 201 ) thereof and perpendicular to an axis (A-A) through an apex (S) of the convex section, or is arranged on a line which is an intersecting line between a sectional plane (E) and the further wall ( 121 , 221 ), the sectional plane (E) being perpendicular to an axis (A-A) through the apex (S) of the convex section and intersecting the further wall ( 121 , 221 ) in the convex section ( 101 , 201 ). 4. The cryogenic vessel ( 300 a , 300 b ) according to claim 1 , wherein one or more lines ( 311 , 312 , 313 ) leading out of the outer container ( 302 ) are each individually connected to one of the plurality of openings ( 111 , 112 , 113 , 211 , 212 , 213 ). 5. The cryogenic vessel ( 300 a , 300 b ) according to claim 1 , wherein the fluid distribution container ( 100 , 200 ) is arranged completely in the intermediate space ( 303 ), which can be evacuated, between the inner container ( 301 ) and the outer container ( 302 ). 6. The cryogenic vessel ( 300 a ) according to claim 1 , wherein the fluid distribution container ( 100 ) is connected to the inner container ( 301 ) at the convex section ( 101 ), or the fluid distribution container ( 100 , 200 ) has a cylindrical section ( 102 , 203 ) connected to the convex section ( 101 , 201 ). 7. The cryogenic vessel ( 300 a , 300 b ) according to claim 6 , wherein the further wall of the fluid distribution container ( 100 , 200 ), in a region connected to the inner container ( 301 ), has a wall thickness which is greater than in another region. 8. The cryogenic vessel ( 300 a , 300 b ) according to claim 1 , wherein said vessel has two of said fluid distribution containers ( 100 , 200 ), wherein a first fluid distribution container ( 100 , 200 ) is arranged at said first end wall of the inner container ( 301 ) and a second fluid distribution container ( 100 , 200 ) is arranged at the second end wall of the inner container ( 301 ), which is opposite the first end wall. 9. The cryogenic vessel ( 300 a , 300 b ) according to claim 1 , wherein the further wall ( 120 , 220 ) of the fluid distribution container ( 100 , 200 ) has at least three openings ( 111 , 112 , 113 , 211 , 212 , 213 ) for connecting a respective line ( 311 , 312 , 313 ). 10. The cryogenic vessel according to claim 9 , wherein the further wall ( 120 , 220 ) of the fluid distribution container ( 100 , 200 ) has four openings for connecting a respective line ( 311 , 312 , 313 ). 11. The cryogenic vessel ( 300 a , 300 b ) according to claim 1 , configured to store the fluid ( 304 ) at a pressure of up to 40 bar. 12. The cryogenic vessel ( 300 a , 300 b ) according to claim 1 , wherein said vessel has a plurality of said fluid distribution containers ( 100 , 200 ). 13. The cryogenic vessel according to claim 1 , wherein a wall thickness of the further wall of the fluid distribution container in the convex section is, at least at one point, smaller than the wall thickness of the walls of the inner container in regions in which no fluid distribution container is located. 14. The cryogenic vessel according to claim 1 , wherein a wall thickness of the further wall ( 121 , 221 ) at at least one point is less than 60% of a wall thickness of the wall of the inner container ( 301 ) and more than 10% of the wall thickness of the inner container. 15. The cryogenic vessel according to claim 1 , wherein the one or more fluid distribution containers has a greater wall thickness in a region thereof which is connected to the inner container than in another region of said one or more fluid distribution containers. 16. The cryogenic vessel ( 300 a , 300 b ) according to claim 1 , wherein said first end wall of said inner container ( 301 ) is a first upper end wall, and said second end wall of said inner container ( 301 ) is a second lower end wall. 17. A method for producing a cryogenic vessel ( 300 a , 300 b ) according to claim 1 , said method comprising: providing the inner container ( 301 ) with one or more of said through-holes wherein each through-hole is for connection of one or said one or more fluid distribution containers ( 100 , 200 ), and attaching by welding one or more fluid distribution container ( 100 , 200 ) to the one or more of said through-holes of said inner container. 18. A cryogenic vessel ( 300 a , 300 b ) comprising: an inner container ( 301 ) having a cylindrical side wall and two end walls, wherein one of said end walls is a first end wall and the other of said end walls is a second end wall, an outer container ( 302 ), an intermediate space ( 303 ), which can be evacuated, between the inner container ( 301 ) and the outer container ( 302 ), and a fluid distribution container ( 100 , 200 ) connected to the first end wall of the inner container or the second end wall of the inner cont