Method for the production of a hollow fiber module, and hollow fiber module

The invention claimed is: 1. A method for producing a hollow fiber module ( 1 , 1 ′), comprising: inserting a hollow fiber bundle ( 3 ) into a module housing ( 2 , 2 ′) that has an end closed by a cap ( 17 ) that defines a removable sprue cover ( 18 , 18 ′, 18 ″); filling a fluid first component ( 27 ) via a first inflow ( 26 ) and into an intermediate space arranged between the hollow fiber ends ( 6 , 7 ) and the cap ( 17 ) to form a spacer, the fluid first component ( 27 ) being formed from a material that can assume a solid state and being filled so that the hollow fiber ends ( 6 , 7 ) project into the first component ( 27 ); introducing a fluid curable second component ( 4 ) upstream of the first component ( 27 ), directed away from the cap ( 17 ), via a second inflow ( 28 ); curing the second component ( 4 ) to form a sealing layer ( 9 ) that embeds the hollow fiber bundle ( 3 ) and seals the hollow fiber bundle ( 3 ) with respect to an adjacent module housing wall ( 29 , 29 ′); applying a rotary pulling movement to the cap ( 17 ) and thereby severing the hollow fibers ( 5 ) in a boundary layer formed by the first component ( 27 ) and the second component ( 4 ); and removing from the module housing ( 2 , 2 ′) an assembly that includes: the cap ( 17 ), the first component ( 27 ) that has been solidified to form a plug ( 30 ), and the hollow fiber ends ( 6 ) embedded in the plug ( 30 ) and projecting out of the end face ( 10 ) of the layer ( 9 ) formed by the second component ( 4 ). 2. The method of claim 1 , further comprising centrifuging the module housing ( 2 , 2 ′) in a centrifuge between the second filling of the fluid first component ( 27 ) and the introducing of the fluid curable second component ( 4 ). 3. The method of claim 2 , further comprising centrifuging the module housing ( 2 , 2 ′) again after solidification of the first component ( 27 ) and before the curing of the second component ( 4 ). 4. The method of claim 1 , further comprising providing the hollow fiber bundle ( 3 ) with a supporting fabric before inserting the hollow fiber bundle ( 3 ) into the module housing ( 2 , 2 ′). 5. The method of claim 1 , further comprising cutting the hollow fiber bundle ( 3 ) to a prespecified length before inserting the hollow fiber bundle ( 3 ) into the module housing ( 2 , 2 ′). 6. The method of claim 1 , wherein silicone is filled into the module housing ( 2 , 2 ′) as the first fluid component ( 27 ), and polyurethane is filled into the module housing ( 2 , 2 ′) as the second fluid component ( 4 ). 7. A hollow fiber module ( 1 , 1 ′), comprising: a module housing ( 2 , 2 ′), a hollow fiber bundle ( 3 ) formed from hollow fibers ( 5 ) and arranged in the module housing ( 2 , 2 ′), at least one sealing layer ( 9 ) made of a cured second component ( 4 ) disposed on an end of the hollow fiber bundle ( 3 ) and extending transverse to a longitudinal direction of the hollow fiber bundle ( 3 ), wherein the sealing layer ( 9 ) embeds the hollow fiber bundle ( 3 ) and seals the hollow fiber bundle ( 3 ) with respect to an adjacent module housing wall ( 29 , 29 ′), wherein the hollow fibers have ends ( 7 ) that form a common plane with an end face ( 10 ) of the sealing layer ( 9 ), the hollow fibers ( 5 ) have lumens ( 11 ) that are freely accessible at the common plane defined by the ends ( 7 ) of the hollow fibers ( 5 ) and the end face ( 10 ) of the sealing layer ( 9 ), the end face ( 10 ) of the sealing layer ( 9 ) is recessed by a prespecifiable distance ( 14 ) with respect to an end face ( 12 ) of an adjacent free end ( 13 , 13 ′) of the module housing ( 2 , 2 ′), and the module housing ( 2 ′) is a flexible tube. 8. The hollow fiber module of claim 7 , wherein the free end ( 13 ′) of the module housing ( 2 ′) is configured to be directly connected to a tube connector ( 16 ). 9. A cap ( 17 ) defining a sprue cover ( 18 , 18 ′, 18 ″) for producing a hollow fiber module ( 1 , 1 ′), the hollow fiber module ( 1 , 1 ′), including: a module housing ( 2 , 2 ′); a hollow fiber bundle ( 3 ) formed from hollow fibers ( 5 ) and being arranged in the module housing ( 2 , 2 ′); at least one sealing layer ( 9 ) made of a cured second component ( 4 ) being disposed on an end of the hollow fiber bundle ( 3 ) and extending transverse to a longitudinal direction of the hollow fiber bundle ( 3 ), the sealing layer ( 9 ) embedding the hollow fiber bundle ( 3 ) and sealing the hollow fiber bundle ( 3 ) with respect to an adjacent module housing wall ( 29 , 29 ′), the hollow fibers ( 5 ) having ends ( 7 ) that form a common plane with an end face ( 10 ) of the sealing layer ( 9 ), the hollow fibers ( 5 ) having lumens ( 11 ) that are freely accessible at the common plane defined by the ends ( 7 ) of the hollow fibers ( 5 ) and the end face ( 10 ) of the sealing layer ( 9 ), the end face ( 10 ) of the sealing layer ( 9 ) being recessed by a prespecifiable distance ( 14 ) with respect to an end face ( 12 ) of an adjacent free end ( 13 , 13 ′) of the module housing ( 2 , 2 ′), wherein the sprue cover ( 18 , 18 ′, 18 ″) comprises: a circumferential collar ( 19 , 19 ′, 19 ″) that can be inserted into the free end ( 13 , 13 ′) of the module housing ( 2 2 ′), and when inserted receives the free hollow fiber ends ( 6 ) of the hollow fiber bundle ( 3 ), an end of the collar ( 19 , 19 ′, 19 ″) that faces away from the hollow fiber bundle ( 3 ) is closed by an end wall ( 25 ), and the sprue cover ( 18 , 18 ′, 18 ″) has a first inflow ( 26 ) for a first fluid component ( 27 ). 10. The cap of claim 9 , wherein the circumferential collar ( 19 , 19 ′, 19 ″) has a profiling ( 21 ) or resistive elements ( 22 , 23 ) on its inner surface ( 20 , 20 ′, 20 ″) facing the hollow fiber bundle ( 3 ).