Wound heat exchanger, method for producing a wound heat exchanger and method for exchanging heat between a first fluid and a second fluid

The invention claimed is: 1. A wound heat exchanger ( 1 ) comprising: a core tube ( 21 ) extending along a longitudinal axis (L) in an axial direction (a); a tube bundle ( 2 ) having a plurality of tubes ( 20 ) for conducting a first fluid, wherein the tubes ( 20 ) are wound about the core tube ( 21 ) in a plurality of windings ( 23 ), and a plurality of webs ( 6 ) extending in the axial direction (a), wherein the webs are provided as spacers between adjacent tube layers ( 22 ) in the radial direction such that the webs ( 6 ) each form a distance in the radial direction (r) between two respective adjacent tube layers ( 22 ), wherein the tubes ( 20 ) are arranged in a radial direction (r) perpendicular to the axial direction (a) in a plurality of tube layers ( 22 ), wherein the core tube supports the load of the tube bundle, wherein, in at least a section of the tube bundle ( 2 ), tube layers ( 22 ) adjacent to each other in the radial direction (r) have different radial distances (D) from one another in a cross-sectional plane perpendicular to the longitudinal axis (L), wherein the radial distances (D) of the adjacent tube layers ( 22 ) increase monotonically in the radial direction (r), and wherein (a) at least two of said plurality of webs ( 6 ) have different thicknesses (d) in the radial direction (r), and/or (b) the thickness (d) of at least one of the webs ( 6 ) varies along the axial direction (a) such that adjacent windings ( 23 ) of at least one of said plurality of tube layers ( 22 ) are spaced different distance in the radial direction (r) from the longitudinal axis. 2. The wound heat exchanger according to claim 1 , wherein one or more windings ( 23 ) of at least one of said plurality of tube layers ( 22 ) have different radial distances (D) from the longitudinal axis (L) in the radial direction (r) than other windings ( 23 ) of said at least one of said plurality of tube layer ( 22 ). 3. The wound heat exchanger according to claim 2 , wherein, in at least in a section of the tube bundle ( 2 ), the radial distances (D) of the windings ( 23 ) of said tube layer ( 22 ) from the longitudinal axis (L) increase monotonically in the axial direction (a). 4. The wound heat exchanger ( 1 ) according to claim 1 , wherein the tube bundle ( 2 ) has a first section ( 31 ) and a second section ( 32 ), adjacent to the first section ( 31 ) in the axial direction (a), wherein adjacent windings ( 23 ) of at least one of said plurality of tube layers ( 22 ) in the first section ( 31 ) have an axial distance (T) which differs from an axial distance (T) of adjacent windings ( 23 ) of at least one of said plurality of tube layers ( 22 ) in the second section ( 32 ). 5. The wound heat exchanger ( 1 ) according to claim 4 , wherein said at least one of said plurality of tube layers ( 22 ) has in the first section ( 31 ) a first number (n1) of windings ( 23 ), a first height (h1) extending in the axial direction (a) and a first packing density (p1), wherein the first packing density (p1) is equal to the quotient (n1/h1) of the first number (n1) and the first height (h1), and wherein said at least one of said plurality of tube layers ( 22 ) has in the second section ( 32 ) a second number (n2) of windings ( 23 ), a second height (h2) extending in the axial direction (a) and a second packing density (p2), wherein the second packing density (p2) is equal to the quotient (n2/h2) of the second number (n2) and the second height (h2), and wherein the first packing density (p1) differs from the second packing density (p2). 6. The wound heat exchanger ( 1 ) according to claim 4 , wherein the first section ( 31 ) is formed by a central section ( 35 ) of the tube bundle ( 2 ), wherein the second section ( 32 ) is formed by an end section ( 36 ) of the tube bundle ( 2 ). 7. The wound heat exchanger ( 1 ) according to claim 1 , wherein the tube bundle ( 2 ) has an inner region ( 41 ) and an outer region ( 42 ) which surrounds the inner region ( 41 ) in a cross-sectional plane perpendicular to the longitudinal axis (L), wherein the tube layers ( 22 ) of the inner region ( 41 ) adjacent to one another in the radial direction (r) have radial distances (D) from one another in the cross-sectional plane that differ from the radial distances (D) in the cross-sectional plane between the tube layers ( 22 ) of the outer region ( 42 ) adjacent to one another in the radial direction (r). 8. The wound heat exchanger ( 1 ) according to claim 1 , wherein at least two of said plurality of webs ( 6 ) have different thicknesses (d) in the radial direction (r). 9. The wound heat exchanger ( 1 ) according to claim 1 , wherein the thickness (d) of at least one of the webs ( 6 ) varies along the axial direction (r a) such that adjacent windings ( 23 ) of at least one of said plurality of tube layers ( 22 ) are spaced at different distances in the radial direction (r) from the longitudinal axis. 10. The wound heat exchanger ( 1 ) according to claim 1 , wherein (a) at least two of said plurality of webs ( 6 ) have different thicknesses (d) in the radial direction (r), and (b) the thickness (d) of at least one of the webs ( 6 ) varies along the axial direction (a) such that adjacent windings ( 23 ) of at least one of said plurality of tube layers ( 22 ) are spaced different distance in the radial direction (r) from the longitudinal axis. 11. A method for producing a wound heat exchanger ( 1 ) according to claim 1 , comprising winding the tubes ( 20 ) around the core tube ( 21 ) in such a way that tube layers ( 22 ) adjacent to one another in the radial direction (r) have different radial distances (D) from one another in a cross-sectional plane perpendicular to the longitudinal axis (L), and the radial distances (D) of the adjacent tube layers ( 22 ) increase monotonically in the radial direction (r), in at least a section of the tube bundle ( 2 ), and providing the plurality of webs ( 6 ) so that they extend in the axial direction (a), and function as spacers between adjacent tube layers ( 22 ) in the radial direction of the webs ( 6 ), and the webs each form a distance in the radial direction (r) between two respective adjacent tube layers ( 22 ), and wherein (a) at least two of said plurality of webs ( 6 ) have different thicknesses (d) in the radial direction (r), and/or (b) the thickness (d) of at least one of the webs ( 6 ) varies along the axial direction (r) such that adjacent windings ( 23 ) of at least one of said plurality of tube layers ( 22 ) are spaced at different distances from the longitudinal axis. 12. A method for exchanging heat between the first fluid and a second fluid by means of a wound heat exchanger ( 1 ) according to claim 1 , comprising flowing the first fluid flows through the tubes ( 20 ) of the tube bundle ( 2 ), and flowing the second fluid is provided in a shell space (M) in which the tube bundle ( 2 ) of the heat exchanger ( 1 ) is arranged so that heat is exchanged between the first fluid and the second fluid. 13. The method for exchanging heat according to claim 12 , wherein in a first section ( 31 ) of the tube bundle ( 2 ) in which turbulence or a pressure loss of the second fluid provided in the shell space (M) influences the heat exchange between the first fluid and the second fluid, the adjacent windings ( 23 ) of at least one tube layer ( 22 ) have an axial distance (T) that differs from an axial distance (T) of the adjacent windings ( 23 ) of the respective tube layer ( 22 ) in a second section ( 32 ) of the tube bundle ( 2 ) adjacent to the first section ( 31 ) in the axial direction (a), wherein in the second section ( 32 ), the turbulence or pressure loss of the second flu