Method for connecting tubes of a tube bundle heat exchanger to a tubesheet of the tube bundle heat exchanger

1 . A method for connecting tubes ( 121 , 125 ) of a tube bundle heat exchanger ( 100 ) to a tubesheet ( 130 ) of the tube bundle heat exchanger ( 100 ), wherein the tubes ( 121 , 125 ) are connected to the tubesheet ( 130 ) in a material-bonding manner by means of laser welding, in the course of which a laser beam ( 211 ) is generated and focused on a location to be welded in a connecting region ( 250 ) between the tube ( 125 ) and the tubesheet ( 130 ), wherein the laser beam ( 211 ) is moved in such a way that it produces a first movement over the connecting region ( 250 ) and a second movement superposed on the first movement, which is different from the first movement, and wherein melt bath dynamics are influenced by the second movement in a targeted manner and/or a vapor capillary that forms is modified in a targeted manner. 2 . The method as claimed in claim 1 , wherein the vapor capillary that is formed is modified into an elongate or oval form. 3 . The method as claimed in claim 1 , wherein a main direction of extent ( 251 ) of a weld seam ( 260 ) is predetermined by the first movement and/or wherein a width ( 302 ) of the weld seam ( 260 ) is predetermined by the second movement. 4 . The method as claimed in claim 1 , wherein the first movement and/or the second movement are produced by movement of individual optical elements ( 223 , 226 ) in a beam path of the laser beam ( 211 ). 5 . The method as claimed in claim 4 , wherein at least one mirror ( 223 , 226 ) in the beam path of the laser beam ( 211 ) is rotated. 6 . The method as claimed in claim 1 , wherein the first movement and/or the second movement are produced by a device for laser welding ( 200 ) or part of a device for laser welding ( 200 ) being moved. 7 . The method as claimed in claim 6 , wherein a laser head ( 220 ) of the device for laser welding ( 200 ) is moved. 8 . The method as claimed in claim 1 , wherein the first movement is a circular movement, the radius ( 301 ) of which corresponds substantially or completely to the radius of a tube ( 125 ). 9 . The method as claimed in claim 1 , wherein the second movement is a circular and/or elliptical and/or translational movement alternating in its direction. 10 . The method as claimed in claim 9 , wherein the second movement is performed with a transversal deflection of 0.15-0.25 mm, in particular 0.23 mm, and/or with a longitudinal deflection of 0.15-0.25 mm, in particular 0.23 mm. 11 . The method as claimed in claim 9 , wherein the second movement is performed with a frequency of 3000-4500 Hz, in particular 3500 Hz. 12 . The method as claimed in claim 1 , wherein the tubes ( 121 ) and/or the tubesheet ( 130 ) are respectively produced from steel or a nonferrous metal and/or are respectively produced from aluminum or an aluminum alloy. 13 . The method as claimed in claim 1 , wherein the tubes ( 121 ) and the tubesheet ( 130 ) of a straight-tube heat exchanger, of a U-tube heat exchanger or of a helically coiled tube bundle heat exchanger ( 100 ) are connected to one another. 14 . The method as claimed in claim 1 , wherein the laser beam ( 211 ) is generated by a CO 2 laser, CO laser, solid-state laser, Nd:YAG laser ( 210 ), Nd-glass laser, erbium-YAG laser, disk laser, fiber laser and/or diode laser. 15 . A device ( 200 ) for laser welding, which is designed for connecting tubes ( 121 , 125 ) of a tube bundle heat exchanger ( 100 ) to a tubesheet ( 130 ) of the tube bundle heat exchanger ( 100 ), wherein the device ( 200 ) has a laser ( 210 ) for generating a laser beam ( 211 ), a first control unit ( 230 ) for activating a first traversing mechanism ( 231 ) for producing a first movement of the laser beam ( 211 ) and a second control unit ( 240 ) for activating a second traversing mechanism for producing a second movement of the laser beam ( 211 ), the first and second control units ( 230 , 240 ) being designed to carry out a method as claimed in claim 1 .