Laser tool having a hollow shaft drive and non-rotating lens; method for setting the focal position of the laser beams in a laser tool

What is claimed is: 1. A laser tool for the structuring of cylinder running surfaces, the laser tool comprising: a laser source that produces a laser beam that is passed through a lens tube located in a hollow shaft, the hollow shaft being rotatable by a hollow-shaft motor and the hollow shaft having a first end facing towards the laser source and a second end that opposes the first end and faces away from the laser source; a lens through which the laser beam is passed is attached to the lens tube; a spindle having a first end facing towards the laser source and a second end that opposes the first end and faces away from the laser source, the first end of the spindle being attached to the second end of the hollow shaft and the second end of the spindle having an optical device attached thereto, the optical device provided to deflect the laser beam onto a workpiece surface, a collimator that is movable in a direction parallel to the laser beam via a drive, the collimator having a cylindrical outer surface, and a sleeve, the sleeve having a first end facing towards the laser source and being attached to the collimator and the sleeve having a second end that opposes the first end and faces away from the laser source, wherein the second end of the sleeve is directly attached to and covers a part of an outer surface of the lens tube, wherein in a direction of a beam path of the laser beam, the collimator is located downstream of the laser source and upstream of the lens tube, and the second end of the sleeve is located downstream of the laser source and upstream of both the first end of the hollow shaft and the first end of the spindle, wherein the hollow shaft is rotatable independently of the lens, and wherein due to the attachment of the sleeve to both the collimator and the lens tube, the collimator, the sleeve and the lens tube are simultaneously movable in a direction parallel to the laser beam. 2. The laser tool according to claim 1 , wherein the drive is an electric drive, a servomotor, a hydraulic drive, or a pneumatic drive. 3. The laser tool according to claim 1 , wherein the collimator is connected to the lens tube. 4. The laser tool according to claim 1 , wherein the drive has a sensor. 5. The laser tool according to claim 4 , wherein the movement of the collimator is based on a signal from the sensor. 6. The laser tool according to claim 1 , wherein the movement of the collimator is based on at least one predefinable parameter. 7. The laser tool according to claim 6 , wherein the at least one predefinable parameter is a feed of the collimator toward the optical device or a feed of the collimator toward the laser source. 8. The laser tool according to claim 1 , wherein the laser tool has a lower stop and an upper stop each having a surface that delimit a length of a movement path of the collimator in the direction parallel to the laser beam. 9. The laser tool according to claim 8 , wherein the sleeve has a radially extending protrusion that is positioned between the surface of the lower stop and the surface of the upper stop, such that depending upon an upward or downward movement of the sleeve in the direction parallel to the laser beam, the radially extending protrusion will abut either the surface of the lower stop or the surface of the upper stop so as to delimit the length of the movement path of the collimator in the direction parallel to the laser beam. 10. The laser tool according to claim 1 , wherein the optical device is a reflecting prism or a mirror. 11. A method for setting a focal position of a laser beam in a laser tool comprising a laser source for producing the laser beam and a collimator for producing a parallel course of the laser beam from the laser source, the collimator having a cylindrical outer surface and the laser beam passing through a lens attached to a lens tube, the method comprising: arranging the lens inside a rotatable spindle, the rotatable spindle having a first end that faces towards the laser source and a second end that opposes the first end and faces away from the laser source; deflecting, via an optical device, the laser beam onto a material surface, the optical device being attached to the second end of the rotatable spindle that faces away from the laser source; moving the collimator in a direction parallel to the laser beam via a drive; predefining at least one parameter via a controller that controls a motion of the collimator, wherein the collimator is moved in a direction toward the optical device or opposite to the direction toward the optical device as a function of the at least one parameter, wherein a hollow shaft is provided and has a first end facing towards the laser source and a second end that opposes the first end and faces away from the laser source, the lens tube being located in the hollow shaft, the hollow shaft being rotatable and the second end of the hollow shaft being attached to the first end of the rotatable spindle, wherein a sleeve is provided, the sleeve having a first end facing towards the laser source and being attached to the collimator and the sleeve having a second end that opposes the first end and faces away from the laser source, wherein the second end of the sleeve is directly attached to and covers a part of an outer surface of the lens tube, wherein due to the attachment of the sleeve to both the collimator and the lens tube, the collimator, the sleeve and the lens tube are simultaneously movable in the direction parallel to the laser beam, and wherein in a direction of a beam path of the laser beam, the collimator is located downstream of the laser source and upstream of the lens tube, and the second end of the sleeve is located downstream of the laser source and upstream of both the first end of the hollow shaft and the first end of the spindle. 12. The method according to claim 11 , wherein the at least one parameter is a feed of the collimator toward the optical device or a feed of the collimator toward the laser source. 13. The method according to claim 11 , wherein the lens is arranged in a fixed position in the lens tube and wherein the lens tube is attached to the collimator. 14. The method according to claim 11 , wherein the movement of the collimator is based on a signal from a sensor. 15. The method according to claim 11 , wherein the laser tool has a lower stop and an upper stop each having a surface that delimit a length of a movement path of the collimator in the direction parallel to the laser beam, and wherein the sleeve has a radially extending protrusion that is positioned between the surface of the lower stop and the surface of the upper stop, such that depending upon an upward or downward movement of the sleeve in the direction parallel to the laser beam, the radially extending protrusion will abut either the surface of the lower stop or the surface of the upper stop so as to delimit the length of the movement path of the collimator in the direction parallel to the laser beam.