Method and tool for roughening an inner surface of a cylindrical bore

The invention claimed is: 1. A method to roughen an inner surface ( 8 ) of a cylindrical bore ( 9 ), comprising: introducing into the cylindrical bore or leading through this, without removal of material, a rotating tool ( 1 ) having a radial cutting head ( 7 ) having at least one cutting edge of the radial cutting head ( 7 ), positioning the tool ( 1 ) in the radial direction, and removing material by lifting off shavings ( 12 ) via the rotating tool ( 1 ) while driving the tool ( 1 ) out of the cylindrical bore in its feed direction (V), said tool ( 1 ) being moved in a translational manner in the axial direction of the cylindrical bore ( 9 ) and said shaving ( 12 ) being broken off via the radial cutting head ( 7 ), in order to generate the roughened surface, wherein a finishing processing of the inner surface ( 8 ) of the cylindrical bore ( 9 ) is carried out by a further radial head ( 16 ), positioned in the feed direction (V) in the work process before the radial cutting head ( 7 ) for roughening the inner surface ( 8 ), and wherein a flushing medium for flushing and/or cooling is supplied with a directional component, against the feed direction (V), in the region of the radial cutting head ( 7 ) for roughening the inner surface ( 8 ), and a flushing medium for flushing and/or cooling is supplied with a directional component, in the feed direction (V), in the region of the further radial cutting head ( 16 ). 2. The method according to claim 1 , wherein a material removal is carried out exclusively when driving the tool ( 1 ) out of the cylindrical bore ( 9 ). 3. The method according to claim 1 , wherein the region of the radial cutting head ( 7 ) is provided with a flushing medium for flushing and/or cooling. 4. The method according to claim 3 , wherein an oil-free and at least extensively dry gas is used as the flushing medium. 5. The method according to claim 4 , wherein the oil-free and at least extensively dry gas is compressed air. 6. The method according to claim 1 , herein potentially remaining protrusions of the broken-off shavings ( 12 ) are trimmed by a further radial cutting head ( 19 ) in the same work process, in the feed direction (V), after the radial cutting head ( 7 ) for roughening the inner surface ( 8 ). 7. The method according to claim 1 , wherein it serves as preparation for a thermal coating. 8. The method according to claim 1 , wherein it is used for roughening the inner surface of a cylindrical bore ( 9 ) made from a non-iron metal. 9. The method according to claim 1 , wherein the inner surface ( 8 ) of a cylindrical bore ( 9 ) is a working surface in a cylindrical bore or cylinder liner of a combustion engine. 10. The method according to claim 1 , wherein it serves as preparation for a thermal coating by means of electric arc wire spraying. 11. A tool ( 1 ) for roughening an inner surface ( 8 ) of a cylindrical bore ( 9 ), having a radial cutting head ( 7 ), for lifting off a shaving ( 12 ) and for breaking off the shaving ( 12 ) in order to generate a roughened surface, a tool receiver ( 2 ), designed to interact with a machining tool, and a tool tip ( 6 ) opposite the tool receiver ( 2 ) in the axial direction, wherein a further radial cutting head ( 16 ) is arranged for finishing the inner surface ( 8 ) of the cylindrical bore ( 9 ) in the axial direction between the tool receiver ( 2 ) and the radial cutting head ( 7 ) for roughening the inner surface ( 8 ) of the cylindrical bore ( 9 ), and wherein at least one flushing medium ( 14 ) is provided with a respective flushing medium outlet ( 15 , 17 ) corresponding to the radial cutting head ( 7 ) and the further radial cutting head ( 16 ), wherein the flushing medium outlet ( 15 ), which corresponds to the radial cutting head ( 7 ) for roughening the inner surface ( 8 ) of the cylindrical bore ( 9 ), is formed with a directional component in the direction of the tool tip ( 6 ), and the flushing medium outlet ( 17 ) which corresponds to the radial cutting head ( 16 ) for finishing the inner surface ( 8 ) of the cylindrical bore ( 9 ) is formed with a directional component in the direction of the tool receiver ( 2 ). 12. The tool ( 1 ) according to claim 11 , wherein the two radial cutting heads ( 7 , 16 ) are arranged to be offset to one another in the peripheral direction at an angle (α) of up to 120°. 13. The tool ( 1 ) according to claim 11 , having its receiver on a horizontal spindle of a machining tool having at least one horizontal spindle. 14. The tool ( 1 ) according to claim 11 , wherein the two radial cutting heads ( 7 , 16 ) are arranged to be offset to one another in the peripheral direction at an angle (α) of up to 90°. 15. A tool ( 1 ) for roughening an inner surface ( 8 ) of a cylindrical bore ( 9 ), having a radial cutting head ( 7 ) for lifting off a shaving ( 12 ) and for breaking off the shaving ( 12 ), in order to generate a roughened surface, a tool receiver ( 2 ) designed to interact with a tool machine, and having a tool tip ( 6 ) lying opposite the tool receiver ( 2 ) in the axial direction, wherein a further radial cutting head ( 16 ) for finishing the inner surface ( 8 ) of the cylindrical bore ( 9 ) is arranged in the axial direction between the tool receiver ( 2 ) and the radial cutting head ( 7 ) for roughening the inner surface ( 8 ) of the cylindrical bore ( 9 ), wherein at least one flushing medium line ( 14 ) is provided with a respective flushing medium outlet ( 15 , 17 ) corresponding to the radial cutting head ( 7 ) and the further radial cutting head ( 16 ), wherein a third radial cutting head ( 19 ) for trimming potentially remaining protrusions of shavings ( 12 ) is provided which is arranged between the radial cutting head ( 7 ) for roughening the inner surface ( 8 ) of the cylindrical bore ( 9 ) and the tool tip ( 6 ) in the axial direction, and which is arranged to be offset to each of the two other radial cutting heads ( 7 , 16 ) in the peripheral direction, wherein the third radial cutting head ( 19 ) is formed without a flushing medium supply. 16. The tool ( 1 ) according to claim 15 , wherein all three radial cutting heads ( 7 , 16 , 19 ) are arranged to be offset to one another in the peripheral direction at an angle (α+β) of at most between the radial cutting heads ( 7 , 16 , 19 ) of 120°. 17. The tool ( 1 ) according to claim 15 , wherein the flushing medium outlet ( 15 ), which corresponds to the radial cutting head ( 7 ) for roughening the inner surface ( 8 ) of the cylindrical bore ( 9 ), is formed with a directional component in the direction of the tool tip ( 6 ), and the flushing medium outlet ( 17 ), which corresponds to the radial cutting head ( 16 ) for finishing the inner surface ( 8 ) of the cylindrical bore ( 9 ), is formed with a directional component in the direction of the tool receiver ( 2 ). 18. The tool ( 1 ) according to claim 15 , wherein all three radial cutting heads ( 7 , 16 , 19 ) are arranged to be offset to one another in the peripheral direction at an angle (α+β) between the two outer-lying radial cutting heads ( 7 , 16 , 19 ) of up to 90°.