Self-propelled fastening unit and method for fastening sealing webs

The invention claimed is: 1. A method for fastening material webs located on a surface to fastening points arranged beneath the material webs, the fastening points being embodied as metallic head disks including a hot-melt adhesive layer directed toward the material web, the method comprising: providing a self-propelled fastening unit; (A) detecting a route marking affixed to the material webs or the surface by a first detector on the fastening unit and moving the fastening unit along the route marking; (B) detecting a head disk located below the material web by a second detector and determining a position of the head disk; (C) the self-propelled fastening unit approaching and remaining at an operating position in order to carry out a fastening process which includes: (D) positioning an induction heater of the self-propelled fastening unit and heating up the head disk for a period of time Th; (E) removing the induction heater and pressing the material web against the head disk by a cooling device of the fastening unit; (F) taking off the cooling device after a predetermined time Tk; and (G) the self-propelled fastening unit repeating steps (A)-(G), until an end of the route marking is reached. 2. The method according to claim 1 , wherein the route marking is affixed to the material web and the method further comprises the first detector on the fastening unit including an optical sensor for detecting the route marking. 3. The method according to claim 1 , wherein the route marking is affixed below the material web and the method further comprises the first detector on the fastening unit including an inductive, magnetic or capacitive sensor for detecting the route marking. 4. The method according to claim 1 , further comprising, the process steps (B)-(D) including: (B1) detecting the position of the metallic head disk relative to the fastening unit by a linear detector line which forms the second detector, which is arranged linearly, transversely to a driving direction, formed from discrete inductions sensors; (B2) calculating a driving distance Sr, which is still required, along the route marking until a first operating position of the fastening unit is reached; (C1) moving the fastening unit by the distance Sr; (C2) stopping the fastening unit; (D1) positioning a fine measuring device by information from step (B1) above the first operating position; (D2) increasing a precision of the determined first operating position using information from the fine measuring device and determining a second, more precise operating position; (D3) positioning the induction heater on the second, more precise operating position; and (D4) then heating up the head disk for the period of time Th. 5. A self-propelled fastening unit for carrying out the method according to claim 1 , comprising: a chassis; at least one electric motor on the chassis; wheels or caterpillar tracks attached to the chassis that are drivably connected to the at least one electric motor; an induction heater for heating up a metallic head disk supported by the chassis; a cooling device for pressing on and cooling a connection point between a material web and the metallic head disk supported by the chassis; a first detector supported on the chassis that is adapted to detect a route marking; a second detector supported on the chassis that is adapted to detect a position of a head disk; a navigation system adapted to control a movement of the fastening device; at least one computer processor configured to evaluate signals from the first and second detectors, to generate drive signals, and to control the fastening process using the induction heater and cooling device. 6. The self-propelled fastening unit according to claim 5 , further comprising an additional positioning system configured to provide a fine orientation of at least one of the induction heater or the cooling device, respectively, while the fastening unit remains in the operating position. 7. The self-propelled fastening unit according to claim 5 , wherein the positioning system provides for fine orientation in all three cartesian spatial axes. 8. The self-propelled fastening unit according to claim 5 , wherein the positioning system is adapted to press at least one of the induction heater or the cooling device, respectively, on a set point position with a defined contact pressure. 9. The self-propelled fastening unit according to claim 5 , wherein the cooling device is a passive cooling element. 10. The self-propelled fastening unit according to claim 5 , wherein the cooling device is a cooling element comprising a fluid-supported, gas-supported or electrically active cooling. 11. The self-propelled fastening unit according to claim 5 , further comprising a third detector or set of detectors affixed to the cooling device, which are connected in a feedback loop with the positioning system and act as a fine measuring device to allow a fine positioning. 12. The self-propelled fastening unit according to claim 5 , wherein the induction heater and the cooling device are installed in a rotatable revolver carrier, which allows positioning of the induction heater or the cooling device above a same setpoint position on the surface in an alternating manner by a rotation of the rotatable revolver carrier, without movement of the fastening unit itself or the positioning system. 13. The self-propelled fastening unit according to claim 5 , wherein the rotatable revolver carrier has at least one further position adapted to receive a marking device, of a measuring platform or a quality testing device. 14. The self-propelled fastening unit according to claim 5 , further comprising a third detector or set of detectors arranged around the induction heater.