Stud welding process and stud welding device for welding a stud to a workpiece

The invention claimed is: 1. A stud welding method for welding a stud to a workpiece ( 2 ), wherein with an aid of a pulsed welding current (I s ) an arc (LB) is generated between a surface of the stud facing the workpiece and the workpiece, and the arc (LB) is deflected with an aid of a magnetic field generated by a coil through which a current (I A ) flows, the method comprising controlling the current (I A ) synchronously and in opposition to the pulsed welding current (I s ) through the coil for generating the magnetic field for deflecting the arc (LB), by applying a current (I A ) to the coil whenever the pulsed welding current (Is) is minimal, and the coil is switched off or the current (I A ) through the coil is reduced to a minimum when the welding current (I s ) is maximum. 2. The stud welding method according to claim 1 , comprising pulsing the pulsed welding current (I s ) with a pulse frequency (f p ) between 10 Hz and 1000 Hz. 3. The method of claim 2 , comprising pulsing the pulsed welding current (I s ) between 50 Hz and 150 Hz. 4. The stud welding method according to claim 1 , comprising changing the pulsed welding current (I s ) between an upper threshold value (I s,o ) and a lower threshold value (I s,u ) or changing welding power (P s ) between an upper value (P s,o ) and a lower value (P s,u ). 5. The stud welding method according to claim 1 , wherein the duty cycle of the pulsed welding current (I s ) is between 10% and 90%. 6. The method of claim 5 , wherein the duty cycle of the pulsed welding circuit (I s ) is 50%. 7. The stud welding method according to claim 1 , comprising regulating the pulsed welding current (I s ) for a constant welding power (P s ). 8. The method of claim 7 , comprising regulating the pulsed welding circuit (I s ) for a constant welding power (P s ), between 2 kW and 10 kW. 9. The stud welding method according to claim 1 , comprising applying the current (I A ) through the coil with a time offset (Δt) with respect to the welding current (I s ). 10. The stud welding method according to claim 1 , comprising switching off the current (I A ) through the coil for a predetermined time span (t a ) after starting the pulsed welding current (I s ) and/or for a predetermined time span (t e ) before ending the welding pulsed current (I s ). 11. The stud welding method according to claim 1 , comprising pulsing the current (I A ) through the coil with a DC offset (I A, DC ). 12. The stud welding method according to claim 1 , comprising changing a rate of rise (t r ) of the current (I A ) through the coil. 13. The stud welding method according to claim 1 , comprising inserting a pre-current phase (t v ), before starting the method. 14. The method of claim 13 , comprising inserting a pre-current phase between 1 ms and 100 ms before starting the method. 15. The stud welding method according to claim 1 , comprising determining a maximum pulse frequency (f P, max ) of the welding current (I s ) from a time profile of the current (I A ) through the coil. 16. A stud welding device for welding a stud to a workpiece, having a welding current source for providing a pulsed welding current (I s ) for generating an arc (LB) between a surface of the stud facing the workpiece and the workpiece, and having a coil for generating a magnetic field for deflecting the arc (LB), comprising a control device for controlling the current (I A ) provided by the coil synchronously and in opposition to the pulsed welding current (I s ), so that the coil can always be supplied with a current (I A ) when the pulsed welding current (Is) is minimal, and so the coil is switched off or the current (I A ) through the coil is reduced to a minimum when the pulsed welding current (I s ) is maximum. 17. The stud welding device according to claim 16 , characterized in that wherein the welding power source is designed to regulate the pulsed welding current (I s ) for a constant welding power (P s ). 18. The stud welding device of claim 17 , wherein the welding power source is designed to regulate pulsed welding current (I s ) for a constant welding power (P s ) between 2 kW and 10 kW. 19. The stud welding device according to claim 16 , wherein a stud holder for receiving the stud to be connected to the workpiece and a lifting device for lifting the stud from the workpiece is provided against a force of a spring. 20. The stud welding device according to claim 19 , wherein the control device for determining a maximum pulse frequency (f P,max ) of the welding current (I s ) from the time profile of the current (I A ) through the coil is formed.