Workpiece processing machine and method for operating the workpiece processing machine

The invention claimed is: 1. A method for operation of a workpiece processing machine ( 1 ), comprising performing an automatically controlled adjustment movement of at least one stop finger ( 17 ) of a stop device ( 16 ) along at least one driven adjustment axis ( 22 ) into a stop position ( 19 ) provided for positioning of a workpiece ( 4 ), placing the workpiece ( 4 ) against a contact surface ( 21 ) of the at least one stop finger ( 17 ) to position the workpiece, during the automatically controlled adjustment movement of the at least one stop finger ( 17 ), using an illuminating device ( 36 ) motion-coupled to the stop finger ( 17 ) along the at least one driven adjustment axis ( 22 ) to radiate a first light beam ( 38 ) into an area ahead of the at least one stop finger ( 17 ) in an adjustment direction ( 39 , 45 ), using at least one stationary optical detection device ( 37 ) to monitor a monitoring area ( 41 ) for adjustment movements of the at least one stop finger ( 17 ), initiating an automatically controlled safety measure when a first light image ( 43 ) projected by the first light beam ( 38 ) onto an object surface ( 42 ) is detected. 2. The method according to claim 1 , wherein the illuminating device ( 36 ) is adjusted with the stop finger ( 17 ) in a motion-coupled manner at least along two adjustment axes ( 22 ). 3. The method according to claim 2 , wherein the first light beam ( 38 ) is directed into the area ahead of the stop finger ( 17 ) in the adjustment direction ( 39 , 45 ) by an optical mirror surface ( 40 ). 4. The method according to claim 1 , wherein the first light beam ( 38 ) is radiated into the area ahead of the stop finger ( 17 ) as an at least largely parallel light beam ( 38 ) whose beam path ( 48 ) forms a first, planar light surface ( 49 ). 5. The method according to claim 4 , wherein the first light beam ( 38 ) is radiated into the area ahead of the stop finger ( 17 ) in the adjustment direction ( 39 ) such that a light beam transverse axis ( 51 ) of the first light surface ( 49 ) extending transversely to the beam path ( 48 ) is at least largely parallel to a contact surface ( 21 ) of the stop finger ( 17 ). 6. The method according to claim 5 , wherein the first light beam ( 38 ) is radiated into the area ahead of the stop finger ( 17 ) in the adjustment direction ( 39 ) such that a transverse extent ( 53 ) of the first light surface ( 49 ) parallel to the light beam transverse axis ( 51 ) in the area of the stop finger ( 17 ) is bigger than a width ( 55 ) of the stop finger ( 17 ) extending between two side edges ( 54 ). 7. The method according to claim 4 , wherein the illuminating device ( 36 ) comprises a line laser ( 52 ). 8. The method according to claim 1 , wherein the first light beam ( 38 ) is radiated into the area ahead of the stop finger ( 17 ) in the adjustment direction ( 39 ) at least at a minimum distance ( 56 ) from a limiting edge ( 57 ) of the stop finger ( 17 ) that leads in the adjustment direction ( 39 ). 9. The method according to claim 1 , wherein the illuminating device ( 36 ) is not adjusted in the direction of a vertical adjustment axis ( 22 ) that is perpendicular to a base surface ( 5 ). 10. The method according to claim 1 , wherein a second light image ( 58 ) is projected by the illuminating device ( 36 ) that is motion-coupled to the stop finger ( 17 ) onto a surface ( 59 ) of the stop finger ( 17 ) that is detectable by means of the at least one optical detection device ( 37 ). 11. The method according to claim 10 , wherein the second light image ( 58 ) has a linear edge parallel to a contact surface ( 21 ) of the stop finger ( 17 ). 12. The method according to claim 11 , wherein a third light image ( 61 ) having a linear edge that is parallel to the linear edge of the second light image is projected onto the surface ( 59 ) of the stop finger ( 17 ) at a distance from the second strip of light ( 60 ) by the illuminating device ( 36 ) that is motion-coupled to the stop finger ( 17 ). 13. The method according to claim 12 , wherein a position of the stop finger ( 17 ) is determined computationally from the visually detected location of the second light image and/or the third light image ( 61 ) in the monitoring area ( 41 ). 14. The method according to claim 1 , wherein the monitoring area ( 41 ) is monitored by means of at least one stationary imaging camera ( 46 ). 15. The method according to claim 14 , wherein a distance between a limiting edge ( 57 ) of the stop finger ( 17 ) on a workpiece feed side and the camera ( 46 ) is determined computationally from a visually detected, apparent perpendicular distance ( 66 ) between the second strip of light ( 60 ) and the third strip of light ( 61 ). 16. The method according to claim 1 , wherein the first light beam ( 38 ) is immediately activated in the event of an automatically controlled start of an adjustment movement of the stop finger ( 17 ) into a stop position ( 19 ). 17. The method according to claim 1 , wherein the first light beam ( 38 ) is immediately deactivated upon reaching a selected stop position ( 19 ). 18. The method according to claim 1 , wherein, during an adjustment movement into a selected stop position ( 19 ), the first light beam ( 38 ) is deactivated during the adjustment movement, at a distance from the stop position ( 19 ) until the stop position ( 19 ) is reached. 19. The method according to claim 1 , wherein the first light beam ( 38 ) is deactivated when the stop finger ( 17 ) is at a standstill. 20. The method according to claim 1 , wherein an immediate retraction movement of the stop finger ( 17 ) is triggered as an automatically controlled safety measure. 21. The method according claim 1 , wherein no automatically controlled safety measure is triggered when the stop finger ( 17 ) is at a standstill. 22. The method according to claim 1 , wherein the first light beam ( 38 ) is radiated into the area ahead of the stop finger ( 17 ) during an adjustment movement of the stop finger ( 17 ) into a stop position ( 19 ) performed along a horizontal adjustment axis ( 22 ) in the direction of a workpiece feed side ( 20 ). 23. A workpiece processing machine ( 1 ), comprising: an automatically controlled stop device ( 16 ), comprising at least one automatically controlled stop finger ( 17 ) that is displaceable along at least one driven adjustment axis ( 22 ) and has at least one contact surface ( 21 ) intended for placement of a tool to be formed in a stop position ( 19 ), a control device ( 23 ) for automatic control of adjustment movements of the stop finger ( 17 ) along the at least one adjustment axis ( 22 ), a monitoring device ( 35 ) connected by signaling means to the control device ( 23 ) and comprising an illuminating device ( 36 ) and at least one optical detection device ( 37 ), wherein the illuminating device ( 36 ) is arranged to be motion-coupled to the stop finger ( 17 ), and is configured to radiate a first light beam ( 38 ) into an area ahead of the stop finger ( 17 ) in the adjustment direction ( 39 , 45 ) during an automatically controlled adjustment movement of the at least one stop finger ( 17 ) in operation of the workpiece processing machine ( 1 ), and wherein the at least one detection device ( 37 ) is arranged to be stationary for monitoring of a monitoring area ( 41 ), and is configured to detect a first light image ( 43 ) created when the first light beam ( 38 ) is incident on an object surface ( 42 )