Method for controlling an electrostatic atomizer for liquids

The invention claimed is: 1. A method for controlling an electrostatic atomizer for liquids, the atomizer comprising a liquid tank and a delivery device for liquid from the liquid tank, a high-voltage source and a plurality of atomizer nozzles for the atomization of liquid, the plurality of atomizer nozzles are arranged in a rectangular geometrical ring arrangement, which is formed of elongated grid lines extending in parallel directions that form a plurality of columns that are arranged next to one another and grid lines extending in parallel directions that form a plurality of rows that are arranged below one another, with the elongated grid lines and the grid lines crossing at points, respectively, thereby forming a grid of parallel grid lines including grid points on outermost grid lines of the rectangular geometrical ring arrangement, such that the plurality of atomizer nozzles are arranged only at the grid points on the outermost grid lines of the rectangular geometrical ring arrangement, with at least one of the atomizer nozzles being connected to the high-voltage source, wherein a voltage and a current intensity at the at least one of the atomizer nozzles are detected by sensors of control electronics and/or wherein a voltage and a current intensity at the high-voltage source are detected by sensors of the control electronics. 2. The method as claimed in claim 1 , wherein the atomizer comprises: a housing, an electrical energy source, by which the high-voltage source is supplied, an activation mechanism, by which the atomizer is activated, and the control electronics, by which the dispensing of liquid by the atomizer is controlled. 3. The method as claimed in claim 2 , wherein an analysis of the current intensity and the voltage at the at least one of the atomizer nozzles and an electrically conductive portion of the housing or of an operating element of the activation mechanism is performed and a comparison of these measurements with reference values is carried out. 4. The method as claimed in claim 3 , wherein by an analysis of measured current intensities and voltages, a distance value between the at least one of the atomizer nozzles and a surface to be sprayed is determined. 5. The method as claimed in claim 3 , wherein by an analysis of measured current intensities and voltages, a coating parameter of a surface to be sprayed is determined. 6. The method as claimed in claim 1 , wherein the delivery device is arranged between the liquid tank and the at least one of the atomizer nozzles, the delivery device being connected to the liquid tank by a first line and liquid being sucked out of the liquid tank by the delivery device, and the delivery device being connected to the at least one of the atomizer nozzles by a second line and liquid being delivered by the delivery device to the at least one of the atomizer nozzles, the first line and the second line being formed as a hose extruded in one piece. 7. The method as claimed in claim 6 , wherein the delivery device and/or the high-voltage source are controlled, in a closed-loop manner, in dependence on the voltage and the current intensity measured at the at least one of the atomizer nozzles and/or in dependence on the voltage and the current intensity measured at the high-voltage source to optimize the dispensing of liquid by the atomizer. 8. The method as claimed in claim 1 , wherein by an analysis of measured current intensities and voltages of the at least one of the atomizer nozzles, an alignment of the at least one of the atomizer nozzles with respect to a surface to be sprayed is determined. 9. The method as claimed in claim 1 , wherein the atomizer comprises in addition to the first liquid tank a second liquid tank, wherein the atomizer comprises in addition to the first delivery device a second delivery device, in that arranged between the delivery devices and the at least one of the atomizer nozzles is a mixing device, a delivery volume of the first delivery device and a delivery volume of the second delivery device being controlled in such a way that a mixed liquid of a prescribed composition is produced in the mixing device. 10. The method as claimed in claim 1 , wherein the atomizer comprises a heating device and/or a cooling device, the liquid being heated or cooled to achieve a prescribed temperature and/or viscosity before leaving the at least one of the atomizer nozzles. 11. The method as claimed in claim 1 , wherein, when there is an activation of the atomizer, first the high-voltage source generator is activated and then the delivery device is activated. 12. The method as claimed in claim 11 , wherein, when there is an activation of the atomizer before an activation of the high-voltage generator, the at least one of the atomizer nozzles is brought from an inactive position into an active position, the at least one of the atomizer nozzles and/or the housing being moved for this purpose and/or at least one housing portion, as a slide, being moved in relation to the at least one of the atomizer nozzles. 13. The method as claimed in claim 11 , wherein, when there is a deactivation of the atomizer after a deactivation of the high-voltage source generator, the at least one of the atomizer nozzles is brought from an active position into an inactive position, the at least one of the atomizer nozzles and/or the housing, at least one housing portion, being moved for this purpose. 14. The method as claimed in claim 1 , wherein, when there is a deactivation of the atomizer, first the delivery device is deactivated and then the high-voltage source generator is deactivated, it being provided that, before its deactivation, the delivery device is automatically switched from forward delivery to brief backward delivery.