Method and device for ink-jet printing onto containers

The invention claimed is: 1. A method for ink-jet printing onto containers, where a print advance with respect to at least one print module is created at least by rotation of said containers about themselves and/or by transporting said containers along at least one curved trajectory, where surface velocities of lateral portions of said containers are measured during said rotation/said transport and fluctuations of the surface velocity of individual lateral portions, caused by eccentrically held and/or non-rotationally-symmetrical container cross-sections, are measured upstream of the ink-jet printing onto the containers, and where time intervals between printing times of said print module and/or an angular velocity of said rotation are adapted in dependence of said measured surface velocities, where time intervals between printing times of individual nozzles or rows of nozzles of said print module are defined, and wherein the measured surface velocities correspond to actual print advance rates of individual lateral portions of the containers relative to the print module. 2. The method according to claim 1 , where time intervals associated with different lateral portions and/or intermediately disposed portions of said containers are set respectively greater the lower said associated surface velocities are. 3. The method according to claim 2 , where said printing times and/or said angular velocity are adapted to associated print distances from said lateral portions of said containers and/or said intermediately disposed portions of said containers. 4. The method according to claim 3 , where said containers are at least one of glass bottles with a rotationally-symmetrical nominal cross-section and shaped bottles made of plastic, and wherein the time intervals are adjusted by a temporal offset, the temporal offset based on the associated print distances. 5. The method according to claim 1 , where said surface velocities are measured during ongoing print advance. 6. The method according to claim 5 , where the printing times are adapted on-the-fly, during rotation at a constant angular velocity and in consideration of a time offset until a respective nozzle or nozzle row is reached. 7. The method according to claim 1 , where said surface velocities are measured during rotation and/or transport at a known angular velocity. 8. The method according to claim 7 , where said surface velocities are associated with rotational positions of said containers. 9. The method according to claim 7 , where the known angular velocity is overlaid by a known transport velocity. 10. The method according to claim 1 , where said surface velocities are measured with a friction wheel rolling laterally along said containers. 11. The method according to claim 1 , where said surface velocities are measured in a contactless manner by optical and/or acoustic scanning of said lateral portions, the surface velocities being a sum of a rotational component due to the rotation and a translational component due to the transporting. 12. A device for ink-jet printing onto containers, comprising: at least one print module; at least one positioning unit for holding and rotating a container about itself in front of said print module; at least one measuring device for measuring surface velocities of lateral portions of said rotating container; wherein said measuring device operates in a contactless manner on the basis of an optical and/or acoustic scanning beam, and wherein time intervals are adjusted by a temporal offset, the temporal offset based on associated print distances; and a control device, said control device containing instructions for actuating said print module while adapting time intervals between printing times of said print module in dependence of said measured surface velocities, where time intervals between printing times of individual nozzles or rows of nozzles of said print module are defined, and wherein the measured surface velocities correspond to actual print advance rates of individual lateral portions of the containers relative to the print module. 13. The device according to claim 12 , where said measuring device comprises a friction wheel with a rotary encoder, and where said friction wheel is resiliently preloaded in a direction toward said container having its surface velocity measured. 14. The device according to claim 13 , where at least one print head on said print module is movably supported together with said friction wheel in the direction toward said container. 15. The device according to claim 12 , where said optical scanning beam is at least one of a laser light, an optical code reader, a line scanner, and a camera; and where said acoustic scanning beam is an ultrasound acoustic scanning beam. 16. The device according to claim 12 , where the control device adapts the printing times on-the-fly, during rotation at a constant angular velocity and in consideration of a time offset until a respective nozzle or nozzle row of the least one print module is reached. 17. A device for ink-jet printing onto containers, comprising: at least one print module; a carousel with positioning units circulating thereon for holding and rotating said containers about themselves; at least one measuring device for measuring surface velocities of lateral portions of said circulating containers; and a control device for actuating said print module while adapting time intervals between printing times of said print module in dependence of said measured surface velocities, where time intervals between printing times of individual nozzles or rows of nozzles of said print module are defined, and wherein the measured surface velocities correspond to actual print advance rates of individual lateral portions of the containers relative to the print module; and wherein the time intervals are adjusted by a temporal offset, the temporal offset based on associated print distances. 18. The device according to claim 17 , where said measuring device operates in a contactless manner on the basis of an optical and/or acoustic scanning beam; where said optical scanning beam is at least one of a laser light, an optical code reader, a line scanner, and a camera; and where said acoustic scanning beam is an ultrasound acoustic scanning beam. 19. The device according to claim 17 , where the at least one measuring device measures the surface velocities of the lateral portions at a known angular velocity of the lateral portions and at a known transport velocity of the lateral portions, the angular velocity and the transport velocity being overlaid with each other. 20. The device according to claim 17 , where the at least one measuring device is positioned upstream of the at least one print module.