The invention is directed to a method for setting the idle distance of an engraving stylus for engraving a rotogravure printing cylinder from the cylinder surface of the rotogravure printing cylinder upon involvement of a sliding foot that is provided for the guidance of the engraving stylus connected to the sliding foot along the cylinder surface during engraving.
The invention is also directed to an adjustment mechanism, preferably for implementation of the method.
For rotogravure, a printing form is usually engraved into the cylinder surface of a rotogravure printing cylinder with an engraving stylus or with a plurality of engraving styli. The tip of the engraving stylus thereby normally comprises diamond.
For the engraving, the engraving stylus is driven in vibrating fashion with a prescribed frequency and amplitude. The image information to be engraved is superimposed as a signal on this basic vibration, so that the engraving stylus, when vibrating, enters into the cylinder surface with a different depth or does not enter thereinto according to the image information. Simultaneously, the rotogravure printing cylinder is driven in rotating fashion, and the engraving stylus is moved along the cylinder surface in the axial direction either continuously or in steps in order to achieve a continuation of the engraving image, which usually comprises a matrix of cups. During its relative motion over the cylinder surface, an engraving head comprising the engraving stylus is supported on the cylinder surface via a sliding foot, likewise preferably comprising diamond. For varying the spacing of the engraving head from the cylinder surface, the sliding foot can usually be retracted or extended farther transverse relative to the axis of the rotogravure form cylinder with a spindle, whereby “transverse” does not necessarily mean perpendicular to the axis and the sliding foot also need not necessarily lie in a radial path relative to the axis but, for example, can also be secantially aligned.
When the vibratory drive is turned off, the engraving stylus is situated at a slight clearance from the cylinder surface in its idle position, whereby this idle distance is prescribed by the setting of the extended length of the sliding foot. This idle distance, of course, must agree very precisely so that the image information is engraved into the cylinder surface as intended. The position of the engraving tip corresponds to the zero-axis crossing of the amplitude of the basic vibration of the engraving stylus without image information or given the image information, to not engrave at the corresponding location of the cylinder surface. The idle distance amounts, for example, to 3 through 5 micrometers, preferably 4 micrometers, and should be set to a precision of at least 10%.
During engraving, however, the engraving stylus wears over time or can even be damaged. The engraving styli must therefore be replaced by new ones relatively often. After such a replacement, however, the idle distance must be reset because, although the engraving tips or the cutting geometry of the engraving styli coincide, the engraving styli do not otherwise have structural lengths that coincide precisely enough. Just like the setting of the idle distance, thus the change of the engraving styli must be undertaken more frequently in engraving operations, namely more or less at the same time for a plurality of engraving machines since the rotogravure printing cylinders for the various colors of a color printing are usually engraved roughly simultaneously.
Up to now, one proceeded for setting the idle distance such that the new engraving stylus is roughly positioned and the spindle of the sliding foot is then moved slowly inward given a rotating rotogravure printing cylinder until the engraving stylus just barely lies against the cylinder surface and leaves a very slight scratch thereon, this lie there against being recognizable therefrom. With the assistance of a precision thread, the spindle is in turn moved outward by precisely the desired idle distance, as a result whereof this idle distance of the engraving stylus is directly produced.
This, however, is an inadequate and unsatisfactory procedure. Great care must be exercised in the described setting. A specific test cylinder is employed, this having to be chucked into the engraving machine for the setting and in turn removed therefrom later. Despite its high capital costs, the engraving machine cannot be used for engraving for the entirety of the adjustment work. The test cylinder does not rotate under machined drive, but is carefully manually turned a little over and over again by a person. The creation of the scratch is subjectively checked, and the return turning of the spindle of the sliding foot occurs with an angle prescribed by the operator. The procedure can therefore only be imprecisely objectively reproduced. Each operator obtains a somewhat different result.
An object of the invention is to improve the setting of the idle distance of the engraving stylus in rotogravure engraving.
According to the invention, the setting of the idle distance is undertaken with reference to a reference surface that replaces or represents the cylinder surface.
Exemplary embodiments to which the scope of the invention is not limited are shown in the drawings.
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For the purposes of promoting an understanding of the principles of the invention, reference will now be made to the preferred embodiments illustrated in the drawings and specific language will be used to describe the same. It will nevertheless be understood that no limitation of the scope of the invention is thereby intended, such alterations and further modifications in the illustrated device and/or method, and such further applications of the principles of the invention as illustrated therein being contemplated as would normally occur now or in the future to one skilled in the art to which the invention relates.
With the system and method disclosed, a rotogravure printing cylinder to be engraved can advantageously remain in the engraving machine, and the engraving machine can also be used during the setting event, particularly when it is provided according to a development of the method that the engraving head or the sliding foot with the engraving stylus that is connected to it and at which the setting is to be undertaken is moved out of its working position during the setting, preferably being removed from the engraving machine, and is replaced by an engraving head that has already been adjusted. The method appears especially economical in that only one setting device need be provided for an entire set or stock of engraving machines.
Since, ultimately the engraving stylus fundamentally works in a tangential plane of the cylinder surface, a plane, preferably a planar surface of a plate, can be employed as a reference surface, as provided in a development of the method, for easier setting and manipulation as well as installation of a device.
There are fundamentally different, conceivable possibilities of monitoring and measuring the setting of the idle distance. In particular, the monitoring and measurement, potentially even the setting event itself, should be implemented as objectively and reproducibly as possible, potentially even automated.
One possibility is comprised in a mechanical or electromechanical monitoring. For that purpose, for example, the engraving stylus can be moved against a resilient region of the reference surface by moving the spindle of the sliding foot in and the resiliency thereof can be registered and measured with a sensor. This can then be taken with the desired precision as a reference for the adjustment, whereby the necessary movements are preferably undertaken motorized and not manually by a person in order to achieve a reproducible precision and avoid jerky movements that could destroy the engraving stylus. Care can thereby also be exercised to see that the setting is always undertaken with a specific moving direction of the engraving stylus in order to avoid hystereses of the system or spindle running imprecisions in the measurement. This, of course, also applies to monitoring modes other than mechanical ones.
Another possibility of monitoring and measuring is comprised in an optical procedure.
The idle distance between the engraving tip and the reference surface that has been set and the variation thereof can thereby by made directly visible and observed. For example, a measurement or scale microscope can be employed therefor. One can look directly through this, or the generated image can be rendered visible in an even easier way by video camera on a picture screen, whereby an additionally improved and more precise scale can be selected by means of a projection factor generated in the transmission system. Moreover, an additionally more exact and more objective setting is possible when the reference surface is mirrored or reflective since the (double) idle distance of the engraving tip relative to its mirror image can then be set, whereby a zero point to be exactly defined can then be eliminated due to the symmetry that is thereby obtained, the zero point being potentially not optically recognizable precisely enough and capable of being absolutely defined.
In a side view,
The engraving head 1 is resiliently seated on a support 9 (not shown in detail), and is pivotably seated via leaf springs 10 that serve as a revolute joint and which is supported on coil springs 11.
In particular,
For setting or for reference definition of the idle position of the engraving stylus 3 here, the engraving stylus 3 is moved against a detent pin 13 by moving the spindle 7 of the sliding foot 1 in with a motor (not shown) instead of the adjustment wheels 8, the motion path thereof being registered and measured with an electronic distance sensor 14. After the reference for the engraving stylus 3 acquired in this way, this is precisely brought into it a desired position relative to the sliding foot 1 in that the spindle 7 is in turn moved outward in defined fashion. The measuring pin 13 is seated in softly resilient fashion with a spring 15 in order to avoid damage to the engraving stylus 3. For this same reason, a motor is employed instead of the hand wheel 8 in order to be able to implement the movement of the engraving stylus with greater control. For the precise reference measurement to the sliding foot 6, the measuring pin 13, in its non-deflected position, has its end face terminating precisely with a surface of a ground detent plate 16 for the sliding foot 6.
The detent plate 16 with sensor 14 is folded away for a problem-free stylus replacement. In this position, the newly introduced engraving stylus can also be set in height with the assistance of a camera (not shown). For that purpose, the engraving head 1 is placed on a carrier 17 in a corresponding measuring device outside an engraving machine, the detent plate 16 and the sensor 14 being hinged thereto and pivotable up to a stop 19.
The motor 18 that drives the spindle 7 via a V-belt can also be seen in
The reference surface 25 of the reference plate 24 is reflective. It is therefore not only the stylus tip of the engraving stylus 3 itself that can be recognized with the camera, but also its mirror image 3′ in the reference surface. As a result thereof, the stylus tip can be set symmetrically relative to its own mirror image, which can be measured or calibrated with a scale (ocular micrometer 26) in the ocular viewing field 27 of the microscope 22.
While preferred embodiments have been illustrated and described in detail in the drawings and foregoing description, the same is to be considered as illustrative and not restrictive in character, it being understood that only two of the preferred embodiments have been shown and described, that all changes and modifications that come within the spirit of the invention are desired to be protected, and that the invention may be provided in additional embodiments now or in the future.
Number | Date | Country | Kind |
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100 64 813 | Dec 2000 | DE | national |
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Number | Date | Country | |
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20020089697 A1 | Jul 2002 | US |