Ink metering system in a printing press with piezoelectric actuating element

Information

  • Patent Grant
  • 6634293
  • Patent Number
    6,634,293
  • Date Filed
    Tuesday, November 13, 2001
    22 years ago
  • Date Issued
    Tuesday, October 21, 2003
    20 years ago
Abstract
An ink metering system in a printing press is described. The printing press has a roller that is divided into a plurality of ink zones, whereby each of the ink zones has an associated piezoelectrical actuating drive. An ink metering system is characterized by a control device containing the actuating drive and a sensor.
Description




BACKGROUND OF THE INVENTION




1. Field of the Invention




The invention is directed to an ink metering system in a printing press that is divided into ink zones, whereby each of which has a piezoelectrical actuating drive.




Piezoelectrical actuating drives are known per se, as can be seen from Published, Non-Prosecuted German Patent Application No. 44 45 642 A1, and are used in different technical fields.




German Utility Model No. 91 12 926 U1 describes an ink metering system corresponding to the ink metering system of the aforementioned species. The regulation, actually the control, occurs according to a stored characteristic curve reproducing the context by an applied voltage and alternation of length of the piezoelectrical actuating drive, so that the status message of the respective position of the metering element via potentiometer, as known from other ink metering systems, is not necessary with respect to the ink metering system described in the aforementioned utility model.




What is disadvantageous about it is that hydrodynamic influences of the metered printing ink on the ink metering system and a drift of the metering element occurring in the actuating drive as a result of typesetting processes remain unconsidered.




SUMMARY OF THE INVENTION




It is accordingly an object of the invention to provide an ink metering system in a printing press that overcomes the above-mentioned disadvantages of the prior art devices of this general type, which operates in a more metering-stable manner.




With the foregoing and other objects in view there is provided, in accordance with the invention, an ink metering system for a printing press having a roller divided into ink zones. The ink metering system includes a control device for each of the ink zones. The control device has a piezoelectrical actuating drive and a sensor.




A critical advantage of the inventive ink metering system is its high metering stability.




Modifications of the distance of the metering element from a roller occurring during the metering operation are measured by the sensor and are compensated via a status message by the control device, so that the distance is kept the same under all operating conditions. The metering system is allocated to the roller.




In accordance with an added feature of the invention, the control device has a metering element and the piezoelectrical actuating drive engages the metering element for adjusting the metering element and a distance between the metering element and the roller is a measuring variable of the control device.




In accordance with an additional feature of the invention, the sensor is a distance sensor secured to the metering element and is directed toward the roller.




In accordance with another feature of the invention, the control device has a metering element and the piezoelectrical actuating drive engages the metering element for adjusting the metering element. The control device has a machine element disposed adjacent the metering element, and a distance between the metering element and the machine element is the measuring variable of the control device.




In accordance with a further feature of the invention, the sensor is a distance sensor fastened to the machine element and is directed toward the metering element.




In accordance with a further added feature of the invention, the control device has a gear with a gear element, the piezoelectrical actuating drive and the metering element are connected in terms of driving through the gear element.




In accordance with a further additional feature of the invention, the gear is a translation gear for translating a short regulating distance of the piezoelectrical actuating drive into a long regulating distance of the metering element.




In accordance with another further feature of the invention, the sensor is a deformation sensor attached to the gear.




In accordance with an added feature of the invention, the gear has a flexible joint.




In accordance with a further feature of the invention, the piezoelectrical actuating drive and the metering element have regulating directions deviating from one another.




With the foregoing and other objects in view there is provided, in accordance with the invention a printing press containing a roller divided into ink zones and an ink metering system having a control device for each of the ink zones. The control drive has a piezoelectrical actuating drive and a sensor.




Other features which are considered as characteristic for the invention are set forth in the appended claims.




Although the invention is illustrated and described herein as embodied in an ink metering system in a printing press, it is nevertheless not intended to be limited to the details shown, since various modifications and structural changes may be made therein without departing from the spirit of the invention and within the scope and range of equivalents of the claims.




The construction and method of operation of the invention, however, together with additional objects and advantages thereof will be best understood from the following description of specific embodiments when read in connection with the accompanying drawings.











BRIEF DESCRIPTION OF THE DRAWINGS





FIG. 1

is an illustration of a roller and an ink metering system allocated to it with control devices according to the invention;





FIG. 2

is a block diagram of one of the control devices; and





FIGS. 3-7

are sectional views showing different exemplary embodiments and modifications of the ink metering system.











DESCRIPTION OF THE PREFERRED EMBODIMENTS




Referring now to the figures of the drawing in detail and first, particularly, to

FIG. 1

thereof, there is shown a section of a printing press


1


, specifically a rotary offset printing press. The section shows a roller


2


acting as an ink duct roller divided into ink zones


4


,


5


and an ink metering system


3


that is allocated to it. The ink metering system is formed of tongue-shaped metering elements


6


,


7


which are disposed parallel to the roller


2


and which are individually adjustably toward and away from the roller


2


for generating a zonal ink profile with an ink layer thickness on the roller


2


that is different from ink zone to ink zone. Each of the metering elements


6


,


7


adjustable in regards to one another, together with the roller


2


, forms a metering nip


8


,


9


through which a printing ink of the roller


2


is transported. A control device


10


,


11


having a sensor


13


,


13


′ or


13


″ sensing a measuring value for independently controlling sizes of the metering nip


8


,


9


is allocated to each of the metering elements


6


,


7


. The control device


10


,


11


is shown in

FIG. 1

with a control circuit symbol.




As an example for all the control devices


10


,


11


,

FIG. 2

shows a block diagram of the control device


11


which is fashioned as a closed loop and which contains an actuator (actuating drive


12


), the measuring device (sensor


13


,


13


′ or


13


″), a set value adjuster


14


, a comparator


15


and an amplifier


16


and which functions as now described.




A metering nip set value that is required for the ink profile is adjusted at the set value adjuster


14


, whereby the metering ink set value, in the comparator


15


, is compared to a metering nip actual value measured by the measuring device. The comparator


15


determines a deviation of the actual value from the set value, which is caused by a disturbance variable


17


acting upon a controlled system (a metering element


7


).




The disturbance variable


17


can be a typesetting process within the actuating drive


12


composed of piezo individual elements that are piled on top of one another or can be a drifting of the metering element


7


from the roller


2


when the hydrodynamic pressure of the printing ink in the metering nip


9


onto the metering element


7


increases as a result of an increase in speed of the roller


2


.




Subsequent to a change of sign of the deviation and its amplification in the amplifier


16


, the actuator


12


is charged with the negative and amplified deviation, so that a correcting variable is generated which influences the controlled system such that the regulating variable (width of the metering nip


9


) assumes the set value again. The amplified deviation is a modification of the electrical voltage at the actuating drive


12


, whereby the modification—dependent on the preceding sign —effects an extension or contraction of the actuating drive


12


and therefore an adjustment of the metering element


7


.




The sensor


13


,


13


″ can be a non-contact distance sensor, such as an ultrasound sensor, for directly measuring. The sensor


13


′, however, can also be a deformation sensor, such as a calibrated stretch measuring strip, for indirectly measuring.




In a side view,

FIG. 3

shows a first exemplary embodiment of the ink metering system


3


. The actuating drive


12


, in terms of driving, is connected to the metering element


7


via a gear element


18


of a translation gear


19


. The translation gear


19


enlarges a small regulating distance a of the actuating drive


12


into a large regulating distance b of the metering element


7


, which makes it possible for a large ink amount to pass through the metering nip


9


. The gear element


18


is a lever arm and resides at a right angle in a direction of the regulating distance a. An angle α extending between a longitudinal axis of the actuating drive


12


, which is identical with the linear direction of the regulating distance a, and a radial line of the roller


2


extending through the metering nip


9


is also 90°.




The gear element


18


and the metering element


7


together form an angle lever and are pivotably disposed about a flexible joint


20


, i.e. a flector, of the translation gear


19


. On one hand, the joint


20


forms a connecting element between the gear element


18


and the metering element


7


and a support


21


, on the other hand. The actuating drive


12


, which approximately forms a parallelogram together with the plate-shaped or bridged-shaped joint


20


, is coupled at the support


21


with its one end and is coupled at the gear element


18


with its other end. The regulating distances a and b are approximately perpendicularly oriented toward one another.




For the positive squeezing or doctoring of the roller


2


, the metering element


7


has a wiping edge


22


, whose position relative to the roller


2


determines the metering nip


9


and which is set against the roller


2


by forming the metering nip


9


given an open ink zone


5


and is set against the roller


2


practically without forming the metering nip


9


given a closed ink zone


5


.




Close to the wiping edge


22


, the sensor


13


that is fashioned as a distance sensor


13


and that is directed toward the roller


2


is fastened at the metering element


7


, whereby the sensor


13


measures a distance proportional to the metering nip


9


between the metering element


7


and a circumferential surface of the roller


2


. The sensor


13


is placed in a borehole of the metering element


7


and is covered by printing ink


23


in a wedge-shaped ink duct that is formed by the metering elements


6


,


7


, whereby the measuring occurs through the printing ink


23


. Instead of the sensor


13


, the sensor


13


′ can also be used for determining the distance of the metering element


7


from the roller


2


. The sensor


13


′ attached to the translation gear


19


is a deformation sensor, specifically is a stretch measuring strip measuring a deformation of the translation gear


19


proportional to the metering nip


9


. To be more precise, the sensor


13


′ is attached to the joint


20


and measures its increasing or decreasing deflection given the adjustment of the metering element


7


—dependent on the adjustment direction.





FIG. 4

shows a modification of the first exemplary embodiment and differs from the last one only regarding a few characteristic features, which are subsequently explained in greater detail. In view of the other constructive features, the description of the last exemplary embodiment is valid in terms of sense with respect to the modification, so that the same reference numbers are used in the

FIGS. 3 and 4

for components having the same function, so that they do not have to be described a second time.




A characteristic feature of the modification of the first exemplary embodiment is that the support


21


and the gear element


18


are not only connected to one another via the joint


20


but also via a second connector in the form of a flexible joint (flector)


24


, so that the support


21


, the gear element


18


and the joints


20


and


24


form one single component in the form of a parallelogram or, respectively, closed frame. The end of the actuating drive


12


linked at the support


21


is closer to the joint


20


than the end of the actuating drive


12


linked at the gear element


18


, so that its regulating distance a, given the modification of the first exemplary embodiment, extends at an inclined angle relative to the longitudinal direction of the joints


20


and


24


and an acute angle β between the longitudinal axis of the actuating drive


12


or, respectively, direction of the regulating distance a and the radial line of the roller


2


extending through the metering nip


9


is less than 90°.




The maximum regulating distance a of the actuating drive


12


is relatively small and can range from 0.05 mm to 0.20 mm. The translation ratio ü=b: a of the translation gear


19


is relatively great and can be ü=10, for example, so that a regulating distance a of 0.10 mm is translated into a regulating distance b of 1.00 mm.




Joint profile tapers


25


to


28


disposed at the ends of the joints


20


and


24


represent a further characteristic feature, whereby set bending points of the joints


20


and


24


are prescribed by the joint profile tapers. Given the modification of the first exemplary embodiment, the sensor


13


′ is no longer attached to the joint


20


but to the joint


24


in the region of the taper


28


.





FIG. 5

shows a second exemplary embodiment of the ink metering system


3


, which differs from the first exemplary embodiment (

FIG. 3

) and its modification (

FIG. 4

) only regarding a few constructive characteristic features. These characteristic features of the second exemplary embodiment are subsequently explained in greater detail. Therefore, the description of the other constructive features, which the second exemplary embodiment and the first exemplary embodiment and its modification have in common, can be transferred from the

FIGS. 3 and 4

to

FIG. 5

, so that the reference numbers already used in the

FIGS. 3 and 4

are kept.




A characteristic feature of the second exemplary embodiment is that the metering element


7


and the gear element


18


have longitudinal axes situated in straight alignment, so that the longitudinal axis of the metering element


7


perpendicularly extends relative to longitudinal axes of the joints


20


and


24


. This is advantageous with respect to an adjustment of the metering element


7


occurring approximately in a radial direction of the roller


2


for regulating the metering nip


9


.




Another characteristic feature of the second exemplary embodiment is the orientation of the actuating drive


12


, whose end supported at the gear element


18


is closer to the joint


20


than the end supported at the support


21


. Therefore, an angle γ>90° arises, in the second exemplary embodiment, between the longitudinal axis of the actuating drive


12


or, respectively, the direction of the regulating distance a identical with the latter, on one hand, and the radial line of the roller


2


extending through the metering nip


9


, on the other hand.





FIG. 6

shows a modification of the second exemplary embodiment, whereby the second joint


24


and the joint profile tapers


25


to


28


are foregone here. Given the modification of the second exemplary embodiment, the gear element


18


, the joint


20


and the support


21


together form an essentially U-shaped component. The description of the second exemplary embodiment corresponds to its modification in all points.





FIG. 7

shows a third exemplary embodiment of the ink metering system


3


. The metering element


7


and a machine element


29


in the form of a support


29


are produced from a four-edged shaped bar, which is cut-in along a separating line


30


by an eroding tool.




A straight spring (leaf spring)


31


having a thickness of approximately 1.5 mm, which is connected to the support


29


and which is subject to bending, results from the curve of the separating line


30


at the metering element


7


and essentially wedge-shaped contours of the metering element


7


and the support


29


. In the area of the spring


31


, which serves the purpose of setting back the metering element


7


away from the roller


2


, the separating line


30


extends parallel to an outside surface of the metering element


7


, which forms an ink duct bottom and ends in a wiping edge, and also extends parallel to a longitudinal axis or, respectively, to a regulating path a of the actuating drive


12


.




In an area following the spring


31


, the separating line


30


is expanded to an air gap


32


, which extends essentially diagonal and at a flat angle relative to the standardized outside surface of the metering element


7


and to the regulating distance a or, respectively, to the longitudinal axis of the actuating drive. The air gap


32


extends in a U-shaped manner at the end of the separating line


30


opposite the spring


31


and forms a projection


33


of the support


29


between two stop surfaces


34


and


35


of the metering element


7


that are situated opposite to one another.




The actuating drive


12


, with its one end, flexibly supports itself at the support


29


and flexibly supports itself at the metering element


7


with its other end and is inserted into a recess


36


, which has been drilled through the support


29


and into the metering element


7


, before the support


29


and the metering element


7


have been unraveled along the separating line


30


. A sufficient margin in the form of an annular gap


37


enabling a swiveling movement of the metering element


7


relative to the support


29


is present between the outside diameter of the actuating drive


12


and the inside diameter of the recess


36


given an utilized actuating drive.




A sensor


13


″ acting as a distance sensor is embedded into the support


29


in the diagonally extending region of the air gap


32


, whereby the sensor


13


″ is directed to a measuring surface at the metering element


7


.




A configuration of the sensor


13


″ and the measuring surface exchanged with one another vis-à-vis is also conceivable, whereby the sensor


13


″ is fastened at the metering element


7


and would be directed to the support


29


.




The sensor


13


″ shown in

FIG. 7

measures a width of the air gap


32


, which changes proportionally to a width of the metering nip


9


given its adjustment, so that an indirect measuring of the measuring nip


9


ensues given its control by the control device


11


.




Instead of the sensor


13


″ measuring the air gap


32


, a sensor that is disposed close to the wiping edge of the metering element


7


and that is directed toward the roller


2


can also be used, whereby the sensor is comparable to the sensor


13


of the first two exemplary embodiments.




Regardless of which exemplary embodiment is used for the ink metering system


3


, each ink zone


4


,


5


has the configuration of the actuating drive


12


, of the sensor


13


;


13


′;


13


″ and of the support


21


;


29


connected in terms of gearing to the metering element


7


as shown in

FIG. 3

,


4


,


5


,


6


or


7


.




In all exemplary embodiments, the metering nip is independently controlled, whereby the control is as follows. The disturbance variable


17


in the form of the typesetting process makes oneself conspicuous in the actuating drive


12


of the ink zone


5


, which therefore slightly collapses in the direction of the regulating path a. As a result thereof, the metering nip enlarges in an undesired manner. The enlargement of the metering nip


9


is measured by the sensor


13


;


13


′ or, respectively,


13


″ and is signalized to the measuring device


11


, which increases the voltage at the actuating drive


12


such that the actuating drive


12


expands and therefore reaches its original position prior to the collapse. The metering nip


9


thereby is set back to the width corresponding to the desired ink profile.



Claims
  • 1. An ink metering system for a printing press, comprising:ink zones, the ink metering system being divided into said ink zones; each of said ink zones having a control device disposed in a closed loop containing a piezoelectrical actuating drive and a sensor; and each of said piezoelectrical actuating drives being formed of individual piezo-elements disposed on top of one another.
  • 2. The ink metering system according to claim 1, wherein said control device has a metering element and said piezoelectrical actuating drive engages said metering element for adjusting said metering element, and a distance between said metering element and a roller is a measuring variable of said control device.
  • 3. The ink metering system according to claim 2, wherein said sensor is a distance sensor secured to said metering element and is directed toward the roller.
  • 4. The ink metering system according to claim 1, wherein:said control device has a metering element and said piezoelectrical actuating drive engages said metering element for adjusting said metering element; and said control device has a machine element disposed adjacent said metering element, and a distance between said metering element and said machine element is a measuring variable of said control device.
  • 5. The ink metering system according to claim 4, wherein said sensor is a distance sensor fastened to said machine element and is directed toward said metering element.
  • 6. The ink metering system according to claim 1, wherein said control device has a gear with a gear element and a metering element, said piezoelectrical actuating drive and said metering element are drivingly connected through said gear element.
  • 7. The ink metering system according to claim 6, wherein said gear is a translation gear for translating a short regulating distance of said piezoelectrical actuating drive into a long regulating distance of said metering element.
  • 8. The ink metering system according to claim 7, wherein said gear has a flexible joint.
  • 9. The ink metering system according to claim 6, wherein said sensor is a deformation sensor attached to said gear.
  • 10. The ink metering system according to claim 1, wherein said control device has a metering element, and said piezoelectrical actuating drive and said metering element have regulating directions deviating from one another.
  • 11. A printing press, comprising:a roller; an ink metering system associated with said roller, said ink metering system being divided into ink zones; each of said ink zones having a control device disposed in a closed loop containing a piezoelectrical actuating drive and a sensor; and each said prezoelectrical actuating drives being formed of individual piezo-elements disposed on top of one another.
Priority Claims (1)
Number Date Country Kind
100 55 827 Nov 2000 DE
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Number Name Date Kind
4381708 Hirt et al. May 1983 A
5287808 Lippold Feb 1994 A
5438927 Banike et al. Aug 1995 A
6029573 Capdeboscq Feb 2000 A
6062139 Tomita et al. May 2000 A
Foreign Referenced Citations (4)
Number Date Country
2728738 Jan 1979 DE
3727656 Mar 1989 DE
3914831 Nov 1990 DE
9112926.5 Jan 1992 DE
Non-Patent Literature Citations (2)
Entry
Japanese Patent Abstract No. 2-29337 (Takei), dated Jan. 31, 1990.
Japanese Patent Abstract No. 3-227240 (Isono et al.), dated Oct. 8, 1991.