Drive mechanism for the cylinders of a printing press

Information

  • Patent Grant
  • 6334389
  • Patent Number
    6,334,389
  • Date Filed
    Monday, June 12, 2000
    24 years ago
  • Date Issued
    Tuesday, January 1, 2002
    22 years ago
Abstract
A drive mechanism for cylinders in a rotary press utilizes a plurality of motors associated with various cylinders. These motors are offset axially with respect to each other.
Description




FIELD OF THE INVENTION




The present invention is directed to a drive mechanism for the cylinders of a printing press.




A plurality of drive motors are assigned to the cylinders and are arranged axially offset.




DESCRIPTION OF THE PRIOR ART




A rotary offset printing press with rubber blanket and plate cylinders is known from EP 0 644 048 A2. For being driven together, these rubber blanket and plate cylinders have been combined in pairs into cylinder groups by a mechanical coupling. Each of these cylinder groups is driven by its own drive motor.




DE 44 30 693 A1 discloses printing units of a rotary offset printing press, wherein at least one cylinder is individually driven. Associated plate and rubber blanket cylinders are combined into groups for being driven.




U.S. Pat. No. 3,730,090 A describes an ink duct with individually adjustable inking blades. These inking blades are adjusted by means of step motors, which are arranged in an offset manner.




JP-A 56-21860 discloses individually driven cylinders of a printing unit.




SUMMARY OF THE INVENTION




The present invention is has the object of providing a drive mechanism for cylinders of a printing press.




In accordance with the present invention, this object is attained by the provision of a plurality of drive motors for the cylinders of the printing press. At least two of the drive motors assigned to the cylinders are arranged offset in respect to each other in the axial direction of the cylinders.




With the drive mechanism for cylinders of a printing press in accordance with the present invention, it is possible, in an advantageous manner, to use drive motors whose diameter is greater than the diameter of the cylinder for adjoining cylinders having their own drive motor.




Such an arrangement of the drive motors also allows satisfactory access for maintenance and repair work of the drive motors. This access is also facilitated in case of drive motors whose diameter is less than the diameter of the associated cylinder.




If movable cylinders, for example rubber blanket cylinders seated in eccentric bushings, are connected by means of a coupling, for example a universal joint shaft, with a drive motor, a small angular offset of the coupling is achieved by an arrangement which is distanced from a lateral frame.











BRIEF DESCRIPTION OF THE DRAWINGS




preferred embodiments of the present invention are represented in the drawings and will be described in greater detail in what follows. Shown are in:





FIG. 1

, the schematic representation of a view from above on a printing unit of a first preferred embodiment,





FIG. 2

, the schematic representation of a lateral view from the right side of a printing unit without a lateral frame of the first preferred embodiment, and in





FIG. 3

, the schematic representation of a view from above on a printing unit of a second preferred embodiment.











DESCRIPTION OF PREFERRED EMBODIMETS




In the present, first preferred embodiment as depicted in

FIGS. 1 and 2

a printing unit


1


of an offset rotary printing press is embodied in the form of a so-called nine piece satellite printing unit. This printing unit


1


is essentially formed by four printing cylinders


2


,


3


,


4


and


6


and by four transfer cylinders,


7


,


8


,


9


,


11


, for example printing cylinders


2


,


3


,


4


and


6


and rubber blanket cylinders,


7


,


8


,


9


,


11


, and by a counter-pressure cylinder


12


. The rubber blanket cylinders


7


,


8


,


9


,


11


can be selectively placed against the counter-pressure cylinder


12


for printing a web. It is also possible to place adjoining rubber blanket cylinders


7


,


8


,


9


,


11


selectively against each other, which adjoining blanket cylinders then print the front and back of a web.




These printing and rubber blanket cylinders


2


,


3


,


4


,


6


;


7


,


8


,


9


,


11


are provided with journals, which are seated in lateral frames


13


,


14


of the offset rotary printing press. In a known manner, the printing and/or rubber blanket cylinders


2


,


3


,


4


,


6


,


7


,


8


,


9


,


11


are arranged to be moved into or out of contact with each other and with cylinder


12


, for example by means of eccentric bushings. For example, the rubber blanket cylinders


7


,


8


,


9


,


11


can be arranged to be moved into or out of contact with the associated printing cylinders


2


,


3


,


4


,


6


and/or with the counter-pressure cylinder


12


. The printing cylinders


2


,


3


,


4


,


6


can also be moved into or out of contact with the rubber blanket cylinders


7


,


8


,


9


,


11


.




The journals of the printing and rubber blanket cylinders


2


,


3


,


4


,


6


,


7


,


8


,


9


,


11


extend through the lateral frame


13


at a drive side of the printing unit


1


. In the first preferred present exemplary embodiment, each cylinder


2


,


3


,


4


,


6


,


7


,


8


,


9


,


11


,


12


has its own drive mechanism which may be, for example a position-controlled electric motor


16


,


17


,


18


,


19


,


21


,


22


,


23


,


24


,


26


, as seen in

FIG. 1 and 2

. The rotors of these drive motors


16


,


17


,


18


,


19


,


21


,


22


,


23


,


24


,


26


are connected, for example directly, i.e. without a gear, such as, or by means of a gear, for example an integrated planetary gear, with the journals of the respective cylinders


2


,


3


,


4


,


6


;


7


,


8


,


9


,


11


,


12


. Also, a compensating coupling


27


is arranged in an advantageous manner between each of the drive motors


16


,


17


,


18


,


19


,


21


,


22


,


23


,


24


,


26


and the associated journals of the cylinders


2


,


3


,


4


,


6


,


7


,


8


,


9


,


11


,


12


. In the first preferred embodiment, a double-joint coupling


28


, for example a universal joint, is arranged, fixed against relative rotation, between the journals of the movable rubber blanket cylinders


7


,


8


,


9


,


11


and the respective associated drive motor


21


,


22


,


23


,


24


for each rubber blanket cylinder. In the present preferred embodiment, the drive motors


16


,


17


,


18


,


19


,


21


,


22


,


23


,


24


,


26


are arranged fixed in place on the frame. The drive motors


16


,


17


,


18


,


19


,


21


,


22


,


23


,


24


,


26


are represented schematically in FIG.


1


and

FIG. 2

in a cylinder shape. This does not necessarily mean that they have to be embodied exactly in a cylinder shape, instead, it is intended for other geometric shapes (for example cube-shaped), or projecting parts, to be included by the schematically depicted cylinder shape




In the present exemplary embodiment, all drive motors


16


,


17


,


18


,


19


,


21


,


22


,


23


,


24


,


26


are identical and have a greater diameter d


16


, d


19


, d


21


, d


24


, d


26


than the diameters d


2


, d


6


, d


7


, d


11


, d


12


of the associated cylinders. However, it is also possible to employ different drive motors within a printing unit.




The drive motors


16


,


17


,


18


,


19


, or respectively


26


, of the printing cylinders


2


,


3


,


4


,


6


and of the counter-pressure cylinder


12


are arranged in a first plane


29


, as seen in FIG.


1


. The drive motors


21


,


22


,


23


,


24


of the rubber blanket cylinders


7


,


8


,


9


,


11


are arranged in a second plane


31


also as seen in FIG.


1


. The first plane


29


and the second plane


31


are spaced apart, are we parallel with each other and extend vertically in respect to the axes of rotation of the cylinders.




The drive motors


16


,


17


,


18


,


19


, or respectively


26


, of the printing cylinders


2


,


3


,


4


,


6


and of the counter-pressure cylinder


12


are spaced apart from each other in the axial direction of the cylinder, i.e. they are arranged offset with respect to the other drive motors.




In place of the motor groupings groups provided for the printing, or respectively counter-pressure cylinders, and for the rubber blanket cylinders, it is also possible to provide motor groupings. However, it is common to all such arrangements or motor groupings that at least the drive motors of cylinders, which work directly together, are arranged offset with respect to each other in the axial direction.




The length l of the axial offset as seen in

FIG. 1

advantageously corresponds to at least a length


116


,


119


,


121


,


124


,


126


of a housing of a drive motor


16


,


19


,


21


,


24


,


26


.




In a second preferred embodiment, as seen in

FIG. 3

the drive motors


21


,


22


,


23


,


24


, of the rubber blanket cylinders


7


,


8


,


9


,


11


are arranged on the first lateral frame


13


which is the so-called drive side SII, and the drive motors


16


,


17


,


18


,


19


,


26


, of the printing cylinders


2


,


3


,


4


,


6


and of the counter-pressure cylinder


12


are arranged on the second lateral frame


14


which is the so-called operating side SI. The drive motors


21


,


22


,


23


,


24


assigned to the journals of the rubber blanket cylinders


7


,


8


,


9


,


11


are arranged opposite the drive motors


16


,


17


,


18


,


19


,


26


assigned to the opposite journals of the printing cylinders


2


,


3


,


4


,


6


and of the counter-pressure cylinder


12


. The drive motors


21


,


22


,


23


,


24


, of the rubber blanket cylinders


7


,


8


,


9


,


11


are assigned to the first lateral frame


13


, and the drive motors


16


,


17


,


18


,


19


,


26


, of the printing cylinders


2


,


3


,


4


,


6


and of the counter-pressure cylinder


12


are assigned to the second lateral frame


14


, i.e. fastened directly or indirectly on the lateral frame


13


, or respectively


14


.




The drive motors, arranged in an offset manner, can also be used in a ten piece satellite printing unit in particular, instead of in a nine piece satellite printing unit, wherein preferably each cylinder has its own drive motor assigned.




In these described preferred embodiments, each cylinder of a printing unit is assigned its own drive motor. It is also possible to drive cylinder groups, for example consisting of printing and transfer cylinders, respectively by means of a drive motor within a printing unit. In this case, the drive motors are also offset with respect to each other in the axial direction. For example, the drive motors of the cylinder groups in respect to a drive motor of a counter-pressure cylinder can be offset.




This arrangement of drive motors can also be employed in a folding apparatus or in other units, such as a roll changer a superstructure of a printing press.




While preferred embodiments of a drive mechanism for the cylinder of a printing press have been set forth fully and completely hereinabove, it will be apparent to one of skill in the art that a number of changes in, for example, the overall sizes of the various cylinders, the specific types of cylinders and the like could be made without departing from the true spirit and scope of the present invention which is accordingly limited only by the following claims:



Claims
  • 1. A drive mechanism for a printing press comprising:a plurality of cylinders in the printing press, each of said cylinders having an axis of rotation; and a plurality of drive motors associated with said plurality of cylinders, at least two of said drive motors being offset with respect to each other in an axial direction with respect to said plurality of cylinder, each of said plurality of drive motors having a drive motor length and further wherein an offset length between said at least two offset drive motors is greater than said drive motor length.
  • 2. The drive mechanism of claim 1 wherein said at least two offset drive motors are associated with two cylinders of said plurality of cylinders which work directly together.
  • 3. The drive mechanism of claim 1 wherein the printing press includes at least a first side and further wherein all of said drive motors are arranged on said first side of the printing press.
  • 4. The drive mechanism of claim 1 wherein said plurality of cylinders are arranged in a folding apparatus.
  • 5. A drive mechanism for a printing press comprising:a plurality of cylinders arranged in a printing unit in the printing press, each of said cylinders having an axis of rotation; and a plurality of drive motors associated with said plurality of cylinders, at least two of said drive motors being offset with respect to each other in an axial direction with respect to such plurality of cylinders, each one of said plurality of cylinders having its own one of said plurality of drive motors associated with it.
  • 6. The drive mechanism of claim 5 wherein said printing unit is a nine piece satellite printing unit of an offset rotary printing press.
  • 7. The drive mechanism of claim 5 wherein said printing unit is a ten piece satellite printing unit of an offset rotary printing press.
  • 8. A drive mechanism for a printing press comprising:a plurality of cylinders in the printing press, each of said cylinders having an axis of rotation; and a plurality of drive motors associated with said plurality of cylinders, at least two of said drive motors being offset with respect to each other in an axial direction with respect to said plurality of cylinders, said printing press having a first side and a second side and wherein each of said cylinders has an associated cylinder journal, drive motors for a first group of said cylinders being secured to said journals associated with said first group of said cylinders on said first side of said printing press, drive motors for a second group of said cylinders being secured to said journals associated with said second group of said cylinders on said second side of said printing press.
  • 9. A drive mechanism for a printing press comprising:a plurality of cylinders in the printing press, each of said cylinders having an axis of rotation; and a plurality of drive motors associated with said plurality of cylinders, at least two of said drive motors being offset with respect to each other in an axial direction with respect to said plurality of cylinders, one of said plurality of drive motors associated with said plurality of cylinders being assigned to one of said cylinders whose position can change.
Priority Claims (1)
Number Date Country Kind
197 55 316 Dec 1997 DE
PCT Information
Filing Document Filing Date Country Kind
PCT/DE98/03625 WO 00
Publishing Document Publishing Date Country Kind
WO99/30906 6/24/1999 WO A
US Referenced Citations (7)
Number Name Date Kind
2003799 Barber Jun 1935 A
3730090 Lamberg et al. May 1973 A
5485782 Van Der Horst Jan 1996 A
5570633 Schultz et al. Nov 1996 A
5771804 Knauer et al. Jun 1998 A
5782182 Ruckmann et al. Jul 1998 A
5943955 Niemiro et al. Aug 1999 A
Foreign Referenced Citations (5)
Number Date Country
44 08 025 Sep 1995 DE
44 30 693 Mar 1996 DE
644 048 Mar 1995 EP
771198 Mar 1957 GB
56021860 Jul 1979 JP