DE4136195C1 - Drive for modular,rotary sheet printing machine - involves several printing units with transfer drum between them, and appropriate gear train - Google Patents

Abstract

The printing machine has two drive pinions (14,15) enclosing a specific inner angle (beta), and by allocation of the drive pinions to a gear wheel of an outer printing mechanism the angle is between 60 and 90 deg. By allocation of the drive pinions to a gear wheel of a middle printing mechanism the angle (beta) is between 150 and 170 deg. The double-sized printing and transfer cylinders as against the plate and blanket cylinder are arranged at an angle (alpha) from 10 to 20 deg. By allocation of the drive pinions to a gear wheel of an off-centre printing mechanism, the inner angle (beta) enclosed by the drive pinions is between 90 and 150 deg. USE/ADVANTAGE - For rotary sheet printing machine,with a single drive mechanism and good printing quality.

Description

The invention relates to a drive for sheet rotation Printing machines, according to the preamble of patent claims 1 to 3.

Single drives, over which the total drive power in a sheet-fed rotary printing machine in aggregate design have been known for a long time.

The drive on such machines is such that the gears of adjacent arc-guiding cylinders in Tooth mesh and a closed in the printing press Form gear train.

Are known for. B. Single-motor drives that have a wedge belt drive with its drive pinion in the gear one Intervene in the transfer drum or pressure cylinder.

In an aggregate printing machine that consists of a system printing unit, Follow-up printing unit (s) and delivery printing unit can do that Drive pinion can be assigned to each printing unit, what this Printing unit then to the drive printing unit of the sheet rotation printing press makes.  

A disadvantage of such a single-motor drive with transmission via the gear train is that from the An Radial forces on the driven gear and thus on the bearing of the sheet-guiding cylinder that are transmitted to the cylinder by bending forces thigh and ultimately to negatively influence the Can lead print image.

From the German utility model 73 19 412 is an An Drive device for a ring gear via two pinions (Multi-motor drive) known. This is used Drive connection in fine grinding mills or grinding plants for the mining and cement industry, where large and very heavy rotatable drums or cylinders driven should be.

The ring gear is supplied with at least two drive pinions arranges.

As shown in Fig. 2 of the utility model, the drive pinions on the circumference of the ring gear are arranged at a distance, whereby the radial forces resulting from the drive pinions acting on the bearing point of the cylinder can influence one another.

However, this document does not teach what measures are to be taken to an arch Rotary printing machine in unit design with a single Drive unit to design the drive so that the from the drive coming on the driven sheet leading Forces acting on the cylinder, leading to malfunctions in the cylinder Lead printing process, largely avoided  can be.

Based on the disadvantages mentioned in the prior art Technology is the object of the invention, a drive for Sheet-fed rotary printing presses that drive over get a single drive printing unit to create which in the drive printing unit has no adverse effects on the Print result generated.

According to the invention the task is characterized by Features of claims 1, 2 and 3 solved.

The arrangement of the two drive pinions according to the invention to the gear of a sheet-guiding cylinder of the drive printing unit has the advantage that the resulting from the drive Radial forces on each other almost cancel. This means there are no effects on the bearing Bending forces that negatively generated in the drive printing unit Influence the printed image.

Using an exemplary embodiment, the Invention will be explained in more detail.

In the accompanying drawings

Fig. 1 is a schematic representation of a rotary sheet printing machine with five printing units,

Fig. 2: schematic representation of the gear train of Figure 1.

3 shows a driving printing unit with the two driving pinions (shown schematically)..

Fig. 4a: symbolized representation of the power flow on a sheet-fed rotary printing press with seven printing units. The drive printing unit is the delivery printing unit,

FIG. 4b: symbolized representations of power flow in a sheet-fed rotary printing machine having three printing units. The drive printing unit is the system printing unit,

Fig. 4c: symbolized representation of the power flow on a sheet-fed rotary printing press with seven printing units. Drive printing unit is the middle printing unit,

Fig. 4d: symbolized representations of power flow in a sheet-fed rotary printing machine according to Figure 1 with the driving printing unit is the last episode printing unit..

The sheet-fed rotary printing press shown in FIG. 1 in the form of an assembly, shown with five printing units 2 , 3 , 5, consists of the sheet feeder 1 , the system printing unit 2 , the delivery printing unit 5 , and the subsequent printing units 3 enclosed by the system and delivery printing units 2 , 5 ; ie 3.1 ; 3.2 ; 3.3 and the sheet delivery 6 .

The follow-up printing units 3 are identical in construction.

The printing units 2 , 3 , 5 can be differentiated into

• - external printing units 2 , 5 . Outside printing units 2 , 5 are the system printing unit 2 and the delivery printing unit 5 ,
• - Real and fake center printing units 3 M. A printing press with an odd number of printing units 2 , 3 , 5 has a real center printing unit 3 M.
  A printing press with an even number (and with more than two printing units 2 , 5 ) has two spurious center printing units 3 M.
  On a printing press consisting of five printing units 2 , 3 , 5 , the third printing unit 3.2 is therefore a real center printing unit 3 M.
  On a printing press consisting of four printing units, the second and third printing units 3.1 ; 3.2 spurious middle printing units 3 M. center printing units are 3M result printing. 3
• - Off-center printing units 3 A.
  Off-center printing units have printing presses that consist of five or more than five printing units 2 , 3 , 5 be. Off-center printing units 3 A are subsequent printing units 3 , which are arranged between the central printing unit or units 3 M and the external printing units 2 , 5 . A printing press consisting of seven printing units 2 , 3 , 5 thus has four off-center printing units 3 A.

The invention is based on the fact that the sheet-fed rotary printing press consists of at least three printing units 2 , 3 , 5 .

The printing units 2 , 3 , 5 each contain a printing cylinder 7 , a blanket cylinder 8 , a plate cylinder 9 and a transfer cylinder 10 .

The sheet-guiding cylinder 7 ; 10 - pressure cylinder 7 and transfer cylinder 10 - have gears 11 ; 12 on, wherein the gears 11 ; 12 adjacent cylinders 7 ; 10 mesh with one another and thus form a closed gear train 13 . The gear train 13 is part of the drive system of the printing press.

The impression cylinder 7 and transfer cylinder 10 have a double diameter compared to the rubber and plate cylinders 8 , 9 and the assignment of the impression cylinder 7 and transfer cylinder 10 takes place at an angle α which is between 10 to 20 ° (see FIG. 1).

Fig. 3 shows the allocation of the driving pinions 14, 15 to the gear 11 of the pressure cylinder 7.

However, there is the same success if the drive pinion 14 , 15 the gear 12 of the respective pressure cylinder 7 following transfer cylinder 10 are assigned. The drive pinion 11 or 12 and thus only one printing unit 2 , 3 , 5 assigned to the printing press.

The drive pinions 14 , 15 can be assigned to each printing unit 2 , 3 , 5 of the printing press. However, it has proven to be advantageous to assign the drive pinions 14 , 15 to a center printing unit 3 M or one of the two outside printing units 2 , 5 .

By assigning the drive pinions 14 , 15 to a printing group 2 , 3 , 5 , this becomes the driving printing group 2 or 3 or 5 . The drive power required is transmitted from the drive printing unit 2 or 3 or 5 via the gear train 13 to the other printing units 2 , 3 , 5 .

FIG. 2 schematically shows the gear train 13 according to the embodiment according to FIG. 1.

As Fig. 3 shows, the drive pinion 14, 15 arranged on the circumference of the gear 11 in a certain distance to each other.

The drive of the drive pinions 14 , 15 is not shown since this is not the subject of the invention.

By assigning the drive pinions 14 , 15 to one another, the inner angle β is created. The angle β is chosen so that the resultants of the radial forces acting on the pressure cylinder leg through the drive pinions 14 , 15 via the gearwheel 11 are almost or completely canceled out.

The size of the inner angle β depends on

• - Position of the drive unit 2 or 3 or 5 in the sheet-fed rotary printing press,
• - Power split between the drive pinions 14 , 15 ,
• - The number of printing units 2 , 3 , 5 , which the printing press has.

The power flow on sheet-fed rotary printing presses is shown in a symbolized representation in FIGS . 4a to 4c. The printing units 2 , 3 , 5 are drawn as a box, the double arrows symbolize the drive printing unit 2 or 3 or 5 .

The arrow shown in broken lines shows the sheet run direction.

The printing unit output (DWL) to be delivered to the rear and / or to the front by the drive printing unit 2 or 3 or 5 is likewise marked with.

The drive power required by the drive printing unit itself is not designated with.

In Fig. 4a the driving printing unit is the delivery print engine 5. There are 0 DWL to the rear and 6 DWL to the front.

In FIG. 4b, the driving printing unit 2 is fixed printing unit 2.

There are 2 DWL to the rear and 0 DWL to the front.  

If an external printing unit 2 , 5 becomes the drive printing unit, the inside angle β of the drive pinion 14 ; 15 , 75 ± 15 degrees; ie the inner angle β is between 60 and 90 degrees.

In Fig. 4c, the average printing unit (printing unit sequence 3) is designed as a driving printing unit 3. 3 DWL are to be submitted equally towards the front and back.

The drive printing unit 3.3 ; 3M is therefore a mid-printing unit 3 M.

When using a real or fake center pressure unit 3 M, the inner angle β which is enclosed by the drive pinions 14 , 14 is 160 ± 10 degrees. The internal angle β is therefore between 170 and 150 degrees.

In Fig. 4d is a composed of five printing units 2, 3, 5 printing machine is shown, in which an off-center printing unit 3.3; 3 A is used as the drive printing unit. When using an off-center printing unit 3 A as the drive printing unit, the inner angle β is 120 ± 30 degrees; the internal angle β is therefore between 150 and 90 degrees.

List of reference symbols

1 sheet feeder
2 system printing unit
3 subsequent printing unit
3 A off-center printing unit
3 M real or fake center printing unit
5 delivery printing unit
2 , 5 external printing unit
6 sheet delivery
7 printing cylinders
8 rubber cylinders
9 plate cylinders
10 transfer cylinders
7 , 10 sheet-guiding cylinders
11 gears on the pressure cylinder
12 gears on the transfer cylinder
13 gear train
14 , 15 drive pinion
α Constellation of the arc-guiding cylinders 7 , 10
β inside angle

Claims (3)

1. Drive for sheet-fed rotary printing presses in unit construction, consisting of a system printing unit, one or more subsequent printing units and a delivery printing unit, the sheet-fed rotary printing press consisting of three or more printing units with a transfer drum between the printing units and the gears of the printing cylinders and transfer cylinders forming a closed gear train and the drive of the sheet-fed rotary printing press takes place via a gearwheel of a printing unit by means of a drive pinion, the printing and transfer cylinders, which are double in size compared to plates and blanket cylinders, being arranged at an angle α of 10 to 20 °, characterized in that two, one internal angle is used to drive the sheet-fed rotary printing press β-including drive pinions ( 14 ; 15 ) are provided which, when the drive pinions ( 14 ; 15 ) are assigned to a gear ( 11 or 12 ) of an external printing unit ( 2 or 5 ), have a size between 60 and 90 degrees. 2.Drive for sheet-fed rotary printing presses in unit design, consisting of a system printing unit, one or more subsequent printing units and a delivery printing unit, the sheet-fed rotary printing press consisting of three or more printing units with a transfer drum between the printing units and the gears of the printing cylinders and transfer cylinders forming a closed gear train and the drive the sheet-fed rotary printing press via a gearwheel of a printing unit by means of a drive pinion, the double-size printing and transfer cylinders being arranged at an angle α of 10 to 20 ° relative to plate and blanket cylinders, characterized in that two, an internal angle β. are used to drive the sheet-fed rotary printing press Including drive pinion ( 14 ; 15 ) are provided, which when assigning the drive pinion ( 14 ; 15 ) to a gear ( 11 or 12 ) of a real or spurious middle printing unit ( 3 M) has a size between 150 to 170 degrees. 3. Drive for sheet-fed rotary printing presses in unit construction, consisting of a system printing unit, one or more subsequent printing units and a delivery printing unit, the sheet-fed rotary printing press consisting of five or more printing units with a transfer drum between the printing units and the gears of the printing cylinders and transfer cylinders forming a closed gear train and the The sheet-fed rotary printing press is driven by a gearwheel of a printing unit by means of a drive pinion, the double-size printing and transfer cylinders compared to plate and blanket cylinders being arranged at an angle α of 10 to 20 °, characterized in that two, an internal angle β, are used to drive the sheet-fed rotary printing press Including drive pinion ( 14 ; 15 ) are provided, which when assigning the drive pinion ( 14 ; 15 ) to a gear ( 11 or 12 ) of an eccentric printing unit ( 3 A) has a size between 90 to 150 degrees.