DE4139667A1 - Pivot suction system in sheet guide cylinder of sheet rotary print machine - involves coupling mechanism of pivot system ensuring register and accurate sheet turning - Google Patents

Abstract

The sheet rotary printing machine can be adjusted to printing on first side only or on both sides with the sheet turned in accordance with the sheet rear edge turning principle. Two correlative sheet holding systems which work together are provided, which are arranged on driven pivot shafts coupled by means of tooth segments. The pivot shafts (5,6) are arranged fixed by means of at least two axially space gearwheel pairs (7) which are displaced in the radial plane, with a connected toothing area via a synchronisation area. A pivot system control gear (22-24,25) fitted to a gripper pivot shaft (6) is arranged on both sides on the sheet guide cylinder (1). USE - A drive for the pivot system in sheet guide cylinders of sheet rotary printing machine.

Description

The invention relates to a drive for vibration systems in Sheet guiding cylinders of sheet-fed rotary printing machines according to the preamble of claims 1 and 2.

The vibrating system is known to consist of a suction cup oscillator and a gripper oscillator, the sucker swings the sheet from the ge closed surface of the upstream cylinder or drum takes over and in the swiveled-in position on the gripper swivel ger passes, who after swinging out the bow to the following cylinder.

The vibration systems become relative to the movement of the arches feed drum (turning drum) in the in and out swing moving phase on a circular path, the Schwingwin is the same for both transducers.

The vibrating systems are coupled by means of a tooth segment and the drive takes place via the suction oscillator.

A disadvantage of such a drive for an oscillator system is that the coupling of the vibrating systems only one side of the sheet guide cylinder.

When moving the vibrating systems, it can be twisted vibration waves and thus to transfer errors adversely affects a register-accurate sheet turning can know.

DE-PS 31 46 837 is a drive for a swing system known where the radii of suction oscillators and Grei transducers have a different size. The  Suction transducer has compared to the gripper vibrator a much smaller radius, which makes for the Vacuum cleaner more favorable conditions until delivery of the bow to the gripper system.

According to this document, the radii of the gripper are oscillator and that on the oscillating shaft of the gripper oscillation gers arranged tooth segment the same.

The suction transducer and its have the same radii Tooth segment on.

This is the oscillation angle that the gripper oscillator follows Place the suction cup on the sheet, rela tiv big. The more bespoke claw vibrator must therefore in a short time to take over the sheet from the vacuum to the Suction cups to be swung in. This creates dynami cal disturbances that lead to imprecise sheet acceptance by the Gripper vibrators and thus lead to register errors nen.

Because the vibration systems are driven by the suction oscillator done, it must be stable. This is with a high cost of materials and thus with a larger, connected to moving mass.

In addition, such a drive (coupled Systems using a toothed segment) in sheet guiding cylinders small diameter proved to be a disadvantage because of the small dimensions no space for the swinging movement of the Tooth segments over the entire swing angle is present. Either therefore have to be smaller in sheet guiding cylinders Diameter other drives can be created or it must a weakening of the axis that hinders the oscillating movement of the sheet guiding cylinder.

Based on the disadvantages mentioned in the prior art Technology is the object of the invention, a drive for To create vibration systems in sheet guiding cylinders, the  is dimensionally designed and with coupling of the vibration systems a precise turning of the bow by means of the vibration systems enables and small even in sheet guiding cylinders rer diameter can be used.

The solution according to the invention constantly ensures that Coupling the vibration waves.

This has the advantage that a synchronized movement ab run is achieved.

The coupling takes place either via a first tooth range outside the sheet guide cylinder arranged pair of toothed segments, within a syn chronization area by meshing all teeth ment pairs, or via the inside of the Bogenführungszylin ders arranged segments of tooth segments.

By dividing the toothing of the tooth segments into min at least two levels with an overlap will be less and even deformation of the vibration systems achieved. This is supported by the drive of the necessary drive motor mentes on the gripper vibrating shaft and by the drive both on the side of the gripper vibrating shaft.

This will result in a higher level of work accuracy and therefore one accurate sheet turning and register sheets delivery and transfer achieved.

The gearing area within the Arch guide cylinders arranged tooth segments will be like this placed that the toothed segments not be the pressure cylinder stir and damage it.

Through such an arrangement of the teeth on tooth segments ten is the use of coupled vibration waves by means of Tooth sarge also in smaller bow guide cylinders Diameter possible without the diameter of the cylinder derachse directly next to the bearing in the thigh area  weakened in terms of space requirements for the tooth segments must become.

The different sizes of gripper swing radius too Pitch circle diameter of the gripper vibrating shaft tooth segment or from suction oscillating shaft to suction cup pitch circle Vibrating shaft tooth segments ensure harmonic movement processes over a large angle of rotation of the sheet guide cylinder.

The input of the drive torque via the gripper rocker shaft allows the suction transducer including Vacuum oscillation shaft can be designed with low mass, because these elements are the output link and not moments for the The drive of the gripper vibrator must apply.

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

The attached pictures show

Fig. 1: Detail of a sheet guide cylinder with upstream and downstream printing cylinders

Fig. 2: Detail according to Fig. 1 with different gear ratios

Fig. 3: Schematic representation of the drives and the coupling of the vibration systems in the phase of the connection in the synchronization area.

Fig. 1 shows a sheet guide cylinder 1 of a perfecting machine, which is known for example from the DD-PS 54 703 also like the vibration system, consisting of a suction oscillator 2 and a gripper oscillator 3 , and are therefore not the subject of the invention.

The sheet guiding cylinder 1 is of a first and a second printing cylinder 4.1; 4.2 included.

The points of contact (tangent point) of the impression cylinder 4 and sheet guiding cylinder 1 are marked with t _1.1 and t _1.2 . Sheet guide and impression cylinder 1; 4 are twice the size.

Fixed on the vibrating shafts 5, 6 are the suction vibrating tooth segment 7 and the gripper vibrating tooth segment 8 , each forming a pair of tooth segments 7, 8 .

The radii of the tooth segments 7, 8 are different in length, ie the pitch circle diameter of the gripper oscillating shaft tooth segment 8 is larger than the pitch circle diameter of the suction vibrating shaft tooth segment 7 . Over the length of Sucker and gripper rocker shaft 5, 6 are at least two Zahnsementpaare 7, 8; 7.1, 8.1 seen before, which are arranged axially at a distance. However, more than two pairs of tooth segments 7, 8; 7.1, 8.1 can also be provided (see FIG. 3 ) . The pairs of tooth segments 7; 8 are arranged outside the contour of the pressure cylinder 4 on the curved guide cylinder 1. The pairs of tooth segments 7 , 1; 8,1 are provided within the sheet guiding cylinder 1 .

The toothing of the pairs of tooth segments 7, 8; 7.1, 8.1 is designed such that, depending on the angular position of the vibration systems 2, 3 on the outer pair of tooth segments 7, 8, a first toothed area 9 and on the inner pair of tooth segments 7.1; 8.1, a second toothed area 10 are provided. The first and second toothed areas 9, 10 are arranged offset to one another in the radial plane. (see Fig. 2)

The first and second toothing regions 9 overlap in a common section ; 10th This part of the tooth segment pairs 7, 8; 7.1, 8.1 is referred to as synchronization area 11 .

The suction oscillator 2 consists of the suction holder 13 and the suction 14 with the suction surface 15 .

The suction oscillating radius 16 is thus the distance between the suction surface 15 and the pivot point of the suction oscillating shaft 5 .

The suction oscillation shaft 5 has a smaller diameter than the gripper oscillation shaft 6 .

The gripper vibrator 3 consists of the gripper strike 17 , the gripper tongue 18 and the gripper shaft 19 . The gripper shaft 19 is rotatably mounted in the gripper vibrator 3 and is firmly connected to the gripper tongue 18 .

The drive of the gripper tongue 18 is not shown. The hook swing radius 20 is the distance between the surface of the hook impact 17 and the fulcrum of the hook swing shaft 6 .

According to embodiments of FIG. 1 is the size of suction grippers and swing radius 16, 20 equal to the pitch circle diameter of the respective toothed segment 7, 8.

FIG. 2 shows another variant of the ratios of the size of the pitch circle diameter of the tooth segments 7, 8 to the suction and oscillating radius 16, 20 .

The pitch circle diameter of the gripper vibrating shaft segment 8 is, as in the variant according to FIG. 1, larger than the pitch circle diameter of the suction vibrating shaft segment 7 .

The suction swing radius 16 is larger than the pitch circle diameter of the suction swing shaft tooth segment 7 and the gripper swing radius 20 is smaller than the pitch circle diameter of the gripper swing shaft tooth segment 8 .

A gearwheel 21 is connected to the gripper oscillating shaft 6 in a rotationally fixed manner, into which a toothed roller lever 22 engages, which is rotatably mounted in the sheet guide cylinder 1 and is connected to a lever 23 . The lever 23 carries a cam roller 24 which is associated with a cam 25 arranged on the machine frame.

Control cam 25 , cam roller 24 , lever 23 and the toothed roller lever 22 form the vibration system control gear 22-25 . The vibration system control gear 22-25 is arranged on both sides of the sheet guide cylinder 1 .

The vibrating system is spring-loaded by means of a spring 26 assigned to the suction oscillator 2 .

The mode of operation of the vibration system according to the invention is the following:

The sheet (not shown) is conveyed in face and face printing in a known manner with the leading edge ahead beyond the tangent point t ₁ , 1 and is sucked in the area of the trailing edge by the suction device 14 of the suction oscillator 2 under the periphery of the sheet guiding cylinder 1 and handed over to the gripper vibrator 3 .

This transfers the turned sheet in the swung out position at the tangent point t _1,2 to the printing cylinder 4,2 .

The gripper and suction transducers 3.2 are controlled by the vibration system control gear 22-25 .

This process is known and for example in the patent DD-PS 54 703 described.  

The coupling of the oscillating shafts 5, 6 and the transmission of the oscillating movement from the gripper oscillating shaft 6 to the suction oscillating shaft 5 proceeds according to the invention as follows:

Before the takeover of the sheet at the tangent point t _1,1 (before settling), during the takeover of the sheet by the suction device 14 at the tangent point t _1,1 and in the settling phase for the sheet transfer from the suction vibrator 2 to the gripper vibrator 3 , the tooth segment pairs are 7.1, 8.1 ment couple with the second gear section 10 in contact, ie, which is arranged within the sheet guiding cylinder 1 Zahnseg 7.1; 8.1 is in mesh.

The outer pair of tooth segments 7, 8 is decoupled. Then the coupling takes place via the Synchronisierungsbe range 11 ; Settling phase. In this phase, all tooth segment pairs 7, 8; 7.1, 8.1 connected via tooth mesh.

Thereafter, up to and including the transfer of sheets from the suction oscillator 2 to the gripper oscillator 3 , only the pairs of tooth segments 7, 8 which are on the outside are in meshing engagement via the first toothed region 9 .

The connection of the pairs of tooth segments 7; 8th; 7.1; 8.1 during the swinging and up to the handover of the bow in the tangent point 1, 2 takes place in reverse order. Then the process is repeated as described above.

List of reference symbols

1 sheet guide cylinder
2 suction cups
3 grab arms
4 pressure cylinders
4.1 first impression cylinder
4.2 second pressure cylinder
5 suction oscillating shaft
6 gripper vibrating shaft
7 suction vibrating shaft tooth segment
7.1 suction vibrating shaft tooth segment
8 gripper vibrating shaft tooth segment
8.1 Claw swing shaft tooth segment
7; 8 outer pair of tooth segments
7.1; 8.1 pair of inner tooth segments
9 first tooth area
10 second tooth area
11 synchronization area
13 suction cup holder
14 suction cups
15 suction surface
16 suction swing radius
17 gripper impact
18 gripper tongue
19 gripper shaft
20 gripper swing radius
21 gear
22 roller lever
23 levers
24 cam roller
25 control curve
26 spring
22-25 vibration system control gear
t _1.1 tangent point
t _1.2 tangent point

Claims (5)

1.Drive for vibration systems in sheet guiding cylinders of sheet-fed rotary printing presses which can be used either in straight printing or in face and back printing and in which the sheet is turned in face and face printing according to the principle of the trailing edge application, whereby two correlatively interacting sheet holding systems are provided are fixedly arranged on driven vibration shafts coupled by means of a toothed segment, characterized in that the vibration shafts ( 5; 6 ) are permanently assigned at least two axially spaced-apart gear pairs ( 7; 8; 7.1; 8.1 ) which are arranged in have radial plane offset, by a synchronization area ( 11 ) connected tooth areas ( 9, 10 ). 2.Drive for vibration systems in sheet guiding cylinders of sheet-fed rotary printing presses, which can be used either in straight printing or in face and back printing and in which the sheet is turned in face and face printing according to the principle of the trailing edge application, whereby two correlatively interacting sheet holding systems are provided are fixedly arranged on driven oscillating shafts coupled by means of a toothed segment, characterized in that an oscillating system control gear ( 22-25 ) assigned to the gripper oscillating shaft ( 6 ) is arranged on both sides of the sheet guiding cylinder ( 1 ). 3. Drive according to claim 1, characterized in that the pitch circle diameter of the hook vibrating shaft segment ( 8 ) is greater than the hook swing radius ( 20 ) and that the suction swing radius ( 16 ) is greater than the pitch circle water of the suction rocker tooth segment ( 7 ). 4. Drive according to claim 1, characterized in that at least one pair of toothed segments ( 7; 8 ) outside and at least one pair of toothed segments ( 7.1; 8.1 ) is arranged within the archery cylinder ( 1 ). 5. Drive according to claim 1 and 4, characterized in that the sheet guiding cylinder (1) depending on a sector gear pair (7, 8) preferably on both sides and inside the Bogenfüh approximately cylinder (1) has two toothed segment pairs (7,1; 8,1) are vorgese hen .