EP1921035A2 - Sheet delivery device in a processing machine for sheet material - Google Patents

Abstract

The device (1) has an endless rotating paper sheet conveying system that supplies a sheet material to a delivery pile area. A drum (6) is provided for selectively removing a paper sheet exhibiting at a paper sheet holding unit. The paper sheet holding unit acts as a guide in a delivery direction in front of the delivery pile area. A frame fixed transport module is attached to the drum in a distance such that the transport module (13) can be driven on a sheet material guided to the drum in a rotative manner.

Description

The invention relates to a delivery device on a processing machine for sheet material according to the preamble of claim 1. The delivery device is particularly suitable for a sheet-fed rotary printing press or Bogenrotationslackiermaschine.

A delivery device of this kind is made DE 198 19 490 C1 and DE 198 19 491 C1 known. This delivery device has an endless circulating conveyor system for feeding and depositing sheets on a first delivery stack (main stack). The conveyor system is assigned a acting as a switch, at least one gripper bar having drum, so that by means of the drum certain sheets on a second, arranged below this drum delivery stack can be stored. The second delivery stack is preferably designed as a stacking system with pallet or can be designed as a lattice box, for example for receiving waste paper. In a further development, the second delivery stack can also be embodied as a stacking system with stop means and straight bumpers for the exact stacking edge formation.

A further education is missing DE 102 22 542 A1 with a downstream in the direction of rotation of the drum, drivable sheet transport means known. The sheet transport means may be formed as a belt conveyor or paddle wheel, which is arranged downstream of a second delivery system.

The invention is based on the object to provide a delivery device of the type mentioned above, which allows improved storage of sheet material on the second delivery stack and facilitates the subsequent removal of sheet material.

The object is solved by the training features of claim 1. Further developments emerge from the subclaims.

A first advantage is due to the fact that the guiding and the decrease of the sheet material of the acting as a soft drum is non-positively by means of a drivable transport module. The non-positive guiding or removal is preferably realized with a voltage applied to the transport module vacuum. Alternatively, by adjusting the transport module to the drum circumference, the sheet material may be guided in frictional engagement. Thus, the sheet material can be safely guided and then arranged in an orderly manner on the respective storage device of the second delivery stack.

A second advantage results from the fact that the transport module can be realized in various designs. Thus, in a first embodiment, the transport module can be arranged to extend at least over the minimum format width of the sheet material. In a further development, the transport module can extend beyond the maximum format width of the sheet material. In a second embodiment, the transport module can be arranged at least over the minimum format width in zones (zones) and be adjustable transversely to the conveying direction of the sheet material. In a further development, the transport module can extend in zones (and adjustable transversely to the conveying direction of the sheet material) over the maximum format width of the sheet material.

As a third advantage can be listed that the storage of the sheet material on at least one of the drum acting as a drum adjacent storage device can be realized. If necessary, the drum are associated with several of these storage devices adjacent, for example, a display in packet stack.

In conclusion, the fourth advantage that can be mentioned is that the sheet material can be designed without damage to the respective storage device. Thus, the sheet material can be used again, for example, as a flow sheet. Alternatively, the sheet material can be fed to a further printing process or a further processing.

Fig. 1

eine Auslegevorrichtung an einer Bogenrotationsdruckmaschine mit einem ersten und einem zweiten Auslegerstapel (erste Ausbildung),

Fig. 2

eine Auslegevorrichtung in zweiter Ausbildung,

Fig. 3

eine Weiterbildung der Auslegervorrichtung gem. Fig. 1.

The invention will be explained in more detail using an exemplary embodiment. Showing:

Fig. 1

a delivery device on a sheet-fed rotary printing machine with a first and a second delivery stack (first embodiment),

Fig. 2

a delivery device in second embodiment,

Fig. 3

a development of the jib device gem. Fig. 1.

A sheet-fed rotary printing machine with printing / coating works is followed by a delivery device 1 in the conveying direction 8 of the sheet material. The delivery device 1 consists inter alia of a continuous in the conveying direction 8 sheet conveying system 2 with a plurality of spaced sheet holding means 3, such as gripper systems, wherein the sheet conveying system 2 is preferably designed as a chain conveyor with an associated first, preferably pneumatically actuated sheet guiding device 7. Outside the lower run of the sheet conveying system 2, a recess extending over the format width for discharging the sheet material within the sheet guiding device 7 is arranged at a short distance from the sheet conveying system 2.

The lower run of the sheet conveying system 2 is associated with the sheet material leading drum 6 below in the region of the recess. The drum 6 is drivably mounted in the frame of the delivery device 1 and has at least one sheet holding means 15, for example gripper systems, which cut the recess with their circle. In the present example, the drum is 6 - related on a single-sized plate / forme cylinder - double-sized and thus has two circumferentially arranged gripper systems 15.

For the sheet storage a second boom stack area 5 is downstream of the drum 6 in the direction of rotation. The second delivery stack region 5 has at least one deposit device 10, which receives the sheet material designed in the second delivery region 5.

In the conveying direction 8 before this first delivery stack 4 is a sheet braking device 14 and this upstream of the sheet conveying system 2, the drum 6 is assigned.

The drum 6 acts as a switch for the selective removal or storage of sheet material from the circulating in the conveying direction 8 sheet conveying system 2. For this purpose, the drum 6 is preferably assigned to this in a horizontally disposed portion of the sheet conveying system 2 and the guided on the drum 6 by sheet holding means 15 sheet material is in the second boom stack area 5 can be stored.

For the transport and storage of the sheet material at least one frame-mounted storage transport module 13 of the drum 6 is assigned in a, preferably adjustable distance 16. The transport module 13 is effective under adhesion to the guided on the drum 6 sheet material and is rotatably driven. In this case, each transport module 13 is followed by a storage device 10 for the sheet material in the conveying direction of the drum 6.

The transport module 13 extends in the first embodiment completely transverse to the conveying direction 8 of the sheet material at least over the minimum format width.
In a second embodiment, the transport module 13 extends in zones transversely to the conveying direction 8 of the sheet material at least over the minimum format width. In this case, the transport module 13 arranged in zones is preferably adjustable transversely to the conveying direction 8 of the sheet material. Preferably, the transport module 13 is formed from at least one roller or at least one circulating conveyor belt.

In a preferred embodiment, the transport module 13 is coupled to a pneumatic source. When formed as at least one roller, the roller can be subjected to negative pressure and thus can be used as a suction roller. In training as at least one conveyor belt, the conveyor belt can be subjected to negative pressure and thus can be used as a suction belt.

The drum 6 is shown in the conveying direction (arrow) with a Cartesian coordinate system with four quadrants 1 to IV. In Fig. 1, the transport module 13 is the III. Squares of the drum 6 at a distance 16 assigned. Alternatively, as shown in Fig. 3 - the II. And / or III. and / or IV. Quadrants ever assigned a transport module 13.
In Fig. 1, a second sheet guiding device 9 is arranged to the drum 6 at a defined distance, which in turn is arranged downstream of the transport module 13. If necessary, the transport module 13 may be arranged downstream of a third sheet guiding device 12. The sheet guiding device 12 follows the depositing device 10.
In Fig. 2, the embodiment is analogous to Fig. 1, but the transport module 13 is shown as rotatably driven, circulating conveyor belt. The conveyor belt is in turn downstream of the storage device 10 in the conveying direction of the drum 6.
In Fig. 3, a plurality of transport modules 13, 13 ', 13 "shown, each of which a storage device 10, 10', 10" is arranged downstream. This design is preferably suitable for the formation of packets. Each transport module 13 to 13 "may be followed by a sheet guiding device 12. For reasons of clarity, a sheet guiding device 12 is shown here only on the transport module 13.

Depending on the design, the drum 6 is designed such that the sheet holding means 15 arranged thereon in the region of the associated transport modules 13, 13 ', 13 "by suitable adjusting means, such as gripper opening curves, are opened and the sheet material on the associated storage device 10 - 10" can be stored. The actuating means open the sheet holding means 15 immediately after the sheet removal by the respective transport module 13 - 13 ".

The distance 16 between the drum 6 (lateral surface) and the transport module 13 is manually or motor-adjustable. The rotary drive for the transport module 13 may be coupled to the drive of the drum 6. Alternatively, a self-propelled individual drive can be coupled to the transport module 13. The drive of the transport module 13, in particular in the form of a single drive, is preferably coupled in terms of circuitry to a machine control. Preferably, the peripheral speeds of transport module 13 and drum 6 are the same. If necessary, the peripheral speed of the respective transport module 13-13 "to the peripheral speed of the drum 6 can be changed, so that the transport module 13 can be driven with a peripheral speed deviating from the circumferential speed of the drum 6. In deviation from the peripheral speed of the drum 6, the transport module 13-13" have a positive or negative peripheral speed. For this purpose, the individual drive can be activated or deactivated by the machine control with a corresponding signal.

The transport module 13 may be formed as a rotationally symmetrical body. Preferably, the body is tubular, specially designed as a roller or wheel. Preferably, the roller or the wheel on the periphery openings. In another embodiment, the transport module 13 is designed as a conveyor belt with circumferentially arranged openings.
These openings are coupled to the pneumatic source, so that the transport module 13 can generate a negative pressure (force fit) on the sheet material guided on the drum 6.
In zonal training of the transport module 13 in the form of multiple rolls or wheels or conveyor belts transversely to the conveying direction 8 of the sheet material, each transport module 13 can be set to preferably pressure-free zones or be positioned. This positioning can be realized manually or by motor.
The surface of the rollers or wheels used may be formed of a metallic material or a plastic material. The metallic surface may additionally be adhesively coated with a layer of a plastic material. The conveyor belts are preferably designed as a fabric and / or plastic tape.

In the first embodiment, the storage device 10 is completely height-adjustable (double arrow) formed. In a second embodiment, the storage device 10 is pivotally mounted about a pivot 11 (principle: inclined plane). Depending on the desired stack formation and / or taking into account the modulus of elasticity of the sheet material and / or the arrangement of the transport module 13, the distance (to the drum 6) and / or the inclination of the depositing device 10 can be influenced by means of the formations for a quality-compliant sheet delivery. The adjustability of the respective storage device 10 can be realized manually or by motor (pneumatic or electric drive).

In a further embodiment, the processing machine has an arc inspection device, which is coupled in terms of circuitry and data with a machine control. The sheet inspection device is upstream of the drum 6 in the conveying direction 8. For example, a camera installed on the last printing / coating unit is designed in such a way that each individual sheet material can be checked for any errors (slugs, printing / varnish defects, folds, etc.). If an error is found, the faulty sheet material can be stored in a separate storage device 10, for example, the storage device 10 'instead of 10, or a grid box or other collecting device.

For this purpose, the respective sheet holding system 15 or the associated adjusting means is controlled such that the drum 6, the defective sheet material of the associated storage device 10 supplies. The adjusting means of arranged on the drum 6 sheet holding means 15 and the drive of the transport module 13 are in Dependence of the error analysis created by means of a sheet inspection device can be activated or deactivated by means of a machine control.

1

Auslegevorrichtung

2

Bogenfördersystem

3

Bogenhaltemittel (Bogenfördersystem)

4

erster Auslegerstapelbereich

5

zweiter Auslegerstapelbereich

6

Trommel

7

erste Bogenleiteinrichtung

8

Förderrichtung

9

zweite Bogenleiteinrichtung

10

Ablageeinrichtung

11

Drehgelenk

12

dritte Bogenleiteinrichtung

13

Transportmodul

14

Bogenbremseinrichtung

15

Bogenhaltemittel (Trommel)

16

Abstand

I

erster Quadrant

II

zweiter Quadrant

III

dritter Quadrant

IV

vierter Quadrant

LIST OF REFERENCE NUMBERS

1

A display device

2

Sheet conveyor system

3

Sheet holding means (sheet conveying system)

4

first boom stack area

5

second boom stack area

6

drum

7

first sheet guiding device

8th

conveying direction

9

second sheet guiding device

10

Bin Setup

11

swivel

12

third sheet guiding device

13

transport module

14

Sheet braking mechanism

15

Sheet holder (drum)

16

distance

I

first quadrant

II

second quadrant

III

third quadrant

IV

fourth quadrant

Claims (10)

A delivery device on a sheet-fed processing machine having an endlessly circulating sheet conveying system feeding the sheet material to a first delivery stacking section and having a selective discharge sheet drum in the conveying direction in front of the first delivery stacking section, the drum being associated with the lower section of the sheet conveying system is and the sheet material is stored in a second boom stack area,
characterized,
in that at a distance (16) at least one frame-mounted transport module (13) is associated with the drum (6),
that the transport module (13) is effective and rotatably driven under adhesion to the on the drum (6) guided sheet material, and
that each transport module (13) comprises a storage device (10) is arranged downstream of the sheet material. Delivery device according to claim 1,
characterized,
that the transport module (13) extends completely transversely to the conveying direction (8) of the sheet material at least over the minimum format width. Delivery device according to claim 1,
characterized,
that the transport module (13) extends in zones transverse to the conveying direction (8) of the sheet material at least over the minimum format width. Delivery device according to claims 1 and 3,
characterized,
that the transport module (13) is zonal adjustable transversely to the conveying direction (8) of the sheet material. Delivery device according to claim 1,
characterized,
that the transport module (13) is formed from at least one roll or at least one circulating transport belt. Delivery device according to claim 1,
characterized,
that the transport module (13) is coupled to a pneumatic source. Delivery device according to claim 1,
characterized,
that the drive of the transport module (13) circuitry coupled to a machine control. Delivery device according to claim 1,
characterized,
that the transport module (13) with a to the circumferential speed of the drum (6) different peripheral speed is driven. Delivery device according to claim 1,
characterized,
that in the conveying direction (8) of the drum (6) is arranged upstream of a circuit-controlled with a machine control sheet inspection device. Delivery device according to claims 1, 7 and 9,
characterized,
in that the adjusting means of the sheet holding means (15) arranged on the drum (6) and the drive of the transport module (13) can be activated by means of a machine control as a function of the error analysis produced by means of the sheet inspection device.

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