EP0429884A1 - Folder for a printing press - Google Patents

Abstract

The invention relates to a folder of a rotary printing machine, in which a first transport unit (7) and a second transport unit (8) are assigned to one another in such a manner that the folded copies (5) leaving the first transport unit (7) at high speed (V) pass directly into the second transport unit (8) and are braked to a low speed (v) by a deceleration device (9) of at least one gripping element (15). …<IMAGE>…

Description

The invention relates to a folder for a printing press.

Methods and devices for changing the conveying speed of paper products are known from the prior art.

From EP-OS 0 189 897 A2 an apparatus for increasing the conveying speed of paper products is known, in which five rollers arranged in a star shape and rotatable about a common axis are arranged over a first endless belt. A further endless belt running over several deflecting rollers is guided parallel to the first endless belt over two of the rollers arranged in a star shape during a partial stretch. The rotational speed of the rollers arranged in a star shape differs from the rotational speed of the two endless belts and causes an acceleration of the paper products.

The disadvantage of this device is that three separate drives or a drive with intermediate step-up or step-down gears are required; synchronization of the endless belts is therefore quite complex and expensive.

Another unfavorable feature of the device can be seen in the fact that the paper products are exposed to strong mechanical stresses due to the rollers, since the rollers arranged in a star shape bulge the first endless belt downward, despite the resilient mounting.

On the basis of this prior art, the object of the invention is to improve the accuracy of the product delivery in the folder of a rotary printing press for a large number of paper types.

According to the invention, the object is achieved in that a first transport unit and a second transport unit are arranged with respect to one another in such a way that the folded copies leaving the first transport unit at high speed (V) go directly into the second transport unit and are slowed down by at least one gripping element to a low one Speed (v) are braked.

It is advantageous that the folded copies are not detected at their front edge for slowing down, but are correctly aligned in a stream of shingles by one or more gripping elements. Subsequent processing of the folded copies is thereby considerably simplified. The use of two transport units allows the fold copies to be guided precisely at different transport speeds.

In a favorable embodiment of the invention, the folded copies are conveyed in the first transport unit at a distance C which is greater than the length of the folded copies and conveyed in a shingled arrangement in the second transport unit.

The advantage of this embodiment of the invention is the slowdown to a short deceleration path in the folder.

In a preferred embodiment of the subject matter of the invention, the deceleration device comprises a shaft, cylinder faces and a hollow cylinder, in which at least one gripping element is arranged on shafts, the tangential speed of which corresponds to the low speed (v).

It is advantageous in this embodiment that there is no relative speed between the conveyor belt and the gripping element and thus the braking action on the top and bottom of the folded copies starts at the same time. As a result of the rotation of the deceleration device, the gripping elements implement a periodic braking to the speed of the conveyor belt of the second deceleration unit.

In further design options, gripping elements can be arranged fixedly or rotatably in the deceleration device.

Another favorable embodiment of the subject matter of the invention provides that the gripping elements rotate in the opposite direction with respect to the rotation of the deceleration device.

The rotation of the gripping elements advantageously allows an effective delay of the folded copies entering the second transport unit. The gripping elements, which rotate counter to the transport direction of the lower conveyor belt, allow uniformly scaled fold copy delivery even at high feed speeds.

Another cheap variant of the subject matter of the invention provides that one pulley is attached to the housing wall and one pulley is assigned to shafts, via which a belt rotates. In this way, a safe drive of the gripping elements can be achieved in a compact, space-saving design.

The further development of the subject matter of the invention provides that the transport units comprise endless conveyor belts on which the first or the second sequence of folded copies is conveyed, the lower conveyor belts are moved by driven cylinders which work together in such a way that the relationship between low speed ( v) and high speed (V) is maintained, that the decelerator grips copies at the right moment and that the speed (V) corresponds to that of the incoming product stream due to the connection to the printing press. This ensures an exact, synchronous interaction of the individual transport units and the deceleration device, which does not require readjustment and remains constant over time.

A further embodiment provides that adjusting devices are provided in order to regulate the height of the axis of rotation of the cylinder of the lower conveyor belt and to adjust the position of the gripping elements of the deceleration device. This allows the deceleration device to be easily adapted to different types of paper and to different types of folds, the distance between the folds in the stream of shingles also being adjustable.

In another embodiment of the invention, the first transport unit and the second transport unit each comprise an endless upper transport belt, which corresponds to the respective lower transport belt, in order to ensure the sequence of the folded copies, the driven cylinders cooperating with one another in such a way that in the first transport unit the upper one Conveyor belt and the lower conveyor belt assume the speed (V) and the driven cylinders of the second transport unit work together so that the upper and lower conveyor belts assume the speed (v). It is advantageous to guide the folded copies on the top and bottom at the same speeds, so that slipping of the folded copies is prevented and uniform delivery is achieved.

Another favorable embodiment provides that the lower conveyor belt and the upper conveyor belt of the first transport unit rotate on driven cylinders, the axes of rotation of which lie in a transversely inclined plane. This supports the transition of the folded copies emerging from the first transport unit into the second transport unit and therefore also allows high production speeds.

In a further embodiment, it is provided that the front area of the upper conveyor belt of the second transport unit overlaps with the rear area of the upper conveyor belt of the first transport unit and that the folded copies are guided during the transition from the first transport unit to the second transport unit. The advantage of this embodiment is the guidance during the transition through moving belts, so that no relative movements occur between the top and bottom of the folded copy and the conveyor belts.

Finally, in a further embodiment, the upper conveyor belts consist of several belts, with a shaft being provided after the first transport unit, which receives a plurality of rollers, which are independent of rotation, and a belt of the upper conveyor belt of the first transport unit on one roller and one belt each of the upper belt of the second transport unit on another roller. In this way, a continuous upper hinge guide can be achieved in a space-saving design. The independence of the rotation of the individual rollers from one another enables the belts to be tensioned evenly.

Finally, an embodiment is provided in which the deceleration device comprises a hollow cylinder which has at least one gripping element and that the belts of the upper conveyor belt of the second transport unit connect the outlet of the first transport unit to the lower conveyor belt of the second transport unit, by the belts between rollers and on run off the jacket of the hollow cylinder.

The spreading of the entry for the folded copies into the second transport unit, given by the band guide, is advantageous. This favors the transition from the inclined exit from the first transport unit to the subsequent second transport unit.

• Fig. 1 ein Längsschnitt durch einen erfindungsgemäßen Falzapparat,
• Fig. 2 einen Schnitt durch die Verlangsamungseinrichtung des Falzapparates,
• Fig. 3 den Antrieb von Greifelementen,
• Fig. 4 eine sich überschneidende Bänderführung an der ersten Transporteinheit,
• Fig. 5 eine Seitenansicht des Antriebs und
• Fig. 6 eine Antriebsansicht von oben dargestellt sind.

The features of the invention are explained below with reference to the drawing, in which

• 1 is a longitudinal section through a folder according to the invention,
• 2 shows a section through the slowdown device of the folder,
• 3 the drive of gripping elements,
• 4 shows an overlapping belt guide on the first transport unit,
• Fig. 5 is a side view of the drive and
• Fig. 6 are a drive view from above.

In Fig. 1 runs a web 1, which receives a first longitudinal fold in a not shown former, between a cutting cylinder 2 and a puncture cylinder 3. There it is cut into successive fold copies 5. These fold copies 5 receive the first transverse fold when point cylinder 3 is transferred to the jaw cylinder 4. The folding copies 5 are removed from the folding jaw cylinder 4 by scrapers 6. Behind the folding jaw cylinder 4, a first transport unit 7 is provided, onto which the folding copies 5 removed from the scrapers 6 arrive. The folded copies 5 are conveyed in the transport unit 7 at the speed V prevailing in the upstream printing press. In the transport unit 7, the folded copies 5 follow one another at a distance C, which corresponds to the circumference of the printing cylinder. The length L of the folding copies 5 corresponds to half the distance C, since the transverse fold is made by the folding knife between the puncturing cylinder 3 and the folding jaw cylinder 4 in the middle of the separated web sections.

In a second transport unit 8, which is arranged behind the first transport unit 7, the folded copies 5 follow one another at a distance p, that is to say they overlap one another in scale form. The speed at which the folded copies 5 are conveyed in the second transport unit 8 is v and is given by the relationship

The two transport units 7 and 8 are arranged with respect to one another in such a way that the folded copies 5 emerging from the first transport unit 7 at the speed V reach the second transport unit 8 directly and are braked at the right moment by a deceleration device 9. Each incoming folder 5 arrives at speed V via a folder 5 preceding it, which is transported at speed v. If the distance p is reached when the folded copies 5 are pushed over one another, the new folded copy is pressed against the belts of the transport unit 8 by gripping elements 15, the tangential speed of which corresponds to the speed v, so that the new folded copy assumes the speed v. The gripping elements 15 can for example be designed as brake rollers.

The transport units 7 and 8 comprise lower conveyor belts 20 and 21, which consist of several narrow belts arranged next to one another. The conveyor belts 20, 21 rotate around cylinders so that a driven cylinder 22 moves the endless conveyor belt 20, a driven cylinder 23 moves the endless conveyor belt 21. The non-driven cylinders and rollers are used to tighten and deflect the belts. The position of the cylinder 24 of the second transport unit 8 is adjustable such that the strength of the braking can be adjusted by turning the cylinder 24 on or off the deceleration device 9. The two transport units 7 and 8 also have upper conveyor belts 25 and 26. The driven cylinder 27 drives the upper conveyor belt 25, the upper conveyor belt 26 is moved by the driven cylinder 28. The driven cylinders 22, 23 and 27 and 28 work together in such a way that the associated conveyor belts have the same speed.

As is apparent from Fig. 2, the deceleration device 9 has a shaft 10 which is rotatably mounted in the housing 11 of the folder. Two cylinder faces 12A and 12B are arranged on the shaft 10, which carry a hollow cylinder 13. At a distance R measured between the respective axes of rotation, two shafts 14A and 14B are provided opposite one another, each of which has a plurality of gripping elements 15 with the radius r. The peripheral surfaces of the gripping elements 15 are provided with an elastomer. In the hollow cylinder 13, openings are provided on the lateral surface for the gripping elements 15, since the sum of the radii r + R is greater than the radius of the hollow cylinder 13. Two pulleys 16A and 16B of diameter D are provided opposite the cylinder faces 12A and 12B on the housing side. while each of the shafts 14A and 14B has a pulley 17A and 17B of diameter d. A belt 18A rotates on the pulleys 16A and 17B, while the belt 18B rotates around the pulleys 17A and 16B, thus driving the shafts 14A and 14B. The deceleration device 9 rotates at such a speed that the tangential component of the speed of the hollow cylinder 13 is greater than the speed v, while the gripping elements 15 rotate at a speed in the opposite direction so that the difference is compensated for. This means that the gripping elements 15 have a tangential speed equal to the speed v. The speed of rotation of the deceleration device 9 is equal (in revolutions per unit of time) to the stream of folding copies (number per unit of time) divided by the number k of gripping points that is provided. In the present case, this is two, with a new fold copy 5 entering the transport unit 8 being braked by the gripping element 15 following on the circumference of the hollow cylinder 13.

bestimmbar.In Fig. 3 the drive of the gripping elements is shown. The ratio D / d of the pulley diameter is from the relationship

determinable.

befände. R ist größer als T und aus dem dargestellten Beispiel ergibt sich, berücksichtigt man die Werte von p und von k, daß T kleiner als r, sogar kleiner als r/2 ist.In this connection it should be noted that in a variant in which a gripping element would be firmly attached to the cylinder jacket as a simple thickening, the acting surface of this gripping element is at a distance with respect to the axis of rotation of the cylinder

would be. R is greater than T and from the example shown, taking into account the values of p and of k, it follows that T is less than r, even less than r / 2.

In addition to the belt drive described, there are further drive variants for the gripping elements 15. For example, fixed gears arranged coaxially to the shaft 10 can be provided in the housing 11. On each of the shafts 14A and 14B there would be a gearwheel, which could mesh with the fixed gearwheels via a gear train, rotatably arranged on the cylinder faces 12A and 12B. The belt drives can be replaced with gear counters.

In another variant, the gripping elements 15 could be driven in a manner fixed to the housing and arranged coaxially to the shaft 10 thanks to a gearwheel with internal teeth. Conventional gear wheels are then arranged on the shafts 14A and 14B, which mesh with the internally toothed wheel.

4 shows an overlapping belt guide behind the first transport unit. The cylinder designated 27 there consists of rollers 46 and 47 arranged next to one another on a shaft 45. The belts of the upper conveyor belt 26 are guided over the rollers 47 rotating loosely on the shaft 45. The rollers 47 drive the belts of the upper conveyor belt 25 of the first transport unit 7. The shaft 45 is rotatably mounted in the housing 11 of the folder.

The drives assigned to FIGS. 2 and 4 are shown in FIGS. 5 and 6.

Outside the housing 11, several drive trains can be seen, with which a synchronous drive takes place in both transport units. The cylinders 23, 28, 27 and 22 required to drive the belts in the two transport units 7 and 8 are driven without slippage via gearwheels 30, 31, 32 and 33. A pulley 35 is arranged on the axis of the gearwheel 30 and works together with the pulley 34 via a belt 36, which is fastened on the shaft of the jaw cylinder 4. From the shaft on which the toothed wheel 31 is seated, a drive train goes to the shaft 10 of the deceleration device 9 via a pulley 37, a belt 39 and a pulley 38. This is also integrated in the synchronous drive of the folder. A belt drive, consisting of two pulleys 40 and 41 and a belt 42, completes the drive configuration of the individual shafts.

To clarify the geometrical position, reference is made to FIG. 5, which particularly shows the orientation of the individual axes of rotation with respect to one another.

REFERENCE SIGN LIST

• 1 lane
• 2 cutting cylinders
• 3 point cylinders
• 4 jaw cylinders
• 5 folded copies
• 6 wipers
• 7 transport unit
• 8 transport unit
• 9 slowdown unit
• 10 wave
• 11 housing
• 12A cylinder face
• 12B cylinder face
• 13 hollow cylinder
• r14A shaft
• 14B wave
• 15 gripping element
• 16A pulley
• 16B pulley
• 17A pulley
• 17B pulley
• 18A strap
• 18B strap
• 19th
• 20 lower conveyor belt
• 21 lower conveyor belt
• 22 driven cylinder
• 23 driven cylinder
• 24 cylinders
• 25 upper conveyor belt
• 26 upper conveyor belt
• 27 driven cylinder
• 28 driven cylinders
• 29
• 30 gear
• 31 gear
• 32 gear
• 33 gear
• 34 pulley
• 35 pulley
• 36 straps
• 37 pulley
• 38 pulley
• 39 straps
• 40 pulley
• 41 pulley
• 42 straps
• 43
• 44
• 45 wave
• 46 rolls (fixed)
• 47 rolls (loose)

Claims (14)

1. folding apparatus for a printing press, the folding products being exposed to system pressure,
characterized,
that a first transport unit (7) and a second transport unit (8) are arranged in relation to one another such that the folded copies (5) leaving the first transport unit (7) at high speed (V) go directly into the second transport unit (8) and through one Slowing device (9) can be braked to a low speed (v) by at least one gripping element (15). 2. folder according to claim 1,
characterized,
that the folded copies (5) in the first transport unit (7) are transported with the distance C, the is greater than the length of the folded copies (5) and the folded copies (5) are transported in a second transport unit in a shingled arrangement. 3. folder according to claim 1,
characterized,
that the deceleration device (9) comprises a shaft (10), cylinder faces (12A, 12B) and a hollow cylinder (13) in which at least one gripping element (15) is arranged on shafts (14A, 14B), the tangential speed of the low speed ( v) corresponds. 4. folder according to claim 3,
characterized,
that the gripping elements (15) are fixed in the deceleration device (9). 5. folder according to claim 3,
characterized,
that the gripping elements (15) are round and rotatably mounted in the deceleration device (9). 6. Folding apparatus according to claim 3,
characterized,
that the gripping elements (15) rotate in the opposite direction with respect to the rotation of the deceleration device (9). 7. folder according to claim 1,
characterized,
that one pulley (16A and 16B) is attached to the housing wall (11) and one pulley (17A and 17B) is assigned to the shafts (14A and 14B), through which a belt (18A and 18B) rotates. 8. folder according to one or more of claims 1 to 7,
characterized,
that the transport units (7, 8) comprise endless conveyor belts (20, 21) on which the first and second series of folded copies (5) are conveyed, the lower conveyor belts (20, 21) by driven cylinders (22, 23) are moved, which work together in such a way that the ratio between low speed (v) and high speed (V) is maintained, that the decelerator (9) grips copies at the right moment (5) and that through the connection to the printing press Speed (v) corresponds to the incoming product stream. 9. folder according to claim 8,
characterized,
that adjusting devices are provided to regulate the height of the axis of rotation of the cylinder (24) of the lower conveyor belt (21) and to adjust the adjustment of the gripping movement of the deceleration device (9). 10. Folding apparatus according to one of claims 8 or 9,
characterized,
that the first transport unit (7) and the second transport unit (8) each comprise an endless upper conveyor belt (25, 26) which corresponds to the lower conveyor belt (20, 21) in order to ensure the succession of the folded copies (5), the driven cylinders (22, 27) work together so that in the first transport unit (7) the upper conveyor belt (25) and the lower conveyor belt (20) assume the speed (V) and the driven cylinders (23, 28) of the second transport unit (8) work together so that the upper conveyor belt (26) and the lower conveyor belt (21) assume the speed (v). 11. Folding apparatus according to claim 9,
characterized,
that the lower conveyor belt (20) and the upper conveyor belt (25) of the first transport unit (7) rotate on driven cylinders (22, 27), the axes of rotation of which in a transversely inclined plane lie. 12. Folding apparatus according to one of claims 10 or 11,
characterized,
that the front area of the upper conveyor belt (26) of the second transport unit (8) overlaps with the rear area of the upper conveyor belt (25) of the first transport unit (7) and the folded copies (5) at the transition from the first transport unit (7) the second transport unit (8) are guided. 13. Folding apparatus according to claim 12,
characterized,
that the upper conveyor belts (25, 26) consist of several belts and after the first transport unit (7) a shaft (45) is provided which receives a plurality of rollers (46, 47), the rollers (46, 47) independent of each other in rotation and a belt of the upper conveyor belt (25) rotates on a roller (46) and a belt of the upper conveyor belt (26) on a roller (47). 14. Folding apparatus according to claim 13,
characterized,
that the deceleration device (9) comprises a hollow cylinder (13) which has at least one gripping element (15) and that the belts of the upper conveyor belt (26) of the second transport unit (8) have the exit of the first transport unit (7) with the lower conveyor belt ( 21) of the second transport unit (8), in which the belts run between the rollers (47) and on the jacket of the hollow cylinder (13).

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