WO2003037628A1 - Drawing-in device for drawing in a web of material - Google Patents

Abstract

The invention relates to a drawing-in device for drawing in a web of material into a machine, the web of material being at least partially coupled with the drawing-in device. The drawing-in device (01) can be optionally equipped with at least one functional element (11, 12) that can be detachably fixed on the drawing-in device.

Description

description

Pull-in means for pulling in a material web

The invention relates to a drawing-in means for drawing in a material web according to the preamble of claims 1 or 3.

Such feeding means are used in particular in web-fed rotary printing presses in order to pull the beginning of the web of the new paper web through the printing press after a roll change. In order to achieve different printing results, the paper web can be guided through the printing press along different paths in modern web-fed rotary printing presses, so that the drawing-in means must be reversed accordingly along different drawing-in paths. Due to the complex geometry of the necessary pull-in paths, for example in the area of turning bars, the pull-in means must be guided in three-dimensional guides running through the room.

DE 94 15 859 U1 discloses a pull-in means designed in the manner of a metal strip. This metal strip can either be designed as an endless strip, which is guided over deflection rollers. Alternatively, a metal strip section can be used, the two ends of which are each wound on a drivable winding roll.

DE 22 41 127 A1 discloses a pull-in means which is designed as a spring steel strip and is guided between two parallel tubes arranged at a short distance from one another. Functional surfaces are profiled into the spring steel strip, which engage in the recesses of a drive pulley, so that the drive force can be transmitted from the drive pulley to the pull-in means. DE 44 09 693 C1 describes the use of a side arch chain as a pull-in means. The rivet bolts of the side arc chain are conical, so that the side arc chain is axially movable in each chain link by a small area deviating from the direction of the longitudinal axis.

EP 0 418 903 A2 describes a paper web holding part which is fastened to the pull-in means by means of a flexible band. In addition to being fastened by means of the band, it can be secured to the pull-in means by means of a clip, for example when returning the pull-in means.

DE 100 24 013 C1 describes a pull-in chain on which a coupling element designed as a driver is detachably arranged.

DE 198 02 194 A1 discloses a feed element in which rotationally symmetrical bodies, e.g. B. balls are embedded. The balls can move in openings in the feed element with little friction, but remain centered in the respective opening.

The invention has for its object to provide a pull-in means for pulling a web of material.

The object is achieved by the features of claims 1 or 3.

An advantage that can be achieved with the invention is, in particular, that the optional equipping of the pull-in means with functional elements creates a flexible system that can be converted and adapted in a simple manner depending on the application and functional requirements. The pull-in means designed as a metal strip section represents a base support element on which, depending on the application, the different configurations can be realized by fixing different functional elements. This is particularly advantageous if the material web that is drawn in is divided in the longitudinal direction during the drawing in and the partial webs that are created as a result are to be drawn in along different drawing paths. To implement this function, the pull-in means can be equipped with a plurality of coupling elements, to each of which a partial web can be coupled. If a whole web of material is to be retracted at a later point in time, all but one of the coupling elements are removed from the infeed means.

The resulting feed system with various functional elements that can be combined to create the feed means that a wide variety of pulling tasks can be solved flexibly.

Embodiments of the invention are shown in the drawings and are described in more detail below.

Show it:

Figure 1 shows a first embodiment of a broken Einzugmitteis in top view.

FIG. 2 shows a metal strip section of a pull-in center according to FIG. 1;

Fig. 3 shows a second embodiment of a broken-in Einzugmitteis in top view;

FIG. 4 shows a metal strip section of a feed means according to FIG. 3; 5 shows a cross section through the pull-in means according to FIG. 1 along the section line V - V;

6 shows a cross section through the pull-in means according to FIG. 3 along the section line VI-VI;

FIG. 7 shows the pulling means guided in a guide according to FIG. 3 in cross section;

8 shows the pull-in means guided in a guide;

9 shows a cross-section of a transfer station of a third exemplary embodiment of a pull-in means.

In a work machine, in particular a web-fed rotary printing press, a start of a material web 13, e.g. B. a paper web 13, by means of a feed means 01.

The pull-in means 01 shown in FIGS. 1 and 5 essentially consists of a finite band section 02 which is largely dimensionally stable in its longitudinal direction, in particular a metal band section 02 (see FIG. 2) which is covered at least in sections with a plastic layer 03 , The metal strip section has e.g. B. a thickness d02 of a maximum of 0.3 mm, in particular a maximum of 0.2 mm. That means the z. B. made of spring steel metal band section 02 forms the core of the Einzugmitteis 01, in which tensile and shear forces can be transmitted, whereas the required functional surfaces of the Einzugmitteis 01 are realized by the coating 03 designed as a plastic layer 03 by means of appropriate shaping. The plastic layer 03 represents, for example, individual carrier elements 03, e.g. B. plastic segments 03, to which functional elements described in more detail below can be releasably attached. The plastic layer 03 is structured in sections. Sections alternate as functional surfaces 04, z. B. tooth flanks 04, in which a gear for driving the feed means 01 can engage, and sections with as functional surfaces 06, z. B. sliding elements 06, which can come to rest in a profile guide not shown here, in pairs in the longitudinal direction of the feed means 01. In the intermediate regions 07, through which the sections of the tooth flanks 04 and the sliding elements 06 are separated, the metal band section 02 can only be covered with a thin plastic layer, so that the pull-in element 01 can be twisted along its longitudinal axis.

To drive the feed element 01 through the non-illustrated rotary printing press, guides 32, z. B. guide profiles 32 (Fig. 7) arranged. Drive motors with gearwheels are provided at certain intervals along the guide profile 32, the distance between the gearwheels being chosen to be smaller than the length of the feed means 01, so that the feed means 01 can be transferred from one gearwheel to the next during the conveyance along the feed path. Due to the deformability of the pull-in means 01, complex guide geometries can be realized.

Clip structures 08 and 09 are formed on the coating 03 formed as a plastic layer 03 on the top and bottom of the metal strip section 02, each lying opposite the tooth flanks 04 and the sliding elements 06. Various functional elements can be clipped into these clip structures 08 or 09 in a form-fitting manner, in order to equip the pull-in means 01 with the required functional elements in accordance with the respective intended use. The pull-in means 01 shown in FIG. 1 is equipped with two functional elements 11, 12. The first functional element 11 is designed in the manner of a coupling element 11, to which a material web 13 can be coupled, for example using a pull-in tip. The functional element 12 is, for. B. formed as an initiator element 12 and can be evaluated contactless by a sensor. By evaluating the position of the initiator element 12, the position of the pull-in tip in the printing press can be determined. If the pull-in means 01 is to be used for a different type of pull-in task, the functional elements 11, 12 can be removed in a simple manner and the pull-in means 01 can be equipped with other functional elements in sufficient numbers.

Fig. 2 shows the metal strip section 02 in a view from above. In order to be able to permanently and reliably connect the plastic layer 03 or the sections to the metal strip section 02, recesses 14, 16 are provided in the metal strip section 02, through which the plastic layer 03 flows in a form-fitting manner. The annular recesses 14 are arranged in pairs in the area of the tooth flanks 04 or sliding elements 06 or the clip structures 08, 09, since in these areas the greatest forces have to be transferred from the plastic layer 03 to the metal strip section 02. The recesses 16 are slit-shaped transversely to the longitudinal axis of the metal strip section 02, whereby the deformability and in particular the torsion of the metal strip section 02 is increased.

3 and 6 to 8 illustrate a second exemplary embodiment of a pull-in means 20. The core of the pull-in means 20 is in turn guided by a band section 21, e.g. B. metal strip section 21 (see FIG. 4), wherein the coating 22 formed as a plastic layer 22 is releasably connected to the metal strip section 21 in this embodiment. For this purpose, carrier elements 23, for. B. slotted plastic segments 23 pushed from the side onto the metal strip section 21 and reach through with corresponding projections 25 z. B. the circular recesses 24 or the slot-shaped recesses 26 in the metal strip section 21. In order to produce a pull-in means 20 of basically any length, a metal strip section 21 of corresponding length must be cut off and can then be made with a sufficient number of plastic segments 23 be provided. Different configurations of feed means 20 can be produced by suitably arranging the individual plastic segments 23.

Each plastic segment 23 has, for. B. two functional surfaces 27, z. B. two tooth flanks 27, in which a gear for driving the pull-in means 20 can engage. Plastic segments with sliding elements from FIG. 1 can also be provided. On the opposite side of the plastic segments 23, two recesses are provided which, after the plastic segments 23 have been attached to the metal strip section 21, come to lie congruently above the recesses 24. As a result, fastening bolts 28 can be used to optionally equip the pull-in means 20 with functional elements 11; 12; 29 are inserted. In the embodiment shown in FIG. 3, two functional elements 29 are fitted on the pull-in means 20. Both functional elements 29 are constructed identically in the manner of coupling elements 29, on which the beginning of the material web 31 to be pulled through, for. B. a paper web 31, for example using a pull-in tip (see FIG. 6), can be coupled.

As shown in FIG. 7, the pull-in means 20 can be guided in the guide profile 32 along the desired pull-in path. The guide profile 32 surrounds the plastic segments 23 only in the region of the tooth flanks 27, whereas the functional element 29, which is designed in the manner of a coupling element 29, projects beyond the guide profile 32.

As shown in FIG. 8, it can be achieved by fitting the pull-in means 20 with two functional elements 29 that two material webs 31, on each of which a pull-in tip is provided, can be coupled to the pull-in means 20. The coupling elements 29 are designed such that the fastening bolts 33 provided on the pull-in tips are used to couple the material webs 31 the slotted guide of the coupling elements 29 can be pushed out and inserted into an oppositely arranged coupling element.

A coupling station 34 required for this is shown in FIG. 9. The pull-in means 36 and 37, the structure of which essentially corresponds to the pull-in means 20, are arranged one above the other in the transfer station 34 such that the coupling elements 38, 39 come to lie one above the other. Slide rails 40 are arranged in pairs on the top and bottom of the coupling elements 38, 39, so that the coupling elements 38, 39 can be supported on one another. For coupling, a push rod (not shown) is then extended and presses the fastening bolt 33 together with the pulling-in tip of the material web 31 into the coupling element 39 located below.

The formation of the functional elements 11; 12 can also be combined, so that, for example, a coupling element 11 has additional tooth flanks 04; 27 and / or has a permanent magnet as an initiator.

At the feeder 01; 20; 36; 37 can thus, depending on the requirement, in addition to a first coupling element, a further functional element 11; 12; 29; 38; 39 are releasably attached. If the first pull-in means is also detachably arranged, it can be removed if necessary and in a new position along the pull-in means 01; 20; 36; 37 can be fixed.

This applies both to the attachment to support elements 03 fixedly connected to the pull-in means 01 according to the first embodiment, and also to the attachment of detachable support elements 23 according to the second embodiment.

The functional element 11; 12; 29; 38; 39 is with the carrier 03; 23 and / or the releasably designed carrier 23, preferably in a form-fitting manner, at least with regard to the Direction of transport executed. For this, the functional element 11; 12; 29; 38; 39 and the associated carrier 03; 23 with appropriate means (clip structure 08; 09) or the releasable carrier 23 and the pull-in means 01 (or the band section 02) with appropriate means (projection 25 and 24; 26).

LIST OF REFERENCE NUMBERS

01 Feeding device

02 band section, metal band section

03 plastic layer, coating (02), carrier element, plastic segment

04 functional surface, tooth flank

05 -

06 functional surface, sliding element

07 intermediate area

08 clip structure

09 clip structure

10 -

11 functional element, coupling element

12 functional element, initiator element

13 material web, paper web

14 recess (02)

15 -

16 recess (02)

17 -

18 -

19 -

20 feed means

21 band section, metal band section

22 plastic layer, coating (21)

23 support element, plastic segment

24 recess (21)

25 head start

26 recess (21)

27 functional surface, tooth flank Fastening bolt functional element, coupling element - material web, paper web guide, guide profile fastening bolt (31) Coupling station - retraction means retraction means coupling element coupling element slide rail

Strength

Claims

Expectations

1. pull-in means (01; 20; 36; 37) for pulling in a beginning of a material web (13; 31), wherein the material web (13; 31) can be coupled at least in sections to the pull-in means (01; 20; 36; 37) and wherein the pull-in means (01; 20; 36; 37) is equipped with at least one coupling element (11; 29; 38; 39) to which the material web (13; 31) can be coupled to the pull-in means (01; 20; 36; 37) , characterized in that the pull-in means (01; 20; 36; 37) can optionally be equipped with a further functional element (06; 11; 12; 23; 29; 38; 39) which can be detachably attached to the pull-in means (01; 20; 36 ; 37) can be fixed.

2. Pull-in means according to claim 1, characterized in that the pull-in means (01; 20; 36; 37) for transmitting tensile and / or pushing forces has a band section (02; 21), in particular a metal band section (02; 21).

3. pull-in means (01; 20; 36; 37) for pulling in a beginning of a material web (13; 31) which has a belt section (02; 21) for transmitting tensile and / or pushing forces, characterized in that the pull-in means ( 01; 20; 36; 37) can optionally be equipped with at least one functional element (06; 11; 12; 23; 29; 38; 39) that can be fixed completely detachably on the pull-in means (01; 20; 36; 37).

4. Feeding device according to claim 3, characterized in that the functional element (06; 11; 12; 23; 29; 38; 39) as a coupling element (11; 29; 38; 39) for coupling the material web (13; 31) with the Pull-in means (01; 20; 36; 37) is executed.

5. Pull-in means according to claim 1 or 3, characterized in that the functional element (06; 11; 12; 23; 29; 38; 39) can be fixed positively on the pull-in means (01; 20; 36; 37).

6. Pull-in means according to claim 1 or 3, characterized in that the pull-in means (01; 20; 36; 37) with a further coupling element (11; 29; 38; 39) on which a material web (13; 31) to the pull-in means ( 01; 20; 36; 37) can be coupled, can be equipped.

7. Pull-in means according to claim 1 or 3, characterized in that the pull-in means (01; 20; 36; 37) with at least one sliding element (06) which guides the pull-in means (01; 20; 36; 37) (32 ) can come to the system, can be equipped.

8. pull-in means according to claim 1 or 3, characterized in that the pull-in means (01; 20; 36; 37) with at least one initiator element (12) which can be evaluated by a sensor attached to a guide (32) or a frame, can be equipped.

9. Feeding device according to claim 9, characterized in that the takeover, parking, transfer and / or delivery position of the feeding means (01; 20; 36; 37) can be determined by the sensor attached to the guide (32).

10. Feeding device according to claim 2 or 3, characterized in that the band section (02; 21) at least in regions has a coating (03; 22), in particular a plastic layer (03; 22).

11. Pull-in means according to claim 2 or 3, characterized in that a carrier element (23) is detachably connected to the band section (21), in particular that the carrier element (23) can be clipped in segments into the band section (21).

12. Feeding device according to claim 2 or 3, characterized in that a carrier element (03) is fixedly connected to the band section (21), in particular that the carrier element (23) is connected in segments to the band section (21).

13. Feeding means according to claim 10, characterized in that the coating (03) is inextricably linked to the band section (02), in particular that the band section (02) is essentially completely encased and forms the core of the drawing-in means (01).

14. Feeding device according to claim 10, 11 or 12, characterized in that at least one functional surface (06; 27) is provided on the outside of the coating (03; 22) or of the carrier element (03; 23).

15. Feeding device according to claim 10, 11 or 12, characterized in that the metal strip section (02; 21) recesses (14; 16; 24; 26) for positive engagement with the plastic layer (03; 22) forming plastic or with a Carrier element (23) arranged projection (25).

16. Pull-in means according to claim 14, characterized in that the functional surface (04; 27) is designed for engagement with a drive means, in particular with a gear.

17. The pull-in means according to claim 16, characterized in that functional surfaces (04; 27) designed as tooth flanks (04; 27) for engaging a drive means, in particular a gearwheel, are provided on both sides of the metal strip section (02; 21).

18. Pull-in means according to claim 14, characterized in that the functional surface (06) is designed in the manner of a sliding element (06) which can come to rest on a guide (32) guiding the pull-in means (01).