EP1854108A1

EP1854108A1 - Device for producing a cabling with alternating direction of lay

Info

Publication number: EP1854108A1
Application number: EP06704701A
Authority: EP
Inventors: Peter Khu
Original assignee: Individual
Current assignee: Individual
Priority date: 2005-03-03
Filing date: 2006-02-16
Publication date: 2007-11-14
Also published as: AT501304A4; WO2006091989A1; AT501304B1

Abstract

The invention relates to a device for producing a cabling with alternating direction of lay (SZ cabling) from individual strands, said device comprising a fixed guiding element for the individual strands, a plurality of accumulation disks that are arranged in the tractive direction of the individual strands and can be driven in alternating directions, and a stranding disk. The disks can be driven by transmission elements by means of at least one drive, a common drive being provided for at least two disks. The aim of the invention is to enable the exact determination of the rotational speed and rotational speed ratios for and between the individual disks, even for the maximum rotational speeds and working speeds. To this end, all disks (7) which can be driven by means of an individual drive (3) common to the disks are connected to at least one rigid element (5) by means of the associated transmission elements (1, 4, 8) thereof. Said rigid element (5) is oriented essentially parallel to the tractive direction of the individual strands and can be pivoted about an axis (A) perpendicular to the tractive direction by means of the common drive (3). The axis (A) is located between the guide and the first disk (7) connected to the rigid element (5).

Description

Device for producing a stranding with alternating direction of impact

The invention relates to a device for producing a stranding with alternating direction of impact (SZ stranding) from single strands, in which a fixed guide element for the individual strands and a plurality of spaced in the pulling direction of the individual strands spaced, drivable in alternating directions, also with guides for receiving the provided to be stranded individual strands storage discs and a Verseilscheibe, which discs are driven via transmission members by means of at least one drive, wherein a common drive is provided for at least two discs.

In such devices, it is known to drive the individual stranding or storage discs on each of these discs associated drives and gearbox so that along the direction of the individual strands different speeds are achieved. These many drives and gear comprehensive devices are therefore very expensive, which still increases by the demand of the braked in a very short time and in the opposite direction to be accelerated large masses of this effort. Therefore, these designs did not find and find very widespread.

In DE 3536488 A1 a device for reversing stranding is described, in which the stranding disk is alternately driven by a geared motor and a toothed belt left and right-handed rotation. The drive of the storage discs via a series of free-angle couplings, the coupling halves are freely rotatable in each case by a certain clearance angle until they intervene torque-locking. As a result, successive storage disks are always delayed by the clearance angle.

An SZ stranding device in which the stranding disk, a guide disk and a plurality of storage disks are arranged so that they can not rotate directly on a torsionally elastic shaft is described in EP 582 802 A. The stranding disc is driven in reverse, whereby the shaft is twisted and entrains the discs during this torsion. A similar construction is also shown in EP 767 965 B1, where a torsionally elastic shaft is rotatably connected to at least a portion of traction sheaves for the storage and Verseilscheiben. The torsionally elastic shaft is provided at one end with a drive and fixedly mounted at the other end. In this type of stranding can not be guaranteed exact ratio between the speeds of the individual discs, and also the time of change of the direction of rotation is not exactly definable. These disadvantages are exacerbated by vibration and resonance effects in the torsionally elastic wave, so that such machines are not suitable for fast work and the necessary high speeds. In order to counteract the latter disadvantage, it has been proposed in EP 1 340 232 B1 to drive the torsion element at several points by a plurality of drives at different rotational speeds. In this case, this torsion element can be connected directly to the discs rotatably or with traction sheaves, which are then coupled via transmission elements with the storage discs and the stranding disc. The more precisely the rotational speed and the time of reversing the direction of rotation are to be defined, the more drives or gear ratios must be provided, so that a complex design which is not suitable for high speeds quickly arises again. If, on the other hand, the effort is kept small, large lengths of the torsion element remain, on which lengths the twisting behavior remains inaccurate and not exactly definable, and on which lengths resonance effects can result up to the turning over and possibly screwing in of the torsion element. Also, this latter design is therefore not really suitable for high speeds and thus high stranding speeds.

The object of the present invention was therefore a device of the type described above, which allows the exact specification of speeds and speed ratios for and between the individual discs, which remain safely even for the highest speeds and operating speeds of the device.

To achieve this object, the device according to the invention is characterized in that all discs which are driven by means of a single, these discs common drive are connected via their associated transmission elements with at least one rigid element, which element oriented substantially parallel to the direction of the single strands and is pivotable about a transverse axis transverse to the pulling direction by means of the common drive, wherein the axis between the guide and the first connected to the rigid element disc is located. About the distance ratios of the connection points of the transmission elements with the rigid element, the speed ratios between the discs can be specified exactly and invariably over the entire speed range of the device. The absolute speed is defined by the drive and the geometric conditions of the rigid element also exactly specifiable.

According to an advantageous embodiment, it is provided that the transmission members comprise a drive pulley connected to the pulleys to be driven via a closed cable, a belt, a toothed belt, a chain or the like. As a result, the area of the stranding, the slices and the strands to be stranded can be kept free of other facilities as far as possible.

According to a further feature of the invention, all the disks of the device are connected to at least one rigid element and a common drive for all disks is provided. A first embodiment of the invention relating to the transmission of drive torque to the discs is characterized in that the transmission member comprises an open cable, a belt, a toothed belt, a chain or the like, one end of which is connected to the rigid element and the other End is coupled with an elastic element or a counterweight. This can be found with only a rigid element Auslangen.

Another embodiment, however, provides for the most exact control of the movement of the discs of the stranding device that two rigid elements are provided and about the same axis by means of a common drive gegengleich pivot.

It is preferably provided that in each case one end of a flexible, connected to the driven pulley transmission member is connected to one of the rigid elements.

Preferably, the transmission member comprises an open cable, a belt, a toothed belt, a chain or the like, whose ends are each connected to one of the rigid elements.

According to a further feature of the invention, to increase the flexibility in the speeds and speed ratios imposed on the driven pulleys, it may be provided that the axis of the one or more rigid elements (s) is movable, for example by means of a drive, in a plane oriented perpendicular to this axis. In addition to an active drive of the axis of the rigid element and a passive movement is conceivable, for example, by supporting the axis in an elastic bearing, such as a rubber block.

According to a further feature of the invention can be provided in a simple and easily adjustable manner that the or each drive has at least one rotatable, drivable crank disc, in which engages at least one of the rigid elements. Of course, other types of drive elements could be provided, such as chains, ropes or belts with parallel sections to which the ends of the rigid element are coupled. By integrating vario-transmissions or cam arrangements, the substantially sinusoidal deflections of the rigid elements over time can be approximated more to the triangular shape advantageous for the stranding.

In order to be able to change the deflection and thus the rotational speed of the discs, in one embodiment of the invention, the point of application of the rigid element on the disc can be radially adjustable or changed.

A very simple compensation for the device according to claim 9, characterized in that the coupling of the rigid element takes place on the disc in a slot extending in the longitudinal direction of the rigid element. According to another embodiment of the invention may also be provided that the or each drive is formed by a linear drive. With such drive variants, which can be implemented both mechanically, for example via a cam drive, as well as electrical, hydraulic or pneumatic, the stranding advantageous triangular shape for the deflections of the rigid elements can be achieved over time easier.

In the following description, the invention will be explained in more detail with reference to the accompanying drawings.

1 is a schematic side view of an SZ stranding machine, FIG. 2 is a schematic side view of a drive device according to the invention for a SZ stranding machine, FIG. 3 is a schematic front view of a stranding machine with a drive device according to the invention in a first embodiment, FIG. 4 is a schematic front view of a stranding machine with a drive device according to the invention in a further embodiment, FIG. 5 is a schematic front view of a stranding machine with a drive device according to the invention in a third embodiment, and FIG. 6 shows a schematic side view of a drive device according to the invention for an SZ stranding machine in a further advantageous embodiment.

In Fig. 1, the standard trained parts and portions of a device for producing a stranding with alternating direction of impact (SZ stranding) are shown from single strands. These usual components of such devices include, from left to right in Fig. 1, the storage drums for stranded single strands, possibly a storage drum P for paper to be inserted, which then the section S with about a fixed guide element for the single strands and several in the pulling direction of the Single strands spaced apart, drivable in alternating directions, also provided with guides for receiving the individual strands to be stranded storage discs follows. Immediately behind this section S with the storage discs follows the section V with the actual Verseilscheibe or Verseilrohr. The stranded product provided with the paper insert then passes into the section marked N for post-processing.

The discs in the section S and possibly also in the section V are preferably drivable via transmission members by means of at least one drive, wherein a common drive for at least two slices, preferably all slices of the SZ machine, is provided. These transmission links can originate directly from the drive or else from a traction sheave for each storage or stranding disk, which traction sheave 1 is arranged in bearing bodies 2 outside the area of the individual strands to be stranded. are orders. The driven wheels can be connected via a closed cable, a belt, a toothed belt, a chain or the like. With the traction sheaves 1.

All traction sheaves 1 of the device, which are drivable by means of this disc common to drive 3, are, as shown in a first embodiment in Fig. 2, connected via associated transmission elements 4 with at least one rigid element 5. This element 5 is oriented substantially parallel to the pulling direction of the individual strands and thus also to the line of successively arranged storage discs and is pivoted by means of the common drive 3 about an axis A transverse to the direction of pull axis A, wherein the axis A between the guide and the first with the rigid element 5 connected disc 1 is located. About the distance ratios of the connection points P of the transmission elements 4 with the rigid element 5, the speed ratios between the discs 1 and thus between the individual storage discs and the Verseilscheibe can be specified, while the drive 3 in connection with the geometric conditions on the rigid element, the absolute Values are defined.

As shown in Fig. 3, may be provided as the transmission member 4, an open rope, a belt, a toothed belt, a chain or the like., One end of the connection point P is connected to the rigid element 5 and the other end via an elastic Element 6 is connected to a fixed point. Adjustment of the elastic element 6 could also be provided a counterweight.

Furthermore, an embodiment of the invention is shown in Fig. 3, in which the stranding or storage disc 7 is driven by its own transmission element 8, which leads to a traction sheave 1, which in turn is coupled to the transmission member 4. Advantageously, traction sheave 1 as well as stranding or storage disc 7 can be accommodated in a common bearing body 2.

At most, the transmission member 4 could also be connected directly to the stranding or storage disk 7, as shown in Fig. 4. This Fig. 4 also illustrates an embodiment of the invention, in which two rigid elements 5 are provided and about the same axis A by means of a common drive 3 are pivoted gegengleich same. In this variant, preferably one end of the transmission member 4 is connected to one of the rigid elements 5, in which case transmission member 4 will be formed by an open cable, a belt, a toothed belt, a chain or the like., Both ends with one each the rigid elements 5 are connected and either - as shown - are guided directly over the driven pulleys 7 or these disks 7 indirectly, ie via a traction sheave 1 and another transmission element 8 - as shown in Fig. 5 - drive. The drive can have at least one rotatable, drivable crank disk 10, which is coupled to the rigid elements 5. Of course, other types of drive elements could be provided, such as chains, cables or belts with parallel sections to which the ends of the rigid element 5 are coupled, causing a sinusoidal deflection of each point of the rigid element 5 with respect to time. Vario transmissions, cam arrangements and advantageously also mechanical, electrical, pneumatic or hydraulic linear drives allow the approach of this sinusoidal movement to a triangular shape which is more advantageous for the stranding.

In order to be able to change the deflection to a certain extent, the point of application S of the rigid element 5 on the disk 10 can be adjusted radially. In order to allow the length compensation in the course of the circular movement of the point S during rotation of the crank disk 10, the coupling of the rigid element 5 takes place on the disc 10 in a longitudinal direction of the rigid element 5 extending slot 11th

Finally, FIG. 6 shows an embodiment according to the invention which allows increased flexibility in the speeds and speed ratios imposed on the driven pulleys. For this purpose, also the axis A of the rigid element (s) 5 is either passively movably mounted in an elastic element or movable by means of its own drive 3a in a plane oriented perpendicular to this axis A. For the design of the second drive 3a essentially the same principles apply as for the drive 3, wherein the drive 3a for the axis A but not so large deflections must cause and therefore may be smaller. In Fig. 6 it is also made clear that the rigid element 5 does not have to be directly coupled to the crank disks 10, 10a of the drives 3, 3a, but also intermediate levers or links 11, 11a can be provided.

Claims

claims:

1. Apparatus for producing a stranding with alternating direction of impact (SZ stranding) from single strands, in which a fixed guide element for the individual strands and a plurality of spaced in the pulling direction of the individual strands spaced, drivable in alternating directions, also with guides for receiving the stranded Single strands provided storage discs and a Verseilscheibe are provided, which discs are driven via transmission members by means of at least one drive, wherein a common drive is provided for at least two discs, characterized in that all discs (7), which by means of a single, these discs common Drive (3) are drivable, via their associated transmission elements (1, 4, 8) are connected to at least one rigid element (5), which element (5) oriented substantially parallel to the pulling direction of the single strands and by means of the common drive (3)about an axis transverse to the direction of pull (A) is pivotable, wherein the axis (A) between the guide and the first with the rigid element (5) connected to the disc (7).

2. Apparatus according to claim 1, characterized in that the transmission members one with the driven pulleys (7) via a closed cable, a Rie-. men, a toothed belt, a chain or the like. (4) connected drive pulley (1).

3. Apparatus according to claim 1 or 2, characterized in that all the discs (7) of the device with at least one rigid element (5) are connected and a common drive (3) is provided for all discs.

4. Apparatus according to claim 3, characterized in that the transmission member comprises an open cable, a belt, a toothed belt, a chain or the like. (4), one end of which is connected to the rigid element (5) and the other end with an elastic element (6) or a counterweight is coupled.

5. Apparatus according to claim 1 or 2, characterized in that two rigid elements (5) are provided and about the same axis (A) by means of a common drive (3) are pivoted gegengleich same.

6. Apparatus according to claim 5, characterized in that in each case one end of a flexible, connected to the driven pulley transmission member (4) is connected to one of the rigid elements (5).

7. Apparatus according to claim 6, characterized in that the transmission member comprises an open cable, a belt, a toothed belt, a chain or the like. (4), whose ends are connected to one of the rigid elements (5).

8. Device according to one of claims 1 to 7, characterized in that the axis (A) of the one or more rigid elements (s), for example by means of a drive (3a) in a direction perpendicular to this axis (A) oriented plane is movable.

9. Device according to one of claims 1 to 8, characterized in that the or each drive (3, 3 a) at least one rotatable, drivable crank disc (10, 10 a), in which at least one of the rigid elements (5) engages.

10. Apparatus according to claim 9, characterized in that the engagement point (S) of the rigid element (5) on the disc (10, 10 a) is radially adjustable or variable.

11. The device according to claim 10, characterized in that the coupling of the rigid element (5) on the disc (10, 10 a) takes place in a longitudinal direction of the rigid element (5) extending slot (11).

12. Device according to one of claims 1 to 8, characterized in that the or each drive (3, 3 a) is formed by a linear drive.