EP2935066A1 - Winding device for strand-like material to be wound - Google Patents

Abstract

The invention relates to a winding device for winding strand-like material to be wound (8), for example wire, having a winding disc (1) onto which the strand-like material to be wound (8) is wound up, and a housing arranged adjacently to the winding disc (1). The winding disc (1) is prevented from moving, in particular rotating, by at least one magnetic holding device (2), wherein the magnetic holding device (2) has a first magnetic arrangement (5) connected to the housing for conjoint rotation and a second magnetic arrangement (6) connected to the winding disc (1) for conjoint rotation, each magnetic arrangement having a north pole N and a south pole S. Between the first magnetic arrangement (5) and the second magnetic arrangement (6) there is a gap (4), and the first magnetic arrangement (5) and the second magnetic arrangement (6) are magnetically coupled across the gap (4), wherein the strand-like material to be wound (8) is guided through the gap (4). In this case, the two magnetic arrangements (5, 6) are arranged such that the south pole S of the first magnetic arrangement (5) is located opposite the north pole N of the second magnetic arrangement (6) and the north pole N of the first magnetic arrangement (5) is located opposite the south pole S of the second magnetic arrangement (6), with the result that particularly high holding forces are achievable. Preferably, the first magnetic arrangement (5) and/or the second magnetic arrangement (6) are formed in a horseshoe-shaped manner.

Description

 Winding device for stranded winding material

Description

Hereby, the entire content of the priority application DE 10 2012 024 759.1 by reference is part of the present application.

The present invention relates to a winding device for winding stranded winding material. The strand-shaped winding material may be, for example, a metallic or non-metallic, coated or uncoated wire, a single or multi-core cable, a fiber, for example a natural or a synthetic fiber, in particular a fiber for special technical applications such as an optical waveguide, a thread, a Be a string or a rope. The winding device has a winding disk with a generally round cross section, on the outer peripheral surface of the strand-shaped winding material is wound up. The winding disk preferably has the shape of a flat cylinder, the height of which is dimensioned such that a plurality of windings of the strand-like winding material can be wound on its outer circumferential surface at the same time. The winding disk is preferably arranged horizontally in the winding device, but may also be arranged vertically or in another orientation. The winding disk is fixed during operation of the winding device. The winding of the strand-like winding material on the winding disk is carried out by a suitable rotating Stranggutaufwickelmechanismus which leads around the peripheral winding surface of the winding disk, preferably via one or more pulleys, with a continuous rotational movement around the peripheral surface of the winding disk outside and settles in the form of a circumferential turn on this peripheral surface. The settling of the strand-like winding material is preferably carried out near an axial end of the winding disk. The resulting on the peripheral surface of the winding disc turns push each other then in the axial direction of the winding disk until they reach the other axial end of the winding disk.

However, the strand-shaped winding material after winding on the winding disk is not intended to remain on this (in the sense of a reel spool for storage and transport of the winding material), but is further processed after winding on the winding disk in various ways:

On the one hand, the turns of the strand-like winding material at the other axial end of the winding disk can again slip off the winding disk without further support or guidance and fall into a container, for example a drum, which serves for storage and transport of the strand-like winding material. In this case, the winding disk is preferably arranged horizontally, and the container is under the winding disk. A winding device of this type is also referred to as a drum winder. It is preferably suitable for strand-shaped winding material, which is plastically deformed during winding on the winding disk to a certain extent, so that the turns remain largely dimensionally stable when falling into the container. For this purpose come as a winding material essentially metallic wires or wires or cables made therefrom in question.

On the other hand, the turns of the strand-shaped winding material can also be controlled at the other axial end of the winding disk and under tension be deducted again. In this way, the winding device can be used as a storage device for the strand-shaped winding material, wherein the windings wound on the winding disk are "cached". By varying the degree of filling of the winding disk, for example, the feed speed can be decoupled from the take-off speed of the strand-like winding material, whereby speed fluctuations or even short stoppages within the processing process of the strand-like winding material can be compensated. The present invention will be described using the example of a drum winder with horizontally arranged winding disk. However, this is not a limitation. The invention can also be used for a storage device or for another winding device for a stranded winding material.

In a winding device of the type described above, the following problem arises: Since the winding disk is continuously encircled by the strand winding mechanism and the windings of the strand-like winding material arise on the outer peripheral surface of the winding disk, a volume in the form of a cylinder jacket, in the case of a round winding disk, So a tubular volume, with a specific, u. A. be released from the diameter of the strand-like winding material dependent radially measured thickness. Since the strand-shaped winding material moves in this tubular volume, there may be no other body such as levers or linkage there.

However, the winding disk experiences by the winding of the strand-like winding material on the winding disk and / or by the contact of the strand-like winding material with the winding disk forces and / or moments, which must be supported. For example, u is due to the strand-shaped winding material. A. a torque applied to the winding disk, which the Wrapping disk would turn. In particular, a horizontally arranged winding disk would be rotated about its vertical axis.

The winding disk is therefore stored in known winding devices, for example, by bearings depending from above. For this purpose, a vertically arranged, rotating hollow shaft through which the strand-shaped winding material of the winding device is fed and from which the winding material exits through an opening laterally to be passed to the Stranggutaufwickelmechanismus extended down towards the winding disk, and the winding disk is through a pivot bearing, preferably a rolling bearing, mounted on the vertical shaft rotatably mounted on this. As a result, forces can be absorbed in all directions and also torques about other axes than the vertical axis. Torques about the vertical axis and thus co-rotation of the winding disk can not be prevented by such storage.

For this reason, known winding devices use, for example, so-called zero gear or compensation gear, which generate by their kinematics counter-rotating movement, whereby the winding disk is held in the direction of rotation about the vertical axis. The zero gear thus serves to prevent rotation of the winding disk.

Alternatively, the winding disk in known winding devices and positive-locking elements for receiving forces and torques, for example in the form of a so-called "mechanical sword", ie a simple ridge on the underside of the winding disk, in a corresponding groove on the top of the container for the strand-shaped winding material engages. By the resulting positive connection between the web and the groove co-rotation of the winding disk is prevented. DE 36 42 177 A1 proposes further as anti-rotation for the winding disk (also called "Scholl disc") of a drum winder before the use of permanent magnets, which consist of pairs of different pole, plate-shaped segments. In each case one segment is fastened on a flange of the winding disk and the other segment on a housing-fixed holder. The two segments are arranged so that they attract magnetically in the vertical direction. Between the two segments runs in a small air gap a disc, within which the strand-shaped winding material, passed over two pulleys on the winding disk and wound up there.

A magnetic rotation for the winding disk is particularly suitable for non-magnetic strand-shaped winding material, for example, for non-metallic stranded winding material or copper or aluminum wires.

Similarly, DE 23 52 521 A1 proposes for a storage device for a filamentary material to prevent the vertically arranged winding disk by a permanent magnet mounted in her and a stationary fixed in the machine frame permanent magnet from rotating. The two block-shaped magnets are in this case radially with respect to the winding disk, wherein between the magnets, a gap is formed, through which the filamentary material can move. The present invention is based on the object to provide a winding device of the type described with an improved device by which the winding disk is prevented from rotating.

This object is achieved by a winding device according to claim 1. Further advantageous embodiments of the invention are contained in the dependent subclaims. The invention relates to a winding device for winding strand-like winding material with a winding disk on which the strand-shaped winding material is wound, and a housing adjacent to the winding disk arranged, wherein the winding disk by at least one magnetic holding device at a movement, in particular at a rotation, is prevented, wherein the magnetic holding device comprises a first, rotatably connected to the housing and a second, non-rotatably connected to the winding disk magnetic arrangement, each having a north pole and a south pole, wherein between the first and the second magnetic arrangement, a gap is present , the first and the second magnetic arrangement are magnetically coupled across the gap and the strand-shaped winding material is guided through the gap.

For such a winding device, the invention provides that the two magnetic arrangements are arranged so that the south pole of the first magnetic arrangement is opposite the north pole of the second magnetic arrangement and the north pole of the first magnetic arrangement is opposite the south pole of the second magnetic arrangement. This results in a particularly high holding force between the two magnetic assemblies and thus between the housing and the winding disk of the winding device, since the proportion of the magnetic flux which extends outside of the first and the second magnetic arrangement, essentially extends only in the gap. Thus, a particularly large proportion of the magnetic field generated by the two magnetic devices can be used to generate the holding force. In particular, the field lines of the magnetic field extending outside the two magnetic devices are aligned substantially parallel to one another, so that conversely there hardly occur regions of the magnetic field with diverging field lines in which the magnetic field contributes only little to the generation of the holding force. In this case, a magnetic arrangement is understood to mean an arrangement of one or more magnetic or magnetizable materials or components, wherein the arrangement has two magnetic poles of different polarity, if necessary after magnetization, which are referred to below as north pole and south pole.

To form a magnetic holding device magnetic circuits with hard and / or soft magnetic sections can be constructed. The hard and / or soft magnetic sections are preferably arranged within a magnetic holding device in parallel connection and / or in series connection.

The materials mentioned are preferably soft magnetic materials such as ferromagnetic materials or permanently magnetizable hard magnetic materials. The components mentioned are preferably permanent magnets. Further preferably, electromagnets or combinations of permanent magnets and electromagnets can also be used as magnetic sources. The first and second magnetic arrangements are coupled in accordance with the invention such that the field lines exiting from the north pole of the first magnetic arrangement pass through and enter the south pole of the second magnetic arrangement, inside the second magnetic arrangement thereof Be conducted north pole, pass through the gap to the south pole of the first magnetic arrangement and enter into this and are conducted inside the first magnetic arrangement to the north pole and close there.

In a particularly preferred embodiment of the invention, the two poles of the first magnetic arrangement in the circumferential direction of the winding disk are substantially adjacent to each other, and also the two poles of the second magnetic arrangement are in the circumferential direction of the winding disk essentially next to each other. The magnetic circuit, which is formed by the magnetic coupling of the first and the second magnetic arrangement, then runs essentially in a plane which contains a tangent of the winding disk or a straight line parallel thereto.

If the winding disk should rotate slightly with stronger torques acting on it, due to the resulting shift in the said, particularly preferred arrangement of the first and the second magnetic arrangement of the south pole of the first magnetic arrangement in the vicinity of the south pole of the second magnetic arrangement or the north pole of the first magnetic arrangement near the north pole of the second magnetic arrangement. As a result, in both cases, in addition to the attractive forces between the various pin poles, repulsive forces still act between the respective poles of the same name, which support a turning back of the winding disk into the starting position.

In a further particularly preferred embodiment of the invention, the two poles of the first magnetic arrangement in the axial direction of the winding disk substantially adjacent to each other, and also the two poles of the second magnetic arrangement are in the axial direction of the winding disc substantially side by side. In the considered horizontally arranged winding disk, the two poles then each lie substantially vertically one above the other. The resulting magnetic circuit then runs essentially in a vertical plane.

Preferably, a plurality of such magnetic holding devices are arranged distributed with magnetic arrangements with vertically superposed poles in the circumferential direction of the winding disk. In this way, the magnetic holding devices take up only a small amount of space in the circumferential direction, as a result of which a large number of such holding devices can be arranged along the circumference of the winding disk. Preferably, the polarities of circumferentially adjacent magnetic assemblies are interchanged, ie, the north poles and south poles of the magnetic assemblies are circumferentially alternately top and bottom. A particularly uniform arrangement with continuously alternating polarities therefore results if the number of magnetic holding devices is even.

In a further preferred embodiment of the invention, the first and the second magnetic arrangement are opposite in the radial direction of the winding disk. As a result, torques acting around the vertical axis of the winding disk can be absorbed particularly well, without unwanted tilting moments or transverse forces acting on the winding disk.

But it is also possible that the first and the second magnetic arrangement are in the axial direction of the winding disk or in a different direction opposite.

In a further preferred embodiment of the invention, the magnetic circuit, by which the first and the second magnetic arrangement are coupled, extends substantially in a plane parallel to the winding disk.

In a further preferred embodiment of the invention, the first or the second magnetic arrangement is formed horseshoe-shaped. As a result, the arrangement according to the invention, according to which poles of different polarity of the two magnetic arrangements are opposite, can be produced in a simple manner.

The term "horseshoe-shaped" is intended here to mean that the two poles of different polarity of the magnetic arrangement have substantially in the same direction and within the magnetic arrangement are continuously connected by magnetic or magnetizable materials or components.

The term "horseshoe-shaped" is to be understood independently of the actual geometric shape of the magnetic arrangement, d. H. This term includes both magnetic arrangements that actually have the shape of a horseshoe, as well as, for example, U-shaped or V-shaped magnetic arrangements and, in particular, magnetic arrangements in the form of a rectangle that is open on one side.

The second magnetic arrangement need not be horseshoe-shaped, but may for example have the shape of a flat plate or a rod. Preferably, however, both the first and the second magnetic arrangement are formed horseshoe-shaped. As a result, the advantages of a horseshoe-shaped training in both magnetic arrangements can be achieved, which reinforces the holding force again. Particularly preferably, the first and / or the second magnetic arrangement has at least one permanent magnet. The magnetic assemblies are then completely maintenance-free and can, for example by the use of neodymium magnets, generate large holding forces. Preferably, the first and / or the second magnetic arrangement has at least one electromagnet. As a result, on the one hand high magnetic holding forces can be generated, on the other hand, the magnetic holding forces can also be switched off in a simple manner, for example, when the winding disk is to be replaced. Furthermore, by a change in the current flowing through the electromagnet, the holding force of the electromagnet can be accurately adjusted and thereby, for example, a precise centering of the winding disk in the winding device and on be reached the container. Preferably, only the first, fixed to the housing fixed magnetic arrangement is equipped with an electromagnet, since the power supply on the housing side is easier to implement than on the largely free-standing winding disk.

Preferably, the first and / or the second magnetic arrangement comprises at least one component of a magnetizable material, for example of soft iron or of a ferrite. Preferably, the first or the second magnetic arrangement has a permanent magnet or electromagnet and the respective other magnetic arrangement has only one component made of a magnetizable material. Preferably, the first or the second magnetic arrangement is horseshoe-shaped in such a way that their poles are formed by two parallel, magnetized in opposite directions permanent magnet, which are connected on one side by a soft magnetic closing and guiding element.

In a preferred embodiment of the invention, the winding disk is prevented by at least two magnetic holding devices on a movement, in particular on a rotation, which are arranged along the circumference of the winding disk. Preferably, the magnetic holding devices are arranged at uniform intervals along the circumference of the winding disk in order to achieve a uniform distribution of the forces acting on the winding disk magnetic holding forces.

Preferably, in this embodiment, at least two magnetic holding devices face each other with respect to the circumference of the winding disk. Particularly preferably, all the magnetic holding devices face each other with respect to the circumference of the winding disk, ie the n magnetic holding devices, where n is an even number, form in a plane parallel to the cross-sectional plane of the winding disk the corners of a regular / 7-corner. This will be on the Winding disk acting holding forces distributed symmetrically on the circumference of the winding disk, so that it is particularly well centered and a bearing through which the winding disk is mounted relative to the winding device is not burdened by high lateral forces.

Further embodiments and advantages of the invention are explained below in conjunction with the attached, partially schematic figures. 1 shows a winding disk and two magnetic holding devices of a winding device according to the invention, showing the magnetic field lines;

2: detailed representations of two inventive magnetic

 Holding devices with two horseshoe-shaped magnetic

assemblies;

3 shows a winding device according to the invention with eight uniformly arranged magnetic holding devices;

Fig. 4: a magnetic holding device of Fig. 3 in one

 Detailed representation;

Fig. 5: an embodiment with two or three magnetic holding devices with vertically arranged magnetic arrangements in different views.

All figures are shown in a plan view from above on a horizontally arranged winding disk 1.

1 shows a schematic representation of a winding disk 1 and two magnetic holding devices 2 of a winding device according to the invention for a wire 8, wherein the two holding devices 2 are arranged diametrically opposite to the outer edge of the winding disk 1 such that in each case the first magnetic arrangement 5 and the second magnetic arrangement 6 are radially opposite. In each case, the south pole S of the first magnetic arrangement 5 is opposite to the north pole N of the second magnetic arrangement 6 and vice versa. The respective first magnetic arrangement 5 is fixedly fixed to a (not shown) housing of the winding device. The respective second magnetic arrangement 6 is rigidly fastened to the winding disk 1.

The cylindrical winding disk 1 is connected in its central region with the outer side of a pivot bearing 3, in particular a ball, needle or roller bearing, wherein the inner side of the pivot bearing 3 via a vertical suspension and optionally via a further pivot bearing with the housing the winding device is connected. The winding disk 1 is thereby rotatably mounted relative to the housing. By the pivot bearing 3 and the suspension thus acting on the winding disk 1 transverse forces are largely absorbed, but not caused by the wound up strand-shaped co-rotating Mitdrehmomente about the vertical axis through the center of the winding disk. 1

The co-rotation of the winding disk 1, however, is prevented by the two symmetrically arranged magnetic holding devices 2. Between the respective first magnetic arrangement 5 and the respective second magnetic arrangement 6 there is an air gap 4, through which the wire 8 is guided and wound onto the outer surface of the winding disk 1. The closed magnetic field lines 7 within each magnetic holding device 2 are each shown schematically. In Fig. 2, two embodiments of magnetic holding devices according to the invention are shown in detail. In Fig. 2a, the first magnetic holding device 5 has two arranged at their poles permanent magnet 9, each having a north pole N and a south pole S, which are arranged in opposite polarity and in the circumferential direction of the winding disk 1 side by side and parallel to each other. The width of the permanent magnet 9 in the circumferential direction of the winding disk 1 is 120 mm in the embodiment, its height in the axial direction of the winding disk 1 is 30 mm, and the gap between them is 10 mm. At their radially outer ends, the two permanent magnets 9 are connected by a return plate 10 made of soft iron. The first magnetic arrangement 5 is thus formed horseshoe-shaped, so that the magnetic field lines emerge from the first magnetic arrangement 5 only in the air gap 4. The air gap 4 in the embodiment has a width between 5 and 20 mm, preferably about 15 mm.

Directly opposite the first magnetic arrangement 5, a second magnetic arrangement 6 is arranged on the winding disk 1 in a mirror-image manner. The difference to the first magnetic arrangement 5 is that the poles of the second magnetic arrangement 6 are not formed by permanent magnets, but by soft iron blocks 1 1, which are also connected to a return plate 10 made of soft iron. Also, the second magnetic arrangement 6 is thus formed horseshoe-shaped. The entire second magnetic arrangement 6 and the return plate 10 of the first magnetic arrangement 5 are magnetized by the two permanent magnets 9 of the first magnetic arrangement 5, and a closed magnetic flux forms across the air gap 4 through the two magnetic arrangements 5 and 6.

The magnetic holding device 2 in Fig. 2b differs from that in Fig. 2a only in that the poles of the second magnetic arrangement 6 are not formed by soft iron blocks 1 1, but also by permanent magnets 9, which are arranged so that poles different Polarity of the four permanent magnets involved 9 at the air gap 4 are opposite.

Likewise, it is possible to provide as a component of the second magnetic arrangement 6 an electromagnet. This can be easily produced, for example, by wrapping the return plate 10 with a coil.

An arrangement according to FIG. 2b can be chosen, for example, if the lateral, d. H. to the winding disk 1 tangential holding force of an arrangement of FIG. 2a is not sufficient. This holding force must be dimensioned so that the co-torque acting through the wire 8 and acting on the winding disk 1 is taken together by taking into account a safety factor by all the magnetic holding devices 2. In the exemplary embodiment, the holding force of a single magnetic holding device 2 to be achieved is set to 100 N, for example.

FIG. 3 shows a winding disk 1 according to the invention with eight magnetic holding devices 2, which are arranged uniformly along the circumference of the winding disk 1. Here, only the first magnetic arrangements 5 are shown schematically as separate units. The diameter of the winding disk 1 in the embodiment is 650 mm.

Also shown is a Drahtaufwickelmechanismus 12 with a first guide roller 13, which deflects the vertically fed from above the winding disk 1 wire 8 in the horizontal direction, and a slightly tilted relative to the horizontal second guide roller 14, the wire 8 slightly obliquely down into a to the winding disk 1 almost tangential direction deflects. The first guide roller 13 and the second guide roller 14 are rigidly connected to each other and run on a (not shown) rotor on or around the winding disk 1, in the embodiment in Fig. 3 in the counterclockwise direction. Thereby, the wire 8 in the air gap 4 between the first magnetic assemblies 5 and the second magnetic arrangements 6 applied tangentially to the outer surface of the winding disk 1 to form there the desired turns.

Due to the large number of eight magnetic holding devices 2, the winding disk 1 can be sufficiently retained to be prevented from turning on the winding disk 1 by the torque exerted by the live wire 8. At the same time results in a circumferential bias of the magnets to each other. FIG. 4 shows a detail from FIG. 3, wherein one of the eight magnetic holding devices 2 is shown, which has two horseshoe-shaped magnetic arrangements 5 and 6 as shown in FIG. 2b.

5a and 5b schematically show an embodiment with two magnetic holding devices 2, wherein Fig. 5b shows a plan view of the perspective view in Fig. 5a.

Fig. 5c and 5d show schematically an embodiment with three magnetic holding devices 2, wherein Fig. 5d shows a view in the direction indicated by the arrow A direction in the plan view shown in Fig. 5c.

In both embodiments, the poles of the first and second horseshoe-shaped magnetic assemblies 5, 6 are each arranged vertically one above the other. The first and second magnetic assemblies 5, 6 are also radially opposite each other.

In the case of the three magnetic holding devices 2 illustrated in FIGS. 5c and 5d, the north poles N and the south poles S of the first and second magnetic arrangements 5, 6 alternately face upwards and downwards in the circumferential direction of the winding disk 1. LIST OF REFERENCE NUMBERS

1 winding disk

 2 Magnetic holding device

 3 pivot bearings

 4 air gap

 5 First magnetic arrangement

 6 Second magnetic arrangement

 7 magnetic field lines

 8 wires

 9 permanent magnet

 10 return plate

 1 1 soft iron block

 12 wire winding mechanism

 13 First pulley

 14 second pulley

Claims

claims

Winding device for winding strand-shaped winding material (8) with a winding disk (1) on which the strand-shaped winding material (8) is wound, and one to the winding disk (1) adjacent arranged housing, wherein the winding disk (1) by at least one magnetic holding device (2) on a movement, in particular on a rotation, is prevented, wherein the magnetic holding device (2) has a first, with the housing rotatably connected magnetic arrangement (5) having a north pole (N) and a south pole (S) and a second in which the winding disk (1) has a magnetic arrangement (6) with a north pole (N) and a south pole (S), in which there is a gap (4) between the first magnetic arrangement (5) and the second magnetic arrangement (6) is present, the first magnetic arrangement (5) and the second magnetic arrangement (6) over the gap (4) are magnetically coupled away and the strand-shaped winding material (8) through the gap (4) gef is characterized in that the two magnetic arrangements (5, 6) are arranged so that the south pole (S) of the first magnetic arrangement (5) is opposite the north pole (N) of the second magnetic arrangement (6) and the north pole (N) of the first magnetic arrangement (5) faces the south pole (S) of the second magnetic arrangement (5).

Winding device according to claim 1, characterized in that the two poles of the first magnetic arrangement (5) in the circumferential direction of the winding disk (1) are substantially adjacent to each other and that the two poles of the second magnetic arrangement (6) in the circumferential direction of the winding disk (1) in Essentially next to each other. Winding device according to claim 1, characterized in that the two poles of the first magnetic arrangement (5) in the axial direction of the winding disk (1) are substantially adjacent to each other and that the two poles of the second magnetic arrangement (6) in the axial direction of the winding disk (1 ) are substantially adjacent to each other.

Winding device according to at least one of the preceding claims, characterized in that the first magnetic arrangement (5) and the second magnetic arrangement (6) lie in the radial direction of the winding disk (1).

Winding device according to at least one of the preceding claims, characterized in that the first magnetic arrangement (5) or the second magnetic arrangement (6) is formed horseshoe-shaped.

Winding device according to claim 5, characterized in that the first magnetic arrangement (5) and the second magnetic arrangement (6) are horseshoe-shaped.

Winding device according to at least one of the preceding claims, characterized in that the first magnetic arrangement (5) and / or the second magnetic arrangement (6) has at least one permanent magnet (9).

Winding device according to at least one of the preceding claims, characterized in that the first magnetic arrangement (5) and / or the second magnetic arrangement (6) comprises at least one electromagnet.

Winding device according to at least one of the preceding claims, characterized in that the first magnetic Arrangement (5) and / or the second magnetic arrangement (6) comprises at least one component made of a magnetizable material. 10. Winding device according to at least one of the preceding claims, characterized in that the winding disk (1) by at least two magnetic holding devices (2) is prevented from moving, in particular at a rotation, which along a circumference of the winding disk (1) are arranged ,

1 1. Winding device according to claim 10, characterized in that at least two magnetic holding devices (2) with respect to each other with respect to the circumference of the winding disk (1).