EP4010968A1 - Twisting device and method for a hairpin winding - Google Patents

Abstract

The present invention relates to a device (1) for twisting hairpin ends of a coil, which is formed from hairpins, for an electrical machine, comprising a plurality of coaxially arranged twisting rings (2.1; 2.2; 3), wherein two outer twisting rings (2.1; 2.2) and, therebetween, at least two inner twisting rings (3) are arranged, wherein the twisting rings (2.1; 2.2; 3) each have, at an axial end which faces the hairpin ends, a large number of pockets (6; 6.1; 6.2), which are distributed over the circumference, for receiving in each case one hairpin end, and wherein the twisting rings (2.1; 2.2; 2.3) can be twisted in opposite directions to one another, characterized in that the twisting rings (2.1; 2.2; 3) have coupling means (4.1; 4.2) by way of which twisting rings (2.1; 2.2; 3) with the same rotation direction can be connected.

Description

Twist device and method for hairpin winding

The present invention relates to a device and a method for so-called twisting in the production of a coil from hairpins, in which the individual hairpin ends protruding axially from the coil body are deformed or interlaced in the circumferential direction by a certain amount to make electrical contact with further hairpin ends to allow.

In the prior art it is known to reshape the hairpin ends arranged in layers individually or in each case individual layers.

It is also known from US 2009-302705 A to drive several coaxial rings individually. The rings have eroded recesses for the hairpin ends. Problems of the prior art include, among other things, the complex structure of the device and the individual parts of this device that are expensive to manufacture.

The object of the present invention is to provide a simpler device.

The object is achieved by a device or method according to the independent claims.

According to the invention, a device for twisting hairpin ends of a coil formed from hairpins for an electrical machine comprising a plurality of coaxially arranged twist rings, two outer twist rings and at least two inner twist rings between them, the twist rings each on one of the hairpin ends facing, axial end has a plurality of over the circumference ver divided pockets for receiving a hairpin end each, and wherein the twist rings are rotatable in opposite directions to each other, characterized in that the twist rings have coupling means through which twist rings can be connected with the same direction of rotation.

A hairpin winding is formed from several hairpins or shaped rods that have contact points at their ends on the winding head. At least two hairpins are electrically conductive with one another at the contact points connected to produce the coils of the hairpin winding from the hairpins. The contact points to be connected to one another are called hairpin ends and the respective individual contact points at the start and end of the respective coils are called connection pins. To control the electrical machine, the connection pins are connected to an interconnection in an electrically conductive manner. Hairpin windings are generally formed with at least four, often six or eight, and possibly more layers of hairpins per groove, depending on the design and the power of the electrical machine. The device has at least a number of twist rings corresponding to the number of layers, which are sleeve-shaped and are arranged coaxially nested in one another. At one axial end that faces the hairpin ends, the twist rings have pockets for receiving one hairpin end.

A small gap is provided between the twist rings in order to allow a relative movement of the twist rings to one another, the gap being smaller, preferably smaller than half the width of a hairpin end in the radial direction, in order to prevent the hairpin ends from entering to prevent the gap. The gap is made as small as possible in order to prevent the hairpin end from entering or the hairpin end from being deformed.

The inner twist rings have a width in the radial direction which corresponds to at least the width of one hairpin end in the radial direction in order to allow sufficiently large pockets to accommodate the hairpin ends. The maximum width of the inner twist rings is preferably less than three times, in particular less than twice the width of a hairpin end.

The outer twist rings can be made more massive, since they are only adjacent to another twist ring on one side. The device is advantageously connected to a drive or receiving element of a machine tool via the outer twist rings.

The ends of the straight hairpins or shaped rods used in the grooves protrude beyond the stator. In order to achieve a distributed coil winding, the hairpin ends must be bent in the circumferential direction so that contact points of different hairpins to be connected can be arranged adjacent to one another and then connected to one another in an electrically conductive manner. For this purpose, the twist rings of the device are designed to be rotatable relative to one another. Furthermore, the device has coupling means with which twist rings, which are rotated in the same direction, can be connected to one another and moved together. By means of the coupling means, the number of drives can be kept low and devices for different coils can optionally be used on the same system.

Embodiments of a device are characterized in that directly adjacent twist rings are rotatable in opposite directions. In particular, directly adjacent twist rings can be rotated in opposite directions in order to achieve uniform deformation of the hairpin ends. Thus, the hairpins can be connected to a coil with a wel len-shaped circumferential conductor.

Apparatus according to the embodiment are characterized in that at least the inner twist rings have a passage for the coupling means of the twist rings with a different direction of rotation. So that the coupling means can establish a connection between twist rings with the same direction of rotation without possibly interfering with intervening twist rings with no or an opposite direction of rotation, at least one passage is provided in the twist rings for the coupling means in a different direction of rotation.

Preferred embodiments of an aforementioned device are characterized in that the passage is designed as extending over part of the circumference of the elongated hole. A passage for the coupling means can easily be provided through an elongated hole extending over part of the circumference. Preferably, the elongated hole extends at least over an angle of the circumference which corresponds to the sum of the angles of rotation in both directions of rotation. In a starting position, the coupling means is preferably located in the circumferential direction at one end of the elongated hole. This end of the elongated hole can serve as a stop before geous, in further preferred embodiments, whereby the device can easily be reset to a defined starting position. Apparatus according to the embodiments are characterized in that the twist rings each have at least two coupling means, preferably symmetrically distributed over the circumference. In order to achieve an even distribution of the drive force and to reduce the risk of the twist rings jamming with one another, several coupling means are distributed over the circumference angeord net. This also reduces the force to be transmitted per coupling means. The at least two coupling means are preferably distributed symmetrically over the circumference, which ensures a more uniform force distribution. For example, two coupling means can be provided diametrically opposite each other per direction of rotation. In the case of larger devices, three coupling means, for example offset by 120 °, four by 90 ° or more, are also possible.

If coupling means are provided for different directions of rotation, these are preferably arranged alternately in the circumferential direction.

Embodiments of a device are characterized in that the coupling means are designed as a dowel pin which is received in corresponding receptacles on the twist strings. For a rigid connection between the twist rings, coupling means such as dowel pins or screws are advantageous due to the simple availability and assembly. Above all, dowel pins still have the advantage that there is a defined contact surface over the standardized outer surface of the dowel pins.

Preferred embodiments of a device are characterized in that some of the twist rings have receptacles which have a clear width in the direction of movement compared to the dowel pin in the starting position in order to move the twist ring by a rotation angle corresponding to the clear width less than the dowel pin. Instead of a fixed connection in the circumferential direction of the twist rings with the same direction of rotation, some of the receptacles for the coupling means, in particular dowel pins, can have a clear width in the direction of movement, which means that the twist ring can be carried along by one of the clear widths. speaking angle is reduced. Due to the delay in taking the corresponding twisting ring due to the clearance, since the coupling means only comes into contact with the receptacle after a certain angular range has already been covered in the circumferential direction, different twist angles can be achieved for the individual twist rings. Different twist angles of the different layers can be advantageous with regard to the geometric arrangement of the hairpin ends or their arrangement with respect to one another.

Apparatus according to the embodiments are characterized in that the number of twist rings corresponds to the number of layers of the coil. In order to twist all layers of a coil with hairpin winding simultaneously or in one work step, at least one number of twist rings corresponding to the layers is advantageously provided.

Embodiments of a device are characterized in that the number of pockets per twisting corresponds to the number of slots in the coil. In order to reshape all hairpin ends of a layer simultaneously in a twisting ring, a number of pockets corresponding to the number of grooves are advantageously provided on one axial end of the respective twisting ring.

Embodiments of a device are characterized in that the pockets are designed to be open on one side in the radial direction, the pockets of the outer twist rings being designed to be open in the direction of the further twist rings, and that the pockets of the inner twist rings each point to the open side of the pockets of a directly adjacent twisting ring are open. The pockets provided in the twist rings are open along a circumferential surface of the twist ring. As a result, the width of the, in particular inner, twist rings can be kept small, so that the unformed hairpin ends can be more easily accommodated in the pockets after being inserted into the bobbin. Another advantage of the pockets, which are radially open on one side, is that during the twisting movement in which the Hairpin ends are reshaped in the circumferential direction, these also experience a Kraftwir effect in the radial direction. Due to the force acting in the radial direction, the hairpin ends either rest against the radial circumferential wall of the pocket and are thus completely held in place, or slide on the open side along the circumferential surface of the adjacent twist ring and the hairpin ends thus approach each other the hairpin ends of this adjacent layer, to which they will be connected in an electrically conductive manner in a later work step.

Apparatus according to embodiments are characterized in that the pockets have at least one depth in the axial direction which corresponds to a non-isolated length of the hairpin ends. For a later connection, the hairpin ends preferably have end regions which are not insulated or have been freed from insulation. In order to maintain the most axial alignment possible of the non-insulated end regions, these are advantageously included in the pockets. By appropriately deep trained Ta rule in the axial direction transmission of the force during the twisting movement is improved. The pockets can also have a depth so that isolated areas can also be accommodated. Advantageously, pockets with different axial depths can also be provided in order to be able to accommodate different long hair pin ends or, in particular, connection pins.

Embodiments of a device are characterized in that the outer twist rings have fastening means with which the device can be connected to drives for the rotary movements. A connection with one or more drives is necessary to move the twist rings in the circumferential direction. Preferably, a drive is provided per direction of rotation, which are connected to the device via fastening means, in particular detachably. By appropriately designing the connection points of the drives, for example as a turntable to which a twist ring is attached with fastening means such as screws, or as circumferential levers or ring segments with which a twist ring is connected, devices for differently dimensioned spools on a machine be used. Instead of the twist rings with which the coupling means are firmly connected, the coupling means can also be connected directly to the drives.

Another aspect of the invention is a method for twisting hairpin ends of a coil for an electrical machine by means of a device according to the description and figures, comprising the method steps

- Placing the device on the hairpin ends, at least the non-isolated hairpin ends are received in pockets of the twist rings,

- Turning the twist rings in opposite directions, twisting rings connected to one another via coupling means being turned in the same direction,

- Removal of the coil with reshaped hairpin ends from the device.

As also stated in the description of the device, the, preferably not isolated, end regions of the hairpins are taken in the pockets of the twist rings. The twist rings are then rotated relative to one another, with twist rings being connected with the same direction of rotation via coupling means. The connection via the coupling means can be rigid, as a result of which all connected twist rings are moved by the same angle of rotation. Alternatively, the coupling means can also be designed in such a way that the twist rings are moved by different angles of rotation by the coupling means being formed, for example, by gears or the like, or by means of corresponding receptacles on the twist rings, these only come into operative connection with the coupling means later. Different twist angles for the different layers can be represented by different angles of rotation.

Relative rotational movement of the twist rings in opposite directions of rotation can take place simultaneously or sequentially.

After the twisting process, the coil is removed from the device, the end areas of the now reshaped hairpins being pulled in the axial direction out of the pockets of the twist rings. The coil is then fed to the further production steps, for example welding the deformed hairpin ends. Preferably, after the bobbin has been removed, the twist rings are rotated back into their starting position before the next bobbin is inserted.

Likewise, an electrical machine with a coil formed from hairpins, which is produced by means of a described method on a device according to the description, is an aspect of the invention.

The machine here has at least one drive with which the fastening means of the device can be connected.

The invention is explained in more detail below with reference to figures. Identical or similar components are denoted by uniform reference symbols. The figures show in detail:

Fig. 1 shows an embodiment of a device.

Fig. 2 shows a further embodiment of a device.

FIG. 3 shows a section in the radial direction of an exemplary embodiment according to FIG.

Fig. 4 shows part of a further embodiment of a device axially cut.

In Fig. 1 an embodiment of a device (1) is shown. The device (1) comprises several twist rings (2.1; 2.2; 3) which are arranged coaxially. Thus there are several inner twist rings (3) between the two outer twist rings (2.1; 2.2), wherein the outer twist rings (2.1; 2.2) can be made more massive. The radially inner outer twist ring (2.2) can also be designed as a solid cylinder.

The outer twist rings (2.1; 2.2) are each connected to a separate drive (8) via fastening means (7) in order to move the twist rings (2.1; 2.2) in opposite directions to one another in the circumferential direction. In Fig. 1 only a carrier plate for a drive (8) is shown, which is connected to the radially outer outer twist ring (2.1).

The twist rings (2.1; 2.2; 3) with the same direction of rotation are each connected to one another via Kopplungsmit tel (4; 4.1; 4.2). The coupling means (4; 4.1; 4.2) apply a driving force from a driven twist ring (2.1; 2.2; 3), preferably an outer twist ring (2.1; 2.2), to the further twist rings (2.1; 2.2; 3), preferably inner twist rings (3), transferred with the same direction of rotation.

In order to prevent the coupling means (4; 4.1; 4.2) from being blocked by twist rings (2.1; 2.2; 3) lying between or adjacent to the connected twist rings (2.1; 2.2; 3), these twist rings (2.1; 2.2; 3) each passage (5; 5.1;

5.2) for the coupling means (4; 4.1; 4.2) of the other direction of rotation. In FIG. 1, openings (5; 5.2) are also provided in the radially outer outer twist ring (2.1). These passages (5; 5.1; 5.2) improve the guidance of the coupling means (4; 4.1; 4.2), in particular in the axial direction, as well as better power transmission to the adjacent twisting ring (3) connected to the coupling means (4; 4.1; 4.2) ) improved. Correspondingly, passages (5; 5.1) can also be provided on the radially inner outer twist ring (2.2) analogously. The passages (5; 5.1;

5.2) instead of continuous recesses in the outer twist rings (2.1;

2.2) can also be formed by grooves. Embodiments are also possible in which no passage (5; 5.1; 5.2) is provided in the outer twist rings (2.1; 2.2), which reduces the manufacturing effort.

In embodiments, instead of the twist rings (2.1; 2.2; 3), the coupling means (4; 4.1; 4.2) can also be connected to the respective drive. This is particularly advantageous in embodiments in which the outer twist rings (2.1;

2.2) have the same direction of rotation. At one axial end of the individual twist rings (2.1; 2.2; 3) pockets (6; 6.1; 6.2) are provided, which serve to accommodate hairpin ends of a coil held at least in the circumferential direction. When the twist rings (2.1; 2.2; 3) are rotated, the hairpin ends are thereby moved in the circumferential direction and thus reshaped.

The coil is preferably only guided in the axial direction, whereby a change in the axial length due to the deformation of the hairpin ends in the circumferential direction can be compensated for or adjusted.

In Fig. 1, optional positioning aids (9) are also shown, with which, for example, a starting position of the device can be marked. The positioning aids (9) are provided as radial markings on two adjacent twist rings (2.1; 2.2; 3). Correct positioning or alignment of the device (1), more precisely the twist rings (2.1; 2.2; 3) with respect to one another, can thus be checked and ensured.

Embodiments are also possible in which the outer twist rings (2.1;

2.2) have no pockets (6; 6.1; 6.2) or their pockets (6; 6.1; 6.2) are not used and the outer twist rings (2.1; 2.2) are connected to the drives and only actuate the coupling means (4) and the Hold the inner twist ring (3). As a result, the same outer twist rings (2.1; 2.2) can be used for different designs with different inner twist rings (3) in order to reduce the tool costs per design.

Fig. 2 shows a further embodiment of a device (1). The basic one

The structure largely corresponds to that of the structure described above for FIG. 1, to which reference is made.

A difference to the embodiment in Fig. 1 is that the outer de outer twist ring (2.1) and the inner twist rings (3) rest on a radially extending section of the inner outer twist ring (2.2) on the side facing away from the pockets (6) . This has the advantage, among other things, that the Direction (1) can be prepared or provided separately and can be handled as a unit and installed in the machine.

Fuses (11) are preferably provided which, in particular, secure the outer twist rings (2.1; 2.2) from being lifted off from one another, but allow a relative movement in the circumferential direction. In the embodiment shown, fuses (11) are provided which intervene in an extension of the passages (5).

As positioning aids (9), several notches provided on the jacket surfaces of the outer twist rings (2.1; 2.2) are introduced in FIG. 2. By means of several positioning aids (9) provided at a defined distance from one another, different positions can be marked and, in addition to, for example, an initial position, different twist angles can also be determined for different versions of coils.

In Fig. 3 is a sectional view of an embodiment according to FIG. 2 is shown, the section along a plane perpendicular to the axis of rotation Ebe ne in the area of the passages (5).

The outer twist rings (2.1; 2.2) are solid. The inner outer twist ring (2.2) is connected to a drive with fasteners (7), here screws. Furthermore, the inner, outer twisting ring (2.2) has an area which extends outward in the radial direction and on which safeguards (11) are provided. The fuses (11) are designed in this Ausführungsbei play as ring disks flattened on one side, which, depending on the rotational position, enables the outer twisting ring (2.1) to be lifted off or in a groove of the outer twisting ring (2.1) formed in extension of the passage (5; 5.2) ) intervenes to prevent lifting. The groove can be connected to the passage (5; 5.2) or can also be designed separately from it. The groove can also have a width and / or depth that differs from the passage (5; 5.2) and / or be provided at a different height in the axial direction. It is also possible for the groove to be formed by the passage (5; 5.2) itself is, especially when the passage (5; 5.2) comprises a larger circumferential area than the twist angle or the coupling means (4.2) arranged in the passage (5; 5.2) does not extend over the complete radial length of the outer twist ring (2.1).

Coupling means (4.1; 4.2) are received in each of the outer twist rings (2.1; 2.2) in order to connect twist rings (2.1; 2.2; 3) with one another in the same direction of rotation. Correspondingly, corresponding passages (5.1; 5.2) for the coupling means (4.1; 4.2) of the respective other direction of rotation are provided in the twist rings (2.1; 2.2; 3). Through the passages (5.1; 5.2), the twist rings (2.1; 2.2; 3) can be rotated relative to the coupling means (4.1; 4.2) passing through.

In the illustrated embodiment, the coupling means (4.1; 4.2) are designed as dowel pins extending in the radial direction. A threaded hole is provided at one end of the dowel pins in order to enable or simplify dismantling of the device.

For each direction of rotation, three coupling means (4.1; 4.2) are arranged uniformly distributed over the circumference in FIG. Depending on the size of the device and the forces that occur, more or fewer coupling means (4.1; 4.2) can be provided for each direction of rotation. A different number of coupling means (4.1; 4.2) can also be provided for the different directions of rotation.

For a first direction of rotation, coupling means (4.1) for a first direction of rotation are added to the outer twisting ring (2.1). These coupling means (4.1) are also connected to every second of the inner twist rings (3) in order to be able to move them in the same direction of rotation by the same twist angle. Corresponding passages (5.1) are provided in the intermediate inner twist rings (3) and the inner outer twist ring (2.2), through which the coupling means (4.1) can pass for a first direction of rotation and can thus be moved relative to one another.

Accordingly, coupling means (4.2) are added for a second direction of rotation in the inner lying outer twist ring (2.2). These coupling means (4.2) connect the inner outer twist ring (2.2) with the corresponding inner ones Twist rings (3) with the same direction of rotation. The twist rings (2.1; 3) with a first direction of rotation similarly have corresponding passages (5.2) for the coupling means (4.2) of the second direction of rotation.

4 shows a section along a plane of a further exemplary embodiment running in the radial and axial directions, only one half being shown. The twist rings (2.1; 2.2; 3) are shown in an initial position.

In this exemplary embodiment, in addition to the outer twist rings (2.1; 2.2), four inner twist rings (3) are provided, with a different number of twist rings being able to be provided, just as in the other exemplary embodiments, depending on the coil to be produced.

At one axial end of the twist rings (2.1; 2.2; 3) pockets (6; 6.1; 6.2) for receiving the contact ends to be formed are formed in each case. It is shown here that the pockets (6; 6.1; 6.2) in this embodiment are each open to a circumferential surface of the twist rings (2.1; 2.2; 3) and the open circumferential surface of directly adjacent twist rings (2.1; 2.2; 3) each other are facing. Correspondingly, the result for the inner twist rings (3) is that their closed circumferential surfaces likewise each face a closed circumferential surface of a directly adjacent inner twist ring (3). Such a configuration enables the contact ends, in addition to the twisting movement, in which they are reshaped in the circumferential direction, to be brought closer to one another at the same time as contact pairs to be connected to one another in a double layer.

In the case of individual pockets (6; 6.1; 6.2) of a twisting ring (2.1; 2.2; 3), in particular of an inner twisting ring (3), the open and closed circumferential surfaces can be exchanged in order to provide contact pairs for a transition between the double layers. Correspondingly, pockets (6.1) for contact ends, which are to be connected to an interconnection and therefore not connected to another contact end, can be formed without an open circumferential surface or, at the end of the twisting movement, lie opposite a closed circumferential surface. In particular, the outer twist rings (2.1; 2.2) can have a number of pockets (6; 6.1; 6.2) that differs from the number of slots in the coil to be manufactured. Especially in embodiments in which a total of more twist rings are provided than layers on the spool.

The inner twist rings (3) shown in Fig. 4 pockets (6.2) have a second depth in the axial direction in order to safely accommodate at least the, preferably non-isolated, con tact ends which are to be deformed and then connected to contact pairs can and through this second axial depth, an end region of the contacts that extends in the axial direction after the deformation is maintained.

The outer twist rings (2.1; 2.2) shown in Fig. 4, however, have pockets (6.1) which have a first axial depth with a greater extent in the axial direction than the pockets (6.2) with a second depth of the inner twist rings (3) . These are provided for receiving contact ends, which are connected to a circuit and are not connected to a contact pair. The greater axial extension of the first axial depth provide space for the contact ends, which are generally longer, for the interconnection.

Pockets (6; 6.1; 6.2) with a first and / or second axial depth can be provided on a twist ring (2.1; 2.2; 3). The pockets (6.1) with a first axial depth are provided at least at the positions for contact ends to be connected with an interconnection. In order to use the same twist rings (2.1; 2.2;

3) to be able to use for different coils and / or to simplify the production and assembly, all pockets (6) of a twisting ring (2.1; 2.2; 3) can be provided with pockets (6.1) of a first axial depth, since these also allow individual Contact ends that are to be connected to a contact pair can be kept for the deformation.

The inner twist rings (3) of the embodiment shown in Fig. 4 have on their axial side facing away from the pockets (6; 6.1; 6.2) coaxially nested projections in the radial direction in order to increase the width of this end face in the radial direction. The coupling means (4.1; 4.2) are connected to the outer twist rings (2.1; 2.2) and initially comprise a section extending in the axial direction, with a sufficient clearance between the coupling means (4.1; 4.2) to allow the nested projections of the to accommodate inner twist rings (3) in the radial direction.

The axial section of the coupling means (4.1; 4.2) is followed by radially extending sections which cover at least the radial projections of the inner twist rings (3) with the same direction of rotation. Here, the radia len sections of the coupling means (4.1; 4.2), as shown, follow one another in the axial direction. In such a structure, at least the coupling means (4.1; 4.2) facing the inner twist rings (3), in FIG. 4 the coupling means (4.2) for a second direction of rotation, openings (5.1; 5.2) for the coupling means (4.1; 4.2) the opposite side.

The connection between the coupling means (4.1; 4.2) and the inner Twistrin gene (3) takes place in the illustrated embodiment via connecting bolts (10), where in Fig. 4 the connecting bolts (10) of the coupling means (4.1) for a first direction of rotation through passages (5.1) run in the coupling means (4.2) for a second direction of rotation. Instead of the connecting bolts (10), dowel pins or the like can also be used. For the passages (5.1) apply in terms of the circumferential length and the like analogously to the information given in the other exemplary embodiments.

Alternatively, the radially extending sections of the coupling means (4.1; 4.2) can run in one plane if they each extend only over partial areas of the circumference and have a clear width sufficient for the twisting movement in the circumferential direction. In such variants, a passage (5.1; 5.2) can be dispensed with and the coupling means (4.1; 4.2) can be used directly as a stop for limiting the twist angle.

The invention is not restricted to the embodiments described. As stated above, only individual advantageous features can be provided. or different features of different examples are combined with one another.

Description of twist device Outer twisting ring Outer twisting ring lying radially outside Outer twisting ring lying radially inside Inner twisting ring coupling means coupling means for a first direction of rotation coupling means for a second direction of rotation passage passage for coupling means of a first direction of rotation passage for coupling means of a second direction of rotation pockets pockets with a first axial depth pockets with a second axial depth pockets Depth fasteners Drive positioning aid Connecting bolt Securing

Claims

Claims

1. Device (1) for twisting hairpin ends of a coil formed from hairpins for an electrical machine, comprising several coaxially arranged twist rings (2.1; 2.2; 3), two outer twist rings (2.1; 2.2) and at least two inner twist rings ( 3) are arranged, the twist rings (2.1; 2.2; 3) each having at an axial end facing the hairpin ends a plurality of pockets (6; 6.1; 6.2) distributed over the circumference for receiving one hairpin end , and wherein the twist rings (2.1; 2.2; 3) are rotatable in opposite directions to one another, characterized in that the twist rings (2.1; 2.2; 3) have coupling means (4.1; 4.2) through which twist rings (2.1; 2.2; 3) with are connectable in the same direction of rotation.

2. Device (1) according to claim 1, characterized in that directly neighboring twist rings (2.1; 2.2; 3) are rotatable in opposite directions.

3. Device (1) according to claim 1 or 2, characterized in that at least the inner twist rings (3) have a passage (5.1; 5.2) for the coupling means (4.1; 4.2) of the twist rings (2.1; 2.2; 3) with another Have direction of rotation.

4. Device (1) according to claim 3, characterized in that the passage (5.1; 5.2) is formed as an elongated hole extending over part of the circumference.

5. Device (1) according to one of the preceding claims, characterized in that the twist rings (2.1; 2.2; 3) each have at least two coupling means (4.1; 4.2) distributed around the circumference, preferably symmetrically.

6. Device (1) according to one of the preceding claims, characterized in that the coupling means (4.1; 4.2) are formed as a dowel pin which is received in corresponding receptacles on the twist rings (2.1; 2.2; 3).

7. Device (1) according to claim 6, characterized in that some of the twist rings (2.1; 2.2; 3) have receptacles which have a clear width in the direction of movement compared to the dowel pin in the starting position, around the twist ring (2.1; 2.2 ; 3) To move a rotation angle that is smaller than the dowel pin according to the clear width.

8. Device (1) according to one of the preceding claims, characterized in that the number of twist rings (2.1; 2.2; 3) corresponds to the number of layers of the coil.

9. Device (1) according to one of the preceding claims, characterized in that the number of pockets (6; 6.1; 6.2) per twist ring (2.1; 2.2; 3) corresponds to the number of slots in the coil.

10. Device (1) according to one of the preceding claims, characterized in that the pockets (6; 6.1; 6.2) are formed open on one side in the radial direction, the pockets (6; 6.1; 6.2) of the outer twist rings (2.1 2.2) are each designed to be open in the direction of the further twist rings (2.1; 2.2; 3), and that the pockets (6; 6.1; 6.2) of the inner twist rings (3) each face the open side of the pockets (6; 6.1; 6.2) of a directly adjacent twisting (2.1; 2.2; 3) are open.

11. Device (1) according to one of the preceding claims, characterized in that the pockets (6; 6.1; 6.2) have at least a depth in the axial direction which corresponds to a non-isolated length of the hairpin ends.

12. Device (1) according to one of the preceding claims, characterized in that the outer twist rings (2.1; 2.2) fastening means (7) aufwei sen with which the device (1) can be connected to drives (8) for the rotary movements.

13. A method for twisting hairpin ends of a coil for an electrical Ma machines by means of a device (1) according to one of claims 1 to 12, to summarize the method steps

- Placing the device (1) on the hairpin ends, at least the non-insulated hairpin ends in pockets (6; 6.1; 6.2) of the twist rings (2.1; 2.2; 3) are taken up,

- Rotation of the twist rings (2.1; 2.2; 3) in opposite directions, with the twist rings (2.1; 2.2; 3) connected to each other via coupling means (4.1; 4.2) being rotated in the same direction,

- Removal of the coil with reshaped hairpin ends from the device (1).

14. Electrical machine with a coil formed from hairpins, which is produced by means of a method according to claim 13 on a device (1) according to one of claims 1 to 12.