EP2272072A1

EP2272072A1 - Coil and method for producing a coil

Info

Publication number: EP2272072A1
Application number: EP09728741A
Authority: EP
Inventors: Bernhard Roellgen; Herbert-Maurizio Cardarelli
Original assignee: Epcos AG
Current assignee: TDK Electronics AG
Priority date: 2008-03-31
Filing date: 2009-03-23
Publication date: 2011-01-12
Anticipated expiration: 2029-03-23
Also published as: US9424973B2; DE102008016488A1; JP5753488B2; CN102047356A; WO2009121749A1; EP2272072B1; US20110068886A1; JP2011517077A

Abstract

The invention specifies a coil which has at least four electrical lines (2, 2'), wherein the electrical lines (2, 2') are wound around a common winding centre (3). Each of the at least four electrical lines (2, 2') is at a constant distance from the winding centre (3) of the coil (1) over the entire length of the coil (1). The coil (1) is inherently stable.

Description

description

Coil and method of making a coil

The invention relates to a coil and to methods for producing coils.

From the document DE 44 32 739 B4 an inductive electrical component is known.

It is an object of the present invention to provide a coil having a winding that comes as close as possible to the theoretically ideal winding.

The object is achieved by a coil according to claim 1. Furthermore, the object is achieved by a method according to claim 12 and a method according to claim 24. Advantageous embodiments of the high-performance coil or the method of production are the subject of dependent claims.

It is specified a coil comprising at least four electrical lines. The electrical cables are wound around a common winding center. Over the entire length of the coil, each of the at least four electrical

Leaves a constant distance to the winding center of the coil. Under the winding center is the respective geometric center of the windings to understand. Viewed over the entire length of the coil, the winding center corresponds for example to the longitudinal axis of the coil. The individual windings of each individual electrical line are arranged side by side over the entire length of the coil. The windings of the next outward adjacent electrical line are arranged directly over the windings of the electrical cables arranged further inside. The distance of the first electrical line is constant over the entire length of the coil. The distances between the further electrical lines have, corresponding to their position, a greater distance to the winding center, wherein the distance of each individual electrical line preferably remains constant over the entire length of the coil.

Preferably, the electrical lines in the coil windings of the coil are insulated from each other. The mutual insulation of the lines reduces eddy current losses to a minimum.

Preferably, at the respective end of the coil, the at least four electrical lines are electrically conductively connected to each other, so that the lines are preferably connected in parallel. For parallel connection of the electrical lines, the electrical lines are preferably connected to each other at least at the ends of the coil by means of solder bridges. The equalizing currents flowing through the individual electrical leads are thus minimized within the winding.

In a preferred embodiment, the coil is particularly suitable for high frequency applications. However, it is also possible that the coil is used for example at high currents. Here, the current of the coil is divided by flows on the at least four parallel electrical lines. Due to the almost ideal nature of the windings, the coil can be used in almost every area in which such coils are needed. In a preferred embodiment, the electrical leads comprise twisted individual wires. These are preferably twisted strands with thin individual wires. Each current-carrying electrical conductor has a certain inductance due to the surrounding, caused by the current magnetic field. To increase the inductance of the electrical conductor can be provided with a certain number of turns. Due to the magnetic concatenation (flux linkage) of the individual windings with each other, due to the close proximity

Arrangement of the individual windings, the inductance of wound coils increases in square with the number of turns. By twisting the individual wires in an electrical line at least partially overlapping opposing magnetic fields is achieved, the magnetic fields are thus partially extinguished.

The coil is preferably constructed such that the coil has a self-supporting shape by mechanically interconnected electrical wires wound around a winding center. The self-supporting shape of the coil is preferably achieved by the mutually mechanically connected electrical lines. The coil therefore preferably does not require a bobbin that maintains the stability of the coil.

The electrical lines are at least partially mechanically fixed to each other.

In a preferred embodiment, the electrical lines are mechanically interconnected at regular or even irregular intervals. Due to the interconnected electrical cables, which are connected to a wound coil winding center, the coil reaches a self-supporting stability of their shape.

In a preferred embodiment, the electrical lines have mechanical connections with each other at regular intervals.

In a further embodiment, it is sufficient if the individual lines are only selectively connected to each other. A complete mechanical connection of the electrical

Lines over the entire length of the coil is not necessary here.

For the mechanical connection of the lines, these can be enveloped, for example, with a thermoplastic which softens during heating, for example by means of infrared light or a hot air flow, and then demoulded and connects the lines to one another. Wires that are wrapped with a thermoplastic material are also referred to as baked enamel wires.

In a further embodiment, the electrical leads can be connected to one another, for example, by applying UV-curing adhesives. The application of the UV-curing adhesive can be done, for example, while the individual lines are on a guide roller. Alternatively, the application of a UV-curing adhesive may occur shortly after peeling off the guide roll. The curing of the adhesive takes place for example by means of UV light, which is generated for example by means of a UV LED array. Alternatively, a flashlamp can be used with curing by the UV light within 200 ms. In a further embodiment, the mechanical connection of the lines can be carried out, for example, by gluing by means of an underlying piece of adhesive film. The bonding by means of adhesive film can for example be done shortly before a first pressure roller with the upward adhesive layer in the guide roller.

In a further embodiment, the lines can be connected by weaving, for example, with a plastic yarn. For the plastic yarn, for example, polyester is suitable as a base material. In a further embodiment, the plastic yarn may, for example, be provided with a baked enamel layer or a pressure-sensitive adhesive. The plastic yarn is injected, for example, by means of an air flow between the individual lines. The electrical lines connect to the plastic yarn, for example, additionally by means of pressure. Alternatively, the electrical wires can connect to the yarn by heating.

The above-mentioned possibilities for connecting the lines can be combined with each other in a suitable manner.

In a preferred embodiment, the coil may have a round, elliptical or rectangular shape as the coil cross section. However, to achieve the lowest possible electrical resistance, a circular shape is the best possible shape.

In a preferred embodiment, the inner electrical leads of the coil have a length that is shorter than the length of the next outwardly adjacent electrical lead. The parallel lines are preferably connected together so that the length of the outermost line is longer than the length of the inwardly adjacent line, wherein the length of the electrical lines thus decreases inwardly.

Due to the different lengths of the electrical lines which are mechanically connected to one another, the electrical lines thus have a curved shape after connection. The interconnected lines run in the form of a helical band, which corresponds approximately to the shape of an Archimedean screw.

In a preferred embodiment, the respective ends of the electrical leads have electrical contacts. The beginning and the end of each line is preferably designed as a pin. At low mechanical loads, these pins are sufficient to allow mounting of the device. In an arrangement of the coil with a ferrite core, the ends may be formed, for example, as SMD solder pads to the ferrite core.

In a further preferred embodiment, the ends of the electrical lines are each connected to separate contact pins. By the additional

Contact pins or solder pins can act on the contacts higher mechanical loads without the ends change their original position and shape.

The inner diameter of a coil as described above can be reduced to a minimum by the type of winding described above and the self-supporting property. The coil can already be used as an air coil, which is achieved by a winding described above, as a component. The coil in this case has no additional bobbin, which would contribute to increase the stability. Thus, the theoretically available changing room is completely available. Thus, a larger usable changing room is available.

Since no additional bobbin to stabilize the coil is necessary, extremely thin turns are achievable. In contrast to conventional flat windings, a large number of electrical lines can be accommodated in one winding.

This is for example especially for the construction of

Lamp chokes advantageous. The construction of lamp inductors requires relatively large numbers of turns, which are installed in flat ferrite cores, so that a desired switching frequency of 45 kHz, for example, can be achieved. The height of the inductors is limited by the relatively low height of the standard housing used.

In a further embodiment, for example, a plurality of coils with different diameters as described above can be inserted into one another or placed one above the other. The coils are galvanically separated from each other and thus have windings which are magnetically coupled. Thus, it is possible to form a device having the function of a transformer by using two coils. For safe separation between the individual coils, for example tubular plastic spacers inserted between the individual coils.

For example, in a further embodiment, the bobbin may function as a transformer by weaving yarns of polyester or nylon suitably incorporated into the conduits. For example, in this embodiment, the coil has an inner layer of windings of one or more electrical conductors which have been followed by one or more layers of windings of insulating material. Then follows again one or more layers of windings of an electrical conductor.

To increase the inductance of coils so-called ferrite cores are often used. The ferrite core is in this case preferably arranged such that the windings of the coil are guided around the ferrite core. Ferrite cores can be designed as ring cores, rod cores or in any other form. An air gap in the otherwise closed course of a ferrite core reduces the magnetic flux density of the core considerably and thus causes z. B. a linearization of the magnetization characteristic, according to the relationship between magnetic field strength and magnetic flux density of the component. The magnetic saturation of the core material thus occurs only at much higher field strengths. In the air gap of storage chokes, a substantial portion of the magnetic energy is stored.

When using ferrite cores having three legs, such as E cores, which preferably have a large air gap in the area between the two center limbs, It is necessary for the construction of particularly low-loss transformers or storage chokes that the windings maintain a certain minimum distance from the air gap. For this purpose, bobbins are often used with a pillow-shaped portion of the coil. Under a pillow is a

To understand area of the coil in which there are no or few windings in the region of the air gap between two ferrite cores. Such a cushion can be achieved with the coil described above, for example, by pulling apart the windings in the region of the air gap. The targeted stretching of the coil ensures that only a few windings of the coil are located in the area of the air gap. In order to stabilize the coil in the region of the pad, a circular segment-shaped plastic part can be arranged, for example, in this area. The plastic part may be inserted, for example, in the region of the air gap.

To fix the coil, the preferably pressed coil can be provided, for example, with an additional potting compound. The potting compound serves as an insulating protective layer. Furthermore, the coil through the layer of potting compound on a further stabilization.

To produce a coil as described above, at least four electrical lines are pressed by means of at least a first and a second conical pressure roller on a preferably conical guide roller. The guide roller has guides, which are preferably arranged concentrically around the axis of rotation of the guide roller. Preferably, the guide roller has the shape of a truncated cone. In a preferred embodiment, the guides may be arranged as groove-shaped, concentric depressions on the guide roller. Each of the at least four electrical lines is guided in a separate guide of the guide roller. The electrical leads are preferably mechanically connected to each other during rotation of the guide roller. After the circulation of the guide roller, the electrical lines in the form of a helical band.

By mechanically connecting the individual lines and by the circulation of the guide roller, the electrical wires bend automatically into a helical band. In a theoretically endlessly long band of such linked wires would be a helical

Forming an endless band resembling an Archimedean screw.

The pressure rollers are preferably mounted with respect to shape and size accurately to the guide roller. The first pressure roller leads the electrical lines with the speed corresponding to the respective radius of the guide roller to the guide roller. For safe guidance of the individual electrical lines in the guides of the guide roller, the second Andrucksrolle is also precisely matched to the leadership role.

Preferably, when circulating the guide roller, the lines are mechanically interconnected. The connection of the individual lines can take place, for example, according to the alternatives described above for the component For further fixing, the preferably pressed coil can be immersed in a trough with potting compound after winding. This creates a protective layer, through which the winding is further fixed. The winding thus also receives an insulating protective layer.

Another method for producing a coil is a method in which at least four electrical lines are wound around a rotating axis of a winding tool by means of a wire guide. In this case, each of the at least four electrical lines has a separate wire guide. Preferably, the individual wire guides are arranged side by side in a single component. The electrical lines are in a winding plane perpendicular to the axis of rotation of the

Winding tool is arranged, wound around the axis of rotation. With increasing number of turns, the wire guide is guided parallel to the axis of rotation, so that a winding is formed. The electrical leads are preferably mechanically interconnected during winding.

At the beginning of the winding process, the first ends of the electrical lines are inserted in a guide of a first winding tool. The guide can be formed for example by a slot or a recess in the winding tool. By means of, for example, a magnet, the electrical lines are fixed in the recess.

The inner diameter of the coil to be wound is determined by the outer diameter of the rotating axis around which the wires are wound. Preferably, the wire guide moves at the speed in the winding direction, with which the already wound up winding grows. A shield arranged on the wire guide, which is arranged concentrically around the axis of rotation, can serve, for example, to exert pressure on the already finished area of the coil, so that the position of this area can no longer change. As soon as the wire guide has reached the end of the coil to be wound up, the wire ends can, for example, be manually introduced into further slot-shaped depressions of a second winding tool. The second winding tool is connected to the first winding tool via, for example, a coupling with each other and rotates in the same speed and with the same direction of rotation, as the first winding tool.

For fixing the roll, for example, when using lines which are enveloped by a thermoplastic layer, the winding is heated during winding with an infrared radiator or a hot air flow above the softening point of the thermoplastic layer. The coil can be taken after cooling below the softening temperature of the thermoplastic layer of plastic from the form-giving winding tool. The previously inserted into the wells of the winding tools ends are taken out of this case.

Alternatively, the coil can be fixed, for example, by means of a fast-curing adhesive which is introduced during winding. In this case, cables of any type can be used. The adhesive can, for example, enforce the entire winding. In a In another embodiment, only the end or the beginning of the roll can be penetrated by an adhesive layer. When using winding tools, which consist of Teflon, for example, acrylate adhesives or epoxy resins can be used without causing problems during demoulding.

For further fixing, the preferably pressed coil can be immersed in a trough with potting compound after winding. This creates a protective layer through which the

Winding is further fixed. The winding thus also receives an insulating protective layer.

The coil described above is preferably used as a high-frequency choke in the range of 30 kHz to well over 5 MHz.

Due to the low-capacitance structure of the coil by the use of, for example, twisted strands, which are stacked on top of each other, a high Q-factor is achieved.

The use of twisted strands achieves a reduction in the proximity effect. In one embodiment, strands of 30 to 50 twists / meter are used. Preference is given to using strands having a number of preferably up to 200 twists per meter.

The coil has a high DC resistance at low frequencies compared to a flat coil. At high

However, the HF resistance does not increase as much as frequencies of flat windings or conventional windings (layer windings). A layered wrap with For example, 27 turns has, for example, a RM6 core of N49 material, 0.48 ohms air gap, 350 ohms frequency, 0.78 ohms resistance, and 750 kHz, 2.86 ohms resistance , A winding as described above has a resistance of 1 ohm at the same number of turns and the same core at 350 kHz, but at 750 kHz only a resistance of 2 ohms.

Due to the higher Q-factor, the coil has a narrower and higher resonance curve at high frequencies (eg 500 kHz) when excited at the 3rd, 5th and 7th harmonic.

The objects described above will be explained in more detail with reference to the following figures and exemplary embodiments.

The drawings described below are not to be considered as true to scale. Rather, for better representation, individual dimensions can be enlarged, reduced or distorted. Elements that are equal to each other or that perform the same functions are denoted by the same reference numerals.

FIG. 1 shows a schematic structure of a coil,

FIG. 2 shows a schematic structure of the windings of a coil,

FIG. 3 schematically shows a first apparatus for producing a coil, FIG. 4 shows schematically another device for producing a coil.

1 shows a schematic diagram of a first embodiment of a coil 1. Several electrical lines 2, 2 'are wound around a common winding center 3. The distance d of the electrical line 2 to the longitudinal axis of the coil 1 is equal over the entire length of the coil 1. The distances between the further electrical leads 2 'to the longitudinal axis of the coil 1 are also approximately constant over the entire length of the coil 1. The coil 1 has an inner diameter D1, which is approximately equal over the entire length of the coil 1. The electrical lines 2, 2 'of a winding plane are preferably arranged uniformly one above the other. By co-winding the electrical lines 2, 2 'is achieved that the electrical lines 2, 2' come to lie directly above each other. Preferably, at the beginning and at the end of the coil 1, the electrical lines 2, 2 'are electrically connected together. The electrical lines 2, 2 'are arranged parallel to one another over the entire length of the coil 1. The coil 1 preferably has at the beginning and at the end of an electrical contact 4, via which the coil 1 can be electrically connected.

Due to the windings of the electrical lines 2, 2 ', the coil 1 has a sufficiently high stability, so that the coil 1 does not require an additional bobbin. In the winding center 3 of the coil 1, a ferrite core 5 may be inserted. Alternatively, the coil 1 may also be pushed, for example, onto the arms of a ferrite core having an E-shape. Preferably in the region of the air gap of the E cores, the coil 1 is pulled apart, so that a kind of cushion is created in the area of the air gap of the E-cores. In the area of the pillow are ideally no, or as few turns.

In FIG. 1, a part of the turns is marked as area A. The area is shown enlarged in FIG.

FIG. 2 shows a section of the coil from FIG. The electrical lines 2, 2 'are in the

Figure 2 shown as strands. In this case, each of the strands about 12 individual wires, which are twisted into each other. However, the electrical leads 2, 2 'may also consist of individual wires, rectangular flat wires or other wire forms. The individual electrical lines 2, 2 'are arranged exactly one above the other. The distance of the first electrical line 2 to the winding center of the coil 1 is approximately equal over the entire length. Directly above the first electrical line 2, a second 2 'and further electrical lines are arranged, which are wound together with the first electrical line 2 to a common winding center.

FIG. 3 schematically shows a first possible arrangement for producing a coil 1, which is shown in FIGS. 1 and 2. To produce a coil 1, a plurality of electrical lines 2, 2 'are guided via a wire guide 100 to a first pressure roller 11. The first pinch roller 11 presses the electrical leads 2, 2 'on guides 13 of a guide roller 12. The first pinch roller 10 is adapted in shape to the guide roller 12 and rotates at the same speed as the guide roller. The guide roller 12 has a conical shape in the illustrated arrangement. The electrical lines 2, 2 'are guided on differently sized concentric guide grooves around the guide roller 12. Due to the conical shape of the guide roller, the electrical lines 2, 2 'are guided around the guide roller 12 at different speeds. In order to guide the electrical lines 2, 2 'for about a quarter turn on the guide roller 12, a second pressure roller 11 is arranged at an angle of approximately 90 ° to the first pressure roller 10. The second

Pinch roller 11 is like the first pinch roller 10 adapted to the shape and size of the guide roller 12 and rotated at the same speed.

Between the two pinch rollers 10, 11, the electrical lines 2, 2 'by means of an infrared line emitter 15 mechanically connected. The electrical lines 2, 2 ', for example, a thermoplastic plastic sheath (baked enamel wires), which stick together when heated.

For example, the first pressure roller 10 can additionally be heated so that the thermoplastic plastic coating (baked enamel layer) in the region of the first pressure roller 10 to slightly below the first

Softening temperature of the plastic wrap is heated. By means of infrared light or with a hot air flow, the individual electrical lines 2, 2 'are mechanically interconnected. For cooling the plastic envelopes, for example, the guide roller 12 and / or the second pressure roller 11 is cooled. Alternatively, the electrical leads 2, 2 'can also be interconnected by means of a UV-curing adhesive. The adhesive can be applied, for example, as long as the electrical leads 2, 2 'are located in the guides of the guide roller 12. Alternatively, the adhesive can also be applied to the electrical leads 2, 2 'shortly after leaving the guide roller 12. The curing of the adhesive takes place by means of UV light from a UV LED array or a flashlamp, preferably within 200 ms.

In order to connect the electrical lines 2, 2 'mechanically with each other, and adhesive tape can be used. For this purpose, the adhesive strips are placed only shortly before the first pressure roller on the guide roller 12 with the upward adhesive layer.

In order to achieve sufficient stability of the coil 1, it is sufficient if the individual electrical lines 2, 2 'are only selectively connected to each other. It is sufficient if the electrical lines 2, 2 'are connected to each other at regular intervals.

After the circulation of the guide roller 12, the mechanically interconnected electrical lines 2, 2 'have a helical shape. The helical shape is due to the fact that the length of the outermost electrical line 2 is longer than the length of the adjacent electrical line 2 '. The next inwardly adjacent electrical line 2, 2 'is always shorter in each case. If the electrical lines 2, 2 'endlessly linked in such a way, a helical endless belt is formed - similar to an Archimedean screw. The endless band can, as shown in FIG. 3, for example collected in a co-rotating collecting cup 14. By gravity, the windings automatically overlap, which compresses the resulting winding. After reaching the desired number of turns, the endless belt can be severed. Further compression of the loose roll in the collecting cup 14 can be done for example by simple pressing. Alternatively, the winding can also be further compressed by means of a shrink tube.

FIG. 4 diagrammatically shows a further arrangement for producing a coil 1. For this purpose, a plurality of electrical lines 2, 2 'by means of a two-part winding tool 102, 103 wound around a rotating shaft 101. The ends of the electrical leads 2, 2 'are in slot-shaped recesses 105 of the first winding tool

102 and fixed by means of a magnet 106. The two halves of the winding tool 102, 103 are set at the same speed and direction in rotation. In order to achieve a synchronization of the two winding tools 102, 103, the two halves of the winding tool 102,

103 connected to each other by means of a coupling 107. However, it is also possible to achieve the synchronization of the two halves by means of other technical devices.

The forming winding tool 102, 103 is in two parts, so that the finished winding after winding can be easily removed from the winding tool 102, 103. The rotating axis 101 preferably has the outer diameter D2, which corresponds to the inner diameter Dl of the coil 1 to be wound. To guide the electrical lines 2, 2 ', a wire guide 100 is arranged in the region of the rotating axis 101. By means of the wire guide 100, the electrical lines 2, 2 'are wound in the winding plane one above the other about the rotating axis 101. Here, the electrical line 2 ', which has the smallest distance d to the winding center, which is here formed by the rotating axis 101, guided at a lower speed about the rotating axis 101 as further outwardly disposed electrical lines 2. The length of the farther inside arranged electrical lines 2 'is thus shorter than that of the further outwardly disposed electrical lines 2. To prevent slippage of the already wound windings, a shield 104 is parallel to the wire guide. The shield 104 and the wire guide 100 are arranged on a slidable in the x-direction slide, which is not shown here for reasons of clarity. The carriage shifts the wire guide 100 and the shield 104 with increasing winding along the rotating axis 101. The shield 104 additionally causes, because of strong pressure on already finished wound areas of the coil 1, these areas can no longer change their position. As soon as the wire guide 100 has almost reached the inner boundary of the right-hand winding tool 103, the ends of the electrical leads 2, 2 'become slotted

Recesses 105 of the right winding tool 103 inserted manually or by means of a tool. In this case, the wire guide 100 is no longer moved, so that further pressure can be exerted on the already wound areas of the coil 1 by the shield 104.

To fix the windings can, for example, in the use of electrical lines 2, 2 'with a thermoplastic encasing, already during the Wickeins by means of an infrared radiator or a hot air stream, the plastic covering over the

Softening temperature of the plastic layer are heated. After the coil has cooled below the softening temperature of the plastic covering, the finished wound coil 1 can be removed from the winding tool 102, 103. The ends of the electrical lines 2, 2 'are previously at least partially taken from the slot-shaped recesses 105 of the two halves of the winding tool, so that the ends can not tilt.

To stabilize the roll, it is also possible to use UV-curing adhesive which is introduced during winding. In this case, any electrical lines 2, 2 'can be used. The adhesive can pass through the entire winding, or alternatively only partial area such as the beginning or end of the roll. In another embodiment, the parts of the assembly which come in contact with the adhesive may be made of Teflon. This makes it possible to use epoxy or acrylic resins to stabilize the coil 1, without causing problems during demoulding.

When using an additional bobbin around which the electrical lines 2, 2 'are wound, only the winding start and the end must be fixed.

Although only a limited number of possible developments of the invention could be described in the embodiments, the invention is not limited to these. It is possible in principle further possible arrangements to use, with which a coil described above can be made.

The invention is not limited to the number of elements shown.

The description of the objects specified here is not limited to the individual specific embodiments, but the features of the individual embodiments, as far as technically feasible, can be combined with each other arbitrarily.

LIST OF REFERENCE NUMBERS

1 coil

2, 2 'electrical lines

3 winding center

4 electrical contacts

5 ferrite core

A section

10 first pinch roller

11 second pinch roller

12 leadership role

13 tours

14 collection cup

15 infrared line emitters

16 mechanical connection

100 wire guide

101 rotating axis

102, 103 Wiekel tool

104 shield

105 deepening

106 magnet

107 clutch d distance from an electrical line (2, 2 'to the winding center 3

Dl inner diameter of the coil 1

D2 outer diameter of the rotating axis 101

Claims

claims

1. coil, comprising at least four electrical lines (2, 2 '), - wherein the electrical lines (2, 2') are wound around a common winding center (3), wherein each of the at least four electrical lines (2, 2 ') over the entire length of the coil (1) has a constant distance from the winding center (3) of the coil (1), and wherein the coil (1) is mechanically stable in itself.

2. Coil according to claim 1, wherein the electrical lines (2, 2 ') in the region of the windings are insulated from each other.

3. Coil according to one of the preceding claims, wherein the electrical lines (2, 2 ') at least at the ends of the coil (1) are contacted with each other.

4. Coil according to one of the preceding claims, wherein the electrical lines (2, 2 ') consist of twisted individual wires.

5. Coil according to one of the preceding claims, wherein the electrical lines (2, 2 ') are mechanically interconnected.

6. A coil according to claim 5, wherein the electrical lines (2, 2 ') are interconnected at regular intervals.

7. Coil according to one of the preceding claims, wherein the length of the inner electrical line (2) over the entire coil (1) is shorter than the length of the outwardly adjacent electrical line (2 ').

8. A coil according to any one of the preceding claims, wherein the respective ends of the electrical lines (2, 2 ') have electrical contacts (4).

9. A coil according to claim 8, wherein the ends of the electrical leads (2, 2 ') are connected to contact pins.

10. Coil according to one of the preceding claims, wherein in the winding center (3) a ferrite core (5) is arranged.

11. Coil according to one of the preceding claims, wherein the coil (1) has a square shape in cross section.

12. Coil according to one of the preceding claims, wherein the coil (1) is coated with a potting compound.

13. A method for producing a coil, wherein at least four electrical lines (2, 2 ') by means of at least a first (10) and a second conical pressure roller (11) on a conical

Guide roller (12) are pressed, wherein the guide roller (12) grooved concentric

Recesses (13), - wherein each of the electrical lines (2, 2 ') in a separate guide (13) of the guide roller (12) is guided, wherein the electrical lines (2, 2 ') are mechanically connected to each other during the rotation of the guide roller (12), wherein the electrical lines (2, 2') after having circulated the guide roller (12) have a helical shape.

14. The method according to claim 13, wherein the electrical lines (2, 2 ') are mechanically connected to each other when the guide roller is rotated.

15. The method according to any one of claims 13 or 14, wherein the finished coil (1) is immersed in a container with potting compound.

16. A method for producing a coil, wherein at least four electrical lines (2, 2 ') by means of a wire guide (100) about a rotating axis (101) of a winding tool (102, 103) are wound, each electrical line (2, 2 ') has a separate wire guide (100), wherein the electrical lines (2, 2') in a winding plane, which is arranged perpendicular to the axis of rotation (101) of the winding tool (102, 103) are wound, wherein the wire guide (100) with increasing number of turns parallel to the axis of rotation (101) is guided, - wherein the electrical lines (2, 2 ') are mechanically connected to each other during Wickeins.

17. The method of claim 16, wherein the first ends of the electrical leads (2, 2 ') are fixed in a first part of the winding tool (102).

18. The method according to claim 16, wherein the inner diameter (D1) of the roll is determined by the outer diameter (D2) of the rotating axis (101).

19. The method of claim 16, wherein the cross section of the coil through the cross section of the rotating axis

(101) is determined.

20. The method of claim 16, wherein the electrical leads (2, 2 ') are connected together during winding.

21. The method according to any one of claims 16 to 20, wherein the finished wound coil (1) is taken from the winding tool (102, 103).

22. The method of claim 21, wherein the finished coil (1) is immersed in a container with potting compound.