WO2016087139A1 - Coil component and method for manufacturing a coil component - Google Patents

Abstract

Disclosed is a coil component (1) comprising a winding member (2) and at least one winding (4, 5) of a wire (6, 7); the winding (4, 5) has at least one turn (10, 11) of the wire (6, 7) about the winding member (2), the geometry of the turn (10, 11) allowing the turn (10, 11) to rotate about the winding member (2). Also disclosed is a method for manufacturing a winding of a coil component (1). The coil component (1) comprises at least one connecting element (21, 22, 23, 24) that protrudes from a main shape of the winding (4, 5).

Description

description

Coil component and method for producing a

coil device

It is a coil component and a method for

Production of a coil component specified. The

Coil component is in particular as electrical

Component, for example, as an inductive component formed. In particular, the coil component as

Throttle or used as a transformer.

To make a coil component, it is necessary to deform a wire and, for example, one

Wrap winding body. In the document WO 2011/015491

AI is a method for producing a current-compensated choke described in which a preformed winding is wound on a ferrite core. In the document DE 3540098 AI a method for winding ring cores is described with wire.

It is an object of the present invention to provide a

to provide improved coil component and an improved method for producing a coil component.

According to a first aspect of the present invention, a coil component comprising a winding body and at least one winding of a wire is indicated around the winding body. The winding body has in particular a closed shape, for example a closed frame shape. The

Closed mold is preferably already present when applying the winding. For example, the closed mold is integrally formed. Thus, the closed form and preferably the entire winding body no joining seams or the like. Thus, no additional

Composition of the winding body required. The winding body may have a core for increasing the

 Inductance, in particular a ferrite core, or be formed as a core. The core has in particular a closed shape. The closed mold is present in particular even before the application of the winding. The core is preferably formed in one piece. Thus, the core has no joining seams or the like. Thus, no subsequent composition of the core is required.

For example, the winding body may have a housing which surrounds the core. Alternatively, no housing may be provided so that the wire is directly around the core

is wound.

The winding has at least one turn of the wire around the winding body, in particular around a portion of the

Bobbin, on. The geometry of the winding allows one

Rotation of the winding around the winding body, in particular around the associated portion of the winding body. For example, the winding is at least during manufacture to the

Rotatable winding body. "Rotatable" means that a rotation of the winding without deformation of the winding and without

Damage to the bobbin and the winding is possible. For this purpose, the turn must sit sufficiently loosely on the winding body. In this case, the case is included that the finished coil component, z. B. due to a subsequently applied housing or a subsequently formed deformation of a Drahtanfangs- and / or wire end of

Winding the winding can not be rotated around the winding body. For example, the winding in a plan has a

Circular shape on. In particular, the wire is wound as a circular helix around the winding body. Accordingly, the winding comprising all the turns of the wire,

for example, a cylindrical basic shape. In this case, the wire end and / or the wire beginning protrude from the basic shape.

In one embodiment, the winding body, in particular the portion around which the winding is guided, in cross-section an outer circumferential line, which differs in geometry from the shape of the winding in the plan.

For example, the winding body in cross-section on an outer peripheral line with corners, while the winding in the plan view has a circular shape. For example, the outer circumferential line of the winding body has at least one rectilinear section. In particular, the outer circumferential line of the winding body can have the shape of a rectangle.

In an alternative embodiment, the outer shape of the winding body in cross section corresponds to the shape of the winding in the plan view. For example, both the outer ones

Circumferential line as well as the winding on a circular geometry.

In one embodiment, the winding has a longitudinal axis that corresponds to the winding axis of the windings. The winding has in particular a cylindrical basic shape. The section of the bobbin to which the winding

is arranged, for example, has a curved shape. For example, the winding body is annular. In one embodiment, the winding axis is not at the Adjusted course of bending of the bobbin.

For example, a cylindrical winding is arranged on an annular winding body. In one embodiment, between the winding and the

Winding formed at least one gap. For example, the gap is circumferentially around the bobbin

formed so that the winding at any point on

Winding body rests. This allows application of the winding without damaging the bobbin.

In one embodiment, the coil component

at least one connection element for the electrical connection of the coil component. The connection element is

arranged in particular on the uppermost and / or lowermost turn. The connection element preferably projects out of a basic form of the winding.

In one embodiment, the connection element is formed directly from the wire of the winding, in particular the wire beginning and / or the wire end. Thus, the formation of a

Terminal element requires no separate element that is attached to the top and / or bottom winding of the winding. For example, both the wire beginning and the wire end are led out of the basic form of the winding. In one embodiment, at least a portion of the

Connecting element on a bend. The bend differs in particular from the bending of the wire within the winding.

The wire beginning and / or the wire end may alternatively or additionally also serve as support elements for the winding and / or the entire coil component. In an alternative embodiment, the

Coil component one or more separate connection and / or support elements having, on the winding

are attached. In particular, a separate element may be attached to the uppermost and / or lowermost turn.

For example, the separate element is soldered.

In one embodiment, there are successive ones

Windings of the winding to each other. In particular, there is no gap between successive turns. In this way, a high degree of filling of the windings can be achieved. Such an embodiment is with a

Method in which a preformed wire on the

Winding body is turned on, not or only with difficulty

achievable because there the windings are spread for applying the winding.

According to another aspect of the present invention, there is provided a method of manufacturing a coil device

specified. In particular, the method is suitable for

 Production of the previously described coil component.

According to the method, a bobbin and a wire are provided. The bobbin is placed, for example, in a tool. The wire is brought to the winding body. For example, the tool has a guide, in which the wire is inserted and guided to the winding body. Preferably, the wire is advanced in the guide. For example, a force is exerted on the wire end.

The wire is then slid along a bend generator while bending, with at least one turn of the wire is generated around the winding body. For example, the bending transducer has a wall against which the wire starts, so that a resulting bending of the wire corresponds to the course of the wall. In particular, the wall may have a curved shape. By way of example, the wall is shaped in such a way that the wire is bent in a circular manner as it travels along the wall.

In one embodiment, a lead of the wire is generated perpendicular to a bending plane at the same time or after the wire is pushed along the bending sensor. Thus, the wire is given a helical shape, for example the shape of a circular helix. For this purpose, in one embodiment, the wall of the

 Biegungsgebers a corresponding slope. Alternatively or additionally, the pitch may be generated by a separate pitch transmitter. The separate pitch sensor is designed, for example, as a pin or plate which deflects the wire in a direction perpendicular to the bending plane.

In one embodiment of the method, the wire beginning is rotated around the winding body until all turns of the winding are produced. Preferably, the wire beginning is moved simultaneously on the winding body. In particular, all finished turns of the winding are accordingly moved around the winding body. Thus, the turns each have a geometry that allows rotation and preferably also a displacement relative to the winding body.

In one embodiment of the method, the

Wire beginning and / or the wire end after formation of all

Windings of the winding reshaped. In this way, the Wire start and / or the wire end serve as connection elements and / or connection elements for electrical contacting of the winding, without a separate element on the

Winding must be attached.

With the described method is in particular a

Non-contact wrapping the bobbin possible. Thus, a mechanical stress on the wound body and / or the wire can be reduced or avoided altogether. In addition, with the method an automated application of a winding on a winding body,

in particular on a bobbin in the form of a closed frame, possible. According to another aspect of the present invention, there is provided a coil device for the manufacture of which the method described above is used.

In the present disclosure, several aspects of an invention are described. All the properties disclosed with respect to the coil devices and the method are also disclosed correspondingly with respect to the respective other aspects and vice versa, even if the respective property is not explicitly mentioned in the context of the respective aspect.

The objects described here are explained in more detail below with reference to schematic and not to scale embodiments.

Show it: FIGS. 1A to 1C show an embodiment of a

 Coil component in different views,

Figures 2 to 5 further embodiments of a

 Coil device,

Figures 6A to 6D process steps in the production

 a coil component. Preferably, the same reference in the following figures

 Reference numerals to functionally or structurally corresponding parts of the various embodiments.

FIG. 1A shows a coil component 1 in a lateral view. FIG. 1B shows the coil component 1 in a rear view.

The coil component 1 provides, for example, a defined inductance. The coil component 1 can be used as a passive component and serve, for example, for damping electromagnetic interference. For example, the coil component 1 can be used as a throttle. The

Coil component 1, for example, in a

Transformer can be used. It can be

in particular a transformer for signal transmission or to act on a power transformer.

The coil component 1 has a winding body 2. The winding body 2 is formed like a frame. In particular, the winding body 2 has a closed ring shape.

Alternatively, the winding body 2, for example, a

Base in the form of a "D" or a rectangular

Base area have. In an alternative embodiment the coil body does not have a frame shape or an open frame shape. For example, the bobbin

rod-shaped. The winding body 2 has, for example, a core for

Adaptation of the inductance of the coil component 1.

In particular, the winding body 2 may be formed as a core having ferrite or having such a core. The core is preferably formed in one piece.

The coil component 1 has two windings 4, 5 of wires 6, 7, which are arranged on two opposite sections 33, 34 of the winding body 2. The windings 4, 5 each have a plurality of turns 10, 11 of the wire 6, 7 around the associated section 33, 34 of the winding body 2.

For example, it is a copper wire. The wire is designed as a round wire. It may alternatively be an aluminum wire or a steel wire. Alternatively, the wire may be formed, for example, as a rectangular wire, in particular as a flat wire. The wires 6, 7 may be provided with a lacquer. For example, the wires 6, 7 have a cross-sectional area of 0.001 mm ^ to 2500 mrn ^ on. For example, the wires have one

circular cross section, as shown in Figures 1A and 1B. The wires 6, 7 can also others

Have cross-sectional geometries, for example, a rectangular or a square cross-section. FIG. 1C schematically shows the course of a turn 10 about a section 33 of the winding body 2 in a plan view of the turn 10, wherein the associated section 33 of the winding body 10

Winding body 2 can be seen in cross section. The others Windings of the winding 4 are not shown for clarity.

The winding 10 runs around the portion 33 of the winding body 2 in the form of a circular helix. In particular, the winding 10 is wound around an imaginary winding axis 19, which runs perpendicularly through the image plane of FIG. 1C. The winding axis 19 corresponds to a longitudinal axis of the winding 4. The winding 4 has the shape of a circular cylinder.

As can be seen in FIGS. 1A to 1C, a gap 8, 9 is formed in each case between the windings 10, 11 and the winding body 2. The gap 8, 9 can run around the entire portion 33, 34 of the winding body 2, as can be seen in Figure IC. Alternatively, the gap 8, 9 only between a portion of the portion 33, 34 of the

Winding body 2 and the respective winding 10, 11 may be formed, so that the windings 10, 11 have areas which lie close to the winding body 2. The windings 10, 11 may also lie so close to the winding body 2, that they can just turn without the winding body 2 and / or the wire 8, 9 is damaged. In particular, the windings 10, 11 also rest without gaps rotatably on the winding body 2.

The shape of the respective turn 10, 11 is formed non-complementary to the shape of the winding body 2. In particular, the shape of the winding 10, 11 differs in the

Top view of the geometry of the outer circumferential line 3 of the respective section 33, 34 of the winding body 2. As can be seen in Figure IC, the winding 10 has a

circular course on. The outer circumference 3 of associated portion 33 of the bobbin 2 has a rectangular shape.

The geometry of the respective turn 10, 11 is such as to cause the turn 10, 11 to rotate about the associated one

 Section 33, 34 of the winding body 2 allowed. The rotatability of the windings 10, 11 can in the finished trained

Winding 4, 5, however, be hindered, for example by a bent wire end 12, 13 and / or a bent wire beginning 14, 15th

As can be seen in Figures 1A and 1B lie

successive turns 10 of the winding 4 or

successive turns 11 of the other winding 5 close to each other. Between the turns 10 and 11, there is no gap. This allows a high degree of filling of the windings 4, 5.

The wire ends 12, 13 (Figure 1A) and wire starts 14, 15 (Figure 1B) of the windings 4, 5 protrude from the cylindrical

Basic shape of the windings 4, 5 out. In particular, the wire ends 12, 13 and wire starts 14, 15 each have at least one rectilinear portion. For example, the wire ends 12, 13 and wire starts 14, 15 extend at least in sections parallel to the winding axis of the windings 4, 5. The wire ends 12, 13 and wire starts 14, 15 pass through holes in a support 16 and allow electrical connection of the windings 4, 5 Thus, the wire ends 12, 13 and wire starts 14, 15 as

Connection elements 21, 22, 23, 24 are formed. In particular, the coil component 1 can be designed as a PTH (English pin through hole) component. In this case, the connection elements 21, 22, 23, 24 through holes in a Guided circuit board and attached to the circuit board, in particular soldered. In an alternative embodiment, the coil component is designed as an SMD (English surface mounted device) component. In this case, the connection elements 21, 22, 23, 24, for example, to a

Printed circuit board placed and attached to this, in particular soldered.

In an alternative embodiment, the carrier 16 may also be omitted. In addition serve the wire ends 12, 13 and

Wire starts 14, 15 as support elements in particular as

Legs, for the coil component. 1

FIG. 2 shows a further embodiment of a

Coil component 1 in a lateral view.

The coil component 1 differs from the

Coil component 1 of Figure 1A, inter alia, characterized in that between successive turns 10 of a winding 4, a gap 17 is formed. The successive ones

 Windings 10 are therefore not directly adjacent to each other. The further winding 5 has a gap 18 between successive turns 11. Thus, the slope of the

Winding 4 larger than the wire thickness. The coil component 1 has only two complete turns 10 per winding 4.

For example, the wires 6, 7 have thicknesses in a range of 0.4 to 8.0 mm, for example, the thicknesses are 1.8 mm. The winding 4 or 5 has, for example, an outer diameter in the range of 3 mm to 25 mm,

For example, the outer diameter is 14 mm. The inner diameter of the winding 4 or 5 is for example in a range of 2 mm to 20 mm, in particular 9 mm. The ratio of the outer diameter of the winding 4 or 5 to the diameter of the wire 6 or 7 is for example in the range of 3 to 20, in particular, the ratio may be less than or equal to 10.

FIG. 3 shows a further embodiment of a

Coil component 1 in oblique view. For example, it is an SMD device, d. H.

surface-mountable device, which is designed for arrangement on a printed circuit board.

The winding body 2 and the windings 4, 5 have a similar basic shape as in the coil component according to Figures 1A to IC. However, this is the case

Coil component 1 arranged on a support 16 such that the base of the annular winding body. 2

is parallel to an upper side of the carrier 16.

Accordingly, a winding axis of the windings 4, 5 runs parallel to the upper side of the carrier 16.

Between the windings 4, 5 is a divider 36 for

improved insulation of the windings 4, 5 arranged against each other. The separating web 36 is attached, for example, after the winding process.

The wire ends 12, 13 and wire starts 14, 15 lead

perpendicular to the winding axis of the windings 10, 11 away, through holes in a support 16 through and are then bent outwards. For example, the wire starts 14, 15 are opened after winding in the winding device and straightened. Subsequently, the wire starts 14, 15 and wire ends 12, 13 are guided through openings in the carrier 16 and bent outwards. FIG. 4A shows a further embodiment of a coil component 1 in an oblique lateral view. FIG. 4B shows the coil component 1 in an oblique rear side

View .

The coil component 1 has a winding body 2 in the form of a closed rectangular frame with bevelled outer edges. The winding body 2 is formed as a ferrite core, wherein the ferrite core for electrical insulation, for example, with a coating, in particular a plastic coating, is provided.

The wires 6, 7 of the windings 4, 5 are formed as flat wires. For example, the wires 6, 7 have a rectangular cross-section. The wires 6, 7 have a larger side surface and a smaller side surface and are wound around the winding body 2 such that the

Winding axis is approximately perpendicular to the larger side surface. In particular, the wires 6, 7 are wound edgewise around the winding body 2. Successive turns 10 of a winding 4 are narrow, in particular gap-free,

to each other. Thus, the pitch of the winding 4 corresponds to the wire thickness. Such a winding 4, 5 allows in the electrical application high currents at high

Inductance due to the high achievable number of turns.

The coil component 1 has connection elements 21, 22, 23, 24 for electrical connection. In addition to this are

Connection elements 21, 22, 23, 24 as support elements for

Setting up the coil component 1 is formed. The

Connection elements 21, 22, 23, 24 lead out of the cylindrical basic shape of the windings 4, 5. In the case of the coil component 1 of FIGS. 4A and 4B, the connection elements 21, 22, 23, 24 formed such that the windings 4, 5 can be placed standing on a support. In particular, the winding axis runs perpendicular to a carrier surface on which the coil component 1 is placed.

Two connection elements 21, 22 are formed directly from the wire ends 12, 13. Two further connection elements 23, 24 are attached to the wire starts 14, 15 as separate elements. When mounting a connection element 23, 24 am

Beginning of wire 14, 15 is no lead out of the wire beginning 14, 15 from the basic shape of the winding 4, 5 required.

For example, the separate connection elements 23, 24 are soldered to the winding 4, 5. The attachment can also be done in other ways, for example by a press fit method or a surface mounting method.

In an alternative embodiment, all

Connection elements 21, 22, 23, 24 of the wire ends 12, 13 and wire starts 14, 15 are formed. Further alternatively, all connection elements 21, 22, 23, 24 as separate

Be formed elements which are attached to the wire ends 12, 13 and wire starts 14, 15.

FIG. 5 shows a further embodiment of a

Coil component 1 in oblique view.

The coil component 1 is different from

Coil component according to Figures 4A and 4B lying

arranged. In particular, the coil component 1

Connection elements 21, 22, 23, 24, with which the

Coil component 1 can be placed on a support so that the winding axis of the windings 4, 5 extends parallel to a support surface. As with the coil component 1 according to FIGS. 4A and 4B, two connection elements 21, 22 are formed directly by the wire ends 12, 13. Two separate connection elements 23, 24 are attached to the wire starts 14, 15, for example by means of a solder 37. Alternatively, all connection elements 21, 22, 23, 24 may be formed by the wire ends 12, 13 and wire starts 14, 15 or at the wire ends 12, 13 and

Wire beginners 14, 15 attached.

With reference to FIGS. 6A to 6D, a method for the

Production of a coil component, for example a coil element according to FIGS. 1 to 5. A winding body 2 is provided, which can be seen in FIG. 6A in a cross section. The winding body 2 has a closed frame shape. In particular, the

Winding body 2 formed as a rectangular frame. There are also other shapes, such as a ring shape or a D-shape possible. The winding body 2 may also have other shapes than a frame shape, for example rod-shaped

be educated. The winding body 2 is inserted into a tool 30, in particular into a recess in the tool 30. A wire 6 is inserted into a guide 25 of the tool 30 and pushed forward in the direction of the arrow. The guide 25 is made to fit the wire 6. The wire 6 may have, for example, a round or a rectangular cross-section. For example, it is a flat wire, the edgewise on the winding body. 2

is wound. In particular, it may be a

Copper wire, preferably a copper enamel wire act. For advancing the wire, for example, a slide (not shown), which pushes the wire 6 still front.

The guide 25 has a straight section 26 and a bent section 27. The bent portion 27 is formed as a bending encoder 28. The wire 6 becomes the winding body 2 through the straight section 26

advanced, for example, to an outside of the

Winding body 2 introduced.

As can be seen in FIG. 6B, the wire 6 subsequently runs into the bent portion 27, thereby abutting against a wall of the bent portion 27. As a result, a bend of the wire 6 in the direction of an opening 32 in

Winding body 2 generated. In particular, the wire 6 is deflected to a circular shape and thereby guided around a portion 33 of the winding body 2. Thus, by the

Bend encoder 28 a turn of the wire 6 to the

Winding body 2 generated. The bending encoder 28 acts

especially as a forming backdrop.

The guide 26 and in particular the bending sensor 27 are for example designed such that the wire 6 does not come into contact with the winding body 2 during the winding process. In particular, the wire 6 is spaced apart during the winding process from the winding body ^¬. 2

Alternatively, the wire 6 can lie so close to the winding body 2 that it comes into contact with the winding body 2. This can be achieved by the winding of the windings 10 am

Winding 2 spiral-shaped scratch marks of the wire 6 on the bobbin arise. In contrast, arise in known methods in which the windings around the Winding bodies are laid without turning the

Windings around the winding body takes place, for example

Pressure points on the wound body and / or on the wire. In an alternative embodiment, 25 individual fingers are used to generate a bend of the wire 6 instead of a continuous guide, wherein the wire starts during the feed against the fingers and is deflected by these on a circular path.

Furthermore, alternatively, the guide may be formed such that the rectilinear portion leads from the front through the opening 32 in the winding body 2 and the bent portion 27 then leads out around the winding body 2 around. Thus, in this case, the wire is wound around the bobbin 2 from inside to outside.

In addition to bending the wire 6 in the plane, a slope of the wire 6 is created out of the plane. For this purpose, the guide 25, for example, a corresponding

Climb up, so that the lead 25 at the same time as

Gradient 29 acts. The guide 25 can in particular helically run around a portion of the winding body 2. Alternatively, a pitch of the wire 6 can be generated for example by a separate pitch encoder.

The wire 6 is further advanced, so that the

Wire start 14 to the portion 33 of the bobbin 2 screws until the entire winding of the wire 6 is generated.

Figure 6C shows in a perspective view that

Coil component 1 after the generation of all turns 10th The wire beginning 14 forms the end-side conclusion of the cylindrical basic shape of the winding 4. The wire end 12 has a linear course and leads out of the basic shape of the winding 4.

In a further method step, the wire beginning 14 is bent out of the basic shape of the winding 4. In this way, the wire beginning 14 can act as a connection element and / or as a support element.

FIG. 6D shows the step of bending out the wire beginning 14 to form a connection element 23.

For this purpose, the tool 30 on a forming element 31, which is formed for example as a plate or finger. The forming element 31 is guided to the wire beginning 14, so that it abuts the wire beginning 14 and presses the wire beginning 14 out of the winding geometry outwards. In this case, counter stops can be provided, against which the wire beginning 14 is pressed.

The tool 30 may also have several forming elements 31

have, for example, act successively from different sides on the wire beginning 14 and bend it into the desired shape. Additionally or alternatively, the wire end 12 can be formed after the winding process by one or more forming elements.

Preferably, when forming the wire beginning 14 and / or the wire end 12, the winding 4 is at least partially still included in the guide 25. In this case, a counterforce can be applied by the guide 26. In an alternative embodiment, one or more separate connection elements are attached to the beginning and / or end of the wire, in particular soldered. In one embodiment of the method can simultaneously be a winding of another wire to another

Section, for example, an opposite one

Section, the winding body 2 are generated. For this purpose, a further guide, a further bending generator and a further pitch sensor can be present.

 With the described method it is possible to use a

Automatically wind bobbins with a wire.

In particular, the forming of the wire beginning and / or the wire end can also be automated. Due to the increasing miniaturization in electronics at the same time

As the currents increase, the coil cores become smaller and smaller as the wire size increases. The method described

in particular also allows automated winding of small closed cores with a thick wire, as shown for example in FIG. The wire can be any

Have cross sections, in particular a circular or rectangular cross section.

To generate the winding no winding mandrel, in particular no co-rotating or fixed winding mandrel is needed.

In particular, the wound body is stationary during the winding process. Furthermore, the wire can be wound without contact to the winding body. This allows, for example, the application of a winding directly to a ferrite core, without the need for an additional housing or a bandage to protect the core. Also, the requirements on the strength of a paint on the wire can be compared to a method in which the wire is pulled around a mandrel, be reduced.

Reference sign list

1 coil component

 2 bobbins

3 outer circumferential line

4 winding

 5 winding

 6 wire

 7 wire

8 gap

 9 gap

 10 turns

 11 turn

 12 wire ends

13 wire end

 14 wire start

 15 wire start

 16 carriers

 17 gap

18 gap

 19 winding axis

 20 outer edge

 21 connection element

 22 connection element

23 connection element

 24 connection element

 25 leadership

 26 straight line section

27 bent section 28 Bend

 29 pitch sensor

 30 tool

31 forming element Opening Section Section Housing Divider Lot

Claims

claims 1. coil component comprising a winding body (2) and at least one Winding (4, 5) of a wire (6, 7), wherein the winding (4, 5) at least one turn (10, 11) of the wire (6, 7) around the winding body (2) and wherein the geometry of the winding (10, 11) a rotation of the winding (10, 11) around the Winding body (2) allowed, and having at least one Connection element (21, 22, 23, 24) for electrical connection of the coil component (1), wherein the connection element protrudes from a basic shape of the winding. 2. coil component according to claim 1, wherein the Connection element (21, 22, 23, 24) of a wire beginning (14, 15) and / or a wire end (12, 13) of the winding (4, 5) is formed. 3. coil component according to claim 1, wherein the Connection element (21, 22, 23, 24) at a wire beginning (14, 15) and / or a wire end (12, 13) of the winding (4, 5) is attached. 4. coil component according to one of the preceding claims, in which successive turns (10, 11) abut each other. 5. coil component according to one of the preceding claims, wherein between the winding (10, 11) and the winding body (2) at least one gap (8, 9) is formed. 6. coil component according to one of the preceding claims, wherein the winding body (2) in cross-section an outer Circumferential line (3), which differs in geometry from the shape of the winding (10, 11) in the plan. 7. coil component according to one of the preceding claims, wherein the winding (10, 11) in the plan view has a circular shape. 8. coil component according to one of the preceding claims, wherein the winding body (2) in cross section an outer Having circumferential line (3) with corners. 9. coil component according to one of the preceding claims, wherein the winding body (2) is annular. 10. coil component according to one of the preceding claims, wherein the winding (4, 5) has a cylindrical basic shape. 11. coil component according to one of the preceding claims, wherein the winding body (2) as a closed frame is trained. 12. coil component according to claim 11, wherein the application of the winding (4, 5) is carried out on the closed frame. 13. coil component according to one of the preceding claims, wherein the winding body (2) is integrally formed. 14. coil component according to one of the preceding claims, wherein the winding body (2) as a coil core for increasing the Inductance is formed. 15. coil component according to claim 14, in which the spool core is integrally formed. 16. Coil component according to one of the preceding claims, in which the connection element (21, 22, 23, 24) is designed for PTH mounting on a printed circuit board. 17. Coil component according to one of the preceding claims, in which the connection element (21, 22, 23, 24) is designed for SMD mounting on a printed circuit board. 18. A process for producing a winding of a Coil component comprising the steps:  A) providing a wound body (2) and a wire (8, 9) B) leading the wire (8, 9) to the winding body (2) C) bending the wire (8, 9) by pushing along the Wire (8, 9) to a bend transmitter (28) and thereby Forming at least one turn (10, 11) of the wire (8, 9) about the winding body (2) to form a winding (4, 5),  D) forming a connection element (21, 22, 23, 24) for electrical connection of the coil component (1), wherein the connection element (21, 22, 23, 24) protrudes from a basic shape of the winding (4, 5). 19. The method according to claim 18, wherein the wire beginning (14, 15) is rotated about the winding body (2) until all turns (10, 11) of the winding (4, 5) are generated. 20. The method according to any one of claims 18 or 19, wherein the bender (28) has a curved wall along which the wire (8, 9) runs. 21. The method according to any one of claims 18 to 20, wherein the connecting element (21, 22, 23, 24) by a Wire start (14, 15) and / or a wire end (12, 13) is formed. 22. The method according to claim 21, wherein in step D) the wire beginning (14, 15) or the Wire end (12, 13) for forming the connection element is transformed. 23. The method according to any one of claims 18 to 21, wherein the connection element (21, 22, 23, 24) at the wire beginning (14, 15) and / or wire end (12, 13) is attached. 24 coil component, for the production of a method according to any one of claims 18 to 23 is used.