EP3731343A1 - Antenna - Google Patents

Abstract

Antenna having a magnetic core (1) and a coil (2) which is wound around the magnetic core (1), the magnetic core (1) having at least two sub-cores (1.1), the at least two sub-cores (1.1) one behind the other are arranged in a longitudinal direction (7) of the magnetic core (1). The at least two lower cores (1.1) have a continuous recess in the longitudinal direction. The antenna also has a support rod (4) which extends through the continuous recesses of the at least two lower cores and holds the lower cores (1.1) in their position

Description

Technical area

The invention relates to an antenna, in particular to an antenna for use in a vehicle designed for the transmission of key data for opening and / or starting the vehicle.

State of the art

Antennas usually consist of a core and a coil. Depending on the transmission frequency and the bandwidth, the core and the coil must be designed accordingly. The bandwidths of antennas are getting wider, e.g. for UWB antennas and the range of the antenna is getting bigger, which means, for example, that the cores are getting longer and longer. Long cores are also more prone to breakage than short cores and are more complex to manufacture.

It is therefore now known to form the core by a plurality of sub-cores arranged one behind the other, for example in US10056687 , EP1397845 , US2018 / 159224 . This has the advantage that the manufacture of the individual sub-cores is simpler and the susceptibility of the sub-cores to breakage is reduced. It has been shown, however, that the magnetic properties of the core formed from several sub-cores are very susceptible to shocks or temperature fluctuations and that these antennas often have problems with the stability of the antenna properties. The lower cores are arranged one behind the other either with a gap or in contact. If the lower cores touch, the magnetic properties fluctuate with the contact pressure between the lower cores, which can fluctuate depending on the temperature or vibrations. If the lower cores are arranged at a distance from one another, the distance often varies as a function of temperature or external forces, which in turn negatively affects the electrical properties of the core and thus of the antenna influenced. The relative arrangement of the lower cores to one another can also be influenced by strong impacts or by temperature fluctuations, which also results in a change in the electrical properties of the antenna. Therefore, it has not yet been possible to realize a high quality antenna with a plurality of sub-cores.

Presentation of the invention

It is an object of the invention to find an antenna that is robust, easy to manufacture and has good and preferably stable antenna properties.

According to the invention, this object is achieved in an antenna and a manufacturing method for such an antenna according to the independent claims.

The use of the support rod, which extends through recesses in the longitudinal direction of the at least two lower cores, allows a very stable and simple arrangement of the lower cores one behind the other. The production is very simple, as the lower cores can simply be pushed onto the carrying rod and are already correctly positioned. A lateral displacement of the lower cores to one another is thus excluded. Stronger impacts on the antenna are also mainly absorbed by the support rod and only to a lesser extent by the lower cores. This ensures that the lower cores are very break-resistant.

In another embodiment, this is achieved by an antenna, which has the following: a magnetic core and a coil which is wound around the magnetic core, the magnetic core having at least two sub-cores, the at least two sub-cores one behind the other in a longitudinal direction of the magnetic Core are arranged. The antenna further has pressure means which are designed to press the lower cores against one another in the longitudinal direction.

This allows the lower cores to be arranged one behind the other with a contact pressure. This reduces the gap effect or contact effect of two sub-cores arranged one behind the other. It is thus possible to use a large number of very short sub-cores without noticeably impairing the antenna properties. The contact pressure ensures good and stable electrical properties of the antenna even with temperature fluctuations and bumps, since the contact pressure between the antennas hardly fluctuates in the event of bumps or temperature fluctuations.

The two exemplary embodiments are particularly advantageous in combination.

Further advantageous embodiments are specified in the dependent claims.

The pressure means is preferably designed such that the contact pressure between the lower cores can be adjusted. This can preferably be achieved by arranging the sub-cores between two stops, e.g. on the support rod, done, at least one of the two stops is adjustable in its axial position. By adjusting the contact pressure, the electrical properties of the antenna can also be fine-tuned.

Brief description of the figures

Fig. 1

eine erste Seitenansicht auf eine Antenne nach einem ersten Ausführungsbeispiel der Erfindung.

Fig. 2

eine Schnittansicht entlang der Linie A-A der Antenne nach dem ersten Ausführungsbeispiel.

Fig. 3

eine Schnittansicht entlang der Linie B-B der Antenne nach dem ersten Ausführungsbeispiel.

Fig. 4

eine Schnittansicht entlang der Linie C-C der Antenne nach dem ersten Ausführungsbeispiel.

Fig. 5

eine 3D Ansicht der Antenne nach dem ersten Ausführungsbeispiel mit halb aufgeschnittenem Gehäuse und Vergussmaterial.

The invention is explained in more detail with reference to the accompanying figures, which show

Fig. 1

a first side view of an antenna according to a first embodiment of the invention.

Fig. 2

a sectional view along the line AA of the antenna according to the first embodiment.

Fig. 3

a sectional view along the line BB of the antenna according to the first embodiment.

Fig. 4

a sectional view along the line CC of the antenna according to the first embodiment.

Fig. 5

a 3D view of the antenna according to the first embodiment with half-cut housing and potting material.

Ways of Carrying Out the Invention

Figs. 1 to 5 show a first embodiment of the invention.

In the following description, three orthogonal directions are used, a first direction 7, a second direction 8 and a third direction 9. The first direction 7 is preferably orthogonal to the second direction 8 and the third direction 9. The second direction 8 is preferably orthogonal on the first direction 7 and the third direction 9. The third direction 9 is preferably orthogonal to the first direction 7 and the second direction 8.

The antenna has a core 1, a coil 2 and a support rod 4. The antenna preferably also has a housing 3 and a potting compound 5.

The magnetic core 1 is also referred to as just core 1 for short in the following. The core 1 is made of a magnetic material. Magnetic material means that the material is paramagnetic or ferromagnetic, preferably ferromagnetic. The core 1 is preferably made of a ferrite material (ferrite core) or a powder material (powder core). The core 1 is preferably made of a rigid magnetic material, e.g. the magnetic core 1 is not elastic or pliable.

The core 1 preferably extends along the first direction 7. The first direction is therefore also referred to as the longitudinal direction 7 of the core 1 or the antenna. The longitudinal axis of the core 1 thus extends in the first direction 7. The core 1 is preferably longer in the longitudinal direction 7 than in the second direction 8 and the third direction 9. In one embodiment, the core 1 is in the second direction 8 and in the third direction is the same (see first embodiment). In another embodiment, the core is 1 in the second direction 8 (width) larger than in the third direction 9 (thickness or height).

According to the invention, the core 1 has at least two lower cores 1.1. In the first exemplary embodiment, the core 1 has six sub-cores 1.1. The core 1 can also have two, three or more sub-cores 1.1. exhibit. The magnetic material of the core 1, which has been described above, corresponds to the magnetic material of the sub-cores 1.1. Preferably, all of the lower cores 1.1 have the same magnetic material. However, it is also possible to use different magnetic materials in different sub-cores 1.1, 1.2.

The lower cores 1.1 have a longitudinal axis which extends in the longitudinal direction 7. The lower cores 1.1 are preferably longer in the longitudinal direction 7 than in the second direction 8 and / or than in the third direction 9. The lower cores 1.1 preferably each have a first axial side or a first end and a second axial side opposite the first axial side or a second end opposite the first end. The first and second axial sides are preferably arranged parallel to one another. The first and / or second axial side preferably each form a flat surface which is in contact with a corresponding axial side of a possibly adjacent lower core 1.1. Preferably, the lower cores 1.1 and the core 1 each have a cross section whose external shape (external cross-sectional shape of the lower core 1.1 and the core 1) is circular. However, it is also possible for this external cross-sectional shape to be rectangular, triangular, semicircular, C-shaped or U-shaped or otherwise shaped. The outer cross-sectional shape of the lower cores 1.1 is preferably constant / the same along the longitudinal direction 7 of the lower core 1.1 or of the core 1. Preferably, all lower cores 1.1 have the same outer cross-sectional shape. The cross-sectional shape of a sub-core 1.1 or the core 1 is defined as the cross-section at right angles to the longitudinal direction 7. All lower cores 1.1 are preferably designed with the same shape. The lower cores 1.1 are preferably arranged one behind the other in the longitudinal direction 7. The first sub-cores are preferably 1.1 so arranged one behind the other that the longitudinal axes of the lower cores 1.1 are arranged coaxially, ie the longitudinal axes of the first lower cores 1.1 form the respective extension of the adjacent lower cores 1.1. The first axial side of a first lower core 1.1 is preferably arranged opposite a first axial side of a second lower core 1.1. The first sub-cores 1.1 are preferably arranged one behind the other such that the first axial side of the first sub-core 1.1 completely overlaps the first axial side of the second sub-core 1.1, ie the axial side of the first sub-core 1.1 overlaps the axial side of the second sub-core 1.1 and / or the axial side of the second sub-core 1.1 overlaps the axial side of the first sub-core 1.1. In other words, a first lower core 1.1 represents an extension of the adjacent second lower core 1.1 in the longitudinal direction 7. The axial sides of the lower cores 1.1 are preferably arranged in contact with one another. However, it would also be possible to arrange the lower cores 1.1 with a spacing between the axial sides of the lower cores 1.1.

The lower cores 1.1 have a recess in the longitudinal direction 7. The recess is continuous, ie extends from the first axial side or the first end to the second axial side or the second end of the corresponding lower core 1.1. The recess preferably extends along the longitudinal axis of the lower core 1.1 and / or the recess is arranged in the center in the cross section of the lower core 1.1. The recess of the lower core 1.1 is preferably completely enclosed in the cross section of the lower core 1.1 or embodied in a ring shape. However, it would also be possible for the recess to be open on a lateral side. This could be achieved, for example, with a C-shaped or U-shaped cross section of the lower core 1.1. The lower core 1.1 is preferably designed in the shape of a hollow cylinder. The cross-sectional shape of the recess or the hollow cylinder opening (inner cross-sectional shape of the lower core 1.1 or the recess or the hollow cylinder) is preferably circular. The inner cross-sectional shape can, however, also have a different shape, for example triangular, square, polygonal. The external cross-sectional shape of the hollow cylinder is preferably circular, as described above, but can also other shapes such as rectangular, triangular, polygonal or other-shaped. The inner cross-sectional shape of the hollow cylinder is preferably circular, as described above, but can also be other shapes such as rectangular, triangular, polygonal or some other shape. In one embodiment, the inner cross-sectional shape and the outer cross-sectional shape have the same shape (of course with different sizes). In another embodiment, the inner cross-sectional shape and the outer cross-sectional shape have a different shape. The description of the recess of the lower core 1.1 applies to all lower cores 1.1. The recesses of all lower cores 1.1 are preferably designed in the same way. However, it would also be possible to design the recesses of the lower cores 1.1 differently in certain features.

The support rod 4 is designed to be guided through the recesses of the at least two lower cores 1.1. The support rod 4 preferably extends through the recesses of the lower cores 1.1 in such a way that the lower cores 1.1 are aligned in their longitudinal axes in the first direction 7 and thus form the core 1. The recesses in the lower cores 1.1 and the support rod 4 are preferably designed in such a way that the support rod 4 cannot be displaced relative to the lower cores in the second direction 8 and / or in the third direction 9. As a result, the lower cores 1.1 are automatically aligned with one another when they are arranged on the support rod 4. This also makes the core 1 stable with respect to a displacement of the lower cores 1.1 with respect to one another caused by a shock or a temperature fluctuation. The inner cross section of the recesses of the lower cores 1.1 and the outer cross section of the support rod 4 are preferably designed so that the support rod 4 cannot be displaced relative to the lower cores 1.1 in the second direction 8 and / or in the third direction 9. As a result, the lower cores 1.1 are automatically aligned with one another when they are arranged on the support rod 4. This can be achieved, for example, in that the inner cross-section of the recesses of the lower cores 1.1 and the outer cross-section of the support rod 4 correspond to one another. Preferably, the inner cross section of the recesses of the lower cores 1.1 and the outer cross section of the support rod 4 allow the Lower cores 1.1 can rotate around the support rod 4. This prevents possible tension when the lower cores 1.1 are pressed against one another axially in the longitudinal direction 7 by screwing, which will be described later. This further reduces the risk of breakage.

The support rod 4 is preferably made of a different material than the magnetic material of the lower cores 1.1. As a result, the breaking stability of the core 1 is no longer defined by the material of the lower cores 1.1, but by the support rod 4. The support rod 4 is preferably made of a material that is more resistant to breakage than the magnetic material of the lower cores 1.1. This significantly improves the stability of the core 1. The material of the support rod 4 preferably has a lower magnetic permeability than the magnetic material of the core 1 or the lower cores 1.1. Materials with high permeability are often more prone to breakage. The support rod 4 is preferably made of metal, for example copper. However, it would also be possible to manufacture the support rod from plastic. In one embodiment, the support rod 4 is made of an electrically conductive material. In another exemplary embodiment, the support rod 4 is made of an electrically insulating material.

The support rod 4 has a first end in the longitudinal direction 7 and an end opposite the first end. The support rod 4 preferably has a first stop 42 at the first end of the core 1 and / or at the first end of the support rod 4. The first stop 42 is designed to allow the first end of the core 1 or the axial side of the lower core 1.1 arranged at the first end to rest against the first stop 42 and thus to block it in the axial direction 7 (in a first axial displacement direction). In this exemplary embodiment, the first stop 42 is formed integrally from the support rod 4. However, it is also possible to fasten the first stop 42 on the first support rod 4. In this exemplary embodiment, the first stop 42 cannot be displaced in the axial direction 7. However, it is also possible to design the first stop 42 to be displaceable in the axial direction (see, for example, second stop 44). The support rod 4 preferably has at the second end of the core 1 and / or at the second end of the support rod 4 a second stop 44. The second stop 44 is designed to allow the second end of the core 1 or the axial side of the lower core 1.1 arranged at the second end to rest against the second stop 44 and thus to block it in the axial direction 7 (in a second axial displacement direction). In this exemplary embodiment, the second stop 44 is designed to be axially displaceable, so that the second stop 44 can be adjusted in its axial position in the longitudinal direction 7. The second stop 44 is preferably designed to be detachable from the support rod 4 so that the lower cores 1.1 can be pushed onto the support rod 4 (in the axial direction 7) and can then be fastened with the second stop 44 in their axial position. Preferably, the support rod 41 and the second stop 44 (or the first stop 43) have a screw mechanism that allows the axial position of the second stop 44 (or the first stop 43) to be adjusted and / or the second stop 44 (or the first Stop 43) for sliding the lower cores 1.1 onto the support rod 4 in the axial direction 7. For this purpose, the support rod 7 preferably has an external thread 41 and the second stop 44 (or the first stop 43) has a recess with an internal thread, so that the second stop 44 can be screwed onto the external thread 41 of the support rod 4. As a result, the second stop 44 can be screwed against the axial side of one of the lower cores 1.1 resting on the second stop 44.

The support rod 4 preferably has pressure means. The pressure means are designed to compress the lower cores 1.1 in the longitudinal direction 7 (ie to press them against one another). This has the advantage that the core 1 with the transitions between the lower cores 1.1 behaves much more similarly to a one-piece magnetic core of the same size, since the axial sides of the lower cores 1.1 are pressed against one another. The pressure means are preferably achieved by the two stops 42 and 44 described, the axial position of at least one of the two stops 42 and 44 being adjustable. The first stop 42 and the second stop 44 can thus be moved towards one another and the lower cores 1.1 located between the stops 42 and 44 can be pressed against one another with their axial sides or - be pressed. However, it is also possible to implement the pressure medium differently. The adjustment of the axial position preferably also allows adjustment of the contact pressure between the lower cores 1.1, which in turn allows fine adjustment of the electrical parameters of the antenna.

Core 1 is thus formed by a plurality of lower cores 1.1 arranged one behind the other on support rod 4. The core 1 has two opposite ends in the longitudinal direction 7, which are formed by the corresponding ends or axial sides of the respective last lower cores 1.1 in the longitudinal direction 7. The pressure medium ensures stable positioning of the lower cores 1.1 and small fluctuations in the electrical parameters of the antenna.

The coil 2 is wound around the core 1. The winding direction of the coil 2 is in the longitudinal direction 7. The coil 2 preferably has a plurality of turns around the core 1, preferably with more than two, preferably with more than five, preferably with more than ten, preferably with more than fifteen, preferably with more than twenty turns. The coil 2 preferably extends from the first end of the core 1 to the second end of the core 1, so that the area between the last turn of the coil 2 in the direction of the first end of the core 1 and the last turn of the coil 2 in the direction second end of the core 1 make up at least 70%, preferably at least 75%, preferably at least 80% of the longitudinal extent of the core 1. The coil 2 preferably extends over the at least two lower cores 1.1, preferably over all lower cores 1.1. The coil 2 or a coil wire of the coil 2 is preferably wound onto the core 1. However, it is also possible that the core 1 is held in a core carrier and that the coil 2 or the coil wire is wound onto this one core carrier. The coil 2 preferably has a coil wire which is wound around the core 1 or the core carrier 4. The coil wire is preferably insulated. This allows the coil wire to be wound directly onto the core 1. Preferably, the coil wire is wound so that both ends of the coil wire at one end of the core 1 are connected to terminals of the antenna. By doing The embodiment shown, the coil wire is wound in both directions (cross winding). In another embodiment, the coil 2 is wound from the first end of the core 1 to the second end of the core 1 in one direction and the coil wire is then wound from the second end of the core 1 to the first end of the core 1 (without turns around the core 1) returned. It would of course also be possible to lead the coil wire first from the first end of the core 1 to the second end of the core 1 (without turns around the core 1) and then from the second end of the core 1 to the first end of the core 1 in wrap one direction.

The housing 3 is designed to enclose the core 1 with the coil 2. The housing 3 is preferably designed to accommodate and / or enclose the core 1 formed from the lower cores 1.1 pushed onto the support rod 4 and the coil 2. The housing 3 preferably has a first opening which is designed to introduce the core 1 with the coil 2 into the housing 3. The first opening is preferably closed by a closure 43. The closure 43 is preferably formed by the first end of the support rod 44, so that the support rod 4 closes the housing 3 with the closure 43 when it is inserted into the housing 3. This has the advantage that the closure 43 is used both for positioning the core 1 and the coil 2 in the housing 3 and for closing it. However, it is also possible for the first opening to be closed by a separate closure 43.

The closure 43 preferably has a connection for the electrical connection of the antenna, in particular the coil 2. The connection preferably has two electrically conductive rods 6 which extend through the closure 43. One side of each conductive rod 6 protrudes from the closure 43 on the outer side, so that the finished antenna can be electrically connected. The opposite side of each conductive rod protrudes on the inner side of the closure 43, the ends of the coil 2 or the coil wire being connected to one of these conductive rods 6 (on the inside). The support rod 4 is preferably so designed that the core 1 or the support rod 4 has a predefined position after assembly in the housing 3. On one side of the antenna, this is achieved, for example, by positioning the closure 43 in the first opening of the housing 3. The support rod 4 preferably also has positioning means which hold the support rod 4 in the predefined position when the core carrier 4 is mounted in the housing 3. The further positioning means are preferably arranged on the end of the support rod 4 opposite to the closure 43. The further positioning means are implemented here, for example, by the second stop 44, which has an alignment shape 45 on the side opposite the stop surface, which engages in a corresponding alignment shape 32 of the housing 3 so that the support rod 4 is correctly positioned in the housing 3. However, the alignment form 45 could also be arranged directly on the support rod. The alignment shape 45 of the support rod 4 or of the second stop 44 is here a central depression (female connection shape). The alignment shape 32 of the housing 3 is a corresponding projection 32 (male connection shape) which engages in the central recess. The alignment form 32 is arranged here in a second closure 31 which closes a second opening of the housing 3.

A potting compound 5 is arranged between the housing 3 and the core 1 with the coil 2 or the support rod 4 with the core 1 and the coil 2. The core 1 with the coil 2 is inserted into the housing 3 and encapsulated therein with the potting compound 5. The sealing compound 5 is often referred to as potting. The potting compound 5 preferably fills the, preferably all, cavities in the housing 3 so that the heat from the core 1 and the coil 2 are effectively dissipated and the core 1 with the coil 2 or the core carrier 4 with the core 1 and the Coil 2 is stored stably. Preferably, a potting compound 5 is used which (in the cured state) is softer than 60 Shore A, preferably 40 Shore A, preferably 35 Shore A, preferably 30 Shore A, preferably 27 Shore A, preferably 25 Shore A. It was found that the casting compound 5 is softer than 60 Shore A or than the other preferred values mentioned, not just the breaking stability Improved, but surprisingly also improves the stability of the electrical values of the antenna. However, the potting compound 5 (in the cured state) is preferably harder than 10 Shore A, preferably than 15 Shore A. The potting compound 5 with a deformation between 10 and 35 Shore A has been found to be particularly advantageous.

The features described above with regard to the possible movements of the support rod 4, the stops 42, 44, the lower cores 1.1 relate, of course, to a state before the potting compound 5 was cast.

The antenna described is preferably designed for use in a vehicle for the transmission of key data for opening and / or starting the vehicle. This antenna is preferably mounted in a vehicle.

The antenna described can be designed for many different radio frequencies. In one embodiment, the radio frequency of the antenna is greater than 10 kHz, preferably greater than 50 kHz, preferably greater than 100 kHz. In one embodiment, the radio frequency of the antenna is less than 500 kHz, preferably less than 250 kHz, preferably less than 150 kHz. Preferably the radio frequency is 125 kHz. The radio frequency describes the center frequency of the transmitted radio frequency band.

To produce the antenna, the lower cores 1.1 with their recesses are first pushed onto the support rod 4. The lower cores 1.1 are preferably pushed onto the support rod 4 in the longitudinal direction 7. For this purpose, the second stop 44 is removed from the second end of the support rod 4. When all the lower cores 1.1 have been pushed onto the support rod 4, the second stop 44 is fastened again, preferably screwed, onto the support rod 4. In an alternative embodiment with laterally open lower cores 1.1, the lower cores 1.1 could also laterally (in the direction of any linear combination of the second direction 8 and the third direction 9 or in the direction radial to the longitudinal direction 7) onto the support rod 4 be pushed. The stop 44 therefore does not have to be removed. The lower cores 1.1 are preferably pressed against one another with their axial sides with the pressure medium. This can be done, for example, by moving the second stop 44 axially, here for example screwing it shut. The coil 2 is then wound onto the core 1 or onto the lower cores 1.1. The coil wire is connected to the connector of the antenna. The manufacturing process preferably also provides for a fine adjustment step. For this purpose, the pressure of the pressure medium on the axial sides of the lower cores 1.1 is adjusted so that the electrical properties of the antenna or the magnetic properties of the coil 2 and / or the core 1 match predetermined values. This step can be done automatically by a production robot or a production machine, which is connected to the connection of the antenna or to the two coil ends, and which adjusts the pressure of the pressure medium depending on a measurement result at the connection or the coil ends. The pressure can be adjusted, for example, by the screwing state of the second stop 44. This enables a very high quality antenna to be produced. The core 1 with the coil 2 or the support rod 4 with the core 1 and the coil 2 is inserted into the housing 3. The core 1 with the coil 2 or the support rod 4 with the core 1 and the coil 2 is cast in the housing 3 with the potting compound 5. The potting compound 5 then hardens and the antenna is ready.

Claims (14)

Antenna having a magnetic core (1) and a coil (2) which is wound around the magnetic core (1), the magnetic core (1) having at least two sub-cores (1.1), the at least two sub-cores (1.1) one behind the other are arranged in a longitudinal direction (7) of the magnetic core (1);
characterized,
that the at least two lower cores (1.1) have a continuous recess in the longitudinal direction, and
that the antenna has a support rod (4) which extends through the continuous recesses of the at least two lower cores and holds the lower cores (1.1) in their position. Antenna according to Claim 1, the carrying rod (4) having pressure means (41, 42, 44) which are designed to press the lower cores (1.1) against one another in the longitudinal direction (7). Antenna according to Claim 2, the pressure means (41, 42, 44) being arranged at the first end and / or at the second end of the core (1). Antenna according to Claim 2 or 3, the pressure means (41, 42, 44) having a first stop (42) arranged on the support rod (4) at a first end of the core (1) and a first stop (42) arranged at a second end of the core (1) has a second stop (44) arranged on the support rod (4), the first stop and / or the second stop (43) being movably attached to the support rod (4) in the longitudinal direction (7) so that the at least two lower cores ( 1.1) are pressed against each other between the first stop (42) and the second stop (44). Antenna according to claim 4, wherein the first stop (42), which can be movably fastened in the longitudinal direction (7) on the support rod (4) and / or the second stop (44) has an internal thread which is attached to an external thread (41) of the support rod (4) is screwed. Antenna according to one of the preceding claims, wherein the lower cores (1.1) are designed as a hollow cylinder. Antenna according to one of the preceding claims, wherein an outer cross-sectional shape of the lower cores (1.1) is circular and / or wherein a cross-sectional shape of the recess of the lower cores (1.1) and / or the cross-sectional shape of the support rod in the area of the lower cores (1.1) is circular. Antenna according to one of the preceding claims, wherein the coil (2) is wound directly onto an outside of the lower cores (1.1). Antenna according to one of the preceding claims, comprising a housing (3) which contains the carrying rod (4), the lower cores (1.1) held on the carrying rod (4) and the coil (2) wound on the lower cores (1.1), which are in the Housing (3) are cast with a potting compound (5). Antenna according to Claim 9, the potting compound (5) being softer than 60 Shore A, preferably than 40 Shore A. Antenna according to one of the preceding claims, wherein the coil (2) is wound on the magnetic core (1) in such a way that the coil (2) extends over more than 80% of the length of the magnetic core (1). Antenna according to one of the preceding claims, wherein the antenna is designed for use in a vehicle for opening and / or starting the vehicle. Vehicle having an antenna according to one of the preceding claims, wherein the antenna is designed for the transmission of key data for opening and / or starting the vehicle. Manufacturing method for an antenna comprising the steps: Arranging at least two sub-cores (1.1) in one Longitudinal direction (7) to form a magnetic core (1); Winding the magnetic core (1) with a coil (2); characterized, that the step of arranging at least two lower cores (1.1) comprises arranging the at least two lower cores (1.1) on a support rod (4) so that the support rod (4) extends through recesses of the lower cores (1.1) running in the longitudinal direction (7) .

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