DE102021201095A1 - Space-saving antenna for a hearing instrument - Google Patents

Abstract

An antenna (18), in particular a magnetic-inductive antenna (18), for a hearing instrument (2) and a hearing instrument (18) with such an antenna (18) are specified. The antenna (18) has a first antenna surface (30) and a second antenna surface (32), each of which is formed from a magnetic, flexible film (22). The antenna (18) furthermore has a base (34) formed from a magnetic material or comprising a magnetic layer (22), which connects the two antenna surfaces (30,32) to one another, the two antenna surfaces (30,32) from the Base (34) are angled in the same direction. The antenna (18) finally comprises an antenna winding (46) with at least one first single-layer spiral coil (48) which is arranged on the outside of the first antenna surface (30), in particular attached so that an axis (49) of the first spiral coil (48) is aligned perpendicularly with respect to the first antenna surface (30).

Description

The invention relates to an antenna, in particular a magnetically inductive antenna (in short: MI antenna, that is to say an antenna for magneto-inductive near-field transmission) for a hearing instrument and to a hearing instrument with such an antenna.

A hearing instrument is generally referred to as an electronic device that emits a sound signal into the ear of a person wearing the hearing instrument (also referred to as “user” or “wearer”) and thus supports this person's hearing. In the narrower sense, this includes in particular hearing aids that are used to care for hearing impaired wearers. Such hearing aids pick up ambient sound and emit it to the user in processed, in particular frequency-dependent, amplified form as airborne and / or structure-borne sound, wholly or at least partially compensating for the user's hearing loss. Other hearing instruments process - similar to classic hearing aids - a recorded ambient sound, but serve to supply normal hearing users in order to protect their hearing ability in special situations (e.g. special sound-absorbing hearing instruments for musicians) or to support them in some other way. In the following, hearing instruments are also understood to mean devices that convert a wired or wirelessly received audio signal into airborne or structure-borne sound and transmit it to the user in this form, e.g. headphones, ear pieces, etc.

There are known different designs of hearing instruments. So-called “behind-the-ear” devices (BTE for short) are worn between the skull and the auricle, with the amplified sound signal being introduced into the person's auditory canal by means of a sound tube or by means of an in the sound transducer sitting in the ear canal (also known as "listener" or "receiver"). Another version of a hearing instrument is an "in-the-ear device" (ITE for short), in which the entire hearing aid device itself is introduced into the ear, in particular into the auditory canal. There are also hearing instruments that transmit sound information in the form of structure-borne sound or that stimulate the auditory nerve directly.

Magnetic inductive near-field transmission is used in hearing instruments as an alternative to classic radio transmission technologies (e.g. Bluetooth) for the wireless transmission of data, especially audio signals, with external devices. In particular, magnetically inductive near-field transmission is often used for the communication between two hearing instruments of a binaural hearing system. Magnetic-inductive methods are also used for energy transmission, i.e. for wireless charging of rechargeable batteries in hearing instruments.

So far, the MI antennas required for this (that is, for magneto-inductive data and / or energy transmission) have been produced regularly by winding a ferrite core with an antenna winding (also referred to as a coil). The antenna performance can be increased here with larger ferrite cores, special wrapping and special ferrite materials. Due to the restricted installation space, the sensitive (and therefore fault-prone) electronics in hearing instruments and the desire for the lowest possible weight, however, there are narrow limits to the increase in performance of conventional MI antennas for use in hearing instruments.

In WO 2017/153274 A1 describes a concept for an alternative design of an MI antenna in which the cross section of a coil core (base) wound with an antenna winding is expanded by flat magnetic foils. In this film antenna, the antenna surfaces formed by the films (referred to there as “screens”) are oriented approximately orthogonally to the axis of this base. The antenna surfaces are optionally provided with a para- or diamagnetic layer on the inner sides facing one another, by means of which the interior space formed between the antenna surfaces is magnetically shielded. Electrical or electronic components of the hearing aid (for example the battery) can therefore be accommodated in a space-saving manner in the interior space between the antenna surfaces.

Further developments of this antenna design are in DE 10 2018 209 189 A1 and DE 20 2018 104 183 U1 disclosed. According to DE 10 2018 209 189 A1 the antenna surfaces angled from the base are partially formed into lateral coil core sections that flank the base on both sides and each carry a further coil. The antenna winding here thus comprises three coils which are angled relative to one another with regard to their axes. According to DE 20 2018 104 183 U1 the magnetic coil forming the antenna winding is integrated into a flexible printed circuit board. This circuit board is provided with two conductor layers that sandwich the magnetic film between them. The two conductor layers are each subdivided into a multiplicity of conductor tracks, with mutually opposing conductor tracks of the two conductor layers being electrically connected to one another via through-contacts (vias) to form the antenna winding.

Out EP 3 614 494 A1 a further variant of a film antenna is known. Here, the antenna surfaces are made up of separate ones magnetic foil blanks formed. The base wound with the antenna winding has an opening on each of its two end faces, into each of which one of the foil blanks is inserted.

The invention is based on the object of further improving an antenna for a hearing instrument, in particular with regard to manufacturing aspects. In particular, the antenna should be particularly inexpensive and inexpensive to manufacture.

This object is achieved according to the invention by an antenna having the features of claim 1. Advantageous embodiments of the invention are set out in the subclaims and the following description.

The antenna according to the invention is intended and suitable for use in a hearing instrument, in particular a hearing aid. The antenna is preferably a magnetically inductive antenna (MI antenna) which is set up for data and / or energy transmission in the magnetic near field, in particular at frequencies of up to approximately 300 MHz (megahertz). The antenna has a first antenna surface and a second antenna surface, each of which is formed from a magnetic, flexible film, in particular a ferrite film.

The antenna furthermore has a base which is formed from a magnetic material or at least comprises a magnetic layer. The base is arranged between the two antenna surfaces and connects the two antenna surfaces to one another mechanically and magnetically. The two antenna surfaces are angled from the base in the same direction, so that the base together with the two antenna surfaces roughly forms the shape of a letter “U”. The two antenna surfaces and the base enclose a volume of space (also known as the “interior”) on three sides. The sides of the two antenna surfaces and the base facing this interior space are each referred to as "inner sides". The opposite sides of the two antenna surfaces and the base to these inner sides are referred to as "outer sides". The terms "inside" and "outside" are used accordingly. The two antenna surfaces are in particular (but not necessarily) angled at right angles from the base, so that the antenna surfaces face one another parallel to one another on this side and on the other side of the interior space. The two antenna surfaces are preferably designed symmetrically to one another.

The antenna finally comprises an antenna winding.

To this extent, the antenna according to the invention is similar to a film antenna as is known per se from the prior art described above. In contrast to the known film antennas, the antenna winding is not wrapped around the base in the antenna according to the invention. Rather, the antenna winding according to the invention has at least one first single-layer spiral coil. This first spiral coil is arranged on the outside of the first antenna surface, so that a (coil) axis of the first spiral coil is oriented perpendicularly with respect to the first antenna surface. The spiral coil is attached in particular to the first antenna surface, in particular glued (directly or indirectly) to the first antenna surface.

In the following, a single-layer spiral coil is understood to mean a magnetic coil in the form of a flat (e.g. round, polygonal or irregularly shaped) spiral in which the coil wire or conductor winds in more than one turn with a changing diameter within the same area. In certain embodiments of the invention, the antenna winding consists exclusively of the first spiral coil. In order to achieve a higher antenna efficiency for a given size of the antenna, the antenna winding in expedient embodiments of the invention comprises at least one further spiral coil.

Thus, in a variant of the invention, a second single-layer spiral coil is provided in addition to the first spiral coil, which is arranged on the outside of the second antenna surface, in particular is attached so that an axis of this second spiral coil is oriented perpendicularly with respect to the second antenna surface. Expediently, the second spiral coil is constructed identically to the first spiral coil and / or is arranged centered with respect to the latter (i.e. coaxially with respect to the two coil axes).

As an alternative or in addition to the second spiral coil, the antenna in a further variant of the invention comprises at least one third single-layer spiral coil which is arranged on the outside and - with respect to the spiral plane - parallel to the first spiral coil on the first antenna surface, in particular is attached. The third spiral coil is also constructed identically to the first spiral coil in expedient designs and / or is arranged centered with respect to the latter (that is to say, again, coaxially with respect to the two coil axes).

Within the scope of the invention, the antenna can contain further second or third spiral coils which flank the second or first antenna surface. The terms “second” spiral coil and “third” spiral coil thus only serve to uniquely identify the respective spiral coil with regard to its arrangement relative to the first spiral coil, but not to count the spiral coils. Corresponding In certain embodiments of the invention, the antenna can also have only the first spiral coil and one or more third spiral coils, but not a second spiral coil.

The multiple single-layer spiral coils which may be present can be permanently connected to one another within the scope of the invention (in particular connected electrically in series) and thus together form a multilayer antenna winding. In a particularly advantageous embodiment of the invention, both spiral coils or at least two of possibly several spiral coils can be controlled independently of one another, i.e. coupled to a corresponding circuit for sending or receiving a signal or for supplying or removing energy. The independent control of at least two spiral coils enables, on the one hand, a temporary increase in the transmission power of the antenna by switching off a spiral coil and the associated increase in the amperage of the winding current. On the other hand, the independent control of at least two spiral coils enables a temporary increase in antenna efficiency by connecting a spiral coil.

In particularly advantageous embodiments of the invention, the or each spiral coil is manufactured using RFID technology (i.e. in the manner of the antenna coil of an RFID transponder). The spiral coil is produced in particular by printing, galvanic deposition, vapor deposition, sputtering, etching of conductor tracks or by embedding a coil wire on a carrier film. The use of RFID technology to manufacture the or each spiral coil has the advantage that the or each spiral coil can be manufactured in this way in a particularly uncomplicated and inexpensive manner.

In a likewise expedient alternative, the or each spiral coil is formed by a conductor track on a flexible printed circuit board. This has the particular advantage that the spiral coil can be produced comparatively easily integrally with associated control electronics and optionally also with the signal processing of the hearing instrument that is usually present anyway.

In principle, the two antenna surfaces can be formed from separate pieces of film. In order to further simplify the production and to achieve a particularly high antenna efficiency, the two antenna surfaces and the base are preferably formed by a one-piece foil cut of the magnetic foil.

Analogously to the film antennas known from the prior art, the two antenna surfaces are preferably each widened with respect to the base. In particular, the two antenna surfaces each have a circular widening, as differs from the in EP 3 614 494 A1 disclosed antennas is known per se.

In order to shape the magnetic field of the antenna favorably and thus to significantly increase the efficiency of the antenna, taking into account a limited installation space and / or maximum weight of the antenna, the antenna preferably has a first magnetic reflective layer made of an electrically conductive material with low magnetic permeability. This first reflective layer consists in particular of copper or aluminum, for example in the form of a film or coating. The first reflective layer is in each case arranged on the outside of the first antenna surface and the second antenna surface, in particular attached, so that the first reflective layer is arranged between the antenna surfaces and the or each spiral coil. The or each spiral coil and the respectively assigned antenna surface thus sandwich the first reflective film between them. In the area of each of the two antenna surfaces, the first reflective layer has a recess (i.e. a hole) through which the magnetic flux is bundled into the antenna surfaces and directed out of the antenna surfaces. The or each spiral coil is arranged in the area of one of the two recesses, in particular centered with respect to the associated recess. In embodiments of the antenna in which only the first antenna surface is assigned one or more spiral coils, the first reflective layer on the second antenna surface is optionally omitted. In this case, the first reflective layer only covers the first antenna surface and preferably the base.

In an expedient embodiment of the invention, the first reflective layer is dimensioned in such a way that it protrudes laterally over the antenna surfaces (i.e. transversely to the axis of the or each spiral coil). A particularly effective field shaping is achieved in this way. In addition, the first reflective layer preferably covers not only the two antenna surfaces, but also the base, in order to avoid undesired leakage of magnetic stray fields from the magnetic material of the base as far as possible. In particular, the first reflective layer forms a coherent surface that covers the two antenna surfaces and the base.

The first reflective layer preferably has a slot in the region of each antenna surface on the side facing away from the base, which slot extends from the respective cutout to the outer edge of the first reflective layer. As a result of the slot, the first reflective layer is therefore not annular around the cutouts closed, which counteracts the occurrence of disruptive circular currents in the first reflective layer.

In addition or as an alternative to the first reflective layer, the antenna preferably has a second magnetic reflective layer made of an electrically conductive material with low magnetic permeability, in particular made of copper or aluminum. This second reflective layer is arranged, in particular attached, on the inside of the first antenna surface and the second antenna surface. The second magnetic reflective layer also preferably extends over the base and here expediently forms a coherent surface that covers the two antenna surfaces and the base.

The antenna according to the invention has the particular advantage that it has only a very low weight and requires very little installation space, since it consists exclusively of very thin foils or layers (namely the magnetic foil, in particular the ferrite foil, the first and / or second foil, which may be present Reflective layer and the at least one winding layer) is formed. As a result of the U-shaped structure, which is formed by the antenna surfaces and the base connecting them, the antenna encloses a comparatively large volume with a small installation space. As a result of this large volume, the antenna has a high performance on the one hand; In particular, the antenna thereby generates a magnetic field profile in the excited state which approximately corresponds to that of a rod antenna of the same volume. In contrast to such a rod antenna, the enclosed volume is largely empty and can therefore be used to accommodate at least one other component of the hearing instrument, in particular a battery. The accommodation of the battery or another component with a metallic housing in the interior space enclosed by the antenna has the additional effect that the metal housing guides the magnetic flux within the magnetic film of the antenna and thus additionally promotes the antenna's performance.

The antenna according to the invention has the further advantage that it is very inexpensive and inexpensive to manufacture - even in comparison to conventional film antennas - due to the flat design of the coil (s) in RFID technology or on a printed circuit board; the formation of the coil (s) on a printed circuit board has the additional advantage that the or each coil can be integrated with the signal processing and / or control electronics of the hearing instrument in a common circuit board (and are preferably also integrated), thereby reducing the assembly effort for the hearing instrument is reduced. In particular, in this case there is no need for soldering or other contacting of the antenna winding with the associated transmitting and / or receiving circuit or the charging electronics of the hearing instrument.

An additional advantage of the antenna according to the invention is that it is highly flexible and can therefore be adapted to the structural boundary conditions in the hearing instrument. In particular, the antenna can be adapted to different body shapes. The turns of the coil (s) do not necessarily have to be round. Rather, within the scope of the invention, they can also assume other shapes, in particular angular, oval, organic shapes or combinations of these shapes (e.g. a contour adapted to the shape of the hearing instrument). In order to obtain the highest possible performance antenna, the shape of the coil (s) is preferably designed so that the antenna winding fills the maximum available area. Furthermore, by selecting the number of single-layer spiral coils, the antenna can be easily adapted to the performance and / or inductance desired in the respective application; In particular, by adding one or more spiral coils, a high performance or inductance of the antenna can be achieved even with only a very small usable area.

A particular embodiment of the invention is a hearing instrument which is equipped with the antenna according to the invention described above, in particular in one of the embodiments described above. The hearing instrument has an output transducer, for example an earpiece for outputting a sound signal into the ear of a user, in a manner that is conventional per se - inside or outside a housing. The hearing instrument furthermore preferably has a (programmable, non-programmable or partially programmable) signal processor for processing, in particular amplification, of the sound signal to be output to the user. Furthermore, the hearing instrument preferably has an input transducer, in particular at least one microphone, for capturing ambient sound, this captured ambient sound being output via the output transducer after processing, in particular amplification.

In practical embodiments, the hearing instrument has a functional component, e.g. a (rechargeable or non-rechargeable) battery or a receiver, this functional component being provided with a housing made of an electrically conductive material with low magnetic permeability, in particular made of copper, aluminum or sheet steel is. The antenna is placed on the functional component in such a way that the housing covers the antenna surfaces (and preferably also the base) tightly flanked on the inside. The housing of the functional component thereby fulfills the effect of the second reflective layer described above, which is therefore obsolete in this embodiment and therefore preferably also not present. The housing preferably rests directly on the respective inside of the antenna surfaces and optionally also on the inside of the base.

Within the scope of the invention, the antenna according to the invention can in principle advantageously be used in any hearing instruments of the type described at the outset, in particular also in headphones, ear pieces, etc. However, the hearing instrument according to the invention is preferably a hearing aid that can optionally be present as a BTE or ITE device, for example.

• 1 in schematischer Darstellung ein Hörinstrument, hier in Form eines Hinter-dem-Ohr-Hörgeräts, mit einer Batterie, und einer hierauf aufgesetzten Antenne,
• 2 in perspektivischer Darstellung die Antenne des Hörgeräts aus 1, wobei die Antenne eine Ferritfolie, eine außenseitig auf die Ferritfolie aufgebrachte erste Reflexionsfolie und eine wiederum außenseitig auf die erste Reflexionsfolie aufgebrachte Antennenwicklung umfasst, wobei die Antennenwicklung aus einer einlagigen Spiralspule gebildet ist,
• 3 in Darstellung gemäß 2 die Antenne in dem auf die Batterie des Hörinstruments aufgesetzten Zustand,
• 4 in Darstellung gemäß 3 die Batterie und die Ferritfolie der Antenne,
• 5 in Darstellung gemäß 3 die Batterie sowie die Ferritfolie und die erste Reflexionsfolie der Antenne,
• 6 die Ferritfolie der Antenne in aufgefaltetem Zustand,
• 7 die erste Reflexionsfolie der Antenne in einer alternativen Ausführungsform, in der auf der ersten Reflexionsfolie zwei jeweils einlagige Spiralfolien der Antennenwicklung aufgebracht sind, wobei die beiden Spiralfolien an zueinander entgegengesetzten Längsenden der ersten Reflexionsfolie aufgebracht sind,
• 8 in einem schematischen Querschnitt einen Ausschnitt der Batterie und der darauf aufgesetzten Antenne gemäß 2,
• 9 in Darstellung gemäß 8 eine alternative Ausführungsform der Antenne, in der die Antennenwicklung zwei aufeinander angebrachte, jeweils einlagige Spiralspulen umfasst, und
• 10 in Darstellung gemäß 8 eine weitere Ausführungsform der Antenne mit einer innenseitig auf der Ferritfolie aufgebrachten zweiten Reflexionsfolie.

Exemplary embodiments of the invention are explained in more detail below with reference to a drawing. Show in it:

• 1 a schematic representation of a hearing instrument, here in the form of a behind-the-ear hearing aid, with a battery and an antenna attached to it,
• 2 in a perspective view of the antenna of the hearing aid 1 , wherein the antenna comprises a ferrite film, a first reflective film applied on the outside of the ferrite film and an antenna winding again applied on the outside of the first reflective film, the antenna winding being formed from a single-layer spiral coil,
• 3rd in representation according to 2 the antenna in the state placed on the battery of the hearing instrument,
• 4th in representation according to 3rd the battery and the ferrite foil of the antenna,
• 5 in representation according to 3rd the battery as well as the ferrite foil and the first reflective foil of the antenna,
• 6th the ferrite foil of the antenna in the unfolded state,
• 7th the first reflective foil of the antenna in an alternative embodiment, in which two single-layer spiral foils of the antenna winding are applied to the first reflective foil, the two spiral foils being applied to mutually opposite longitudinal ends of the first reflective foil,
• 8th in a schematic cross section a section of the battery and the antenna placed thereon according to FIG 2 ,
• 9 in representation according to 8th an alternative embodiment of the antenna in which the antenna winding comprises two single-layer spiral coils attached to one another, and
• 10 in representation according to 8th a further embodiment of the antenna with a second reflective film applied on the inside of the ferrite film.

Corresponding parts are always provided with the same reference symbols in all figures.

1 shows a hearing instrument, which here is a hearing aid 2 acts to support the hearing of a hearing impaired user. With the hearing aid 2 In the example shown here, it is a BTE hearing aid that can be worn behind an ear of a user.

The hearing aid 2 includes within a housing 4th two microphones 6th as an input transducer and a listener 8th (Receiver) as an output converter. The hearing aid 2 further comprises a battery 10 and signal processing in the form of a signal processor 12th . Preferably the signal processor comprises 12th both a programmable sub-unit (e.g. a microprocessor) and a non-programmable sub-unit (e.g. an ASIC).

The signal processor 12th is from the battery 10 with an electrical supply voltage U provided.

During normal operation of the hearing aid 2 take the microphones 6th an airborne sound from the vicinity of the hearing aid 2 on. The microphones 6th convert the sound into an (input) audio signal I, which contains information about the recorded sound. The input audio signals I. are inside the hearing aid 2 the signal processor 12th fed to these input audio signals I. , modified to support the user's hearing.

The signal processor 12th gives an output audio signal O containing information about the processed and thus modified sound to the listener 8th out.

The listener 8th converts the output sound signal O into a modified airborne sound. This modified airborne sound is transmitted through a sound channel 14th who is the listener 8th with a tip 16 of the housing 4th connects, as well as a (not explicitly shown) flexible sound tube that connects the tip 16 with an earpiece inserted into the ear canal of the user, transferred into the ear canal of the user.

In order to use peripheral devices such as a second hearing aid to supply the second ear to be able to exchange data of the user includes the hearing aid 2 still an antenna 18th . At the antenna 18th it is an MI antenna that uses magnetically inductive near-field transmission for data exchange. To control the antenna 18th includes the hearing aid 2 an associated transmit / receive circuit 20th , the one hand with the antenna 18th and on the other hand with the signal processor 12th of the hearing aid 2 connected is. In addition or as an alternative, the antenna is used 18th to wirelessly absorb energy to the battery 10 to load. The antenna 18th is in this case (possibly also) with an electronic charging control of the hearing aid 2 connected to the battery charging process 10 controls.

According to 2 includes the antenna 18th Instead of a solid magnetic core, a magnetic, flexible foil, here in the form of a ferrite foil 22nd which has a thickness of approximately 30 to 400 µm (micrometers), preferably 50 to 300 µm and in particular 100 µm. As in particular from the 2 , 4th and 6th is the ferrite foil 22nd formed by a (preferably one-piece) dumbbell-shaped blank. The ferrite foil 22nd thus has in the embodiment shown here at their opposite longitudinal ends 24 each a circular widening 26th on, with the two widenings 26th by a narrower connecting section 28 are connected. To form the antenna 18th is the ferrite foil 22nd Folded to a U-shaped contour, the legs of which each by one of the two widenings 26th and an adjacent piece of the connecting portion 28 are formed. The legs of the U-shaped contour, i.e. both widenings 26th and the respective adjacent pieces of the connecting portion 28 , thus form two parallel and at a distance opposite antenna surfaces 30th and 32 . Of these two antenna surfaces 30th and 32 connecting part of the connecting section 28 is used as a base 34 designated.

As from the 2 and 5 can be seen is on the outside of the ferrite foil 22nd a reflective film as the first reflective layer 36 made of copper applied with the ferit foil 22nd is preferably glued. The reflective tape 36 has one on the ferrite foil 22nd adapted shape, in the case of the present example also a dumbbell shape. It is compared to the ferrite foil 22nd but with larger widenings 38 at their longitudinal ends 40 provided so that the reflective tape 36 in the area of the antenna surfaces 30th and 32 laterally over the edge of the ferrite foil 22nd stands out. Furthermore, the reflective tape is 36 in the area of their widening 38 each with a central circular recess 42 provided so that the widenings 38 each have the shape of a circular ring. At theirs from the base 34 facing away sides (i.e. at the longitudinal ends 40 the reflective tape 36 ) are the circular widenings 38 each through a thin slot 44 interrupted from the respective recess 42 to the outer edge of the reflective tape 36 extends.

The antenna 18th finally includes an antenna winding 46 . In the in the 2 to 6th and 8th illustrated embodiment is this antenna winding 46 by a single layer spiral coil 48 formed, which in turn on the outside of the reflective film 36 is upset. The spiral coil 48 is centered on the broadening 26th the ferrite foil 22nd and the broadening 38 the reflective film (and thus also centered with respect to the recess made in the latter 42 ) arranged. The antenna winding is different from the conventional film antennas described at the beginning 46 thus not about the ferrite foil 22nd or another magnetic core wound around it. The spiral coil 48 is rather related to the ferrite foil 22nd arranged such that the coil axis 49 (Figs, 3 and 7) of the spiral coil 48 perpendicular to the area of the ferrite foil 22nd and thus perpendicular to the antenna surface 30th stands.

The spiral coil is a preferred embodiment 48 formed like the antenna coil of an RFID transponder. For this purpose, it is in particular by means of a carrier film 50 printed or in the carrier film 50 embedded electrical conductor track (see in particular 8th ) formed, this carrier film 50 preferably on the reflective tape 36 is glued on. The one with the spiral coil 48 provided carrier film 50 is in summary also as a wrapping foil 52 designated.

As in particular from the 3rd to 5 and 8th can be seen is the antenna 18th in the assembled state on the (cylindrical) battery 10 put on that the antenna surfaces 30th and 32 the two end faces of the battery 10 flank tightly or even on the front sides of the battery 10 issue.

Like that 3rd and 5 is removable, is the reflective tape 36 dimensioned so that the widenings 38 in terms of their shape and size roughly the end faces of the battery 10 correspond. The spiral coil 48 is in turn dimensioned in such a way that it corresponds to the associated widening 38 the reflective tape 36 The open area is largely used.

In operation of the antenna 18th becomes that from the antenna winding 46 generated magnetic field through the perforated reflective foil 36 Shaped so that the magnetic field of the antenna 18th approximately the magnetic field of a rod antenna with the distance between the antenna surfaces 30th and 32 corresponds to the same length. Through the reflective tape 36 and a metal case 54 the battery 10 is forced that the magnetic field in the interior between the antenna surfaces 30th and 32 largely inside the ferrite foil 22nd runs. The metal case 54 the battery 10 In this respect, acts as an inside magnetic reflective layer, which on the one hand supports the antenna 18th the enclosed interior space and, on the other hand, the performance of the antenna 18th elevated.

In order to improve the performance of the antenna for a given installation space (and thus limited size) 18th further increase will be in further versions of the antenna 18th one or more further spiral coils to the antenna winding 46 added.

So is based on 7th who have favourited the reflective tape 36 with the antenna winding applied to it 46 shows in the unfolded state an embodiment of the antenna 18th shown with the antenna winding 46 in addition to the spiral coil 48 another single layer spiral coil 56 includes. This more spiral coil 56 is on the other antenna surface 32 appropriate. The antenna 18th is in this embodiment with respect to the shape of the ferrite layer 22nd and the reflective layer 36 as well as with regard to the structure (in particular with regard to the arrangement of the two spiral coils 48 and 56 ) designed symmetrically so that the two spiral coils 48 and 56 in the (folded) assembly state of the antenna 18th with respect to their coil axes 49 are arranged coaxially to one another. The coil axis 49 the spiral coil 56 is also perpendicular to the area of the ferrite foil 22nd (and thus perpendicular to the antenna surface 32 ) aligned.

In the execution according to 7th are the two spiral coils 48 and 56 to a common electrical supply line 58 connected and connected electrically in series. In an alternative embodiment, there are two coils 48 and 56 on the other hand, separately from each other with the transmit / receive circuit 20th connected and can operate the antenna 18th can be switched on and off individually, as required, or controlled independently of one another in some other way. In one embodiment of the antenna 18th is just the signal coil 48 with the transmit / receive circuit 20th connected while the signal coil 56 as a charging coil with the charging control of the hearing aid present here 2 connected is.

In a further embodiment of the antenna 18th includes the antenna winding 46 in addition to the spiral coil 48 also another single-layer spiral coil 60 comprises, this further spiral coil 60 but according to 9 along with the spiral coil 48 on the antenna surface 30th is appropriate. The spiral coil 60 is in this case preferably directly on the spiral coil 48 attached, especially glued to the latter. The two spiral coils 48 and 60 are preferably arranged to one another in such a way that they with respect to their coil axes 49 are arranged coaxially to one another.

Also in the execution according to 9 are the two spiral coils 48 and 60 preferably connected electrically in series and thus controlled together. The two single-layer spiral coils 48 and 60 thus together form a multi-layer coil. Alternatively, the two coils 48 and 60 within the scope of the invention, in turn, be controlled separately from one another.

About the performance of the antenna 18th To increase even further, the two spiral coils will be 48 and 56 or. 48 and 60 If necessary, additional spiral coils can be added, optionally on the antenna surface 30th and / or on the antenna surface 32 can be arranged.

The spiral coils 48 and 56 or 48 and 60 as well as possibly further spiral coils are preferably produced identically and are therefore in particular in the form of a winding foil that can be produced inexpensively and is easy to handle 52 in front. However, the antenna winding 46 also include differently designed coils (in particular with regard to the number of turns and the diameter).

In a further embodiment, the antenna comprises 18th according to 10 a further reflective film as a second reflective layer 62 , the inside on the ferrite foil 22nd is upset. This more reflective tape 62 preferably has one of the reflective films 36 corresponding shape (but without the recesses 42 and the slots 44 ) and is in alignment with the reflective tape 36 arranged so that the reflective films 36 and 62 the ferrite foil 22nd wrap in a sandwich-like manner. The reflective tape 62 is preferably analogous to the reflective tape 36 formed by a metal foil made of copper or aluminum and with the ferrite foil 22nd and the reflective tape 36 preferably glued. The inner reflective foil 62 improves the magnetic shielding of the antenna 18th enclosed interior and the conduction of the magnetic flux inside the ferrite foil 22nd . It is provided in particular when the antenna is installed 18th in this interior different from 1 to 5 magnetically susceptible components are arranged, which are not sufficiently magnetically shielded themselves.

The reflective tape 62 can also be provided to prevent the heating of metallic bodies in the interior of the antenna 18th (e.g. des Metal housing 54 the battery 10 ) as a result of eddy currents.

The invention is particularly clear from the exemplary embodiments described above, but is in no way restricted to these exemplary embodiments. Rather, further embodiments of the invention can be derived from the claims and the above description.

List of reference symbols

2

Hearing aid

4th

casing

6th

Microphones

8th

Listener

10

battery

12th

Signal processor

14th

Sound channel

16

top

18th

antenna

20th

Transmit / receive circuit

22nd

Ferrite foil

24

Longitudinal end

26th

Broadening

28

Connection section

30th

Antenna area

32

Antenna area

34

Base

36

Reflective tape

38

Broadening

40

Longitudinal end

42

Recess

44

slot

46

Antenna winding

48

Spiral coil

49

Coil axis

50

Carrier film

52

Wrapping foil

54

Metal case

56

Spiral coil

58

Supply line

60

Spiral coil

62

Reflective tape

I.

(Input) audio signal

O

Output audio signal

U

Supply voltage

QUOTES INCLUDED IN THE DESCRIPTION

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Patent literature cited

• WO 2017/153274 A1 [0006]
• DE 102018209189 A1 [0007]
• DE 202018104183 U1 [0007]
• EP 3614494 A1 [0008, 0023]

Claims (15)

Antenna (18), in particular magnetic-inductive antenna (18), for a hearing instrument (2), - with a first antenna surface (30) and a second antenna surface (32), which are each formed from magnetic, flexible film (22), - With a base (34) formed from a magnetic material or comprising a magnetic layer (22), which connects the two antenna surfaces (30, 32) to one another, the two antenna surfaces (30, 32) from the base (34) being the same Direction are angled, and - with an antenna winding (46), characterized in that the antenna winding (46) has at least one first single-layer spiral coil (48) which is arranged on the outside of the first antenna surface (30), in particular attached so that a Axis (49) of the first spiral coil (48) is aligned perpendicular to the first antenna surface (30). Antenna (18) Claim 1 , with a second single-layer spiral coil (56) which is arranged on the outside of the second antenna surface (32), in particular is attached so that an axis (49) of this second spiral coil (56) is oriented perpendicularly with respect to the second antenna surface (32). Antenna (18) Claim 1 or 2 , with at least one third single-layer spiral coil (60) which is arranged, in particular attached, on the outside and parallel to the first spiral coil (48) on the first antenna surface (30). Antenna (18) Claim 2 or 3rd , wherein the first spiral coil (48) and the second spiral coil (56) or third spiral coil (60) can be controlled independently of one another. Antenna (18) according to one of the Claims 1 to 4th wherein the or each spiral antenna (48, 56, 60) is produced in RFID technology, in particular by printing, galvanic deposition, vapor deposition, sputtering, etching or embedding a coil wire on a carrier film (50). Antenna (18) according to one of the Claims 1 to 4th wherein the or each spiral antenna (48,56,60) is formed by a conductor track of a flexible printed circuit board. Antenna (18) according to one of the Claims 1 to 6th , wherein the two antenna surfaces (30,32) and the base (34) are formed by a one-piece foil cut of the magnetic foil (22). Antenna (18) according to one of the Claims 1 to 7th wherein the two antenna surfaces (30, 32) are each widened relative to the base (34), in particular having a circular widening (26). Antenna (18) according to one of the Claims 1 to 8th , with a first magnetic reflective layer (36) made of an electrically conductive material with low magnetic permeability, in particular made of copper or aluminum, which is in each case arranged on the outside of the first antenna surface (30) and the second antenna surface (32), in particular attached, so that the first reflective layer (36) is arranged between the or each spiral coil (48,56,60) and the respectively assigned antenna surface (30,32), the first reflective layer (36) in the area of each of the two antenna surfaces (30,32) has a recess (42), and wherein or each spiral coil (48,56,60) is arranged in the region of one of the two recesses (42). Antenna (18) Claim 9 , wherein the first reflective layer (36) protrudes laterally beyond the antenna surfaces (30, 32). Antenna (18) Claim 9 or 10 wherein the first reflective layer (36) also covers the base (34). Antenna (18) according to one of the Claims 9 to 11 , wherein the first reflective layer (36) has a slot (44) in the region of each antenna surface (30, 32) on the side facing away from the base (34), which slot extends from the respective recess (42) to the outer edge of the first reflective layer (36) extends. Antenna (18) according to one of the Claims 1 to 12th , with a second magnetic reflective layer (62) made of an electrically conductive material with low magnetic permeability, in particular made of copper or aluminum, the second magnetic reflective layer (62) being arranged on the inside of the first antenna surface (30) and the second antenna surface (32) , in particular is appropriate. Hearing instrument (2) with an antenna (18) according to one of the Claims 1 to 13th . Hearing instrument (2) Claim 14 , with a functional component, in particular a battery (10) or a receiver (8), wherein the functional component has a housing (54) made of an electrically conductive material with low magnetic permeability, in particular made of copper, aluminum or a sheet steel, and wherein the The antenna (18) is placed on the functional component in such a way that the housing (54) flanks the antenna surfaces (30, 32) on the inside.

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