Hearing aid with electronics frame and antenna integrated therein

A hearing aid includes a housing and a frame inserted in the housing and serving to receive electrical or electronic assemblies which include a transmitting and/or receiving unit for electromagnetic waves. The frame includes an associated antenna configured as an integral part of the frame, as a stamped/bent part or as an inlay part made of metal. The antenna includes a first part with two ends. The first part in particular has a winding profile or is configured as an open loop, and a segment along the profile of the first part forms a first auxiliary structure having the shape of a closed loop.

CROSS-REFERENCE TO RELATED APPLICATION

This application claims the priority, under 35 U.S.C. § 119, of German Patent Application DE 10 2018 207 179.9, filed May 8, 2018; the prior application is herewith incorporated by reference in its entirety.

BACKGROUND OF THE INVENTION

Field of the Invention

The invention relates to a hearing aid with a housing, a frame inserted in the housing and serving to receive electrical or electronic assemblies which include a transmitting and/or receiving unit for electromagnetic waves and an associated antenna, in which the antenna is configured as an integral part of the frame, as a stamped/bent part or as an inlay part made of metal.

Hearing devices are known per se and are described in great detail in various publications, for example in International Publication WO 2014/090419 A1, corresponding to U.S. Pat. Nos. 9,571,944 and 9,980,062. “Hearing aids” include portable hearing devices that serve to assist those with hearing impairments. In order to satisfy numerous individual needs, various structural types of hearing aids are made available, such as behind-the-ear hearing aids (BTE), hearing aids with an external receiver (RIC: receiver-in-canal), and in-the-ear hearing aids (ITE), e.g. also concha hearing aids or canal hearing aids (ITE, CIC). The listed examples of hearing aids are worn on the outer ear or in the auditory canal. In addition, however, bone conduction hearing aids, implantable or vibrotactile hearing aids, are also available on the market. In those, the damaged hearing is stimulated either mechanically or electrically. Such hearing aids are also designated as “hearing devices.”

In addition to the classic hearing aids described above, hearing aids have also recently been developed that assist people with normal hearing. Such hearing aids are also referred to as “Personal Sound Amplification Products” or “Personal Sound Amplification Devices” (abbreviated to “PSAD”). Those hearing aids are not provided to compensate for hearing losses. Instead, such hearing aids are used precisely to assist and improve normal human hearing capacity in specific hearing situations, e.g. to assist hunters out on the hunt, or in order to assist in the observation of animals, to be better able to perceive animal noises and other sounds generated by animals, for sports reporters in order to permit improved speaking and/or speech understanding under difficult conditions, for musicians, in order to reduce the strain on their hearing, and so on.

In principle, the basic components of hearing aids are an input transducer, an amplifier and an output transducer. The input transducer is normally an acoustic-electric transducer, e.g. a microphone, and/or an electromagnetic receiver, e.g. an induction coil. The output transducer is generally realized as an electroacoustic transducer, e.g. a miniature loudspeaker (receiver), or an electromechanical transducer, e.g. a bone-conduction receiver. The amplifier is usually integrated in a signal-processing device.

Modern hearing aids are often equipped with transmitting and/or receiving units that permit wireless communication with other electronic devices, in particular with other hearing aids (e.g. in order to form a binaural hearing aid system), remote controls, programming devices or cell phones. The wireless communication is often effected by using electromagnetic waves in the radiofrequency range, e.g. using Bluetooth technology at 2.4 GHz.

A problem with hearing aids lies in the realization of the (RF) antennas needed for them, since standard antenna constructions cannot easily be used due to the free-space wavelength (corresponding to the above-mentioned frequency range) of more than 10 cm and due to the electrically small volume of conventional hearing aids. That problem is becoming increasingly important as the miniaturization of hearing aids gathers pace.

In the hearing aid known from International Publication WO 2014/090419 A1, corresponding to U.S. Pat. Nos. 9,571,944 and 9,980,062, the antenna is formed by a conductive structure which is an integral part of the (electronics) frame of the hearing aid. That allows the antenna to be accommodated in a space-saving manner in the housing of the hearing aid. Moreover, the antenna can be installed with the frame in a large number of different housings, without the antenna construction always having to be reconfigured.

SUMMARY OF THE INVENTION

It is accordingly an object of the invention to provide a hearing aid with an electronics frame and an antenna integrated therein, which overcomes the hereinafore-mentioned disadvantages of the heretofore-known hearing aids of this general type and which improves the antenna construction known from International Publication WO 2014/090419 A1, corresponding to U.S. Pat. Nos. 9,571,944 and 9,980,062.

With the foregoing and other objects in view there is provided, in accordance with the invention, a hearing aid which comprises a housing and, inserted in the housing, an (electronics) frame for receiving electrical and/or electronic assemblies. The assemblies received in the frame include a transmitting and/or receiving unit for electromagnetic waves, in particular radio waves in the MHz or GHz range, e.g. 2.44 GHz (corresponding approximately to a wavelength of 65 mm). The hearing aid moreover includes an antenna which is assigned to the transmitting and/or receiving unit and which is configured as an integral part of the frame. Integral part is to be understood in this case in particular as meaning that the antenna or a structure partially or completely forming the antenna cannot be released from the frame without destruction and/or is substantially part of the outer shape of the frame, i.e. does not protrude much therefrom, wherein the frame is made of a different, non-conductive material, in particular a plastic. In an alternative embodiment of the invention, the antenna is constructed as a stamped/bent part (connected to the frame) or as an inlay part (connected to the frame) made of metal.

According to the invention, the antenna moreover has a first part, which in particular has a winding profile or is configured as an open loop with two ends. That is to say, the first part usually has a non-rectilinear profile, typically with several changes of direction, for example a meandering configuration. Moreover, a segment along the profile of the first part forms a first auxiliary structure having the shape of a closed loop, for example a kind of ring shape or an oval shape.

With this auxiliary structure, the effective length of the antenna-forming structure is then increased, without this requiring a greater surface area for accommodating the antenna. That is to say, the space available for the antenna or the surface area available for the antenna is utilized more effectively in this way. In addition, the radiating characteristics of the antenna can be favorably influenced by this auxiliary structure, particularly with regard to the intensity and spatial angle of the radiation. In addition, the auxiliary structure permits a relatively good impedance adaptation to an impedance of 50Ω.

It is furthermore advantageous if the frame has an upper face, an underside and two mutually opposite flanks, and if the first auxiliary structure is positioned on one of the two flanks of the frame. In this case, side region or flank designates a side of the frame that interconnects the upper face and the underside of the frame. The corresponding designation of the sides of the frame with upper face, underside and flank relates to the intended orientation of the hearing aid relative to a wearer or user of the hearing aid while wearing the corresponding hearing aid. The underside of the frame then typically points in the direction of the torso of the user or wearer, and one of the two flanks or one of the side regions points in the direction of the head, while the other of the two flanks or the other of the two side regions is directed away from the head. The resulting relative configuration and/or orientation of the first auxiliary structure relative to the user or wearer of the hearing aid is relevant with regard to the radiating characteristics of the antenna during transmission.

In an advantageous development, the antenna additionally includes a second part, which in particular has a winding profile or is configured as an open loop with two ends. The two parts of the antenna are preferably electrically shorted to each other at one of their ends by a bridge, and the bridge is configured in particular as an integral part of the frame. Such a bridge or a part of such a bridge is formed, for example, by at least one electrical conductor track which completely or at least partially bridges the distance between the short-circuit ends of the parts of the antenna and which is therefore referred to below as a “bridging conductor.” Like the whole antenna, the bridging conductor or each bridging conductor is configured in this case as an integral part of the frame, a stamped/bent part or inlay part.

It is expedient if the two parts of the antenna are positioned on the two mutually opposite flanks of the frame. In particular, in this case the bridge is preferably routed over the upper face at the frame.

In an embodiment variant, the frame is moreover formed from two frame halves, wherein the first part of the antenna is disposed on one of the two frame halves, and the second part of the antenna is disposed on the other of the two frame halves.

It is additionally advantageous if the two parts, i.e. the first part of the antenna and the second part of the antenna, are formed symmetrically to each other with respect to a separating plane that separates the frame halves. The symmetrical configuration of the antenna advantageously facilitates a side-independent use of the hearing aid. This feature in other words allows one and the same housing, including the frame and the components received in the latter, to be used both for use on the left ear and also for use on the right ear.

However, in differing embodiments of the invention, the two parts of the antenna can also be formed asymmetrically with respect to each other. The asymmetric configuration of the two parts is preferably always chosen when a symmetrical configuration of the parts would lead to stronger electromagnetic interference between the antenna and the other electrical or electronic assemblies in or on the frame. The asymmetry between the two parts is preferably slight. The parts of the antenna are in particular made as symmetrical as possible while avoiding such interference.

In addition, the antenna is usually constructed as a folded dipole antenna and, according to an embodiment variant, the two ends of both parts of the antenna are disposed at the same longitudinal end of the frame.

Moreover, a segment along the profile of the second part of the antenna preferably forms a second auxiliary structure having the shape of a closed loop.

The geometric configuration of the auxiliary structures is typically adapted to the particular use. According to an embodiment variant, at least one auxiliary structure, in particular each auxiliary structure, has a substantially elliptical shape or an oval shape. In the case of a substantially elliptical shape, the main axis of the elliptical shape is then preferably oriented vertically, i.e. vertically with respect to the earth system. A tapering shape is also useful for one of the auxiliary structures or for both auxiliary structures. In particular, if at least one auxiliary structure or each auxiliary structure has an elliptical shape, it preferably tapers to a point at both ends of its main axis.

Through the integration of the antenna on the frame, in combination with the special configuration of the antenna, it is considerably easier, as has already been explained above, to obtain the antenna length that is necessary for effective transmitting and/or receiving characteristics of the antenna. Each part of the antenna then preferably has a (line) length which corresponds with good approximation to a quarter or an eighth of the wavelength of the radio waves for which the transmitting and/or receiving unit is constructed.

According to a further advantageous embodiment of the hearing aid, the frame is produced from a non-conductive material, in particular a plastic, that has a higher permittivity than the material of the housing. In particular, the frame material of the hearing aid according to the invention also has a higher permittivity than materials that are generally used for electronics frames of conventional hearing aids. In particular, the frame material of the hearing aid according to the invention has a relative permittivity of at least 3.8, preferably at least 4.5. It has been found that the increased permittivity of the frame material as a result of dielectric interaction with the electromagnetic field that is produced or received by the antenna allows significant shortening of the antenna length at given transmitting/receiving characteristics. This in turn represents a considerable advantage for accommodating the antenna on the frame.

In order to provide for the integration of the antenna or parts of the antenna in the frame, the surface of the frame is preferably first of all structured in such a way that, when the conductive layer is applied, the latter is applied only as per the structuring. This is effected, for example, by using laser direct structuring (LDS). The surface of the frame in this case is treated with a laser in such a way that a conductor track deposits only on the treated locations in an electroplating bath.

In another embodiment of the method, a conductive layer is first of all applied to the surface of the frame, after which the conductive layer is structured. In this case, the conductive layer is applied, for example, by bonding, sputtering or some other measures.

In a further alternative in this context, the antenna is printed onto the frame, or parts of the antenna are printed onto the frame.

Although the invention is illustrated and described herein as embodied in a hearing aid with an electronics frame and an antenna integrated therein, it is nevertheless not intended to be limited to the details shown, since various modifications and structural changes may be made therein without departing from the spirit of the invention and within the scope and range of equivalents of the claims.

DETAILED DESCRIPTION OF THE INVENTION

Referring now in detail to the figures of the drawings, in which parts that correspond to each other are always provided with the same reference signs, and first, particularly, toFIG. 1thereof, there are simply seen principal elements of a hearing aid100, without reproducing the true positions, connections or shapes of those elements.

The embodiment shown inFIG. 1is a behind-the-ear hearing aid100. However, the invention is also conceivable for in-the-ear hearing aids, in which case there is then a different configuration of the components shown.

The hearing aid100has a housing1which is made of plastic and in which a frame11is inserted. The frame11is preferably an injection-molded plastics part. The frame11serves generally to hold electrical and electronic assemblies of the hearing aid100and to fix these assemblies in defined positions relative to one another. Specifically, one or more microphones2for receiving sound (i.e. acoustic signals) from the environment are disposed in the frame11. For this purpose, a printed circuit board (PCB) carrying at least some of the electrical or electronic components is in particular folded into the frame11.

The microphones2are acoustic-electric transducers for converting the sound into audio signals. A signal-processing device3, which is likewise integrated in the housing1, processes these audio signals. The output signal of the signal-processing device3is transmitted to a loudspeaker or receiver4, which emits an acoustic signal. The sound is transmitted to the eardrum of the device wearer, possibly through a sound tube that is fixed in the auditory canal with an ear mold. The power supply for the hearing aid and particularly for the signal-processing device3is provided by a battery5that is likewise integrated in the housing1. The signal-processing device3, the receiver4and the battery5are likewise disposed in the frame11in such a way that the frame11, with the components disposed therein, can easily be removed from the housing1, for example in order to be able to exchange the housing1.

The signal-processing device3according to the invention is also configured to process electromagnetic waves. The signal-processing device3has a transmitting and receiving device6for producing and detecting electromagnetic waves and/or for decoding. The transmitting and receiving device6is electrically connected to an antenna10in order to transmit and receive electromagnetic waves.

The antenna10is configured as an integral part of the frame11, namely as a conductive structure integrated in the frame11. The antenna10is mounted directly on the frame11. It is not spaced apart from the surface and cannot be released from the frame11without destruction.

The antenna10is mounted on the frame11in particular by using MID technology. This is accomplished in particular by using laser direct structuring (LDS). In an alternative embodiment, the antenna10is printed directly onto the frame11. The conductor structures placed onto the surface of the frame11are then optionally electrically insulated and protected against damage by a protective lacquer or coating.

FIG. 2shows a first embodiment of the frame11with a first configuration of the antenna10. An opening, below which the microphone2(or one of several microphones2) is disposed, is provided on an upper face36of the frame11as is seen at the top in the view according toFIG. 2. The frame11also has an underside39. Recesses in the frame11, which are not shown explicitly, serve to accommodate the receiver4and the transmitting and receiving unit6. Moreover, the frame11forms a battery compartment for accommodating the battery5.

When the hearing aid100is operated as intended, a sound tube is attached to a tip or front35of the frame11and allows the sound generated by the receiver4to be conveyed to an ear mold insertable into the auditory canal of a user. The sound tube and the ear mold are not shown inFIG. 2. When the hearing aid is being worn as intended on the ear, the frame11is oriented in its longitudinal direction with the tip or front35facing forward in the viewing direction of the wearer. A transverse direction of the frame11is perpendicular to the viewing direction of the wearer and more or less parallel to a connecting line between the ears of the wearer. Two parts40,41of the antenna10are disposed on lateral surfaces or flanks37of the frame11.

The frame11is divided into two frame halves lengthwise along a dividing plane or separating plane (not shown) and each of the two frame halves having a flank37. After the insertion of the assemblies accommodated therein, the frame halves are in this case connected by clipping, screwing, adhesive bonding and/or by using retaining pins.

In the embodiment of the hearing aid100shown inFIG. 2, the two parts40,41of the antenna10each have the shape of an open loop. A first part40is disposed on one frame half42, while a second part41is disposed on another hidden frame half.

The two parts40,41of the antenna10, seen transversely with respect to the dividing plane or separating plane of the frame11, run parallel to each other and are thus aligned with each other. The antenna10therefore has mirror symmetry with respect to the dividing plane or separating plane of the frame11.

Each of the two parts40,41has two respective ends, namely an attachment end44,45and a bridging conductor end61,62. In this case, both ends44,62and45,61of a respective part40,41of the antenna10are each disposed inFIG. 2at the same longitudinal end of the frame11(namely at the tip or front35). The two bridging conductor ends61,62are electrically shorted to each other through an electrical cross-connection or bridge46that also spans the separation of the two frame halves. The two other ends, i.e. the attachment ends44,45, are in contact with the transmitting and receiving device6.

Depending on the embodiment, the bridge46is formed at least partly by conductor tracks, which are likewise mounted directly on the frame halves of the frame11using MID technology (particularly by LDS). Alternatively, the bridging conductor ends61,62already abut each other, and in this case the bridging conductor ends61,62are electrically connected to each other, for example by a solder point64. That is to say, the bridge46is then formed by the solder point64.

FIG. 3shows an alternative embodiment of the antenna10. In this embodiment, the bridge46is formed, for example, by a continuous conductor track and moreover is not disposed in the region of the front35but instead is routed over the upper face36in the rear region, i.e. on the right-hand side in the figure. Moreover, the two parts40,41of the antenna10are not configured as open loops. Instead, they have a winding profile with several changes of direction.

Moreover, in each part40,41of the antenna10, a segment along the profile forms an auxiliary structure70,71. Each of the two auxiliary structures70,71has the shape of a closed loop. That is to say, the first part40of the antenna10forms a first auxiliary structure70, and the second part41of the antenna10forms a second auxiliary structure71.

In the illustrative embodiment according toFIG. 3, the two auxiliary structures70,71are of identical configuration, symmetrical and positioned opposite each other on the two flanks37of the frame11.

Moreover, in the illustrative embodiment, each auxiliary structure70,71has an approximately elliptical shape. The main axis of each elliptical shape preferably has a good approximation to a vertical orientation, i.e. it is vertical with respect to the earth, when the hearing aid100is being worn by a user. In addition, each auxiliary structure70,71preferably tapers to a point at both ends, as seen in the direction of the main axis.

The invention will be particularly clear from the illustrative embodiments described above. However, it is not limited to these illustrative embodiments. Instead, many other embodiments of the invention may be derived from the claims and from the above description.

LIST OF REFERENCE SIGNS