DE202014000874U1 - Electronic assembly for a body-worn audio device - Google Patents

Abstract

Electronic assembly for an audio device (210) to be worn on the body for wireless transmission of an audio signal to at least one hearing device (16, 16R, 16L) to be worn on or in the ear, with a printed circuit board and an antenna mounted on the printed circuit board by means of an SMT method (38) with two orthogonal polarization directions, the antenna having a rod-shaped ferrite core (42) with a longitudinal direction, at least the ferrite core. partially surrounding, electrically insulating housing (40, 44, 46), a first antenna winding (48) which surrounds the ferrite core in the circumferential direction around the longitudinal direction of the ferrite core, a second antenna winding (50) which surrounds the ferrite core in the longitudinal direction, and Has electrically conductive contact elements (54) connected to the housing, each of which is electrically connected via a contact (56) to the first antenna winding or the second antenna winding and, on the other hand, is mounted in electrical contact with a corresponding conductor track of the circuit board on the circuit board to electrically contact the antenna windings with the circuit board, the housing having a component (60) asymmetrical in a plan view in a direction perpendicular to the longitudinal direction of the ferrite core, in order to differentiate the orientation of the housing with respect to a rotation by 180 when the circuit board is fitted Degrees around the direction of supervision t to enable.

Description

The present invention relates to an electronic assembly for a body-worn audio device for wirelessly transmitting an audio signal to at least one hearing device to be worn on or in the ear, for example a so-called "audio streamer" for a hearing aid.

Such audio streamer are, for example, designed so that they receive audio data wirelessly via a Bluetooth connection and transmitted to the hearing device via a short-range wireless connection, which is typically designed to be inductive. It is understood that such an audio device should be lightweight and small, yet allow for a continuous operating time of several hours. However, use of antenna booster circuits significantly reduces battery life. Through the use of efficient built-in ferrite antennas, a range of 40 to 54 cm between the audio device and the hearing device can be achieved even without the use of a booster circuit. However, due to the angular dependence of the radiated field, it may be difficult to reliably maintain a connection between the audio device and two hearing devices at the same time. To increase the reliability of the connection, it may therefore be necessary to use relatively large ferrite antennas, e.g. B. with dimensions of 10 × 40 mm to use. However, this contradicts the pursuit of a lightweight and compact design of the audio device.

Another known approach is therefore to implement so-called antenna diversity, which involves the use of at least two antennas to improve the quality and reliability of the wireless link. There are different possibilities for the realization of an antenna diversity; an example is the so-called polarization diversity, in which pairs of antennas with vertical planes of polarization are used. It uses the fact that reflected signals, depending on the medium through which they move, may undergo polarization changes, with a polarization difference of 90 ° leading to a weakening of the signal strength. By pairing two complementary polarizations together, one system can then be protected from polarization differences that would otherwise result in signal fading.

The provision of antenna diversity on the transmitter side allows the elimination of the angular dependence between the hearing device and the audio device, which would otherwise result from a change in the position of the audio device on the body or from a head rotation.

In the EP 2 453 585 A1 A wireless near-field communication system is described which includes two ferrite antennas whose windings are perpendicular to each other to generate perpendicular magnetic fields for an inductive wireless communication link.

In the US 6,924,767 B2 An electronic car key is described which has mutually perpendicularly wound antennas on a common carrier body.

In the US 6,134,420 a wireless communication system with a bidirectional communication path between a stationary base unit, for example a telephone system, and a headset is described, in which antennas are provided with mutually perpendicular windings on a common carrier body. A similar system is in the US 5,966,641 described.

In the WO 2013/133931 A1 a clock with wireless reception of a time signal is described, the antennas having mutually perpendicular windings has a ferrite core containing a common carrier body.

It is an object of the present invention to provide an electronic assembly for a body-worn audio device for wirelessly transmitting an audio signal and at least one hearing aid to be worn on or in the ear, which on the one hand as reliable as possible transmission of the audio signal, in particular with the lowest possible angular dependence, allows and on the other hand can be made as efficient as possible.

This object is achieved by an assembly according to claim 1.

In the solution according to the invention, it is advantageous that the contact element for the two antenna windings connected to the antenna housing is advantageous in that the antenna surrounds a first antenna winding which surrounds the ferrite core in the circumferential direction about the longitudinal direction, and a second antenna winding which surrounds the ferrite core in the longitudinal direction wherein the housing has an asymmetric component in a plan view in a direction perpendicular to the longitudinal direction of the ferrite core to allow the orientation of the housing to be rotated 180 ° around the direction of the view when the circuit board is mounted, on the one hand only little angle-sensitive signal transmission of the antenna is enabled, and On the other hand, the circuit board can be equipped with the antenna by means of an SMT (Surface Mount Technology) method, whereby a particularly simple assembly method of the electronic module is made possible. In particular, the antenna housing can thereby be gripped in a simple manner by means of a vacuum pipette for equipping the printed circuit board, without any confusion of the orientation of the antenna can occur.

Preferred embodiments of the invention will become apparent from the dependent claims.

In a method for assembling a body-worn audio device for wirelessly transmitting an audio signal to at least one hearing aid to be worn on or in the ear, an SMD antenna is manufactured by making an electrically insulating housing provided with electrically conductive contact elements. the housing is attached to a rod-shaped ferrite core so that the housing at least partially surrounds the ferrite core, creates a first antenna winding surrounding the ferrite core in the circumferential direction about the longitudinal direction of the ferrite core, and electrically conductively connects via corresponding contacts of the contact elements to the respective contact element is, and a second antenna winding, which surrounds the ferrite core in the longitudinal direction, created and electrically connected via corresponding contacts of the contact elements with the respective contact element; the antenna is then mounted on the circuit board by an SMT method, the contact elements being mounted in electrical contact with corresponding circuit traces of the circuit board on the circuit board to electrically contact the antenna windings with the circuit board. The housing has an asymmetric component in a plan view in a direction perpendicular to the longitudinal direction of the ferrite core to allow the orientation of the housing to be rotated 180 degrees about the direction of view when SMT mounting the circuit board to the antenna. The asymmetrical component may be detachably attached to the housing prior to SMT placement of the circuit board with the antenna. The asymmetric component can be removed from the package after SMT placement of the printed circuit board with the antenna.

In the following, preferred embodiments of the invention will be described by way of example with reference to the accompanying drawings. Showing:

1 a schematic representation of an audio system for use with an electronic assembly according to the invention;

2 a schematic block diagram of the audio system of 1 ;

3 a perspective view of an example of an antenna housing of an assembly according to the invention;

4 a perspective view of the antenna housing of 3 from another direction;

5 a side view of the antenna housing of 3 and 4 with antenna windings mounted thereon and a ferrite core disposed in the antenna housing; and

6 a cross-sectional view along the line AA of 5 ,

In 1 is an example of an audio system shown schematically which two hearing aids 16R and 16L and an audio device to be worn on the body 210 in the form of a transmitting unit. The transmitting unit 210 typically includes a wireless interface (eg, a Bluetooth interface) for receiving audio signals over a wireless link 37 from external audio devices such as a TV set 31 or a mobile phone 33 , Furthermore, the transmitting unit 210 a wired interface for receiving audio signals over a wired connection 39 from an external audio device, such as a music player 35 , exhibit. Furthermore, the transmitting unit 210 adapted to that of the respective audio signal source 31 . 33 respectively. 35 received audio signals over a wireless link 212 , which is typically an inductive link, to the hearing aids 16R . 16L to convey. Such audio equipment 210 are also called streamer.

In 2 is a schematic block diagram for the construction of the hearing aids 16 or the audio device 210 shown. The hearing aid 16 has the typical hearing aid components 252 as well as a unit 232 for communication with the audio device 210 on an inductive route. Accordingly, the audio device 210 also such an inductive communication unit 232 including an inductive antenna 38 , on. Furthermore, the audio device includes 210 a user interface 234 (including control panel and display), a control unit 236 and the corresponding interfaces for the connection to the respective audio signal sources, for example a USB interface 220 , a Euro plug entrance 222 , an audio plug input 224 , a microphone input 226 ; furthermore, the audio device has 228 a Bluetooth interface 230 and an audio signal processing unit 228 on.

In 3 to 6 is an example of an antenna 38 for use in the audio device 210 shown in FIG 3 and 4 two different perspective views of an antenna housing prior to attaching the antenna windings, in 5 a side view of the antenna housing after application of the antenna windings and in 6 a sectional view taken along the line AA of 5 is shown.

The antenna 38 is for mounting on a printed circuit board (not shown) of an electronic assembly (not shown) of the audio device 210 formed by means of an SMT process.

The antenna housing 40 is formed around a rod-shaped ferrite core 42 at least partially surrounded. In the in the 3 to 6 The example shown is the housing 40 in two cap-like parts 44 respectively. 46 divided, each one of the two ends of the ferrite core 42 surrounded and between them a middle area of the ferrite core 42 set free. The cap-like parts 44 . 46 For example, on the ferrite core 42 be glued on. In the area between the two cap-like parts 44 . 46 of the antenna housing 40 is a first antenna winding 48 provided the ferrite core 42 in the circumferential direction, ie around the longitudinal direction of the ferrite core 42 around, surrounds. Further, a second antenna winding 50 provided the ferrite core 42 surrounds in the longitudinal direction. For this purpose, the two housing parts 44 . 46 with a corresponding groove 52 provided for receiving the second antenna winding 50 serves and extends in the longitudinal direction of the ferrite core 42 extends.

In an alternative embodiment of the antenna housing 40 The housing extends over the entire length of the ferrite core 42 , wherein then a central portion of the housing is provided with a circumferentially extending groove, which the first antenna winding 48 receives.

By providing two mutually perpendicular antenna windings 48 . 50 For example, an antenna with two orthogonal directions of polarization is implemented in order to minimize the dependence of the antenna sensitivity on the orientation of the antenna.

The antenna also has four electrically conductive contact elements 54 on, which are firmly connected to the housing and on the one hand an antenna solder contact 56 for contacting the respective antenna winding 48 . 50 and on the other hand, a circuit board solder contact 58 for electrical contacting of the printed circuit board, so that by means of the respective contact element 54 the respective antenna winding 48 . 50 can be contacted with the corresponding trace of the circuit board. It is understood that for each of the two antenna windings 48 . 50 two corresponding contact elements 54 required are. Conveniently, the contact areas 58 each at a corner of the housing 40 arranged and lie in a plane. The contact elements 54 are in the case 40 integrated and are made of metal.

Preferably, the housing 40 formed as a casting, wherein the contact elements 54 are poured into the housing.

In addition to the previously mentioned components, the housing 40 a component 60 on (in 5 not shown), which is in a plan view in a direction perpendicular to the longitudinal direction of the ferrite core 42 is formed asymmetrically to distinguish the orientation of the housing in the assembly of the circuit board 40 with respect to a rotation through 180 ° to allow the direction of the supervision. Preferably, this asymmetric component 60 designed so that it is removable after the assembly of the circuit board with the antenna; for example, the asymmetric component 60 on the case 40 be pluggable. In the example shown, it is the asymmetric component 60 around a plate tangent to the case 40 is formed and the two cap-like parts 44 and 46 connects with each other. Conveniently, the asymmetric component 60 dimensioned so that it can serve as a suction surface for a vacuum pipette during assembly of the circuit board. Due to the asymmetrical shape of the component 60 For example, the optical inspection system of the placement machine can determine if the orientation of the antenna for placement is correct.

The antenna should be made of materials that are temperature resistant to at least 260 ° C to ensure that the antenna survives the soldering step in the SMT assembly process.

Conveniently, a process for the preparation of in 3 to 6 The antenna shown in the following steps: in a first step, the two cap-like housing parts 44 respectively. 46 by means of an adhesive process on the ferrite core 42 attached. In a second step, the first antenna winding is in the area between the two housing parts 44 . 46 on the ferrite core 42 appropriate. In a third step, the two ends of the first antenna winding 48 with corresponding antenna contact 56 electrically contacted, typically by a solder joint. In a fourth step, the second antenna winding 50 in the housing groove 52 applied, and in a fifth step, the two ends of the second antenna winding 50 with the corresponding antenna contacts 56 electrically connected, typically by a solder joint. After all becomes in a sixth step the asymmetric plate 60 on the two housing parts 44 . 46 attached.

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• EP 2453585 A1 [0005]
• US 6924767 B2 [0006]
• US 6134420 [0007]
• US 5966641 [0007]
• WO 2013/133931 A1 [0008]

Claims (20)

Electronic assembly for a body-worn audio device ( 210 ) for wirelessly transmitting an audio signal to at least one hearing device to be worn on or in the ear ( 16 . 16R . 16L ), comprising a printed circuit board and an antenna mounted on the printed circuit board by means of an SMT method ( 38 ) with two orthogonal directions of polarization, wherein the antenna has a rod-shaped ferrite core ( 42 ) with a longitudinal direction, a ferrite core at least. partly surrounding, electrically insulating housing ( 40 . 44 . 46 ), a first antenna winding ( 48 ) surrounding the ferrite core in the circumferential direction about the longitudinal direction of the ferrite core, a second antenna winding (FIG. 50 ), which surrounds the ferrite core in the longitudinal direction, as well as electrically conductive, with the housing connected contact elements ( 54 ), each on the one hand via a contact ( 56 ) is electrically connected to the first antenna winding and the second antenna winding, respectively, and are otherwise mounted in electrical contact with a corresponding trace of the printed circuit board on the printed circuit board to electrically contact the antenna windings with the printed circuit board, the housing being in a direction in one direction perpendicular to the longitudinal direction of the ferrite core asymmetric component ( 60 ) in order to allow for a differentiation of the orientation of the housing with respect to a rotation of 180 degrees around the direction of the supervision in the assembly of the circuit board. An assembly according to claim 1, characterized in that the asymmetric component ( 60 ) is designed to be removable after placement. An assembly according to claim 2, characterized in that the asymmetric component ( 60 ) on the housing ( 40 . 44 . 46 ) can be plugged. Assembly according to one of the preceding claims, characterized in that the asymmetric component ( 60 ) is formed as a plate. An assembly according to claim 4, characterized in that the plate ( 60 ) tangentially to the housing ( 40 . 44 . 46 ) is trained. Assembly according to one of the preceding claims, characterized in that the asymmetric component ( 60 ) is dimensioned to serve as a suction surface for a vacuum pipette during assembly. Assembly according to one of the preceding claims, characterized in that the housing ( 40 . 44 . 46 ) is formed as at least one casting. Assembly according to one of the preceding claims, characterized in that the contact elements ( 54 ) in the housing ( 44 . 46 ) are integrated. An assembly according to claim 8, characterized in that the contact elements ( 54 ) in the housing ( 44 . 46 ) are poured. Assembly according to one of the preceding claims, characterized in that the contact elements ( 54 ) are made of metal. Assembly according to one of the preceding claims, characterized in that each contact element ( 54 ) a contact area ( 58 ) for contacting the printed circuit board, wherein all contact areas lie in one plane. An assembly according to claim 11, characterized in that each of the contact areas ( 58 ) each at a corner point of the housing ( 40 . 44 . 46 ) is arranged. Assembly according to one of the preceding claims, characterized in that the housing ( 40 . 44 . 46 ) with at least one longitudinal groove ( 52 ), which the second antenna winding ( 50 ). Assembly according to one of the preceding claims, characterized in that the housing ( 40 ) into two cap-like parts ( 44 . 46 ), each one of the two ends of the ferrite core ( 42 ) and leave between them a middle region of the ferrite core, wherein the first antenna winding ( 48 ) surrounds this central region of the ferrite core. An assembly according to claim 14, characterized in that the cap-like parts ( 44 . 46 ) on the ferrite core ( 42 ) are glued. Assembly according to one of claims 1 to 13, characterized in that the housing over the entire length of the ferrite core ( 42 ), wherein a central region of the housing is provided with a circumferentially extending groove, which the first antenna winding ( 48 ). Assembly according to one of the preceding claims, characterized in that the antenna ( 38 ) is made of materials that are temperature resistant up to at least 260 ° C. To be worn on the body audio device for wirelessly transmitting an audio signal to at least one on or in the ear to be worn hearing ( 16 . 16R . 16L ), with an assembly ( 232 ) according to one of the preceding claims. System comprising an audio device ( 210 ) according to claim 18 and at least one hearing device to be worn on or in the ear ( 16 . 16R . 16L ). System according to claim 19, characterized in that the system further comprises an audio signal source ( 31 . 33 . 35 ) for wireless transmission of the audio signal to the audio device ( 210 ).

Images