EP3484179A1 - Hearing aid - Google Patents

Abstract

The invention relates to a hearing aid (1, 41, 61) which can be inserted into the ear of a hearing aid wearer, comprising a housing shell (3, 43, 62) for receiving hearing aid components, a faceplate (5, 45) closing the housing shell (3, 43, 62) , 63), and a dipole antenna (13, 47, 65), the dipole antenna (13, 47, 65) having a helical structure with at least one complete turn (17, 51, 71) and one parallel to the faceplate (5, 45 , 63) aligned helix axis (15, 49, 69) is formed.

Description

The invention relates to an insertable into the ear of a hearing aid wearer hearing aid according to the preamble of claim 1. Such a hearing aid is made EP 2 986 030 A1 known.

A hearing aid is used to supply a hearing-impaired person with acoustic ambient signals, which are processed according to a compensation of the respective hearing impairment and in particular amplified. A hearing device for this purpose usually comprises an input transducer, for example in the form of a microphone, a signal processing unit with an amplifier, and an output transducer. The output transducer is usually realized as a miniature speaker and is also referred to as a handset or receiver. In particular, it generates acoustic output signals which are conducted to the patient's hearing and produce the desired auditory perception in the patient.

To meet the numerous individual needs, different types of hearing aids are offered. In the so-called BTE hearing aids (behind-the-ear, also behind-the-ear or BTE) a housing with components such as a battery and the signal processing unit is worn behind the ear. Depending on the configuration, the receiver can either be directly in the auditory canal of the wearer (so-called ex-earphone hearing aids or receiver-in-the-canal (RIC) hearing aids). Alternatively, the receiver is arranged inside the housing itself and a flexible, also referred to as a tube sound tube directs the acoustic output signals of the receiver from the housing to the ear canal (tube hearing aids). In ITE hearing aids (in-the-ear, also IdO or in-the-ear) is a housing, which includes all functional components including contains the microphone and the receiver, at least partially worn in the ear canal. Completely-in-Canal (CIC) hearing aids are similar to ITE hearing aids, but are worn fully in the ear canal.

The wireless communication of a hearing aid, for example, with audio equipment or (in a binaural supply) with a second hearing aid inserted into the other ear of a hearing aid wearer is often carried out by inductive signal transmission. As the antenna for transmitting and receiving the signals in this case (magnetic) coils are used with a plurality of turns whose geometrical dimensions are much smaller than the wavelength of the transmitted or received signals. In inductive signal transmission between hearing aids or a hearing aid and another peripheral device, the frequency of the transmitted or received signals is regularly in the range of about 10 kHz to about 50 MHz. The range of such antennas is limited to the near field range of the transmitted or received signals.

Alternatively, electromagnetic signals in the GHz range are used for signal transmission between hearing aids or a hearing aid and another peripheral device whose wavelengths are approximately of the order of magnitude of a hearing aid. In this case one also speaks of radio frequency (RF) signals or RF (signal) transmission. A commonly used standard for transmitting RF signals is, for example, the Bluetooth standard. The RF signal transmission is routinely carried out over distances which are a multiple of the wavelength of the transmitted or received signals and thus utilizes the far field of these signals. For transmitting and receiving RF signals, dipole antennas are often used.

The length of a dipole antenna is advantageously chosen to be half the wavelength or a small multiple thereof. Due to the extremely tight installation space and due to the shielding of electromagnetic radiation by the surrounding body tissue of a hearing aid wearer, the integration of such an antenna in the housing of a hearing aid worn in the ear is problematic. The transmission and reception efficiency of such hearing aids used antennas is therefore often less than required or desired.

In order to improve the efficiency of the antenna, in the DE 696 37 454 T2 and the US 2010/0020994 A1 proposed to integrate the antenna in a pull-out string or a pull-out stick of a hearing aid, ie in a cord or rod-like object, which queries from the faceplate of the hearing device to the outside, and with inserted hearing aid can be taken with the fingers to pull the hearing aid out of the ear canal. In this case, advantageously, the part of the hearing device which is disposed at the extreme in the worn state is used in order to keep the shielding influence of the body of the hearing device wearer on the antenna as low as possible. However, a retrieval cord or retrieval rod is substantially parallel to the axis of the ear canal.

Seen from the outside, the return cord or the return rod therefore only have a virtually disappearing extent. The emission of such an antenna directed outward from the opening of the ear canal is correspondingly weak. By contrast, such an antenna radiates the predominant portion of the field intensity perpendicular to its longitudinal extension, where this field component is in turn attenuated by the outer region of the auditory canal and the outer ear.

Out DE 10 2008 022 127 A1 Further, a method for reducing body effects on radio frequency antennas in hearing aids is known in which the antenna matching is set to a frequency that differs from the actual operating frequency of the radio system. The DE 10 2008 022 127 A1 discloses in this context a behind the ear to be worn hearing aid, wherein the antenna is mounted on a hearing aid housing.

The invention is therefore based on the object of specifying a way to increase the radiation efficiency of an integrated in a hearing aid antenna in a simple manner.

This object is achieved by the features of claim 1. Advantageous embodiments of the invention are set forth in the dependent claims and the description below.

The hearing aid according to the invention, which is inserted into the ear of a hearing aid wearer, comprises a housing shell for accommodating hearing device components, a faceplate closing the housing shell. The faceplate is formed either flat or slightly curved in the usual way. The position of the faceplate thus defines a (flat or slightly curved) surface - slightly curved means that the radius of curvature of the surface is significantly (in particular at least by a factor of 5 to 10) greater than the extent of the faceplate.

The hearing aid further comprises a dipole antenna, which is formed with a helical structure with at least one complete turn and a helical axis aligned parallel to the faceplate. As a complete turn here a section of the antenna is called, which - seen in projection along the helix axis - forms a full circle (360 °).

In a preferred embodiment of the invention, the or each turn of the dipole antenna penetrates a surface occupied by a faceplate so that at least an inner portion of the dipole antenna is guided on the inside of that face and at least an outer portion of the dipole antenna is on the outside of that face. It is also advantageous in the context of the invention, when the dipole antenna is integrated into the faceplate. In such an embodiment, no portion of the dipole antenna protrudes from the material of the faceplate. A likewise preferred embodiment of the invention provides that the faceplate is arranged in a groove formed in the faceplate.

The use of a dipole antenna designed as described above and arranged on the faceplate enables both wireless communication of hearing aids with one another and with external audio sources. The inventive arrangement of the dipole antenna on the faceplate, the radiation characteristic the dipole antenna improves. The radiation pattern of the dipole antenna has a maximum outside the ear of the respective hearing device wearer, so that radiation losses through the ear are minimized and thereby the efficiency of the dipole antenna is correspondingly improved. In other words, the radiation efficiency of the dipole antenna is increased compared to conventional antennas in the arrangement according to the invention.

In the context of the present invention, a helical structure is understood essentially to be a helical structure with a number of turns. The helical structure has a helical axis oriented parallel to the faceplate. Preferably, the two poles of the dipole antenna are bent in opposite directions. In other words, each pole of the dipole antenna is bent in the opposite direction with respect to the other pole.

The housing shell and this closing faceplate together form the housing of the hearing aid. The faceplate is expediently equipped with standard components such as microphones, battery contacts and the like. Furthermore, the faceplate can be designed with actuating elements, such as rotary knobs or switches, which make it possible to operate the hearing aid (for example by changing a hearing program).

In the context of the invention, a section of the dipole antenna guided on the inside of the area occupied by the faceplate is understood to be the section of the dipole antenna which is arranged within the housing or within the housing shell when the housing is assembled. In other words, the at least one inner section of the dipole antenna, in particular with respect to the housing, is guided on the inside of the area occupied by the faceplate. Analogously, in the context of the invention, under the section of the dipole antenna, which are guided on the outside of the area occupied by the faceplate, those sections are understood which are arranged outside the housing when the housing is assembled, that is to say on the outwardly directed side of the housing. In other words, it is at least one outer one Section of the dipole antenna in particular based on the housing outside of the surface occupied by the faceplate out.

Preferably, the dipole antenna has more than one complete turn and up to two turns. For the number of turns N, it is thus preferable for 1> N≥2, where N can be any real number. Most preferably, the dipole antenna has 1.5 turns.

In a preferred embodiment, the or each outer portion of the dipole antenna projects from the material of the faceplate. As a result, the radiation efficiency or the radiation characteristic of the dipole antenna is further improved.

In an alternative preferred embodiment of the invention, the faceplate on its outer side at least one integrally formed with the faceplate projection in which the or each outer portion of the dipole antenna is embedded. For this purpose, it is preferred if the or each guided on the outside of the faceplate (partial) winding of the dipole antenna is encapsulated.

Conveniently, the dipole antenna is formed as a metallic wire. Within the scope of the invention, the metallic wire can be flexible and thus adaptable to the geometry of the faceplate of the corresponding hearing device. Alternatively preferably, a rigid wire is used as the dipole antenna. The metallic wire forming the dipole antenna is formed in an advantageous embodiment with a round cross section. In an alternative preferred embodiment, the dipole antenna is formed as a metallic ribbon

More preferably, the faceplate is formed integrally with the housing shell. In this case, the faceplate is not a separate component but part of the housing shell. In other words, the faceplate is made in one piece with the housing shell.

The hearing aid itself expediently comprises at least one microphone, a signal processing unit with an amplifier and a receiver, as well as further electronic and functional components. The respective components are preferably arranged within the housing shell and / or are components of the housing. The hearing aid is preferably designed as an ITE hearing aid. Alternatively, preferably, the hearing aid is designed as a CIC hearing aid.

Fig. 1

in dreidimensionaler Darstellung ein Hörgerät mit einer die Faceplate durchdringenden Dipolantenne mit 1,5 Windungen,

Fig. 2

die Dipolantenne gemäß Fig. 1 in separater Darstellung,

Fig. 3

die Strahlungscharakteristik der Dipolantenne gemäß den Fig. 1 und 2.

Fig. 4

in schematischer Darstellung ein Hörgerät mit einer die Faceplate durchdringenden Dipolantenne mit einer vollständigen Windung in einem außermittigen Längsschnitt, sowie

Fig. 5

in schematischer Darstellung ein weiteres Hörgerät mit einer die Faceplate durchdringenden Dipolantenne mit einer vollständigen Windung in einem außermittigen Längsschnitt.

Embodiments of the invention will be explained in more detail with reference to a drawing. Show:

Fig. 1

in a three-dimensional representation a hearing aid with a faceplate penetrating dipole antenna with 1.5 turns,

Fig. 2

the dipole antenna according to Fig. 1 in separate representation,

Fig. 3

the radiation characteristic of the dipole antenna according to Fig. 1 and 2 ,

Fig. 4

a schematic representation of a hearing aid with a faceplate penetrating dipole antenna with a complete turn in an off-center longitudinal section, and

Fig. 5

a schematic representation of another hearing aid with a faceplate penetrating dipole antenna with a complete turn in an off-center longitudinal section.

In Fig. 1 is a usable in the ear of a hearing aid wearer hearing aid 1 with a housing shell 3 and the housing shell 3 closing faceplate 5 is shown. The housing shell 3 and the faceplate 5 together form the housing 7 of the hearing aid 1. In the faceplate 5 is a toggle switch 9 as an actuating element of the interior 11 of the housing 7 arranged electronic components. These are not visible due to the closed representation of the hearing aid 1. This also applies to the others within the housing 7 arranged hearing aid components such as one (or more) microphones, a signal processing unit with an amplifier and a receiver, and other electronic and functional components.

On the faceplate 5 a dipole antenna 13 is disposed of metallic wire. The dipole antenna 13 has a helical structure with a parallel to the faceplate 5 oriented helical axis 15 and in this case 1.5 turns 17 and. The turns 17 of the dipole antenna 13 penetrate an area occupied by a faceplate 5 (this is in the 4 and 5 shown). Accordingly, two outer sections 19 of the dipole antenna 13 are guided on the outside of this surface F and thus outside of the housing 7 or outside the housing shell 3. An inner portion 21 of the dipole antenna 13 is guided inside the surface F and thus disposed within the housing 7 and outside of the housing shell 3 (in the interior 11). For this purpose, 5 corresponding openings 23 are introduced in the faceplate, through which the turns 17 of the dipole antenna 13 are guided. The outer portions 19 of the dipole antenna 13 are exposing and protrude from the material of the faceplate 5.

In Fig. 2 is the dipole antenna 13 according to Fig. 1 shown separately. The dipole antenna 13 has two poles 27, 29 which are bent in the opposite direction with respect to the other pole 27, 29. In the present case, the lower pole 27 is bent in the clockwise direction 31, the upper pole 29 in the counterclockwise direction 33. By such a trained and arranged on the faceplate 5 of a hearing aid 1 dipole antenna 13, the radiation characteristic of the dipole antenna 13 is improved over conventional antennas. The radiation pattern of the dipole antenna 13 has a maximum outside of the ear of the respective hearing aid wearer due to the exposed outer portions 19 of the dipole antenna 13 in the inserted state so that radiation losses through the ear are minimized and the efficiency of the dipole antenna is correspondingly improved.

The radiation characteristic or the radiation pattern of the dipole antennas 13 used in the hearing aid 1 is shown in FIG Fig. 3 shown by the spatial directions 35 (x-direction), 37 (y-direction), 39 (z-direction). The maximum of the radiation extends in the present case in the y direction 37, which extends away from the ear or the head of the hearing device wearer in the case of an inserted hearing device 1.

In Fig. 4 is a roughly schematic eccentric longitudinal section shown by another usable in the ear of a hearing aid wearer hearing aid 41. The hearing device 41 comprises a housing shell 43 and a housing shell 43 closing faceplate 45, which together form the housing 46 of the hearing aid 41. On the faceplate 45, a dipole antenna 47 made of metallic wire is also arranged here. The dipole antenna 47 has a helical structure with a helical axis 49 oriented parallel to the faceplate 45 and, in the present case, a turn 51. The winding 51 penetrates a surface F occupied by a faceplate 45. The inner portion 53 of the dipole antenna 47 is guided inside the surface F relative to the housing 46, while the outer portion 55 of the dipole antenna 47 is guided outside the surface F relative to the housing 46 is. The section 53 of the dipole antenna 47 according to Fig. 4 is exposed and stands out from the material of the faceplate 5.

Fig. 5 shows a further usable in the ear of a hearing aid wearer hearing aid 61 in a roughly schematic eccentric longitudinal section. The hearing device 61 likewise comprises a housing shell 62 and a faceplate 63 which closes the housing shell 62. The housing shell 62 and the faceplate 63 form the housing 64 of the hearing aid 61 Fig. 4 is disposed on the faceplate 63 of the hearing aid 61, a dipole antenna 65 of metallic wire. The dipole antenna 65 has a helical structure with a helical axis 69 oriented parallel to the faceplate 63 and likewise a turn 71 which penetrates an area F occupied by a faceplate 63. Again, the inner portion 73 of the dipole antenna 65 is guided with respect to the housing 64 inside the surface F. The outer portion 75 is guided relative to the housing 64 on the outside of the surface F.

In contrast to the hearing aid 41 according to Fig. 4 is the faceplate 63 on its outer side 76 in the present case formed with an integrally molded projection 77, with which the outer portion 73 is encapsulated. Section 75 of the dipole antenna 63 is thus not exposed, but embedded in the projection 77.

The invention will be particularly apparent in the embodiments described above, is nevertheless not limited to these embodiments. Rather, other embodiments of the invention may be derived from the claims and the foregoing description.

LIST OF REFERENCE NUMBERS

1

hearing Aid

3

shell

5

faceplate

7

casing

9

counter

11

inner space

13

dipole antenna

15

helix axis

17

convolution

19

inner section

21

outer section

23

opening

27

Pole of the dipole antenna

29

Pole of the dipole antenna

31

Direction clockwise

33

clockwise opposite direction

35

x-direction

37

y-direction

39

z-direction

41

hearing Aid

43

shell

45

faceplate

46

casing

47

dipole antenna

49

helix axis

51

convolution

53

inner section

55

outer section

61

hearing Aid

62

shell

63

faceplate

64

casing

65

dipole antenna

69

helix axis

71

convolution

73

inner section

75

outer section

76

outside

77

head Start

Claims (7)

In the ear of a hearing aid wearer deployable hearing aid (1, 41, 61), comprising a housing shell (3, 43, 62) for receiving hearing aid components, a housing shell (3, 43, 62) closing faceplate (5, 45, 63), and a dipole antenna (13, 47, 65),
characterized in that the dipole antenna (13, 47, 65) having a helical structure with at least one complete turn (17, 51, 71) and a parallel to the faceplate (5, 45, 63) oriented helix axis (15, 49, 69) is trained. Hearing aid (1, 41, 61) according to claim 1, wherein the two poles (27, 29) of the dipole antenna (13, 47, 65) are bent in the opposite direction. Hearing aid (1, 41, 61) according to claim 1 or 2, wherein the dipole antenna (13, 47, 65) has more than one complete turn (17, 51, 71) and up to two turns (17, 51, 71). Hearing aid (1, 41, 61) according to one of the preceding claims, wherein the or each outer portion (19, 55, 75) of the dipole antenna (13, 47, 65) protrudes from the material of the faceplate (5, 45, 63) , Hearing aid (1, 41, 61) according to claim 1 or 2, wherein the faceplate (5, 45, 63) has on its outer side (76) at least one projection (77) formed integrally with the faceplate (5, 45, 63). in which the or each outer portion (19, 55, 75) of the dipole antenna (13, 47, 65) is embedded. Hearing aid (1, 41, 61) according to one of the preceding claims, wherein the dipole antenna (13, 47, 65) is formed as a metallic wire. Hearing aid (1, 41, 61) according to one of the preceding claims, wherein the faceplate (5, 45, 63) is formed integrally with the housing shell (3, 43, 62).

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