EP1874090A1 - Auxiliary hearing aid - Google Patents

Abstract

The hearing aid (1) has a section (100) arranged in or at human ear, and a multi-channel tube (200) protrudes from the section. The tube is inserted with its free end section (230) into an acoustic meatus (300) of the ear. An earpiece channel (212) of the tube at an earpiece and an acoustic meatus microphone channel (214) of the tube at an acoustic meatus microphone (114) are respectively connected within the hearing aid in an acoustic manner. The earpiece and microphone form an electromagnetic shielded acoustic module (110).

Description

The invention relates to a hearing aid, in particular a hearing aid such. As an in-the-ear hearing aid (IdO) or a behind-the-ear hearing aid (BTE).

In order to meet the aesthetic needs of a wearer of a hearing aid, they should be as little visible as possible on a wearer from the outside. A therefore required miniaturization of the hearing aid devices on the one hand, and their versatile range of functions and high-quality processing necessary for improving the hearing signals within the hearing aid devices on the other hand, represent conflicting requirements. Especially in the case of the IdOs these requirements are particularly high.

In the case of hearing aid devices, a closure effect perceived as unpleasant by the wearer - the so-called occlusion - can occur, since here often the space for a pressure equalization bore - the so-called venting - can not be dimensioned sufficiently large. Because of this closure, the hearing aid wearer's own voice sounds louder and louder. The occlusion effect occurs z. B. by the inserted into the ear IdO or by earmold of a BTE.

The diameter of a Venting to 1mm serve almost exclusively the pressure equalization when inserting an IdOs in the ear or a portion of the hearing aid to be inserted into the ear. Furthermore, such small ventings are used to equalize the pressure with temporally short pressure fluctuations in the environment, as z. B. in an airplane, door closing, in the elevator or swallowing can occur. Venting diameters up to 3mm have a major impact on low frequency response, but also reduce the occlusion effect in the ear canal when the hearing aid is in the ear or on the pinna is placed and this at least partially clogged the external auditory canal.

All holes and channels in a hearing aid are acoustically regarded as "long tubes" and have a low-pass character. Larger diameter holes have larger cutoff frequencies and less damping. It can be z. B. a necessary baffle function between a handset (loudspeaker) of the hearing aid or a radiating sound tube, and an ambient microphone in the vicinity of the ear, are no longer met from a certain acoustic amplification, resulting in an acoustic feedback, a "whistle" comes , This acoustic feedback is also related to a size of the venting.

To counteract the occlusion, the acoustic feedback and other acoustic problems in a hearing aid, methods and devices are known, which record the acoustic conditions in the external auditory canal and provide a signal processing within the hearing aid to provide the known problems by means of an ear canal microphone minimize. Such methods that require an ear canal microphone to operate a hearing aid, z. B. from the DE 698 26 331 T2 and the EP 1 251 714 A2 known.

A hearing aid to be produced efficiently, in particular an IDO with a hearing aid microphone, must be built as space-saving as possible, so that the number of people that can be supplied at all is as large as possible because their auricle and ear canal shape and size can deviate greatly from one another. So z. For example, the volume of the ear canal in an average man is about ² cm ³ , while this volume is reduced by half on average in a woman. Furthermore, the size of a hearing aid depends on the size of the components to be accommodated therein (on the basis of the degree of hearing loss to be treated and a functional scope of the hearing aid), thus also of the auditory canal microphone, as well as the way in which the auditory canal microphone is acoustically connected to the external auditory canal.

The DE 39 08 673 A1 discloses a hearing aid, in particular a plug-in hearing aid, which reduces the risk of leading to "whistling" acoustic feedback. The plug-in hearing aid has a microphone for receiving ambient sound and a microphone for receiving sound from the ear canal, the two signals of which are further processed by a signal processor and made available to a listener. Here, the ear canal microphone sits on the side of a ventilation duct of the plug-in hearing aid. This lateral, ie provided in a side wall of the ventilation duct, ear canal microphone forms part of the wall of the ventilation channel and does not protrude into this, so that the ventilation channel is not reduced in its cross section and therefore caused by the hearing aid occlusion is not increased.

The position of the ear canal microphone in a wall of the ventilation channel is unfavorable, since this can not adequately reproduce the sound wave spectrum of the auditory canal. In general, it is better if the ear canal microphone is coupled as directly as possible to the ear canal. Another problem is that an opening in the wall for the auditory canal microphone is not accessible and therefore poorly protected against cerumen, and thus difficult to clean.

The AT E 76 549 B discloses a system and method for compensating for hearing damage by means of an IdO, in whose plastic housing a hearing aid microphone, a woofer and a tweeter are housed. The respective sound tube for the hearing aid microphone, the woofer and the tweeter loudspeaker are formed separately in the housing of the IdOs.

By comparatively thick, can be used in the ear canal and this completely occlusive free end portion of the IdOs, it is not possible to couple the hearing aid microphone, the woofer and tweeter directly to the sound conditions in the ear canal.

It is therefore an object of the invention to provide an improved hearing aid device. In particular, a hearing aid microphone should be coupled as directly as possible to the sound conditions in an auditory canal, so as to achieve a better signal processing within the hearing aid, wherein the ear canal should be concentrated as little as possible.

The object of the invention is achieved by a hearing aid having a predictable in or on an ear portion from which protrudes a multi-chamber or a multi-channel tube, which is inserted or insertable with its free end in an external ear canal of the ear, wherein a first feedthrough (first channel, earphone channel) of the multichannel tube is acoustically connected to a receiver within the hearing aid and transports sound from the listener into the ear canal during operation of the hearing aid, and a second feedthrough (second channel, ear canal microphone channel) of the multichannel tube with an ear canal microphone within the ear canal Hearing aid is acoustically connected and transported during operation of the hearing aid sound from the ear canal to the ear canal microphone.

According to the invention, the multi-channel tube is at least a two-channel tube, which transports sound from the listener in parallel into the auditory canal and sound of the auditory canal to the auditory canal microphone. According to the invention, the multi-channel tube can also have a third channel, preferably a so-called venting channel, which leads to a venting of the hearing aid. Furthermore, of course, a multi-channel tube is possible, which has more than three channels or more than three bushings. In general, the channels of the multi-channel tube take over any acoustic tasks. So it is z. B. possible that two channels of sound from the listener in the ear canal and / or two channels conduct sound from the ear canal to one or two ear canal microphones. Of course, a Ventingkanal can be provided here.

The multi-channel tube preferably consists of an outer wall and an inner dividing wall, which separates the hollow volumes (preferably two or three) extending along the multi-chamber tube from one another. Here, the cross-sectional areas of the channels or the hollow volumes of the channels may be different in size and / or shape, wherein preferably a cross-sectional area of the channel for the ear canal microphone is less than or equal to a cross-sectional area for the channel of the listener. If a venting channel is provided in the multi-chamber tube, its cross-sectional area is preferably smaller or equal to that of the canal for the auditory canal microphone.

A choice of material for the multi-channel tube and a dimensioning of the multi-channel tube with respect to its cross-sections and its sound transport lengths (ie channel volumes) must ensure that the acoustic crosstalk between the channels as low as possible, but at least low enough, so that there are no disadvantages for the acoustic qualities of the hearing aid. It is also possible, for. B. due to a small thickness of the inner partition wall of the multi-channel tube to allow a certain crosstalk, which in the worst case may only be so large that it is due to the available data of the ear canal microphone and the capacity of a signal processing to an acceptable level traceable.

Through the multi-channel tube according to the invention, it is now possible to couple a hearing aid microphone directly to an external auditory canal of the human ear and thus to obtain a good information base for a further processing of the sound waves picked up by the auditory canal microphone.

The tubes used in hearing aids have an inner diameter of usually about 1.4mm and an outer diameter of usually about 2.4mm. Compared to using two tubes - one for the auditory canal microphone and one for the listener - saves space by a two-channel tube by at least one wall diameter, which - with the same cross-sectional area of the channels - depends on a diameter of the inner partition wall of the two-channel tube. Assuming that the outer dimensions of the two-channel tube are reduced by an outer wall thickness, the above dimensions result in a reduction of the clear width of more than 10%, which corresponds to a reduction of a cross-sectional area of about 20%. As a result, it is possible according to the invention to provide space in the external auditory canal or on the hearing aid device itself for ventilation (for example via a vent) for occlusion reduction. This is especially important for an IDO because it has the biggest problems with occlusion.

Furthermore, the use of the multi-channel tube makes direct access to the auditory canal microphone within the hearing aid device possible in the first place.

In addition, a wax guard can be attached to a free end of the multi-channel tube for opening the auditory canal microphone channel, which can also be made interchangeable if required. This also applies to the receiver channel of the multi-channel tube.

In a preferred embodiment of the invention, within the hearing aid device, the earpiece and the auditory canal microphone form a preferably glued-together acoustic unit to which the multichannel tube according to the invention can be connected. In this case, the openings of the acoustic module for the auditory canal microphone channel and the receiver channel are preferably located either on one side or on two different sides of the acoustic unit, which in the latter case are preferably arranged at a substantially 90 ° angle.

In an ITE hearing aid device, the multi-channel tube is preferably arranged in / on the ITO that in the ear inserted into an ear state of IdOs, the smallest channel is located as far as possible from a wall of the external auditory canal, so this channel is not so fast can be added by cerumen, which would result in a cleaning of the multi-channel tube. It may depend on the type of hearing aid, the outer ear of the wearer of the hearing aid and the external auditory canal, if it is necessary to rotate the two longitudinal ends of the multi-channel tube relative to each other, so that on the one hand the correct position of the hearing aid in the ear and on the other hand the right Position of the multi-channel tube in the external auditory canal is ensured.

Further embodiments of the invention will become apparent from the remaining dependent claims.

Fig. 1

in einer schematischen Darstellung eine erste Ausführungsform eines erfindungsgemäßen Hörhilfsgeräts mit Mehrkanalschlauch, der in einen äußeren Gehörgang eines menschlichen Ohrs hineinragt;

Fig. 2

eine zweite Ausführungsform des erfindungsgemäßen Hörhilfsgeräts gemäß einer in Fig. 1 gezeigten Lage;

Fig. 3

eine dritte Ausführungsform des erfindungsgemäßen Hörhilfsgeräts gemäß einer in Fig. 1 gezeigten Lage;

Fig. 4

drei Querschnittsdarstellungen (Fig. 4a-4c) eines als Zweikanalschlauch ausgebildeten erfindungsgemäßen Mehrkanalschlauchs; und

Fig. 5

drei Querschnittsdarstellungen (Fig. 5a-5c) eines als Dreikanalschlauch ausgebildeten erfindungsgemäßen Mehrkanalschlauchs.

The invention will be explained in more detail below with reference to embodiments with reference to the accompanying drawings. In the drawing show:

Fig. 1

in a schematic representation of a first embodiment of a hearing aid according to the invention with multi-channel tube, which projects into an external auditory canal of a human ear;

Fig. 2

a second embodiment of the hearing aid according to the invention according to a position shown in Figure 1;

Fig. 3

a third embodiment of the hearing aid according to the invention according to a position shown in Figure 1;

Fig. 4

three cross-sectional views (Figures 4a-4c) of a multi-channel tube according to the invention designed as a two-channel tube; and

Fig. 5

three cross-sectional representations (FIGS. 5a-5c) of a multi-channel tube designed as a three-channel tube according to the invention.

The following statements relate to an in-the-ear hearing aid (IdO), wherein the IdO is at least partially inserted into an external auditory canal of a human ear and protrudes in the inserted state of the IdOs a multi-channel tube according to the invention in the outer auditory canal with its free end. However, the invention should not be limited to IdOs, but all hearing aids, z. B. a behind-the-ear hearing aid (BTE) or its earmold, a headset, a (miniature) phone o. Ä. Hearing aids include.

1 shows a first embodiment of a hearing aid device 1 according to the invention, wherein an outer side 130 or a wall 130 of the hearing aid device 1 is partially arranged in or on an outer auditory canal 300 of a human ear. In this case, a section of the outer side 130 of the hearing aid device 1 preferably rests against an auditory canal wall 310.

Towards the rear into the external auditory canal 300, a multi-channel tube 200 protrudes out of the hearing aid 1 and at least partially extends into the outer auditory canal 300 with its free end section 230. In this case, the multi-channel tube 200 is received with a bound portion 240 in the hearing aid 1 and acoustically coupled or connected within the hearing aid 1 to an acoustic module 110.

The acoustic module 110 has a receiver 112 or a loudspeaker 112 and an auditory canal microphone 114. Here, earphone 112 and earphone microphone 114 are fixed together on two sides to a support structure, preferably glued. Damping materials may be provided between the support structure and ear canal microphone 114 and / or between the support structure and the earphone 112. It is at this point explicitly on the EP 1 377 119 A2 referenced, which teaches such an acoustic module. The disclosure of this document should be included here expressly. It should be noted, however, that one or both are in the EP 1 377 119 A2 learned Microphones (ambient microphones) here the auditory canal microphone 114 should correspond.

However, it is also possible not to connect the multi-channel tube 200 according to the invention to a single acoustic module 110, but separately to a receiver 112 and a hearing aid microphone 114, wherein earphone 112 and earphone microphone 114 may be provided at different positions within the hearing aid 1 (not in the drawing) shown). In this case, it is not necessary to design the two channels 212, 214 of the multi-channel tube 200 to have the same length. It is quite possible that one of the two channels 212, 214 has a longer bound longitudinal end portion 240, wherein the multi-channel tube 200 is preferably cut in its intermediate wall 222. This is also possible for the free end portion 230.

In the embodiment illustrated in FIG. 1, the multi-channel tube 200 is designed as a two-channel tube 200 which has a receiver channel 212 and a hearing aid microphone channel 214. In this case, the handset channel 212 is acoustically connected to the handset 112 or loudspeaker 112 and the auditory canal microphone channel 214 to the auditory canal microphone 114. In the hearing aid 1 inserted in the ear, the multi-channel tube 200 preferably protrudes into the external auditory canal 300 so far that it bridges a constriction in the external auditory canal 300.

In the exemplary embodiment illustrated in FIG. 1, the two channels 212, 214 of the multi-channel tube 200 have the same length and open on one side into the acoustic module 110 and are connected there to the earphone 112 or the auditory canal microphone 114, the earphone channel 212 sound waves from the earpiece 112 into the external auditory canal 300 and the auditory canal microphone channel 214 conducts sound waves from the external auditory canal 300 to the auditory canal microphone 114.

Furthermore, the hearing aid 1 preferably has a vent 126 or a ventilation bore 126 in its wall 130. This vent 126 is freely acoustically connected to an outside of the hearing aid 1 (i.e., outside the ear) to provide pressure equalization upon insertion of the hearing aid 1 into the ear. Preferably, this venting channel 216 can also serve to reduce the occlusion caused by the inserted hearing aid 1. This depends on a diameter of the vent 126 or a diameter available for the vent 126.

FIG. 2 shows a second embodiment of the hearing aid device 1 according to the invention, wherein the two acoustic connections of the acoustic module 110 are not accessible from the same side as shown in FIG. 1. These are in the illustrated embodiment, on two sides of the acoustic module 110. In the illustrated embodiment, these two sides are arranged at a 90 ° angle to each other.

The bound end portion 240 of the multi-channel tube 200 shown in Fig. 2 is partially separated, so that the comparatively longer auditory canal microphone channel 214 branches off from the earphone channel 212 and so can contact the acoustic module 110 acoustically on another side. Of course, this can also be reversed.

Furthermore, in contrast to FIG. 1, which represents channels 212, 214 of equal size in terms of length and cross-section, FIG. 2 shows a smaller auditory canal microphone channel 214 of the multi-channel tube 200 than the ear canal 212. More generally, it is preferred to use the ear canal 212 larger in cross-section than the auditory canal microphone channel 214, since the ear canal 212 has to transmit a certain sound energy, while it is sufficient in the auditory canal microphone channel 214 substantially to transmit information. Furthermore, of course, again an embodiment is possible in which the earphone 112 and earphone microphone 114 are not combined to form an acoustic module 110.

FIG. 3 shows a multi-channel tube 200 embodied as a three-channel tube 200, wherein a venting channel 216 is provided in addition to the receiver channel 212 and the auditory canal microphone channel 214. As a result, a position of the venting 126, as shown in FIGS. 1 and 2, omitted. However, this does not have to be the case. The Venting 126 shown in FIGS. 2 and 3 may nevertheless be provided, which is particularly advantageous for pressure equalization when inserting the hearing aid 1 into the ear.

The venting channel 216 of the multi-channel tube 200 preferably leads to a vent 127 of the hearing aid device 1, which is preferably arranged outside or at the ear in the inserted state of the hearing aid device 1. Here, the Ventingkanal 216 or a continuation of the Ventingkanals 216 is passed to the acoustic module 110, if it is present; otherwise the venting channel 216 preferably passes by the earphone 112 and / or the ear canal microphone 114. This can be done either by virtue of the fact that the venting channel 216 is designed to be longer than the remainder of the multi-channel tube 200, or the venting channel 216 is connected within the hearing aid device 1 to a channel present there, which leads to the venting 127, or else only freely in the hearing aid device 1 ends.

In one embodiment according to FIG. 3, the receiver channel 212 is preferably the largest in its cross section, wherein it is again preferred that the cross section of the auditory canal microphone channel 214 is larger than the cross section of the venting channel 216.

In all embodiments of the invention, it is not necessary to combine earphone 112 and earphone microphone 114 in an acoustic module 110, but to provide them separately in the hearing aid 1. This may result that z. B. all channels 212, 214, (216, if any) of the multi-channel tube 200 have a different length. This is then again around the partition 222 between the channels 212, 214, 216 preferably centrally separated.

In all embodiments of the invention, it is preferred that the smallest channel (212, 214,) 216 of the multi-channel tube 200 or the smallest channels (212,) 214, 216 of the multi-channel tube 200 are provided in such a way in / on the ear canal 300 when the hearing aid 1 is inserted in that, if possible, these do not rest against the inner wall of the ear canal 310. This serves to protect against cerumen, which for the smaller channels (212,) 214, 216 represents a potentially greater risk of clogging than for the larger channels 212, (214, 216).

In order to find an optimal position of the multi-channel tube 200 in the external auditory canal 300 when the hearing aid 1 is inserted, it may be necessary for the free end or the free end section 230 of the multi-channel tube 200 to be opposite the bound end or its bound end section 240 or relative to the hearing aid device 1 to rotate (not shown in the drawing).

FIGS. 4 a, 4 b and 4 c now show embodiments of the multi-channel tube 200 designed as a two-channel tube 200. In this case, FIGS. 4 a and 4 c show a multi-channel tube 200 shown in longitudinal section in FIG. 1, and FIG. 4B shows a multi-channel tube 200 in FIG FIGS. 4a and 4c show a multi-channel tube 200 with two chambers 21, 214 of equal size, which are divided by the intermediate wall 222 or a membrane 222 into channels 212, 214 of equal cross-section. In particular, FIG. 4 c shows a preferred embodiment of the invention, wherein the transitions between an inner side of an outer wall 224 and the intermediate wall 222 are rounded off. 4b shows a multi-channel tube 200 having a larger ear canal 212 from the cross-section and a smaller auditory canal micro-channel 214 from the cross-section.

5a, 5b and 5c show embodiments of the multi-channel tube 200 designed as a three-channel tube 200. FIG. 5a shows a three-channel tube 200 having channels 212, 214, 216 which have the same cross-section and which are separated from one another by intermediate walls 222. FIG. 5b shows a receiver channel 212, which has the same cross section as an auditory canal microphone channel 214, wherein between these two channels the smaller venting channel 216 is formed. 5 c again shows three different-sized channels 212, 214, 216, wherein the cross-sectional area of the receiver channel 212 is greater than that of the auditory canal microphone channel 214, whose cross-sectional area is in turn greater than that of the venting channel 216. In addition, FIG. 5 c shows an inner side of the outer wall 224 of the three-channel tube 200 which is rounded off with the respective intermediate wall 222 and also has rounded transitions between the intermediate walls 222.

A meeting point P of partitions 222 in a three-channel tube 200 may be arbitrarily selected within the cross-section of the three-channel tube 200. It is possible to arrange this in the center (see Fig. 5a), wherein the channels 212, 214, 216 cover a more or less large (circular) sector of the cross-sectional area of the three-channel tube 200. However, this meeting point P can also lie off-center (see Figures 5b and 5c), wherein the intermediate walls 222 can meet one another vertically (see Fig. 5c) or not vertically (see Fig. 5b).

However, the meeting point P can also migrate to the outer wall 224 of the three-channel tube 200, so that a three-channel tube 200 is formed, the two intermediate walls 222 (not shown in the drawing) no meeting point P inside the cross-section of the three-channel tube 200 more. Here, the cross sections of the channels 212, 214, 216 are substantially triangular. Shares this point on the outer wall 224 so create two partitions 222 in the three-channel tube 200, which are arranged more or less parallel to each other.

Preferably, the multi-channel tube 200 is substantially circular in cross-section. However, depending on the shape of the external auditory canal 300 or a constriction of the auditory canal 300, it may be advantageous to use a multi-channel tube 200 which is elliptical in cross-section.

Claims (16)

Hearing aid, with a foreseeable in or on an ear portion (100) from which a multi-channel tube (200) protrudes, which is insertable with its free end portion (230) in an outer ear canal (300) of the ear,
a listener channel (212) of the multichannel tube (200) to a listener (112), and a auditory canal microphone channel (214) of the multichannel tube (200) to an ear canal microphone (114) are acoustically connected within the hearing aid (1). Hearing aid according to claim 1, wherein the channels (212, 214, (216)) of the multi-channel tube (200) cover a sector of a cross-sectional area of the three-channel tube 200. Hearing aid according to claim 1 or 2, wherein in the operation of the hearing aid (1) sound from the handset (112) through the handset channel (212) through the ear canal (300) and
Sound from the ear canal (300) through the auditory canal microphone channel (214) through the ear canal microphone (114) is transportable. Hearing aid according to one of claims 1 to 2, wherein earphone (112) and earphone microphone (114) of the hearing aid (1) form a preferably electromagnetically shielded acoustic unit (110). Hearing aid according to one of claims 1 to 4, wherein an opening in the receiver (112) for the acoustic coupling of the receiver channel (212), and
an opening in the ear canal microphone (114) for acoustically coupling the ear canal microphonic channel (214) to each other such that
the bonded end portions (240) of the channels (212, 214) of the multi-channel tube (200) are substantially the same length. The hearing aid according to claim 5, wherein the earpiece (112) and the ear canal microphone (114) are arranged to each other such that the opening for the auditory canal microphone channel (214) and the opening for the ear canal (212) are arranged on a single side. Hearing aid according to one of claims 1 to 4, wherein the opening in the receiver (112) for the acoustic coupling of the receiver channel (212), and
the opening in the ear canal microphone (114) for the acoustic coupling of the auditory canal microphone channel (214), are positioned to each other, that
the bonded end portions (240) of the channels (212, 214) of the multi-channel tube (200) have different lengths. Hearing aid according to claim 7, wherein the earpiece (112) and the auditory canal microphone (114) are arranged relative to each other such that the opening for the auditory canal microphone channel (214) and the opening for the ear canal (212) on two sides, preferably a 90 ° Occupy angles to each other, are arranged. Hearing aid according to one of claims 1 to 8, wherein a cross-sectional area of the ear canal microphonic channel (214) is less than or equal to a cross-sectional area of the earphone channel (212). Hearing aid according to one of claims 1 to 9, wherein the multi-channel tube (200) has a Ventingkanal (216), which preferably leads to a Venting (216) of the hearing aid (1). The hearing aid according to claim 10, wherein a cross-sectional area of the venting channel (216) is less than or equal to a cross-sectional area of the ear canal microphonic channel (214). Hearing aid according to one of claims 1 to 11, wherein the smallest of the cross-sectional area channel (214; 216) or the smallest of the cross-sectional area ago channels (214, 216) are arranged in the multi-channel tube (200) that he or she at placed in the ear hearing aid (1) away from an ear canal wall (310) are arranged to ensure protection against cerumen. Hearing aid according to one of claims 1 to 12, wherein the channels (212, 214, 216) of the multi-channel tube (200) by an intermediate wall (220) are substantially acoustically isolated from each other. Hearing aid according to one of claims 1 to 13, wherein the walls (220; 222, 224) of the multi-channel tube (200) on an inner side of the multi-channel tube (200) have rounded transitions. The hearing aid according to any one of claims 1 to 14, wherein the acoustic unit (110) comprises a feedback suppression signal processing unit electrically connected to the earphone (112) and the ear canal microphone (114). IdO hearing aid, which is designed according to one of claims 1 to 15.

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