DE102009033317A1 - Receiver for completely-in-canal hearing aid used for hearing impaired persons, has plastic filling filled in hollow space formed between receiver-housing inner side and generator outer side and strongly damping acoustic waves than air - Google Patents

Abstract

The receiver (1) has a sound wave generator (2) i.e. inductive loudspeaker, arranged in a receiver-housing (3) at a sound emission opening (4). A hollow space is formed between an inner side of the receiver-housing and an outer side of the generator. The hollow space is filled with an acoustic, damping plastic filling (7) e.g. polyurethane filling, in gel form, where the plastic filling strongly damps acoustic waves than air. A barometric compensation opening (8) of the generator is covered by a membrane, which is impermeable for the plastic material.

Description

The The invention relates to a hearing aid with a vibration-damped Handset (receiver) and a vibration-damped Handset for a hearing aid.

hearing aids serve to hearing loss in the hard of hearing compensate. There are so-called behind-the-ear devices known from an earmold worn in the ear, as well as from behind the earmold Ear-worn case exist, which necessary for the realization of a hearing aid function contains electrical components. Next are in-ear devices known, which consist only of a part carried in the ear, which contains the electrical components. Further, not mentioned Designs are also known.

The electrical components of a hearing aid comprise one or more microphones, a signal processing device and one usually as Receiver designated listener or speakers. The signal processing device processes by the microphones recorded ambient signals accordingly a hearing program, which is suitable to compensate for the respective hearing losses. The processed and reinforced Signals are converted into acoustic output signals by the receiver implemented, which are fed to the ear of the hard of hearing.

A common one Problem with hearing aids is that the output signals of the receiver within or outside of the housing get to the one or more microphones and can couple there. Thereby creates an acoustic feedback, which are in one for the hearing aid wearer very much unpleasant loud whistle sounds. moreover can feedback also by structure-borne sound transmission occur where the acoustic output signals of the receiver and vibration of the receiver itself transmitted via the housing of the hearing aid to the microphone (s) become. It is known to avoid feedback (feedback) through Borne sound transmission to store the microphones or the receiver muffled. Although by doing so Improvement is achieved, the feedback inclination can nevertheless not completely repressed become.

The The object of the invention is to provide a receiver and a hearing aid Specify receivers in which, in an inexpensive and cost-effective manner the feedback slope is reduced.

The Invention solves this task with a receiver with the features of the claim 1 and by a hearing aid with the features of the further independent claim.

One The basic idea of the invention comprises a receiver for a hearing aid comprising a receiver housing and one in the receiver housing arranged sound wave generator, wherein between inside of the receiver housing and outside the sound wave generator is a cavity, and wherein the cavity filled with a plastic is, the acoustic waves stronger dampens as Air.

One Another basic idea of the invention comprises a hearing aid comprising a housing and one in the housing arranged receiver, being between the inside of the housing and the outside the receiver is a cavity, and being in the cavity a plastic that dampens acoustic waves more than air.

Thereby, that the plastic dampens acoustic waves more than air can will the transmission from sound waves from the receiver to the microphone (s) and thus reduces the feedback slope. In addition, a plastic filling a uncomplicated and is easy to implement constructive action. Depending on the strength and flexibility of the plastic can Cavity or specially to be provided damping components variously Design filled and so their acoustic damping be improved. Last but not least, plastics are available for this purpose are relatively inexpensive. Such plastics are z. B. under the protected name Technogel distributed by Technogel GmbH. Similar plastics are included available from other manufacturers, z. At the Gelmec company. The available cushioning plastics are based often on polyurethanes in various forms.

Not Last is not only by such a damping plastic a transmission of Sound waves over the air is reduced, but in addition also becomes acoustic energy from sound waves in the form of room sound in the air as well as structure-borne noise through the damping destroyed or converted the plastic. This is a reduction the feedback inclination also given with respect to the structure-borne sound transmission.

A advantageous development of the basic idea is that the plastic is liquid.

One liquid Damping plastic offers the advantage that any shaped cavities in the receiver or hearing aid without further adjustments of the plastic are easily filled can.

Another advantageous development be is that the plastic is a gel.

One gel-like plastic consists of a solid plastic matrix, in the liquid or at least flowable plastic parts are involved. This results in a relatively soft, flexible, yielding and easily deformable structure. A gel is therefore easy to work with and can be easily adapted to different cavity shapes. In addition, a gel has excellent damping properties. in the Compared to a liquid Plastic is particularly advantageous that no liquid-tight Cavity is required.

A Another advantageous development is that the sound wave generator in the receiver housing is stored at only one point, in particular at the sound outlet opening.

Around the transfer of structure-borne noise To avoid or reduce, the sound wave generator in the receiver housing as possible stored a few places. in principle However, storage is essential In particular in the area of the sound outlet is a soundproof Connection of sound wave generator and receiver housing obvious and usual. It therefore reduces the tendency for transmission of structure-borne sound when stored at the sound outlet provided as the only storage of the sound wave generator in the receiver housing becomes.

A Another advantageous development is that the sound wave generator a barometric compensation opening has, and that the compensation opening is covered by a membrane, the for the plastic impermeable is.

The barometric compensation opening is for the Function and efficiency of the sound wave generator extraordinary important so that neither should be waived nor one Deterioration of their function due to obstruction or clogging with damping plastic should occur. This can be avoided by the compensation opening through a membrane is covered, which is impermeable to the plastic, however permeable to air and for transmission of air pressure changes sufficiently permeable and flexible.

Further advantageous embodiments are the subject of the dependent claims and in the following with reference to figures explained. Show it:

1 Receiver with damping plastic filling, and

2 Hearing aid with muted receiver.

In 1 is a receiver 1 schematically shown with acoustically damping plastic filling. Centerpiece of the receiver 1 is a sound wave generator 2 , z. B. an inductively operating speaker. The receiver 1 has a receiver housing 3 on, in which the speaker and possibly other components not shown are used. The receiver housing 3 can be made of plastic or metal. With a receiver 1 , which is intended for installation in a hearing aid, the housing has suitable installation dimensions and possibly angular contours or attachment points, which are also not shown. With a receiver 1 For use in a receiver-in-canal hearing aid, the receiver 1 or the receiver housing 3 a form that is either suitable for mounting in a Eartipp or use directly in the ear canal, so for example, sharp edges and angles avoids. In each of the applications described the structure is chosen as small as possible in order to promote the reduction of hearing aids or obstruct the ear canal of the hearing aid wearer as low as possible ear canal cross-sectional area.

The sound wave generator 2 gives the generated sound waves through a sound outlet 4 passing through the receiver housing 3 passes through, to the outside. In order not to hinder the generation of sound waves and the power output due to pressure fluctuations in the sound wave generator 2 To obstruct, he has a barometric compensation opening 8th on. This ensures that pressure fluctuations are reduced and the membrane of the sound wave generator 2 can move more freely. Electric lines 6 serve the electrical contacting of the sound wave generator 2 , In the area of the sound outlet 4 is a neck 5 provided with the sound wave generator 2 in the receiver housing 3 is attached or stored. The stub 5 protrudes from the receiver housing 3 out, so that it can optionally be plugged into another nozzle or a tube for the most soundproof possible connection.

Between the outside of the sound wave generator 2 and the inside of the receiver housing 3 there is a cavity. The sound wave generator 2 has smaller dimensions than the receiver housing 3 , all around. The only point of contact between the two, next to the electrical wires 6 , is the neck 5 with which the sound wave generator 2 in the area of the sound outlet opening 4 in the receiver housing 3 is stored. By minimizing the number of points of contact between sound wave generators 2 and receiver housing 3 the number of sound bridges is minimized. As a result, the tendency to structure-borne sound transmission is reduced, as explained above, contributes to reducing the feedback slope.

The sound transmission through air, referred to as space sound transmission is reduced by the fact that in the cavity an acoustically damping plastic filling 7 is located. Acoustically damping plastics which have the required damping properties are available, for example, under the registered name Technogel or from Gelmec. The are usually based on polyurethane (PU) in various forms of presentation, for example as a gel, foam or ordinary solid plastic. If necessary, silicone-free or plasticizer and curing agent-free polymers can be used. An essential feature of the acoustically damping plastics is an attenuation of acoustic waves, at least in the audible frequency range between 10 Hz and 20 kHz, preferably in the working range of the sound wave generator 2 or a microphone used in the hearing aid, which is stronger than the attenuation by air in the case of room sound transmission. To the effect of plastic filling 7 To maximize, of course, a material suitable plastic material is selected with the highest possible acoustic attenuation in the relevant wavelength range. The attenuation of the room sound transmission contributes to a further reduction of the feedback slope.

An additional beneficial effect of the acoustically damping plastic filling 7 is that it attenuates acoustic energy and thus destroys or transforms into forms of energy. As a result, in addition to the attenuation of the room sound transmission, for example, structure-borne noise from the sound wave generator 2 recorded and muted. The attenuation of structure-borne noise causes a lower structure-borne noise transmission from the sound wave generator 2 on the receiver housing 3 , In general, the destruction of acoustic energy is in the room or in the housing of the sound wave generator 2 and the receiver housing 3 occurs, advantageous because any attributable by damping sound or vibration component can not get to a microphone and couple.

In 2 is a hearing aid 10 in CIC (completely-in-canal) design. It has a housing suitably shaped for insertion into a human auditory canal 14 by having the electronic components required for hearing aid assistance. A battery 11 , which can be rechargeable or non-rechargeable, supplies the hearing aid 10 with electrical energy. A signal processing device 12 takes acoustic ambient signals from microphones 13 be recorded as an input signal. The microphones 13 may be, for example, commercially available electret microphones. The signal processing device 12 Processes and amplifies the signals in accordance with a suitable for hearing aid support of the individual hearing aid wearer hearing aid. The processed and amplified signals are provided by the signal processing device 12 to a receiver 15 from that generates acoustic output signals that are delivered into the ear canal of the hearing aid wearer.

CIC hearing aids are usually used primarily in hearing aid wearers with severe hearing loss, as the hearing aid 10 closes the auditory canal with respect to space sound and thus an increased sound pressure can be generated in the closed interior of the ear canal. In the case of hearing aids for hearing aid wearers with severe hearing loss, a particularly high amplification of acoustic signals is also used, ie the receiver 15 is operated with a very high output power. With the output power of the receiver 15 the probability increases that structure-borne noise or room sound from the receiver 15 to the microphone 13 is transferred and coupled there. In other words, the feedback inclination grows. As explained above, the transmission of room sound through a plastic filling 7 damped, which also reduces attenuation of any sound waves and vibrations, as far as they are not released into the auditory canal of the hearing aid wearer, by damping. In order to achieve greater damping, in the illustrated embodiment, a voluminösere plastic filling 7 as provided in the embodiment shown above.

In the ear canal facing part of the housing 14 is the receiver 15 for generating acoustic output signals. He has a barometric compensation opening 18 which helps reduce power losses due to pressure fluctuations in the receiver 15 contributes. The barometric compensation opening 18 is closed by a special membrane to prevent the entry of the plastic filling 7 in the compensation hole 18 to prevent. An entry of plastic would make the compensation opening 18 close and reduce their effectiveness. This is especially true if the plastic filling 7 made of liquid plastic. Even with soft, especially flowable, plastics, the membrane may be required. The membrane is designed so that it is impermeable to the one for the plastic and this holds back reliably. On the other hand, it is sufficiently flexible and permeable to air or gas to allow the desired barometric compensation. As a material, inter alia, Gore-Tex membrane (protected name) in question.

The receiver 15 has a nozzle 16 on top of the sound outlet 17 surrounds. The stub 16 is in the case 14 stored, and represents the only connection between receiver 15 and housing 14 except for electrical wiring. The housing 14 is in the area of the sound outlet opening 17 shaped so that the neck 16 as soundproof as possible in the housing 14 inserted or plugged. By minimizing the points of contact between receivers 15 and housing 14 the structure-borne sound transmission becomes the housing 14 and about this to the microphone or the microphones 13 reduced. By the highest possible soundproof mounted nozzle 16 will reduce the sound transmission within the housing 14 reached. Remaining room and structure-borne noise that does not have the sound outlet 17 is given in accordance with the rules, by the plastic filling 7 attenuated.

A basic idea of the invention can be summarized as follows: The invention relates to a hearing aid with a vibration-damped receiver receiver and a vibration-damped receiver for a hearing aid. The object of the invention is to provide a receiver and a hearing aid with receiver, in which the feedback tendency is reduced in an inexpensive and cost-effective manner. A basic idea of the invention consists in a receiver 1 for a hearing aid comprising a receiver housing 3 and one in the receiver housing 3 arranged sound wave generator 2 , being between inside of the receiver housing 3 and outside of the sound wave generator 2 a cavity is located, and wherein the cavity is filled with a plastic that dampens acoustic waves stronger than air. Another basic idea of the invention is a hearing aid 10 comprising a housing 14 and one in the housing 14 arranged receiver 15 , being between the inside of the case 14 and the outside of the receiver 15 a cavity is located, and wherein in the cavity is a plastic that attenuates acoustic waves stronger than air. The fact that the plastic attenuates acoustic waves more than air can do, reduces the transmission of sound waves from the receiver to the microphone or microphones and thus reduces the feedback slope. Such a plastic filling not only reduces the transmission of room sound via the air, but also the acoustic energy of room sound and structure-borne noise is destroyed or converted by the damping of the plastic. Thus, a reduction of the feedback slope is also given with respect to the structure-borne sound transmission.

Claims (14)

Receiver ( 1 ) for a hearing aid comprising a receiver housing ( 3 ) and one in the receiver housing ( 3 ) arranged sound wave generator ( 2 ), characterized in that between the inside of the receiver housing ( 3 ) and outside of the sound wave generator ( 2 ) is a cavity, and that the cavity is filled with a plastic that dampens acoustic waves stronger than air. Receiver ( 1 ) according to claim 1, characterized in that the plastic is liquid. Receiver ( 1 ) according to claim 1, characterized in that the plastic is a gel. Receiver ( 1 ) according to one of the preceding claims, characterized in that the plastic is a polyurethane. Receiver ( 1 ) according to one of the preceding claims, characterized in that the distance between the inside of the receiver housing ( 3 ) and the outside of the sound wave generator ( 2 ) is between 1 and 5 mm. Receiver ( 1 ) according to one of the preceding claims, characterized in that the sound wave generator ( 2 ) in the receiver housing ( 3 ) is mounted at only one point, in particular at the sound outlet opening ( 4 ). Receiver ( 1 ) according to one of the preceding claims, characterized in that the sound wave generator ( 2 ) a barometric compensation opening ( 8th ), and that the compensation opening ( 8th ) is covered by a membrane that is impermeable to the plastic. Hearing aid ( 10 ) comprising a housing ( 14 ) and one in the housing ( 14 ) arranged receiver ( 15 ), characterized in that between the inside of the housing ( 14 ) and the outside of the receiver ( 15 ) is a cavity, and that in the cavity is a plastic that dampens acoustic waves stronger than air. Hearing aid ( 10 ) according to claim 8, characterized in that the plastic is liquid. Hearing aid ( 10 ) according to claim 8, characterized in that the plastic is a gel. Hearing aid ( 10 ) according to one of claims 8 to 10, characterized in that the plastic is a polyurethane. Hearing aid ( 10 ) according to one of claims 8 to 11, characterized in that the thickness of the plastic layer between the inside of the housing ( 14 ) and the outside of the receiver ( 15 ) is at least 1 mm, preferably at least 3 mm. Hearing aid ( 10 ) according to one of claims 8 to 12, characterized in that the receiver ( 15 ) is mounted in the housing at only one point, in particular at the sound outlet opening ( 17 ). Hearing aid ( 10 ) according to one of claims 8 to 13, characterized in that the receiver ( 15 ) a barometric compensation opening ( 18 ), and that the compensation opening ( 18 ) is covered by a membrane that is impermeable to the plastic.