EP3070965A1 - Acoustic tube for a hearing aid - Google Patents

Abstract

The invention specifies a sound conductor (1) for a hearing aid (90), in particular for a hearing aid (91), comprising a housing (2), at least one sound generator (26, 44, 46), a number with the at least one sound generator ( 26, 44, 46) and attachment means (16) for reversibly attaching to a main unit (70) of the hearing aid (90) to electrically connect the or each signal port (36) to a signal output (86) of the main unit (70), wherein in the housing (2) a sound channel (4) is formed, which is adapted to at least one sound generator (26, 44, 46) generated sound along a propagation direction (22) to a sound outlet (24) of the housing (2), and wherein the at least one sound generator (26, 44, 46) is formed by a thermoacoustic transducer (28, 48, 50). The invention further provides a corresponding main unit (70) with fastening means (76) for the reversible attachment of a sound conductor (1) and a hearing aid (90) with a main unit (70) and a sound conductor (1), which are connected via the respective fastening means (16, 16). 76) are fastened together.

Description

The invention relates to a sound conductor for a hearing aid, in particular for a hearing aid, comprising a housing and fastening means for reversible attachment to a main unit of the hearing aid, wherein in the housing a sound channel is formed, which is adapted to sound along a propagation direction to a sound output of the housing to lead.

In a hearing aid having a microphone and an electroacoustic transducer, mechanical vibrations caused by the electroacoustic transducer can lead to instability of the signal path. For example, the vibrations may be recorded by the microphone through an acoustic feedback and converted into an electrical signal which, after amplification, is applied to the electroacoustic transducer and converted into sound by it. As a result, a closed loop is formed in which vibrations can be amplified more and more.

Such purely acoustic feedback is usually suppressed as far as possible by suitable signal processing, for example by means of an adaptive filter, as well as by sufficient acoustic shielding. In many hearing aids, however, additionally caused by the electro-acoustic transducer vibration can feedback electromagnetically. The electroacoustic transducer usually has a membrane. From an electrical input signal, a time-varying magnetic field is generated, by which - possibly indirectly via a magnetizable connecting rod - the membrane is excited to vibrate, which generate the desired sound signal. Mechanical vibrations of the electroacoustic transducer, which may be caused for example by a resonant excitation of the surrounding housing in the hearing aid, result in the coils, which the time-variable Generate magnetic field from the input signal to interference in the form of high-frequency signal components.

Furthermore, many hearing aids have an additional receiver coil, a so-called "Telecoil", via which electromagnetic signals from an external transmitter can be directly coupled. Such external stations are used, for example, in museums or churches; also a multiplicity of TV Heimgeräten are equipped with appropriate transmitters for Telecoil receipt. The time-varying magnetic field, which causes the membrane to vibrate, is now received by the telecoil, whereby a signal is generated from this and transmitted to a signal processing unit of the hearing aid. In particular, in this case high-frequency signal components can be coupled, which are caused by an additional mechanical vibration of the electro-acoustic transducer in the coil.

In order to reduce the influence of mechanical oscillations of the electroacoustic transducer on the stability of the signal path, both the occurrence and the transmission of the vibrations by means of attenuations on the suspension of the electroacoustic transducer - e.g. made of rubber - to be suppressed. Likewise, a separate shield, for example by means of a screen of highly permeable metal, reduce coupling of the electromagnetic signal components. This shielding is effective particularly in the high frequency signal components resulting from the vibration of the electroacoustic transducer.

However, the above-mentioned procedure is in each case constructive measures which require the arrangement of additional components-a mechanical damper or an electromagnetic shielding-in the hearing aid. However, this is often only possible to a limited extent for reasons of space. This also increases the weight of the hearing aid, whereby the wearing comfort is restricted for a user.

The invention is therefore based on the object to reduce vibrations in the generation of sound in a hearing aid as possible, and to prevent electromagnetic feedback as possible.

The above object is achieved by a sound conductor for a hearing aid, in particular for a hearing aid, comprising a housing, at least one sound generator, a number of connected to the at least one sound generator signal terminals and fastening means for reversible attachment to a main unit of the hearing aid to produce an electrical Connecting the or each signal terminal to a signal output of the main unit, wherein in the housing a sound channel is adapted, which is adapted to guide sound generated by at least one sound generator along a propagation direction to a sound outlet of the housing, and wherein the at least one sound generator by a thermoacoustic Transducer is formed. Advantageous and partly inventive in themselves embodiments are the subject of the dependent claims and the following description.

In this case, the sound output can be configured to lead a sound signal directly to the ear of a user, or be set up via a corresponding holding device such that an earmold piece can be placed on the sound output, via which a sound signal is conducted from the sound channel to the user's ear. By way of example, a mechanical screw connection or a latching plug connection may be included among the fastening means, the main unit each being to be equipped with corresponding counterparts. The length of the sound channel is presently defined in particular with the aid of the propagation direction of sound, which propagates in the sound channel. The width of the sound channel is accordingly to be understood as locally orthogonal to the propagation direction dimension. In a preferred, because functional variant The sound channel has a width that is much smaller than its length. In this case, a width which is substantially smaller than the length is to be understood in particular to mean a width which is on average at least a factor of 5, preferably on average at least a factor of 10, smaller than the length.

The use of a thermoacoustic transducer as a sound generator in this case has the advantage that it does not generate any vibration energy in the generation of sound. In a thermoacoustic converter, a sound signal is generated from an electrical signal by generating temperature fluctuations on a surface or a surface of the thermoacoustic transducer by the electrical signal. These rapidly oscillating temperature fluctuations on the surface or surface of the thermoacoustic transducer lead to a time-variable temperature gradient of the adjacent air layers. By this time-varying temperature gradient, the adjacent air layers can be set in vibration, which propagate as a sound signal.

For such a sound generation of any kind of proper movement of the thermoacoustic transducer is not required, and not provided. When the sound is generated by the thermoacoustic transducer thus no vibrations, which can be delivered to the environment or to a suspension. This is relevant in the case of the sound conductor for a hearing aid, in particular against the background that the dimensions commonly used lead to a resonance spectrum, in particular for the sound channel, which can easily lead to instability of the system by mechanical vibration in frequency ranges above 1 kHz. A thermoacoustic transducer, in particular one which is suitable from its dimensioning for an arrangement in a sound conductor has, for frequencies above 1 kHz particularly dynamic playback behavior.

The invention makes use of the surprising finding that a thermoacoustic transducer arranged in the sound conductor can influence the resonance spectrum of the sound conductor and in particular of the sound channel. Usually, by means of damping elements, it is attempted to optimize the resonance spectrum of the sound conductor for a particularly dynamic reproduction behavior in relevant frequency ranges, while at the same time the production of mechanical vibrations by a propagating sound signal should as far as possible be prevented.

In this case, in particular frequencies between 2 kHz and 4 kHz are to be regarded as relevant frequency ranges. A good reproduction dynamics, ie, in particular a very high output level in this frequency band, is of particular importance for speech intelligibility, since particularly important formants for recognizing consonants occur in this frequency band. The resonant spectrum of the sound conductor should therefore allow the loudest possible interference-free transmission in this frequency band in order to be able to produce as rich a sound image as possible when reproducing speech. On the other hand, resonances which can lead to mechanical vibrations should as far as possible be prevented. By suitable dimensioning and positioning of the thermoacoustic transducer in the sound conductor can be influenced on the resonance spectrum, so that on the one hand in the desired frequency band from 2 kHz to 4 kHz, a particularly dynamic reproduction is possible, and on the other unwanted by the damping effect of the thermoacoustic transducer in the sound conductor Resonance maxima can be damped.

Thus, while the use of a thermoacoustic transducer as a sound generator initially allows a substantially vibration-free sound generation, so that no primary vibrations are coupled into the sound conductor, is achieved via the damping effect of the thermoacoustic transducer in the sound channel, that by propagating the Sound signal, which was generated by the thermoacoustic transducer itself initially vibration-free, a resonant excitation of the sound conductor to vibration can be largely prevented.

Preferably, a sound chamber is formed with a sound passage in the housing, wherein the sound channel leads from the sound passage to the sound output of the housing, and wherein the at least one sound generator is arranged in the sound chamber.

The dimensions of the sound channel of a sound conductor for a hearing aid often allow little room for design changes, since the dimensions of the propagation, in particular of the width, the propagation of sound through the sound channel and ultimately the resonance spectrum of the sound conductor. This, in turn, influences which maximum sound pressure level can be transmitted at any one frequency without producing an unwanted vibration of the sound conductor which could be transmitted to the main unit and at which frequencies the maximum gain for a sound signal is possible. Since the dimensions of the sound channel can usually only be slightly adapted, but the sound pressure power of a thermoacoustic transducer can also depend on its size, it may be advantageous to use a thermoacoustic transducer which does not fit in the sound channel, preferably in the sound channel to arrange transitioning sound chamber.

Conveniently, the thermoacoustic transducer comprises at least one film formed of carbon nanotubes, which is connected to at least one signal terminal, wherein by applying a signal voltage to the or each signal terminal, a time-varying heating in the or each film is caused, by means of which moakustischen effect a sound is generated. In such a film, the carbon nanotubes can be aligned substantially parallel to each other, even multiple layers of bundles parallel to each other carbon nanotubes, wherein the orientations of the carbon nanotubes of two successive layers are mutually orthogonal, this is possible.

The described microstructure of the film allows a largely unimpeded propagation of a sound through the film, while still maintaining a minimum damping effect, via which the resonances in the sound channel can be influenced. On the one hand, this makes it possible to arrange a plurality of such thermoacoustic transducers parallel to one another without a sound signal generated in one film of a thermoacoustic transducer being adversely affected or even absorbed by an adjacent film of another thermoacoustic transducer. On the other hand, this also allows the use of a sound generator in the main unit such that in the attachment of the sound conductor to the main unit a generated in this sound generator there sound signal via a sound input of the sound conductor is directed into the sound space and can be continued from there to the sound channel, without doing to affect the function of the thermoacoustic transducer, which is arranged in the sound chamber or in the sound channel.

In an advantageous embodiment of the invention, in this case the film of the at least one sound generator is oriented substantially perpendicular to the propagation direction of a sound predetermined at least partially by the sound channel. In this case, if the sound generator is not arranged in the sound channel itself but, for example, in a sound chamber passing in it, an extrapolation of the propagation direction in the sound channel into the sound chamber is to be used for determining the local propagation direction of the sound in the sound chamber. An arrangement of the film perpendicular to the propagation direction can develop a particularly good damping effect with respect to the resonance spectrum of the sound conductor, so that as a result resonance maxima at undesired frequencies can be largely suppressed.

In an alternative embodiment of the invention, the film of the at least one sound generator is aligned substantially longitudinally to the propagation direction of a sound predetermined at least partially by the sound channel. The concrete arrangement of the film with respect to the direction of propagation is to be determined here in particular as a function of the effects of the positioning and the orientation of the film on the resonances of the sound conductor.

As further proves to be advantageous if the housing has a sound input, which is acoustically connected via the sound channel with the sound output. In this case, an acoustic connection means such a connection, which enables a controlled, in particular an unimpeded propagation of a sound signal. In particular, this includes a fluidic connection. In this case, the sound input is preferably set up to conduct a sound generated in the main unit via the sound channel to the sound output during a fastening to the main unit of the hearing device. In particular, if due to the dimensions of the sound conductor of the therein arranged ther-moakustische converter only for higher frequencies sufficient dynamics in the reproduction achieved by the sound input generated in the main unit sound signal, which has a higher sound pressure at lower frequencies than this could be reached by means of the thermoacoustic transducer in the sound conductor, are supplied to the user. Through the achievable dynamics over a wide bandwidth, the sound quality for the user can be improved.

Conveniently, the sound conductor comprises another sound generator formed by a thermoacoustic transducer, which is connected to the or each signal terminal. With a plurality of particularly largely identical sound generators can generally produce a higher sound pressure than by a single sound generator. The usage of two or more thermoacoustic transducers for generating sound in the sound conductor is particularly advantageous if the maximum possible dynamic range, so for different frequencies of each maximum sound pressure at which still no vibrations of the sound conductor are excited by a single thermoacoustic transducer is not exhausted.

In addition, with several thermoacoustic transducers, each having a film of carbon nanotubes, the resonances in the sound channel of the sound conductor can be tuned in more detail, which in particular undesirable resonances at unfavorable frequencies, in which, for example, a transmission of resulting vibrations to the main unit possible is, can be particularly effectively suppressed.

The invention further mentions a main unit of a hearing device, in particular a hearing aid, comprising a signal processing unit, a signal output connected to the signal processing unit and fastening means for reversibly mounting a prescribed sound conductor to produce an electrical connection of the or each signal terminal of the sound conductor with the signal output.

In this case, the main unit preferably has at least one electroacoustic transducer connected to the signal processing unit and / or at least one microphone connected to the signal processing unit. In particular, in combination with an electroacoustic transducer in a main unit, which may be designed primarily for the reproduction of low frequencies, the thermoacoustic transducer of the sound conductor, which allows a particularly dynamic reproduction above 1 kHz, advantageous.

In addition, the invention provides a hearing aid, in particular a hearing aid, comprising a prescribed main unit and a sound conductor as described above, wherein the main unit and the sound conductor are fastened together via the respective fastening means. The advantages stated for the sound conductor and his further developments can be transferred analogously to the main unit and the hearing aid.

In particular, the hearing device also comprises an earmold mounted on the sound exit of the sound conductor, which is designed and intended to guide a sound signal generated in the main unit or in the sound conductor and routed through the sound conductor to its sound output to the hearing of a user of the hearing aid.

FIG 1

in einer Schnittdarstellung einen Schallleiter für ein Hörgerät mit einem thermoakustischen Wandler im Schallraum,

FIG 2

in einer Ausschnittdarstellung eine alternative Anordnung des thermoakustischen Wandlers im Schallraum des Schallleiters nach FIG 1,

FIG 3

in einer Ausschnittdarstellung einen Schallraum eines Schallleiters nach FIG 1 mit einer Mehrzahl an thermoakustischen Wandlern,

FIG 4

in einer Schnittdarstellung eine Haupteinheit eines Hörgeräts, und

FIG 5

in einer Seitenansicht ein Hörgerät mit einem Schallleiter nach FIG 1 und einer Haupteinheit nach FIG 4.

An embodiment of the invention will be explained in more detail with reference to a drawing. Here are shown schematically in each case:

FIG. 1

in a sectional view of a sound conductor for a hearing aid with a thermoacoustic transducer in the sound space,

FIG. 2

in a sectional view of an alternative arrangement of the thermoacoustic transducer in the sound space of the sound conductor after FIG. 1 .

FIG. 3

in a detail representation of a sound space of a sound conductor after FIG. 1 with a plurality of thermoacoustic transducers,

FIG. 4

in a sectional view a main unit of a hearing aid, and

FIG. 5

in a side view of a hearing aid with a sound conductor after FIG. 1 and a main unit FIG. 4 ,

Corresponding parts and sizes are provided in all figures with the same reference numerals.

In FIG. 1 is shown schematically in a sectional view of a sound conductor 1 for a hearing aid not shown in detail. The sound conductor 1 comprises a housing 2 in which a sound channel 4 and a sound chamber 8 connected to the sound channel 4 via a sound passage 6 are formed. The housing 2 has at one end a protruding neck 10, on the outside thereof in the longitudinal direction a spring tongue 12 is arranged with a snap hook 14 at its end. The nozzle 10, the spring clip 12 and the snap hook 14 in this case form fastening means 16 for reversible attachment to a main unit of the hearing aid, not shown in the drawing.

At the free end 18 of the nozzle 10, this has a sound input 20, which leads into the sound chamber 8. A sound signal generated in the main unit of the hearing aid can thus be guided via the fastening means 16 through the sound input 20 via the sound chamber 8 and the sound channel 4 along the propagation direction 22 to a sound outlet 24 during attachment of the sound conductor 1 to the main unit. At the sound outlet 24 a circumferential groove 25 is introduced in the sound channel 4, by means of which a plugged onto the sound outlet earmold can be attached.

In the sound chamber 8, a sound generator 26 is arranged, which is formed by a thermoacoustic transducer 28. The thermoacoustic transducer 28 in this case has a film 30 of carbon nanotubes, which is provided at two opposite edges in each case with contact points 32 for contacting. In this case, the film 32 is arranged substantially perpendicular to the local propagation direction 22 of the sound along which propagates a sound signal in the sound chamber 8 from the sound input 20 via the sound channel 4 in the direction of the sound output 24.

In the area of the sound chamber 8, the housing 2 has a closing surface 34 on which the socket 10 is seated, and which rests against the hearing aid when attached to the main unit. On the end surface 34, two signal terminals 36 are arranged next to the nozzle 10, which are each connected to a contact point 32. During attachment of the sound conductor 1 to the main unit, an electrical signal, which is output via a corresponding signal output of the main unit, can be supplied to the thermoacoustic converter 28 via the signal terminal 36. Thus, by attaching the sound conductor 1 to the main unit, the thermoacoustic transducer 28 can receive an electrical signal for conversion into sound from the signal terminals 36 and the contact points 32 respectively connected thereto.

In FIG. 2 is shown in a cutout view an alternative arrangement of the thermoacoustic transducer 28 in the sound space 8. While the direction of propagation 22 in the sound channel 4 is predetermined by its Bewandung 40, it can be in the sound chamber 8, a local propagation direction 22 by extrapolation 42 of the propagation direction 22 in sound channel 4 on the sound passage 6 out in the direction of the sound input 20 determine. In the present illustration, the film 30 of the thermoacoustic transducer 28 is oriented substantially longitudinally of the local propagation direction 22 of the sound in the acoustic chamber 8.

In FIG. 3 is in a cutout view of the sound space 8 of in FIG. 1 shown sound conductor 1, in which three sound generators 26, 44, 46 are arranged, which are each formed by a thermoacoustic transducer 28, 48, 50. The carbon nanotube films 30, 52, 54 of the thermoacoustic transducers 28, 48, 50 are aligned substantially parallel to one another and essentially perpendicular to the local propagation direction 22. Each of the films 30, 52, 54 has contact points 32, 56, 58 respectively at two opposite edges, which are each connected to one of the two signal terminals 36, so that each film 30, 52, 54 is connected to both signal terminals 36 connected is. In the fastened state of the sound conductor 1 to the main unit, the three thermoacoustic transducers 28, 48, 50 can be controlled simultaneously by means of an electrical signal, which is fed via a corresponding signal output of the main unit in the signal terminals 36, so that they are the electrical signal in sound convert.

In general, the concrete selection of the number of thermoacoustic transducers and the determination of their positioning with respect to the sound channel and, if provided in the sound conductor, with respect to the sound space to vote on the resonance behavior of the sound conductor. The same applies in the case of carbon nanotube-based thermoacoustic transducers for the alignment of the respective film with respect to the local propagation direction of the sound. In this case, for the resonance spectrum in each case a damping effect to be considered, which deploys a carbon nanotube film as a limiting element of an air column in the sound channel or in the sound space.

In FIG. 4 is shown in a sectional view of a main unit 70 of a hearing aid. The main unit 70 in this case has a receptacle 72 for the neck of a sound conductor FIG. 1 on, with a hold ash 74 is provided for locking the snap hook. The receptacle 72 and the retaining tab 74 in this case form fastening means 76 for the reversible attachment of the sound conductor. The receptacle 72 leads to a sound space 78 in the main unit, in which an electroacoustic transducer 80 projects. The electroacoustic transducer 80 is connected to a signal processing unit 82 and is adapted to convert an electrical signal output therefrom to sound, which propagates primarily into the sound space 78 and thus in the direction of the receptacle 72. In this case, the electroacoustic transducer 80 may be designed, for example, as a loudspeaker.
The signal processing unit 82 is connected to a microphone 84, which is set up to record sound signals from the environment and to convert them into electrical signals. which are passed to the signal processing unit 82. The signal processing unit 82 is also connected to a signal output 86 which is adapted to output an electrical signal to the signal terminals of the sound conductor when the sound conductor is fastened via the fastening means 76. In the sound conductor, the electrical signals received by the latter at its signal terminals are converted into corresponding sound signals by the thermoacoustic transducer arranged in the sound conductor. In particular, in this case, the signal processing unit 82 comprise a signal splitter, so that the signal output 86 primarily high-frequency signal components of an intended for conversion into a sound signal electrical signal are output, while the electroacoustic transducer 80 primarily low-frequency signal components are output for conversion into a sound signal.

In FIG. 5 a hearing aid 90 with a main unit 70 and a sound conductor 1 is shown in a side view. The hearing aid 90 is designed here as a hearing aid 91. The sound conductor 1 and the main unit 70 are in this case attached to each other by fastening means, as in FIG. 1 respectively. FIG. 4 are shown. At the sound output corresponding end of the sound conductor 1, an earmold 92 is attached. A sound signal, which is generated in the main unit 70 and / or in the sound conductor 1 and guided through the sound conductor, passes through the ear piece to the hearing of a user of the hearing aid 91.

Although the invention has been illustrated and described in detail by the preferred embodiment, the invention is not limited by this embodiment. Other variations can be deduced therefrom by those skilled in the art without departing from the scope of the invention.

LIST OF REFERENCE NUMBERS

1

sound conductor

2

casing

4

sound channel

6

Sound Transmission

8th

Schallenkammer

10

Support

12

spring shackle

14

snap hooks

16

fastener

18

free end

20

sound input

22

(local) propagation direction

24

sound output

26

sound generator

28

thermoacoustic transducer

30

(Carbon nanotube) film

32

contact point

34

end surface

36

signal connection

40

Bewandung

44

sound generator

46

sound generator

48

thermoacoustic transducer

50

thermoacoustic transducer

52

(Carbon nanotube) film

54

(Carbon nanotube) film

56

contact point

58

contact point

70

main unit

72

admission

74

retaining tab

76

fastener

78

sound chamber

80

electroacoustic transducer

82

Signal processing unit

84

microphone

86

signal output

90

hearing Aid

91

hearing aid

92

Eartip

Claims (10)

A sound conductor (1) for a hearing aid (90), in particular for a hearing aid (91), comprising a housing (2), at least one sound generator (26, 44, 46), a number of with the at least one sound generator (26, 44, 46) and attachment means (16) for reversibly attaching to a main unit (70) of the hearing aid (90) to electrically connect the or each signal port (36) to a signal output (86) of the main unit (70); wherein in the housing (2) a sound channel (4) is formed, which is adapted to at least one sound generator (26, 44, 46) generated sound along a propagation direction (22) to a sound outlet (24) of the housing (2) direct, and
wherein the at least one sound generator (26, 44, 46) is formed by a thermoacoustic transducer (28, 48, 50). Sound conductor (1) according to claim 1,
wherein a sound chamber (8) with a sound passage (6) is formed in the housing (2),
wherein the sound channel (4) leads from the sound passage (6) to the sound outlet (24) of the housing (2), and
wherein the at least one sound generator (26, 44, 46) is arranged in the sound chamber (8). Sound conductor (1) according to claim 1 or claim 2,
wherein the thermoacoustic transducer (28, 48, 50) comprises at least one film (30, 52, 54) formed of carbon nanotubes, which is connected to at least one signal terminal (36), and
wherein, by applying a signal voltage to the or each signal terminal (36), time-varying heating in the or each film (30, 52, 54) is caused becomes, by means of which a sound is generated by means of the thermoacoustic effect. Sound conductor (1) according to claim 3,
wherein the film (30, 52, 54) of the at least one sound generator (26, 44, 46) is oriented substantially perpendicular to the propagation direction (22) of a sound predetermined at least partially by the sound channel (4). Sound conductor (1) according to claim 3,
wherein film (30) of the at least one sound generator (26) is oriented substantially longitudinally of the propagation direction (22) of a sound predetermined at least partially by the sound channel (4). Sound conductor (1) according to one of the preceding claims,
wherein the housing (2) has a sound input (20) which is acoustically connected to the sound output (24) via the sound channel (4). Sound conductor (1) according to one of the preceding claims,
comprising a further sound generator (44, 46) formed by a thermoacoustic transducer (48, 50) connected to the or each signal terminal (36). Main unit (70) of a hearing aid (90), in particular a hearing aid (91), comprising a signal processing unit (82), a signal output (86) connected to the signal processing unit (82) and fastening means (76) for reversibly attaching a sound conductor (1) according to one of the preceding claims, making an electrical connection of the or each signal terminal (36) of the sound conductor (1) to the signal output (86). The main unit (70) of a hearing aid (90) according to claim 8, comprising at least one electroacoustic transducer (80) connected to the signal processing unit (82) and / or at least one microphone (84) connected to the signal processing unit (82). Hearing aid (90), in particular hearing aid (91), comprising a main unit (70) according to one of claims 8 or 9, and a sound conductor (1) according to one of claims 1 to 8, wherein the main unit (70) and the sound conductor (1 ) are fastened together via the respective fastening means (16, 76).

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