Patent Application
20240323587
The invention relates to a loudspeaker system for a hearing device to be worn in the ear. In addition, the invention also relates to a hearing device.
Hearing devices are typically used to output a sound signal to the sense of hearing of the wearer of this hearing device. The output takes place by means of an output transducer, usually acoustically via airborne sound by means of a loudspeaker (also referred to as a “receiver”). Such hearing devices are often used here as so called hearing aid devices (also in short: hearing aids). For this purpose, the hearing devices normally comprise an acoustic input transducer (in particular a microphone), and a signal processor, which is configured to process the input signal (also: microphone signal) generated by the input transducer from the ambient sound with application of at least one signal processing algorithm, which is usually stored specifically for the user, such that a hearing loss of the wearer of the hearing device is at least partially compensated for. In particular in the case of a hearing a device, the output transducer can also be, in addition to a loudspeaker, alternatively a so-called bone vibrator or a cochlear implant, which are configured for mechanically or electrically coupling the sound signal into the sense of hearing of the wearer. The term hearing devices additionally also includes devices such as so-called tinnitus maskers, headsets, headphones, and the like.
Typical designs of hearing devices, in particular hearing aids, are behind-the-ear (“BTE”) and in-the-ear (“ITE”) hearing devices. These designations are directed to the intended wearing position. Behind-the-ear hearing devices thus have a (main) housing, which is worn behind the pinna. A distinction can be made here into models, the loudspeaker of which is arranged in this housing—the sound output to the ear typically takes place by means of a sound tube, which is worn in the auditory canal—and into models which have an external loudspeaker that is placed in the auditory canal. In-the-ear hearing devices, in contrast, have a housing which is worn in the pinna or even completely in the auditory canal.
In-the-ear hearing devices are known to require the smallest possible structural embodiment in order to also be able to arrange all required electrical components in the auditory canal or at least inside the pinna. However, some components, such as loudspeakers and/or microphones, also require a vibration-damped mounting, in order to avoid a (structure-borne) sound coupling from the loudspeaker to other components (in particular a microphone), but also to avoid mechanical damage to these components. However, such a mounting is usually associated with a comparatively large installation space requirement.
The invention is therefore based on the object of specifying an improved mount of a loudspeaker in a hearing device.
This object is achieved according to the invention by a loudspeaker system having the features of claim 1. Furthermore, this object is achieved according to the invention by a hearing device having the features of claim 10. Advantageous embodiments and refinements of the invention, which are in some cases inventive as such, are represented in the dependent claims in the following description.
The loudspeaker system according to the invention is configured and provided for use with, specifically in, a hearing device to be worn in the ear (such as an “ITE”). For this purpose, the loudspeaker system has a loudspeaker having a housing, which in turn has a sound exit opening arranged in a coupling surface of the housing. Furthermore, the loudspeaker system has an antenna body, which has a carrier plate having a sound passage opening, a carrier sleeve connected rigidly to the carrier plate and connected fluidically to the sound passage opening, and an antenna coil wound around the carrier sleeve. Furthermore, the loudspeaker system has a damping body made of a yielding material, by means of which the loudspeaker is coupled using its coupling surface with the carrier plate of the antenna body. The loudspeaker system thus comprises as the main components the loudspeaker and the antenna. The loudspeaker is coupled here by means of the damping body with the carrier plate for the antenna (or its carrier sleeve).
The hearing device to be worn in the ear according to the invention has a housing body and the loudspeaker system described in more detail here and hereinafter. The loudspeaker system is mounted by means of the antenna body in the housing body.
Hearing devices to be worn in the ear, in particular those for binaural use, often have an antenna in the form of a coil to be able to transmit data over a comparatively short radio link and in as directed a manner as possible. Since hearing devices to be worn in the ear often also have a very limited installation space, the most space-saving arrangement possible of all components is expedient. The above-described combination of loudspeaker and antenna coil has often proven itself, since the loudspeaker often has a sound exit nozzle (also referred to as a “spout”), by means of which the loudspeaker is coupled for sound conduction to a sound guide to the ear of the person using it. This sound outlet nozzle is usually omitted in the present embodiment. Its function is assumed here by the carrier sleeve, which moreover in particular also forms the ferrite core for the antenna coil.
According to the present invention, the antenna body is now coupled by means of the damping body with the loudspeaker. This is advantageous since the loudspeaker is usually mounted by means of the antenna body in the housing body of the hearing device in such an embodiment. The damping body therefore enables a vibration decoupling or at least damping of the loudspeaker from the housing body of the hearing device.
The hearing device has the same features and also advantages as the loudspeaker system.
The damping body is preferably made essentially plate-shaped, i.e., in particular flat and cuboid. In particular, the damping body thus has a plate or an essentially plate-shaped base structure. This plate can be made plane-parallel here, for example. A particularly simple structure thus results.
“Essentially plate-shaped” is to be understood here and hereinafter in particular to mean that in an optional variant the damping body can also be designed such that the loudspeaker plunges slightly, i.e., for example, up to at most 5 or 10% of its thickness, into the damping body. This predominantly has advantages during assembly. The loudspeaker can thus be aligned comparatively easily on the damping body (or vice versa) during adhesive bonding with the damping body.
In an alternative variant (in particular to the plane-parallel embodiment of the plate), the damping body, in particular its plate-shaped base structure, has a wedge shape. I.e., the plate has two opposing flat sides placed at an angle to one another, in particular a particularly flat angle of less than 15°, preferably of less than 10°. In this case, “flat sides” are to be understood as the two large-area flat lateral faces of the “plate” delimited by the edge faces extending approximately perpendicular thereto.
Furthermore, the damping body optionally has, in particular instead of the above-described depression in the damping body into which the loudspeaker plunges, additional elements for positioning the loudspeaker (in particular on the damping body). These elements are formed, for example, by at least one side wall, which protrudes at least approximately perpendicularly from the above-described plate.
The damping body optionally additionally also has fastening means, by means of which the loudspeaker can be fastened or else only supported in addition to the fastening by means of the antenna body in the housing body of the hearing device. For pure support, these fastening means can be formed, for example, by pin-like extensions, which support the loudspeaker system against and inside of the housing body. For fastening, these fastening means are expediently formed as a T-part. For example, this T-part is formed on the above-described side wall but can also protrude from the plate-shaped base structure of the damping body. During assembly of the loudspeaker system in the housing body, the T-part is inserted into a corresponding groove (“T-groove”) formed in the housing body and thus offers fixing in the direction of the “bottom bar” of the T.
The loudspeaker and also the antenna body are expediently adhesively bonded to the damping body. Alternatively, however, they can also be welded to one another.
In order to be able to protect the loudspeaker as extensively as possible against damage when the hearing device falls to the ground, for example, in an advantageous embodiment, a material thickness and/or a shear modulus of the damping body (in particular its plate or plate-shaped base structure) is selected such that at a specified falling height, which in particular relates to a body size of the person using the hearing device, and a specified maximum acceleration for the loudspeaker, a sufficient braking path by the damping body is retained. This braking path is preferably dimensioned extending parallel to the coupling surface of the loudspeaker, i.e., in the plane of the planar extension of the damping body.
The material thickness or the shear modulus-in particular the required shear modulus value-is preferably additionally dimensioned as a function of a deceleration force and a connection area (in particular its size) of the damping body on the coupling surface and/or on the carrier plate, by means of the following formula, which in particular forms a first approximation or first design (for example, for a following simulated component design of the damping body building thereon):
wherein:
This leads to the deceleration force
The deceleration path is determined from
In particular, the damping body meets the conditions introduced above as equations (1) to (3).
At an assumed maximum permissible acceleration (for the loudspeaker) of 8,000 times the acceleration of gravity (g) and a falling height of 1.65 m, a deceleration path of approximately 0.21 mm results, which has to be retained by the damping body. In particular, this can be produced by a yielding material (such as an elastomer) having a shear modulus of less than 3 N/mm2. Such an elastomer (for example a rubber) can have, for example, a Shore hardness of 90. Due to the installation situation of the loudspeaker system, this deceleration path is required above all in the surface direction of the damping body. Deceleration paths in other spatial directions (for example, approximately perpendicular (plus/minus 10°) to the surface extension of the damping body) can usually be compensated or provided by the housing body of the hearing device (in particular in the insertion direction of the hearing device)-in particular in combination with the damping body, which is predominantly strained by tension and pressure in this case. The component design and design of the damping body are preferably carried out by means of a simulation—for example, a falling test and vibration simulation. Optionally, a simulation iteration is also used in this case. In particular, the above-described design on the basis of formulas (1) to (3) forms a starting point for the simulated design, in which a sufficient damping effect is optionally (iteratively) studied step-by-step.
The connection surface corresponds, for example, to the coupling surface of the loudspeaker or also a corresponding surface of the carrier plate of the antenna body.
In a further expedient embodiment, connection contacts of the loudspeaker are arranged in a connection surface of the housing differing from the coupling surface.
In a particularly expedient embodiment, the loudspeaker system is exclusively mechanically mounted by means of the antenna body on the housing body. Any possible force transmission via electrical wiring of the loudspeaker with an electronics unit is negligibly small here and preferably also formed such that in this way no intentional force dissipation takes place. For example, corresponding cables are laid sufficiently loose (also “slack” or not tensioned).
The conjunction “and/or” is to be understood here and hereinafter in particular such that the features linked by means of this conjunction can be formed both jointly and also as alternatives to one another.
An exemplary embodiment of the invention is explained in more detail hereinafter on the basis of a drawing. In the figures:
Parts corresponding to one another are always provided with identical reference signs in all figures.
The loudspeaker system 8 has the loudspeaker 6, which is formed having a cuboid housing 9. Furthermore, the loudspeaker system 8 has an antenna body and a damping body 12, which is arranged between the loudspeaker 6 and the antenna body 10.
The loudspeaker 6 has a sound exit opening on a lateral face (not shown in detail), designated as a coupling surface, with which the loudspeaker 6 presses against the damping body 12. The loudspeaker 6 bears multiple connection contacts 16 on a lateral or end face 14 perpendicular thereto (also: “connection surface”).
The damping body 12 is formed in the present exemplary embodiment as a flat plate, which spans the coupling surface of the loudspeaker 6. In addition, the damping body 12 is formed slightly concave (see
The antenna body 10 has a carrier plate 20 and a carrier sleeve 22 standing on this carrier plate 20. The carrier plate 20 has a sound passage opening (not shown), which in the intended assembly state has a fluidic connection to the sound exit opening of the loudspeaker 6 and thus also to the sound opening 18. The carrier sleeve 22 is formed hollow. Carrier sleeve 22 and carrier plate 20 are formed from ferrite. The antenna body 10 additionally has an antenna coil 24, the coil wire of which is wound around the carrier sleeve 22.
The loudspeaker 6 is adhesively bonded using the damping body 12 on a first adhesive surface 26 and this is adhesively bonded via a second adhesive surface 28 to the carrier plate 20. The damping body 12 is designed as a function of a maximum permissible acceleration for the loudspeaker 6. For this purpose, a shear modulus for the material of the damping body 12 is determined on the basis of formulas (1) to (3) introduced above on the basis of a falling height to be expected, a thickness of the damping body 12, a surface on which the damping body 12 is fixed (“attachment surface”, for example, the adhesive surface 28 to the carrier plate 20 or the adhesive surface 26 to the loudspeaker 6), a deceleration force, and a deceleration path. This shear modulus is preferably less than 3 N/mm2.
As can be seen in
In addition to this plate 36, the damping body 12 also has a side wall 38, which is aligned perpendicular to the plate 36 and presses laterally against the loudspeaker 6. This plate 36 offers additional damping.
In addition, the damping body 12 has fastening means for additionally fixing the loudspeaker 6 in the housing body 2. These are formed in the form of a T-part 40, which is formed on the side wall 38. The T-part 40 is specifically used to be inserted into a corresponding groove (not shown) formed in the housing body 2. The T-part 40 is formed from the same material as the plate 36 (and this as the damping body 12 from the preceding exemplary embodiment) and also the side wall 38. Additional stabilization and thus also vibration damping therefore results for the loudspeaker. Optionally, the side wall 38 and/or the T-part 40 can also be omitted, however, if the fastening body 12 is embodied having the wedge-shaped plate 36.
The subject matter of the invention is not restricted to the above-described exemplary embodiment. Rather, further embodiments of the invention can be derived by a person skilled in the art from the above description.
| Number | Date | Country | Kind |
|---|---|---|---|
| 10 2023 202 591.4 | Mar 2023 | DE | national |
