The invention concerns a microphone module for a hearing aid device with a microphone carrier to which a plurality of microphones are attached, as well as a method to produce such a microphone module.
For cosmetic reasons, there is with hearing aid devices the desire for an extensive miniaturization of the devices. Furthermore, the devices should be as cost-effective as possible. In order to be able to achieve these goals, high standards are employed in the production and test methods. The generation of individual modules that can be prefabricated before the assembly of the hearing aid device, and also can be individually tested first with regard to their functionality, represents a possibility for lowering the production costs of a hearing aid device.
Hearing aid devices are known with a plurality of microphones that are arranged on a common carrier, and thus form a microphone module that can be integrated as a structural unit in the housing of a hearing aid device, or can be connected with a housing of a hearing aid device. For example, German patent document DE 196 35 229 A1 shows such a hearing aid device.
Components are known from the electro-technical industry in which injection-molded plastic moldings are provided with three-dimensionally directed conductor traces. These components are designated as MID (Molded Interconnect Devices) and, for example, used as chip sockets or plug connections. The MID technology allows mechanical and electronic functions to be combined in a component. Mostly thermoplastic synthetics serve as a base material, however duroplasts [thermosetting materials] or elastomers are also used. The conductor traces are, as a rule, applied directly to the component via metallization. Further electronic components (resistors, capacitors, etc.) can subsequently by applied via gluing or soldering.
A modular hearing device with a microphone, a receiver, an amplifier and a battery is known from German patent document DE 691 11 668 T2, in which the microphone is incorporated into a microphone module, the receiver is incorporated into a receiver module, the amplifier is incorporated into an amplifier module, and the battery is incorporated into a battery module. The individual modules can be removably connected with one another via dovetail-shaped connections. The electrical connection of the individual modules ensues by way of a flexible circuit board that is soldered with contact points of the modules.
A hearing device is likewise known from U.S. Pat. No. 6,456,720, in which a plurality of components are electrically connected with one another via a flexible circuit board.
As to the formation of conductor traces, various methods for metallization and structuring of the synthetic carrier are known, in particular from MID technology, of which the common ones are be briefly mentioned:
In heat stamping, the synthetic substrate is metallized and structured in one step. With a stamping die on which the positive conductor pattern is applied, a copper stamping foil with an intermediate bonding layer is pressed under pressure and the addition of heat onto the synthetic substrate. The substrate is melted on the surface via the heating effect. The conductor traces are cropped from the copper foil and connected with the substrate.
In metal-backed injection, a structured conductive pattern develops on a foil via screen or pad printing of a primer. During a conditioning process under temperature, the primer undergoes a chemical connection with the substrate surface and provides for a good bond strength. In this process, the foil is simultaneously formed. The foil is subsequently placed in an injection molding machine and back-injected. After the back-injection, the conductor traces are galvanically strengthened and refined.
In the two-component injection molding method, the structure of the conductive pattern is produced with a first injection molding made of metallizable synthetic that serves as a substrate for the chemical metallization. Depending on the synthetic, the surface must be treated again after the first injection molding. The small injection is newly inserted/loaded into a mold and extrusion-coated with non-metallizable synthetic. The free remaining conductor traces are subsequently chemically metallized and enriched.
In the masking method, the metallization of the synthetic carrier ensues via chemical coating. A synthetic injection molding part serves as a substrate in which the surface is initially prepared via corrosion or, respectively, etching for the next step of the process. The metallization subsequently ensues. A photoresist is applied for structuring and exposed with UV light via a three-dimensional mask. After development of the photoresist, the uncovered metal layer is galvanically strengthened and coated with an etching mask. After removal of the photoresist, the remaining metal is etched away and the surface is subsequently enriched.
In contrast to the masking method, in direct laser structuring the etching resist is directly structured with the laser. At the points at which the etching resist was removed by the laser, the metal is etched away. The surface is subsequently enriched.
In the LPKF laser direct structuring method, which is named after the company LPKF, a synthetic part is first injection molded. The transfer of the structure pattern subsequently ensues with a writing or imaging laser system. The subsequent metallization ensues in a chemically reductive bath.
It is the object of the present invention to simplify the production of a hearing aid device with a plurality of microphones.
This object is achieved via a microphone module for a hearing aid device with a microphone carrier on which a plurality of microphones are attached, where the microphone carrier is fashioned as a solid plastic molding with three-dimensionally directed conductor traces for electrical connection of the microphones.
Furthermore, the object is achieved via a method for production of a microphone module for a hearing aid device, with the following steps:
a) generation of a microphone carrier in the form of a solid plastic molding, from a synthetic material,
b) application of three-dimensionally directed conductor traces on the synthetic material,
c) attachment of microphones on the carrier, and production of electrical connections between microphone contacts and the conductor traces.
A microphone carrier is generated first in the production of a microphone module according to the invention. In a preferred embodiment, this is designed such that all microphones present in a hearing aid device can be attached to it. In order to allow for the acoustic requirements for the microphones as well as the crowded space proportions in the housing of a hearing aid device, inevitably an uneven shaping normally results for the microphone carrier.
The microphone module according to the invention assumes not only the function of attaching the microphones, but additionally and advantageously serves at least in part for electrically connecting the microphones among one another and with an electronic signal processing unit in the hearing aid device. In order to enable an almost arbitrary shaping of the microphone carrier, the carrier is preferably constructed from a thermoplastic, duroplastic or elastomer synthetic material. According to an embodiment of the invention, direct conductor traces for the electrical connection of the microphones are also applied to this synthetic material. Alternatively, the conductor traces can also be wholly or partially enclosed by the synthetic material of the microphone carrier.
The formation of the microphone carrier in MID technology enables both an almost arbitrary shaping of the microphone carrier and the generation of three-dimensionally directed conductor traces on the microphone carrier or, respectively, in the microphone carrier for electrical connection of the microphones. This has a plurality of advantages according to various embodiments of the invention:
Via the microphone carrier, the microphones may be combined in a simple and cost-effective manner into a modular structural group—a microphone module. This can be directly soldered to the microphone carrier to attach the microphones. The electrical connection is thus also simultaneously produced. Since the microphones are already electrically connected with one another via the conductive pattern applied to the microphone carrier, two conductors (positive pole, ground conductor) are sufficient for a voltage supply of all microphones of the hearing aid device, for which, until now, two conductors for each microphone have been necessary. Furthermore, the microphones can already be tuned to one another and tested with regard to their transmission behavior after the assembly of the module, before their installation and integration into a hearing aid device.
A further advantage is that, in a simple manner, a plurality of different hearing device variants can be generated via different microphone modules that, for example, can be equipped with two, three or more microphones. Different functionalities of the resulting hearing device can result, and thus different hearing device variants, depending on with which type of microphone module (for example, with two, three or four microphones) a hearing device is equipped.
Furthermore, embodiments of the invention offers the advantage that the microphone carrier can be equipped with further electronic components in addition to the microphones. If the microphones are omnidirectional microphones, an electrical circuiting of the microphones is necessary for assembly of a directional microphone system. The microphone signal of at least one microphone must be delayed and inverted and added to the microphone signal of a further microphone. For this, necessary components (for example, delay elements and inverters) are advantageously directly placed on the microphone carrier, such that the microphone module already generates a distinct directional characteristic. The microphone carrier may also comprise the conductor traces for electrical connection of these components. Moreover, in modern hearing devices, at least one digital signal processing ensues. The embodiments of the invention also enable the attachment of A/D converters on the microphone carrier, such that digital signals are already supplied by the microphone module.
The electrical contacts of a microphone module according to embodiments of the invention can be realized via stranded conductors, flexible circuit boards or plug connectors. Furthermore, it is possible that the microphone module itself serves as a plug connector.
To generate a directional microphone system from a plurality of omnidirectional microphones electrically circuited with one another, it is necessary that the microphones are very precisely tuned to one another with regard to their amplitudes and phase transmission behavior. The embodiments of the invention also offer advantages in that components (for example, resistors and capacitors) necessary for microphone tuning may be directly arranged with one another on the microphone carrier. The microphones can thus advantageously already be tuned (“matched”) before the installation in the hearing aid device. A directional microphone system can thus be produced, calibrated and tested as a separate physical unit. Last, but not least, advantages also result in the event of repairs of a hearing device. Instead of individually replacing defective microphones, the complete microphone module may now be exchanged, foregoing the calibration of a replaced microphone with microphones remaining in the hearing device.
Via the invention, it is furthermore possible to shrink the microphone modules such that they fit into hearing aid devices of smaller design, for example behind-the-ear hearing aid devices. Additionally, this achievable reduction of the number of the connection wires for electrical connection of the microphones (for example, from nine to five connection wires in a microphone module with three microphones), via the softer arrangement of the microphone module connected therewith, brings an acoustic advantage.
A further embodiment of the invention provides an oscillation-damped arrangement of a microphone module according to the invention in a hearing aid device. The oscillation-damped arrangement can ensue both via the microphones and via the microphone carrier. For example, for this the microphones and also the socket of the microphone inlet may be coated with elastic, oscillation-damping material, for example, rubber jackets. An oscillation-damping arrangement of the individual microphones in the housing of a hearing aid device is thus no longer necessary. Damping elements made of elastic, oscillation-damping materials are also advantageously located between the microphone carrier and acceptances for mounting the microphone carrier in the hearing device housing. The entire microphone module may thus be largely decoupled from the housing of the hearing aid device via oscillation technology.
The microphone module according to the invention can be used in all common hearing device designs, for example, in in-the-ear hearing aid devices (IdOs), behind-the-ear hearing aid devices (HdOs), pocket hearing aid devices, and so forth.
Further advantages and details of the invention emerge from the subsequent specification of exemplary embodiments of the invention and the drawings.
In the production of the microphone carrier according to an embodiment of the invention, in a first method step, a plastic injection-molded part is produced in the shape visible from
Altogether, the electrical connection of the three microphones ensues via the five conductor traces 2-6. To connect the microphone module with an amplifier (not shown), only five (instead of the normal nine) connection conductors are thus necessary. The microphone module thereby contributes to a lowering of the production costs of a hearing aid device.
The bottom of the microphone carrier 1 is visible from
The physical unit 27′ can be implemented as an integrated circuit, and thus as an electronic component with it own housing. However, a plurality of electrical components can likewise also be placed in a distributed manner on the microphone carrier 1′. The conductor traces for electrical connection of the component 27′ are also advantageously located directly on the microphone carrier. A directional microphone system can thus by realized in a simple manner, in that electronic components necessary to fashion the directional microphone system are also comprised by the microphone module. The microphones 13′, 14′, 15′ of the microphone module can then already be calibrated before the microphone module is used in a hearing aid device. The calibration with regard to the transmission behavior of the microphones 13′, 14′, 15′ is particularly necessary when a directional microphone system of higher order should be formed via electrical circuiting.
Furthermore, the microphone carrier 1′ can be provided with further electrical components, where the functionality of the microphone module is, for example, expanded to the effect that a signal preamplification and A/D conversion of the microphone signals also ensues. These components can also be comprised by a single integrated circuit on the microphone carrier. However, a plurality of electrical components can also be mounted on the microphone carrier 1′. Digital, and thus largely interference-insensitive signals are thus already supplied from the microphone module to the signal outputs.
For the purposes of promoting an understanding of the principles of the invention, reference has been made to the preferred embodiments illustrated in the drawings, and specific language has been used to describe these embodiments. However, no limitation of the scope of the invention is intended by this specific language, and the invention should be construed to encompass all embodiments that would normally occur to one of ordinary skill in the art. The particular implementations shown and described herein are illustrative examples of the invention and are not intended to otherwise limit the scope of the invention in any way. For the sake of brevity, conventional electronics and other functional aspects of the systems (and components of the individual operating components of the systems) may not be described in detail. Furthermore, the connecting lines, or connectors shown in the various figures presented are intended to represent exemplary functional relationships and/or physical or logical couplings between the various elements. It should be noted that many alternative or additional functional relationships, physical connections or logical connections may be present in a practical device. Moreover, no item or component is essential to the practice of the invention unless the element is specifically described as “essential” or “critical”. Numerous modifications and adaptations will be readily apparent to those skilled in this art without departing from the spirit and scope of the present invention.
Number | Date | Country | Kind |
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10260303.0 | Dec 2002 | DE | national |
This Application is a divisional of parent application Ser. No. 10/741,769, filed Dec. 19, 2003. The parent application is herein incorporated by reference.
Number | Date | Country | |
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Parent | 10741769 | Dec 2003 | US |
Child | 11772381 | Jul 2007 | US |