EP2087769A2

EP2087769A2 - Mounting electronic components

Info

Publication number: EP2087769A2
Application number: EP06804864A
Authority: EP
Inventors: Erdal Karamuk
Original assignee: Phonak AG
Current assignee: Sonova Holding AG
Priority date: 2006-11-09
Filing date: 2006-11-09
Publication date: 2009-08-12
Anticipated expiration: 2026-11-09
Also published as: DK2087769T3; WO2007038897A3; WO2007038897A2; EP2087769B1

Abstract

In order to mount, in a damped manner, electronic components inside an accommodating housing of an electronic small device, an elastic and/or flexible holding element (15) with inwardly projecting mounting areas (17) for mounting or holding the component (1) in position is placed along at least portions of the inside wall of the accommodating housing (3).

Description

Storage of electronic components

The present invention relates to a device for damped storage of electronic components according to the preamble of claim 1 and a method for producing an integral, damping storage with a device.

The present invention is a construction for the storage of electro-acoustic transducers or other electronic components in electronic micro devices, such as hearing aids. In general, such electronic components, such as a handset or electro-acoustic transducer, are held in position by means of rubber parts. These rubber mounts are usually attached directly to the electronic component, glued or slipped over this and define the contact surface with the rest of the electronic micro device, such as a hearing aid structure. In addition to the individual bearings, connection lines to the component, such as a sound conduit, are usually required, which connects the component to the surrounding environment, such as the acoustic environment, and often also has a mechanical support function.

The well-known rubber bearings have three functions:

They hold the electronic component in the desired position in the microdevice, such as the transducer in the desired position in the hearing aid;

- they isolate the component from its mechanical environment and damp vibrations; and they protect the electronic component from shock loads. For the above-described, general approach to the damping storage of electronic components in electronic microdevices various possibilities are described in the literature, for example, to store transducers, especially listeners (speakers) in hearing aids. Thus, for example, EP 1 249 496 describes a multi-part receiver bearing, which takes into account the force distribution on the listener surface by using rubber parts with different stiffness. In US 47 29 451 an integrated storage of a handset and an in-ear hearing aid is described. An earpiece dummy is placed in an individual bowl and the bowl tip is filled with a pourable rubber material. After drying, the dummy is removed leaving behind an integrated cavity, which serves as a receiver storage.

In US 6,751,326 a storage concept is described in which a handset is housed in a two-part housing. The rubber parts are mounted on the handset and / or the housing.

In WO20055652 a mounting for a listener in a hearing aid is described, which is also fixed by means of several rubber parts in position, these rubber parts must be fixed both on the handset as well as on corresponding housing parts.

EP 1 316 239 generically describes the use of multi-component injection molding technology for hearing aids on the basis of some examples of use. These are seals on the housing, sound channels for sound inlet and outlet and an elastic receiving cavity for transducers.

Finally, WO00 / 79835 shows a behind-the-ear hearing device in which an electrical / acoustic converter unit is provided with a loudspeaker housing, wherein the housing is resiliently mounted in an encapsulation such that encapsulation and loudspeaker housing define a gap. In the bearings, as used in the current state of the art, in particular the following draws:

The rubber parts used are relatively expensive to produce and a consistency of material properties (stiffness, damping) is not always guaranteed because of the small amounts of vulcanizate.

The mounting of the sometimes very thin-walled rubber mountings on the transducers is extremely delicate. On the one hand, a great deal of time in production associated with it, on the other hand, the acoustic stability of the hearing depends very much on the precision of the assembly. A slight deviation or displacement of the rubber parts can lead to tilting of the transducers in the hearing device housing and thus to mechanical feedback.

- Most bearings in the prior art do not allow separation of shock absorption and vibration isolation, because both functions must be covered with the same component - consisting of the same material.

Of course, there are also approaches to reduce the requirements for the storage of transducers. One is to make the transducer less susceptible to shock loads, such as e.g. in EP 0 993 759. In addition, there are also efforts by converter manufacturers to make the earphones less vibratory, as described for example in EP 1 248 496, US 6 751 326 or EP 127 442. These approaches are all in the right direction, but may be for one specific application in the hearing aid unsuitable because they increase the cost and / or size of the transducer.

Due to the above, it is accordingly an object of the present invention, a storage for to develop electronic components, such as a transducer, in a micro-electronic device, such as a hearing aid, which meets the main requirements below, namely to ensure vibration isolation of the component and a shock absorption in the event of a shock.

According to the invention, a device according to the wording of claim 1 is proposed.

The device for the damped storage of electronic components in a single or multi-part receiving housing of a micro electronic device according to the present invention is that an along, at least on parts of the inner wall of the receiving housing arranged elastic and / or flexible retaining element is provided, with in the direction of the interior the receiving inwardly projecting storage areas for in-situ bearings or holding the component in the receptacle.

As already mentioned, the device according to the invention for damping basically has two functions, namely the provision of vibration isolation on the one hand and shock absorption on the other hand. It has been found that for vibration isolation, the storage should have a low to very low stiffness and low attenuation. By contrast, contrary to the vibration isolation for shock absorption, storage must be much stiffer, with much higher internal damping of the material being desirable.

According to an embodiment variant of the present invention, it is proposed that the receptacle is coated or lined at least in part with an elastically soft and / or flexible material, elevations projecting from the layer being provided. These elevations may be ridge, cone, knob-like elevations, with, for example, pointed, dull or rounded bearing surfaces for the electronic component.

Again, according to a further embodiment, the lining or the holding element may consist of the same material as the above storage areas or protrusions protruding from the layer or for the storage areas or elevations, a different material may be selected to meet the above-mentioned, different requirements to cope with vibration isolation and shock absorption.

The holding element or the lining as well as the elevations or storage areas may consist of a thermoplastic elastomer (TPE). Particularly suitable are block copolymers such as, for example, a styrene elastomer (TPE-S) or a polymer blend such as a polyolefin elastomer (TPE-O) have been found. Depending on the application, however, other TPE types such as thermoplastic polyurethane (TPE-U) are also conceivable or also vulcanizates such as silicone rubber, etc.

Particularly suitable are materials with a Shore hardness> 25, preferably in the range of about 30 to 60.

Further preferred embodiments of the device according to the invention for the damping storage of an electronic component are characterized in the dependent claims.

For the production of the inventive device or the introduction of the damping retaining element in a receptacle of an electronic component there are different manufacturing options.

Thus, first of all, the retaining element can be produced, for example by means of injection molding, having the bearing areas and subsequently introduced into a receiving housing. Or the holding element or the elastic coating can in turn directly, for example by injection molding in a already existing receiving housing are entered, which receiving housing in turn may consist of a thermosetting or thermoplastic polymer.

Again, according to a further embodiment, it is possible to directly produce the receiving housing and the damping device by means of so-called 2K injection technique by simultaneously or in subsequent injection processes, the respective polymer is injected into the mold.

The invention will now be explained in more detail by way of example and with reference to the accompanying drawings. Showing:

1 is a schematic sectional view of a storage of an electronic component according to the prior art,

2 shows schematically in section the mounting of an electronic component according to the present invention,

Fig. 3 in a sectional perspective a possible

Embodiment of a damping bearing provided for the installation of an electronic component,

4 schematically shows the damping bearing of an electronic component, having a non-symmetrical center of mass.

5 shows a further embodiment of a damping storage,

Fig. 6 again in section another

Embodiment of one of the inventive damping and

Fig. 7a - 7d examples of damping elements suitable for a damping arrangement. The basis of the proposed invention is that the storage is integrated into the housing of the electronic device, such as the hearing aid, as shown in Figures 1 and 2 described below using the example of a listener storage. The main difference between the prior art shown in Figure 1 is that the bearing is no longer mounted on the transducer but becomes part of the hearing aid housing, as shown in Figure 2.

FIG. 1 shows schematically in section a transducer 1 which is arranged in a corresponding hearing device housing 3. For shock absorption or vibration isolation a rubber bearing 5 is provided, comprising outwardly projecting support ribs 7 for point storage.

In contrast, the transducer 1 as shown in Figure 2 is no longer stored in a rubber pad 5, but is "free" on support ribs 17, which is part of a damping insert, which is arranged directly on the inner surface of the hearing aid housing 3. This in turn has a rubber pad 15, with inwardly projecting support ribs 17 for point storage.

According to Figure 2, the cavity in the hearing aid, which accommodates the transducer, lined with a layer of a soft, elastic material which has sufficient wall thickness and rigidity to meet the above-mentioned requirements for shock absorption. From this layer protrude various conical or rib-like elevations 17, which provide for a defined positioning of the transducer 1. Due to the design of these support elements 17 whose rigidity can be adjusted in the direction of optimal vibration isolation. For example, these elements can be designed to be loaded primarily on thrust rather than pressure, resulting in much lower stiffness. A concrete application example of the invention will be shown below and with reference to FIG. 3: A receiver bearing is being developed, which is introduced directly into the hearing aid housing, for example, by means of a 2K injection molding process. In this case, the housing 3 is designed in several parts and in each part is a part of the integrated storage. This integrated storage has the following characteristics:

The primary bearing 25 made by a thermoplastic elastomer (TPE) by injection molding.

The storage is integrated directly into the housing 3 in one operation by means of 2K spray technology.

The connection between bearing 25 and housing 3 via adhesion according to the art of hard / soft compounds

The bearing 25 has enough wall thickness to intercept a shock.

The material has an average hardness and low resiliency, preferably having a Shore hardness in the range of 30 to 60. An example of this is a thermoplastic elastomer based on SEBS (styrene-ethylene-butylene-styrene).

The transducer rests on a plurality of thin tips 27, which have a very low rigidity.

The storage has lateral support ribs 28, which serve to fix the transducer.

The transducer can now be entered into the cavity provided for this purpose in the multi-part hearing device housing produced in this way. The housing further has an opening 21 for sound channel, sound tube, connections, etc. In addition to the above-described other features are of course conceivable: The bearing is integrated in a second operation in the housing, which must be inserted for this in an injection mold.

The connection between the bearing and the housing is supported not only by the pure adhesion but also by mechanical anchoring. That can be done by mechanical

Design elements (holes, rear handles, etc.) or by increasing the specific surface of the housing by chemical or physical etching as in particular in hearing aids often not enough space is available for mechanical anchoring.

The material of the storage consists of a hot vulcanised silicone, which is also processed by injection molding.

The storage also includes a seal of the housing and / or a seal of the sound outlet 21 at the same time.

Due to the configuration and the position of the support ribs 28 and support tips 27, a statically balanced storage can be established. It can be taken into account the fact that the excitation of the listener is not symmetrical. This approach is shown schematically in FIG. Due to the internal structure of the transducer, the center of mass M or 14 is outside its geometric center. In order nevertheless to achieve a statically balanced storage, the support tips can be designed so that, for example, support tip 18, which is closer to the center of mass, has a higher rigidity than the other tip 16. This can of course theoretically be achieved with today's bearings, but In this case, the installation specifications become even narrower because the symmetry of the bearings is eliminated. Figure 5 shows in section a further embodiment of an inventive damping arrangement for the storage of an electronic component 1. Again, a damping layer 15 is disposed in the rigid receiving wall 3 of a micro electronic device, consisting of an elastic material, as described above. As in the preceding examples, inwardly projecting projections 17 are also provided for supporting the component 1. In addition, in FIG. 5, air pockets 31 are formed in the inwardly projecting projections 17 to provide an additional damping effect. These damping air pockets 31 may be formed relatively small as shown in Fig. 5 or as shown schematically in Fig. 6 and provided with the reference numeral 35 may be formed such that the inwardly projecting projection 37 is formed like a pillow or leaf spring. On the one hand, this can increase the damping effect, but on the other hand, this reduces the storage stability.

Further recognizable in FIG. 5 are rear handles 33, which allow a better connection or even a non-adhesive connection between the damping layer 15 and the rigid housing wall 3.

Illustrated in FIGS. 7a to 7d are examples of inwardly projecting projections 17 which are intended to demonstrate that any shapes are possible for achieving suitable damping or to be selected as required. 7a shows a cone-like projection, FIG. 7b shows a rib, while FIG. 7c shows a cushion-like or leaf-spring-like damping element 17 analogous to FIG. Similarly, a leaf spring-like damping element 17 is shown in Fig. 7d, which is arranged in a corner region of the receiving housing 3. To reinforce the damping, in turn, a cavity 35 is provided. The advantages of the present invention are that the manufacturing costs for the damping storage can be reduced:

The cost of Guinitiiteile falls away.

The assembly effort is significantly reduced by integrating the bearings, as not only the soft rubber mountings must be individually drawn over the transducer, but the converter can be easily inserted into the space provided for this purpose.

The ease of assembly also increases the production tolerance as it becomes more difficult to incorporate the transducers incorrectly.

By integrating the bearings, new designs can be realized, which can lead to a higher reliability and more reinforcement by the extensive separation of the two functions "vibration isolation" and "shock isolation".

By integrating the bearings, a type of bearing can be realized that is precisely optimized for a particular transducer. In particular, statically balanced bearings can be realized more easily, without elaborate installation instructions created or additional rubber parts must be mounted.

Of course, the damping devices or bearings shown with reference to FIGS. 1 to 7 are only examples of the better understanding of the present invention. The bearings or dampings are of course not limited to the illustrated examples, but it can also be used different bearings or damping devices, which for example have different wall thicknesses, different stiffnesses of the materials, different geometries or embodiments of projecting storage areas or elevations, different manufacturing techniques, etc., etc. The essence of the present invention is that the damping element or the damping bearing is arranged on the housing inner wall of the electronic construction device for positioning and holding an electronic component, wherein the damping Element facing the interior and has projecting storage areas.

Claims

claims

1. A device for the damped storage of electronic components in a receiving housing of a micro electronic device, characterized by a along at least parts of the inner wall of the receiving housing (3) arranged, elastic and / or flexible holding element (15) with inwardly projecting storage areas (17) for in Position Storing or holding the component (1).

2. Apparatus according to claim 1, that the receptacle (3) is coated or lined at least in part with an elastic, soft and / or flexible material (15), wherein from the layer (15) projecting elevations (17) are provided.

3. Device according to one of claims 1 or 2, characterized in that elastic and / or flexible material has a Shore hardness of> 25, preferably 30 to 60 has.

4. Device according to one of claims 1 - 3, characterized in that the storage areas or elevations (17) are rib-shaped, conical or knob-like, preferably with pointed or rounded bearing surfaces for the component (1).

5. Device according to one of claims 1 to 4, characterized in that the holding element or the flexible material (15) and the inwardly projecting storage areas or elevations (17) made of a thermoplastic elastomer

(TPE) exist, such as a styrene elastomer, a polyolefin elastomer, a thermoplastic polyurethane or a vulcanizate such as silicone rubber, etc.

6. Device according to one of claims 1 to 5, characterized in that the holding element or the elastic or flexible material has a different stiffness or softness than the storage areas or inwardly projecting elevations (17), wherein preferably the holding element or the material has a higher rigidity than the inwardly projecting storage areas or elevations.

7. Device according to one of claims 1 to 6, characterized in that the storage areas or elevations (17) have different geometries and / or have different stiffness or elasticity, especially in non-symmetrical arrangement of the center of mass of the component to be stored.

8. Device according to one of claims 1 to 7, characterized in that in the holding element or the elastic or flexible layer (15) and / or in the inwardly projecting elevations (17) air inclusions (35) are provided to a leaf spring-like damping to enable.

9. A method for producing a device according to one of claims 1 to 8, characterized in that the holding part or elastic or flexible material together with the projecting storage areas or elevations by pouring or injected by injection into a receiving housing of the electronic component or injected becomes.

10. A method for producing a device according to one of claims 1 to 8, characterized in that both receiving housing of the electronic component as well as the elastic and / or flexible storage area for the damping bearings of the component are produced by means of so-called 2K spray technique.

11. A method for producing a device according to one of claims 1 to 8, characterized in that the connection of the elastic and / or flexible storage areas in the receiving housing of the electronic component via adhesion of the both materials by injection molding or by forming mechanical anchors.

12. Use of the device according to one of claims 1 to 8 or prepared by a method according to claims 9 to 11 for supporting an electronic transducer or receiver part in a receiving housing of a hearing aid.