Micromechanical sound transducer system and corresponding manufacturing method

Abstract

A micromechanical sound transducer system includes a substrate that includes (a) a cavity with a cavity edge area, (b) a front side, and (c) a rear side; a piezoelectric vibrating beam that is elastically suspended on the front side and that extends across the cavity; and, for the piezoelectric vibrating beam, a respective deflection limiting device that is on a front edge area of the respective vibrating beam and that is configured to limit a deflection of the respective vibrating beam to a limiting deflection by causing the respective front edge area of the respective vibrating beam to interact with the cavity edge area or an opposing front edge area of another vibrating beam.

Claims

1. A micromechanical sound transducer system, including: a substrate having a cavity with a cavity edge area, a front side, and a rear side; at least two front piezoelectric vibrating beams, each of which is elastically suspended on the front side and which extends across the cavity towards the rear side; at least two rear piezoelectric vibrating beams, each of which is elastically suspended on the rear side and which extends across the cavity towards a corresponding one of the front piezoelectric vibrating beams of the front side, so that there at least two pairs of front and rear piezoelectric vibrating beams; and a respective deflection limiting device, connecting each of the at least two pairs of front and rear piezoelectric vibrating beams, which is on a front edge area of a respective one of the vibrating beams and which is configured to limit a deflection of the respective vibrating beam to a limiting deflection by causing the respective front edge area of the respective vibrating beam to interact with an opposing front edge area of the corresponding one of the vibrating beams, which forms a corresponding one of the pairs.

2. The micromechanical sound transducer of claim 1, wherein the front and rear piezoelectric vibrating beams includes a plurality of piezoelectric vibrating beams, and the deflection limiting device connects to each other opposing front edge areas of a respective pair of the vibrating beams to thereby cause the interaction.

3. The micromechanical sound transducer system of claim 2, wherein the deflection limiting device is a hook-like or comb-like integral molding configured to cause the opposing front edge areas to stop at a maximum deflection and thereby cause the interaction.

4. The micromechanical sound transducer system of claim 1, wherein the deflection limiting device is a respective elastic strip device that mechanically connects to the cavity edge area of the respective front edge area of the respective vibrating beam on which the deflection limiting device is positioned to cause the interaction.

5. The micromechanical sound transducer system of claim 4, wherein the respective elastic strip device is a non-linear spring device.

6. The micromechanical sound transducer system of claim 4, wherein the respective elastic strip device is formed of at least one of a polymer, an AIN, and a metal.

7. The micromechanical sound transducer system of claim 3, wherein, in a non-deflected state of the front and rear piezoelectric vibrating beams, the deflection limiting device is situated in a plane of the vibrating beams.

8. The micromechanical sound transducer system of claim 2, wherein the deflection limiting device is a hook-like integral molding or a comb-like integral molding.

9. A method for manufacturing a micromechanical sound transducer system, the method comprising: providing a substrate having a cavity with a cavity edge area, a front side, and a rear side; forming at least two front piezoelectric vibrating beams, each of which is elastically suspended on the front side and which extends across the cavity towards the rear side; forming at least two rear piezoelectric vibrating beams, each of which is elastically suspended on the rear side and which extends across the cavity towards a corresponding one of the front piezoelectric vibrating beams of the front side, so that there at least two pairs of front and rear piezoelectric vibrating beams; and forming a respective deflection limiting device, connecting each of the at least two pairs of front and rear piezoelectric vibrating beams, which is on a front edge area of a respective one of the vibrating beams and which is configured to limit a deflection of the respective vibrating beam to a limiting deflection by causing the respective front edge area of the respective vibrating beam to interact with an opposing front edge area of the corresponding one of the vibrating beams, which forms a corresponding one of the pairs.

10. The method of claim 9, wherein the front and rear piezoelectric vibrating beams includes a plurality of piezoelectric vibrating beams, and the deflection limiting device connects to each other opposing front edge areas of a respective pair of the vibrating beams to thereby cause the interaction.

11. The method of claim 10, wherein the deflection limiting device is a hook-like or comb-like integral molding configured to cause the opposing front edge areas to stop at a maximum deflection and thereby cause the interaction.

12. The method of claim 9, wherein the deflection limiting device is a respective elastic strip device that mechanically connects to the cavity edge area of the respective front edge area of the respective vibrating beam on which the deflection limiting device is positioned to cause the interaction.

13. The method of claim 12, wherein the respective elastic strip device is a non-linear spring device.

14. The method of claim 12, wherein the respective elastic strip device is formed of at least one of a polymer, an AIN, and a metal.

15. The method of claim 11, wherein, in a non-deflected state of the front and rear piezoelectric vibrating beams, the deflection limiting device is situated in a plane of the vibrating beams.

16. The method of claim 10, wherein the deflection limiting device is a hook-like integral molding or a comb-like integral molding.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

(1) FIG. 1 shows schematic representations of a micromechanical sound transducer system, and in particular a top view in part (a) and a vertical cross section along line A-A of part (a) in parts (b)-(d) in various deflection states, according to an example embodiment of the present invention.

(2) FIG. 2 shows a top view of a schematic representation of a micromechanical sound transducer system, according to an alternative example embodiment of the present invention.

(3) FIG. 3, parts (a)-(c) show schematic partial cross-sectional illustrations of a modification of the elastic strip device of the first and second example embodiments in various deflection states, according to an example embodiment of the present invention.

(4) FIG. 4 show schematic representations of a micromechanical sound transducer system, and in particular a top view in part (a) and a vertical cross section along line B-B of part (a) in parts (b)-(c) in various deflection states, according to an alternative example embodiment of the present invention.

DETAILED DESCRIPTION

(5) In the figures, identical reference numerals denote identical or functionally equivalent elements.

(6) In FIG. 1, reference S denotes a substrate having a front side V and a rear side R and a cavity K having a cavity edge area KR.

(7) A first through sixth piezoelectric vibrating beam Z1 through Z6, which extend across cavity K, are elastically suspended on front side V of substrate S. Vibrating beams Z1 through Z6 are situated in pairs opposite each other, the pairs being formed by vibrating beams Z1 and Z2, Z3 and Z4, and Z5 and Z6. A gap SP, which ensures the elastic deflectability of vibrating beams Z1 through Z6, is provided toward cavity edge KR and on respective front edge areas ST1 through ST6.

(8) A deflection limiting device E1-E3 is provided between the front edge areas of opposing pairs ST1 and ST2, ST3 and ST4, ST5 and ST6, which is configured in such a way that it causes opposing front edge areas ST1 and ST2, ST3 and ST4, ST5 and ST6 to interact in order to limit a deflection of the pairs of vibrating beams Z1 and Z2, Z3 and Z4, Z5 and Z6 to an upper and a lower limiting deflection h1. Upper and lower limiting deflections h1 can, but need not, be symmetrical, and are to be activated in such a way that the desired acoustic spectrum of the sound transducer system is achievable.

(9) In the first example embodiment, deflection limiting device E1-E3 is a respective elastic strip device, which is manufactured, for example, by a deposition and structuring process, and mechanically connects opposing front edge areas ST1 and ST2, ST3 and ST4, ST5 and ST6 and thereby causes the interaction.

(10) Elastic strip devices E1-E3 are preferably implemented using polymers.

(11) Part (b) of FIG. 1 shows the non-deflected position of vibrating beams Z5, Z6 of the sound transducer.

(12) Part (c) of Figure shows the upper limiting deflection of vibrating beams Z5, Z6 of the sound transducer in a position where elastic strip device E1 through E3 not yet or hardly influences the deflection behavior. Elastic strip device E1 through E3 extends continuously and preferably does not generate an additional restoring force. Upper limiting deflection h1 defines the operating range of the sound transducer system, for example of a microphone system. As a result, the maximum sound pressure level to be detected should be within this operating range.

(13) Part (d) of FIG. 1 shows a case in which an excessively high sound pressure or extreme shock is present. A further deflection of vibrating beams Z5, Z6 beyond upper limiting deflection h1 is avoided with the aid of elastic strip devices E1 through E3. At a certain tension of elastic strip devices E1 through E3, a restoring force occurs, which prevents further deflection. This is apparent in part (d) by inflection points in the curvature of vibrating beams Z5, Z6.

(14) FIG. 2 shows a schematic representation of a micromechanical sound transducer system according to a second example embodiment of the present invention in a top view.

(15) In the second example embodiment according to FIG. 2, first through fourth vibrating beams Z1 through Z4 are suspended on front side V, which extend across cavity K and which have respective front edge areas ST1 through ST4. Vibrating beams Z1 through Z4, in turn, are spaced apart from cavity edge KR and from adjoining vibrating beams by a gap SP to ensure the elastic deflectability.

(16) In this second example embodiment, a respective elastic strip device E1 through E4 is provided between a respective front edge area ST1 through ST4 and cavity edge area KR to limit the deflection of respective vibrating beams Z1 through Z4 to a limiting deflection.

(17) The deflection limiting device in the form of the elastic strip device in the second example embodiment is designed similarly to the first example embodiment.

(18) The function is also similar to that which has already been described with respect to parts (b)-(d) of Figures.

(19) FIG. 3 shows schematic partial cross-sectional illustrations of a modification of the elastic strip device of the first and second example embodiments in various deflection states.

(20) FIG. 3 shows a possible embodiment of deflection limiting device E, which can be used with the first and second example embodiments. Elastic strip device E is designed as a non-linear crimped spring device here. Part (a) of Figure shows the non-deflected state, part (b) of FIG. 3 shows the deflected state to the limiting deflection, and part (c) of FIG. 3 shows the case in which an undesirable shock or an excessive sound pressure level is present. In the latter case, a further deflection is prevented by the non-linear behavior, the configuration preferably being in such a way that the restoring force of the spring device occurs preferably suddenly.

(21) FIG. 4 shows schematic representations of a micromechanical sound transducer system according to a third example embodiment of the present invention, in which two vibrating beams Z1, Z2 are elastically suspended as a pair opposite each other on front side V, which extend across cavity K. In this third example embodiment, a respective hook-like integral molding H1, H2 is situated on opposing front edge areas ST, ST2 as deflection limiting device H1, H2, which causes opposing front edge areas ST1, ST2 to stop in the limiting deflection h1 and thereby causes the interaction.

(22) In the non-deflected state of vibrating beams Z1, Z2, hook-like integral moldings H1, H2 are situated in a plane of vibrating beams Z1, Z2, as is apparent from part (b) of FIG. 4, and engage each other.

(23) Opposing integral moldings H1, H2 only interlock in the upper or lower limiting deflection, as shown in part (c) of FIG. 4, and thus abruptly limit upper or lower limiting deflection h1.

(24) This third example embodiment has an advantage that hook-like integral moldings H1, H2 can be created in the same manufacturing process as vibrating beams Z1, Z2 and from the same materials, for example silicon or polycrystalline silicon or piezoelectric materials, such as AIN or PZT, or metals, which are typically used as electrodes (Mo, Pt, W). The third example embodiment is thus even simpler to manufacture compared to the above-described first and second example embodiments.

(25) Additionally, there is no interaction whatsoever between two vibrating beams Z1, Z2 in the third example embodiment until upper or lower limiting deflection h1 is reached.

(26) Although the present invention has been described above based on preferred exemplary embodiments, it is not limited thereto, but is modifiable in a variety of ways. In particular, the described geometries and materials are also only provided by way of example and can be varied depending on the application. Even though mutually engaging hook-like integral moldings are described as the deflection limiting device in an above-described example embodiment, it is also possible to use comb-like integral moldings.