DE2116573A1 - Structure-borne noise-compensating microphone - Google Patents

Description

Structure-borne noise compensating microphone The invention relates to a microphone with several electroacoustic transducers that are electrically switched are that the interference voltages generated in them by structure-borne noise conduction essentially cancel. The transducers work preferably according to the piezoelectric and / or according to the piezoresistive principle.

Compared to the carbon microphones commonly used in telephone handsets have the piezoelectric. Microphones have the advantages of higher distortion attenuation, lower noise and better temporal constancy, but they show significantly higher sensitivity to body reverberation. On the one hand, the reasons lie in a so-called threshold value effect the sensitivity of the carbon microphones, but on the other hand in the greater rigidity and Nasse, which is much smaller and thicker than the carbon microphone piezoelectric membrane. With the same transmission reference attenuation of the two microphone systems Because of its higher airborne sound excitation, the coal system has the larger one and a lighter membrane, less sensitivity to structure-borne noise.

The disadvantages of the transmission of structure-borne noise can be seen in z. B.

in the amplified sound reproduction when moving the TTandaT) ready-to-use cord or in the feedback whistling with loudspeakers at the distant participant, if by structure-borne sound transmission from the telephone via the handset to the microphone the acoustic attenuation is too small.

There are various measures for the transmission of structure-borne sound in telephone handsets to belittle. It is thus effective to make the microphone larger in size and to be stored soft and elastic in the handset. These mechanical However, funds are often not enough.

Compensation microphones are also known, the purpose of which is mostly is to pick up the room noise at a reduced level when viewing at close range. So shows the German Auslegeschrift 1 114 539 Fig. 7 and 8 a microphone arrangement, the two individual Has transducer and two fin-speaking openings.

From one of the opening, cannulas guide the room sound to the front one and the back of the other transducer membrane and the other injection port Cannulas to the back of one and the front of the other transducer membrane. never Microphone voltages generated by the two converters are electrically connected in opposition, that they cancel each other out for room sound, but as far as possible for the protective sound add only to the one opening.

This microphone arrangement would pick you up from the same direction Both diaphragms reproduce structure-borne sound impacting like the useful sound and do not compensate like the room hall. Already the task of this interpretative document so differs from that of the invention.

In contrast, the present invention addresses the problem of in a microphone containing a plurality of transducer elements to compensate for the structure-borne noise and solves the problem in that the randler elements conduct sound-borne sound with one another that they generate tensions through structure-borne noise when they are excited together, which essentially compensate each other through counter-connection and that each transducer element in the case of joint excitation by useful sound, the useful sound is supplied from the direction receives that the voltages generated essentially add up.

The transducer elements are advantageously composed of piezoelectric ones Circular plates installed coaxially in a cylindrical housing at a distance are. The rsum between the two circular plates becomes the useful sound through holes so that the plates move in phase outwards and inwards.

In a particularly advantageous embodiment of the inventive concept the transducer elements consist of diaphragm domes, which - with niezoelectric and / or Piezoresistive layers provided - are glued to a sheet of rice, whereby the convex sides of the domes of the useful echo is fed in phase.

In this case, the membrane backs that are not acted upon are acoustical tightly closed by cavities.

In a further embodiment of the invention, the active layers are the piezoelectric and / or piezoresistive transducer using the vapor deposition process applied to an aluminum membrane and provided with contact layers.

Further forms of embodiment of the invention emerge from the description and the drawing; this shows in Fig. 1 an axial section through a cylindrical Microphone housing with two transducer circular plates, Fig. 2 the section through the two bilaminar piezoelectric circular plates according to FIG. 1 with indication of the direction of formation and electrical connections, Fig. 3 a step through a Nikrofon with two Dome-shaped transducer elements that are exposed to sound from the outside.

The embodiment according to FIG. 1 represents a cylindrical, closed at the top Housing 1 represents, dn.s is closed with the cover 2. Between the rings of aging 3 and 4 are the two circular plate-shaped transducer elements 5. through the bores 6 in the housing part 1 and the ring 4 between the two circular plates 5 the useful sound is fed in such a way that the two inner sides of the transducer elements are excited in phase; the two outer sides are closed off by the cavities 11.

In Fig. 2 is an enlarged section through the two bilaminar Piezoelectric transducer elements shown with arrows, in which direction the individual ceramic plates from z. B. barium titanate were electrically formed. As is well known occur radially when the panels bend due to the acoustic irradiation Pressures and pulls on, which in turn appear as pressures and pulls on the thickness of each piezoelectric plates.

These fluctuations in the thickness of the panels are the cause of the electrically conductive paving 10 (highlighted in black in the drawing) occurring, in, their polarity changing voltages. So that the partial stresses of the transducer elements glued together from two plates. add up if in the one plate a pressure and in the other a tension occurs, the two plates must of a converter like in Pig. 2 shown, opposite, polarized opposite. To the Explanation of the polarization should only be noted that it is the parallel position of the elementary dipoles with the application of an approximately 3000 V DC field in Direction of the arrow and heating of the polycrystalline ceramic material.

If the sound pressure is fed between the transducer elements according to FIG. 1, so in Fig. 2 the upper element bends with the one sound pressure half-wave right end shown aborted, for example, upwards while at the same time dna bends lower with the corresponding end nacli below. To those of the same kind To connect converter elements generated the same voltages in series, the from the plate assignments 10 outgoing connecting lines crossed as shown to the microphone connector be guided. The conductive connection at the joint between the two plates of a transducer is usually not led out. It is within the scope of the invention to use a different way of connecting the e.g. connect Uu via bridges and transformers or the plate voltages for purposes Better adaptation to the lower internal resistances of the connected barley not to be connected in series but in parallel.

The compensation of the stresses generated by structure-borne noise on the both transducer elements is based on the Pig. 1 explained as follows: During the useful sound entering through the holes 6, the insides of the two transducer elements 5 are in phase excited, whereby - as described above - the partial voltages of the transducer elements add at the terminals, the structure-borne sound hits the one transducer element from the inside, the other from the outside. The ones from the transducer elements The voltages generated are of the same size, but in phase opposition and at the terminals 7 they cancel each other out due to the electrical circuit. Is the source of structure-borne noise for example below the microphone shown in Fig. 1, then transmits the housing 1 to the lower transducer element 5 the structure-borne noise from the side of the lower Kemmer 11 and onto the upper transducer element 5 from the side of the middle chamber the holes 6. These different phase positions of the useful and structure-borne noise voltages establishes the addition in the first case and the compensation of the in the second case Tensions of the individual elements.

In Fi. 3 and the two round transducer elements 9 by means of spherical diaphragms formed and glued to the Kreissoheibe 8 akuntisch tight. In this version According to the invention, the useful sound is in phase not the inside but the outside the transducer elements 9 supplied.

In this case, the air cushions of the closed chambers 11 are located on the circular disc 8.

While the piezoelectric. Tensions in Figures 1 and 2 through Earth generated by piezoceramic disks is the active niezoelectric or piezoresistive Material in FIG. 3 is vaporized onto thin metal membranes 9. As vapor deposition materials e.g. selenium, tellurium, gallium or indium antimonide, or according to DBP 1 226 647 selenium with a barrier layer-forming cadmium indicated. To the Contacting, of which only the soldering connections are indicated in FIG. 3 in the form of black semicircles are suitable e.g. Bismuth.

It is within the scope of the invention, the metal membranes only inside, only, to be vaporized on the outside or on both sides and the coverings accordingly 10 to interconnect.

In the case of electroresistive materials, it is advisable to use the connections 7 to switch on a DC voltage. It is important that the generated voltages or the resistance fluctuations generated in piezoresistive materials, if possible are the same and that, according to the invention, they occur when arriving from two directions Add useful sound and compensate for structure-borne sound arriving from a direction.

In the embodiment according to Fig; 3 is the body-sound conductive connection between the two-n transducer elements in the form of the circular bar 8, especially the over the softest possible attachment of this plate in the handset housing and the possible Structure-borne sound transmitted through stranded connecting wires is transmitted evenly to both Diaphragms passed on.

The low mass of the vaporized has also proven to be advantageous Membrane, which further reduces the microphone's sensitivity to structure-borne noise will.

Claims (8)

P a t e n t a n s p r ii c h e 1. Body scale compensating microphone, especially piezoelectric Microphone whose at least two similar transducer elements are so electrical are connected to each other that the output voltages generated by useful sound substantially support each other, characterized in that the transducer elements (5, 9) are connected to one another so that they are conductive to structural sound, deß when they are shared Excitation through structure-borne noise generates tensions that result from counter-switching in the substantially compensate and that each transducer element (5, 9) with common excitation by useful sound, the useful sound is supplied from the direction that the generated Tensions essentially add up. 2. Microphone according to claim 1, characterized in that the transducer elements designed as bilaminar piezoelectric circular plates (5) and in a cylindrical Housing (1) are arranged coaxially at a distance from one another that the useful sound through holes (6) in the cylindrical housing (1) in this way between the circular plates (-5) is introduced that they move outwards and inwards in phase and that the sum of the electrical voltages generated due to the piezoelectric Polarization of the circular plates (5) and the interconnection of their linings (10) arise. 3. Microphone according to claim 1, characterized in that the converter elements (9) as diaphragm domes with piezoelectric and / or piezoresistive layers (9) are executed, dip - preferably on a heavy circular plate opposite them (8) acoustically serves glued on - in phase with from their convex sides the useful sound are applied. 4. Microphone according to claim 1 to 3, characterized in that the Rear sides of the transducer elements (5, 9) that are not exposed to useful sound acoustically tight cavities (11) are closed. 5. Microphone according to claim 1 to 4, characterized in that the Microphone artificially weighted, softly supported with structure-borne sound-absorbing material and is electrically connected via flexible strands. 6. Microphone according to claim 3, characterized in that the piezoelectric and / or piezoresistive layers and their contact layers (10) are vapor-deposited are. 7. Microphone according to claim 2, 3 and 6, characterized in that the piezoelectric layers by a high electric field under simultaneous Warming are formed. 8. Microphone according to claim 3 and 6, characterized in that the active layers of the transducer elements (9) are supported by aluminum membranes.