DE7022626U - BODY SOUND MICROPHONE - Google Patents

Description

F 4 H Schumann GmbH 4051 Hirsbeck Wevelinghoven 30

Structure-borne sound microphone

The innovation relates to a body microphone with a rod-shaped, electroactivity converter to piezoelectric Base.

A structure-borne sound microphone converts the vibrations picked up by a button directly into electrical vibrations by means of a piezoelectric carding element

There are structure-borne sound microphones where the ceramic transducers are in soft, thermoplastic molded pieces are stored, and in which the coupling of the button to the transducer element also takes place via soft plastic molded pieces.

With this structure, friction and congestion occur under the bearings and fittings and the internal structure of the microphones that falsify the transmission of the signals. Furthermore, the plastic becomes the bearing when the temperature rises softer, so that the clamping of the ceramic transducer elements becomes looser. This results in a proportional Decrease in sensitivity.

The innovation is based on the task of creating a temperature-resistant bearing for the ceramic transducer and eliminating deformation friction and congestion on the bearings and fittings. to avoid ken.

24 175 HC / Tn. - 2 -

According to the innovation, there is a structure-borne sound microphone of the above type, the mounting of the piezoelectric transducer from one or more suspension elements, the Pederungskraft within the relevant temperatures temperature independent? is.

A bracket for the piezoelectric transducer is both a bracket opposite the housing and the button Roger that.

10

As a refinement, the innovation suggests that transmission of the structure-borne noise from the button to the transducer

Suspension element is attached, the suspension force of which is temperature-independent within the temperatures in question is, and that a plastic molding is attached to the transducer to which the suspension element is attached.

As an alternative, the innovation suggests that the ends of the piezoelectric Wanlers in plastic molded pieces are attached, which are connected to the inner housing and from one within the temperatures under consideration temperature-independent, hard plastic.

Three exemplary embodiments are shown in the drawings and are described in more detail below. It show:

Fig. 1 is a plan view of the first and second embodiment the structure-borne sound microphone,

FIG. 2 shows a cross section through the first embodiment of the structure-borne sound microphone according to FIG. 1, along the line II,
35

Pig. 3 is a plan view of the first version of the

Structure-borne sound microphones with partially removed cover plate,

Pig. U a holder for the converter element, j

5 shows a cross section through the second embodiment j of the structure-borne sound microphone according to FIG. 1, along | of the line I-I, |

I.

6 is a plan view of the third embodiment of the | Structure-borne sound microphones, jj

Fig. 7 shows a cross section through the third embodiment \ of the structure-borne sound microphone according to Fig. 6, along 1

the line U-II. \

The structure-borne sound microphone consists of a plastic inner housing 8, which is surrounded by a protective metal housing 11. give is. The metal protective housing has openings for a button 10 which picks up the structure-borne sound vibrations. The ceramic transducer element 1 is divided by two Plastic molded parts 5 mounted on two spiral springs 2, the resilience of which is within the range in question

Temperatures is independent of temperature. The

Plastic molded parts 5 represent an insulation between the spiral springs 2 and the silver coatings 3 and 4 of the transducer 1.

In the first embodiment, the body-borne sound microphone has a coupling element 9> made of plastic which transmits the structure-borne noise from the button 10 to the converter 1.

In the second embodiment, the structure-borne sound microphone has a spiral spring 13 instead of the coupling member 9, the Suspension force within the coming in bed wire

Temperatures is independent of temperature, and a plastic molded part 12 between the spiral spring 13 and the transducer 1.

The third embodiment differs from the second embodiment in that the ends of the piezoelectric

Converter 1 are firmly clamped in plastic molded pieces 15 which are firmly connected to the inner housing 19 and consist of a hard plastic that is temperature-independent within the temperatures in question. 10

Protection claims:

Claims (5)

Protection claims: Ι = ^: personal microphone with rod-shaped !!!, electroacoustic transducer on a piezoelectric basis, characterized in that the holder of the piezoelectric transducer (1) consists of one or more suspension elements (2, 13 * 17), the resilience of which is within the temperatures in question is temperature independent. 2. Structure-borne sound microphone according to claim 1, characterized in that for the transmission of the structure-borne sound from the Pushbutton (10) to the transducer (1) a suspension element is attached, the suspension force within the into consideration coming temperatures is independent of temperature. 3. Structure-borne sound microphone according to claim 2, characterized in that that on the converter (1) a plastic i-'ormteil (12) is attached to which the suspension element (13) is attached. 4. Structure-borne sound microphone according to one of claims 1 to 3 » characterized in that the ends of the piezoelectric transducer (1) are fastened in molded plastic pieces (15) which are connected to the inner housing (19). 5. Structure-borne sound microphone according to claim 4, characterized in that the shaped pieces (15) from a within the in Considered temperatures consist of temperature-independent, hard plastic. 7Π / 9 R? Pl; /. ο