FI57680B - FREQUENCY REQUIREMENT FOR ELECTRIC MICROPHONE WITH ETC GRAPHIC BUTTON - Google Patents

Description

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The Patent and Registration Board '7 amMcm expense and the issue public · »* 30.05.80 (32) (33) (31) Pyydetty utuolkuu * - Improved priority 15.08.74

Ruotsi Sweden (SE) 74ΐθ4θ8-4 (71) 0 / Y L M Ericsson A / B, 02420 Jorvas, Suomi-Finland (FI) (72) Nils Alee Martin Andersson, Nynäshamn, Rolf Bertil Göran Jönsson,

Tyresö, Ruotsi-Sweden (SE) (74) Oy Kolster Ab (54) Procedure for the production of an electret microphone with a carefully determined air gap - Menetelmä elektreetti microphone valmistamisexi, jossa on tarkoin määrätty ilmaväli

The invention relates to a method for producing an electret microphone with a precisely determined air gap, comprising a first process step in which a first plastic film is polarized and a second plastic film metallized, and a second process step in which these plastic films are mounted as a moving electrode on top of a fixed electrode. electrode.

Swedish patent specification 362 572 describes an electret microphone of the type defined above. Between these movable and fixed electrodes, air gaps are formed as a result of microcopic irregularities in the surfaces of the plastic films and the fatty electrode. These microcopic air gaps give the electret microphone a high capacitance and thereby a high sensitivity. One disadvantage, however, is that variations in sensitivity can occur due to the fact that the air gaps are not sufficiently precisely determined. Canadian Pat. which constitute a moving electrode. This electret microphone can be given a more precisely determined air gap at the cost of an increased cost of producing the electret film. However, the tension of the diaphragm is here also similar to the electret microphone according to the above mentioned Swedish patent. There is a risk that the diaphragm will stretch when temperature changes and after a long time, the air gap will change.

The invention relates to a method for producing an electret microphone which can be given a precisely determined air gap without the clamping of the membrane being! critical. The process is characterized according to the following claims.

The invention will now be described in more detail with reference to the accompanying drawing, in which Fig. 1 shows a sectional view of an electret microphone having a precisely determined air gap according to the invention, Fig. 2 shows a sectional view of a device for producing an electret to the electret microphone in Fig. 1. Figs. 3 and k show a top and sectional view, respectively, of a detail of the device of Fig. 2, and Fig. 5 shows an alternative device for producing the electret.

Fig. 1 shows a sectional view of an electret microphone comprising a solid electrode in the form of a metallic base plate 1 and a movable electrode consisting of a first and a second membrane 2 and 3 respectively mounted on the base plate 1. The membranes 2 and 3 are arranged to pivot in The polyester film is provided with a metallic layer U and the teflon film constitutes an electret in which electrical charges are stored in a known manner, the latter being cascaded on the impact of acoustic walls and consisting of a polyester film and a "Teflon" film (registered trademark). in addition, given a relief structure as described in more detail below.

The low temperature expansion coefficient of the polyester film, approx. 27 x 10 6 / ° C allows the sensitivity of the electret microphone to be relatively independent of temperature, while the high resistivity of the Teflon film, 2 x 10 10 ohm meters, ensures a very slow discharge process for said charges.

The electret microphone has an insulating housing 5 provided with acoustic windows 6. The metallic base plate 1 is designed in known manner to have air ducts 7. Acoustic walls are intended to enter through the windows 6 and affect the cascading membranes 2 and 3, whereby a signal voltage may be drawn between an electrical connection 8 to the metallic base plate 1 and another electrical connection 9 to the metallic surface layer k of the membrane 2. The connection 8 is designed to spring against the base plate 1.

Fig. 2 shows a sectional view of a polarization furnace for producing electrons to the electret microphone of Fig. 1. According to the example, five teflon films 10 measuring 70 x 70 x 0.012 mm and six glass weaving discs 11, which will be described in more detail, are stacked vertically between a lower and an upper metal electrode are arranged to be measured with a direct voltage of about 10 kV, respectively.

The upper electrode 13 is surrounded by an insulating housing 1U against which a screw 15 in a clamping jaw 16 abuts to compress the stack, and the lower electrode 12 is embedded in a foot 17 of the clamping jaw 16. The latter, which thus consists of insulating material , further comprises fasteners for a heating coil 18 arranged to be measured with an alternating voltage of 220 V.

A hood 19 encloses the stack of Teflon films 10 and glass fabric sheets 11 during heating by the heating coil 18. Just before the melting point of the Teflon films 10 is reached, the temperature is stabilized by controlling the alternating voltage to the heating strip 18 by means of a thermostatic coupling not shown, and the DC voltage is applied. then a current that drops to a constant value over the course of a few tens of minutes. When this is essentially sectional, the alternating voltage of the heating coil 18 is completely broken and the polarization furnace is cooled by compressed air through inlets and outlets 20 and 21. Finally, the DC voltage is also disconnected to the electrodes 12 and 13, the hood 19 is raised and the teflon films 10 which now constitute finished electrons are removed.

Figures 3 and k show a top and sectional view, respectively, of the glass weave sheets 11 of Figure 2. These each comprise two glass fabrics having fibers · 22 consisting of several threads 23 and fixed by gluing on respective sides of an insulating sheet 2k having satisfactory resistivity and shape control and, which according to the example consists of "Kapton". If the stack of Teflon films 10 and glass weave sheets 11 in Fig. 2 is compressed by the clamping jaw 16 and heated by the heat coil 18, the glass weave samples are hot-stamped on both sides of the Teflon films 10. These thereby obtain a microscopic relief structure and after cutting and mounting in the membrane 3 the membrane 3 Fig. 1 shows a carefully determined air gap without the tensioning of the membrane 2 or 3 becoming critical either during mounting or with respect to fire effects.

Fig. 5 shows an alternative device for producing electret to the electret microphone in Fig. 1. A Teflon film 25 wound on a roll 26 is arranged to be drawn between two rollers 27 and 28 which are heated to a temperature below the melting point of Teflon film 25 and whose mantle surfaces. are given a relief structure molded from the example of a glass fabric of the kind shown in Fig. 3.

This relief structure is heat embossed on both sides of the Teflon film 25 which is then arranged to pass a polarizing means 29 and finally as the finished electrics are wound on a second roll 30. The polarizing means 29 can simply be formed of a metal comb which is piled with a high electrical potential to give rise to to a corona injecting charges in the teflon film 25 ·