DE898763C - Carbon core microphone - Google Patents

Description

The invention relates to carbon grain microphones between a thin membrane and the microphone housing have an air chamber,

In a known microphone of this type (British patent specification 430150), the air chamber behind the membrane is closed on all sides ¹ , so that the vibrations of the membrane are strongly damped due to the rigidity of the volume of air enclosed in this. The microphone therefore responds poorly, especially at low frequencies. It is therefore necessary to keep the air chamber behind the membrane relatively large. However, this has an unfavorable effect on the frequency response of the microphone.

The invention aims to avoid these disadvantages, and is characterized by a uniform Response sensitivity of the microphone over the speech frequency range, which thereby it is achieved that the volume of the air chamber, which lies behind the membrane ', is kept small is that openings are provided in the housing, which openings said air chamber with connect the external ventilation, and that these openings

are covered with material which represents an acoustic resistance.

The essence of the invention should be based on the description and drawings of two exemplary embodiments are explained in more detail.

Fig. Ι shows a cross section through a microphone;

Fig. 2 is a view of the rear of the microphone shown in Fig. Ι;

ίο Fig. 3 and 4 show how the uniform response of the microphone is achieved by the νοτ ¹ -liegenda invention;

Fig. 5 shows in cross section a voirzugswedses Embodiment of the microphone; FIG. 6 shows a rear view of the microphone shown in FIG.

In Figs. 1 and 2, the membrane 2 of the microphone is on an annular body 1 by means a ring 15 and an overlapping cover 12 held. The light metal piston leg membrane has an opening in its center for attaching a hemispherical graphite electrode 3, a flexible metal spider or membrane 4 and a Silk ring 5 are on the membrane around the carbon electrode 3 and on an annular disc 16 attached to the body 1 in order to close off the grain chamber on one side. the In this way, the spider or membrane connects the electrode to the microphone housing, which at the same time forms the back wall of the electrode. The silk ring is used to hold the grains of coal Keep away from the spider or membrane and ensure that the grains of coal only represent Make contact with the electrode.

The grain chamber 17, 18 is made of an insulating ring 6, for example made of porcelain or similar material, and a graphite counter electrode 7, which is formed by an insulating ring 9 and a screw-on cover latte 10 is held. The electrodes and the ring 5 have such a shape that the Grain chamber breaks up into two parts 17 and 18, which are connected to one another via a constriction stand.

The counter electrode has an opening 19 for filling the canal chamber. After the chamber has been filled, the opening 19 is closed by a closure cap 11. The cover plate 10 and the cap 11 represent the microphone lock, if the microphone is used in a handset. The space 20 between the back of the membrane 2 and the body 1 is kept particularly narrow, 1500 mm ³ or less, and the microphone body has one or more openings 13 covered with sound-absorbing material, for example silk 14, through which the space 20 between the membrane back and the housing is in communication with the outside air.

The graph (Fig. 3) shows the novel by the various factors present Arrangements achieved mode of action.

The frequencies in Hertz are on the abscissa and the ordinates. the attenuation in decibels applied. The curves are only approximations in order to improve the response of the microphone as a result of the various factors to illustrate.

Curve I is the curve corresponding to an undamped membrane with a natural frequency of approximately 500 Hz.

Curve II essentially corresponds to the microphones common nowadays. The natural frequency has been increased to about 18 (00 Hz, due to the rigidity of the air chamber behind the Diaphragm that makes it difficult to respond at low frequencies.

However, if the air space behind the membrane is further reduced, its rigidity becomes greater continue to increase and the natural frequency even further increases, as curve III shows.

Until now, the openings behind the airspace have not been taken into account. These openings ensure as long as they are not covered with sound-absorbing material, the unimpeded passage the air when the membrane moves, the membrane moves freely at low frequencies, and the effective rigidity of the air space here is small.

At high frequencies, however, the openings' resistance to air movement becomes effective and prevents the passage of air, the rigidity of the air space being almost perfect is. Due to the different behavior of the openings and the reduced air gap pronounced highs and lows appear at high and low frequencies (Curve IV).

If the openings are now covered with an acoustic dampening material such as silk, then these high and low points are given a gradual course, as is illustrated by curve V.

It follows that the openings and. the reduced air space behind the membrane in such a way cooperate that one to be found to any degree according to the use Damping material, damped natural frequency and a uniform response of the microphone is achieved over the entire voice frequency range.

Fig. 4 shows damping curves recorded under different operating conditions for a, Microphone with a reduced air space and six silk-covered openings, each with a diameter of 8.8 mm and 1 mm axial depth, bad sect with a single layer heavier Silk.

Curve α was obtained when all openings were completely closed, curve b when a single opening was covered with silk, curve c when two openings were covered with silk, and curve d when all six openings were covered with silk and warm.

The use of openings. 13 with noticeable Depth produce the same results, but openings are noticeable Preferable volume.

Apart from that achieved by the new arrangement behind the membrane. Improvements the space in front of the membrane and the openings in the cover plate are expediently determined in such a way that that a certain natural frequency is achieved to further improve the microphone.

In the embodiment of the invention, as shown in FIGS. 5 and 6, there is the main membrane 2 made of light metal, e.g. made of an aluminum alloy, has a thickness of 0.08 mm and is in the main body 1 of the microphone by means of one between the main diaphragm 2 and the Cover 12 arranged clamping ring 15 clamped, which at the same time to fix an auxiliary membrane made of the same material 21 serves.

When assembling the microphone, the two membranes are inserted and a thin lacquer coating is applied to the lower side of the membrane 21. The clamping ring is then inserted and ¹ with its rear edge 23 is pulled over the housing body 1. While the paint is being painted over, the paint is pressed out between the two membranes and fills the conical space

as 22 between the membrane 21 and the locking ring 15, whereby a moisture-proof seal is achieved. This prevents the Breath moisture of a person speaking into the microphone accumulates in the microphone and Causes corrosion of the metal membrane.

A flexible metal spider or membrane 4 and a silk ring 5 are round on the membrane around the essentially spherical graphite electrode 3 attached. The electrode protrudes into the core chamber, which consists of two parts 17 and 18 into it.

The spider or membrane 4 connects the hemispherical shape Electrode with the microphone housing, which closes the microphone on one side.

The silk ring is used to prevent contact between the carbon grains and the Spider or membrane and to ensure contact between the electrode and the Grains of coal. If a spider is used, the silk ring prevents it from falling out at the same time the grains of coal from the microphone.

An insulator 4 made of porcelain or similar insulating material is arranged over the silk ring and above the circular carbon electrode 7, which is used to fill the carbon grains into the chamber 17, 18 has an opening 25. The counter electrode is made of a metal. Version 26, held in which a closure piece 27 is screwed in after filling the grains of coal. This closure piece 27 has a base part 28 with which it can be inserted into a handset.

The metal frame 26 is isolated from the microphone body by means of a ring 28. The inner of the main body is threaded, and a screw ring 30 is inserted into the holes 31 by means of a special tool.

In the main body of the microphone is a number

of openings 13th provided, each of which has a Has a diameter of 3.8 mm and an axial depth of ι mm, so that the space between the back the membrane 2 and the housing is in communication with the outside air. The inner ends of this Openings 13 are covered with slices of thick silk 14.

The mode of action of these openings covered with silk is the same as in the exemplary embodiment of the invention described above, i.e. ζ. Β ·, a uniform response of the microphone over the entire speech frequency range, as shown in curves a, b, c and d in Fig. 4.

The speech frequencies below 300 Hz have a very high intensity and cause large vibration amplitudes in the membrane and front electrode. These large oscillation amplitudes cause harmonics appearing in the output power which in turn have an unpleasant effect on the modulation and on the reproduced language Have effects.

To avoid these effects, the membrane 2 has a small hole 32 with a diameter of 0.8 mm. The effect of this hole is that it acts on the membrane Pressure at low frequencies creates a bypass path that controls the oscillation amplitudes the membrane and thus the size of the movement of the front electrode 3 at low frequencies degrades. At higher frequencies, this hole has, with regard to the characteristics of the Microphones have a negligible effect. The effect of the small hole in the membrane 2 is depending on the rigidity of the air behind the main membrane.

The sensitivity of the microphone is increased by the effect of the small hole and all frequencies below 300 Hz are suppressed.

The conical auxiliary membrane 21 has a Flange. As a result of this arrangement, the membrane vibrates as a whole when speech vibrations strike, and, due to the rigidity of the air between the two membranes, there is a resonance in the frequency characteristic of the; Microphone achieved at around 3000 Hz. It is not beneficial to have one to use flat auxiliary membrane, since scattered resonances would be introduced through such membranes as a result of the slight inhomogeneities that are always present in flat membranes. Through the already mentioned lacquer coating on the auxiliary membrane becomes a complete and watertight closure of the microphone.

As soon as speech vibrations hit the membrane with which the front electrode of a If carbon grain microphones are connected, the breath sounds are also transmitted. By the arrangement an auxiliary membrane in front of the main membrane, however, these breath sounds are not transmitted.

The microphone is built in such a way that a small air space between the auxiliary electrode and the Cover plate is created. The openings in the deck

plate are larger, 'so that a resonance of about 50! CO Hz is achieved, according to ^one of the effects of the space in front of the auxiliary membrane and the openings in the cover plate is.

With the microphone described in Figs. 5, 6, one of the membrane resonance frequency is generated when excited Obvious resonance achieved, for example that between 1000 and 1500 Hz natural membrane resonance frequency when the air space behind the membrane is insufficient Has rigidity.

Claims (11)

Patent claims: i. Carbon grain microphone, which has an air chamber between a thin membrane and the microphone housing, characterized by a uniform sensitivity of the microphone over the speech frequency range, ζ. B. from 300 to 4000 Hz, which is achieved in that the volume of the air chamber (z. B. 20), which is behind the membrane, small, z. B ^:. 0.095 cubic inches, that openings (e.g. 13) are provided in the housing, which openings connect said air chamber (e.g. 20) with the outside air, and that these openings (ζ. B. 13) with material (z. B. 14) are covered, which represents an acoustic resistance. 2. Microphone according to claim 1, characterized in that that the responsiveness at the lower frequencies, e.g. B. below 300 Hz, with the help of a small opening in the membrane, z. 0.032 inch diameter, which is an acoustic shunt represents to the membrane. 3. Microphone according to claim 1 or 2, characterized in that · the acoustic resistance material (ζ. B. 14) at the inner ends of said openings (e.g. 13) in the housing is attached. 4. Microphone according to claim 1, 2 or 3, characterized in that an auxiliary membrane the front of the microphone is completely sealed off, preventing moisture and the Transmission of breath sounds is prevented. 5. Microphone according to claim 4, characterized in that the auxiliary membrane is a has a conical shape and vibrates as a whole when speech vibrations strike and is dimensioned so that the microphone has a resonance range of about 3000 Hz. 6. Microphone according to one of the preceding claims, characterized in that a Dome-shaped electrode on the microphone membrane using a flexible metal spider or membrane is attached, which is covered by a disc of saide or similar material and is held in place by the microphone housing, which moves the microphone to one side is completed. 7. microphone according to claim 6, characterized in that that the counter electrode is insulated from the flexible spider or membrane by means of a porcelain or other insulator and that the counter electrode, insulator and the electrode attached to the membrane with the Silk washer form the boundary of the grain chamber. 8. Microphone according to claim 7, characterized in that the counter electrode with a the filling of the seeding chamber from the back of the microphone from serving opening is. 9. Microphone according to claim 8, characterized in that the opening with a metal flap is closed, which represents the rear limitation of the microphone. 10. Microphone according to claim 8, characterized in that that the counter-electrode is held in a metal holder, in which to close the opening in the counter-electrode a closure piece is screwed in, which closes the microphone to the rear. 11. Microphone according to claim 10, characterized in that that the metal socket for the counter electrode insulates against the microphone housing is and is held with the help of a locking ring screwed into the housing. For this purpose 2 sheets of drawings 1 5606 11.53