DE408219C - Microphone receiver for recording sound waves in liquids and gases - Google Patents

Description

Nikrophone receiver for picking up sound waves in liquids and gases. The commercially available ones: Have microphones, as far as they work with contacts a tightly tensioned membrane and are therefore particularly suitable for vibrations and adapt to them. But such microphones are so suitable for the transmission of sounds as well as speech, they are so unsuitable for time measurements, be it that the time measurement is to be carried out by display or by registration, since it does not matter here both in their different coloring and tones To absorb strength, rather than to precisely when the one to be absorbed hits To interrupt a circuit or at least a sharp change in resistance bring about.

The purpose of the invention is therefore to provide a microphone receiver, which is suitable to absorb sound waves in liquids and gases in such a way that thereby an immediate power interruption is caused.

This is done according to the invention primarily in that the movable electrode .des microphone per se rigid and either entirely freely arranged or only in one place, for example on the edge or in the: litte, is fixed in such a way that it is affected by an incident sound wave as a whole of removed from the fixed contacts.

A similar type of attachment of the: membrane is already available for the commercial ones Microphones have been proposed. Here, however, the membrane is more self-oscillating Body formed, which should be suitable as a result of the self-oscillations, the tone color of the incident sound waves as naturally as possible and their '' transmission to favor. in any case, microphones of this type are used for the present purpose just as unsuitable as that of the well-known type in which the membrane is on its scope is firmly clamped.

To prevent your new recipient from getting through the contacting Parts of a shielding effect on the sound waves are the former arranged outside of the cross section touched by the sound waves.

The attachment of the movable electrode can be different, for example the electrode can have a hole in the middle and can move freely on a guide pin ride, or it can be hinged like a lid on one side and on the opposite Side carry a contact that may be seated on a lever, or it can Form a contact bridge, the support of which is designed as 2 isolated contacts are to which the power is supplied; Finally, the movable electrode can form the bottom of a R.esonator or one, for example, on a Helmholtz Close the opening provided for the spherical resonator.

The solid contact can be either ring-shaped, the sound waves be designed as a conductive body, or if there are 2 fixed contacts, they are semicircular are executed.

Since the movable contact, which is designed as a rigid plate, is practical only comes into play at three points, there is a possibility that one is not quite perfect current flow. As a result, according to the invention, the movable Electrode consist of several strip-shaped or similarly designed parts. Each of these strips will in turn come to rest at three points; the number of points of contact is therefore corresponding to the number of stripes increased and consequently the contact more secure and intimate, while the current load of the individual contact points, does not become too large. For better contact formation can also a weight or spring load can be provided, which can be adjusted to the movable or moving electrodes with the contact (s) in contact. Under Under certain circumstances it may be necessary to give the movable electrode an air gap upstream. Here, the movable electrode can terminate a sound pipe form, the other end is provided with a clamped sound membrane.

This arrangement also enables (read with the movable electrode cooperating end of the air duct in one or two parts as a fixed annular To train contact. Instead of the intermediate air gap, the movable electrode by a rigid pin, which is free by the fixed contact is passed through, be connected to the receiving membrane.

Is it the use of a microphone that is made of liquid is surrounded, it must be taken into account that the movable electrode carries the sound waves throws back as completely as possible.

As a result, metal plates are how to manufacture such Diaphragms used are unsuitable because they do not produce sound waves in liquids throw back, but let go through you.

As a result, according to the invention, the movable electrode should be a have significantly different sound permeability than the surrounding liquid, in this way a total reflection of the sound waves and the IVIaximtim one To achieve relative movement of the plate with respect to the liquid. This can be, for example .by applying an air cushion by making the contact either init an air space is designed or with a cork, paper or fabric layer is documented that must guarantee that those included in this layer Air cannot be displaced by the liquid.

Several embodiments of the subject matter of the invention are in part shown purely schematically in Figs. i to 12 of the drawing and are to be used in the following where the same parts are given the same reference numerals in all figures are provided. It goes without saying that the invention is not intended to apply to these exemplary embodiments be limited.

In the embodiment according to Figs. Both contacts 13 and 11 are conductively connected to one another by a plate-like membrane 16 made of any metal, but preferably made of carbon, so that any circuit is closed in this way. The membrane is arranged completely freely and is guided only with the help of the central opening 17 on a bolt 19 standing vertically in the frame 18, but in such a way that the freedom of movement of the membrane is not influenced in any way.

Hitting incoming sound waves in the direction of the arrows the membrane 16, this is from the contacts 13 and 1.1. lifted off and interrupted in this way the circuit running through these contacts.

The mass of the membrane 16 is not sufficient to generate the necessary counter pressure to generate, an increase in the contact pressure by a controllable additional load 2o take place. In general, however, this additional load is made more practical by a Spring 21 caused, sitting on the bolt i9, on the one hand against the Membrane 16, differently against a plate 23 adjustable by a screw 22 supports. In this way, the contact pressure of the membrane 16 can be adjusted with ease and adjust to the greatest possible accuracy.

In the embodiment according to FIG. 3, the membrane 16 encloses it Pipe 24 off. This tube 24 has an arm 25 on which the membrane 16 at 2o is hinged like a hinged lid. This joint also serves as the feed line for the Stromes, during which by the movement of the membrane 16 to unterbreclicn.de contact is provided on an arm 27 connected to the membrane at 28. The direction of the arrows striking the diaphragm 16 cause a movement this around the pivot point 26 and thereby an interruption of the circuit at 28. As a result of the lever arm 27, which is variable in its position, the accuracy and adjust sensitivity.

In this embodiment, too, as can be seen from Figure 4, an additional load or an increase in the contact pressure can easily be achieved by providing either an exchangeable additional weight or a spring 29 above the contact 28, which can be tensioned with the aid of a screw 30 can easily be changed within the desired limits. The contact overhangs are formed here by balls 31 or Grus made of conductive material, which also increases the accuracy of the operation of the device. Of course, in the case of the embodiments described so far, instead of the drawn edge transitions from contact to contact, such can occur with the mediation of spheres or grit. Figs. 5 and 6 show an embodiment similar to Figs. only (let instead of the one-piece membrane bridging the contacts 13 and 14 one made up of several parts or rods 32 is chosen.

In the embodiment according to Figure 7, the membrane plate 16 forms the Completion of a resonator 33, for example as a Helmholtz spherical resonator can be designed and has the purpose of enabling timely sound reception. The sound waves stimulate the air in the resonator to vibrate, which the floating membrane 16 from the annular contact 34. in the direction of the Arrows lifted off. This contact is connected to one pole of a circuit, while the other is connected to the membrane 16, so that by lifting this the circuit is interrupted. The guide that allows the freely floating membrane be configured in a manner similar to the embodiments described above. A weight or spring load can also reduce the contact pressure in the desired Way adjustable.

Fig. 8 shows an arrangement with an upstream air section, such as they are especially useful for underwater sound receivers, for example for echo sounders, is particularly suitable. Here is a clamped: membrane 35 with your water directly in connection, while the freely oscillating membrane 16 is behind the membrane 35 subsequent air gap 36 closes off. This forms the tubular Support 37 one and the membrane 16 itself the other contact. Of course the air gap can also be significantly longer, for example within this to be able to provide special closing organs, which are only shortly before the ones to be measured Sound waves hit the outer membrane 35 are opened. The intermediary Air gap 36 transmits the sound waves hitting the membrane 35 freely floating membrane 16, so that it stands out from the contact with the moment where the first sound wave hits the clamped membrane.

Fig. 9 shows a slightly different configuration in which the air gap is replaced by a rigid body, for example a bolt 38, which is fixed with the clamped membrane 35 on the one hand and with the freely floating membrane 16 is connected on the other hand. The bolt 38 here goes through the ring-shaped. Contact body 39 through and lifts as soon as the .Membrane 35 is set in vibration, the membrane 16 from your contact consisting of balls or grit .4o. Additional Loads can also be similar in the two embodiments according to FIGS. 8 and 9 Can be used as described above.

Fig. Ro shows an embodiment similar to Fig. I, in which only in place of the two semi-ring-shaped contacts 13 there is a full contact ring. The contact ring on the one hand and the membrane 16 on the other hand form the poles of a circuit which is interrupted when the membrane 16 is raised by the sound waves impinging in the direction of the arrows.

Fig. I i shows another type of additional load. An iron core 4.2 with the membrane is also concentric with the guide pin 19 16 firmly connected and an electromagnet 43 is arranged above this. By switching on a larger or smaller resistance in the circuit of the electromagnet its effect on the iron core can be changed so that it becomes the 1 membrane 16 more or less burdened or also completely removes the burden.

Finally, Fig. I2 shows a hollow membrane 16, such as it in connection with any of the just described or similar devices can be used to be used in liquids as it is in such it is necessary that the sound wave does not pass smoothly through the membrane, what would happen without an air cushion if you baked in hard rubber or glass used in water.

The main advantages of the invention are to be found therein see that the membrane is already due to its freely oscillating arrangement responds precisely to an extremely low level of sonic liveliness, and does so suddenly, since the membrane does not have to be tensioned first. At the same time, however, enables Arrangement of the membrane behind the contacts, that by the timely and sudden If the membrane oscillates, so does the circuit in the same way sharply and precisely in time is interrupted. Above all, this is extraordinary in all cases Importance in which the exact time of the arrival of an immediate or a thrown back Sound wave should be determined, whereby it does not matter the maximum of the sound wave, but rather the arrival of the first wave of a sound wave group. This is the only way to measure the time between, for example, when taking measurements in water Delivering a group of sound waves and the arrival of the from the ocean floor or another to detect echoes thrown back from an object in the water. Under Consideration of the most diverse possible uses of a sound receiver, to absorb sound waves in liquids or gases with the aid of this Of course, in a constructive relationship the widest limits are drawn without thereby to fall outside the scope of the invention, provided that this is a perfect free floating membrane or one that is only in one place, for example at the edge or in the middle, is attached, is used.

Claims (4)

PATENT CLAIM: i. Microphone receiver for recording sound waves in liquids and gases, characterized in that the movable electrode of the microphone in itself rigid and either arranged entirely freely or only at one point, for example on the edge or in the middle, attached in this way is that it is separated from the solid by an impinging sound wave as a whole Contacts removed, causing an immediate power interruption. 2. Sound receiver according to claim i, characterized in that the contact-making parts outside of the cross section touched by the sound waves. 3. Sound receiver after Claims 1 and 2, characterized in that d4ß the movable electrode of the microphone in the middle has a hole with which it, otherwise freely movable, on one Guide pin rides. q .. Sound receiver according to claim i and 2, characterized in that that the movable electrode of the microphone is hinged like a lid on one side is and on the opposite side a possibly seated on a lever Contact carries. 5. Sound receiver according to claim i to 3, characterized in that that the fixed contact is designed as a ring-shaped body that conducts the sound waves is. 6. Sound receiver according to claim i to 3, characterized in that the movable Electrode of the microphone forms a contact bridge and, their support as two isolated contacts are carried out, which .the current is supplied. 7. Sound receiver according to claim 6, characterized in that the two fixed Contacts are formed by semi-circular bodies that conduct sound waves. B. sound receiver according to claim 6, characterized in that the movable electrode of the microphone consists of several, strip-shaped or similar parts. G. Sound receiver according to claims i and 2, characterized in that the movable Electrode of the microphone forms the bottom of a resonator or one, for example provided on a Helmholtz spherical resonator (opening closes. io. sound receiver according to claim i to 3, characterized in that the contact pressure between movable Electrode of the microphone and contact or contacts by weight or spring loading o. The like. Is adjustable. ii. Sound receiver according to claim io, characterized in that that the spring loading the movable electrode of the microphone or the corresponding one Weight is under the influence of an electromagnet. 12. Sound receiver after Claims i to 3, characterized in that in front of the movable electrode of the microphone an air gap is switched. 13. Microphone receiver according to claim i, characterized characterized in that the movable electrode of the microphone terminates a sound pipe forms, the other end is provided with a clamped sound membrane. 1. 4th Sound receiver according to Claims 12 and 13, characterized in that the free vibrating electrode of the microphone cooperating end of the air line is formed in one or two parts as a fixed annular contact. 15. Microphone receiver according to claim i, characterized in that the movable electrode of the microphone by a rigid pin that is freely passed through the fixed contact, is connected to a receiving membrane. 16. Sound receiver according to claim i and 2, when it is used in liquids, characterized in that the movable The microphone electrode has a significantly different sound permeability than the surrounding liquid.