DE241159C - - Google Patents

Description

IMPERIAL

PATENT OFFICE.

- JVe 241159 - CLASS 74 d. GROUP 6.

The subject of the invention is a device for '. Evoking musical Sounds for the transmission of underwater signals. Is different from older arrangements the subject of the invention by the simple and in its frequency by its dimensions predetermined sound source; with the sound exciter is known per se Way an air line in connection to

ίο electrical simultaneously with the acoustic waves To be able to send out waves. A metallic sound conductor is arranged between the sound generator and the water Sound waves both before they are delivered to the metallic conductor and before they are delivered to the water are amplified by a tuned resonance body.

Since the Helmholtz resonator consists of only one tangle of sounds belonging to it Selects tone and works badly or not at all even with small detunings, especially in the case of great distances, the transmitter must be designed accordingly, d. H. it must have a constant, tuned exactly to the same number of vibrations, purely musical tone. The pitch and timbre must be completely constant be; Sender and receiver will only work accurately if they are in full consonance.

This complete consonance can only be achieved if the vibrations of the tuned transmitter are purely sinusoidal. If they are not, the resonator will be bad work and thereby also called into question the effect of the entire receiving device will. To generate only undamped, coordinated sound waves, as already suggested is not enough. Because the sudden interruptions of jets of liquid that Electromagnetically operated siren and buzzer-type devices therefore give more howling and whistling noises, but 'not pure, musical tones, even if theirs Waves are undamped. If, for example, you get a jet of liquid from you several times can interrupt a wheel perforated in a circle with a high number of revolutions, so receives one undamped vibrations, d. H. the oscillation amplitude is from period to almost constant to period. Just this regular sound of undamped waves can You can't call it a pure musical tone that you can use to work properly of the resonator.

However, devices for producing continuous tones have become known, according to previously known physical facts, a microphone in front of a telephone arrangement (Iron membrane with an electromagnet behind it) is used as a sound generator.

With this arrangement, however, the two devices must work together to produce a sound to create. If the microphone is omitted, there is no sound. Since furthermore the two Devices are not coordinated with one another,

so pitch and timbre are automatically variable quantities, of a purely musical tone with constant pitch and There can therefore be no question of timbre. Furthermore, those generated by the apparatus Sound vibrations through the air and through the undulating currents of the microphone, possibly also through a wire, but not as sound waves on and through that

ίο water propagated.

Finally, in arrangements in which sound vibrations are transmitted through the water and electrical waves through the air at the same time, the vibrations can only be transmitted through the intermediary of a new switched-on apparatus, e.g. B. a microphone, are transmitted to the electrical current and oscillation circuits of a wireless transmitter. When object of the present invention, however, produces a tuned -elektromagnetisch operated tuning fork in itself without a microphone a musical tone, the pitch and timbre by omitting the interrupter contacts and committed just before the tuning fork tines disposed, with, switched to the tuning fork electromagnet in series microphone made quite constant will. The tuning fork electromagnets are operated in this way with undulating direct current (wave current) and not, as usual, with so-called chopped direct current.

The direct transmission of the sound vibrations to the water does not take place by means of a thin intermediate medium (the air), but directly through one equally dense metallic conductor, which adapts to the spatial conditions in the ship's hull can be easily adjusted, the vibrations immediately before they are released to the water are first amplified by a resonance device. The metallic Sound conductor wire, the z. B. consists of aluminum, the actual transmitter above to arrange the waterline at any suitable point in the hull, where it is easily accessible for control.

The sending apparatus; is now set up that the excited sound waves simultaneously both by means of purely acoustic vibrations as well as can be propagated through the air with the help of electrical waves. Because The latter can be used for this because of their extremely high speed of reproduction in a correspondingly set up receiver at a remote signal pick-up point to bring the temporal beginning of the sound wave transmission to the display, so that the time between the emission and arrival of the sound waves and the distance sought from the product: time multiplied by the speed of reproduction can be determined. The transmitting apparatus therefore consists of an apparatus for generating sound and a device to transmit the sound waves. This latter device includes an arrangement to guide the excited sound waves to the water and to transmit them through it and a second device, in order to generate the electric waves and the superimposed on them To transmit waves of the sound exciter through the ether into the form.

Fig. Ι of the drawing illustrates the transmission apparatus together with circuitry in FIG a vertical cut. Fig. 2 shows a modified circuit arrangement. Fig. 3 shows a further modification of the circuit arrangement using a special telephone relay.

Two or more electromagnetically operated tuning forks 26, 27 are attached to the resonance box or the resonance plate r of an elastic metal cylinder in FIG. The electromagnets 28, 29, which are fed by the current source taken from the terminals 32, 33, are each connected in series with a microphone, telephone (monophone) 30, 31. The elastic metal cylinder μ is soundproof insulated by an acid-proof rubber sleeve 36 in the sound tube 35 rotatable by a toothed gear and in the parabolic horn 37 connected to it so that the tuned record 38 arranged at the lower end of the elastic metal cylinder -m is in the focal line of the parabolic bell 37 is located. When vibrating through the contact 39, the tuning fork 27 closes the oscillation circuit, which is provided with the adjustable self-induction 40 and the adjustable capacitor 41, of a wireless telegraph device, which is fed by the direct current machine 43 and contains the oscillation generator 42. The record 38 can also be arranged so that it is always firmly connected to the elastic metal cylinder, supported soundproof by rubber rings, closes the opening of the horn against the water or transmits the sound perpendicular to the record onto the water without a funnel.

In Fig. 2, another circuit of the microphone and the electromagnet is shown. The microphone 44 is located here in the primary circuit fed by the battery 46 47 of a transformer, whereby a capacitor 45 can be connected in parallel. The electromagnet or electromagnets 50 are located in the from a higher voltage power source 51, 52 fed with the series-connected capacitor 49 provided secondary circuit 48 of the transformer.

The mode of operation of the transmitter is as follows:

- If current is drawn from the plug-in contact 32, 33, the two electromagnets 28, 29 are excited via the microphones, telephones or mono-telephones 30, 31 with the same tuning. As a result, the tuning forks begin to vibrate and sound, and the soundboard r resonates. These vibrations, however, excite the microphones that are in series with the electromagnets and are arranged in the direction of vibration of the tuning fork prongs, the current of which begins to fluctuate in the rhythm of the tuning fork vibrations. These rhythmically fluctuating currents now excite the electromagnets in the same rhythm and thus have a regulating effect on them, so that the tuning fork tines are attracted and repelled in the correct cycle, whereby the maximum oscillation amplitude is achieved with the appropriate current strength and voltage. This circuit and arrangement of tuning fork and microphone, which are known per se, generate maximum, continuous, sinusoidal vibrations and are attached to the elastic metal cylinder 111 and to the lower end thereof by the resonance plate r. Record (resonance tube) 38 transmitted, the vibrations of which are reflected from the inner wall of the parabolic horn 37 parallel to the axis, penetrate the water in a sharply defined sound beam, which can be given any direction by rotating the horn 37. Instead of the record 38, however, an identically tuned tuning fork could also be used. Likewise, flat steel rods (steel springs) made to vibrate by electromagnets can be used for the tuning forks 26, 27.

All of these tuning fork arrangements could be made by others, purely musical Sound-producing sound sources are replaced.

Since the microphone can only tolerate weak currents, the device shown in FIG. 2 is used in addition, despite the microphone or telephone, the electromagnets by stronger currents to excite, making it possible to amplify the dimensions of the tuning forks and make them louder To achieve tones.

The energized tuning fork in this case energizes the microphone 44, which is from the battery 46 is fed and its current fluctuations through the capacitance 45 connected in parallel be enlarged. This transformer action, either by means of an ordinary transformer or a response that can be adjusted to resonance at 47, 48 generated currents in the secondary circuit, that of a higher voltage, from the terminals 51, 52 withdrawn current is flowing through, so strong current fluctuations that the capacitor 49 begins to sound to the rhythm of the microphone streams. , These large fluctuations in current now energize the electromagnet 50 of the tuning fork.

In the same. But the moment when the tuning forks begin to vibrate is 39 by a contact device, e.g. B. by a mercury contact, an electric current or oscillation circuit of a generator of electrical waves closed, its oscillations can be transmitted to the antenna 51 by a coupling. But it won't just be the electrical oscillations, but also the superimposed tuning fork vibrations wirelessly transmitted, and as a result, in a conventional hearing receiver of a signal recording apparatus the tuning fork tone can be played. But there, as already mentioned, the time difference with the electric waves between transmission and arrival is so diminishingly small that the two points in time actually coincide in one, so will the moment of arrival of the electric Waves in the signal receiving apparatus also set the moment of transmission and thereby the beginning of a movement is given, from which one can calculate the distance according to known physical laws.

The arrangement shown in FIG. 3 can also be used for the stated purpose the.

From the battery 53 of the telephone relay shown in this figure, two or several microphones, telephones or tuned to the tone of the tuning forks 73, 75 Monotelephone fed which with the two coils 56, 57, which by the screw spindle 58 arranged precisely adjustable on a carriage not shown in the drawing are connected in series. The high-voltage current of the telephone relay flows from the terminals 60, 61 Via the regulating resistor 62 and the coil 63, which is firmly seated on the iron core 59, via the nodes 64 and 65 and from these via the electromagnets 66, 67 those connected in series with the latter and appropriate in their magnetic field arranged positive or negative glow resistor 68, whereby the - main circuit closed is. Parallel to this, branching off from the nodes 64, 65, there is a Thomson's i (Duddell's) oscillatory circuit in which the variable capacitor 69 and the controllable self-induction 70 are connected in series. With this oscillation circle the tuning forks 73, 75 arranged on the resonance boxes 74, 76 are galvanic (conductive) or coupled differently. Just-. so can the undulating microphone currents by a coupling other than that shown in the drawing to the circuit or circuits of the telephone relay.

The mode of operation using this telephone relay is as follows:

If current is drawn from terminals 60, 61, thus an alternating current is formed in the Thomsonian (Düddellian) oscillation circuit off, the period of which depends on the capacitance 69 and the self-induction 70 and can be regulated as required by appropriate setting of the same. Once the electromagnet 71, 72 are set in action, the tuning forks 73, 75 begin to sound. Of the Tuning fork tone, amplified by the resonance boxes 74,76, excites the microphones 54, 55, their Undulating currents flow through the coils 56, 57, which, by the screw spindle 58, flow Set resonance, let their lines of force all go through the field of the coil 63, whereby the undulating currents of the microphone circuit on the main circuit and in the further course transferred to the Thomson (Düddell) oscillation circuit which now attracts and repels the prongs in time with the rhythm of the tuning fork tones.

Claims (5)

Patent Claims: i. Device for producing musical tones for the transmission of underwater signals with a body that is made to vibrate with the help of an electromagnet, in its circuit a sound receiver (microphone, telephone) placed in front of the vibrating body is switched on, characterized in that the vibrations of electromagnetic excited tuning forks or steel rods, which as well as the sound receivers arranged in front of them the resonator of the receiver are tuned by means of a resonance body on a metallic wire and transferred from this through the intermediary of a resonance body to the water where electrical current is generated by one of the vibrating bodies or oscillation circuits of a generator for electrical waves are influenced. 2. Device according to claim i, characterized in that the tuning forks exciting electromagnet (50) with a capacitor (49) with the secondary coil through which a higher voltage current flows (48) of a transformer is connected in series, in whose primary circuit (47) the tuned sound receiver (44) is connected to which a capacitor (45) is connected in parallel can be. 3. Device according to claim 1, characterized in that the at the end of the sound-conducting metal wire fm) fastened resonance body (38) insulated soundproof, is arranged in the focal line of an arbitrarily adjustable, parabolic sound funnel (37), which is the sound waves transmitted to the water emits parallel to the axis of the funnel in a sharply defined sound beam. 4. Device according to claim 1, characterized in that the resonance body (38) with the sound-conducting metal wire fm) is connected directly or by means of an elastic intermediate piece in such a way that the resonance body (38) is either exposed or supported soundproof by appropriate insulation, the Opening of the arbitrarily adjustable horn against the water either completely or partially closes. 5. Device according to claim 1, characterized in that the vibrating Tuning forks or steel rods rhythmically influence the supply current or oscillation circuit of an electrical oscillation generator through a contact, whereby electric waves with superposed tuned tuning fork tone through a coupling to an air duct system and can be transmitted wirelessly to the distance through this .. In addition 1 L31att drawings.