DE1288960C2 - Alarm giver - Google Patents

Description

The present invention relates to an alarm device, which periodic tones of different Pitch emits as a battery-operated, self-contained unit made up of semiconductors is formed, and from a continuously oscillating oscillator as a modulation control device, a self-oscillating tone generator whose frequency is periodically changed by the modulation control device is changed, and a speaker powered by the tone generator.

Such an alarm device is already known (German Auslegeschrift 1 150008). The self-oscillating In this case the oscillator is a multivibrator, while the self-oscillating is a tone generator is also an LC generator that can be modulated in amplitude.

An alarm device is also known (see brochure "Vanguard 100" from LTV University in Oklahoma City, USA), in which a blocking transducer is used to generate the audio frequency, while for the generation of the periodic, symmetric, d. H. triangular, pitch variations a cross-coupled multivibrator is used.

It is the object of the present invention to develop the alarm device of the type mentioned at the beginning in such a way that that a particularly conspicuous and urgent alarm signal is generated and that the alarm transmitter can be produced as an extremely compact unit with little circuitry and has a lower power requirement.

According to the invention this object is achieved in that the modulation control device a uni-function transistor having a sawtooth generator and that the tone generator is an approximately proportional to the output voltage of the sawtooth generator, controllable in frequency, automatically tilting, cross-coupled multivibrator. As such, they are sawtooth generators with a uni-function transistor and also automatically tilting, crosswise

ίο coupled multivibrators known, their frequency can be controlled by changing the input voltage (»Electronics«, 1965, pp. 325 to 328 or »Electronic Engineering ", 1965, pp. 182 to 185).

Compared to the known alarm transmitters mentioned at the beginning, the one according to the invention is distinguished Alarm device from the fact that a transformer provided with three windings is dispensed with can be, so that there is the possibility of producing the alarm device as an extremely compact unit.

ao steep. Using one with a unijunction transistor provided sawtooth generator as a modulation control device caused by the not symmetrical periodic pitch variations even without amplitude modulation the feeling of a

»5 special urgency.

The alarm transmitter according to the invention can be used primarily in connection with various alarm systems - for example to protect buildings and other enclosed spaces - against unauthorized access be used.

In order to be able to set the alarm signal as desired, it has proven to be useful that in in a manner known per se for influencing the maximum frequency of the multivibrator at least one its resistances is adjustable.

In order to ensure that the warning signals emitted by the loudspeaker have sufficient amplitude are strong, it also proves to be advantageous that between the tone generator and the loudspeaker a power amplifier is arranged and that the power amplifier is either a symmetrical one Two-stage amplifier or a push-pull amplifier with four transistors each.

The invention is to be explained in more detail below using an exemplary embodiment, wherein Reference is made to the drawing. It shows

Fig. 1 is a schematic circuit diagram of a transistor current circuit within the scope of the present invention,

F i g. FIG. 2 shows a waveform for a better understanding of the operation of the invention and FIG

3 is a schematic representation of a modification a part of the in F i g. 1 circuit shown.

The in F i g. 1 consists of three separate sub-units, which are separated from one another by dashed lines A and B in the drawing. These subunits consist of a periodic sawtooth voltage generator 10, a cross-coupled multivibrator 12 and a power amplifier 14.

The power supply for the circuits is provided by a pair of battery sets 16 and 18 in series inside the power amplifier 14. The outer of the positive and negative terminals of these battery packs are connected to respective positive and negative voltage conductors 20 and 22, which are through the subunits 10, 12 and 14 extend.

The periodic sawtooth voltage generator 10 consists of a resistor 24 and a capacitor 26 connected in series between the positive and negative voltage conductor 20 and 22 are connected. The sawtooth voltage generator 10 includes additional a unijunction transistor 28, which is connected to its two base terminals via resistors 30 and 32 is connected to the positive and negative voltage lines 20 and 22, respectively. The emitter connection of the Unijunction transistor 28 is connected to resistor 24 and capacitor 26 via a terminal 34 wire : ■.

The Ri_Jime 34 is also with the base connection an NPN transistor 36 is connected. The collector terminal of this transistor 36 is connected to the positive voltage line 20, its emitter connection to the frequency control line 38.

The cross-coupled multivibrator consists of a pair of NPN transistors, their collector connections Via resistors 44 and 46 with ao the positive voltage conductor 20 are vetuunden and the emitter connections of which are directly connected to the negative voltage line 22. The basic connections of the the two transistors 40 and 42 are connected to the respective capacitors 48 and 50 iigen collector connections of the other transistor a!> also connected to line 38 via corresponding resistors 52 and 54. The output signals The cross-coupled multivibrator 12 are connected to the terminal 56 at the collector connection of the transistor 42 is removed and passed to the power amplifier 14 via the output line 58.

The power amplifier 14 consists of two stages, namely a first stage with the transistors 60 and 62 and a second stage with transistors 64 and 66.

The transistors 60 and 62 of the first stage, of which 60 an NPN transistor, 62 a PNP transistor are connected to a grounded terminal 68 with their emitter connections as a complementary unit. Furthermore, the base connections of these transistors are connected via a common resistor 70 the output line 58 of the multivibrator 12 is connected. Additional lines lead from the collector connections to the second stage, namely to the base connections of transistors 64 and 66.

The second stage consists of a PNP transistor 64 and an NPN transistor 66. These transistors rt represent a complementary unit, with their collector connections via a common Terminal 72 with one of the connections of the loudspeaker 74 and its emitter connections with each other positive and negative voltage conductors 20 and 22 are connected. The second connection of the loudspeaker 74 takes place via the connecting terminal 76 and is connected to ground 78. The connecting terminal 76 points in addition, connections to a pair of switches 80 and 82 that control the battery packs 16 and 18 Connect in series with each other or voltage values between the positive and negative voltage lines 20 and 22 place.

The functioning of the circuit described above will now be described in the following:

The cross-coupled multivibrator unit 12 oscillates continuously and generates on the output side a tension with an essentially rectangular shape Wave course, the frequency of which, however, depends on the bias voltage on line 38. the The mode of operation of the cross-coupled subunit J 2 is undoubtedly easy to understand for the person skilled in the art. In principle, this takes place on the basis of a switching process that alternates between the two Transistors 40 and 42 can be made conductive. This creates a substantially square voltage waveform on the multivibrator output line 58 Switching between the two transistors 40 and 42 takes place as a function of the current via the frequency control line 38, namely as soon as the Capacitor 48 or 50 in the base line of the non-conductive transistor 40 or 42 at the time has a sufficiently large charge This gives the relevant, previously non-conductive transistor a Sufficient bias voltage above the threshold voltage so that it becomes conductive. As soon as this happens the capacitor discharges, causing the other transistor to have less than its threshold voltage receives and therefore loses its ability to operate. Over the frequency control line S8 thereupon electrical charge carriers to the other capacitor brought, as a result of which this is now discharged and the mode of action is reversed.

3a the size of the current flow via the frequency control line 38 regulates the speed, with that the capacitors 48 and 50 charge, the duration of the switching period changes accordingly or the frequency of the 1 square voltage wave. It is therefore possible through recruitment a resistor in the frequency control line 38, the current flow through the same and thus set the maximum output frequency of the multivibrator.

As soon as switches 80 and 12 are closed, the battery acid 16 and 18 lie between the positive and negative voltage lines 20 and 22, respectively in series with each other. This biases the output transistors 64 and 66 and above their base connections to the driver transistors 60 and 62. Furthermore, voltage values are applied to the Multivibrator transistors 40 and 42, on the NPN transistor 36, at the unijunction transistor 28 and the resistor and capacitor 24 and 26, respectively Closing the switches 80 and 82 creates a circuit across the resistors 30 and 32 and across the Base terminals of the unijunction transistor 28. The resistors 30 and 32 act as a voltage divider and serve to apply a base bias to the unijunction transistor. At the same time a current flows through the resistor 24 and charges the capacitor 26.

F i g. 2 shows the time course of the charge or the voltage on the capacitor 26. How can be seen from this, the voltage on the capacitor increases steadily from 0 to a maximum value and then falls off abruptly. The maximum value is reached as soon as the voltage at the emitter connection of the Unijunction transistor 28 is greater than the voltage at the base terminal by a certain amount. The internal resistance between the emitter and base of the unijoint transistor 28 then collapses, and the capacitor 26 discharges instantaneously through the low resistance created in this way Current path. As a result, the voltage across capacitor 26 will drop and consequently it will also drop The emitter voltage at the unijunction transistor 28 is below the critical value, which means that the inner Resistance between the emitter and the base

builds. The capacitor 26 is then recharged as before and the cycle repeats. The frequency at which this cycle takes place can of course be changed in various ways, namely by changing the resistance IA or the capacitance of the capacitor 26, by changing the voltage between the lines 20 and 22 or by changing the characteristic curve of the uni-function transistor 28. In any case it is important that the waveform of the voltage is unbalanced and according to F t g. 2 has discontinuities. Of course, this takes place through a time sequence of steadily rising and abruptly falling voltage values. It has been found that particularly good results are achieved with a cycle sequence in the vicinity of 50 periods per minute.

The voltage on the capacitor 26 is used to connect the base terminal of the NPN transistor 36 to give a bias. This in turn changes and determines the impedance of this transistor the size of the current flow on the frequency control line 38. For this reason, the current flow follows on this line the waveform shown in FIG. As already described, is the output frequency? of the multivibrator 12 of the current size? determined on the frequency control line 38. the The output frequency of the multivibrator therefore also follows that in FIG. 2 waveform.

The working frequencies of the multivibrator are in the audible range. The current changes in the Frequency control lines 38 are dimensioned so that the output frequencies are between certain limits lie within the audible range. In a certain embodiment according to the invention, multivibrator output frequencies between 1200 and 1800 Hertz were preferably chosen.

The multivibrator is connected with the terminal 56 via the resistor 70 to the input of the power amplifier 14. From there it is connected to the base connections of the transistors 60 and 62 of the first stage of the amplifier. Due to their properties, i. H. by the fact that the one NPN, the other is a PNP transistor, and by virtue of their circuitry, i. H. in that the emitter connections are grounded and the base connections are connected to one another, the same result very effective, symmetrical amplification in cascade and a very faithful reproduction of the multivibrator signal.

The output of the first stage, i.e. H. of transistors 60 and 62, goes to a second stage, i.e. H. the Base terminals of the transistors 64 and 66, fed. These transistors are in a similar fashion switched and therefore bring about a further symmetrical, very precise and effective amplification. The output signal of the transistors 64 and 66 is taken from the common interconnected Kotlektor connections and ground and used to control the loudspeaker 74.

From the above description it can be seen that the loudspeaker generates acoustic signals, the tone of which periodically increase the non-symmetrical changes gene is subject to discontinuities, and more precisely these correspond to the sawtooth curve shown in FIG. It has been found that this course is a subjective alarm

vo effect which is very persistent in its effect and which neither affects the volume nor depends on the pitch for creating the sense of urgency. Furthermore, that stops this created a sense of urgency, because the ear cannot easily adapt to the non-symmetrical modulation of the output signal.

With reference to FIG. 1 it can be seen that the circuit described therein has two separate switches

• 0 80 and 82 required to switch the system on and off. The use of two different Switches can be made by the in F i g. 3 circuit shown can be avoided. There is only one in it Battery 100 shown in series with a switch 102 between positive and negative lines 20 and 22 lies. The output stage of this amplifier consists of four transistors 104,106,108 and 110, which are connected to one another in a connection and of which 104 and 108 are NPN Transistors, 106 and 110 are PNP transistors. While the collector connections of the NPN transistors 104 and 108 are connected to the positive line 20, the collector connections of the PNP transistors 106 and 110 on the negative lei tung22. The emitter terminals of the transistors 104 and 106 and the transistors 108 and 110 are connected in pairs to the two terminals of the loudspeaker 74. Furthermore, the base connections are of transistors 104 and 106 through the interconnect terminal 56 with the multivibrator output and the

Base connections of the transistors 108 and 110 with

the emitter terminals of transistors 40 and 42 of the multivibrator connected.

The circuit shown in Fig. 3 has the opposite

clock amplifier a high degree of linearity on and ensures an accurate reproduction of the input

Circuits are open

The invention Reason of their

Circuit very effective and so able to go far for a given current source to deduct higher output powers over longer periods of time than previously known circuits Similar Nature The present invention therefore makes the construction of extremely compact, self-contained, battery-powered Alann devices possible for use in many operating situations including the use of Alarm systems was not possible until today.

1 sheet of drawings

Claims (3)

Patent claims: 1. Alarm device, which periodic tones different Pitch emits as built up from semiconductors, - powered by, in them !: closed Unit is formed and consists of a continuously oscillating oscillator as a modulation control device, a self-oscillating tone geoeraiior whose frequency is periodic is changed by the modification control means, and one fed from the tone generator Loudspeaker consists, characterized in that the modulation control device (10) is a unijunction transistor (28) having a sawtooth generator and that the Tone generator (12) on. roughly proportional to the output voltage of the sawtooth generator in its Frequency controllable, automatically tilting, cross-coupled multivibrator is. 2. Alarm device according to claim 1, characterized in that for influencing the maximum frequency of the multivibrator (12) at least one of its resistors (44, 46, 52, 54) is adjustable. 3. Alarm device according to claim I or 2, characterized in that between the tone generator (12) and the loudspeaker (74) a Power amplifier (14, is arranged and that the power amplifier (14) is a symmetrical one Two-stage amplifier, which is a push-pull amplifier with four transistors each