DE8704328U1 - Monitoring device - Google Patents

Description

1308 BV

Giovanni Bravi/. 6112 Large rooms

Monitoring device

The invention relates to a monitoring device with an acousto-electrical transducer.

In well-known monitoring devices, also called alarm systems, sensors are installed at the places to be monitored, such as doors and windows, which, in the event of damage or unauthorized access, report signals to a control center, where an alarm is triggered, for example by a siren and/or a flashing light.

The well-known alarm systems and their installation are often quite expensive because many sensors are required to monitor a building, for example. In addition, so-called glass break sensors have proven to be unreliable because their response can be prevented by various tricks, for example by dampening the pane of glass to be monitored using a silicone compound.

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The aim of the present invention is to propose a monitoring device that is as simple as possible and works reliably. The monitoring device according to the invention is characterized in that a high-pass filter is connected downstream of the converter. The converter can be a ceramic microphone.

The invention is based on the knowledge that the higher frequency components of sound waves that enter a building from outside are dampened, while noises caused by a break-in have higher frequency components. Although a significant advantage of the invention is that one microphone can be used to monitor a large area with multiple entrances, several microphones can also be used in individual cases within the scope of the invention.

An advantageous development of the invention consists in the fact that a rectifier circuit is connected to the output of the high-pass filter, the output of which is connected to a threshold circuit via a low-pass filter. This enables an advantageous further evaluation of the signals passed through by the high-pass filter. In particular, triggering by interference pulses on the mains voltage is prevented.

Advantageous embodiments consist in that the high-pass filter is formed by an operational amplifier whose negative feedback branch consists of a low-pass filter, or that the negative feedback branch is formed by a voltage divider whose longitudinal branch consists of at least one resistor and whose transverse branch consists of

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' a series of switching stages of a capacitor with a certain resistance.

Another development of the invention provides that the output of the threshold circuit is connected on the one hand to an alarm device and on the other hand to a timer, which in turn is connected to other inputs of the threshold circuit. This makes it possible for the monitoring device to be temporarily ineffective after it has been switched on.

An advantageous embodiment of this further development consists in the timing element essentially consisting of a capacitor which can be charged by the output voltage of the threshold circuit via a series connection of a resistor and a diode and to which the collector-emitter path of a transistor is connected in parallel via a further resistor, which can be controlled by the threshold circuit via a preferably adjustable voltage divider.

A further improvement of the monitoring device according to the invention is possible in that ^a

A key switch is provided/ the contacts of which are inserted into the control circuit of a relay/ and that the relay has a normally closed contact which is inserted into the supply of the operating voltage to the monitoring device.

These measures ensure that destroying the key switch does not result in the alarm system being deactivated.
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1308 BV-4-

The invention allows for numerous embodiments. One of them is shown schematically in the drawing using several figures and described below. It shows:

Fig. 1 an alarm system according to the invention, Fig. 2 Parts of the circuit diagram of the inventive

Alarm system, which are necessary to explain the invention, and

Fig. 3 a circuit for indicating a mains voltage failure Ils.

The monitoring device shown in Fig. 1 comprises a housing 1 in which the necessary circuits are housed. The housing 1 also comprises a sound inlet opening 2, behind which a microphone 3 is arranged. Finally, three rotary knobs 4, 5, 6 of potentiometers are provided, with which various settings can be made. In addition, light-emitting diodes 7, 8, 9, 10, 11 are arranged in the front panel, the function of which will be explained in more detail later in connection with Fig. 2.

In Fig. 1, a siren and a flashing light 12 are connected as alarm devices. A key switch 13 is used to switch on the monitoring device, which can be arranged at a suitable location outside the building to be monitored - for example on the outer wall or on a door frame.

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^ In the circuit shown in Fig. 2, the

The output signal L of the microphone 3 is passed through a capacitor 21 to the non-inverting input of an operational amplifier 22 and amplified there. The -* resistors 23, 24, 25 serve to generate a bias voltage for the non-inverting input of the operational amplifier 22. The inverting input of the operational amplifier 22 is connected to the output via a series circuit consisting of an adjustable resistor 26 and a further resistor 27, which together with a capacitor 28 act as a low-pass filter. For low frequencies, this results in strong negative feedback, so that only the higher frequency components of the output signal of the

^-* microphone 3. In order to achieve a defined amplification for these frequencies, a resistor 29 is connected in series with the capacitor 28.

A peak value rectifier circuit consisting of two diodes 31, 32, a resistor 33 and a capacitor 34 is connected to the output of the operational amplifier 22 via a resistor 30. This peak value rectifier circuit,

" which in principle corresponds to an amplitude demodulator, emits a voltage which corresponds to the amplitude of the higher frequency components of the output signal of microphone 3. Since in the event of a break-in such frequencies hit the microphone 3·

3U" are contained in the sound waves, the output voltage of the peak value rectifier circuit 31 to 34 increases in the event of an alarm.

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The signal is passed to the base of the transistor 38 via an adjustable voltage divider, which is formed by a resistor 35 and a potentiometer 36, and via a Zener diode 37. A resistor 39 is located on the emitter of the transistor 38. In addition, another transistor 41 is connected via a resistor 40, which becomes conductive when the higher frequency components of the audio signal exceed the specified level. A light-emitting diode 9, which is connected in series with the transistor 41 and a wide-stand 43, then lights up. This allows the alarm system to be checked to see whether it is responding.

A further transistor stage with the transistor 44 and the resistors 45 and 46 amplifies the signal almost to the operating voltage. A low-pass filter consisting of a resistor 47 and a capacitor 48 is connected to the output of this stage. This low-pass filter suppresses any S'-öi-pulses from the power supply that may occur and crosstalk into the circuit described. A logic circuit consisting of the NOT-AND circuits 49, 50, 51 is connected to the low-pass filter 47, 48, which at the same time forms a threshold circuit for the signals supplied. In addition to the signal generated with the aid of the microphone 3, a further signal supplied at 52 can be evaluated, which can be obtained, for example, with the aid of a so-called differential loop.

A timing element consisting of a diode 53 and an electrolytic capacitor 54 is connected to the output of the non-and circuit 51. If the output signal of the non-and circuit

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51 from L to H, which occurs when an alarm is triggered, the capacitor 54 is charged relatively quickly via the diode 53 and an output transistor 57 is controlled into the conductive state via a further NOT-AND circuit 55 _and a resistor 56. The output transistor 57 then switches on alarm devices such as a siren or

a flashing light.
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If the switching event that triggers the alarm is only of short duration, the output signal of the NOT-AND circuit 51 falls back to L after a short time. This blocks the diode 53 and the capacitor 54 is discharged via the resistors 58, 59 and the base-emitter path of the transistor 60. The duration of the alarm is therefore dependent on the size of the capacitor 54 and the resistors 58, 59. The resistor 59 is designed as a potentiometer, so that the

Alarm duration can be set.

When the alarm system is switched on, the previously discharged capacitor 62 is gradually charged via the resistor 63 and the diode 64. The capacitor 62 is connected to one input of the NAND circuits 49 and 50. As long as the voltage at the capacitor 62 has not yet reached the switching threshold of the NAND circuits 49 and 50, no alarm signals are transmitted by the NAND circuits 49 and 50. For a short time after the

When switched on, the monitoring device according to the invention is therefore insensitive.

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If the voltage at capacitor 62 has exceeded the switching threshold, signals can be forwarded from low-pass filter 47>48 and from input 52. During the alarm, capacitor 62 is discharged via transistor 60 and resistor 65, so that signals that arrive during the alarm do not lead to an extension of the alarm.

In order to be able to recognize later whether and by ueLchem Sen-

so that an alarm has been triggered, the outputs of the NOT-AND circuits 49 and 50 are each connected to a flip-flop 75, 76 via a series circuit consisting of a resistor 71, 72 and a diode 73, 74. These are reset every time the monitoring device is switched on and triggered by an alarm

set. In order to enable the display even after the alarm system has been switched off, the outputs of the flip-flops 75, 76 are each connected to a timer 77, 78, 79; 80, 81, 82. Two NOT-AND circuits 83, 84; 85, 86 are connected to the timer, which only serve as an impedance converter or as an output stage for the LEDs 10, 11 connected via a resistor 87, 88. The NOT-

AND circuits S3 to 86 receive their operating voltage

voltage directly from the constantly operating power supply unit 91.

If an alarm has been triggered during the operating time of the monitoring device, at least one of the capacitors 78, 81 is charged so that at least one of the LEDs 10, 11 lights up. The discharge time constant of the capacitors 78, 81 is dimensioned such that when the monitoring device is switched on again, which normally only occurs several hours after it has been switched off.

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&Iacgr; the storage of the alarms is released.

Except for the NOT-AND circuit 83 to 86, the power supply to the individual circuits of the monitoring device is via the normally closed contact 92 of a relay 93. The coil of the relay 93 receives operating voltage via the contacts 94 of the key switch 13 (Fig. 1). To switch on the monitoring device, it is therefore necessary that the coil of the relay 93 is de-energized, i.e. that the contacts 94 of the key switch 13 are open. This ensures that if the key switch 13 is destroyed or if the key switch is torn out of its installation location, the alarm system will not be triggered.

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In order to enable operation even in the event of a power failure, a rechargeable battery 95 is provided, which is connected to the output 96 of the power supply unit.

^O tes 91 via a rectifier diode 97. During mains operation, the voltage at the output 96 of the power supply 91 is higher than at the positive pole 98 of the battery 95, the rectifier diode is conductive and is used to charge the battery and operate the

" Alarm system sufficient power is taken from the power supply unit.

If the mains voltage fails, the rectifier diode becomes non-conductive in order to prevent the battery 95 from discharging via the power supply unit 91. The circuit according to Fig. 3 then serves to indicate the mains voltage failure. For this purpose, an input of the NOT-AND circuit 101 is connected to

connected to the output 96 of the power supply 91. 35

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The output voltage of the NOT-AND circuit becomes slightly positive, whereupon an astable multivibrator 104 connected via a resistor 103 begins to oscillate and a light-emitting diode 7> connected via a resistor 10&oacgr; flashes.

The non-and circuits forming the astable multivibrator 104 as well as the non-and circuit are combined in an integrated circuit 107 of type CD 40111. An unused non-and circuit 108 receives a defined potential from the battery via a resistor. A resistor 110 is provided to further reduce the already low power consumption of the integrated circuit 107.

The following values have proven to be suitable dimensions for the high-pass and for the low-pass filter:

Resistance 26: 1 MOhm Resistance 27: 15 0hm capacitor 28: 10 nF Resistance 29: 1 kOhm Resistance 47: 33 kOhm capacitor 48: 150 nF.

Claims (9)

1308 BV Giovanni Bravi, 6112 Groß-Ziminern Claims 1. Monitoring device with an acoustoelectrical transducer, characterized in that a high-pass filter (22, 26 to 29) is connected downstream of the transducer (3). 2. monitoring device according to claim 1, characterized in that the converter has a ceramic microphone (3) ⁵ pcs. 3. monitoring device according to one of the preceding claims, characterized in ² S that a rectifier circuit (31 to 35) is connected to the output of the high pass filter (22, 26 to 29), the output of which is connected via a low pass filter (47, 48) to a threshold circuit (50 to 55). 4. Monitoring device according to one of the preceding claims, characterized in that the high-pass filter is formed by an operational amplifier (22) whose negative feedback branch consists of a Low pass filter (26 to 29). &igr; * ·« it ti ti t * · * t * ttt * &bull; ■ · · · It ■ _t * »·&igr;&igr; ··· ·■ 1 > > > II Il &igr;, ' 1308 BV- - 2 - 5. Monitoring device according to claim 4, characterized in that that the negative feedback branch is formed by a voltage divider, the longitudinal branch (26, 27) of which consists of at least one resistor and the transverse branch of which consists of a series connection of a capacitor (28) with a resistor (29). 6. Monitoring device according to one of the preceding claims, characterized in that the output of the threshold circuit (50 to 55) is connected on the one hand to an alarm device and on the other hand to a timing element (60, 62 to 65), which in turn is connected to further inputs of the threshold circuit (50 to 55). 7. Monitoring device according to claim 6, characterized in that the timing element essentially consists of a capacitor (62) which can be charged via a series circuit consisting of a resistor (63) and a diode (64) from the output voltage of the threshold circuit (50 to 55) and to which the capacitor/lector-emitter path of a transistor (60) is connected in parallel via a further resistor (65), which can be controlled by the threshold circuit via a preferably adjustable voltage divider (58, 59, 61). 8. Monitoring device according to one of the preceding claims, characterized in that a key switch (13) is provided, the.- sen contacts (94) in the control circuit of a relay ft j) ItI 1308 BV-3- t ■ t 11 11 ( tt &igr;&igr;&Mgr; (93) are inserted/ ürtd that the relay (93) is connected via a normally closed contact (92) which is connected to the supply of operating voltage to the monitoring device. 9. Monitoring device according to one of the previous claims/ characterized in that a rechargeable battery (95) is provided for power supply in the event of a mains voltage failure* 1Ö that a flashing circuit (101 to 110) is connected to the battery { rie and a control input of the flashing circuit (K01 to 110) is connected to the output (96) of a power supply unit (91).