EP0026383A1 - Alarm system for the protection of glass surfaces, especially show-window panes - Google Patents

Abstract

Alarm system with ultrasound which propagates in the pane, and in which continuously received signals are compared with an undisturbed reception signal. <IMAGE>

Description

The invention relates to an alarm system as specified in the preamble of claim 1.

A number of alarm systems which operate on different principles are known for securing shop window panes in particular against break-in with smashing or cutting out at least a portion of the glass pane. For example, electrical current loops have been attached to the inside of the glass panes. If such systems are to offer comprehensive protection, a relatively dense routing of the current conductors on the pane is generally required, which in particular impairs the optical appearance and the transparency of the pane.

Another widespread system is that of the use of structure-borne microphones with which in the Structure-borne noise occurring is recorded and converted into an alarm signal. In principle, such systems are relatively sensitive to structure-borne noise that has nothing to do with the destruction of the window. Such systems respond, for example, to the fact that a bicycle is leaned against the window or that the window is somehow touched by hand without the slightest intent to break in. Faults can also be caused by heavy vehicles passing by. In addition, in systems with recording of structure-borne noise as an alarm signal, these systems have to cover a very wide frequency band because of the many possibilities. However, broadband in particular leads to false alarm triggering, as described above.

It is an object of the present invention to provide an alarm system for glass panes which has a high level of security against false alarm triggering and which does not adversely affect the appearance and the transparency of the pane.

This object is achieved with an alarm system according to the preamble of claim 1 with the features of the characterizing part of claim 1.

The invention is based on the basic idea that the need for broadband detection should be avoided. The solution principle for this is to monitor only very specific predetermined structure-borne sound waves of a preferably even very narrow frequency range instead of detecting any structure-borne sound waves that somehow occur in connection with a break in the pane. For this purpose, the invention provides, primarily artificially in the pane to be monitored generate certain structure-borne sound waves and only monitor these specific structure-borne sound waves without being confused with other possible structure-borne sound waves. For this purpose, it is provided that a predetermined structure-borne sound wave of a certain frequency range is coupled into the pane with the aid of an ultrasound transducer, and signals of this structure-borne sound wave are taken again from the detector receiver also attached to the pane.

At rest, i.e. in the state of an unimpaired pane, constant received signals for all transmission pulses result from structure-borne sound wave pulses coupled into the pane. The structure-borne sound wave pulses are generated at sufficiently short intervals of e.g. 0.1 sec to 0.01 sec coupled in and detected. The sudden occurrence of a crack, a break in the pane or even the cutting out of a portion of the pane leads to a change in the received signals, which is determined electronically by comparison.

For the comparison, it is provided to store an undisturbed received signal and to compare the stored signal with the respectively newly received signal.

• Fig.1 zeigt ein erfindungsgemäßes Alarmsystem für eine Schaufensterscheibe.
• Fig.2 zeigt ein Diagramm des Sendesignals und des ungestörten Empfangssignals.
• Fig.3 ein Diagramm des Sendesignals und eines entsprechend einem Alarmzustand veränderten Empfangssignals.
• Fig.4 zeigt 'ein Prinzipschaltbild der Elektronik eines erfindungsgemäßen Alarmsystems.

Further explanations emerge from the following description of an exemplary embodiment of the invention.

• 1 shows an alarm system according to the invention for a shop window pane.
• 2 shows a diagram of the transmitted signal and the undisturbed received signal.
• 3 shows a diagram of the transmission signal and of a reception signal changed in accordance with an alarm state.
• 4 shows a basic circuit diagram of the electronics of an alarm system according to the invention.

In FIG. 1, 1 denotes a pane to be protected. 2 and 3 designate a known structure-borne sound transmitter and receiver, both of which are known for transmitting acoustic structure-borne sound waves between the transmitter 2 and the pane 1 or between the pane 1 and the receiver 3 on the pane. ter way are attached. An ultrasonic oscillator made of piezoceramic material is preferably used for the transmitter 2. The vibrator is allowed to vibrate at a resonance frequency. For the receiver 3 it is recommended to use the same ultrasonic transducer. how to use for the transmitter 2, with which the requirement of matching frequency position for transmission and reception can be met in a simple manner.

FIG. 2 shows in a diagram the amplitude distribution of the transmission signal S and the undisturbed, that is to say reception signal E not changed by an alarm state, plotted over time t. The pulse length of the transmission signal S is e.g. 10 wavelengths of ultrasonic radiation with e.g. 100 kHz sound frequency long.

3 shows a diagram, comparable to FIG. 2, of such an amplitude distribution, as occurs with a sound wave in a glass pane, which, however, has undergone a substantial change compared to FIG. 2 due to a crack or break, with the correspondingly changed one Receive signal E '.

Fig. 4 shows a block diagram of the electronics of a alarm system according to the invention. With 1 is again the glass pane to be protected, with 2 is the transmitter converter and with 3 is the receiver converter. designated. It should be pointed out here that the transmitter transducer 2 and the receiver transducer 3 can also be one and the same ultrasound transducer and, in the normal case, the signal reflected at the edges of the pane 1 is received by the receiver transducer 3. 3 relates to such an embodiment and shows echo signals.

A generator for the ultrasound transmission signal is designated by 11. A time clock is indicated by 12, the output clock signals of which reach the gate circuit 14 via a divider 13. When a clock pulse is received at the gate circuit 14, a transmit pulse from the generator 11 is fed to the transmit converter 2.

The time clock pulses of the time clock 12 also go to a counter 15, in which the clock pulses of the time clock 12 are divided into, for example, eight lines 115.

The reception signal of the reception transducer 3 goes to an analog-digital converter 23 via an amplifier 21 and a filter 22. The filter 22 is in particular a bandpass filter which is tuned to the ultrasound frequency. The filter 22 also preferably has an amplitude-limiting effect.

24 denotes a memory, to which the output signal of the analog-to-digital converter 23 and the divided time clock pulses are fed in accordance with the lines 115. In the position of the switch 25 shown in dashed lines, the output signal of the analog-digital converter 23, ie the converted received signal, arrives in the memory, in accordance with the time pulse pulse in temporally successive division into eight memory cells. The signal component of the time range t ₂ -t _{1 shown} in FIG. ₂ is thus fed to the first memory cell. The signal component of the time range t3 _- t ₂ is accordingly fed to the second memory cell the following memory cells are stored. A correspondingly higher detector sensitivity can be achieved by a larger number of time ranges provided in accordance with the distribution of the received signal.

In the position of the switch 25 shown by the solid line, namely the "read" mode, signal components divided in time as described above are supplied to the units shown in the lower line of the memory 24 in the same clock sequence of the counter 15 in the manner described above.

The mode of operation of the alarm system in FIG. 4 is that first of all a received undisturbed reception signal (corresponding to the broken line of the switch 25) is written into the memory 24. This is done e.g. with the commissioning of the alarm system.

During the continuous operation of the alarm system, the incoming signals received in the switch position "read" are fed to the memory 24. There is a constant comparison between the signal components stored in the memory cells of the upper line of the memory 24 and the respective time-related, incoming signals to the units indicated in the lower line of the memory 24, for which purpose as shown comparator 28 is provided. If no changes have occurred in or on the disk 1, the signals which come into the units of the lower line of the memory 24 in accordance with the function of the counter 15 each largely with the associated, previously stored signals of the memory cells indicated in the upper line of the memory 24 to match. However, this correspondence is no longer present and the comparator emits an alarm signal if, for example, the pane 1 has got a crack, as a result of which a received signal E 'which has now been changed is received by the receive converter 3.

To take into account long-term changes in disc 1, e.g. warming up of the pane in sunlight, it can be advantageous to do so at long intervals, e.g. at intervals of 10 minutes to 1 hour, to carry out the "registered" operation in accordance with the dashed position of the switch 25, i.e. to replace the previous signal in the memory cells of the upper line of the memory 24 with a corresponding new signal. In the "read" operating state, this is then carried out as described above. Comparison .. Since the writing is carried out, for example, with only a single transmission pulse with a duration of approximately 0.1 ms, there is no danger that such damage to the disk 1 will be carried out at this moment and only at this moment of the rewriting which could not be immediately recognized as an alarm condition during further "reading" operation.

A mean value signal of a plurality of successive undisturbed reception signals (FIG. 2) can also be provided as the written signal for the upper line of the memory 24.

The invention is particularly suitable for protecting glass surfaces. However, the system according to the invention can also be used to protect other surfaces, such as doors, paneling and the like, in which an ultrasound propagation, as is necessary here, with spatial limitation (reflection of the ultrasound) is possible at the edge.

Claims (3)

1. Alarm system for the monitoring of glass panes, in particular window panes, with the aid of ultrasonic structure-borne sound waves, which are picked up by a receiver attached to the pane and evaluated in an electronic circuit, characterized in that to prevent false alarms being triggered on the pane (1 ) an ultrasonic transmitter (2) is attached, with the aid of which predetermined ultrasonic structure-borne sound waves are coupled into the window, which are received by the ultrasonic receiver (3), and that such an electronic evaluation circuit with a memory (28) in which initially the Received signal (E) of an undisturbed state of the disk (1) is written into signal components with a time resolution and then, in monitoring mode, the continuously received further received signals (E, E ') are time-resolved in the same scheme as when writing into signal components and with the stored signal components of the undisturbed one Si gnals (E) are compared in a comparator (28) for changes that indicate an alarm condition. 2. Alarm system according to claim 1, characterized in that renewed writing to the memory (28) is provided at larger time intervals. 3. Alarm system according to claim 1 or 2, characterized. that an average signal from a plurality of successive undisturbed received signals (E) is written.

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