EP0358942A2 - Glass plate breakage detector - Google Patents

Abstract

A glass plate breakage detector is to be presented, which can be mounted without connection cables on a pane of glass to be monitored and has small outer dimensions. The glass plate breakage detector is to be designed in such a way that it can be manufactured by fully automatic production methods. Inside the glass plate breakage detector, the receiver detecting the vibrations typically occurring when there is a glass breakage consists of a frequency sensor (F), manufactured micromechanically, which is integrated, together with an electronic evaluation device (A) and a transmission device (SE), in a common substrate (S). The transmission device (SE) passes a detected glass breakage radiotelegraphically to a receiving device which has access to an alarm system. The glass plate breakage detector additionally contains its own power supply. Glass plate breakage detectors of this type are very small and can therefore be mounted easily and inconspicuously, especially since no cabling is necessary. The glass plate breakage detectors can be manufactured particularly inexpensively by automatic production methods. <IMAGE>

Description

The invention relates to a glass break detector with a receiver which detects the vibrations which occur when a glass breaks, which is attached to a glass pane to be secured together with a downstream evaluation electronics and which cooperates with an alarm system.

A method and device for determining the vibrations that occur when an object, in particular a glass pane, is damaged is known from DE-OS 27 38 793. It is a glass break detector, the individual components, in particular the electronic parts, are applied to a ceramic plate. Some switching elements can be built using thick film circuit technology, as described on page 6. However, as separate components, the piezo elements have to be fitted and soldered onto the corresponding contact surfaces of the ceramic plate. Even when using monolithically integrated circuits for the evaluation electronics, these must be assembled as separate components. In addition, a cable connection is provided for the transmission of the generated alarm message. A glass breakage detector constructed in this way requires a relatively large number of individual work steps during manufacture and the laying of a cable during installation.

From DE-OS 32 43 161 a device for securing windows, doors and the like is known. Electrical warning devices are attached to the points to be secured, which each have an independent power generator, a sensor and a signal-generating transmitter. The alarm signals are perceived by a receiver which is followed by an alarm device. In this device, the alarm signal is initially given wirelessly from the point of origin, so that no cabling of, for example, glass break detectors is required. Since the task with the subject matter described in this document is merely to achieve greater flexibility for known sensor devices, in particular with regard to the power supply, no precise information about the nature of sensors, in particular glass breakage detectors and their internal structure, can be found at this point.

A vibration sensor with one or more tongues that can be excited by mechanical vibrations is known from European patent application 88 106 263.2. The tongues are etched from a substrate, and the devices for converting the mechanical vibrations of the tongue into electrical signals and the devices for evaluating the same are accommodated on the same substrate. In this patent application, the vibration sensor is only described as such, and special applications are only hinted at.

The object of the invention is to present a glass breakage detector in miniature design, which has an extremely small footprint and can be easily installed at any point without a connection cable. Fully automatic manufacturing processes should be able to be used in the production, whereby the assembly of individual components can be largely avoided.

This object is achieved with a combination of features as specified in claim 1.

This advantageously ensures that the installation of glass break detectors is so simplified that no special expertise is required. Because there are no cables, and because the glass breakage detectors are very small, they can be attached inconspicuously anywhere. They can also be manufactured inexpensively through the use of fully automated manufacturing processes.

The developments of the invention specified in the subclaims provide advantageous examples of use of the miniature glass break detector described.

An embodiment of the invention is explained below with reference to a drawing. The drawing shows schematically how the individual components of the glass break detector are arranged on a common substrate S. The frequency sensor F can be incorporated into the substrate in such a way that it does not have to appear as an independent component. The frequency sensor F is electrically connected to an evaluation device A with conductor tracks applied or etched out on the substrate S. The output of the evaluation device A is connected to a transmission device SE, which transmits a corresponding signal wirelessly when the evaluation device A has detected the typical vibrations that occur in the event of a glass breakage using the frequency sensor F.

The substrate S consists of silicon, the tongue Z of the frequency sensor F located in an opening O being produced by etching. The opening O can either be designed as a depression or as an opening in the thin substrate sheet. The tongue Z is provided with an electrically conductive layer S1 and the fixed part at the level of the tongue Z with a further electrically conductive layer S2. Both layers S1 and S2 form the electrodes of a capacitor and are over

Lines L are electrically connected to the evaluation device A. The second layer S2 does not necessarily have to be applied opposite the end of the tongue Z, it can also be applied next to the tongue Z or below or above it. The tongue Z can also be provided with a piezoactive layer which is connected to the evaluation device A by lines. The layers and the lines L can be applied by vapor deposition.

The evaluation device A is incorporated as an integrated circuit in the substrate S made of silicon, and amplifiers, memories, etc. may be present. The transmission device SE is also integrated in the substrate in the same way. The connections for the power supply and the signal inputs and the outputs can be designed for connecting gold wires by means of bonds, which lead to the electrical connections of the integrated circuits.

The opening O and the tongue Z can be produced in a series of process steps, which are followed by a series of further process steps for producing the layers S and lines L. Subsequently, the evaluation circuit A and the transmission device SE are then produced on the substrate S as integrated circuits in the substrate S.

The evaluation device A and the transmission device SE do not necessarily have to be arranged in the same plane and on the same side of the substrate S, rather it is also conceivable for the layers S and the lines L on one side of the substrate and on the other side of the Apply the evaluation device A or the transmission device SE to the substrate S, the lines L correspondingly being led from one side to the other side of the surfaces of the substrate S.

In the event that the substrate S, which is used for the production of the evaluation devices designed as integrated circuits device A, or the transmitter SE is suitable, has unfavorable properties with respect to the vibration behavior of the tongue Z, or that the manufacture of the tongue Z causes great difficulties for manufacturing reasons, it is also conceivable to divide the substrate S functionally, two substrates with different physical properties are used. One substrate favors the production of the tongue Z using micromechanical etching techniques and / or its vibration behavior, while the other substrate is suitable for producing integrated circuits by means of microelectronic process steps.

The frequency sensor F, the tongue shape of which can have different geometries, can be designed for a specific frequency or for a frequency range, in the latter case there being a plurality of tongues of different lengths. By comparing the desired frequency spectrum, there is the possibility of being able to react frequency-selectively to selected vibrations.

The frequency sensor F thus works in such a way that the typical broken glass noises are detected by excitation of the micromechanically produced tongue structures and / or converted into electrical signals via piezoelectric conversion. These electrical signals then arrive at an evaluation device A, where they are checked for their amplitudes and buffered when activated. As a result, the transmitting device SE is controlled and gives an alarm signal to a receiving device, which can be done on the basis of radio waves (microsender), infrared sources (IR diode) or ultrasound. Appropriate signal coding can ensure that signaling devices respond selectively.

If the glass break detector is to be operated as an active detector, a piezo film P is additionally placed on the substrate underside applied, which is then glued to the glass pane to be monitored. Monitoring signals are coupled into the glass pane via this piezo film, so that an alarm can be triggered when the receiving frequencies change. In such a case, as described above, a wireless alarm signal is emitted by the transmitter SE.

The piezo film mentioned is a thermoplastic (PVDF-polyvinylidene fluoride), to which a piezoelectric behavior is imparted by mechanical / electrical pretreatment.

A space is also provided on the substrate S for the power supply SV, from where the corresponding conductor tracks for feeding the individual parts of the glass break detector lead to the individual connection points. Contact elements can be located here so that mono button cells or miniature batteries can be attached. At this point it is also possible to connect solar generators which are applied to the outer surface of a housing (not shown) or to the substrate S in a housing which is then translucent.

The alarm signal emitted by the transmitter device SE of the glass break detector can be received by any nearby telecommunication terminal which has a suitable receiver. It can be a telephone set FA, which is then automatically activated so that an alarm message can be issued. When a glass break alarm message is received, a telephone number stored in the telephone set FA can be dialed, a telephone connection being set up in a known manner. At the point answering the call, special measures can then be used to determine from where the

Call has been made. This enables the alarm message to be localized. When setting up such an alarm connection, it can also be provided that an alarm system is controlled directly and, when the connection is established, special characteristics, which are also stored in said telephone set FA, are transmitted.

However, it is also possible to provide a receiving device in a detector M, which is connected to a line of a hazard detection system. This can be an already existing detector, for example a fire detector, which is activated by the transmitting device SE. The alarm and the determination of the location of the detector are then taken over by the relevant alarm system.

When glass breakage detectors are attached, it can of course be done in such a way that each individual glass breakage detector acts on a predetermined receiving device in which different frequencies and / or different codes are used when transmitting the alarm signal. However, it is also conceivable that several individually attached glass break detectors act together on the receiving device of a telephone set FA or a detector M.

Claims (10)

1. glass break detector with a receiver which recognizes the typical vibrations that occur when a glass breaks, which is attached to a glass pane to be secured together with a downstream evaluation electronics and cooperates with an alarm system,
characterized,
that the receiver consists of a micromechanical frequency sensor (F) produced by etching on a substrate (S) and a downstream evaluation device (A) integrated into the same substrate (S), which also integrates into the same substrate (S) Controls transmission device (SE), which wirelessly forwards a detected glass breakage message to a receiving device with access to an alarm system, which uses a silicon chip as a common substrate (S), and the production according to a method customary for monolithically integrated circuits, or with which Microelectronics known etching process is performed
and that a separate power supply (SV) is installed in the glass break detector. 2. glass break detector according to claim 1,
characterized,
that a telephone (FA) serves as a receiving device for the wireless reception of alarm messages from the glass break detector. 3. glass break detector according to claim 1,
characterized,
that a detector (M) connected directly to an alarm system serves as a receiving device for the wireless reception of alarm messages from the glass break detector. 4. glass break detector according to claim 1,
characterized,
that a microphone transmitter is used as the transmitting device (SE). 5. glass break detector according to claim 1,
characterized,
that an infrared transmitter is used as the transmitting device (SE). 6. glass break detector according to claim 1,
characterized,
that an ultrasound transmitter is used as the transmitting device (SE). 7. glass break detector according to claim 1,
characterized,
that at least 2 frequency sensors (F) are provided, one of which reacts to the sound of falling glass fragments, and that the signal generated therefrom is linked to the signal of the breaking noise of glass. 8. glass break detector according to claim 1,
characterized,
that in the case of active glass breakage detectors, in addition to a frequency sensor (F), a piezo film (P) is provided for coupling signals to the glass pane. 9. glass break detector according to claim 1,
characterized,
that a mono button cell or a miniature battery is used as the power supply (SV). 10. glass break detector according to claim 1,
characterized,
that for the power supply (SV) solar cells are provided, which are applied either on the housing or on the substrate (S) in a then translucent housing.

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