DE3535222A1 - Burglary alarm - Google Patents

Abstract

In order to detect pressure fluctuations when a window or a door is opened, a detector (5) which is sensitive to pressure in the infrasonic range is present, downstream of which detector (5) a signal processing circuit (10, 11) for forming a signal which is dependent on pressure changes is connected. The detector (5) is preferably composed of a ferromagnetic crystal, for example from LiTaO3. The housing (1, 12, 14, 15) for the detector (5) can be partially formed from a diaphragm (15) for the transmission of pressure fluctuations. <IMAGE>

Description

To secure buildings, houses, rooms etc. it is known to place alarm sensors in different locations bring to. This involves extensive installation work perform. For example, there is an alarm system of a two family house

• - an alarm center
• - Sensors for securing the outer skin
• - Sensors for partial interior security.

Passive infrared detectors are used to secure the interior or ultrasonic sensors are provided. With such senso Ren can only in the field of view of each individual sensor Alarm can be detected. Not to let the burglar in the first place Leaving home will continue to be on all doors windows and either contact electrodes attached, who give contact when opening or closing or interrupt an existing contact and the on it following circuit break to the alarms report trale. This in turn gives the alarm. A second possibility Securing the outer skin are so-called glass break alarms that vibrate or smash Window panes react capacitively and a signal to the Submit alarm center. All outer skin devices of this type naturally require supply of lead gen. These are usually plastered so that a considerable installation effort on the future Operator of such a security system. The Installation costs for such a system are approximately  70% to 80% of the creation costs.

The object of the invention is to provide an intruder alarm create, in which the installation effort is eliminated.

This object is achieved by an im Infrasound range pressure sensitive detector, the one Signal processing circuit for forming a pressure Changes dependent signals is connected downstream.

If a closed system is opened, the calls Opening up a dynamic pressure change. These Pressure change is due to the slump according to the invention detectors detected. The pressure change depends on the Ge speed of the opening mechanism. With very slow To open the mechanism, the pressure sensor must also be in deep frequency areas can still be very sensitive.

Ferromagnetic crystals have in certain crystal Orientation directions a pyro-electrical effect. In addition to this pyroelectric effect exists a piezoelectric effect, i.e. Pressure fluctuations who converted into electrical potential shifts and can be detected with a suitable amplifier will. The sensitivity of such crystals to pressure fluctuations, even in the low-frequency area, is very high.

If one starts from a door or a window as an opening mechanism, a very slow opening of these two mechanisms causes a pressure change in the frequency range well below 10 Hz. In this frequency range, ferromagnetic crystals, especially LiTaO ₃ , are still very sensitive. The sensitivity is sufficient so that a measurable signal can be transmitted through doors and rooms located by the transmitter and detector. However, this means that, for example, in a two-family house, the system (detector and signal electronics) can be placed at any point in the middle of the building and opening a door or window on another floor even through the closed doors of the rooms in between can be detected.

The invention is described in more detail below with reference to two exemplary embodiments shown in FIGS. 1 and 2.

In Fig. 1, a base plate 1 is shown, from which three pins 2 , 3 , 4 protrude downward. On the top of the base plate 1 , a pressure-sensitive detector 5 is arranged in the infrasound range, from the connection wires 6 to another, attached to the base plate 1 lead 7 , namely to conductive tracks 8 , 9 on this insulating plate 7th Between the conductive tracks 8 , 9 , a high resistance 10 is arranged. Furthermore, a field effect transistor 11 sits on the conductive path 9 . The components 5 , 10 , 11 are wired in the manner shown and connected to the pins 2 , 3 , 4 .

The detector 5 is located with the components 10 , 11 in a housing, one part of which is formed by the base plate 1 and the other part by a cap 12 connected to it. At least one opening 13 is provided in the cap 12 , through which pressure fluctuations are transmitted to the detector 5 .

In the embodiment of FIG. 2, parts that are the same as parts of FIG. 1 are designated by the same reference numerals. With the base plate 1 , a cap 14 is connected in this example, which has a membrane 15 on its top, through which pressure fluctuations are transmitted to the detector 5 . In the example according to FIG. 2, the detector 5 is accordingly arranged in a closed housing 1 , 14 , 15 , the wall of which is partially formed by the membrane 15 . The membrane 15 mechanically amplifies the pressure fluctuations through optimal coupling.

Claims (6)

1. Intrusion detector, characterized by a pressure-sensitive detector in the infrasound range ( 5 ), which is followed by a signal processing circuit ( 10 , 11 ) for forming a pressure-dependent signal. 2. Intruder detector according to claim 1, characterized in that the detector ( 5 ) is formed by a ferromagnetic crystal. 3. Intruder detector according to claim 2, characterized in that the crystal consists of LiTaO ₃ . 4. Intruder detector according to one of claims 1 to 3, characterized in that the detector ( 5 ) is arranged in a housing ( 1 , 12 ) provided with at least one opening ( 13 ). 5. Intruder detector according to one of claims 1 to 3, characterized in that the detector ( 5 ) is arranged in a housing ( 1 , 14 , 15 ), the wall of which is partially formed by a membrane ( 15 ). 6. Intruder detector according to claim 1, characterized in that the detector ( 5 ) is formed from a pressure-sensitive material.