RU19929U1 - SOUND GLASS DESTRUCTION DETECTOR FOR SECURITY DETECTOR - Google Patents

Description

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y —O-rQ. -; -; - v. - - GLASS DESTRUCTION SOUND DETECTOR FOR SECURITY

DETECTOR

The utility model relates to radio engineering, more specifically to devices for registering the destruction of a glass sheet, rounded in the frame.

The utility model can be used in security detectors containing a sound (acoustic) glass break detector.

It is widely known that such devices are used, the operation of which is based on the amplitude-frequency and time analysis of acoustic waves converted into an electrical signal of sound frequencies in certain frequency ranges in order to register vibrations characteristic of glass breaking.

An important advantage of acoustic glass break detectors is the ability to install the detector at a considerable distance from the protected structure and at the same time control a large number of objects of various sizes and locations 1.

Acoustic detectors can be an integral part of combined detectors, we are talking about combining two detection channels in one detector, the operation of which is based on physically different principles of operation. As a rule, the acoustic channel is combined with detectors of moving objects, for example, a passive infrared (IR) detection channel.

An electret microphone or a piezoelectric element is used as a transducer (sensitive element according to GOST R 50775-95) of acoustic vibrations to an electric signal. Therefore, when installing the detector, it is necessary to take into account not only the maximum removal of the detector to the extreme point of the glass being monitored, but also the viewing angle of the radiation pattern of its sensitive element 2.

Sound detectors can be installed relative to the protected surface on the opposite wall, side wall and ceiling. The optimal values of the angle a between the axis of symmetry of the detection zone (axis

GOIS 13/00

microphone) and the detector mounting plane in the indicated ones differ. So for the opposite wall aa (70 °, 90 °), side wall ac (20 °, 45 °), ceiling - ac (10 °, 30 °). In known cases, a fixed value of the angle a is structurally provided, the value of which determines the preferred installation location of the detector, limiting the conditions of use. Thus, C & K 1025 detectors are known for mounting on the opposite wall with a value of a 90 ° and 1025Z with a value of 15 ° for mounting on the side wall and ceiling 3. Domestic detectors Glass-2-1, Glass-2-2 and Glass- are known 3 (YAL KG. 42513 2.002 TU, YALKG.425132.003 TU, YALKG.425132.004 TU), in which an intermediate value of a is used at 50 °, and for which installation in all of the above cases is allowed.

The required orientation of the detection zone of the sound detectors can be carried out using special plastic corners, for example, the corner 5702 of the 5728 detector from Sentrol, or rotary crown arms, for example, BR-1/2/3 from Visonic, mounted under or on the base of the case. This change in orientation, external to the detector case, is suitable only for detectors that do not contain other detection channels. The disadvantages of this solution in relation to single-channel detectors are insignificant and may be associated with complication of installation, unmasking of the detector at the facility and deterioration of the interior of the room.

For combined detectors, contradictions may arise in the optimal orientation of the detection zones of diverse channels. For example, when combining an acoustic detector with an IR detector. If the axis of the detection zone of the first should be oriented to the protected glass, then the axis of the second should be oriented tangentially to the glass (window) surface. Thus, it is desirable to use these combined detectors on the side wall, i.e. in the case of a (20 °, 45 °). But, a fixed value of a (for a Φ 90 °) would lead to the creation of left and right detectors. The fact is that the zone of the IR detector of the wall application is not symmetrical and such an IR detector does not allow rotation around the normal to the surface of the housing.

In all known detectors containing an acoustic (sound) glass break detector, the attachment angle of the sensitive element (microphone) but with respect to the corne is fixed uniquely.

As a prototype, lime was chosen; atelier Glass-3 YALKG.425132.004 TU. The detector includes a sensitive element (electret microphone) and a signal processing unit. The microphone is actually a microphone capsule (electret with a pre-amplifier), which is placed in some holder, which is uniquely mounted on a printed circuit board on which the signal processing unit is made. In this case, the angle a between the axis of the microphone and the plane of the board is equal to 50 °, and the board is installed in the housing parallel to the plane of installation of the detector to the wall or ceiling. The electrical terminals of the microphone are connected to the circuits of the processing unit by means of hard wire metal contacts.

The task this utility model is aimed at is ensuring the optimal orientation of the detection area of the acoustic glass break detector for all types of installation, not by changing the angle of attachment of the detector housing to the surface of attachment, but by changing the angle of attachment of the microphone relative to the housing.

This problem is solved by the fact that in the glass break sound detector for a security detector, comprising a sensing element (microphone) located in the housing located in the holder and connected to a signal processing unit made on a printed circuit board whose angular position is uniquely fixed relative to the housing, the electrical terminals of the microphone are connected to the circuits of the processing unit by means of flexible contacts, and the microphone holder is configured to change position relative to the housing.

In accordance with claim 2 of the utility model formula, the microphone holder is configured to change position relative to the housing by rotation in one of the planes.

In accordance with n.Z of the utility model formula, the microphone holder is made with the possibility of changing the position relative to the housing by rotation in two planes, while flexible contacts provide

 g

the possibility of multiple rotation of the holder at an angle of 180 ° in one or the other direction.

In accordance with claim 4 of the utility model formula, the microphone holder is capable of changing position relative to the housing by means of removal, while flexible contacts provide the possibility of multiple rotation of the holder through an angle of 180 ° in one direction or another.

The essence of the utility model is illustrated by the drawings:

Figure 1 - diagram of the detector, the arrow indicates the rotation of the holder of the water plane;

Figure 2 - explains the rotation of the holder in two planes;

Fig.Z - explains the possibility of removal and change of position of the holder, where:

1- building;

2- sensitive element;

3- holder.

The acoustic glass break detector operates as follows. When installing the detector, it is necessary to determine the optimal orientation of the detection zone of the glass break detector relative to the protected surface. Having fixed the detector in the selected place, it is necessary to ensure a certain optimal angle.

According to Clause 2 (Figure 1), the optimal angle is provided by turning the holder 3 relative to an axis orthogonal to the plane of rotation. The possibility of rotation is provided by the shape of the holder, which is part of the cylinder.

According to paragraph 3 (Figure 2), the optimal angle is provided by the possibility of rotation of the holder 3 relative to two axes orthogonal to the planes of rotation. The possibility of rotation is provided by the shape of the holder, which is part of a sphere or cone.

According to paragraph 4 (Fig.Z), the optimal angle is provided with the possibility of removing the holder from the housing and turning about an axis orthogonal to the mounting surface of the housing 1.

Thus, the presented utility model can be used in sound detectors for glass breakage.

- 4 The simplest implementation, for example, according to claim 4, corresponds to two positional

installing a microphone holder that provides a values of 70 ° (for mounting on the opposite wall) and a s 20 ° (for mounting on the side wall or ceiling).

Such a decision to change orientation by a significant amount (in our example by 50 °) will not lead to complication of installation, unmasking of the detector at the facility or to deterioration of the interior of the room.

The presented utility model can be used in combined; known and ateliers. For example, when combining an acoustic glass break detector with an IR detector, you can also use the microphone holder according to claim 4 with a two-position installation. Which, for example, provides values a s ± 50 ° for mounting on the left and right side walls. You can use the microphone holder with a three-position installation, providing, for example, a ± 50 ° (for mounting the detector on the side walls), as well as an additional angle of 90 ° (for mounting, for example, directly in the opening of a protected window).

Such a change in microphone orientation relative to the body

automatically leads to a change in the orientation of the acoustic detector coverage area relative to the IR detector zone to ensure optimal mutual orientation of the detector zones.

- G References:

1. Afanasyev N., Klimov A., Nikitin A. Acoustic annunciators of glass destruction. Security information accuracy. N4 (19), 1998

2. Members A.N. Sound annunciators of the destruction of glazed structures. SIC "Protection, Moscow, 2000

3.Volkhonsky V.V. Alarm devices. Ecopolis and Culture, St. Petersburg, 1999.

Claims (4)

1. A sound glass break detector for a security detector, comprising a sensing element (microphone) located in the housing located in the holder and connected to a signal processing unit made on a printed circuit board, the angular position of which is uniquely fixed relative to the housing, characterized in that the electrical leads the microphone is connected to the circuits of the processing unit by means of flexible contacts, and the microphone holder is configured to change position relative to the housing.  2. The sound glass break detector according to claim 1, characterized in that the microphone holder is configured to change position relative to the housing by rotation in one of the planes. 3. The sound detector of glass breakage according to claim 1, characterized in that the electrical terminals of the microphone are connected to the circuits of the processing unit by means of flexible contacts that enable the holder to be repeatedly rotated through an angle of 180 ^° to one or the other side, and the microphone holder is configured to change position rotation relative to the housing in two planes. 4. The sound detector of glass destruction according to claim 3, characterized in that the microphone holder is configured to be removed and positioned relative to the housing.