ITMI20111990A1 - MAGNETIC SENSOR SUITABLE FOR OPERATING WITH A CORRESPONDING MAGNET AND MAGNETIC CONTACT INCLUDING SUCH MAGNETIC SENSOR AND RELATED MAGNET. - Google Patents

Description

"Magnetic sensor adapted to operate with a corresponding magnet and magnetic contact comprising said magnetic sensor and corresponding magnet"

DESCRIPTION

The present invention relates to a magnetic sensor for alarm systems adapted to operate with a corresponding magnet.

The present invention also relates to a magnetic contact for alarm systems comprising said magnetic sensor and said corresponding magnet.

The magnetic contacts used in alarm systems consist of two parts: a magnetic sensor connected via electrical cables or wireless signals to an alarm panel, and a corresponding magnet.

Depending on the presence or absence of the corresponding magnet near the magnetic sensor, the latter closes or opens an electrical measuring circuit connected to it.

The sensor is intended to be mounted on fixed structures, for example of doors, windows, gates, while the magnet is intended to be mounted on moving parts, for example of doors, windows, gates so as to be positioned near the sensor. when the door, the window, the gate is closed. This position is called the safe position.

When the magnet moves away from the safe position and therefore from the sensor, the sensor sends an intrusion signal to the alarm panel, for example by opening the electrical circuit connected to it.

EN 50131-2-6, section 4.5.5 lists four grades of magnetic contacts, from 1 to 4, where grade 4 is assigned to the safest magnetic contacts. For a magnetic contact model to be "grade 4" certified, each magnet must be paired with a sensor and the manufacturer must supply at least eight different sensor / magnet matching pairs.

In other words, a necessary condition for a magnetic contact model to be considered grade 4 is that the sensors and the corresponding magnets correspond in pairs: a magnet taken from an â € œalphaâ € pair must not be detected as valid when safely placed for a sensor from a â € œbetaâ € pair. In this case, the sensor should send an intrusion signal to the alarm panel even when the magnet is in the safe position. Only an â € œalfaâ € magnet works correctly with an â € œalfaâ € sensor as well as only a â € œbetaâ € magnet works correctly with a â € œbetaâ € sensor.

The aforementioned standard also requires that the relationship between sensors and corresponding magnets should not be evident from a simple visual inspection of the devices.

The purpose of the present invention is to propose a magnetic sensor and a magnetic contact which satisfy the above requirements.

This object is achieved by a magnetic sensor in accordance with claim 1.

This object is also achieved by a magnetic contact in accordance with claims 5 and 6.

Further characteristics and advantages of the magnetic sensor and magnetic contact according to the present invention will result from the following description of a preferred embodiment example, given by way of non-limiting example, with reference to the attached figures in which:

- figure 1 shows a front view of a magnetic sensor and a magnet according to the present invention,

Figure 2 shows a sectional front view of the magnetic sensor and the magnet of Figure 1 according to a first embodiment,

Figure 3 shows a sectional front view of the magnetic sensor and of the magnet of Figure 1 according to a second embodiment.

With reference to the attached figures, 1 globally indicates a magnetic contact for alarm systems in accordance with the present invention.

The magnetic contact 1 comprises a magnetic sensor 10 and a corresponding magnet 20.

The magnetic sensor 10 is intended to be associated with a stationary structure while the corresponding magnet 20 is intended to be associated with a movable structure to and from the magnetic sensor 10.

When the corresponding magnet 20 is arranged in proximity to the magnetic sensor 10, the magnetic contact 1 is in a safe position. When the corresponding magnet 20 moves away from the magnetic sensor 10, the magnetic sensor 10 is intended to send an intrusion signal to an alarm panel.

The magnetic sensor 10 comprises sensor housing 11.

In accordance with an embodiment, the sensor casing 11 has two output terminals 12, 13 for the electrical connection to an alarm panel. Alternatively, it is possible to provide a wireless card (not shown in the figures).

Inside the casing 11 there are first switches 30 and second switches 40.

The first switches 30 are adapted to close in proximity to corresponding first magnets 31 and to open in proximity to second magnets 41.

The second switches 40 are adapted to close in proximity to corresponding second magnets 41 and to open in proximity to first magnets 31.

It should be noted that the first switches 30 are able to open even in the absence of corresponding first magnets 31 and that the second switches 40 are able to remain closed even in the absence of corresponding second magnets 41.

In the embodiment shown in Figure 2, the first switches 30 and the second switches 40 are connected in series according to a predefined sequence to identify a sequence of switches having two terminals 14,15.

In the embodiment shown in Figure 3, the first switches 30 and the second switches 40 are connected in parallel according to a predefined sequence to identify a sequence of switches having the two terminals 14,15.

In the figures, each output terminal 12,13 is connected to a corresponding terminal 14,15 of the sequence of switches. Alternatively, the terminals 14,15 can be connected to a wireless card for connection to an alarm panel.

The corresponding magnet 20 comprises a magnet casing 21 inside which first magnets 31 and second magnets 41 are housed for identifying a sequence of magnets.

In the embodiment of figure 2, the sequence of switches 30,40 is homologous to the sequence of magnets 31,41 so that when the corresponding magnet 20 is in the vicinity of the magnetic sensor 10, that is, it is in a safe position, all the first switches 30 and second switches 40 are closed while, when the corresponding magnet 20 is moved away from the magnetic sensor 10 or away from the safe position, at least one of the first switches 30 or second switches 40 is open. In this way it is possible to create pairs of magnetic sensors and corresponding magnets using a number n of first 30 and second switches 40 and a number n of first 31 and second magnets 41 arranged according to the same sequence in the respective sensor 11 and magnet 21 casings. This allows you to create 2 <n> magnetic contacts, each of which is made up of a predefined pair of magnetic sensor and corresponding magnet. Therefore, only a corresponding magnet 20 constructed with a sequence of first magnets 31 and second magnets 41 homologous to the sequence of first switches 30 and second switches 40 of a magnetic sensor 10 allows all the first and second switches to be closed. In other words, a first magnet 31 must correspond to each first switch 30 and a second magnet 41 must correspond to each second switch 40. Any other corresponding magnet having a different sequence of first and second magnets will not allow the closing of the first and second switches. and therefore it will determine the generation of an alarm signal. In particular, at least one of the first or second switches 30,40 is open when a corresponding magnet having a sequence of magnets not homologous to the sequence of switches of the magnetic sensor 10 is in a safe position.

It should be emphasized that in this embodiment the magnetic sensor 10 correctly detects the corresponding magnet 20 in a safe position only when all the first switches 30 and the second switches 40, being connected in series, are closed, i.e. when the sequence of first and second magnets 31 and 41 in the corresponding magnet is homologous to the sequence of first and second switches 30 and 40 in the coupled sensor. In this way, the magnetic contact 1 according to the invention complies with the EN 50131-2-6 standard, section 4.5.5, allowing this magnetic contact 1 to be classified as "grade 4".

In the embodiment of Figure 3, the sequence of switches 30,40 is dual to the sequence of magnets 31,41 so that all the first and second switches 30,40 are open when the corresponding magnet 20 is in a safe position, while at least one of the first or second switches 30,40 is closed when the corresponding magnet 20 is moved away from the safe position or when a corresponding magnet having a sequence of magnets not dual to the sequence of switches is in a safe position.

The sensor housing 11 is configured to prevent recognition of the sequence of the first switches 30 and second switches 40 in the sensor housing 11.

In particular, the sensor casing 11 can be of plastic or metal material having opacity characteristics such as to prevent the first switches and second switches housed inside it from being seen. Alternatively, it is possible to provide individual housings for each first switch 30 and second switch 40, also leaving the sensor housing 11 transparent or semi-transparent.

In one embodiment, the sensor housing 11 extends along a prevailing longitudinal direction X-X. The first switches 30 and second switches 40 are arranged adjacent in line along this longitudinal direction X-X. In particular, the first 30 and second switches 40 are arranged spaced apart along the longitudinal direction X-X by a distance sufficient to allow the correct operation of the same when arranged in proximity to a corresponding magnet.

Advantageously, the first switches 30 and second switches 40 are Magnasphere switches. In particular, the first switches 30 are form A switches, ie closed with the magnet present, and the second switches 40 are form B switches, ie open with the magnet present.

In this case it is useful to define magnet form A as a magnet that generates a magnetic field sufficient to close a switch form A and to open a switch form B. It is also useful to define a magnet form B as a magnet that generates a magnetic field weak enough to do not close a form A switch and do not open a form B switch.

The magnet housing 21 is configured to prevent the recognition of the sequence of the first 31 and second magnets 41 in the magnet housing 21.

As for the sensor casing 11, the magnet casing 21 can be of plastic or metal material having opacity characteristics such as to prevent the first and second magnets housed inside it from being seen. Alternatively, it is however possible to provide individual casings for each first magnet 31 and second magnet 41, leaving the magnet casing 21 also transparent or semitransparent.

In one embodiment, the magnet housing 21 extends along the prevailing longitudinal direction X'-X '. The first magnets 31 and second magnets 41 are arranged in line along this longitudinal direction X'-X 'which, in the safe position, are parallel to each other and adjacent to the first switches 30 and second switches 40 of the magnetic sensor 10.

The first magnets 31 can be of magnetic material and the second magnets 41 can be of non-magnetic material.

In the example shown in Figure 2, the magnetic sensor 10 comprises first switches 30 and second switches 40 connected in series, in the example respectively form A and form B, which determine the following sequence of switches: A B A A. The corresponding magnet 20 comprises the homologous sequence of first magnets 31 and second magnets 41, in the example form A and form B respectively, which determine the following homologous sequence of magnets: A B A A.

In the example shown in Figure 3, the magnetic sensor 10 comprises first switches 30 and second switches 40 connected in parallel, in the example respectively form A and form B, which determine the following sequence of switches: A B A A. The corresponding magnet 20 comprises the dual sequence of first magnets 31 and second magnets 41, in the example form A and form B respectively, which determine the following dual sequence of magnets: B A B B.

According to an embodiment, the first and second switches 30,40 are arranged in the sensor housing 11 asymmetrically with respect to a centerline A-A passing perpendicular to the longitudinal direction X-X in the midpoint of the longitudinal extension of the sensor housing 11. Similarly, the first and second magnets 31, 41 are arranged in the magnet casing 21 asymmetrically with respect to a centerline B-B passing perpendicular to the longitudinal direction X'-X 'at the midpoint of the longitudinal extension of the magnet casing 21. This allows to establish the coupling direction of the magnetic sensor 10 with the corresponding magnet 20.

As can be appreciated from what has been described, the present invention achieves the intended purposes.

Obviously, a person skilled in the art, in order to satisfy contingent and specific needs, can make numerous modifications and variations to the invention described above, all of which however are contained within the scope of protection of the invention as defined by the following claims.

Claims (9)

CLAIMS 1. Magnetic sensor (10) for alarm systems adapted to operate with a corresponding magnet (20), said magnetic sensor (10) comprising: - a sensor housing (11), - first commutators (30) able to close in proximity of corresponding first magnets (31) and to open in proximity of second magnets (41), - second switches (40) able to close in proximity of corresponding second magnets (41) and to open in proximity of first magnets (31), in which: - said first switches (30) and second switches (40) are housed in said sensor casing (11), - said first switches (30) and said second switches (40) are connected to each other according to a predefined sequence to identify a sequence of switches. Magnetic sensor (10) according to claim 1, wherein said sensor housing (11) is configured to prevent recognition of the sequence of said first and second switches (30,40). Magnetic sensor (10) according to claim 1 or 2, wherein said sensor housing (11) extends along a prevalent longitudinal direction (X-X), said first and second switches (30,40) being arranged adjacent along said longitudinal direction (X-X). Magnetic sensor (10) according to any one of claims 1 to 3, wherein said first and second switches (30,40) are Magnasphere switches. 5. Magnetic contact (1) for alarm systems comprising: - a magnetic sensor (10) intended to be associated with a stationary structure, - a corresponding magnet (20) intended to be associated with a structure movable to and from said magnetic sensor (10), in which: - said magnetic contact (1) is in a safe position when said corresponding magnet (20) is arranged in proximity of said magnetic sensor (10), - said magnetic sensor (10) is configured in accordance with any one of claims 1 to 4, in which said first switches (30) and said second switches (40) are connected together in series, - said corresponding magnet (20) comprises: - a magnet housing (21), - first magnets (31), - second magnets (41), in which - said first (31) and second magnets (41) are housed in said magnet casing (21) to identify a sequence of magnets, - said sequence of switches is homologous to said sequence of magnets so that: - when said corresponding magnet (20) is in a safe position, all the first and second switches (30,40) are closed, - when said corresponding magnet (20) is moved away from the safe position or when a corresponding magnet having a sequence of magnets not homologous to said sequence of switches of said magnetic sensor (10) is in a safe position, at least one of the first or second switches (30,40) is open. 6. Magnetic contact (1) for alarm systems comprising: - a magnetic sensor (10) intended to be associated with a stationary structure, - a corresponding magnet (20) intended to be associated with a structure movable to and from said magnetic sensor (10), in which: - said magnetic contact (1) is in a safe position when said corresponding magnet (20) is arranged in proximity of said magnetic sensor (10), - said magnetic sensor (10) is configured in accordance with any one of claims 1 to 4, in which said first switches (30) and said second switches (40) are connected together in parallel, - said corresponding magnet (20) comprises: - a magnet housing (21), - first magnets (31), - second magnets (41), in which - said first (31) and second magnets (41) are housed in said magnet casing (21) to identify a sequence of magnets, - said sequence of commutators is dual to said sequence of magnets so that: - when said corresponding magnet (20) is in a safe position, all the first and second switches (30,40) are open, - when said corresponding magnet (20) is moved away from the safe position or when a corresponding magnet having a sequence of magnets not dual to said sequence of switches of said magnetic sensor (10) is in a safe position, at least one of the first or second switches (30,40) is closed. Magnetic contact (1) according to claim 5 or 6, wherein said magnet housing (21) is configured to prevent recognition of the sequence of said first (31) and second magnets (41). Magnetic contact (1) according to any one of claims 5 to 7, wherein said magnet casing (21) extends along a prevailing longitudinal direction (X'-X '), said first and second magnets (31, 41) being arranged adjacent along said longitudinal direction (X'-X '). Magnetic contact (1) according to any one of claims 5 to 8, wherein said first magnets (31) are magnets which generate a magnetic field sufficient to close said first switches (30) and to open said second switches ( 40) and said second magnets (41) are magnets which generate a sufficiently weak magnetic field not to open said second switches (40) and not to close said first switches (30).