RU170689U1 - MAGNETIC CONTACT ALARM SYSTEM - Google Patents

Abstract

The utility model relates to the field of security alarm sensors that respond to changes in the state of a protected object, and can be used to detect unauthorized attempts to open doors, gates, windows, safes and provide an alarm by opening the contacts of a magnetically controlled sensor. Most existing magnetocontact sensors allow the possibility of sabotage external magnetic field. Existing sabotage resistant magnetocontact sensors have a complex structure. The utility model presents a tamper-resistant magnetocontact security system of simple design.The essence of the utility model is to use an anti-tamper sensor in the burglar alarm system based on a normally closed reed switch installed in front of the main sensor in the direction of a possible sabotage effect by a magnetic field. In the proposed technical solution, the main and anti-tamper reed switches are connected in series with the electric circuit, and thus, an alarm is generated when an attempt is made to sabotage.

Description

The utility model relates to the field of security alarm sensors that respond to a change in the state of a protected object, and can be used to detect unauthorized attempts to open doors, gates, windows, safes and ensure the formation of an alarm by opening the contacts of a magnetically controlled sensor.

Known magnetic contact detectors of the type SMK-1, SMK-3, IO-102-4, IO-102-5, IO-102-6, containing a sealed magnetically controlled contact (reed switch) and a permanent magnet in plastic or metal non-magnetic cases [1]. As part of the mounted security device, the reed switch and magnet modules are installed parallel to each other (open-mounted detectors) or coaxially (hidden-mounted detectors). The listed and other similar types of magnetocontact sensors allow the technical possibility of sabotage by a strong external permanent magnet, which ensures the preservation of the closed state of the contacts when you remove your own magnet at a response distance.

There are recommendations [2] to increase the reliability of security systems based on the listed magnetic detectors, which consist of installing two similar sensors located at a distance of about 15 mm and connected in series with each other, while the necessary condition is that the directional magnets have magnetic field directions permanent magnets should be counter. The disadvantages of this solution are the need to install two sensors, which leads to more expensive construction, and the need for individual adaptation of the distance between the sensors for each specific type of sensors.

There is a solution [3] that provides a blocking signal when an attempt is made to sabotage when exposed to an extraneous magnet. To ensure this function, the magnetocontact sensor contains two reed switches located in one housing and separated by a magnetic screen. When an external permanent magnet approaches, an additional reed switch is triggered and a device lock signal is generated. The disadvantages of this invention are the complexity of the design of the magnetic sensor, the complexity of combining the output signals with the output device of the security alarm, as well as the structural impossibility of execution in the form of coaxial detectors of flush mounting.

The patent [4] describes the design of a magnetocontact sensor of a balanced type, including several magnetically controlled contacts located in a specific geometric order in a single housing, and a counterpart containing permanent magnets in a geometric order corresponding to the location of the reed switches. The security sensor of this design provides high resistance to sabotage by an external magnet, however, it is quite complicated to manufacture and requires high accuracy of installation on the guarded object. In addition, the disadvantage of the sensor is the impossibility of a hidden installation in the form of coaxial detectors. Security sensors have a similar design, the description of which is contained in the patents [5-7].

A magneto-contact sensor, resistant to sabotage by an external magnet, is described in the patent [8], which contains five magnetically switching contacts, which are electrically connected so that in the normal state the Alarm output is open and the Guard output is normally closed. If any of the magnetically controlled contacts goes into a closed state on the output "A1app" an alarm is received. The device does not require precise adjustment, unlike balanced systems, however, it is quite difficult to manufacture.

The patent [9] describes several design options for the magnetocontact sensor, each of which contains four permanent magnets (2 or 3 on the moving part of the sensor and 1 or 2 magnets on the fixed part of the sensor, respectively). Permanent magnets create a special configuration of the magnetic field, in accordance with which there are magnetically controlled switches connected in a certain way. When you try to expose the security sensor with an external magnet, the magnetic field configuration is violated, and the system gives an alarm. The disadvantages of this solution include the complexity of manufacturing and configuration during installation.

The patent [10] describes a security sensor with magnetic control, which includes several Hall sensors and several permanent magnets installed in a complementary sequence. Magnets have different pole directions. If you try to influence this system with a strong external magnet, the signal from the Hall sensors will be determined by the polarity of the external magnet and the preset code sequence will be violated, which will lead to an alarm. The disadvantages include standby power consumption, low noise immunity, high cost

The patent [11] presents the design of a security sensor containing two reed switches and two small permanent magnets and one large permanent magnet in a movable block in a fixed unit. Each of the reed switches is in the field of action of its permanent magnet, while the system is configured so that in the normal state the magnetic fields of the small magnets and the magnet of the fixed block compensate each other, and the contacts of the reed switches open. In the case of moving the permanent magnet of the moving block, the balance is disturbed and the contacts are closed. The system is resistant to the effects of an external magnet, which will lead to a violation of the overall field balance and closure of at least one of the reed switches. The disadvantage is the complexity and the need to fine tune the system before operation.

Magneto-contact security sensors based on freely moving spherical magnets (MAGNASFERA sensor) described in the patents patents [12, 13] provide resistance to external magnetic field, however, they have high cost, manufacturing complexity and low switching characteristics (low switching current).

Closest to the proposed technical solution is the door opening sensor [14]. The fixed part of the sensor includes two normally open reed switches (main and anti-tamper) connected in parallel and separated by a magnetic screen, a small permanent magnet and a switching main reed switch. In the normal state of the sensor (the door is closed), a permanent magnet installed in the moving part of the sensor compensates with its magnetic field the field of a small magnet in the region of the main reed switch so that it is in the open state. Also in the open state is an anti-sabotage reed switch, the functional purpose of which is to detect exposure to a permanent magnet. If the door is opened, the field balance is disturbed, and the main reed switch closes. When the sensor is exposed to a permanent magnet, the contacts of the anti-tamper reed switch are closed. Since the reed switches are connected in parallel, any of the above actions will lead to the generation of an alarm. The disadvantage of this solution is the high complexity of the design.

The claimed utility model solves the problem of creating a magnetocontact security system resistant to sabotage of a simple design.

In FIG. 1 shows the design options of the magnetic contact security system in an open design. In FIG. 2 presents the design options of the magnetic contact security system in the performance of flush mounted sensors.

The essence of the utility model consists in the use of an additional anti-tampering normally-closed sensor 2 (or several sensors) in a magnetocontact alarm system based on a normally-closed reed switch installed near the main normally-open magnetocontact sensor 1 (based on a normally-open reed switch) in the direction of the possible sabotage effect of a magnetic field. The functional purpose of the anti-tamper sensor is a reaction to exposure to an external magnetic field, in which a normally-closed magnetocontact sensor opens. In the proposed technical solution, the main and anti-tamper sensors are connected to the electric circuit 4 sequentially and in such a way as an unauthorized attempt to change the state of the protected object (opening a door, a window, etc.) and an attempt to sabotage with an external magnet 7 will lead to an open circuit, which corresponds to the alarm. The distance between the permanent magnet 3 of the main magnetocontact sensor and the additional (additional) anti-tamper magnetocontact sensor is set so that in the normal mode the anti-tamper normally closed sensor 2 maintains a normally closed state, and the main normally open sensor 3 closes. In this case, the permanent magnet 3, which is part of the system, changes the state of only the main magnetocontact sensor 1. In those shown in FIG. In 1 open mounting versions of the magnetically contact security system, the permanent magnet 3 is fixed on the door 5, and the main and anti-tamper sensors on the door jamb 6. In the installation options of the magnetically contact security system of the hidden design shown in Fig. 2, the permanent magnet is fixed in the hole on the door end, and main and anti-tamper magnetic contact sensors in the holes in the door jamb 6.

Embodiments of the device are also possible in which the main normally-open magnetocontact sensor and the anti-tamper normally-closed magnetocontact sensor are located in a single housing.

Thus, in the proposed technical solution of the security alarm system, tamper resistance is ensured by exposure to a strong permanent magnet, installation complexity is reduced compared to security systems of a balanced type, and it is possible to use a combination of mass-produced magnetocontact sensors.

LITERATURE

1. RM 78.36.001-99 Directory of engineering and technical workers and electricians of technical means of fire alarm.

2. "Hidden camera" (from 01.01.2005, "Facets of security") No. 556 (05) 2002, line 22-25.

3. Patent for the invention of the Russian Federation No. 2115954 Security alarm device.

4. Patent US 2010/0245004 HIGH SECURITY BALANCED MAGNETIC SWITCH

5. Patent US 5,233,323 DEFEAT RESISTANT INTERLOCK / MONITORING SYSTEM,

6. Patent US 4,661,805 DEVICE FOR INDICATING THE MOVEMENT AND / OR POSITION OF A SHUTOFF 'MEANS

7. Patent US 4,210,889 MAGNETICALLY ACTUATED SENSING DEVICE

8. Patent US 2003/0052780 A1 TAMPER RESISTANT MAGNETIC CONTACT APPARATUS FOR SECURITY SYSTEMS

9. Patent US 8,350,650 B2 QUADRUPOLE MAGNETIC CODED SWITCH

10. Patent US 7,999,644 B2 SWITCH

11. Patent US 7,242,297 B2 ALARM SENSOR

12. Patent US 7,218,194 B2 TAMPERPROOF MAGNETIC SWITCH,

13. Patent US 5,673,021 MAGNETIC SWITCH ASSEMBLY FOR DETECTING UNAUTHORIZED OPENING OF DOORS OR WINDOWS

14. Patent US 3,668,579 MAGNETIC ALARM

Claims (5)

1. Magnetocontact alarm system, consisting of a main normally-open magnetocontact sensor, an additional anti-tampering normally-closed magnetocontact sensor and a permanent magnet, installed in such a way that in the working guard position the field of the permanent magnet closes the main sensor, but does not change the state of the anti-tamper, different the fact that the anti-tampering normally-closed magnetocontact sensor is located near the main sensor in the direction of possible ca with a magnetic field, while the primary and secondary sensors are connected in a series electric circuit. 2. The device according to p. 1, characterized in that the device uses several anti-tampering normally-closed magnetocontact sensors. 3. The device according to p. 1, characterized in that the main normally-open magnetocontact sensor and anti-tampering normally-closed magnetocontact sensor are located in a single housing. 4. The device according to p. 1, characterized in that the main and anti-tamper (anti-tamper) sensors included in the system are made in a design that provides the possibility of flush mounting. 5. The device according to claim 1, characterized in that the tamper sensor included in the system is located in the magnetic sensitivity zone of the main sensor.

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