RU2267814C1 - Alarm signaling system for protection of real estate objects - Google Patents

Abstract

FIELD: technical alarm signaling means for protecting real estate objects.

SUBSTANCE: across territory of protected object, sound emitters are positioned, each one of which is made with light indicator, and signaling cables, to which sound emitters are connected. Also present are receiving and controlling device and control panel. Client has additional mark. Receiving and control device has control device, connected to signaling cables and to control panel, reader, connected to mark via radio, notifications transmission block, made with possible transmission of notifications along wireless and/or wired communication channels to centralized surveillance station. Also, control device has power circuit, consisting of serially connected stabilized power source and first accumulator, and also switch, mounted between output of first accumulator and signal power input of control device, one of outputs of which is connected to input of notifications transmission block. System additionally has generic power bus and one or more voice emitters, each one of which has serially connected power and control blocks, generator of voice messages and loudspeaker. Each sound emitter and each light emitter also has power and control blocks, outputs of which are connected respectively to siren and light indicator. Inputs of all power and control blocks are connected to generic power bus, which is connected to power input of controlling portion of receiving and controlling device. Controlling device is made with possible generation and transfer over generic power bus of high-frequency frequency-modulated signals, carrying control commands for controlling sound, light and voice emitters.

EFFECT: possible prevention or substantial decrease of property damage risk from presence of perpetrators on an object until arrival of fast response forces.

2 cl, 3 dwg

Description

The invention relates to technical means of burglar alarms used to protect real estate (apartments, cottages, cottages, etc.).

Depending on the characteristics of the protected real estate object (length, number of premises, number of storeys, etc.) and the value of material assets placed on it, the protection of this real estate object can be implemented through one or more security alarm loops. The protected property may be a separate room containing material or other valuables, equipped with technical means of a security alarm, or a complex of premises dispersed within one or more buildings, united by a common territory.

The security structure of an immovable property may include several security alarm loops arranged in such a way that when an intruder penetrates a protected real estate object and moves towards material assets, he needs to overcome several protected zones controlled by various security alarm loops (multi-border security).

A security alarm loop is an electric circuit that connects a control and reception device with one or more security detectors - technical means for detecting an intrusion, attempted entry or physical impact exceeding a certain normalized level, and generating a penetration notification. The receiving-control device is a technical tool for receiving notifications (from security alarm loops), converting them into notifications designed for direct human perception, and their subsequent transmission via communication channels (wired or wireless) of the notification transmission system to the central monitoring station ) and / or for issuing commands to enable sirens. In most alarm systems, sound sirens containing a siren and light sirens are used.

The technical equipment described above is a classic scheme for building alarm systems used for centralized protection of various geographically distributed real estate objects ("Directory of Engineering and Technical Workers and Electricians of Technical Equipment for Security and Fire Alarms", Moscow, Ministry of Internal Affairs, GUVO, 1997).

The main differences in the construction of alarm systems are related to the type of notification transmission system used.

In recent years, alarm systems with a wireless notification system have become widespread.

For example, the monitoring and protection system for real estate objects against unauthorized exposure is known according to DE patent No. 4415052, 60 R 25/00, which contains a telephone communication network and data transmission to the monitoring station and beacon-type subscriber transmitters installed on the protected real estate, as well as a notification transmission system with geographically distributed transponders configured to receive alarms from beacon-type transmitters and transmit notifications to at least one of the base stations of the geographically distributed a divided notification transmission system related to the monitoring station, which contains the reception unit and the primary processing unit connected in series, the outputs of which are connected, respectively, to the registration unit and to the display unit.

In a number of notification transmission systems, these repeaters are combined with object terminal devices, forming a microcellular radio channel notification transmission network (patents RU No. 2201363, 60 R 25/10, G 08 B 25/08, RU No. 2198800, 60 R 25/00, G 08 B 13/00).

The disadvantage of the above systems for monitoring and protection of real estate with a microcellular radio channel notification network is the difficulty of their practical implementation, due to the need to agree on a frequency-territorial plan for installing repeaters, obtaining land allotments for their installation, solving the problem of electromagnetic compatibility and a number of other problems.

Therefore, at present, the non-departmental security units, which include quick reaction forces, mainly use the existing telephone network and / or standard mobile cellular networks of regional operators to transmit notifications.

In case of centralized protection of real estate objects, the emphasis is on the reliability of the security alarm equipment and on the speed of reaction of the quick reaction forces to an attempt or the fact that intruders penetrate the protected real estate object. It is assumed that the security alarm system is in constant combat readiness, and if alarm messages are received from it at the monitoring station, the quick reaction forces will be able to arrive at the guarded real estate faster than the violators have time to leave it. However, this is not always possible, especially in large cities, where traffic jams can interfere with the movement of the quick reaction forces. In addition, it is known that serial alarm systems operating on the principle: “the detector has triggered - the alarm notification at the monitoring station has gone” is not effective enough. Some attackers even specifically choose real estate with a centralized security console, knowing that, as a rule, a calmed client doesn’t put anything else besides her. Statistics show that, when attacking, experienced enough attackers previously disrupt telephone communications in order to prevent a regular notification system from working. If the protected property is equipped with a cellular mobile terminal, then an jammer can be used for cellular mobile networks - the so-called jammer, the cost of which on the radio market currently does not exceed $ 20 (for example, advertising materials from the Israeli company NetLine, which mass-produces the jammer C -Guard LP).

Another disadvantage of complexes with a centralized security console is the inconvenience for users associated with the daily procedures for arming and disarming. It is also inconvenient for users to need to transfer keys to the secured property to private security. It should also be borne in mind that, as a rule, the responsibility for false calls of the quick reaction forces rests with the client.

These circumstances deter many potential customers, especially owners of expensive real estate, from concluding contracts for their centralized protection. In recent years, the number of such incredulous potential customers has increased markedly. Accordingly, the number of criminal attacks on expensive real estate has increased. As noted in the newspaper "My Home is My Fortress", No. 1, September 2004, the boom of cottage construction that began among wealthy people was faced with a wave of organized crime. This sets the task of finding alternative ways to build alarm systems. One of such ways is to use the possibility of psychological impact on the attacker.

The fact is that at the time the crime was committed, the attacker, like any predator, is extremely aggravated by all his feelings. It is important for attackers to know that they are alone in the room and their actions are not controlled by anyone. Having penetrated into the guarded premises, the attacker tries, first of all, to turn off the security alarm, for example, by disconnecting the control and receiving device without power or by closing the wires that go to the security detectors. Any sound or light alarms the attacker, and an increased and growing level of sound and light alarm over time can lead him to a state of panic and a readiness to flee.

Robbery statistics show that in (40-65)% of cases (depending on the region), attackers run away if at least some siren sounds in the guarded room and its sounds can be heard outside. Unfortunately, the widespread use of sirens has created more resistant to this type of alarm signaling of intruders. First of all, they seek to stop this noise by returning conditions that are comfortable for robbery. As a rule, especially in small rooms, finding a siren is not difficult. It is also incapacitating from failure. After neutralizing the siren, the attackers suspend their activities for a while and wait. They listen to everything that happens around. This creates the prerequisites for an effective response. Imagine that some time after the first siren is turned off, the second siren is triggered, and with a higher volume than the first. Further, a third siren may work, etc. At the same time, the sound pressure level gradually rises. This scares not only the mindless violators (homeless people, drug addicts, etc.), but also experienced professionals. In such an environment, any surprise can lead to a nervous breakdown and flight of the attacker from the crime scene.

The technical solution proposed below is aimed at using this psychological factor.

The prototype of the invention is the well-known fire alarm system of the Struna family, which includes the Struna-3M notification system with the Struna-801 receiving and control device PPKOP0114-8-1 / 1 GKUN.425513.001, commercially available the applicant company. Information about the specified equipment is given, for example, on the website of the Scientific Research Institute "Security" (www.nicohrana.ru). as well as in the passport GKUN.425513.001 PS for the receiving and control device “Struna-801” PPKOP0114-8-1 / 1.

The security and fire alarm equipment of the Struna family is designed to protect real estate objects and contains sound annunciators distributed throughout the protected property, each of which contains a siren, and light annunciators, each of which contains a light indicator, such as a strobe light, as well as cables security and fire alarms to which security or fire detectors are connected, a control and reception device, connected - directly - with a remote control panel and - p on the air - with a label that is worn by any of the users of the protected real estate object (for remote user identification). The receiving-control device comprises a control unit configured to exchange data with the control panel, a reader configured to interact with the tag over the air, a notification transmission unit, configured to receive notifications from the control unit and transmit them over a wired and / or wireless communication channels to the monitoring station, and the power circuit, consisting of a stabilized power source connected in series, made with the possibility of connecting with the help of a knife switch to the 220 V power supply network, cut a separate battery and a switch connected to the power input of the control unit, to which the fire alarm loops are connected.

Schemes for constructing transmission channels, devices for receiving and processing information in the monitoring station are not considered, since this does not apply to the subject of this invention. Beyond the scope of the present invention, everything related to fire alarms is also deduced.

As in other regular security alarm systems designed for centralized protection of real estate, the security and fire alarm systems of the Struna family do not have anti-intruder mechanisms in place to prevent or at least reduce the risk of losses from their actions on the property’s territory (before the arrival of the rapid reaction forces). This is a disadvantage of the specified fire alarm equipment.

The present invention seeks to remedy this drawback.

The subject of the invention is an alarm system for the protection of real estate, containing sound annunciators distributed throughout the protected property, each of which is made with a siren, light annunciators, each of which is made with a light indicator, and security alarm loops, with which security detectors are connected, as well as a control panel, a control panel and a label located at the user, while the control panel contains a control device, connected to the security alarm loops and with the control panel, a reader connected directly to the control device and tagged radio, a notification transmission unit configured to transmit notifications via a wired and / or wireless communication channel to the monitoring station, and a power circuit consisting of in series connected stabilized power source, configured to connect using a knife switch to the mains, and the first battery, as well as a switch installed between the output of the first a kumulyatora and the input power control device, one of which is connected to the input notification transmission unit outputs. At the same time, the considered alarm system also contains a common power bus and one or more voice annunciators, each of which contains serially connected voice power supply and control units, a voice message shaper and a loudspeaker. Each sound siren and each light siren also includes sound and light power and control units, the outputs of which are connected respectively to the siren and to the light indicator, the inputs of all power and control units are connected to a common power bus, which is connected to the power input of the device control device reception and control, while the control device is configured to generate and transmit on a common power bus high-frequency modulated signals, bearing control commands for sound, light and voice sirens.

Private essential features of the invention are two possible options for the construction of blocks (sound, light and voice) power and control. For all the aforementioned sirens (sound, light and voice) these options are the same.

In the first embodiment, each of the power and control units contains a matching unit in series, the signal input of which is the input of a given power and control unit, a decoder, a microprocessor and a controlled relay, the contact group of which forms the output of this power and control unit, as well as a charging circuit connected in series , the input of which is connected to the signal input of the matching unit, and a second battery, to which the contact group of the controlled relay and power inputs of the matching unit are connected Decoder and a microprocessor.

In the second embodiment, each of the power and control units contains a matching unit in series, the signal input of which is the input of this power and control unit, a decoder, a microprocessor and a controlled relay, the contact group of which forms the output of this power and control unit, as well as a charging circuit connected in series the input of which is connected to the signal input of the matching unit, a second battery and a power switching circuit, the input of which is connected to the signal input of the matching unit, and Exit is connected to the contact group managed relay and to the inputs of power matching block decoder and a microprocessor.

The objective of the present invention is to provide an alarm system for the protection of real estate, which would have incorporated a mechanism for counteracting intruders, which would prevent or at least reduce the risk of material damage from the actions of intruders at the real estate before the arrival of quick reaction forces.

The expected technical result consists in the implementation of a more intelligent algorithm of sirens management, than in the well-known alarm systems, that provides psychological impact on the attackers in order to cause them to panic and want to escape from the crime scene.

The invention is illustrated using the drawings shown in figures 1-4.

Figure 1 shows the General structural diagram of the proposed alarm system for the protection of real estate.

Figure 2 shows the structural diagram of the device control panel.

Figure 3 and figure 4 shows two possible variants of the structural diagram of the power supply and control unit, which can be either an audio power supply and control unit, or a light power supply and control unit, or a voice power supply and control unit.

Figure 1-4 used the following notation:

1 - device control panel; 2 - circuit breaker; 3 - control panel; 4 - security alarm loops; 5 - security detectors; 6 - reader; 7 - label; 8 - control device; 9 - block transmission of notices; 10 - sound annunciator; 11 - light annunciator; 12 - siren; 13 - light indicator; 14 - voice annunciator; 15 - loudspeaker; 16 - common power bus; 17 - sound power supply and control; 18 - light power supply and control; 19 - voice power supply and control; 20 - stabilized power source; 21 - the first battery; 22 - switch; 23 - charging circuit; 24 - the second battery; 25 - matching unit; 26 - decoder; 27 - microprocessor; 28 - controlled relay; 29 is a power switching circuit; 30 - shaper voice messages.

The considered alarm system for real estate protection contains sound annunciators 10 distributed over the territory of the protected real estate, each of which contains a siren 12, to the input of which an audio power and control unit 17 is connected, light annunciators 11, each of which contains a light indicator 13, the input of which is connected to a light unit 18 for power and control, and one or more voice annunciators 14. Each of the voice annunciators 14 contains a series-connected goal axial power and control unit 19, voice message driver 30 and loudspeaker 15. Security detectors 5 and a control and reception device 1 are connected to security alarm loops 4, to which a control panel 3 is connected (containing a control button not shown in FIG. 1, an indicator and buzzer) and the user’s label 7. The security alarm loops 4 are intended for transmitting to the device 1 receiving and control notifications from security detectors 5 and for supplying voltage from the device 1 receiving and control security detectors 5. The receiving-control device 1 contains (Fig. 2) a control device 8 connected with security alarm loops 4, with a control panel 3 and with a reader 6. The reader 6 is connected via radio to label 7. Block 9 of the notification transmission connected to one of the outputs of the control device 8 is configured to transmit notifications to the monitoring station via wired and / or wireless communication channels. The composition of the control and reception device 1 also includes a power circuit, consisting of a stabilized power source 20 connected in series, made with the possibility of connecting with a circuit breaker 2 to the mains, and the first battery 21, as well as a switch 22 installed between the output of the first battery 21 and the input power supply device 8 control.

The considered alarm system also contains a common power bus 16, to which the inputs of all sound 17, light 18 and voice 19 power and control units are connected, as well as the power input of the control device 8, which is part of the control and reception device 1. The specified control device 8 is configured to generate and transmit via a common power bus 16 high-frequency frequency-modulated signals carrying control commands of sound 10, light 11 and voice sirens 14.

The block diagram of the execution of all sound 17, light 18 and voice 19 power supply and control units is the same. In this application presents two of its options (figure 3 and figure 4).

In the first embodiment (Fig. 3), each of the power and control units (sound 17, light 18, or voice 19) contains a matching block 25, the signal input of which is the input of this power and control unit, decoder 26, microprocessor 27, and a controlled relay 28, the contact group of which is the output of this power supply and control unit. The power and control unit also includes a series-connected charging circuit 23, the input of which is connected to the signal input of the matching unit 25, and a second battery 24, to which the contact group of the controlled relay 28 and power inputs of the matching unit 25, decoder 26, and microprocessor 27 are connected.

The second variant of the structural diagram of the power supply and control unit (Fig. 4) differs from the first option (Fig. 3) in that a power switching circuit 29 is introduced into the power and control unit through which the second battery 24 is connected to the contact group of the controlled relay 28 and with the power inputs of the matching unit 25, the decoder 26 and the microprocessor 27. In this case, the second input of the power switching circuit 29 is connected to the signal input of the matching unit 25.

All of the above nodes, blocks and their components (with the exception of the common power bus 16, sound 17 and light 18 power supply and control units, as well as voice sirens 14) are used in the receiver-control device “Struna-801” ППКОП0114 commercially available -8-1 / 1 (Passport ГКУН.425513.001 ПС, Moscow, "Altonika", 2004).

The common power bus 16 and the circuit, consisting of series-connected matching unit 25, decoder 26, microprocessor 27 and controlled relay 28, implement the HOOK-UP technology, a method for controlling security system nodes using a standard power supply bus. The use of this method for the protection of automobiles was proposed by the applicant company in 1996 (patent RU No. 96114269, 60 R 25/00). This technical solution was widely used and was implemented in the family of security and anti-theft systems (catalog "Automotive Security Systems", Moscow, "Altonika", 2004, p. 4-7), commercially available by the applicant company under the trademarks BLACK BUG® ( Certificate No. 158593) and REEF® (Certificate No. 182300). The combination of the control signal transmission channel with the common power bus 16 made it possible to simplify the installation of the alarm system nodes (fewer wires are required), and most importantly, to increase the secrecy of their installation in cars. The same positive result is achieved in the considered alarm system for the protection of real estate.

An analogue of the voice recorder 30 is used in the REEF HF-1000 car speakerphone set commercially available by the applicant company (certificate of conformity No. POSS RU.ME30.B.01281). In addition, the specified voice messaging driver 30 is an integral part of a number of automotive security systems previously patented by the applicant company (for example, RU No. 2211159, 60 R 27/00, RU No. 2214933, 60 R 25/00, 60 R 27 / 00).

As for such units or their components as the first 21 and second 24 batteries, a stabilized power supply 20, a charging circuit 23, a power switching circuit 29 and switching means (switch 2, switch 22), these are ordinary electrical devices widely used at home.

Thus, all the functional units and blocks used in the proposed system are well known, are commercially available and are available for commercial use. Therefore, the possibility of practical implementation of the proposed technical solution is not in doubt.

The considered alarm system for the protection of real estate works as follows (the logic of the work of the security and fire alarm equipment of the Struna family based on the reception and control device Struna-801 PPKOP0114-8-1 / 1 GKUN.425513.001 is taken as the basis).

The connection of the control panel 1 to the 220 V power supply network is carried out using the switch 2 and is indicated on the control panel 3.

The power supply voltage through the loops 4 of the alarm goes to the security detectors 5.

For some time (for example, two minutes) after turning on the power, the control and reception device 1 does not respond to the state of the security alarm loops 4 and, accordingly, does not turn on the alarm in the event of the operation of any security detector 5.

The main modes of the system are:

DISARMED. In this mode, the system monitors the status of only some of the security alarm loops 4. Typically, such security alarm loops 4 are a fire loop (triggered when a fire is detected) and a panic button (triggered if one of the users detects a disturbing effect by an unauthorized person, for example, sees a weapon in the hands of a visitor and presses a special panic button).

Taken under guard. In this mode, the system monitors the status of the entire set of loops 4 alarm.

ANXIETY. The system goes into this mode from the DISARMED or DISARMED modes when one of the security detectors 5 is triggered, in the corresponding mode, and when the device 1 receives a control-alarm signal on the operation of this security detector 5 via the corresponding security alarm loop 4. In addition, the transition to the ALARM mode is also carried out in case of violation of the corresponding security alarm loop 4 (for example, when it is broken). From the ALARM mode, the system can be switched to the DISARMED mode by means of certain user actions.

The switching of operating modes (from the DISARMED state from ARMED to the ARMED ARMED mode, or from the ARMED ARMED mode to the DISARMED mode, or from the ALARM mode to the DISARMED state) is carried out by the user using the control panel 3.

Any of these switching modes of operation is possible only if, in the range of the antenna of the reader 6, which is part of the receiving-control device 1 (Fig. 2), there is a mark 7 previously registered in the non-volatile memory of the control device 8 of the receiving device 1 control. The radius of the range of the reader 6 antenna is about a meter, which allows the user to use the tag 7 without removing it from the pocket. Up to ten tags registered in the memory of control device 8 can be used with the Struna-3M notification transmission radio system.

Consider the basic operations performed by the system.

If the user needs to transfer the system from the DISARMED SECURITY mode to the ARMED SECURITY mode, then he must first make sure that all users except the user have left the protected room. Then this user should, being in the range of the reader antenna 6, issue, with the help of the control panel 3, a command to switch to the ARMED ARMED mode. The control device 8 controls that the reader 6 has detected a tag registered in the memory of the control device 8, and a command to enter the ARMED SECURITY mode has come from the control panel 3. After that, the control device 8 waits for a signal from the security detector 5 installed on the entrance door of the secure room. This signal corresponds to the opening of the front door and its subsequent closure when the user leaves the guarded room. After the user leaves the guarded room and closes the front door, the reception and control device 1 delays the transition to the TAKE-IN-GUARD mode for a further period of time necessary for the transition processes in those security detectors 5, which are volume sensors. The duration of the specified period of time is set programmatically. For example, for the device of the control and monitoring "String-801" PPKOP0114-8-1 / 1 GKUN.425513.001 the typical value of this time period is 45 s. After the specified period of time has elapsed, the control and reception device 1 puts the system in the ARMED PROTECT mode. At the same time, according to the corresponding command of the control device 8, the notification transmission unit 9 sends a TAKE message to the monitoring station.

The transition of the system from the ARMED SECURITY mode to the DISARMED mode starts after the user opens the entrance door, enters the secure room and closes the entrance door. The opening of the entrance door is recorded by the corresponding security detector 5. The signal from this security detector 5 is sent to the control device 8 of the control panel 1 of the control panel via the corresponding security alarm loop 4. According to this signal, the control device 8 captures the beginning of the time interval, which is called the "entry delay" and issues to the reader 6 the command to search for the tag 7 registered in the memory of the control device 8. The entry delay time is set when programming the control device 8. The typical “entry delay” value is 30 s.

During the “entry delay”, the user with the tag 7 registered in the memory of the control device 8 must enter the range of the reader 6 antenna. The tag code 7 passes through the reader 6 to the control device 8. The control device 8 identifies the tag 7 as one of the memory 8 of the control device. At the command of the control device 8, the system enters the DISARMED state. At the same time, according to the appropriate command of the control device 8, the notification unit 9 sends the message DISCONNECTED to the monitoring station.

If the tag 7, registered in the memory of the control device 8, is not detected, then at the end of the "entry delay" time, the system goes into ALARM mode.

When any security detector 5 is triggered, except for the security detector 5 of the front door, as well as if any of the security alarm loops 4 is violated, the system goes into ALARM mode instantly.

When entering the ALARM mode by the appropriate command of the control device 8, the notification unit 9 sends an ALARM message to the monitoring station (with a possible addition to the nature of the alarm).

As in the prototype system, the ALARM mode is accompanied by the inclusion of sound 10 and light 11 sirens, in which sirens 12 and light indicators 13 respectively fire.

In the system under consideration, in addition to sound 10 and light 11 sirens, in the ALARM mode one or several voice sirens 14 can be turned on. Each voice siren 14 allows you to synthesize a specific voice message and sound it using a loudspeaker 15. This creates an attacker who illegally penetrated guarded property (for example, inside a guarded building), the illusion that the property is under surveillance.

The logic of operation (on / off order, duration and loudness of the sound of sirens 12, the brightness of the glow and / or flashing lights 13, etc.) is set programmatically using special software settings. The control commands for sound 10, light 11, and voice 14 sirens are supplied via a common power bus 16 in the form of high-frequency frequency-modulated signals from the control device 8 of the control device 1 of the control panel to the inputs of the sound 17, light 18, and voice 19 power supply and control units (Fig. .one).

The power supply of the considered alarm system is carried out using a power circuit consisting of a stabilized power source 20, the input of which is connected via a circuit breaker 2 to a 220 V network, and a first battery 21 connected through a switch 22 to the power input of the control device 8 and to the common power bus 16 . The switch 22 is used to remove power from the control device 8 in order to prevent a false alarm when making any changes to the program of operation of the control device 8. The opening of the switch 22 also prevents a false alarm, which can cause signals on the alarm loops 4 that occur, for example, when replacing any security detectors 5 or when connecting new alarm loops 4. During normal operation of the system, the switch 22 is always in the closed state.

When the circuit breaker 2 is open (or if the voltage of 220 V is lost for some reason), the stabilized power source 20, which is part of the control and reception device 1, is de-energized and ceases to supply voltage to the first battery 21. In this case, the device 1 is received -control goes to backup power from the first battery 21, which by this time should be reasonably well charged.

After restoring the power from the 220 V power supply, the control-receiving device 1 returns to the mode in which it was before the power was turned off. The facts of power failure are stored in the non-volatile memory of the control device 8 and then, using the notification transmission unit 9, the corresponding notifications can be transmitted to the monitoring station.

A distinctive feature of the proposed alarm system, in comparison with the prototype system, is the ability to control sirens using commands sent in the form of frequency-modulated signals via a common power bus 16 from the control device 8, as soon as the system enters the ARMED SECURITY mode. The sequences of these commands are recorded in the power and control units. As noted above, the construction scheme of each of these power supply and control units is the same. This application provides two options for constructing a power supply and control unit circuit (Fig. 3 and Fig. 4).

In the first embodiment (Fig. 3), the supply voltage from the common power bus 16 is supplied to the input of the charging circuit 23, the output of which is connected to the second battery 24. The charging circuit 23 controls the charging voltage of the second battery 24, for example, a rechargeable battery.

The second battery 24 provides power to the matching unit 25, the decoder 26, the microprocessor 27. The outputs of the second battery 24 are also connected to the contact group of the controlled relay 28.

Passing through the charging circuit 23, the current charges the second battery 24 for a certain period of time. As soon as the voltage on the second battery 24 reaches a predetermined threshold level, the matching unit 25, the decoder 26, and the microprocessor 27 are turned on. At the signal input of the matching unit 25 from device 8 control device 1 control panel via a common bus 16 power supply sequence of commands in the form of frequency-modulated signals. Block 25 matching converts the frequency-modulated signals into a sequence of binary characters, which is supplied to the decoder 26. The decoder 26 extracts from the sequence of binary characters the codes of the commands intended for this power supply and control. These command codes are sequentially supplied to the microprocessor 27 and stored in its non-volatile memory, as specified software settings.

The specified frequency-modulated signals carrying the specified program settings are supplied immediately after the system enters the ARMED SECURITY mode, when the security alarm loops 4 and the common power bus 16 are not violated.

In the second embodiment of the construction of the aforementioned power and control units (Fig. 4), the voltage to the contact group of the controlled relay 28 and the power to the matching unit 25, to the decoder 26 and to the microprocessor 27 are supplied via a common power bus 16 through the power switching circuit 29. If there is no voltage on the common power bus 16, for example, because the attackers cut off the common power bus 16, then the power switching circuit 29 connects to the contact group of the controlled relay 28 and to the power inputs of the matching unit 25, decoder 26 and microprocessor 27 a second battery 24, which at this moment should be in a fully charged state. If on the common power bus 16 there is a necessary supply voltage, then the power switching circuit 29 connects the aforementioned inputs directly to the common power bus 16.

Otherwise, the work of the first (Fig. 3) and second (Fig. 4) embodiments of the sound 17, light 18 and voice 19 power and control units is the same. And after the system enters the ARMED PROTECT mode, the corresponding program settings are entered into the non-volatile memory of the microprocessor 27.

An open of the common power bus 16 for both variants of the power supply and control unit circuit is a command to start the execution of a sequence of commands recorded in the memory of the microprocessor 27. The microprocessor 27 executes these commands until the second battery 24 has developed its resource and voltage at the microprocessor 27 power input will not fall below a given threshold level. These commands are sent to the controlled relay 28. According to these commands, at certain times, the contacts of the controlled relay 28 are closed or opened. The output of the second battery 24 appears and turns off at the output of the controlled relay 28 (applied to the contact group of the controlled relay 28). Accordingly, sirens 12, light indicators 13 or voice generators 30 are turned on or off.

The programming of the system, that is, the recording of software settings in the non-volatile memory of the device 8 of the control device 1 of the control panel is carried out using the so-called master tag.

As in the prototype system (reception and control device “Struna-801” PPKOP0114-8-1 / 1, passport GKUN.425513.001 PS, Moscow, “Altonika”, 2004), to change the program settings, you must first change the contents of the master label using a special programmer. Then, the changed parameters must be rewritten from the master tag into the non-volatile memory of the control device 8.

To do this, the system is transferred to the DISARMED state, and then a master tag is installed near the reader antenna 6. Using the control panel 3, the control unit 8 sets the mode for overwriting software settings from the master tag into the non-volatile memory of the control device 8. The dubbing process is controlled using the control panel 3. At the end of the dubbing process of the software settings, the system automatically returns to the DISARMED state. The return of the system to the DISARMED mode is also fixed using the control panel 3.

As described above, rewriting of software settings in the power supply and control units for sound 10, light 11 and voice 14 sirens is carried out automatically after the system is placed in the ARMED PROTECT mode.

Consider the behaviors of the considered alarm system, depending on the actions of attackers seeking to penetrate the protected real estate.

Suppose that the robbers pick up the keys or crack the front door. This leads to the operation of the security detector 5 of the front door, but, as noted above, for a certain period of time corresponding to the specified "entry delay", the system does not go into the ALARM mode.

During this time, attackers can try various options for influencing the alarm system in order to neutralize or disable it.

Option 1

Attackers disconnect the receiving-control device 1 from the power supply, either by opening circuit breaker 2, or by damaging the electrical wires leading external power supply (220 V) to the protected property.

Like the prototype system, this system will automatically switch to power from a backup source - the first battery 21.

Through a closed switch 22, the voltage will be supplied to the control device 8 and to the common power bus 16, to which the power inputs of all sirens are connected.

Accordingly, after the “entry delay” time has passed, the system will go into ALARM mode, that is, sound 10, light 11 and voice 14 sirens will start to turn on / off sequentially, and alarm notifications will be transmitted to the monitoring station through the notification transmission unit 9. This, of course, does not suit intruders.

Option 2

The attackers knew in advance or immediately discovered the installation location of the device 1 reception and control. Then, after entering the protected property, they can damage the common power bus 16 and all security alarm loops 4. If this had been done with the prototype system, then it would have been completely disabled and the attackers would be able to continue their actions without hindrance without risking being detected.

In the system under consideration, this does not happen, since when the common bus 16 is disconnected from the sound 10, light 11, and voice 14 sirens, each of them switches to stand-alone power from the backup source installed in the power supply and control unit, the second battery 24.

At the same time, in accordance with the software settings previously copied from the memory of the control device 8 to the memory of the microprocessor 27 of this siren, for example, the siren 10, at a given point in time from the output of the microprocessor 27, the siren 12 command is sent to the winding of the controlled relay 28. with it, the controlled relay 28 turns on the siren 12, applying to it from the contact group of the controlled relay 28 the supply voltage from the second battery 24. The siren 12 starts to sound audible alarms. The duration of the supply of each sound signal will be determined by a software installation recorded in the non-volatile memory of the microprocessor 27. After a specified period of time (or when the supply voltage on the microprocessor 27 drops below a certain threshold level), the controlled relay 28 will remove power from this siren 12, and it will stop supplying alarms.

Attackers who entered the guarded real estate property may find the installation site of the activated sound siren 10, after which they will neutralize it even before it has time to exhaust the resource of its backup power source - the second battery 24.

However, it should be noted that this will require certain physical efforts and time from the attackers, since the specified siren 10 can be installed in an inaccessible place, for example, under the roof of a house. But even if the aforementioned sounder 10 can be disabled, such actions will not lead to the desired result, because after a certain programmed interval of the "siren delay", the microprocessor 27 will work in another sounder 10 installed, for example, in the basement guarded house. Accordingly, the output of the microprocessor 27 to the winding of the controlled relay 28 will receive a command to turn on the siren 12. In accordance with it, the controlled relay 28 will turn on this siren 12, applying voltage to it from a backup power source (second battery 24). Siren 12 will start to sound an alarm. The volume of its sound signal will be determined by the corresponding software installation recorded in the non-volatile memory of its microprocessor 27. In this case, the sound volume of the siren 12 of the newly activated sound siren 10 can be set much higher than the previously sounded siren 12.

Similarly, in accordance with predetermined program settings, either light 11 and voice 14 sirens can be switched on sequentially or simultaneously. The software settings recorded in the microprocessors 27 will set for each specific siren:

- the necessary time "delay of the siren";

- the duration and brightness of the light indicators 13;

- content and loudness of sounding by loudspeakers of 15 voice messages recorded in their shapers 30 voice messages.

A set of voice messages, for example, “Penetration Notice has been transmitted,” “Order No. XXX has left,” etc., is designed to have a demoralizing effect on the attackers and force them to abandon their original intentions.

This achieves a psychological effect, the idea of using which is the basis of this invention - to scare off intruders by forcing them to panic escape from a guarded real estate object, without having time to cause substantial material damage to property and material values.

Thus, the combination of new and common with the prototype system essential features allows us to solve the stated problem: to create an alarm system to protect real estate, which can prevent or at least significantly reduce material damage from the presence of cybercriminals at a guarded real estate.

The ensured technical result consists in the implementation of a more intelligent than in the well-known alarm systems, the control mode of sirens, providing psychological pressure on the attackers.

Claims (3)

1. An alarm system for protecting real estate objects, containing sound annunciators distributed throughout the guarded object, each of which is made with a siren, light annunciators, each of which is made with a light indicator, and security alarm loops with which security detectors are connected, as well as the control and reception device, the control panel and the user’s label, while the control and reception device contains a control device associated with security alarm loops and with a control panel, a reader connected directly to the control device and over the air with a tag, a notification transmission unit configured to transmit notifications via a wired and / or wireless communication channel to a central monitoring station, and a power circuit consisting of a stabilized source connected in series power, made with the ability to connect using a knife switch to the mains, and the first battery, as well as a switch installed between the output of the first battery and the power input of the control device, one of the outputs of which is connected to the input of the notification unit, characterized in that a common power bus and one or more voice annunciators are introduced into it, each of which contains a voice and power control unit connected in series, a voice message generator and a loudspeaker, and the structure of each sound siren and each light siren also includes sound and light power and control units, the outputs of which are connected respectively As regards the siren and the indicator light, the inputs of all power and control units are connected to a common power bus, which is connected to the power input of the control device of the control panel, while the control device is configured to generate and transmit high-frequency frequency-modulated high-frequency signals carrying control commands for sound, light and voice sirens. 2. The system according to claim 1, characterized in that each of the power and control units contains a matching unit in series, the signal input of which is the input of this power and control unit, a decoder, microprocessor and a controlled relay, the contact group of which forms the output of this power unit and control, as well as a series-connected charging circuit, the input of which is connected to the signal input of the matching unit, and a second battery, to which the contact group of the controlled relay and power inputs are connected acceptance unit, a decoder and a microprocessor. 3. The system according to claim 1, characterized in that each of the power and control units contains a series-matched matching unit, the signal input of which is the input of a given power and control unit, a decoder, a microprocessor and a controlled relay, the contact group of which forms the output of this power unit and control, as well as a series-connected charging circuit, the input of which is connected to the signal input of the matching unit, a second battery and a power switching circuit, the input of which is connected to the signal input of the unit and matching, and the output is connected to the contact group managed relay and to the inputs of power matching block decoder and a microprocessor.

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