RU2226003C1 - Object device - Google Patents

Abstract

FIELD: object devices monitoring and controlling terminal alarm and warning devices at object. SUBSTANCE: device is designed for two-way digital data exchange with message transfer systems through busy telephone communication lines. It enables automatic invocation of current- consuming sensors by controlling power supplied to them with aid of microcomputer incorporated in this object device and real-time check-up for changes in all events occurring at object. EFFECT: enhanced self-descriptiveness and automation of device. 1 cl, 1 dwg

Description

The invention relates to object devices, monitoring and controlling terminal devices of protection and signaling at the object and performing two-way digital information exchange with notification transmission systems.

A device is known object system for the transmission of notifications “Cyclone” (TU 25-08.430-80, TU 25-08.431-80, TU25-08.432-80. - Security equipment, No. 1/94), containing fire protection lock cables, property protection lock cables , a block of switches, indication blocks, a signal generator, a code lock, a power source, the disadvantage of which is low information content due to the fixation of a single “actuation” of the object device loops.

A device is known object system for the transmission of notifications “Comet-K” (II1.220.003.TU.- Security Equipment, No. 1/94), containing security lock cables, pulse-width signal block, display units, code lock, power source. The disadvantages of this scheme are the low imitation resistance and information content.

The closest in technical essence to the proposed solution is an object device (RF Patent No. 2110094) containing a microcomputer, an address block, a communication unit made in the form of a level control unit, a matching unit with a communication line, a resonant amplifier unit, a digital signal driver unit and a controlled divider, cipher number block, backup power level block, mains voltage supply block, group of security lock loops, switch block, code lock, the first and second group of information inputs mic the computer is connected to the group of security lock loops, respectively, the third group of inputs is connected to the group of outputs of the switch block, the fourth group of inputs of the microcomputer is connected to the group of outputs of the address block, the fifth group of inputs is connected to the group of outputs of the block of cipher number, the first group of inputs and outputs of the microcomputer is connected to the group inputs / outputs of the code lock, the second group of inputs and outputs is connected to the group of inputs and outputs of the communication unit, the group of outputs of the microcomputer is connected to the group of inputs of the display unit, the first input is is dined with the output of the mains supply unit, the input of which is connected to the input of the power source and the input of the backup power unit, the output of which is connected to the second input of the microcomputer via the backup power level unit.

The known circuit device object (UO) works as follows.

After turning on the power to the UO, its microcomputer with built-in ROM and RAM runs a test diagnostic program. When the diagnostics are completed normally, the microcomputer executes the initial settings program and includes the interrogation of the corresponding security monitoring lock loops (for example, such as “Police Call”, “Firefighter”, etc.) from the group of security lock loops, the purpose of which is stored in the microcomputer memory . The microcomputer UO and through the communication unit provides two-way digital communication with the notification system. If during the survey there were violations of the integrity of any of the interrogated security lock-out loops, then during the next communication session with the notification system of the micro-computers through the communication unit, the UO will send her alarm messages about the status of the broken security loops.

To install UO under protection, it is necessary to go outside the entrance door of the object of protection and close it, insert the key token into the UO code lock. The UO microcomputer reads the key code, at the next communication session, transfers it to the notification system and receives a command in response to take the object under guard. After this, the microcomputer begins a periodic interrogation and monitoring of the status of the corresponding (status of “Security”) security lock loops. It turns on the “Protection” indicator and the “Confirmation” indicator, which is built into the code lock constructively, outputs signals of a given duration, indicating that the object has been armed. Similar to the one described above, but with the polling of the corresponding security loops and the "Security" indicator turned off, the operation of disarming the object is performed. If during the security in the security center there was a change in the status of a security lock loop, then during the next communication session with the security system and the notification system, the security system sends alarm messages to it about all changes in the status of the corresponding security lock cables and will receive a confirmation of the receipt of these messages. Thus, the operator of the notification transmission system has the opportunity to observe the change in events on the plan of the guarded object in real time, make adequate decisions and correctly orient the detention group or fire brigade.

If a current-consuming detector is included in the security lock loop, this type of detector “fires” once and is fixed in this state, ceasing constant monitoring at the facility. To bring the detector back into working condition, in which it starts to record violations at the facility again, it is necessary to find the person responsible for the facility, arrive at the facility with it, open the facility and turn it off, and then turn on the power to the UO. And so with every “trip” of the current-consuming detector.

The disadvantage of this device is that when powered from the UO loops of current-consuming detectors, the detectors are fixed in this state at the first “operation” and information from them stops being transmitted to the notification transmission system until manually disconnecting and then turning on the UO power again .

The aim of the invention is to increase the information content and automation of the object device.

This goal is achieved by the fact that in the object device containing a microcomputer, a block of indicators, a code lock, a communication unit, a first group of security lock loops, the outputs of which are connected to the first group of inputs of the microcomputer, the first group of inputs and outputs of which are connected to a code lock, the second group of inputs / outputs is connected to the communication unit, and the first group of outputs of the microcomputer is connected to the group of inputs of the indicator block, a group of power control units, a stabilizer unit, a second group of protection lock loops are entered, corresponding the outputs of which are connected to the second group of inputs of the microcomputer, the second group of outputs of which is connected respectively to the first inputs of the group of power control units, the outputs of which are connected respectively to the inputs of the second group of security lock cables, and the inputs of the group of power control units are connected to the first output of the stabilizer unit, the group of inputs of which is connected to an external power source, and the second output of the stabilizer block is connected to the first input of the microcomputer, and the third output is connected to the second input of the microcomputer.

Figure 1 presents a block diagram of an object device. The object device contains a microcomputer 1, a block of indicators 2, a first group of security lock loops 3, a code lock 4, a communication unit 5, a second group of security lock loops 6, a group of power control units 7, a stabilizer block 8.

The object device (UO) works as follows. After connecting the power supply (220 V) to an external uninterruptible voltage source, the operating voltage of which, for example, is 12 V, and the information signals “There are 220 V”, and “Level of the backup power source”, which are fed to the group of inputs of the stabilizer block 8 UO, and then the stabilized DC voltage is supplied from it to the power inputs of the electrical circuits of the UO, and the power input of the microcomputer 1. Microcomputer 1 with built-in ROM and RAM runs a test diagnostic program. With the normal completion of the diagnostics of the microcomputer 1 UO through the second group of inputs and outputs and the communication unit 5 carries out periodic sessions of two-way digital communication with the notification transmission system connected between the communication unit 5 and the notification transmission system of the communication line. After establishing a stable connection with the notification system of the microcomputer 1, the UO executes the initial settings program and sends the signals to the corresponding second inputs of the group of power control units 7 to the corresponding outputs of the second group of outputs (marked as permanent control loops in its memory), which according to these signals, power is connected from the output 1 of the stabilizer block 8, through the inputs of the group of power control units 7 to the corresponding inputs of the second group of protection loops 6, respectively but, information about the purpose of which is recorded in the memory of the microcomputer. Then the microcomputer 1 switches to periodic monitoring of the state of these and other loops from the first group of loops 3 of constant monitoring (for example, “Call the police”, “Call the fire”, etc.) information about which is stored in the memory of the microcomputer 1.

Monitoring the current state, the corresponding loops of the second group of security loops 6, is carried out by the microcomputer 1 by periodically polling the corresponding inputs in the second group of inputs of the microcomputer 1, and the first group of security loops 3 by periodically polling the corresponding inputs in the first group of inputs of the microcomputer 1. Information about the state change (for example, “Rupture”, “Norm” or “Closing”) of the controlled loops in both groups of security loops 3 and 6, the form of a message is transmitted from the MA to the notification transmission system during the next session with Tie UO through the communication unit 5 with the notification system. After the occurrence of a “trip” in some loop of the second group of security loops 6 from the current-consuming detector (for example, “Photon-8”, “DIP”), it “trips” once and is fixed in this state, ceasing constant monitoring at the facility. To bring the detector back into working condition, in which it again begins to record violations at the facility, the microcomputer 1 turns off the signal to the corresponding output of the second group of outputs, which through the first group of inputs of the group of power control units 7 and through the corresponding power control unit briefly turns off, and then it turns on the supply voltage to the corresponding loop of the second group of security loops 6. Such a power operation restores the current-consuming detector to its original state. If during the next interrogation of the microcomputer 1 of the “triggered” current-consuming detector, its state has not changed, then the above operation with power and interrogation of the detector will be performed until the loop with the connected detector changes its status to “Normal”. During the next communication session, this state of the microcomputer 1 UO will transmit to the notification transmission system and continue to monitor the status of the described security loop. Similarly to the above, the microcomputer 1 also works with the rest of the constant monitoring loops to which current-consuming detectors are connected.

To install the UO under protection, it is necessary to go outside the entrance door of the object of protection and close it, insert the key token into the 4 UO code lock. Microcomputer 1 UO considers the key code and, at the next communication session, transfers it to the notification system and receives a command in response to take the object under guard. After that, the microcomputer 1 to the corresponding outputs of the second group of outputs (marked in its memory as control loops in the “Protection” mode) sets the signals that arrive at the corresponding second inputs of the group of power control units 7, which by these signals connect the power from the output 1 of the stabilizer block 8, through the inputs of the group of power control units 7 to the corresponding inputs of the second group of security loops 6, respectively. Then the microcomputer 1 begins a periodic interrogation and monitoring of the state of the first and second groups of security lock loops 3 and 6, described in the memory of the microcomputer 1, as constantly monitored and monitored in the "Protection" mode. It turns on the “Security” indicator on the indicator block 2, and the “Confirmation” indicator, which is built constructively in the code lock 4, outputs a signal of a given duration, indicating that the object has been armed. Similar to the above, but with the power off and the polling corresponding to the “Security” mode of the security lock loops and the “Security” indicator, the microcomputer 1 performs the operation of disarming the object. If in the “Protection” mode any violations of the security lock loops occurred, then during the next communication session between the UO and the notification system, the UO sends alarm messages to it about all changes in the status of the corresponding security lock loops and receives an acknowledgment of receipt of these messages in the same way as described above during operation with constantly monitored security loops.

If at the time of installation of the facility under protection or before that, the microcomputer 1 UO determined by polling the stabilizer 8 through its input 1 that the voltage level of the backup power supply of an external uninterruptible voltage source is not sufficient for the operation of the UO, then a message will be sent to the notification system, and the UO will not be secured until the backup power level is established sufficient. If the AC mains voltage disappears or reappears on an external uninterruptible voltage source that will record the microcomputer 1. UO by interrogating the stabilizer 8 through its input 2 and the UO will transmit a message about these events to the notification transmission system during the next communication sessions.

Thus, the increased information content of the proposed MA allows the operator of the notification transmission system to observe on his monitor, on the plan diagram of the protected object, changes in all events occurring at the object (coming from all controlled security loops) in real time, which will allow adequate decisions to be made in a timely manner and properly orient the actions of the detention group and the fire brigade.

Claims (1)

An object device containing a microcomputer, a block of indicators, a code lock, a communication unit, a first group of security lock cables, the outputs of which are connected to the first group of inputs of the microcomputer, the first group of inputs and outputs of which is connected to the code lock, the second group of inputs and outputs is connected to the block communication, and the first group of outputs of the microcomputer is connected to the group of inputs of the indicator block, characterized in that a group of power control units, a stabilizer block, a second group of security lock loops, the corresponding outputs of the swarm are connected to the second group of inputs of the microcomputer, the second group of outputs of which is connected respectively to the first inputs of the group of power control units, the outputs of which are connected respectively to the inputs of the second group of security lock cables, and the inputs of the group of power control units are connected to the first output of the stabilizer block, the group of inputs of which connected to an external power source, the second output of the stabilizer block is connected to the first input of the microcomputer, and the third output is connected to the second input of the microcomputer.

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