RU99222U1 - SYSTEM OF RECOGNITION OF THE STATE OF MONITORED OBJECTS - Google Patents

Abstract

 1. A recognition system for the state of controlled objects, including a controlled object, containing a detector for the presence of traces of explosive, or poisonous, or narcotic, or radioactive substances, or traces of firing products, combined with any digital information reader, the output of the detector is connected by the corresponding communication lines to the input of an existing one in the given local area network by means of fixing and positioning, and with the alarm input of the control panel of the security service of the controlled object, and with the input m single situation center, also associated with the output video device and the output of the remote security control signaling controlled object. ! 2. The system according to claim 1, in which the output of the detector in the controlled object is additionally connected to the input lock of the Executive unit of the digital information reader. ! 3. The system of claim 1, wherein the digital information reader is a biometric information scanner, or a public transport validator, or an electronic lock, or an ATM card reader, or a barcode scanner. ! 4. The system according to claim 1, in which the fixing and positioning means is a video surveillance device, a GPS navigator. ! 5. The system according to claim 1, in which the detector with any of the digital information readers is placed in one housing. ! 6. The system according to claim 1, in which the threshold sensitivity of the detector is not lower than 10-12-10-13 g / cm3. ! 7. The system according to claim 1, in which the response speed of the detector is comparable to the time of reading digital information from the media by the reader. ! 8. The system according to claim 1,

Description

The utility model relates to technical methods for ensuring the protection of public order, explosion safety and security of life support facilities, as well as industrial and technological safety at work, and can be used in investigative, forensic, forensic, forensic practice, during operational search measures and ensuring technological and personal safety in crowded places and when monitoring industrial safety on potentially hazardous duction.

A known alarm system and local positioning of a vehicle, containing a transportable complex installed on board the guarded vehicle, which includes a microcontroller, security detectors connected to the inputs of the microcontroller, actuators configured to block the movement of the vehicle and connected to the control outputs of the microcontroller , and a transportable hopping signal transmitter with a reference frequency generator and a transportable transmitting antenna connected to the signal output of the microcontroller, as well as a wearable complex located by the user, which includes a wearable antenna, a portable hopping signal receiver and a personal navigator connected to the first output of the first output of the portable hopping signal receiver and made with the azimuth calculator connected in series and an indication unit, the second input of which is the first input of a personal navigator - RF patent No. 2309064, B60R 25/10, 2007

The disadvantages of the system include the lack of the possibility of continuous monitoring of hazardous substances, as well as the need to purchase and install additional navigation and control equipment (high cost of equipment), lack of signals to automatically ensure the required level of security of the protected facility.

The prototype of the utility model is a security system and a method for checking objects for the presence of hazardous substances - patent for invention of the Russian Federation No. 2236041, G08В 21/00, 2004

Variants of the invention and prototype relate to a terminal security system, a support system in this terminal security system, and to a method for checking items for dangerous substances in parcels or in baggage of passengers or in delivered goods, or in suspicious objects in order to protect people, structures and environment from their possible impact. In this case, "hazardous substances" refers to explosives (EX), poisonous gases and flammable substances.

In general, the terminal system for safety includes a sampling device that takes the surrounding object to be sampled - air together with all the gases contained in it, a mass spectrometer designed to analyze the mass of gas taken for verification by the sampling device, a device communication, which transmits and receives information on the communication line, a display designed to display information, and a control device for all of the above devices, while using the device control In the case of communication, the communication device transfers the mass spectrometric analysis data of the sample obtained with the mass spectrometer to the communication line, the communication device receives information on the determination of the hazardous substance received on the basis of the communication line from the mass spectrometric analysis, and then reproduces it this information on the display.

The way to detect hazardous substances during the operation of this system is that the user purchases or rents a mass spectrometer, which is intended for mass spectrometric analysis of the sample for the content of certain elements in it, and the service company receives mass spectrographic data obtained via the communication line using a mass spectrometer, compares these data with the reference data characterizing hazardous substances, and then sends the results of the verification she received to the user.

The disadvantages of the terminal system and the method of its operation include the need to purchase or rent a mass spectrometer, i.e. the high cost of equipment, the duration of the process of detecting hazardous substances, the inability to continuously determine the presence of hazardous substances — monitoring with a large number of objects being inspected, and the lack of signals to automatically ensure the required level of security of the protected object.

In this regard, the technical problem solved by the utility model is the creation of an easy-to-maintain, fully automated system for recognizing the state of controlled objects of increased accuracy and reliability when determining the presence of traces of explosives, toxic substances, narcotic and radioactive substances, as well as traces of firing products (diphenylamine) , and other (e.g. toxic) substances on the surface of digital information carriers.

This problem is solved in a recognition system for the state of controlled objects, including a controlled object containing a detector for the presence of traces of explosive, or poisonous, or narcotic, or radioactive substances, or traces of shot products, combined with any digital information reader, the output of the detector is connected by appropriate communication lines to the input of the fixation and positioning tool available on the local network, and with the alarm input of the security service control panel object, and with the entrance of a single situational center, also associated with the output of the video surveillance device and the alarm output of the control panel of the security service of the controlled object.

In the particular case of the system execution, the detector output in the controlled object can be additionally connected to the blocking input of the executive unit of the digital information reader.

Specific digital information readers can be a biometric information scanner, or a public transport validator, or an electronic lock, or an ATM card reader, or a barcode scanner.

A specific device used as a fixation and positioning tool may be a video surveillance device, a GPS navigator, etc.

The combination of the detector with any of the digital information readers in the particular case of execution is possible when they are placed in one housing.

For reliable continuous monitoring (detection of traces) of substances on objects carrying digital information, it is necessary to observe several technically important conditions:

- threshold sensitivity of the detector is not lower than 10 ^-12 -10 ^-13 g / cm ³ ;

- the response speed of the detector is comparable to the time of reading digital information from media by a reader;

- a detector is used that determines the traces of these substances from the reading distance, which relates to the possibility of research of contactless cards.

The physical basis of this technical solution is the fact that upon contact of the surface of a person’s body with these substances (for example, when firing a shot, contact with an explosive charge when assembling an explosive device, storing, wearing it, etc.) traces of these substances remain on the surface the human body and then transferred for quite some time to other objects with which it is in contact, which, in particular, are digital information carriers such as an electronic key, contactless card, magnetic card, barcode od on the product, etc. This is due to the low solubility of these substances in water and the renewal time of the sweat layer of human skin (up to 7-10 days).

To illustrate the technical implementation of the recognition system for the state of monitored objects, Table No. 1 shows some basic technical characteristics of the conditions for reliable reading of information from various carriers, and for comparison, Table No. 2 shows some technical characteristics of the Pilot-M explosive vapor detector (according to the manufacturer - LLC "Lavanda-U", Russia).

Table 1 Name of the parameter for reading information contactless card magnetic card (ticket of ground urban transport) train ticket or any barcode carrier ATM minimum time (speed) of reading 0.1 sec 75-1250 mm / s 70-180 lines / sec 75-1250 mm / s positioning not required required required required distance from 0.01 to 5 cm contact up to 1 cm contact

table 2 [Threshold sensitivity (concentration of explosives) not lower than 10 ^-13 g / cm ³ Response time for the presence of explosive vapor no more than 1-2 sec Sampling distance up to 10 cm

Direct comparison of the data in Table No. 1 and Table No. 2 shows that the standard explosive vapor detector used for experimental verification of the system’s operability is suitable for solving this problem.

The drawing shows a block diagram of a system.

The recognition system for the state of controlled objects includes a controlled object 1, comprising a housing with a detector 2 inside it containing traces of explosive, or poisonous, or narcotic, or radioactive substances, or traces of shot products (diphenylamine) and a digital information reading device 3.

The output of the detector 2 of object 1 is connected to the input of any fixation and positioning means available in this local network, in particular, to the video surveillance device 5, as well as to the alarm input of the security control panel 6 of the controlled object 1 and with a single situational center 7 connected also with the output of the video surveillance device 5 and the alarm output of the control panel 6 of the security service of the controlled object 1.

When using the system at facilities where a fast response of the security service of the controlled object is possible, the output of the detector 2 in the controlled object 1 is connected to the blocking input 4 of the executive unit of the digital information reader 3.

As detector 2, detectors Pilot-M, Argus-7, Biotox-10M, Lakmus-4, Kron-VV, MO-2M, Shelf-DS, and many others can be used.

The system of recognition of the state of controlled objects, in accordance with the above scheme, is as follows.

Consider the operation of the system in the subway.

A person who has traces of explosives on his hands must pass through the turnstile. Traces of explosives transferred by the detector 2 of the controlled object 1, which in this case is a turnstile, are transferred from his hands to the magnetic card used by him for this. Since the traces of explosives are fixed simultaneously with the reading of the card, the blocking 4 of the executive unit of the reader 3 occurs, i.e. the turnstile does not open for admission. Simultaneously with the indicated event, the security service was notified by a signal to the remote control 6, therefore, an additional check of the detained person should be carried out with the help of explosive indicators available to security personnel.

To reserve the system, in the event of a person entering through the turnstile, the unified situational center 7 receives information about this event from the output of detector 2, from the video surveillance device 5, and also from the control panel 6 of the metro security service.

A single situational center 7 can monitor the location of the object and its movement using means of fixation and positioning in the presence of several devices in the local network.

To test the possibility of a qualitative determination of the presence of explosive traces when transferring them from the surface of the human body to objects that carry digital information, the following model experiment was performed.

We used the standard Pilot-M explosive vapor detector (supplied as standard), consisting of a vortex sampler, a beta-active drug ionizer, a high voltage asymmetric pulse generator, a low voltage sawtooth voltage generator, and a microprocessor ion spectrum analyzer. The principle of operation of the device detector is drift spectrometry (analysis of the movement of ions in an alternating electric field).

The imitation of the transfer of explosive traces was carried out in two versions - to VISA plastic bank magnetic cards, as well as to Mosgortrans standard paper transport tickets. In this case, the subject contacted the surfaces of the palms for 1-2 seconds with samples of various individual explosives, and then, at the same time, with the indicated information carriers. To simulate a non-contact method of reading information, detection was also carried out at a distance of 5-10 cm from the surface of the carrier object. To simulate the long time elapsed between contact with the explosive and the information carrier, after contact with the explosive, the subject once washed the surface of the palms of his hands with soap and warm water, and then contacted with the indicated information carriers. Simulation of an alarm (security) signal was observed and recorded visually by applying the built-in ALARM signal of the detector itself. Detailed experimental conditions and the name of the explosives used are given in Table No. 3.

It can be seen directly from the data in Table No. 3 that in all cases there is a steady detection of explosive traces, which confirms the operability of the proposed system.

Table 3 №№p / p Name BB Storage medium Detection Method The presence of explosives one 2, 4, 6-trinitrotoluene magnetic card immediately after contact with explosives is detected 2 2, 4, 6-trinitrotoluene paper ticket immediately after contact with explosives is detected 3 cyclotrimethylenetrinitroamine magnetic card immediately after contact with explosives is detected four cyclotrimethylenetrinitroamine paper ticket immediately after contact with explosives is detected 5 pentaerythritol tetranitrate magnetic card immediately after contact with explosives is detected 6 pentaerythritol tetranitrate paper ticket immediately after contact with explosives is detected 7 2, 4, 6-trinitrotoluene magnetic card imitation of a long period of time is detected

8 2, 4, 6-trinitrotoluene paper ticket imitation of a long period of time is detected 9 cyclotrimethylenetrinitroamine magnetic card imitation of a long period of time is detected 10 cyclotrimethylenetrinitroamine paper ticket imitation of a long period of time is detected eleven pentaerythritol tetranitrate magnetic card imitation of a long period of time is detected 12 pentaerythritol tetranitrate paper ticket imitation of a long period of time is detected

Claims (8)

1. A recognition system for the state of controlled objects, including a controlled object, containing a detector for the presence of traces of explosive, or poisonous, or narcotic, or radioactive substances, or traces of firing products, combined with any digital information reader, the output of the detector is connected by the corresponding communication lines to the input of an existing one in the given local area network by means of fixing and positioning, and with the alarm input of the control panel of the security service of the controlled object, and with the input m single situation center, also associated with the output video device and the output of the remote security control signaling controlled object. 2. The system according to claim 1, in which the output of the detector in the controlled object is additionally connected to the input lock of the Executive unit of the digital information reader. 3. The system of claim 1, wherein the digital information reader is a biometric information scanner, or a public transport validator, or an electronic lock, or an ATM card reader, or a barcode scanner. 4. The system according to claim 1, in which the fixing and positioning means is a video surveillance device, a GPS navigator. 5. The system according to claim 1, in which the detector with any of the digital information readers is placed in one housing. 6. The system according to claim 1, in which the threshold sensitivity of the detector is not lower than 10 ^-12 -10 ^-13 g / cm ³ . 7. The system according to claim 1, in which the response speed of the detector is comparable to the time of reading digital information from the media by the reader. 8. The system according to claim 1, in which a detector is used that detects traces of these substances from a reading distance of information.