RU69997U1 - DEVICE FOR IDENTIFICATION OF EXPLOSIVES AND EXPLOSIVE HAZARDS IN VEHICLES - Google Patents

Abstract

The utility model relates to the field of gas analysis and is intended to increase the reliability of the detection of explosives (explosives) and explosive objects (GP) in vehicles. The utility model can also be used to detect narcotic (HB) and poisonous substances (OS). The objective of this technical solution is to significantly increase the reliability of the detection of explosives, HB, OV and GP in vehicles. A device for detecting explosives and explosives in vehicles contains a camera whose internal dimensions exceed the dimensions of the object being examined, a vacuum unit and an explosive vapor absorption unit. The evacuation unit is made in the form of one or more suction pumps, one or more flexible ducts are attached to each of them, and the suction ends of the flexible ducts are equipped with individual distance sensors and associated control channels for individual displacement drives. At the same time, the suction ends of flexible ducts with individual distance sensors and individual displacement drives can be placed at a distance of 2 ... 10 internal diameters of the air duct on one or more frames equipped with movement mechanisms. 2 s.p. f-ly, 1 ill.

Description

The utility model relates to the field of gas analysis and is intended to increase the reliability of the detection of explosives (explosives) and explosive objects (GP) in vehicles. The utility model can also be used to detect narcotic (HB) and poisonous substances (OS).

A device for detecting explosives and VOP in suspicious objects and baggage with a relatively isolated internal volume, containing a camera whose internal dimensions exceed the dimensions of the object being examined, with a device for evacuating it and a unit for absorbing explosive vapor [1].

The disadvantage of this device is the low reliability of detection of explosives and VOP in vehicles, due to the complexity of the long-term ensuring the tightness of the chamber in the conditions of repeatedly repeated cycles of sealing and evacuation, especially when examining heavy vehicles with a dirty chassis. Under these conditions, even powerful vacuum pumps with an appropriate energy consumption may not be able to cope with the influx of air from outside through contaminated chamber seals.

The objective of this technical solution is to significantly increase the reliability of the detection of explosives, HB, OV and GP in vehicles.

The problem is solved in that in the device for detecting explosives and GPs in vehicles containing a camera, internal dimensions

which exceeds the size of the test object, with a vacuum unit and a vapor vapor absorption unit, the vacuum unit is made in the form of one or more suction pumps, to each of which one or more flexible air ducts are connected, and the suction ends of the flexible air ducts are equipped with individual distance sensors and associated control channels for individual displacement drives. In this case, the suction ends of flexible ducts with individual distance sensors and individual displacement drives can be placed one from another at a distance of 2 ... 10 internal diameters of the air duct on one or more frames equipped with movement mechanisms.

The analysis of the claimed solution showed that a significant increase in the reliability of the detection of explosives and airflow in vehicles is ensured by the implementation of the vacuum unit in the form of one or more suction pumps, to each of which one or more flexible air ducts are connected, and the supply of the suction ends of the flexible air ducts with individual sensors distances and associated control channels for individual displacement drives.

Figure 1 presents a diagram of a device for detecting explosives and VOP in vehicles in the embodiment of the placement of the vacuum unit on a U-shaped frame that moves along the vehicle.

The device comprises a chamber 1, the internal dimensions of which exceed the dimensions of the examined vehicle 2. The chamber 1 can be made with a rigid non-deformable body, or from elastic materials. In this embodiment, the vacuum unit in the form of several suction pumps 3, each of which is connected to one flexible duct 4, is placed on a U-shaped frame 5 that is moved along the vehicle, for example, along rails, similar to automated X-ray television systems for inspecting vehicles . The suction ends of the flexible ducts 4 are provided

individual distance sensors 6 and associated control channels for individual displacement drives 7. The internal diameter of the flexible ducts 4 may be 10 ... 50 mm. Individual displacement drives 7 may be electromechanical or pneumomechanical. Blocks of vapor absorption of explosives (not shown), for example, in the form of a grid-concentrator from a set of portable explosive vapor detector [2], are placed between the suction end of each flexible duct 4 and the corresponding pump 3.

Instead of absorption blocks of explosive vapor or in conjunction with them, absorption blocks of narcotic and toxic substances can be used, which greatly expands the device's ability to detect hazardous substances.

During the inspection, the frame 5 moves along the vehicle 2. Individual distance sensors 6 constantly monitor the distance between the suction tip of each flexible duct 4 and the corresponding nearest surface of the vehicle 2 and transmit control signals via individual control channels to individual displacement drives 7. The optimal distance for vapor collection or microparticles BB from the surface of the vehicle 2 - not more than 50 ... 100 mm. Upon receipt of the control signal from the sensor 6, the corresponding individual displacement drive 7 provides the extension, retraction or bending of the suction tip of the flexible duct 4 in order to provide the optimal distance for collecting vapors and microparticles of explosives from the surface of the vehicle 2 and eliminating hooks.

Suction pumps 3 provide a vacuum in the air near the surface of the object being examined. Air flows with microparticles and explosive vapors pass through explosive vapor absorption blocks. A possible influx of air from outside through the dirty seals of the chamber 1 does not affect the results of the examination.

After the passage of the frame 5 along the entire vehicle 2, the blocks of absorption of explosive vapor are analyzed using various explosive detectors or chemical rapid tests for the presence of explosive traces. In the case of using absorption units for narcotic and toxic substances, their analysis is carried out using appropriate detectors or chemical rapid tests.

Thus, the proposed technical solution provides a significant increase in the reliability of the detection of explosives, HB, OV and GP in vehicles.

List of sources of information:

1. A device for detecting explosives and explosive objects in suspicious objects and baggage with a relatively isolated internal volume. - Application for utility model No. 2007117860, IPC ⁸ : G01N 1/22. 2007.

2. Pilot-M explosive vapor detector. - User's manual. M., Lavender-Yu (www.lavanda-u.ru).

Claims (3)

1. A device for detecting explosives and explosive objects in vehicles, containing a vacuum unit and an absorption unit for explosive vapor, characterized in that the vacuum unit is made in the form of one or more suction pumps, to each of which one or more flexible ducts are connected, and the suction ends of the flexible ducts are equipped with individual distance sensors and associated control channels for individual displacement drives. 2. A device for detecting explosives and explosive objects in vehicles according to claim 1, characterized in that the suction extremities of the flexible ducts are placed at a distance of 2 ... 10 internal diameters of the duct. 3. A device for detecting explosives and explosive objects in vehicles according to claims 1 and 2, characterized in that the suction ends of flexible ducts with individual distance sensors and individual displacement drives are placed on one or more frames equipped with movement mechanisms.