RU2642599C2 - Set of quick tests for presence of explosive materials - Google Patents

Abstract

FIELD: measuring equipment.

SUBSTANCE: invention relates to devices for the study and analysis of non-biological materials by chemical indicator means for the purpose of rapid detection of explosive residue in a contact test portion, including during examinations in an off-laboratory environment. The quick tests set for the presence of explosives consists of a portable plastic container equipped with an internal cushioning insert with functional recesses, including recesses for installation of microcolumns, bottles with solutions placed in the recesses, as well as micro-column test systems for detecting the presence of chlorates and perchlorates, cases with rolls tapes of reactive indicator materials containing reagents immobilized on the surface of the carrier. Cases with rolls of tapes of reactive indicator materials consist of a body made of an elastic inert material in the form of hollow cylinders with a coaxial cap tightly adjacent to the cylindrical surface. The side walls of the cases have longitudinal slots through which the edge of the tape passes, and in addition, the body and the cover have mutual angular mobility around the axis, providing, when their longitudinal slots are aligned along one line, before the open window is formed, the function of opening the case with release of the edge of the tape, or mutual overlapping of their longitudinal slots function of hermetic sealing of the case with fixation of the edge of the tape.

EFFECT: higher safety of use and simplified operation.

9 cl, 2 dwg, 1 tbl

Description

The invention relates to devices for the study and analysis of non-biological materials by chemical indicator means, designed more specifically for the express detection in a contact sample of the presence of traces of explosives (BB) and components of explosive compositions (BC) with their preliminary classification as the main chemical classes of energy compounds, including during research in off-laboratory conditions, in particular, directly at the sites of operational-technical, screening events at in the open air.

Both in our country and abroad, technical means are being developed that allow timely detection of improvised explosive devices and the identification of persons involved in their trafficking. From this point of view, the most unambiguous and reliable criterion for assessing objects is the determination of direct signs of potential danger - the presence of explosives and aircraft in the composition of the studied substances of an unknown nature, on the packaging or surface of the examined objects, skin and clothing. Despite significant advances in the development of detection equipment (drift and mass spectrometers, IR and Raman spectrometers, chromatographic analyzers) based on various physicochemical principles, the most affordable, cheapest, easiest to use devices and equipment are chemical tests for indicator rapid detection of traces of explosives. The principle of their action is based on visual control of color changes when specific chromogenic reagents act on a sample.

The first analogues of a set of rapid tests for explosives were developed in the last century and were focused on the detection of only the most common types of explosives: TNT, tetryl, as well as RDX, HMX, nitroglycerin, TEN [Pat. US 4,618,452, Pub. 10.21.1986, IPC G01N 31/00, G01N 31/22, G01N 33/22; Pat. EP 0264252 Publ. 10/13/1987, IPC G01N 31/22, G01N 33/22].

Technical solutions proposed in some modern sets of chemical rapid tests for the presence of explosives are aimed at ensuring high sensitivity and selectivity of detection for target classes of compounds, safety, speed and ease of analysis, including in off-laboratory conditions. The development of the prior art in the field of improving the devices for express analysis of the main classes of explosives, including those modified with the aim of identifying inorganic nitrates, is implemented in a number of developments [Pat. RF 2369444, Publ. 03/21/2008, IPC B05V 17/00, G01N 33/22; Pat. RF 2203487, Publ. 11/22/2001, IPC G01N 31/22, G01N 33/22; Pat. RF to the floor. Model No. 40488, Publ. 09/10/2004, IPC G01N 31/22, С07С 203/00, С07С 243/02, С07С 205/06].

In particular, the hallmark of the device disclosed in the patent of the Russian Federation 2203487 is the material of construction elements. According to the patent of the Russian Federation for utility model No. 40488, the authors identify the material and the shape (size allows carrying in your pocket) of the container, and the fact that bottles with indicators are used as the detector assembly, and porous (filter) paper is proposed as an auxiliary element .

First of all, the disadvantages of all of the above devices should be attributed to their limited functional purpose, which provides for the detection of only the main classes of traditional nitrogen-containing explosives. In addition, one of the main disadvantages of almost all existing rapid tests is their poor resistance to external factors, their lack of reliability in the reliability and durability of their operation during the period of their service, usually not exceeding one year.

The design of the test kit described in RF patent 2369444 is characterized in that each liquid reagent-identifier BB is applied in metered quantities to its own sampler, each of which is placed in a separate polymer sealed bag. Despite the fact that in off-laboratory conditions this provides a guaranteed dosed sequential effect of explosive identifiers of explosives on the sample of the test substance and the absence of erosion, and also slightly increases the stability of the reagents distributed in different sealed packages, the device has a limited range of detectable explosives, additional analysis is required time to open sealed bags.

Recently, the variety of explosives used for criminal purposes has expanded significantly around the world. The tendency to increase the number of types of explosives used by terrorists is facilitated by the availability of previously limited literary sources and the distribution of thematic information through the World Wide Web electronic network. In this regard, the list of explosives detected by various technical means of detection over the past decades has expanded significantly. With the expansion of the list dictated by emerging new threats, sets of chemical rapid tests for explosives are also being improved.

In [Pat. US 5480612 Publ. 01/02/1996, IPC G01N 37/00] disclosed information about an improved kit for detecting explosive classes of nitroaromatic compounds, nitroesters, nitramines, inorganic nitrates, and also chlorates and bromates. The design of the device includes polyethylene thin-walled tubes with ampoules filled with ready-made liquid reagents prepared according to the claimed formulations. Additional structural elements: paper disks - perform the function of samplers, containers are intended for their storage; the auxiliary device, made in the form of a lever clamp, serves to crush ampoules with reagents. The listed elements that make up the device are placed in a container that is a case. The kit features do not include analysis of other classes of potentially dangerous explosives. The kit also has drawbacks in terms of ensuring the safety of personnel working with it, due to the presence of very aggressive reagents, including strongly acidic solutions, in its composition.

Known sets of rapid tests for the presence of explosives, narrowly focused on the detection of specific types of explosives and aircraft. So, to solve the urgent task of detecting improvised explosives, devices have been invented that focus on the indicator detection of organic peroxides, chlorates and bromates [Pat. RF 2352936, Publ. 05/10/2008, IPC G01N 33/22, G01N 31/22; Pat. US 7829020 Publ. September 11, 2010, IPC G01N 33/22]. The design of these kits, disclosed in the descriptions, also does not guarantee safety when working with aggressive environments that perform the functions of device elements. In addition, the described kits do not reveal the presence of other explosive classes in the sample, which requires the use of complex analysis using other devices.

Described in [Application US 20120003746, Publ. 01/05/2012, IPC G01N 33/22, C07D 279/20] the method and device for identifying explosives, according to the result achieved, are further improved relative to other analogues. When conducting a comprehensive analysis using the claimed kit, in addition to the ability to identify the main classes of traditional nitrogen-containing explosives, perchlorates, chlorates, bromates and peroxides can also be identified. The technical essence of the invention lies in the inclusion of interconnected elements (indicator components with certain parameters), including additional reagents, allowing to expand the list of detectable classes of energy compounds. The algorithm for using the elements that make up the device, in accordance with the method described in the application, allows the successive exposure of reagents to detect the presence of the corresponding classes of explosives. But the disadvantage inherent in other analogues, in terms of the danger of using aggressive reagents, as follows from the description, is also not technically resolved. The device does not offer technical solutions to simplify its practical application, to provide simplicity and speed of analysis, to increase the safety of reagents.

Proposed in [Pat. US 8772045 Publ. 07/08/2014, IPC G01N 33/00, G01N 33/22] the method is based on the use of a device that allows the analysis of explosives with known combinations of reagents (Yanovsky, Griss reactions) in the forced heating mode. The sampler placed in the heater with the sample is dosed with reagents. The analysis is carried out in various temperature conditions from 35 ° C to 135-165 ° C (temperature control is provided), with light indication of the modes, as well as with a possible metered supply of indicator solutions with a flow rate of up to 0.05 ml / analysis. The temperature control function allows you to reduce the analysis time and lower the activity of the solutions used, and therefore the safety of work. At the same time, along with common problems for analogs regarding the short shelf life of liquid reagents and a narrow list of detectable explosives limited to nitro compounds, the device including electronic elements has other disadvantages: the difficulty in operation and maintenance, the availability of power sources and related additional difficulties in maintaining health, increased size and weight.

A tool for the same purpose as the claimed set of rapid tests, approximate to the achieved result and technical nature and adopted as a prototype of the proposed device, is a set for rapid analysis of samples for the presence of explosives "VIRAZH-BB (PS)" (Passport FSUE " State Research Institute of Crystal, ZAO Petro-Sorb-Komplektatsiya on the product VIRAZH-VV (PS) IShDV.415310.001 TU; [http://www.niikristall.ru/index.php?id_page=168] (15.09. 2014); [http://petrosk.ru/catalogpsk/mvd/analizatory_vzryvchatyh_vewestv/virazh-vv2/] (September 15, 2014)). This kit consists of a detector and an auxiliary device, placed inside a plastic container intended for their storage and carrying. The product is an improved device, the prototype for the creation of which was the utility model (Pat. RF utility model No. 40488). As a detector, 5 bottles with indicators are used, and the function of an auxiliary device is performed by porous (filter) paper, which serves to wipe the surface of suspicious objects. Application to the sample of five reagents from the vials of the kit (“A”, “B”, “C”, “D” and “E”) in a certain sequence allows the presence of TNT, tetryl, RDX, HMX, ten, nitroglycerin, nitrate and peroxides. Alkaline solutions (bottle “A”), an acid solution of derivatives of sulfanilic acid (bottle “B”), aromatic amine (bottle “C”), zinc microspheres (bottle “D”) and a starch and potassium iodide reagent (“E”) are used "). The passport contains a user manual, supplemented by a color image of the positive response of the detector.

The disadvantage of the prototype device, common to all analogues, is the use of solutions of reactive compounds, including liquid acids. Due to the use of aggressive liquids, the kit cannot be considered safe, the use of dissolved indicator forms, where the reagents are in a solvated state, reduces their storage stability. As a result, the kit has a short designated life. The disadvantages also include: the need to use four bottles in the detection cycle of explosives of one group (saltpeter and nitroesters, nitramines), low sensitivity and selectivity in the determination of peroxides. The narrow temperature range of the application does not allow the device to be used below 0 ° C due to the crystallization of indicator solutions. This complicates the analysis and imposes significant limitations in the implementation of practical research in off-laboratory conditions, in the open air. Reagents "D" and "E" are powders, the dosage of which from dropping vials is difficult. The main disadvantage of the prototype - the nomenclature detected by the explosive device - does not cover the entire list of classes of energy compounds that are potentially dangerous in the criminal aspect.

The technical result of the present invention is to ensure the presence of virtually all potentially dangerous for illegal use of explosives and aircraft, with their classification as classes: aromatic polynitro compounds, nitramines, nitroesters, nitromethane, nitrates, perchlorates, chlorates and organic peroxides, as well as ensuring safety and simplicity in operation when using the proposed kit for complex analysis, increasing the resistance of this device to external factors: the maximum rate temperatures from minus 40 ° C to 50 ° C, high humidity, shock and vibration loads, and, in addition, to ensure for at least 3 years during operation, including in off-laboratory conditions at an ambient temperature of at least minus 10 ° C and not more than 40 ° C in the absence of liquid atmospheric precipitation, detection of target substances and assigning them to the chemical classes of energy compounds with high sensitivity and selectivity for a period of 1-3 minutes.

This technical result is achieved by a set of rapid tests for explosives, consisting of a portable plastic container equipped with an internal shock-absorbing liner with functional recesses, including recesses for installing microcolumns placed in recesses of bottles with solutions for determining explosives, as well as microcolumn test systems for detecting the presence of chlorates and perchlorates, cases with rolls of tapes of reactive indicator materials containing immobilized reagents for detecting explosives on the surface of the carrier, while cases with rolls of tapes of reactive indicator materials consist of elastic inert material in the form of hollow cylinders of the body with a coaxial cover that fits tightly on the cylindrical surface, and the side walls of the cases have longitudinal slits through which they pass the edge of the tape of the reactive indicator material, and in addition, the housing and the cover have a mutual angular mobility around the axis, providing when combining their products hollow slots in one line until the formation of an open window, the function of opening the case with the release of the edge of the tape, or when their longitudinal slots overlap, the function of sealing the case with fixing the edge of the tape.

In specific forms of execution of a set of rapid tests for explosives, the technical result is achieved by the fact that to perform the function of detecting the presence of polynitroaromatic compounds, nitramines, nitroesters, nitromethane and nitrates, the detector elements are: a bottle with an aqueous-organic solution of the base in the form of tetrabutylammonium hydroxide in aqueous mixtures of dimethyl sulfoxide with ethanol; a bottle with an acidic solution in the form of a solution of citric and sulfanilic acids in a water-alcohol mixture; reactive indicator material that acts as a sampler, containing a derivative of N- (1-naphthyl) ethylenediamine immobilized on the surface of the carrier; reactive indicator material containing a salt of 1,2-naphthaquinone-4-sulfonic acid immobilized on the surface of the carrier; reactive indicator material containing zinc dust immobilized on the surface of the carrier. To perform the function of detecting the presence of organic peroxides, the detector elements are: a bottle with an acetate-buffer solution of peroxidase and 2,2'-azino-bis (3-ethylbenzothiazole il-6-sulfonic acid); Reactive indicator material that acts as a sampler with heterogeneous fluorosulfonic acid immobilized on the surface of the carrier. To perform the function of detecting the presence of chlorates, the detector elements are prefabricated containers with an aqueous solution of sodium chloride and a microcolumn, inside which is placed a layer of a solid-phase sorbent containing acid fragments and sulfuric acid molecules, an immobilized aniline derivative and a soft porous sorption fiber in contact with it which forms a sampling surface at the end of the microcolumn. To perform the function of detecting the presence of perchlorates, the detector elements are prefabricated container designs with a mixture of acetone and tetrahydrofuran and a microcolumn, inside which a layer of a solid-phase sorbent and a solid-phase sorbent with an immobilized cationic dye, mainly diamond green, and a soft porous sorption fiber in contact with it, which forms a sampling surface at the end of the microcolumn.

Also, in special cases, the technical result achieved is ensured by a set of rapid tests for explosives, characterized in that the reactive indicator material tapes are made of a carrier based on a nonwoven polypropylene mesh fiber laminated on the back with a polymer film; and the cases are made of an elastic inert material selected from the series: polyethylene, polypropylene, fluoroplastic. In addition, one of the edges of the longitudinal slit of the side wall of the cover of the case is made in the form of a comb with a transverse position of the teeth, providing easy separation of fragments of the reactive indicator material from the tape.

In special cases of implementation or use, the achieved technical result is ensured by a set of rapid tests for explosives, additionally characterized by the fact that it includes auxiliary devices consisting of a device for puncturing a container with an eluent of a microcolumn test system made in the form of a needle having a wide the basis of the colorographic (s) scheme (s) for displaying the analysis algorithm, the color response of the positive and background detector response signals to a set, and discs of desalted paper.

The use of a shockproof container equipped with an internal shock-absorbing liner with reductions for orderly placement of detector elements and auxiliary devices allows the developed device to withstand significant vibration loads and satisfy additional strength requirements for mechanical shock with peak shock acceleration up to 1471 m / s ² (150 g), which makes it possible to transport it in any conditions and allows it to be used as part of objects parachuted benefits. Convenience and speed of work with the device are provided by recesses that perform the functions of a desktop, in which, in off-laboratory conditions, analytical operations with microcolumn test systems are performed.

The technical approach used to create the kit, which consists in transferring aggressive and reactive reagents to a state immobilized on the surface of a reactive indicator material, made it possible to increase the service life of solution bottles and minimize the danger when working with the device as a whole. The form of active reagents used in the solid-state state immobilized on the surface of the reactive indicator material ensures the absence of mass transfer during operation and storage stability. The design of the cases further increases the durability of the reactive indicator materials sealed in them during their storage under various external factors. When using reactive indicator material, there is no need for a clearly standardized dosage of liquid reagents, which greatly simplifies the work and increases the reliability of the analysis.

Simplicity and speed in operation is ensured by the ease of opening the case, carried out by mutual rotation of its cover and housing, the subsequent extraction of the necessary fragment of the tape of the reactive indicator material; the fixation of the tape between the case and the cover of the case during its sealing makes it possible to evenly remove the extracted fragments from the tape, in order to facilitate which there is a comb from the transverse teeth on the cover. Tests have shown that the functional purpose of the cases and the provision of all the requirements for the device are fulfilled when elastic chemically inert polymers are used as structural materials for their manufacture: polyethylene, polypropylene, and fluoroplastic.

As a supporting web of reactive indicator material, anesthetized papers, polyester porous films can be used, but the best indicators of reliability and ease of use are achieved with a carrier based on a non-woven polyolefin mesh fiber laminated on the back with a polyethylene impermeable film. This carrier is inert to the applied reagents, provides efficient sampling and a clear analytical signal.

Detector elements designed to detect the presence of chlorates and perchlorates are made in the form of test systems that implement independent functions of sampling and subsequent analysis with visual control of the result. The sample taken on the sampling surface of the microcolumn is transported inside it by dosing the eluent included in the prefabricated test kit container system. This allows for parallel analyzes with the selective classification of the substances present in the corresponding classes of energy compounds.

The elements that make up the device and perform the functions of auxiliary devices are devices for puncturing a container with an eluent of a micro-column test system, made in the form of a needle with a wide base, eliminating the possibility of injury to hands. In addition, such elements include a colorographic scheme that displays the color response of possible positive and background signals from the detector of the kit, and an analysis algorithm, as well as desalted paper, which serves as a comparison medium for determining false positive responses of the detector elements and an additional sampling tool.

The inventive rapid test kit for explosives is illustrated in a perspective view of FIG. 1. One of the four cases with a roll of tape of reactive indicator material included in the rapid test kit is shown in FIG. 2: view A is an axonometric projection of the case assembly and view B is an axonometric projection of the case with spaced parts.

A set of rapid tests for explosives [Fig. 1] consists of a portable plastic container with a handle for carrying (1), equipped with an internal shock-absorbing insert (2) with recesses serving as a desktop for operations with microcolumns (3) and containing detector elements and accessories located in the recesses: bottle “A "With a solution of the base - tetrabutylammonium hydroxide in an aqueous mixture of dimethyl sulfoxide and ethanol (4), a bottle of" B "with an acid solution - a solution of citric and sulfanilic acids in a water-alcohol mixture (5), a bottle of" C "with stab with the peroxidase and 2,2'-azino-bis (3-ethylbenzthiazolyl-6-sulfonic acid) acetate buffer solution (6), microcolumn chlorate detection test systems - prefabricated container with an aqueous solution of sodium chloride and a microcolumn inside which a layer is placed solid phase sorbent containing acid fragments and sulfuric acid molecules on the surface, an aniline derivative immobilized and a soft porous sorption fiber in contact with it, which forms a sampler in the end part of the microcolumn surface (7), microcolumn test systems for detecting the presence of perchlorates, prefabricated container designs with a mixture of acetone and tetrahydrofuran and a microcolumn, inside which a layer of solid-phase sorbent and solid-phase sorbent with immobilized cationic dye, mainly brilliant green, and in contact with it, is soft porous sorption fiber, which forms a sampling surface in the end part of the microcolumn (8); cases with rolls of tapes of reactive indicator material made from a carrier of non-woven polypropylene net fiber laminated on the back with a plastic film: with a roll of tape of reactive indicator material “I” containing N- [2- (naphthylene-1-ylamino) immobilized on the surface of the carrier ethyl] acetamide (9), with a roll of a strip of reactive indicator material "II" containing a salt of 1,2-naphthaquinone-4-sulfonic acid immobilized on the surface of a carrier (10), with a roll of tape of a reactive indicator material iala III containing zinc dust immobilized on the carrier surface (11), a case with a roll of a strip of reactive indicator material IV containing heterogeneous perfluorooctane sulfonic acid surface immobilized in a polymer matrix on a carrier (12), as well as auxiliary devices: container puncture devices with an eluent of a microcolumn test system (13), sheets of desalted paper (14) and colorographic scheme (s) (15), while cases with rolls of tapes of reactive indicator material (9-12) [Fig. 1] consist of a housing (16) made of a resilient inert polymer [Fig. 2] and covers (17), the side walls of which have longitudinal slots, through which the edge of the tape of the reactive indicator material (18) passes.

The action of the rapid test kit for the presence of explosives that solves the problem, in the General case, but not limiting the possibilities of the present invention, are explicitly as follows for a person skilled in the art, as follows. The open container 1 is mounted on a hard surface. From the deepening of the cushioning insert 2, a sealed case 9 is removed with a roll of tape of the reactive indicator material "I". The case is opened by mutual rotation of the housing 11 and the cover 12 to align the longitudinal slots of their side walls. The edge of the tape of the reactive indicator material (18) is released to the required length (4-8 cm) from the case. Then, by mutual rotation of its housing 16 and the cover 17 until the longitudinal slots overlap with the released edge of the tape being fixed, the case is sealed. A fragment of the reactive indicator material “I” is torn from the fixed edge of the tape, in a particular case violating the integrity of the tape about the profile of the transverse toothed comb of the cover 17, and wiping it with the fluffy part carries out sampling from the surface being examined. After sampling, the sampling surface of the used fragment of the reactive indicator material “I” is treated with solution “A” from bottle 4. If the detector element is triggered, the resulting color is compared with the color scheme 15 and concludes that there are polynitroaromatic compounds in the explosive sample. If there is no color, the fragment of the reactive indicator material “I” already treated with solution “A” is brought into contact with the fragment of the reactive indicator material “II” extracted from the case 10 by the above-described actions. In the case of a change in its color, a comparison of the appeared color is carried out with the colorographic scheme 15 and a conclusion is made about the presence of explosives based on nitromethane. To identify the explosive classes of nitramines and nitroesters, the same fragment of the reactive indicator material “I” is additionally treated with solution “B” from bottle 5. The presence of explosives is judged by the presence of a color identical to that available in the colorographic scheme 15. If there is no color, the previously sequentially processed fragment of the reactive indicator material “I” is brought into contact with a fragment of the reactive indicator material “III” extracted by analogy from the case 11. The subsequent change in color with nitrate detector elements in accordance with the color scheme confirms the presence of explosives and / or components of the sun. To determine the organic peroxides, the sample is transferred to the fragment of the reactive indicator material “IV” extracted from the case 12 above. In order to exclude false positive detections of the detector elements for sampling directly from the test object, an anesthetized paper disk 14 is used, with the secondary contact of which the sample is transferred to a fragment of the reactive indicator material “IV”. From bottle 6, solution “B” after about half a minute after transferring the sample is applied to the sampling surface of the desalted paper and in parallel to the fragment of the reactive indicator material “IV” with the sample. The appearance of a color identical to that shown in the colorographic scheme 15 only on the fragment of the reactive indicator material “IV” indicates the presence of peroxide explosive. To detect the presence of chlorates from the container 1, the packed microcolumn test system 7 is removed, the microcolumn and the container with the eluent are released from the package, a sample is taken on the sampling surface of the microcolumn and set it in one of the recesses 3. The container with the eluent is punctured using a puncture device needle 13 and dose the eluent to the sampling surface of the microcolumn. Similarly, operations are carried out with a micro-column test system 8 for detecting perchlorates. The presence of the corresponding desired explosive or BC component is confirmed by visual inspection of the result obtained within about 2 minutes after the dosage of the eluent when compared with the color scheme 15.

The implementation of the invention in action, confirming the solution of the problem, is confirmed by the following specific example.

The test is subjected to a sample of a set of rapid tests for explosives, after three years after its manufacture and subjected during this time to a three-fold cycle of exposure to the following external factors:

- exposure at a temperature of 40 ° C and high humidity of 98% for at least 96 hours;

- thermal cycling with sequential exposure for 3 hours at a temperature of 40 ° C and 3 hours at a temperature of minus 10 ° C, repeated five times;

- exposure at a temperature of minus 40 ° C for 3 hours;

- exposure at a temperature of 50 ° C for 3 hours;

- vibration on the shock stand at a frequency of 25 Hz with an acceleration of 19.6 m / s ² (2 g) for 30 minutes;

- shock shaking on the shock stand at a changing frequency from 20 to 80 Hz with an acceleration of 39 m / s ² (4 g) for 1 hour;

- mechanical shocks with peak shock acceleration of 1471 m / s ² (150 g) in the amount of 20 shocks in each of three mutually perpendicular directions.

External influencing factors did not violate the tightness and integrity and orderliness of the arrangement of the elements making up the kit; when using polyethylene, polypropylene or fluoroplastic for the manufacture of cases 9-12, the properties and functionality of the details of their design and reactive indicator materials in them are preserved.

The formation of samples of the desired substances is carried out by applying the calculated volume of the solution of the corresponding substance to the surface of the slides. The initial solutions with a given concentration are prepared by the method of precise weights. Additionally, an analysis of samples taken from field samples is carried out. The conclusion about the positive or background (interference) operation of the detector is made by comparing the appearing color with the color scheme 15 by the method of expert estimates.

To conduct a comprehensive analysis by a set of rapid tests for the presence of explosives, the actions described above are carried out in the example embodiment of the invention, generally relying on the algorithm reflected in the color scheme 15. The tests are carried out in a climate chamber at a temperature of 40 ° C and a relative humidity of more than 98% (with a slight fog visually observed), and outdoors in winter at an ambient temperature of about minus 10 ° C. The test results are shown in the table:

Liquid components of the detector elements, direct contact of solid analytical surfaces on the skin and cotton items of clothing during the analysis did not cause irritation, corrosion or destruction. Desinzed paper constituent auxiliaries was successfully used to remove unwanted excess fluids and to wipe hands after analysis cycles. The placed needles of the puncture devices in the recess of the wide base ensured injury safety when working with microcolumn test systems.

The above information confirms all the claimed advantages of the developed device.

Claims (9)

1. A set of rapid tests for the presence of explosives, consisting of a portable plastic container equipped with an internal shock-absorbing insert with functional recesses, including recesses for installing microcolumns placed in recesses of solution bottles for determining explosives, as well as micro-column test systems for detecting the presence of chlorates and perchlorates, cases with rolls of tapes of reactive indicator materials containing reagents immobilized on the surface of the carrier for determination fission of explosives, while the cases with rolls of tapes of reactive indicator materials consist of elastic inert material in the form of hollow cylinders of the body with a coaxial cover that fits snugly along the cylindrical surface, and the side walls of the cases have longitudinal slots through which the edge of the ribbon of reactive indicator material and, in addition, the housing and the cover have mutual angular mobility around the axis, which ensures that when combining their longitudinal slots in a single line until they form open window the function of opening the case with the release of the edge of the tape, or with mutual overlapping of their longitudinal slots, the function of sealing the case with fixing the edge of the tape. 2. A set of rapid tests for the presence of explosives according to claim 1, characterized in that for the function of detecting the presence of polynitroaromatic compounds, nitramines, nitroesters, nitromethane and nitrates, the detector elements are: a bottle with an aqueous-organic solution of the base in the form of tetrabutylammonium hydroxide in an aqueous mixture of dimethyl sulfoxide with ethanol; a bottle with an acidic solution in the form of a solution of citric and sulfanilic acids in a water-alcohol mixture; reactive indicator material that acts as a sampler, containing a derivative of N- (1-naphthyl) ethylenediamine immobilized on the surface of the carrier; reactive indicator material containing a salt of 1,2-naphthaquinone-4-sulfonic acid immobilized on the surface of the carrier; reactive indicator material containing zinc dust immobilized on the surface of the carrier. 3. A set of rapid tests for the presence of explosives according to claim 1, characterized in that to perform the function of detecting the presence of organic peroxides, the detector elements are: a bottle with acetate-buffer solution of peroxidase and 2,2'-azino-bis (3-ethylbenzothiazolyl -6-sulfonic acids); Reactive indicator material that acts as a sampler with heterogeneous fluorosulfonic acid immobilized on the surface of the carrier. 4. A set of rapid tests for the presence of explosives according to claim 1, characterized in that, to perform the function of detecting the presence of chlorates, the detector elements are prefabricated containers with an aqueous solution of sodium chloride and a microcolumn, inside which a layer of a solid-phase sorbent containing acid fragments and molecules of sulfuric acid, an immobilized derivative of aniline and a soft porous sorption fiber in contact with it, which forms a sample at the end of the microcolumn hydrochloric surface. 5. A set of rapid tests for the presence of explosives according to claim 1, characterized in that for the function of detecting the presence of perchlorate, the detector elements are prefabricated container designs with a mixture of acetone and tetrahydrofuran and a microcolumn, inside which a layer of solid-phase sorbent and solid-phase sorbent with immobilized a cationic dye, mainly diamond green, and a soft porous sorption fiber in contact with it, which forms a sampling sample at the end of the microcolumn hydrochloric surface. 6. A set of rapid tests for the presence of explosives according to claim 1, characterized in that the reactive indicator material tape is made of a carrier based on a non-woven polypropylene mesh fiber laminated on the back with a polymer film; 7. A set of rapid tests for the presence of explosives according to claim 1, characterized in that the cases are made of an elastic inert material selected from the series: polyethylene, polypropylene, fluoroplastic. 8. A set of rapid tests for the presence of explosives according to claim 1, characterized in that one of the edges of the longitudinal slit of the side wall of the cover of the case is made in the form of a comb with a transverse position of the teeth, providing easy separation of the fragment of the reactive indicator material from the tape. 9. A set of rapid tests for explosives according to claim 1, further characterized in that it includes auxiliary devices consisting of a device for puncturing a container with an eluent of a microcolumn test system made in the form of a needle with a wide base, colorographic ( (i) schemes (s) for displaying the analysis algorithm, the color response of the positive and background signals of the detector operation of the kit, and paper-free paper disks.

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