BR102013024135B1 - RECORDING METHOD AND IDENTIFICATION AND SINGLE FILM - Google Patents

Abstract

recording method and object traceability. The present invention provides a film for recording and identifying objects, preferably objects, preferably solid projectile launchers and projectiles, without being visible, so that their scratching or illicit tampering is impossible. applications can be carried out on weapons, security materials such as secret codes and passwords, and on simple objects such as key chains and jewelry. the present invention provides security of information secrecy, due to the impossibility of being visualized by optical systems, and total security against recording location.

Description

[001] The present invention relates to a method for recording objects, such as solid projectile launching artifacts, mainly firearms, and projectiles, and other objects of interest. The method allows the identification not to be visible, so that it is difficult to scrape or illicit tampering, maintaining the method of traceability of this recording by the expert examiner. The present invention also provides a method of tracking these objects through the use of a scanning electron microscope.

Fundamentals of the Invention

[002] The solid projectile launching device, preferably, when used illicitly and effectively identified and tracked, is the most important material evidence in a criminal investigation. If the identification of the artifact is erased or tampered with, the origin of the weapon is lost, making it more difficult to associate a specific suspect.

[003] For the purposes of identification and tracking, the objects must be properly marked in order to allow the retrieval of the model, manufacturer's name, place of manufacture and serial number. This standard also applies to imported projectile-launching artifacts, in order to allow the identification of the name and address of the importer.

[004] Artifacts of this type that are sanded, scraped or tampered with are subject to confiscation and destruction and their bearer will have non-bailable retention until the expertise verifies the traceability and signature of the weapon.

[005] In Brazil, 70% of homicides are caused by firearms. Mostly by artifacts traded illegally. This is what the Map of Violence published by the Ministry of Justice shows. According to the study, in the states with the highest number of legal gun registrations, the homicide rate as a cause of death for young people is always lower than the national average (39.7%). In the least armed state of Brazil (Pernambuco), according to official figures, murders are responsible for 57.7% of deaths recorded among this part of the population.

[006] It is estimated that there are around 7.5 million weapons traded on the black market, many of them with the numbers suppressed or erased. Weapons with scratched off serial numbers are equated with restricted-use weapons (weapons used by the armed forces). And this is the understanding applied by the Superior Court of Justice (STJ) to numerous requests for habeas corpus. Those who respond to a lawsuit for possession of restricted weapons must await the trial in prison.

[007] Firearms are engraved using punches (a steel tool, with letters engraved in relief, with which the dies on which the typographic characters are engraved are beaten). The engraved digits have an excellent engraving quality, allowing marking on parts of the most varied sizes and shapes. The punch digits are made of carbide or high speed steel and are specially developed to work with high hardness materials. The foundations used today for the determination of numbering or inscriptions removed by abrasive methods are based on the principle that when a metal is cold deformed or marked by the action of a blow, the microstructure is subjected to plastic deformation. This plastic deformation is responsible for the increase in energy stored under the engraved digits.

[008] Now, if by an instrument, such as emery, sandpaper, abrasive or similar, the metal surface is attacked in order to eliminate the registration made in low relief, it may be that even below this grinding the microstructure is altered by the action of the record recording process. In this area, after sanding, by applying suitable chemical reagents, the recovery of the previously performed identification may occur.

[009] The professional teams of criminal expertise are capable of regenerating the original marking or numbering by physical and chemical operations that will be used according to the material of the support where the marking is found and the method used for its erosion, obtaining in some cases the full restoration of the numbering, and thus, after investigations determine the original owner of the firearm.

[010] It is recommended that this work be carried out by chemical, metallurgical or materials science technicians with adequate professional training, due to the dangerousness of the reagents that are used and the care of direct contact with the skin, eyes, mucous membranes, breathing of vapors, etc. In addition to avoiding any accident due to the environmental impact resulting from the disposal of these reagents, as well as to avoid failure of the analysis due to erroneous procedures that make a new analysis unfeasible.

[011] Currently, industries also employ laser engraving. There are different laser engraving technologies to meet the needs of engraving on various types of surface. Among the main features of laser engraving, it is essential to emphasize the quality and speed of marking, as this technology is capable of creating an image with (or without) contrast on the surface to be marked.

[012] With this process, logos, texts, drawings, bar codes and 2D can be marked, making it possible to engrave the most diverse materials such as: carbon steels, microalloyed steels, stainless steel, aluminum, brass, copper, titanium, gold, plastic, leather, ceramics, wood, etc. The most common lasers in engraving are C02 gas lasers or YAG solid state (ytterbium or vanadium) gas lasers, both controlled through software that allows from simple text engraving to complex logos, being able to import a wide variety of graphic formats, being It is possible to simulate the recording before performing it on the part, using a red diode.

[013] The laser is generated from a crystal (YAG) or gas (C02), being collimated and guided through mirrors attached to targets and concentrated through different types of lenses. In some equipment the laser is guided by optical fiber and can record in very restricted areas.

[014] Although all engraving technology has evolved, laser engravings when sanded are practically impossible to be traced by conventional forensic techniques, even with sophisticated equipment.

[015] In the state of the art, several patent documents describe types of engravings used on objects such as firearms or projectiles, but all are physically visible. W02011 072672, published June 23, 2011, describes an apparatus and a method for identifying projectiles. The projectile is equipped with an RFID (Radio Frequency Identification) chip to generate an identification signal. A reader unit that reads the identification signal generated by the RFID chip is disposed inside or in front of the weapon and I or in the ammunition compartment. Patent document US2010289627, published November 18, 2010, describes the use of radio frequency identification, stenography, nanolithography, and fingerprints. Document W0200901 0173, published January 22, 2009, presents a method of identifying an ammunition cartridge that allows identification of the respective cartridge type, even in the dark, without the need to mechanically damage the base of the cartridge. The invention is characterized by perforations within the ignition housing. Patent document 20 RU2298464, published on May 10, 2007, provides a method that consists of applying to the inner surface of the cartridge chamber a mixture of divalent lead fluoride or quadrivalent germanium oxide activated by thulium or ytterbium capable of generation of luminescent radiation in the blue band, La203S activated by ytterbium or erbium capable of generating radiation in the green band, and Y203-YOF activated by ytterbium or erbium, as well as Y203-YOCI activated by ytterbium or erbium capable of generating radiation in the band red. Patent document RU2298755, published on May 10, 2007, presents a method for identifying the barrel of a firearm, in which grooves are made on the inner surface of the barrel. Patent document US2001027619, published October 11, 2001, provides identification marks that are elongated (grooves or grooves) in the direction of casing extraction. Patent US6226913, published May 8, 2001, discloses a weapon that includes a housing, a firing mechanism, an electronic tag, and at least one weapon identification. The electronic tag may be located inside the box in a location normally physically inaccessible to weapon users. Patent document BG101362, published September 30, 1998, presents an identification method and a device for marking the firing arm, the identification being done mechanically. Patent document FR2730803, published August 23, 1996, presents a system for identifying a firearm that includes an electronic circuit that transmits information about the weapon, which is integrated into a non-conductive part of the weapon, for example, at one end part. The information contained in the circuit can be read remotely by a portable device that is able to activate the circuit and gain access to the memory, without the need for physical contacts.

[016] As detailed above, the state of the art presents several methods of identifying artifacts, but all of them are weakened by the possibility of scraping, use of abrasives or any other form of tampering.

Description of the State of the Technique

[017] The present invention consists of a marking method that employs a totally innovative technology. A mask is constructed containing essential information on a weapon, such as the manufacturer's name, place of manufacture, serial number, etc. This mask is then superimposed at various locations on the weapon where a thin film of a material with an atomic number different from the material of the object will be deposited, such as a material other than the steel of the weapon. The greater this difference, the greater the desired contrast. Tungsten, tantalum, hafnium, iridium and platinum are examples of materials with a high atomic number, beryllium, magnesium, aluminum and silicon or their oxides are examples of materials with a low atomic number. Both examples show excellent contrast to steel, which has an atomic number of 26.

[018] The film, when passing through the mask, is deposited on the weapon, in accordance with the characters of the mask, necessary for identification of the weapon. This film would be easily removed by abrasion if the illicit user noticed the recording. However, this recording is hidden by depositing a very thin film of the weapon's material on it, that is, covering the trace of the recording and making it impossible to discover its location or read the aforementioned inscription. The weapon continues to have its traditional engraving, and even if it is removed, using the method described in the present invention, using a reading technique described below, it can be traced.

[019] A scanning electron microscope (SEM) can obtain images of polished or rough surfaces, with great depth of field and high resolution, facilitating the interpretation of images and enabling the microanalysis of elements through the use of multiple effects of the interaction between the electrons and matter.

[020] As a consequence of the interaction of the electron beam with the surface of the sample, a series of radiations are emitted such as: secondary electrons (ES), backscattered electrons, characteristic X-rays, Auger electrons, photons, among others. These radiations, when captured correctly, will provide characteristic information about the sample, such as surface topography, composition and crystallography.

[021] The secondary electron detector is quite efficient and the images are easy to interpret. It is primarily for this reason that its image is most commonly used in scanning electron microscopy. The backscattered electron signal results from a sequence of elastic and inelastic collisions, in which the change in direction is satisfactory to eject it from the sample. The backscattered electrons launch a very important signal for obtaining images in the SEM. It distinguishes regions with different compositions in an image and also contains information about the topography of the sample.

[022] As we have two materials of different atomic number in the recording, when introducing the weapon into a scanning electron microscope and performing the observation with the backscattered electron signal, an atomic number contrast will be formed that will allow the reading of the information.

[023] Films can be deposited by different physical or chemical deposition techniques, including physical depositions, such as resistive evaporation, electron beam, RF or DC sputtering, laser ablation and others. As chemical deposition processes, chemical vapor deposition (CVD) or spray pyrolysis can be used.

[024] The thickness of the film used as atomic number contrast is around 700 to 900 nanometers. The thickness of the cover film (cap layer) with the same metal or base material as the structure of the weapon or artifact is around 100 nanometers. As the penetration of the beam in the sample is of the order of μm, it is possible to recover the image in the SEM in backscattered mode without changing the optical aspect of the surface.

[025] Metal oxide films such as titanium oxide, silicon oxide, zinc oxide, hafnium oxide or zirconium and others, are transparent and can be deposited as a contrast without the need to cover the deposited film with the same base material as the artifact or weapon intended to conceal the recording. In order for the film with the engraving to remain hidden from visual inspection, its thickness must be properly calculated as a function of the refractive index of the metal oxide, so that the wavelengths reflected by the two interfaces do not provide constructive interference causing a contrast, or more specifically a certain color, visible on the surface of the artifact or weapon. The precise choice of contrast film thickness (marking) should generate ultraviolet (very thin films) or infrared reflections that are invisible to the human eye. Even using metal oxide films for contrast or engraving, the use of a cover film, with material similar to the weapon or artifact (most often steel alloys) in addition to hiding the contrast film, increases the protection of the recording. and its adherence to the material of the artifact or weapon.

[026] The covering layer can be the material of the weapon or artifact itself, or another material similar to the surface treatment of the weapon such as chromium, titanium nitride, nickel or black oxidized steel, in order to hide the contrast film.

[027] The present invention makes the easy identification of a secret recording, with a reading technique unavailable to the user, but quite common in forensic and police forensics. The invention also allows recording simultaneously in several areas of the weapon, guaranteeing the possible accidental damage and mistreatment of the weapon.

Objectives of the Invention

[028] It is an object of the present invention a method for recording and reading information essential to criminal expertise and public safety such as the serial number, manufacturer, batch, dates and the name of the importer if the weapon is of foreign origin.

[029] It is an additional objective of the present invention to hide recorded information in order to prevent an intentional abrasive process in order to erase the firearm's identification.

Summary of the Invention

[030] The present invention achieves the above objectives by the simple methodology of recording and reading information on firearms or other objects of interest without their being identified without adequate instruments of difficult access to the general public.

[031] In a preferred embodiment of the present invention, the engraving medium can be extended to all parts of the weapon as a matrix engraving process.

[032] The present invention provides that the recording process is extended to a means of transporting sensitive and confidential information without the risk of being intercepted by an agent disqualified to this access.

[033] The present invention also provides for the possibility of developing chemical treatment techniques or paints or electroplating baths in order to obtain the thin films described in the method.

Brief Description of Drawings

[034] Figure 1 is a view of a weapon with the identifications scraped off.

[035] Figure 2 shows images deposited on steel using a mask made of copper and using silicon nitride (SbN4) as material of different atomic number (as a contrast) analyzed in electron microscopy.

[036] Detailed Description of the Invention The present invention presents a method for recording and identifying objects characterized by applying a material with an atomic number different from the atomic number of the object of interest. The material consists of materials with a high atomic number selected from the group consisting of tungsten, tantalum, hafnium, rhenium, osmium, iridium, platinum and other materials with a high atomic number in the periodic table or by materials with a low atomic number selected from the group composed of beryllium, magnesium, aluminum, silicon, their oxides and the other materials with low atomic number in the periodic table. Thus, the materials used can be any from the periodic table of the elements, their alloys or compounds that have adequate adhesion, as long as they present a difference in atomic number sufficient to identify them.

[037] The method for recording and identifying objects is carried out through the deposition process, such as physical depositions, chemical depositions, baths, paintings or electrodeposition.

Example 1

[038] With reference to figure 2, the substrate on which the numbering and the CBPF symbol doll were deposited are of the same steel used in the manufacture of firearms. The mask was made on a 0.5 mm copper plate, clean and degreased, on which letters and numbers were printed, simulating a serial by laser engraving. The plate was immersed in an iron perchloride solution until it was poured. The mask was fixed with bioriented polyamide kapton tape on the steel previously cleaned with isopropyl alcohol and placed inside a vacuum chamber at a pressure of 3 millitorr. A silicon nitride film with a thickness of 700 nanometers was deposited by cathodic deposition. A steel film with the same stoichiometry as the target was deposited on the surface of the film using the same technique. The substrate was analyzed by electron microscopy, and the hidden number deposited could be easily observed.

[039] The description of the production process of the serial number presented provides an embodiment of the invented technique, however several other embodiments can be used without departing from the scope of the invention proposed in the present patent application such as the production of the technique by electroplating, paints or chemical baths in the factory.

[040] It should be understood that the description provided based on the above processing refers only to the possible embodiment, but should not be restrictive to the secret recording medium by difference of materials with differentiated atomic number given by the present invention, which is defined according to the claims that follow.

Claims (7)

1. Method for recording and identifying objects characterized by comprising the steps of: a. Apply a film of material with an atomic number different from the atomic number of the object of interest; B. Apply a film of the same material to the one used on the object of interest on the film. 2. Method for recording and identifying objects according to claim 1, characterized in that the object of interest consists of a polymeric or ceramic metallic material. 3. Method for recording and identifying objects according to claim 1, characterized by the fact of applying a film consisting of materials with high atomic number selected from the group consisting of tungsten, tantalum, hafnium, rhenium, osmium, iridium, platinum and the others high atomic number materials on the periodic table. 4. Method for recording and identifying objects according to claim 1, characterized by the fact of applying a film consisting of materials with low atomic number selected from the group consisting of beryllium, magnesium, aluminum, silicon, its oxides and other materials of number low atomic number on the periodic table. 5. Method for recording and identifying objects according to claim 1, characterized in that the deposition process is selected from the group consisting of physical depositions, chemical depositions, baths, paintings or electrodeposition. 6. Method for recording and identifying objects according to claim 1, characterized in that the materials used can be any from the periodic table of the elements, their alloys or compounds that have adequate adhesion and a difference in atomic number sufficient to identify them. them. 7. Single film for recording solid artifacts characterized in that it comprises a transparent oxide, said transparent oxide being metallic oxides selected from titanium oxide, silicon oxide, zinc oxide, hafnium oxide or zirconia with a thickness between 700 and 900 nm so that there is no visible color reflection of the engraving on the material of the object, weapon or artifact.

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