RU179757U1 - SEAL AUTHENTICITY CONTROL DEVICE - Google Patents

Abstract

The utility model relates to the field of engineering. The authentication device for seals consists of an infrared laser to excite the ultraviolet radiation of the phosphor applied to the seal when it is painted, a lens, a light filter emitting a specific wavelength of radiation, a photodetector that converts optical radiation into an electrical signal, an electric signal amplifier, and an indicator device. The technical result consists in providing the possibility of using instrumental authentication of seals. 1 ill.

Description

The utility model relates to the field of mechanical engineering and can be used to protect various objects from falsification or substitution, including the detection of fake or opened seals with camouflage traces of exposure.

In existing seals, along with structural strength, the epoxy-polyester coating of the body is a means of protecting it from replacement or tampering. This coating, like all traditional coatings, differs only in layer thickness and various color versions.

When falsifying or substituting a seal for a similar one, these coatings can be reproduced or camouflaged by an attacker.

An additional means of protecting a seal is its marking with an individual serial number and a company logo applied by a laser method, engraving or another method of mechanical action, which can be easily reproduced using modern marking devices.

Known seal with protection against fake or substitution (RF patent for utility model No. 48346 dated 05/04/2005, G09F 3/03), comprising a housing with a locking mechanism and a flexible covering element, the surface of the housing partially or completely coated; containing a phosphor of organic or inorganic origin, having a luminescence spectrum in the region of 100-1200 nm. The authentication of the seal is carried out by placing it under a radiation source of a certain wavelength (depending on the type of phosphor), and the presence of the afterglow of the phosphor is visually checked. The absence of a phosphor in the coating of the seal body over its entire surface or in a certain part of it indicates a criminal effect on the phosphor seal, depending on the climatic and functional purpose, it can be used both organic and inorganic origin. The introduction of phosphor markers into the coating composition of the seal allows under the influence of natural or artificial light to give the coating surface of the seal an additional photoluminescent glow that differs in color from the main tone of the painted surface. The difference in the color of the coloring and the background color of the phosphor is a sign of a fake or a substitute seal. It should be noted that it is advisable to verify the authenticity of seals in a darkened room or at dusk, because usually the percentage of phosphor added to the coating does not exceed 5% of the total paint volume, which makes it difficult to detect fakes.

A disadvantage of the known device for controlling the authenticity of seals is the subjectivity of decision-making, due to possible errors caused by the contaminated surface of the seal, and the inability to control the seals at a high level of illumination.

The technical result of the utility model is the possibility of applying instrumental authentication of seals, as well as providing a control procedure at a high level of illumination and increasing its reliability.

The indicated technical result is achieved by the fact that to identify cases of falsification or substitution of a seal, a device consisting of an infrared laser is used to excite ultraviolet radiation of a phosphor, a lens, a light filter emitting a certain wavelength of radiation, a photodetector that converts optical radiation into an electrical signal, an electric signal amplifier and indicator device.

The operation of the seal authentication device is illustrated in the circuit of FIG. 1. The numbers on the diagram indicate: infrared laser (1), controlled seal (2), lens (3), light filter (4), photodetector (5), electric signal amplifier (6) and actuator (7). Structurally, all the constituent elements of the control method can be placed in one housing. Naturally, the device should include a power source and an on-off button.

The authentication device seals works as follows. The controlled filling (2) is illuminated using an infrared laser (1). The phosphor included in the coating of the seal (2) converts the infrared radiation of the laser into a photoluminescent glow in the ultraviolet wavelength range. Ultraviolet radiation, with the help of a lens (3), is passed through a light filter (4) and focuses on the sensitive area of the photodetector (5). The photodetector converts optical radiation into an electrical signal, which is amplified by an amplifier (6) and fed to an actuator (7), which is used, for example, a speaker that emits an audio signal or an LED, the glow of which indicates that the seal is genuine. In the event that the phosphor is absent in the paintwork coating, there is no sound or light indication. Also, the indication will be absent if the attacker, while faking a seal, inflicts a phosphor with another wave of photoluminescence. If the phosphor is applied over the entire surface of the seal, then using this device it is possible to identify areas on the surface of the seal where its integrity has been violated, for example, by drilling followed by camouflage of the drilling site.

Claims (1)

An authentication device for seals, consisting of an infrared laser, for exciting ultraviolet radiation of a phosphor applied to a seal when it is painted, a lens, a light filter emitting a specific wavelength of radiation, a photodetector that converts optical radiation into an electrical signal, an electric signal amplifier, and an indicator device.

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