EA034164B1 - Device to control optical thickness of anisotropic layer - Google Patents

Abstract

A device to control the optical thickness of an anisotropic layer of polymerized liquid crystals containing a latent polarizing image, that includes a housing with a through hole in which a working element of polaroid film is installed, divided into zones with phase plates aligned with it, and a central zone with a phase plate is located in the center of the working element; the plate has a zero phase incursion; to the right of the central zone, phase plates are placed in the working element, which provide a step-by-step reduction of phase incursion in relation to the phase incursion provided by the phase plate of the central zone; to the left of the central zone the phase plates are placed in the working element, which provide a step-by-step increase in phase incursion in relation to phase incursion provided by the phase plate of the central zone. The device enables to promptly check the optical thickness of anisotropic layer of polymerized liquid crystals in the course of manufacturing protective equipment.

Description

The claimed invention relates to means of protection against counterfeiting of securities, documents, banknotes, excise and control marks, accompanying shipping documents, tickets, etc., in particular, to devices designed to control the optical thickness of the anisotropic layer of polymerized liquid crystals (PLC) ), which is used in the aforementioned protective equipment, in the manufacturing process of protective equipment.

An anisotropic layer of FFA contains a latent polarization image, which is visualized by polarized light. Visualization of the said latent polarization image with sufficient contrast occurs when the optical thickness of the anisotropic layer deviates from the nominal one within ± 10%. Within the same limits, a deviation from the nominal physical thickness of the anisotropic layer of PZhK is allowed. In the event that the thickness of the anisotropic layer of PZhK exceeds the nominal value more than the specified acceptable value, there is an increased consumption of liquid crystals, which is not economically feasible, since it leads to unjustified costs. If the thickness of the anisotropic layer of FFA is less than acceptable, the quality of the latent polarization image is deteriorated (contrast is lost) and the anisotropic layer of FFA is unsuitable for use in protective equipment.

Consequently, operational control of the thickness of the anisotropic layer of PZhK in the technological process of its deposition is necessary to create the optimal thickness by timely adjustment of the parameters of the technological process of its production. The efficiency of the mentioned control can be ensured if it is carried out by visualization of latent images using devices for visualization based on a polaroid film.

The identifier of the latent image is known, which is a body with a through hole in which a working element is installed, which ensures the polarization that is closest to circular during the passage of light, said working element made of a polaroid film combined with a birefringent transparent polymer film [1].

The disadvantage of this identifier is that only one image is visualized, which does not allow us to quickly determine the trends in the thickness of the anisotropic layer from the FFA.

Closest to the claimed device is the identifier of the latent polarizing image [2], which consists of a housing with a through hole in which a working element is installed made of a polaroid film, and the working element is divided into zones with phase plates aligned with it, which form the difference in stroke between ordinary and extraordinary rays from zero to a quarter wavelength [2]. This value is equivalent to a change in the phase incursion at the exit of the phase plate from zero to ninety angular degrees. The path difference between the ordinary and extraordinary rays at the exit of the phase plate, multiplied by the wave number k (k = 2n / X), gives a phase incursion.

The disadvantage of this device is that it has only one direction of change in the phase incursion, which is formed by phase plates, which does not allow to quickly determine the trends in the thickness of the anisotropic layer of PZhK.

The objective of the present invention is to provide an easy-to-manufacture and use device for the operational control of the optical thickness of an anisotropic layer of PUFAs in the manufacturing process of protective agents.

The problem is solved by the claimed device for controlling the optical thickness of the anisotropic layer of gulimerized liquid crystals containing a latent polarizing image that contains:

a housing with a through hole in which;

a working element made of a polaroid film installed in the housing and divided into zones by phase plates combined with it; at the same time, a central zone with a phase plate is placed in the center of the working element, which provides zero phase incursion and thereby contrast visualization of the latent polarization image for the nominal optical thickness of the anisotropic layer;

to the right of the central zone, phase plates are placed in the working element, which provide a step-by-step reduction of the phase incursion relative to the phase incursion provided by the phase plate of the central zone;

to the left of the central zone, phase plates are placed in the working element, which provide a stepwise increase in the phase shift relative to the phase shift provided by the phase plate of the central zone.

The claimed device has an advantage in which the step of phase incursion of each zone is -14 (minus fourteen) angular degrees for phase plates located to the right of the central plate, and +14 (plus fourteen) angular degrees for phase plates located to the left of it.

The claimed device also has an advantage in which the number of zones to the left and to the right of the central zone does not exceed four zones.

- 1 034164

At a step of the phase incursion of 14 angular degrees, an excess of the number of zones in excess of four will lead to the impossibility of modulating the anisotropic layer from the FFA to obtain a contrasting hidden polarization image for any magnitude of the phase incursion of the zone.

The claimed device also has an advantage, in which an image is made on the housing above or below the through hole, showing the direction of increase in the phase shift at the output of the phase plates

The claimed device also has an advantage, in which on the case to the left and / or to the right of the through hole the arrows show the direction of orientation of the device with respect to the direction of deposition of the anisotropic layer of polymerized liquid crystals. Since the protective equipment for the most part is manufactured using roll technology, the arrows in this case indicate the direction of unwinding of the roll.

An exemplary embodiment of the claimed device is illustrated by the drawings in FIG. 1-4.

In FIG. 1 shows a device in a static state /

In FIG. 2 shows the device when rendering a latent image at a nominal optical thickness of the anisotropic layer of PZhK.

In FIG. Figure 3 shows the device when rendering a latent image with an optical thickness of the anisotropic layer of PZhK exceeding the nominal.

In FIG. 4 shows the device when rendering a latent image with an optical thickness of the anisotropic layer of PUFAs below the nominal.

According to FIG. 1, the device comprises a housing 1 in which a through hole 2 is formed. A working element in the form of a polaroid film is inserted into the through hole 2, which is divided into zones with phase plates 3, 4, 5 aligned with it. A central zone with a phase plate is located in the center of the working element 3, which has a zero phase shift and, therefore, contrast visualization of the latent polarization image for the nominal optical thickness of the anisotropic layer. On the right are zones with phase plates 5 that provide a negative phase incursion at its output, i.e. provide a stepwise decrease in phase incursion relative to the phase plate of the Central zone. On the left are zones with phase plates 4, which provide a positive phase incursion at its output, i.e. provide a stepwise increase in phase incursion relative to the phase plate of the Central zone.

Under the phase plates 4 and 5 there is an image of an arrow 6, showing the direction of increase in the magnitude of the phase incursion. To the right of the through hole, arrow 7 shows the direction of orientation of the device with respect to the direction of deposition of the anisotropic layer of polymerized liquid crystals, in this case, this is the direction of unwinding of the roll.

In FIG. 2, 3 and 4, the aforementioned device is shown when rendering a latent image at different optical thicknesses of the anisotropic layer of PLC, i.e. actually illustrate the method of using the inventive device to control the optical thickness of the anisotropic layer.

The claimed device is used as follows. Put it on the anisotropic layer of PZhK, orienting along arrow 7 in the direction of unwinding of the roll, while the hidden image of the anisotropic layer is visualized. Since visualization occurs simultaneously under all phase plates of the device, the zone in which the most contrast visualization is observed is clearly distinguishable. Three options are possible for visualizing a latent image in an anisotropic layer of FFAs, which are shown in FIG. 2 - FIG. 4.

In FIG. 2 shows the device when rendering a latent image at a nominal optical thickness of the anisotropic layer of PZhK. In this case, the most contrasting image is in the central zone 3. In this case, intervention in the process is not required.

In FIG. Figure 3 shows the device when rendering a latent image with an optical thickness of the anisotropic layer of PZhK exceeding the calculated one. In this case, the most contrasting image is located to the right of the central zone 3, in the zone of arrangement of the phase plates 5. In this case, the adjustment of the technological process is required, since the material used to form the anisotropic layer is overused. It is necessary to reduce the physical thickness of the anisotropic layer, which will entail a decrease in optical thickness and the process will return to normal. Knowing the step of the phase incursion of the zone (in this example, -14 angular degrees), one can judge the degree of decrease in the thickness of the anisotropic layer.

In FIG. Figure 4 shows the device when rendering a latent image with an optical thickness of the anisotropic layer of PZhK lower than the calculated. In this case, the most contrasting image is located to the left of the central zone 3, in the zone where the phase plates are located 4. In this case, it is necessary to take measures to increase the thickness of the anisotropic layer, since there is a danger of loss of contrast and the release of low-quality products.

The inventive device allows you to quickly control the optical, and, consequently, physical thickness of the anisotropic layer of PZhK and timely make adjustments to the technological operation for applying liquid crystals to form an anisotropic layer of PZhK.

Thus, the technical result achieved by this invention consists in the possibility

- 2 034164 for the operational determination of the trend in the optical thickness of the anisotropic layer of PZhK during the manufacturing of protective equipment., Using the feature of human vision, with a high degree of reliability to evaluate the contrast of identical images when they are simultaneously considered.

Sources of information:

1. RU 65255 U1, 07.27.2007;

2. EA No. 027392, 11.24.2014.

Claims (5)

CLAIM 1. A device for controlling the optical thickness of an anisotropic layer of polymerized liquid crystals containing a latent polarizing image that contains a housing with a through hole in which a working element of a polaroid film is mounted, divided into zones with phase plates aligned with it, characterized in that in the center of the working the element has a central zone with a phase plate, which has a zero phase incursion; to the right of the central zone, phase plates are placed in the working element, which provide a step-by-step reduction of the phase incursion relative to the phase incursion provided by the phase plate of the central zone; to the left of the central zone, phase plates are placed in the working element, which provide a stepwise increase in the phase shift relative to the phase shift provided by the phase plate of the central zone. 2. The device according to claim 1, characterized in that the step of the phase incursion of each zone is -14 (minus fourteen) angular degrees for the plates located to the right of the central plate, and +14 (plus fourteen) angular degrees for the plates located to the left of her. 3. The device according to claim 2, characterized in that the number of zones to the left and to the right of the central zone does not exceed four zones. 4. The device according to claim 1, characterized in that on the housing above or below the through hole, an image is made showing the direction of increase in the magnitude of the phase incursion of the phase plates. 5. The device according to claim 1, characterized in that on the housing to the left and / or right of the through hole, the arrows show the orientation direction of the device with respect to the direction of deposition of the anisotropic layer of polymerized liquid crystals.