KR101341487B1 - Polarizing fiber and security paper using the same - Google Patents

Abstract

The present invention relates to a polarizing fiber and a security paper using the same.
The polarizing fiber of the present invention contains a coloring material in an island-in-the-sea nanofiber having 30 or more island components having a fiber diameter of 500 nm or less, thereby exhibiting color in visible light with excellent polarization characteristics due to the birefringent interface of the island-in-the-sea nanofiber. And high strength physical properties. Therefore, by applying the polarizing fiber of the present invention to the security paper, in addition to the security yarn characteristics determined in the conventional UV or IR region, due to the excellent polarization characteristics by the birefringent interface of the island-in-the-sea nanofibers, The transparency can be distinguished from visible light because it can be distinguished from visible light, which is useful for preventing counterfeiting of banknotes, passports, checks, and securities, or imitation of expensive brand goods.

Description

Polarized fiber and security paper using the same {POLARIZING FIBER AND SECURITY PAPER USING THE SAME}

The present invention relates to a polarizing fiber in which color is contained in the island-in-the-sea type nanofibers having a birefringent interface and expressing color in visible light, and a security paper using the same. The present invention relates to a polarizing fiber in which color is expressed in visible light with excellent polarization characteristics due to the birefringent interface of the island-in-sea type nanofibers, and a security paper using the same.

In general, paper used as security papers such as banknotes, checks, passports, bonds, and other securities incorporates security fibers (security threads) as a means for counterfeit prevention, visual and authenticity. Use it.

In general, the short fibers of about 3 to 10 mm are partially colored or fluorescent color is added, and some of the short fibers are added during the papermaking process of the paper to make them visually dichroic or to display fluorescent colors under ultraviolet light. Differentiate with.

As such, the goal of recent security factors is to enable visual identification as well as authenticity by the identifier. In other words, due to the securities deposit and withdrawal by automated devices, the use of vending machines and the distribution of various security products, machine reading for fast and clear authenticity assessment becomes essential.

In the case of the fluorescent color yarn manufactured by Korean Patent No. 346056, there is disclosed a monochromatic fluorescent color yarn manufactured by mixing and melting the fluorescent pigment with synthetic resin raw materials. In the case of the fluorescent color yarn used for the security film of Korean Patent No. Blue and green fluorescent materials are dyed in nylon yarns by color to prepare fluorescent yarns having a single color such as red, blue, or green, respectively, according to each strand of the fluorescent yarns, and then mixed and used fluorescent yarns of different colors. However, in the case of the conventional fluorescent color yarn, the color or structure is monotonous, and there is a drawback in that the uniformity of the color at the time of dyeing is much lowered, so that the anti-counterfeiting function is deteriorated.

It is a diversified technology that solves these problems and applies the visual effect of fluorescent color yarns, leaving the fibers at regular intervals, primary dyeing and drying with the rest blocked, and then opening the blocked portions and The method for producing dichroic fibers or color copper fibers in which two or more colors are dyed in fibers by blocking and dyeing other colors therein is described in Korean Patent No. 1996-13836, and Korean Patent No. 259825 describes a number of strands. A method for producing colored copper fibers, in which the fibers are twisted and dyed to expose the exposed portions, the fibers are cut and unwound, and then undyed to recolor in different colors. However, the prior art has been pointed out a problem that the dyeing process is complicated, mass production is difficult, the interface of the dyeing portion is uneven, and the durability of the dyeing on the fiber surface is poor.

Accordingly, the present inventors have tried to solve the problem of the conventional fluorescent color yarn, as a result of applying a polarizing fiber containing a coloring material in the islands of the islands-shaped nanofibers with 30 or more fiber diameter 500nm or less distributed to the security paper, the conventional UV or In addition to the security yarn characteristics determined in the IR region, due to the excellent polarization characteristics due to the birefringent interface of the island-in-the-sea nanofibers, the transparency of the fibers varies depending on the polarization direction, so that discrimination is possible even in visible light, thereby reducing the possibility of replication. By confirming, the present invention was completed.

An object of the present invention is to provide a polarizing fiber in which a color material is contained in the island-in-the-sea nanofibers having a birefringent interface to express color in visible light.

Another object of the present invention is to provide a method for producing the polarizing fiber.

Still another object of the present invention is to provide a security paper for manufacturing anti-counterfeiting banknotes, passports, checks and securities containing the polarizing fiber.

The present invention is a birefringence of the island-in-the-sea nano-fibers, containing at least one colorant selected from dichroic dyes, dyes, pigments, or fluorescent substances in the island-in-the-sea nano-fibers with 30 or more island components having a fiber diameter of 500 nm or less, It provides a polarizing fiber in which the color is expressed in visible light by the sex interface.

The island-in-the-sea nano-fiber of the present invention will contain 5 to 95% by weight of islands.

The island-in-the-sea nanofiber has a circular cross section; Or any other shape selected from the group consisting of triangle, rectangle, polygon, ellipse, -type, Y, +, #, and *.

As a coloring material for implementing color in the polarizing fiber of the present invention, one or more selected from dichroic dyes, dyes, pigments, or fluorescent materials may be used. However, for the island-in-the-sea type nanofibers, the content of the coloring material may be from 0.001 to It is contained in 50 weight%.

At this time, the island-in-sea component or sea component of the island-in-the-sea nanofiber may be contained, and to be contained in both components of the island-in-the-sea component and sea component of the island-in-the-sea nanofiber.

In addition, the present invention provides a manufacturing method of the first preferred embodiment to provide the polarizing fiber. Specifically,

1) preparing a master batch for preparing sea component consisting of hydrophilic polymer resin,

2) Prepare a master batch for preparing the island component consisting of one or more selected from thermoplastic polymer resins, at least one component or both components when preparing the master batch of the sea component or island component, 0.001 to 50% by weight of the coloring material Add,

3) The master batches of sea component and island component are respectively put into a melt spinning machine, and composite spinning at a spinning speed of less than 500 to 3,000 m / min to obtain undrawn or partially drawn yarn of island-in-the-sea nanofibers.

4) The non-drawn or partially drawn yarn is heat-treated after in-line or offline stretching to provide a fully drawn yarn of island-in-the-sea nanofibers.

In addition, the present invention, in order to provide the polarizing fiber, as a manufacturing method of the second preferred embodiment,

1) preparing a master batch for preparing sea component consisting of hydrophilic polymer resin,

2) Prepare a master batch for preparing the island component consisting of one or more selected from thermoplastic polymer resins, at least one component or both components when preparing the master batch of the sea component or island component, 0.001 to 50% by weight of the coloring material Add,

3) The master batch of sea component and island component is introduced into a melt spinning machine, and the composite spinning is carried out at a spinning speed of 3,000 to 8,000 m / min in which strain-induced crystallization occurs, thereby providing a high orientation yarn of island-in-the-sea nanofibers.

Thus, in the manufacturing method of the first embodiment and the second embodiment of the present invention, the content of the island component constituting the island-in-the-sea nanofibers is contained within 5 to 95% by weight.

Furthermore, the present invention provides a security paper for manufacturing anti-counterfeiting banknotes, passports, checks, and securities for incorporation into the papermaking process.

More specifically, the security paper of the present invention is incorporated in the form of short fibers cut into 20 or more fiber sheets (L / D) when the polarizing fibers are incorporated in the papermaking process.

In addition, the polarizing fibers may be provided on a transparent film made of paper or thermoplastic polymer resin, it is incorporated in a form woven in one direction (UD) can provide a security paper.

The present invention provides a polarized fiber containing a coloring material in an island-in-the-sea nanofiber having a fiber diameter of 500 nm or less distributed 30 or more, thereby providing color in visible light with excellent polarization characteristics due to the birefringent interface of the island-in-the-sea nanofiber. Expresses, and achieves high orientation and high strength compared to the island-in-the-sea fibers of the micro-fiber size obtained in the conventional melt composite spinning.

Accordingly, the present invention is incorporated into the papermaking process, or weaved polarized fibers that are expressed in visible light in the papermaking process, by applying the security yarn, which is determined in the conventional UV or IR region, the birefringent interface of the island-in-the-sea type nanofibers Due to the excellent polarization characteristics, the transparency of the fiber is changed according to the polarization direction can be distinguished even in visible light can further lower the replicability. Therefore, since the security paper of the present invention can be visually identified, it provides a convenience that can be quickly applied in the field without using an identifier for authenticity assessment.

Therefore, the security paper of the present invention is useful for anti-counterfeiting banknotes, passports, checks, and securities manufacturing, in particular, security paper containing the same due to the high-strength characteristics of island-in-the-sea nanofibers having 30 or more island components distributed therein. Provides durability.

1 is a cross-sectional photograph of an island-in-the-sea nanofiber according to Example 1 of the present invention,
2 is a cross-sectional photograph of an island-in-the-sea nanofiber according to Example 2 of the present invention;
3 is a view showing a change in light transmittance according to the polarization direction with respect to the security paper using the island-in-the-sea nanofiber of Example 1 of the present invention.

Hereinafter, the present invention will be described in detail.

The present invention is a birefringence of the island-in-the-sea nano-fibers, containing at least one colorant selected from dichroic dyes, dyes, pigments, or fluorescent substances in the island-in-the-sea nano-fibers with 30 or more island components having a fiber diameter of 500 nm or less, It provides a polarizing fiber in which the color is expressed in visible light by the sex interface.

The polarizing fiber of the present invention has a birefringent interface from the structure in which the island-in-the-sea type nanofibers are distributed more than 30 island components having a fiber diameter of 500 nm or less, and thus is due to the knitting characteristics implemented thereby. In addition, it is possible to visually identify the visible light due to the excellent polarization characteristics.

Therefore, the island-in-the-sea nanofiber of the present invention has a fiber diameter of 500 nm or less, more preferably 300 nm or less, and contains 30 or more, more preferably 1,000, most preferably at most 4,000 islands. Structure. The island-in-the-sea nanofiber of the present invention preferably contains 5 to 95% by weight of island-in-the-sea component in the island-in-the-sea nanofiber, and by adjusting the above components, the specific gravity of the island-in-the-sea nanofiber can be designed to be at least one or more. Specifically, when the specific gravity of polypropylene (PP), polyethylene (PE) and the like used as a island component in the island-in-sea type nanofiber of the present invention is less than 1, the island-in-the-sea type nanofibers are determined by the weight ratio of the hydrophilic polymer resin of the sea component. Adjust the total specific gravity of to be at least 1. In addition, if any one of the components out of the above range, the cross-sectional shape of the island-in-the-sea nanofibers is non-uniform, there is a problem that the effect on improving the water dispersibility is reduced, or the dichroic color expression is insufficient.

The sea component and island component constituting the island-in-the-sea nanofiber of the present invention are nanofibers satisfying the above requirements, and are not limited to the components thereof and can be prepared from known materials.

However, more preferably, the sea component of the island-in-the-sea nanofiber of the present invention may use a hydrophilic polymer resin to improve water dispersibility during the papermaking process, thereby increasing the miscibility with the paper.

Thus, the hydrophilic polymer resin that can be used as a sea component in the present invention is nylon, polyacrylonitrile, polyacrylic acid, polyacrylate, polymethyl methacrylate, polyethyleneimide, cellulose acetate, cellulose triacetate, polyvinyl alcohol, At least one selected from the group consisting of polyvinylpyrrolidone, polyethylene glycol, sulfonated polysulfone, polyethylene oxide and polyvinylacetate is used.

In addition, polyester-based resins having moderate polarity of hydrophilicity and hydrophobicity may also be used, and preferred examples thereof include polyethylene terephthalate (PET), polybutylene terephthalate (PBT), polytrimethylene terephthalate (PTT) and Any one selected from the group consisting of polyethylene naphthalate (PEN) can be used.

In addition, the island component in the island-in-the-sea nanofiber of the present invention should have excellent spinning properties, and should not be thermally decomposed when the coloring material is mixed due to the small change in physical properties. Preferred examples of meeting these requirements include polypropylene (PP), polyethylene (PE), polyethylene terephthalate (PET), polyethylene naphthalate (PEN), polystyrene (PS), polycarbonate (PC), polymethylmethacrylate. (PMMA), polyethersulfone (PES), polyvinylidene fluoride (PVDF), polyetherketone (PEEK), polyphenylsulfide (PPS) and at least one selected from the group consisting of aromatic polyesters.

In the embodiment of the present invention as a most preferred example, the sea component and island component is described as limited to the island-in-the-sea nano-fiber made of nylon-polypropylene, as described above, the sea component and island component of the present invention If it meets the requirements, it may be selected from the group of materials presented above and modified by appropriate combinations.

The islands-in-the-sea nanofiber has a circular cross section; Or any one cross-section selected from the group consisting of triangle, square, polygon, oval, -type, Y-type, + -type, # -type and * -type; Include a structure.

As the coloring material to implement the color in the polarizing fiber of the present invention may be used any one or more selected from dichroic dyes, dyes, pigments or fluorescent materials, preferably invisible UV fluorescent pigments, infrared reaction type or absorption type The pigment provides a security firm that can be distinguished even in the ultraviolet or infrared region.

Examples of coloring materials that can be used in the present invention include azo, anthraquinone, perylene, indanthrone, imidazole, indigoide, oxadine, naphthalocyanine, phthalocyanine, triphenylmethane, Pyrazolone-based, stilbene-based, diphenylmethane-based, naphthoquinone-based, methocyanine-based, quinophthalone-based, xanthene-based, alizarin-based, acridine-based, quinoneimine-based, thiazole-based, dithiol-based metal complexes, di- Various kinds of dyes, dyes and pigments such as immonium-based, methine-based, nitro-based and nitroso-based may be used.

In this case, the content of the colored material is preferably contained in 0.001 to 50% by weight with respect to the island-in-the-sea nanofibers, if the content of the colored material is less than 0.001% by weight, the color of the final polarized fiber is insufficient, 50 When the excess content exceeds the weight%, there is a problem in the compatibility with the polymer resin when preparing the master batch is not uniformly dispersed, the efficiency of the content is lowered.

The coloring material may be contained in the island component or sea component of the island-in-the-sea nanofibers. In addition, both islands and sea component of the island-in-sea nanofibers contain a coloring material of a different color or property to realize the dichroism.

1 is a cross-sectional photograph of the island-in-the-sea nanofibers prepared by the spinning speed of 1,000 m / min in melt spinning in Example 1 of the present invention, Figure 2 is a spinning speed of 7,000 m / min in melt spinning in Example 2 The cross-sectional photograph of the island component is shown in the island-in-the-sea nanofiber manufactured by the present invention. From the above results, it is possible to confirm the island-in-the-sea nanofiber structure in which 3808 island components having a fiber diameter of 300 nm are distributed. These structural features not only provide excellent polarization characteristics due to the birefringent interface, but also provide high orientation and high strength compared to the island-in-the-sea fibers of the microfiber size obtained in the conventional melt composite spinning.

In addition, the island-in-the-sea nanofiber of the present invention is characterized in that the high-speed spinning of 1 km / min or more during the island-in-the-sea melt melt spinning.

Thus, the manufacturing method of the first preferred embodiment of the island-in-the-sea nanofiber of the present invention is prepared by 1) preparing a master batch for preparing sea component consisting of a hydrophilic polymer resin,

2) Prepare a master batch for preparing the island component consisting of one or more selected from thermoplastic polymer resins, at least one component or both components when preparing the master batch of the sea component or island component, 0.001 to 50% by weight of the coloring material Add,

3) The master batches of sea component and island component are respectively put into the melt spinning machine and combined spinning at a spinning speed of less than 500 to 3,000 m / min, resulting in undrawn yarn (UDY) or partial drawn yarn (Partial Oriented Yarn). ),

4) The non-drawn or partially drawn yarn is heat-treated after in-line or offline stretching to provide a completely drawn yarn (FDY).

In the manufacturing method of the first embodiment described above, if the spinning speed is less than 500 m / min during melt-combined spinning, the fiber orientation of the island component is not sufficient due to the low spinning tension, and thus it is not preferable. Composite spinning at spinning speed yields the desired undrawn or partially drawn yarn.

Moreover, the manufacturing method of 2nd Embodiment of a island-in-sea type nanofiber of this invention is

1) preparing a master batch for preparing sea component consisting of hydrophilic polymer resin,

2) Prepare a master batch for preparing the island component consisting of one or more selected from thermoplastic polymer resins, at least one component or both components when preparing the master batch of the sea component or island component, 0.001 to 50% by weight of the coloring material Add,

3) The master batch of the sea component and the island component is put into a melt spinning machine, and the composite spinning is carried out at a spinning speed of 3,000 to 8,000 m / min in which strain-induced crystallization occurs, and a high oriented yarn (High Oriented Yarn) , HOY).

In the manufacturing method of the second embodiment, a high-oriented yarn (HOY) is performed at a high spinning speed of 3,000 to 8,000 m / min so that strain-induced crystallization occurs during melt-combined spinning. You can get it. On the other hand, if the maximum exceeds 8,000 m / min, it is not preferable to form a non-uniform fiber structure by the cooling rate difference in and out of the fiber at high speed.

According to the spinning conditions during the melt-composite spinning, filament-shaped long fibers can be produced.

In the production methods of the first and second embodiments of the present invention, the island-in-the-sea nanofibers produced by melt-combined spinning are controlled so that their total specific gravity is at least one or more.

As a method of increasing the specific gravity of the fiber, it controls by controlling the content of sea component and island component constituting the island-in-the-sea nanofiber. More specifically, in the case of the polypropylene (PP) used as the island component in the embodiment of the present invention, the specific gravity is less than 1, but the weight of the hydrophilic polymer resin as the sea component so that the total specific gravity of the island-in-the-sea nanofibers is 1 or more. You can adjust it by increasing the ratio.

Thus, more preferably, the island-in-the-sea component is included in the island-in-the-sea nanofibers 5 to 95% by weight, and the specific gravity of the island-in-the-sea nanofibers is adjusted to a desired level according to the content thereof.

As another method for increasing the specific gravity of the fibers, a method of increasing the degree of crystallization of the fibers can be applied. This is accomplished by means of increasing the fiber heat treatment temperature or extending the heat treatment time at the time of drawing or post-processing. Alternatively, there is a method of causing strain-induced crystallization in fibers through high-speed spinning. For example, even with the same PET fiber, the specific gravity of the non-crystalline structure may be about 1.36, but the specific gravity of the crystalline structure may be increased to about 1.45.

At this time, in the island-in-the-sea nanofibers produced from the manufacturing method of the first embodiment and the second embodiment of the present invention, the material and the content of the sea component and the island component are the same as above, and detailed description thereof will be omitted. However, since the sea component in the island-in-the-sea nanofiber of the present invention is composed of a hydrophilic polymer resin, it is possible to improve water dispersibility during the papermaking process, and the island component uses a thermoplastic polymer resin having excellent spinning property.

Furthermore, the present invention provides a security paper for the anti-counterfeiting banknote, passport, check and securities manufacturing purpose in which the polarizing fiber is incorporated.

Preferably, the polarizing fiber of the present invention is cut into a staple form having a fiber length (L / D) of 20 or more and incorporated into the papermaking process.

In addition, the security paper of the present invention may be mixed in a form in which the polarizing fibers are woven in a predetermined width and one direction (UD) on a transparent film made of a paper or thermoplastic polymer resin.

FIG. 3 illustrates the change in the light transmittance according to the polarization direction of the security paper made of the island-in-the-sea nanofibers containing 3808 prepared 200nm grade components. When the polarization direction of the island-in-the-sea nanofibers is 0 degrees, While showing a transmittance of 92%, when the polarization direction is 90 degrees, by showing a transmittance of 5%, a remarkable polarization effect can be confirmed. In addition, as a result of comparing the light transmittance according to the polarization direction with respect to the polarized light of _548nm , a distinct light transmittance difference that is bright when the fiber weaving direction is perpendicular to the polarization direction (n _ㅗ ), and dark when parallel (n _// ) ( Due to the polarization characteristics, in particular, when perpendicular to the polarization direction, the fiber shape of the organic nano long fibers is not seen, and thus the light transmittance is high, and thus the transmittance improvement can be expected.

On the other hand, the conventional islands-in-the-sea type microfibers containing 74 1 μm grade components show a transmittance of 10 to 20% when the polarization direction for the island-in-the-sea microfiber is 0 degrees, while the polarization direction is 90 degrees. It has a low polarization effect with a transmittance of 5%.

In this case, the island-in-the-sea nanofibers constituting the polarizing fiber of the present invention are incorporated into a papermaking process by satisfying the requirement that the sea component is made of a hydrophilic polymer resin by melt-combination, and the total specific gravity of the island-in-the-sea nanofibers is 1 or more. By optimizing the conditions, the content and miscibility can be increased.

The polarizing fiber of the present invention has a polarization characteristic due to the birefringent interface on the island-in-the-sea nanofiber structure, so that color can be realized even in visible light, so that the security paper containing the polarizing fiber is characterized by the security yarn characteristics determined in the UV or IR region. In addition, due to the excellent polarization characteristics by the birefringent interface of the island-in-the-sea nanofibers, the transparency of the fiber is changed according to the polarization direction can be distinguished even in visible light can further reduce the replication possibility.

Thus, the polarizing fiber of the present invention can be quickly applied in the field without using an identifier for authenticity feeling. In addition, the island-in-the-sea nanofibers implement a high orientation and high strength compared to the island-in-the-sea microfiber obtained in the conventional melt-composited spinning, security paper containing it can ensure durability.

Thus, the security paper of the present invention can be applied to the anti-counterfeiting of banknotes, gift certificates, securities, passports, etc., can also be applied to the anti-counterfeit group of imitation prevention.

Hereinafter, the present invention will be described in more detail with reference to Examples.

This embodiment is intended to illustrate the present invention in more detail, and the scope of the present invention is not limited to these examples.

Example 1 Preparation of Polarizing Fiber 1

46% by weight of hydrophilic resin nylon (Nylon-6) as a sea component and 50% by weight of polypropylene (PP) as a island component were mixed with 4% by weight of UV-fluorescent yellow-green pigment and melted, respectively. Melt-composite spinning was carried out using an island-in-the-sea nozzle to contain island-in-law components, and spinning was performed at a speed of 1,000 m / min, thereby preparing polarized fibers made of island-in-the-sea nanofibers containing 3808 200 nm-grade components. .

Spinning Nozzle: Insulated Spinning Nozzle capable of spinning 3808 islands in one hole

Spinning temperature: 275 ℃

Spinning speed: 1,000 m / min

Example 2 Polarizing Fiber Preparation 2

In the process of Example 1, using the island-in-the-sea spinning nozzle that can emit 3808 islands in one hole, except that the spinning speed was performed at 7,000 m / min, the same as in Example 1 To prepare a polarizing fiber made of island-in-the-sea nanofibers containing 3808 200nm grade components consisting of Nylon-PP.

Example 3 Polarizing Fiber Preparation 3

2% by weight of yellow-green pigment is mixed with 48% by weight of hydrophilic resin nylon (Nylon-6) as a sea component, and 2% by weight of red pigment is made by 48% by weight of polypropylene (PP) as a island component. Is melted and melted and spun at a rate of 1,000 m / min using a island-in-the-sea nozzle that contains 3808 islands, and the islands contain 3808 islands of 3rd grade 200nm A polarizing fiber made of nanofibers was prepared.

Example 4 Preparation of Security Paper 1

Polarized fibers made of island-in-the-sea nanofibers prepared in Example 1 were woven side by side in one direction (UD), and then placed on a stock, and then compressed and melted by a high-pressure press at 200 ° C., press-molded into a film, followed by cooling to form polarized fibers. Woven security paper was prepared.

Example 5 Preparation of Security Paper 2

Polarization fibers made of islands-in-the-sea nanofibers prepared in Example 1 were prepared by cutting into a fiber length (L / D) 20, and the islands-in-the-sea nanofibers were mixed and papermaking in an initial process.

Comparative Example 1 Polarizing Fiber Preparation

In the process of Example 1, except for using a conventional islands-in-the-sea spinning type spinning nozzle capable of spinning 74 1 μm grade components in one hole, the island-in-the-sea micro Fibers were prepared.

Comparative Example 2 Preparation of Security Paper

The islands-in-the-sea microfibers prepared in Comparative Example 1 were woven side by side in one direction (UD), and then placed on a stock, compressed and melted by a high pressure press at 200 ° C., press-molded into a film, and cooled to prepare a security paper.

Experimental Example 1 Optical Characteristic Evaluation

For each of the security papers of Example 4 and Comparative Example 2 using the island-in-the-sea fibers prepared in Example 1 and Comparative Example 1, the light transmittance and polarization characteristics along the polarization direction were measured with a polarizing optical microscope.

As a result, Figure 3 is a result showing the change of the light transmittance according to the polarization direction when made of island-in-the-sea nanofibers containing 3808 200nm grade components prepared in Example 1. From the above results, when the polarization direction for island-in-the-sea nanofibers is parallel (n _// ) or 0 degrees, the transmittance is 92%, while when the polarization direction is perpendicular (n _ㅗ ) or 90 degrees, the transmittance of 5% is obtained. By showing, the remarkable polarization effect was confirmed.

Thus, in the case of the island-in-the-sea nanofibers, the light transmittance according to the polarization direction with respect to the polarized light of 548nm is compared, it is bright if the fiber weaving direction is perpendicular to the polarization direction (n _밝 ), and parallel (n _// ) The light transmittance difference (polarization characteristic) became dark. In addition, when the direction perpendicular to the polarization direction, the fiber shape of the organic nano-long fibers were not seen, the light transmittance was high, and thus the possibility of improving the transmittance was confirmed.

On the other hand, in the case of the island-in-the-sea microfibers containing 74 1 μm-grade islands prepared in Comparative Example 1, when the polarization direction of the island-in-the-sea microfibers is parallel (n _// ) or 0 degrees, 10 to 20% On the other hand, when the polarization direction was perpendicular (n _ㅗ ) or 90 degrees, the transmittance of 5% was confirmed, resulting in less polarization effect. From the above results, there is a limit in the application of the polarizing fiber, which is poor in all directions.

In the case of the island-in-the-sea microfiber containing 74 1 μm-grade conductive components prepared in Comparative Example 1, the light transmittance according to the polarization direction with respect to the polarized light of 548 nm is compared, and the fiber weaving direction is perpendicular to the polarization direction (n _ㅗ ), it is bright and parallel (n _// ), it shows a distinct light transmittance difference (polarization characteristic), which becomes dark, but it shows a 1μm-fiber form and a low transmittance.

As described above,

First, the present invention provides a polarizing fiber in which the color is expressed in visible light due to the excellent polarization characteristics of the island-in-the-sea nano-fibers having a birefringent interface.

Second, the present invention provides a method for producing a polarizing fiber optimized to control the specific gravity of the island-in-the-sea nanofibers constituting the polarizing fiber to one or more.

Third, the present invention provides a security paper for manufacturing anti-counterfeiting banknotes, passports, checks, and securities by incorporating or weaving polarized fibers that express color in visible light in a papermaking process. In addition to the security yarn characteristics determined in the UV or IR region, the security paper has excellent polarization characteristics due to the birefringent interface of the island-in-the-sea nanofibers. It can be further lowered, and the naked eye can be identified, which provides convenience for quick application in the field without using an identifier for authenticity assessment.

While the invention has been shown and described with reference to certain exemplary embodiments thereof, it will be understood by those skilled in the art that various changes and modifications may be made without departing from the spirit and scope of the invention as defined by the appended claims.

Claims (12)

The island-in-the-sea nanofibers having 30 or more island diameters of 500 nm or less are distributed therein, and at least one coloring material selected from dichroic dyes, dyes, pigments, or fluorescent substances is contained. Color is expressed in visible light, polarized fiber characterized in that the sea component of the island-in-the-sea nanofiber is a hydrophilic polymer resin. The polarizing fiber according to claim 1, wherein the island-in-the-sea nanofiber contains 5 to 95% by weight of a island component. According to claim 1, The island-in-the-sea nanofibers are circular cross-section; Or any one cross-section selected from the group consisting of triangles, squares, polygons, ellipses, -types, Y-types, + -types, # -types, and * -types. The polarizing fiber of claim 1, wherein the coloring material is contained in an amount of 0.001 to 50% by weight in the island component or sea component of the island-in-the-sea nanofibers. The polarizing fiber of claim 1, wherein the coloring material is contained in an amount of 0.001 to 50% by weight in the island component and the sea component of the island-in-the-sea nanofiber. 1) preparing a master batch for preparing sea component consisting of hydrophilic polymer resin,
2) Prepare a master batch for preparing the island component consisting of one or more selected from thermoplastic polymer resins, at least one component or both components when preparing the master batch of the sea component or island component, 0.001 to 50% by weight of the coloring material Add,
3) A master batch of sea component and island component is placed in a melt spinning machine equipped with an island-in-the-sea spinning nozzle containing 30 or more island components, and at a spinning speed of less than 1,000 to 3,000 m / min during island-in-the-sea melt spinning. It is obtained by the unstretched or partially stretched yarn of islands-in-sea nanofibers in which 30 or more island components having a fiber diameter of 500 nm or less are distributed by complex spinning,
4) A method for producing a polarizing fiber, characterized in that the non-drawn or partially drawn yarns are heat-treated after in-line or offline stretching to provide a completely drawn yarn of island-in-the-sea nanofibers. 1) preparing a master batch for preparing sea component consisting of hydrophilic polymer resin,
2) Prepare a master batch for preparing the island component consisting of one or more selected from thermoplastic polymer resins, at least one component or both components when preparing the master batch of the sea component or island component, 0.001 to 50% by weight of the coloring material Add,
3) The master batch of the sea component and island component is placed in a melt spinning machine equipped with an island-in-the-sea spinning nozzle containing 30 islands or more island components, and strain-induced crystallization occurs during island-in-the-sea melt-fusion spinning. The method of manufacturing a polarizing fiber, characterized in that the composite yarn at a spinning speed of min, provided as a high orientation yarn of island-in-the-sea nanofibers having 30 or more island components having a fiber diameter of 500 nm or less. The method of claim 6 or 7, wherein the island-in-the-sea nano-fibers are contained in an amount of 5 to 95% by weight, and the specific gravity of the island-in-the-sea nanofibers is designed to be 1 or more. . Security paper for manufacturing anti-counterfeiting banknotes, passports, checks and securities in which the polarizing fibers of any one of claims 1 to 5 are mixed. The security paper according to claim 9, wherein the polarizing fiber is cut into a fiber length (L / D) of 20 or more and incorporated into a papermaking process. The security paper according to claim 9, wherein the polarizing fibers are mixed in a woven form in one direction on a transparent film made of paper or thermoplastic polymer resin. According to claim 1, wherein the sea component of the island-in-the-sea nanofibers are nylon, polyacrylonitrile, polyacrylic acid, polyacrylate, polymethyl methacrylate, polyethyleneimide, cellulose acetate, cellulose triacetate, polyvinyl alcohol, poly At least one hydrophilic polymer resin selected from the group consisting of vinylpyrrolidone, polyethylene glycol, sulfonated polysulfone, polyethylene oxide and polyvinylacetate; Or the polyester-based resin selected from the group consisting of polyethylene terephthalate, polybutylene terephthalate, polytrimethylene terephthalate and polyethylene naphthalate.

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