KR100797794B1 - The cloth scheme and military use cloth to high quality products inclusive of infaraed rays cut ablility - Google Patents

Abstract

A military fabric and a method for manufacturing the same are provided to improve the durability and the tensile strength to improve the durability, tensile strength and other functionalities of the military cloth, by coating the military fabric with various functional materials including fluorine-based polyurethane and flame-retardant. A military fabric comprises a first coating layer(23) containing fluorine-based polyurethane and flame-retardant and a second coating layer(25) containing fluorine-based polyurethane, flame-retardant, and UV blocker. The military fabric is manufactured by forming the first coating layer on a fabric(21), and forming a second coating layer on the first coating layer. The first coating layer has a viscosity of 6,000-15,000 cps, and the second coating layer has a viscosity of 15,000-25,000 cps.

Description

The cloth scheme and military use cloth to high quality products inclusive of infaraed rays cut ablility}

1 shows an apparatus for the implementation of a coating method according to the invention.

Figure 2 shows a tent cloth fabric according to the invention the coating is made in stages.

Figure 3 shows a cross-sectional view of the tent paper fabric coated in accordance with the coating method of the present invention.

Figure 4 shows a cross-sectional view of the tent paper fabric showing the distribution form of the coating liquid according to the coating method of the present invention.

5a to 5e show various embodiments of the coating method according to the invention.

The present invention relates to a high-strength, high-quality military fabric including an infrared blocking function and a method of manufacturing the same, and more particularly, to a considerable fastness and tensile strength required for outdoor military fabrics (military outdoor tents, tents, other fabrics, etc.) In addition, the present invention relates to a high-quality military fabric with enhanced gastrointestinal function (IR function) from the nighttime infrared night vision equipment, which is particularly important in military fabrics, such as waterproofing, water repellent, flameproofing, and antifungal.

Normally, military fabrics (military outdoor tents, tents, military equipment coverings, etc.) are basically not only excellent in terms of fastness, tensile strength, but also excellent waterproof, water-repellent, flame-retardant, and anti-corrosive, considering their use in emergencies such as outdoor mountain environments and exhibitions. In addition to the fungal function, in recent years, IR function that can be disguised from enemy surveillance using infrared night vision equipment is particularly required.

However, the conventional military fabrics give the infrared blocking function first in the printing process and then apply the polyurethane coating on the surface through the subsequent process. The polyurethane has a very smooth surface, good friction resistance, elasticity, flexibility and flexibility. Has many advantages such as chemical resistance, cold-resistance,

Not only does it have a problem of releasing a large amount of volatile organic substances that can cause environmental pollution harmful to human body, but also has a problem of not meeting the considerable durability and high tensile strength, which is the required quality according to the characteristics used in harsh outdoor environments,

In particular, it has been found that there is a problem that does not properly express the effective gastrointestinal performance (IR shielding function) from the infrared night vision equipment has been evaluated as not suitable as a military fabric.

Accordingly, the present invention has been devised to solve the above problems, and greatly improves durability and tensile strength of military fabrics, and also adds various functional materials to prevent fire, antifungal function, and in particular, the quality of military fabrics. It was completed as a technical task with the focus on providing high quality military fabric and its manufacturing method including the desirable infrared blocking function that can exhibit the effective and excellent camouflage performance (IR function) from the infrared of the equipment, and also possess eco-friendly characteristics. .

In order to achieve the above technical problem, the present application will be described in more detail through the following manufacturing method.

The present invention, the military fabric is a first coating layer containing a fluorine-based polyurethane and flame retardant; The fluorine-based polyurethane (fluorine-based polyurethane can be synthesized using organic diisocyanate, macroglycol and diol), may comprise a second coating layer comprising a flame retardant and UV blocker.

According to another suitable embodiment of the present invention, the military fabric further comprises a backing layer, and the first coating layer and the second coating layer are sequentially laminated to the military fabric and the backing layer is opposite the first and second coating layers. Can be formed.

On the other hand, according to another suitable embodiment of the present invention, the coating method of the military fabric comprises the steps of forming a first coating layer comprising a fluorine-based polyurethane and flame retardant in the military fabric; And forming a second coating layer including a fluorine-based polyurethane, a flame retardant, and a UV blocking agent on the first coating layer, wherein the first coating layer is formed at 6,000 to 15,000 cps, and the second coating layer is formed at 15,000 to 25,000 cps. Can be.

The fluorine-based polyurethanes described above can be synthesized using organic diisocyanates, macroglycols and diols, and macroglycols are composed of polyols and fluorinated polyethers finished with hydroxide ions or carboxy ions. Diols contain hydrophilic ionizable functional groups. The hydroxyl groups of the organic diisocyanate and the polyol undergo a blocking reaction to form a urethane bond.
At this time, the ionizable groups in the diol can be converted into hydrophilic anions through a salification process to make the whole stabilized state, and then dispersed in water to form a water-soluble fluorine-based polyurethane.
In addition, the coating thereby greatly improves waterproofness and breathability, and contributes greatly to the improvement of durability of the fabric and the increase and decrease of tensile strength and environmental friendliness.
According to another suitable embodiment of the present invention, the adjustment of the coating liquid for the formation of the first and second coating layers may be achieved by a valve using a first container for storing the coating liquid and a second container for supplying the coating liquid.

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1 shows an apparatus for the implementation of a coating method according to the invention.

According to the coating method of the present invention, the fluorine-based polyurethane is coated on the fabric by a knife coating method. Knife coating is a method of installing a knife and coating it with a constant thickness. It is used when a thin and uniform coating is required. 1 shows an apparatus for such a knife coating.

Referring to FIG. 1, the knife coating according to the present invention uses a first container 11, a second container 13, an induction pipe 15, a valve 16, a knife 17 and a roller 18. It becomes practice.

The first container 11 is large in size to store the coating liquid, and the second container 13 directly supplies the coating liquid to the fabric 19 to be coated in a small size. In the conventional knife coating, the container containing the coating liquid and the knife remain in close contact with each other.

And the coating liquid flows out of the container and passes through the roller is coated by the knife. As such, the conventional coating method is directly supplied to the fabric without undergoing an intermediate adjustment process in a state where the coating liquid is filled in the container.

Therefore, the coating is made in a state where a load of the coating liquid itself in the coating liquid container is applied, and the coating liquid penetrates to the back surface of the fabric, thereby causing a problem in the process.

As shown in FIG. 1, in the coating method according to the present invention, the first container 11 for storing the coating liquid and the second container 13 for supplying are installed and the supply amount is adjusted using the valve 16. This solves this problem.

The coating liquid stored in the first container 11 is transferred to the second container 13 using a pump. The coating liquid of the delivered second container 13 is flowed out so that, for example, about 60 g is used for fabric coating by the valve 16 before being applied to the military fabric 19.

As described above, the coating method according to the present invention can prevent the coating liquid from penetrating the back surface of the military fabric 19 by reducing the amount of the coating liquid immediately before the coating. In addition, the coating liquid may be uniformly and uniformly coated by, for example, 60 g.

In general, the thickness and quality of the fabric coating depends on the thickness of the knife blade, the shape of the knife or the angle of the knife. In addition, there is a need to replace the knife for the optimum coating treatment according to the steps.

Unlike the known close coating method, the coating method according to the present invention allows the knife to be easily replaced by installing the knife at a predetermined distance from an outlet through which the coating liquid flows. In the coating method according to the present invention, functional materials such as, for example, flame retardants and sunscreens are added to the fluorine-based polyurethane liquid.

The coating liquid added with such a functional material may be coated in different conditions step by step, and thus, the fabric may have a water repellent and waterproof function without requiring a separate water repellent and waterproof process.

In addition, such a step coating can improve physical properties such as tear strength and tensile strength.

Figure 2 shows a military fabric 21 according to the invention the coating is made in stages.

Referring to Figure 2, the coating consists of two steps. In the first step, the fabric is coated using a fluorine-based polyurethane and flame retardant. Flame retardants that may be used include antimony antimony trioxide, antimony pentoxide, ammonium sulphide, and ammonium bromide. Or any flame retardant known in the art such as urea or borax may be used.

The mixing ratio of the fluorine-based polyurethane liquid and the flame retardant is about 6-8: 4-2. In the one-step coating process using such a fluorine-based polyurethane and flame retardant, the viscosity of the coating solution may be 6,0000 to 15,000 cps, preferably 10,000 cps.

And the thickness of the knife is about 0.3 to 0.8 mm, preferably 0.5 mm. As shown in FIG. 2, the primary coating layer 23 is directly formed on the surface of the fabric 21. The secondary coating layer 25 above the primary coating layer 23 is formed by a two-stage coating process according to the present invention.

In the two-stage coating process, the coating solution consists of a fluorine-based polyurethane solution + flame retardant + UV blocker. Flame retardants that can be used are similar to those used in the one step coating process. UV blocking agents can be known in the art such as zinc oxide, titanium dioxide, iron oxide and the like.

In addition, the mixing ratio of the fluorine-based polyurethane, UV blocking agent and flame retardant in the two-step coating process is 18 to 25: 1: 1 to 8-12, preferably 22.3: 1: 1.

In the two-step coating process, the coating liquid may have a viscosity of 15,000 to 25,000 cps, preferably 20,000 cps.
And the thickness of the knife used is 1.5 to 2.5 mm and preferably 2 mm. The secondary coating layer 25 formed by the two step coating process is shown in FIG. 2.

In this way, the coating is divided into two stages, so that the coating liquid may penetrate the surface, the inside of the fabric, and the back of the fabric, thereby increasing the tear and tensile strength. In the case of military fabric coated according to the coating method of the present invention, the tear and tensile strengths were 2,500 g and 5 kgf / mm 2, respectively.

In the coating process according to the present invention does not have a separate water repellent and waterproof treatment. In the coating process divided into two steps described above, since the coating liquid penetrates to the back surface of the fabric 21, a separate waterproof and waterproof process is not required, and the waterproof and water-repellent functions are maintained after washing. In the case of military fabric coated according to the coating method of the present invention, the water pressure was 5,000 mmH 2 O, and the water repellency was almost 100%.

Figure 3 shows a military fabric coated in accordance with the coating method of the present invention.

As shown in FIG. 3, the coating solution penetrates to the rear surface of the military fabric 21. The primary coating layer and the secondary coating layer together form the surface layer 31 and are shown in a circular shape with the military fabric 21 and the lower surface with the back layer 33.

Figure 4 shows a cross-sectional view of a military fabric coating in accordance with the coating method of the present invention.

As shown in FIG. 4, the coating layer comprises two layers. The formation of each coating layer is made according to the method described above. As described above, the coating liquid penetrates to the inside of the fabric 21. The coating liquid penetrated into the military fabric 21 forms the back layer 41. For this reason, the military fabric 21 coated according to the coating method of the present invention forms three layers such as the first coating layer 23, the second coating layer 25, and the back surface layer 41 as a whole.

In the coating liquid distributed in each coating layer, about 15 to 25% of the coating liquid on the first and second coating layers 23 and 25 and about 5 to 15% of the coating liquid on the back layer 41 are present.

The remaining 80 to 60% of the coating liquid is present in the penetrated state in the fabric (21). Preferably, about 20% of the first and second coating layers 23 and 25, about 10% of the back layer 41, and the remaining 70% may be present in the fabric 21.

The coating fabric according to the present invention formed as described above has a tear strength of about 2,500g, a tensile strength of about 5kgf / mm2 and the UV blocking effect reaches about 97%. The flame retardant performance is also about 1.5 seconds afterglow, 0 seconds afterglow, and 7.6 inch (60g / m2) carbonization distance.

5A to 5E illustrate various embodiments of a coating method according to the present invention.

Military fabric 21 of the present invention is coated in a single layer or a double layer by the first treatment agent 51 or the second treatment agent (52). The first treatment agent 51 is composed of a (fluorine-based polyurethane + catalyst) solvent + flame retardant + anti-mold agent and the second treatment agent 52 is (fluorine-based polyurethane + catalyst) solvent + flame retardant + UV blocker + anti-mildew agent.

The catalyst may be a metal catalyst or a sulfur catalyst and the like and an organic solvent such as hexane or ether may be used as a solvent for mixing. The catalyst or solvent may be any material known in the art, and may add an antifungal agent to the second coating layer, which may be silver.

Mixing of the solvent is carried out at 1500 to 2000rpm rotation state at room temperature for 5 to 10 minutes. In each coating condition, the viscosity of the coating liquid is 10,000 to 20,000 cps, and the thickness of the knife is 0.5 to 2.5 mm.

FIG. 5A illustrates that the second treatment agent 52 is coated on the fabric 21, and FIG. 5B illustrates that the second treatment agent 52 is sequentially coated on the fabric 21.

In addition, FIG. 5C illustrates a form in which the second treatment agent 52 is coated toward the outside of the fabric 21 and the second treatment agent 52 is coated in the same direction toward the inside thereof.

5D is a coating layer formed in the same manner as described above, in which the first treating agent 51 and the second treating agent 52 are coated. 5E illustrates that a coating layer is formed on the inside and outside of the fabric 21 using the first treatment agent 51 and the second treatment agent 52, respectively.

Fabric according to the present invention is excellent in durability by forming a functional coating, and exhibits light weight and high toughness compared to conventional PU products, and is not only expressed together with flame retardant, UV blocking and anti-mildew, but also high from infrared night vision equipment. It is evaluated that the utility as a military fabric is very high, such as exhibiting gastrointestinal performance, and in particular, the fluorine-based polyurethane presented in the present invention has a very high environmentally friendly factor due to its water solubility, and at the same time, This is a great invention because it provides considerable durability and tensile strength.

Claims (4)

In coated military fabric, A first coating layer comprising a fluorine-based polyurethane and a flame retardant; High quality military fabric including an infrared ray blocking function comprising a second coating layer comprising a fluorine-based polyurethane, flame retardant and UV blocker. delete delete In the coating method of military fabric, Forming a first coating layer comprising a fluorine-based polyurethane and a flame retardant; And forming a second coating layer comprising a fluorine-based polyurethane, a flame retardant, and a UV blocking agent on the first coating layer, wherein the first coating layer is formed at 6,000 to 15,000 cps, and the second coating layer is formed at 15,000 to 25,000 cps. High quality military fabric manufacturing method comprising an infrared cut function, characterized in that.

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