KR20100052766A - Bulletproof product - Google Patents

Abstract

PURPOSE: A manufacturing method of bulletproof products is provided to improve bulletproof property by optimizing seam intensity for sewing fabric, and to reduce processing costs of the bulletproof products. CONSTITUTION: A manufacturing method of bulletproof products includes a step for sewing a plurality fabrics consisting of multifilament. The seam intensity of the fabric is 60 ~ 200 kgf/inch. The fabric is sewn with 20 ~ 60 number/cm. The sewing yarn is made of nylon or polyester materials. Multifilament is made of wholly aromatic polyamide multifilament.

Description

Bulletproof product

FIELD OF THE INVENTION The present invention relates to antiballistic products, and more particularly to sewing of bulletproof products.

Bulletproof products are products for protecting the human body from the fracture of bullets or shells, and there are various types of bulletproof products such as body armor, bulletproof helmets, and bulletproof plates.

Bulletproof products are manufactured through a process of weaving nylon or aramid yarns to obtain a bulletproof fabric, and then sewing the obtained bulletproof fabric.

The anti-ballistic properties of such anti-ballistic products are known to be greatly influenced by the structure of the yarn and the fabric constituting the anti-ballistic fabric, and thus, there have been various proposals for high strength yarn and optimal fabric structure. However, the proposed yarn and fabric structure alone have not yet obtained a bulletproof product having the desired antiballistic properties. Accordingly, the bulletproof product may be increased by increasing the number of layers of bulletproof fabrics or adding a thermosetting resin between the bulletproof fabrics. Although methods have been developed to supplement the anti-ballistic properties of the anti-ballistic fabric by producing a, it has a disadvantage in that the weight of the bulletproof product increases as the number of laminated layers is increased or a thermosetting resin is added.

Therefore, in addition to the yarn or fabric structure of the bulletproof fabric, there is a demand for a method for understanding the factors that may affect the bulletproof characteristics of bulletproof products and improving the factors.

While the present inventors studied the factors that can improve the bulletproof properties of bulletproof products, it was confirmed that the sewing strength of the fabric by sewing the impact on the bulletproof properties of the bulletproof products, accordingly, by optimizing the strength of bulletproof bulletproof It is an object of the present invention to provide a bulletproof product capable of enhancing properties.

As a technical means for achieving the above object, the present invention is a plurality of fabrics made of warp and weft multifilament is sewn by a predetermined sewing thread, ballistic strength, characterized in that the bark strength is in the range of 60 ~ 200 kgf / inch Provide the product.

Here, the sewing thread may be sewn at 20 to 60 stitches / cm.

The sewing thread may be made of nylon or polyester material.

The multifilament may be made of wholly aromatic polyamide multifilament.

The fabric may have a 3A grade V0 of 436 m / s or more in a 44 Magnum bullet test based on the National Institute of Justice (NIJ) standard when stacked 30 to 35 sheets.

The fabric may be more than 90% sewing efficiency.

According to the present invention as described above has the following effects.

Bulletproof products according to the present invention has the effect of improving bulletproof properties by optimizing the bark strength by sewing of the fabric.

Hereinafter, embodiments of the present invention will be described in detail.

1. Bulletproof Products

The antiballistic product according to the present invention comprises a plurality of fabrics sewn by a predetermined sewing thread.

The fabric is a yarn (Yarn) constituting the warp and weft yarn is made of a multifilament, the multifilament may be used a wholly aromatic polyamide multifilament.

The multifilament may be composed of 400 to 1,000 monofilaments having a fineness of 0.7 to 1.6 denier. If a monofilament with a fineness of 1.6 denier or less is used, a larger number of monofilaments can be used to obtain multifilaments of the same fineness, thereby improving the absorbing force of bullet impact, and the fineness less than 0.7 denier In the case of using monofilament of the weaving process weaving may be inferior. It is advantageous that the multifilament has a tensile strength of 22 g / d or more to improve ballistic resistance. However, the present invention does not specifically limit the fineness and number of monofilaments and the tensile strength of multifilaments.

The fabric may be woven into plain or basket weave, the warp density and weft density may be 5 to 15 bone / cm, respectively, and the tensile strength of the fabric is 5,000 to 10,000 N / 5 cm. The range is advantageous for improving the ballistic resistance. However, the present invention does not specifically limit the tensile strength, the warp density and the weft density of the fabric.

A plurality of the fabric is sewn by a predetermined sewing thread to constitute a bulletproof product, wherein the bulletproof product is formed so that the sewing strength of the sewing is in the range of 60 ~ 200 kgf / inch.

When the bullet impacts the bulletproof product, the impact applied to the bulletproof product may be spread along the sewn portion, and thus the bulletproof performance may vary depending on the strength of the sewing. That is, when the bark strength is small, the sewing part may be destroyed during the collision of the bullet, and even if the sewing part is not destroyed, the effect of spreading the impact due to the impact of the bullet may be reduced and the bulletproof performance may be reduced. Therefore, increasing the bark strength can increase the impact diffusion effect and increase the bulletproof performance. However, if the bark strength is too large, the sewing efficiency is lowered, and if the predetermined strength or more, the sewing process itself may be impossible. Accordingly, by optimizing the bark strength, it is possible to improve the ballistic performance of the bulletproof product as well as to increase the sewing efficiency. Specifically, it is preferable to form the bark strength in the range of 60 to 200 kgf / inch. That is, when the bark strength is less than 60 kgf / inch may be less impact diffusion effect, if the bark strength is greater than 200 kgf / inch may be less sewing efficiency.

Factors that may influence the strength of the bulletproof products include sewing stitches and the material of the sewing thread. Therefore, in order to optimize the bark strength within the above range, the number of sewing stitches should be optimized and the sewing material should be appropriately selected.

With regard to sewing stitches, it is preferable that the sewing thread is sewn at 20 to 60 stitches / cm. If the number of stitches is less than 20 stitches / cm, the stitching strength may drop below 60 kgf / inch, and if the stitches are greater than 60 stitches / cm, the stitching strength may exceed 200 kgf / inch. In addition, when the number of stitches is greater than 60 stitches / cm, not only the sewing process is easy but also the manufacturing cost may be increased.

With regard to the material of the sewing thread, it must have a certain strength and have a predetermined elongation characteristic so as not to break upon impact of the bullet. Conventionally, only the ease of the sewing process is considered without considering such characteristics, but in consideration of the ease of the sewing process and the strength and elongation properties, it is preferable to use a nylon or polyester sewing thread.

Referring to the manufacturing method of the antiballistic product according to the present invention as described above, the antiballistic product according to the present invention is a process for preparing a multifilament, a process of weaving the fabric by the warp and weft of the multifilament, and a plurality of the fabric After the dog is aligned, it is manufactured through a process of sewing with a sewing thread.

In the step of preparing the multifilament, an aromatic polyamide polymer is prepared by polymerizing an aromatic diamine and an aromatic dieside chloride in a polymerization solvent, and then dissolving the aromatic polyamide polymer in a concentrated sulfuric acid solvent to prepare a spinning dope. Thereafter, the spinning dope may be spun through a spinneret, and then, the spinning material may be solidified to produce a wholly aromatic polyamide multifilament.

The wholly aromatic polyamide multifilament is composed of a monofilament having a fineness in the range of 0.7 to 1.6 denier, and the tensile strength is 22g / d or more is advantageous as described above.

In the process of weaving the fabric, the multifilament may be woven into a plain or a basket with a warp density and a weft density of 5 to 15 bones / cm, respectively. The tensile strength of the fabric is in the range of 5,000 ~ 10,000N / 5cm is preferable for improving the ballistic resistance as described above.

After weaving the fabric, a scouring treatment process and a water repellent treatment process may be performed on the fabric.

The refining process is a process of removing the oil or foreign matter adhering to the wholly aromatic polyamide multifilament constituting the fabric, if the water repellent treatment process is performed without performing such a refining process is not smoothly made It is also possible to reduce the flexibility of the fabric.

The refining process may be carried out using a surfactant such as NaOH or Na ₂ CO ₃ at 40 ℃-100 ℃, after the surfactant treatment is followed by a washing step and a drying step.

The water-repellent treatment process is a process to prevent the fabric from absorbing moisture, the wholly aromatic polyamide multifilament constituting the fabric is generally a problem that the long-term absorption of water is deteriorated in physical properties and eventually the ballistic characteristics of the fabric is gradually reduced As it occurs, water repellent treatment is performed on the fabric to prevent deterioration of ballistic resistance due to water absorption.

As described above, the water repellent treatment process may be performed by completely removing foreign matters adhered to the surface of the fabric through a refining process, and then immersing the fabric in a fluorine-based or silicone-based water repellent composition and drying the same.

After the water repellent treatment process can be carried out a heat treatment process on the fabric. The heat treatment process may be performed at 120-200 ° C. for about 15-150 seconds. At this time, if the heat treatment temperature is less than 120 ° C. or the heat treatment time is less than 15 seconds, the adhesion of the water repellent may be lowered. Exceeding 150 seconds can damage the fabric and reduce water repellency.

The process of sewing the fabric is such that the suture strength of the bulletproof product finally obtained by applying the sewing thread and the number of stitching as described above is in the range of 60 ~ 200 kgf / inch. When sewing the fabric under such conditions, the sewing efficiency is more than 90%.

The bulletproof product according to the present invention manufactured by the above method has a grade of 3A V0 of 436 m / s or more when testing bullets of 44 Magnum, which is a standard of NIJ (National Institute of Justice) standard when 30 to 35 sheets of bulletproof fabrics are laminated. Becomes The antiballistic product according to the present invention may be applied to a body armor, a bulletproof helmet, a bulletproof board, or the like, and further processing may be performed according to each product.

2. Examples and Comparative Examples

Example 1

Para-phenylenediamine, which is an aromatic diamine, and terephthaloyl dichloride, which is an aromatic dieside chloride, are polymerized in a polymerization solvent in which CaCl ₂ is added to N-methyl-2-pyrrolidone (NMP) to give poly (paraphenylene terephthalate). Amide) polymer was prepared, and then the polymer was dissolved in concentrated sulfuric acid solvent to prepare a spinning dope, the spinning dope was spun through a spinneret, and then the coagulum was solidified in a coagulation bath through an air gap to obtain 1.0 denier of mono. A totally aromatic multifilament of 1000 filaments consisting of 1000 filaments was obtained and then dried.

Thereafter, the wholly aromatic multifilament was woven into a plain weave with a warp density and a weft density of 10 bones / cm, respectively, to prepare a bulletproof fabric.

Thereafter, two prepared bulletproof fabrics were prepared and sewn at 30 stitches / cm using nylon as a sewing thread to obtain a bulletproof product.

Example 2

In Example 1 described above, a ballistic fabric was manufactured by the same method as Example 1, except that 50 stitches / cm were sewn.

Comparative Example 1

In Example 1 described above, a ballistic fabric was manufactured by the same method as Example 1, except that sewing at 18 stitches / cm.

Comparative Example 2

In Comparative Example 1 described above, a bulletproof fabric was produced in the same manner as in Example 1, except that sewing was performed at 64 stitches / cm.

Table 1 summarizes the process conditions for the production of bulletproof fabrics according to the above Examples and Comparative Examples.

division Sewing thread Sewing stitches (stitches / cm) Example 1 nylon 30 Example 2 nylon 50 Comparative Example 1 nylon 18 Comparative Example 2 nylon 64

3. Experimental Example

Bark Strength Measurement

After preparing a sample with a bulletproof fabric prepared according to the Examples and Comparative Examples, the bark strength was measured by the ASTM D 1683 method. The results are shown in Table 2 below.

division Bark Strength Example 1 85.7 Example 2 187.5 Comparative Example 1 54.2 Comparative Example 2 208.7

Bulletproof performance measurement

After cutting the bulletproof fabrics prepared according to the above Examples and Comparative Examples in 38cm x 38cm to prepare 34 ply layers, samples were prepared according to the NIJ (National Institute of Justice) standard. The bullet used in the bulletproof test was 44 magnums. The results are shown in Table 3 below. In the table below, V0 is the maximum velocity at which the bullet does not pass the target.

division Bulletproof performance V0 (m / s) Example 1 440 Example 2 441 Comparative Example 1 429 Comparative Example 2 448

Sewing efficiency measurement

Sewing efficiency was measured when sewing the bulletproof fabric according to the above Examples and Comparative Examples. The sewing efficiency is a value in which the sewing machine lasts for a certain time without stopping once and the predetermined distance is calculated as 100%, and the sewing distance for the predetermined time when the sewing is stopped in%. That is, the sewing efficiency is calculated as [actually sewn distance / theoretically sewn distance] × 100 when sewing for a certain time. The calculated values are shown in Table 4 below.

division Sewing efficiency (%) Example 1 94 Example 2 92 Comparative Example 1 96 Comparative Example 2 80

As can be seen from Tables 2, 3 and 4, in the case of Comparative Example 2, the 3A grade V0, which is the NIJ (National Institute of Justice) standard, satisfies 436m / s or more, but the sewing stitches are too high to increase sewing efficiency. The results were very low, and in Comparative Example 1, there is no problem in sewing efficiency, but the bark strength is low, and it can be seen that 3A grade V0, which is a National Institute of Justice (NIJ) standard, does not satisfy more than 436 m / s.

Claims (6)

Ballistic product characterized in that a plurality of fabrics of warp and weft yarn made of multifilament is sewn by a predetermined sewing thread, the bark strength is in the range of 60 ~ 200 kgf / inch. The method of claim 1, The sewing thread is bulletproof product, characterized in that sewn at 20 to 60 stitches / cm. The method of claim 1, The sewing thread is ballistic product, characterized in that made of nylon or polyester material. The method of claim 1, The multifilament is ballistic product, characterized in that consisting of a wholly aromatic polyamide multifilament. The method of claim 1, Bulletproof products characterized in that 3A grade V0 is 436m / s or more when the bullet test of 44 Magnum, which is the NIJ (National Institute of Justice) standard when laminating 30 to 35 sheets of the fabric. The method of claim 1, The fabric is ballistic product, characterized in that the sewing efficiency is more than 90%.