KR20110090444A - The bullet-proof material of multilayer structure continued seamlessly and a method to manufacture the said material and protective clothing with the said material - Google Patents

Abstract

PURPOSE: A bulletproof material of a multilayer structure continued seamlessly, a manufacturing method thereof and a bulletproof jacket are provided to remove the external shock energy of bulletproof fabrics or laminated materials through the energy absorbing mechanism like as a yarn pullout, a fiber plastic deformation, and a fiber fracture. CONSTITUTION: A manufacturing method of bulletproof material(100) of a multilayer structure continued seamlessly comprises the following steps. The materials for the bulletproof or laminated materials are lapping many times. The seamless multilayer is formed. Accordingly, the elimination amount of the pulling of the yarn and the shock energy disappearing the plastic deformation and burst of the fiber is increased.

Description

{The bullet-proof material of multilayer structure continued seamlessly and a method to manufacture the said material and protective clothing with the said material}

The present invention wraps a bulletproof fabric or laminate several times so as to have a seamless multilayer structure, so that the impact absorption length of the fiber or yarn absorbing and extinguishing the impact energy from the outside becomes significantly longer than the bulletproof material of the conventional configuration. The present invention relates to a chain-shaped multilayered antiballistic material made, a method of manufacturing the same, and a body armor.

In addition, the present invention forms a restraint portion at regular intervals along the longitudinal direction of the chain-shaped multilayer anti-ballistic material to induce the impact energy to propagate only in the wrapping direction, thereby increasing the impact absorption length of the fiber or yarn It can be extinguished through, and at the same time, the relative movement between each layer overlapping each other is suppressed.

The laminate type bulletproof material of the conventional configuration is a multilayer structure in which a bulletproof fabric made of high strength aramid fibers is cut to a certain size to make a large number of scraps, and then piled up as many scraps as necessary, and the number of scraps is increased. It has been recognized by those skilled in the art as the only way to improve the performance.

In general, the combatability of a combatant wearing a body armor increases the better the bulletproof performance of the body armor, while the heavier the body armor, the more the body's mobility (mobility) is impaired, making it difficult to avoid enemy attacks.

From this point of view, the body armor made of the laminate type bulletproof material of the conventional configuration has a better ballistic performance, the heavier the weight, which hinders the combatant's activity, there is room for improvement.

The present invention can be applied not only to military and civilian body armor that requires weight reduction, but also to safety suits of mine removal and explosives removal groups that require protection from debris, and are more suitable than the conventional bulletproof materials and body armor. The same anti-ballistic performance can be exhibited even if used less, thereby reducing the manufacturing cost of the bulletproof material or the body armor, and in particular, the weight of the body armor which is most problematic for the combatant can be reduced, thereby increasing the survival of the combatant. An object of the present invention is to provide a bulletproof material, a manufacturing method thereof, and a body armor.

The chain-shaped multilayered antiballistic material according to the present invention, which can solve the above problems, is characterized in that it is formed into a seamless multi-layer structure by wrapping (wrapping) a bulletproof fabric or a bulletproof laminate.

Here, aramid-based kevlar or stabond, polyethylene-based dyneema may be used as the material for the bulletproof fabric or the laminate, and other glass fibers or carbon fibers may be used.

In addition, the chain-shaped multilayer antiballistic material according to the present invention is preferably characterized in that a restricting portion is further formed at regular intervals so that relative movement of each layer due to an impact from the outside is suppressed.

In addition, the body armor according to the present invention is characterized in that the chain-shaped multilayered body antiballistic material having the above-described configuration is inserted into the body armor that constitutes the body armor of the conventional configuration, instead of the laminate type ballistic material of the conventional configuration. It is preferable to limit the height (ie, thickness) of the chain-shaped multilayered bulletproof material inserted into the bulletproof shell to 30 to 800 mm, and to limit the constant distance between the restraints to 10 to 500 mm. Corresponds to the numerical range of the laminate type bulletproof material used in the present invention.

The restraint can be formed by stitching, bonding or clamping.

From previous studies, the external impact energy applied to bulletproof fabrics or laminates is absorbed through energy absorption mechanisms such as yarn pullout, fiber plastic deformation, and fiber fracture. It is known to vanish.

In this respect, the chain-shaped multilayered antiballistic material according to the present invention is bulletproof until the required number of layers is achieved without cutting pieces of bulletproof fabrics or laminates provided in very large sizes into very small scrap forms. Since the fabric or laminate is wrapped in a compressed or folded manner, the length (impact absorption length) of the yarn or fiber is significantly longer than that of the laminate type ballistic material of the conventional construction. That is, in the chain-shaped multilayer antiballistic material of the present invention, the impact absorption length of yarn or fiber that absorbs impact energy is increased so as to be incomparable with the antiballistic material of the conventional configuration. Accordingly, the body armor made of the chain-shaped multilayered body bulletproof material of the present invention is superior in bulletproof performance compared to the body armor made of the conventional laminate type ballistic material.

Further, the restraint portion formed along the longitudinal direction of the chain-shaped multilayered ballistic material of the present invention induces the impact energy applied by the bullet or the like to propagate in the wrapping direction of the ballistic fabric, so that more impact energy is generated by the fibers or the like. It can be extinguished through the shock absorption length of the yarn, and the relative movement of each layer is suppressed so that the overlapping layers do not move.

In addition, the chain-layered multi-layer bulletproof material and body armor of the present invention, because the same ballistic performance can be exhibited even if the material is used less than the conventional ballistic material or body armor, the cost saving effect, the weight of the body armor which is most problematic for combatants Can be reduced to increase the survival of combatants.

1 (a) to (c) is an exemplary view showing various lapping methods of the chain-shaped multilayered anti-ballistic material according to the present invention.
2 is a photograph showing a preferred embodiment of a chain-shaped multilayered antiballistic material according to the present invention.
FIG. 3 is a graph showing results obtained when shooting with fragments of 540 m / s in order to compare the ballistic performance of a chain-shaped multilayered ballistic material according to the present invention and a laminate type ballistic material having a conventional configuration. Iii), the vertical axis is a graph showing the amount of speed change (speed difference) before and after the debris passes through the specimen.

EMBODIMENT OF THE INVENTION Hereinafter, with reference to drawings, the chain-shaped multilayered antiballistic material according to this invention, its manufacturing method, and a body armor are demonstrated. As used herein, the term " multilayer structure continued seamlessly " is used to continuously fold one piece of bulletproof fabric or laminate in one direction, or to zigzag and fold it once, It is defined as having the structure of the ballistic-proof material according to the present invention by winding after pressing and winding and then pressing, or after pressing several times and pressing at once, or by appropriately combining these methods.

First, as shown in (a) to (c) of FIG. 1, the chain-shaped multilayer antiballistic material 100 according to the present invention may be manufactured through various lapping methods. For example, as shown in (a) of FIG. 1, one end portion of the bulletproof fabric is folded by a predetermined width and then compressed, and then wrapped once by wrapping it around the sheet, and then wrapping the sheet by pressing it. As shown in Fig. 1, the two ends of the bulletproof fabric are folded in half, and the ends of the bulletproof fabric folded in half are wrapped in such a manner as to be folded in half, or as shown in FIG. As described above, the bulletproof fabric may be folded in half to form a centerline in the center, and then wrapped in a manner in which both ends of the bulletproof fabric are folded several times in accordance with the centerline. By the alternative method, of course, it can be wrapped until the desired ballistic-proof material is completed.

FIG. 2 illustrates, for example, a 35-ply chain-layer multilayer antiballistic material 100 formed by lapping as shown in FIG. 1 (a). An example in which the restricting portion 200 is formed every 15 cm in the longitudinal direction is shown. It is shown. The restraint part 200 was formed by stitching.

FIG. 3 is a graph showing results obtained when shooting with fragments of 540 m / s in order to compare the ballistic performance of a chain-shaped multilayered ballistic material according to the present invention and a laminate type ballistic material having a conventional configuration. Iii), and the vertical axis represents the amount of speed change (speed difference) before and after the debris passes through the specimen.

As can be seen from this graph, the 35-ply chain-layer multilayer ballistic material 100 shown in FIG. 2 has a speed change of about 520 m / s for 540 m / s fragmented coal, whereas a 34-ply ballistic material according to the conventional configuration The speed change was about 220m / s, and the 36-ply speed change was about 270m / s. Thus, even though the number of layers of the ballistic material used in the experiment is almost similar, about 2 times the difference in the rate of change, the reason is that the yarn or fiber in the chain-shaped multilayered ballistic material 100 according to the present invention than the ballistic material of the conventional configuration This is because the length of the is much longer, and the magnitude of energy dissipated due to the drawing of the yarn is larger for the present invention.

100 ... Multilayer Multilayer Bulletproof Material
200 ...

Claims (4)

To increase the impact absorption length of the yarn or fiber absorbing the impact energy so that the amount of impact energy lost through the drawing of the yarn and the plastic deformation and rupture of the fiber increases, A method for producing a chain-shaped multilayered antiballistic material, characterized by lapping to form a seamless multilayered structure. Chain-shaped multi-layer bulletproof material (100) produced according to the manufacturing method of claim 1. The method of claim 2,
A chain-shaped multilayer antiballistic material (100) characterized in that a restraint portion (200) is formed at regular intervals so that relative movement of each layer due to an impact from the outside is suppressed. A body armor made of the chain-shaped multilayered antiballistic material according to claim 3 (100).

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