RU9520U1 - FLEXIBLE PACKAGE ARMOR - Google Patents

Abstract

1. Flexible package armor, consisting of sequentially arranged layers of fabric based on high modulus fibers, characterized in that the layers of homogeneous fabrics are combined into packages, while fabrics of different packages differ in a variable number of weaves per unit length of weft and warp, and the average package consists of fabric with the least amount of these weaves. 2. Armor according to claim 1, characterized in that all the packages making up the armor are arbitrarily connected by piercing threads. Armor according to claim 1, characterized in that the packages making up the armor, with the exception of the outer one, are arbitrarily connected by piercing threads. Armor according to claim 1, or 2, or 3, characterized in that it is provided with a layer of easily deformed porous material located in its middle part. The armor according to claims 1 to 4, characterized in that it is provided with layers of a polymer composite or a polymer film placed on its back side.

Description

Description of utility model.

FLEXIBLE PACKAGE ARMOR

The utility model relates to the field of individual protection of a person from bullets of small arms, including high-speed bullets of small caliber, namely, protective vests.

Known layered flexible armor (App. For utility model No. 2864 announced July 15, 1995). It contains sequentially arranged fabric layers based on high-modulus fibers, having layers varying in thickness and the number of weaves per unit length of weft and warp threads, connected by firmware along grid lines with a cell measuring no more than 40 mm. This armor solves the problem of impenetrability with blunt-pointed bullets having initial speeds of up to 400 m / s. The disadvantage of this type of armor is the lack of resistance to bullets moving at speeds above 400 m / s and fragments of damage.

The proposed flexible package armor depicted in figure 1, consists of sequentially located packages consisting of high modulus fabric. The outer bag 1, facing the projectile, is made of layers of high-strength fabric with a large number of weaves per unit length of weft and warp, for example, plain weave fabric, and the next medium packet 2 is made of layers of high-strength fabric with a small number of weaves of threads per unit lengths of weft and warp, for example twill and / or satin weave.

The back package 3 consists of several layers of high-strength fabric with a large number of weaves of warp and weft threads per unit length, for example, plain weaving. The inner package 2 and the rear package 3 are randomly connected with the firmware threads 6.

Improving the ballistic properties of the above-described armor is possible with additional firmware 6 of outer package 1 (FIG. 2), stitching in the middle layers of the armor a layer of easily deformable porous material 4 (FIG. 3), installing layers of a polymer composite 5 or polymer on the back of the armor film 7 (Figure 4).

Obviously, the outer fabric layers 1 with a high density of weaves actively absorb bullet energy during penetration, and the less dense underlying fabric layers 2 inhibit its movement due to the high possible deformation before destruction, this provides the effect of increasing the cross section of the moving projectile by winding the threads on the bullet and layers of fabric. The specified effect increases the bulletproof design. The increase in bullet resistance is additionally facilitated by the presence of the firmware of the outer package 1, and the presence of an average package of easily deformable porous material 4. The easily deformable material 4 can be placed both between packages with

a different number of weaves per unit of weft and warp, and inside one of the packages (Fig.Z). The overall increase in the thickness of the package leads to a smoother braking of the bullets, and, as a consequence, to lower loads at the point of impact and increase the bulletproof armor. Bullets with low residual energies are finally caught by an inner pack of fabrics with an increased number of weaves per unit length of weft and warp 3, due to increased internal friction between the threads. This helps to reduce the deflection in places of impact. Strengthening the back of the armor by placing layers of polymer composites 5 or films 7, more evenly distributing energy from the point of impact.

The action of the proposed flexible package reservation is as follows:

1) a bullet falling into the layers of the outer bag 1 and punching them loses a significant part of its energy due to the high density of the weave that prevents the thread from sliding apart, the additional connection of the layers of fabric of the outer bag with piercing threads 6 enhances this process;

2) a bullet with a reduced speed penetrating into the middle package of armor 2 cannot penetrate it due to a different fabric structure, namely with a smaller number of weaves per unit length of weft and warp, allowing the fabric to withstand large deformations before rupture, in the case of the use of additionally easily deformed porous layer 4, this effect is enhanced;

3) a bullet with an enlarged cross-section, formed due to the non-penetrated layers of the middle packet 2, hits the inner packet 3 intensively inhibiting the bullet due to the dense interweaving of warp and weft threads, and due to the possible placement of layers of a polymer composite 5 or polymer films 7.

The proposed armor resists high-speed bullets of TT, PMM pistols and peaked small-caliber bullets of the PSM pistol, with less contingent injury than known types of flexible armor based on fabrics.

Claims (5)

1. Flexible package armor, consisting of sequentially arranged layers of fabric based on high modulus fibers, characterized in that the layers of homogeneous fabrics are combined into packages, while fabrics of different packages differ in a variable number of weaves per unit length of weft and warp, and the average package consists of fabric with the least amount of these weaves.  2. Armor according to claim 1, characterized in that all the packages making up the armor are arbitrarily connected by piercing threads.  3. Armor according to claim 1, characterized in that the packages making up the armor, with the exception of the outer one, are arbitrarily connected by piercing threads.  4. Armor according to claim 1, or 2, or 3, characterized in that it is provided with a layer of easily deformed porous material located in its middle part. 5. Armor according to claims 1 to 4, characterized in that it is provided with layers of a polymer composite or a polymer film placed on its back side.