NL1014345C2 - Ballistic vest. - Google Patents

Abstract

The invention relates to a ballistic vest containing a stack of flexible fabrics and a stack of flexible unidirectional layers, in which the fabrics contain strong fibres of a first kind, the unidirectional layers contain strong fibres of a second kind, and in which the fibres in a unidirectional layer run essentially parallel and are disposed at an angle to fibres in an adjacent layer which is greater than 0 degrees, where in that the flexible fabric is a loose fabric and is located on the strike side of the vest. The percentages by weight of the loose fabrics and the stack of UD layers preferably is between 15:85 and 30:70 %. In that case, a vest of areal density less than 6 kg/m<2> can have such ballistic resistance as to stop an Action 3 bullet with a velocity of up to 437 m/s with a trauma to NIJ Standard of less than 44 mm.

Description

BALLISTIC CARDIGAN

5

The invention relates to a ballistic vest comprising a stack of flexible fabrics and a stack of flexible unidirectional layers, in which the fabrics contain strong fibers of a first kind, the unidirectional layers of strong fibers of a second kind, and in which the fibers in a unidirectional layer run mainly parallel and make an angle with fibers in an adjacent layer that is greater than 0 degrees. The invention particularly relates to vests which offer protection against hollow-point bullets.

Changing threats in the form of new types of bullets require constant changes in the concepts for bulletproof clothing. For example, it has been found that none of the existing vest concepts offers protection against the new Action 3 bullets used by the Dutch police, which have the property of sticking in the body due to their hollow point. Protection against this type of bullet requires a weight of the vest, which is so high that the vest can no longer be comfortably worn.

Vests against various threats are known. For example, US 5,926,842 discloses a ballistic vest consisting of a stack of flexible fabric layers with a flat bond and a stack of flexible unidirectional layers, hereinafter referred to as UD layers, in which the fibers mainly run parallel and with the fibers in an adjacent layer make an angle of 90 degrees. Such a stack of at least 1 3 O * i? 1U i 1 d Ί b - 2 - at least two mutually perpendicular UD layers is referred to herein as a UD crossply. US 5,926,842 teaches that the UD crossplies are preferably located on the side of the vest. Such a vest provides, for example, protection against threats as specified in the NIJ2 and NIJ2a standard at a surface weight of approx. 4.9 kg / m2.

To gain protection against Action 3 bullets, various concepts from US 5,926,842 10 were tested. For example, it has been found that fabric, whether or not in combination with high-strength polyethylene fibers in a UD-crossply composition for a vest according to the compositions of US 5,926,842, only protects against Action 3 bullets at a speed of 430 m / s if the surface weight of the vest is at least 6.5 kg / m2. Such a high surface weight considerably reduces the wearing comfort of the vest.

The object of the invention is to provide a vest, with a lower surface weight, which offers protection against Action 3 bullets.

This object is achieved according to the invention in that the flexible fabric is a loose fabric and is located on one side of the vest. Hereby it is achieved that a vest according to the invention provides protection against Action 3 bullets, with a surface weight of less than 6 kg / m2.

Loose fabric is here and hereafter understood to mean a fabric in which the yarns slide easily relative to each other. Such fabric 30 is also deformable. Surprisingly, it appeared that a vest with a loose fabric on the side of the vest against Action 3 offers more protection. The vest according to the invention with a lower surface weight can also offer the same protection as a vest in which no loose tissue is present on the target side.

An advantage of the vest according to the invention is that it is more comfortable to wear thanks to the lower weight.

The ballistic resistance of a vest can be classified according to different standards.

One of those standards is the NIJ Standard 0101.03, which defines 10 different levels of protection. For example, a vest according to the NIJ2a standard must stop a .357 Magnum JSP at a speed of 381 m / s and also a 9 mm FMJ at a speed of 332 m / s.

15 A vest according to the NIJ3a standard must stop a .44 Magnum SWC at 426 m / s and a 9 mm FMJ at 426 m / s. In addition to not penetrating through a projectile, the degree to which the body side deforms behind an impact is a second requirement according to 20 NIJ Standard 0101.03. This deformation measures the trauma experienced by the wearer of a vest after the impact of a projectile. An advantage of the vest according to the invention is that, despite the lighter weight, the deformation on a body side of the vest falls within the requirement set by the NIJ Standard 0101.03.

Loose fabrics can be, for example, fabrics with twill weaves, wafer weaves, cord weaves or three-dimensional weaves. It is important here that the fabric is a drapable fabric. Drapable fabrics are generally fabric in which the number of flotations is at least 3, i.e. the fabric contains yarns which cross at least 3 other yarns at the same time.

Also, the fibers in the loose fabrics are preferably substantially stretched. Non-wovens did not contribute to the stopping of Action 3 bullets.

Preferably the loose fabric contains a twill weave.

Twill weave fabrics are fabrics in which the warp and weft do not intersect in a 1: 1 ratio as in a plain weave fabric, but in a 1: 1 ratio.

For example, in a fabric with a 4.1 twill weave, the weft crosses 4 warp yarns on one side of the fabric, 1 warp yarn on the other side of the fabric and so on. The number of flotations in such a fabric is 4. Preferably, the fabric according to the invention has a 5.1 twill weave. This gave the highest protection against Action 3 bullets at the lowest weight of a vest.

The stack of UD layers can consist of one or 20 multiple UD packages. Preferably, the stack of UD layers consists of multiple UD packages, each of which contains two or four UD layers. The packages are preferably provided with a smooth film on both sides, which reduces friction between the packages, and the stack 25 gains flexibility.

By "fibers" is here meant stretched objects, the length of which is much greater than the width and thickness. Fibers include continuous mono and multifilaments, as well as discontinuous filaments, such as staple or cut fibers.

In general, the weight percentages of the pile of loose fabrics and the pile of UD layers in the vest can be between 10:80 and 101431ύ - 5 - 50: 50% · With weight percentages of less than 10% of loose fabrics, a disproportionate amount of UD layers should be be added to the vest, losing the benefit of the lower weight. At weight percentages above 50% loose fabrics, additional layers of twill weave contribute less than proportionally to protection against Action 3, thereby also losing the benefit of the lower weight.

Preferably, the weight percentages of the loose fabric stack and the stack of UD layers are between 15:85 and 30:70%.

Hereby it is achieved that such a vest according to the invention with a first and second stack, which together have a surface weight of less than 6 kg / m2, has a ballistic resistance whereby an Action 3 bullet is stopped at a speed of up to 437 m / s. a trauma according to NIJ Standard of less than 44 mm.

Hereby it is also achieved that such a vest according to the invention, in which the first and second stack together have a surface weight of less than 5.2 kg / m2, has a ballistic resistance such that the vest complies with the standard NIJ3a.

This also achieves that such a vest according to the invention with a first and second stack, which together have a surface weight of less than 4.5 kg / m2, has a ballistic resistance, whereby an Action 3 bullet with a speed of up to 385 m / s is stopped with trauma according to NIJ 30 Standard of less than 44 mm.

"Strong fibers" of a first or a second type can be of different or similar type and in this invention are generally fibers 10-Si-6 - having a strength of at least 6 dN / tex, a modulus of at least 130 dN / tex and a fracture energy of at least 8 J / g. Preferred are strong fibers, fibers with a strength of at least 10 dN / tex, a modulus of at least 200 dN / tex and a breaking energy of at least 20 J / g. More preferred are fibers with a strength of at least 16 dN / tex, a modulus of at least 400 dN / tex and a breaking energy of at least 27 J / g. Most preferred are fibers with a strength of at least 28 dN / tex, a modulus of at least 1200 dN / tex and a breaking energy of at least 40 J / g. If the fibers of the first kind do not have the same strength as the fibers of the second kind, it is recommended that the fibers of the first kind be stronger than the fibers of the second kind.

Suitable strong fibers are fibers of aramid, polybenzazole (PBO), silicon carbide, and / or a stretched polymer, such as, for example, stretched ultra-high molecular weight polyethylene (HPPE), and / or combinations thereof. Ultra high molecular polyethylene is understood to mean polyethylene having a weight average molecular weight of at least 500,000 kg / kmol.

Preferably, the molecular weight is more than 2,000,000 kg / kmol. The vest according to the invention preferably has a stack of UD layers, in which the UD layers mainly contain aramid or PBO fibers. This achieves that a vest in which the first and second stack together have a surface weight of less than 4 kg / m2 has a ballistic resistance such that an Action 3 bullet is stopped with a speed of up to 385 m / s with trauma according to NIJ Standard of less than 44 mm.

i 014 3 '1 ij - 7 -

An advantage of the vest according to the invention is that more protection is provided against certain types of ammunition, including the Action 3 bullet, with a construction in which unidirectional layers 5 are replaced by loose fabrics. Since loose fabrics are much easier to produce, the production costs of a vest according to the invention are lower than that of the known vests consisting exclusively of UD layers.

Ballistic fabrics as used in known cardigans are mainly tightly woven solid fabrics, often with a yarn having the lowest possible titer. Both the manufacture of yarns and the fabrication of fabrics therefrom are much more expensive than making UD crossply.

No special requirements are imposed on the titer of the loose fabric yarns. Preferably, however, the vest according to the invention contains a fabric package, in which the fabric mainly consists of yarns with a titer of at least 1000 dTex. This gives better results than with yarn fabric packages with a titer less than 100% Tex. An additional advantage of yarns with a higher titer is that both the yarns and the fabric formed therefrom are cheaper to produce than yarns with a lower titer.

The invention will be elucidated by means of a few examples.

The surface density (AD) of a fabric or UD layer or package is understood to mean the weight of fabric or UD layer per unit area.

UD-SB2 is a package of four interlaced layers in which the fibers in each layer are substantially parallel 1014343 - 8 - perpendicular to the fibers in an adjacent layer, and each layer is made from 1760 dTex HPPE yarns (Dyneema SK76) layer is 26 g / m2. The UD-SB2 package contains a 5 rubber matrix and is covered on both sides with a PE foil. A UD-SB2 package has an AD of 155 g / m2.

UD-SB21 is a package of four interlaced layers in which the fibers in each layer are nearly parallel perpendicular to the fibers in an adjacent layer, and each layer is made of 1760 dTex HPPE yarns (Dyneema SK76) The yarn weight per layer is 26 g / m2. The UD-SB21 package contains a rubber matrix and is covered on both sides with a PE foil. A UD-SB21 package has an AD of 145 g / m2.

15 Goldflex is a 4-layer crossply UD based on 1100 dTex aramid yarns with an AD of 233 g / m2.

W557 is a 5.1 twill weave fabric, warp and weft consisting of a 1760 dTex HPPE yarn (Dyneema SK75). The surface density of a fabric layer is 270 g / m2. The fabric is loose and easy to drape.

Aramid fabric is a non-deformable fabric with a flat bond based on 930 dTex 25 aramid yarn (Twaron CT) with an AD of 200 g / m2.

Twaron VD0461 is a solid, non-deformable fabric based on a 3360 dTex aramid yarn with a surface weight of 475 g / m2.

Fraglight is a nonwoven based on HPPE 30 staple fiber of more than 880 dTex with an AD of 205 g / m2.

In all examples and comparative experiments, the tissue on the target side of a

Ί »0 i i *" "- U

11/1 1 ^ i - 9 - package with fabric and UD installed unless expressly stated otherwise.

Example I

Vests of a stack of 29 packages of UD-SB2 and 5 layers of W557 with a total surface density of 5.85 kg / m2 were bombarded with an Action 3 (A3) bullet at 440, 432, 433, 430 and 437 m / s.

No overshoot was obtained. This finding is very surprising because the fabric in question is a fairly coarse fabric made from 1760 dTex Dyneema SK76 yarn. The development of progressively better ballistic fabrics has hitherto led to the use of progressively finer fabrics with, moreover, an increasingly lower surface weight per layer.

Example II

A vest of a stack of 20 packages of UD-SB2 and 4 layers of W557 was bombarded with an A3 bullet 20 at 385 m / sec. No overshoots were found in the vest, with an AD of 4.2 kg / m2. Compared to the vest mentioned under Example I, which stops A3 at 430 m / sec, this vest is 385 m / sec lighter than should be expected on the basis of the energy absorption in the vest with an AD 25 of 5.85 kg / m2. turn into.

Example III

A vest of a stack of 12 packages of aramid crossply-UD (Goldflex) and 4 layers of W557 was bombarded with an A3 bullet at 385 m / sec. No overshoots were found in the vest, with an AD of 3.9 kg / m2.

101434 Ü - 10 -

Example IV

A vest of a stack of 20 packages of UD-SB2 and 4 layers of fabric with a 3.1 twill weave from 5 1760 dTex yarns (AD per layer of 275 g / m2, AD of the vest is 4.4 kg / m2) was shot at 362 378, 416, 422, 430 and 431 m / sec.

Interleaves were found at 378 and 430 m / s. Stops were found at 362, 416, 422 and even 10 431 m / s. Due to the inconsistency (overshoot at 378 and a stop at 431 m / s), a 2nd vest with the same composition was tested, result: 1 overshoot at 431 m / s, otherwise only stops at 407, 415, 426, 431, 433 , 425 and 436 m / s. This fabric therefore also makes it possible to stop the A3 in combination with SB2, but seems less consistent in connection with the overshoot at 378 m / s.

Example V

Shooting tests were performed according to the NIJ2 standard, in which a vest from a stack of 20 packages of UD-SB2 and 4 layers of W557 was tested against the 9mm at 360 m / s and the .357 Magnum at 425 m / s. No overshoot was found in either case.

A vest of a stack of 20 packages UD-SB2 and 4 layers W557 with an AD of 4.2 kg / m2 therefore complies with the NIJ2 standard. The current recommendation for a N2 2 compliant SB2 vest is a stack of 29 packages of UD-SB2 with an AD of 4.5kg / m2.

30

Example VI

Shooting tests were performed according to the NIJ3a standard.

1014315 - 11 - a. Against 9mm: On a vest of a stack of 26 packages UD-SB2 and 4 layers W557 was fired with 9mm at 425 m / s. Then the V50 was determined. 3 stops were found at 425m / s and a V50 of 5 491m / s.

b. against .44 Magnum: On a vest of a stack of 26 packages of UD-SB2 and 4 layers W557 was fired with .44 Magnum at 425 m / s and then the V50 was determined.

10 Stops were found at 425m / s with trauma less than 44mm and a V50 of 476m / s.

Conclusion: A vest of a stack of 26 packages UD-SB2 and 4 layers W557 with an AD of 5.1 kg / m2 meets 15 standard NIJ3a for 9 mm and .44 Magnum. The current SB2 recommendation for achieving this standard is a vest with a stack of UD-SB2 packs of 5.3 kg / m2.

Example VII

20 Testing protection against Ranger SXT

+ P + ammunition. Like the Action 3, this is a Jacketed Hollow Point bullet.

A vest of a stack of 20 packages of UD-SB2 and 4 layers of W557 (4.2 kg.m2 AD) was tested against the Ranger SXT 9mm bullet at 425 m / s.

Stops were found at 421 and 425 m / s with trauma of 33 and 35 mm, respectively.

Since the vest tested here is identical to the vest in example V and the vest in example VI contains 6 extra UD-SB2 30 packages, this means that the vests against NIJ2 and NIJ3a as in Examples V and VI also include this Ranger SXT + P + stop.

1014345 - 12 -

Example IIX

A vest of a stack of 20 packages of UD-SB2 and 4 layers of a loose, easily deformable fabric (368 g / m2) with a flat bond, in which both warp and weft were 5 parallel HPPE 1760 dTex yarns (SK 60) processed (5 flotations) was bombarded with an A3 bullet at 410 m / sec. No overshoot was found in the vest, with an AD of 4.6 kg / m2.

Example IX

A vest of a stack of 20 packages of UD-SB2 and 3 layers of a loose and easily deformable fabric (287 g / m2) with a cord binding with 3 and more flotations made of 1760 dTex HPPE (SK65) was bombarded with a A3 bullet at 410 m / sec. No overshoots were found in the vest, with an AD of 4.3 kg / m2.

20

Example X.

Vests from a stack of 20 packages of UD-SB21 and 4 layers of W557 with a total surface density of 4 kg / m2 were bombarded with FSP fragments for the determination of the V50.

A V50 of 549 m / s was found.

Example XI

Vests of a stack of 20 packages of UD-30 SB21 and 4 layers of W557 with a total surface density of 4 kg / m2 were bombarded with a 9 mm cu jacket bullet. Stops were found at 383 m / s. The depth of the trauma was 25-35 mm.

1014010 - 13 -

Example XII

Vests from a stack of 18 packages of UD-SB21 and 4 layers of W557 with a total surface density of 3.7 kg / m2 were bombarded with 5 FSP fragments for the determination of the V50.

A V50 of 523 m / s was found. This shows that the vest according to the invention has an unexpectedly high V50 against FSP fragments at this low surface weight. Therefore, the energy absorption per surface weight is exceptionally high.

Example XIII

Vests of a stack of 18 packages of UD-SB21 and 4 layers of W557 with a total surface density of 3.7 kg / m2 were bombarded with a 9 mm normal bullet. Stops were found at 382 m / s. The depth of the trauma was 29-38 mm.

Example XIV

Vests of a stack of 18 packages of UD-SB21 and 4 layers of W557 with a total surface density of 3.7 kg / m2 were bombarded with a 9 mm cu jacket bullet. Stops were found at 382 m / s. The depth of the trauma was 24-33 mm.

25

Example XV

Vests of a stack of 18 packages of UD-SB21 and 4 layers of W557 with a total surface density of 3.7 kg / m2 were bombarded with a 9 mm SXT ranger bullet. Stops were found at 375 m / s. The depth of the trauma was 26-31 mm.

1014340 - 14 -

Comparative Experiment A

Shooting tests were performed with A3 bullets and packages of different compositions.

The following results were found: 5 a) A vest of 12 layers of aramid fabric and a stack of 29 packages of UD-SB2 with an AD of 6.9 kg / m2 gives penetration at 411 m / s.

b) A vest of 20 layers of aramid fabric and a stack of 14 packs of SB2 with an AD of 6.2 kg / m2 gives 10 penetration at 442 m / s.

c) A vest of 24 layers of aramid fabric and a stack of 9 packages of UD-SB2 with an AD of 6.2 kg / m2 gives penetration at 436 m / s.

d) A vest of 28 layers of aramid fabric and a stack of 4 layers of SB2 with an AD of 6.2 kg / m2 gives penetration at 436 m / s.

e) A vest of 31 layers of aramid fabric with an AD of 6.2 kg / m2 gives penetrations around 430 m / s.

f) A vest of 18 layers of aramid fabric behind a 20 stack of 20 packages of UD-SB2 with an AD of 6.9 kg / m2) shot through at 417 m / s g) A vest of ?? layers of fraglight for a pile of ?? packages UD-SB2 with an AD of 6.5 kg / m2 gave a shot through at 421 m / s.

H) A vest of 21 packages W557 with an AD of 5.7 kg / m2 was found necessary to stop A3 at 385 m / s.

i) A vest of 51 packages of UD-SB2 with an AD of 7.9 kg / m2 proved insufficient to stop A3 bullets at a speed of 400 m / s.

J) How many aramid fabric layers were required to stop an A3 bullet at a speed of 430 m / s. It turned out that this required a stack of 31 layers with an AD of 6.5 kg / m2.

ί 014 3 4 5 - 15 -

Comparative Experiment B

Based on 20 packages of UD-SB2, it has been determined how many layers of a non-deformable aramid fabric (Twaron VD 0461) with a flat bond 5 of yarns with a titre of 3360 dTex are required to place in front of the stack of UD-SB2 packages. A3 to stop. It was found that 20 packages of UD-SB2 and 8 layers of aramid fabric with an AD of 6.8kg / ms are needed to stop A3. This is much more than the 4.2 10 kg / m2 found for the combination UD-SB2 and W557.

Comparative Experiment C

To measure a standard ballistic performance of the different materials, vests 15 of approx. 3.2 kg / m2 have been created. The V50 was determined against 9mm parabellum.

Results:

Material: layers: AD (kg / m2) V50 (m / s) 20 SB2 20 3.1 439 W557 12 3.2 <295

Twaron CT 930dtex 16 3.2 353

Twaron VD0461 7 3.3 <304 25 These results confirm the image that a loose fabric only has a lesser performance: the Dyneema W557 and the Twaron VD0461 fabric cannot even stop the 9mm bullet at approx. 300m / s. It also shows that SB2 scores better than an aramid fabric based on Twaron CT 930 dTex with a comparable surface weight.

101434S

Claims (10)

1. Ballistic vest comprising a stack of flexible fabrics and a stack of flexible unidirectional layers, in which the fabrics contain strong fibers of a first type, the unidirectional layers of strong fibers of a second type, and in which the fibers in a unidirectional layer mainly parallel and angled with fibers in an adjacent layer greater than 0 degrees, characterized in that the flexible fabric is a loose fabric and is located on a target side of the vest. 2. Vest according to claim 1, wherein the loose fabric contains at least 3 floats. Vest according to any one of claims 1 or 2, wherein the loose fabric contains a twill weave. Vest as claimed in any of the claims 1-3, wherein the weight percentages of the stack of loose fabrics 20 and the stack of UD layers lie between 15:85 and 30:70%. 5. Vest according to any one of claims 1-4, wherein the first and second stack together have a surface weight of less than 6 kg / m2 and the vest has a ballistic resistance such that an Action 3 bullet with a velocity of up to 437 m / s trauma to NIJ Standard less than 44 mm is stopped. 6. Vest according to any one of claims 1-4, wherein the first and second stack together have a surface weight of less than 4.5 kg / m2 and the vest has a ballistic resistance such that an Action 3 bullet with a speed of 10143 - 17. - up to 385 m / s is stopped with trauma according to MIJ Standard of less than 44 mm. 7. Vest as claimed in any of the claims 1-4, wherein the first and second stack together have a surface weight of less than 5.2 kg / m2 and in which the vest has a ballistic resistance such that the vest complies with the NIJ3a Standard 0101.03 . 8. Vest according to any one of claims 1-7, wherein the unidirectional layer mainly contains aramid or polybenzazole (PBO) fibers. 9. Vest according to claim 8, wherein the first and second stack together have a surface weight of less than 4 kg / m2 and the vest has a ballistic resistance such that an Action 3 bullet is stopped at a speed of up to 385 m / s with a trauma according to NIJ Standard of less than 44 mm. 10. Vest according to any one of claims 1-9, wherein the fabric is 5.1 twill fabric. i 0 1 4 vl '1 ö COOPERATION TREATY (PCI) REPORT ON NEWNESS RESEARCH OF INTERNATIONAL TYPE IDENTIFICATION OF OE NATIONAL APPLICATION Characteristic of the applicant ol of the authorized representative ____ 4110NL_ · Dutch application no. (filing date 1014345 10 February 2000) NV Date of the request for an international type study O for the International Investigation Authority (ISA) granted to the net request for an international type study No SN 34566 EN I. SUBJECT CLASSIFICATION where different classifications are applied, all Specify classification symbols) According to the International Classification ((PC) lnt.CI.7: F41H5 / 04 II. RESEARCHED FIELDS OF TECHNIQUE _ Minimum documentation examined____ Classification system Classification symbols lnt.CI.7: F41H Documentation examined other than the minimum documentation to the extent that such documents in the area studied n are included lil · l | NO RESEARCH POSSIBLE FOR CERTAIN CONCLUSIONS (comments on supplement sheet)! V- l I LACK OF UNIT OF INVENTION (comments on supplement sheet! / J ~ Farm PCT /! SA / 201 (a) 07.T979