• 专利附录
  • 专利说明
  • 权利要求
  • 类似技术
  • 同族专利
  • 引用文献
  • 法律状态
  • 优先权
    • 专利摘要:
    A flexible ballistic resistant article is disclosed that includes a plurality of fabric layers having an area density of 2 to 10 kg / m 2, in which at least two fabric layers are loosely woven. The loosely woven fabric layer comprises a fabric with a fabric density factor of 0.3 to 0.6, using continuous filament yarns having a linear density of at least 200 decitex, a toughness of at least 10 grams per decitex and a tensile modulus of at least 150 grams per decitex. Are manufactured. The loosely woven fabric layers are joined together by layer fixing means that limit the relative movement of each other.
    公开号:KR20030086622A
    申请号:KR10-2003-7013356
    申请日:2002-03-27
    公开日:2003-11-10
    发明作者:민숀 제이. 치우
    申请人:이 아이 듀폰 디 네모아 앤드 캄파니;
    IPC主号:
    专利说明:

    Ballistic Resistance Article {BALLISTIC RESISTANT ARTICLE}
    [2] There is a continuing need in the art for articles such as vests, garments and the like that are comfortable to wear and yet have improved ballistic resistance. In an effort to increase ballistic resistance of articles, the prior art has focused on increasing the strength or reducing the denier of the fibers used in these articles.
    [3] For example, WO 93/00564 discloses ballistic structures using layers of fabric from highly tough para-aramid yarns.
    [4] U. S. Patent No. 4,850, 050 discloses body armor made from p-aramid yarns each comprising filaments of low linear density. The ballistic performance of the body armor produced according to the invention has been reported to exhibit a 5% improvement over prior art fabrics.
    [5] Melliand Textilberichte, Structure and Action of Bullet-resistant Protection Vest, No. 6, pp. 463-8 (1981) discloses, for example, fabrics made of fine aramid yarns of 220 or 440 decitex, providing better ballistic protection than fabrics made of coarser yarns.
    [6] U. S. Patent No. 5,187, 003 discloses fabrics useful for ballistic protection having fibers of different warp and weft directions. In terms of fabric cover factors, it is shown that fabrics with cover factors of less than 0.6 are too loose for effective ballistic protection.
    [7] US Pat. No. 4,287,607 discloses a ballistic vest made from multiple double-woven layers of loosely woven aramid fibers with a nylon film or nylon fabric sandwiched between some layers of double-woven fabric. These double woven layers have a fabric density factor defined herein of about 0.71.
    [8] Summary of the Invention
    [9] The present invention relates to a flexible ballistic resistant article having an area density of 2 to 10 kg / m 2 and comprising a plurality of loosely woven fabric layers of two or more fabric layers. The loosely woven fabric layer comprises a fabric with a fabric density factor of 0.3 to 0.6, a continuous filament yarn with a linear density of at least 200 decitex, a toughness of at least 10 grams per decitex, and a tensile modulus of at least 150 grams per decitex. It is prepared using. The adjacent loosely woven fabric layers are joined together by layer fixing means that limit the relative movement between the loosely woven fabric layers.
    [1] The present invention relates to the field of ballistic resistant articles.
    [10] The present invention relates to a flexible ballistic resistant article. The article includes a plurality of fabric layers in which two or more fabric layers are loosely woven. Loosely woven layers are joined together to limit the relative movement of each other. Very surprisingly, this article exhibits improved ballistic resistance.
    [11] The inventors have found that the ballistic resistance of the fabric is dramatically improved when the article comprises fabric layers having yarns woven with a dense factor of less than 0.6. It is believed that if the density coefficient is as low as 0.3, it will provide improved ballistic resistance. As used herein, the term "loosely woven" means a fabric layer having yarns woven with a dense factor of about 0.3 to about 0.6 when used in the fabric layer.
    [12] Prior to the present invention, ballistic resistant fabrics were tightly woven. In an attempt completely contrary to current technical knowledge, the inventors have found that loosely woven fabrics exhibit improved ballistic resistance. All fabrics with a reduced density coefficient may show some improvement, but the most improvement was found at a density factor of less than 0.6. As the dense factor decreases, the ballistic resistance improves further until the fabric texture becomes too loose to reach a density factor of about 0.3, where an unacceptably high area density is required for effective ballistic protection.
    [13] Ballistic articles of the present invention are made using a plurality of layers of protective fabric and comprise at least two layers of loosely woven fabric. The loosely woven layers are joined together by layer fixing means that limit the relative movement of each other. This securing means can be any means commonly used to bond fabric layers together, such as sewing, stitching, adhesives and / or tapes. There is no limitation as to how to sew and / or stitch the loosely woven layers together. Stitching and / or stitching may surround the edges or traverse the layers, for example, by diagonal stitching and / or stitching or quilt-like stitching and / or stitching.
    [14] In addition, although other fabric layers can be joined together by means of fastening, it is not important to combine these layers together so that there is no relative movement between these other layers.
    [15] In the case of knife stave penetration resistant articles, in order to increase the knife stab penetration resistance of the article, the relative movement of each other is free without joining adjacent layers of the protective fabric together. The composition of ballistic articles is in contrast.
    [16] The present invention does not require a steel plate or platelet, nor does it require a matrix resin or binder to coat or impregnate the fabric material and consists only of fabric. However, such steel sheets or small plates or matrix resins or binders may be used in the articles of the present invention.
    [17] Articles of the present invention are more flexible, lighter in weight, softer to the touch, more comfortable to wear and more flexible than conventional ballistic resistant articles of the prior art.
    [18] Fabrics of the present invention comprising a loosely woven fabric layer are made, in whole or in part, from yarns whose toughness is at least 10 grams per decitex and the tensile modulus is at least 150 grams per decitex. Such yarns can be made from aramids, polyolefins, polybenzoxazoles, polybenzothiazoles, and the like, and fabrics can be made from mixtures of these yarns, if desired. For example, the fabric may include one type of yarn in the weft direction and a different type of yarn in the fill direction.
    [19] "Aramid" means a polyamide having at least 85% of amide (-CO-NH-) bonds attached directly to two aromatic rings. Suitable aramid fibers are described in Man-Made Fibers-Science and Technology, Volume 2, Section titled Fiber-Forming Aromatic Polyamides, page 297, W. Black et al., Interscience Publishers, 1968. Aramid fibers can also be found in US Pat. No. 4,172,938; 3,869,429; 3,819,587; 3,673,143; 4,076,384; 3,354,127; 3,354,127; And 3,094,511.
    [20] Additives may be used with the aramid and up to 10% by weight of other polymeric materials may be blended with the aramid or other diamine 10% substituted in place of the diamine of the aramid or other diacid chloride substituted in place of the diacid chloride of the aramid. It has been found that copolymers with% can be used.
    [21] Para-aramid is the main polymer of the aramid yarn fibers of the present invention, with poly (p-phenylene terephthalamide) (PPD-T) being the preferred para-aramid. PPD-T is a homopolymer obtained by mole-for-mole polymerization of p-phenylene diamine and terephthaloyl chloride, and a small amount of other diamine and p-phenylene diamine and a small amount of other diacid chloride and terephthal It means a copolymer obtained by incorporating monochloride. Usually, other diamines and other diacid chlorides may be used in amounts up to about 10 mole percent of p-phenylene diamine or terephthaloyl chloride, under the condition that the other diamines and diacid chlorides do not have a reactor that interferes with the polymerization reaction. It may also be used in slightly more amounts. PPD-T can also be obtained by incorporating other aromatic diamines and other aromatic diacid chlorides such as 2,6-naphthaloyl chloride or chloro- or dichloroterephthaloyl chloride or 3,4'-diaminodiphenylether. It means a copolymer. The preparation of PPD-T is described in US Pat. No. 3,869,429; No. 4,308,374; And 4,698,414.
    [22] "Polyolefin" means polyethylene or polypropylene. Polyethylenes may comprise up to about 50% by weight of alken-1-polymers, particularly low, which may contain trace chain branches or comonomers having no more than 5 modification units per 100 backbone carbon atoms One or more polymer additives, such as density polyethylene, propylene, or the like, or low molecular weight additives such as commonly incorporated antioxidants, lubricants, sunscreens, colorants, and the like, preferably having a molecular weight of at least 1 million and being primarily linear polyethylene Mean material. This is commonly known as extended chain polyethylene (ECPE). Similarly, polypropylene is a predominantly linear polypropylene material, preferably having a molecular weight greater than 1 million. High molecular weight linear polyolefin fibers are commercially available. The production of polyolefin fibers is discussed in US Pat. No. 4,457,985.
    [23] Preferably, the polybenzoxazoles and polybenzothiazoles consist of units of the following structure:
    [24]
    [25] The aromatic group shown to be bonded to the nitrogen atom may be heterocyclic, but is preferably carbocyclic; They may be fused or unfused polycyclic systems, but are preferably single six-membered rings. As the group appearing in the main chain of the bis-azole, a para-phenylene group is preferable, and this group may be substituted with any divalent organic group that does not interfere with the preparation of the polymer, or any group may not be used. For example, this group can be aliphatic, tolylene, biphenylene, bis-phenylene ether, etc. having up to 12 carbon atoms.
    [26] The polybenzoxazoles and polybenzothiazoles used to prepare the fibers of the present invention should have at least 25, preferably at least 100, mer units. The preparation of polymers and the spinning of these polymers are disclosed in WO 93/20400, supra.
    [27] "Fabric density factor" and "cover factor" are names for tissue density of fabrics. The cover factor relates to the shape of the fabric tissue and is a calculated value representing the percentage of the total surface area occupied by the yarn of the fabric in the fabric. The equation used to calculate the cover factor is as follows (see Weaving: Conversion of Yarn to Fabric, Lord and Mohamed, published by Merrow (1982), pages 141-143):
    [28] d w = warp width in fabric
    [29] d f = width of the fill yarn in the fabric
    [30] p w = warp pitch (end per unit length)
    [31] p f = pitch of fill yarn
    [32]
    [33]
    [34]
    [35] Depending on the type of fabric tissue, the maximum cover factor may be very low even if the yarns of the fabric are in close proximity to each other. For this reason, a more useful indicator of fabric tightness is the "fabric density factor". Fabric density factor is a measure of the tightness of fabric tissue compared to the maximum fabric tightness as a function of cover factor.
    [36]
    [37] For example, for plain weave the maximum cover factor is 0.75; Thus, a plain weave with an actual cover factor of 0.45 will have a fabric density factor of 0.60. Different fabric tissues such as plain weave, twill or satin weave and variants thereof can be used as the fabric of the invention. Twill and satin weaves and their variants, including crowfoot weaves, often known as four-harness satin weaves, are more flexible and flexible than plain weaves and can better adhere to complex curves and surfaces. It is preferable to the practice of the present invention since it can.
    [38] Yarns used in the present invention should have a high toughness of 10 grams or more per decitex (11.1 grams per denier) and there is no upper limit of known toughness values. At toughness values below about 5 grams per decitex, the yarn does not exhibit adequate strength to provide sufficient protection. Since too low tensile modulus can cause excessive fiber stretching and inefficiently limit the movement of the bullet, the yarn must have a tensile modulus of at least 150 g / dectex. There is no known upper limit for tensile modulus.
    [39] The single layer of fabric of the present invention provides a measure of ballistic resistance and consequently protection; However, in the case of a final ballistic resistant article, multiple layers with two or more loosely woven fabric layers are required. The two or more fabric layers are loosely woven fabric layers, and a plurality of fabric layers having a total area density of 2 to 10 kg / m 2 or more, preferably 2.5 to 8 kg / m 2, as measured by the total weight of the fabric layer per unit area In use, the present invention showed the most noticeable and surprising improvements. It has been found that when the loosely woven fabric layers of the present invention are put together, preferably in a plurality of layers, the loosely woven fabric layers are fixed to each other to limit the relative movement between adjacent layers, resulting in surprisingly effective ballistic resistance.
    [40] In addition, the constituents of the protective article of the present invention can be used with other networked ballistic layers of woven or nonwoven fibers, such as unidirectional, mono-tissue, and the like. These layers can usually be prepared from aramids, polyolefins, polybenzoxazoles, polybenzothiazoles, or other polymers used for ballistic protection. The fabric layer of the present invention may be located above or below another ballistic layer, or between two different ballistic layers. In addition, if necessary, the fabric of the present invention may be coated or impregnated with a matrix resin or binder to increase the rigidity of the fabric layer.
    [41] Test Methods
    [42] Linear density . It was measured by weighing a yarn or filament of length that knew the linear density of the yarn or filament. "Decitex" is defined as the weight in grams of a material of 10,000 meters. "Denier" is defined as the weight in grams of material of 9000 meters.
    [43] In practice, the measured decitex, test conditions and sample name of the yarn or filament sample are entered into the computer prior to the start of the test; The computer records the load-elongation curve up to failure of the sample and then calculates its properties.
    [44] Tensile properties . The yarn to be tested for tensile properties is first conditioned and then braided to have a twist factor of 1.1. Yarn's twist coefficient (TM) is defined as follows:
    [45] TM = (twist / cm) (decex) -1/2 /30.3
    [46] = (Twist / inch) (denier) -1/2 / 73
    [47] The yarn to be tested is conditioned at 25 ° C., 55% relative humidity for at least 14 hours, and a tensile test is performed under these conditions. Yarn is fracture tested using an Instron tester (Instron Engineering Corp., Canton, Mass.) To measure toughness (break toughness), fracture elongation, and tensile modulus.
    [48] Toughness, elongation and tensile modulus as defined in ASTM D2101-1985 are measured using a yarn gauge length of 25.4 cm and an elongation rate of 50% strain / minute. Tensile modulus is calculated from the slope at 1% strain of the stress-strain curve and is equal to the stress in grams at 1% strain (absolute value) multiplied by 100 and divided by the linear density of the test yarn.
    [49] Toughness, elongation and tensile modulus of each filament are measured in the same manner as yarn; However, the filaments are not twisted and use a gauge length of 2.54 cm.
    [50] Ballistic performance . The ballistic limit (V50) was measured by performing a ballistic test of a multi-layer panel according to MIL-STD-662e, except for the following choice of projectiles: A sample mounted to support a panel tensioned perpendicular to the path of the test projectile. Panels to be tested were placed facing backing material, which is Roman Plastina No. 1 clay in the interior. The projectiles are 9 mm all-metal jacketed pistols weighing 124 grains and soft point bullets of 0.357 magnum jackets weighing 158 grains, which can fire projectiles at different speeds. Propelled from the test barrel. The first shot of each panel is for projectile velocity estimated to be close to the trajectory limit V50. When the first shot had completely penetrated the panel, the next shot was conducted at a speed of less than about 15.5 meters (50 feet) per second to allow the panel to partially penetrate. On the other hand, when not penetrating or partially penetrating with the first shot, the next shot was made at a speed of more than about 15.2 meters (50 feet) per second in order to penetrate completely. After one partial penetration and one complete penetration of the projectile, the trailing speed was increased or decreased to about 15.2 meters per second (50 feet) per second until sufficient shots were made to measure the panel's trajectory limit (V50).
    [51] Only if there is a difference of less than 38.1 meters (125 feet) per second between each highest and lowest impact velocity, the ballistic limit ( V50) was calculated.
    [52] In the examples below, ballistic resistant penetration of a composite of multiple fabric layers was tested. For testing, all fabric layers were stitched around the edges, and additionally a 16 "by 16" ballistic panel was constructed with cross-stitch stitched diagonally. Several different fabrics having various dense factors made from yarns of different materials and yarns of those fabrics were tested at various fabric density factors and area densities between 5.4 and 6.2 kg / m 2.
    [53] Example 1-4 and Comparative Example 5
    [54] For these examples, a plurality of layers of woven aramid yarns were prepared. Yarn is under the trademark Kevlar®. children. Aramid Yarn, marketed by E. I. du Pont de Nemours and Company. Aramid was poly (p-phenylene terephthalamide).
    [55] In Example 1, 40 fabric layers were woven from a Kevlar® 29 of 1111 decitex® with a plain weave of 0.59, an area density of about 5.8 kg / m 2, and a 6.3 × 6.3 end per cm. In Example 2, 40 fabric layers were fabricated as in Example 1, except that it was made of crofoot with 6.7 × 6.7 ends per cm and the fabric had a fabric density factor of 0.53 and an area density of about 6.2 kg / m 2. Prepared.
    [56] In Example 3, 40 fabric layers were woven from 933 decitex Kevlar 129 with plain weave having a fabric density factor of 0.6, an area density of about 5.4 kg / m 2, and 7 × 7 ends per cm. In Example 4, 40 layers of fabrics were made as in Example 3, except that the fabric was made with crofoot having a 7.9 × 7.9 end per cm and the fabric had a fabric density factor of 0.56 and an area density of about 5.8 kg / m 2. Was prepared.
    [57] In Comparative Example 5, the fabric was prepared to have approximately the same area density as the fabric of Examples 1-4. A fabric comprising 22 densely woven fabric layers of 933 Desitex Kevlar 129 was made of plain weave with a fabric density factor of 0.93, an area density of about 5.4 kg / m 2 and 12.2 × 12.2 ends per cm.
    [58] The fabric configurations in Examples 1-4 and Comparative Example 5 are summarized in Table 1 below.
    [59] The ballistics V50 for 9 mm and 0.357 mag bullets were tested on the fabric layers in Examples 1-4 and Comparative Example 5. The ballistic test results shown in Table 2 show that the V50 results of the articles of the invention shown in Examples 1-4 were significantly better than the V50 of the articles of Comparative Example 5. In summary, compared to the article of Comparative Example 5, the article of the present invention showed an improvement of about 7.5 to 13%.
    [60] Example numberFabric compositionFabric Density FactorArea density (kg / ㎡) One40 layers, 1111 decitex yarn plain weave, 6.3 × 6.3 end / cm0.595.8 240 layers, 1111 decitex yarncroft weave, 6.7 × 6.7 end / cm0.536.2 340 layers, 933 decitex yarn plain weave, 7 × 7 end / cm0.605.4 440 layers, 933 decitex yancrofoot woven, 7.9 × 7.9 end / cm0.565.8 Comparative Example 522 layers, 933 decitex yarn plain weave, 12.2 × 12.2 end / cm0.935.4
    [61] 9 mm0.357 mag. Example numberV50% ImprovingV50% Improving One11696 ft / sec9.116527.5 2171110.116648.3 3173111.4169110.0 4174112.0173713.0 Comparative Example 51554No improvement1537No improvement
    [62] Example 6-7 and Comparative Example 8
    [63] For these examples, multiple layers of woven polybenzoxazole (PBO) yarns were prepared. Yarn is marketed by Toyobo Co., Ltd. under the trademark Zylon®.
    [64] In Example 6, 40 layers of fabric were woven from 1111 decitex® nylon with a weave density factor of 0.59, an area density of about 5.8 kg / m 2, and 6.3 × 6.3 ends per cm. In Example 7, the fabric was fabricated as in Example 6 except that the fabric was made with crofoot having a 7.5 × 7.5 end per cm and the fabric had a fabric density factor of 0.58 and an area density of about 5.9 kg / m 2. 35 layers were prepared.
    [65] In Comparative Example 8, 30 fabric layers were woven from 1111 decitex xylon® manufactured with a 0.76 density of fabric, an area density of about 5.8 kg / m 2, and made of 8.7 × 8.3 ends per cm.
    [66] The fabric configurations in Examples 6-7 and Comparative Example 8 are summarized in Table 3 below.
    [67] The fabric layers in Examples 6-7 and Comparative Example 8 were tested as above, for example 1-4 and Comparative Example 5. The ballistic test results for 9 mm and 0.357 mag bullets, shown in Table 4, showed that the V50 results of the articles of the present invention were significantly higher compared to the V50 of Comparative Example 8. In summary, compared to the article of Comparative Example 8, the article of the present invention showed an improvement of about 5.9 to 13%.
    [68] Example numberFabric compositionFabric Density FactorArea density (kg / ㎡) 640 layers, 1111 decitex yarn plain weave, 6.3 × 6.3 end / cm0.595.9 735 layers, 1111 decitex yancrofoot weave, 7.5 × 7.5 end / cm0.585.9 Comparative Example 830 layers, 1111 decitex yarn plain weave, 8.7 × 8.3 end / cm0.765.9
    [69] 9 mm0.357 mag. Example numberV50% ImprovingV50% Improving 62033 ft / sec10.520479.5 720761319815.9 Comparative Example 81839No improvement1870No improvement
    权利要求:
    Claims (12)
    [1" claim-type="Currently amended] A plurality of fabric layers, two or more of which are loosely woven, the loosely woven fabric layer having a fabric density factor of 0.3 to 0.6 and a linear density of at least 200 decitex and a toughness of at least 10 grams per decitex. And continuous filament yarns having a tensile modulus of at least 150 grams per decitex, wherein adjacent loosely woven fabric layers are joined together by layer fixing means that limit the relative movement between the loosely woven fabric layers. A flexible ballistic resistant article having an area density of 10 kg / m 2.
    [2" claim-type="Currently amended] The flexible ballistic resistant article of claim 1 having an area density of 2.5 to 8 kg / m 2.
    [3" claim-type="Currently amended] The flexible ballistic resistant article of claim 1, wherein said loosely woven fabric layer comprises a matrix resin or binder.
    [4" claim-type="Currently amended] The flexible ballistic resistant article of claim 1, wherein said loosely woven fabric layer comprises aramid yarns.
    [5" claim-type="Currently amended] 5. The flexible ballistic resistant article of claim 4 wherein said aramid yarn is a poly (p-phenylene terephthalamide) yarn.
    [6" claim-type="Currently amended] The flexible ballistic resistant article of claim 1, wherein said loosely woven fabric layer comprises polyolefin yarns.
    [7" claim-type="Currently amended] The flexible ballistic resistant article of claim 1, wherein the loosely woven fabric layer comprises polybenzoxazole or polybenzothiazole yarns.
    [8" claim-type="Currently amended] The flexible ballistic resistant article of claim 1 wherein the yarns of the loosely woven fabric layer are different from each other in the warp and fill directions.
    [9" claim-type="Currently amended] 10. The flexible ballistic resistant article of claim 8 wherein the yarn in the warp direction comprises aramid and the yarn in the fill direction comprises polybenzoxazole or polybenzothiazole.
    [10" claim-type="Currently amended] The flexible ballistic resistant article according to claim 8, wherein the warp yarns comprise polybenzoxazole or polybenzothiazole, and the yarns in the fill direction comprise aramid.
    [11" claim-type="Currently amended] The flexible ballistic resistant article of claim 1, wherein the loosely woven fabric layer comprises yarns having a linear density of 0.5 to 8 decitex.
    [12" claim-type="Currently amended] The flexible ballistic resistant article of claim 1 having a sufficient number of loosely woven fabric layers to have a ballistic V50 greater than 320 m / sec for a 9 mm bullet.
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    引用文献:
    公开号 | 申请日 | 公开日 | 申请人 | 专利标题
    法律状态:
    2001-04-12|Priority to US09/833,454
    2001-04-12|Priority to US09/833,454
    2002-03-27|Application filed by 이 아이 듀폰 디 네모아 앤드 캄파니
    2002-03-27|Priority to PCT/US2002/009800
    2003-11-10|Publication of KR20030086622A
    2008-07-28|Application granted
    2008-07-28|Publication of KR100848453B1
    优先权:
    申请号 | 申请日 | 专利标题
    US09/833,454|2001-04-12|
    US09/833,454|US6610617B2|2001-04-12|2001-04-12|Ballistic resistant article|
    PCT/US2002/009800|WO2002084202A1|2001-04-12|2002-03-27|Ballistic resistant article|
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