RU2155313C1 - Cloth armoring panel, cloth armoring module and armored cloth - Google Patents

Abstract

FIELD: armored devices and cloths, mainly for manufacture of armored clothing, armored vests inclusive. SUBSTANCE: cloth armoring panel has a frontal multilayer cloth structure, at least one cloth armoring module and a rear multilayer cloth structure successively located from the frontal surface to the rear surface of the armoring panel, the degree of fastening of fibres of the base and weft in the cloth fragments increases from the frontal surface to the rear surface of the cloth armoring panel. The cloth armoring module is made of cloth fragments with unfastened cut edges folded in such a way that an irregular reticular structure of unfastened cut edges of cloth fragments is formed. The rear multilayer cloth structure is made of cloth fragments solid-cut in the plane contour of the armoring panel. EFFECT: enhanced armoring and operating parameters of light armored cloth devices, reduced specific consumption of materials and improved dimensional and human engineering characteristics. 23 cl, 6 dwg

Description

 The invention relates to armor-protective devices and to fabric of special, armored purpose, and more particularly, to means of light armor protection of people, animals, cars, structures, terrain from striking means such as bullets, fragments, and cold steel using armored fabric structures, and can used in the manufacture of armored clothing, including body armor.

 Ballistic-resistant garments are known that are intended to protect a person from being hit by bullets, shots, fragments, melee weapons (see US patent N 5479659, CL 2 / 2.5, publ. 02.01.1996). A well-known garment contains the chest and dorsal parts that are joined together to fasten on the human body; each part contains at least two panels that are interconnected and overlap each other. Between two paired panels there is a central panel designed to cover the human body in the sternum and, accordingly, in the spine. Moreover, each panel includes at least two layers of protective woven material. These panels are stitched with many stitches of high-strength aramid yarn Kevlar. The woven material consists of yarns having a predetermined number of Kevlar aramid fibers, and may have the same or unequal number of yarns along the length and width of the woven material. The parameters of the woven material provide the absorption and dispersion of bullet energy in its plane in the lateral direction, preventing the bullet from penetrating deeply.

 A disadvantage of the known structure of the fabric protective panel is that the layered planar structure of the panel contains tissue layers located with their planes only frontally and only at the same angles to the directions of impact of the striking bodies. The threads, especially the first frontal layers, are located in the most unfavorable transverse position relative to the direction of impact of the striking bodies. Therefore, the first frontal tissue layers in the known protective panels break through without significant energy expenditure of the damaging body due to the transverse destruction of the threads.

 Due to such an unfavorable orientation of high-strength filaments in the front layers of fabric protective panels, they turn out to be ineffective and very material-intensive, requiring the use of multiple layers of fabric while providing even low classes of protection against bullets with speeds of no more than 330 m / s.

 The level of effectiveness of armored panels is evaluated in terms of critical speed, i.e. critical value of the speed of impact of the striking body on the armored panel. At impact speeds higher than the critical speed inherent in the given design of the armored panel, this armored panel is assessed for one reason or another as not withstanding these impacts, i.e. not suitable for armor protection against defeat by such attacks. In particular, the effectiveness of fabric armor panels is determined by the given standards of such parameters as the number of punched or non-punctured fabric layers, the rear external linear dimensions of the backward deflection of the fabric layers. In known fabric armor panels, the lower the critical speed inherent in a particular design, the greater the number of tissue layers in it breaks through and the wider the backward deflection of tissues, the greater the number of tissue layers to be applied; therefore, the greater will be the surface density and mass of the armor plate with the same class of armor protection.

 The disadvantages of the known fabric armor panels include their characteristic low critical speeds, of the order of 330 m / s, with generally accepted standards for permissible mass (surface density) and backward deflection.

 A modular device for armor protection is known, which is a layered structure based on elastomer and fibers of organic matter and containing at least one flexible module consisting of many composite layers, each of which has an intermediate layer of textile fibers, for example aramid, on both sides of which a thin film of elastomer is applied; the composite layers are bonded to each other by vulcanization, and their number is determined by the required degree of flexibility of the module (see EP 0221794, CL F 41 H 5/04, 1987). This well-known solution is mainly aimed at providing the required flexibility and adaptation to the form of protected objects of various configurations and does not address the issues of creating fully fabric armored modules and their optimization in terms of increasing their armor-protecting properties.

 Protective fabrics for ballistic protection from high-strength filaments are known, optimized to increase shape stability, resistance to dynamic impact and destruction (see RF patents 2041986, D 03 D 15/00, 1992 and 2126856, D 03 D 15/00, 1997 and US patent 5479659, CL 2 / 2.5, 1996). In particular, as the closest analogue of the invention, protective fabric according to the patent of the Russian Federation 2126856, made of high-strength aramid yarn, equal to the linear density of the warp and weft, with the same longitudinal configuration and the same number of threads per unit width in both directions, can be adopted. However, the above result is achieved in known fabrics to a limited extent due to the fact that the choice of textile parameters of the structure of ballistic resistant fabric is carried out without taking into account the design and operating conditions of fabric armored panels. The lack of linking the properties of the fabric with the structure and properties of the threads and with the design of the fabric armor panel does not allow to achieve the required effectiveness in countering high-pulse hits of the damaging bodies on the front surfaces of the armor panels, i.e. in the most unfavorable directions, across the threads.

The objective of the invention is the creation of a fabric armored panel, tissue armored module and armored fabric, providing increased armor and operational parameters of light armored fabric devices, in particular, increasing armor-protecting properties of armored panels, reducing their material consumption and improving overall ergonomic characteristics. More specifically, the invention provides protection against damage by bullets with impact speeds of up to 470 m / s and fragments with speeds of up to 700 m / s, lowering the surface density to 6 kg / m ^{2 of} armored panels while maintaining sufficient flexibility.

 This result is achieved in that in a fabric armored panel made in the form of a multilayer structure formed by fragments of armored fabric and having a front and rear surfaces, in accordance with the invention, said multilayer structure includes a front multilayer fabric structure located in series from the front surface to the rear surface of the armored panel. at least one tissue armored module and a rear multilayer tissue structure, while the frontal multilayer Kano structure is bonded together tissue fragments, some of which form a front edge surface of the armor panels and the other edges in direct contact with the first fabric layer of said bronemodulya; said at least one tissue armored module is made of tissue fragments with loose cut edges twisted so that the armored module, in planes parallel to the front surface of the armored panel, has an irregular mesh structure of loose cut edges of tissue fragments of armored fabric; the rear multilayer tissue structure in direct contact with the last tissue layer of the said armored module is made of fabric fragments that are completely cut along the planar contour of the armored panel with loose cut edges and with rolled cut edges; moreover, the degree of fixation of warp and weft threads in tissue fragments, determined by the textile structure of the armored fabric and the multilayer tissue structures of the armored panel, increases starting from the front surface to the back surface of the fabric armored panel.

Moreover, the frontal multilayer tissue structure preferably consists of tape fragments of armored fabric with a width of from 1 to 2 of the largest longitudinal dimensions of the likely attacking bodies of firearms, said tape fragments stacked parallel to one another at an angle to the front surface of the armored panel in the range from 3 ^o to 90 ^o , at the same time, tape fragments of the armor-protective fabric can be fastened parallel to one another by high-strength piercing threads with efforts ensuring the number of threads about new and weft per unit of linear dimension of the front surface of the armor panels 10-20% minimal amount of warp and weft threads per unit of linear dimension in the warp and weft fabric tape bronezaschitnoy fragments.

 In addition, fragments of armor-protective fabric, which are integral across the planar contour of the armor panel, forming the rear multilayer tissue structure, are preferably bonded in thickness with high-strength stitching threads that provide a thickness of the rear laminated fabric structure 10-15% more than the total thickness of the set of whole-arm fragments of the armored fabric forming the rear laminated fabric structure.

Each of the armored fabric modules is preferably formed by four partial fragments of armored fabric with loose cut edges overlapable and bent around the armor panel by 180 ^° to form an irregular mesh structure along the thickness of the armored module with loose cut edges of the armored fabric fragments, which are not cut edges zones in the said irregular mesh structure, are removed from one another in the directions along the warp threads and the weft is an armored fabric and at distances that ensure a frontal impact of the striking body, its falling into the region of edge zones and the emergence, due to asymmetric fastening of the ends of the warp and weft threads, of unbalanced reactive sliding friction forces, leading to a change in the velocity vector of the striking body in tissue armored modules, and the ratio of the minimum number layers of armored fabric and the minimum number of edge zones at any point on the frontal projection of the armored module is 4: 1.

 It is also preferable that the linear dimensions of the said armor panel in length and width correspond to the linear dimensions of the protected objects, and the fabric armor modules located within the planar contour of the armor panel are joined together, while the fabric armor panel may contain armor panels in different parts within the planar contour between the front and with its back sides the same or locally increased number of tissue armored modules corresponding to local functionally important parts of the defense direct object.

 Moreover, the said multilayer structure of the fabric armored panel preferably has the flexibility to enable its use for sheltering protected objects of any configuration, and said armored panel can be placed in a fabric cover covering one or both of the front and back sides of the armored panel, the edges of which in the fabric cover can be stitched in a zigzag seam. In this case, preferably on the outer sides of the front and / or back multilayer structure or on a fabric cover from the front and / or back of the armored panel, a marking is applied that designates the front and back sides of the armored panel and the types of damaging means against which protection is guaranteed.

 The specified technical result is also achieved by the fact that the fabric armored module, intended for use in the multilayer structure of the fabric armored panel, in accordance with the invention contains tissue fragments of the armored fabric with loose cut edges, turned up to form an irregular mesh structure of the cut edges and edge zones of the mentioned tissue fragments.

In this case, the fabric armored module is preferably made of four fragments of the armored protective fabric with loose cut edges overlapping and bent around the armored module by 180 ^° , the ratio of the minimum number of layers of armored fabric and the minimum number of edge zones at any point on the frontal projection of the armored module is 4: 1, and the degree of fixation of the warp and weft threads of the armor-protective fabric at the loose cut edge and at the turn of the edge of the tissue fragments were chosen significantly different to ensure cheniya occurrence unbalanced lateral reaction forces on impact on bronemodul striking body.

 In addition, the specified technical result is achieved in that the armor-resistant fabric intended for use in the manufacture of fabric armored panels with a multilayer structure made of high-strength aramid threads with the same longitudinal configuration, linear density and number of threads per unit of linear dimensions of the warp and weft, in accordance with the invention has a predetermined, depending on the location of the tissue fragment in the multilayer structure of the fabric armor panel, l threads in the fabric structure, the same basis and weft, provided by the corresponding values of textile parameters selected from the group including the type and pattern of weaving, the linear density and twisting coefficient of the threads, the multiplicity of reinforcement and the number of threads per unit of linear dimensions of the fabric, the length of overlapping threads warp and weft, as well as any combination of these textile parameters.

 In this case, the warp and weft of the armor-resistant fabric preferably consist of the same number of high-strength microfibers of the Rusar family of circular cross section of the same diameter, not exceeding 10 microns, and the warp and weft are weakly twisted threads with a twist coefficient of less than 2, the linear density of which is the same and does not exceed 14.3 tex, and the gain is in the range from 1 to 10. In this case, the warp and weft have the lowest possible stresses determined by the manufacturing technology, are the same by any stretch of the fabric.

 In addition, the armor-resistant fabric is preferably made equally spaced, which is expressed in providing the same reaction in the directions along the base and the weft with respect to the frontal impact of the striking body in the form of bullets at a speed of up to 470 m / s and in the form of fragments with a speed of up to 700 m / s, and possesses stable characteristics determined during tests with the indicated impact velocities, such as the same number of punctured tissue layers, the repeatability of the average values of the distance between the threads and the length of the os new and duck in the structure of the first three unbreakable tissue layers.

 Thus, the achievement of the technical result in the invention is ensured with an integrated approach to solving the problem, taking into account the design of the entire fabric armored panel as a functionally autonomous armored barrier and all its structural components: the structure of the armored panel, the structure of the armored modules that make up the armored panel, and the structure of the armored fabric.

 The invention is based on an integrated approach to the development of fabric armored panels, armored modules, as well as armored fabric used in the manufacture of armored panels and armored modules. A significant increase in the critical speed for a fabric armored panel is based on a variation in the degree of fastening of high-strength aramid fibers in the structures of threads, armored fabrics, in multilayer fabric structures, including those forming armored modules, and within the finite limits of the structure of armored panels. According to the invention, the degrees of fixation of fibers and threads as elementary structural details in the fabric structure and multilayer tissue structures of the armor panel vary within wide limits: from degrees of fixation approaching one theoretical limit, caused by absolutely rigid fixations of the ends of the threads, to degrees of fixation approaching a different theoretical limit caused by the absolutely free position of the threads and their ends, showing only inertial reaction forces.

 In real cases, approaching the first limiting state of fiber and thread fixation, there is a minimal probability of fibers and threads following in their contacts with the striking body after its progress in tissue structures and multilayer tissue structures of the armored panel. In these cases, due to extremely short durations of contacts and, accordingly, extremely high loading speeds of fibers and threads, the most unfavorable conditions for their loading and destruction are created. Tissues and multilayer tissue structures capable of withstanding only reduced impact speeds are characterized by low critical velocities. In the case of impacts under conditions approaching the second limiting state of fiber and thread fixation, on the contrary, there is an increased likelihood of contact following of fibers and threads behind a moving attacking body, the duration of contact increases, the loading speed decreases, and the probability of destruction of fibers and threads, therefore, breakdown of layers tissues, multilayer tissue structures and armor panels are reduced. Tissues and multilayer tissue structures realizing such reduced degrees of fiber and filament fixation are characterized by increased critical speeds. New approaches to the implementation of the principle of varying the degree of fixation of fibers and threads in the structures of fabric and armored panels were manifested in the creation of new solutions for armored high-strength fabrics and multilayer armored structures from them. These solutions quantitatively characterize the state of the surface of microfibers, which determines the optimal friction forces inside and outside the complex threads in the structures of the fabric and armored panels, as well as the textile parameters of the threads and fabrics of the fabric armored structures.

 In accordance with the invention, the degree of fixation of the threads in the structure of the fabric and the armored panel increases with the removal of layers of fabric along the thickness of the armored panel from the front side of the armored panel to its rear side, gradually from one layer of fabric to another or spasmodically from one multilayer fabric structure to another and from one armored module to to another. The degrees of fixation of both ends of the warp and weft threads, determined mainly by the design of the armored modules, are mainly different, which creates an imbalance in the reactive forces developed by the threads and the effect of the rotation of the damaging bodies in the fabric layers of the armored panel.

 Before considering preferred embodiments of the invention, it is advisable to introduce the definitions used in the present description to characterize the features of the invention.

 The intensive development of individual means of local armor protection, primarily of humans, requires the creation of technical fabrics specialized for armor protection from bullets and fragments with increased impact speeds. In this regard, it became necessary to purposefully develop armored fabric as a special category of technical fabric. Since in the prior art until now there was no special definition of the term “armor-proof fabric”, then along with the development of the armor-proof fabric itself, it was necessary to formulate the concept of “armor-proof fabric” for the first time, characterized by the features included in the claims related to this object.

The invention is illustrated by examples of its implementation, illustrated by the drawings, which show the following:
FIG. 1 is a conditional spatial image of a fabric armored panel made according to the invention;
FIG. 2 - conditional spatial image of a flat rectangular tissue scan designed for the manufacture of one tissue armored module;
FIG. 3 is a conditional image on the frontal projection of an irregular mesh structure of loose cut edges and edge zones of an armored fabric for a portion of a fabric armored panel formed by fabric armored modules;
FIG. 4, 5, 6 - conditional image of samples of textile structures of armored fabric in comparison with the structure of the fabric known from the prior art.

 In FIG. 1 shows a conditional spatial image of a fabric armored panel 1 and an attacking body 2 at any meeting angles 3 with the frontal surface 4. The frontal projection 5 of the armored panel 1 and a vertical section of 1/4 of the armored panel are also conventionally presented. The armor panel 1 is characterized by linear dimensions: length 6, width 7 and thickness 8, as well as planar contours 9, 10, 11, corresponding to the front surface, the middle part of the thickness of the armor panel and its rear surface. Typical ratios of linear dimensions can be as follows: the ratio of length 6 to width 7 - 1 or more, the ratio of length 6 or width 7 to thickness 8 - not less than 50. Armor panel 1 may have a cover 12, covering all or part of the surface of the armor panel.

 The armor panel 1 in thickness consists of a number of tissue fragments 13, 14, 15. The tissue fragments 13 located in the armor panel 1 in thickness 8 are the first from the side of the probable blows of the attacking body 2, form a frontal surface 4, leaving one of its edges directly outside the armor panel to its frontal side, while the main part of the tissue fragments 13 and their second edges are located under the frontal surface 4 of the armor panel 1. The tissue fragments 13 form a frontal multilayer structure 16 with one after another in common parallel to one another and at an angle to the frontal surface with layers 17 of armor-protective fabric fastened with piercing threads 18 with the required force.

 From fabric fragments 14 located behind the frontal multilayer structure 16, fabric armored modules 19 are formed, which are located in the middle of the thickness 8 of the armored panel 1. Each tissue armored module 19 is formed by a turn of the loose cut edges 20 of tissue fragments 14 so that the thickness of the armored module 19 and, respectively, a thickness of 8 armor panels 1 within its mid-planar contour 10 forms a rectangular irregular grid of cut edges 20 of fabric fragments 14. In the frontal projection 5 armor panels 1 containing the armored modules 19 in it jointly form a grid of cut edges 20 of tissue fragments 14 so that on any portion 24 of the frontal projection 5 there is necessarily a portion of a grid of cut edges 20 that ensures the appearance of armored panels in tissue arm 1, more specifically in the warp and weft threads of tissue fragments 14, unbalanced lateral reaction forces acting on the damaging body 2 and contributing to its rotation around its own center of mass, which leads to a change in its velocity vector.

 From fabric fragments 15 with cut loose non-fixed edges 21 and with tucked edges 22 located last in thickness 8 of the armor panel 1, a back multilayer tissue structure 23 is formed, the tissue layers 15 of which form the back surface 11 of the armor panel 1.

 In FIG. 2 shows a flat rectangular tissue scan 25, intended for the manufacture of tissue armored module. Scan 25 consists of rectangular tissue fragments 14 cut from one type of armored fabric along cut lines oriented in the directions of warp and weft threads. Tissue fragments 14 within scan 25 during overlap assembly overlap with overlap values 26 and 27 along scan length and width, respectively. All cut edges 20 fragments 14 are not fixed and are even rows of cut ends of warp and weft threads. The assembly of fragments 14 overlapping within the planar contour of the reamer 25 forms a rectangular irregular grid of loose cut edges 20, which divides the entire reamer plane 25 into zones 28, 29, 30 with the number of layers of armor-resistant fabric along the reamer thickness 25 equal to 1, 2, 4, respectively. The grid of loose cut edges 20 and zones 28, 29, 30 with a different number of layers causes, during convolution of the armored module, the formation of an irregular mesh structure of edge zones with unequal fastening of the ends of the fabric in the tissue planes x layers.

 In FIG. 3 shows a conditional image on the frontal projection 5 of an irregular mesh structure of loose cut edges 20, an arbitrary section 24 of fabric armor plate 1 with a thickness of 8, formed by fabric armored modules 19. Turned in the manufacture of fabric armored modules 19 loose cut edges of a tissue scan (such as 31, 32), combined when laying armored modules 19 in the composition of the armored panel 1, form within the planar contour 10 of the armored panel and in its thickness 8 a mesh structure with uneven edge zones is fixed the ends of the tissue-forming yarns and with sections 33, 34, 35, 36 (shown in Fig. 3 as shaded in different ways) with an unequal number of layers of armored fabric in a thickness of 8 armor panels 1 (in this case, the number of layers is 16, 18, 20, 24 ) The mesh structure contains combined loose edges, for example 31, 32, fragments of armored fabric with the number of combined edges in the thickness of 8 armor plate 1, respectively, equal to 4 and 7.

 In FIG. 4 shows a conditional image of samples of textile structures for uniformly unloading armored fabric in comparison with a sample of the textile structure of ordinary plain weave fabric, known from the prior art, which does not provide the same perception of impact energy on warp threads 37 and 38 weft threads. A section along the line I-I (Fig. 4b) and a section along the line II-II (Fig. 4c) shows that the warp yarns 37 and the weft yarns 38 in sections 39, 40 of the armored fabric have the same longitudinal profile. This ensures the same perception by the warp threads 37 and the weft threads 38 of the energy of the striking body 2 during a frontal impact into the fabric armor panel 1, i.e. makes armor-proof fabric equally spaced along warp and weft threads. In contrast to the threads of uniformly unloading armored fabric, the warp threads 37, 38 and the ordinary plain weave (Fig. 4d, e), presented in sections 41, 42, respectively, have a different longitudinal profile. Sections I-I and II-II for sections 43 (Fig. 4e), 44 (Fig. 4g) illustrate the change in the longitudinal profile of warp and weft threads 37, 38 as a result of their 2-fold reinforcement. When the threads are reinforced, for example, 2 times or more, the same longitudinal profiles of the warp and weft threads are created and, therefore, the prerequisites are created for the same perception by these threads of the impact energy of the striking body and the equally unloading behavior of the armored fabric in the fabric armor panel. At the same time, the lengths of the mutual overlapping of warp and weft threads increase, which reduces the degree of their fixation in the fabric structure and can be used in the design of armored fabric and armored multilayer fabric structures.

In FIG. 4e, c, g show the angles of coverage α ₁ , α ₂ , α _{3 of the} yarn 37 of the warp yarn 38 weft for plain weaving, including α ₁ for known fabric, α ₂ , α ₃ for armor-resistant fabric according to the invention in the case respectively single (Fig. 4b, 4c) and doubled (Fig. 4e, 4g) warp and weft. It can be seen that the magnitude of the coverage angles in the sections of profile sections 42, 40, 44 decreases significantly with an obvious decrease in the areas of mutual contact of the threads and their fixation in real tissue structures, varying in the multiplicity of the same gain of warp and weft threads.

 In FIG. 5 depicts the textile structure of the armor-proof fabric of one of the main structural types of weaving, which is equally unloaded under the impact of the striking body. On the example of warp yarns 37 and weft yarns 38, shown in section III-III, it can be seen that the fabric and weaving provide the same longitudinal profiles of yarns 37, 38, due to the property of armor-resistant fabric to perceive impact equally warp and weft yarns.

 In FIG. 6a shows the textile structure of the armor-proof uniformly unloading fabric of another of the main types of weaving. FIG. 6b illustrates a section IV-IV section of tissue along the warp yarn 37. The warp yarns 37 and the weft yarns 38 have the same longitudinal profile.

 The textile structures of the armor protective fabrics of the invention, in particular those shown in FIG. 4, 5, 6, form a family of armored fabric, varying in the degree of thread fixation, the same for warp and weft threads. The choice of textile weaves, as shown, for example, in FIG. 4, 5, 6, and the multiplicity of reinforcement of warp and weft threads, as shown in FIG. 4b, 4c, 4e, 4g, variants of armor-resistant fabric are created that differ in the size of the area of mutual contact in the places of bending of warp and weft threads when they are interlaced, the number of bending of threads when bending one thread with another thread, increasing the length of the mutual overlap of warp and weft threads in each form weaves, which leads to an extensive set of options for armor-resistant fabric with varying degrees of thread fixation, the same for warp and weft threads in fabric structures.

When the armor plate 1 and the striking body 2 collide (for example, a bullet or a fragment), the impact contact is localized at the first moment between the front of the striking body 2 and the frontal surface 4, formed by the edges of the tape tissue fragments 13 of the frontal multilayer tissue structure 16. Since the tissue fragments 13 are located and fastened with piercing threads 18 at a certain angle (γ) ranging from 3 ^o to 90 ^o to the front surface 4, then the warp threads 37 and weft 38 are located more favorably with respect to the direction of the macaw of the striking body 2 due to the appearance and growth due to the transverse components of the longitudinal components of the reaction forces in the threads of the tissue fragments 13. As a result, the strands are able to withstand without breaking the ultra-high-strength microfibres of rosars, threads and tissue, the impact of the striking body 2 with significantly higher speeds than when using known ballistic-resistant fabrics, up to 470 m / s in cases of bullet impact and up to 700 m / s in cases of fragments. Unexploded ultrahigh-strength microfibres of rosars of low-twisted warp threads 37 and weft 38 are layered on the front of the striking body 2, neutralizing their sharp parts and increasing the impact area, as a result of which the uniformity of the unloading energy of the impact on the warp threads 37 and weft 38 and the fabric as a whole increases. In addition, the tape shape of the tissue fragments 13 and a certain angle (γ) ranging from 3 ^o to 90 ^o their inclination to the front surface 4 or, more precisely, the sum of the angles 3 and γ, cause the appearance of lateral asymmetric reaction forces acting on the armor panel embedded in 1 damaging body 2 and causing a change in the velocity vector of its movement.

 The frontal multilayer tissue structure 16, the first to perceive the impact of the striking bodies, even at increased speeds of impact of bullets up to 470 m / s and fragments up to 700 m / s, is able to increase the contact area of the impact, prevent the breaking of high-strength microfibers rosar equally in warp and weft during contact movement together with the striking body and transform the energy of the striking body 2 into the energy of the lateral movements of the warp and weft threads in the structure of the armor-protecting fabric.

 The design of the fabric armored module 19, due to the irregular mesh structure of the loose cut edges 20 of the tissue fragments contained in it 14, ensures guaranteed penetration of the striking bodies into zones 33, 34, 35 and 36 with an edge effect that causes and increases the spread of the striking body around its own center of mass. As a result, the energy of the damaging body is transformed into the energy of motion of non-destructible warp and weft threads 37, 38, and, accordingly, the speed of impact decreases. To enhance this effect in the design of fabric armored modules 19, they used fragments of 14 armored fabric with an increased degree of fixation of warp and weft threads, compared with the fastening of threads in the front multilayer fabric structure 16. When used for armor protection against attacking bodies at high speed, about 470 m / s and above, more than one armored module 19, they use variants of armored fabric with an increase in the degree of fixation of threads in the textile structure. In this case, the first armored module 19 after the frontal multilayer tissue structure 16 should contain tissue fragments 14 with an increased length of the mutual overlap of the threads and, therefore, with a reduced degree of their fixation in the textile structure (for example, such as in Fig. 6), and the last armored module 19 should contain tissue fragments 14 with a reduced length of the mutual overlap of the threads and, therefore, with a high degree of their fixation in the textile structure (for example, such as in Fig. 5). The necessary options for armor-resistant fabric, differing in the degree of uniform fixation of warp and weft threads, can be provided, for example, by choosing the type and report of textile weaving, by changing the multiplicity of the same gain of warp and weft threads in the range from 1 to 10.

 In addition to a significant transformation in the thickness 8 of the armored panel 1 of the energy of the striking body 2 into the energy of movement of the strands 37, 38, the most important function of the fabric armored modules 19 is the reduction at the level of the middle planar contour 10 along the thickness of the armored panel 1 of the path of movement of the striking body 2 and the microfibers that are in contact with it Rusar, forming a local funnel-shaped deflection in the direction of the back surface in multilayer tissue structures 16, 19, 23.

 The back multilayer fabric structure 23, which includes armor panels 1 seamlessly framed along a planar contour 11, tissue fragments 15 with uncovered 21 and / or 22 turned upside down cut edges of the armor protective fabric, has the most severe resistance to penetrating the thickness of 8 armor panels 1 to the damaging body 2. Such toughened resistance characterized by the cessation of the increase in the direction of the back surface 11 of the armor plate 1 deflection of fragments 14, 15 armored modules 19 and the rear multilayer tissue structure 23. This can be used using armor-resistant fabric with the highest degree of fixation of threads 37, 38 in a textile structure (for example, such as 39, 40 (Fig. 4)), as well as using fabric fragments, one-piece on the rear planar contour 11, and securing the cut edges with their turn along the path 11. Termination of the development of local deflection of multilayer tissue structures 19, 23 towards the back surface 11 of the armor panel 1, i.e. a complete stop of the damaging body 2 in the thickness 8 of the armor plate 1 is achieved not only by extremely rigid, with minimal compliance, resistance of the fragments 15 of the armor protective fabric, but also by changing the direction of movement of the damaging body to the sides in the thickness 8 of the armor panel 1 along the tissue fragments of 14 armored modules 19.

Claims (23)

 1. Fabric armored panel made in the form of a multilayer structure formed by fragments of armored fabric and having a front and rear surfaces, characterized in that the multilayer structure includes a frontal multilayer fabric structure located at a succession from the front surface to the back surface of the armored panel, at least one fabric the armored module and the back multilayer tissue structure formed by fragments of armored fabric, while the frontal multilayer tissue structure The tour is made of tissue fragments fastened together, one edge of which forms the frontal surface of the armored panel, while the other edges are in contact with the first tissue layer of the said armored module, and the degree of fixation of warp and weft threads in tissue fragments, determined by the textile structure of the armored fabric and the structure of the armored panel, starting from front surface to the back surface of the fabric armor panel. 2. The fabric armor panel according to claim 1, characterized in that the frontal multilayer fabric structure consists of tape fragments of armor-resistant fabric with a width of 1 to 2 of the largest longitudinal dimensions of the likely attacking bodies of firearms, with tape fragments stacked parallel to one another at an angle to the front surface of the armor panel ranging from 3 to 90 ^o .  3. The fabric armored panel according to claim 2, characterized in that the ribbon fragments of the armored fabric are fastened parallel to one another by high-strength stitching threads with efforts that provide the number of warp and weft threads per unit of linear size of the front surface of the armor panel is 10 - 20% less than the number of warp threads and weft per unit of linear size along the base and weft of armored fabric of tape fragments.  4. The fabric armor panel according to claim 1, characterized in that the rear multilayer fabric structure that is in direct contact with the last tissue layer of the armored module is made of fabric fragments that are seamlessly cut along the planar contour of the armored panel with loose cut edges and with rolled cut edges.  5. The fabric armor panel according to claim 4, characterized in that the whole armor panel fragments of armor-protective fabric, which are completely flat along the plane contour, forming the rear multilayer fabric structure, are fastened in thickness by high-strength stitching threads, providing the thickness of the rear multilayer fabric structure by 10 - 15% more than the total thickness of the set one-piece fragments of armor-resistant fabric, forming the back multilayer tissue structure. 6. The fabric armored panel according to claim 1, characterized in that each of the fabric armored modules is formed by four partial fragments of the armored fabric with loose cut edges, overlapable and bent along the armor panel outline by 180 ^o , to form an irregular mesh structure of loose armored frames along the armor module thickness fragments of armored fabric.  7. The fabric armor panel according to claim 6, characterized in that the loose cut edges that form the edge zones in an irregular mesh structure are removed from each other in the directions along the warp threads and the weft of the armor-protecting fabric for distances that ensure that it gets into the frontal impact of the striking body the region of edge zones and the emergence, due to asymmetric fastening of the ends of the warp and weft threads, of unbalanced reactive sliding friction forces, leading to a change in the velocity vector of the moving body in tissues x bronemodulyah.  8. The fabric armor panel according to claim 7, characterized in that the ratio of the minimum number of layers of armored fabric and the minimum number of edge zones at any point on the frontal projection of the armored module is 4: 1.  9. The fabric armored panel according to any one of claims 1 to 8, characterized in that the linear dimensions of the armored panel in length and width correspond to the linear dimensions of the protected objects, while the fabric armored modules located within the planar contour of the armored panel are docked to each other.  10. The fabric armored panel according to any one of claims 1 to 9, characterized in that it contains at different sites within the planar contour of the armored panel between its front and rear sides the same or locally increased number of fabric armored modules corresponding to the locally functionally important parts of the protected object.  11. The fabric armored panel according to any one of claims 1 to 10, characterized in that the said multilayer structure is made with flexibility, providing the possibility of its use for shelter of protected objects of any configuration.  12. The fabric armor panel according to any one of claims 1 to 11, characterized in that it is placed in a fabric cover covering one or both of the front and back sides of the armor panel.  13. The fabric armor panel of claim 12, wherein the edges of the armor panel in the fabric cover are stitched with a zigzag seam.  14. Cloth armor panel according to any one of claims 1 to 13, characterized in that on the outer sides of the front and / or rear multilayer structure or on a fabric cover from the front and / or back of the armor panel, a marking is applied that designates the front and back sides of the armor panel, respectively types of damaging agents against which protection is guaranteed.  15. A fabric armored module designed for use in a multilayer structure of a fabric armored panel, characterized in that it contains fragments of an armored fabric with loose cut edges twisted to form an irregular mesh structure of the cut edges and edge bands of the zones of said tissue fragments. 16. The fabric armored module according to clause 15, characterized in that it is made of four fragments of armored fabric with loose cut edges, overlapable and bent around the armored module by 180 ^o .  17. The fabric armored vehicle according to clause 16, wherein the ratio of the minimum number of layers of armored fabric and the minimum number of edge zones at any point of the frontal projection of the armored module is 4: 1.  18. The fabric armored module according to any one of paragraphs.15 to 17, characterized in that the degree of fixation of the warp threads and the weft of the armored fabric at the loose cut edge and the exposed edge of the tissue fragments are significantly different to ensure the occurrence of unbalanced lateral reactive forces upon impact on the armored module of the damaging body.  19. Armored fabric intended for use in the manufacture of fabric armored panels with a multilayer structure, made of high-strength aramid yarns with the same longitudinal configuration, linear density and number of threads per unit of linear dimensions of the warp and weft, characterized in that it has a predetermined depending on the location of the tissue fragment in the multilayer structure of the fabric armor panel, the tightness of the threads in the tissue structure, the same basis and weft, providing emuyu corresponding values of textile parameters selected from the group consisting of view and repeat of the weave, size of the linear density and coefficient of twist yarns, the multiplicity of amplification and the number of yarns per unit of linear tissue size, the length of overlapping warp and weft, and any combination of said textile parameters.  20. Armored fabric according to claim 19, characterized in that the warp and weft threads consist of the same number of high-strength microfibers of the Rusar family of circular cross section of the same diameter, not exceeding 10 microns.  21. Armored fabric according to claim 19 or 20, characterized in that the warp and weft are low-twisted yarns with a twist coefficient of less than 2, and the linear density of the warp and weft is the same and does not exceed 14.3 tex, and the multiplicity of the threads is ranging from 1 to 10.  22. Armored fabric according to any one of paragraphs.19 to 21, characterized in that the warp and weft have the lowest possible stresses determined by the manufacturing technology, the same in any area of the fabric.  23. Armored fabric according to any one of paragraphs.19 to 22, characterized in that it is made equally spaced, provides the same reaction in the directions along the weft and the weft with respect to the frontal impact of the striking body in the form of bullets at a speed within 470 m / s and in the form fragments with a speed of up to 700 m / s, and has stable characteristics determined during testing in multilayer tissue structures with specified impact velocities, such as the same number of punctured tissue layers, repeatability of the average statistical values oyany prodernutosti between the yarns and the warp and weft yarns in the structure as a punched and no penetration of tissue layers.

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