WO2015069139A1 - Multilayered protective material - Google Patents

Abstract

The multilayered protective material is intended primarily for producing protective clothing to protect against the wounding effect of piercing, striking and cutting elements. The technical result of the utility model is an increase in the protective properties of the material. The technical result is produced by the above-mentioned material which comprises at least one internal layer, at least one intermediate layer and at least one external layer, which layers are tear-resistant and are interconnected. The special characteristic of the technical solution is that the intermediate layer is connected by the opposite ends thereof to the internal layer in such a manner that said intermediate layer can move and slide by the centre thereof along the internal layer, and the external layer is formed by a multiplicity of elements which are arranged with an overlap in relation to one another. Each element is fixed by one side thereof on the intermediate layer, and the final element is formed from a film or film material having smooth sliding surfaces for the external layer and internal layer of material to slide therealong.

Description

 MULTILAYER PROTECTIVE MATERIAL

This technical solution relates mainly to means of protecting a person from the damaging effects of traumatic elements (animal teeth, knives, fragments, bullets). It is intended for use in the manufacture of protective clothing and protective equipment for people, animals, as well as various objects exposed to the danger of mechanical destruction.

 Known multilayer protective material (adopted as a prototype), containing protective elements attached to a flexible base, and an absorbing shock-absorbing layer, which is made of individual components with the possibility of their movement relative to one another, and the protective elements are fixed on a flexible basis with the possibility of their movement, at least on one side of the flexible base (see patent RU 2030705 C1, publ. 03/10/1995). This material is provided with anti-friction layers located at least between the individual components of the absorbing shock-absorbing layer and / or protective elements. The antifriction layers are made in the form of flexible sheets of polyethylene, or propylene, or Teflon. The components of the absorbing cushioning layer are impregnated with an antifriction compound. As an antifriction composition, it contains molybdenum disulfide, or graphite, or a melt of polyethylene, or polypropylene, or Teflon. The protective elements are end-to-end, and additional protective elements are located above the junction, fastened on a flexible base along the junction and in their central part at least at two points.

The distance b between the protective elements at the junction and the width c of the additional protective element covering the joint are in the following ratio: a> cb + 2k, where a is the width of the protective element, mm; b is the distance between the protective elements at the junction, mm; s is the width of the additional protective element, mm; k is a constant equal to 4 - 16 mm.

Protective clothing is provided, consisting of protective elements located in textile pockets attached to the circuit board, and an absorbing shock-absorbing bag, the absorbing shock-absorbing bag made of separate components with the possibility of their movement relative to one another, and textile pockets attached to the circuit board at least on the one hand and with the possibility of their movement. The clothes are equipped with a power tape for attaching the free ends of the textile pockets to the circuit board with the possibility of their adjustment. The clothes are made in the form of a vest and are equipped with a cover, a fabric screen and an elastic tape and / or flexible elastic porous material, pressing the pockets to the cushioning bag and / or mounting plate. Clothing is equipped with anti-friction layers. The antifriction layers are located at least between the components of the absorbent cushioning bag and / or textile pockets and / or protective elements. The antifriction layers are made in the form of flexible sheets of polyethylene, or propylene, or Teflon. The components of the shock absorption package are impregnated with an antifriction compound. As an antifriction composition, it contains molybdenum disulfide, or graphite, or melts of polyethylene, or propylene, or Teflon. Textile pockets with protective elements are end-to-end, with additional protective elements located above the junction located in textile pockets fixed in the central part along the joint on the circuit board (see patent RU 2030705 C1, published on March 10, 1995). A significant drawback of the multilayer protective material (prototype) is its complexity and large specific gravity, limiting the use of the material for the manufacture of clothing from it, covering parts of the body over the entire area of the clothing. This reduces the protective ability of the material.

 The technical result of the invention is to increase the protective properties of the material.

 The technical result is obtained by a multilayer protective material containing tear-resistant and interconnected at least one inner layer, one intermediate layer and one outer layer, characterized in that the intermediate layer is connected with its opposite ends to the inner layer so that it has the ability to move it middle on the inner layer, the outer layer is formed by many elements that are overlapped with respect to each other and each element is fixed with one side on the intermediate In the final layer, the latter is made of a film having smooth sliding surfaces for sliding the outer and inner layers of material along them.

 Figure 1 shows a diagram of the protective material in a front view in a vertical operating position.

The protective material comprises at least one inner layer 1, one intermediate layer 2 and one outer layer 3. The outer layer 3 is located on the front side of the material. In other versions of the material options, layers 1-3 may be several, while the number of layers is obtained by calculation and experimental methods. The intermediate layer 2 with opposite ends 4 and 5 is connected to the inner layer 1 with the possibility of moving the middle part 6 the intermediate layer relative to the inner layer 1 by sliding the middle part 6 on the adjacent surface of the inner layer 1.

 The outer layer 3 is formed by many separate from each other elements 7, which are fixed on the intermediate layer 2 and are overlapped with respect to each other so that each element 7 either partially covers the surface of an adjacent element at an estimated distance, or is itself covered adjacent element, both in vertical and horizontal directions. In the working position of the material, said overlap in the vertical direction (vertical overlap) is shown with a height h equal to the distance from the lower edge of the element 7 to the attachment point of the adjacent element with the intermediate layer. It was found that the value of h is most effective for the following dependence h = (0.3-0.5) H, where H is the height of element 7. In the working position of the material, the overlap in the horizontal direction (horizontal overlap) is shown with a length of 1 equal to the distance between the side the edges of adjacent elements 7 in the horizontal direction. It is established that the value 1 is most effective when the dependence 1 = (0.3-0.5) L, where L is the length of the element 7 in the horizontal direction. Each element 7 is fixed by one of its upper side 8 to the intermediate layer 2. The intermediate layer 2 is made of a high-strength film having smooth sliding surfaces 9 and 10, intended for sliding on them the elements 7 of the outer layer 3 and the inner layer 1 of the material. The intermediate layer 2 can also be made of any other known high-strength material having smooth sliding surfaces for sliding the outer and inner layers of material on them.

The indicated ends of the intermediate layer 2 are connected to the inner layer 1 by connectors 11. Each element 7 is fixed to the intermediate layer 2 by other connectors 12, which are located mainly on the same line. Connectors 11 and 12 are selected from among the known means of connecting the elements (glue, threads, quick disconnect elements - Velcro). The inner layer 1 and each element 7 of the outer layer are made of various high-strength woven fabrics, and the tensile strength of the inner layer 1 is higher than the strength of each element 7 of the outer layer. It is essential that each element 7 of the material is fixed by its upper side 8 to the intermediate layer 2 so that its sides 13 and the lower side remain free, falling from top to bottom. ^' In this regard, the protective material in its vertical position has an upper side 14 and a lower side 15. In this position of the material, the axis of symmetry of each element 7 is always in the vertical position. In this position, the use of the material is most effective.

 In the case of using the described material for sewing protective clothing, it is cut in such a way that in the vertical position the axis of symmetry of each element 7 is located vertically.

Each mentioned layer of material can have a different density, strength and thickness, the parameters of these values are selected by calculation, provided that each layer must have the flexibility necessary for the greatest efficiency of the material of the protected object. Each said material layer can be multilayer, consisting of two or more layers that are not identical in strength. Also, in the case of production of protective individual blocks from the material superimposed on the protected object, these blocks are designed so that when the block is superimposed on the protected object, the elements 7 of the material from which the block is made are oriented vertically. Such protective the blocks can be attached to ordinary clothing in places most vulnerable to damage. Separate protective blocks made of material can be fixed with quick-disconnect connectors on the human body or on the body of an animal, or of any object requiring protection.

 The material works as follows. When exposed to stitching elements or any known piercing elements (hereinafter referred to as traumatic elements), these traumatic elements meet the resistance of the material elements 7. In this case, the elements 7 are pressed against the surface 9 of the intermediate layer 2, slide along the surface 9 and partially shift the direction of the force of the traumatic element. At the same time, the surface 10 of the intermediate layer is pressed against the surface of the inner layer 1, slides along the inner surface of the inner layer 1 and further shifts the direction of the force of the traumatic element. As a result, the force of the traumatic element is decomposed into different components, and the resulting force aimed at breaking the inner layer is reduced. Within the established limits of material strength, traumatic elements do not pass through the material. In these cases, the traumatic elements do not touch the human body, which eliminates skin tears and bleeding. In connection with the features of this technical solution, the protective properties of the material are increased.

Claims

Claim 1. A multilayer protective material comprising tear-resistant and interconnected at least one inner layer, one intermediate layer and one outer layer, characterized in that the intermediate layer is connected at its opposite ends to the inner layer so that it has the ability moving its middle part along the inner layer by sliding along it, the outer layer is formed by many elements that are overlapped with respect to each other in the vertical and horizontal directions, while the first element is fixed with one of its sides on the intermediate layer so that the non-fixed part of the element is freely located on the intermediate layer with the possibility of movement and sliding along it, the latter being made of high-strength film material having smooth sliding surfaces for sliding the outer and inner layers of material on them.  2. The multilayer protective material according to claim 1, characterized in that the inner layer and each element of the outer layer are made of high strength woven fabrics, and the tensile strength of the inner layer is higher than the strength of each element of the outer layer.  3. The multilayer protective material according to claim 1, characterized in that any layer of the material can be multilayer, consisting of two or more layers that are not identical in strength.