RU2260164C1 - Protecting helmet - Google Patents

Abstract

FIELD: personal protection-gear.

SUBSTANCE: protecting helmet comprises metallic housing, crown device, mental belt, and textile-polymeric support. Over periphery, the housing and support are bordered with a belt made of woven or unwoven materials or rubber. The thickness of the housing is 0.8-2.0 mm, and textile-polymeric support is multilayer and has 4-20 layers of ballistic textile of 1.5-4 mm total thick interlaid by adhesive sheets of 01-2.5 mm total thick.

EFFECT: enhanced reliability.

20 cl, 1 tbl, 7 ex

Description

The invention relates to personal protective equipment, namely, protective helmets that can protect a person’s head from blows and from damage by bullets and / or fragments.

Known metal safety helmets in the form of steel army helmets (M.V.Silnikov and others. Means of individual armor protection. St. Petersburg University of the Ministry of Internal Affairs of Russia. 2000, p.330-334). The body of such a helmet (for example, helmets of the SSh-68 type), made of armored steel, has insufficient bulletproof and anti-shatter resistance, when interacting with damaging means it is quite easily deformed, it bends inward. In addition, a secondary damaging factor is formed in the form of a residual stream of fragments of the hull and damaging elements, which in total can lead to fatal injury. In this regard, the traditional steel helmets of the SSh-68 type must be modernized.

Protective helmets are known whose casings are made of layered polymeric materials. In accordance with French patent No. 2426238 (1980, F 41 H 1/08), in order to make such a helmet, it is necessary to first cut each of the layers of ballistic fabric, impregnate them with a binder based on the adhesive composition, lay the layers according to a certain pattern and form the helmet . At the same time, along with a complex and labor-intensive manufacturing process, harmful substances are released into the surrounding atmosphere. In addition, the strength of such a helmet cannot provide the necessary level of protection.

More preferred is the manufacturing technology of the protective helmet described in patent RU No. 2097187, from 11.27.1997. B 29 C 43/20. In accordance with the aforementioned patent, a packet of alternating layers of ballistic (aramid) fabric and thermoplastic materials used as a binder is assembled and pressed at a temperature exceeding the softening temperature of the interlayers. The result is a protective helmet housing made of a multilayer polymer material while reducing labor intensity and improving environmental factors. However, such a helmet requires a large amount of expensive aramid fabric.

Known combined protective helmet containing a metal base, visor, support, sub-muzzle device, liner and lower belt (chin strap). The head support is made of a fabric-polymer composition, has a constant or variable thickness and is made in the form of segments. (Certificate for utility model RU 2429 U1 dated July 16, 1996, F 41 H 1/04.)

The closest analogue of the invention is a protective army helmet, consisting of a steel case with a sub-body device and chin strap installed in it. On the inner side of the steel casing, repeating its shape, a one-piece fabric-polymer support based on ballistic fabric is installed. The ratio of the thickness of the fabric-polymer backing and the thickness of the steel body is in the range from 3 to 10, and along the perimeter, the body and the backing are jointly edged with a tape of woven polymeric materials or rubber. (Utility Model Certificate RU 8460 U1 of 11.16.1998, F 41 H 1/04.) When interacting with striking means, the helmet’s metal body is deformed, bends into the body and injures the head. In addition, the residual stream of fragments is a damaging factor. To prevent this, the thickness of the backwater should be sufficient and optimal to absorb the action of damaging agents.

In addition, when performing the known helmet when the ratio of the thickness of the fabric-polymer backing and the thickness of the steel casing in the range from 3 to 10, the optimum ratio of protective properties and weight of the product is not achieved.

The invention is aimed at solving the problem of increasing the protective properties of the helmet while reducing the total weight of the product.

The technical result of the invention is to obtain a protective helmet with a minimum weight due to the use of a minimum number of layers of ballistic fabric as part of a fabric-polymer backing with a minimum number of interlayers. In addition, with the selected ratio of the content of fabric and interlayers in the composition of the fabric-polymer backbone, the optimum backwater strength is ensured, guaranteeing maximum bulletproof and anti-splinter resistance and reducing the backward action of bullets and fragments to a safe level.

To solve this problem, a protective helmet is proposed, including a metal body, a sub-body device, a chin strap and a fabric-polymer backing, while the body and backing are edged around the perimeter with a tape of woven (non-woven) materials or rubber. In this case, the metal casing is made 0.8–2 mm thick, and the fabric-polymer backing is multilayer and contains 4–20 layers of high-modular ballistic fabric with a total (total) thickness of 1.5–4 mm and binding layers with a total (total) thickness of 0 , 1-2.5 mm, providing adhesive interaction between tissue layers.

In the manufacture of the helmet, various types of domestic or imported high-strength (high-modulus) ballistic fabrics made, for example, of polyethylene or polyamide fibers can be used. Preferably from aramid fibers.

When using ballistic (aramid) fabric of the specified thickness, the fabric-polymer head support can be performed with a ratio of the total thickness of the fabric layers to the total thickness of the interlayers in the range from 1 to 30, while the ratio of the support thickness to the thickness of the body is in the range from 1.0 to 10. The choice in the specified interval of the ratio of the thickness of the layers of fabric and the thickness of the binder layers, providing adhesive interaction between the layers of fabric, allows you to maximize the use of material properties, reduce the weight of the helmet, increase p accuracy and damping characteristics of the fabric-polymer backwater, which reduces the straddling effect of a bullet or fragments and reduces the concussion effect of damaging factors.

The proposed helmet can be made using a fabric-polymer backfill containing at least 4 layers of aramid high modulus fabric, that is, the backing can contain 4 or more layers of fabric. Moreover, if the interlayers providing adhesive interaction are made of polypropylene fabric with a thickness of 0.15-0.25 mm, then the ratio of the total thickness of the fabric layers to the total thickness of the interlayers will be optimal in the range from 1 to 5.1.

If the helmet is made using a fabric-polymer backwater containing 4 or more layers of aramid high modulus fabric, and the interlayers providing adhesive interaction are made of a polyethylene film 30-50 microns thick, then the ratio of the total thickness of the fabric layers to the total thickness of the interlayers will be optimal in range from 5.5 to 30.

The metal case of the helmet can be made of high-strength or armor steel with armor-resistant properties. Moreover, if the helmet body is made of armored steel, then its thickness should be 0.8-2.0 mm, then the fabric-polymer backing is made of 4-8 layers of aramid (high-modulus) fabric.

Interlayers providing adhesive interaction between tissue layers can also be made of glue. For example, epoxy resins can be used as an adhesive binder. However, this option is associated with high complexity and the danger of releasing highly toxic volatile components, which requires special safety measures.

The fabric-polymer backing can be made of ballistic (aramid) high-modulus twill, satin or linen weave with a thread thickness of 29.4-100 tex from whole pieces or from segmented pieces of aramid high-modulus fabric with cuts that allow you to lay the fabric in the form of a helmet without wrinkles or - with a given overlap.

However, in the manufacture of the helmet, it is more expedient to carry out layers of fabric-polymer backing from whole pieces of aramid high-modulus fabric in order to reduce labor intensity and optimally use the strength of undamaged aramid fibers.

To increase the level of protective properties, the helmet may contain a fabric-polymer backing of increased thickness, including 12 or more layers of aramid high modulus fabric.

During stamping, the domed part of the steel helmet, as a rule, turns out to be thinner and therefore requires additional protection.

To increase the level of protective properties and to compensate for the thinning of the metal helmet case in its domed part, it can additionally contain a fabric-polymer reinforcing element installed in the domed part of the case. That is, the thickness of the fabric-polymer backwater can vary in different areas of the helmet, in particular, due to a change in the number of layers of fabric and interlayers in different areas of the helmet.

The fabric-polymer support can be installed on the inside or on the outside of the metal case, repeating its shape.

The metal case and the fabric-polymer support can be permanently connected to each other with glue or with glue and mechanical fastening at the same time.

However, the connection of the metal casing and the fabric-polymer backwater can be made in the form of a detachable mechanical fastener for easy replacement. Due to this, the maintainability of the helmet, hygiene parameters, versatility of use can be improved. At the same time, the service life of the helmet increases.

Camouflage properties can be improved if the metal case on the outside is provided with a plain or colored paint or enamel coating, including those with radar absorbing and / or radar dispersive properties to reduce the possibility of detection in different wavelength spectra. In addition, the helmet can additionally be equipped with a camouflage cover, which, if necessary, can be made with water-repellent impregnation.

When constructing a helmet, the thickness of the backwater is a variable, depending on several parameters. Firstly, it depends on the selected thickness of the metal casing. Secondly, it depends on the required level (class) of protection. Thirdly, from the technological parameters of the pressing of the backwater selected in its manufacture.

With an increase in the thickness of the metal case, the reliability of protection increases, however, the weight of the helmet as a whole increases significantly. In technical terms, a helmet is one of the most complex elements of military equipment. Filtering and absorbing elements can be mounted in the helmet, allowing them to function in contaminated areas. Helmets can be equipped with various electronics, a laser target designator, a thermal imaging camera, headphones, a microphone, etc., with each additional tool increasing the total weight of the helmet. Therefore, given the density, it is more advisable to increase the thickness of the backwater, rather than the thickness of the metal casing. In this case, the mass of the backwater should not exceed 300 g. However, the main criterion for choosing the thickness of the backwater is the required level of protection.

The optimal embodiment of the invention is a protective helmet, including a metal body, a sub-body device, chin strap and fabric-polymer support. The helmet body and support are edged around the perimeter with tape, and the metal body is made of armored or high-strength steel with a thickness of 0.8-2 mm. In this case, the fabric-polymer backing is multilayered and contains 4-20 layers of aramid high-modulus fabric with a total thickness of 1.5-4 mm and binder layers made of polyethylene or polypropylene with a total thickness of 0.1-2.5 mm.

Examples of the invention.

Example 1. A protective helmet was made, including a metal body made of armored steel 1.2 mm thick, a sub-body device, a chin strap and a fabric-polymer support. In this case, the housing and the support are jointly edged around the perimeter of the tape. The tape may be made of natural fibers, woven or non-woven polymeric materials or rubber. The fabric-polymer backing is multi-layered and is permanently installed on the inside of the case. The support contains 10 layers of heterogeneous aramid high modulus twill and linen weave with a surface density of 180 to 260 g / dm ² with an average thread thickness of 29.4 tex and 9 layers of polypropylene fabric with a thickness of 0.18 mm. The thickness of the backwater in the helmet is sufficient to protect the helmet user from the bullets of the PM pistol when fired from a range of 5 m.

Examples 2-7. Protective helmets corresponding to the claimed invention, the parameters of which are shown in Table 1, are manufactured analogously to Example 1. Protective helmets additionally had paint or enamel coatings on the outside, in particular, made with radar absorbing properties. In addition, if necessary, the helmet was additionally equipped with a camouflage cover.

Table 1 Example No. Backwater Fabric Thickness of 1 layer of backing fabric, mm The number of layers of fabric in the backwater Interlayer The thickness of 1 layer of the layer, microns Number of layers Helmet weight, kg Protective properties 2 TSVM-J 0.18 10 Polyethylene 40 nine 1.55 PM
10 m 3 TSVM-J (A) 0.20 14 Polyethylene 32 thirteen 1.68 PM
5 m 4 Twaron 0.65 5 Polypropylene 0.2 mm 4 1.75 PM
5 m 5 Armos 0.36 8 Polyethylene 48 7 1,69 PM
5 m 6 RusAr 0.20 12 Polyethylene 40 eleven 1,67 PM
5 m 7 UD 0.32 8 Polyethylene 40 7 1,60 PM
5 m

The examples 1-7 show that the manufacture of a protective helmet in accordance with the parameters specified in the claims, allows you to get a helmet with a minimum weight of 1.55-1.75 kg, since the number of layers of ballistic fabric and the interlayers between them in the composition of the polymer fabric the backwater is minimal, but at the same time, the optimal backwater strength is ensured, guaranteeing maximum bulletproof and anti-shatter resistance and reducing the back-breaking action of bullets and fragments to a safe level.

Claims (20)

1. A protective helmet, including a metal case, a sub-body device, a chin strap and a fabric-polymer backing, while the case and backing are edged around the perimeter with a tape, characterized in that the metal case is 0.8-2 mm thick and the fabric-polymer backing made multilayer and contains 4-20 layers of ballistic fabric with a total thickness of 1.5-4 mm and interlayers with a total thickness of 0.1-2.5 mm, providing adhesive interaction between the layers of fabric. 2. The helmet according to claim 1, characterized in that the fabric-polymer backing is made of aramid high modulus fabric with a ratio of the total thickness of the fabric layers to the total thickness of the interlayers in the range of 1-30, while the ratio of the thickness of the backing to the thickness of the body is in the range of 1, 0-10. 3. The helmet according to claim 1, characterized in that the fabric-polymer backing is made of at least 4 layers of aramid high modulus fabric, and the interlayers are made of polypropylene fabric with a thickness of 0.15-0.25 mm with respect to the total thickness of the fabric layers to the thickness of the interlayers in the range from 1 to 5.1. 4. The helmet according to claim 1, characterized in that the fabric-polymer backing is made of at least 4 layers of aramid high modulus fabric, and the interlayers are made of polyethylene film 30-50 microns thick with a ratio of the total thickness of the fabric layers to the total thickness of the interlayers in the range of 5.5 to 30. 5. The helmet according to claim 1, characterized in that the metal casing is made of armored steel with a thickness of 0.8-2.0 mm, and the fabric-polymer backing is made of 4-8 layers of aramid high modulus fabric. 6. The helmet according to claim 1, characterized in that the interlayers are made of glue. 7. The helmet according to claim 1, characterized in that the fabric-polymer backing is made of aramid high-modulus twill, satin or linen weave with a thread thickness of 29.4-100 tex. 8. The helmet according to claim 1, characterized in that the layers of fabric-polymer backing are made of whole pieces of aramid high modulus fabric. 9. The helmet according to claim 1, characterized in that the layers of fabric-polymer backing are made of segmented pieces of aramid high-modulus fabric with cuts that allow you to lay the fabric in the shape of a helmet without wrinkles, or with a given overlap. 10. The helmet according to claim 1, characterized in that to increase the level of protective properties it contains a fabric-polymer backbone of increased thickness, including at least 12 layers of aramid high modulus fabric. 11. The helmet according to claim 1, characterized in that to increase the level of protective properties, it further comprises a fabric-polymer reinforcing element mounted in the domed part of the housing. 12. The helmet according to claim 1, characterized in that the fabric-polymer support is installed on the inner side of the metal casing and repeats its shape. 13. The helmet according to claim 1, characterized in that the fabric-polymer support is installed on the outside of the metal casing and repeats its shape. 14. The helmet according to claim 1, characterized in that the metal casing and the fabric-polymer support are inseparably connected with glue. 15. The helmet according to claim 1, characterized in that the metal casing and the fabric-polymer support are inseparably connected using glue and mechanical fastening. 16. The helmet according to claim 1, characterized in that the connection of the metal body and the fabric-polymer backwater is made in the form of a detachable mechanical fastener. 17. The helmet according to claim 1, characterized in that the metal casing is provided on the outside with a plain or colored paint or enamel coating. 18. Helmet according to claim 17, characterized in that the coating is absorbing and / or scattering electromagnetic waves in various ranges. 19. The helmet according to claim 1, characterized in that it is additionally equipped with a camouflage cover. 20. A protective helmet, including a metal case, a sub-body device, a chin belt and a fabric-polymer backing, the case and backing being edged around the perimeter with a tape, characterized in that the metal case is made of armored or high-strength steel with a thickness of 0.8-2 mm, and the fabric-polymer backing is multilayer and contains 4-20 layers of aramid high-modulus fabric with a total thickness of 1.5-4 mm and interlayers made of polyethylene or polypropylene with a total thickness of 0.1-2.5 mm.