RU2503913C2 - Light protective suit of rescuer with body protecting waistcoat against electromagnetic radiation - Google Patents

Abstract

FIELD: rescue operations.

SUBSTANCE: light protective suit of rescuer with a protective waistcoat consists of trousers with stockings, a shirt with a hood, two-fingered gloves and a balaclava. The protective waistcoat against electromagnetic radiation consists of a fabric lining which is connected to the protective shell. In the fabric lining the elastic frame racks are secured by clips to the belt. The protective shell is attached to the elastic frame racks and is made of three layers. The first layer faces the environment surrounding the operator and is made in the form of interconnected rings. The third layer faces the body of the operator and is made of perforated polymeric material. The second layer is located between the first and the third layers and is made elastic of elastic mesh elements. The material of the rings is used as stainless steel which is processed with a composite material with higher protecting properties against electromagnetic radiation.

EFFECT: improvement of effectiveness of protection of rescuer against electromagnetic exposure.

Description

The invention relates to the equipment of rescuers in the field of emergency, in particular for the equipment of rescuers during emergency rescue operations in natural and man-made emergencies that cause destruction of objects, as well as in traffic accidents.

The closest technical solution to the claimed object is a light protective suit L-1 of the company LLC “Raboservice +”, published on the website http://www.raboservice.ni/about [1], designed to protect against radioactive dust, chemical and bacteriological effects per person. Suit L-1 is a special protective clothing and is used in areas contaminated with toxic substances and emergency chemically hazardous substances. It is intended to protect skin, clothing and shoes from the long-term effects of toxic and toxic substances, toxic dust, to protect against solutions of acids, water, alkalis, sea salt, varnishes, paints, oils, fats, and petroleum products, and to protect against harmful biological factors, when performing degassing, decontamination and disinfection work. The costume is made of rubberized T-15 fabric and consists of trousers with protective stockings, a shirt with a hood, two-fingered gloves and a comforter. The trousers are sewn together with stockings ending in rubber osoyuzka, and ribbons are sewn to them for fastening to the legs. The selection of suits L-1 is carried out by height: the first size is for people up to 165 cm tall, the second - from 166 to 172 cm, the third - 173 cm and above. TU 005296-84. Protective raincoat OP-1M according to TU 005296-84. Protective stockings in accordance with TU 00529b-84. Suit sizes L-1 are indicated on the front side of the shirts and at the bottom. Weight about 3 kg - [prototype].

A disadvantage of the known design of lifeguard clothes is the relatively low degree of protection against the electromagnetic impact of a lifeguard in emergency rescue operations.

A technically achievable result is an increase in the effectiveness of the rescuer’s protection against electromagnetic interference.

This is achieved by the fact that in a light protective lifeguard suit with a protective vest from electromagnetic radiation, consisting of trousers with protective stockings, hooded shirts, two-fingered gloves and a cap comforter, the trousers are sewn together with stockings ending in rubber boots with bots to which the ribbons are sewn for fastening to the legs, while in the upper part of the trousers there are shoulder straps and half rings, and the shirt is combined with a hood, and an intermediate strap is sewn to the lower edge of the hem, which is passed between the legs and fastens on the button at the bottom of the shirt in front, and the sleeves end with loops that are worn on the thumb after putting on the gloves, while on the shirt’s sleeves there are cuffs that fit the wrist, and the hood is fixed on the neck with a tape and a plastic peg, and the bottom of the shirt is pulled with an elastic tape and equipped with an inguinal belt, and the trousers are held with two straps and buckles made of half rings and are fixed with straps at the bottom, an additional protective vest from electromagnetic radiation is provided, consisting of a fabric lining, attached to the protective shell, and in the fabric lining elastic frame stands are fixed by means of clips on the waist belt, and the protective shell is attached to the elastic frame stands, while the protective shell is made of three layers, and the first layer facing the operator’s environment is made in the form of interconnected rings, and the third layer facing the operator’s body is made of perforated polymeric material, for example, aramid fiber, and the second layer located between them is made of elastic mesh of the elements, stainless steel is used as the material of the rings, which is treated with a composite material with enhanced protective properties against electromagnetic radiation.

In Fig.1 shows a General view of the proposed protective suit of a lifeguard, Fig.2 is a variant of the protective suit of a lifeguard with a gas mask, Fig.3 is a structural diagram of a protective suit of a lifeguard, Fig.4 shows the construction of a protective vest from electromagnetic interference, Fig. 5 is a diagram of a protective shell of a protective vest; FIG. 6 is a structure of a composite material.

Lightweight protective suit of a lifeguard with a protective vest from electromagnetic radiation (Figs. 1 and 3) consists of trousers 7 with protective stockings, a shirt 1 with a hood 2, two-fingered gloves 11 and a cap comforter. Pants 7 are sewn together with stockings ending in rubber osoyuzki with bots 8. Ribbons 9 are sewn to them for fastening to the legs. In the upper part of the trousers there are shoulder straps 10 and half rings (not shown in the drawing). Shirt 1 is combined with hood 2, an intermediate strap 5 is sewn to the lower edge at the back, which is passed between the legs and fastens on a button in the lower part of shirt 1 in front. Bag 6 is fixed on the strap. The sleeves end with loops 4, which are worn on the thumb after putting on the gloves 11. On the sleeves of the jacket there are cuffs that fit the wrist. The hood 2 is fixed to the neck with a tape 3 and a plastic peg. The bottom of the jacket (shirt) is pulled together with elastic tape and equipped with an inguinal belt (not shown in the drawing). The trousers are held with two straps 10 and buckles of half rings and are fixed at the bottom with straps.

A variant of the suit is possible (Fig. 2) as an army tool for individual protection from radioactive dust and drip-aerosol poisonous substances, equipped with a gas mask. The suit is not insulating. When infected, the suit is subject to special treatment and can be used many times in the future. It is made of rubberized fabric UNKL-3 or fabric T-15, and consists of one-piece trousers with stockings, a jacket with a hood and three-fingered mittens. On the sleeves of the jacket there are cuffs that fit the wrist.

A light protective suit of a lifeguard can be equipped with a protective vest from electromagnetic radiation (Fig. 4), which consists of a fabric lining 12, in which elastic frame racks 13 are fixed by means of latches 15 on the waist belt. The protective shell 14 is mounted on the elastic frame racks 13. The protective shell (figure 5) 14 can be fixed on the frame racks 13 over the entire area of the torso of a human operator, including the shoulder joints and hands (not shown).

The protective shell 14 is made of three layers, and the first layer facing the operator’s environment is made in the form of interconnected rings, the material of which is stainless steel, which is treated with a composite material with enhanced protective properties against electromagnetic radiation. The third layer 16, facing the operator’s body, is made of perforated polymeric material, for example, aramid fiber, and the second layer 17 located between them is made of elastic mesh elements. The density of the mesh structure of the elastic mesh elements is in the optimal range of 1.2 g / cm ³ ... 2.0 g / cm ³ , the material of the wire of the elastic mesh elements is steel grade EI-708, and its diameter is in the optimal range of values 0.09 mm ... 0.15 mm.

Composite material for protection against electromagnetic radiation (Fig.6) consists of a polymer base with particles 18 and 20, in which particles of 19 compounds are distributed - (Fe, Si) or - Co with a nanocrystalline structure of bulk density (0.6 ÷ 1.4 ) · 10 ^-5 1 / nm ³ . The polymer base for fixing the position of powder particles with a nanocrystalline structure is made in the form of alternating structural elements with particles 18 and 20 located at an angle of 90 ° to each other, and each of the elements with particles is made in the form of elongated particles arranged in parallel rows, moreover, the particles located to the left and to the right of it are shifted by an amount not exceeding half the maximum particle size. The use of a material with a nanocrystalline structure as a filler provides an increase in magnetic permeability.

It was experimentally established that when the bulk density of nanocrystals in the amorphous matrix is less than 0.6 · 10 ^-5 1 / nm ^{3, the} effect of increasing the magnetic permeability is not observed. When the bulk density of the nanocrystals in the amorphous matrix is greater than 1.4 · 10 ^-5 1 / nm ³ , the magnetic permeability decreases. Therefore, the following range of bulk density of nanocrystals in the amorphous matrix is optimal: more than 0.6 · 10 ^-5 1 / nm ³ , but less than 1.4 · 10 ^-5 1 / nm ³ .

Lightweight protective suit of a lifeguard with a protective vest from electromagnetic radiation works as follows.

It also protects the human operator from sudden impacts from both the mechanical impact of the environment and, for example, animals such as cattle. The implementation of the frame racks 13 elastic allows you to dampen the impact (make it elastic), and the protective shell 14 will prevent injury to the skin of the human operator.

Composite material works as follows.

An electromagnetic wave that penetrates deep into the material is more actively absorbed in it due to the higher absorption capacity of the nanocrystalline structure, which has a greater magnetic permeability compared to amorphous. When the electromagnetic wave reaches the opposite surface, its greater absorption occurs, which leads to an increase in the screening coefficient.

The technical and economic efficiency of the invention is expressed in reducing the thickness and weight and size characteristics of the composite material, which will improve the reliability of electronic and electrical equipment, provide effective protection of biological objects by increasing the magnetic permeability of the composite material and, as a result, the shielding coefficient of electromagnetic fields of the radio frequency range .

When the bulk density of nanocrystals is (Fe, Si) or - Co (0.6 ÷ 1.4) · 10 ^-5 1 / nm ^{3, the} magnetic permeability of the composites in comparison with the amorphous state increases by 2-3 times and ranges from 90 to 135 units

The light protective suit of the lifeguard can be used when performing degassing, decontamination and disinfection works to protect skin, clothing and shoes from the long-term effects of poisonous and toxic substances, toxic dust, to protect against solutions of acids, water, alkalis, sea salt, varnishes, paints, oils , fats, and petroleum products, protection against harmful biological factors, is used in areas contaminated with toxic and chemically hazardous substances, in the chemical and military industries, as well as from electromagnetic effects .

Claims (2)

1. A light protective lifeguard suit with a protective vest from electromagnetic radiation, consisting of trousers with protective stockings, a shirt with a hood, two-fingered gloves and a comforter, and the trousers are sewn together with stockings ending with rubber boots with bots to which ribbons are sewn for attaching to the legs , while in the upper part of the trousers there are shoulder straps and half rings, and the shirt is combined with a hood, and an intermediate strap is sewn to the lower edge of the hem, which is passed between the legs and fastens with a button in the lower part and shirts on the front, and the sleeves end with loops that are put on the thumb after putting on the gloves, while on the sleeve of the shirt there are cuffs that fit the wrist, and the hood is fixed on the neck with tape and a plastic peg, and the bottom of the shirt is pulled with an elastic tape and equipped with an inguinal belt, and the trousers are held by two straps and buckles of half rings and are fixed below with straps, characterized in that it is additionally equipped with a protective vest from electromagnetic radiation, consisting of a fabric lining connected with a protective shell, and elastic frame racks are fixed in the fabric lining by means of clips on the waist belt, and the protective shell is attached to the elastic frame racks, while the protective shell is made of three layers, the first layer facing the operator’s environment, made in the form of interconnected rings, and the third layer facing the operator’s body is made of perforated polymer material, for example, aramid fiber, and the second layer located between them is made of elastic mesh elements, the material of the rings used is stainless steel, which is treated with a composite material with enhanced protective properties against electromagnetic radiation. 2. A light protective lifeguard suit with a protective vest from electromagnetic radiation according to claim 1, characterized in that the composite material for protection against electromagnetic radiation consists of a polymer base in which particles of compounds - (Fe, Si) or - Co with a nanocrystalline structure are distributed bulk density (0.6 ÷ 1.4) · 10 ^-5 1 / nm ³ , while the polymer base for fixing the position of powder particles with a nanocrystalline structure is made in the form of alternating structural elements located at an angle of 90 ° to each other, but each of the elements is made in the form of elongated particles arranged in parallel rows, and the particles located to the left and to the right of it are shifted by an amount not exceeding half the maximum particle size, while the following range of bulk density of nanocrystals in an amorphous matrix is optimal: more 0.6 · 10 ^-5 1 / nm ³ , but less than 1.4 · 10 ^-5 1 / nm ³ .

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