RU2612696C2 - Protective material and protective products of such material - Google Patents

Abstract

FIELD: textile, paper.

SUBSTANCE: protective material for work in the conditions of external influences, such as electromagnetic field radio frequency bands, electric field of industrial frequency, and switching and stepping voltage and/or electric arc, is made of conductive fabric composed of filaments on the basis of meta-aramid fibers based on poly m-phenylene isophthalamide and/or its derivatives and a stainless metal staple and/or monofilament fibers in a ratio of 70:30 to 30:70 pts. wt. respectively, with a density of 250 to 400 g/m² and heat resistance at not less than 13 cal/cm² minimum density. Stainless metal fiber for providing corrosive resistance is made of stainless iron-based steel alloy with an additive selected from a number of chromium, nickel, titanium, carbon, manganese, copper, boron, vanadium, niobium, aluminum, tungsten, molybdenum. The fabric is adapted to coloring by using an appropriate hue aramid fiber and a linen weaving (1/1) or broken twill (2/1 or 3/1) are usually used. The protective product is made in the form of a garment, or hat, or hood, or helmet, or screened helmet, or shoes, or protective cover, or shoe covers, or gloves, or mittens, or socks.

EFFECT: invention allows for the possibility of wet washing without loss of protective properties and protect against electrical and thermal injuries when hitting an electric arc in a person.

8 cl, 1 dwg

Description

The invention relates to chemical fibers from polymers and protective materials and products from such a material for working in electromagnetic fields, under operating voltage, under the conditions of induced and step voltage and thermal and / or electrical risks of an electric arc. Products made of such material for human protection can be such as shoes, shoe covers, hats, overalls, made as separate elements, or in the form of any sets, for example jackets with bib pants or trousers.

The resulting material, as well as products from it, are universal (electric field, induced voltage and electric arc), easily controlled from the point of view of protective properties (there are no additional conduction channels and the outer layer of the material), light (about 1.5 kg against 2-3 kg for prototypes in summer performance), as there are no additional conduction channels and an outer layer of material, and the front screen is made of soft stainless steel mesh, a protective set that is resistant to external influences (and without additional top fabric).

Additional useful properties include:

- soft and lightweight front screen,

- a design with a hood, a shield and additional valves for use in high frequency electromagnetic fields,

- gloves made of shielding fabric that have a higher shielding coefficient of the high-frequency field,

- it is possible to manufacture clothes in corporate styles and colors of operating organizations.

The novelty lies in the fact that the shielding suit, items of clothing and shoes as a result of the use of new material acquire (unify) the properties of four personal protective equipment (PPE) at once:

- shielding kits for protection against an electric field of industrial frequency,

- protective shunt kits for protection against electric shock under induced and step voltage,

- shielding kits for protection against electromagnetic radiation of high-frequency ranges,

- protective clothing from the thermal risks of the electric arc (the level of protection can be selected as minimally sufficient from the point of view of the simultaneous use of the kit in adjacent areas of work with a different set of risks).

It is possible to make kits for individual protection of a person from the effects of an electric field of industrial frequency, electric shock under induced and step voltages, bias current, thermal risks of an electric arc, electromagnetic field of the radio frequency range and aero ions. These harmful and dangerous production factors affect personnel servicing electrical installations of high and extra-high voltage (including work carried out under operating and induced voltage), as well as radiating equipment of the radio frequency range.

The prior art various types of protective materials against various hazardous factors, such as activated carbon fibers (New chemical fibers for technical purposes, under the editorship of BC Smirnov, KE Perepelkina. - Chemistry, L., 1973, pp. 60-64 ) However, these materials cannot be used directly in protective clothing, but only as an internal sorbent layer in a non-woven material, as possess low operational stability (fragility, instability to attrition). In addition, a significant disadvantage of this kind of activated carbon textile materials is their high cost.

Non-woven protective materials and products are also known, for example, on the basis of a canvas stitched fleece fabric (RU 2107520, class A62B 17/00, 1998), the disadvantage of which is the large thickness, complexity of production and low degree of protection against electromagnetic fields. In addition, in the manufacture and operation of protective clothing, experiencing stresses on kink and tension, is destroyed, which reduces the protective properties during operation.

Composites for protection against electromagnetic fields are also known (US patent No. 4923533, No. 5252148 and Japanese patent No. 59201493) in the form of a composite material from powders of amorphous magnetically soft alloys based on a polymer binder. For the manufacture of such materials, flake-shaped powders of amorphous alloys of the base systems Fe-Si-B or Co-Fe-Ni-Si-B are used. The particle size of the powder varies from 0.01 to 300 microns, and the shape coefficient (ratio of thickness to maximum particle length) of such powders varies from 10 to 1500. The volumetric content of the powder in the polymer binder varies from 1 to 60%.

Known fabric made on the basis of simple weaving, and as a conductive thread using a combined thread with a specific electrical resistance of 103 Ohms, which contains a metal thread with a specific electrical resistance of 102 Ohms, which is included in the warp and weft of the fabric. The main yarn is a polyester textured yarn, and weft - cotton yarn (patent RU No. 2229544. Publ. 2004).

Known conductive fabric containing interwoven between the main and weft combined conductive threads, consisting of electrical insulating and conductive components, additionally insulating main and weft threads are introduced into the fabric, and the threads in the fabric are interwoven with minimal gaps, and the insulating component is made of yarn used in the production of household fabrics (patent RU No. 2354766, 2006).

Known protective clothing for working under voltage, containing a jacket (with a hood), bib suit, helmet, gloves made of electrically conductive fabric and shielding shoes on electrically conductive soles galvanically connected to each other by means of electrically conductive contact leads (USSR Author's Certificate No. 1105180, А62В 13/00, 1982).

The fabric used in well-known protective clothing consists of intertwined metal threads, while its checkered structure does not allow to achieve high electrical conductivity and, as a consequence, a high coefficient of shielding from electric and electromagnetic fields. Such fabric is hard, dense, heavy, and there is poor electrical contact between the threads. Metallized threads easily break when the fabric is wrinkled repeatedly during wear, which leads to a decrease in its electrical conductivity.

In the process, the user is forced to stay in protective clothing for a long time, hence the increased requirements for its hygienic and operational properties - wear, air permeability, softness of the fabric, its heat-insulating properties. In the case of using well-known clothing for personal protection from the effects of an electric field of industrial frequency, the required level of performance is unattainable.

Known protective clothing for working under voltage and in an electric field of industrial frequency, containing a jacket with a hood, bib overall, a helmet, gloves made of electrically conductive fabric and shielding shoes, galvanically connected to each other by means of electrically conductive contact leads, characterized in that the jacket, bib overall and shielding shoes made of three layers, while the upper layer of the jacket, semi-overalls and shoes is made of oil and water resistant and dirt-repellent material, the middle layer is made of electric of a conductive material with a uniformly distributed double-sided electrically conductive coating, and the inner one of cotton fabric, in addition, an electrically conductive silver-plated tape galvanically connected to this layer is additionally installed on the middle layer, and the conductive contact leads of the jacket, bib overall and shielding shoe are connected to the middle layer and brought out through loops in the inner or outer layer of the corresponding layer of clothing. Additionally, the clothes are equipped with a protective helmet and a shielding net mounted on the helmet using a removable holder (patent RU 2276570, 2006).

The shielding fabric used in well-known protective clothing is made by galvanic deposition of a metal layer on a fabric base. In this case, a continuous metal layer does not allow to achieve stable adhesion of the shielding layer when worn, which leads to a decrease in the shielding coefficient. This clothing must not be washed. The three-layer structure used to protect the shielding layer from human body secretions and external aggressive influences against the background of a continuous metallized layer on the shielding fabric increases the thickness of the material package and significantly impairs air permeability. This, especially in a hot climate and (or) the warm season, in the process of many hours of constant work leads to significant discomfort when worn, which often causes personnel errors and (or) not using these clothes. In addition, the presence of an outer layer of material makes it impossible to visually monitor the condition of the shielding fabric during operation. As a result, there is the possibility of an unpredictable decrease in the shielding coefficient during wear and / or damage to the shielding fabric. The mesh screen with the helmet holder used in the kit with the clothes makes the structure heavier and is not suitable for use on live overhead power lines when respiratory protection from air ions is required. In addition, the use of such a screen in clothing for protection against electromagnetic high-frequency fields (the presence of such a screen in these PPEs is mandatory) complicates the view for the user.

The technical task is to eliminate the disadvantages of the described materials and products from them, i.e. increasing the degree of protection against additional thermal risk of the electric arc when working in electrical installations and (or) near high-frequency radiating equipment. This is especially important when working under induced voltage, when touching live parts can be accompanied by an arc discharge, which can cause destruction, for example, of gloves and a breakthrough of current to the human body, followed by electrical injury. In addition, this increases the risks of improper use of PPE when changing clothes. In particular, this can occur if it is necessary to repeatedly move from an electrical installation with a voltage of, for example, 6 kV, where there are no risks of exposure to an electric field of industrial frequency with a voltage above the acceptable level, but there are high thermal risks of an arc to a switchgear of 330 kV or higher, where vice versa thermal risks of an electric arc are relatively low.

The technical result of the development of the material and products of protective clothing is to increase its reliability and comfort, providing the possibility of wet washing without loss of protective properties and unification of relatively dangerous and harmful production risks for personnel working in the electric frequency zone of industrial frequency, under operating, induced and step voltages, as well as in the zone of influence of powerful radio transmitting installations. An additional result of the development is the protection not only from the thermal risk of the electric arc, but also from the most common complex practice of the impact of this dangerous production factor, which includes the possibility of burns and the possibility of electrical injuries, often fatal, if the arc directly hits the human body.

The result is achieved using new material and products from it, which are characterized by the following features.

Protective material for working in conditions of external influences, such as an electromagnetic field of high-frequency ranges, an electric field of industrial frequency, induced and step voltages and / or an electric arc, is characterized by the fact that it is made of an electrically conductive fabric consisting of threads based on poly meta-aramide fiber m-phenyleneisophthalamide and / or its derivatives and metallic stainless staple and / or monofilament fibers with a ratio of from 70:30 to 30:70 mass parts, respectively, with a flat from 250 to 400 g / m ² and heat resistance at a minimum density of at least 13 cal / cm ² , while the stainless steel metal fiber is made of stainless steel based on iron with an additive selected from the range of chromium, nickel, titanium, to ensure corrosion resistance carbon, manganese, copper, boron, vanadium, niobium, aluminum, tungsten, molybdenum, and the fabric is dyed by using aramid fiber of the corresponding shade, and weaving the fabric using plain (1/1) or twill (2/1 or 3 /one).

Equally spaced threads are introduced into the fabric structure crosswise to reinforce the “rip-stop” type, to improve the physicomechanical properties, an increase in the twist of the threads is used, to improve the physicomechanical properties, additional components of the thread and / or fibers having high abrasion resistance, tensile and tearing loads, such as polyamides or nylon.

The protective product is made of material that is described above in the form of a garment, or a hat, or a hood, or a helmet, or a helmet, or shoes, or a protective cover, or shoe covers, or gloves, or mittens, or socks.

The protective product can be made in the form of a single overalls with fasteners that provide electrical connection using contact tapes with metal buttons with response contacts in the form of metal half rings to minimize the transitional electrical resistance of contact surfaces, with a hood and a removable knitted mask or face shield made of metal or metallized monofilament filament with a mesh size of not more than 2 mm and a filament diameter of not more than 60 microns to protect the face from electromagnet GOVERNMENTAL fields and high-frequency range of the respiratory system of ions.

The protective product can be made with a lining of cotton fabric with a density of not more than 170 g / m ² .

The essence of the invention lies in an electrically conductive fabric made of threads based on meta-aramid (Nomex® (DuPont), Teijinconex® (Teijin), Newstar® (Yantai Taiho), poly m-phenylene isophthalamide and its derivatives) and metallic stainless (stainless alloys based on iron with chromium, nickel, titanium, carbon, manganese, copper, boron, vanadium, niobium, aluminum, tungsten and molybdenum, introduced to ensure corrosion resistance and physical and mechanical properties according to the rule "N / 8") staple and (or) monofilament fibers with their percentage weights from 70:30 to 30:70 mass parts and a density of 250 to 400 g / m ² , and also characterized by heat resistance according to GOST 12.4.234-2012 with a minimum density of at least 13 cal / cm ² .

The protective material for working under the complex effects of an electric field of industrial frequency, induced and step voltage, as well as an electric arc is made of this fabric made of threads based on meta-aramid (Nomex® (DuPont), Teijinconex® (Teijin), Newstar® (Yantai Taiho), poly m-phenylene isophthalamide and its derivatives) and stainless metal (stainless alloys based on iron with chromium, nickel, titanium, carbon, manganese, copper, boron, vanadium, niobium, aluminum, tungsten and molybdenum, introduced to provide corrosion ion resistance and physico-mechanical properties according to the rule N / 8) of staple and (or) monofilament fibers with their percentage ratio of 30-40: 60 mass parts and density from 250 to 400 g / m ² , and also characterized by heat resistance according to GOST Ρ 12.4 .234-2012 at a minimum density of at least 13 cal / cm ² .

And in the case of protection from the electromagnetic field of high frequencies, and in the case of complex protection from the electric field of industrial frequency, induced and step voltages, and also the electric arc, the fabric is dyed by using meta-aramid fiber and the corresponding shade, and weaving the fabric using linen ( 1/1) or twill (2/1 or 3/1).

The protective material can be characterized by the fact that equally spaced threads are introduced into the fabric structure crosswise to reinforce the rip-stop type, and to improve the physicomechanical properties, increase the twist of the threads or use additional components (threads and (or) fibers having high abrasion resistance, tensile and tearing loads - polyamides, nylon, etc.). At the same time, high abrasion resistance in combination with thermo-flame retardant properties can be achieved with a low content in comparison with meta-aramid components (not more than 5-10 parts by weight).

The technical result is achieved by a protective product made of a material as described above, in the form of a garment, or a hat, or a hood, or a helmet, or a helmet, or shoes, or a protective cover, or shoe covers, or gloves, or mittens, or socks.

The protective product can be made in the form of a single overalls with fasteners that provide electrical connection using contact tapes with metal buttons with reciprocal contacts in the form of metal half rings to minimize the transient electrical resistance of the contact surfaces, with a hood and a removable knitted mask or face shield made of monofilament metal filaments with a mesh size of not more than 2 mm and a filament diameter of not more than 60 microns to protect the face from electromagnetic fields Foot and respiratory range of ions (under operating voltage) and lined with cotton fabric density not exceeding 170 g / m ^2.

Example 1

The protective material is made of an electrically conductive fabric consisting of filaments based on meta-aramid fiber based on poly-m-phenylene isophthalamide and stainless metal staple fiber with a ratio of 70:30 mass parts, respectively, with a density of 250 g / m ² and heat resistance at a minimum density of 13 cal / cm ² .

Stainless steel metal fiber for ensuring corrosion resistance is made of stainless alloy based on iron with the addition of chromium. Plain weaving (1/1).

Protective products are made of the material described above, in the form of a helmet, shoe covers and gloves.

Example 2

The protective material is made of electrically conductive fabric with a fiber ratio of 60:40 mass parts, respectively, with a density of 400 g / m ² and heat resistance at a minimum density of 13 cal / cm ² .

Alloy - with the addition of tungsten and molybdenum. The additive is aramid colored fiber.

Twill weave (2/1). In another example, (3/1) was used.

Example 3

According to example 1, additionally equally spaced yarns were introduced into the fabric structure crosswise to reinforce the rip-stop type, to improve the physicomechanical properties, the twist of the yarns positively affected.

To improve the physical and mechanical properties, polyamide was used in the thread (in another example, nylon).

Made gloves with a lining of cotton fabric with a density of 170 g / m ² .

The essence of the invention lies in the fabric, which is made of threads based on meta-aramid and metallic stainless fiber. The percentage of these fibers can be from 70:30 parts by weight accordingly, to ensure protection only from the electromagnetic field of high-frequency ranges and up to 30:70 wt.h. accordingly, if necessary, comprehensive protection, including induced and step voltage. In this case, the fabric can be of any color, for which aramid fiber of the corresponding shade is selected. The use of metallic stainless fiber allows you to wash products without loss of protective properties. The weave of the fabric can be plain (1/1) or twill (2/1 or 3/1). The density of the fabric determines the heat-resistant and physico-mechanical properties (from 250 to 400 g / cm ² ). Heat resistance of the fabric according to GOST Ρ 12.4.234-2012 with a minimum density of at least 13 cal / cm ² . The physicomechanical properties of the fabrics used can be enhanced, for example, using the rip-stop scheme, increasing the twist of the threads and (or) introducing additional components into the threads. This fabric is used for the manufacture of clothing, means of protection for the hands, head and legs, as well as the interlining of shoes. Moreover, the fabric has high physico-mechanical as well as heat-resistant properties due to the meta-aramid component. The fabric acquires shielding and electrically conductive (shunting) properties due to metal fiber and mesh structure, since the size of the tissue cell at any of these weaves is multiple small compared to the wavelengths of electromagnetic fields under industrial conditions (from 30 Hz to 60 GHz).

The kits consist of clothing, head and face protection, hand protection and shoes.

Clothing can be made in the form of:

- overalls - in kits for protection against electromagnetic radiation of high frequencies or for work under operating voltage on the wires of overhead power lines;

- jackets and trousers - in order to further facilitate the design;

- jackets and semi-overalls - in order to enhance the shielding properties when protecting from an electric field of industrial frequency.

Jacket can be made:

- with a central zipper and an additional strip of shielding fabric covering it from above;

- with a central fastener on buttons without an additional valve;

- without a central fastener - to ensure the best shielding properties and the reliability of ensuring these properties during use (it is impossible to unfasten the jacket during operation).

Hand protection can be in the form of gloves or mittens with short or long gaiters with 1 or 2 elastic bands in cuffs.

To protect the legs, boots or boots with an inter-lining of shielding fabric on an electrically conductive sole can be used. To protect against electromagnetic radiation of the high frequency range, ordinary safety shoes with shoe covers or socks made of shielding fabric can be used. The sole of the shoe is electrically conductive on the basis of finely dispersed carbon, fastened by the flash-stitching method, and reliable electrical contact of the sole with the screening inter-lining is achieved by stitching and gluing the elements with a special electrically conductive composition.

As the main means of protecting the head, a nakasnik of shielding fabric with an elastic band treated with ordinary cotton cloth is used. The nakasnik has a loop in the front part for fastening the nakasnik on a heat-resistant shield if it is used to protect against thermal risks of an electric arc. Nakasnik is removable, single-layer, entirely from shielding fabric. For additional head protection, a hood designed for a helmet is provided in the design of the jacket (overalls). At the edges of the front of the hood provides lightning for attaching a removable front screen. The design of the hood should provide tight galvanic contact of the screen mesh in the buttoned position with the material of the hood. This is ensured by two valves of shielding fabric on both sides of the zipper, the valves are fastened with three - in the sides and in the pocket area - or more metal buttons on the hood. Outside above the front of the hood there is a pocket for folding the front screen.

The means of protecting the face (from electromagnetic fields of the high frequency range) and respiratory organs (from air ions during certain types of work on the potential of unconnected overhead lines) is a removable face shield made of soft mesh knitted metal material with a zipper around the perimeter. Knitted screen material is made of monofilament metal thread. The size of the material cells should be no more than 2 mm, the diameter of the thread - not more than 60 microns. Such a screen effectively reduces the high frequency field and does not complicate the view for the user. It is very important that the design of the clothing does not provide for the use of additional through tapes to ensure reliable electrical conductivity of the kit. This function is reliably performed by the whole set, the elements of which are electrically connected to each other by the end sections of shoes, clothes and hand protection. In addition, an electrical connection is provided using contact tapes with metal buttons on the sleeves and trousers with reciprocal contacts in the form of metal half rings on shoes and hand protection. Thus, as a result of the actual parallel connection of the conductors, the transient electrical resistance of the contact surfaces is minimized. Nakasnik connects to clothes with a contact tape with metal buttons. In order that contact tapes during operation do not create the possibility of a hook for protruding parts at the workplace, one loop is provided for each contact connection.

To connect the kit with the potential of the workplace (wire or ground), 2 contact pins of shielding fabric sewn together in 4 layers with removable clips or clamps are provided on the clothes, the length of the pins is at least 1.5 m.

A feature of the sets for protection against high-frequency fields is that they can be single-layer, made entirely of shielding fabric, without lining. In this case, a nasal head is not needed - the hood and screen fully perform the function of protecting the face and head. In this case, it is sufficient to make contact connections without special conclusions; it is enough to lengthen the leggings of hand protection equipment.

To ensure isolation of the human body from the shielding fabric of clothing, including the hood and excluding the helmet, and hand protection, ordinary cotton fabric with a density of not more than 170 g / m ^{2 is used} . In shoes for this purpose, kersey or natural fur is used (in the case of winter shoes). All details of the cut are performed immediately on 2 layers - cotton and shielding. The cut is made so that the clothes are as continuous as possible. Stitching is done with a jeans seam with an additional five stitches to ensure a snug fit on the electrically conductive surfaces of the cut details.

Further, the claimed development is presented in the drawing, which shows a protective kit for working in an electromagnetic field, under operating voltage, under the conditions of induced, step voltage and thermal risks of an electric arc performed with trousers and a jacket in an assembled (operational) state.

The drawing shows:

1 - removable face screen made of soft knitted metallized material (for protection against air ions) with a zipper; 2 - a protective hood with a lining of cotton fabric inside, the hood in the front part is equipped with additional sealing valves (on both sides of the zipper) to protect against high-frequency electromagnetic waves; 3 - pocket with zipper in the hood for storing the front screen; 4 - a protective nakasnik; 5 - set-in elastic bands for tight pressing; on the shoulder pad, the elastic at the top is covered with a cotton cloth; 6 - contact tapes with metal buttons; 7 - the cotton lining fabric at the bottom of the jacket is not fixed with the free end when put on, tucked into trousers; 8 - central zipper; 9 - a protective valve that closes the fastener; 10 - retroreflective tape; 11 - contact tapes with metal buttons; 12 - protective gloves with contact joints on half rings, 13 - contact tapes with metal half rings and signal flags, are made in pairs: left and right on trousers from the outside and on the jacket from the inside; 14 - contact conclusions from the shielding fabric for grounding or equalization of potential; 15 - contact clamps or clamps for connecting the terminals when grounding the kit or equalizing the potential; 16 - knee pads made of metallized fabric (for reinforcement); 17 - safety boots with contact connections on the half rings; 18 - conductive sole; 19 - loops for attaching gloves contact tapes (to prevent hooks during operation); 20 - loops for fixing the contact tapes of the shoes (to prevent hooks during operation)

Kits provide protection against the following harmful and dangerous factors:

- electric field of industrial frequency;

- bias current flowing through the human body when it is in an electric field;

- pulse current (discharges) when touching grounded or insulated objects, parts of equipment, as well as grass and small bushes;

- intense electromagnetic radiation in a wide range of radio frequencies generated by a corona discharge, as well as arising from a discharge between the contacts of disconnectors, especially when they disconnect unloaded transformers and power lines;

- thermal risks of the electric arc;

- possible electrical injury when operating under induced and step voltage;

- air ions, especially heavy ones (aerosols).

Shielding coefficient at a frequency of 50 Hz of clothing in general, dB, not less than 60.

The shielding coefficient at high frequencies is 30-40 dB.

Shielding clothing resistance, Ohm, no more than 10.

Shielding gloves resistance, Ohm, no more than 5.

Resistance of shielding boots, Ohm, not more than 500.

Thus, the claimed material and a shielding product, such as a suit, as a result of the use of a new material acquires (unifies) the properties of four personal protective equipment (PPE) at once:

- a shielding kit for protection against an electric field of industrial frequency,

- a protective shunt kit for protection against electric shock under induced and step voltage,

- shielding kit for protection against electromagnetic radiation of high-frequency ranges,

- protective clothing from the thermal risks of the electric arc (in this case, the level of protection against the arc can be chosen as minimally sufficient from the point of view of simultaneous use of the kit in adjacent areas of work with a different set of risks).

Useful additional properties include:

- soft and lightweight front screen,

- a design with a hood, a shield and additional valves for use in high frequency electromagnetic fields,

- gloves made of shielding fabric that have a higher shielding coefficient of the high-frequency field,

- it is possible to manufacture clothes in corporate styles and colors of operating organizations,

- the ability to protect against complex (electrical and thermal) injuries when an electric arc enters a person (when blocked on the human body as a result of approaching live parts at an unacceptably close distance for electrical breakdown of the air gap).

Claims (8)

1. Protective material for working in conditions of external influences, such as an electromagnetic field of high-frequency ranges, an electric field of industrial frequency, induced and step voltage and / or electric arc, characterized in that it is made of an electrically conductive fabric consisting of threads based on meta-aramid fiber based on poly m-phenyleneisophthalamide and / or its derivatives and metallic stainless staple and / or monofilament fibers with a ratio of from 70:30 to 30:70 wt.h. respectively, with a density of 250 to 400 g / m ² and heat resistance at a minimum density of at least 13 cal / cm ² , while the stainless steel metal fiber is made of an iron-based stainless alloy with an additive selected from the range of chromium, nickel, to ensure corrosion resistance titanium, carbon, manganese, copper, boron, vanadium, niobium, aluminum, tungsten, molybdenum, the fabric is dyed by using aramid fiber of the corresponding shade, and weaving the fabric using plain (1/1) or twill (2/1 or 3/1). 2. The protective material according to claim 1, characterized in that equally spaced threads are introduced into the fabric structure crosswise to reinforce the rip-stop type. 3. The protective material according to p. 1, characterized in that to improve the physical and mechanical properties using an increase in the twist of the threads. 4. The protective material according to claim 1, characterized in that to improve the physicomechanical properties in the yarn, additional yarn components and / or fibers are used that have high abrasion resistance, tensile and tearing loads, such as polyamides. 5. A protective product made of material according to any one of paragraphs. 1-4, characterized in that it is made in the form of an article of clothing, or a headdress, or a hood, or a helmet, or a helmet, or shoes, or a protective cover, or shoe covers, or gloves, or mittens, or socks. 6. The protective product according to claim 5, characterized in that it is made with a lining of cotton fabric with a density of not more than 170 g / m ² . 7. A protective product made of material according to any one of paragraphs. 1-4, characterized in that it is made in the form of a single overalls with fasteners that provide electrical connection using contact tapes with metal buttons with response contacts in the form of metal half rings to minimize the transient electrical resistance of the contact surfaces, with a hood and a removable knitted mask or screen for faces made of metal or metallized monofilament yarn with a mesh size of not more than 2 mm and a thread diameter of not more than 60 microns to protect the face from electromagnetic high-frequency fields and respiratory organs from air ions. 8. The protective product according to claim 7, characterized in that it is made with a lining of cotton fabric with a density of not more than 170 g / m ² .

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