RU2516842C2 - Suit of combat garment of rescuers operating under conditions of burning objects in presence of flying and falling items of destructible object - Google Patents

Abstract

FIELD: rescue operations.

SUBSTANCE: suit of combat garment of rescuers operating under conditions of burning objects in the presence of flying and falling items of the destructible object is proposed. The suit with flame retardant properties consists of a jacket with sleeves and a hood with a protective transparent element located in working condition on the front part of the head, trousers with suspenders and a rigid belt, boots of flame retardant material resistant to mechanical stress of seismic nature. At that as the fabric for the combat garment top the heat-resistant fabric of yarns of polyphenylene oxadiazol fibre and filament yarn "Rusar" is used. The suit also comprises a protective helmet of company "Cromwell F600" with a high level of comfort, and a protective vest. The protective vest consists of a fabric lining connected with a protective shell, and in the fabric lining the elastic frame racks are secured by clips on the belt of trousers, and the protective shell is attached to the elastic frame racks and comprises internal and external protective packages between which a gasket is placed, made in the form of a tape with the fixed pleats placed with a constant pitch from the side of the protected object, and is sequentially placed in two outer layers, and the outer package facing the surrounding environment of the operator is made multi-layered. Each layer is made in the form of interconnected rings, in which stainless steel is used as the material. The layers are located with overlapping the lumen of the rings by their articulation, and the inner protective package is made three-layered, at that the layer in contact with the outer membrane, and the layer facing the operator's body, are made of perforated polymeric material such as aramid fibres, and the intermediate layer located between them is formed resilient from elastic mesh elements, at that the density of the mesh structure of resilient-elastic mesh elements is within the optimal range of values of 1.2 g/cm³-2.0 g/cm³. At that the wire material of elastic mesh elements is steel EI-708, and its diameter is in the optimal range of values of 0.09 mm-0.15 mm. According to the invention, the protective membrane of the protective waistcoat comprises layers of outer membrane, such as aramid fabric impregnated with a polymer binder, hard-alloy or curvilinear or plain-variable inserts and the inner membranes similar to the outer ones, and the inserts are made of elementary cells fastened with each other and with the membranes by adhesive chemically compatible to the binder of the membranes. The inserts are made of isotropic material such as ceramic, with a minimum linear dimension of the cells exceeding their twice thickness, and for attaching them the elastic glue is used based on the synthetic elastomer such as cast polyurethane. The cells can be made square and located chequerwise or in a shape of regular hexagon.

EFFECT: improvement of efficiency and reliability of the design of clothing for rescuers operating under conditions of burning objects in the presence of flying and falling items of the destructible object.

10 dwg

Description

The invention relates to the equipment of rescuers in the field of emergency.

The closest technical solution to the claimed object is a suit of combat clothing of fire rescuers, described in a review article by the authors: Rusetskiy Yu.G., Ivanov A.V. Suit of combat clothing of fire-rescuers of the first level of protection. Firm "Volbrok", [1] - site http://volbrok.ru/article01.shtml, [prototype], and consisting of a jacket with a detachable hood and trousers, while developed as part of the fabric for the top of combat clothing assignments of the State Scientific and Technological Park “Emergencies” heat-resistant fabric from polyphenylene-oxadiazole fiber yarn and Rusar multifilament yarn (TU RB 300620644.008-2003 “Severe fire-resistant fabrics for clothing of firefighters-rescuers of the first level of protection”). Comparative characteristics of the most important technical and economic indicators of heat-resistant fabric at the top of a firefighter-rescue combat clothing suit are presented in Table 1. The technical specifications of TU RB 300620644.007-2003 “Suit of combat clothing of fire-rescuers of the first level of protection” have been developed and approved. The article describes the progress of the research work carried out by the Research Center (SIC) of the Vitebsk Regional Department of the Ministry of Emergencies (Belarus).

Table 1 The most important technical and economic indicators of the developed heat-resistant fabric for the top of the firefighter-rescue combat clothing suit. Indicator Created Material The best Russian analogue (CBM) Best Western counterpart (Nomex) Surface density, g / m ² , no more 270 220 265 Breaking load, N, not less than: based 1400 1200 1200 by duck 1000 1000 1000 Elongation at break,%, not less than: based 33 twenty twenty by duck 22 22 twenty Tearing load, N, not less than: based one hundred one hundred 80 by duck 120 one hundred 60 Shrinkage after heating, no more 5 7 12 Resistance to ambient temperature up to + 300 ° C, s, not less than 300 300 300 Resistance to contact with hard surfaces heated to + 400 ° C, s, not less than 10 10 5

Tests of a package of materials, the material of the top of the obtained sample were carried out for compliance with thermal and physical and mechanical parameters of the requirements of fire safety [1]. The tests showed that the manufactured experimental model fully complies with the fire safety standards NPB 29-2000 for combat clothing of fire-rescuers of the 1st level of protection, provides convenience in dynamics when performing fire-rescue work. The designed suit protects the human body not only from high temperature, heat fluxes of high intensity, but also from possible flames. The calculation of technical and economic indicators allows us to conclude that it is expedient and economical to manufacture firefighter-rescue clothing from domestic materials.

Comparative characteristics of the most important technical and economic indicators

table 2 Technical and economic indicators of a suit of combat clothing firefighter-rescuer Indicator Created Sample The best Russian analogue (CBM) Best Western counterpart (Nomex) Resistance to heat flux: 5,0 kW / m ² , s not less 250 240 240 40.0 kW / m ² , s, not less 10 10 5 Water permeability, mm. water column, not less 1000 1000 220 Resistance to weak (up to 20%) acids and alkalis (H ₂ SO ₄ , HCl, KOH, NaOH), flow volume at zero penetration,%, not less 80 80 80

A disadvantage of the well-known suit of combat clothing of rescuers operating in conditions of burning objects in the presence of flying and falling objects of a collapsing object is its weak degree of protection against the mechanical effects of piercing and cutting objects of a collapsing object.

Currently, a protective vest according to the patent of the Russian Federation No. 2426059 (an analogue of the claimed object) is known for protecting against mechanical impact of piercing and cutting objects flying and falling from a collapsing object, which consists of a fabric lining in which elastic frame racks are fixed by means of latches on the waist belt where the protective shell is secured against mechanical stress.

A technically achievable result is an increase in the efficiency and reliability of the design of clothing of rescuers operating in conditions of burning objects in the presence of flying and falling objects of a collapsing object.

This is achieved by the fact that in a suit of combat clothing of rescuers operating in conditions of burning objects in the presence of flying and falling objects of a collapsing object, containing combat clothing of rescuers having fire-retardant properties and consisting of a jacket with sleeves and a hood with a protective transparent element located in the working condition on the front of the head, as well as trousers with suspenders and a hard belt, and boots made of fireproof and resistant to mechanical stresses seismic nature of the material, and in quality Your fabrics for the top of combat clothing use a heat-resistant fabric made of polyphenylene oxadiazole fiber yarn and Rusar complex yarn, as well as a protective helmet made by Cromwell F600, with a high level of comfort and a protective vest, the protective vest consists of a fabric lining connected to the protective the shell, and in the fabric lining the elastic frame racks are fixed by means of the clips on the waist belt of the trousers, and the protective shell is attached to the elastic frame racks, and contains external and internal protective packages, between the gasket is made in the form of a tape with fixed folds placed at a constant step from the side of the protected object, and placed sequentially in two outer shells, and the outer package facing the operator’s environment is multilayer, and each layer is made in the form of interconnected rings, the material of which is stainless steel, the layers are located with overlap of the lumen of the rings by their joint, and the inner protective package is made of three layers, while contacting the outer shell and the layer facing the operator’s body are made of perforated polymeric material, for example, aramid fiber, and the intermediate layer located between them is made elastic of elastic mesh elements, while the density of the mesh structure of elastic-elastic mesh elements is in optimal the range of values of 1.2 g / cm ³ ... 2.0 g / cm ³ , and the material of the wire of the elastic mesh elements is steel EI-708, and its diameter is in the optimal range of 0.09 mm ... 0.15 mm.

Figures 1 and 2 show a sketch of a model of a rescue combat clothing suit (front and rear views, respectively), Fig. 3 is a general view of a protective helmet of a lifeguard combat clothing, and Figures 4, 5, 6 are a technical sketch of a jacket, hood, and trousers, Fig.7 shows a profile projection of a protective vest, Fig.8 is a frontal view of a protective vest, Fig.9 is a diagram of the protective shell of a protective vest, Fig.10 is a variant of the protective shell of a protective vest.

The combat clothing suit of rescuers operating in conditions of burning objects in the presence of flying and falling objects of a collapsing object is a set of the following objects. Rescue combat clothing (Figs. 1, 2, 4, 5, 6), which has fire retardant properties and consists of a jacket 1 with sleeves 2, and a hood 6 with a protective transparent element 3, located in working condition on the front of the head, as well as trousers 4 with suspenders and a hard belt, and boots 5 made of fireproof and resistant to mechanical stresses (including seismic nature) material (not shown in the drawing). The fabric for the top of combat clothing is a heat-resistant fabric made of polyphenylene-oxadiazole fiber yarn and Rusar multifilament yarn (TU RB 300620644.008-2003 “Hardened fire-resistant fabrics for clothing of fire-rescue workers of the first level of protection”).

The next protection element used in burning facilities with flying and falling objects of a collapsing object is the Cromwell F600 safety helmet (figure 3), used by most firefighters in the UK, and having a reputation for a helmet with a high level of comfort (double CE certification , both a helmet and a visor, providing maximum protection for the head and face). The material of the outer shell 7 of the helmet is fiberglass coated with fire-retardant paint, which is resistant to the open flame of the helmet body 7 with the upper forehead protective part 8, at least 15 seconds, and the face shield 9-10 seconds. An easily replaceable upper forehead protector 8 protects the visor 9 and the front of the helmet where the most damage occurs. The visor is made of polycarbonate and protects the most important part of the helmet and is easily replaced if damaged; provides a wide view, optically correct for anti-distortion. Comfortable temperature is maintained by the inner insulating layer. The helmet is compatible with all types of breathing apparatus. There is a simple four-position adjustment for all head sizes (52 ÷ 63 cm) using a special mechanism. The helmet can be moved forward or backward on the head with a bezel over the eyebrows. The bezel around the eyebrows is very soft - for optimal comfort. The height of the seat is regulated by tensioning or loosening the chin strap 10. The fire-resistant, quickly detachable chin strap can withstand a static load of 500 N. The angle of the helmet is regulated by turning the rim above the eyebrows (compatibility with the breathing apparatus is also provided).

Specifications: weight - 1320 grams, the helmet can withstand vertical impact of a blunt object with an energy of 80 J; in a vertical impact with a sharp object with an energy of 30 J, it is impossible to touch the surface of the head; the visor withstands single strokes of a load with an energy of 1.2 J while maintaining the operability of the rotary locking device; the connection of parts of the internal equipment with the helmet body at each attachment point can withstand a load of 80 N. The helmet body protects against electric shock with a voltage of 400 V.

The helmet can be made with a protective shell, which contains layers of the outer shell of, for example, aramid fabric impregnated with a polymeric binder, hard-alloy curvilinear or plane alternating inserts and, similar to the outer, layers of the inner shell, and the inserts are made of unit cells bonded to each other and with shells with glue chemically compatible with the binder of the shells, while the inserts are made of isotropic material, for example, ceramics, with a minimum linear cell size exceeding their double thickness, and To their fastening elastic adhesive used with synthetic elastomer, such as polyurethane injection, the cells can be made square and are arranged in a staggered manner or in the form of a regular hexagon (see. Figure 10).

The next protection element used in conditions of burning objects in the presence of flying and falling objects of a collapsing object is a protective vest (Figs. 7, 8, 9), which protects the human operator from sudden impacts of mechanical impact from the surrounding burning environment, and which put on under a jacket 1. The implementation of the elastic material of the frame racks 12 connected to the belt of the trousers 4 allows you to dampen the impact (make it elastic), and the protective shell 13 prevents injury to the skin of the lifeguard.

The protective vest consists of a fabric lining 11 in which the elastic frame racks 12 are fixed by means of the clips 14 on the hard waist belt of the trousers 4. The protective shell 13 is mounted on the elastic frame racks 12. The protective shell 13 can be fixed on the frame racks 12 over the entire area of the lifeguard torso , including the shoulder joints and hands (not shown in the drawing).

The protective shell 13 (Fig. 9) contains an external 15 and an inner protective bag, between which there is a gasket 17 with folds 18 placed in the shell 19. The gasket 17 is made in the form of a tape with fixed folds 18 placed with a constant step from the side of the protected object, and placed sequentially in two outer shells 19. The outer package 15, facing the environment, is multilayer, and each layer is made in the form of interconnected rings, the material of which used stainless steel. In this case, the layers are arranged with overlapping lumen of the rings by their articulation. The inner protective bag is made three-layer, with the layer 16 in contact with the outer shell 19 and the layer 21 facing the operator’s body made of perforated polymeric material, for example, aramid fiber, and the intermediate layer 20 located between them is made of elastic from elastic mesh elements, while 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 , moreover, the material of the wire of the elastic mesh elements is steel EI-708, and its diameter is in the optimal range of 0.09 mm ... 0.15 mm.

An embodiment of the protective jacket of the protective vest (FIG. 10) comprises layers of the outer shell 22 of, for example, aramid fabric impregnated with a polymer binder, hard-alloy curvilinear or flat alternating inserts 23 and, similar to the outer ones, layers of the inner shell 24. The inserts 23 are made of unit cells bonded between each other and with the shells 22 and 24 with glue 25 chemically compatible with the binder of the shells 22 and 24, and each cell is made with a minimum linear size 26 exceeding its double thickness 27. For shells 22 and 24, an epoxy is used holding the binder, and the cells used for fastening elastic adhesive 25 on the basis of a synthetic elastomer such as polyurethane DCCH PFL. The cells can be made square and staggered or in the shape of a regular hexagon (not shown in the drawing).

A possible embodiment is that the outer shell 22 is a carrier on which all the inserts 23 are mounted, and the inner shell 24 is a support for the inserts 23 made of isotropic material, for example ceramic, constant curvature and square cell configuration, and also performs supporting functions (not shown in the drawing). The thickness of 27 cells corresponds to the size of the main damaging factor, and the linear size of 26 exceeds the double thickness of 27 by 1.5 ÷ 1.7 times. To facilitate a protective vest, cells can be located in areas of its most likely damage.

The combat clothing suit of rescuers operating in conditions of burning objects in the presence of flying and falling objects of a collapsing object works as follows.

With a large kinetic energy of a mechanical action or an attacking element, an external protective package 15 can be pierced with a loss of this energy to a certain extent. But the damaging fragment approaches the inner protective package with less speed and, as a result, with less energy, which ensures the penetration of the hard layers 16 and 21 of the material of this layer. In this case, the elastic material 20 acts as a shock absorber, reducing the shock pulse to a safe level.

If the outer layer 15 is not broken, the gasket 17 begins to work as a means of reducing the shock pulse. In this case, partial absorption of energy occurs due to the closing of the folds and the simultaneous dispersion of the shock pulse over a larger area due to the air present between the folds. In this case, the air gradually leaves due to the load from the shells, which allows you to stretch the shock pulse in time. Further removal of the shock pulse occurs due to the internal protective package.

The protective shell of the protective vest (figure 10) works as follows. When the damaging factor interacts with the protection elements, the outer shell 22 is overcome, the protective insert 23 receives damage in the area of the direct wave of critical deformations. In this case, the effect of the reflected wave is significantly attenuated due to the optimization of the backwater material (inner shell 24) and the adhesive joint 25. The damaging factor when passing through the cell array of the protective insert 23 is broken into fragments, loses a significant part of its energy and stops in the backwater layers 24. However , due to the damping of the waves by the material of the adhesive joints 25, only one cell and possibly several neighboring ones are damaged, and the main array of the insert remains without damage, which confirms the high the volatility of the safety vest.

Using the proposed device will significantly increase the safety of rescuers in the liquidation of emergency situations and their consequences.

Claims (1)

Suit of combat clothing of rescuers operating in the presence of burning objects in the presence of flying and falling objects of a collapsing object, containing combat clothing of rescuers having fire-retardant properties and consisting of a jacket with sleeves and a hood with a protective transparent element located in working condition on the front of the head, and also trousers with suspenders and a rigid belt and boots made of fireproof and resistant to mechanical influences seismic nature of the material, moreover, as a fabric for the top combat clothing We use a heat-resistant fabric made of polyphenylene oxadiazole fiber yarn and Rusar multifilament yarn, as well as a Cromwell F600 safety helmet with a high level of comfort and a protective vest, and the protective vest consists of a fabric lining connected to the protective shell and a fabric the elastic frame is fixed to the lining by means of the clips on the waist belt of the trousers, and the protective shell is attached to the elastic frame racks and contains external and internal protective packages, between which the gasket is placed, you filled in the form of a tape with fixed folds placed at a constant step from the side of the protected object, and placed sequentially in two outer shells, and the outer bag facing the operator’s environment is multilayer, each layer made in the form of interconnected rings, the quality of the material of which stainless steel is used, the layers are arranged with overlapping lumen of the rings by their articulation, and the inner protective package is made of three layers, while the layer in contact with the outer shell a spectacle, and the layer facing the operator’s body is made of perforated polymeric material, for example, aramid fiber, and the intermediate layer located between them is made elastic of elastic mesh elements, while the density of the mesh structure of elastic-elastic mesh elements is in the optimal range of values 1.2 g / cm ³ ... 2.0 g / cm ³ , moreover, the material of the wire of the elastic mesh elements is steel grade EI-708, and its diameter is in the optimal range of 0.09 mm ... 0.15 mm, characterized in that the protective shell The protective package contains layers of the outer shell of, for example, aramid fabric impregnated with a polymeric binder, hard-alloy curvilinear or plane-variable inserts and similar outer layers of the inner shell, and the inserts are made of unit cells bonded to each other and to the shells with glue chemically compatible with the binder shells, the inserts are made of an isotropic material, such as ceramic, with a minimum linear cell size exceeding their double thickness, and elastic s based synthetic elastomer, such as polyurethane injection, the cells can be made square and are arranged in a staggered manner or in the form of a regular hexagon.

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