RU2540375C1 - Clothes for rescuers operating under extreme, seismically dangerous conditions combined with radioactive emission - Google Patents

Abstract

FIELD: personal use articles.

SUBSTANCE: clothes for rescuers operating under extreme, seismically dangerous conditions combined with radioactive emission consist of a jacket for protection against mechanical impacts, a bib overall, a vest and a rescuer headpiece. The protective jacket has a protective shell consists of a textile lining connected to the protective shells; fixed in the textile lining by means of belt fixtures are resilient framework posts with the protective shells mounted on the resilient framework posts; the protective shell consists of three layers; the first layer turned towards the environment surrounding the operator is designed in the form of interconnected rings made of stainless steel while the third layer turned towards the operator body is made of a perforated polymer material such as aramid fibre; the second layer positioned in between is made resilient, composed of ferromagnetic textile containing a base, a binding polymer substance and a ferromagnetic material powder. The textile base is woven by plain weave with warp and filling filaments alternatively represented by lavsan filaments and magnetically soft monofilaments, the number of filaments per 1 m equal to 5000÷7000; magnetically soft monofilaments arte made of supermalloy or molybdenum permalloy with cross section size equal to 0.05÷0.1 mm; lavsan filaments have linear density equal to 10÷20 tex; the ferromagnetic powder is represented by high-coercitivity alloy powder. The ration of components in the textile (wt %) is as follows: lavsan filaments - 10÷15; magnetically soft monofilaments - 20÷25; binding polymer material (acryl copolymers) - 10÷15; high-coercitivity alloy powder - 50÷55.

EFFECT: increased efficiency of protection under extreme, seismically dangerous conditions combined with radioactive emission by way of application of a ferromagnetic material with improved indices of radioactive emission absorption and scattering and increased strength.

8 dwg

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.

The closest technical solution to the claimed object is the clothes of rescuers according to the patent of the Russian Federation No. 2495610, publ. BI No. 29 dated 10.20.13 [prototype], consisting of a protective jacket from mechanical stress, semi-overalls, a vest, vibration-proof shoes and a lifeguard helmet, while the protective jacket is made with a protective shell consisting of a fabric lining connected to the protective shells in a fabric the elastic frame racks are fixed to the lining by means of the clips on the belt, the protective shells are mounted on the elastic frame racks, and the protective shell is made of three layers.

A disadvantage of the known design of lifeguard clothes is the relatively low protection against the mechanical action of the lifeguard in the conditions of flying and falling objects of a collapsing object, as well as in conditions of radioactive radiation.

A technically achievable result is an increase in the efficiency of protection of a lifeguard in seismically hazardous conditions in combination with radioactive radiation through the use of ferromagnetic material with increased absorption and scattering of radioactive radiation, as well as its increased strength.

This is achieved by the fact that in the clothes of rescuers operating in extreme seismic hazardous conditions in combination with radioactive radiation, consisting of a protective jacket from mechanical stress, semi-overalls, a vest, vibration-proof shoes and a lifeguard helmet, the protective jacket is made with a protective sheath, consisting of a fabric lining connected to the protective shells, elastic frame racks are fixed in the fabric lining by means of latches on the belt, and the protective shells are mounted on elastic frame racks the protective shell is made of three layers, the first layer facing the operator’s environment, made in the form of interconnected rings, the material of which is stainless steel, 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 elastic of ferromagnetic fabric containing a base, a binder polymer substance and a powder of ferromagnetic material, while the fabric base is made by the method weaving with plain weave, while the main and weft threads are made of alternating dacron and soft magnetic monofilaments, the number of threads per meter is 5000 ÷ 7000, soft magnetic monofilaments are made of superalloy or molybdenum permalloy with a cross-sectional size of 0.05 ÷ 0.1 mm, and lavsan filaments have a linear density of 10–20 tex, a highly coercive alloy powder is used as a ferromagnetic powder, and the content of components in the fabric by mass is in the ratio, wt.%: lavsan filament 10–15; monofilament of soft magnetic material 20 ÷ 25; polymer binder - acrylic copolymers 10 ÷ 15; highly coercive alloy powder 50 ÷ 55.

Figure 1 shows the frontal projection of the design of the protective jacket from mechanical stress, figure 2 is its profile projection, figure 3 is a diagram of the protective shell of the protective jacket, figure 4 is a General view of the clothes of lifeguards, figure 5 is a General view of the lifeguard helmet, FIG. 6 shows a general view of vibration-proof shoes, FIG. 7 shows elastic-damping elements in the heel of the shoe, and FIG. 8 shows elastic-damping elements in the sole.

Clothing of rescuers operating in extreme seismic-hazardous conditions in combination with radioactive radiation (Fig. 4) consists of a protective jacket from mechanical impact (Figs. 1, 2) with a protective shell (Fig. 3) and a rescue helmet (Fig. 4). 5).

Lifeguard clothes (Fig. 4) includes a protective jacket 1, which has a central zipper on the front side 11, closed with a windproof valve on the buttons (not shown in the drawing), side and vertical welt pockets with a “zipper”, volumetric patch a pocket for a walkie-talkie and a welt pocket with a "zipper" on the shoulder yoke left and right, respectively (not shown in the drawing). There is a welt pocket with a flap on the right sleeve. On the back of the jacket is the inscription "EMERCOM OF RUSSIA." On the bottom of the jacket is pulled together by a cord 12 with clamps. The bottom of the sleeves is treated with a cuff, tightened with an elastic tape and a strap with a textile fastener. The set-in hood 10, which is retractable in a pocket on the collar, has adjustment according to the front cut-out with the help of an elastic cord. Reflective stripes are sewn along the chest line, on the bottom of the jacket, on the front and on the back, and also on the bottom of the sleeves. The removable insulation, fastened to the sides of the jacket with a "zipper", has front patch pockets and a knitted collar in front.

Semi-overalls 8 has a zipper closure, closed by a valve on the buttons, as well as stitched straps, the free ends of which are attached to the front upper part with zupfer locks. Side welt pockets with a zipper are placed below the waistline of the semi-overalls, a welt pocket with a zipper is located on the right of the chest line on the right, and side welt pockets with a textile fastener in the knee area, including on the right is a pocket for a knife (not shown in the drawing). Five loops are located along the waistline. The knee area and the seating area are reinforced with pads (not shown in the drawing). The bottom of the overalls has pockets with "zippers" and cords with a retainer covering the vibration-proof shoes 9. Reflective strips are sewn below the knee area. The removable insulation, fastened to the jumpsuit on top with buttons, has a zipper fastener, a drawstring with a cord along the waistline, knitted erasers and dowels. The vest is made of one-piece with fixation on a textile fastener and has a retroreflective strip at the bottom. On the back of the vest is the inscription "EMERCOM OF RUSSIA."

The design of the protective jacket from mechanical stress (Figs. 1, 2) consists of a fabric lining 1, in which the elastic frame racks 2 are fixed by means of the clips 4 on the belt 5. The protective shells 3 are mounted on the elastic frame racks 2. The protective shells 3 are mounted on the frame racks 2 over the entire area of the lifeguard torso.

Each of the protective shells 3 is made three-layer, and the first layer facing the environment of the lifeguard is made in the form of interconnected rings, the material of which is stainless steel. The third layer 6, facing the body of the rescuer, is made of perforated polymer material, for example, aramid fiber, and the second layer 7 located between them is made of elastic ferromagnetic fabric containing a base, a binder polymer substance and a powder of ferromagnetic material, while the fabric base by weaving by plain weaving, while the main and weft threads are made of alternating dacron and soft magnetic monofilaments, the number of threads per meter is 5000 ÷ 7000, magnetically soft mononi and are made of supermalloy or molybdenum permalloy with a cross-sectional size of 0.05–0.1 mm, and mylar threads have a linear density of 10–20 tex, a highly coercive alloy powder is used as a ferromagnetic powder, and the content of components in the fabric by weight is in the ratio , wt.%: lavsan filament 10 ÷ 15; monofilament of soft magnetic material 20 ÷ 25; polymer binder - acrylic copolymers 10 ÷ 15; highly coercive alloy powder 50 ÷ 55.

The lifeguard’s clothes are also equipped with a lifeguard helmet (Fig. 5) of the “Cromwell ER1” type, designed for trips to rescue operations in various accidents where the use of a fire helmet is not required (accident, fires in the forest, rescue operations on the water, search and rescue of victims under rubble, industrial accidents). The Cromwell ER1 helmet is made of thermoplastic (high temperature resistant PVC). Visor and glasses - polycarbonate.

Vibro-protective shoes consist of an internal protective toe 13 (Fig.6-8) made of composite material that protects against shock. Gasket 14 eliminates possible pressure on the foot. Polyurethane pad 15 (filling) of the toe of the shoe protects the foot of the foot from mechanical damage. The insert insole 16 of an anatomical shape, together with the set-in (strobelny) insole 17 optimizes the dynamics of the foot during operation. A two-layer sole 18 with an intermediate layer of polyurethane and a layer 29 of elastic-elastic mesh elements with shock-absorbing properties and a running layer of thermoplastic polyurethane with wear-resistant properties creates comfortable conditions for the operator when working with vibroactive equipment. 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 and 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.

The details of the upper 19 shoes are made of heat-resistant waterproof leather, and the lining 20 of the shoes is made of leather split. The protector of the sole 21 is made with increased adhesion to the surfaces of the operator’s working area, and the hard back 22 of thermoplastic material protects the heel of the operator from mechanical and thermal effects.

In the heel of the shoe (Fig. 7), under the insert insole 16 of an anatomical shape, there is a tab 24 of elastically damping elements containing a support plane with bushings 25 fixed on it, in which elastic elements are located, for example, springs 23 in contact with the damping block made three-layer and containing plates 26 and 28 of a hard vibration-damping material, for example, of the type "Agate", between which is a layer of polyurethane 27, damping vibration at medium frequencies. The elastic elements in contact with the damping block are made in the form of conical springs 23 having equal-frequency properties, while the coils of the springs 23 are covered with a layer of vibration-damping mastic (not shown in the drawing).

The inner protective toe cap 13, made of composite material, is made in the form (in the section of the upper part) of the arch type (not shown in the drawing), and on top of it is a polyurethane pad 15 (filling) of the toe of the shoe, which is also made in this part of the arch type. When performing work belonging to the category of “heavy”, the internal protective toe cap 13 may be made of perforated metal of increased strength (not shown in the drawing).

Clothing rescuers operating in extreme, seismic-hazardous conditions in combination with radioactive radiation, works as follows.

Protective jacket 1 for rescuers also protects a person in the winter season from sudden blows from flying and falling objects of a collapsing object. The implementation of the frame racks 2 elastic allows you to soften the shock, protective shells 3 prevent injury to the skin of the lifeguard and increase the absorption and scattering of radioactive radiation when it passes through the material, and also increase the overall strength of the protective jacket 1.

By magnetizing the fabric in different directions, using soft magnetic monofilaments made of supermalloy or molybdenum permalloy, applying an external magnetic field of different sizes, varying its direction, you can control the characteristics of the magnetic field created by the fabric as a whole and in microvolumes limited by soft magnetic monofilaments. Changing the magnetic field in the above zones allows you to control the properties of magnetic systems that use ferromagnetic tissue, as well as the process of shielding radioactive radiation when changing the wavelength and power of this radiation.

Vibration protection shoes 9 works as follows.

The inner protective toe cap 13, made of composite material, protects against shock, and the gasket 14 eliminates possible pressure on the foot. A polyurethane pad 15 (filling) of the toe of the shoe protects the foot of the foot from mechanical damage, and an insert insole 16 of an anatomical shape optimizes the dynamics of the foot during operation.

A two-layer sole 18 with an intermediate layer of polyurethane and a layer 29 of elastic-elastic mesh elements with shock-absorbing properties creates comfortable conditions for the operator when working with vibroactive equipment. The protector of the sole 21 is made with increased adhesion to the surfaces of the operator’s working area, and in the heel of the shoe, under the insert insole 16 of an anatomical shape, there is a tab 24 made of elastic damping elements that provide vibration protection and damping at medium frequencies. The elastic elements in the form of conical springs 23 have equal frequency properties, therefore, they will compensate for the change in operator weight in connection with the performance of heavy work with weight transfer.

Helmet ER1 (figure 5) can also be used by paramedics, lifeguards on the water and civil defense - it is equipped with goggles and an accessory for optional ear protection. In addition, this helmet can be made for use in a helicopter (not by pilots), coastguards and airborne marine rescuers, etc. When developing the helmet, international anthropometric data were used for men and women - members of the fire and rescue teams. These data include differences of many ethnic groups, which makes this helmet convenient for use in all countries by representatives of any nationalities.

Using the proposed device will significantly increase the safety of rescuers in the conditions of flying and falling objects of a collapsing object, as well as in extreme, seismically dangerous conditions in combination with radioactive radiation.

Claims (1)

Clothing of rescuers operating in extreme seismic-hazardous conditions in combination with radioactive radiation, consisting of a protective jacket from mechanical impact, semi-overalls, vest, vibration-proof shoes and a lifeguard helmet, while the protective jacket is made with a protective shell consisting of a fabric lining connected with protective shells, and elastic frame racks are fixed in the fabric lining by means of clamps on the belt, and protective shells are mounted on elastic frame racks, the protective shell is three-layer, and the first layer facing the operator’s environment is made in the form of interconnected rings, the material of which is stainless steel, the third layer facing the operator’s body is made of perforated polymeric material, for example aramid fiber, characterized in that the second layer located between them is made elastic of ferromagnetic fabric containing a base, a binder polymer substance and a powder of ferromagnetic material, while the fabric base is made by the method of quality plain weaving, while the main and weft yarns are made of alternating dacron and soft magnetic monofilaments, the number of threads per meter is 5000 ÷ 7000, the soft magnetic monofilaments are made of superalloy or molybdenum permalloy with a cross-section size of 0.05 ÷ 0.1 mm, and mylar the filaments have a linear density of 10 ÷ 20 tex, a highly coercive alloy powder is used as a ferromagnetic powder, and the content of components in the fabric by mass is in the ratio, wt.%: lavsan filament 10 ÷ 15; monofilament of soft magnetic material 20 ÷ 25; polymer binder - acrylic copolymers 10 ÷ 15; highly coercive alloy powder 50 ÷ 55.

Images